JP2003018739A - Protective relay, and test method and test cable therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a protective relay that allows the manufacturing cost to be reduced, and a test method and test cable therefor. SOLUTION: When testing protective properties, the control equipment side connector 42 of the control cable 7 is disconnected from the control equipment side connector 31 of the protective relay 65 the switch side connector 61 and the control equipment side test connector 62 are connected to the two connectors 42 and 31, respectively. This allows a ground fault property test to be conducted on the switch 3 and the protective relay 6 using installed connectors 21, 31 and the control cable 7. Thus, in contrast to prior art, there is no need to provide in advance a cable lead-out connector on the control cable 7 connecting the switch 3 and the protective relay 6, thereby reducing the manufacturing cost of the protective relay 6.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a protective relay that automatically opens a switch by detecting a short circuit or a ground fault occurring in a distribution line, a test method therefor, and a test cable.

[0002]

2. Description of the Related Art In this type of protective relay, whether or not the switch can be opened within a predetermined time in the event of a short circuit or ground fault, using a protective characteristic tester prepared separately for monthly inspection and annual inspection. It is obligatory to carry out a characteristic test such as the above, and for example, the structure described in JP-A-52-112745 is known. That is, a control cable is connected between the protective relay and the switch, and a wire extraction connector (test connector) is permanently installed in the middle of the control cable.

During normal operation without a protective characteristic test,
The connector for normal operation is connected to the connector for taking out the wiring, whereby the trip circuit on the switch side and the trip circuit on the protective relay side are connected to each other and the closed state is maintained. On the other hand, during the protection characteristic test, the normal operation connector is removed from the wiring extraction connector, and the wiring extraction connector is connected to the test connector on the protection characteristic tester side instead of the normal operation connector. As a result, the protection characteristic test circuit is configured, and the trip circuit on the switch side and the trip circuit on the protective relay side are cut off and held in the open state.

[0004]

However, in the above-mentioned conventional protective relay, it is necessary to previously provide a wiring lead-out connector on the control cable connecting between the switch and the protective relay. Further, it is necessary to prepare a connector for normal operation that is connected to the connector for taking out the wiring during normal operation. Therefore, there is a problem that the manufacturing cost of the protective relay increases.

The present invention has been made to solve the above problems, and an object thereof is to provide a protective relay and a test cable for the protective relay, which can reduce the manufacturing cost.

[0006]

According to a first aspect of the present invention, a detection signal from an abnormality detecting means provided on a distribution line is input through a control cable, and a switch is opened based on the detection result of the signal. In a protective relay equipped with a control device that outputs a trip signal to the trip means via the control cable, disconnect one end of the control cable connection side of the control cable from the control device during the protection characteristic test, and control the control device of the control cable. The gist is that the test cable from the protective characteristic tester is connected to the connector on one end of the connection side and the control device, respectively.

According to a second aspect of the present invention, in the first aspect of the invention, the test cable is provided so as to branch from the protective characteristic tester connection side to the switch connection side and the control device connection side, respectively. What is done is the summary.

According to the third aspect of the present invention, the detection signal from the abnormality detecting means provided on the distribution line is input through the control cable, and the trip means of the switch is based on the detection result of the signal. In a test cable for a protective relay equipped with a control device that outputs a trip signal via a control cable, a switch side test connector connectable to one end of the control cable on the control device connection side, and the control device The gist of the invention is to include a control-device-side test connector that can be connected to the test device and a test-device-side test connector that can be connected to the protection characteristic test device.

According to a fourth aspect of the invention, in the invention according to the third aspect, the switch is provided with a switch-side connector to which a switch-side connector of a control cable is connected.
The control device is provided with a control device side connection connector to which the control device side connector of the control cable is connected, and the switch side connection connector, the control device side connection connector and the switch side test connector are made compatible with each other. The gist is that the switch-side connector, the controller-side connector, and the controller-side test connector are made compatible with each other.

According to a fifth aspect of the present invention, the detection signal from the abnormality detecting means provided in the distribution line is input through the control cable, and the trip means of the switch is based on the detection result of the signal. In a test method for a protective relay equipped with a control device that outputs a trip signal via a control cable, a test from the protective characteristic tester is performed between the control cable and one end of the control cable connected to the control device during the protective characteristic test. The gist is that the connector is connected via a cable for use. (Operation) In the invention described in claim 1, one end of the control cable on the control device side is disconnected from the control device during the protection characteristic test. Then, the test cable from the protective characteristic tester is connected to the control device side end of the control cable and the control device, respectively.

According to the invention described in claim 2, in addition to the function of the invention described in claim 1, at the time of the protection characteristic test, one end of the control cable on the control device connection side and the control device are connected to the protection characteristic tester. The test cables are connected so as to branch off.

According to the third aspect of the invention, the switch side test connector is connected to one end of the control cable on the side of the control device connection during the protection characteristic test. A control device side test connector is connected to the control device. The test connector on the tester side is connected to the protective characteristic tester.

According to the invention described in claim 4, in addition to the operation of the invention described in claim 3, the switch-side connector, the controller-side connector and the switch-side test connector each have the same structure. To be done. Further, the switch side connector, the control device side connector and the control device side test connector have the same configuration. Therefore, the types of connectors used are reduced.

According to the fifth aspect of the present invention, at the time of the protection characteristic test, one end of the control cable on the side of the control device connection and the control device are connected by a connector through the test cable from the protection characteristic tester.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described below with reference to an overcurrent trip circuit.
An embodiment of a directional ground fault trip control type protective relay will be described with reference to FIGS. 1 and 2.

As shown in FIG. 2, a switch 3 is fixed to the arm 2 attached to the upper part of the electric pole 1. A housing case 5 is fixed to the arm 4 attached to the middle of the electric pole 1, and a protective relay 6 is housed in the housing case 5. The protective relay 6 is connected to the switch 3 via a control cable 7. To the switch 3 and the protective relay 6, a portable tester 8 for testing a ground fault characteristic and a short-circuit characteristic, which will be described later, is detachably connected via a test cable 9.

(Switch) As shown in FIG. 1, in the case 3a of the switch 3, the distribution line 11 of each phase consisting of U-phase, V-phase and W-phase is opened / closed by an external operation handle (not shown). An opening / closing unit 12 that is operated is provided. Further, a trip coil 13 for automatically tripping the opening / closing part 12 is provided in the case 3a.

The automatic trip operation includes a ground fault trip operation and an overcurrent trip operation. The ground fault trip operation is to detect the ground fault current when a ground fault current flows through the distribution line 11 due to a ground fault accident that occurs on the load side, and when the ground fault current exceeds a set value, excite the trip coil 13 This is an operation of releasing the engagement of the engagement member 14 with the engaged member 15 and automatically opening the opening / closing portion 12. In the overcurrent trip operation, when an overcurrent of a certain set value or more is detected in a short-circuit accident, the trip coil 13 is excited to automatically open the opening / closing part 12 instantly, as in the case of the ground fault. It is an operation to do.

A zero-phase current transformer (ZCT) 16 for detecting U-phase, V-phase and W-phase zero-phase currents is provided on the distribution line 11. Around the iron core (not shown) of the zero-phase current transformer 16, when confirming whether the operation of the protective relay 6 is normal,
A test wire 17 for passing a ground fault test current is wound around the zero-phase current transformer 16. Further, on the distribution line 11, between the switching unit 12 and the zero-phase current transformer 16, for zero-phase voltage detection for performing selective protection between a ground fault on the load side and a ground fault on the power supply side. A capacitor (ZPD) 18 is provided. Furthermore, on the U and W phases of the distribution line 11,
A current transformer (C
T) 19u and 19w are provided respectively.

(Switch-side connector) The case 3a is provided with a female switch-side connector 21, and the switch-side connector 21 is provided with a plurality of female terminals AK. The female terminals A and C are ground fault test current input / output terminals, and both ends of the test line 17 are connected to each other. Normally, the test line 17 is in an unused state and is used only when a ground fault test current is applied during the ground fault characteristic test. The female terminals B and D are ground fault current detection terminals, and both ends of the zero-phase current transformer 16 are connected to each other.

An intermediate portion of the zero-phase current transformer 16 on the side where the female terminal D is connected is connected to a ground terminal 22a of the case 3a via a ground wire 22. The female terminals E and F are zero-phase voltage detection terminals, respectively, and the zero-phase voltage detection capacitor 18 is connected via the converter 23. The female terminals G and H are trip current input terminals, and both ends of the trip coil 13 are connected. The female terminals I, J, and K are overcurrent detection terminals, and the female terminal K is on the ground side. Both current transformers 19u and 19 are connected to the female terminals I and J, respectively.
One end of w is connected, and both current transformers 1 are connected to the female terminal K.
The other ends of 9u and 19w are connected.

(Protective Relay) The protective relay 6 is provided with a female control device side connection connector 31, and the control device side connection connector 31 is provided with a plurality of female type terminals A1 to K1. The female terminals A1 and C1 are ground fault test current input / output terminals, respectively. The female terminals B1 and D1 are ground fault current detection terminals, respectively. The female terminals E1 and F1 are zero-phase voltage detection terminals, respectively. The female terminals G1 and H1 are trip current output terminals, respectively. Female terminals I1, J1, K
Reference numerals 1 are overcurrent detection terminals, respectively.

Further, the protective relay 6 is a ground fault detection circuit (not shown) for detecting the ground fault current output from the zero-phase current transformer 16.
And a control device 3 including an overcurrent detection circuit (not shown) for detecting an overcurrent output from both the current transformers 19u and 19w
Equipped with 2. The control device 32 outputs a trip signal to the trip coil 13 based on the detection results of both detection circuits. The female terminals A1 to K1 are respectively connected to the control device 32.
It is connected to the.

(Control cable) During normal operation for monitoring a ground fault in the distribution line 11 (during a non-ground fault characteristic test), the switch-side connector 21 and the controller-side connector 31 are connected.
And the control cable 7 are connected between the two. The control cable 7 includes a male switch-side connector 41 and a male controller-side connector 42. The switch-side connector 41 has male terminals a to k, and the controller-side connector 42 has male terminals a1 to k1. A plurality of control lines 43 are connected between the male terminals a to k and the male terminals a1 to k1, respectively.

The switch side connector 41 and the control device side connector 42 can be connected to the switch side connector 21 and the control device side connector 31, respectively. That is, the male terminals a to k of the switch-side connector 41 can be connected to the female terminals A to K of the switch-side connector 21, respectively. The male terminals a1 to k1 of the controller-side connector 42 are connectable to the female terminals A1 to K1 of the controller-side connector 31, respectively.

(Tester) The tester 8 is provided with a female tester-side connector 51, and the tester-side connector 51 is provided with a plurality of female terminals A2 to K2. The female terminals A2 and C2 are ground fault test current input / output terminals, respectively. The female terminal F2 is a ground fault test voltage output terminal that outputs a voltage to the converter 23 to determine the directionality during the ground fault test. The female terminals G2 and H2 are trip current input terminals, respectively. Also, female terminals I2, J2, K
2 are test overcurrent output terminals, respectively. Each female terminal A
2, C2 and F2-K2 are connected to an operation test circuit (not shown) built in the tester 8. Female terminal B
2, D2 and E2 are unused terminals.

(Test Cable) During the ground fault characteristic test, the control device side connector 42 of the control cable 7 is removed from the control device side connector 31 of the protective relay 6,
Control device side connector 42 and control device side connector 3
1 is connected to a tester 8 via a test cable 9. The test cable 9 includes a female switch-side test connector 61, a male control device-side test connector 62, and a male tester-side test connector 63.

The switch side test connector 61 is a female terminal a2.
~ K2. The controller-side test connector 62 has male terminals a3 to k3. The tester-side test connector 63 includes male terminals a4 to k4. The female terminals b2, d2, e2 of the switch side test connector 61 and the male terminals b3, d3, e3 of the controller side test connector 62 are connected by a plurality of control lines 64, respectively. A plurality of control lines 65 are connected between the female terminals a2, c2, f2 of the switch side test connector 61 and the male terminals a4, c4, f4 of the test side test connector 63, respectively. A plurality of control lines 66 are connected between the male terminals g3 to k3 of the control device side test connector 62 and the male terminals g4 to k4 of the tester side test connector 63, respectively.

Female terminal g2 of switch side test connector 61
~ K2, the male terminal a3 of the controller side test connector 62,
male terminals b of c3, f3 and the tester side test connector 63
4, d4 and e4 are unused terminals. The female terminals g2 to k2 of the switch side test connector 61 also function as protective covers for the male terminals g1 to k1 of the control cable 7 when mounted during the test. In particular, by covering the charging exposed portions of the male terminals i1 to k1 connected to the current transformers 19u and 19w, the safety of the worker can be achieved.

The switch side test connector 61 can be connected to the control device side connector 42 of the control cable 7. The control device side test connector 62 is connectable to the control device side connection connector 31. The tester-side test connector 63 can be connected to the tester-side connector 51. That is, the switch side test connector 61
The female terminals a2 to k2 can be connected to the male terminals a1 to k1 of the control device side connector 42 of the control cable 7, respectively. The male terminals a3 to k3 of the control device side test connector 62 can be connected to the female terminals A1 to K1 of the control device side connection connector 31, respectively. Male terminal a4 of the tester side test connector 63
k4 is the female terminals A2 to K2 of the tester-side connector 51
Can be connected to each.

The switch-side connector 21, the controller-side connector 31, the tester-side connector 51, and the switch-side test connector 61 are compatible with each other. Also, the switch side connector 4
1, the controller-side connector 42, the controller-side test connector 62, and the tester-side test connector 63 are compatible with each other. In the present embodiment, the trip coil 13, the engaging member 14 and the engaged member 15 constitute trip means. The zero-phase current transformer 16, the zero-phase voltage detecting capacitor 18, and the current transformers 19u and 19w constitute abnormality detecting means. The tester 8 constitutes a protective characteristic tester.

Next, the operation of the protective relay configured as described above will be described. (During the non-ground fault characteristic test) During the non-ground fault characteristic test, the switch side connector 21 and the control device side connector 31 are connected by the control cable 7. When a ground fault occurs on the load-side distribution line 11, the zero-phase current transformer 16 detects the ground fault current, and the ground fault current passes through the control cable 7 to control the protective relay 6. It is output to 32. Then, the control device 32 causes a trip current to flow through the trip coil 13 when it is determined that there is a ground fault on the load side due to the ground fault current element and the zero-phase voltage element from the converter 23. As a result, the trip coil 13 is excited and the opening / closing part 12 is opened.

(During ground fault characteristic test) At the time of ground fault characteristic test,
The control device side connector 42 of the control cable 7 is detached from the control device side connection connector 31 of the protective relay 6, and both connectors 42 and 31 have a switch side test connector 61 and a control device side test connector of the test cable 9, respectively. 6
2 are connected. The ground fault test current generated in the tester 8 is the female terminal A2 of the tester-side connector 51,
Female terminal A and female terminal C of switch-side connector 21 via test cable 9 and control cable 7, female terminal C2 of tester-side connector 51 via control cable 7 and test cable 9. Flowing through the circuit. Then, a ground fault current is generated at the female type terminals B and D which are the ground fault current detection terminals of the zero-phase current transformer 16, and this ground fault current flows to the protective relay 6 via the control cable 7 and the test cable 9. It is input to the female terminals B1 and D1 which are ground fault current detection terminals. At the same time, a voltage for determining the directionality is applied from the female terminal F2, which is the ground fault test voltage output terminal of the tester 8, to the female terminal F, which is the zero-phase voltage detection terminal of the converter 23. , From the converter 23 to female terminals E and E1 which are zero-phase voltage detection terminals.
The zero-phase voltage signal is input to the control device 32 via the.

Based on these ground fault currents and zero-phase voltage elements, the controller 32 makes a directional ground fault detection determination, and outputs a trip current to the trip coil 13 of the switch 3 when a ground fault accident is determined. To do. However, the female terminals G and H, which are the trip current input terminals of the switch 3, are connected to the protective relay 6
Since it is open to the female terminals G1 and H1 which are the trip current output terminals, the switch 3 does not trip due to this test operation. In addition, the control device 32
Is output to the female terminals G2 and H2 of the tester-side connector 51 via the test cable 9, and the tester 8 performs a ground fault characteristic test. Therefore,
The earth fault characteristic test of the protective relay 6 can be completed in the uninterrupted state of the power distribution line.

(During non-short-circuit characteristic test) During the non-short-circuit characteristic test, the switch-side connector 21 and the controller-side connector 31 are connected by the control cable 7 and are female type terminals which are overcurrent detection terminals. Terminals I, J, K and female terminal I1,
J1, K1, and female terminals G1, H1 that are trip current output terminals and female terminals G that are trip current input terminals,
H and are connected. When a short circuit accident occurs in the distribution line 11, the control device 32 detects an overcurrent via the current transformers 19u and 19w and causes a trip current to flow in the trip coil 13 to open and close the opening and closing unit as in the case of a ground fault. 12 is automatically opened.

(During a short circuit characteristic test) During a short circuit characteristic test,
The control device side connector 42 of the control cable 7 is removed from the control device side connection connector 31 of the protective relay 6. The switch side test connector 61 and the controller side test connector 62 of the test cable 9 are connected to both connectors 42 and 31, respectively. The test overcurrent generated in the tester 8 is the female terminal I of the tester-side connector 51.
2, J2, K2, control device 3 via test cable 9
It is output to the female terminals I1, J1 and K1 which are the second overcurrent detection terminals. Based on this test overcurrent, the controller 32
Output trip current. This trip current is output to the female terminals G2, H2 of the tester-side connector 51 via the test cable 9, and the tester 8 performs a short-circuit characteristic test. Therefore, the short circuit characteristic test of the protective relay 6 can be completed in the uninterrupted state of the power distribution line.

Therefore, according to this embodiment, the following effects can be obtained. (1) At the time of the protection characteristic test, the control device side connector 42 is disconnected from the control device side connection connector 31, and both connectors 4
The switch side test connector 61 and the control device side test connector 62 of the test cable 9 are connected to 2, 31 respectively. That is, in the switch 3 and the protective relay 6, the existing connectors 21, 31 and the control cable 7 can be used to perform the ground fault characteristic test. Therefore, unlike the prior art, it is not necessary to permanently install a wiring extraction connector (test connector) on the control cable 7 that connects the switch 3 and the protective relay 6 to each other. In addition, a normal operation connector (jumper for closing the trip circuit) connected to the wiring extraction connector during normal operation is also unnecessary. Therefore, the manufacturing cost of the protective relay 6 can be reduced. Further, since there are no parts to be removed and stored at the time of the ground fault characteristic test, parts such as a conventional connector for normal operation are not lost.

(2) The switch cable side test connector 61 connectable to the control unit side connector 42 and the control unit side test connector connectable to the control unit side connector 31 are connected to the test cable 9. 62 and a tester side test connector 63 connectable to the tester side connection connector 51. Then, the switch side test connector 6
1 and the control device side test connector 62 were respectively connected to the tester side test connector 63 so as to branch. At the time of the ground fault characteristic test, the connectors 61 to 61 of the test cable 9
It is only necessary to connect 63 to the respective connectors 42, 31, 63. For this reason, for example, an operator connects the control cables 64 to 66 of the test cable 9 to the terminals B1, D1 and E, respectively.
1, A to F, G1 to K1 need not be connected. Therefore, the tester 8 can be easily connected regardless of the skill level of the operator. Further, it is possible to eliminate connection mistakes in the test cable 9.

(3) The switch-side connector 21, the controller-side connector 31, the tester-side connector 51, and the switch-side test connector 61 of the test cable 9 are made compatible with each other. Further, the switch side connector 41 of the control cable 7, the control device side connector 42,
The controller-side test connector 62 and the tester-side test connector 63 of the test cable 9 are made compatible with each other. That is, each connector 21, 31, 51, 61
Have the same configuration. Each connector 4
1, 42, 62 and 63 have the same configuration. Therefore, unlike the case where the connectors are not compatible with each other, the types of connectors used can be reduced.

The above embodiment may be modified as follows. The connection between the switch 3 and the control cable 7 and between the tester 8 and the test cable 9 may not be connector connection. For example, the switch-side connector 21 and the tester-side connector 51 may be replaced with terminal blocks, and the control cable 7 and the test cable 9 may be connected and fixed to the terminal blocks. Even in this case, the tester 8 is connected to the switch 3 and the control device 32 by a connector.

Each connector 61 to 6 of the test cable 9
3 may be divided into a plurality of parts, and the control device side connector 42, the control device side connection connector 31 and the tester side connection connector 51 of the control cable 7 may be respectively divided so as to be connected to them. For example, the tester side test connector 63 is used for a ground fault characteristic test (male terminals a4 to f4).
And a short-circuit characteristic test (male terminals g4 to k4), and the tester-side connector 51 of the tester 8 is used for a ground fault test (female terminals A2 to F2) and an overcurrent test (female terminal). Mold terminals G2 to K2).

Each of the control cable 7 and the test cable 9 may be divided into a plurality of pieces. -The protective relay 6 may be replaced with various protective relays such as a ground fault relay with an overcurrent accumulation trip.

At the time of the ground fault characteristic test, the control cable 7 may be removed and the switch 3, the protective relay 6 and the tester 8 may be connected only by the test cable 9.
At this time, the switch side test connector 61 is a male connector. Even in this case, the tester 8 can be easily connected regardless of the skill level of the operator.

・ Each connector 21, 31, 51, 41, 4
The males and females of 2, 61 to 63 may be reversed. That is, each connector 21, 61, 31, 51 is changed from a female type to a male type, and each connector 41, 42, 62, 63 is changed from a male type to a female type.

[0045]

According to the present invention, it is not necessary to previously provide a wiring lead-out connector (test connector) on the control cable for connecting between the switch and the protective relay. Since the protection characteristic test can be performed using the existing connector, the manufacturing cost of the protection relay can be reduced.

[Brief description of drawings]

FIG. 1 is a connection diagram between a switch, a relay, and a tester.

FIG. 2 is an explanatory view showing how a switch, a relay and a tester are attached to a utility pole.

[Explanation of symbols]

3 ... Switch, 3a ... Case, 6 ... Protective relay, 7 ... Control cable, 8 ... Tester (protective characteristic tester), 9 ... Test cable, 11 ... Distribution line, 13 ... Trip coil that constitutes trip means , 14 ... Engaging members forming trip means, 15 ... Engaged members forming trip means, 16
... Zero-phase current transformer constituting abnormality detecting means, 18 ... Zero-phase voltage detecting capacitor constituting abnormality detecting means, 19u, 1
9w ... Current transformer constituting abnormality detecting means, 21 ... Switch side connector, 31 ... Control device side connector, 32 ...
Control device, 41 ... Switch side connector, 42 ... Control device side connector, 43, 45, 64 to 66 ... Control line, 51 ... Tester side connection connector, 61 ... Switch side test connector, 6
2 ... Control device side test connector, 63 ... Tester side test connector.

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Hideaki Ichinose             Chubuden, 1 Higashishinmachi, Higashi-ku, Nagoya-shi, Aichi             Power Co., Ltd. (72) Inventor Junzo Takemura             Chubuden, 1 Higashishinmachi, Higashi-ku, Nagoya-shi, Aichi             Power Co., Ltd. (72) Inventor Naoya Yamaguchi             1-1, Oitakitamachi, Saga City, Saga Prefecture             Togami Denki Seisakusho (72) Inventor Kurita Corporation             Energy, No. 1, Upper Hand, Inuyama, Aichi Prefecture             Port Co., Ltd. F-term (reference) 5G034 AE01                 5G042 FF01 FF07 FF09 FF15 FF22

Claims (5)

[Claims] 1. A detection signal from an abnormality detecting means provided on a distribution line is inputted via a control cable, and a trip signal is sent to a trip means of a switch via a control cable based on the detection result of the signal. In a protective relay equipped with a control device that outputs the output, disconnect one end of the control cable on the control device connection side from the control device during the protection characteristic test, and protect the control cable on one end of the control cable and the control device. A protective relay that connects the test cable from the tester to the connector. 2. The protective relay according to claim 1, wherein the test cable is provided so as to branch from a protection characteristic tester connection side to a switch connection side and a control device connection side, respectively. 3. A detection signal from an abnormality detecting means provided on a distribution line is inputted through a control cable, and a trip signal is sent to a trip means of a switch through a control cable based on the detection result of the signal. In a test cable for a protective relay equipped with a control device that outputs as a switch, a switch side test connector that can be connected to one end of the control cable on the control device connection side and a control device that can be connected A test cable for a protective relay, comprising a control device side test connector and a tester side test connector connectable to the protection characteristic tester. 4. The switch has a switch-side connector to which the switch-side connector of the control cable is connected, and the controller has a controller-side connector to which the controller-side connector of the control cable is connected. The switch-side connector, the controller-side connector, and the switch-side test connector are compatible with each other, and the switch-side connector, the controller-side connector, and the control-device-side test connector are compatible with each other. The test cable for the protective relay according to claim 3, wherein the test cable is provided. 5. A detection signal from an abnormality detecting means provided on a distribution line is inputted through a control cable, and a trip signal is sent to a trip means of a switch based on a detection result of the signal. In the test method of the protective relay equipped with the control device that outputs via the control characteristic, at the time of the protection characteristic test, connect one end of the control cable on the control device connection side and the control device with the connector through the test cable from the protection characteristic tester. Test method for protective relays.