CN209833652U - Outdoor turnout debugging device - Google Patents

Abstract

The utility model provides an outdoor turnout debugging device, which comprises a generator, a control unit, an action unit and a representation unit, wherein the action unit and part of the control unit form an independent loop, the representation unit and the other part of the control unit form an independent loop, the control unit comprises a power supply voltage transformation component, a wireless signal transmitter, a circuit breaker and a power supply interface, the power supply voltage transformation component is used for transforming and rectifying current input by the generator, the output end of the power supply voltage transformation component is connected with the power supply interface, the fixed operation button, the reverse operation button and the indicating lamp, the fixed operation button and the reverse operation button are connected with the integrated cable connection interface, the wireless signal transmitter is connected with the two wireless transmission control components, and the two wireless transmission control components are respectively connected in parallel on the fixed operation button and the reverse operation button. The utility model discloses can debug the action unit and the expression unit of outdoor whole group switch under the condition that indoor outdoor not communicate.

Description

Outdoor turnout debugging device

Technical Field

The utility model relates to a railway communication technical field, concretely relates to outdoor switch debugging device.

Background

Railway signals play a very important role in ensuring the safe operation of trains. The turnout is the main equipment for controlling the running direction of the train, and the turnout is pulled by the point switch to act and be locked, so that the train is ensured to be opened to a correct station track. The present switch control circuit includes two parts of switch action circuit and switch indication circuit. The action circuit makes the electric switch machine act to switch the switch according to the operation intention of the operator or the train operation route plan, and the indication circuit reflects the switched switch position to the interlocking device interface in the signal building. According to the development of railways and urban rails in China, a three-phase alternating current hydraulic switch machine ZYJ7+ SH6 is widely used in passenger special lines and high-speed railways. In order to ensure that the switch machine can work normally after construction, the switch machine needs to be accurately debugged. Due to the limitation of construction conditions, the switch machine often cannot meet the debugging requirement in time. Generally, the indoor and outdoor connection debugging cannot be directly carried out, most indoor simulation debugging is carried out, outdoor mechanical test and simple circuit conduction are carried out, and the problem-free connection debugging is ensured. However, in the railway signal engineering construction process, the outdoor turnout debugging is often limited by the construction progress in the signal building, namely the outdoor turnout (ZYJ7+ SH6) can not be debugged under the condition that the construction in the signal building is not finished.

In conclusion, an outdoor turnout debugging device is urgently needed to solve the problem that outdoor turnout debugging work in the prior art is restricted by construction progress in a signal building.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an outdoor switch debugging device, concrete technical scheme is as follows:

an outdoor turnout debugging device comprises a generator, a control unit, an action unit and a representation unit, wherein the action unit and part of the control unit are connected to form an independent loop, the representation unit and the rest of the control unit are connected to form an independent loop, wherein,

the control unit comprises an internal component and an external component, the internal component comprises a power supply transformation component and a wireless signal transmitter, the external component comprises a circuit breaker, a power supply interface, a fixed operation button, a reverse operation button, an indicator light, an integrated cable connecting interface and two wireless transmission control components (the wireless transmission control components adopt Bluetooth or infrared rays as components of a control module, the wireless transmission control components are controlled by a remote controller to realize the operation of connecting a fixed operation/reverse operation circuit or disconnecting the fixed operation/reverse operation circuit, namely, the 'fixed operation' button on the remote controller is pressed down to realize the connection of the fixed operation circuit and the disconnection of the fixed operation circuit after the fixed operation circuit is released, the 'reverse operation' button on the remote controller is pressed down to realize the connection of the reverse operation circuit and the disconnection of the reverse operation circuit after the releasing, the functions realized by the wireless transmission control components are equal to the functions realized by the fixed operation button and the reverse operation button), the output end of the generator is connected with the input end of the power supply transformation assembly through the circuit breaker, the power supply transformation assembly is used for transforming and rectifying current input by the generator and then outputting the current through the output end of the power supply transformation assembly, the output end of the power supply transformation assembly is connected with the power interface, the fixed operation button, the reverse operation button and the indicator lamp, the fixed operation button and the reverse operation button are also connected with the integrated cable connecting interface, the wireless signal transmitter is connected with the two wireless transmission control assemblies, and the two wireless transmission control assemblies are respectively connected on the fixed operation button and the reverse operation button in parallel;

the action unit comprises a turnout action power supply interface, an open-phase protection device and a switch machine motor, wherein the turnout action power supply interface is connected with the switch machine motor through the open-phase protection device;

the indicating unit includes a flip indicating relay circuit and a position indicating relay circuit.

Preferably, the current input by the generator is AC 380V.

Preferably, the circuit breaker comprises a circuit breaker RD1, a circuit breaker RD2 and a circuit breaker RD3, wherein the voltage and current of the circuit breaker RD1 are DC24V and 5A, respectively, the voltage and current of the circuit breaker RD2 are AC380V and 5A, respectively, and the voltage and current of the circuit breaker RD3 are AC220V and 0.5A, respectively.

Preferably, the power interfaces include two AC380V power interfaces, two AC220V power interfaces and two DC24V power interfaces, wherein the AC380V power interface is used for supplying power to the action unit, and the AC220V power interface and the DC24V power interface are used for supplying power to the representation unit.

Preferably, the indicator lights include an AC380V indicator light, an AC220V indicator light, and a DC24V indicator light.

Preferably, the AC380V indicator light is connected in parallel with two AC380V power interfaces, the AC220V indicator light is connected in parallel with two AC220V power interfaces, and the DC24V indicator light is connected in parallel with two DC24V power interfaces.

Preferably, a positioning microelectronic relay is arranged in each of the outgoing line and the return line of the positioning indicating relay circuit, and a positioning indicating lamp is arranged between the outgoing line and the return line; the reverse indicating relay circuit is characterized in that reverse microelectronic relays are arranged in outgoing lines and return lines of the relay circuit, and reverse indicating lamps are arranged between the outgoing lines and the return lines.

Preferably, the position indication relay circuit and the flip indication relay circuit are connected with the integrated cable connection interface.

Use the technical scheme of the utility model, following beneficial effect has:

(1) the utility model discloses in outdoor switch debugging device include generator, the control unit, action unit and show the unit, the control unit forms independent return circuit with the action unit, the control unit forms independent return circuit with the expression unit. The utility model discloses can be under the condition that indoor outdoor not communicate, directly carry out the debugging in step to the action unit and the expression unit of outdoor whole group switch, after the construction is accomplished in the signal building, directly accomplish final antithetical couplet in inserting the signal building with outdoor switch debugging device, this not only can save time, has still guaranteed the experimental whole face nature that the action unit and the expression unit of whole group switch carry out the debugging in step of outdoor switch. Furthermore, the utility model discloses the location that sets up shows the lamp and the counterpoint shows the lamp and makes and decide, counterpoint to show has the direct display function, and this accuracy that has both guaranteed the switch operation has also made things convenient for operation personnel's operation and has avoided operation personnel's error.

(2) The utility model discloses in the circuit breaker includes circuit breaker RD1, circuit breaker RD2 and circuit breaker RD3, wherein, circuit breaker RD 1's voltage and electric current are DC24V and 5A respectively, circuit breaker RD 2's voltage and electric current are AC380V and 5A respectively, circuit breaker RD 3's voltage and electric current are AC220V and 0.5A respectively, the setting up of different circuit breakers has guaranteed that power transformer subassembly carries out the accuracy of vary voltage and rectification with the electric current of generator input and the precision when the electric current after the rectification exports through power transformer subassembly's output.

(3) The utility model discloses in AC380V power source is used for the action unit power supply, and AC220V power source and DC24V power source set up not only satisfied the work demand for representing the unit power supply through the gradient of power source voltage, still very big electric energy of having saved. Furthermore, the utility model discloses still connect the pilot lamp that corresponds at corresponding power source interface department, whether the lamp through the pilot lamp lights the behavior that corresponds power source interface of real time monitoring, simultaneously, can also detect when the pilot lamp lights and correspond power source interface and can normally work, and then reduced operation personnel's working strength, can also improve operation personnel's work efficiency.

In addition to the above-described objects, features and advantages, the present invention has other objects, features and advantages. The present invention will be described in further detail with reference to the drawings.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. In the drawings:

fig. 1 is a schematic diagram illustrating an internal circuit structure connection of an outdoor switch debugging apparatus according to embodiment 1 of the present invention (in the figure, partial circuit connections between a control unit and an action unit and between the control unit and a display unit are omitted);

FIG. 2 is a schematic diagram of the external electrical component connections of the control unit of FIG. 1;

FIG. 3 is a schematic diagram showing the connection of the circuit structures of the control unit (left) and the display unit (right) in the JDF (J) module of FIG. 1;

FIG. 4 is a schematic diagram showing the connection of the circuit structures of the action unit and the presentation unit in the JDF (J) module of FIG. 1;

FIG. 5 is a schematic diagram showing the connection of the circuit structure of the control unit (left) and the display unit (right) in the JDF (X) module of FIG. 1;

fig. 6 is a schematic diagram showing the connection of the circuit structures of the action unit and the presentation unit in the jdf (x) module of fig. 1.

Detailed Description

The embodiments of the invention will be described in detail hereinafter with reference to the accompanying drawings, but the invention can be implemented in many different ways, which are defined and covered by the claims.

Example 1:

referring to fig. 1 and 2, a circuit of an outdoor turnout debugging device, the debugging device comprises a generator, a control unit, an action unit and a representation unit, the action unit and a part of the control unit form an independent loop, the representation unit and the other part of the control unit form an independent loop, wherein the control unit comprises an internal component and an external component, the internal component comprises a power supply transformation component and a wireless signal transmitter, the external component comprises a circuit breaker, a power supply interface, a fixed operation button, a reverse operation button, an indicator lamp, two integrated cable connection interfaces (including an integrated cable KZ and an integrated cable KF) and two wireless transmission control components (the wireless transmission control components adopt bluetooth or infrared rays as control modules, the wireless transmission control components are controlled by a remote controller to realize the communication of the fixed operation/reverse operation circuit or the disconnection of the fixed operation/reverse operation circuit, namely, a 'fixed operation' button on the remote controller is pressed to realize the connection of a fixed operation circuit, and the fixed operation circuit is disconnected after the fixed operation circuit is released; the 'reverse operation' button on the remote controller is pressed to realize the connection of the reverse operation circuit, the reverse operation circuit is disconnected after the reverse operation circuit is released, and the function realized by the wireless transmission control assembly is equal to the function realized by the fixed operation button and the reverse operation button. ) The output end of the generator is connected with the input end of a power supply transformation assembly through a circuit breaker, the power supply transformation assembly is used for transforming and rectifying current input by the generator and then outputting the current through the output end of the power supply transformation assembly through a power supply, the output end of the power supply transformation assembly is connected with a power interface, a fixed operation button, a reverse operation button and an indicator lamp, the fixed operation button and the reverse operation button are also connected with two integrated cable connecting interfaces, the wireless signal transmitter is connected with two wireless transmission control assemblies, and the two wireless transmission control assemblies are respectively connected on the fixed operation button and the reverse operation button in parallel;

the action unit comprises a turnout action power supply interface, an open-phase protection device and a switch machine motor, wherein the turnout action power supply interface is connected with the switch machine motor through the open-phase protection device;

the indicating unit includes a flip indicating relay circuit and a position indicating relay circuit.

The current at the generator input is AC 380V.

The circuit breaker comprises a circuit breaker RD1, a circuit breaker RD2 and a circuit breaker RD3, wherein the voltage and the current of the circuit breaker RD1 are respectively DC24V and 5A, the voltage and the current of the circuit breaker RD2 are respectively AC380V and 5A, and the voltage and the current of the circuit breaker RD3 are respectively AC220V and 0.5A.

The power interfaces comprise two AC380V power interfaces, two AC220V power interfaces and two DC24V power interfaces, wherein the AC380V power interface is used for supplying power to the action unit, and the AC220V power interface and the DC24V power interface are used for supplying power to the representation unit.

The indicator lights include an AC380V indicator light, an AC220V indicator light, and a DC24V indicator light.

The AC380V indicator light is connected in parallel with two AC380V power interfaces, the AC220V indicator light is connected in parallel with two AC220V power interfaces, and the DC24V indicator light is connected in parallel with two DC24V power interfaces.

A positioning microelectronic relay is arranged in each of the outgoing line and the return line of the positioning indicating relay circuit, and a positioning indicating lamp (a gauge lamp is abbreviated in fig. 1, 3 and 5) is arranged between the outgoing line and the return line; the reverse indicating relay circuit is provided with a reverse microelectronic relay in the outgoing line and the return line, and a reverse indicating lamp (a reverse lamp is abbreviated in figures 1, 3 and 5) is arranged between the outgoing line and the return line.

The positioning representation relay circuit and the reverse position representation relay circuit are connected with the integrated cable connecting interface.

The specific process of the embodiment for performing the setting operation debugging is as follows:

when the RD2 breaker of the control unit is closed, the AC380V indicator light, the AC220V indicator light and the DC24V indicator light are turned on, when the turnout is in a reverse position, the reverse position indicator lights of the JDF (J) module and the JDF (X) module are turned on, and at the moment, a fixed operation button (self-reset switch) of the control unit is pressed, so that the turnout is turned on to be positioned from the reverse position.

The turnout is positioned and operated in the reverse direction: microelectronic relay 1DQJ and compound relay 1DQJF of microelectronic relay in JDF (J) module and JDF (X) module attract, microelectronic relay 2DQJ change pole, three-phase power A, B, C separated by AC380V power interface through breaker RD2 respectively enters microelectronic open-phase protector DBQ, and power is supplied to three-phase motor by X1, X2 and X5 respectively.

Referring to fig. 1 and 3, the current flow direction of the control unit in jdf (j) module is:

(1) integrated cable KZ → 1DQJ (1DQJ suck up) → 2DQJ-14 (141-;

(2) integrated cable KZ → 1DQJ-4 → integrated cable KF;

(3) DZ24V power interface (KZ) → RD1 → 1DQJF (1DQJF suck up) → 1DQJ-3 → RD1 → DZ24V power interface (KF);

(4) when the DBQ is electrified and works, the microelectronic relay BHJ is sucked up;

(5) DZ24V power interface (KZ) → RD1 → 1DQJ (suck up) → BHJ-3 → 1DQJ-3 → RD1 → DZ24V power interface (KF);

(6) DZ24V power interface (KZ) → RD1 → 1DQJF-4 → 2DQJ (2DQJ suck up) → integration cable KF;

(7) DZ24V power interface (KZ) → RD1 → 1DQJF-3 → 2DQJ (2DQJ suck up) → integration cable KF.

Referring to fig. 1 and 4, the current flow direction of the circuit of the action unit in the jdf (j) module is:

(1) AC380V power interface → RD2 → switch action power a → DBQ (11-21) → 1DQJ-1 → X1-J → switch motor W coil (switch motor W coil not shown in fig. 1 and 4);

(2) AC380V power interface → RD2 → switch action power B → DBQ (31-41) → 1DQJF-1 → 2DQJ-11 (111-;

(3) AC380V power interface → RD2 → turnout action power supply C → DBQ (51-61) → 1DQJF-2 → 2DQJ-12 (121-;

(4) the phase sequence of the switch machine motor is W-U-V, and the switch machine motor rotates clockwise to drive the switch rail to move towards the positioning direction.

When the switch is switched from the reverse position to the positioning position, referring to fig. 1 and fig. 3-4, the current flow direction of the circuit of the on-position indicating unit in the jdf (j) module is as follows:

(1) AC220V power interface → RD3 → microelectronic transformer BD1-7(DJZ220, No. 2 terminal and No. 3 terminal) → 1DQJ-2 → 2DQJ-13 (131-;

(2) AC220V power interface → microelectronic transformer BD1-7(DJF220, terminal No. 1 and terminal No. 4) → 1DQJ-1 → X1-J;

(3) DC24V power interface (KZ) → RD1 → DBJ-3 → position indicating lamp → DBJ-4 → RD1 → DC24V interface (KF);

(4) the switch rail positioning indicator lamp is turned on.

Referring to fig. 1 and 5, the current flow direction of the control unit in the jdf (x) module is:

(1) integrated cable KZ → 1DQJ (1DQJ suck up) → 2DQJ-14 (141-;

(2) DC24V power interface (KZ) → RD1 → 1DQJF (1DQJF suck up) → 1DQJ-3 → RD1 → DC24V power interface (KF);

(3) when the DBQ is electrified to work, the BHJ is sucked up;

(4) DC24V power interface (KZ) → RD1 → 1DQJ (suck up) → BHJ-3 → 1DQJ-3 → RD1 → DC24V power interface (KF);

(5) DC24V power interface (KZ) → RD1 → 1DQJF-4 → 2DQJ (2DQJ suck up) → integration cable KF;

(6) DC24V power interface (KZ) → RD1 → 1DQJF-3 → 2DQJ (2DQJ suck up) → integration cable KF.

Referring to fig. 1 and 6, the current flow direction of the action circuit in the jdf (x) module is:

(1) AC380V power interface → RD2 → switch action power a → DBQ (11-21) → 1DQJ-1 → X1-X → switch motor W coil (switch motor W coil not shown in fig. 1 and 6);

(2) AC380V power interface → RD2 → switch action power B → DBQ (31-41) → 1DQJF-1 → 2DQJ-11 (111-;

(3) AC380V power interface → RD2 → turnout action power supply C → DBQ (51-61) → 1DQJF-2 → 2DQJ-12 (121-;

(4) the phase sequence of the switch motor is W-U-V, and the switch motor rotates clockwise to drive the point rail to move in a positioning way.

When the switch is switched from the reverse position to the positioning position, referring to fig. 1 and fig. 5-6, the current flow direction of the circuit of the on-position indicating unit in the jdf (x) module is as follows:

(1) AC220V power interface → RD3 → microelectronic transformer BD1-7(DJZ, terminal No. 2 and terminal No. 3) → 1DQJ-2 → 2DQJ-13 (131-;

(2) AC220V power interface → microelectronic transformer BD1-7(DJF, terminal No. 1 and terminal No. 4) → 1DQJ-1 → X1-X;

(3) DC24V power interface (KZ) → RD1 → DBJ-3 → position indicating lamp → DBJ-4 → RD1 → DC24V power interface (KF);

(4) the point rail positioning indicator lamp is lighted.

The specific process of performing the reverse operation debugging in this embodiment is as follows:

when the RD2 breaker of the control unit is closed, the AC380V indicator light, the AC220V indicator light and the DC24V indicator light are turned on, when the switch is positioned, the positioning indicator lights of JDF (J) and JDF (X) are turned on, and at the moment, the reverse operation button (self-reset switch) of the control unit is pressed, so that the switch is turned on to move from the positioning to the reverse operation.

The turnout is moved from positioning to reverse position: 1DQJ and 1DQJF in the JDF (J) module and the JDF (X) module are sucked up and switched to the pole of 2DQJ, and the three-phase power A, B, C separated by an AC380V power interface through a circuit breaker RD2 respectively enters a microelectronic open-phase protector DBQ and supplies power to a three-phase motor through X1, X3 and X4 respectively.

Referring to fig. 1 and 3, the current flow direction of the control unit in jdf (j) module is:

(1) integrated cable KZ → 1DQJ (1DQJ suck up) → 2DQJ-14 (141-;

(2) integrated cable KZ → 1DQJ-4 → integrated cable KF;

(3) DC24V power interface (KZ) → RD1 → 1DQJF (1DQJF suck up) → 1DQJ-3 → RD1 → DC24V power interface (KF);

(4) when the DBQ is electrified to work, the BHJ is sucked up;

(5) DC24V power interface (KZ) → RD1 → 1DQJ (suck up) → BHJ-3 → 1DQJ-3 → RD1 → DC24V power interface (KF);

(6) DC24V power interface (KZ) → RD1 → 1DQJF-4 → 2DQJ (2DQJ suck up) → integration cable KF;

(7) DC24V power interface (KZ) → RD1 → 1DQJF-3 → 2DQJ (2DQJ suck up) → integration cable KF.

Referring to fig. 1 and 4, the current flow direction of the action circuit in the jdf (j) module is:

(1) AC380V power interface → RD2 → switch action power a → DBQ (11-21) → 1DQJ-1 → X1-J → switch motor W coil (switch motor W coil not shown in fig. 1 and 4);

(2) AC380V power interface → RD2 → switch action power B → DBQ (31-41) → 1DQJF-1 → 2DQJ-11 (111-;

(3) AC380V power interface → RD2 → turnout action power supply C → DBQ (51-61) → 1DQJF-2 → 2DQJ-12 (121-;

(4) the phase sequence of the switch machine motor is W-V-U, and the switch machine motor rotates anticlockwise to drive the switch rail to move in a reverse position.

When the switch is switched to the position from the reverse position to the positioning position, referring to fig. 1 and fig. 3-4, the current flow direction of the circuit of the on reverse position indicating unit in the jdf (j) module is as follows:

(1) AC220V power interface → RD3 → microelectronic transformer BD1-7(DJZ220, No. 2 terminal and No. 3 terminal) → 1DQJ-2 → 2DQJ-13 (131-;

(2) AC220V power interface → microelectronic transformer BD1-7(DJF, terminal No. 1 and terminal No. 4) → 1DQJ-1 → X1-J;

(3) DC24V power interface (KZ) → RD1 → FBJ-3 → flip indicating lamp → FBJ-4 → RD1 → DC24V power interface (KF);

(4) the point rail inversion indicating lamp is lighted.

Referring to fig. 1 and 5, the current flow direction of the control unit in the jdf (x) module is:

(1) integrated cable KZ → 1DQJ (1DQJ suck up) → 2DQJ-14 (141-;

(2) DC24V power interface (KZ) → RD1 → 1DQJF (1DQJF suck up) → 1DQJ-3 → RD1 → DC24V power interface (KF);

(3) when the DBQ is electrified to work, the BHJ is sucked up;

(4) DC24V power interface (KZ) → RD1 → 1DQJ (suck up) → BHJ-3 → 1DQJ-3 → RD1 → DC24V power interface (KF);

(5) DC24V power interface (KZ) → RD1 → 1DQJF-4 → 2DQJ (2DQJ suck up) → integration cable KF;

(6) DC24V power interface (KZ) → RD1 → 1DQJF-3 → 2DQJ (2DQJ suck up) → integration cable KF.

Referring to fig. 1 and 6, the current flow direction of the circuit of the action unit in the jdf (x) module is:

(1) AC380V power interface → RD2 → switch action power a → DBQ (11-21) → 1DQJ-1 → X1-X → switch motor W coil (switch motor W coil not shown in fig. 1 and 6);

(2) AC380V power interface → RD2 → switch action power B → DBQ (31-41) → 1DQJF-1 → 2DQJ-11 (111-;

(3) AC380V power interface → RD2 → turnout action power supply C → DBQ (51-61) → 1DQJF-2 → 2DQJ-12 (121-;

(4) the phase sequence of the switch motor is W-V-U, and the switch motor rotates anticlockwise to drive the point rail to move in a reverse position.

When the switch is switched from the flip position to the positioning position, referring to fig. 1 and fig. 5-6, the current flow direction of the circuit of the on flip position indicating unit in the jdf (x) module is as follows:

(1) AC220V power interface → RD3 → microelectronic transformer BD1-7(DJZ, terminal No. 2 and terminal No. 3) → 1DQJ-2 → 2DQJ-13 (131-;

(2) AC220V power interface → microelectronic transformer BD1-7(DJF, terminal No. 1 and terminal No. 4) → 1DQJ-1 → X1-X;

(3) DC24V power interface (KZ) → RD1 → FBJ-3 → flip indicating lamp → FBJ-4 → RD1 → DC24V power interface (KF);

(4) the point rail inversion indicator light is on.

This embodiment can be under the condition of indoor outdoor not intercommunicating, directly carry out the synchronous debugging to the action unit and the presentation unit of outdoor whole group switch, and after the construction was accomplished in the signal building, direct complete the final antithetical couplet of debugging device access signal building with outdoor switch, this not only can save time, has still guaranteed that the action unit and the presentation unit of outdoor whole group switch are experimental carries out the comprehensiveness of synchronous debugging. In addition, the location that this embodiment set up shows the lamp and the counterpoint shows the lamp and makes and decide, counterpoint to show has the direct display function, and this both has guaranteed the accuracy of switch operation, has also made things convenient for operation of operating personnel and has avoided operating personnel's error.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The outdoor turnout debugging device is characterized by comprising a generator, a control unit, an action unit and a representation unit, wherein the action unit and part of the control unit are connected to form an independent loop, the representation unit and the rest of the control unit are connected to form an independent loop, wherein,

the control unit comprises an inner member and an outer member, the inner member comprises a power supply transformation assembly and a wireless signal transmitter, the external component comprises a circuit breaker, a power interface, a fixed operation button, a reverse operation button, an indicator light, an integrated cable connecting interface and two wireless transmission control components, the output end of the generator is connected with the input end of the power supply transformation component through the circuit breaker, the power supply transformation component is used for transforming and rectifying the current input by the generator and then outputting the current through the output end of the power supply transformation component, the output end of the power supply transformation component is connected with the power interface, the fixed operation button, the reverse operation button and the indicator light, the wireless signal transmitter is connected with two wireless transmission control components which are respectively connected in parallel on the fixed manipulation button and the reverse manipulation button;

the action unit comprises a turnout action power supply interface, an open-phase protection device and a switch machine motor, wherein the turnout action power supply interface is connected with the switch machine motor through the open-phase protection device;

the indicating unit includes a flip indicating relay circuit and a position indicating relay circuit.

2. The commissioning apparatus of claim 1, wherein the current of the generator input is AC 380V.

3. The commissioning apparatus of claim 2, wherein said circuit breaker comprises circuit breaker RD1, circuit breaker RD2, and circuit breaker RD3, wherein the voltage and current of circuit breaker RD1 are DC24V and 5A, respectively, the voltage and current of circuit breaker RD2 are AC380V and 5A, respectively, and the voltage and current of circuit breaker RD3 are AC220V and 0.5A, respectively.

4. The debugging apparatus according to claim 3, wherein the power interfaces comprise two AC380V power interfaces, two AC220V power interfaces and two DC24V power interfaces, wherein the AC380V power interface is used for supplying power to the action unit, and the AC220V power interface and the DC24V power interface are used for supplying power to the presentation unit.

5. The commissioning apparatus of claim 4, wherein the indicator lights comprise an AC380V indicator light, an AC220V indicator light, and a DC24V indicator light.

6. The debugging device of claim 5, wherein the AC380V indicator light is connected in parallel with two AC380V power interfaces, the AC220V indicator light is connected in parallel with two AC220V power interfaces, and the DC24V indicator light is connected in parallel with two DC24V power interfaces.

7. The commissioning apparatus of any one of claims 1 to 6, wherein the position indicating relay circuit is provided with a position microelectronic relay in both the outgoing and return lines and a position indicating light between the outgoing and return lines; the reverse indicating relay circuit is characterized in that reverse microelectronic relays are arranged in outgoing lines and return lines of the relay circuit, and reverse indicating lamps are arranged between the outgoing lines and the return lines.

8. The debugging device of claim 7 wherein said detent indicating relay circuit and said flip indicating relay circuit are connected to an integrated cable connection interface.