 |
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
|
| If you can't view the Datasheet, Please click here to try to view without PDF Reader . |
|
|
| Datasheet File OCR Text: |
| csm_k2cm_ds_e_4_1 1 motor protective relay k2cm solid-state relay enables choice of three operating functions (overcurrent, open- phase, and reverse-phase) ? protects 3-phase induction motors and their loads from dam- age. ? selection and combination of operating functions from overcur- rent, open-phase, and reverse-phase. ? circuit and output relay operation can be checked by just oper- ating the test button. ? the set time value can be checked easily because operation time is indicated from the start of operation. ? space-saving, integrated construction. note: if the k2cm is used with an invert er, the operating conditions will depend on the load wiring length, inverter carrier frequency, basic frequency, and load conditions. erro r will occur in the operating values of the overload elements. it is recommended to test operation before using the k2cm. model number structure model number legend 1. model k2cm: motor relay 2. mounting style none: surface-mounting, integrated type 3. operating time characteristics none: inverse type q: instantaneous type 4. supply voltage of control circuit 1: 100/110/120 vac 2: 200/220/240 vac 4: 400/440 vac 5. current setting range ls: 2 to 8 a l: 8 to 26 a m: 20 to 65 a h: 50 to 160 a 6. operating time none: 1 (2 to 10 s)/ 4 (8 to 40 s) switchable 7. resetting method none: manual reset a: automatic reset 8. reverse-phase detection type none: current reverse-phase detection v: voltage reverse-phase detection ordering information list of models voltage reverse-phase detection models 12 3 4 5 6 k2cm- @@@ - @@ time specification inverse type instantaneous type resetting method current setting range 8 to 26 a 20 to 65 a 50 to 160 a 8 to 26 a 20 to 65 a 50 to 160 a operating voltage manual 200/220/240 vac k2cm-2lv k2cm-2mv K2CM-2Hv k2cm-q2lv k2cm-q2mv k2cm-q2hv automatic 200/220/240 vac k2cm-2lav k2cm-2mav K2CM-2Hav k2cm-q2lav k2cm-q2mav k2cm-q2hav
k2cm 2 current reverse-phase detection models note: the manual resetting method must be used with reverse-phase detection. related product transformer note: use this transformer when a voltage revers e-phase detection model is used on a 400-v line. specifications ratings other features, such as 100% ov ercurrent capacity and flush mount ing are also available. see model number legend on page 1 for details. note: the start-up lock timer restarts when the operating value at starting becomes less than 30% of the set current value. time specification inverse type instantaneous type resetting method current setting range 2 to 8 a 8 to 26 a 20 to 65 a 50 to 160 a 2 to 8 a 8 to 26 a 20 to 65 a 50 to 160 a operating voltage manual 100/110/120 vac k2cm-1ls k2cm-1l k2cm-1m k2cm-1h k2c m-q1ls k2cm-q1l k2cm-q1m k2cm-q1h 200/220/240 vac k2cm-2ls k2cm-2l k2cm-2m K2CM-2H k2c m-q2ls k2cm-q2l k2cm-q2m k2cm-q2h 400/440 vac --- k2cm-4l k2cm-4m k2cm-4h --- k2cm-q4l k2cm-q4m k2cm-q4h automatic (see note.) 100/110/120 vac k2cm-1lsa k2cm-1la k2cm-1ma k2cm-1ha k2cm-q1lsa k2cm-q1la k2cm-q1ma k2cm-q1ha 200/220/240 vac k2cm-2lsa k2cm-2la k2cm-2ma K2CM-2Ha k2cm-q2lsa k2cm-q2la k2cm-q2ma k2cm-q2ha 400/440 vac --- k2cm-4la k2cm-4ma k2cm-4ha --- k2cm-q4la k2cm-q4ma k2cm-q4ha model voltage specification secondary power consumption se-pt400 primary side 380 to 480 v (wide power supply range) 7va secondary side 190 to 240 v (wide power supply range) supply voltage of motor circuit 200/220, 400/440 vac, 50/60 hz supply voltage of control circuit 100/110/120, 200/220/240, 400/440 vac, 50/60 hz insulation breakdown of output contact 500 vac operating voltage/curren t of output contact (pf = 0.4 when breaking contact) no contact: 120 vac/2 a, 240 vac/1 a, 440 vac/0.5 a, 110 vdc/0.2 a, 220 vdc/0.1 a nc contact: 120 vac/5 a, 240 vac/2 a, 440 vac/1 a, 110 vdc/0.2 a, 220 vdc/0.1 a contact form of output contact current reverse-phase detection models: spst-no + spst-nc voltage reverse-phase detection models: spdt operating current range of input circuit 2 to 160 a (number of passes: 1) operating voltage range of control circuit 85% to 110% of rated voltage, but operates normally at 50% of open-phase supply voltage operating frequency range of control circuit 95% to 105% of rated frequency power consumption approx. 3 va (in standby state); 5 va (in operating state) overcurrent function operating value 115 10% of the setting value overcurrent function operating time setting range inverse type inverse time both at startup and during operation: timer scale 1 (s) at 600% overload timer scale 3 (s) at 200% overload note: the above values are for a time factor setting of 1. instantaneous type fixed time at starting (start-up lock) ? time setting value (varies between 2 and 40 s) at 140% overload and starting instantaneous during operation: 0.5 s max. (when cu rrent is increased from 100 to 140% of the set current value) case color munsell 5y7/1 overcurrent function operating time characteristics inverse type: 10% of maximum setting value (at 600% overload) instantaneous type: 20% of maximum setting value (at 140% overcurrent and at starting) overcurrent function resetting value 100% min. of the setting value overcurrent function start-up operating value inverse type: not applicable instantaneous type: 30% max. of the setting value (see note.) open-phase operating value 85% max. of the set current value (at open-phase) open-phase operating time 2 s max. (at overcurrent operating value) reverse-phase operating value 50% max. of the current value (80% max. of the operating voltage) reverse-phase operating time 1 s max. (at overcurrent operating value) imbalance operating value 85% of the set current value current imbalance factor high: 35 10%; low: 60% min. (at overcurrent operating value) w here im b alance factor = re v erse phase portion n ormal phase portion 100 ( % ) k2cm 3 characteristics note: this means that no malfunction occurs with the open-phase elem ent, but the operating value of the overload element may vary. variation due to temperature fluctuation at 20 20 c overcurrent: 5% of operating value, 10% of operating time open-phase: 10% of operating value, 10% of operating time reverse-phase: 10% of operating value, 10% of operating time at 20 30 c overcurrent: 10% of operating value, 20% of operating time open-phase: 20% of operating value, 20% of operating time reverse-phase: 20% of operating value, 20% of operating time variation due to voltage fluctuation at 85% to 110% of rated voltage overcurrent: 5% of operating value, 10% of operating time open-phase: 5% of operating value, 10% of operating time reverse-phase: 5% of operating value, 10% of operating time variation due to frequency fluctuation at 95% to 105% of rated frequency insulation resistance 10 m ? min. (between current-carrying terminals and mounting panel) 5 m ? min. (between current-carrying terminals and between contact poles) dielectric strength 2,500 vac (between current-carrying terminals and mounting panel and between current-carrying terminals) 1,000 vac (between contact poles) permissible impulse voltage current reverse-phase detection models: 6,000 v (between current-carrying terminals and mounting panel) 4,500 v (between current-carrying terminal s and between control power supply terminals) waveform: 1.2/50 s voltage reverse-phase detection models: 4,500 v (between current-carrying terminals and mounting panel) waveform: 1.2/50 s overcurrent strength of main circuit no abnormality develops when 20 times the set curr ent value is applied for 2 s, 2 times with a 1- minute interval. overvoltage strength of control power supply circuit no abnormality develops when 1.15 times the rela y?s rated voltage is applied once for 3 hours. variation due to waveform distortion no malfunction occurs when pulse containing 100 % of the 2nd to 9th harmonics is applied (open- phase switch set to ?low?). (see note.) vibration malfunction: 10 to 55 hz, 0.3-mm double amplitude (in x, y, and z directions for 10 minutes each) destruction: 10 to 25 hz, 2-mm double amplitude (in x, y, and z directions for 2 hours each) shock malfunction: 98 m/s 2 (approx. 10 g) in x, y, and z directions destruction: 294 m/s 2 (approx. 30 g) in x, y, and z directions test current (reference only) operating time set time value setting characteristics of operating time approx. 30% of the maximum setting value service life electrical: 10,000 operations ambient temperature operating: ? 10 to 60 c (with no icing) storage: ? 25 to 65 c humidity 35% to 85% altitude 2,000 m max. k2cm 4 connections voltage reverse-phase detection models terminal arrangement perform the external connections by referring to the examples given below. obtain the control power supply from the same phase as the power supply to the magnet contactor coil. connect the phase advancing capacitors cl oser to the power supply than the current transformer, as shown in the examples. tighten the terminal screws to a torque of 0.98 nm max. (the appropriate tightening torque is 0.49 to 0.67 nm.) use of insulated solderless terminals is recommended for connection to the relay terminals (m3.5). note: 1. in principle, the k2cm must be surface mounted with the terminal block facing downward. 2. use m5 screws with spring washers and flat washers for mounting. tighten the screws to a torque of 1.77 nm max. (the appropriate tightening torque is 1.08 to 1.57 nm.) manual operation low-voltage circuit manual operating low-voltage circuit ( start) manual operation low-voltage circuit (high- capacity motor) automatic operation low-voltage circuit manual operation high-voltage circuit note: connect the phase advancing c apacitor on the power supply side of the motor protective relay as shown in the above dia- grams. ta tc tb u v w output contacts (spdt) control power supply 200 vac 50/60hz rst stop start phase advancing capacitor alarm buzzer bz magnet contactor r u a 1 s v b 2 t w c 3 ta tc tb u v w motor protective relay motor m rst bz r u a 1 s v b 2 t w c 3 ta tc tb u v w m changeover 200 vac 50/60hz stop start phase advancing capacitor alarm buzzer magnet contactor motor protective relay rst current converter for measuring device @ /5a bz r u a 1 s v b 2 t w c 3 ta t c t b u v w motor m 200 vac 50/60hz stop start phase advancing capacitor alarm buzzer magnet contactor motor protective relay rst automatic contact bz r u a 1 s v b 2 t w c 3 ta tc tb u v w m motor 200 vac 50/60hz phase advancing capacitor alarm buzzer magnet contactor motor protective relay 3, 300 vac 50/60hz rst x/a auxiliary relay bz r u a 1 s v b 2 t w c 3 ta tc tb u v w high-voltage motor m x transformer @ /200v high-tension fuse current converter for measuring device @ /5a stop start phase advancing capacitor alarm buzzer high-voltage magnet contactor motor protective relay k2cm 5 current reverse-phase detection models terminal arrangement perform the external connections by referring to the examples given below. connect the phase advancing capacitors closer to the power supply than the current transformer as shown in the examples. tighten the terminal screws to a torque of 0.98 nm max. (the appropriate tightening torque is 0.49 to 0.67 nm.) use of insulated solderless terminals is recommended for connection to the relay terminals (m3.5). note: 1. in principle, the k2cm must be surface mounted with the terminal block facing downward. 2. use m5 screws with spring washers and flat washers for mounting. tighten the screws to a torque of 1.77 nm max. (the appropriate tightening torque is 1.08 to 1.57 nm.) manual operation low-voltage circuit manual operating low-voltage circuit ( start) note: connect the phase advancing capacitor on the power supply side of the motor protective relay as shown in the above diagrams. manual operation low-voltage circuit (high- capacity motor) automatic operation low-voltage circuit manual operation high-voltage circuit s 1 c 2 b 2 a 1 c 1 s 2 output contacts (no and nc) control power supply rst bz r u a 1 s v b 2 t w c 3 a 1 c 1 b 2 c 2 s 1 s 2 m 200 vac 50/60hz stop start phase advancing capacitor alarm buzzer magnet contactor motor protective relay motor rst bz r u a 1 s v b 2 t w c 3 a 1 c 1 b 2 c 2 s 1 s 2 m changeover 200 vac 50/60hz stop start phase advancing capacitor alarm buzzer magnet contactor motor protective relay rst bz r u a 1 s v b 2 t w c 3 a 1 c 1 b 2 c 2 s 1 s 2 m current converter for measuring device @ /5a motor 200 vac 50/60hz stop start phase advancing capacitor alarm buzzer magnet contactor motor protective relay rst bz r u a 1 s v b 2 t w c 3 m a 1 c 1 b 2 c 2 s 1 s 2 automatic contact motor 200 vac 50/60hz phase advancing capacitor alarm buzzer magnet contactor motor protective relay rst x/a bz r u a 1 s v b 2 t w c 3 m transformer @ /100v a 1 c 1 b 2 c 2 s 1 s 2 x 3,300 vac 50/60hz auxiliary relay high-voltage motor high-tension fuse current converter for measuring device @ /5a stop start phase advancing capacitor alarm buzzer high-voltage magnet contactor motor protective relay k2cm 6 output circuits internal circuit and operation description 1) overcurrent circuit overcurrent detecting circuit this circuit detects when the current reaches the overcurrent operat- ing level (115% of the set current value). time setting circuit (inverse type) this circuit performs time setting us ing the vr (variable resistor) for the operating time setting and obtai ns inverse-type characteristics using an rc time-limiting circuit. the operating time can be set within a range from 2 to 10 s or 8 to 40 s by operating the setting switch using a vr. the vr covers a time range 5 times the standard range. start-up detecting circui t (instantaneous type) instantaneous-type models output a tr ip signal instantaneously when the motor current exceeds the overcurrent operating value (115% of the set current value). at the start of motor operation, a starting cur- rent several times the rated current flows and so to prevent the motor circuit being tripped by the starting current, instantaneous operation is not enabled until a fixed time tc has elapsed, as shown in the fig- ure. instantaneous operation starts after tc has elapsed. motor start- ing time ?to? varies, depending on motor type, within a range from several seconds to several tens of seconds. there are even slight dif- ferences in starting time between the same type of motors and so be sure to set tc so that to to k2cm 7 2) open-phase circuit open-phase level detecting circuit this circuit detects when the current reaches the open-phase operat- ing level (85% max. of the set current value). therefore, open-phase is not detected until the maximum phase of the current exceeds 85% of the set current value. open-phase detecting circuit output of the maximum value detect ing circuit is divided and used as reference values for comparison with the output of the rectifier/ smoothing circuits for the respec tive phases. if a phase has a value lower than the reference value, the k2cm judges it to be open-phase and outputs an open-phase signal. the following imbalance factors can be selected by setting the open- phase switch. ?high? . . operating imbalance factor: 35 10% ?low?. . . operating imbalance factor: 60% min. the imbalance factor can be eas ily obtained from the following graph. in the graph, the horizontal axis indicates the maximum phase of the current whereas the two vert ical axes indicate the remaining two phases. the maximum phase of the current is taken to be 1.0 as a reference point. the imbalance fact or is obtained as a percentage from the curve around the center of the graph. obtain the imbalance factor for a motor current with i r = 100 a, i s = 70 a, and i t = 60 a as follows: 1. on the r axis, locate point a, where i r = 1.0. 2. move from point a to point b, where i s = 0.7 on the s axis. 3. on the t axis, locate point c, where i t = 0.6. 4. follow the curves that pass through points b and c and locate the intersection point d. 5. locating the point corresponding to point d on the imbalance fac- tor curve gives an imbalance factor of 36%. take the maximum phase of current on the horizontal axis without considering axes r, s, and t. generally, in open-phase detecti on, detecting a complete open- phase is sufficient. in such a case, set the open-phase switch to the ?low? position. if using the motor in an imbalanced condition causes problems, or when detecting inte rnal open-phases of a delta-con- nected motor, set the switch to the ?high? position. depending on the motor?s load condition and the imbalance of the power supply, how- ever, special consideration may be r equired for the detection of inter- nal open-phases in delta-connected motors. consult your omron representative before using this me thod. when a transformer is con- nected as a load, the harmonics increase at low loads. therefore, in such a case, set the open-phase switch to the ?low? position. 3) reverse-phase circuit 1. current reverse-phase detection models reverse-phase level detecting circuit this circuit detects whet her the current is in the operating level (50% max. of the set current value) as a precondition to detect the reverse- phase. reverse-phase detecting circuit the current reverse-phase detecting method is employed for detect- ing reverse-phase as shown below. after the motor starts operating, the current phase becomes transient ly unstable during t1 (approx. 0.4 s) and so reverse-phase detection is not performed during this period but it is performed during t2 (approx. 0.1 s). after t2 has elapsed, reverse-phase detection is not performed. for this reason, this method cannot be applied to cases where instantaneous reverse-phase is not permitted. when a reverse-phase is detected, the relay is held in the latched state even after the motor current stops (in both manual and automatic release types). 2. voltage reverse-phase detection models reverse-phase detecting circuit reverse-phase detecting is perform ed by using the voltage reverse- phase detection method. by voltage division within the above rc phase circuit, the output becomes 0 v in the normal state or 1.5 v uv in the reverse-phase state. using the output from this circuit, the reverse-phase level detecting circuit detects when the current reaches the reverse-phase operating level (80% or less of the control power supply). 90.0 95.0 8 0.0 8 5.0 75.0 65.0 70.0 60.0 50.0 55.0 40.0 45.0 35.0 30.0 25.0 20.0 15.0 10.0 5.0 point d 1.6 1.5 1.4 1.3 1.2 1.1 1.0 0.9 t (r, s) 0. 8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 1.6 1.5 1.4 1.3 1.2 1.1 1.0 0.9 0. 8 s (t, r) 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0. 8 0.9 1.0 point b point c point a r (s, t) 1.0 0.5 0.5 1.0 0 s phase t phase open-phase s w itch maxim u m phase of c u rrent: r phase = 1.0 "lo w " "high" a 35 % 60 % 25 % n on-operating area "high" operating area "lo w " operating area t 1 n on-detecting area detecting area t 2 motor start u v w re v erse-phase o u tp u t re v erse-phase le v el detecting circ u it or phase circ u it k2cm 8 nomenclature 10 (side) 9 6 7 8 r s t r s t 1 pass 2 passes current-setting knob by operating the setting knob, set the current value to be equal to the rated current of the motor to be used. the current-setting knob uses the same scale as the rated current. therefore, the operating value will be 115% of the set current value. example: operating current value = 12 1.15 (115%) = 13.8 a the list of current settings shows an example. the rated current differs depending on the motor?s type, construction, manufacturer, etc. therefore, set the operating current after chec king the specifications of the motor. trip indicator in normal operation, only the upper half of the display window is colored orange, whereas when the motor circuit has tripped, the entire display window becomes orange. time-setting knob* reset button with manual resetting models, when the motor circuit trips during normal operation or test operati on, the operation indicators and the output relay can be immediately reset by pressing the reset button. when the motor circuit trips due to reverse-phase with automatic resetting models, the operation indicators and the output relay can be immediately reset by pressing the reset button. reset button operation is ineffective when the operation power supply is off. when the motor circuit trips during normal opera- tion, identify the abnormal input f unction by checking the led indi- cators, then turn off the power switch of the main circuit and proceed with troubleshooting. after the abnormality is removed, turn on the power switch of the main circuit to reset the k2cm. test button inverse type operation checks of the overcurrent function can be performed. pressing the test button for the time -setting value will cause the motor circuit to trip. with manual resetting models, even if the test button is released after the motor circuit has tripped, the circuit remains tripped, whereas with automatic resetting models, the motor circuit continues operating and the output relay releases. be sure to perform the test operation with the overcurrent switch set to on. set both the open-phase and reverse-phase switches to off. if one of these switches is set to on , the motor circuit may trip if an open-phase or reverse-phase occu rs before an overcurrent does. instantaneous type perform the test operation with input current at 0 and the overcurrent switch set to on. pressing the test button for the set start-up lock time will cause the motor circuit to trip. with manual resetting models, even if the test button is released after the motor circuit has tripped, the circuit remains tripped, whereas with automatic resetting models, the motor circuit continues operating and the output relay releases. deciding the number of primary conductor passes when using a motor with a small current rating, decide the num- ber of primary conduc tor passes through the current transformer holes and the tap setting by referring to the list of current set- tings. pass all the three wires through the respective holes of the current transformer. basically, the wi res should be passed through the specified holes. if this is difficu lt, however, they can be passed through any holes provided that the phase order is r, s, and t. if the wires are passed through the holes only once, a current within the full scale of the current-setting knob can be set. if they are passed more than once, however, the current setting range will change according to the number of passes. the current setting range when the number of conductor passes is n can be obtained by dividing the full scale of the cu rrent-setting knob by n. for exam- ple, the current setting range of the k2cm- @@ l @ is 8 to 26 a when the wires are passed only once. this range is 4 to 13 a when the wires are passed twice, 2 to 6.5 a when the wires are passed four times, and 1 to 3.25 a when the wires are passed eight times. the wires can be passed through the holes any number of times. it is convenient for the calculation, however, if the number of passes is 2, 4, or 8. the signal from a high-voltage moto r is input to the motor protec- tive relay via an external current transformer. in this case, the cur- rent can be set in the same manner as above by dividing the rated current of the high-voltage motor by the transformation ratio of the current transformer. time-setting knob set the required operating time by operating the time-setting knob. (with instantaneous-type models, the set operating time is used as the start-up lock time). note: 1. the setting scale is the op- erating time when 600% of the current value is input. 2. the required operating time varies depending on the type of motor, load con- dition, etc. you can take the time from when the motor starts to when the motor enters the steady state as a guide for setting this val- ue. when setting the oper- ating time for submersible motors, which require very short operating times, con- sult the manufacturer to obtain the correct operat- ing time. an operating time shorter than 5 s can be used as a rough guide. the scale multiplying factor can be selected by the time scale multiplying factor switch. scale multiplying factor time scale multiplying factor switch time scale value 1 (s) 4 (s) 228 3312 4416 5520 6624 7728 8832 9936 10 10 40 k2cm 9 led indicators when the motor circuit trips due to overcurrent, open-phase, or reverse-phase, the respective le d indicator lights (continuously). the overcurrent indicator also indicates the start of operation. with the inverse-type models, when the motor current exceeds the overcurrent operating value, the overcurrent indicator blinks at the bright level and then remains lit at the dimmed level. after the oper- ating time has elapsed, with the manual resetting models, the motor circuit trips and the overcurrent indicator remains lit at the bright level, whereas with automat ic resetting models, the indicator remains lit at the bright level until the motor current descends below the resetting value. since the indicator status is not stored in memory when the opera- tion power supply is turned off, be sure to check which indicators were illuminated when the motor circuit was tripped. the functions of the k2cm can be used in the following seven combi- nations. for each function, turn on the corresponding setting switch. when the setting switches for overcurrent, open-phase, or reverse- phase function are turned off, t he following functions becomes invalid. 1. overcurrent setting switches these switches select the overcurrent setting and the multiplying fac- tor linked with operating time setting. 2. open-phase setting switches these switches select the open-phase detecting function and the ?high? or ?low? current imbalance factor for operation. 3. reverse-phase setting switches these switches select the reve rse-phase detection function and reverse-phase polarity. by sele cting the reverse-phase polarity accordingly, the k2cm can operate normally without changing the connections when wired with the order of the phases reversed. if the k2cm detects reverse-phase although the motor is rotating in the forward direction (e.g., because of incorrect wiring of power lines), set the reverse-phase polarity switch to the ?reverse? position to enable normal operation. note: the k2cm detects reverse-phase at a point before the current transformer. if a reverse connecti on is made at the load side far from the current transformer and the motor rotates in the re- verse direction, the k2cm does not detect the reverse-phase. reverse-detectable range * the reverse-phase polarity switching function is applicable to cur- rent reverse-phase detection models only. function overcurrent open-phase reverse-phase combination 1on 2on 3on 4onon 5onon 6on on 7 ononon function setting switch set to off invalid function overcurrent time setting and multiplication open-phase ?high? and ?low? imbalance factors reverse-phase ?forward? and ?reverse? function overcurrent detecting function on enabled off disabled time setting multiplying factor 4 (s) time setting scale value 4 = 8 to 40 s 1 (s) time setting scale value 1 = 2 to 10 s open-phase detecting function on enabled off disabled imbalance factor high the motor circuit operates at an operating imbalance factor of 35 10%. low the motor circuit operates at an operating imbalance factor of 60%. start trip bright bright dimmed overcurrent operating value (115% of current-setting value) motor current reverse-phase detecting function on enabled off disabled reverse-phase polarity normal the motor circuit trips at reverse- phase when a reverse-phase is detected. reverse used when a reverse-phase connection is made in the power line of the motor at a point before the current transformer (including external current transformer). phase condition normal reverse reverse connections reverse-phase polarity switch position normal normal normal trip none yes none direction of motor rotation forward reverse (see below.) reverse coun- ter- mea- sure reverse- phase polarity switch position reverse reverse reverse reverse wiring wiring changed at (a). wiring changed at (b). wiring changed at (c). wiring changed at (d). direction of motor rotation forward rs m t motor relay rst rs m t motor relay rst (a) (b) rs m t motor relay rst (c) (d) rs m t rst detectable: reverse-phase state can be detected with the motor protective relay only on the power supply side. undetectable: reverse-phase state on the motor side cannot be detected with the motor protective relay. k2cm 10 engineering data 2 4 6 8 10 time scale 70 60 50 40 30 20 10 0 100 200 300 400 500 600 700 280 240 200 160 120 80 40 0 time scale multiplying factor ( 4) ( 1) motor current (percentage of current-setting value) operating time (s) 0.2 0.1 0 100 200 300 400 500 600 700 operating time (s) motor current (percentage of current-setting value) this graph shows the behavior when the current changes from 100% of the current- setting value to the percentage shown on the horizontal axis. overload operating time characteristics for inverse type overload operating time characteristics for instantaneous type 2.0 1.0 0 100 200 300 400 500 600 700 this graph shows the behavior when the current changes from 100% of the current-setting value to the percentage shown on the horizontal axis. operating time (s) motor current (percentage of current-setting value) 0.6 0.5 0.4 0.3 0.2 0.1 0 100 200 300 400 500 600 700 this graph shows the behavior when the current changes from 100% of the current-setting value to the percentage shown on the horizontal axis. operating time (s) motor current (percentage of current-setting value) typical characteristics of open-phase operation typical characteristics of reverse-phase operation k2cm 11 dimensions note: all units are in millimeter s unless otherwise indicated. surface-mounting models operating procedures operation, setting, and indication based on the current value of the motor to be used, perform t he setting of each item of the k2cm motor protective relay. list of current settings (w hen using a 200-vac motor) * the squares ( @ ) represent the symbols defined under model number legend . ** the rated current is the current at full load. *** supply: low-voltage 3-phase basket type induc tive motor, full-load characteristic s of 200 vac, 4-pole, totally-enclosed. note: when using a large-capacity or hi gh-voltage motor whose capacity is 45 kw or more, calculate the rated current/alternating curr ent ratio by converting with the alternating current ratio of the external current transformer. type* k2cm- @@ ls @ k2cm- @@ l @ k2cm- @@ m @ k2cm- @@ h @ number of passes 11248 1 1 setting time scale value 2 to 8 8 to 26 20 to 65 50 to 160 current setting range (a) 2 to 8 8 to 26 4 to 13 2 to 6.5 1 to 3.25 20 to 65 50 to 160 motor*** rated output (kw) rated current (a)** 0.2 1.8 0.4 2.8 0.75 4.2 1.5 7.3 2.2 10 3.7 16.1 5.5 24 7.5 32 11 45 15 61 18.5 74 22 87 30 117 37 143.0 126 80 6 60 46.5 120 11 33 55 52 11.5 4 48.5 15 six, m3 terminal screws 33.5 33.5 36 three, 20-dia. holes 80 0.5 52 0.5 four, 6-dia. mounting holes or four, m5 mounting-screw holes k2cm 12 testing method current reverse-phase detection models the operating characteristics listed in the table below are tested using the circuit shown on the right. decide the number of conductor passes through the holes of the current trans- former in accordance with the operating current range of the motor protective relay and by referring to the current setting method described under operation, setting, and indication . * balance the currents between phases by adjusting variable resistor r1. ** if a current equal to 600% of the set current value cannot be attained by adjusting the voltage regulator, increase the numbe r of conductor passes through the holes of the current transformer. test item test procedure operating value operating time over- current inverse type 1. turn on sw1. 2. turn on sw2 to operate auxiliary relay y. 3. gradually increase the current by adjusting the voltage regulator. with inverse-type models, read the value of the current when the overcurrent led indicator blinks. with instantaneous-type models, read the value when it lights (continuously).* 4. turn off sw1 and sw2. 1. turn on sw1 and sw2. increase the current to 600% of the set current value by adjusting the voltage regulator. turn off sw1 and sw2.** 2. tu r n o n s w 1 . 3. turn on sw2 and read the position (i.e., time) of the pointer of cycle counter cc when cc is stopped by the operation of the k2cm. the read time is the operating time for inverse-type models and the lock time of the instanta- neous-type models. 4. turn off sw1 and sw2. instantaneous type 1. turn on sw1 and sw2. increase the current to 100% of the set current value by adjusting the voltage regulator. turn off sw1 and sw2. 2. turn on sw1 and sw2 again and wait 2 seconds mini- mum. 3. using the voltage regulator, abruptly increase the current to 140% of the set current value. confirm that the k2cm performs instantaneous operation. 4. turn off sw1 and sw2. open-phase 1. open (disconnect) any one of the input phases for the cur- rent transformer. 2. turn on sw1 and sw2. gradually increase the current by adjusting the voltage regulator. 3. confirm that the k2cm operates at a current no greater than 85% of the set current value and that, at this current, the trip indicator is orange and the open-phase led indica- tor lights. 4. turn off sw1 and sw2. 1. open (disconnect) any one of the input phases for the cur- rent transformer. 2. turn on sw1 and sw2. increase the currents of the other two phases to 115% of the set current value by adjusting the voltage regulator. turn off sw1 and sw2 temporarily. 3. turn on sw1 and sw2 again. read the position (i.e., time) of the pointer of cycle counter cc when cc is stopped by the operation of the k2cm. 4. turn off sw1 and sw2. reverse-phase 1. interchange any two phases at a position closer to the power supply than the current transformer. (in the above figure, phases u and v are interchanged as shown by the dotted lines.) 2. turn on sw1 and sw2. decrease the current to 50% of the set current value by adjusting the voltage regulator. then turn off sw1 and sw2 temporarily. 3. turn on sw1 and sw2 again. confirm that the k2cm operates, the trip indicator is orange, and that the reverse- phase led lights. 4. turn off sw1 and sw2. 1. interchange any two phases at a position closer to the power supply than the current transformer. (in the above figure, phases u and v are exchanged as shown by the dotted lines.) 2. turn on sw1 and sw2. increase the current to 100% of the set current value by adjusting the voltage regulator. then turn off sw1 and sw2 temporarily. 3. turn on sw1 and sw2 again. read the position (i.e., time) of the pointer of cycle counter cc when cc is stopped by the operation of the k2cm. 4. turn off sw1 and sw2. r 1 r 1 c 1 s 1 s 2 c 2 b 2 a 1 r 2 y uvw sw 1 sw 2 cc 100 v c k2cm motor protective relay 3 sd: three-phase voltage regulator (5 to 15 a) a: ac ammeter (5 a) v: ac voltmeter (300 v) cc: cycle counter y: auxiliary relay (15 a) r1: variable resistor (50 ? , 400 w + 400 w) r 2 : fixed resistor (50 ? , 400 w + 400 w) sw 1 : knife switch (3-phase) sw 2 : toggle switch 200 v 50/60 hz (3-phase) 100 vac 50/60hz 3 sd minimum set time is 2 s. k2cm 13 voltage reverse-phase detection models the operating characteristics listed in the table below are tested using the circuit shown on the right. decide the number of conductor passes through the holes of the cu rrent transformer in accordance with the operating current range of the motor protective relay and by referring to the current setting method described under operation, setting, and indication . * balance the currents between phases by adjusting variable resistor r1. ** if a current equal to 600% of the set current value cannot be attained by adjusting the voltage regulator, increase the numbe r of conductor passes through the holes of the current transformer. test item test procedure operating value operating time over- current inverse type 1. tu r n o n s w 1 . 2. turn on sw2 to operate auxiliary relay y. 3. gradually increase the current by adjusting the voltage regulator. with inverse-type models, read the value of the current when the overcurrent led indicator blinks. with instantaneous-type models, read the value when it lights (continuously).* 4. turn off sw1 and sw2. 1. turn on sw1 and sw2. increase the current by adjusting the voltage regulator to 600% of the set current value. turn off sw1 and sw2.** 2. turn on sw1. 3. turn on sw2 and read the position (i.e., time) of the pointer of cycle counter cc when cc is stopped by the operation of the k2cm. the read time is the operating time for inverse-type models and the lock time of the instanta- neous-type models. 4. turn off the sw1 and sw2. instantaneous type 1. turn on sw1 and sw2. increase the current to 100% of the set current value by adjusting the voltage regulator. then turn off sw1 and sw2. 2. turn on sw1 and sw2 again and wait 2 seconds mini- mum. 3. using the voltage regulator, abruptly increase the current to 140% of the set current value. confirm that the k2cm performs the instantaneous operation. 4. turn off sw1 and sw2. open-phase 1. open (disconnect) any one of the input phases for the cur- rent transformer. 2. turn on sw1 and sw2. gradually increase the current by adjusting the voltage regulator. 3. confirm that the k2cm operates at a current no greater than 85% of the set current value and that, at this current, the trip indicator is orange and the open-phase led indica- tor lights. 4. turn off sw1 and sw2. 1. open (disconnect) any one of the input phases for the cur- rent transformer. 2. turn on sw1 and sw2. increase the currents of the other two phases to 115% of the set current value by adjusting the voltage regulator. turn off sw1 and sw2 temporarily. 3. turn on sw1 and sw2 again. read the position (i.e., time) of the pointer of cycle counter cc when cc is stopped by the operation of the k2cm. 4. turn off sw1 and sw2. reverse-phase 1. change the phase sequence to reverse-phase by switch- ing the u and w input terminals of the k2cm as shown by the dotted lines. 2. turn on sw1 and sw2 and confirm that the k2cm oper- ates. 3. add a three-phase voltage regulator to the u, v, and w ter- minal inputs. 4. adjust the voltage regulator and confirm that the k2cm operates at less than 80% of the rated supply voltage. 1. put the voltage input in the reverse-phase state. 2. turn on sw1 and sw2 and read the position of the pointer of cycle counter cc when cc is stopped. 3. turn off sw2. r 1 r 1 t a t c t b uvw k2cm motor protective relay r 2 3 sd: three-phase voltage regulator (5 to 15 a) a: ac ammeter (5 a) v: ac voltmeter (300 v) cc: cycle counter y: auxiliary relay (15 a) r1: variable resistor (50 ? , 400 w + 400 w) r 2 : fixed resistor (50 ? , 400 w + 400 w) sw 1 : knife switch (3-phase) sw 2 : toggle switch y uvw 200 v 50/60 hz (3-phase) 100 vac 50/60 hz sw 1 sw 2 cc 3 sd 100 v c minimum set time is 2 s. k2cm 14 safety precautions correct use the operation check using the test button is intended to check the operation of the overcurrent functions. therefore, be sure to turn on the overcurrent switch. also, at this time, turn off the open- phase switch and reverse-phase switch to prevent unnecessary operations from being performed. the operating time of inverse-type models and the lock time of the instantaneous-type models depend upon the set operating time. therefore, do not hold down the test button for more than the set operating time. the reverse-phase can be detected in the wiring up to the current transformer (including an external current transformer). check the wiring between the current transformer and the motor before start- ing the motor. current reverse-phase detection m odels cannot be used in applica- tions that do not allow even momentary reversals of motor direc- tion. jogging of the motor can be performed. for details, consult your omron representative. when using the k2cm to control inching shorter than 0.5 s, the reverse-phase level detection circui t may operate. in this case, be sure to use the k2cm with the reverse-phase switch set to off. the k2cm is basically intended to protect three-phase loads. its overcurrent function, however, can also be applied to single-phase loads. in this case, the conductors can be passed through the holes in any direction and sequence. when applying the k2cm to a circui t with a high imbalance factor due to the nature of the power suppl y or load, actually measure the imbalance factor and select the open-phase sensitivity accordingly (i.e., set the open-phase switch to either the high or low position). the k2cm cannot be used if the imbalance factor is 60% or higher. when applying the k2cm to the pr otection of three-phase trans- formers, give consideration to t he imbalance factor due to single- phase loads. a power supply with a frequency other than commercial frequency cannot be used as the control power supply. use of circuits containing a hi gh percentage of harmonics, such as circuits incorporating scr control circuits, vvvf inverters, or recti- fiers, may cause errors and malfunctions. consult your omron representative for details. when applying the k2cm to the protection of a high-voltage motor or low-voltage, high-capacity motor, use an external rectifier that does not saturate at currents up to 600% of the rated motor current and thus permits a large overcurren t; otherwise, the k2cm will out- put a tripping signal because of imbalanced operation when an overcurrent occurs and, with reverse-type models, the motor may be damaged by burning. never tamper with the trip indicator. use the reset switch to reset the k2cm. when a power failure occurs in the control power supply, the k2cm is not reset even when the reset switch is pressed. this is not an error. the k2cm can be reset only when control power is applied to it. be sure to remount the front cover after detaching it for operating or setting the switches on the front panel. the rectifier and control circuits are combined by tightening the two screws on the right and left sides. never loosen these screws. the variable resistors used to make settings are equipped with mechanisms to stop them rotating outside the valid scale range. do not rotate the variable resistors at a torque of 1 kgcm or more. when using the k2cm- @@@ a (instantaneous, automatic reset- ting), be sure to apply power to the motor protective relay from the same power line as the magnet contactor for switching the motor. be sure to provide the control power supply for the k2cm- @@@@ v (voltage reverse-phase detection) from the same line as the motor. if current reverse-phase detection models are used in a circuit with distorted current waveforms, t he reverse-phase element may per- form an unwanted operation. in such circuits, use of the k2cm- @@@@ v (voltage reverse-phase detection) is recommended because it is not affected at all by current waveform distortion. combination function setting switches led indicators note overcur- rent open- phase reverse- phase overcur- rent open- phase reverse- phase 1 on on if the inputs for combinations of two or more functions are simultaneously generated, the k2cm detects the inputs in the order reverse-phase, open- phase, overcurrent. take combination 4 as an example. if the open-phase and over- current occur at the same time, there is insufficient time to detect the overcurrent becaus e the open-phase is first de- tected and the k2cm outputs the tripping signal (causing the magnet contactor to turn off). therefore, the overcur- rent indicator does not light. 2on on 3onoffon 4onon on 5ononoffon 6on onoff on 7 onononoffoffon k2cm 15 maintenance and inspection the k2cm motor protective relay offers very stable characteristics. to maintain these characteristics for a long time, the following inspections are recommended. daily inspection the purpose of daily inspection is to discover causes of failure before using the motor protective relay. this inspection depends somewhat on the perception of the operator as it includes visual checking, etc. periodic inspection this inspection is performed by tu rning off the power at regular intervals to check the aging caused by long-time operation. it is rec- ommended that periodic inspecti on is performed once a year. motor protective relay external rectifier check for adhesion of dust and foreign objects, damage to wirings by burning, and loosening of mounting screws. what is the va consumption of the ct section? the consumption is 0.4 va/phase max. for any ct section. what action is required if an inverter circuit is used? as shown in the following figure, insert the k2cm and turn off the reverse-phase switch before using the k2cm. always insert the k2cm on the secondary side (load side) of the inverter. error may occur in the operating values depending on the inverter specifications and settings. set the values after performing tests and confirming operation. using a k2mr is recommended to protect the inverter motor. what action is required if single phase is used? the following describes the operating procedure for using a single phase with the k2cm. connection method pass wires through any two of the three holes on the k2cm. if a single phase is used, set the open-phase and reverse- phase switch to off. make the overload settings so that they match the motor current. do not apply control power supply voltage between the v- w terminals if a model with voltage reverse-phase detection is used. classification inspection items connections loosening, damage, and dust collection at screw terminals, damage to wiring insulation sheaths, excessive force applied on wirings, adhesion of foreign objects to terminal screws motor protective relay adhesion of foreign objects and dust to the operation panel, shift of set value, indication status of operation indicators and trip indica- tor, presence/absence of front cover, loos- ening of screws combining rectifier and control circuits, deformation of case, abnor- mal temperature on housing surface external rectifier loosing of te rminals, unusual odor, discolor- ation of surface classification inspection item construction adhesion of dus t and foreign objects to terminals, cracks in insulators around terminal block, burn damage to wirings, damage to setting knobs, selector switches, test button, and reset button, damage to insulators of solderless ter- minals, rust and disc oloration of screw terminals operating characteristics refer to testing method . insulation resistance between terminals and mounting panel operation check with test button checking of operating time, operation indicators, and trip indicator mounting location element inverter power supply inverter load overcurrent ng ok open-phase ng ok reverse-phase ng ng q&a q q m motor k2cm inverter q m motor k2cm in the interest of product improvement, specif ications are subject to change without notice. all dimensions shown are in millimeters. to convert millimeters into inches, multiply by 0.03 937. to convert grams into ounces, multiply by 0.03527. r e a d a n d u n d e r s t a n d t h i s c a t a l o g p l e a s e r e a d a n d u n d e r s t a n d t h i s c a t a l o g b e f o r e p u r c h a s i n g t h e p r o d u c t s . p l e a s e c o n s u l t y o u r o m r o n r e p r e s e n t a t i v e i f y o u h a v e a n y q u e s t i o n s o r c o m m e n t s . w a r r a n t y a n d l i m i t a t i o n s o f l i a b i l i t y w a r r a n t y o m r o n ' s e x c l u s i v e w a r r a n t y i s t h a t t h e p r o d u c t s a r e f r e e f r o m d e f e c t s i n m a t e r i a l s a n d w o r k m a n s h i p f o r a p e r i o d o f o n e y e a r ( o r o t h e r p e r i o d i f s p e c i f i e d ) f r o m d a t e o f s a l e b y o m r o n . o m r o n m a k e s n o w a r r a n t y o r r e p r e s e n t a t i o n , e x p r e s s o r i m p l i e d , r e g a r d i n g n o n - i n f r i n g e m e n t , m e r c h a n t a b i l i t y , o r f i t n e s s f o r p a r t i c u l a r p u r p o s e o f t h e p r o d u c t s . a n y b u y e r o r u s e r a c k n o w l e d g e s t h a t t h e b u y e r o r u s e r a l o n e h a s d e t e r m i n e d t h a t t h e p r o d u c t s w i l l s u i t a b l y m e e t t h e r e q u i r e m e n t s o f t h e i r i n t e n d e d u s e . o m r o n d i s c l a i m s a l l o t h e r w a r r a n t i e s , e x p r e s s o r i m p l i e d . l i m i t a t i o n s o f l i a b i l i t y o m r o n s h a l l n o t b e r e s p o n s i b l e f o r s p e c i a l , i n d i r e c t , o r c o n s e q u e n t i a l d a m a g e s , l o s s o f p r o f i t s o r c o m m e r c i a l l o s s i n a n y w a y c o n n e c t e d w i t h t h e p r o d u c t s , w h e t h e r s u c h c l a i m i s b a s e d o n c o n t r a c t , w a r r a n t y , n e g l i g e n c e , o r s t r i c t l i a b i l i t y . i n n o e v e n t s h a l l t h e r e s p o n s i b i l i t y o f o m r o n f o r a n y a c t e x c e e d t h e i n d i v i d u a l p r i c e o f t h e p r o d u c t o n w h i c h l i a b i l i t y i s a s s e r t e d . i n n o e v e n t s h a l l o m r o n b e r e s p o n s i b l e f o r w a r r a n t y , r e p a i r , o r o t h e r c l a i m s r e g a r d i n g t h e p r o d u c t s u n l e s s o m r o n ' s a n a l y s i s c o n f i r m s t h a t t h e p r o d u c t s w e r e p r o p e r l y h a n d l e d , s t o r e d , i n s t a l l e d , a n d m a i n t a i n e d a n d n o t s u b j e c t t o c o n t a m i n a t i o n , a b u s e , m i s u s e , o r i n a p p r o p r i a t e m o d i f i c a t i o n o r r e p a i r . a p p l i c a t i o n c o n s i d e r a t i o n s s u i t a b i l i t y f o r u s e o m r o n s h a l l n o t b e r e s p o n s i b l e f o r c o n f o r m i t y w i t h a n y s t a n d a r d s , c o d e s , o r r e g u l a t i o n s t h a t a p p l y t o t h e c o m b i n a t i o n o f p r o d u c t s i n t h e c u s t o m e r ' s a p p l i c a t i o n o r u s e o f t h e p r o d u c t s . a t t h e c u s t o m e r ' s r e q u e s t , o m r o n w i l l p r o v i d e a p p l i c a b l e t h i r d p a r t y c e r t i f i c a t i o n d o c u m e n t s i d e n t i f y i n g r a t i n g s a n d l i m i t a t i o n s o f u s e t h a t a p p l y t o t h e p r o d u c t s . t h i s i n f o r m a t i o n b y i t s e l f i s n o t s u f f i c i e n t f o r a c o m p l e t e d e t e r m i n a t i o n o f t h e s u i t a b i l i t y o f t h e p r o d u c t s i n c o m b i n a t i o n w i t h t h e e n d p r o d u c t , machin e , s y s t e m , o r o t h e r a p p l i c a t i o n o r u s e . t h e f o l l o w i n g a r e s o m e e x a m p l e s o f a p p l i c a t i o n s f o r w h i c h p a r t i c u l a r a t t e n t i o n m u s t b e g i v e n . t h i s i s n o t i n t e n d e d t o b e a n e x h a u s t i v e l i s t o f a l l p o s s i b l e u s e s o f t h e p r o d u c t s , n o r i s i t i n t e n d e d t o i m p l y t h a t t h e u s e s l i s t e d m a y b e s u i t a b l e f o r t h e p r o d u c t s : o u t d o o r u s e , u s e s i n v o l v i n g p o t e n t i a l c h e m i c a l c o n t a m i n a t i o n o r e l e c t r i c a l i n t e r f e r e n c e , o r c o n d i t i o n s o r u s e s n o t d e s c r i b e d i n t h i s c a t a l o g . n u c l e a r e n e r g y c o n t r o l s y s t e m s , c o m b u s t i o n s y s t e m s , r a i l r o a d s y s t e m s , a v i a t i o n s y s t e m s , m e d i c a l e q u i p m e n t , a m u s e m e n t m a c h i n e s , v e h i c l e s , s a f e t y e q u i p m e n t , a n d i n s t a l l a t i o n s s u b j e c t t o s e p a r a t e i n d u s t r y o r g o v e r n m e n t r e g u l a t i o n s . s y s t e m s , m a c h i n e s , a n d e q u i p m e n t t h a t c o u l d p r e s e n t a r i s k t o l i f e o r p r o p e r t y . p l e a s e k n o w a n d o b s e r v e a l l p r o h i b i t i o n s o f u s e a p p l i c a b l e t o t h e p r o d u c t s . n e v e r u s e t h e p r o d u c t s f o r a n a p p l i c a t i o n i n v o l v i n g s e r i o u s r i s k t o l i f e o r p r o p e r t y w i t h o u t e n s u r i n g t h a t t h e s y s t e m a s a w h o l e h a s b e e n d e s i g n e d t o a d d r e s s t h e r i s k s , a n d t h a t t h e o m r o n p r o d u c t s a r e p r o p e r l y r a t e d a n d i n s t a l l e d f o r t h e i n t e n d e d u s e w i t h i n t h e o v e r a l l e q u i p m e n t o r s y s t e m . p r o g r a m m a b l e p r o d u c t s o m r o n s h a l l n o t b e r e s p o n s i b l e f o r t h e u s e r ' s p r o g r a m m i n g o f a p r o g r a m m a b l e p r o d u c t , o r a n y c o n s e q u e n c e t h e r e o f . d i s c l a i m e r s c h a n g e i n s p e c i f i c a t i o n s p r o d u c t s p e c i f i c a t i o n s a n d a c c e s s o r i e s m a y b e c h a n g e d a t a n y t i m e b a s e d o n i m p r o v e m e n t s a n d o t h e r r e a s o n s . i t i s o u r p r a c t i c e t o c h a n g e m o d e l n u m b e r s w h e n p u b l i s h e d r a t i n g s o r f e a t u r e s a r e c h a n g e d , o r w h e n s i g n i f i c a n t c o n s t r u c t i o n c h a n g e s a r e m a d e . h o w e v e r , s o m e s p e c i f i c a t i o n s o f t h e p r o d u c t s m a y b e c h a n g e d w i t h o u t a n y n o t i c e . w h e n i n d o u b t , s p e c i a l m o d e l n u m b e r s m a y b e a s s i g n e d t o f i x o r e s t a b l i s h k e y s p e c i f i c a t i o n s f o r y o u r a p p l i c a t i o n o n y o u r r e q u e s t . p l e a s e c o n s u l t w i t h y o u r o m r o n r e p r e s e n t a t i v e a t a n y t i m e t o c o n f i r m a c t u a l s p e c i f i c a t i o n s o f p u r c h a s e d p r o d u c t s . d i m e n s i o n s a n d w e i g h t s d i m e n s i o n s a n d w e i g h t s a r e n o m i n a l a n d a r e n o t t o b e u s e d f o r m a n u f a c t u r i n g p u r p o s e s , e v e n w h e n t o l e r a n c e s a r e s h o w n . p e r f o r m a n c e d a t a perfor m a n c e d a t a g i v e n i n t h i s c a t a l o g i s p r o v i d e d a s a g u i d e f o r t h e u s e r i n d e t e r m i n i n g s u i t a b i l i t y a n d d o e s n o t c o n s t i t u t e a w a r r a n t y . i t m a y r e p r e s e n t t h e r e s u l t o f o m r o n ? s t e s t c o n d i t i o n s , a n d t h e u s e r s m u s t c o r r e l a t e i t t o a c t u a l a p p l i c a t i o n r e q u i r e m e n t s . a c t u a l p e r f o r m a n c e i s s u b j e c t t o t h e o m r o n w a r r a n t y a n d l i m i t a t i o n s o f l i a b i l i t y . e r r o r s a n d o m i s s i o n s t h e i n f o r m a t i o n i n t h i s d o c u m e n t h a s b e e n c a r e f u l l y c h e c k e d a n d i s b e l i e v e d t o b e a c c u r a t e ; h o w e v e r , n o r e s p o n s i b i l i t y i s a s s u m e d f o r c l e r i c a l , t y p o g r a p h i c a l , o r p r o o f r e a d i n g e r r o r s , o r o m i s s i o n s . 2009 . 12 i n t h e i n t e r e s t o f p r o d u c t i m p r o v e m e n t , s p e c i f i c a t i o n s a r e s u b j e c t t o c h a n g e w i t h o u t n o t i c e . o m r o n c o r p o r a t i o n i n d u s t r i a l a u t o m a t i o n c o m p a n y h t t p : / / w w w . i a . o m r o n . c o m / ( c ) c o p y r i g h t o m r o n c o r p o r a t i o n 2 0 0 9 a l l r i g h t r e s e r v e d . |
Price & Availability of K2CM-2H
 |
|
|
|
|
All Rights Reserved © IC-ON-LINE 2003 - 2022 |
| [Add Bookmark] [Contact Us] [Link exchange] [Privacy policy] |
|
Mirror Sites : [www.datasheet.hk]
[www.maxim4u.com] [www.ic-on-line.cn]
[www.ic-on-line.com] [www.ic-on-line.net]
[www.alldatasheet.com.cn]
[www.gdcy.com]
[www.gdcy.net] |