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BOOK OF ELECTRICAL ELECTRICAL ENGINEERING CONTENTS Electrical Hazards ............................................................................................................... 2 Physiological effects of electricity ...................................................................................... 3 SOLAS Requirements……………………………………………………………………..6 Safety Requirements of Electrical equipments ................................................................... 6 Ship’s Electrical system .................................................................................................... 23 Power Distribution System ............................................................................................... 24 Insulated and earthed neutral system ................................................................................ 26 Distribution Circuit Breakers ............................................................................................ 31 Transformers ..................................................................................................................... 31 Instrument Transformers ................................................................................................... 35 Shore Supply Connection ................................................................................................. 36 Circuit Protection .............................................................................................................. 38 Cables................................................................................................................................ 43 Principle of 3 phase A.C. generation ................................................................................ 45 Alternator construction ..................................................................................................... 47 Automatic Voltage Regulation ......................................................................................... 50 Alternators in parallel ....................................................................................................... 51 Generator protection ......................................................................................................... 53 Main Switchboard ............................................................................................................. 53 Main Circuit Breakers ....................................................................................................... 54 Single phase a.c. motor ..................................................................................................... 57 3 Phase AC induction motors ........................................................................................... 58 3 phase squirrel cage induction motor .............................................................................. 60 Motor Starters ................................................................................................................... 61 Contactors ......................................................................................................................... 65 Induction Motor Speed Control ........................................................................................ 66 Motor Protection ............................................................................................................... 68 Single-phasing................................................................................................................... 70 Motor enclosures ............................................................................................................... 71 Insulation class .................................................................................................................. 72 Electrical Practice for Tankers .......................................................................................... 73 Stroboscopic effect of light ............................................................................................... 76 Navigation and Signal Lights............................................................................................ 77 Electrical Diagrams ........................................................................................................... 78 Battery ............................................................................................................................... 81 Rev 1 Dated: 01.02.2012 Page 1 of 86 Electrical Hazards 1. Electrical shock 2. Electrical fire 3. Non-operation of essential equipments 4. Incorrect operation of equipments 1. Electrical shock A person may be electrocuted. We will study the physiological effects of electrocution on human body and immediate assistance and first aid to be provided to the victim later on. 2. Electrical Fires There is a second major hazard of fire or an explosion due to electrical causes. When, you read in a newspaper regarding any big fires, the cause normally given is “due to electrical short circuit”. ELECTRICAL CAUSES OF FIRE I. Fires due to use of electricity as a form of heat II. Fires caused due to overloading of wires and equipment III. Fault in wiring IV. Things stored below transmission line due to earth fault currents Fires due to use of electricity as a form of heat This group includes such fires as those due to pans of fat boiling over or material being dropped over electric heaters. Leaving electric irons ‘on’ and then going to do some petty job and totally forgetting about the iron has caused many fires. Fires caused due to overloading of wires and equipment Overloading leads to overheating which ultimately leads to fire. Fuses and miniature circuit breakers (MCB’s) are meant to prevent overloading. Fault in wiring The shorts occurring between phase wires or between phase and neutral or earth gives rise to sparks and heat. If faults occur in places where easily combustible materials are lying around, fire will take place. Fuse or MCB’s cannot stop this as they come into action only after the short circuit has taken place. The heat and sparks produced cause the damage and they are already there although the fuse has blown or the MCB has tripped. Things stored below transmission line due to earth fault currents It is better to leave the space below transmission line free of easily combustible materials. With proper earth wires such fires are totally avoided but if earth wire is broken it takes some time to replace it. In that interval some mishap can take place. Fire Extinguishing Great care is required in case of extinguishing fire where electricity is also present. Water is not the right fire-extinguishing agent where electricity is concerned. Since water is a good conductor of electricity, there are chances that the person pouring water may get severe shock. The right extinguishing agent for such fires is carbon dioxide or dry powder. Burns Fire and burns generally go hand in hand. Human beings are intolerant of even quite moderate heat. Temperatures above 65 degree C are tolerated for only limited periods. Above 90 degree C, the tolerance time drops sharply. 120 degree C can be tolerated for 15 minutes, 145 degree C becomes intolerable in 5 minutes and at 175 degree C, irreversible injury occurs to the skin in less than one minute. Generally in a fire, temperature may reach 150 degree C 3 metres ahead of the blaze and over 500 degree C above the fire. Burns classification Rev 1 Dated: 01.02.2012 Page 2 of 86 The severity of burn is determined by many factors. They are intensity of heat, the length of exposure, size of body area burnt, the thickness of skin, the age and health of victim and the speed of subsequent cooling. Degree of burn • First degree - When skin is reddened but there is no blistering • Second degree - Includes reddening and blistering but does not destroy the full thickness of the skin. In such cases new skin can grow from uninjured cells below • Third degree - Where full thickness of skin is destroyed, injuring all cells below. No chances of new skin growing. Skin grafting will become necessary Care of burn Generally if a burn hurts, it is a good sign. A full thickness burn (3rd degree) destroys the nerve endings and does not hurt. A wound that hurts will heal if proper care is taken. Danger is always involved if a burn becomes infected. Pathogenic bacteria i.e. the germs that can cause infection are everywhere. Hence no burn should be neglected. Any burn more than 3 cm square needs a doctor’s care. Cold Water One can actually decrease the severity of a burn if the skin is cooled quickly by pouring cold water. If you wait for 5 minutes and then put cold water on broken blisters, more harm than good is done by introducing pathogenic bacteria in the wound. Quickness is essential, if cold water is to be used. 3. Non-operation of essential equipment This may make the ship unsafe resulting in loss of life, loss of ship, loss of cargo and possibly a hazard to nearby people and floating/fixed objects. 4. Incorrect operation of equipment Can be injurious/ harmful to operator and others on board the ship Physiological effects of electricity 1. Heat and burn 2. Preventing muscles from acting 3. Effect heart muscles Heat and burn Effect of electricity on living tissue: current makes it heat up. If the amount of heat generated is sufficient, the tissue may be burnt. The effect is physiologically the same as damage caused by an open flame or other high-temperature source of heat, except that electricity has the ability to burn tissue well beneath the skin of a victim, even burning internal organs. Preventing muscles from acting “Nerve cells" process and conduct the multitude of signals responsible for regulation of many body functions. The brain, spinal cord, and sensory/motor organs in the body function together to allow it to sense, move, respond, think, and remember. Nerve cells communicate to each other by acting as "transducers:" creating electrical signals (very small voltages and currents). Prevents muscles from acting If electric current of sufficient magnitude is conducted through a human body, its effect will be to override the tiny electrical impulses normally generated by the nerve cells, overloading the nervous system and preventing both reflex and volitional signals from being able to actuate muscles. Muscles triggered by an external current will involuntarily contract, Medically, this condition of involuntary muscle contraction is called tetanus. Temporary immobilization Rev 1 Dated: 01.02.2012 Page 3 of 86 Even when the current is stopped, the victim may not regain voluntary control over their muscles for a while, as the neurotransmitter chemistry has been thrown into disarray. A wellplaced shock has the effect of temporarily (a few minutes) immobilizing the victim. Effect of current on heart The diaphragm muscle controlling the lungs and the heart (which is a muscle in itself) can also be "frozen" in a state of tetanus by electric current. Currents are able to scramble nerve cell signals so that the heart cannot beat properly, sending the heart into a condition known as fibrillation. Fibrillating heart A fibrillating heart flutters rather than beats, and is ineffective at pumping blood to vital organs in the body. In any case, death from asphyxiation and/or cardiac arrest will surely result from a strong enough electric current through the body. Shock current path Without two contact points on the body for current to enter and exit, respectively, there is no hazard of shock. Body resistance varies depending on how contact is made with the skin: is it from hand-to-hand, hand-to-foot, foot-to-foot, hand-to-elbow, etc. Decrease in body resistance Sweat, being rich in salts and minerals, is an excellent conductor of electricity for being a liquid. So is blood, with its similarly high content of conductive chemicals. Thus, contact with a wire made by a sweaty hand or open wound will offer much less resistance to current than contact made by clean, dry skin. Effect of current 60 Hz A.C. • Slight sensation felt at hand – 0.4 mA • Threshold of perception – 1.1 mA • Painful, but voluntary muscle control maintained – 9 mA • Painful, unable to let go wires – 16 mA • Severe pain, difficulty in breathing – 23 mA • Possible heart fibrillation after 3 sec. – 100 mA Resistance of human body • Clean dry skin – 1MΏ • Water on fingers or with sweat – 17 kΏ • With ring on a finger – 1 kΏ Current to induce tetanus • Size of shock current is related to applied voltage and body resistance. • For 16 mA to induce tetanus E=IR • Dry skin: E=(16mA)(1MΏ)=16 kV • Wet hand: E=(16mA)(17kΏ)=272 V • With gold ring: E=(16mA)(1kΏ)=16 V Heart fibrillation For 100 mA to induce heart fibrillation E=IR • Dry skin: E=(100mA)(1MΏ)=100 kV • Wet hand: E=(100mA)(17kΏ)=1700 V • With gold ring: E=(100mA)(1kΏ)=100 V Portable tools and hand lamps In marine industry, voltage of 60 V and below is considered safe for portable hand. Step down transformers are used with portable tools and hand lamps. It is still an excellent idea to keep one's hands clean and dry, and remove all metal jewelry when working around electricity. Metal jewelry Rev 1 Dated: 01.02.2012 Page 4 of 86 Even around lower voltages, metal jewelry can present a hazard by conducting enough current to burn the skin if brought into contact between two points in a circuit. Metal rings, especially, have been the cause of more than a few burnt fingers by bridging between points in a low-voltage, high-current circuit. Hand to hand shock current The path current takes through the human body makes a difference as to how harmful it is. Current will affect whatever muscles are in its path, and since the heart and lung (diaphragm) muscles are probably the most critical to one's survival, shock paths traversing the chest are the most dangerous. This makes the hand-to-hand shock current path a very likely mode of injury and fatality. Work with right hand To guard against such an occurrence, it is advisable to only use only one hand to work on live circuits. Of course, it is always safer to work on a circuit when it is unpowered. For one-handed work, the right hand is generally preferred over the left for two reasons: 1. most people are right-handed (thus granting additional coordination when working), 2. and the heart is usually situated to the left of center in the chest cavity. Add resistance The best protection against shock from a live circuit is resistance, and resistance can be added to the body through the use of insulated tools, gloves, boots, and other gear. Current in a circuit is a function of available voltage divided by the total resistance in the path of the flow. Emergency response If you see someone lying unconscious or "froze on the circuit," the very first thing to do is shut off the power by opening the appropriate circuit breaker. If you do not know the appropriate circuit breaker, then trip the generator from main switchboard. Remember life is very precious. Don’t be a dead hero If someone touches another person being shocked, there may be enough voltage dropped across the body of the victim to shock the would-be rescuer, thereby "freezing" two people instead of one. Don't be a hero. Electrons don't respect heroism. Make sure the situation is safe for you to step into, or else you will be the next victim, and nobody will benefit from your efforts. Cardiopulmonary resuscitation (CPR) Once the victim has been safely disconnected from the source of electric power, the immediate medical concerns for the victim should be respiration and circulation (breathing and pulse). You should follow the appropriate steps of checking for breathing and pulse, then applying CPR as necessary to keep the victim's body from deoxygenating. The cardinal rule of CPR is to keep going until you have been relieved by qualified personnel. Physiological shock There is the possibility of the victim going into a state of physiological shock (a condition of insufficient blood circulation) so he should be kept as warm and comfortable as possible. An electrical shock insufficient to cause immediate interruption of the heartbeat may be strong enough to cause heart irregularities or a heart attack up to several hours later, so the victim should pay close attention to their own condition after the incident. Safe Practices If possible, shut off the power to the circuit before performing any work on it. Some basic safety considerations are given below: 1. Isolate all equipment and apparatus from the supply before carrying out any work on circuits or equipment in them. 2. Apply tests (using lamps or other indicating devices) to ensure that a circuit is ‘dead’ before working on it. 3. Wear protective clothing where you are required to do so 4. Use the correct tools and equipment Rev 1 Dated: 01.02.2012 Page 5 of 86 5. Double-check all apparatus and the electrical supply before switching on 6. When current flow in a highly inductive circuit is suddenly interrupted, the collapsing magnetic field will induce a large current flow: also, if a circuit containing capacitors has been isolated, considerable electric charge may be stored in the system. 7. Check all apparatus to ensure that there is no danger from faulty or poor connections or damaged insulation. 8. Isolate equipment or apparatus from the supply if there are indications of overheating or sparking. Action after incident 1. Isolate the supply from the equipment and the person 2. No one approaches the person without isolating the supply to the equipment. 3. A casualty will have suffered burns and shock and must be treated according to the degree of damage sustained – even to applying artificial respiration or chest compression in serious incidents. Safety Requirements of Electrical equipments The ship is designed and built and the operating staff is to maintain the vessel and its electrical installation to their requirements of following throughout the ship’s lifetime. 1. Various national organisations 2. International Maritime Organization (IMO) 3. Classification Societies 4. Various international organisations 1. Various National Organisations For Indian registered ships, it is necessary to comply, with: • The Merchant Shipping Act, 1958 • Bureau of Indian Standards (BIS) • Institute of Electrical Engineers (IEE) 2. International Maritime Organization (IMO) The International Maritime Organization (IMO) is a specialised agency of the United Nations devoted to maritime affairs. Of all the international conventions made by IMO, the most important is the International Convention for the Safety of Life at Sea,1974 (SOLAS 1974), which covers a wide range of measures designed to improve the safety of shipping. SOLAS 1974 This Convention has twelve chapters. Electrical regulations are part of Chapter II-1, which outlines the requirements for Ship construction - sub-division and stability, machinery and electrical installations. This Chapter has five Parts as follows: • Part A - General • Part B - Sub-division and stability • Part C - Machinery installations • Part D - Electrical installations • Part E - Additional requirements for periodically unattended machinery spaces Electrical Installations The electrical installations (Part D) is sub-divided into regulations as: • Regulation 40 - General • Regulation 41 - Main source of electrical power and lighting systems • Regulation 42 - Emergency source of electrical power in passenger ships • Regulation 43 - Emergency source of electrical power in cargo ships • Regulation 44 - Starting arrangements for emergency generator sets • Regulation 45 - Precautions against shock, fire and other hazards of electrical origin Rev 1 Dated: 01.02.2012 Page 6 of 86 Regulation 40 General 1. Electrical installations shall be such that: 1.1 All electrical auxiliary services necessary for maintaining the ship in normal operational and habitable conditions will be ensured without recourse to the emergency source of electrical power 1.2 Electrical services essential for safety will be ensured under various emergency conditions, and 1.3 The safety of passengers, crew and ship from electrical hazards will be ensured. 2. The Administration shall take appropriate steps to ensure uniformity in the implementation and application of the provisions of this part in respect of electrical installations. Regulation 41 Main source of electrical power and lighting systems 1.1 A main source of electrical power of sufficient capacity to supply all those services mentioned in regulation 40.1.1 shall be provided. This main source of electrical power shall consist of at least two generating sets. 1.2 The capacity of these generating sets shall be such that in the event of any one generating set being stopped it will still be possible to supply those services necessary to provide normal operational conditions of propulsion and safety. Minimum comfortable conditions of habitability shall also be ensured which include at least adequate services for cooking, heating, domestic refrigeration, mechanical ventilation, sanitary and fresh water. 1.3 The arrangements of the ship’s main source of electrical power shall be such that the services referred to in regulation 40.1.1 can be maintained regardless of the speed and direction of rotation of the propulsion machinery or shafting. 1.4 In addition, the generating sets shall be such as to ensure that with any one generator or its primary source of power out of operation, the remaining generating sets shall be capable of providing the electrical services necessary to start the main propulsion plant from a dead ship condition. The emergency source of electrical power may be used for the purpose of starting from a dead ship condition if its capability either alone or combined with that of any other source of electrical power is sufficient to provide at the same time those services required to be supplied by regulations 42.2.1 to 42.2.3 or 43.2.1 to 43.2.4. 1.5 Where transformers constitute an essential part of the electrical supply system required by this paragraph, the system shall be so arranged as to ensure the same continuity of the supply as is stated in this paragraph. 2.1 A main electric lighting system which shall provide illumination throughout those parts of the Ship normally accessible to and used by passengers or crew shall be supplied from the main source of electrical power. Rev 1 Dated: 01.02.2012 Page 7 of 86 2.2 The arrangement of the main electric lighting system shall be such that a fire or other casualty . in spaces containing the main source of electrical power, associated transforming equipment, if any, the main switchboard and the main lighting switchboard, will not render the emergency electric lighting system required by regulations 42.2.1 and 42.2.2 or 43.2.1, 43.2.2 and 43.2.3 inoperative 2.3 The arrangement of the emergency electric lighting system shall be such that a fire or other casualty in spaces containing the emergency source of electrical power, associated transforming equipment, if any, the emergency switchboard and the emergency lighting switchboard will not render the main electric lighting system required by this regulation inoperative. 3. The main switchboard shall be so placed relative to one main generating station that, as far as is practicable, the integrity of the normal electrical supply may be affected only by a fire or other casualty in one space. An environmental enclosure for the main switchboard, such as may be provided by a machinery control room situated within the main boundaries of the space, is not to be considered as separating the switchboards from the generators. 4. Where the total installed electrical power of the main generating sets is in excess of 3 MW, the main busbars shall be subdivided into at least two parts which shall normally be connected by removable links or other approved means; so far as is practicable, the connection of generating sets and any other duplicated equipment shall be equally divided between the parts. Equivalent arrangements may be permitted to the satisfaction of the Administration. 5. Ships constructed on or after 1 July 1998: .1 in addition to paragraphs 1 to 3, shall comply with the following: .1.1 where the main source of electrical power is necessary for propulsion and steering of the ship, the system shall be so arranged that the electrical supply to equipment necessary for propulsion and steering and to ensure safety of the ship will be maintained or immediately restored in the case of loss of any one of the generators in service; .1.2 load shedding or other equivalent arrangements shall be provided to protect the generators required by this regulation against sustained overload; .1.3 where the main source of electrical power is necessary for propulsion of the ship, the main busbar shall be subdivided into at least two parts which shall normally be connected by circuit breakers or other approved means; so far as is practicable, the connection of generating sets and other duplicated equipment shall be equally divided between the parts; and .2 need not comply with paragraph 4. Regulation 42 Emergency source of electrical power in passenger ships 1.1 A self-contained emergency source of electrical power shall be provided. 1.2 The emergency source of electrical power, associated transforming equipment, if any, transitional source of emergency power, emergency switchboard and emergency lighting switchboard shall be located above the uppermost continuous deck and shall be readily accessible from the open deck. They shall not be located forward of the collision bulkhead. 1.3 The location of the emergency source of electrical power and associated transforming equipment, if any, the transitional source of emergency power, the emergency switchboard Rev 1 Dated: 01.02.2012 Page 8 of 86 and the emergency electric lighting switchboards in relation to the main source of electrical power, associated transforming equipment, if any, and the main switchboard shall be such as to ensure to the satisfaction of the Administration that a fire or other casualty in spaces containing the main source of electrical power, associated transforming equipment, if any, and the main switchboard or in any machinery space of category A will not interfere with the supply, control and distribution of emergency electrical power. As far as practicable, the space containing the emergency source of electrical power, associated transforming equipment, if any, the transitional source of emergency electrical power and the emergency switchboard shall not be contiguous to the boundaries of machinery spaces of category A or those spaces containing the main source of electrical power, associated transforming equipment, if any, or the main switchboard. be such as to ensure to the satisfaction of the Administration that a fire or other casualty in spaces containing the main source of electrical power, associated transforming equipment, if any, and the main switchboard or in any machinery space of category A will not interfere with the supply, control and distribution of emergency electrical power. As far as practicable, the space containing the emergency source of electrical power, associated transforming equipment, if any, the transitional source of emergency electrical power and the emergency switchboard shall not be contiguous to the boundaries of machinery spaces of category A or those spaces containing the main source of electrical power, associated transforming equipment, if any, or the main switchboard. 1.4 Provided that suitable measures are taken for safeguarding independent emergency operation under all circumstances, the emergency generator may be used exceptionally, and for short periods, to supply non-emergency circuits. The electrical power available shall be sufficient to supply all those services that are essential for safety in an emergency, due regard being paid to such services as may have to be operated simultaneously. The emergency source of electrical power shall be capable, having regard to starting currents and the transitory nature of certain loads, of supplying simultaneously at least the following services for the periods specified hereinafter, if they depend upon an electrical source for their operation: For a period of 36 h, emergency lighting: .1 at every muster and embarkation station and over the sides as required by regulations III/11.4 and III/16.7; .2 in alleyways, stairways and exits giving access to the muster and embarkation stations, as required by regulation III/11.5; 3 in all service and accommodation alleyways, stairways and exits, personnel lift cars; .4 in the machinery spaces and main generating stations including their control positions; .5 in all control stations, machinery control rooms, and at each main and emergency switchboard; .6 at all stowage positions for firemen’s outfits; Rev 1 Dated: 01.02.2012 Page 9 of 86 .7 at the steering gear; and .8 at the fire pump, the sprinkler pump and the emergency bilge pump referred to in paragraph 2.4 and at the starting position of their motors. For a period of 36 h: .1 the navigation lights and other lights required by the International Regulations for Preventing Collisions at Sea in force; and .2 on ships constructed on or after 1 February 1995, the VHF radio installation required by regulation IV/7.1.1 and IV/7.1.2; and, if applicable: .2.1 the MF radio installation required by regulations IV/9.1.1, IV/9.1.2, IV/10.1.2 and IV/10.1.3; .2.2 the ship earth station required by regulation IV/10.1.1; and .2.3 the MF/HF radio installation required by regulations IV/ 10.2.1, IV/10.2.2 and IV/11.1. For a period of 36 h: .1 all internal communication equipment required in an emergency; .2 the shipborne navigational equipment as required by regulation V/12*; where such provision is unreasonable or impracticable the Administration may waive this requirement for ships of less than 5,000 gross tonnage; .3 the fire detection and fire alarm system, and the fire door holding and release system; and .4 for intermittent operation of the daylight signalling lamp, the ship’s whistle, the manually operated call points, and all internal signals that are required in an emergency; unless such services have an independent supply for the period of 36 h from an accumulator battery suitably located for use in an emergency. For a period of 36 h: .1 one of the fire pumps required by regulation II-2/4.3.1 and 4.3.3;{ .2 the automatic sprinkler pump, if any; and .3 the emergency bilge pump and all the equipment essential for the operation of electrically powered remote controlled bilge valves. 2.5 For the period of time required by regulation 29.14 the steering gear if required to be so supplied by that regulation. 2.6 For a period of half an hour: .1 any watertight doors required by regulation 15 to be poweroperated together with their indicators and warning signals; Part D: Electrical installations Regulation 42 Rev 1 Dated: 01.02.2012 Page 10 of 86 This relates to the chapter V in force before 1 July 2002. The equivalent in the amended chapter V is regulation 19. { These relate to the chapter II-2 in force before 1 July 2002. The equivalents in the amended chapter II-2 are 10.2.2.2 and 10.2.2.3. .2 the emergency arrangements to bring the lift cars to deck level for the escape of persons. The passenger lift cars may be brought to deck level sequentially in an emergency. 2.7 In a ship engaged regularly on voyages of short duration, the Administration if satisfied that an adequate standard of safety would be attained may accept a lesser period than the 36 h period specified in paragraphs 2.1 to 2.5 but not less than 12 h. 3 The emergency source of electrical power may be either a generator or an accumulator battery, which shall comply with the following: 3.1 Where the emergency source of electrical power is a generator, it shall be: .1 driven by a suitable prime mover with an independent supply of fuel having a flashpoint (closed cup test) of not less than 438C; .2 started automatically upon failure of the electrical supply from the main source of electrical power and shall be automatically connected to the emergency switchboard; those services referred to in paragraph 4 shall then be transferred automatically to the emergency generating set. The automatic starting system and the characteristic of the prime mover shall be such as to permit the emergency generator to carry its full rated load as quickly as is safe and practicable, subject to a maximum of 45 s; unless a second independent means of starting the emergency generating set is provided, the single source of stored energy shall be protected to preclude its complete depletion by the automatic starting system; and .3 provided with a transitional source of emergency electrical power according to paragraph 4. 3.2 Where the emergency source of electrical power is an accumulator battery, it shall be capable of: .1 carrying the emergency electrical load without recharging while maintaining the voltage of the battery throughout the discharge period within 12% above or below its nominal voltage; .2 automatically connecting to the emergency switchboard in the event of failure of the main source of electrical power; and .3 immediately supplying at least those services specified in paragraph 4. 3.3 The following provisions in paragraph 3.1.2 shall not apply to ships constructed on or after 1 October 1994: Unless a second independent means of starting the emergency generating set is provided, the single source of stored energy shall 128 Rev 1 Dated: 01.02.2012 Page 11 of 86 Chapter II-1: Construction – structure, stability, installations be protected to preclude its complete depletion by the automatic starting system. 3.4 For ships constructed on or after 1 July 1998, where electrical power is necessary to restore propulsion, the capacity shall be sufficient to restore propulsion to the ship in conjunction with other machinery, as appropriate, from a dead ship condition within 30 min after blackout. 4 The transitional source of emergency electrical power required by paragraph 3.1.3 shall consist of an accumulator battery suitably located for use in an emergency which shall operate without recharging while maintaining the voltage of the battery throughout the discharge period within 12% above or below its nominal voltage and be of sufficient capacity and so arranged as to supply automatically in the event of failure of either the main or emergency source of electrical power at least the following services, if they depend upon an electrical source for their operation: 4. 1 For half an hour: 1 the lighting required by paragraphs 2.1 and 2.2; 2 all services required by paragraphs 2.3.1, 2.3.3 and 2.3.4 unless such services have an independent supply for the period specified from an accumulator battery suitably located for use in an emergency. 4.2 Power to operate the watertight doors, as required by regulation 15.7.3.3, but not necessarily all of them simultaneously, unless an independent temporary source of stored energy is provided. Power to the control, indication and alarm circuits as required by regulation 15.7.2 for half an hour. 5.1 The emergency switchboard shall be installed as near as is practicable to the emergency source of electrical power. 5.2 Where the emergency source of electrical power is a generator, the emergency switchboard shall be located in the same space unless the operation of the emergency switchboard would thereby be impaired. 5.3 No accumulator battery fitted in accordance with this regulation shall be installed in the same space as the emergency switchboard. An indicator shall be mounted in a suitable place on the main switchboard or in the machinery control room to indicate when the batteries constituting either the emergency source of electrical power or the transitional source of emergency electrical power referred to in paragraph 3.1.3 or 4 are being discharged. 5.4 The emergency switchboard shall be supplied during normal operation from the main switchboard by an interconnector feeder which is to be adequately protected at the main switchboard against overload and short circuit and which is to be disconnected automatically at the Part D: Electrical installations Regulation 4 129 emergency switchboard upon failure of the main source of electrical power. Rev 1 Dated: 01.02.2012 Page 12 of 86 Where the system is arranged for feedback operation, the interconnector feeder is also to be protected at the emergency switchboard at least against short circuit. 5.5 In order to ensure ready availability of the emergency source of electrical power, arrangements shall be made where necessary to disconnect automatically non-emergency circuits from the emergency switchboard to ensure that power shall be available to the emergency circuits. 6 The emergency generator and its prime mover and any emergency accumulator battery shall be so designed and arranged as to ensure that they will function at full rated power when the ship is upright and when inclined at any angle of list up to 22.58 or when inclined up to 108 either in the fore or aft direction, or is in any combination of angles within those limits. 7 Provision shall be made for the periodic testing of the complete emergency system and shall include the testing of automatic starting arrangements. Regulation 42-1 Supplementary emergency lighting for ro–ro passenger ships the approach to the means of escape can be readily seen. The source of power for the supplementary lighting shall consist of accumulator batteries located within the lighting units that are continuously charged, where practicable, from the emergency switchboard. Alternatively, any other means of lighting which is at least as effective may be accepted by the Administration. The supplementary lighting shall be such that any failure of the lamp will be immediately apparent. Any accumulator battery provided shall be replaced at intervals having regard to the specified service life in the ambient conditions that they are subject to in service; and 130 Chapter II-1: Construction – structure, stability, installations .2 a portable rechargeable battery operated lamp shall be provided in every crew space alleyway, recreational space and every working space which is normally occupied unless supplementary emergency lighting, as required by subparagraph .1, is provided. Regulation 43 Emergency source of electrical power in cargo ships 1.1 A self-contained emergency source of electrical power shall be provided. 1.2 The emergency source of electrical power, associated transforming equipment, if any, transitional source of emergency power, emergency switchboard and emergency lighting switchboard shall be located above the uppermost continuous deck and shall be readily accessible from the open deck. They shall not be located forward of the collision bulkhead, except where permitted by the Administration in exceptional circumstances. 1.3 The location of the emergency source of electrical power, associated transforming equipment, if any, the transitional source of emergency power, Rev 1 Dated: 01.02.2012 Page 13 of 86 the emergency switchboard and the emergency lighting switchboard in relation to the main source of electrical power, associated transforming equipment, if any, and the main switchboard shall be such as to ensure to the satisfaction of the Administration that a fire or other casualty in the space containing the main source of electrical power, associated transforming equipment, if any, and the main switchboard, or in any machinery space of category A will not interfere with the supply, control and distribution of emergency electrical power. As far as practicable the space containing the emergency source of electrical power, associated transforming equipment, if any, the transitional source of emergency electrical power and the emergency switchboard shall not be contiguous to the boundaries of machinery spaces of category A or those spaces containing the main source of electrical power, associated transforming equipment, if any, and the main switchboard. 1.4 Provided that suitable measures are taken for safeguarding independent emergency operation under all circumstances, the emergency generator may be used, exceptionally, and for short periods, to supply non-emergency circuits 2 The electrical power available shall be sufficient to supply all those services that are essential for safety in an emergency, due regard being paid to such services as may have to be operated simultaneously. The emergency source of electrical power shall be capable, having regard to starting currents and the transitory nature of certain loads, of supplying simultaneously at least the following services for the periods specified hereinafter, if they depend upon an electrical source for their operation: Part D: Electrical installations Regulation 42-1, 43 2.1 For a period of 3 h, emergency lighting at every muster and embarkation station and over the sides as required by regulations III/11.4 and III/16.7. 2.2 For a period of 18 h, emergency lighting: 1 in all service and accommodation alleyways, stairways and exits, personnel lift cars and personnel lift trunks; 2 in the machinery spaces and main generating stations including their control positions; .3 in all control stations, machinery control rooms, and at each main and emergency switchboard; .4 at all stowage positions for firemen’s outfits; .5 at the steering gear; .6 at the fire pump referred to in paragraph 2.5, at the sprinkler pump, if any, and at the emergency bilge pump, if any, and at the starting positions of their motors; and 7 in all cargo pump-rooms of tankers constructed on or after 1 July 2002. 2.3 For a period of 18 h: 1 the navigation lights and other lights required by the International Rev 1 Dated: 01.02.2012 Page 14 of 86 Regulations for Preventing Collisions at Sea in force; .2 on ships constructed on or after 1 February 1995 the VHF radio installation required by regulation IV/7.1.1 and IV/7.1.2; and, if applicable: .2.1 the MF radio installation required by regulations IV/9.1.1, IV/9.1.2, IV/10.1.2 and IV/10.1.3; .2.2 the ship earth station required by regulation IV/10.1.1; and .2.3 the MF/HF radio installation required by regulations IV/10.2.1, IV/10.2.2 and IV/11.1. 2.4 For a period of 18 h: .1 all internal communication equipment as required in an emergency; .2 the shipborne navigational equipment as required by regulation V/12;* where such provision is unreasonable or impracticable the Administration may waive this requirement for ships of less than 5,000 gross tonnage; .3 the fire detection and fire alarm system; and .4 intermittent operation of the daylight signalling lamp, the ship’s whistle, the manually operated call points and all internal signals that are required in an emergency; This relates to the chapter V in force before 1 July 2002. The equivalent in the amended chapter V is regulation 19. Chapter II-1: Construction – structure, stability, installations unless such services have an independent supply for the period of 18 h from an accumulator battery suitably located for use in an emergency. 2.5 For a period of 18 h one of the fire pumps required by regulation II-2/4.3.1 and 4.3.3* if dependent upon the emergency generator for its source of power. 2.6.1 For the period of time required by regulation 29.14 the steering gear where it is required to be so supplied by that regulation. 2.6.2 In a ship engaged regularly in voyages of short duration, the Administration if satisfied that an adequate standard of safety would be attained may accept a lesser period than the 18 h period specified in paragraphs 2.2 to 2.5 but not less than 12 h. 3 The emergency source of electrical power may be either a generator or an accumulator battery, which shall comply with the following: 3.1 Where the emergency source of electrical power is a generator, it shall be: .1 driven by a suitable prime mover with an independent supply of fuel, having a flashpoint (closed cup test) of not less than 438C; Rev 1 Dated: 01.02.2012 Page 15 of 86 .2 started automatically upon failure of the main source of electrical power supply unless a transitional source of emergency electrical power in accordance with paragraph 3.1.3 is provided; where the emergency generator is automatically started, it shall be automatically connected to the emergency switchboard; those services referred to in paragraph 4 shall then be connected automatically to the emergency generator; and unless a second independent means of starting the emergency generator is provided the single source of stored energy shall be protected to preclude its complete depletion by the automatic starting system; and .3 provided with a transitional source of emergency electrical power as specified in paragraph 4 unless an emergency generator is provided capable both of supplying the services mentioned in that paragraph and of being automatically started and supplying the required load as quickly as is safe and practicable subject to a maximum of 45 s. 3.2 Where the emergency source of electrical power is an accumulator battery it shall be capable of: .1 carrying the emergency electrical load without recharging while maintaining the voltage of the battery throughout the discharge period within 12% above or below its nominal voltage; Part D: Electrical installations Regulation 43 These relate to the chapter II-2 in force before 1 July 2002. The equivalents in the amended chapter II-2 are 10.2.2.2 and 10.2.2.3. 133 .2 automatically connecting to the emergency switchboard in the event of failure of the main source of electrical power; and .3 immediately supplying at least those services specified in paragraph 4. 3.3 The following provision in paragraph 3.1.2 shall not apply to ships constructed on or after 1 October 1994: Unless a second independent means of starting the emergency generating set is provided, the single source of stored energy shall be protected to preclude its complete depletion by the automatic starting system. 3.4 For ships constructed on or after 1 July 1998, where electrical power is necessary to restore propulsion, the capacity shall be sufficient to restore propulsion to the ship in conjunction with other machinery, as appropriate, from a dead ship condition within 30 min after blackout. 4 The transitional source of emergency electrical power where required by paragraph 3.1.3 shall consist of an accumulator battery suitably located for use in an emergency which shall operate without recharging while Rev 1 Dated: 01.02.2012 Page 16 of 86 maintaining the voltage of the battery throughout the discharge period within 12% above or below its nominal voltage and be of sufficient capacity and shall be so arranged as to supply automatically in the event of failure of either the main or the emergency source of electrical power for half an hour at least the following services if they depend upon an electrical source for their operation: 1 the lighting required by paragraphs 2.1, 2.2 and 2.3.1. For this transitional phase, the required emergency electric lighting, in respect of the machinery space and accommodation and service spaces may be provided by permanently fixed, individual, automatically charged, relay operated accumulator lamps; and 2 all services required by paragraphs 2.4.1, 2.4.3 and 2.4.4 unless such services have an independent supply for the period specified from an accumulator battery suitably located for use in an emergency. 5.1 The emergency switchboard shall be installed as near as is practicable to the emergency source of electrical power. 5.2 Where the emergency source of electrical power is a generator, the emergency switchboard shall be located in the same space unless the operation of the emergency switchboard would thereby be impaired. 5.3 No accumulator battery fitted in accordance with this regulation shall be installed in the same space as the emergency switchboard. An indicator shall be mounted in a suitable place on the main switchboard or in the machinery control room to indicate when the batteries constituting either the emergency source of electrical power or the transitional source of electrical power referred to in paragraph 3.2 or 4 are being discharged. 134 Chapter II-1: Construction – structure, stability, installations 5.4 The emergency switchboard shall be supplied during normal operation from the main switchboard by an interconnector feeder which is to be adequately protected at the main switchboard against overload and short circuit and which is to be disconnected automatically at the emergency switchboard upon failure of the main source of electrical power. Where the system is arranged for feedback operation, the interconnector feeder is also to be protected at the emergency switchboard at least against short circuit. 5.5 In order to ensure ready availability of the emergency source of electrical power, arrangements shall be made where necessary to disconnect automatically non-emergency circuits from the emergency switchboard to ensure that electrical power shall be available automatically to the emergency circuits. 6 The emergency generator and its prime mover and any emergency accumulator battery shall be so designed and arranged as to ensure that they will function at full rated power when the ship is upright and when inclined at any angle of list up to 22.58 or when inclined up to 108 either in the fore or aft direction, or is in any combination of angles within those limits. Rev 1 Dated: 01.02.2012 Page 17 of 86 7 Provision shall be made for the periodic testing of the complete emergency system and shall include the testing of automatic starting arrangements. Regulation 44 Starting arrangements for emergency generating sets 1 Emergency generating sets shall be capable of being readily started in their cold condition at a temperature of 08C. If this is impracticable, or if lower temperatures are likely to be encountered, provision acceptable to the Administration shall be made for the maintenance of heating arrangements, to ensure ready starting of the generating sets. 2 Each emergency generating set arranged to be automatically started shall be equipped with starting devices approved by the Administration with a stored energy capability of at least three consecutive starts. A second source of energy shall be provided for an additional three starts within 30 min unless manual starting can be demonstrated to be effective. 2.1 Ships constructed on or after 1 October 1994, in lieu of the provision of the second sentence of paragraph 2, shall comply with the following requirements: The source of stored energy shall be protected to preclude critical depletion by the automatic starting system, unless a second independent means of starting is provided. In addition, a second Part D: Electrical installations Regulation 44 135 source of energy shall be provided for an additional three starts within 30 in unless manual starting can be demonstrated to be effective. 2. .1 The stored energy shall be maintained at all times, as follows: electrical and hydraulic starting systems shall be maintained from the emergency switchboard; .2 compressed air starting systems may be maintained by the main or auxiliary compressed air receivers through a suitable nonreturn valve or by an emergency air compressor which, if electrically driven, is supplied from the emergency switchboard; .3 all of these starting, charging and energy storing devices shall be located in the emergency generator space; these devices are not to be used for any purpose other than the operation of the emergency generating set. This does not preclude the supply to the air receiver of the emergency generating set from the main or auxiliary compressed air system through the non-return valve fitted in the emergency generator space. 4.1 Where automatic starting is not required, manual starting is permissible, such as manual cranking, inertia starters, manually charged hydraulic accumulators, or powder charge cartridges, where they can be demonstrated as being effective. 4.2 When manual starting is not practicable, the requirements of paragraphs 2 and 3 shall be complied with except that starting may be manually initiated. Rev 1 Dated: 01.02.2012 Page 18 of 86 Regulation 45 Precautions against shock, fire and other hazards of electrical origin 1.1 Exposed metal parts of electrical machines or equipment which are not intended to be live but which are liable under fault conditions to become live shall be earthed unless the machines or equipment are: .1 supplied at a voltage not exceeding 50 V direct current or 50 V root mean square between conductors; auto-transformers shall not be used for the purpose of achieving this voltage; or .2 supplied at a voltage not exceeding 250 V by safety isolating transformers supplying only one consuming device; or .3 constructed in accordance with the principle of double insulation. 1.2 The Administration may require additional precautions for portable electrical equipment for use in confined or exceptionally damp spaces where particular risks due to conductivity may exist. 1.3 All electrical apparatus shall be so constructed and so installed as not to cause injury when handled or touched in the normal manner. 2 Main and emergency switchboards shall be so arranged as to give easy access as may be needed to apparatus and equipment, without danger to personnel. The sides and the rear and, where necessary, the front of switchboards shall be suitably guarded. Exposed live parts having voltages to earth exceeding a voltage to be specified by the Administration shall not be installed on the front of such switchboards. Where necessary, nonconducting mats or gratings shall be provided at the front and rear of the switchboard. 3.1 The hull return system of distribution shall not be used for any purpose in a tanker, or for power, heating, or lighting in any other ship of 1,600 gross tonnage and upwards. 3.2 The requirement of paragraph 3.1 does not preclude under conditions approved by the Administration the use of: 1 2 impressed current cathodic protective systems; limited and locally earthed systems; or .3 insulation level monitoring devices provided the circulation current does not exceed 30 mA under the most unfavourable conditions. 3.2–1 For ships constructed on or after 1 October 1994, the requirement of paragraph 3.1 does not preclude the use of limited and locally earthed systems, provided that any possible resulting current does not flow directly through any dangerous spaces. 3.3 Where the hull return system is used, all final subcircuits, i.e. all Rev 1 Dated: 01.02.2012 Page 19 of 86 circuits fitted after the last protective device, shall be two-wire and special precautions shall be taken to the satisfaction of the Administration. 4.1 Earthed distribution systems shall not be used in a tanker. The Administration may exceptionally permit in a tanker the earthing of the neutral for alternating current power networks of 3,000 V (line to line) and over, provided that any possible resulting current does not flow directly through any of the dangerous spaces. 4.2 When a distribution system, whether primary or secondary, for power, heating or lighting, with no connection to earth is used, a device capable of continuously monitoring the insulation level to earth and of giving an audible or visual indication of abnormally low insulation values shall be provided. Part D: Electrical installations Regulation 45 4.3 Ships constructed on or after 1 October 1994, in lieu of the provisions of paragraph 4.1, shall comply with the following requirements: 1 Except as permitted by paragraph 4.3.2, earthed distribution systems shall not be used in a tanker. 2 The requirement of paragraph 4.3.1 does not preclude the use of earthed intrinsically safe circuits and in addition, under conditions approved by the Administration, the use of the following earthed systems: 2.1 power-supplied control circuits and instrumentation circuits where technical or safety reasons preclude the use of a system with no connection to earth, provided the current in the hull is limited to not more than 5 A in both normal and fault conditions; or 2.2 limited and locally earthed systems, provided that any possible resulting current does not flow directly through any of the dangerous spaces; or 2.3 alternating current power networks of 1,000 V root mean square (line to line) and over, provided that any possible resulting current does not flow directly through any of the dangerous spaces. 5.1 Except as permitted by the Administration in exceptional circumstances, all metal sheaths and armour of cables shall be electrically continuous and shall be earthed. 5.2 All electric cables and wiring external to equipment shall be at least of a flame-retardant type and shall be so installed as not to impair their original flame-retarding properties. Where necessary for particular applications the Administration may permit the use of special types of cables such as radio frequency cables, which do not comply with the foregoing. 5.3 Cables and wiring serving essential or emergency power, lighting, internal communications or signals shall so far as practicable be routed clear of galleys, laundries, machinery spaces of category A and their casings and Rev 1 Dated: 01.02.2012 Page 20 of 86 other high fire risk areas. In ro–ro passenger ships, cabling for emergency alarms and public address systems installed on or after 1 July 1998 shall be approved by the Administration having regard to the recommendations developed by the Organization.* Cables connecting fire pumps to the emergency switchboard shall be of a fire-resistant type where they pass through high fire risk areas. Where practicable all such cables should be run in such a manner as to preclude their being rendered unserviceable by heating of the bulkheads that may be caused by a fire in an adjacent space. heating of the bulkheads that may be caused by a fire in an adjacent space. * Refer to MSC/Circ.808, Recommendation on performance standards for public address systems on passenger ships, including cabling. 5.4 Where cables which are installed in hazardous areas introduce the risk of fire or explosion in the event of an electrical fault in such areas, special precautions against such risks shall be taken to the satisfaction of the Administration. 5.5 Cables and wiring shall be installed and supported in such a manner as to avoid chafing or other damage. 5.6 Terminations and joints in all conductors shall be so made as to retain the original electrical, mechanical, flame-retarding and, where necessary, fire-resisting properties of the cable. 6.1 Each separate circuit shall be protected against short circuit and against overload, except as permitted in regulations 29 and 30 or where the Administration may exceptionally otherwise permit. 6.2 The rating or appropriate setting of the overload protective device for each circuit shall be permanently indicated at the location of the protective device. 7 Lighting fittings shall be so arranged as to prevent temperature rises which could damage the cables and wiring, and to prevent surrounding material from becoming excessively hot. 8 All lighting and power circuits terminating in a bunker or cargo space shall be provided with a multiple-pole switch outside the space for disconnecting such circuits. 9.1 Accumulator batteries shall be suitably housed, and compartments used primarily for their accommodation shall be properly constructed and efficiently ventilated. 9.2 Electrical or other equipment which may constitute a source of ignition of flammable vapours shall not be permitted in these compartments except as permitted in paragraph 10. 9.3 Accumulator batteries shall not be located in sleeping quarters except where hermetically sealed to the satisfaction of the Administration. 10 No electrical equipment shall be installed in any space where flammable mixtures are liable to collect including those on board tankers or in compartments assigned principally to accumulator batteries, in paint lockers, acetylene stores or similar spaces, unless the Administration is satisfied that such equipment is: Rev 1 Dated: 01.02.2012 Page 21 of 86 1 essential for operational purposes; 2 of a type which will not ignite the mixture concerned; 3 appropriate to the space concerned; and 4 appropriately certified for safe usage in the dusts, vapours or gases likely to be encountered. 11In a passenger ship, distribution systems shall be so arranged that fire in any main vertical zone as is defined in regulation II-2/3.9* will not interfere with services essential for safety in any other such zone. This requirement will be met if main and emergency feeders passing through any such zone are separated both vertically and horizontally as widely as is practicable. 3. Classification Societies Electrical safety requirements and regulations adopted by various classifications societies generally cover installation such as distribution systems, generators, MCB, motors and starters, cables, batteries and other ancillary services. Classification Regulation 1. Location 2. Construction 3. Earthing Location Area, where electrical equipments are installed, should be always well ventilated, easily accessible, adequately lighted, and clear of any flammable material, away from steam, oil and water pipes or otherwise properly protected from splashing of oil or water, and properly shielded so as not to have any interference on magnetic compasses. If located in dangerous zones then the equipment to be of safe type (flame proof or similar). Construction Generally main aspects of construction such as material, sharp corners on edges, insulation grades, resistance to moisture, oil, vapour etc. should be taken care off at the stage of manufacturing. However, one important aspect, that requires special attention, is tightening of screws and nuts used in connection with current carrying parts and other working parts. If neglected, it can lead to serious hazards. Creepage (distance between line metal) distances to be adequate. Earthing It is essential that non-current carrying exposed metal parts of the equipment (including portable) be effectively earthed. Protected against damage and electrolytic action exception - < 55 V. Earthing connections are of copper and 1. Equal to cross-section of cable conductors up to 16 mm2. 2. At least half the cross-section above 10 mm2 with minimum of 16 mm2 4. Various international organisations It has also to follow ‘Safe Working Practices’ as laid down by international bodies or institutes • BS – British Standardization Institute • IEC – International Electrotechnical Commission • API – American Petroleum Institute or • IP – Institute of Petroleum, UK Rev 1 Dated: 01.02.2012 Page 22 of 86 Ship’s Electrical system Auxiliary services on board ship range from engine room pumps, compressors and fans, deck winches and windlasses, to general lighting, catering and air conditioning. Electrical power is used to drive the majority of these auxiliary services. The electrical power system on board ship is designed to provide a secure supply to all loads with adequate built-in protection for the equipment and operating personnel. The general scheme of a ship’s electrical power system is common to nearly all ships. Alternators The main a.c. generators (sometimes called alternators) produce the electrical power. It is supplied to the main switchboard and then distributed to the various auxiliary services comprising the electrical load. Emergency generator An emergency generator and emergency switchboard maintain supplies in the event of a main power failure Prime mover of alternators The generators may be driven by a diesel engine, by a steam or gas turbine, or by the main propulsion engine as a shaft generator. The type of prime mover is determined by the design of the ships and by economic factors. The combined power rating of the generators is determined by the overall demand of the ship’s electrical load. Voltage and Frequency Electrical power onboard a ship is commonly generated at 440V, 60Hz (sometimes 380V, 50Hz). These values have been adopted because they are standard shore supplies in the USA and in Europe. A frequency of 60 Hz is generally a US standard and 50 Hz is a UK standard. Size of Alternators Large passenger ships usually have four large generators rated at 10 MW or more to supply the electric propulsion motors and the extensive hotel services on board. A cargo ship may have two/three main generators typically rated from 350 to 1000 kW which are sufficient to supply the engine room auxiliaries while at sea and the winches or cranes for handling cargo while in port. Emergency generator The limited load required during an emergency requires that an emergency generator may be rated from about 10 kW for a small coastal ship to about 300 kW or more for a cargo liner. The shipbuilder must estimate the number and power rating of the required generators by assessing the power demand of the load for all situations whether at sea or in port. Lighting circuit Lighting and other low power ancillary services usually operate at 110 V or 220 V, single-phase a.c. Transformers are used to reduce the 440 V system voltage to these lower voltage levels. Portable equipments Where portable equipment is to be used in dangerous, hot and ‘damp locations, it is advisable to operate at 55 V or even 24 V, supplied by a step-down transformer. Occasionally, transformers are also used to step-up voltages, e.g. supplying a large 3.3 kV bow thruster motor from a 440 V switchboard supply. Batteries Batteries for various essential services operate at 12 V or 24 V d.c. but sometimes higher voltages are used if such loads require a large power supply. Rev 1 Dated: 01.02.2012 Page 23 of 86 Power Distribution System The function of a ship’s electrical distribution system is to safely convey the generated electrical power to every item of consumer equipment connected to it. Probably the most obvious element in the system is the main distribution centre, i.e. the ship’s main switchboard. Main Switchboard The main board supplies bulk power to motor group starter boards (often part of the main board), section boards and distribution boards. Protection, e.g. circuit-breakers and fuses, strategically placed throughout the system automatically disconnects a faulty circuit within the network. Transformers Transformers inter-connect the high voltage and low voltage distribution sections of the system. Monitoring and protection The operational state of a distribution system is indicated by the monitors for power, voltage, current and by protection relays for over currents and earth-faults at each main control centre. A.C. Distribution system The vast majority of ships have an alternating current (a.c.) distribution system in preference to a direct current (d.c.) system. The required electrical services are broadly considered as main and emergency supplies. Advantages of A.C. An a.c. network is cheaper to install and operate than a d.c. system. In particular, a.c. offers a higher power/weight ratio for the generation, distribution and utilisation of electricity. Rev 1 Dated: 01.02.2012 Page 24 of 86 Simple transformers efficiently step-up or step-down a.c. voltages where required. Three-phase a.c. is effectively converted into rotary mechanical power in simple and efficient induction motors. A ship’s electrical distribution scheme generally follows shore practice. This allows normal industrial equipment to be used on board ship after being “marinised”, where necessary, to withstand the rigours of a sea-life (e.g. it must withstand the vibration, humidity, high temperature, ozone, sea-water, etc. encountered in various parts of the ship). 3 phase insulated neutral The majority of ships have a 3-phase a.c., 3-wire, 440 V insulated-neutral system. This means that the neutral point of star-connected generators is not earthed to the ship’s hull. For continental European vessels, a 380 V, 3-phase system is common. High voltage system Ships with very large electrical loads have generators operating at high voltages (HV) of 3.3 kV, 6.6 kV and even 11 kV. Such high voltages are economically necessary in high power systems to reduce the size of current, and hence reduce the size of conductors and equipment required. Frequency The frequency of an a.c. power system can be 50 Hz or 60 Hz. In Europe and most of the world the national frequency is 50 Hz but is 60 Hz in North America and in a few other countries. The most common power frequency adopted for use on board ships and offshore platforms is 60 Hz. This higher frequency means that motors and generators run at higher speeds with a consequent reduction in size for a given power rating. Lighting and low power Lighting and low power single-phase supplies usually operate at the lower voltage of 220 V a.c. although 110 V a.c. is also used. These voltages are derived from step-down transformers connected to the 440 V system. Branching system The system is called a radial or branching system. This distribution system has a simple and logical structure. Each item of load is supplied at its rated voltage via the correct size of cable and is protected by the correctly rated protection device. Essential and non-essential The main electrical load is divided into essential and non-essential services. Essential services are those required for the safety of personnel and for the safe navigation and propulsion of the ship. They include certain supplies to navigational aids, communications, machinery spaces, control stations and steering gear. The essential services may be supplied directly from the main switchboard or via section boards or distribution boards. Emergency supplies Emergency supplies are necessary for loads which are required to handle a potentially dangerous situation. Preferential load shedding To maintain generator operation during an overload, a preferential load shedding arrangement is employed. This is achieved by a special overload relay, called a preference trip relay. If a generator overload develops, the preference trip relay sets an alarm and acts to trip selected non-essential loads. This reduces the generator load so that it may continue to supply essential circuits. Over current relay Each generator has its own normal over current relay to trip its own circuit-breaker which is typically high set at 150% with a 20 seconds delay. In addition, each generator has its own preference overload trip, this being low set generally at 110% current, instantaneous operation. If a generator overload condition develops, its preference overload trip will operate to energise the timing relay. Timing relay Rev 1 Dated: 01.02.2012 Page 25 of 86 The timing relay then operates to disconnect non-essential services in a definite order at set time intervals, e.g. • 1st trip - air conditioning and ventilation - 5 seconds • 2nd trip - refrigerated cargo plant -10 seconds • 3rd trip - deck equipment -15 seconds When sufficient non-essential load has been disconnected, the preference overload trip resets and no further load is disconnected. The generator preference trip system can also be initiated by low generator frequency or by low speed at the generator prime-mover. Emergency supply An emergency electrical power service must be provided on board in the event of a main power failure. Such a supply is required for emergency lighting, alarms, communications, watertight doors and other services necessary to maintain safety and to permit safe evacuation of the ship. Regulations require that the emergency power source be a generator, or batteries, or both. The emergency power source must be self-contained and not dependent upon any other engine room power supply. A battery when fully charged is obviously self-contained. An emergency generator must have an internal combustion engine as prime mover and have its own fuel supply tank, starting equipment and switchboard in the near vicinity. The emergency power source must come into action following a total mains failure. Emergency batteries can be arranged to be switched into service immediately following a main power failure. Emergency generators can be hand cranked, but are usually automatically started by compressed air or a battery to ensure immediate run-up following a main power failure. Although regulations may permit a battery to be the sole source of emergency power, in practice a suitable battery may be physically very large and hence a diesel driven generator is usually installed with its own small starting battery or airstart supply. Other small batteries may also be installed to locally supply control and communication equipment. On passenger ships, regulations require that the primary emergency power supply be provided by a diesel driven generator for up to 36 hours (18 hours for non-passenger vessels). In addition, an emergency transitional battery must also be installed to maintain vital services (mainly lighting) for a short period - typically a minimum of 3 hours. This emergency battery is to ensures that a total blackout cannot occur in the transitional period between loss of main power and the connection of the emergency generator. Testing of emergency power The emergency power system must be ready and available at all times. Such reliability requires special care and maintenance. At regular intervals it must be tested to confirm that it does operate correctly. The testing is normally carried out during the weekly emergency fire and boat drill practice sessions. The main generators are not shut down but the emergency power sources are energised and connected to supply the emergency services for the period of the practice session. Insulated and earthed neutral system An insulated system is one that is totally electrically insulated from earth (ship’s hull). An earth system has the supply neutral point connected to the earth. Shipboard main systems at 440V a.c. are normally insulated from earth (ship’s hull). Similar system shore are normally earthed to the ground. Continuity – single earth fault The priority requirement on board ship is to maintain continuity of the electrical supply to essential equipment in the event of a single earth fault occurring. The priority requirement ashore is the immediate isolation of earth faulted equipment, which is automatically achieved by an earthed system. Rev 1 Dated: 01.02.2012 Page 26 of 86 Circuit consists of two parts 1. Conductor, the part which carries current through the circuit 2. Insulation, the part which keeps the current inside the conductor. Basic faults 1. An open circuit fault is due to a break in the conductor, as at A, so that current cannot flow. 2. An earth fault is due to a break in the insulation, as at B, allowing the conductor to touch the hull or an earthed metal enclosure. 3. A short-circuit fault is due to a double break in the insulation, as at C, allowing both conductors to be connected so that a very large current by-passes or “short-circuits” the load. QUESTION A 10 A motor operates from a 220 V insulated system. The supply cables have a total impedance of 0.01 Q. What circuit current would flow due to (a) an open-circuit fault, (b) an earth fault and (c) a short-circuit fault occurred. Answers (a) The open circuit fault has infinite impedance. I=V/Z, I=220/∞=0 (b) The earth fault has NO effect on circuit current. I=10A (This is an insulated system). (c) The short circuit fault impedance is only the 0.01Ώ of the cables. Since I=V/Z = 220/0.01 Ώ = 22000 A Need for earthing The majority of earth faults occur within electrical equipment due to an insulation failure or a loose wire, which allows a live conductor to come into contact with its earthed metal enclosure. To protect against the dangers of electric shock and fire that may result from earth faults, the metal enclosures and other non-current carrying metal parts of electrical equipment must be earthed. Equipment at zero volts The earthing conductor connects the metal enclosure to earth (the ship’s hull) to prevent it from attaining a dangerous voltage with respect to earth. Such earth bonding of equipment ensures that it always remains at zero volts. Significance of Earth Faults If a single earth fault occurs on the live line of an EARTHED DISTRIBUTION SYSTEM, it would be equivalent to a short-circuit fault across the generator through the ship’s hull. The resulting large earth fault current would immediately cause the line protective device (fuse or circuit breaker) and to trip out the ‘faulty circuit. Loss of power Rev 1 Dated: 01.02.2012 Page 27 of 86 The faulted electrical equipment would be immediately isolated from the supply and so rendered safe. However, the loss of power supply could create a hazardous situation, especially if the equipment was classed essential, e.g. steering gear. The large fault current could also cause arcing damage at the fault location. Single earth – insulated system In contrast, a single earth fault “A” occurring on one line of an insulated distribution system will not cause any protective trip to operate and the system would continue to function normally. The equipment continues to operate with a single earth fault as it does not provide a complete circuit so no earth fault current will flow. Second earth – insulated system If a second earth fault at “B” occurred on another line in the insulated system, the two earth faults together would be equivalent to a short-circuit fault (via the ship’s hull) and the resulting large current would operate protection devices and cause disconnection of perhaps essential services creating a risk to the safety of the ship. Difference – earthed & insulated An insulated distribution system therefore requires two earth faults on two different lines to cause an earth fault current to flow. In contrast, an earthed distribution system requires only one earth fault on the line conductor to create an earth fault current which will trip out the faulty circuit. Marine – insulated system An insulated system is, therefore, more effective than an earthed system in maintaining continuity of supply to essential services. Hence its adoption for most marine electrical systems. Doublepole switches with fuses in both lines are necessary in an insulated single-phase circuit. Earth fault monitor Regulations require that an earth fault monitor is fitted to the main switchboard to indicate the presence of an earth fault on each isolated section of a distribution system, e.g. on the 440 V and 220 V sections. An earth fault monitor can be either a set of indicator lamps or an instrument (calibrated in kΏ or MΏ) to show the system IR value to earth. Principle of earth lamps When the system is healthy (no earth faults) then the lamps glow with equal half brilliance. If an earth fault occurs on one line, the lamp connected to that line goes dim or extinguished. The other lamps experience an increased voltage so will glow brighter than before. Rev 1 Dated: 01.02.2012 Page 28 of 86 Earth indication lamps have been the most common method used for many years, being an inexpensive installation which is easy to understand. Their major disadvantage is that they are not very sensitive and will fail to indicate the presence of a high impedance earth fault. Instrument type earth fault indicator This has led to the development of instrument type earth fault indicators which are being increasingly used. One common type of earth fault instrument-type monitor connects a small d.c. voltage to the distribution system. Any resulting d.c. current is a measure of the insulation resistance of the system. The injection-type instrument limits the maximum earth fault monitoring current to only 1 mA (compared with about60 mA for earth lamps), and the meter indicates insulation resistance directly in kΏ or MΏ. The monitor triggers an alarm when its set value is reached. Earth fault monitoring by dc injection Search and clear earth fault If the earth fault monitor on the switch-board shows the presence of an earth fault on the distribution system. It is up to the maintenance staff to trace (search for) the exact location of the fault and then to clear it as quickly as possible. Earth fault relay can be used for indication or tripping. In this arrangement a CT is connected across three phases. Under normal operation there will be no current flow as phaser sum of current is zero. When one of the phase earths earth fault current flows and phaser sum of current is not zero. Method of search An apparently simple method would be to open the circuit-breakers feeding loads A, B, C, etc. one at a time and by watching the earth fault monitor while observing which circuit-breaker, when tripped, clears the earth fault. The earth fault must then be on that particular circuit. In practice, circuits cannot be disconnected at random in this way. Some vital service may be interrupted causing the main engines to stop, perhaps in dangerous narrow waters. Tracing the earth fault must be coordinated with the operational requirements of the ship’s electrical services. Rev 1 Dated: 01.02.2012 Page 29 of 86 Earth fault – lighting circuit Suppose the earth fault monitor on the 220 V lighting distribution board (d.b.) indicates the presence of an earth fault. Switches A, B, C, are sequentially opened and closed in turn until the earth fault monitor indicates the earth faulted circuit. Suppose this is switch B. Circuit B supplies a distribution fuse-board (d.f.b.) located near its lighting circuits. Here there is no earth fault monitor so an IR (megger) tester must he used. At this d.f.b. fuse-pair No. 1 is removed to isolate the supply to the load. The IR tester (megger) is now connected with one lead to earth (hull) and the other lead to “b” (the outgoing terminal as shown), and a test applied. If healthy (IR >1 MΏ), connect the test lead to “a” and repeat the test. If both “a” and “b” are healthy, circuit 1 is healthy and fuse-pair 1 can be replaced. Fuse-pair 2 is now removed and tested a t “a” and “b”. If an earth fault is indicated (IR = low) then the faulted circuit has been located. All fuse-pairs are checked in turn to confirm whether healthy or faulted. At the faulted circuit, the fuses should be removed, all switches should be opened, and all lamps taken out. This breaks the circuit into several isolated conductor sections. At the supply distribution board, test at “a” and then at “b”. If both have an IR > 1 MΏ then the conductors connected to “a” and “b” are clear and healthy. Close the switch and re-test at “a”. If the IR is low then the earth fault lies on the conductors beyond the switch. At lamp 1 remove the fitting and disconnect the conductors as shown to further break down the circuit. Use the IR tester on each of these disconnected leads. If one conductor is indicated as having an earth fault (suppose it is the conductor between L1 and L2) then the earth fault lies at lamp 1 or lamp 2 or on the conductor. Both lamp fittings must now be opened and visually inspected to trace the exact location of earth fault. The method of tracing the earth fault is essentially that of continually breaking down the circuit into smaller and smaller sections until it is finally located. When located, the damaged insulation must be repaired. The method of repairing the earth fault depends upon the cause of the earth fault and this is determined by visual examination. A lamp fitting that is damaged must be replaced. Dampness in insulation must be dried out by gentle heat and then some precaution must be taken to prevent the future ingress of moisture. Insulation that has been mechanically damaged or weakened by overheating must be made good again. If surface dirt is the cause, a thorough cleaning will probably cure the fault. Rev 1 Dated: 01.02.2012 Page 30 of 86 Distribution Circuit Breakers The function of any circuit-breaker is to safely make onto and break open the prospective short-circuit fault current expected at that point in the circuit. The main contacts must open rapidly while the resulting arc is transferred to special arcing contacts above the main contacts. Arc chutes with arc-splitters quickly stretch and cool the arc until it snaps. The CB is open when the arc is quenched. Feeder and distribution circuits are usually protected by the moulded-case (MCCB) type or the miniature (MCB) type of circuit-breakers. MCCBs These are small, compact air circuit-breakers fitted in a moulded plastic case. They have a lower normal current rating (50-1500 A) than main breakers and a lower breaking capacity. They usually have an adjustable thermal overcurrent setting and an adjustable or fixed magnetic overcurrent trip for short-circuit protection built into the case. An undervoltage trip coil may also be included within the case. Operation to close is usually by a hand operated lever but motorcharged spring closing can also be fitted. MCCBs are reliable, trouble free and require negligible maintenance. If the breaker operates in the ON position for long periods it should be tripped and closed a few times to free the mechanism and clean the contacts. Terminals should be checked for tightness otherwise overheating damage will develop. The front cover of larger MCCBs (around 1000 A rating) can usually be removed for visual inspection and cleaning. Following tripping under a circuit fault, the breaker should be inspected for damage, checked for correct operation, and its insulation resistance measured. A test result of at least 5 MΏ is usually required. Any other faulty operation usually requires replacement or overhaul by the manufacturer. MCCBs can be used for every application on board ship from generator breakers to small distribution breakers. The limited breaking capacity may demand back-up fuses be fitted for very high prospective short-circuit fault levels. MCBs These are very small air circuit breakers fitted in small moulded cases. They have current rating of 5-100 A, generally thermal over current and magnetic short circuit protection. They have a very limited breaking capacity (about 3000 A) and are commonly used in final distribution boards instead of fuses. The d.b. is supplied via a fuse or MCCB with required breaking capacity. MCBs must be replaced if fault develops. Rev 1 Dated: 01.02.2012 Page 31 of 86 Details of parts of MCB 1. Actuator lever - used to manually trip and reset the circuit breaker. Also indicates the status of the circuit breaker (On or Off/tripped). 2. Actuator mechanism - forces the contacts together or apart. 3. Contacts - Allow current to flow when touching and break the flow of current when moved apart. 4. Terminals 5. Bimetallic strip 6. Calibration screw 7. Solenoid 8. Arc divider / extinguisher Transformers Magnetic flux, like current, lags applied voltage by 900 A transformer is a device made of two or more inductors, one of which is powered by AC, inducing an AC voltage across the second inductor. If the second inductor is connected to a load, power will be electromagnetically coupled from the first inductor's power source to that load. The powered inductor in a transformer is called the primary winding. The unpowered inductor in a transformer is called the secondary winding. Magnetic flux in the core lags 900 behind the source voltage waveform. The current drawn by the primary coil from the source to produce this flux is called the magnetizing current, and it also lags the supply voltage by 900. The principle of operation of a single-phase transformer is simple. An applied a.c. voltage V1 to the primary winding sets up an alternating magnetic flux in the laminated steel core. The flux induces an emf in the secondary whose size is fixed by the ratio of primary and secondary turns in the pair of phase windings (N1 and N2) to give: V1 / V2 = N1/ N2 Schematic symbol for transformer consists of two inductor symbols, separated by lines Rev 1 Dated: 01.02.2012 Page 32 of 86 indicating a ferromagnetic core. Ferromagnetic core with primary coil (AC driven) and secondary coil. Dividing the iron core into thin insulated laminations minimizes eddy current loss. Transformer cross-section cut shows core and windings. Core Characteristics: Transformers are working on principal of mutual inductance. Core of the transformer is required to provide passage to current and flux. Due to alternating current the core is magnetised and demagnetised and therefore, core material should provide minimum resistance to flux flow otherwise hysteresis loss will increase. Ferromagnetic materials are used as core material. Eddy current flows in the core to oppose the flux generated and therefore, material gets heated up and leading to losses. To minimise this loss core is constructed using laminated sheets. Rev 1 Dated: 01.02.2012 Page 33 of 86 Transformer arrangements Step-down transformer: (many turns :few turns). The secondary voltage V2 is available to drive current through a load. It is the load connected to the secondary that sets the size and power factor angle of the load current I2. This is matched on the primary side from: V1 / V2 = I1/ I2 .Transformers are rated in apparent power (VA or kVA) units. Electrical generation on board ship is typically at 3-phase a.c., 440 V, 60 Hz, while fixed lighting and other low power loads are supplied with 220 or 110 V a.c. single-phase from very efficient (typically > 90%) static transformer units. A three-phase transformer is made of three sets of primary and secondary windings, each set wound around one leg of an iron core assembly. Essentially it looks like three single-phase transformers sharing a joined core. Those sets of primary and secondary windings will be connected in either Δ or Y configurations to form a complete unit. The transformers are generally air cooled, being mounted in sheet steel enclosures which are often located adjacent to the main switchboard. Alternatively, they may be fitted within the switchboard so transformer enclosures are not required. Three-phase 440/220 V lighting trans- formers are usually composed of three separate single-phase units inter- connected to form a 3-phase arrangement. This enables easy replacement of a single-phase unit if it develops a fault. The alternative is to use a single 3-phase unit with all windings mounted on a common magnetic core. This type has to be completely isolated in the event of a fault on one phase only. Rev 1 Dated: 01.02.2012 Page 34 of 86 Transformers for use on 3-phase insulated systems are generally interconnected in a delta-delta circuit configuration using copper links between the phase windings. If a fault develops on one phase of such an arrangement, the faulty unit can be disconnected (via the links) creating an open-delta or ‘V” connection and a 3-phase supply will still be available, although at a reduced power capacity. This is obviously a useful safeguard. In some cases, a spare 4th transformer is available to replace the faulty unit. Maintenance Transformers are static items of equipment which are usually very reliable and troublefree. However, like all electrical equipment, transformers must be subjected to the usual maintenance checks. At regular specified intervals, transformers must be disconnected, covers removed and all accumulated dust and deposits removed by a vacuum cleaner and suitable brushes. Windings must be inspected for any signs of damage or over heating. Winding continuity resistance values are measured, recorded and compared with each other for balance. Any differences in continuity readings will indicate winding faults such as short-circuited turns. The insulation resistance of all windings must be measured both with respect to earth and to the other phase windings. The cause of any low insulation resistance reading must be investigated and rectified. Cable connections must be checked’ for tightness. Covers must be securely replaced and the transformers re-commissioned. All test results and observations should then be recorded for future reference. Delta-delta transformer connection. Instrument Transformers Transformers are used to supply instruments and protection relays with proportionally small currents and voltages derived from the large currents and voltages in a high power network. Rev 1 Dated: 01.02.2012 Page 35 of 86 While the PT is a step-down device, the Current Transformer (or CT) is a step-up device (with respect to voltage), which is what is needed to step down the power line current. Bar Primary transformer: Current conductor to be measured is threaded through the opening. Scaled down current is available on wire leads. Quite often, CTs are built as donut-shaped devices through which the power line conductor is run, the power line itself acting as a single-turn primary winding. The bar primary type CT is used with very high primary current ratings the wound primary type being used for small stepdown ratios, e.g. 1000/5 A bar primary; 50/5 A wound primary. The ratio specified on a VT details its input and output voltages, e.g. 3.3 kV/110 V is used on a 3.3 kV mains circuit and steps the voltage down to 110 V. The associated instrument will have its scale calibrated O-3.3 kV and will be marked “3.3 kV/110 V VT ratio”. The ratio specified on a CT similarly details its input and output currents, e.g. 150/5 A CT is used on a 150 A mains circuit and steps the current down to 5 A. The associated instrument will have its scale calibrated “O-150 A” and will be marked “150/5 A CT ratio”. The use of instrument transformers does not eliminate danger to operators. The 110 V output from a VT will apply a severe, possibly lethal shock to un-suspecting fingers. The secondary circuit of a CT must never be opened while mains primary load current is flowing. Excessive heating will be developed in an open-circuited CT with an extremely high voltage arising at the open secondary terminals. If an ammeter is to be removed from circuit, the CT secondary output terminal must be first short-circuited, with the primary circuit switched off. The secondary short circuit will not damage the CT when the primary current is switched on. For further safety, one end of the secondary winding of a CT or VT is connected to earth. Status indicator lamps on switchboards are commonly of the transformer type, having a small transformer built into the lamp fitting. The transformer provides a 6 V or 12 V output. The lamp is of low wattage with small bayonet cap fitting. Although not an accurate instrument transformer, the lamp transformer is similar in function to a VT. Shore Supply Connection A shore-supply is required so that the ship’s generators and their prime-movers can be shut down for major overhaul during a dry-docking period. There must be a suitable connection box conveniently located to accept the shore supply cable. Rev 1 Dated: 01.02.2012 Page 36 of 86 Shore connection box and indicators. The connection box is often located at the entrance to the accommodation or in the emergency generator room. The connection box must have suitable terminals to accept the shore supply cable, including an earthing terminal to earth the ship’s hull to the shore earth. The connection box must have a circuit-breaker or an isolator switch and fuses to protect the cable linking the connection box to the main switchboard, with a data plate giving details of the ship’s electrical system (voltage and frequency) and showing the method for connecting the shore supply cable. A voltmeter is fitted to indicate polarity of a d.c. shore supply. For an a.c. shore supply a phase-sequence indicator (P. S. I.) is fitted to indicate correct supply phase sequence. This indicator may be arranged as two lamps connected as an unbalanced load across the three phases via resistors and capacitors. The sequence is “right” (or correct) when the right side lamp is bright and the other is dark. An alternative P.S.I. indicator is a rotary pointer driven by a small 3-phase induction motor. At the main switchboard an indicator is provided, usually a lamp, to indicate that the shore supply is available for connection to the bus-bars via a connecting switch or circuit-breaker. It is not normally possible to parallel the shore supply with the ship’s generators. The ship’s generators must, therefore, be disconnected before the shore supply can be connected to the main switchboard. Normally, the shore supply switch on the main switchboard is interlocked with the generator circuit-breakers so that it cannot be closed if the generators are still connected. Correct sequence By “correct” we mean that it is the same sequence as the ship’s supply (red-yellow- blue). A reversed phase sequence (red-blue-yellow) will produce a reversed shaft rotation in all 3-phase motors because the direction of their rotating magnetic fields will be reversed with disastrous results. This fault is remedied by interchanging any two conductors of the shore supply cable at the connection box. The shore supply may have a different frequency and/or voltage to that of the ship’s system. Rev 1 Dated: 01.02.2012 Page 37 of 86 A higher frequency will cause motors to run faster, be overloaded and overheat. A higher voltage will generally cause equipment to take excess current and overheat. It will also cause motors to accelerate more rapidly and this may overstress the driven loads. A lower voltage is generally not so serious but may cause motors to run slower and overheat, and may cause motors to stall. If the shore supply frequency differs from the ship’s normal frequency then, ideally, the shore supply voltage should differ in the same proportion. Question: If your ship is designed for 60 Hz at 440 V - what value should the shore supply voltage be if operating at 50 Hz? Answer: Supply voltage should be reduced to about 380 V. Circuit Protection Many forms of electrical protection are available which are designed to protect the distribution system when a fault occurs. Protection relays are used to monitor overcurrent, over/under voltage, over/under frequency, earth leakage, un- balanced loading, over-temperature, reverse power (for generators) etc. As most protection relays monitor Current and/or voltage, we will limit our examination to overcurrent and under-, voltage protection together with an appreciation of protective discrimination. Reverse power protection will be discussed later along with alternator protections. No matter how well designed and operated, there is always the possibility of faults developing on electrical equipment. Faults can develop due to natural wear and tear, incorrect operation, accidental damage and by neglect. The breakdown of essential equipment may endanger the ship, but probably the most serious hazard is FIRE. Overcurrent (I2R resistive heating effect) in cables and equipment will cause overheating and possibly fire. The size of conductor used in cables and equipment is such that with rated full load current flowing, the heat developed does not raise the temperature beyond about 80°C (i.e. 35°C rise above an ambient of 45°C). A copper conductor can withstand very high temperatures (melts at 10830 C), but its insulation (generally organic materials such as cotton or plastic compounds) cannot withstand temperatures much in excess of 100°C. At higher temperatures the insulation suffers irreversible chemical changes, loses its insulation properties and becomes burnt out. Short-circuit and overload currents must, therefore, be detected and rapidly cleared before damage occurs. Reasons why protection equipment is essential in an electrical distribution system: 1. To disconnect and isolate faulty equipment in order to maintain the power supply to the remaining healthy circuits in the system 2. To prevent damage to equipment from the thermal and magnetic forces that occur during short circuit and overload faults 3. To protect personnel from electric shock The protection scheme consists of circuit-breakers, fuses, contactors, overcurrent and undervoltage relays. A circuit-breaker, fuse or contactor interrupts the fault current. An overcurrent relay detects the fault current and initiates the trip action. The circuit-breaker or fuse must be capable of safely and rapidly interrupting a short-circuit current. They must be mechanically strong enough to withstand the thermal and magnetic forces produced by the fault current. The size (strength) of the circuit-breaker or fuse is specified by its breaking capacity which is the maximum fault current it can safely interrupt. For example, an MCCB may be continuously rated at 440 V with a rated current of 600 A. Its breaking capacity may be 12.5 MVA which means it can safely interrupt a fault current of 16,400 A (from 12.5 x 106 /√3.440 =16,400 A). The prospective fault current level at a point in a circuit is the current that arises due to a shortcircuit at that point. Rev 1 Dated: 01.02.2012 Page 38 of 86 Short circuit fault location. The size of this short-circuit fault current is determined by the total impedance of generators, cables and transformers in the circuit between the generator and the fault. This total impedance is generally very small so the maximum fault current (called the prospective fault current) can be very large. A 440 V, 5 kW, 0.8 pf 3-phase load is supplied. The normal full load POWER is P = √3 VL IL cos Φ watts So the load full load current is IL = P/ √3 VLL cos Φ = 5000/ √3 .440. 0.8 = 8.2 A Fault circuit Suppose now a short-circuit fault occurs at the load terminals The total impedance is ZF = 0.025 + 0.01 + 0.015 = 0.05 Ώ and the prospective short-circuit fault current is IF = V/ZF = 440V/0.05 Ώ = 8,800 A So the prospective fault current level at the load is 8800 A. For a short-circuit at the d.b. the 440 V fault level is: 440 V/ (0.025 + O.O1)Ώ = 12,571 A For a short-circuit at the main switchboard 440 V the fault level is: 440 V/ 0.025 Ώ = 17,600 A The fault level increases, the nearer the fault occurs to the generator. The circuit-breaker or fuse must have a breaking-current capacity in excess of the prospective fault current level expected at the point at which it is fitted. If less, the circuit breaker (or fuse) is liable to explode and cause fire. The ability of a protection system to disconnect only the faulted circuits and to maintain the electrical supplies to healthy circuits is called protective discrimination. Discrimination is achieved by co-ordinating the current ratings and time settings of the fuses and overcurrent relays used between the generator and the load. Rev 1 Dated: 01.02.2012 Page 39 of 86 Protective discrimination scheme. The protective devices nearest the load having the lowest current rating and shortest operating time. Those nearest the generator having the highest current rating and longest operating time. If a short-circuit fault occurs in the lamp holder in above figure, the fault current will be large enough to operate all protection devices from the generators to the fault. However, the 5 A fuse protecting the lamp circuit has the lowest current rating and shortest operating time in the system so will be the quickest to operate. This action will clear the fault and leave all other healthy circuits still connected. In the case of fuses, it is generally accepted that discrimination will be achieved if consecutive fuses have a ratio of about 2:l. The shipbuilder specifies the current ratings of fuses, together with the current and time settings of relays, in the protection scheme. It is important that the original settings are maintained to achieve correct discrimination. Overcurrent Protection The general term “overcurrent” applies to a relatively small increase over the full load current (FLC) rating (e.g. due to mechanical overloading of a motor) rather than the massive current increase caused by a short-circuit fault. Generally, an overcurrent, supplied from a CT, is detected by a relay with an appropriate time-delay to match the protected circuit. Short circuit faults in LV distribution circuits are mainly detected and cleared almost instantaneously by fuses, MCCBs or MCBs. Main supply feeders are usually protected against short-circuits by circuit breakers with instantaneous magnetic trip action. Overcurrent relay types All relay types have an inverse current-time characteristic called OCIT (over-current inverse time), i.e. the bigger the current the faster it will operate. The basic inverse I/t curve would tend towards zero time for the highest currents. To make the relay action more precise at very high fault currents the action is arranged to operate at a definite minimum time which is fixed by the design. This type is called an OCIDMT (over current inverse and definite minimum time) relay action. The OCIDMT can also be combined with an instantaneous (high set) trip to give the fastest action against extremely high currents due to a short circuit fault. Magnetic relay A magnetic relay, directly converts the current into an electromagnetic force to operate a trip switch. One type is the attracted armature action similar in construction to a simple signaling relay but with an Rev 1 Dated: 01.02.2012 Page 40 of 86 adjustment for the current setting. The time of operation is fixed at a definite minimum time which is usually less than 0.2 seconds. This is regarded as instantaneous i.e. with no deliberate timedelay. To obtain a magnetic inverse-time action, e.g. for motor overload protection, an induction disc movement is usually employed. This construction is similar to a kWh energy meter used in a house but the disc movement is constrained by a spring so is not allowed to actually rotate. The disc travel is very small but sufficient to operate a set of trip switch contacts. Both current and time settings are adjustable. A combined relay including an attracted armature element and induction disc element will give an instantaneous action (high set current) and an inverse/time characteristic. Thermal relay Thermal relay utilises the bending action of a bimetallic bar (one per phase) to open a normally-closed (NC) contact which then trips a contactor or circuit-breaker. A small circuit current will be allowed to flow directly through the bimetallic strip but larger currents will be directed through a heater coil surrounding the strip. The three bimetal strips in a three phase relay, all bend in the same direction with balanced over currents to cause a trip. A mechanical bellcrank trip arrangement can also operate with unbalanced (differential) currents. This is particularly effective with a single-phasing motor fault. In this case, two of the bimetal strips bend further in the normal direction with increased line current, while the other cools down allowing this strip to move relatively backwards (differential action). The time taken to heat the bimetal strip to cause sufficient bending fixes the required time to trip. Resetting the relay can only be achieved after the strip has cooled down back to the ambient temperature. The inverse I/t overcurrent characteristic of a thermal relay is very useful for the indirect temperature protection of motors. Its thermal time delay is, however, far too long for a short-circuit fault so back-up instantaneous protection must also be used in the form of fuses or a circuit breaker. Electronic relay An electronic overcurrent relay usually converts the measured current into a proportional voltage. This is then compared with a set voltage level within the monitoring unit which may be digital or analogue. In an analogue unit the time delay is obtained by the time taken to charge up a capacitor. This type of relay has separate adjustments for over current and time settings together with an instantaneous trip. The electronic amplifiers within the relay require a low voltage d.c. power supply, e.g. 24 V d.c. derived from a 110 V a.c. auxiliary supply. Here, the input from a line current transformer (CT) is rectified to produce a d.c. voltage which is proportional to the line current. Both the magnetic and electronic relays can be designed to give an almost instantaneous trip (typically less than 0.05 seconds or 50 ms) to clear a short-circuit fault. Thermal relays are commonly fitted in moulded case circuit breakers (MCCBs) and in miniature circuit-breakers (MCBs) to give a “long time” thermal overcurrent trip in addition to a magnetic action for an instantaneous trip with a short-circuit fault. Overcurrent protection relays in large power circuits are generally driven by current transformers (CTs). The CT secondary usually has a 5 A or 1 A rating for full load current in its primary winding. All overcurrent relays can be tested by injecting calibrated test currents into them to check their current trip levels and time delay settings. Primary injection is where a calibrated test current is fed through the normal load circuit. This requires a large current injection test set. The test set is essentially a transformer and controller rather like a welding set, i.e. it gives a low voltage - high current output. Small secondary injection currents (5-50 A) are fed directly into the over current relay usually via a special test plug/socket wired into the relay. Secondary injection does not prove the CT performance (as it is disconnected during the test) but is the usual method for testing an over current relay. The setting up of an overcurrent relay is obviously critical to its protective duty so Rev 1 Dated: 01.02.2012 Page 41 of 86 is carried out in strict accordance with the manufacturer’s instructions. Such setting up is done during new ship trials and at subsequent periodic surveys. Fuse Protection A fuse is the most common type of protection against a short-circuit fault in LV distribution circuits, motor circuits and for portable appliances. It is relatively simple, inexpensive and reliable. As re-wireable fuses tend to be less reliable than the cartridge type and are open to abuse (fitting the wrong size of fuse wire), they are not recommended for marine practice. HRC (high rupturing capacity - e.g. 80 kA) cartridge-type fuse links are normally used. HRC fuse construction. A disadvantage of a fuse is its insensitivity to small over currents. An HRC fuse will blow at currents as low as 25% overload, but only after about 4 hours. The advantage of a fuse is its very high speed of operation (a few milli-seconds) at high short-circuit fault current - faster than a circuitbreaker. Fuses are fitted in circuits to give protection against short-circuits. Protection against relatively small over currents (e.g. due to shaft overloading on a motor) is provided where necessary by an over current relay (OCR). A starter over current relay protects the motor against relatively small over-currents. The fuse links provide back-up protection for the supply cables and generators against a short-circuit fault. Motor fuses are typically rated at 2-3 times the motor full load current in order to withstand the large starting current surge (up to 6 times full load) of the motor. Figure 1Bottle type HRC fuse The motor manufacturer will specify the correct rating of fuse link for a particular motor rating. Hence a typical fuse designation for a motor circuit could be “32M63” which indicates a continuous rating of 32 A but a rating of 63 A for the brief starting period. Important points to note concerning fuses are 1. In the event of a fuse blowing, the cause of the fault must be located and repaired before the fuse link is replaced. 2. The replacement fuse link must be of the correct current rating, grade and type. Usually this means the replacement fuse link is identical to the blown fuse link. 3. Replace all three fuses in a 3-phase supply even if only one is found blown after a fault. The others may be seriously weakened which makes them unreliable for future use. The reference symbols used on an HRC fuse link are devised by the particular manufacturer. They include the current rating, voltage, application (e.g. motor, transformer, diode, general use), physical size, and type of fixing arrangement. Undervoltage Protection TO CHANGE UNDERVOLTAGE COIL DIAGRAM An undervoltage (U/V) release mechanism is fitted to all generator breakers and some main feeder circuit-breakers. Its main function is to trip the breaker when a severe voltage dip (around 50%) occurs. This is achieved by lifting the mechanical latch (which keeps the contacts closed) to allow the trip spring to function which opens the breaker contacts. The U/V release on a generator circuit-breaker also prevents it being closed when the generator voltage is very low or Rev 1 Dated: 01.02.2012 Page 42 of 86 absent. An undervoltage relay may be magnetic or electronic, also provides back-up protection to short-circuit protection. As an example, suppose during generator paralleling procedures, an attempt was made to close the wrong circuitbreaker e.g. the breaker of a stopped and dead generator. If this circuit-breaker was closed, the dead generator would be the equivalent of a short-circuit fault on the bus-bars and cause a blackout. The undervoltage relay prevents the closure of the circuit-breaker of the dead generator. A short-circuit occurs on the main bus-bars and the short-circuit trip of the running generator breaker fails to operate. The short-circuit reduces the bus-bar voltage to zero which causes the U/V release to trip the breaker. Under voltage protection is also required for motor starters. The starter contactor normally provides this protection as it drops out when the supply voltage is lost or is drastically reduced. The starter circuit will not normally allow the motor to re-start when the voltage is restored, except when automatic restarting is facilities are provided. Cables Ship wiring cables have to withstand a wide variety of environmental conditions, e.g. extremes of ambient temperature, humidity and salinity. Improved materials have led to ship wiring cables of a fairly standard design that are safe, durable and efficient under all conditions. The normal distribution voltage on ships is 440 V and cables for use at this voltage are designated 600/1000V, i.e. 600 V to earth or 1000 V between conductors. Higher voltage systems require cables with appropriate ratings, e.g. for a 3.3 kV 3-phase earthed neutral system the required cable rating is 1900/3300V. For 3-phase insulated systems the cable rating would be 3300/3300 V. Cables are constructed of several basic parts Conductors are of annealed stranded copper which may be circular or shaped. Cables with shaped conductors and cores are usually smaller and lighter than cables with circular cores. Cable insulation has a thickness appropriate to the system voltage rating. Insulation materials are generally organic plastic compounds. Butyl rubber, which is tough and resilient, has good heat, ozone and moisture resistance. These excellent properties enable butyl rubber to replace natural rubber as an insulant. Rev 1 Dated: 01.02.2012 Page 43 of 86 Even so, butyl rubber has now been largely superseded by ethylene propylene rubber (EPR) insulation. EPR has similar electrical and physical properties to butyl rubber but with better resistance to moisture and ozone. It should not, however, be exposed to oils and greases. Cross-linked polyethylene (XLPE) is also used as an insulant but has inferior mechanical and thermal properties when compared with EPR. Polyvinyl chloride (PVC) is not generally used for ships’ cables, even though it is very common ashore. PVC tends to soften and flow at high temperatures (melts at 15O0C), and hardens and cracks at low temperatures (- 8°C). Even at normal temperatures PVC tends to flow and become distorted under mechanical stress - for example necking occurs at cable glands causing the gland to lose its watertight properties. Multicore ship wiring cables have the cores identified by either colour, printed numerals on untaped cores or numbered tapes on taped cores. Sheath The, sheath of a cable protects the insulation from damage and injury – it is not classed as an insulant. Sheath materials are required to be heat, oil and chemical resistant and flame retardant (HOFR). The sheath must also be tough and flexible. Polychloroprene (PCP or Neoprene) is a common sheath material but has been largely superseded by chlorosulphonated polyethylene (CSP or hypalon). CSP-HOFR sheathing compound is well suited to shipboard conditions. It offers good resistance to cuts and abrasions, resists weather and ozone, acid fumes and alkalis, and is flexible. Armouring Extra mechanical protection is provided by armouring with basket-woven wire braid of either galvanised steel or tinned phosphor bronze. The non-magnetic properties of phosphor bronze are preferred for single-core cables. A protective outer sheath of CSP compound covers the wire braid. The wire braiding also acts as a screen to reduce interference (caused by magnetic fields) in adjacent communication and instrumentation circuits. Will cable materials burn? All organic materials will eventually burn in a severe fire. Cable sheath materials commonly in use are organic plastic compounds that are classed as flame retardant, i.e. will not sustain a fire. Most cable materials now achieve this property by developing chlorine gas and acid fumes to smother the flame. Rev 1 Dated: 01.02.2012 Page 44 of 86 PVC is notorious for its release of deadly acid fumes, but PCP and CSP do the same. EPR and XLPE do not. Some new materials do not produce acid fumes when burning - an important feature for fire-fighting personnel. However, burning cable materials still tend to produce dense black smoke. Current rating The current rating of a cable is the current the cable can carry continuously without the conductor exceeding 800C with an ambient temperature of 450C (i.e. 350C rise). This rating must be reduced if the ambient temperature exceeds 450C or when cables are bunched together or enclosed in a pipe or trunking, which reduces the effective cooling. The volt drop in cables from the main switchboard to the appliance must not exceed 6% (in practice it is about 2%). The cables installed must comply with both the current rating and the volt-drop limitation. Cable volt drop only becomes a problem in very long cables. Cable gland Cables are insulated, mechanically protected and watertight. They may be armoured and suitable for installation in a hazardous explosive area. A cable gland maintains these properties where the cable is terminated at an appliance, e.g. at a motor terminal box. The cable gland is screwed into the appliance terminal box. Nuts on the gland compress sealing rings to maintain watertight seals on the inner and outer sheaths and to clamp the armour braiding. The gland must be matched to the size and type of cable. Mechanical damage to cables must be made good either by repairing the damage or replacing that section of cable. Unprotected metal armouring and insulation material are vulnerable to attack by moisture, chemicals and corrosive gases, while exposed live conductors are obviously dangerous. Principle of 3 phase A.C. generation AC generator (alternator) provides the power in such a way that the rotating magnetic field passes by three sets of wire windings, each set spaced 120 0 apart around the circumference of the machine. Together, the six pole" windings of a three-phase alternator are connected to comprise three winding pairs, each pair producing AC voltage with a phase angle 1200 shifted from either of the other two winding pairs. The three voltage sources connected together in a Y or star configuration, with one lead of each source tied to a common point . Rev 1 Dated: 01.02.2012 Page 45 of 86 As the magnet rotates, the phase angle shift of 1200 is a function of the actual rotational angle shift of the three pairs of windings. If the magnet is rotating clockwise, winding 3 will generate its peak instantaneous voltage exactly 1200 (of alternator shaft rotation) after winding 2, which will hits its peak 1200 after winding 1. The magnet passes by each pole pair at different positions in the rotational movement of the shaft. Where we decide to place the windings will dictate the amount of phase shift between the windings' AC voltage waveforms. If we make winding 1 our reference voltage source for phase angle (00 ), then winding 2 will have a phase angle of 1200 ( lagging, or 2400 leading) and winding 3 an angle of 2400 (or 1200 leading). This sequence of phase shifts has a definite order. For clockwise rotation of the shaft, the order is 1-2-3 (winding 1 peaks first, them winding 2, then winding 3). This order keeps repeating itself as long as we continue to rotate the alternator's shaft. However, if we reverse the rotation of the alternator's shaft (turn it anticlockwise), the magnet will pass by the pole pairs in the opposite sequence. Instead of 1-2-3, we'll have 3-2-1. Now, winding 2's waveform will be leading 1200 ahead of 1 instead of lagging, and 3 will be another 1200 ahead of 2. Phase sequence Phase sequence is produced (the order in which pole pairs get passed by the alternator's rotating magnet) and how it can be changed by reversing the alternator's shaft rotation. There is a much easier way to reverse phase sequence than reversing alternator rotation: just exchange any two of the three wires going to a three-phase load. Voltage Rev 1 Dated: 01.02.2012 Page 46 of 86 The useful emf level (E) is called the root mean square (rms) value and all equipment is rated in rms terms. The voltage available at the generator terminals is V = E - (I.Z) [phasor calculation]where I is the load current flowing in the stator phase windings. An internal phase volt-drop of (IZ) occurs due to the impedance Z of a phase winding which is made up from its resistance and reactance. Frequency The frequency f (measured in Hertz) of the emf is the number of wave form cycles per second. This obviously depends on the rotational speed and the number of poles. So f = n.p =(N/6O).p where n = speed in rev/s, N = rev/min and p = pairs of poles. These two basic relationships for emf and frequency dictate how to control the voltage and frequency output of a generator. In practice the speed is maintained practically constant by the generator’s prime-mover which fixes the output frequency. The constant speed then allows the size of generated emf to be directly controlled by the size of pole flux (excitation). A practical a.c. generator has three sets of coils, called phase windings, located in slots in the stator surrounding the rotating magnetic poles. The emf induced in each phase is 1200 out of phase with the other two phases. Three-phase windings are labelled as U-V-W with colour coding of red, yellow and blue used on terminals and bus-bars. One end of each of the three phase windings are joined together to form the neutral point of a star connection. The other ends of the phase windings are connected to outgoing conductors called lines. The three output line voltages (represented by VL) and the 3 output line currents (represented by IL) combine to create the three-phase electrical power output of: • P = √3.VL.ILcosΦ watts • In a star connection, any line voltage VL, is made up from two phase voltages, where VL = √3. VPH. The √3 factor is due to the 1200 displacement between phase voltages. Power factor The rated values of a machine always refer to line conditions (as stated on rating plate). Angle Φ is the phase angle between VPH and IPH which is determined by the types of electrical load on the generator (e.g. lighting, motors, galley equipment etc.). CosΦ is the power factor of the electrical load and is typically about 0.8 lagging which means that the current wave form lags about 370 behind the voltage. Alternator construction The two main parts of any rotating a.c. machine are its stator and rotor. The fabricated steel stator frame supports the stator core and its three phase windings. The main outgoing cables connected to these terminals conduct the generator’s electric power to its circuit-breaker at the main switchboard. Rotor The rotor of a main a.c. generator provides the field excitation from its electromagnetic poles. Two constructional forms of rotor are available 1. salient pole type 2. cylindrical type A typical rotating-field ac generator consists of an alternator and a smaller dc generator built into a single unit. The output of the alternator section supplies alternating voltage to the load. The only purpose for the dc exciter generator is to supply the direct current required to maintain the alternator field. This dc generator is referred to as the exciter. Rev 1 Dated: 01.02.2012 Page 47 of 86 The exciter is a dc, shunt-wound, self-excited generator. The exciter shunt field (2) creates an area of intense magnetic flux between its poles. When the exciter armature (3) is rotated in the exciter-field flux, voltage is induced in the exciter armature windings. The output from the exciter commutator (4) is connected through brushes and slip rings (5) to the alternator field. Since this is direct current already converted by the exciter commutator, the current always flows in one direction through the alternator field (6). Thus, a fixed-polarity magnetic field is maintained at all times in the alternator field windings. When the alternator field is rotated, its magnetic flux is passed through and across the alternator armature windings (7). Salient pole type The salient pole type has projecting poles bolted or keyed onto the shaft hub. Field excitation windings are fitted around each pole. This type of rotor is used with medium and slow shaft speeds (1800 rpm and below) and is the most common arrangement for marine generators. If you could compare the physical size of the two types of rotors with the same electrical characteristics, you would see that the salient-pole rotor would have a greater diameter. At the same number of revolutions per minute, it has a greater centrifugal force than high speed rotor. Cylindrical type Cylindrical type rotors are generally used with large power, high speed (1500-3600 rpm) steam/gas turbine drives. The excitation windings are firmly embedded in slots to withstand the tremendous centrifugal forces encountered at high speeds. Unwound sections of the rotor form the pole faces between the winding slots. The windings in the cylindrical type rotor are arranged to form two or four distinct poles. Rotor poles Rev 1 Dated: 01.02.2012 Page 48 of 86 The rotor poles are supplied with direct current (d.c.) from an exciter. If the exciter equipment is a conventional d.c. generator or is static, the d.c. excitation current is fed into the field windings via carbon brushes on a pair of shaft-mounted slip-rings. Brushless excitation To eliminate the maintenance problems associated with rotating contacts, a brushless arrangement is usual for marine generators. All brush gear, commutators and slip rings are eliminated by using an a.c. exciter with its output being rectified by shaft-mounted silicon diodes. The diodes are connected as a three phase a.c./d.c. bridge circuit. The six diodes, mounted on the shaft, convert the a.c. exciter output to d.c. which-is then fed directly into the main generator rotor field windings. The a.c. exciter has its own d.c. fields poles fitted on its stator while the rotor carries its threephase a.c. exciter output windings. This construction layout is inverted compared with that of the main generator. Brushless excitation scheme. Cooling Power losses, typically 10% of the generator rating, cause internal heating in the windings and magnetic cores of both rotor and stator. This heat must be continuously transferred out of the generator to prevent excessive temperature rise causing breakdown of winding insulation. Cooling air is forced through ventilation ducts in the stator core, between rotor poles and through the air gap (a few millimeters) between stator and rotor. Heating during stoppage While the generator is stopped during standby or maintenance periods, low power electric heaters within the machine prevent internal condensation forming on the winding insulation. These heaters may be switched on manually or automatically from auxiliary contacts on the generator circuit-breaker. Heater power supplies are normally 220 V a.c. single-phase supplied from a distribution box local to the generator. The stator core is assembled from laminated steel with the windings housed in slots around the inner periphery of the cylindrical core. The stator coils are interconnected (in the end-winding regions) to form Rev 1 Dated: 01.02.2012 Page 49 of 86 three separate phase windings with six ends. These phase ends are found in the stator terminal box. Automatic Voltage Regulation Sudden load current surges (e.g. due to motor starting) cause a corresponding change in its output voltage. This is due to an internal voltage drop in the generator windings and the effect is usually called voltage dip. Similarly, load shedding will produce an over voltage at the bus-bars. An un-regulated or non-compounded generator excitation system would not be realistic on board ship due to the varying voltage caused by the fluctuating load demand. Automatic voltage regulation (AVR) equipment is necessary to rapidly correct such voltage changes. An AVR will control the generator’s voltage to ±2.5% (or better) of its set value over the full load range. This is its steady-state voltage regulation. Transient voltage dip is usually limited to 15% for a specified sudden load change with recovery back to rated voltage within 1.5 seconds. The AVR senses the generator output voltage and acts to alter the field current to maintain the voltage at its set value. The control circuit for a modern AVR consists of transformers, rectifiers, zener diodes, transistors and thyristors. These are mounted on one or more circuit cards fitted either within the switchboard or local to the generator. Although the AVR control circuit design varies with the manufacturer, the basic scheme contains the elements shown. AVR block diagram The voltage sensing unit transforms down, rectifies and smoothes the generator output voltage. This produces a low voltage d.c. signal that is proportional to the a.c. generator voltage. This actual d.c. signal is compared with a set d.c. value produced by a reference circuit of zener diodes and resistors. An error signal output from the comparator is then amplified and made suitable for driving the field circuit regulating thyristor(s). A thyristor is a fast-acting electronic switch controlled by a voltage signal at its gate terminal. This device rectifies and regulates the generator field current. Insulation test of generator & wiring of AVR Electronic components such as transistors, integrated circuit chips, thyristors, etc. are likely to be damaged during a high voltage (500 V) megger test. To test the generator and its cables to earth and protect the electronic parts, either: Rev 1 Dated: 01.02.2012 Page 50 of 86 1. Short-circuit all outgoing cable terminals during the IR test 2. Remove electronic card(s) 3. Disconnect all cables at both ends and test separately Alternators in parallel Main generator units (gas-turbine, steam turbine or diesel drives) have to be run in parallel to share a total load that exceeds the capacity of a single machine. Changeover of main and standby generator units requires a brief parallel running period to achieve a smooth transition without blackout. Essentially, parallel running is achieved in the two stages of: 1. Synchronising 2. Load Sharing Both operations are carried out automatically but manual control is still in common use and is generally provided as a back-up to the auto control. The generator already on the bus bars is called the running machine and the generator to be brought into service is the incoming machine. To smoothly parallel the incoming generator, it must be synchronised with the live bus-bars. Breaker closing when not synchronised At the instant of closing the breaker, the voltage phase difference causes a large circulating current between the machines which produces a large magnetic force to pull the generator voltages (and field poles) into synchronism. This means rapid acceleration of one rotor and deceleration of the other. The large forces may physically damage the generators and their prime-movers and the large circulating current may trip each generator breaker. Result - Blackout, danger and embarrassment. To achieve smooth manual synchronising, the incomer must be brought up to speed to obtain approximately the same frequency as shown on the bus-bar frequency meter e.g. 60 Hz. The incoming generator voltage is set by its AVR to be equal to the bus-bar voltage. Rev 1 Dated: 01.02.2012 Page 51 of 86 Fine tuning of the speed can now be observed on the synchroscope or synchronising lamps. The incomer is adjusted so that the synchroscope indicator rotates slowly clockwise (fast direction) at about 4 seconds per indicator revolution. The circuit-breaker should be closed as the indicator approaches the 12 o’clock (in-phase) position. Breaker closing between 5 to and 5 past the 12 o’clock synchroscope position is satisfactory as long as the pointer rotation is fairly slow. Back -up As a back-up, or alternative, to the synchroscope a set of lamps may be used. The correct synchronised position may be shown by either of the following methods: 1. Lamps dark method (2 lamps) 2. Lamps bright method (2 lamps) 3. Sequence method (3 lamps) 4. In each case the lamps are connected between the incoming generator and the bus-bars. The sequence method is preferred as it displays a rotation of lamp brightness which indicates whether the incoming machine is running fast (clockwise) or slow (anticlockwise). As with the synchroscope, the lamp sequence must appear to rotate slowly clockwise. Correct synchronisation occurs when the top lamp is dark and the two bottom lamps are equally bright. Without synchroscope or lights Connect a voltmeter across one pole of the open incoming generator circuit breaker. This procedure is more easily (and safely) performed at the synchroscope terminals behind the door of the synchronising panel at the front of the main switchboard. Check the circuit diagrams before such testing. Adjust the generator speed until the voltmeter very slowly fluctuates from zero to maximum. Close the breaker when the voltmeter indication passes through zero Rev 1 Dated: 01.02.2012 Page 52 of 86 The total bus-bar load can now be shared between generators or totally transferred to the new machine. Manual kW load sharing is achieved by raising the governor setting of the incoming machine while lowering the setting on the running machine. The balance of power sharing is dictated by the governor (speed) droop of each generator prime mover. For equal load sharing of kW and kVAr, each machine must have similar droop characteristics which are typically 2-4% between no-load and full-load values. Generator protection The protection of a generator is largely based on the sensing of current and voltage from CTs and VTs. The number and type of protective relay functions increases with the generator kVA rating and voltage level. Protective relays are electromagnetic (traditional) or electronic (increasingly more common) which are mounted on the generator front panel of the main switchboard. Over Current Inverse Time The Over Current Inverse Time relay function monitors general balanced overloading and has current/time settings determined by the overall protective discrimination scheme. • Typical setting ranges for current (I) and time (t) are: • I > : 0.7-2.In, (In = normal or rated generator current) and t: 1-10s Overcurrent (instantaneous) “Instantaneous” trip to protect against extremely high overcurrent caused by a shortcircuit fault. Typical setting ranges are: I > : 2-10.In, and t: 0.1-1s Reverse Power Generators intended to operate in parallel must have reverse power protection. A reverse power relay monitors the direction of power flowing between the generator and the load. If a prime-mover failure occurred the generator would act as a motor. The reverse power relay detects this fault and acts to trip the generator circuit-breaker.The Reverse power relay operation is easily checked during a generator changeover. The outgoing generator is gradually throttled down so that it motors causing the reverse power relay to trip its generator circuit-breaker. Main Switchboard The central section of the main switch-board is used for the control of the main generators. The switchgear cubicles on either side of the generator panels are used for essential services and flanking these are the grouped motor starter panels. Rev 1 Dated: 01.02.2012 Page 53 of 86 Main switchboard layout Handles for opening the doors on switchboard cubicles are usually linked (or interlocked) to an isolating switch. This ensures that supplies to components in the cubicle are switched off before the door can be opened. Fused isolators are isolating switches that incorporate fuses. The action of opening the switch isolates the fuses so that they can be replaced safely. Fused isolators can also be interlocked with the cubicle door handle. Motor starters frequently incorporate this arrangement. One type of interlocked fused isolator can be completely withdrawn and removed to ensure complete safety when carrying out maintenance on equipment. Maintenance on fused isolators consists of periodically checking the operating mechanism. Contacts must be inspected for damage and lightly greased with an electrical lubricant. The interlock mechanism (if fitted) should also be examined for correct and safe operation. A separate section switches the three phase 220 V a.c. low power and lighting services. The alarms and insulation resistance (earth fault) monitors are fitted separately on both the 440 V and the 220 V sections. The 440/220 V lighting transformers may be located inside the main switchboard or, more likely, will be separately mounted nearby. The main generator supply cables are connected directly to their respective circuitbreakers. Short copper bars from each generator circuit breaker connect it to the three bus-bars which run through the length of the switchboard. The bus-bars may be seen if the rear doors of the switchboard cubicle are opened, but they may be in a special enclosed bus-bar duct acting as an internal fire barrier. Switchboard instruments and controls for particular functions are grouped together. For example, the generator synchronising panel has all the instruments, relays and switches necessary for generator paralleling. Each generator panel has all the instruments, relays, switches, controls and status lamps necessary for control of the generators. The instruments on panels of outgoing circuits are usually limited to an ammeter, status lamps, function switches (e.g. manual/off/auto) and push buttons. Low power control and instrument wiring is of relatively small cross-section, with multicoloured plastic insulation which is clearly identified against the larger main power cables. The instrumentation and control wiring is supplied from fuses which are located behind the appropriate panel. Green and yellow striped earth wiring from instruments and panel doors etc., is connected to a common copper earth-bonding bar running the length of the switchboard at its rear. This earth bar is electrically bonded to the ship’s steel hull. Main Circuit Breakers A circuit breaker is an automatically-operated electrical switch designed to protect an electrical circuit from damage caused by overload or short circuit. Unlike a fuse, which operates once and then has to be replaced, a circuit breaker can be reset (either manually or automatically) to resume normal operation. When an alternating current is closed, the current reaches a steady value after a transient process. The time depends upon the resistive, inductive and capacitive Rev 1 Dated: 01.02.2012 Page 54 of 86 elements of the circuit. The highest switching current is achieved if switching is effected at zero voltage (very high peak currents can develop if the switch is closed on short circuit conditions). Opening Below a threshold voltage, any circuit can be opened without any arc formation. In practice, however, the commonly used switches do produce an arc while interrupting the current. The arc must be either kept limited or extinguished at the earliest in order not to damage the contacts. Contacts Copper is by far the most widely used contact material. But since non-conducting layers are formed on copper contacts as a result of switching, a wiping action is provided while designing copper contacts. These are also plated wih a layer of silver in many applictions. In low voltage circuits, silver is also in use as contact material Arc extinction Since switching almost invariably gives rise to arcing, extinguishing such arcs assumes vital importance to prolong contact life. The following methods are employed: • a) Lengthening of the arc till it extinguishes • b) Use of air Insulation The contacts need to be kept properly insulated from other metal parts including the body. Different insulating materials are in use. The most commonly used material is cast epoxy. Besides, PVC, polystyrene, polycarbonate and ceramics are also in use. Operation The circuit breaker must detect a fault condition. In low-voltage circuit breakers this is usually done within the breaker enclosure. Once a fault is detected, contacts within the circuit breaker must open to interrupt the circuit; some mechanically stored energy within the breaker is used to separate the contacts, although some of the energy required may be obtained from the fault current itself. When a current is interrupted, an arc is generated - this arc must be contained, cooled, and extinguished in a controlled way, so that the gap between the contacts can again withstand the voltage in the circuit. Finally, once the fault condition has been cleared, the contacts must again be reclosed to restore power to the interrupted circuit. Magnetic circuit breaker Magnetic circuit breakers use a solenoid, whose pulling force increases with the current. The circuit breaker contacts are held closed by a latch. As the current in the solenoid increases beyond the rating of the circuit breaker, the solenoid's pull releases the latch which then allows the contacts to open by spring action. Some types of magnetic breakers incorporate a hydraulic time delay feature using a viscous fluid. The core is restrained by a spring until the current exceeds the breaker rating. During an overload, the speed of the solenoid motion is restricted by the fluid. The delay permits brief current surges beyond normal running current for motor starting, energizing equipment, etc. Short circuit currents provide sufficient solenoid force to release the latch regardless of core position thus bypassing the delay feature. Thermal circuit breaker Thermal breakers use a bimetallic strip, which heats and bends with increased current, and is similarly arranged to release the latch. This type is commonly used with motor control circuits. Thermal breakers often have a compensation element to reduce the effect of ambient temperature on the device rating. Thermomagnetic circuit breaker Thermomagnetic circuit breakers, which are the type found in most distribution boards, incorporate both techniques with the electromagnet responding instantaneously to large surges in current (short circuits) and the bimetallic strip responding to less extreme but longer-term overcurrent conditions. Rev 1 Dated: 01.02.2012 Page 55 of 86 Arc interuption Miniature low-voltage circuit breakers use air alone to extinguish the arc. Larger ratings will have metal plates or non-metallic arc chutes to divide and cool the arc. Air circuit breakers may use compressed air to blow out the arc, or alternatively, the contacts are rapidly swung into a small sealed chamber, the escaping of the displaced air thus blowing out the arc. Circuit breakers are usually able to terminate all current flow very quickly: typically the arc is extinguished between 30 ms and 150 ms after the mechanisim has been tripped, depending upon the age and construction of the device. Protection Under short-circuit conditions, a current many times greater than normal can flow. When electrical contacts open to interrupt a large current, there is a tendency for an arc to form between the opened contacts, which would allow the flow of current to continue. Therefore, circuit breakers must incorporate various features to divide and extinguish the arc. In air-insulated and miniature breakers an arc chute structure consisting of metal plates or ceramic ridges cools the arc, and magnetic blowout coils deflect the arc into the arc chute. Types of circuit breaker Low voltage (less than 1000 V AC) include: • MCB (Miniature Circuit Breaker)—rated current not more than 100 A. Trip characteristics normally not adjustable. Thermal or thermal-magnetic operation. • MCCB (Moulded Case Circuit Breaker)—rated current up to 1000 A. Thermal or thermal-magnetic operation. Trip current may be adjustable in larger ratings. • Low voltage power circuit breakers can be mounted in multi-tiers in LV switchboards. Each main circuit breaker is mounted on guide rails inside a main switchboard cubicle from which it must be withdrawn and isolated from the bus-bars for maintenance and testing. The breaker and its guide rails are usually mounted in a special cassette bolted into the switchboard cubicle and electrically connected to the bus-bars. If repair work demands that the breaker is to be completely removed from its cassette then usually a special hoist or fork-lift is required for large, heavy-duty units. The action of withdrawing the circuit breaker causes a safety shutter to cover the live bus-bar contacts at the rear of its cubicle. The mechanical linkage in a circuit-breaker is quite complex Rev 1 Dated: 01.02.2012 Page 56 of 86 and should not be interfered with except for maintenance and lubrication as specified by the manufacturer. The main fixed and moving contacts are of copper (sometimes of special arcresistant alloy or silver tipped) and usually silver-alloy coated. Main contacts should not be scraped or filed. If the main contacts suffer severe burning they will probably require realignment as specified by the manufacturer. Arcing contacts normally suffer burning and may be dressed by a smooth file as recommended by the manufacturer. Carborundum and emery should not h used - the hard particles can embed themselves in the soft contacts and cause future trouble. The arc chutes or arc splitter boxes confine and control the inevitable arc to rapidly accelerate its extinction. These must be removed and inspected for broken parts and erosion of the splitter plates. Single phase a.c. motor If the rotating magnet is able to keep up with the frequency of the alternating current energizing the electromagnet windings (coils), it will continue to be pulled around clockwise. However, clockwise is not the only valid direction for this motor's shaft to spin. It could just as easily be powered in a counterclockwise direction by the same AC voltage waveform. With the exact same sequence Rev 1 Dated: 01.02.2012 Page 57 of 86 of polarity cycles (voltage, current, and magnetic poles produced by the coils), the magnetic rotor can spin in either direction. These motors need a little help getting started. Once helped to spin in a particular direction. they will continue to spin that way as long as AC power is maintained to the windings. Where that help comes from for a single-phase AC motor to get going in one direction can vary. Usually, it comes from an additional set of windings positioned differently from the main set, and energized with an AC voltage that is out of phase with the main power. These supplementary coils are typically connected in series with a capacitor to introduce a phase shift in current between the two sets of windings. That phase shift creates magnetic fields from coils 2a and 2b that are equally out of step with the fields from coils 1a and 1b. The result is a set of magnetic fields with a definite phase rotation. It is this phase rotation that pulls the rotating magnet around in a definite direction. Capacitor phase shift adds second phase. 3 Phase AC induction motors 3 phase AC motors require no such trickery to spin in a definite direction. Because their supply voltage waveforms already have a definite rotation sequence, so do the respective magnetic fields generated by the motor's stationary windings. In fact, the combination of all three phase winding sets working together creates what is often called a rotating magnetic field. Three-phase AC motor: A phase sequence of 1-2-3 spins the magnet clockwise, 3-2-1spins the magnet counterclockwise. The short explanation of the induction motor is that the rotating magnetic field produced by the stator drags the rotor around with it. The longer more correct explanation is that the stator's magnetic field induces an alternating current into the rotor squirrel cage conductors which constitutes a transformer secondary. This induced rotor current in turn creates a magnetic field. The rotating stator magnetic field interacts with this rotor field. The rotor field attempts to align with the rotating stator field. The result is rotation of the squirrel cage rotor. Rev 1 Dated: 01.02.2012 Page 58 of 86 Three-phase AC motor: A phase sequence of 1-2-3 spins the magnet clockwise, 3-2-1 spins the magnet counterclockwise. Synchronous speed • If there were no mechanical motor torque load, no bearing, windage, or other losses, the rotor would rotate at the synchronous speed. • The synchronous speed is given by: • Ns =f.60/P rpm • Ns = synchronous speed • f = frequency of applied power, Hz • P = total number of pair of poles • Example: The synchronous speed of 6-pole motor supplied at 60 Hz: • Ns = 60x60/3 = 1200 rpm However, the slip between the rotor and the synchronous speed stator field develops torque. It is the magnetic flux cutting the rotor conductors as it slips which develops torque. Thus, a loaded motor will slip in proportion to the mechanical load. If the rotor were to run at synchronous speed, there would be no stator flux cutting the rotor, no current induced in the rotor, no torque. Torque When power is first applied to the motor, the rotor is at rest, while the stator magnetic field rotates at the synchronous speed Ns. The stator field is cutting the rotor at the synchronous speed Ns. The current induced in the rotor shorted turns is maximum, as is the frequency of the current, the line frequency. As the rotor speeds up, the rate at which stator flux cuts the rotor is the difference between synchronous speed Ns and actual rotor speed N, or (Ns - N). The ratio of actual flux cutting the rotor to synchronous speed is defined as slip. Slip • Slip = (Ns - N)/Ns • where: Ns = synchronous speed, N = rotor speed • Slip at 100% torque is typically 5% or less in induction motors. Why is it so low? The stator magnetic field rotates at 60 Hz. The rotor speed is 5% less. The rotating magnetic field is only cutting the rotor at 3 Hz. The 3 Hz is the difference between the synchronous speed and the actual rotor speed. If the rotor spins a little faster, at the synchronous speed, no flux will cut the rotor at all. Rotor direction reversal By swapping over any two supply line connections at the terminal box, reverses the direction of rotating magnetic field. This reverses the direction of rotation of the rotor. Three-phase, three-wire “Y" connection does not use the neutral wire. Rev 1 Dated: 01.02.2012 Page 59 of 86 • • • • Three-phase, three-wire Δ connection has no common. • The conductors connected to the three points of a three-phase source or load are called lines. • The three components comprising a three-phase source or load are called phases. • Line voltage is the voltage measured between any two lines in a three-phase circuit. Phase voltage is the voltage measured across a single component in a three-phase source or load. Line current is the current through any one line between a three-phase source and load. Phase current is the current through any one component comprising a three-phase source or load. In “star” circuits, Eline = √3 x Ephase and Iline = Iphase In “delta” circuits, Eline = Ephase and Iline = √3 x Iphase 3 phase squirrel cage induction motor An induction motor is composed of a rotor, known as an armature, and a stator containing windings connected to a 3 phase energy source. The stator is wound with pairs of coils corresponding to the phases of electrical energy available. The 3-phase induction motor stator above has 3-pairs of coils, one pair for each of the three phases of AC. The individual coils of a pair are connected in series and correspond to the opposite poles of an electromagnet. The windings of a three-phase motor are installed in the stator slots. The ends of the stator windings are terminated in the stator terminal box where they are connected to the incoming cable from the three-phase a.c. power supply. The coils are wound on an external fixture, then worked into the slots. Insulation wedged between the coil periphery and the slot protects against abrasion. The coils are embedded into slots cut into the stator laminations. The stator laminations are thin insulated rings with slots punched from sheets of electrical grade steel. A stack of these is secured by end screws, which may also hold the end housings. The key to the popularity of the AC induction motor is simplicity as evidenced by the simple rotor. The rotor consists of a shaft, a steel laminated rotor punched from magnetic steel sheets and including slot cutouts, are sandwiched on the rotor shaft. Conducting bars of copper or aluminum are inserted in the slots and cast end rings form a low-resistance short circuit. No insulation is required between the core and the bars because of the low voltages induced into the rotor bars. The size of the air gap, between the rotor bars and stator windings, necessary to obtain the maximum field strength is small. . Rev 1 Dated: 01.02.2012 Page 60 of 86 Stator frame showing slots for windings 3-Φ windings. As compared to a DC motor armature, there is no commutator. This eliminates the brushes, arcing, sparking, graphite dust, brush adjustment and replacement, and re-machining of the commutator. The squirrel cage conductors may be skewed, twisted, with respect to the shaft. The misalignment with the stator slots reduces torque pulsations. Both rotor and stator cores are composed of a stack of insulated laminations. The laminations are coated with insulating oxide or varnish to minimize eddy current losses. The alloy used in the laminations is selected for low hysteresis losses. Motor Starters When an induction motor is connected directly to its three-phase a.c. supply voltage, a very large stator current of 5 to 8 x full-load current (FLC) is taken. This is due to the maximum rate of flux cutting (100%) in the rotor, creating large induced rotor currents. The corresponding supply power factor at start-up is very low, typically about 0.2 lagging, which rises to about 0.5 lagging on no-load then to about 0.85 lagging on full-load. This starting surge current reduces as the motor accelerates up to its running speed. Most induction motors are Direct-on-Line (DOL) switch-started because such starters are inexpensive and simple to operate and maintain. The high starting current surge will not cause serious heating damage to the motor unless the motor is repeatedly started and stopped in a short time period. When very large motors are started DOL they cause a significant disturbance of voltage (voltage dip) on the supply lines due to the large starting current surge. Rev 1 Dated: 01.02.2012 Page 61 of 86 DOL Starter This voltage disturbance may result in the malfunction of other electrical equipment connected to the supply e.g. lighting dip and flickering effects. To limit the starting current some large induction motors are started at reduced voltage and then have the full supply voltage reconnected when they have accelerated close to their rated speeds. Reduced voltage starting is used for large motors driving loads like cargo pumps and bow thrusters. • Two methods of reduced voltage starting by switching are called 1. star-delta starting 2. autotransformer starting. Star-Delta Starting If a motor is direct-on-line started with the stator winding star connected, it will only take one-third of the starting current that it would take if the windings were delta connected. The starting current of a motor which is designed to run delta connected can be reduced in this way. For large power motors, the phase windings are automatically switched using contactors controlled by a timing relay. A choice of time delay relays are available whose action is governed by thermal, pneumatic, mechanical or electronic control devices. Rev 1 Dated: 01.02.2012 Page 62 of 86 Time delay is necessary between the KM2 auxiliary contacts to provide an electrical interlock between contactors KM1 and KM3. This is to prevent a full short-circuit fault across the supply lines during the’ changeover from star to delta. At the instant of starting when the supply has just been switched on and the motor has not yet started to rotate, there is no mechanical output from the motor. The only factors which determine the current taken by the motor are the supply voltage (V) and the impedance of the motor phase windings (ZPH). • • • • • For Delta : Phase current at start IPH = V/Z Line starting current IL =√3. IPH = √3. V/Z For Star : Phase current at start IPH = V/ √3 Z Line starting current IL =IPH = V/ √3 Z Line starting current Delta/ Line starting current Star = √3. V/Z/ V/ √3 Z = 3 This shows that the starting current of a delta connected motor can be reduced to one third if the motor is star connected for starting. The shaft torque is also reduced to one-third which reduces the shaft acceleration and increases the run-up time for the drive but this is not usually a problem. When an induction motor is running on load it is converting electrical energy input to mechanical energy output. The input current is now determined by the load on the motor shaft. An induction motor will run at the same speed when it is star connected as when it is delta connected because the flux speed is the same in both cases being set by the supply frequency. Remember that the motor copper losses are produced by the I2R heating effect so the motor will run (√3)2 = 3 times hotter if left to run in the star connection when designed for delta running. This malfunction may occur if the control timing sequence is not completed or the star contactor remains closed while a mechanical interlock prevents the delta contactor from closing. For Rev 1 Dated: 01.02.2012 Page 63 of 86 correct overcurrent protection, the overcurrent relays must be fitted in the phase connections and not in the line connections. Autotransformer Starting Starting a large motor with a long run-up period will demand a very high current surge from the supply generator for a few seconds. This causes a severe voltage dip which affects every load on the system. Reduced voltage starting will limit the starting surge current. One way to reduce the initial voltage supplied to the motor is to step it down using a transformer. Then, when the motor has accelerated up to almost full speed, the reduced voltage is replaced by the full mains voltage. The transformer used in this starter is not the usual type with separate primary and secondary windings. It is an autotransformer which uses only one winding for both input and output. This arrangement is cheaper, smaller and lighter than an equivalent double-wound transformer and it is only in operation during the short starting period. For induction motor starting, the autotransformer is a 3-phase unit and because of expense, this method is only used with large motor drives, e.g. electric cargo pumps. The supply voltage is connected across the complete winding and the motor is connected to the reduced voltage tapping. The autotransformer usually has a few tapping points to give a set of reduced voltages (e.g. 40%, 50% and 65%) which help to match the motor current demand to the supply capability. As with the star-delta starter, the autotransformer may use what is called an open-transition switching sequence or a closed-transition switching sequence between the start and run conditions. In the former, the reduced voltage is supplied to the motor at start then disconnected and the full supply voltage rapidly reconnected to the motor. The problem with open transition is that a very large surge current can flow after the transition from reduced to full voltage. Rev 1 Dated: 01.02.2012 Page 64 of 86 Contactors When a relay is used to switch a large amount of electrical power through its contacts, it is designated by a special name: contactor. Contactors typically have multiple contacts, and those contacts are usually (but not always) normally-open, so that power to the load is shut off when the coil is de-energized. Perhaps the most common industrial use for contactors is the control of electric motors. Construction A contactor is composed of three different systems. The contact system is the current carrying part of the contactor. This includes Power Contacts, Auxiliary Contacts, and Contact Springs. The electromagnet system provides the driving force to close the contacts. The enclosure system is a frame housing the contact and the electromagnet. Enclosures are made of insulating materials like Bakelite, Nylon 6, and thermosetting plastics to protect and insulate the contacts and to provide some measure of protection against personnel touching the contacts. Open-frame contactors may have a further enclosure to protect against dust, oil, explosion hazards and weather. Contactors used for starting electric motors are commonly fitted with overload protection to prevent damage to their loads. When an overload is detected the contactor is tripped, removing power downstream from the contactor. A basic contactor will have a coil input (which may be driven by either an AC or DC supply depending on the contactor design) and generally a minimum of two poles which are controlled. Operating Principle Unlike general-purpose relays, contactors are designed to be directly connected to high-current load devices, not other control devices. Relays tend to be of much lower capacity and are usually designed for both Normally Closed and Normally Open applications. Devices switching more than 15 amperes or in circuits rated more than a few kilowatts are usually called contactors. Apart from optional auxiliary low current contacts, contactors are almost exclusively fitted with Normally Open contacts. Rev 1 Dated: 01.02.2012 Page 65 of 86 When current passes through the electromagnet, a magnetic field is produced which attracts ferrous objects, in this case the moving core of the contactor is attracted to the stationary core. Since there is an air gap initially, the electromagnet coil draws more current initially until the cores meet and reduct the gap, increasing the inductive impedance of the circuit. For contactors energized with alternating current, a small part of the core is surrounded with a shading coil, which slightly delays the magnetic flux in the core. The effect is to average out the alternating pull of the magnetic field and so prevent the core from buzzing at twice line frequency. Three-phase, 440 volt AC power comes in to the three normally-open contacts at the top of the contactor via screw terminals labeled "L1," "L2," and "L3". Power to the motor exits the overload assembly at the bottom of this device via screw terminals labeled "T1," "T2," and "T3." The main power circuit contacts for the motor are held open by spring tension When the coil becomes energized, the magnetic attraction between the armature and the magnet overcomes spring tension, and the main contacts for the motor close. The motor now operates. Induction Motor Speed Control Induction motor operates as an almost constant speed drive over its load range. This feature is satisfactory for most of the ship’s auxiliary services supplying power to ventilation fans and circulating pumps. Variable speed control is necessary for cranes, winches, windlass etc. • Two main forms of speed change/control are available: 1. Pole-changing for induction motors to give two or more fixed speeds 3-speed winches 2. Continuously variable speed control e.g. smooth control of deck cranes, winches and electric ship propulsion using variable frequency Pole Changing Fixed set speeds can be obtained from a induction motor by using a dual wound stator winding, each winding being designed to create a different number of magnetic poles. Rev 1 Dated: 01.02.2012 Page 66 of 86 A dual-wound induction motor is arranged to create 6 pole and 10 pole stator magnetic fields. Estimate the rated speeds assuming that the rotor slips by 5% and the power supply is at a frequency of 60 Hz. • NS = f.60/p rpm • For 6 poles: Ns = 60x60/3=1200 rpm NR = 0.95x1200=1140 rpm For 10 poles: Ns = 60x60/5=720 rpm NR = 0.95x720=684 rpm A 3-speed pole-change winch motor can be arranged by having two cage rotors mounted on the same drive shaft. One stator winding (usually 24-pole) gives a low speed while the other is dual wound to give medium speed 8 pole) and high speed (4 pole) outputs. Speed control and drive direction are achieved by a set of switching and reversing contactors operated from the winch control pedestal. Remember that to reverse the rotation of an induction motor it is necessary to switch over two of the supply lines to the stator winding. An alternative method giving two fixed speeds in a 2:1 ratio from a cage-rotor induction motor is to use a single stator winding which has centre-tap connections available on each phase. This method uses a starter with a set of contactors to switch the phase windings into either single-star (low speed) or double-stars (high speed). Continuously variable speed A continuously variable speed range of motor control involves more complication and expense than that required to obtain a couple of set speeds. Various methods are available which include: 1. Electro- hydraulic drive. 2. Wound-rotor resistance control of induction motors. 3. Ward-Leonard d.c. motor drive. 4. Variable-frequency induction motor control Electro-hydraulic drive The electro-hydraulic drive, often used for deck crane control, has a relatively simple electrical section. This is a constant single-speed induction motor supplied from a DOL or stardelta starter. The motor runs continuously to maintain oil pressure to the variable-speed hydraulic motors. Wound-rotor resistance control A crude form of speed control is provided by the wound rotor induction motor. The rotor has a 3-phase winding (similar to its stator winding) which is connected to 3 slip rings mounted on the shaft. An external 3-phase resistor bank is connected to brushes on the rotor slip rings. A set of contactors or a slide wiper (for small motors) varies the amount of resistance added to the rotor circuit. Increasing the value of external resistance decreases the rotor speed. Ward-Leonard d.c. motor drive A constant speed induction motor drives a d.c. generator, which in turn supplies one or more d.c. motors. The Rev 1 Dated: 01.02.2012 Page 67 of 86 generator output is controlled by adjusting its small excitation current via the speed regulator. The d.c. motor speed is directly controlled by the generator voltage. The motor generator requires more space and maintenance. An alternative is a static electronic thyristor controller, which is supplied with constant a.c. voltage and delivers a variable d.c. output voltage to control the drive motor. Variable-frequency control A static electronic transistor or thyristor (high power) controller can be used to generate such a variable frequency output to directly control the speed of the motor. Motor Protection Protecting an electric motor basically involves preventing the motor from getting too hot. Every 10°C above the maximum recommended temperature of the insulation can reduce its working life by half. Obviously, the best way to protect a motor against overheating is to directly monitor the temperature of the motor windings. If the temperature exceeds the maximum set value for the motor insulation its contactor is tripped to stop the motor and allow it to cool down. Temperature sensors Three main types of direct temperature sensors can be used. These are: 1. Thermocouple 2. Resistance temperature device (RTD) 3. Thermistor Thermistor protection The Thermistor sensor’s thermal characteristic more closely matches that of a motor than the other types. Thermistors are small pellets of semiconductor material , which are embedded into all three of the motor stator windings during manunufacture. When a thermistor gets hot, their resistance changes dramatically. They are connected so that if the motor temperature gets too high, the starter contactor will be tripped by an electronic relay to stop the motor. Direct thermistor protection is usually only fitted to large motors. Over current relay (OCR) Most motors are protected by monitoring the temperature indirectly by measuring the current flowing in the supply lines. This method uses electronic, thermal or electromagnetic timedelayed overcurrent relays (OCRs) in the motor starter. The system is designed so that if the motor takes too much current because it is mechanically overloaded, the OCR will trip out the contactor coil, after a pre-set time delay, before severe overheating can occur. The largest overcurrent possible is the current taken when the motor has stalled. This, of course, is the starting current of the motor which will be about five times the full load current. The contactor is capable of tripping this stalled current quickly and safely. Short-circuit If a short-circuit occurs in the motor, the starter, or the supply cable, then a huge fault current will flow. If the contactor tries to open under short-circuit conditions, serious arcing will occur at its contacts such that it may fail to interrupt the fault current. The prolonged short-circuit current will cause serious damage to the motor, starter and cable with the attendant risk of an electrical fire. To prevent this, a set of fuses or a circuit breaker is fitted upstream of the contactor which will trip out almost instantaneously thereby protecting the contactor during a short-circuit fault. It is important that the tripping characteristics of the OCR and fuses/circuit breaker are co-ordinated so that the contactor trips on thermal overcurrent, while the fuses/circuit breaker interrupt shortcircuit fault currents. This contactor-fuse arrangement is usually called back-up protection. Rev 1 Dated: 01.02.2012 Page 68 of 86 It must be emphasised that the motor fuses are not chosen for their rated current but for their inverse current/time (I/t) characteristic. This means that the current rating of fuses used to protect a motor does not appear to have any direct relationship to the FLC rating of the motor. Fuses used for back-up protection for motor circuits have a special time/current characteristic. They are generally carrying steady currents well below their rated capacity to allow for short duration DOL starting currents without blowing. Consequently they do not protect against normal overloads but do protect the motor and supply system against short-circuit fault. A typical fuse designation for motor circuits could be ‘32M63’, which indicates a continuous rating of 32 A but a rating of 63A for starting period. Types of OCR • There are three types of OCR used for motor protection: 1. Electronic 2. Thermal 3. Electromagnetic Electronic OCIT Electronic overcurrent inverse time (OCIT) have largely superseded electromagnetic types as they have no moving parts (except for their output trip relay) and their very reliable tripping characteristics can be closely matched to the motor circuit. Such relays are robust, smaller and lighter than the equivalent electromagnetic type. Electromagnetic OCR Although electromagnetic devices with time delays can give adequate protection against large, sustained overloads to motors which are operated well below their maximum output and temperature, they have been found to be inadequate for continuous maximum rated (CMR) motors. Thermal OCR Most motors are protected by less expensive thermal OCRs. Inverse-time thermal OCRs usually work with bi-metal strips. The strips are heated by the motor current and bend depending on the temperature. If the motor takes an overload current, the strips operate a normally-closed (NC) contact which trips out the line contactor to stop the motor. The minimum tripping current of such a device can be adjusted over a small range. This adjustment alters the distance the strips have to bend before operating the trip contact. For larger motors, the heaters do not carry the full motor current. They are supplied from current transformers (CTs) which proportionally stepdown, the motor current so that smaller heater components may be used. Rev 1 Dated: 01.02.2012 Page 69 of 86 Bimetallic overcurrent action. Undervoltage protection Undervoltage protection is necessary in a distribution system that supplies motors. If there is a total voltage loss or black-out, all the motors must be disconnected from the supply. This is to prevent all the motors restarting together which would result in a huge current surge, tripping out the generator again. Motors must be restarted in a controlled sequence after a supply failure. Undervoltage protection for motors is simply provided by the spring-loaded motor contactor because it will drop out when the supply voltage is lost. When the supply voltage becomes available, the motor will not restart until its contactor coil is energised. This will usually require the operator to press the stop/reset button before initiating the start sequence. For essential loads, the restart may be performed automatically by a sequence restart system. This system ensures that essential services are restarted automatically on restoration of supply following a blackout. Timer relays in the starters of essential motor circuits are set to initiate start-up in a controlled sequence. Single-phasing To operate correctly, induction motors must be connected to a three phase a.c. supply. Once started they may continue to run even if one of the three supply lines becomes disconnected. This is called single-phasing and can result in motor burn-out. Single-phasing, is usually caused when one of the three back-up fuses blows or if one of the contactor contacts is open-circuited. The effect of single-phasing is to increase the current in the two remaining lines and cause the motor to become very noisy due to the uneven torque produced in the rotor. An increase in line current due to single-phasing will be detected by the protective OCR. The three thermal elements of an OCR are arranged in such a way that unequal heating of the bi-metal strips causes differential movement, which operates the OCR switch contacts to trip the motor contactor. For star connected motor windings the phase current and line currents are equal so the line connected OCR is correctly sensing the winding current. If the overcurrent setting is exceeded during a single-phase fault, the motor will be tripped off. In delta connected motor, the phase current is about half of line current (IPH =IL/√3 = 0.577 IL). When one of the lines becomes open-circuited a balanced three phase condition no longer exists. Now the sets of line and phase currents are no longer balanced.. Rev 1 Dated: 01.02.2012 Page 70 of 86 Healthy condition (balanced) % of rated FLC 60 70 100 Single phasing – fault condition (unbalanced) % of rated FLC IL2 and IL3 IA and IB IC 102 62 131 130 79 161 243 129 185 The current in winding C is considerably higher than that in the other two windings. When the motor is at 60% of full load and single-phasing occurs: the line currents are 102% of the full load value but the current in winding C is 131% of Its full load value, The 102% line current will probably not activate a line connected OCR and the motor remains connected. However the local overheating in winding C of the motor will quickly result in damage. Motors can be protected against this condition by using a differential type relay which trips out with unbalanced currents. In fact, most modern thermal OCRs for motors have this protection against singlephasing incorporated as a normal feature. If single-phasing occurs when in operation on light load, the motor keeps on running unless the protection trips the contactor. If the motor is stopped, it will not restart. When the contactor is closed, the motor will take a large starting current but develop no rotating torque. The OCR is set to allow the starting current to flow long enough for the motor, under normal conditions, to run up to speed. With no ventilation on the stationary motor, this time delay will result in rapid and severe over-heating. Worse still, if the operator makes several attempts to restart the motor, it will burn out. If a motor fails to start after two attempts, you must investigate the cause. 3 bi-metals - cold position 3 bi-metals – hot (balanced) 2 bi-metals hot,1 cold (differential) Motor enclosures Enclosure protection for electrical equipment is defined in terms of its opposition to the ingress of solid particles and liquids. The enclosure protection is defined by the Ingress Rev 1 Dated: 01.02.2012 Page 71 of 86 Protection (IP’) Code where a two-figure number is used to indicate the degree of protection against the ingress of solids and liquids. First digit indicates protection against ingress of solids and the second digit indicates protection against ingress of liquids. Higher the numerals, greater the degree of protection. Drip-proof open ventilated motors are used where the risk of liquids leaking from overhead pipes and valves may be a problem. Air is drawn into the machine by an internal fan to provide cooling. The ventilation ducts are fitted with mesh screens to prevent any objects from entering the motor and causing damage. These screens must always be kept clean and free from dust otherwise the motor will overheat due to inadequate ventilation. TEFV motor enclosure.. When a greater degree of protection is required the enclosure is made Totally Enclosed Fan Ventilated (TEFV) and jet-proof. No external air is allowed inside the motor. To improve heat transfer the motor casing is finned to increase the surface area, and airflow across the fins is achieved by means of an external fan and cowl arrangement. Deck motors for tankers must have a flameproof (Exd) enclosure if they are within 3m (4.5m for some ships) of an oil tank outlet. Motor nameplate 1. Rated Full Load Current (FLC) 2. Rated Voltage 3. Rated frequency 4. Power rating 5. Rated speed 6. Ingress Protection number (IP) 7. Insulation class Insulation class All electrical equipment heats up when carrying load current with the consequent rise in temperature. This temperature rise is above that of the ambient cooling air temperature. All marine electrical equipment is constructed and rated to work satisfactorily in a maximum ambient air temperature of 45°C. Under these conditions the expected temperature rise will not exceed the permitted temperature limit set for the insulation material. It is therefore the insulation material that dictates the maximum permitted operating temperature of the electrical equipment. For this purpose, insulation is classified according to the maximum temperature at which it is safe to operate. Various classes of insulation are listed. A machine operating continuously with these hot-spot temperatures would have an expected life of 15 to 20 years before the insulation failed completely. However, the life expectancy would be halved for every 10°C above these allowed hot-spot temperatures. Rev 1 Dated: 01.02.2012 Page 72 of 86 Insulation class Maximum temperature allowed (0C) Allowable Typical material temperature rise at full load (0C) A B 105 120 55 70 E 130 80 F 155 105 H 180 130 Cotton, natural silk, synthetic silk, presspan Wire enamels with a base of polyvinyl acetyl, epoxy or polyamide resins Mica products, wire enamels with a base of polyterephthalate, laminated glass fibre materials Mica products, glass fibre, wire enamels with a base of imide-polyester and esterimide Mica products, glass fibre, wire enamels with a base of pure polyimide Electrical Practice for Tankers Hazardous Zones ashore Hazardous areas ashore are classified into zones which indicate the probability of an explosive gas-air mixture being present and, therefore, the likelihood of an explosion occurring. • Zone 0 In which an explosive gas-air mixture is continuously present, or present for long periods. • Zone 1 In which an explosive gas-air mixture is likely to occur in normal operation. • Zone 2 In which an explosive gas-air mixture is not likely to occur in normal operation and, if it occurs, will exist for only a short time. Hazardous Zones in tankers • An area which is not classified Zone 0, 1 or 2 is assumed to be a non-hazardous or safe area. Examples of this zoning applied to ships could be: • Zone 0 Interior spaces of oil cargo tanks, pipes, pumps, etc. • Zone 1 Enclosed or semi-enclosed spaces on the deck of a tanker, the boiler firing area on a LNG gas carrier using methane boil-off as a fuel and battery rooms. • Zone 2 1. Open spaces on the deck of a tanker 2. The cargo pump rooms of tankers are, at present, considered as falling somewhere between Zone 0 and Zone 1. Types of Explosion Protection There are a number of different constructional techniques employed in preventing electrical equipment causing explosions in hazardous areas. Some techniques, such as flameproof enclosures, have long been established but others, such as intrinsic safety and increased safety, are the result of developments in material and electrical/electronic‘ circuit design. It has been internationally agreed that explosion protected equipment be identified by the symbol “Ex” followed by a letter indicating the type of protection employed. Rev 1 Dated: 01.02.2012 Page 73 of 86 Symbol Type of Protection Exd Flameproof enclosure Exi Intrinsic safety Exe Increased safety Exn Non-sparking Exq Powder filled (non-applicable to ships) Exo Oil immersed (non-applicable to ships) Exp Pressurisation Exs Special protection Some equipment may use more than one of these types of protection in its construction. In this case, the primary type of protection is quoted first. For example, an increased Safety motor with a flameproof terminal box would be marked Exe d. Equipment may also be marked with a prefix ‘E” which denotes compliance with European Standards e.g. EExe d. Exd Flameproof Enclosure Exd flamepaths. Type ‘d’ protection, code EExd, uses a flameproof enclosure to contain the electrical apparatus. The internal apparatus may include parts which arc and, surfaces which become hot. Gas may be inside the enclosure so it must fulfill three conditions: 1. The enclosure must be strong enough to withstand an internal explosion without suffering damage. 2. The enclosure must prevent the flame and hot gases from being transmitted to the external flammable atmosphere. 3. The external surface temperature of the enclosure must remain below the ignition temperature of the surrounding gas under all operating conditions. The transmission of flame and hot gases from a flameproof enclosure is prevented because all joints, such as flanges, spigots, shafts and bearings are closely machined to achieve a small gap which is less than a defined maximum. The pressure of an internal explosion is then released through the small gap between machined faces which cools the gas sufficiently to prevent it from igniting any external flammable atmosphere. • The maximum permitted gap depends upon three factors: 1. The type of gas with which the apparatus is safe for use. This is indicated by Apparatus Group. 2. The width of the joint (L). 3. The volume of the’ enclosure (V). Exi Intrinsic Safety These are circuits in which no spark nor any thermal effect produced under prescribed test conditions (which include normal operation and specified fault conditions) is capable of causing ignition of a given explosive atmosphere. Generally, this means limiting the circuit conditions to less than 30 V and 50 mA. Naturally, this restricts the use of Exi protection to low Rev 1 Dated: 01.02.2012 Page 74 of 86 power instrumentation, alarm and communication circuits. The design of the circuit will depend on the type of gas present (gas grouping). In the UK, two grades of intrinsic safety are recognised based on the safety factor of the equipment involved: • Exia - the highest category based on a safety factor of 1.5 with two faults on the circuit. • Exib - based on a safety factor of 1.5 with one fault on the circuit. Exe Increased Safety Increased safety equipment is based primarily on the elimination of open sparking as at relay and switch contacts or on the commutators or slip-rings of motors and generators, and on the close control of surface temperatures. Also, the construction of the equipment is to a very high standard to prevent faults developing. Extra insulation is used, creepage distances between bare terminals are made longer and special enclosures to protect against damage due to entry of moisture and mechanical damage are also specified. Creepage and clearance distances. The enclosure is made to withstand impact and to prevent ingress of solids and liquids. Applications include cage-rotor induction motors, luminaires and connection boxes. Special Exe cable glands, metal or plastic, are used with Exe apparatus. Power and intrinsically safe cable runs should be separately identified. i.e. by labels or by using cables with a distinctive colour (typically blue for Exi). Exn Non sparking Similar to Exe, the designation Exn applies to equipment which has no arcing contacts or hot surfaces which could cause ignition. The Exn requirements are less stringent than for Exe, and designs are very close to that of normal electrical apparatus. The main consideration is extra care to ensure locking of terminal connections to avoid any risk of electric sparking or flashover. Exp Pressurised Enclosure Clean, dry air or an inert gas is supplied to the equipment slightly above atmospheric pressure to prevent entry of the external flammable gas. This method is sometimes used for motors, instrumentation enclosures and lighting. The diagrams in Fig. 6.9 show that the internal pressure may be maintained by leakage compensation or by continuous circulation. A pressurisation system requires a purge flow before the internal electrical equipment is permitted to operate. Also, the pressurised enclosure must be fitted with alarm and trip signaling for a reduction of pressure which in turn will switch-off the enclosed electrical Circuits. Exs Special Protection This includes precautions taken to prevent explosions which are not specifically covered by the previous designations. The table below shows the type of protection which is allowed in the three hazardous zones: Rev 1 Dated: 01.02.2012 Page 75 of 86 Zone 0 Type of Protection Exia Exs (Specially certified for use in Zone 0) 1 Any type of protection suitable for Zone 0 and: Exd; Exib; Exp; Exe and Exs 2 Any type of protection suitable for Zone 0 or 1 and: Exn; Exo and Exq Electrical Testing in Hazardous Areas All electrical apparatus and associated circuits are required to be tested periodically in accordance with a definite testing routine with recorded test results. Insulation resistance, earth loop resistance and earth continuity resistance tests are required to be made, the last two in relation to the setting or rating of the protective devices associated with the apparatus and its circuitry. It is important that insulation resistance tests are NOT made in such a way that the safety devices and insulation used in intrinsically safe apparatus and circuits are damaged by excess test voltages. No apparatus should be opened in a danger area until it has been made dead and effective measures (e.g. locking-off the isolating switch) have been taken to prevent its being made live again inadvertently. Where, for the purpose of electrical testing, it is necessary to restore the power supply before the apparatus is reassembled, tests should be made using a suitable gas detector and continued during the operation to ensure that the combustible does not approach the explosive limit. Unless the hazardous area can be made gas-free or otherwise safe, or the electrical equipment is removed from the area, then insulation resistance testing should be carried out using a 500 V d.c. tester of certified intrinsically safe design. The testing and maintenance of flameproof or intrinsically safe equipment should be entrusted only to competent persons who have received instruction in the special techniques involved. The body material of instruments and tools required for maintenance purposes should be designed so that they will not make a hot spark when dropped. The energy output of all intrinsically safe instruments should be so small that they do not produce hot sparks. An insulation tester has a drooping characteristic to prevent high currents and may be intrinsically safe when applied to circuits of small inductance or capacitance but a risk may arise when such energy-storing properties of a circuit have an appreciable value. Where such instruments are used the test leads should be firmly connected throughout and on completion of the test they should not be detached until the circuit has been discharged through the testing instrument (leave the tester for one minute after test is finished). Stroboscopic effect of light The normal sinusoidal a.c. voltage wave-form causes discharge lamps to extinguish at the end of every half cycle, i.e. every 10 ms at 50 Hz or every 6.7 ms at 60 Hz. Although this rapid light fluctuation is not detectable by the human eye, it can cause a stroboscopic effect whereby rotating shafts in the vicinity of discharge lamps may appear stationary or rotating slowly which could be a dangerous illusion to operators. Methods to alleviate a stroboscopic problem 1. Use a combination of incandescent and discharge lighting in the same area. 2. Use twin discharge lamp fittings with each lamp wired as a lead-lag circuit, i.e. the lamp currents are phase displaced so that they go through zero at different times, hence the overall light output is never fully extinguished. 3. ‘Where a 3-phase supply is available, connect adjacent discharge luminaires to different phases (Red, Yellow, Blue) so the light in a given area is never extinguished. Rev 1 Dated: 01.02.2012 Page 76 of 86 Navigation and Signal Lights The number, position and visible range of navigation lights aboard ships are prescribed by the International Maritime Organization (IMO) in their “International Regulations for Preventing Collisions at Sea”. By far the most common arrangement is to have five specially designed navigation running lights referred to as Foremast, Mainmast (or Aftmast), Port, Starboard and Stem. Two anchor lights, fitted forward and aft, may also be switched from the Navigation Light Panel on the bridge. The side lights are red for Port and green for Starboard while the other lights are white. For vessels length more than 50 metres, the masthead light(s) must be visible from a range of six nautical miles and the other navigation lights from three nautical miles. To achieve such visibility, special incandescent filament lamps are used each with a typical power rating of 65 W but 60 W and 40 W ratings are also permitted in some cases. Due to the essential safety requirement for navigation lights it is common practice to have two fittings at each position, or two lamps and lamp holders within a special dual fitting. Each light is separately .supplied, switched, fused and monitored from a Navigation Light Panel in the wheelhouse. The electric power is provided usually at 220 V a.c. with a main supply fed from the essential services section of the main switchboard. An alternative or standby power supply is fed from the emergency switchboard. A changeover switch on the Navigation Light Panel selects the main or standby power supply. The Navigation Light Panel has indicator lamps and an audible alarm to warn of any lamp or lamp-circuit failure. Navigation light Panel Each lamp circuit has an alarm relay which monitors the lamp current. The relay may be electromagnetic or electronic. Rev 1 Dated: 01.02.2012 Page 77 of 86 Navigation light panel. Signal light arrangement Various signal lights with red, green, white and blue colours are arranged on the signal mast. These lights are switched to give particular combinations to signal states relating to various international and national regulations. Pilotage requirements, health, dangerous cargo conditions, etc. are signalled with these lights. White Morse-Code flashing lights may also be fitted on the signal mast. The NUC (Not Under Command) state is signalled using two all-round red Iights vertically mounted at least 2m apart. Such important lights are fed from 24V dc supply. Electrical Diagrams There are various types of diagram which attempt to show how an electrical circuit operates. 1. Block Diagram 2. System diagram 3. Circuit diagram 4. Wiring diagram Symbols are used to represent the various items of equipment. Block Diagram Rev 1 Dated: 01.02.2012 Page 78 of 86 Diesel Generator (440V) Main Switchboard Auxiliary Switchboard Emergency Generator (440V) Emergency Switchboard Motors (440V) Motors (440V) Change over switch Motors (440V) A block diagram shows in simplified form , the main inter-relationships of the elements in a system, and how the system works or may be operated. Such diagrams are often used to depict control systems and other complex relationships. System diagram A system diagram shows the main features of a system and its bounds, without necessarily showing cause-to-effect. Its main use is to illustrate the ways of operating the system. Detail is omitted in order to make the diagram as clear as possible, and so, easily understood. Circuit diagram Rev 1 Dated: 01.02.2012 Page 79 of 86 A circuit diagram shows, in full, the functioning of a circuit. All essential parts and connections are depicted by means of graphical symbols arranged to show the operation as clearly as possible but without regard to the physical layout of the various items, their parts or connections. (See Star-Delta Starter Circuit Diagram). A most important point is that no attempt is made to show the moving contacts of a relay or contactor alongside the coil that operates them (where they are actually physically located). Instead, the coil and its related contacts are identified by a common number or letter. For example, contactor coil ‘CC’ controls two auxiliary contacts identified as ‘CC-1’ and ‘CC-2’ in addition to the main contacts identified as ‘CC’. The use of a circuit diagram is to enable the reader to understand the operation of the circuit, to follow each sequence in the operation from the moment of initiating the operation (e.g. by pressing a start button) to the final act (e.g. starting of the motor). If the equipment fails to operate correctly, then you can follow the sequence of operations until you come to the operation that has failed. The components involved in that faulty operation can then be examined to locate the suspect item. There is no need to examine other components that are known to function correctly and have no influence on the fault, so the work is simplified. A circuit diagram is an essential tool for fault finding. Salient features of circuit diagram • Every sequence is drawn from left to right and from top to bottom. • Each stage is in order of occurrence from left to right. • All contacts and components which are in series is drawn in a straight line with the component they control. • All contacts and components which are in parallel are drawn side by side and at the same level to emphasise their parallel function. • All major components operating at bus-bar voltage are drawn at the same level to help identify the required components quickly. • All contacts should be shown open or closed as in their normal or de-energised condition. Wiring diagram Rev 1 Dated: 01.02.2012 Page 80 of 86 A wiring diagram shows the detailed connections between components or items of equipment, and in some cases the routeing of these connections. An equipment wiring diagram shows the components in their approximate positions occupied ,within the actual enclosure. The component may be shown complete (e.g. a contactor coil together with all the contacts it drives) or may be simply represented by a block with the necessary terminals clearly marked. A different thickness of line can be used to differentiate between power and control circuit connections. A wiring diagram may be of a fairly simple circuit, but its layout makes it quite difficult to use and to understand the sequential operation of the circuit. The purpose of a wiring diagram is mainly to instruct the wiring installer how to construct and connect the equipment. It is of little use in trouble shooting apart from identifying the exact position of suspect components, terminals and wires. Battery Atoms bound together by electrons are called molecules. Ionic bonds are molecular unions formed when an electron deficient atom (a positive ion) joins with an electron-excessive atom (a negative ion). Chemical reactions involving ionic bonds result in the transfer of electrons between atoms. This transfer can be harnessed to form an electric current. A cell is a device constructed to harness such chemical reactions to generate electric current. A cell is said to be discharged when its internal chemical reserves have been depleted through use. Types of batteries The two main types of rechargeable battery cell are: • Lead-acid • Alkaline The nominal cell voltages of each type are 2 V for lead-acid and 1.2 V for alkaline. Hence, twelve lead-acid cells or twenty alkaline cells must be connected in series to produce a nominal 24 V. More cells may be connected in parallel to increase the battery capacity which is rated in Ampere-hours (Ah). The battery capacity is usually rated in terms of its discharge at the 10 hour rate. A 350 Ah battery would be expected to provide 35 A for 10 hours. However, the battery will generally have a lower capacity at a shorter discharge rate. After a 10 hour discharge a lead-acid cell voltage will have fallen to approximately 1.73 V. The equivalent figure for an alkaline cell is 1.14 V. Lead acid battery In the common "lead-acid" cell the negative electrode is made of lead (Pb) and the positive is made of lead peroxide (PbO2), both metallic substances. The electrolyte solution is a dilute sulfuric acid (H2SO4 + H2O). If the electrodes of the cell are connected to an external circuit, such that electrons have a place to flow from one to the other, negatively charged oxygen ions (O-) from the positive electrode (PbO2) will ionically bond with positively charged hydrogen ions (H+) to form molecules of water (H2O). This creates a deficiency of electrons in the lead peroxide (PbO2) electrode, giving it a positive electrical charge. The sulfate ions (SO4-) left over from the disassociation of the hydrogen ions (H+) from the sulfuric acid (H2SO4) will join with the lead (Pb) in each electrode Rev 1 Dated: 01.02.2012 Page 81 of 86 to form lead sulfate (PbSO4). This process of the cell providing electrical energy to supply a load is called discharging, since it is depleting its internal chemical reserves. Theoretically, after all of the sulfuric acid has been exhausted, the result will be two electrodes of lead sulfate (PbSO4) and an electrolyte solution of pure water (H2O), leaving no more capacity for additional ionic bonding. In this state, the cell is said to be fully discharged. In a lead-acid cell, the state of charge can be determined by an analysis of acid strength. This is easily accomplished with a device called a hydrometer, which measures the specific gravity (density) of the electrolyte. Sulfuric acid is denser than water, so the greater the charge of a cell, the greater the acid concentration, and thus a denser electrolyte solution. There is no single chemical reaction representative of all voltaic cells, so any detailed discussion of chemistry is bound to have limited application. The important thing to understand is that electrons are motivated to and/or from the cell's electrodes via ionic reactions between the electrode molecules and the electrolyte molecules. The reaction is enabled when there is an external path for electric current, and ceases when that path is broken. Being that the motivation for electrons to move through a cell is chemical in nature, the amount of voltage (electromotive force) generated by any cell will be specific to the particular chemical reaction for that cell type. For instance, the lead-acid cell just described has a nominal voltage of 2.2 volts per cell, based on a fully "charged" cell (acid concentration strong) in good physical condition. There are other types of cells with different specific voltage outputs. The Edison cell, for example, with a positive electrode made of nickel oxide, a negative electrode made of iron, and an electrolyte solution of potassium hydroxide (a caustic, not acid, substance) generates a nominal voltage of only 1.2 volts, due to the specific differences in chemical reaction with those electrode and electrolyte substances. The chemical reactions of some types of cells can be reversed by forcing electric current backwards through the cell (in the negative electrode and out the positive electrode). This process is called charging. Any such (rechargeable) cell is called a secondary cell. A cell whose chemistry cannot be reversed by a reverse current is called a primary cell. When a lead-acid cell is charged by an external current source, the chemical reactions experienced during discharge are reversed: Rev 1 Dated: 01.02.2012 Page 82 of 86 Lead acid battery The state of charge held by a lead-acid battery is best indicated by a test on the electrolyte specific gravity (SG) by using a hydrometer as shown in Fig. 5.26. A fully charged lead-acid cell has an SG of about 1.27-1.285 (often written as 1270-1285) which falls to about 1.1 (or 1100) when fully discharged. The cell voltage also falls during discharge and its value can also be used as an indication of the state of charge. A lead-acid battery may be safely discharged until the cell voltage drops to approximately 1.73 V (measured while delivering load current). Rev 1 Dated: 01.02.2012 Page 83 of 86 Alkaline battery The state of charge of an alkaline battery cell cannot be determined from its SG value. The electrolyte density does not change during charge/discharge cycles but gradually falls during the lifetime of the battery. New alkaline cells have an SG of around 1190. When this reduces to about 1145 (which may take 5-10 years depending on the duty cycle) the electrolyte must be completely renewed or the battery replaced. Discharge of alkaline cells should be discontinued when the cell voltage has fallen to about 1.1V. Battery charging equipment uses a transformer/rectifier arrangement to supply the required d.c. voltage to the cells. The size of voltage depends on the battery type (lead-acid or alkaline) and the mode of charging, e.g. charge/discharge cycle, boost charge, trickle or float charge. Check the manufacturer’s instructions for details of the required charging voltages. Do not allow electrolyte temperatures to exceed about 45°C during charging. A lead-acid cell will gas freely when fully charged but an alkaline cell gases throughout the charging period. The only indication of a fully charged alkaline cell is when its voltage remains at a steady maximum value of about 1.6-1.8 V. Generally, alkaline cells are more robust, mechanically and electrically, than lead- acid cells. Nickel cadmium cells will hold their charge for long periods without recharging so are ideal for standby duties. Also they operate well with a float-charge to provide a reliable emergency supply when the main power fails. For all rechargeable batteries (other than the sealed type) it is essential to replace lost water (caused during gassing and by normal evaporation) with the addition of distilled water to the correct level above the plates. Exposure of the cell plates to air will rapidly reduce the life of the battery. Battery installations for both types of battery are similar in that the battery room should be well ventilated, clean and dry. Both types generate hydrogen gas during charging so smoking and naked flames must be prohibited in the vicinity of the batteries. Steelwork and decks adjacent to lead-acid batteries should be covered with acid-resisting paint and alkali resisting paint used near Ni-cad cells. Acid cells must never be placed near alkaline cells otherwise rapid electrolytic Corrosion to metalwork and damage to both batteries is certain. For similar reasons, never use lead-acid battery maintenance gear (e.g. hydrometer, topping up bottles, etc.) on an alkaline installation or vice-versa. Battery maintenance includes keeping the cell tops clean and dry, checking the tightness of terminal nuts and applying a smear of petroleum jelly to such connections to prevent corrosion. Be most careful when handling the battery electrolyte (e.g. when using a hydrometer to check its specific gravity). Use protective rubber gloves and eye goggles when handling electrolyte. Insulated spanners should be available for use on cell connections to prevent accidental short-circuiting of battery terminals. Such a short-circuit across the terminals of just one cell of a battery will cause a blinding flash with the probability of the cell being seriously damaged. Rev 1 Dated: 01.02.2012 Page 84 of 86 Rev 1 Dated: 01.02.2012 Page 85 of 86