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Revision 1 July 2016 AC Motors and Generators Student Guide GENERAL DISTRIBUTION GENERAL DISTRIBUTION: Copyright © 2016 by the National Academy for Nuclear Training. Not for sale or for commercial use. This document may be used or reproduced by Academy members and participants. Not for public distribution, delivery to, or reproduction by any third party without the prior agreement of the Academy. All other rights reserved. NOTICE: This information was prepared in connection with work sponsored by the Institute of Nuclear Power Operations (INPO). Neither INPO, INPO members, INPO participants, nor any person acting on behalf of them (a) makes any warranty or representation, expressed or implied, with respect to the accuracy, completeness, or usefulness of the information contained in this document, or that the use of any information, apparatus, method, or process disclosed in this document may not infringe on privately owned rights, or (b) assumes any liabilities with respect to the use of, or for damages resulting from the use of any information, apparatus, method, or process disclosed in this document. ii Table of Contents INTRODUCTION .............................................................................................................................1 TLO 1 TYPES OF AC GENERATORS ..............................................................................................2 Overview ..................................................................................................................................2 ELO 1.1 Generator Theory ......................................................................................................3 ELO 1.2 Generator Components..............................................................................................9 ELO 1.3 Electrical Terms ......................................................................................................12 ELO 1.4 Types of AC Generators..........................................................................................16 TLO 1 Summary ....................................................................................................................17 TLO 2 TYPES OF AC MOTORS ....................................................................................................19 Overview ................................................................................................................................19 ELO 2.1 Producing a Rotating Magnetic Field .....................................................................19 ELO 2.2 Slip Effects on AC Induction Motor Operation ......................................................23 ELO 2.3 Developing Torque in an AC Induction Motor .......................................................25 ELO 2.4 Starting Current on an AC Induction Motor ...........................................................28 ELO 2.5 AC Synchronous Motor Operation .........................................................................31 TLO 2 Summary ....................................................................................................................33 TLO 3 AC MOTOR OPERATION ..................................................................................................34 Overview ................................................................................................................................34 ELO 3.1 Motor Applications .................................................................................................35 ELO 3.2 Indications of Motor Malfunctions .........................................................................37 ELO 3.3 Consequences of Motor Overheating ......................................................................39 ELO 3.4 Excessive Current in Motors ...................................................................................41 ELO 3.5 Pump Motor Current Relationships ........................................................................43 TLO 3 Summary ....................................................................................................................49 TLO 4 AC GENERATOR OPERATION ...........................................................................................50 Overview ................................................................................................................................50 ELO 4.1 Power Factor and Generators ..................................................................................51 ELO 4.2 Voltage Regulation and Components......................................................................58 ELO 4.3 Paralleling Generators .............................................................................................62 ELO 4.4 Generator Excitation ...............................................................................................71 TLO 4 Summary ....................................................................................................................77 AC MOTORS AND GENERATORS SUMMARY ................................................................................79 KNOWLEDGE CHECK ANSWER KEY ..............................................................................................1 ELO 1.1 Generator Theory ......................................................................................................1 ELO 1.2 Generator Components..............................................................................................1 ELO 1.3 Electrical Terms ........................................................................................................2 ELO 1.4 Types of AC Generators............................................................................................2 ELO 2.1 Producing a Rotating Magnetic Field .......................................................................3 ELO 2.2 Slip Effects on AC Induction Motor Operation ........................................................4 ELO 2.3 Developing Torque in an AC Induction Motor .........................................................4 ELO 2.4 Starting Current on an AC Induction Motor .............................................................5 ELO 2.5 AC Synchronous Motor Operation ...........................................................................6 ELO 3.1 Motor Applications ...................................................................................................7 ELO 3.2 Indications of Motor Malfunctions ...........................................................................7 ELO 3.3 Consequences of Motor Overheating ........................................................................8 ELO 3.4 Excessive Current in Motors .....................................................................................9 iii ELO 3.5 Pump Motor Current Relationships ........................................................................10 ELO 4.1 Power Factor and Generators ..................................................................................11 ELO 4.2 Voltage Regulation and Components .....................................................................12 ELO 4.3 Paralleling Generators .............................................................................................13 ELO 4.4 Generator Excitation ...............................................................................................16 iv This page is intentionally blank. vi AC Motors and Generators Revision History Revision Date Version Number Purpose for Revision Performed By 11/3/2014 0 New Module OGF Team 07/14/2016 1 Incorporated OGF Working Group and Reviewer comments OGF Team vii Introduction AC motors and generators are vital to plant operation. The AC main generator is the plant output, and other AC generators provide emergency power supplies and back-ups. AC motors are the most common means to drive the pumps, compressors and other equipment necessary to all industrial plants, so they are common throughout the plant. Understanding the operation and care of AC motors and generators is vital to successful power plant operation. The plant depends on these components, and operators must be able to properly operate and monitor them. Objectives At the completion of this training session, the trainee will demonstrate mastery of this topic by passing a written exam with a grade of 80 percent or higher on the following Terminal Learning Objectives (TLOs): 1. Describe the construction, operating characteristics, and limitations for an AC generator. 2. Explain the theory of operation of selected types of AC motors. 3. Explain operating characteristics and limitations on AC motors. 4. Analyze the operating characteristics and interactions between two A/C generators operating in parallel. Rev 1 1 TLO 1 Types of AC Generators Overview In this section, you will learn about the components of AC generators and their functions, as well as the different types of AC generators and the advantages of each. AC Generators AC generators are vital to the power plant. The product of the plant is the output of the main AC generator, and each plant has additional AC generators for emergency power supplies and back-up supplies for other loads. Understanding the operation of each type is critical to successful operation. Objectives Upon completion of this lesson, you will be able to do the following: 1. Describe the theory of operation of an AC generator. 2. State the purpose of the following components of an AC generator: a. Field b. Armature c. Prime mover d. Rotor e. Stator f. Slip rings 3. Define the following electrical terms: a. Volts b. Amps c. VARs d. Inductance e. Capacitance f. Watts g. Hertz 4. Describe the following: a. Stationary field, rotating armature AC generator c. Rotating field, stationary armature AC generator Rev 1 2 ELO 1.1 Generator Theory Introduction In this section, you will learn about the theory of operation of an AC generator. Generator Theory A simple AC generator consists of a conductor or loop of wire in a magnetic field produced by an electromagnet. The two ends of the loop connect to slip rings. The slip rings are in contact with two brushes. When the loop rotates, it cuts magnetic lines of force, first in one direction, and then the other. As the conductor passes through the magnetic field, the magnetic field induces a voltage in the conductor and the slip rings conduct the induced voltage as voltage output. Magnitude of Generated Voltage The magnitude of AC voltage generated by an AC generator is dependent on the field strength and speed of the rotor. Most generators operate at a constant speed; therefore, the generated voltage depends on field excitation, or strength. Developing an AC Sine Wave Voltage As the coil rotates in a counter-clockwise direction, each side of the coil cuts through the magnetic lines of force in opposite directions (see the figure below). The direction (polarity) of the induced voltages depends on the direction of movement of the coil. Figure: Simple AC Generator When the loop is in the vertical position, at 0 degrees, (0 degrees of rotation in the figure below) the coils are moving parallel to the magnetic field and do not cut magnetic lines of force. At that instant, there is no voltage induced in the loop. As the coil rotates in a counter-clockwise direction, each side of the coil cuts the magnetic lines of force in opposite directions. Rev 1 3 The direction (polarity) of the induced voltages depends on the direction of movement of the coil. The induced voltages are additive, making slip ring X (see the previous figure) positive (+) and slip ring Y negative (-). The potential across resistor R causes a current to flow from Y to X through the resistor. This current increases until it reaches a maximum value when the coil is horizontal to the magnetic lines of force at 90 degrees. At that instant, the horizontal coil is moving perpendicular to the magnetic field and cutting the greatest number of magnetic lines of force. As the coil continues to turn, the induced voltage and current decrease until both reach zero, when the coil is again in the vertical position (180 degrees). The next half revolution produces an equal voltage, except with reversed polarity (270 degrees and 360 degrees). The current flow through R is now from X to Y. The figure below shows the coil position as it rotates through 360 degrees. Figure: Developing an AC Sine Wave Voltage The alternating reversal of polarity results in the generation of a voltage, as shown above. As the coil rotates through 360 degrees, voltage output in the shape of a sine wave results. Rev 1 4 Period and Frequency E = voltage I = current P = power When an AC generator produces a voltage, the resulting current varies in step with the voltage. As the generator coil rotates 360 degrees, the output voltage goes through one complete cycle. In one complete cycle, the voltage increases from zero to Emax in one direction, decreases to zero, increases to Emax in the opposite direction (negative Emax), and then decreases to zero again. The period is the time required for the generator to complete one cycle. The frequency (measured in hertz) is the number of cycles completed per second 𝑁𝑃 where 𝑓 = where: 120 𝑓 = frequency (Hz) 𝑁 = rotor speed 𝑃 = total number of poles 120 = conversion from minutes to seconds and from poles to pole pairs Peak Voltage and Current In the figure below, Emax occurs at 90 degrees. This value is termed the peak voltage. One way to quantify AC voltage or current is by peak value, peak voltage (Ep) or peak current (Ip). Peak means the maximum voltage or current appearing on an AC sine wave. Peak to Peak Voltage and Current Another commonly used term associated with AC is peak-to-peak value (Ep-p or Ip-p). Peak to peak refers to the magnitude of voltage, or current range, spanned by the sine wave, as denoted in the following figure. Rev 1 5 Figure: AC Sine Wave Voltage Effective Value of AC A sine wave like the one shown below graphically presents the AC generator output. Figure: AC Voltage Sine Wave Effective value is the value most commonly used for quantifying AC. The effective value of AC is the amount of AC that produces the same heating effect as an equal amount of DC. A one-ampere effective value of AC will produce the same amount of heat in a conductor, in a given time, as one ampere of DC. Rev 1 6 The heating effect of a given AC current is proportional to the square of the current. It is possible to calculate the effective value of AC by squaring all the amplitudes of the sine wave over one period, taking the average of these values, and then taking the square root of the average. The effective value, because it is the root of the mean (average) square of the currents, is the root-mean-square, or RMS value. RMS = average value X 1.73 AC Generator Theory Refer to the figure below. The upper illustration shows the value of AC current relative to 0. The lower illustration shows the square of the value of the same AC current. The dashed line in in both illustrations is an average of the I2 values. Square root of that value is the RMS or effective value (Square root of the mean square deviation of the waveform). The average value is ½ Imax2 RMS value is which is equal to 0.707 Imax The effective value of the voltage or current for an AC sine wave can be found by using: Effective value (RMS) = Peak Value X 0.707 Figure: Effective Value of AC Current Rev 1 7 Phase Angle Guidelines Phase angle is the fraction of a cycle, in degrees, that has gone by since a voltage or current has passed through a given value (normally zero). From the figure below, take point 1 on the sine wave as the starting point or “zero phase”. The phase angle at Point 2 is 30 degrees, Point 3 is 60 degrees, Point 4 is 90 degrees, and so on, until Point 13 where the phase angle is 360 degrees, or zero once again. Figure: AC Voltage Sine Wave Phase Angle Example Phase difference is another common term for phase angle. Phase difference describes two different voltages that have the same frequency, which pass through zero values in the same direction, but at different times. In the figure below, the angles along the axis indicate the phases of voltages e1 and e2. At 120 degrees, e1 passes through the zero value, which is 60 degrees ahead of e2 (e2 equals zero at 180 degrees). We describe this as voltage e1 leads e2 by 60 electrical degrees, or voltage e2 lags e1 by 60 electrical degrees. Figure: Phase Relationship Rev 1 8 Phase difference can also compare two different currents or a current and a voltage. If the phase difference between two currents, two voltages, or a voltage and a current is zero degrees, they are termed to be in phase. If the phase difference is any amount other than zero, they are out of phase. Knowledge Check (Answer Key) When two AC voltages reach their peak voltage at the same time, the voltages are said to be ______________. A. lagging B. out of phase C. in phase D. Leading ELO 1.2 Generator Components Introduction In this section, you will learn the major components of the AC generator and the function of each. Generator Components The figure below shows components of a basic AC generator. The following sections discuss key components of an AC generator. Armature Figure: Basic AC Generator Rev 1 9 Field The field in an AC generator consists of coils of conductors within the generator that receive a voltage from a source (excitation) and produce a magnetic flux. The magnetic flux in the field cuts the windings in the armature to produce a voltage. This voltage is the output voltage of the AC generator. Armature The armature is the voltage production source of an AC generator. The armature consists of many coils of wire that are large enough to carry the full-load current of the generator. Prime Mover The prime mover is the component that drives the AC generator rotor. The prime mover may be any type of rotating machine, such as a diesel engine, a steam turbine, or a motor. Rotor The rotor of an AC generator is the rotating component of the generator. The generator's prime mover (a steam turbine, gas turbine, or diesel engine) drives the rotor. Depending on the type of generator, the rotor may be either the armature or the field. The rotor is the armature when it is the source of voltage generation. The rotor is the field when it receives the field excitation. Stator The stator of an AC generator is the part of the machine that is stationary. Like the rotor, this component may be the armature or the field, depending on the type of generator. The stator is the armature when it is the source of voltage output generation. The stator is the field when it receives the field excitation. Slip Rings Slip rings are electrical connections used to transfer power to or from the rotor of an AC generator. A slip ring consists of a circular conducting material mounted on the rotor shaft, as shown in the following figure. The slip ring connects electrically to the rotor windings and insulation isolates it electrically from the shaft. Brushes ride on and contact the slip ring as the rotor rotates. The brushes usually connect to the output of the generator (self-excited), by un-insulated braided copper wires. Rev 1 10 Figure: Slip Rings and Brushes Magnetic Field Current flow through the field coil of the rotor produces a strong magnetic field. Slip rings and brushes conduct excitation to the field coil in the rotor. Continuous Connection Brushes are spring-held in contact with the slip rings to provide a continuous connection between the field coil and excitation circuit, on a rotating field machine. Conductors Each time the rotor makes one complete revolution, one complete cycle of AC is developed. A generator has many turns of wire wound into the slots of the stator. Knowledge Check (Answer Key) An AC generator has all of the following except ______________. Rev 1 A. a commutator B. a magnetic field C. slip rings D. a conductor in relative motion with the magnetic field 11 Knowledge Check (Answer Key) The part of an AC generator that produces the output voltage is called the: A. Armature B. Field C. Stator D. Rotor ELO 1.3 Electrical Terms Introduction In this section, you will learn about common electrical terms used in electrical measurement and AC voltage generation. Units of electrical measurement include the following: Unit of Measurement Symbol Unit is Used to Measure: Ampere I or A Electrical current Volt E or V Electrical potential difference Hertz Hz Frequency (f) Ohm R or Ω Resistance to current flow Watt W Power (P) Henry H Electrical inductance (L) Farad F Electrical capacitance (C) VAR VAR Reactive power (Q) Voltage (Volt) Voltage, electromotive force (EMF), or potential difference, is the pressure or force that causes electrons to move in a conductor. In electrical formulas and equations, you will see voltage symbolized with a capital E, while on laboratory equipment or schematic diagrams, you will see voltage symbolized with a capital V. Rev 1 12 Current (Ampere or Amp) Electron current, or amperage, is the movement of free electrons through a conductor. In electrical formulas, you will see current symbolized with a capital I, while in the laboratory or on schematic diagrams, you will see current symbolized with a capital A to indicate amps or amperage (amps). Resistance (Ohm) Resistance is the opposition to current flow. The amount of opposition produced by a material depends upon the amount of available free electrons and the types of obstacles the electrons encounter as they attempt to move through the material. The symbol (R) represents resistance in equations. One ohm is that amount of resistance that will limit the current in a conductor to one ampere when the potential difference (voltage) applied to the conductor is one volt. The symbol for the ohm is the Greek letter capital omega (Ω). If a voltage difference acts on a conductor, current flows. The amount of current flow depends upon the resistance of the conductor: the lower the resistance, the higher the current flow for a given amount of voltage; the higher the resistance, the lower the current flow. The relationship between these three parameters is referred to as Ohm’s law,(𝐸 = 𝐼 × 𝑅), and will be covered in more detail later in the module. Power (Watt) Electricity generally performs work, such as turning a motor or generating heat. Specifically, power is the rate of performing work, or the rate of heat generation. The unit commonly used to specify electric power is the watt. In equations, the capital letter P denotes power, and the capital letter W denotes watts. Power is also described as the current (I) in a circuit multiplied by the voltage (E) across the circuit. The equation below is a mathematical representation of this concept. 𝑃 = 𝐼 × 𝐸 or 𝑃 = 𝐼𝐸 Using Ohm’s Law for the voltage, E = I x R and using substitution laws, 𝑃 = 𝐼 × (𝐼 × 𝑅) Therefore, power also equals the current (I) in a circuit squared multiplied by the resistance (R) of the circuit or as shown in the formula listed below: 𝑃 = 𝐼2𝑅 Rev 1 13 Inductance (Henry) Inductance is the ability of a coil to store energy, induce a voltage in itself, and oppose changes in current flowing through it. You will see a capital L used to indicate inductance in electrical formulas and equations. Henries are the units of measurement for inductance. The capital letter H denotes the henry. One henry is the amount of inductance that permits one volt to be induced when the current through the coil changes at a rate of one ampere per second. The mathematical representation of the rate of change in current through a coil per unit time is: ∆𝐼 ( ) ∆𝑡 The equation below is the mathematical representation for the voltage VL induced in a coil with inductance L. The negative sign indicates that voltage induced opposes the change in current through the coil per unit time(∆𝐼/∆𝑡). ∆𝐼 𝑉𝐿 = −𝐿 ( ) ∆𝑡 A later section in this lesson presents additional detail on inductance. Capacitance (Farad) Capacitance is the ability to store an electric charge and is symbolized by the capital letter C. Capacitance (C) is measured in farads, and is equal to the amount of charge (Q) that can be stored in a device or capacitor divided by the voltage (E) applied across the device or capacitor plates when the charge was stored. The equation below is the mathematical representation for capacitance. 𝐶= 𝑄 𝐸 Frequency (Hertz) Frequency (measured in hertz) is the number of alternating voltage or current cycles completed per second. Volt Ampere Reactive (VAR) VAR is the unit of reactive power; reactive power in a circuit does no useful work. In AC circuits that are not purely resistive, voltage and current will be out of phase with each other, power is exchanged in these circuits as inductive fields form and collapse, and capacitors charge and discharge. The power triangle graphically displays the relationship between reactive power, apparent power and true power. Rev 1 14 The power triangle, shown below, equates AC power to DC power by showing the relationship between: generator output (Apparent Power - S) in volt-amperes (VA), usable power (True Power - P) in watts, and wasted or stored power (Reactive Power - Q) in volt-amperes-reactive (VAR). The phase angle (θ) represents the inefficiency of the AC circuit and corresponds to the total reactive impedance (Z) to current flow in the circuit. Figure: Power Triangle The power triangle represents comparable values that can be used directly to find the efficiency level of generated power to usable power, which is expressed as the power factor (discussed later). You can calculate Apparent Power, Reactive Power, and True Power by using the DC equivalent (RMS value) of the AC voltage and current components, along with the power factor. Knowledge Check (Answer Key) The unit commonly used to specify electric power is: Rev 1 A. Volt B. Amp C. Watt D. Hertz or frequency 15 ELO 1.4 Types of AC Generators Introduction In this section, we will cover types and classification of AC generators. There are two types of AC generators: the stationary field with rotating armature; and the rotating field with stationary armature. Stationary Field with Rotating Armature Small AC generators usually have a stationary field and a rotating armature, as shown in the figure below. One important disadvantage of this style generator is that the slip ring and brush assembly is in series with the load circuits. Dirt or wear in these components results in a reduction or interruption in current flow to loads. For very large generators, the slip rings and brushes become the limiting factor on the machine capacity. Figure: Stationary Field with Rotating Armature Generator Rotating Field with Stationary Armature Upon connecting a DC field excitation to the rotor, the stationary coils receive induced AC. This arrangement is a rotating field with stationary armature AC generator, as shown in the figure below. Figure: Rotating Field with Stationary Armature Generator Rev 1 16 Large power generation applications typically use the rotating field, stationary armature type AC generator. In this type of generator, a DC source is supplied to the rotating field coils (via slip rings and brushes), which produces a magnetic field around the rotating element. As the prime mover turns the rotor, the field rotates across the conductors of the stationary armature, inducing an EMF into the armature windings. This type of AC generator has the following advantages over the stationary field, rotating armature AC generator: It is possible to connect a load to the armature without having moving contacts (slip rings and brushes) in the circuit. It is much easier to insulate stator conductors than rotating conductors. It is possible to generate very higher output voltages and currents. Knowledge Check (Answer Key) The rotating armature, stationary field type is used for most large power generators. A. True B. False TLO 1 Summary In this section, you learned about generator theory, types of AC generators, major components, ratings, and losses, and the two common generator output connection schemes. 1. A simple AC generator consists of a conductor or loop of wire in a magnetic field produced by an electromagnet, and relative motion between them. 2. Major components consist of a field, armature, prime mover, rotor, stator, and slip rings/brushes. 3. Electrical terminology associated with generators include, voltage, current, frequency, power/watts, and volt-ampere reactive (VAR). 4. AC Generators are generally classified as either stationary field with rotating armature or rotating field with stationary armature machines. Large commercial generators are usually rotating field with stationary armature to mitigate the limitations of slip rings and brushes on generator output. Rev 1 17 5. The two common connection schemes used for AC three-phase generators are delta-connections and wye-connections. Delta-connected: An advantage is that if one phase becomes damaged or open, the remaining two phases can still deliver three-phase power. However, the capacity of the generator is reduced to 57.7 percent. The voltage will be constant on any two phases, however current will be 1.73 times the single-phase value. Wye-connected: The voltage and current characteristics of the wye-connected AC generator are opposite to that of the delta connection. Voltage between any two lines in a wye connected AC generator is 1.73 times the voltage of any one phase, while line currents are equal to the phase currents. An advantage of a wye-connected AC generator is that each phase only has to carry 57.7 percent of line voltage. Summary Now that you have completed this lesson, you should be able to do the following: 1. Describe the theory of operation of an AC generator. 2. State the purpose of the following components of an AC generator: a. Field b. Armature c. Prime mover d. Rotor e. Stator f. Slip rings 3. Define the following electrical terms: a. Volts b. Amps c. VARs d. Inductance e. Capacitance f. Watts g. Hertz 4. Describe the following: a. Stationary field b. Rotating armature AC generator c. Rotating field, stationary armature AC generator Rev 1 18 TLO 2 Types of AC Motors Overview AC motors drive machinery for a wide variety of applications at the station; to monitor and operate these motors correctly, an operator needs to have an understanding of their design and operating characteristics. There are two major types of AC motors used in industrial applications: induction and synchronous motors. Induction motors are the most commonly used AC motor in industrial applications because of their simple, rugged construction, and relatively low manufacturing costs. This TLO will cover the theory of operation for AC induction motors first, followed by synchronous motors theory and operating characteristics. AC motors drive most of the equipment needed to make the power plant work, including pumps, compressors, fans, and other components. Objectives Upon completion of this lesson, you will be able to do the following: 1. 2. 3. 4. Describe how a rotating magnetic field is produced in an AC motor. Define slip and explain its effect on AC induction motor operation. Describe how torque is produced in an AC motor. Explain differences between starting and running current for an AC induction motor, and the operating limits used to mitigate the effects of starting current. 5. Describe how an AC synchronous motor is started and its operating characteristics. ELO 2.1 Producing a Rotating Magnetic Field Introduction The basic principle of operation for AC motors is the interaction of a revolving magnetic field created in the stator by AC current, with an opposing magnetic field in the rotor. The magnetic field in the rotor comes from one of two sources: induced from the rotating stator, or provided by a separate DC current source. The resulting interaction produces torque that turns a shaft that can operate rotating machinery such as pumps, compressors, fans, etc. Rotating Magnetic Field To understand how a rotating magnetic field causes a motor rotor to turn, it is necessary to understand how to produce a rotating magnetic field. The figure below illustrates a three-phase stator with three-phase AC current applied. Rev 1 19 The windings connect in a wye configuration. The two windings in each phase wind in the same direction. At any instant in time, the magnetic field generated by one particular phase will depend on the current flow through that phase. If the current flow through that phase is zero, the resulting magnetic field is zero. If the current flow is at a maximum value, the resulting field is at a maximum value. Since the currents in the three windings are 120 degrees out of phase, the magnetic fields produced will also be 120 degrees out of phase. The stator will produce a rotating magnetic field, which is a combination of the fields produced by the three individual sets of windings. The stator’s magnetic fields will act upon the rotor, inducing a current and a corresponding magnetic field in the rotor. In an AC induction motor, the magnetic field induced in the rotor is opposite in polarity to the rotating magnetic field in the stator. Consequently, as the magnetic field rotates in the stator, the rotor also rotates in an attempt to maintain its alignment with the stator’s magnetic field. The figure below shows each of three phases separately, and all three combined in a three-phase motor stator. Figure: Three-Phase Motor Stator From one instant to the next, the magnetic fields of each stator phase combine to produce a magnetic field whose position shifts through a certain angle. At the end of one cycle of alternating current, the magnetic field will have shifted through 360 degrees, or one revolution around the stator. Since the rotor has an opposing magnetic field induced upon it, it will also rotate through one revolution. For the purpose of explanation, the figure below shows the rotation of the stator’s magnetic field "stopped" at six selected positions, or instances. Rev 1 20 These instances are marked off at 60 degree intervals on the sine waves representing the current flowing in the three-phases, A (1), B (2), and C (3). For the following discussion, when the current flow in a particular phase is positive, the magnetic field will develop a north pole at the poles labeled A, B, and C. When the current flow in a particular phase is negative, the magnetic field will develop a north pole at the poles labeled A', B', and C'. Figure: Rotating Magnetic Field T1 At point T1, the current in phase C (solid line on figure above) is at its maximum positive value. At the same instance, the currents in phases A and B are at half of the maximum negative value. The resulting magnetic field is established vertically downward, with the maximum field strength developed across the C phase, between pole C (north) and pole C' (south). This magnetic field is aided by the weaker fields developed across phases A and B, with poles A' and B' being north poles and poles A and B being south poles. Rev 1 21 T2 At Point T2, the current sine waves have rotated through 60 electrical degrees. At this point, the current in phase A has increased to its maximum negative value. The current in phase B has reversed direction. The currents in phases B and C are at half of the maximum positive value. The resulting magnetic field is established downward to the left, with the maximum field strength developed across the A phase, between poles A’ (north) and A (south). This magnetic field is aided by the weaker fields developed across phases B and C, with poles B and C being north poles and poles B’ and C’ being south poles. Thus, the magnetic field within the stator of the motor has physically rotated 60 degrees. T3 At Point T3, the current sine waves have again rotated 60 electrical degrees from the previous point for a total rotation of 120 electrical degrees. At this point, the current in phase B has increased to its maximum positive value. The current in phase A has decreased to half of its maximum negative value, while the current in phase C has reversed direction and is at half of its maximum negative value. The resulting magnetic field is established upward to the left, with the maximum field strength developed across phase B, between poles B (north) and B' (south). This magnetic field is aided by the weaker fields developed across phases A and C, with poles A' and C' being north poles and poles A and C being south poles. The magnetic field on the stator has rotated another 60 degrees for a total rotation of 120 degrees. T4 At Point T4, the current sine waves have rotated 180 electrical degrees from Point T1 so that the relationship of the phase currents is identical to Point T1 except that the polarity has reversed. Since phase C is again at a maximum value, the resulting magnetic field developed across phase C will be of maximum field strength. However, reversing the current flow in phase C establishes the magnetic field vertically upward between poles C (north) and C (south). As can be seen, the magnetic field has now physically rotated a total of 180 degrees from the starting point at T1. T5 At Point T5, phase A is at its maximum positive value, which establishes a magnetic field upward to the right. Again, the magnetic field has physically rotated 60 degrees from the previous point for a total rotation of 240 degrees. Rev 1 22 T6 At Point T6, phase B is at its maximum negative value, which will establish a magnetic field downward to the right. The magnetic field has again rotated 60 degrees from Point T5 for a total rotation of 300 degrees. T7 Finally, at Point T7, the current returns to the same polarity and values as that of Point T1. Therefore, the magnetic field established at this instance will be identical to that established at Point T1. From this discussion, for one complete cycle of the electrical sine wave (360 degrees), the magnetic field developed in the stator of a motor will rotate one complete revolution (360 degrees). Therefore, applying a threephase AC to three windings symmetrically spaced around a stator, produces a rotating magnetic field in the stator. Knowledge Check (Answer Key) Select all of the statements about creating a rotating magnetic field in a three-phase induction motor that are true. A. Since the windings are 120 degrees out of phase, the magnetic field produced by the windings will also be 120 degrees out of phase. B. The magnetic field induced in each winding rises and falls in a sine wave as the current through that winding rises and falls in a sine wave. C. The magnetic field generated in the motor windings makes 60 revolutions per second in a 60 Hz power system. D. The magnetic field induced in the windings is independent of how the motor is wound and connected. ELO 2.2 Slip Effects on AC Induction Motor Operation Introduction In this section, you will learn how the three-phase AC induction motor generates a magnetic field on the rotor and causes motion in the rotating element. Rev 1 23 Slip Effects on AC Induction Motor Operation It is impossible for the rotor of an AC induction motor to turn at the same speed as that of the rotating magnetic field. If the speed of the rotor were the same as that of the stator, no relative motion between them would exist, and there would be no induced EMF in the rotor (recall that inducing a current requires relative motion between a conductor and a magnetic field). Without this induced EMF, there would be no interaction of magnetic fields to produce motion. Therefore, the rotor must rotate at some speed less than that of the magnetic field in the stator for relative motion to exist. Slip is the percentage difference between the speed of the rotor and the speed of the rotating magnetic field in the stator. The smaller the percentage difference, the closer the rotor speed is to the rotating magnetic field speed. The amount of torque on the rotor will change as the slip ratio changes between the rotor and stator. The change in torque (seen in the figure below) shows that, as slip increases from zero to about 20 percent, the torque increases linearly. As the load and slip increase beyond full-load torque, the torque will reach a maximum value at about 25 percent slip. 𝑆𝑙𝑖𝑝 = 𝑁𝑠 − 𝑁𝑎 = 100 𝑝𝑒𝑟𝑐𝑒𝑛𝑡 𝑁𝑠 Where Ns = Synchronous speed of the rotating field, and Na = Actual speed or the rotor, with typical values of between 1 and 8 percent. Figure: Torque versus Slip for an AC Induction Motor Rev 1 24 Knowledge Check (Answer Key) Select all of the statements that are true regarding threephase induction motor operation. A. The rotor turns at a speed slower than the rotation of the stator magnetic field. B. The rotor turns at the same speed as the stator magnetic field. C. The difference in speed between the stator magnetic field and the rotor is necessary to induce a magnetic field on the rotor. D. The rotor has field windings supplied by an external power supply ELO 2.3 Developing Torque in an AC Induction Motor Introduction In this section, you will learn how a three-phase AC Induction Motor develops torque. Torque Production When alternating current flows through the stator windings of an AC induction motor a rotating magnetic field results, as discussed above. The rotating magnetic field cuts the conductors of the rotor and induces a current in them due to generator action. Figure: Induced Rotor Magnetic Field Rev 1 25 This induced current will produce a magnetic field, opposite in polarity of the field associated with the stator, around the conductors of the rotor. The magnetic field induced on the rotor will try to line up with the magnetic field produced by the stator. Since the stator field is rotating continuously, the rotor cannot line up with, or lock onto, the stator field and, therefore, must follow behind it. The figure below shows force directions of the induced rotor magnetic field. Breakdown Torque The maximum value of torque that an AC induction motor can produce without stalling is the breakdown torque of the motor. If load increases beyond this point, the motor will stall and come to a rapid stop. The typical induction motor breakdown torque varies from 200 percent to 300 percent of full-load torque. Starting Torque Starting torque is the value of torque at 100 percent slip and is normally 150 percent to 200 percent of full-load torque. As the rotor accelerates, torque will increase to breakdown torque and then decrease to the value required to carry the load on the motor at a constant speed, usually between 0-10 percent slip. Figure: Torque versus Slip for an AC Induction Motor Rev 1 26 Developing Torque The torque of an AC induction motor is dependent upon the strength of the interacting rotor and stator fields and the phase relationship between them. The equation below shows the mathematical expression for AC motor torque: 𝑇 = 𝐾𝛷𝐼𝑅 cos 𝜃𝑅 Where: T = torque (lb-ft or N-m) K = constant Φ = stator magnetic flux IR = rotor current (A) cos 𝜃𝑅 = power factor of rotor During normal operation, K, Φ, and cos 𝜃𝑅 are essentially constant, so torque is directly proportional to the rotor current. Rotor current increases in almost direct proportion to slip, so maximum current will occur at maximum slip, which is at motor start-up. Note 100 percent slip occurs upon motor startup. The magnetic field on the stator is rotating as soon as current is applied to the stator upon starting the motor. Initially, there is no magnetic field on the rotor. It is necessary to induce the magnetic field on the rotor; the induced field must always lag the magnetic field on the stator. Once there is relative motion between the stator and the rotor, the rotor will develop a magnetic field, which will try to lineup with the rotating magnetic field of the stator. Knowledge Check (Answer Key) The maximum value of torque that an AC induction motor can produce without stalling is known as: Rev 1 A. Starting torque B. Breakdown torque C. Stalling torque D. Critical torque 27 ELO 2.4 Starting Current on an AC Induction Motor Introduction In this section, you will learn the causes and effects of motor starting current. Starting Current Starting current in an AC motor is a phenomenon that the operator must understand in order to properly monitor and operate large loads in the station. Starting current in an AC motor is greater than the motor’s normal running current. There are several reasons for this high starting current: Power is required to build up the rotating magnetic field in the stator in its initial stationary position. Extra energy is required to overcome the inertia of the rotor in order to place it in motion. Interactions occur between the rotor currents and the stator’s magnetic field, which result in the motor drawing high currents. Rotor speed is too low to generate sufficient counter electromotive force in the stator. At motor start, the rotating magnetic field from the stator cuts the conductors in the rotor inducing in EMF in the rotor. The rotor’s conductors short to one another, causing current flow and a resulting magnetic field around the rotor. Upon energizing the motor, at the instant of energizing, the rotating magnetic field is produced in the stator, but the rotor is not yet rotating. This results in high voltages and induced currents in the rotor. Since the rotor requires time to develop a magnetic field, the counter EMF takes some time to build up. The lack of counter EMF during starting combined with the very low resistance of the motor windings cause the very high currents on startup of a motor. Starting current is typically five to seven times the amount of motor full load current. The motor full load current is the amount of current that a motor draws from the power source when the motor is at full capacity. The motor’s nameplate data (ratings) always shows full load current for the motor. An ammeter (current meter) shows the high starting current for a large motor upon startup. In many cases, the ammeter’s needle will “peg high” on motor start, and then drop down to the normal operating current value. This is a normal indication. If starting current is not observed, it should be considered an abnormal indication that requires investigation. Rev 1 28 Running Current Once an AC motor passes beyond startup, the amount of current it draws while running is directly proportional to the load placed on the motor, a motor attached to a pump provides a common example. As flow through the pump increases (such as when personnel open the throttle valve), the load on the motor increases, causing the pump to slow down slightly under the increased load. When the pump slows, slip increases and the magnitude of the rotor magnetic field and torque increase. The increase in rotor field strength allows the motor to carry more load, but the slower rotor causes counter EMF to drop slightly, increasing motor current. If the throttle valve closes, flow through the pump decreases, load on the motor decreases, and motor current decreases. Starting Current Discussion The resistance in the windings and voltage across the windings determines the current drawn by a three-phase induction motor (stator current). The resistance does not change significantly, and the voltage applied does not change significantly. Upon motor startup, the rotor is not moving, so it is not cutting the lines of flux from the stator. Therefore, no current flows in the rotor and no counter electro motive force (CEMF) exists. Since the resistance is low, the stator (armature) current is initially high (5-7 times full load running current). As the rotor comes up to speed, it cuts the lines of flux more inducing a higher current in the rotor. This higher current creates a field back onto the stator (CEMF). When the load on the motor balances with the torque it is producing, rotor speed will stabilize and the counter EMF induced by the rotor stabilizes. This will cause the stator current to stabilize at the running current. Starting Current Indications The indications expected when starting a large AC induction motor are: Amps immediately increase to many times (normally stated as five to seven times) the normal running current value. Usually this will cause the current indication to go off scale high, since monitoring running current is the normal basis for meter scale selection. After a few seconds, current will come back in scale, and decrease to normal running current for the load applied. Normally, startup loads for large motors are no load or very low load, so the current should drop to the low end of the running current band after startup. Rev 1 29 If the current does not drop back into the normal band for running current within a few seconds, this is an indication that the equipment is not functioning properly, and it is appropriate to shut it down and investigate the reason for the malfunction. Due to the large starting current and heat produced on motor start-up on large pumps, plant operating procedures will often limit the number of pump starts allowed within a given time period to prevent overheating the motor windings. Knowledge Check (Answer Key) If the discharge valve of a large motor-driven centrifugal pump remains closed during a normal pump start, the current indication for the AC induction motor will rise to... A. several times the full-load current value, and then decrease to the no-load current value. B. approximately the full-load current value, and then decrease to the no-load current value. C. approximately the full-load current value, and then stabilize at the full-load current value. D. several times the full-load current value, and then decrease to the full-load value. Knowledge Check (Answer Key) Which one of the following is a characteristic of a typical AC induction motor that causes starting current to be greater than running current? Rev 1 A. After the motor starts, resistors are added to the electrical circuit to limit the running current. B. A large amount of starting current is required to initially establish the rotating magnetic field. C. The rotor does not develop maximum induced current flow until it has achieved synchronous speed. D. The rotor magnetic field induces an opposing voltage in the stator that is proportional to rotor speed. 30 Knowledge Check (Answer Key) Two identical AC induction motors are connected to identical radial-flow centrifugal pumps in identical but separate cooling water systems. Each motor is rated at 200 hp. The discharge valve for pump A is fully open and the discharge valve for pump B is fully closed. Each pump is currently off. If the pumps are started under these conditions, the shorter time period required to reach a stable running current will be experienced by the motor for pump _____ and the higher stable running current will be experienced by the motor for pump _____. A. A; A B. A; B C. B; A D. B; B ELO 2.5 AC Synchronous Motor Operation Introduction In this section, you will learn about the operating characteristics of a synchronous motor. AC Synchronous Motor Operation The second major type of AC motor used in industrial applications is the synchronous motor. Synchronous motors are like induction motors in that they both have stator windings that produce a rotating magnetic field. Unlike an induction motor, an external DC source excites the synchronous motor rotor, and therefore, a synchronous motor requires slip rings and brushes to provide current to the rotor. In the synchronous motor, the rotor locks into step with the rotating magnetic field of the stator and rotates at synchronous speed. If the synchronous motor is loaded to the point where it pulls the rotor out of step with the rotating magnetic field, no torque is developed, and the motor will stop. Rev 1 31 Synchronous motors use a wound rotor, shown in the figure below. This type of rotor contains coils of wire placed in the rotor slots. Slip rings and brushes convey current to the rotor. This type of rotor is much more expensive to manufacture than the squirrel-cage rotor associated with AC induction motors. Figure: Wound Rotor Starting a Synchronous Motor A synchronous motor is not a self-starting motor because it develops torque only when it is running at synchronous speed; therefore, the motor needs some type of device to bring the rotor up to synchronous speed. There are two ways of starting a synchronous motor: 1. Use a separate DC motor 2. Embed squirrel-cage windings on the face of the rotor If starting a synchronous motor with a separate DC motor, both motors may share a common shaft. Upon bringing the DC motor to synchronous speed, the stator windings receive AC current. The DC motor then acts as a DC generator and supplies DC field excitation to the rotor of the synchronous motor. Once operating at synchronous speed, the synchronous motor is ready for load. More often, a squirrel-cage winding embedded in the face of the rotor poles starts synchronous motors. The motor starts as an induction motor, speed increases to about 95 percent of synchronous speed, then direct current is applied, and the motor begins to pull into synchronism. Pull-in torque is the term for the torque required to pull the motor into synchronism. Rev 1 32 Because of their more complex nature and higher manufacturing cost, designers rarely specify synchronous motors as their first choice. However, large industrial applications sometimes use synchronous motors to accommodate large loads or to improve power factor of transformers in large industrial applications, and in applications where a constant speed is important. Knowledge Check (Answer Key) Select all the statements that are true. A. Synchronous motors are the most commonly used motors in large industrial applications. B. Synchronous motors develop starting torque in the same manner as induction motors. C. Synchronous motors are not often used due to their more complex nature and higher manufacturing costs. D. Synchronous motors can continue to operate with more slip than induction motors, thus producing more torque. TLO 2 Summary Types of AC Motors In this section, you learned how AC motors work, including three-phase induction motors, single-phase (split-phase) induction motors, and synchronous motors. 1. AC current in the stator induces a rotating magnetic field in a threephase motor. An AC induction motor is the most commonly used type of AC motor in industrial use. The rotating magnetic fields in the stator induce an opposing rotating field in the rotor that will induce a CEMF in the rotor. 2. The rotor does not rotate at the same speed as the stator, the difference in speed is slip, or ratio of stator speed to rotor speed, the rotor will operate at about 5 to 10 percent less than the speed of the stator. The magnetic field induced on the rotor will try to line up with the magnetic field produced by the stator. Since the stator field is rotating continuously, the rotor cannot line up with, or lock onto, the stator field and, therefore, must follow behind it. 3. The torque of an AC induction motor is dependent upon the strength of the interacting rotor and stator fields and the phase relationship between them. Torque for an AC motor can be expressed mathematically as 𝑇 = 𝐾𝛷𝐼𝑅 cos 𝜃𝑅 Rev 1 33 4. Starting current in an AC motor is greater than the normal running current that is drawn by the motor, due to: Power is required to build up the rotating magnetic field in the stator in its initial stationary position. Extra energy is required to overcome the inertia of the rotor. Interactions occur between the rotor currents and the stator’s magnetic field, resulting in the motor drawing high currents. Rotor speed is too low to generate sufficient counter electromotive force in the stator. 5. A synchronous motor is not a self-starting motor because it develops torque only when it is running at synchronous speed; therefore, the motor needs some type of device to bring the rotor up to synchronous speed. There are two ways of starting a synchronous motor: Use a separate DC motor Embed squirrel-cage windings on the face of the rotor Summary Now that you have completed this lesson, you should be able to do the following: 1. 2. 3. 4. Describe how an AC motor produces a rotating magnetic field. Define slip and explain its effect on AC induction motor operation. Describe how an AC motor produces torque. Explain differences between starting and running current for an AC induction motor, and the operating limits used to mitigate the effects of starting current. 5. Describe how an AC synchronous motor is started, and describe its operating characteristics. TLO 3 AC Motor Operation Overview In this section, you will learn about applications for different AC motor types, indications, and consequences of motor malfunctions, methods to limit starting current, and relationships of motor power to pump head and flow conditions. AC motors power most of the equipment required to operate the power plant, including pumps, compressors and other auxiliary equipment. Understanding their operation, how to monitor them, and care for them is vital to the operator role. Objectives Upon completion of this lesson, you will be able to do the following: 1. State the applications of the following types of AC motors: a. Induction Rev 1 34 2. 3. 4. 5. b. Single-phase c. Synchronous Describe the indications resulting from a locked motor rotor, sheared shaft, or miswired phases. Describe the consequences of overheated motor windings or motor bearings. Describe the causes of excessive current in motors and generators resulting from conditions such as low voltage, overloading, and mechanical binding. Describe the relationship between pump motor current and the following parameters: a. Pump flow b. Pressure c. Speed d. Motor stator temperature ELO 3.1 Motor Applications Introduction Specific applications require AC motors with varying attributes. Best equipment performance results when the application requirements for a motor match the motor attributes. The sections below describe some of the more common types of AC motors used in industry. Induction Motors The induction motor is the most commonly used motor in industrial applications because it is less expensive to manufacture and maintain, and operates reliably. Pumps, fans, compressors and other equipment used throughout the station commonly use induction motors. The induction motor derives its name from the fact that the rotating magnetic field of the stator induces AC currents into the rotor. It is the most commonly used AC motor in industrial applications because of its simplicity, rugged construction, and relatively low manufacturing costs. This mainly attributed to the construction of the self-contained rotor, with no external connections. Most AC induction motors use a particular type of rotor, known as a “squirrel-cage” rotor. Figure: Squirrel-Cage Rotor Rev 1 35 Squirrel-Cage Rotor The induction motor rotor (shown in the figure on the next page) is made of a laminated cylinder with slots in its surface. The name squirrel-cage comes from the idea that the rotor resembles a cage that could contain a small animal, such as a squirrel. This rotor is made of heavy copper bars that connect at each end by a metal ring made of copper or brass. No insulation is required between the core and the bars because of the low voltages induced into the rotor bars. To obtain maximum field strength, the size of the air gap between the rotor bars and stator windings is small. Figure: Squirrel-Cage Induction Rotor Single-phase Motors Very small commercial applications such as household appliances and floor buffers typically use single-phase motors. Synchronous Motors Because of their more complex design and higher manufacturing cost, designers rarely specify synchronous motors as their first choice. However, large industrial applications sometimes use synchronous motors to accommodate large loads and to improve the power factor of transformers in large industrial complexes. Rev 1 36 Knowledge Check (Answer Key) The least often used motor in station applications is the ____________. A. three-phase induction motor B. single-phase (split-phase) motor C. synchronous motor D. squirrel-cage motor ELO 3.2 Indications of Motor Malfunctions Introduction In this section, you will learn about some of the more common motor malfunctions and indications associated with these malfunctions. Indications of Motor Malfunctions Motors or their connected loads are subject to several different types of mechanical failures. Some of the most common are: Locked (seized) rotor Sheared rotor Miswired phases Locked (Seized) Rotor One type of mechanical problem results from binding of the mechanical load component; this binding causes shaft bending, which results in motor rotor (shaft) binding along with the associated motor or component bearing. At the extreme, this situation may cause a locked (seized) rotor. The following indications are typical of a locked rotor: Rotor speed decreases Immediate increase in current to essentially starting current (No rotor speed, no CEMF) Immediate reduction in system flow rate Immediate reduction in component discharge pressure Immediate rise in motor winding temperatures resulting from higher current flow Eventual timed delay tripping of component circuit breaker (therefore the current drops to zero after the breaker trips). Rev 1 37 Sheared Rotor A second mechanical problem that can occur is a sheared rotor (shaft). This allows the motor to operate freely (spinning) with no load mechanically attached. The following indications are typical of a sheared rotor: Rotor speed initially increases due to loss of load (e.g., pump impeller) Load has no (low) running current (as indicated on ampere meter) Immediate reduction in system flow rate Immediate reduction in component discharge pressure The reduction in flow and pressure are similar to that of a locked rotor condition but the current indications will differ (sheared shaft goes to no load running current while the locked rotor goes to starting current and then zero after the breaker trips). Miswired Phases Phases can be miswired after work in which the motor leads were disconnected. Normally, personnel verify the phase rotation following this type of work to ensure that it is correct. If the motor leads (phases) are miswired and two of the motor leads are reversed, the motor will turn in the wrong direction. While the motor will work fine turning backward, the component it is driving generally will not. The consequence to the component can vary from the component not functioning appropriately to the component damaging itself. If the component encounters resistance because of turning in the wrong direction, it can cause more resistance to the motor and damage the motor. Knowledge Check (Answer Key) If a reactor coolant pump (RCP) rotor seizes, RCP motor current will __________; if the rotor shears, RCP motor speed will __________. Rev 1 A. increase; increase B. increase; decrease C. decrease; increase D. decrease; decrease 38 Knowledge Check (Answer Key) A motor-driven cooling water pump is operating normally. How will pump motor current respond if the pump experiences a locked rotor? A. Decreases immediately to zero due to breaker trip. B. Decreases immediately to no-load motor amps. C. Increases immediately to many times running current, then decreases to no-load motor amps. D. Increases immediately to many times running current, then decreases to zero upon breaker trip. ELO 3.3 Consequences of Motor Overheating Introduction In this section, you will learn about the consequences of overheating motor windings and bearings. Loss of Motor Cooling Continuous operation of a motor at rated load with a loss of required cooling to the motor windings would eventually result in breakdown of the motor insulation due to overheating. This will cause increased temperature and current flow due to a decrease in the insulation resistance and, if severe, will result in a short circuit. Overheating, caused by loss of cooling or by any other mechanism will result in this insulation breakdown and eventually lead to motor damage, and need for motor rewind or replacement. A thermal overload device protects many large motors from high temperature by tripping the motor off upon exceeding motor current limits. Loss of Bearing Cooling or Lubrication There are various means of cooling and lubricating motor bearings, depending on the size and application of the motor, however two needs are common to all bearings: 1. The bearing must be properly lubricated to minimize friction 2. The heat generated in the bearing must be removed Rev 1 39 High bearing friction manifests as an additional load to the motor that causes both motor current and motor winding temperature to rise. An increase in bearing friction will cause the bearing to degrade until it fails, resulting in component trip and possible damage to the component, as well. If the increase in friction is significant, it can lead to motor damage. If a bearing is running with higher than normal temperature, but the friction is not excessive, it may run for some time without causing damage. Most bearing lubricants are effective within a specified temperature range; if lubricant temperature is outside that range, there is a reduction in lubricating properties. This can cause increased friction and lead to the difficulties already discussed. Important operator tasks include maintaining bearing lubrication and temperature within the design limits, and maintaining winding temperatures below design limits. Knowledge Check (Answer Key) Which one of the following will result from prolonged operation of an AC induction motor with excessively high stator temperatures? Rev 1 A. Decreased electrical current demand due to reduced counter electromotive force. B. Decreased electrical resistance to ground due to breakdown of winding insulation. C. Increased electrical current demand due to reduced counter electromotive force. D. Increased electrical resistance to ground due to breakdown of winding insulation. 40 Knowledge Check (Answer Key) Continuous operation of a motor at rated load with a loss of required cooling to the motor windings will eventually result in ____________. A. cavitation of the pumped fluid B. failure of the motor overcurrent protection devices C. breakdown of the motor insulation and electrical grounds D. phase current imbalance in the motor and overspeed trip actuation ELO 3.4 Excessive Current in Motors Introduction In this section, you will learn what about causes of excessive current and overload conditions in a motor. Motor Overloading Overloading or just increased loading can result in increased current draw by the motor. Operators should investigate abnormally high running currents promptly, as these high currents may indicate a problem such as mechanical binding of the motor or of the associated component. Rev 1 41 The table below summarizes overcurrent and overload malfunctions and the indicators with likely results: Malfunction Indicator(s) with Likely Result Gradual motor bearing failure Increased friction, current, and temperature could be high enough to cause a thermal overload trip. Packing on a motoroperated valve is tightened excessively Motor current would increase due to increased torque on motor caused by additional friction associated with the packing. These high currents can result in excessive heat within the motor, causing break down of the motor winding insulation and damage to the motor (grounds). Locked or seized rotor (shaft) of the motor or component driven (pump, valve, etc.) Overcurrent trip of the supply circuit breaker Reduced voltage supplied to the motor The motor supplies power needed to drive the load, and when voltage drops, the current increases. Operating for extended periods with reduced voltage can lead to winding damage. Sheared shaft or rotor Abnormally low or no running currents as indicated on an amp meter, with low or no flow/pressure indicated. Failed Bearings Failed bearings are another mechanical problem that can affect electric motor operation. Bearing failure can result from a number of circumstances, including: Insufficient lubrication Poor bearing maintenance practices Improper loading of the component Motor under-voltage situation An under-voltage condition may result in bearing failure due to the development of excessive torque on the motor. Any condition leading to overheating of the bearings can cause bearing failure. The excessive work can cause heat buildup in the machine windings. Rev 1 42 Knowledge Check (Answer Key) Which of the following will cause an increase in motor current? (Select all that are true.) A. An increase in bearing friction due to inadequate maintenance B. Increasing the load on the component driven, such as opening a pump discharge valve to provide more flow C. Increased voltage to the motor D. Reduced voltage to the motor Knowledge Check (Answer Key) Excessive current will be drawn by an AC induction motor that is operating ____________. A. completely unloaded B. at full load C. with open circuited stator windings D. with short circuited stator windings ELO 3.5 Pump Motor Current Relationships Introduction In this section, you will learn about the operating limits imposed to mitigate the effects of starting current. Operating Limits to Mitigate the Effect of Starting Current Recall from the pumps module that centrifugal pumps operate within a known set of laws, known as pump laws. It is possible to determine how changes in pump parameters will affect motor power and current by applying these laws. Rev 1 43 Pump Law Review The pump laws state the relationships between pump speed and the resulting flow, pump head, and power. The flow rate of a pump is directly proportional to pump speed. The discharge head or pressure is directly proportional to the square of the speed. The power required by the pump driver is directly proportional to the cube of pump speed. The following equations express these relationships: a. The flow rate of a pump is directly proportional to pump speed: 𝑉̇ ∝ 𝑛 b. The head of a pump is directly proportional to pump speed squared: 𝐻𝑝 ∝ 𝑛2 c. The power of a pump is directly proportional to pump speed cubed: 𝑝 ∝ 𝑛3 Where: n = speed of pump impeller (rpm) 𝑉̇ = volumetric flow rate of pump (gpm or ft3/hr) Hp = head developed by pump (feet) p = pump power (kW) Determining Changes in Flow, Head, and Power Knowing a change in pump speed allows you to calculate the resultant change in flow, head, and power, using the following relationships: Action Equation Determine the change in flow by using this relationship. 𝑛2 𝑉̇2 = 𝑉1̇ ( ) 𝑛1 Determine the change in head by using this relationship. Notice that the head changes by the square of the change in speed. 𝑛2 2 𝐻𝑃2 = 𝐻𝑃1 ( ) 𝑛1 Determine the change in power by using this relationship. Notice that the power changes by the cube of the change in speed. Rev 1 𝑃2 = 𝑃1 ( 𝑛2 3 ) 𝑛1 44 These relationships are very useful in determining the effects on pump performance, when flow is increased or decreased. Changes in power can affect the amount of current an electric motor (prime mover) will draw. Flow A cooling water pump is operating at a speed of 1,800 rpm. Its flow rate is 400 gpm at a head of 48 ft. The pump’s motor is drawing 45 kW. Determine the new pump flow rate if the pump speed increases to 3,600 rpm. Solution: 𝑉̇2 = 𝑉1̇ ( 𝑛2 ) 𝑛1 3,600 𝑟𝑝𝑚 𝑉̇2 = (400 𝑔𝑝𝑚) ( ) 1,800 𝑟𝑝𝑚 𝑉̇2 = 800 𝑔𝑝𝑚 Head A cooling water pump is operating at a speed of 1,800 rpm. Its flow rate is 400 gpm at a head of 48 ft. The pump's motor is drawing 45 kW. Determine the new pump head if the pump speed increases to 3,600 rpm. Solution: 𝐻𝑃2 = 𝐻𝑃1 ( 𝐻𝑃2 𝑛2 2 ) 𝑛1 3,600 𝑟𝑝𝑚 2 = 48 𝑓𝑡 ( ) 1,800 𝑟𝑝𝑚 𝐻𝑃2 = 192 𝑓𝑡 Rev 1 45 Power A cooling water pump is operating at a speed of 1,800 rpm. Its flow rate is 400 gpm at a head of 48 ft. The pump's motor is drawing 45 kW. Determine the new pump power requirements if the pump speed increases to 3,600 rpm. Solution: 𝑃2 = 𝑃1 ( 𝑛2 3 ) 𝑛1 3,600 𝑟𝑝𝑚 3 𝑃2 = 45 𝑘𝑊 ( ) 1,800 𝑟𝑝𝑚 𝑃2 = 360 𝑘𝑊 Relationship between Pump Head, Brake Horsepower, and Pump Flow The relationship of these parameters can be calculated and plotted on a pump performance curve for specific pumps and operating conditions; the figure below shows these curves. Figure: Pump Flow, Head, and BHP There are some important characteristics to remember when using this type of curves to solve problems; the NRC GFE questions use these curves frequently. Rev 1 46 Brake horsepower is the input power delivered to the pump by the motor, the SI system units are kilowatts (kW). If flow rate is increased, brake horsepower will increase, and pump head will decrease. If flow rate decreases, brake horsepower decreases and pump head will increase. Changes in brake horsepower will be proportional to changes in motor amps (voltage does not change), so if horsepower changes by 0.80, then the resultant change in motor amps will change by the same ratio. Increases in motor amps will result in increases in motor winding temperature. (Heat generation is proportional to the square of the current.) Example: Using the pump curves above, solve the following problem: Consider a pump driven by a single-speed AC induction motor. A throttled discharge flow control valve controls the pump flow rate. The following initial pump conditions exist: Pump motor current = 50 amps Pump flow rate = 400 gpm What will be the approximate value of pump motor current if the flow control valve is repositioned such that pump flow rate is 800 gpm? A. Less than 100 amps B. 200 amps C. 400 amps D. More than 500 amps Solution Note Using the pump curve, 400 gpm is equivalent to ~ 220 BHP; 800 gpm is~ 270 BHP 220 = 50 𝑎𝑚𝑝𝑠/𝑥 270 0.82𝑥 = 50 𝑎𝑚𝑝𝑠 𝑥= 50 = ~ 61 𝑎𝑚𝑝𝑠 0.82 61 amps is less than 100 amps, so the correct answer is A. Rev 1 47 Knowledge Check (Answer Key) A centrifugal pump is operating with the initial conditions as listed: 100 kW 500 gpm 150 ft The operator notices that pump power decreased 50 kW. What is the corresponding change in flow? A. 350 gpm B. 300 gpm C. 396 gpm D. 250 gpm Knowledge Check (Answer Key) A multispeed centrifugal pump is operating with a flow rate of 1,800 gpm at a speed of 3,600 rpm. Which one of the following approximates the new flow rate if the pump speed is decreased to 2,400 rpm? Rev 1 A. 900 gpm B. 1,050 gpm C. 1,200 gpm D. 1,350 gpm 48 TLO 3 Summary AC Motor Operation In this section, you learned the about applications for the different types of motors, the indications and consequences of common equipment problems, and the types of operating limits used to mitigate the effects of starting currents. 1. Most common types of AC motors are: a. Induction – most common used motor for industrial use b. Single-phase – used for small commercial and household applications c. Synchronous – used for constant speed applications and where large loads are needed to improve transformer power factor, more complex design and cost 2. Indications form motor malfunctions are: a. Locked rotor – high current and trip of circuit breaker, if on a pump, both flow and pressure immediately go to zero b. Sheared rotor – motor spins freely with no load, decrease in current, and if connected to a pump, reduction in flow and pressure. c. Miswired motor – if two leads are reversed during motor reassembly, the motor will turn backwards from proper rotation 3. Motor overheating a. Loss of motor cooling - this will cause increased temperature and current flow due to a decrease in the insulation resistance, and if severe will result in a short circuit. b. Loss of bearing cooling or lubrication – this will result in increased friction and load, increased motor current and temperature, and eventually bearing failure, and/or motor damage. 4. Excessive motor current can be caused from: a. Overloading – multiple sources, likely causes are loss of cooling or lubrication to bearings, and loss of motor cooling b. Mechanical binding – such as valve packing over tightened resulting in excessive torque and current to move valve c. Low voltage supplied – results in higher current to produce same amount of work, this leads to overheating and insulation break down. 5. Pump motor current follows power changes with respect pump curves and laws; and changes proportionally with brake horsepower with respect to pump flow changes. Rev 1 49 Summary Now that you have completed this lesson, you should be able to do the following: 1. State the applications of the following types of AC motors: a. Induction b. Single-phase c. Synchronous 2. Describe the indications resulting from a locked motor rotor, sheared shaft, or miswired phases. 3. Describe the consequences of overheated motor windings or motor bearings. 4. Describe the causes of excessive current in motors and generators resulting from conditions such as low voltage, overloading, and mechanical binding. 5. Describe the relationship between pump motor current and the following parameters: a. Pump flow b. Pressure c. Speed d. Motor stator temperature TLO 4 AC Generator Operation Overview On completion of this section, the student will be able to analyze operation of generators in parallel and predict system response to changes in frequency, voltage, and load. The power plant must operate in parallel with the grid to supply power. Knowledge of how to parallel, and control generator parameters is an essential job activity for plant operators. Objectives Upon completion of this lesson, you will be able to do the following: 1. Define apparent, true, and reactive power and power factor using a power triangle, and their effect on generator operation. 2. Describe the purpose of a voltage regulator and function of each of the following typical components: a. Sensing circuit b. Reference circuit c. Comparison circuit d. Amplification circuit(s) e. Signal output circuit f. Feedback circuit 3. Describe the conditions that must be met prior to paralleling two generators including consequences of not meeting these conditions. Rev 1 50 4. Describe the consequences of over-excitation and under-excitation when load sharing. ELO 4.1 Power Factor and Generators Introduction In this section, you will learn about the relationship between apparent, true, and reactive power, and the effect that leading and lagging power factors have on generator operation. Power Triangle In AC circuits, current and voltage are normally out of phase due to the effects of inductive and capacitive reactance. As a result, not all the power produced by a generator in an AC application is available to accomplish work. Similarly, power calculations in AC circuits vary from those in DC circuits. The power triangle, shown in the figure below, equates AC power to DC power by showing the relationship between generator output (called apparent power - S) in volt-amperes (VA), usable power (called true power - P) in watts, and wasted or stored power (called reactive power - Q) in voltamperes reactive (VAR). The phase angle (θ) represents the inefficiency of the AC circuit and corresponds to the total reactive impedance (Z) to current flow in the circuit. Figure: Power Triangle The power triangle represents comparable values that can be used directly to find the efficiency level of generated power to usable power, which is expressed as the power factor (discussed later). With the DC equivalent (RMS value) of the AC voltage, current components, and the power factor, we can calculate apparent power, reactive power, and true power using the power triangle and trigonometric laws. The following sections demonstrate these calculations. Rev 1 51 Apparent Power Apparent power (S) is the power delivered to an electrical circuit, as shown below in a mathematical representation of apparent power. The measurement of apparent power is in volt-amperes (VA). 𝑆 = 𝐼 2 𝑍 = 𝐼𝐸 Where: S = Apparent Power (VA) I = RMS current (A) E = RMS voltage (V) Z = Impedance (Ω) True Power True power (P) is the power consumed by the resistive loads in an electrical circuit, measured in watts. The following equation is a mathematical representation of true power: 𝑃 = 𝐼 2 𝑅 = 𝐸𝐼 cos 𝜃 Where: P = True Power (watts) I = RMS current (A) R = Resistance (Ω) E = RMS voltage (V) θ = Angle between E and I sine waves Reactive Power Reactive power (Q) is the power component in an AC circuit necessary for the expansion and collapse of magnetic (inductive) and electrostatic (capacitive) fields, expressed in volt-amperes-reactive (VAR). The following equation is a mathematical representation for reactive power: 𝑄 = 𝐼 2 𝑋 = 𝐸𝐼 sin 𝜃 Where: Q = Reactive Power (VAR) I = RMS current (A) Rev 1 52 X = Net reactance (Ω) E = RMS voltage (V) θ = Angle between E and I sine waves Unlike true power, reactive power is unavailable power because it is stored in the circuit itself. This power is stored by inductors, because they expand and collapse their magnetic fields in an attempt to keep current constant, and by capacitors, because they charge and discharge in an attempt to keep voltage constant. In AC electrical circuits, the circuit’s inductance and capacitance consume and give back (exchange) reactive power with the circuit’s AC power source. Reactive power is a function of a system’s amperage. The power delivered to the inductance is stored in the magnetic field when the field expands and returns to the source when the field collapses. The power delivered to the capacitance is stored in the electrostatic field when the capacitor charges and returns to the source when the capacitor discharges. There is no consumption of the reactive power delivered to the circuit by the source; circuit components use reactive power as needed, then return it to the source. Therefore, these reactive loads consume no true power to maintain their magnetic and electrostatic fields. Alternating current constantly changes; thus, the cycle of expansion and collapse of the magnetic and electrostatic fields constantly occurs. Circulating current describes the current that is constantly flowing between the source and the inductive and capacitive loads in an AC circuit. Circulating currents account for no real work in the circuit. Circulating currents are measurable and can cause protective relaying to actuate, when significant amounts are present. Total Power The total power delivered by the source is the same as apparent power. Part of this apparent power, is dissipated by the circuit resistance in the form of heat. This power dissipated in heat is true power. The circuit inductance and capacitance return the rest of the apparent power to the source (reactive power). 𝑇𝑜𝑡𝑎𝑙 𝑃𝑜𝑤𝑒𝑟 = 𝐴𝑝𝑝𝑎𝑟𝑒𝑛𝑡 𝑃𝑜𝑤𝑒𝑟 = 𝑃𝑜𝑤𝑒𝑟 𝑑𝑒𝑙𝑖𝑣𝑒𝑟𝑒𝑑 𝑡𝑜 𝑎𝑛 𝑒𝑙𝑒𝑐𝑡𝑟𝑖𝑐𝑎𝑙 𝑐𝑖𝑟𝑐𝑢𝑖𝑡 Rev 1 53 Power Factor Power factor (pf) is the ratio between true power and apparent power. True power is the power consumed by an AC circuit, whereas apparent power is a representation of the total power delivered to an AC circuit. Reactive power comprises a portion of the apparent power; reactive power is power that is stored in an AC circuit and accomplishes no real work in the circuit. Power factor is represented by cos θ in an AC circuit. It is the ratio of true power to apparent power, where θ is the phase angle between the applied voltage and current sine waves; the power triangle (see the figure below) shows that θ is the angle between P and S. The following equation is a mathematical definition of power factor: cos 𝜃 = 𝑃𝑜𝑤𝑒𝑟 𝐹𝑎𝑐𝑡𝑜𝑟(𝑝𝑓) = 𝑃 𝑇𝑟𝑢𝑒 𝑃𝑜𝑤𝑒𝑟 = 𝑆 𝐴𝑝𝑝𝑎𝑟𝑒𝑛𝑡 𝑃𝑜𝑤𝑒𝑟 Where: P = true power (watts) S = apparent power (VA) Figure: Power Triangle Power factor can be either lagging (current lags voltage) or leading (current leads voltage). The make-up of the circuit components determines if the power factor is leading or lagging. Capacitive loads are leading, and inductive loads are lagging. Resistive loads are real loads with a power factor of one. The combination of all loads on the system will determine whether the overall system is leading, lagging, or neutral. Most industrial power grids are lagging (inductive) because more of the loads, (motors) are inductive than capacitive. Rev 1 54 It is important to know whether the power factor of the system is inductive or capacitive, because it allows the system operator to minimize the impact of reactive power on the grid, to allow as much generation as possible from each operating generator. The section on generator excitation covers this topic in more detail. Lagging/Lagging Power Factors In a purely inductive circuit, the current lags the voltage by 90 degrees. In this case no true work is being done and the power factor is equal to zero. In a purely capacitive circuit, the current leads the voltage by 90 degrees. In this case no true work is being done and the power factor is also equal to zero. Power factor determines what part of the apparent power is true power. It can vary from 1, when the phase angle is 0 degrees, to 0, when the phase angle is 90 degrees. An electrical circuit that supplies power to loads such as motors, will exhibit a lagging power factor. An electrical circuit that supplies power to loads such as fluorescent lighting will exhibit a leading power factor. Most industrial electrical distribution systems exhibit a lagging power factor because inductive loads normally account for a larger percentage of the load in most circuits. ELI the ICE Man You may choose to use a mnemonic memory device for voltage and current phase relationships, "ELI the ICE man," to remember the voltage/current relationship in AC circuits. ELI refers to an inductive circuit (L) where current (I) lags voltage (E). ICE refers to a capacitive circuit (C) where current (I) leads voltage (E). Sample Generator Capability Curve One tool used in the operation of large generators is the generator capability curve. Because current in a generator is related to not only the true power output, but to the reactive power output as well, and because the heat output (and thus, needed cooling) is a factor of total current, operators must be able to operate the generator within the limits of their cooling system. The capability curve shows the relationship of real power and reactive power and the limitations of the generator with respect to total current. On the generator capability curve (see figure on the next page), megawatts are measures along the solid horizontal line and reflect 0 VARS. In a purely resistive circuit, the power triangle would be represented as a straight line because there would be no reactive load. It would have a power factor of 1 and true power would equal apparent power. Rev 1 55 As you change the excitation (voltage) of the generator, you would move “up” or “down” the KVA axis increasing the phase angle as you move away from the Megawatts line. While doing so, unless megawatts are reduced, generator current would increase. Figure: Sample Generator Capability Curve VARs Terminology Consider the figure below overlayed against the generator capability curve: As generator excitation increases, lagging VARs result As generator excitation decreases, leading VARs result In both cases, for a constant true power (megawatts out), generator amps increase. In the case of the leading VARs point, a significant amount of current is being consumed by the reactive power which would require a significant decrease in real power output. Figure: Power Factor and VARs Rev 1 56 Consider the figure below overlayed against the generator capability curve. This figure illustrates how a reduction in reactive load (VARs) could result in a significant increase in the availability of real power because of the decrease in total generator current. Figure: Power Factor and VARs Increased Excitation Knowledge Check (Answer Key) Select all that are true. Rev 1 A. Reactive power is imaginary and the currents caused by reactive power do not contribute to heat loads on the generator or current detected by protective relays. B. True power is the power consumed by resistive loads on the system. C. Total power is the power available to do work on the system. D. Reactive power is held and given back by inductive and capacitive loads on the system. 57 Knowledge Check (Answer Key) Select all that are true. A. Power factor is the ratio of true power to apparent power and is always greater than 1. B. Power factor is the ratio of reactive power to real power and is always greater than 1. C. Power factor is the ratio of true power to apparent power and can vary from 0 to 1. D. Power factor is the ratio of true power to reactive power and is always less than 1. ELO 4.2 Voltage Regulation and Components Introduction In this section, you will learn the purpose, basic components, and method of operation of voltage regulators. Voltage Regulation The purpose of a voltage regulator is to maintain the output voltage of a generator at a desired value. As load on an AC generator changes, the output voltage will also change. The main reason for this change is the change in the voltage drop across the armature winding of the generator caused by a change in load current. In an AC generator, there are losses caused by the current flowing through the resistance and inductance of the armature windings. The losses are due to resistance to current flow (IR losses) and inductive reactance to current flow (IXL losses). The IR drop is dependent on the amount of the electrical load change only. The IXL drop is dependent on not only the load change, but also on the power factor of the circuit to which the generator is connected. Therefore, the output voltage of an AC generator varies with both changes in load (i.e., current) and changes in power factor. Because of this output variation, AC generators require some method of regulating output voltage. An AC generator’s voltage regulator continuously compares the voltage output of the machine to a desired value. The voltage regulator varies the DC (rectified AC) excitation applied to the generator’s field in order to maintain generator output voltage constant. Rev 1 58 Voltage Regulator Components The figure below shows a typical block diagram of an AC generator voltage regulator. This regulator consists of six basic circuits that act together to regulate the output voltage of an AC generator from no-load to full-load. Figure: Voltage Regulator Block Diagram Voltage Regulator Components Voltage regulators have the following components to monitor and control generator output voltage: Sensing Circuit The sensing circuit senses output voltage of the AC generator. As the generator is loaded or unloaded, the output voltage changes, and the sensing circuit provides a signal of these voltage changes. This signal is proportional to output voltage the sensing circuit sends the signal to the comparison circuit. Reference Circuit The reference circuit maintains a constant output for reference. This reference signal represents the desired voltage output of the AC generator. Comparison Circuit The comparison circuit electrically compares the reference voltage to the received sensed voltage and provides an error signal. This error signal represents an increase or decrease in output voltage. The comparison circuit sends the error signal to the amplification circuit. Amplification Circuit The amplification circuit, which can be a magnetic amplifier or transistor amplifier, takes the error signal from the comparison circuit, and amplifies the milliamp input to an amp output, then, sends the amplified signal to the signal output, or field circuit. Rev 1 59 Signal Output Circuit The signal output circuit, which controls field excitation of the AC generator, increases or decreases field excitation to either raise or lower the AC output voltage, based on the received, amplified error signal. Feedback Circuit The feedback circuit takes some of the output of the signal output circuit and feeds it back to the amplification circuit. It does this to prevent overshooting or undershooting of the desired voltage by slowing down the circuit response. Changing Output Voltage As generator load changes, output voltage will change, if the generator excitation remains constant. This occurs because load changes cause increases or decreases in the current losses in the generator. The voltage regulator senses the change in output voltage, and changes the generator excitation to return the generator output voltage to the desired value. Generator Voltage Control Generator voltage control at all nuclear stations is accomplished in a manner similar to that described below: Steam applied to rotor of turbine to get it up to 1800 rpm. Permanent Magnet Generator (PMG) generates AC and sends to voltage regulator (sometimes called “field flashing”). Voltage regulator rectifies the AC to DC then sends DC to the exciter (this is the “excitation” referred to in the VARs discussion). Exciter generates AC and sends it to the rectifier banks. Rectifier banks rectify AC to DC. DC applied to the rotor of the main generator and generates AC in the stator (generator output voltage). This voltage also sent to voltage regulator for voltage control. Increasing Generator Load (Output Voltage Drop) An increase in generator load results in a drop in generator output voltage. The voltage regulator will respond to raise output voltage. First, the sensing circuit senses the decrease in output voltage as compared to the reference and lowers its input to the comparison circuit. Since the reference circuit is always a constant, the comparison circuit will develop an error signal due to the difference between the sensed voltage and the reference voltage. The error signal developed will be of a positive value with the magnitude of the signal dependent on the difference between the sensed voltage and the reference voltage. Rev 1 60 The amplifier circuit amplifies this output from the comparison circuit and sends the amplified signal to the signal output circuit. The signal output circuit then increases field excitation to the AC generator. This increase in field excitation causes generated voltage to increase to the desired output. Decreasing Generator Load (Output Voltage Increase) If the load on the generator decreases, the voltage output of the machine would rise. The actions of the voltage regulator for an increase in output voltage would be the opposite of those for a lowering output voltage. In this case, the comparison circuit will develop a negative error signal whose magnitude is again dependent on the difference between the sensed voltage and the reference voltage. As a result, the signal output circuit will decrease field excitation to the AC generator, causing the generated voltage to decrease to the desired output. Knowledge Check (Answer Key) Select all that are true. A. Generator output voltage is affected by the current drawn by the system the generator supplies. B. Generator output voltage is affected by the power factor of the system the generator supplies. C. Generator output voltage is not affected by the system the generator supplies at all. D. Generator output voltage is a function of the number of generator windings and the output voltage variance is insignificant. Knowledge Check (Answer Key) The __________ prevents overshooting or undershooting of the desired voltage by slowing down the circuit response. Rev 1 A. sensing circuit B. comparison circuit C. feedback circuit D. amplification circuit 61 ELO 4.3 Paralleling Generators Introduction In this section, you will learn about the required conditions prior to paralleling two generators including consequences of failing to meet these conditions. Paralleling AC Generators Most electrical power grids and distribution systems have more than one AC generator operating at one time. Normally, systems operate two or more generators in parallel in order to increase the available power. There are three required conditions prior to paralleling (or synchronizing) AC generators: 1. Their terminal voltages must be essentially equal. If the voltages of the two AC generators are not close to equal when the breaker is closed, one of the AC generators will act as a reactive load to the other AC generator. This causes high current exchange between the two machines, possibly causing generator or distribution system damage. Reactive load (VAR) will transfer from the generator with a higher voltage (lagging power factor) to the generator with a lower voltage (leading power factor). 2. Their frequencies must be almost equal. A mismatch in frequencies of the two AC generators will cause the generator with the lower frequency to transfer its real load (watts) to the generator operating at the higher frequency. If the frequency mismatch is significant, the lower frequency machine will act as a load on the other generator (a condition referred to as "motoring or reverse powering") and potentially trip the generator off line. The amount of real load (watts) transfer is relative to the frequency difference between the generators. This can cause an overload in the generators and the distribution system. 3. Their output voltages must be in phase. A mismatch in the phases will cause development of large opposing voltages in the two sources. The worst-case mismatch is 180 degrees out of phase, resulting in an opposing voltage between the two generators of twice the output voltage. This high voltage can cause damage to the distribution system due to extremely high currents and large mechanical torque exerted on both of the generators. The greater the phase mismatch, the greater the damage that will occur to the generator output breaker due to excessive arcing when the circuit breaker is closed. Rev 1 62 During paralleling operations, voltmeters indicate the voltages of the two generators. Output frequency meters facilitate frequency matching. A synchroscope (see figure below), a device that senses the two frequencies and indicates the phase differences between the generators allows phase matching of the two generators. Figure: Typical Synchroscope AC Generator Real Power Sharing With two generators operating in parallel, the real load carried by each generator can be determined by examining the frequency-power characteristics for each generator, as shown in the figure below. This type of figure, which graphically describes load sharing between two power sources, is termed a “House Curve”. Note that the power values for generators G1 and G2 increase both to the left and to the right of the graph vertical centerline. Figure: Two AC Generators Operating in Parallel Those values to the left of the vertical centerline (frequency axis) are the power outputs of generator 1 (G1), while those on the right side of the vertical centerline (frequency axis) are the power outputs of generator 2 (G2). Since parallel generators must operate at the same frequency, we can determine the load carried by each generator by noting the intersection of the generator characteristic for the particular speed regulator setting in use and the operating frequency. Rev 1 63 For example, for the settings shown in the figure above, at an operating frequency of 60 Hz, G1 would carry 350 kW and G2 would carry 50 kW. Points A (generator G1) and B (generator G2) are the points where each generator curve intersects with the operating frequency. The total length of the line A-B represents the total load (400 kW). The figure also shows that if the total load increased to 500kW with no changes in the speed regulator settings, the system frequency would drop to 59.95 Hz and G1 would carry 400 kW and G2 100kW, as indicated by line C-D. AC Generator Real Load Sharing The figure below depicts a load initially unbalanced between two generators, and the proper distribution of the real load between the two generators. The dashed lines in the figure below show the original condition (frequency = 60Hz, G1 load = 350 kW, and G2 load = 50 kW). The solid lines in the figure below show the proper load distribution condition (frequency = 60Hz, G1 load = 200 kW, and G2 load = 200 kW). Figure: Kilowatt Load Balanced by Adjusting Speed Regulator By increasing the speed regulator setting on G2 and decreasing the speed regulator setting on G1 until the no-load frequency of the generators are the same, the load on G2 increases from 50 kW to 200 kW. At the same time, the load on G1 decreases from 350 kW to 200 kW. Note that the total load (400 kW) remains unchanged, as does the system frequency (60 Hz). Also, note that raising or lowering both speed regulator settings together results in a change in system frequency without altering the generator load distribution. For generators with different ratings, the best operating practice is to distribute the kW load (real load) in proportion to the generator ratings. Rev 1 64 AC Generator Reactive Load Sharing After balancing the real load, use a similar procedure to balance the reactive load. With two generators operating in parallel and supplying a constant real power, the reactive loads carried by each of the generators can be determined by examining the terminal voltage versus reactive power characteristics. Different curves on a terminal voltage-reactive power characteristic represent different values of field excitation. For a fixed value of field excitation, the terminal voltage drops off as the reactive load increases, thereby exhibiting a drooping characteristic. Practical generators incorporate automatic voltage regulators, which act on the generator’s field circuitry to correct the terminal voltage-reactive power characteristic to a linear droop. The figure below depicts the redistribution of the reactive load. Figure: Reactive Load Balance by Adjusting Voltage Regulator As with the frequency-power characteristic, values measured along the horizontal axis in both directions from the graph centerline are positive. Since parallel generators must operate at the same voltage, determine the reactive load carried by each generator by finding the intersection of the generator characteristic curve for the particular voltage regulator setting in use and the actual operating voltage. For example, for the figure above, at an operating voltage of 450V, G1 initially carries 600 KVAR and G2 carries 200 KVAR, as shown by the dotted lines. To balance the reactive load while maintaining the terminal voltage at 450V, decrease the voltage regulator setting on G1 so that G1 carries 400 KVAR while increasing the voltage regulator setting on G2 so that G2 carries 400 KVAR. As in the real load case, it is desirable to distribute the load in proportion to generator ratings. Rev 1 65 AC Generator Operation in Parallel with a Large Grid Operation in parallel with a large grid When paralleling a single generator with a large power system (grid), the output of the single oncoming generator is minimal compared with the power output of the entire grid. Hence, the House Curve below shows the system as a constant frequency, constant voltage power source. Figure: Parallel Operation of a Single Generator with the Grid The figure above illustrates the distribution of real and reactive load of a single generator in parallel with a large power grid. An operator independently adjusts the appropriate regulators to set the load distributions on the single generator G1. The power grid will automatically supply the remainder of the required load. It is possible to have a single generator supply negative reactive power, thereby decreasing the total reactive load, improving the power factor, and requiring less current for the same total real power. Rev 1 66 Paralleling Generators Example Consider the following set of conditions: An operator is connecting a main generator to an infinite power grid that is operating at 60 Hz. Generator output voltage is equal to the grid voltage but generator frequency is at 57 Hz. Which one of the following generator conditions is most likely to occur if the operator closes the generator output breaker with the voltages in phase (synchronized) but with the existing frequency difference? (Assume no generator breaker protective trip occurs.) A. B. C. D. Reverse power Under-frequency Under-voltage Over-speed In evaluating this scenario, first remember that the operating is paralleling the generator to an assumed infinite grid. The grid is not infinite, but it is so much larger than any one generator that it can be considered as infinite when determining the expected response for your power plant. When paralleling to an infinite grid, the actions you take with respect to your generator will not change either the frequency or voltage of the grid. They will determine the amount of real and reactive load your generator carries. When paralleling the generator to the grid, the grid will govern the generator’s frequency, voltage, and speed. Therefore, under-frequency, under-voltage, and over-speed trips are not possible answers. By synchronizing your generator to the grid with a frequency much lower than the grid, you have forced your generator to speed up when connected. The additional work to speed up your generator came from the grid; the grid like a motor (motorized) is now driving your generator. The real power is flowing into your generator rather than out, and a reverse power trip is plausible. Therefore, A is the only correct answer. Note that as an operating practice, you synchronize with the generator running slightly faster than the grid (synchroscope moving slowly clockwise), so that when you close the breaker, the generator picks up a small amount of load, rather than being a load on the grid. This prevents motorizing or a reverse power condition being established. Of the choices given, answer A. is the only credible choice. However, in practice, the generator would certainly be reverse powered, and with a frequency difference this large it would almost certainly trip on reverse power if the synchronizing circuit allowed the breaker to close at all. Rev 1 67 Re-energizing a Dead Bus Consider the process of re-energizing a dead bus with a generator. This could occur when using your plant emergency diesel generators. In this circumstance, none of the loads on the bus are running. If you parallel the generator onto the bus without first stripping the loads, all of the bus loads will start at once, when the generator energizes the bus. Recall that electric motors have a starting current equal to several times higher than running current, and if they all start at once, the bus will draw several times its normal full load current. While the generator rating is sufficient to carry all of the bus loads, it is insufficient to carry all of the starting currents simultaneously. Starting all the loads together will result in an overcurrent condition, which will trip the generator. A typical exam question could be: Closing the output breaker of a three-phase generator onto a deenergized bus can result in... A. an overvoltage condition on the bus. - This answer is incorrect. If the voltage was set correctly prior to energizing the dead bus, voltage would tend to drop slightly when loaded. The voltage regulator would compensate and keep it within the band, but it would certainly not result in voltage going too high. B. an overcurrent condition on the generator if the bus was not first unloaded. This answer is correct. All of the motors supplied by this bus would be accelerating to speed and drawing starting current at the same time. This will result in an overcurrent condition that will likely trip the generator and deenergize the bus again. C. a reverse power trip of the generator circuit breaker if generator frequency is low. - Since the generator is the only source of power to this bus, it cannot receive power from any other source- reverse power is not plausible. D. a large reactive current in the generator. - Reactive power should not be higher than the normal reactive load for running this bus. Real load from starting currents will be the problem in this circumstance. In this instance, the only correct choice is B. This is a real operating concern. If a dead bus is re-energized without stripping loads first, it will result in an overcurrent condition, possibly tripping the bus again, and possibly damaging either the generator or the feeder breaker. Rev 1 68 Paralleling Generators Example Consider the following situation. A main generator is about to be connected to an infinite power grid. Closing the generator output breaker with the generator voltage slightly lower than grid voltage and with generator frequency slightly higher than grid frequency will initially result in: (Assume no generator breaker protective trip occurs). A. B. C. D. the generator supplying reactive power to the grid. the generator attaining a leading power factor. the generator acting as a real load to the grid. motoring of the generator. This circumstance requires you to consider both real load and reactive load. Since the generator frequency is slightly higher than grid frequency (the synchroscope will be rotating slowly in the clockwise direction, as it should be when you parallel generators), the generator will pick up real load from the grid. This eliminates options C and D, since both of them imply the generator becomes a load on the grid. You should evaluate reactive load next. Since the generator voltage is slightly lower than grid voltage, it will not supply reactive power to the grid, eliminating option A. It will have a leading power factor, and appear as a capacitive load to the rest of the grid; we have eliminated all possible answers except option B. Knowledge Check (Answer Key) A main generator is being paralleled to the power grid. Generator voltage has been properly adjusted and the synchroscope is rotating slowly clockwise. The generator breaker must be closed just as the synchroscope pointer reaches the 12 o'clock position to prevent... A motoring of the generator due to unequal frequencies. B excessive MW load transfer to the generator due to unequal frequencies. C excessive MW load transfer to the generator due to out-ofphase voltages. D excessive arcing within the generator output breaker due to out-of-phase voltages. Rev 1 69 Knowledge Check (Answer Key) A main generator is about to be connected to an infinite power grid with the following conditions: Generator frequency: 59.5 Hz Grid frequency: 59.8 Hz Generator voltage: 115.1 kV Grid voltage: 114.8 kV When the generator output breaker is closed, the generator will... A. acquire real load and reactive load. B. acquire real load, but become a reactive load to the grid. C. become a real load to the grid, but acquire reactive load. D. become a real load and a reactive load to the grid. Knowledge Check (Answer Key) A main generator is about to be connected to an infinite power grid. Closing the generator output breaker with generator and grid voltages matched, but with generator frequency lower than grid frequency will initially result in the generator... Rev 1 A. picking up a portion of the grid real load. B. picking up a portion of the grid reactive load. C. experiencing reverse power conditions. D. experiencing over-speed conditions. 70 Knowledge Check (Answer Key) Which one of the following evolutions will draw the highest current from the main generator during operation of the output breaker? A. Closing the output breaker with voltages in phase B. Opening the output breaker under full-load conditions C. Opening the output breaker under no-load conditions D. Closing the output breaker with voltages out of phase ELO 4.4 Generator Excitation Introduction An understanding of generator response to over and under excitations conditions and governor speed changes is important to proper generator monitoring and operation. Generator Excitation Guidelines There are two terms commonly used to explain changes in a generator’s airgap flux; over-excitation and under-excitation. These terms describe the changes in a generator's air-gap flux (magnetic field) due to the internally generated voltage (emf) during paralleled generators or generator-grid operation. If the generator is initially in an under excited condition, the power factor angle is lagging. This means that the machine is absorbing reactive power from the system (acting as a reactive load on the system). Conversely, if the generator is in an over-excited condition, the power factor angle is leading. This means that the generator is supplying reactive power to the system. Based on grid conditions and supplied loads, power control/load dispatch may request a change in generator excitation to help maintain grid voltage stability. A generator will react differently to governor speed and field changes, dependent on whether it is operating un-paralleled, paralleled with another generator, or supplying the power grid. During parallel operation to the grid, the generator is a relative small power supply in comparison to the entire grid network, and therefore not able to change grid voltage or frequency significantly. Rev 1 71 Operation with generator not paralleled: Changes to the governor control (prime mover) result in changes to generator output frequency. If you increase the speed of the generator, the frequency will increase (recall that frequency = NP/120, which is rotor speed times number of poles, divided by 120); and if you decrease the generator speed, the frequency will decrease. Changes to the generator field will result in changes in the generator output voltage (recall that the EMF induced in the armature is dependent on the field strength of the rotating magnetic field). If you increase current flow to the field, that will increase field strength, which will increase EMF and generator output voltage. Generator Excitation Guideline Terms Some terms associated with generator over-excitation and under-excitation with a generator paralleled with another generator or the grid include the following: Unity power factor – (VARs at lowest point or zero) for every operating condition, there is one value of field current that will cause the generator to deliver only real power. It is impractical to operate an AC generator at a unity power factor because all AC systems require some reactive power for the generation of magnetic fields, etc. Under-excitation - when field current falls below the value that yields operation at a unity power factor, the generator will absorb reactive power (VARs will increase). The generator acts as inductive coil (consumption of inductive reactive power). This condition is usually not the desired mode of operating an AC generator, since in this condition, the generator is acting as a reactive load on the system. Over-excitation - increasing field current causes the generator to supply increased reactive power. The generator acts as capacitor (delivery of reactive power). Normally, we require generators to provide VARs together with watts; they nearly always operate in the overexcited condition. While there are protective devices that guard against voltage regulator failure, none protect from over-excitation or under-excitation. Rev 1 72 Generator Excitation Guidelines When the generator is under-excited: Reducing the generator voltage signal will make the generator more underexcited. It will look like a larger inductive load to the grid, and draw more reactive load from the grid. Increasing generator voltage will make the generator less under-excited. It will draw less reactive load and move closer to unity power factor. In the under-excited condition, the generator has a leading power factor. When the generator is over-excited: Increasing generator voltage will make the generator more over-excited, it will supply more reactive load to the grid.In the over-excited condition, the generator has a lagging power factor. Power plants generally operate in the over-excited condition because the grid has more inductive than capacitive loads. Note: Generator voltage changes will only affect reactive load (VAR) and not real load (kW). Infinite Versus Isolated Bus Infinite Bus: Nuclear power plant generators are tied, for all practical purposes, what could be considered an infinite bus. The grid is so large that speed and voltage changes of the power plant’s generator have no effect on grid frequency or voltage but only on the real and reactive loads that are shared between the grid and generator. Isolated Bus: An isolated bus (also referred to as a “finite bus”) is a bus in which a single generator provides a significant enough load to a bus such that it can have an impact on bus voltage and frequency. One example would be a large factory that generates its own power. If two generators operating in parallel provided power to the bus, changes made by one generator would affect the voltage and frequency of the bus and the other generator. Rev 1 73 Generator Excitation Example A main generator that connects to an infinite power grid has the following initial indications: 100 MW 0 MVAR 2,900 Amps 20,000 VAC If we reduce the main generator excitation slightly, amps will _________________ and MW will ______________. In order to evaluate this item, we need to consider real load and reactive load separately. Main generator excitation controls reactive load, and generator real load is controlled by raising speed. Speed will be unchanged due to the connection to an infinite grid, but the generator will take load from the grid in its attempt to raise speed. Since speed control has not been touched, real load will remain unchanged. Next, consider the effect of reducing generator excitation. The generator begins at 0 MVARS or no reactive load at all. Therefore, an adjustment in either direction will increase current. In this case, the generator will go from unity power factor to under-excited. It will appear as an inductive load to the grid. Therefore, in answer to the question above: If we reduce the main generator excitation slightly, amps will increase and MW will remain the same. Rev 1 74 Knowledge Check (Answer Key) Two identical 1,000 MW electrical generators are operating in parallel, supplying the same isolated electrical bus. The generator output breakers also provide identical protection for the generators. Generator A and B output indications are as follows: Generator A Generator B 22.5 kV 22.5 kV 60.2 Hertz 60.2 Hertz 750 MW 750 MW 25 MVAR (out) 50 MVAR (out) A malfunction causes the voltage regulator for generator B to slowly and continuously increase the terminal voltage for generator B. If the operator takes no action, which one of the following describes the electrical current indications for generator A? Rev 1 A. Current will decrease continuously, until the output breaker for generator A trips on reverse power. B. Current will decrease continuously, until the output breaker for generator B trips on reverse power. C. Current will initially decrease, then increase until the output breaker for generator A trips on overcurrent. D. Current will initially decrease, then increase until the output breaker for generator B trips on overcurrent. 75 Knowledge Check (Answer Key) Two identical 1,000 MW AC electrical generators are operating in parallel, supplying all the loads on a common electrical bus. The generator output breakers provide identical protection for the generators. Generator A and B output indications are as follows: Generator A Generator B 28 kV 28 kV 60 Hertz 60 Hertz 150 MW 100 MW 25 MVAR (out) 50 MVAR (out) A malfunction causes the voltage regulator setpoint for generator B to slowly and continuously decrease. If no operator action is taken, the electrical current indication for generator B will... Rev 1 A. initially decrease, then increase until the output breaker for generator A trips on overcurrent. B. initially decrease, then increase until the output breaker for generator B trips on overcurrent. C. decrease continuously until the output breaker for generator A trips on overcurrent. D. decrease continuously until the output breaker for generator B trips on reverse power. 76 Knowledge Check (Answer Key) A main generator is about to be connected to an infinite power grid. Generator voltage is slightly higher than grid voltage and the synchroscope is rotating slowly in the clockwise direction. The generator breaker is closed just as the synchroscope pointer reaches the 3 o'clock position. Which one of the following will occur after the breaker is closed? A. The breaker will remain closed and the generator will supply only MW to the grid. B. The breaker will remain closed and the generator will supply both MW and MVAR to the grid. C. The breaker will open due to overcurrent. D. The breaker will open due to reverse power. TLO 4 Summary Parallel Operation of Generators In this section, you learned how generators operate in parallel with other generators of similar size, and in parallel with an infinite grid. You learned how to control real and reactive load and maintain the generator in a stable operating condition in all normal operating circumstances. 1. In AC circuits, current and voltage are normally out of phase due to the effects of inductive and capacitive reactance. As a result, not all the power produced by a generator in an AC application can accomplish work. 2. A power triangle shows apparent, true, and reactive power, and the relationships between them. 3. The power triangle equates AC power to DC power by showing the relationship between generator output (Apparent Power - S) in voltamperes (VA), usable power (True Power - P) in watts, and wasted or stored power (Reactive Power - Q) in volt-amperes-reactive (VAR). The phase angle (θ) represents the inefficiency of the AC circuit and corresponds to the total reactive impedance (Z) to current flow in the circuit. 4. Power factor (pf) is the ratio between True Power and Apparent Power. True Power is the power consumed by an AC circuit, whereas Apparent Power is a representation of the total power delivered to an AC circuit. Rev 1 77 5. The purpose of a voltage regulator is to maintain the output voltage of a generator at a desired value. 6. An AC generator’s voltage regulator continuously compares the voltage output of the machine to a desired value. The voltage regulator varies the DC (rectified AC) excitation applied to the generator’s field in order to maintain generator output voltage constant. 7. To parallel AC generators, three conditions must be met: Their terminal voltages must be essentially equal. Their frequencies must be almost equal. Their output voltages must be in phase. 8. Generator Over and Under-Excitation Unity power factor – (VARs at lowest point or zero) for every operating condition, there is one value of field current that will cause the generator to deliver only real power. Under-excitation - when field current falls below the value for unity power factor operation, the generator will absorb reactive power (VARs will increase). Generator acts as inductive coil (consumption of inductive reactive power). This condition is usually not the desired mode of operating an AC generator, since in this condition the generator is acting as a reactive load on the system. Over-excitation - increasing field current causes generator to supply increasing reactive power. Generator acts as capacitor (delivery of reactive power). Generators normally provide VARs together with watts; they usually operate in the over-excited condition. Summary Now that you have completed this lesson, you should be able to do the following: 1. Define apparent, true, and reactive power and power factor using a power triangle, and their effect on generator operation. 2. Describe the purpose of a voltage regulator and function of each of the following typical components: a. Sensing circuit b. Reference circuit c. Comparison circuit d. Amplification circuit(s) e. Signal output circuit f. Feedback circuit 3. Describe the conditions that must be met prior to paralleling two generators including consequences of not meeting these conditions. 4. Describe the consequences of over-excitation and under-excitation when load sharing. Rev 1 78 AC Motors and Generators Summary This module presented the types of AC motors and generators, their operating characteristics and applications, and the means to control them in conjunction with the power system. Now that you have completed this module, you should be able to demonstrate mastery of this topic by passing a written exam with a grade of 80 percent or higher on the following TLOs: 1. Describe the construction, operating characteristics and limitations for an AC generator. 2. Explain the theory of operation of selected types of AC motors. 3. Explain operating characteristics and limitations on AC motors and generators. 4. Analyze operation of generators in parallel and predict system response to changes in frequency, voltage, and load. Rev 1 79 Motors and Generators Knowledge Check Answer Key Knowledge Check Answer Key ELO 1.1 Generator Theory Knowledge Check When two AC voltages reach their peak voltage at the same time, the voltages are said to be ______________. A. lagging B. out of phase C. in phase D. Leading ELO 1.2 Generator Components Knowledge Check An AC generator has all of the following except ______________. Rev 1 A. a commutator B. a magnetic field C. slip rings D. a conductor in relative motion with the magnetic field 1 Motors and Generators Knowledge Check Answer Key Knowledge Check The part of an AC generator that produces the output voltage is called the: A. Armature B. Field C. Stator D. Rotor ELO 1.3 Electrical Terms Knowledge Check The unit commonly used to specify electric power is: A. Volt B. Amp C. Watt D. Hertz or frequency ELO 1.4 Types of AC Generators Knowledge Check The rotating armature, stationary field type is used for most large power generators. Rev 1 A. True B. False 2 Motors and Generators Knowledge Check Answer Key ELO 2.1 Producing a Rotating Magnetic Field Knowledge Check Select all of the statements about creating a rotating magnetic field in a three-phase induction motor that are true. Rev 1 A. Since the windings are 120 degrees out of phase, the magnetic field produced by the windings will also be 120 degrees out of phase. B. The magnetic field induced in each winding rises and falls in a sine wave as the current through that winding rises and falls in a sine wave. C. The magnetic field generated in the motor windings makes 60 revolutions per second in a 60 Hz power system. D. The magnetic field induced in the windings is independent of how the motor is wound and connected. 3 Motors and Generators Knowledge Check Answer Key ELO 2.2 Slip Effects on AC Induction Motor Operation Knowledge Check Select all of the statements that are true regarding threephase induction motor operation. A. The rotor turns at a speed slower than the rotation of the stator magnetic field. B. The rotor turns at the same speed as the stator magnetic field. C. The difference in speed between the stator magnetic field and the rotor is necessary to induce a magnetic field on the rotor. D. The rotor has field windings supplied by an external power supply ELO 2.3 Developing Torque in an AC Induction Motor Knowledge Check The maximum value of torque that an AC induction motor can produce without stalling is known as: Rev 1 A. Starting torque B. Breakdown torque C. Stalling torque D. Critical torque 4 Motors and Generators Knowledge Check Answer Key ELO 2.4 Starting Current on an AC Induction Motor Knowledge Check If the discharge valve of a large motor-driven centrifugal pump remains closed during a normal pump start, the current indication for the AC induction motor will rise to... A. several times the full-load current value, and then decrease to the no-load current value. B. approximately the full-load current value, and then decrease to the no-load current value. C. approximately the full-load current value, and then stabilize at the full-load current value. D. several times the full-load current value, and then decrease to the full-load value. Knowledge Check Which one of the following is a characteristic of a typical AC induction motor that causes starting current to be greater than running current? Rev 1 A. After the motor starts, resistors are added to the electrical circuit to limit the running current. B. A large amount of starting current is required to initially establish the rotating magnetic field. C. The rotor does not develop maximum induced current flow until it has achieved synchronous speed. D. The rotor magnetic field induces an opposing voltage in the stator that is proportional to rotor speed. 5 Motors and Generators Knowledge Check Answer Key Knowledge Check Two identical AC induction motors are connected to identical radial-flow centrifugal pumps in identical but separate cooling water systems. Each motor is rated at 200 hp. The discharge valve for pump A is fully open and the discharge valve for pump B is fully closed. Each pump is currently off. If the pumps are started under these conditions, the shorter time period required to reach a stable running current will be experienced by the motor for pump _____ and the higher stable running current will be experienced by the motor for pump _____. A. A; A B. A; B C. B; A D. B; B ELO 2.5 AC Synchronous Motor Operation Knowledge Check Select all the statements that are true. Rev 1 A. Synchronous motors are the most commonly used motors in large industrial applications. B. Synchronous motors develop starting torque in the same manner as induction motors. C. Synchronous motors are not often used due to their more complex nature and higher manufacturing costs. D. Synchronous motors can continue to operate with more slip than induction motors, thus producing more torque. 6 Motors and Generators Knowledge Check Answer Key ELO 3.1 Motor Applications Knowledge Check The least often used motor in station applications is the ____________. A. three-phase induction motor B. single-phase (split-phase) motor C. synchronous motor D. squirrel-cage motor ELO 3.2 Indications of Motor Malfunctions Knowledge Check If a reactor coolant pump (RCP) rotor seizes, RCP motor current will __________; if the rotor shears, RCP motor speed will __________. Rev 1 A. increase; increase B. increase; decrease C. decrease; increase D. decrease; decrease 7 Motors and Generators Knowledge Check Answer Key Knowledge Check A motor-driven cooling water pump is operating normally. How will pump motor current respond if the pump experiences a locked rotor? A. Decreases immediately to zero due to breaker trip. B. Decreases immediately to no-load motor amps. C. Increases immediately to many times running current, then decreases to no-load motor amps. D. Increases immediately to many times running current, then decreases to zero upon breaker trip. ELO 3.3 Consequences of Motor Overheating Knowledge Check Which one of the following will result from prolonged operation of an AC induction motor with excessively high stator temperatures? Rev 1 A. Decreased electrical current demand due to reduced counter electromotive force. B. Decreased electrical resistance to ground due to breakdown of winding insulation. C. Increased electrical current demand due to reduced counter electromotive force. D. Increased electrical resistance to ground due to breakdown of winding insulation. 8 Motors and Generators Knowledge Check Answer Key Knowledge Check Continuous operation of a motor at rated load with a loss of required cooling to the motor windings will eventually result in ____________. A. cavitation of the pumped fluid B. failure of the motor overcurrent protection devices C. breakdown of the motor insulation and electrical grounds D. phase current imbalance in the motor and overspeed trip actuation ELO 3.4 Excessive Current in Motors Knowledge Check Which of the following will cause an increase in motor current? (Select all that are true.) Rev 1 A. An increase in bearing friction due to inadequate maintenance B. Increasing the load on the component driven, such as opening a pump discharge valve to provide more flow C. Increased voltage to the motor D. Reduced voltage to the motor 9 Motors and Generators Knowledge Check Answer Key Knowledge Check Excessive current will be drawn by an AC induction motor that is operating ____________. A. completely unloaded B. at full load C. with open circuited stator windings D. with short circuited stator windings ELO 3.5 Pump Motor Current Relationships Knowledge Check A centrifugal pump is operating with the initial conditions as listed: 100 kW 500 gpm 150 ft The operator notices that pump power decreased 50 kW. What is the corresponding change in flow? Rev 1 A. 350 gpm B. 300 gpm C. 396 gpm D. 250 gpm 10 Motors and Generators Knowledge Check Answer Key Knowledge Check A multispeed centrifugal pump is operating with a flow rate of 1,800 gpm at a speed of 3,600 rpm. Which one of the following approximates the new flow rate if the pump speed is decreased to 2,400 rpm? A. 900 gpm B. 1,050 gpm C. 1,200 gpm D. 1,350 gpm ELO 4.1 Power Factor and Generators Knowledge Check Select all that are true. Rev 1 A. Reactive power is imaginary and the currents caused by reactive power do not contribute to heat loads on the generator or current detected by protective relays. B. True power is the power consumed by resistive loads on the system. C. Total power is the power available to do work on the system. D. Reactive power is held and given back by inductive and capacitive loads on the system. 11 Motors and Generators Knowledge Check Answer Key Knowledge Check Select all that are true. A. Power factor is the ratio of true power to apparent power and is always greater than 1. B. Power factor is the ratio of reactive power to real power and is always greater than 1. C. Power factor is the ratio of true power to apparent power and can vary from 0 to 1. D. Power factor is the ratio of true power to reactive power and is always less than 1. ELO 4.2 Voltage Regulation and Components Knowledge Check Select all that are true. Rev 1 A. Generator output voltage is affected by the current drawn by the system the generator supplies. B. Generator output voltage is affected by the power factor of the system the generator supplies. C. Generator output voltage is not affected by the system the generator supplies at all. D. Generator output voltage is a function of the number of generator windings and the output voltage variance is insignificant. 12 Motors and Generators Knowledge Check Answer Key Knowledge Check The __________ prevents overshooting or undershooting of the desired voltage by slowing down the circuit response. A. sensing circuit B. comparison circuit C. feedback circuit D. amplification circuit ELO 4.3 Paralleling Generators Knowledge Check A main generator is being paralleled to the power grid. Generator voltage has been properly adjusted and the synchroscope is rotating slowly clockwise. The generator breaker must be closed just as the synchroscope pointer reaches the 12 o'clock position to prevent... A motoring of the generator due to unequal frequencies. B excessive MW load transfer to the generator due to unequal frequencies. C excessive MW load transfer to the generator due to out-ofphase voltages. D excessive arcing within the generator output breaker due to out-of-phase voltages. Rev 1 13 Motors and Generators Knowledge Check Answer Key Knowledge Check A main generator is about to be connected to an infinite power grid with the following conditions: Generator frequency: 59.5 Hz Grid frequency: 59.8 Hz Generator voltage: 115.1 kV Grid voltage: 114.8 kV When the generator output breaker is closed, the generator will... A. acquire real load and reactive load. B. acquire real load, but become a reactive load to the grid. C. become a real load to the grid, but acquire reactive load. D. become a real load and a reactive load to the grid. Knowledge Check A main generator is about to be connected to an infinite power grid. Closing the generator output breaker with generator and grid voltages matched, but with generator frequency lower than grid frequency will initially result in the generator... Rev 1 A. picking up a portion of the grid real load. B. picking up a portion of the grid reactive load. C. experiencing reverse power conditions. D. experiencing over-speed conditions. 14 Motors and Generators Knowledge Check Answer Key Knowledge Check Which one of the following evolutions will draw the highest current from the main generator during operation of the output breaker? Rev 1 A. Closing the output breaker with voltages in phase B. Opening the output breaker under full-load conditions C. Opening the output breaker under no-load conditions D. Closing the output breaker with voltages out of phase 15 Motors and Generators Knowledge Check Answer Key ELO 4.4 Generator Excitation Knowledge Check Two identical 1,000 MW electrical generators are operating in parallel, supplying the same isolated electrical bus. The generator output breakers also provide identical protection for the generators. Generator A and B output indications are as follows: Generator A Generator B 22.5 kV 22.5 kV 60.2 Hertz 60.2 Hertz 750 MW 750 MW 25 MVAR (out) 50 MVAR (out) A malfunction causes the voltage regulator for generator B to slowly and continuously increase the terminal voltage for generator B. If the operator takes no action, which one of the following describes the electrical current indications for generator A? Rev 1 A. Current will decrease continuously, until the output breaker for generator A trips on reverse power. B. Current will decrease continuously, until the output breaker for generator B trips on reverse power. C. Current will initially decrease, then increase until the output breaker for generator A trips on overcurrent. D. Current will initially decrease, then increase until the output breaker for generator B trips on overcurrent. 16 Motors and Generators Knowledge Check Answer Key Knowledge Check Two identical 1,000 MW AC electrical generators are operating in parallel, supplying all the loads on a common electrical bus. The generator output breakers provide identical protection for the generators. Generator A and B output indications are as follows: Generator A Generator B 28 kV 28 kV 60 Hertz 60 Hertz 150 MW 100 MW 25 MVAR (out) 50 MVAR (out) A malfunction causes the voltage regulator setpoint for generator B to slowly and continuously decrease. If no operator action is taken, the electrical current indication for generator B will... Rev 1 A. initially decrease, then increase until the output breaker for generator A trips on overcurrent. B. initially decrease, then increase until the output breaker for generator B trips on overcurrent. C. decrease continuously until the output breaker for generator A trips on overcurrent. D. decrease continuously until the output breaker for generator B trips on reverse power. 17 Motors and Generators Knowledge Check Answer Key Knowledge Check A main generator is about to be connected to an infinite power grid. Generator voltage is slightly higher than grid voltage and the synchroscope is rotating slowly in the clockwise direction. The generator breaker is closed just as the synchroscope pointer reaches the 3 o'clock position. Which one of the following will occur after the breaker is closed? Rev 1 A. The breaker will remain closed and the generator will supply only MW to the grid. B. The breaker will remain closed and the generator will supply both MW and MVAR to the grid. C. The breaker will open due to overcurrent. D. The breaker will open due to reverse power. 18