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Transcript
Understanding electrical networks to enhance their protection G Points to remember F E Network protection The various discrimination types D The various earthing system types C ? Situate the protection relay Duration: 43:35 min TOLED Network disturbances B Network architecture A What exactly is protection Expert: André TRUONG Training: François BECHERET Layout: Bernadette ETIENNE Understanding networks – June 04 SITUATE THE PROTECTION RELAY Production units Generator Transformers Overhead lines Underground cables MV/MV distribution substations HV/MV substations Motors TOLED Industries MV/LV distribution substations Understanding networks – June 04 2 - Network disturbances Natural phenomena – branches – lightning Works Short-circuit Transient Short-circuit Use – – – – – – capacity problem reconfiguration dust insulators machine start-up pump/turbine blocking ... – harmonics ... TOLED Overloads surges Transient Short-circuit losses Understanding networks – June 04 3 WHAT EXACTLY IS PROTECTION Detect and isolate the fault Preserve continuity of supply Sensor current voltage Measure Compare Decide Tripping coil A protection device does not prevent the fault from occurring, but limits the consequences ... TOLED Understanding networks – June 04 4 - The protection plan Network architectures Types of disturbance PROTECTION PLAN Type of protection function Earthing systems CHOICE OF RELAY Discrimination Settings Components to protect TOLED Understanding networks – June 04 5 NETWORK ARCHITECTURE G Points to remember F E Network protection The various discrimination types D The various earthing system types C ? TOLED Situate the protection relay Network disturbances B Network architecture A What exactly is protection Understanding networks – June 04 6 - Choosing a network Safety of equipment and people Technical and economic aspects Open-endedness Continuity of operation Maintainability Safety $ Open Maint Conti Ease of operation Op TOLED Understanding networks – June 04 7 - Loop distribution Large distances Open loop Closed loop Urban secondary networks = geographical area and continuity of supply Rural secondary networks = geographical area and simplicity Safety Safety $ Open Maint Conti Op TOLED Supplied Strong point Not supplied Weak point $ Open Maint Conti Op Understanding networks – June 04 8 - Antenna distribution Large to average distances Single antenna Safety $ Open Maint Conti Op TOLED Double antenna Simple industries and tertiary: reduced costs Continuous process industries: continuity Supplied Strong point Not supplied Weak point Safety $ Open Maint Conti Op Understanding networks – June 04 9 - Double tap-off distribution Heavy process industries and large tertiary: continuity Safety $ Open Maint Conti Op TOLED Supplied Strong point Not supplied Weak point Understanding networks – June 04 10 - Double busbar distribution Solution for cubicles Continuous process industries Oil & Gas: continuity Safety $ Open Maint Conti Op TOLED Strong point Supplied Weak point Not supplied Understanding networks – June 04 11 - Local production Partial permanent production High consumption industry Expensive electricity TOLED Main / standby production Supplied Not supplied Sites with priority for continuity of supply Understanding networks – June 04 12 - Points to remember Public distribution Rural secondary Open loop Low costs Urban secondary Closed loop Continuity of supply Simple tertiary Single antenna Low costs Tertiary Large tertiary Simple processes Industry Continuous processes « Heavy » continuous processes TOLED Double antenna Double tap-off Double busbars Continuity of supply / Ease of maintenance Complexity of operation Understanding networks – June 04 13 DISTURBANCES G Points to remember F E Network protection The various discrimination types D The various earthing system types C ? TOLED Situate the protection relay Network disturbances B Network architecture A What exactly is protection Understanding networks – June 04 14 - Network disturbances Natural phenomena – branches – lightning Works Simple fault Complex fault short-circuit Surges short-circuit Use – capacity problem – reconfiguration TOLED overloads Transient Losses – – dust insulators – machine start-up – pump/turbine blocking ... – harmonics short-circuit Transient Effects – Customer power supply suspended – Incorrect network operation – Material damage – Bodily damage Understanding networks – June 04 15 - The short-circuit Origin Duration Location – mechanical – self-extinguishing – – electrical – transient – human – permanent – Isc: short-circuit equipment – non-resistive link – impedant phase-to-phase Isc Rare but destructive Isolated two-phase short-circuit Energy loss Three-phase short-circuit (5% of cases) phase-to-earth lsc The most common Earth single-phase short-circuit TOLED Two-phase short-circuit (80% of cases) Understanding networks – June 04 16 - Other disturbances Overload Temperature rise thus ageing In Voltage sag time Surges Undervoltage and voltage sags Arcing Overspeed Saturation Destruction Current increase Overload Ur Temperature rise time Frequency fluctuations, harmonics and transient phenomena TOLED Understanding networks – June 04 17 - Equipment short-circuit withstand Devices Disconnector Isolation function yes Current switching function In service no Main constraints On fault no Input-output crossing withstand Earthing switch: making capacity on a fault no Breaking and making of normal load current Making capacity on short-circuit In association with the fuse: breaking capacity in the fuse non-blowing zone Switch no Contactor no yes if draw-out yes no Nominal breaking and making capacity Maximum load capacity in breaking and making Service and durability characteristics Circuit-breaker no yes if draw-out yes yes Breaking capacity on short-circuit Making capacity on short-circuit Fuse no no yes Minimum breaking capacity on short-circuit Maximum breaking capacity on short-circuit TOLED yes Understanding networks – June 04 18 EARTHING SYSTEMS AND THEIR IMPACTS G Points to remember F E Network protection The various discrimination types D The various earthing system types C ? TOLED Situate the protection relay Network disturbances B Network architecture A What exactly is protection Understanding networks – June 04 19 - Earthing systems and earthing 1 earthing type limits the effects of network disturbances Continuity of supply SERVICE Simple protection OPERATING COSTS Personnel skills Fault energy Transient phenomena SAFETY OF PEOPLE Surges TOLED Understanding networks – June 04 20 - 5 types of earthing system R L Z Unearthed: no connection Earthed: connection TOLED R Earthed via a resistor L Earthed via a reactance Z Earthed via a compensated reactance Understanding networks – June 04 21 - Unearthed neutral Continuity of supply SERVICE Simple protection OPERATING COSTS Personnel skills Advantages – Continuity of supply Drawbacks – 2nd fault = Isc phase-to-phase Fault energy Transient phenomena SAFETY OF PEOPLE surges & transients – Difficult discrimination Surges Type of protection – – Max. directional lo and Max. residual Vo Insulation monitor Applications – TOLED Industry Understanding networks – June 04 22 - Directly earthed neutral Continuity of supply SERVICE Simple protection OPERATING COSTS Personnel skills Advantages – – No surges No specific protection Drawbacks – – High lsc No continuity of supply on the 1st fault Fault energy Transient phenomena SAFETY OF PEOPLE Surges Type of protection – Max. Io Applications – – TOLED US public distribution For small lsc Understanding networks – June 04 23 - Earthing via a resistor Continuity of supply SERVICE Simple protection R Personnel skills Advantages – Isc / surge compromise – Simple & selective protection Drawbacks – Breaking on 1st fault – Expensive resistor OPERATING COSTS Fault energy Transient phenomena SAFETY OF PEOPLE Surges Type of protection – Overcurrent Applications – TOLED Public & industrial distribution Understanding networks – June 04 24 - Earthing via a small reactance Continuity of supply SERVICE Simple protection L Personnel skills Advantages – Limited lsc – Inexpensive reactance OPERATING COSTS Fault energy Transient phenomena SAFETY OF PEOPLE Drawbacks – Breaking on 1st fault – Surges Surges Type of protection – Directional earth protection Applications – TOLED Public distribution > 40 kV Understanding networks – June 04 25 - Earthing via a compensation reactance Continuity of supply SERVICE Simple protection Z Personnel skills Advantages – Limited lsc – Continuity of supply Drawbacks – Expensive reactance – – Surges Discrimination implementation OPERATING COSTS Fault energy Transient phenomena SAFETY OF PEOPLE Surges Type of protection – Max. directional Io Applications – TOLED Public distribution with high capacitive l Understanding networks – June 04 26 - Summary of the 5 earthing systems Unearthed: no connection Earthed: connection Transient phenomena Earthed via a resistor Simple protection Earthed via a reactance Fault energy Earthed via a compensated reactance TOLED Continuity of supply Continuity of supply Personnel skills Fault energy Continuity of supply Surges Simple protection Understanding networks – June 04 27 DISCRIMINATION G Points to remember F Network protection E The various discrimination types D The various earthing system types C ? TOLED Situate the protection relay Network disturbances B Network architecture A What exactly is protection Understanding networks – June 04 28 - 6 types of discrimination to optimise continuity of supply Discrimination: Isolate only the faulty part Supply the healthy sector Choice of protection relay as per: Network 6 discrimination principles: time current logic by directional protection by differential protection combined Disturbances incurred Earthing system TOLED Understanding networks – June 04 29 - Time discrimination Principle: “time” – time delays increasingly short as we move away from the source Source TA =1.1 s. TB =0.8 s. – tripping as close as possible to the fault Advantages – simple – automatic standby TC =0.5 s. TD =0.2 s. Phase-to-phase fault TOLED Drawbacks – tripping too long in A, in event of fault at this level Understanding networks – June 04 30 - Current discrimination Principle: “current” Source – The further the fault from the source, the weaker the fault current IscBmax Section A Advantages – Each relay monitors its section – Simple, inexpensive and fast Drawbacks Section B IsA > IscAmin TOLED – No « standby » protection Condition IsA > IscBmax Understanding networks – June 04 31 - Logic discrimination Principle: “ … ” Source – A (blue) additional network connects all the protection relays to allow exchanges and decisions as to « which relay is concerned ». Advantages Logic wait – Avoids over long tripping times – Tripping time not dependent on number of protection devices – Standby system Drawbacks Phase-to-phase fault – An additional wiring network is required Additional wiring TOLED Understanding networks – June 04 32 - Discrimination by directional protection Principle: “directional” Cable Cable – Measures flow direction – Network in loop on 2 sources Advantages Vref. – Preserves 1 out of the 2 power supplies in event of fault in 1 – Simple solution Busbar Drawback – The cost of the voltage transformers TOLED Understanding networks – June 04 33 - Discrimination by differential protection Principle: "differential" Source – IA = IB ? – Tripping on a difference! Advantages Protected area Section – Sensitive – Instantaneous Drawbacks TOLED – Cost – Implementation – Standby to provide Understanding networks – June 04 34 - In short, discrimination is ... 1 … time 2 … current Discrimination applies to – I phase – Io earth 3 … logic 4 … direction 5 … difference 6 TOLED ? Global discrimination and redundancy – Mix discrimination types 6 Discrimination combination Understanding networks – June 04 35 NETWORK PROTECTION G Points to remember F E Network protection The various discrimination types D The various earthing system types C ? TOLED Situate the protection relay Network disturbances B Network architecture A What exactly is protection Understanding networks – June 04 36 - Connection protection: overhead lines Overhead lines: 80 % of problems Downstream faults: Short-circuits Breakage of a phase Recommended protections: X X X incomer – – – – – overcurrent protection (50/51) max. Io protection (50N/51N) phase unbalance protection (46) distance protection (21) line differential protection (87L) line feeder Protection provided by other devices – Against lightning: overvoltage protection devices – Against transient contacts: automation TOLED Understanding networks – June 04 37 - Connection protection: underground cables Underground distribution in urban environments Downstream faults: short-circuits breakage of a phase No reclosing X X X Recommended protections: incomer cable feeder TOLED – – – – – Directional earth protection (67N) Overcurrent protection (50/51) Residual overcurrent protection (50N/51N) Phase unbalance protection (46) Line differential protection (87L) Understanding networks – June 04 38 - Connection protection: busbars Electrical switchboards – « energy concentration » ! – need to eliminate the fault quickly Schéma F2 busbar Fault – short-circuits (between bars and with the earth) – temperature rise – insulation loss Recommended protections X X X X X X X – Logic discrimination: overcurrent (50/51) and residual overcurrent protection (50N/51N) – Time discrimination: busbar differential protection (87B) TOLED Understanding networks – June 04 39 - Protection example of substation busbars with 2 incomers Directional protection set if fault protections – Overcurrent protection (50/51) – Residual overcurrent protection (50N/51N) – Directional phase protection (67) discrimination – current TOLED Understanding networks – June 04 40 - Switchgear protection: the transformer Faults Protections Short-circuit • Coiling • Tank • Magnetic circuit • Overcurrent 50/51 • transformer differential • 87T • Buchholz • DGPT 63 Earth fault • Coiling • Magnetic circuit • Max. Io 50N/51N • Restricted differential 64REF • Tank earth 50N/51N, 50G/51G • Insulators • Overcurrent 50/51 • Thermal overload 49RMS • Temperature 49T Overload TOLED Impacts Understanding networks – June 04 41 - Switchgear protection: the motor Faults Upstream • Voltage sag • Unbalance Impacts • Active power return: voltage sag • Undervoltage 27 • Max. reverse component 46 • Overpower 32P • Destruction of coiling and magnetic circuit • Motor deceleration • Overcurrent 50/51 • Machine differential 87M • Max. Io 50N/51N, 78PS • Overcurrent • Stator temperature rise • Pump unpriming • Mechanical breakage • Thermal overload 49RMS • 48 • 51LR • Min. I 37, P, 37P • Temperature rise • Limited number of start-ups 66 Internal • Short-circuit • Earth fault • Loss of synchronism Downstream • Overload • Starting too long • Locked rotor Use • Frequent starting TOLED Protections Understanding networks – June 04 42 - Switchgear protection: the generator Faults Internal Impacts • Overcurrent 50/51 • Machine differential 87M • Overcurrent with voltage retention 50V/51V Short-circuit • Destruction of coiling & magnetic circuit Earth fault • Destruction of coiling & destruction of magnetic circuit • Max. Io 50N/51N • Restricted earth differential 64REF •Residual overvoltage 59N • Overspeed Absorption Reactive power (operates as motor) then temperature rise • 78PS • Min. impedance 21B • Temperature rise and poor efficiency • Over and under frequency 81H/81L • Undervoltage 27 • Mechanical danger for turbine + rotor temperature rise 32P, 46, 59 Loss of synchronism Faults relating to incorrect regulation Upstream Active power return Unbalance Surge TOLED Protections Understanding networks – June 04 43 - Switchgear protection: the capacitor Faults TOLED Impacts Protections Internal short-circuit • Reduction in capacity • Thermal overload 49RMS • Max. reverse component 46 • Specific Short-circuit in the connection • Destruction of connections with capacitors • Overcurrent 50/51 • Thermal overload 49RMS • Max. reverse component 46 Earth fault • Destruction of insulators Unbalance • Max. Io 50N/51N • Residual overvoltage 59N • Max. reverse component 46 Surge • Destruction of insulators • Overvoltage 59 Understanding networks – June 04 44 - The protection guide will provide you with more details Electrical network protection Networks Protection Guide Earthing systems Isc Sensors Protection functions Discrimination network TOLED Network protection Understanding networks – June 04 45 POINTS TO REMEMBER Network architectures Types of disturbance PROTECTION PLAN Type of protection function Earthing systems CHOICE OF RELAY Discrimination Settings Components to protect TOLED Understanding networks – June 04 46
