Type CO Overcurrent Relay - ElectricalManuals
Instruction LeafletABB Automation Inc.Substation Automation and Protection DivisionCoral Springs, FL 3306541-101UEffective: January 1992Supersedes I.L. 41-101T, Dated March 1968(Type COOvercurrent Relay) Denotes Change Since Previous Issue!CAUTIONBefore putting relays into service, remove allblocking which may have been inserted for thepurpose of securing the parts during shipment,make sure that all moving parts operate freely,inspect the contacts to see that they are cleanand close properly, and operate the relay tocheck the settings and electrical connections.1.0 APPLICATIONThe CO relay is a single phase non-directional timeac overcurrent device. It is used to sense current level above the setting and normally is used to trip a circuit breaker to clear faults. A wide range of characteristics permit applications involving coordinationwith fuses, reclosers, cold load pickup, motor starting, or essentially fixed time applications. See Table1 for typical applications.Table 1:TYPICAL APPLICATIONS OF THE CO RELAYRELAYTIMECO-2TYPECURVEShortTYPICAL APPLICATIONS1)2)Differential protection where saturation of current transformers is not expected, orwhere delayed tripping is permissible.Overcurrent protection, phase or ground, where coordination with downstreamdevices is not involved and 2 to 60 cycle tripping is allowable.CO-5LongMotor locked rotor protection where allowable locked rotor time is approximatelybetween 10 and 70 seconds.CO-6DefiniteOvercurrent protection where coordination with downstream devices is not involvedand CO-2 is too fast. The operating time of this relay does not vary greatly as current level varies.CO-7Moderately Inverse1)CO-8Inverse2)CO-9Very InverseCO-11Extremely Inverse1)2)Overcurrent protection where coordination with other devices is required, and generation varies.Backup protection for relays on other circuits.Motor protection where allowable locked rotor time is less than 10 seconds.Overcurrent protection where coordination with fuses and reclosers is involved, orwhere cold load pickup or transformer inrush are factors.All possible contingencies which may arise during installation, operation or maintenance, and all details and variations of this equipment do not purport to be covered by these instructions. If further information is desired bypurchaser regarding this particular installation, operation or maintenance of this equipment, the local ABB PowerT&D Company Inc. representative should be contacted.Printed in U.S.A.
41-101UType CO Overcurrent RelayFigure 1:Type CO Relay Without Case. 1 Indicating Instantaneous Trip (IIT). 2 IIT Adjusting Screw.3 Indicating Contactor Switch (ICS). 4 Indicating Contactor Switch Tap Block.Figure 2:Time Overcurrent Unit (Front View). 1 Tap block. 2 Time Dial.3 Control Spring Assembly. 4 Disc. 5 Stationary Contact Assembly.6 Magnetic Plugs. 7 Permanent Magnet.2
Type CO Overcurrent RelayFigure 3:“E” Type Electromagnet.1 Magnet Plugs.2 Tap Block.3 Tap Screw.41-101UFigure 4:Indicating Instantaneous Trip Unit (IIT).Figure 5: Indicating Contactor Switch (ICS).3
41-101UType CO Overcurrent Relay2.0 CONSTRUCTION AND OPERATIONThe type CO relays consist of an overcurrent unit(CO), an indicating contactor switch (ICS), and an indicating instantaneous trip unit (IIT) when required.The principal component parts of the relay and theirlocation are shown in Figures 1 through 5.2.1ELECTROMAGNETThe electromagnets for the types CO-5, CO-6,CO-7, CO-8 and CO-9 relays have a main tappedcoil located on the center leg of an “E” type laminated structure that produces a flux which divides andreturns through the outer legs. A shading coil causesthe flux through the left leg to lag the main pole flux.The out-of-phase fluxes thus produced in the air gapcause a contact closing torque. A torque controlledCO has the lag coil connections of the electromagnetbrought out to separate terminals. This permits control of the closing torque such that only when theseterminals are connected together will the unit operate.The electromagnets for the types CO-2 and CO-11relays have a main coil consisting of a tapped primary winding and a fixed secondary winding. Identicalcoils are on the outer legs of the lamination structureand are connected to the main coil fixed secondaryin a manner so that the combination of all the fluxesproduced by the electromagnet result in out-ofphase fluxes in the air gap. The out-of-phase air gapfluxes produced cause a contact closing torque.2.2INDICATING CONTACTOR SWITCH UNIT(ICS)The dc indicating contactor switch is a small clappertype device. A magnetic armature, to which leafspring mounted contacts are attached, is attracted tothe magnetic core upon energization of the switch.When the switch closes the moving contacts bridgetwo stationary contacts, completing the trip circuit.Also during this operation two fingers on the armature deflect a spring located on the front of theswitch, which allows the operation indicator target todrop.The front spring, in addition to holding the target,provides restraint for the armature and thus controlsthe pickup value of the switch.2.3INDICATING INSTANTANEOUS TRIP UNIT(IIT)The instantaneous trip unit is a small ac operatedclapper type device. A magnetic armature, to whichleaf-spring mounted contacts are attached, is attracted to the magnetic core upon energization of theswitch. When the switch closes, the moving contactsbridge two stationary contacts completing the trip circuit. Also, during the operation, two fingers on the armature deflect a spring located on the front of theswitch which allows the operation indictor target todrop.Sub 3182A755Figure 6:4External Schematic of the Circuit-Closing Type CO Relay for Phase and Ground OvercurrentProtection on a Three-Phase System.
Type CO Overcurrent Relay41-101UENERGY REQUIREMENTSTYPE CO-2 RELAYVOLT e SecondRating*(Amperes)PowerFactorAngle øAtTap ValueCurrentAt 3 TimesTap ValueCurrentAt 10 TimesTap ValueCurrentAt 20 TimesTap 260140817202064CO-5 LONG TIME AND CO-6 DEFINITE MINIMUM TIME RELAYSVOLT e SecondRating*(Amperes)PowerFactorAngle øAtTap ValueCurrentAt 3 TimesTap ValueCurrentAt 10 TimesTap ValueCurrentAt 20 TimesTap 7645053161169988010564/12456781012*øThermal capacities for short times other than one second may be calculated on the basis of time being inversely proportional to the square of the current.**Voltages taken with Rectox type voltmeter.Degrees current lags voltage at tap value current.5
41-101UType CO Overcurrent RelayENERGY REQUIREMENTSCO-7 MODERATELY INVERSE TIME RELAYVOLT e SecondRating*(Amperes)PowerFactorAngle øAtTap ValueCurrentAt 3 TimesTap ValueCurrentAt 10 TimesTap ValueCurrentAt 20 TimesTap 4062668886010324/12456781012CO-8 LONG TIME AND CO-9 DEFINITE MINIMUM TIME RELAYSVOLT AMPERES**ContinuousRating(Amperes)One SecondRating*(Amperes)PowerFactorAngle 07008501020AmpereRange4/12*ø**6Tap456781012AtAt 3 TimesTap Value Tap ValueCurrentCurrentAt 10 Times At 20 TimesTap ValueTap ValueCurrentCurrentThermal capacities for short times other than one second may be calculated on the basis of time being inversely proportional to the square of the current.Degrees current lags voltage at tap value current.Voltages taken with Rectox type voltmeter.
Type CO Overcurrent Relay41-101UENERGY REQUIREMENTSTYPE CO-11 RELAYVOLT e SecondRating*(Amperes)PowerFactorAngle øAtTap ValueCurrentAt 3 TimesTap ValueCurrentAt 10 TimesTap ValueCurrentAt 20 TimesTap 5026102/62.02.53 .8131.6180.0296340378454480600720*ø**Thermal capacities for short times other than one second may be calculated on the basis of time being inversely proportional to the square of the current.Degrees current lags voltage at tap value current.Voltages taken with Rectox type voltmeter.INSTANTANEOUS TRIP UNIT (IIT)RANGE INAMPERES24101040-8164080160BURDEN IN VOLT-AMPS ATMINIMUM SETTING4.54.54.56.59.0MAXIMUM SETTING323240701447
41-101UType CO Overcurrent RelaySub 1619584Figure 7: Typical Time Curves of the Type CO-2 Relay8
Type CO Overcurrent Relay41-101USub 2418245Figure 8: Typical Time Curves of the Type CO-5 Relay9
41-101UType CO Overcurrent RelaySub 2418246Figure 9: Typical Time Curves of the Type CO-6 Relay10
Type CO Overcurrent Relay41-101U*Sub 2418247Figure 10: Typical Time Curves of the Type CO-7 Relay*Denotes Change11
41-101UType CO Overcurrent RelaySub 2418248Figure 11: Typical Time Curves of the Type CO-8 Relay12
Type CO Overcurrent Relay41-101USub 2418249Figure 12: Typical Time Curves of the Type CO-9 Relay.13
41-101UType CO Overcurrent RelaySub 2288B655Figure 13: Typical Time Curves of the Type CO-11 Relay.14
Type CO Overcurrent Relay41-101USub 757D4525Sub 357D4524Figure 14: Internal Schematic of the Double Trip CircuitClosing Relay. For the Single Trip Relay theCircuits Associated with Terminal 2 are Omitted.Figure 15: Internal Schematic of the Single Trip CircuitClosing Relay with Indicating InstantaneousTrip Unit.A core screw accessible from the top of the switchprovides the adjustable pickup range.The indicating instantaneous trip contacts will close30 amperes at 250 volts dc, and will carry this current long enough to trip a breaker.3.0 CHARACTERISTICSThe relays are generally available in the followingcurrent ranges.Range† .1 - .5Taps0.10.12 0.16 0.20.30.40.5.5 - 2.50.50.60.81.01.52.02.52.0 - 6.02.02.53.03.54.05.06.04.0 - 12.0 4.05.06.07.08.0 10.0 12.0† Available for Type CO-11 Relay Only.The indicating contactor switch has two taps thatprovide a pickup setting of 0.2 to 2 amperes. Tochange taps requires connecting the lead located infront of the tap block to the desired setting by meansof a screw connection.3.2TRIP CIRCUIT CONSTANTSContactor Switch 0.2 ampere tap 6.5 ohms dc resistance2.0 ampere tap 0.15 ohms dc resistanceThese relays may have either single or double circuitclosing contacts for tripping either one or two circuitbreakers.4.0 SETTINGSThe time vs. current characteristics are shown in Figures 7 to 13. These characteristics give the contactclosing time for the various time dial settings whenthe indicted multiples of tap value current are appliedto the relay.Since the tap block screw on both the CO unitand IIT unit carries operating current, be surethat the screws are turned tight.3.1TRIP CIRCUITThe main contacts will close 30 amperes at 250 voltsdc and the seal-in contacts of the indicating contactor switch will carry this current long enough to trip acircuit breaker.!CAUTIONIn order to avoid opening current transformercircuits when changing taps under load, the relay must be first removed from the case. Chassisoperating shorting switches on the case will short thesecondary of the current transformer. The tapsshould then be changed with the relay outside of thecase and then re-inserted into the case.15
41-101U4.1Type CO Overcurrent RelayCO UNITThe overcurrent unit settings can be defined eitherby tap setting and time dial position or by tap settingand a specific time of operation at some multiple ofthe current tap setting (e.g., 4 tap setting, 2 time dialposition or 4 tap setting. 0.6 seconds at 6 times tapvalue current).To provide selective circuit breaker operation, a minimum coordinating time of 0.3 seconds plus circuitbreaker time is recommended between the relay being set and the relays with which coordination is tobe effected.The screw on the terminal plate above the time dialmakes connections to various turns on the operatingcoil. By placing this screw in the various terminalplate holes, the relay will respond to multiples of tapvalue currents in accordance with the various typicaltime-current curves.4.2INSTANTANEOUS RECLOSINGThe factory adjustment of the CO unit contacts provides a contact follow. Where circuit breaker reclosing will be initiated immediately after a trip by the COcontact, the time of the opening of the contactsshould be a minimum. This condition is obtained byloosening the stationary contact mounting screw, removing the contact plate and then replacing the platewith the bent end resting against the contact spring.For double trip relays, the upper stationary contact isadjusted such that the contact spring rests solidlyagainst the back stop. The lower stationary contact isthen adjusted such that both stationary contactsmake contact simultaneously with their respectivemoving contact.4.3INDICATING CONTACT SWITCH (ICS)The only setting required on the ICS unit is the selection of the 0.2 or 2.0 ampere setting. This selection ismade by connecting the lead located in front of the tapblock to the desired setting by means of the connecting screw.4.4INDICATING INSTANTANEOUS TRIP ( IIT)The IIT setting is the level of ac current at which it willpickup. It should be set to coordinate with other devices so it will never operate for a fault in protectivezone where tripping should be produced by other devices. The transient reach will not exceed 130% for an80 circuit angle or 108% for a 60 circuit.The proper tap must be selected and the core screwmust be adjusted to the value of pick-up current desired.5.0 INSTALLATION*Sub 5182A754Figure 16: Internal Schematic of the Single Trip CircuitClosing Relay with Indicating InstantaneousTrip Unit.16The relays should be mounted on switchboard panelsor their equivalent in a location free from dirt,moisture, excessive vibration and heat. Mount the relay vertically by means of the rear mounting stud orstuds for the type FT projection case or by means ofthe four mounting holes on the flange for thesemi-flush type FT case. Either the stud or the mounting screws may be utilized for grounding the relay. External toothed washers are provided for use in the locations shown on the outline and drilling plan tofacilitate making a good electrical connection between the relay case, its mounting screws or studs,and the relay panel. Ground wires should be affixed tothe mounting screws or studs as required for poorlygrounded or insulating panels. Other electrical connections may be made directly to the terminals bymeans of screws for steel panel mounting or to theterminal stud furnished with the relay for thick panelmounting. The terminal stud may be easily removedor inserted by locking two nuts on the stud and thenturning the proper nut with a wrench.
Type CO Overcurrent TACTORSWITCHICSICSINDUCTION UNITCOCOCOCOCOINDUCTION UNITICSINDUCTION UNITLAG COILICSINDUCTION UNITLAG COILIITINDICATINGINSTANTANEOUSUNITRED HANDLEIITRED HANDLETEST SWITCHTEST SWITCHCURRENTTEST JACK13254769810FRONT VIEWCHASSISOPERATEDSHORTINGSWITCHTERMINALEXTERNAL CONTACTS MUSTCLOSE FOR RELAY TO TRIP*Sub 557D4528Figure 17: Internal Schematic of the Double Trip CircuitClosing Relay with Torque Control Terminals.For the Single Trip Relay, the Circuits Associated with Terminal 2 are Omitted.For detail information on the FT case refer to Instruction Leaflet 41-076.6.0 ADJUSTMENTS ANDMAINTENANCEProper adjustments for correct operation of this relayhave been made at the factory. Upon receipt of therelay no customer adjustments, other than thosecovered under Section 4 "Settings" should be required.For relays which include an indicating instantaneoustrip unit (IIT), the junction of the induction and indicating instantaneous trip coils is brought out toswitch jaw #3. With this arrangement the overcurrentunits can be tested separately.6.1PERFORMANCE CHECKThe following check is recommended to verify thatthe relay is in the proper working order:6.1.1 Contacta. By turning the time dial, move the moving contacts until they deflect the stationary contact to aposition where the stationary contact is restingagainst its backstop. The index mark located onCURRENTTEST JACK13254769810CHASSISOPERATEDSHORTINGSWITCHFRONT VIEWTERMINALEXTERNAL CONTACTS MUSTCLOSE FOR RELAY TO TRIP*Sub 757D4529Figure 18: Internal Schematic of the Single Trip CircuitClosinF:g Relay with Torque Control Terminals and Indicating Instantaneous Trip Unit.the movement frame should coincide with the “O”mark on the time dial. For double trip relays, thefollow on the stationary contacts should be approximately 1/64”.a. For relays identified with a “T”, located at lowerleft of stationary contact block, the index mark onthe movement frame will coincide with the “O”mark on the time dial when the stationary contacthas moved through approximately one-half of itsnormal deflection. Therefore, with the stationarycontact resting against the backstop, the indexmark is offset to the right of the “O” mark by approximately .020". The placement of the varioustime dial positions in line with the index mark willgive operating times as shown on the respectivetime-current curves. For double trip relays, the follow on the stationary contacts should beapproximately 1/32”.6.1.2 Minimum Trip CurrentSet the time dial to position 6 using the lowest tapsetting, alternately apply tap value current plus 3%and tap value current minus 3%. The moving contactshould leave the backstop at ta
CO-8 Inverse 2) Backup protection for relays on other circuits. CO-9 Very Inverse CO-11 Extremely Inverse 1) Motor protection where allowable locked rotor time is less than 10 seconds. 2) Overcurrent protection where coordination with fuses and reclosers is involved, or where cold load pickup or transformer inrush are factors. Printed in U.S.A.
21 Phase Distance 51V Voltage Controlled/Restrained Overcurrent 24 Volts per Hertz 32 Reverse Power 40 Loss of Field 46 Negative Sequence Overcurrent 50/51 Instantaneous/Time Delayed Overcurrent 50/51GN Instantaneous/Time Delayed Overcurrent in Gen Neutral 51TN Time Overcurrent Relay in GSU Neutral 59 Overvoltage 59GN Ground Overvoltage
Nissan Micra - OWM 4734 Nissan Micra - OWM 4734 CPU E6 H33750 1 Battery 2 Ignition switch 3 Fusible link holder 4 Fuse box 5 Fuse and relay box a) accessory relay b) blower motor relay 6 Intelligent power distribution module a) starter relay b) cooling fan hi relay c) cooling fan lo relay d) fuel pump relay e) ignition relay f) ECM relay
Type KRQ Directional Overcurrent Negataive Sequence Relay 41-164H 5 4.0 SETTINGS 4.1 OVERCURRENT UNIT (I) The only setting required is the pickup current setting which is made by means of the connector screw located on the tap plate. By placing the connector screw in the desired tap, the relay will just close its contacts at the tap value current.
Directional Relay Coordination Coordination of directional overcurrent relays involves setting of relays one by one so that at each stage the relay coordinates with its primary relay. In a loop, the last relay to be set is the very first, in which initial setting were assumed. Relay coordination activity in a mesh system is iterative.
50 Instantaneous overcurrent relay 67 Directional overcurrent relay 21 Distance relay 87 Differential relay 52 Circuit breaker Protective Relaying System 52 Relay DC Supply Communications Channel DC Supply Circuit Breaker Current Transformers (CTs) Voltage Transformers (VTs) 14 Protective Relays Monitor Detect Report
Three-phase Directional Overcurrent (67) Each one of the three-phase overcurrent stages of the P127 can be independently configured as directional protection with specific relay characteristic angle (RCA) settings and boundaries. Each directional stage has instantaneous (start) forward/reverse outputs available. Directional Overcurrent Tripping .
38 - Check voltage output to fuel pump @ relay set 39 - Check voltage input to relay set from ignition switch 40 - Check voltage input to fuel pump relay of relay set 41 - Check input voltage to control relay of relay set 42 - Check input voltage to control relay of relay set (continued)
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