CN112600291A

CN112600291A - Automatic switching system and automatic switching method for secondary voltage loop

Info

Publication number: CN112600291A
Application number: CN202011332357.1A
Authority: CN
Inventors: 张刚; 杨翔; 刘小正; 王建平; 贾昌晖; 王志英; 王向利
Original assignee: Institute of Science and Technology of China Railway Xian Group Co Ltd
Current assignee: Institute of Science and Technology of China Railway Xian Group Co Ltd
Priority date: 2020-11-24
Filing date: 2020-11-24
Publication date: 2021-04-02
Anticipated expiration: 2040-11-24
Also published as: CN112600291B

Abstract

The invention belongs to the technical field of automatic control, and particularly relates to an automatic switching system and an automatic switching method for a secondary voltage loop.

Description

Automatic switching system and automatic switching method for secondary voltage loop

Technical Field

Background

The railway traction substation converts electric energy sent by a power plant through a power transmission line into voltage suitable for locomotive vehicles and distributes the voltage to a place of a contact network, wherein a 27.5KV bus is an important component of the traction substation and is connected with electrical equipment such as a breaker, a disconnecting switch, a current transformer CT, a voltage transformer PT/YH, a lightning arrester, an insulator and the like of the substation, and the working condition of the railway traction substation directly influences the working condition of the whole substation.

A voltage transformer (YH) is arranged on a 27.5kV bus of an existing traction substation, wherein the voltage transformer (YH) is respectively 3YH, 5YH, 4YH and 6YH, usually 3YH and 5YH are a group, 4YH and 6YH are a group, and when the system operates, one group works, and the other group is reserved; the voltage transformer is used for obtaining the voltage of a bus at the side of 27.5kV and converting the voltage into AC100V according to a certain proportion, the working voltage transformer AC100V is used for a relay protection and detection voltage loop, a loop formed by the fact that the AC100V provides a voltage signal for the relay protection and measurement device is a secondary voltage loop, and AC100V output by the standby voltage transformer secondarily serves as a standby;

however, the existing circuit has the following problems: although the existing device can meet the requirement of bus detection, manual switching is needed after an abnormal result is detected, and the problems of slow switching reaction, long switching time, misoperation, high working strength and high personnel investment are caused by manual switching.

Disclosure of Invention

Aiming at the technical problems in the prior art, the invention provides an automatic switching system of a secondary voltage loop, which can monitor the secondary voltage loop in real time, accurately switch a fault circuit to a standby circuit in time and ensure normal use.

Meanwhile, the invention also provides a secondary voltage loop automatic switching method realized by using the secondary voltage loop automatic switching system.

The technical scheme adopted by the invention is as follows:

a secondary voltage loop automatic switching system comprises a voltage transformer, a monitoring module, a switching module and an output circuit;

the input end of the voltage transformer is connected with the secondary voltage loop bus, the output end of the voltage transformer is connected with the input end of the monitoring module, the output end of the monitoring module is connected with the input end of the switching module, and the output end of the switching module is connected with the input end of the output circuit.

Further, the switching module comprises a switching circuit, and the switching circuit comprises a first automatic switch, a double-position relay, a second automatic switch, an intermediate relay and a display circuit;

the input end of the monitoring module is connected with the output end of the voltage transformer, the output end of the monitoring module is connected with the input end of the double-position relay, the input end of the first automatic change-over switch is connected with the output end of the voltage transformer, and the output end of the first automatic change-over switch is connected with the input end of the double-position relay; one end of the second automatic change-over switch is connected with the output end of the voltage transformer, the other end of the second automatic change-over switch is connected to a connecting node of a coil and a contact of the double-set relay, the output end of the double-set relay is connected with the input end of the intermediate relay, and the output end of the intermediate relay is connected with the input end of the output circuit through the display circuit.

Further, the switching module further comprises a manual switching circuit, a remote control module and an emergency control circuit;

the manual switching circuit comprises a first manual switch QK2, an input/output switch and a plurality of diodes; the output end of the first manual switch QK2 is connected with the input/push-out switch, a plurality of diodes are connected in parallel at the output end of the input/push-out switch, and the output ends of the diodes are respectively and correspondingly connected with the input ends of the intermediate relay;

the remote control module comprises remote control switches which correspond to the input ends of the double-position relay one by one, the input ends of the remote control switches are connected with the output end of the first automatic change-over switch, and the output ends of the remote control switches are connected with the input ends of the double-position relay, so that the remote control of the double-position relay is realized;

the emergency control circuit comprises emergency control switches which correspond to the input ends of the double-position relay one by one, and the emergency control switches correspond to the remote control switches one by one and are connected in parallel; the input end of the emergency control switch is connected with the output end of the first automatic change-over switch, and the output end of the emergency control switch is connected with the input end of the double-position relay, so that emergency manual control over the double-position relay is achieved.

Further, the automatic switching system of the secondary voltage loop further comprises a Programmable Logic Controller (PLC), the output end of the monitoring module is connected with the input end of the PLC, and the output end of the PLC is connected with the input end of the switching module.

Further, the monitoring module is a voltage transmitter, the output end of the voltage transformer is connected with the input end of the voltage transmitter, the output end of the voltage transmitter is connected with the input end of the programmable controller, and the output end of the programmable controller is connected with the input end of the switching circuit.

Further, the monitoring module is a voltage monitor, an output end of the voltage transformer is connected with an input end of the voltage monitor, an output end of the voltage monitor is connected with an input end of the programmable controller, and an output end of the programmable controller is connected with an input end of the switching module;

the voltage monitor includes a voltage monitor 3YJ, a voltage monitor 4YJ, a voltage monitor 5YJ and a voltage monitor 6YJ which are connected correspondingly to the voltage transformer, and the voltage monitor 3YJ, the voltage monitor 4YJ, the voltage monitor 5YJ andthe output end of the voltage monitor 6YJ is respectively connected with the input end I of the programmable controller_a0.6、I_a0.7、I_b0.1、I_b0.2And (4) connecting.

Further limiting, the monitoring module is a voltage monitor, and the voltage monitor comprises a voltage monitor 3YJ, a voltage monitor 4YJ, a voltage monitor 5YJ and a voltage monitor 6YJ which are correspondingly connected with each voltage transformer and have an interlocking function in pairs; a normally open contact of the voltage monitor 3YJ is connected in series with a normally closed contact of the voltage monitor 4YJ, and a normally open contact of the voltage monitor 4YJ is connected in series with a normally closed contact of the voltage monitor 3YJ to form an interlock circuit; a normally open contact of the voltage monitor 5YJ is connected in series with a normally closed contact of the voltage monitor 6YJ, and a normally open contact of the voltage monitor 6YJ is connected in series with a normally closed contact of the voltage monitor 5YJ to form an interlock circuit; the output ends of the voltage monitor 3YJ and the voltage monitor 4YJ are respectively connected with the input end of the double-position relay ZJ 3-4; the output ends of the voltage monitor 5YJ and the voltage monitor 6YJ are respectively connected with the input end of the double-position relay ZJ 5-6.

Further, the automatic switching system of the secondary voltage loop further comprises a bypass circuit, wherein the input end of the bypass circuit is connected with the output end of the voltage transformer, and the output end of the bypass circuit is connected with the input end of the output circuit.

A method for automatically switching a secondary voltage loop by using the automatic switching system of the secondary voltage loop comprises the following steps:

(1) the voltage transformer receives voltage signals of a secondary voltage loop bus, outputs mutual inductance voltage after conversion, then the mutual inductance voltage is input into a voltage monitor for detection, a calibration voltage value is set in the voltage monitor, and when the mutual inductance voltage obtained by the voltage monitor is smaller than the calibration voltage, the voltage monitor is conducted and outputs voltage;

(2) the switching module receives the switching signal, and first automatic transfer switch switches to the automatic normally open state, and the coil of two position relay gets electric, and second automatic transfer switch opens, and the contact of two position relay is closed, and the switching contact that the auxiliary relay corresponds gets electric, will switch current output and carry out the switching through output circuit, and simultaneously, the LED lamp that the voltage transformer that is in operating condition among the display circuit corresponds lights, accomplishes the switching of secondary voltage return circuit.

(1) the voltage transformer receives voltage signals of a secondary voltage loop bus, converts the voltage signals and outputs mutual inductance voltage, and the monitoring module receives the mutual inductance voltage signals, converts the mutual inductance voltage into input current signals and transmits the input current signals to the programmable controller;

(2) the programmable controller compares the received input current signal with a preset calibration current value, and when the input current signal is smaller than the calibration current value, the programmable controller outputs a conversion signal to the switching module through the output circuit;

(3) the switching module receives the switching signal, and first automatic transfer switch switches to the automatic normally open state, and the coil of two position relay gets electric, and second automatic transfer switch opens, and the contact of two position relay is closed, and the switching contact that the auxiliary relay corresponds gets electric, will switch current output and carry out the switching through output circuit, and simultaneously, the LED lamp that the voltage transformer that is in operating condition among the display circuit corresponds lights, accomplishes the switching of secondary voltage return circuit.

Compared with the prior art, the automatic switching system and the switching method of the secondary voltage loop have the beneficial effects that:

1. the system adopts a modular design, comprehensively utilizes electronic components such as a voltage monitor or a voltage transmitter, a double-position relay, an intermediate relay PLC and the like, realizes the function of a 27.5KV bus secondary voltage loop automatic switching device, achieves the real-time monitoring of 4-path voltage, has two automatic/manual switching modes, realizes the function of no main-standby switching, achieves the aim of quick automatic switching, provides technical support for the informationized automation of the operation of substation equipment, has complete functions, is simple and clear in circuit design, convenient and quick to install and maintain, saves the working time and improves the working efficiency;

2. the switching module adopted by the system can be timely and effectively switched to the standby circuit when the secondary voltage loop fails, the switching action is fast, the effectiveness and timeliness are improved, and economic loss caused by faults is avoided;

3. the voltage converter of the system obtains different mutual induction voltages by setting different conversion proportions, the application range is wide, the programmable controller is arranged, the accuracy and timeliness of system control are further improved, meanwhile, the system can be suitable for different circuits by changing the setting program, the application range is further improved, meanwhile, the interlocking of the main circuit and the standby circuit is ensured to prevent misoperation by arranging the double-position relay, and the safety of the system is improved;

4. the system can be switched on and off through corresponding multi-channel air switch bypasses by arranging the bypass circuit, so that the standby switching function in emergency is completed.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a block diagram of the system of the present invention;

FIG. 2 is an external wiring diagram of the present invention;

FIG. 3 is a switching circuit diagram according to the present invention;

FIG. 4 is a schematic diagram of the voltage monitor + PLC circuit design of the present invention;

FIG. 5 is a schematic diagram of the voltage transmitter + PLC circuit design of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention. The components of the embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

It is noted that relational terms such as "first" and "second," and the like, may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, or module that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, or module. The term "comprising", without further limitation, means that the element so defined is not excluded from the list of additional identical elements in a process, method, or module that comprises the element.

The features and properties of the present invention are described in further detail below with reference to examples.

Example 1

Referring to fig. 1 to 3, the present embodiment will be described by taking an example of automatic switching of a 27.5KV bus secondary voltage circuit of a railway traction substation.

The 27.5kV bus of the railway traction substation is generally provided with voltage transformers 3YH, 5YH, 4YH and 6YH, wherein 3YH and 5YH are generally a group, and 4YH and 6YH are generally a group. When the voltage transformer works, 3YH and 5YH work, 4YH and 6YH work as standby, the voltage transformer is used for acquiring a bus voltage at the side of 27.5kV and converting the bus voltage into AC100V according to a certain proportion, the working voltage transformer AC100V is used for a voltage loop for relay protection and measurement, and AC100V output by the standby voltage transformer at the secondary side serves as standby.

The automatic switching system for the secondary voltage loop of the embodiment mainly comprises a voltage transformer (YH) connected to a 27.5kV bus, a bypass circuit, a monitoring module, a switching module and an output circuit, wherein the output end of the voltage transformer is connected with the input end of the bypass circuit, and the output end of the bypass circuit is connected with the input end of the output circuit. The monitoring module is a voltage monitor (YJ), wherein: the voltage monitor of the present embodiment includes a voltage monitor 3YJ, a voltage monitor 4YJ, a voltage monitor 5YJ, and a voltage monitor 6YJ which are connected correspondingly to the respective voltage transformers and have an interlock function in pairs; the normally open contact of the voltage monitor 3YJ is connected in series with the normally closed contact of the voltage monitor 4YJ, while the normally open contact of the voltage monitor 4YJ is connected in series with the normally closed contact of the voltage monitor 3YJ to form an interlock circuit, the normally open contact of the voltage monitor 5YJ is connected in series with the normally closed contact of the voltage monitor 6YJ, and the normally open contact of the voltage monitor 6YJ is connected in series with the normally closed contact of the voltage monitor 5YJ to form an interlock circuit.

Further, the switching module of the present embodiment includes a switching circuit, which is a pure relay control circuit, and includes a first automatic switch QK1, a dual position relay, a second automatic switch QK3, an intermediate relay, and a display circuit, to realize the basic function of switching, wherein the switching circuit includes a switching circuit, and the switching circuit includes a first automatic switch QK1, a dual position relay, a second automatic switch QK3, an intermediate relay, and a display circuit

The input end of the monitoring module is connected with the output end of the voltage transformer, and the output end of the monitoring module is connected with the input end of the double-position relay, namely the double-position relay comprises 2 groups of ZJ3-4 and ZJ5-6, and the input ends of two coils of 1 group of ZJ3-4 are respectively connected with the output ends of the voltage monitors 3YJ and 4 YJ; two coil input ends of the other group of coils ZJ5-6 are respectively connected with output ends of voltage monitors 5YJ and 6 YJ; the input of first automatic transfer switch is connected with voltage transformer's output, the output simultaneously with two position relay ZJ3-4, ZJ5-6 coil input is connected, the one end of second automatic transfer switch is connected with voltage transformer's output, the other end is connected on the connected node of the coil of two position relay and contact, two position relay's ZJ3-4, ZJ5-6 contact output and auxiliary relay's 1ZJ, 2ZJ, 3ZJ, 4ZJ coil input corresponds and is connected, auxiliary relay's 1ZJ, 2ZJ, 3ZJ, 4ZJ contact output passes through display circuit and is connected with output circuit's input.

The display circuit of the present embodiment includes display lamps LED1, LED2, LED3, LED4 connected in series with the respective contacts of the intermediate relay, and a manual/automatic state display switch QK4 and manual and automatic state display lamps LED5, LED 6; the contacts of the intermediate relays 1ZJ, 2ZJ, 3ZJ and 4ZJ correspond to the display lamps LED1, LED2, LED3 and LED4 one by one and are connected in series, the output ends of the display lamps LED1, LED2, LED3 and LED4 are connected with an output circuit, and the manual/automatic state display switch QK4 and the second automatic change-over switch QK3 are connected in series, so that the working state of the bus corresponding to each voltage transformer (YH) can be accurately displayed.

To further explain, in order to prevent the automatic switching system from malfunctioning or being unable to be normally used due to an emergency, a manual switching circuit may be added to the switching circuit, the manual switching circuit including a first manual switch QK2 and first and second input/output switches ZK1 and ZK2 and a diode D1, a diode D2, a diode D3 and a diode D4; the output end of the first manual switch QK2 is connected with a first input/push-out switch ZK1 and a second input/push-out switch ZK2, the input ends of a diode D1 and a diode D2 are connected in parallel with the output end of the first input/push-out switch ZK1, the output end of a diode D1 is connected with the 1ZJ contact of the intermediate relay, and the output end of a diode D2 is connected with the 2ZJ contact of the intermediate relay; the input terminals of the diode D3 and the diode D4 are connected in parallel to the output terminal of the second input/output switch ZK2, the output terminal of the diode D3 is connected to the 3ZJ contact of the relay, and the output terminal of the diode D4 is connected to the 4ZJ contact of the relay.

When the buses corresponding to the 3YH and/or 5YH have faults, the mutual inductance voltage converted by the voltage transformer is output to the first manual switch QK2, the mutual inductance voltage is transmitted to the communicated ZK1, an operator knows that the buses corresponding to the 3YH and/or 5YH have faults through the secondary buses, at the moment, the ZK1 is manually disconnected, the intermediate relays corresponding to the ZK2, the 4YH and the 6YH are switched on, and the intermediate relays are simultaneously electrified and connected with the output end to complete manual circuit switching.

In practical use, when the automatic switching function of the secondary voltage loop is failed in case of emergency, the judgment can not be reasonably carried out, and at the moment, the judgment and the switching are carried out manually, so an emergency control circuit is also arranged in the switching module, and comprises an emergency control switch A3-4, an emergency control switch A4-3, an emergency control switch A5-6 and an emergency control switch A6-5; the input ends of the emergency control switch A3-4, the emergency control switch A4-3, the emergency control switch A5-6 and the emergency control switch A6-5 are connected in parallel with the output end of the first automatic switch QK 1; the output ends of the emergency control switch A3-4 and the emergency control switch A4-3 are connected in parallel with the coil input end of the double-set relay ZJ 3-4; the output ends of the emergency control switch A5-6 and the emergency control switch A6-5 are connected in parallel with the coil input end of the double-position relay ZJ 5-6. Wherein, A3-4 is the emergency control switch for switching the voltage transformer 4YH by the voltage transformer 3YH, A4-3 is the emergency control switch for switching the voltage transformer 3YH by the voltage transformer 4YH, A5-6 is the emergency control switch for switching 6YH by 5YH, A6-5 is the emergency control switch for switching 5YH by 6YH, in an emergency situation, the voltage output by the voltage transformer no longer passes through the voltage monitor, but when the emergency control switch a3-4 is pressed, the corresponding 4-a1 is connected with the 4-a2 node, the ZJ3-4 of the double-position relay is switched in a set mode, 14 and 13 of the 2ZJ of the intermediate relay are electrified, the contacts 2-5 and 2-9 are electrified, the LED2 is lightened, the emergency switching operation of switching the 3YH to the 4YH is completed, and similarly, other switching under the emergency operation is also realized through the corresponding emergency control switch.

The automatic switching method of the secondary voltage loop, which is completed by the automatic switching system of the secondary voltage loop, comprises the following steps:

two 27.5KV buses are used as an input circuit, two voltage transformers are connected to the two buses, a No. 3 voltage transformer (3YH) and a No. 4 voltage transformer (4YH) are arranged on one bus, a No. 5 voltage transformer (5YH) and a No. 6 voltage transformer (6YH) are arranged on the other bus, when the bus is used, the 3YH and the 5YH form a group, the 4YH and the 6YH form a group, one group works, the other group is used as a standby, the output end is a secondary bus, and an air switch is installed in a bypass circuit; the bypass circuit mainly comprises parallel 1KK, 2KK, 3KK and 4KK which are respectively correspondingly connected with IN and OUT of 3YH, 4YH, 5YH and 6YH, and the corresponding open circuit is closed to realize the communication of one way corresponding to the bypass circuit so as to manually switch under emergency or special conditions. Taking initial use of 3YH and 5YH as an example, air switches 1KK, 2KK, 3KK and 4KK on the bypass circuit corresponding to 3YH and 5YH are all in a closed state, and when 3YH and 5YH are in a normal working state, mutual inductance voltage converted by the voltage transformer is directly input into the output circuit; when the first automatic transfer switch QK1 is turned to the automatic position, the corresponding node of QK1 is turned on as shown in fig. 3, the manual/automatic status display switch QK4 is turned to the automatic status, and the automatic position indicator LED6 is turned on for display, which shows that after the operating power supply + KM and-KM is turned on, the nodes 3-11 and 3-14 of 3YJ in the voltage monitor 3YJ-4YJ are turned off, and the nodes 4-21 and 4-22 of 4YJ are turned on.

When the voltage monitor 3YJ monitors that the voltage is smaller than the rated voltage 100V, the nodes 3-11 and 3-14 of the 3YJ in the voltage monitor are closed, the nodes 4-21 and 4-22 of the 4YJ are kept closed, the voltage monitor 4YJ is switched on, the nodes 4-1 and 4-10 of the ZJ3-4 of the double-position relay are electrified, the second automatic change-over switch QK3 is automatically opened, the contacts 15-1 and 4-5 of the ZJ3-4 of the double-position relay are switched on, the 2ZJ of the intermediate relay is electrified, the switching current is output and is switched through an output circuit, the 4YH input is simultaneously, the 4YH input indicator lamp LED2 is switched on for displaying, and the switching function of automatically switching the 3YH to the 4YH is realized.

Similarly, after the corresponding bus has a fault when the 4YH works, the 4-11 and 4-14 nodes of the voltage monitor 4YJ are closed, the 3-21 and 3-22 nodes of the 3YJ are kept closed, the reset nodes 3-2 and 3-9 of the ZJ3-4 of the double-position relay are switched on, the second automatic change-over switch QK3 is automatically opened, the contacts 15-1 and 3-6 of the ZJ3-4 of the double-position relay are switched on, the 1ZJ of the intermediate relay is electrified to output the switching current and perform switching through an output circuit, and the 3YH is switched on and the 3YH input indicator light LED1 is switched on for displaying, so that the switching function of automatically switching the 3YH by the 4YH is realized. Similarly, after the bus corresponding to the 5YH fails, the set nodes 5-1 and 5-10 of the ZJ5-6 of the double-position relay are switched on to complete the switching of the 5YH-6YH, and after the bus corresponding to the 6YH fails, the reset nodes 5-2 and 5-9 of the ZJ5-6 of the double-position relay are switched on to complete the switching of the 6YH-5 YH.

Example 2

Different from the embodiment 1 and the embodiment 2, the automatic switching system of the secondary voltage loop of the invention cancels a bypass circuit, is additionally provided with a Programmable Logic Controller (PLC), takes the model Siemens 1214C as an example for explanation, and realizes the automatic switching of the secondary voltage loop. The method specifically comprises the following steps:

the input terminal of the voltage monitor is connected to the secondary voltage loop, and referring to fig. 4, the voltage monitor of the present embodiment includes a voltage monitor 3YJ, a voltage monitor 4YJ, a voltage monitor 5YJ, and a voltage monitor 6YJ connected to the voltage transformer, and the output terminals of the voltage monitor 3YJ, the voltage monitor 4YJ, the voltage monitor 5YJ, and the voltage monitor 6YJ are respectively connected to the input terminal I of the programmable controller_a0.6、I_a0.7、I_b0.1、I_b0.2Connecting; the output end of the PLC is connected with the input end of the switching module, and the output end of the switching module is connected with the input end of the output circuit.

Simultaneously in order to satisfy the in-service use demand, combine PLC automatic control and remote control function, still added remote control module (YD) in the switching module of this embodiment, with telemechanical control system is supporting, realizes remote switch through interface connection, this telemechanical control system belongs to conventional commercial product, can realize the telemechanical control function of this embodiment can.

The input end of the first automatic change-over switch QK1 is connected with a 24V power supply, the automatic output end of the first automatic change-over switch is connected with the Ia0.0 input end of the PLC, the automatic output end of the first automatic change-over switch is connected with the input end of the remote control circuit, and the output end of the manual change-over switch is connected with the input end of the Ia0.1 of the PLC.

The remote control module of the embodiment comprises a remote control switch YD3-4, a remote control switch YD4-3, a remote control switch YD5-6 and a remote control switch YD6-5, wherein the input ends of the remote control switch YD3-4, the remote control switch YD4-3, the remote control switch YD5-6 and the remote control switch YD6-5 are respectively connected with a set node of a ZJ3-4, a reset node of a ZJ3-4, a set node of a ZJ5-6 and a reset node of a ZJ5-6 of a double-position relay correspondingly, and circuit switching can be completed by the remote control module through remote control on each node of the double-position relays ZJ3-4 and the ZJ5-6 under the automatic switching state.

The automatic switching method of the secondary voltage loop of the embodiment is realized by the following steps:

the 24VDC is used as a double power supply, two paths of 24V switching power supplies supply power to a system after passing through a redundant power supply module, mutual inductance voltages output by 4 paths of voltage transformers are input to corresponding voltage monitors 3YJ, 4YJ, 5YJ and 6YJ, output ends of the voltage monitors 3YJ, 4YJ, 5YJ and 6YJ are respectively connected with input ends of Ia0.6, Ia0.7, Ib0.1 and Ib0.2 of the PLC, output ends of intermediate relays 1ZJ, 2ZJ, 3ZJ and 4ZJ are respectively connected with input ends of Ia0.2, Ia0.3, Ia0.4 and Ia0.5 of the PLC, calibration signal values are set in the PLC through a program, Q0.0, Q0.1, Q0.2 and Q0.3 of the output end of the PLC are respectively connected with a circuit for converting from 3YH to 4YH, converting from 3YH to 3YH, converting from 5 to 6YH and 5 of the switching circuit, and a backflow preventing diode is arranged on the circuit.

In the using process, when the mutual inductance voltage converted by the voltage transformer 3YH is less than 100V, the 3-21 and 3-22 nodes of the voltage monitor 3YJ are connected, the 3YJ sends a signal to the PLC from the Ia0.6 end, the PLC analyzes and sends an action signal to Q0.0 after receiving the signal according to a set program, the switching module completes the switching of the 3YH to 4YH according to the switching method of the embodiment 1 after receiving the switching command of the 3YH to 4YH, namely, ZJ3-4 setting nodes 4-1 and 4-10 of the double-position relay are electrified, the action voltage passes through ZJ3-4 contact 15-1 and 4-5 of the double-position relay after passing through the second automatic switch, 2ZJ of the intermediate relay is electrified, the switching current is output and switched through the output circuit, the 4YH is thrown, and the 4YH throw indicator light LED2 is turned on and displayed at the same time, so as the switching function of the 3YH is automatically switched to 4YH, at this time, 4YH and 5YH were operated.

After the 28-27 nodes of the automatic switching input end of the PLC are switched on, the PLC does not receive the input signal of the voltage monitor according to a set program any more, and the circuit switching is completely controlled by the remote control circuit YD; after the 25-26 nodes of the manual switching input end of the PLC are connected, the PLC does not receive input signals of the voltage monitor YJ any more according to a set program, and the connection and disconnection of each node of the voltage monitor are manually adjusted to enable the PLC to make different output signals for different input signals through the set program, so that the PLC controls the input and the exit of each voltage transformer to complete circuit switching.

Example 4

Different from embodiment 3, the monitoring module is a voltage transmitter (YB) of 4 to 20mA, see fig. 5, the voltage transmitters are YB1, YB2, YB3 and YB4, the input ends of the voltage transmitters are connected with the output ends of the voltage transformers 3YH, 4YH, 5YH and 6YH, and the output ends of the voltage transmitters YB1, YB2, YB3 and YB4 are connected with the output end of a of the PLC_I0、A_I1、A_I2And A_I3The input ends are connected.

the 24VDC is used as a double power supply, two 24V switching power supplies supply power to a system after passing through a redundant power supply module, if the voltage output by the 3YH is less than 100V, the current output by the voltage transmitter YB1 according to a set proportion is reduced, the PLC sets a calibration current according to a program, the PLC outputs an action signal to Q0.0 according to the input current analysis at the moment, the 3 YH-to-4 YH circuit completes circuit switching after receiving the signal, the circuit switching process is the same as that of the embodiment 1, and the automatic switching of a secondary voltage loop is completed.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims

1. A secondary voltage loop automatic switching system is characterized by comprising a voltage transformer, a monitoring module, a switching module and an output circuit;

2. The automatic switching system of a secondary voltage loop according to claim 1, wherein the switching module comprises a switching circuit, the switching circuit comprises a first automatic switch, a double-position relay, a second automatic switch, an intermediate relay and a display circuit;

3. The automatic switching system of secondary voltage loop according to claim 2, wherein said switching module further comprises a manual switching circuit and a remote control module, an emergency control circuit;

4. The automatic switching system of a secondary voltage loop according to any one of claims 1 to 3, further comprising a Programmable Logic Controller (PLC), wherein the output end of the monitoring module is connected with the input end of the PLC, and the output end of the PLC is connected with the input end of the switching module.

5. The automatic switching system of a secondary voltage loop according to claim 4, wherein the monitoring module is a voltage transformer, the output terminal of the voltage transformer is connected to the input terminal of the programmable controller, and the output terminal of the programmable controller is connected to the input terminal of the switching circuit.

6. The automatic switching system of a secondary voltage loop according to claim 4, wherein the monitoring module is a voltage monitor, the output terminal of the voltage transformer is connected to the input terminal of the voltage monitor, the output terminal of the voltage monitor is connected to the input terminal of the programmable controller, and the output terminal of the programmable controller is connected to the input terminal of the switching module;

the voltage monitor comprises a voltage monitor 3YJ, a voltage monitor 4YJ, a voltage monitor 5YJ and a voltage monitor 6YJ which are correspondingly connected with the voltage transformer, and the output ends of the voltage monitor 3YJ, the voltage monitor 4YJ, the voltage monitor 5YJ and the voltage monitor 6YJ are respectively connected with the input end I of the programmable controller_a0.6、I_a0.7、I_b0.1、I_b0.2And (4) connecting.

7. The automatic switching system of the secondary voltage circuit according to any one of claims 1 to 3, wherein the monitoring module is a voltage monitor, and the voltage monitor comprises a voltage monitor 3YJ, a voltage monitor 4YJ, a voltage monitor 5YJ and a voltage monitor 6YJ which are correspondingly connected with each voltage transformer and have an interlocking function in pairs; the normally open contact of the voltage monitor 3YJ is connected in series with the normally closed contact of the voltage monitor 4YJ, and the normally open contact of the voltage monitor 4YJ is connected in series with the normally closed contact of the voltage monitor 3YJ to form an interlock circuit; a normally open contact of the voltage monitor 5YJ is connected in series with a normally closed contact of the voltage monitor 6YJ, and a normally open contact of the voltage monitor 6YJ is connected in series with a normally closed contact of the voltage monitor 5YJ to form an interlock circuit; the output ends of the voltage monitor 3YJ and the voltage monitor 4YJ are respectively connected with the input end of the double-position relay ZJ 3-4; the output ends of the voltage monitor 5YJ and the voltage monitor 6YJ are respectively connected with the input end of the double-position relay ZJ 5-6.

8. The automatic switching system of a secondary voltage loop according to any one of claims 1 to 3, further comprising a bypass circuit, wherein an input terminal of the bypass circuit is connected to an output terminal of the voltage transformer, and an output terminal of the bypass circuit is connected to an input terminal of the output circuit.

9. A secondary voltage loop automatic switching method implemented by using the secondary voltage loop automatic switching system according to claim 1, comprising the steps of:

10. A secondary voltage loop automatic switching method implemented by using the secondary voltage loop automatic switching system according to claim 1, comprising the steps of: