CN113709956B - Light remote control system, transformer substation light remote control system and transformer substation light remote control method - Google Patents

Abstract

The application relates to the technical field of transformer substations, and provides a lamplight remote control system, a transformer substation lamplight remote control system and a transformer substation lamplight remote control method, which are used for remotely controlling illumination or closing of an illumination assembly. The light remote control system includes: the main controller is configured to acquire a first control instruction and acquire and send a second control instruction according to the first control instruction; the communication module is in communication connection with the main controller and is configured to acquire and send a second control instruction sent by the main controller; the control loop is connected with the communication module and is electrically connected with the lighting assembly; the control loop is configured to receive a second control instruction sent by the communication module and turn on or off the lighting assembly according to the second control instruction. The application can realize remote control of the illumination of the transformer substation and timely find the defects and potential safety hazards of the transformer substation.

Description

Light remote control system, transformer substation light remote control system and transformer substation light remote control method

Technical Field

The application relates to the technical field of substations, in particular to a lamplight remote control system, a substation lamplight remote control system and a substation lamplight remote control method.

Background

In the related art, the daily patrol of the substation includes: live patrol and video surveillance patrol. Wherein, video monitoring inspection includes: when faults and accidents occur in the transformer substation during daytime patrol and night patrol, monitoring personnel are firstly required to be scheduled to check the field conditions of equipment through video monitoring, determine the conditions and the range of the faults and the accidents, and then report and repair the faults and the accidents.

When a transformer substation breaks down and accidents at night, the monitoring camera has the phenomena of insufficient brightness, insufficient illumination area and the like in fixed-point illumination of the LED in the video monitoring night inspection process, and the faults and the accident points are not easy to find and determine. It is desirable to have enough light inspection equipment for accident judgment, and only on site can the lighting devices of the substation be turned on, with a time lag. Because the lighting device can not be turned on or turned off by remote control, defects and potential safety hazards in the inspection process are not easy to find, the accident expansion or large-area power failure accident is easy to cause, and the accident potential exists.

Content of the application

In view of the foregoing, a first aspect of the present application provides a light remote control system, which solves the problems of inflexible light remote control, poor energy saving effect, inconvenient management and maintenance, and low working efficiency.

A first aspect of the present application provides a light remote control system for remotely controlling illumination or turning off of an illumination assembly, the light remote control system comprising: the main controller is configured to acquire a first control instruction and acquire and send a second control instruction according to the first control instruction; the communication module is in communication connection with the main controller and is configured to acquire and send the second control instruction sent by the main controller; the control loop is connected with the communication module and is electrically connected with the lighting assembly; the control loop is configured to receive the second control instruction sent by the communication module and turn on or off the lighting assembly according to the second control instruction.

According to the lamplight remote control system provided by the first aspect of the application, the lamplight remote control system is used for acquiring and processing the first control instruction through the main controller to generate the second control instruction, then the second control instruction is sent through the communication module, the response speed is high, and the second control instruction is adopted to turn on the lighting assembly for lighting through the connection of the control loop. Or the lighting assembly is closed by cutting off the control loop, so that the intelligent centralized management and control of the lighting assembly are realized, the lighting assembly has a remote control function, the control mode is intelligent and flexible, a good energy-saving effect is achieved, the management and maintenance are convenient, and the aims of saving energy, reducing emission and saving operation cost are fulfilled.

With reference to the first aspect, in one possible implementation manner, the control loop includes: a power supply; the switch conversion element is connected with the power supply through a wire; and the first illumination switch is connected with the switch conversion element and is connected with the illumination assembly.

With reference to the first aspect, in one possible implementation manner, the light remote control system further includes: the light controller is in communication connection with the communication module, and is electrically connected with the switch conversion element, so that the light controller is configured to receive the second control instruction sent by the communication module and generate and send a control signal according to the second control instruction, and the switch conversion element is configured to open the switch conversion element through the control signal so as to switch on the power supply or close the switch conversion element so as to switch off the power supply.

With reference to the first aspect, in one possible implementation manner, the switching element is a relay.

With reference to the first aspect, in one possible implementation manner, the lighting assembly includes: a second illumination switch; the lighting lamp is connected with the second lighting switch; and the emergency lamp is electrically connected with the first lighting switch and the second lighting switch respectively.

With reference to the first aspect, in one possible implementation manner, the main controller includes: an internal processor; and the display device is in communication connection with the internal processor.

The application aims to provide a transformer substation lamplight remote control system, which solves the problems that defects and potential safety hazards in the inspection process are difficult to find and accident hazards exist in the background art.

The remote control system of substation lamplight provided in the second aspect of the present application is used for realizing remote control of an illumination assembly in a substation, and the remote control system of substation lamplight includes: a monitoring center; the lamplight remote control system in any technical scheme; wherein, the main controller is arranged in the monitoring center.

According to the transformer substation lamplight remote control system provided by the second aspect of the application, an operator remotely controls lamplight illumination in the transformer substation through the monitoring center, and the lamplight is turned on at the first time to realize remote control illumination, so that the problem of illumination of a remote control illumination assembly is effectively solved.

With reference to the second aspect, in one possible implementation manner, the substation light remote control system further includes: the switch is in communication connection with the monitoring center; the video server is in communication connection with the switch; the communication module is arranged on the video server, the communication module is respectively in communication connection with the monitoring center and the switch, and the video server is provided with a downlink 485 control port connected with the control loop.

The application aims to provide a remote control method for substation lamplight, which solves the problems that defects and potential safety hazards in the inspection process are difficult to find and accident potential exists in the background art.

The third aspect of the application provides a remote control method for substation lamplight, which adopts a remote control system for the substation lamplight, and the remote control method for the substation lamplight comprises the following steps: acquiring a first control instruction; generating and sending a second control instruction according to the first control instruction; and switching on or switching off the lighting assembly according to the second control instruction.

According to the substation lamplight remote control method provided by the third aspect of the application, the first control instruction is acquired to generate the second control instruction, so that the control loop is electrified or powered off, the response can be fast, the method is simple and reliable, and the lighting assembly can be correspondingly turned on or turned off according to the second control instruction.

With reference to the third aspect, in one possible implementation manner, the lighting assembly is turned on or off according to the second control instruction, and specifically includes: generating a control signal according to the second control instruction; switching on a control loop according to the control signal to turn on the lighting assembly; or switching off the control loop according to the control signal to switch off the lighting assembly.

Drawings

Fig. 1 is a schematic diagram illustrating a light remote control system according to some embodiments of the present application.

Fig. 2 is a schematic diagram illustrating the control loop of the light remote control system provided by the implementation shown in fig. 1.

Fig. 3 is a schematic diagram illustrating the components of the remote control system for light provided by the implementation shown in fig. 1.

Fig. 4 is a schematic diagram illustrating the components of the lighting assembly controlled by the remote control system for light provided by the implementation shown in fig. 1.

Fig. 5 is a schematic diagram illustrating the composition of a main controller of the light remote control system provided by the implementation shown in fig. 1.

Fig. 6 is a schematic diagram illustrating components of a remote control system for substation light according to some embodiments of the present application.

Fig. 7 is a schematic diagram of the remote control system for substation lamplight provided by the implementation shown in fig. 6.

Fig. 8 is a schematic diagram illustrating the composition of a remote control system for substation light provided by another implementation shown in fig. 6.

Fig. 9 is a schematic diagram illustrating the composition of a substation light remote control system provided by the implementation shown in fig. 8.

Fig. 10 is a flowchart of a remote control method for substation lamplight according to some embodiments of the present application.

Fig. 11 is a flowchart of a remote control method for substation lamplight according to another embodiment of the present application.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

Fig. 1 is a schematic diagram illustrating a light remote control system according to some embodiments of the present application. As shown in fig. 1, the light remote control system is for implementing remote control of lighting assembly 200 lighting or turning off, and light remote control system 100 includes: a main controller 110, a communication module 120 and a control loop 130.

The main controller 110 is configured to acquire a first control instruction and acquire and transmit a second control instruction according to the first control instruction, where the first control instruction may be input by a manual input manner, for example, the first control instruction includes a close instruction or an open instruction. The main controller 110 analyzes the first control command after acquiring the first control command to determine and identify that the first control command is a close command, an open command or other commands. And when the first controller recognizes that the first control instruction is an opening instruction or a closing instruction, generating a second control instruction and sending the second control instruction. The second control instruction comprises lamp on information or lamp off information.

The communication module 120 is communicatively connected to the main controller 110, and the communication module 120 is configured to acquire and send the second control instruction sent by the main controller 110, so as to ensure that the second control instruction is sent stably and reliably.

The control loop 130 is connected to the communication module 120, and the control loop 130 is electrically connected to the lighting assembly 200. Wherein the control loop 130 is configured to turn the lighting assembly 200 on or off according to a second control instruction.

Specifically, the control circuit 130 is connected to the communication module 120 such that a second control command transmitted through the communication module 120 reaches the control circuit 130, and the control circuit 130 turns on the power of the lighting assembly 200 according to the second control command, thereby turning on the lighting assembly, or turns off the power of the lighting assembly 200 according to the second control command, thereby turning off the lighting assembly.

The light remote control system obtains and processes the first control command through the main controller 110 to generate a second control command, then sends the second control command through the communication module 120, has high response speed, and adopts the second control command to turn on the lighting assembly 200 for lighting through the connection of the control loop 130. Or the lighting assembly 200 is closed by cutting off the control loop, so that the intelligent centralized management and control of the lighting assembly 200 are realized, the lighting assembly 200 has a remote control function, the control mode is intelligent and flexible, a good energy-saving effect is achieved, the management and maintenance are convenient, and the aims of saving energy, reducing emission and saving operation cost are fulfilled.

Fig. 2 is a schematic diagram illustrating the components of a control loop in the light remote control system provided by the implementation shown in fig. 1. As shown in fig. 2, in one possible implementation, the control loop 130 includes: a power source 131, a switching element 133 and a first lighting switch 135.

The switching element 133 is connected to the power source 131 through a wire, and the power source 131 is an ac power source and has a voltage of 220 v. The switching element can be an automatic switching element with an isolation function, and can realize on-off control on a controlled circuit. Between the input part and the output part of the switching element, there is also an intermediate mechanism for coupling isolation of the input quantity, functional processing and driving of the output part.

The first illumination switch 135 is connected to the switch conversion element 133, and the first illumination switch 135 is connected to the illumination assembly 200. The switching element 133 may be automatically turned on or off, and when the switching element is turned on, the first illumination switch 135 is turned on with the power source 131, and the first illumination switch 135 is connected with the illumination assembly 200 through a wire, so that the illumination assembly 200 may be turned on to illuminate. The first illumination switch 135 may be a normally closed switch. The normally closed switch refers to a switch which is in a closed state under the condition that no external force acts on the switch, and when someone dials a switch button or the switch is controlled by an automatic device to dial, the switch is switched to be open. The first illumination switch 135 in this embodiment is switchable to be opened under the control of the switch switching element 133 to enable automatic control of the illumination assembly 200.

More specifically, the phase line of the control loop 130 coincides with the phase line in the first illumination switch 135, and the positive and negative poles of the control loop 130 coincide with the positive and negative poles in the first illumination switch 135. Ensures that interphase short circuit and homopolar illumination are not caused. The first lighting switch 135 is a normally closed remote control lighting master switch, and the first switch 135 is connected in series with the leakage protector by adopting an air switch with rated current, so that accidents caused by interphase short circuit and ground faults can be prevented.

Fig. 3 is a schematic diagram illustrating the components of the remote control system for light provided by the implementation shown in fig. 1. Fig. 7 is a schematic diagram of the remote control system for substation lamplight provided by the implementation shown in fig. 6. As shown in fig. 3, in one possible implementation, the light remote control system 100 further includes a light controller 140, where the light controller 140 is communicatively connected to the communication module 120, and the light controller 140 is electrically connected to the switch conversion element 133, so that the light controller 140 is configured to turn on the switch conversion element 133 to turn on the power source 131 or turn off the switch conversion element 133 to turn off the power source 131 by a control signal.

Specifically, the light controller 140 generates a control signal after receiving the second control instruction sent by the communication module 120, for example, the control signal may be a certain voltage, and the light controller 140 inputs the voltage into the switching element 133, so that the switching element 133 is turned on or off under the action of the voltage, and the switching element 133 can realize the control of powering on or powering off the control circuit 130.

More specifically, the switching conversion element 133 is a relay. Wherein the relay may be an intermediate relay. The use of an intermediate relay in the control loop 130 can increase the number of contacts and the contact capacity of the protection and control loop 140.

Fig. 4 is a schematic diagram illustrating the components of the lighting assembly controlled by the remote control system for light provided by the implementation shown in fig. 1. As shown in fig. 4, in one possible implementation, the lighting assembly 200 includes: a second lighting switch 210, a lighting fixture 220 and an emergency fixture 230.

The lighting fixture 220 is connected to the second lighting switch 210. In particular, the lighting fixture 220 may be a conventional lighting lamp to provide illumination for a substation.

The emergency light 230 is electrically connected to the first and second light switches 135 and 210, respectively. Specifically, under normal power-on conditions, the emergency light 230 and the light 220 can be controlled to be turned on or off simultaneously by the second light switch 210. The first illumination switch 135 is electrically connected with the emergency light 230, so that the emergency light 230 can be directly controlled to be turned on or off through the control loop 130 after the power of the illumination light 220 is cut off, and meanwhile, the emergency light 230 is connected with the second illumination switch 210, so that the emergency light 230 is manually and directly controlled to be turned on or off on site, and the requirement of on-site illumination is further ensured.

Fig. 5 is a schematic diagram illustrating the composition of a main controller in the light remote control system provided by the implementation shown in fig. 1. As shown in fig. 5, in one possible implementation, the main controller 110 includes: the display device 113 is in communication connection with the internal processor 111.

Specifically, the display device 113 may be a display screen. The internal processor 111 is provided with a memory module that stores a program and is capable of running the program. When the program runs, an illumination control unit is displayed on the display screen, and a closing button and an opening button are displayed in the illumination control unit. The closing button and the opening button are both control buttons. After clicking the control button, the internal processor 111 acquires the first control instruction, and the internal processor 111 processes the first control instruction to generate a second control instruction, where the second control instruction passes through the intra-office network control center converter and reaches the communication module 120 through the optical cable. By inputting the first control command through the display device 113, efficiency and reliability are improved.

Some implementations of the present application provide a remote control system 10 for substation lamplight, which is used for implementing remote control of an illumination assembly 200 in a substation, so as to prevent potential safety hazards and accident hazards caused by incapacitation of lamplight illumination in the substation, and further prevent accidents that a power failure range is continuously enlarged and a large-area power failure is generated due to influence of insufficient illumination on judging the power failure range.

Fig. 6 is a schematic diagram of a substation light remote control system provided by the implementation shown in fig. 1. As shown in fig. 6, the substation light remote control system 10 includes: a monitoring center 300 and the light remote control system 100 of any of the embodiments. Wherein the main controller 110 is disposed in the monitoring center.

Specifically, a plurality of image pickup devices, such as cameras, are provided in the substation, the image pickup devices being configured to take images of lines in the substation, and the monitoring center 300 is configured to receive video information taken by the image pickup devices to observe whether or not there is a line fault. More specifically, fig. 8 is a schematic structural diagram of a substation light remote control system provided by the implementation shown in fig. 6. As shown in fig. 8, the main controller 110 is disposed in the monitoring center 300, the internal processor 111 is disposed in the host of the monitoring center 300, the display device 113 is a display screen, and an operator can observe a region where a fault occurs through the display device 113 of the monitoring center 300. If it is confirmed that the area is malfunctioning, the operator inputs a first control command through the display device 113 of the monitoring center 300.

More specifically, the main controller 110 may be configured by calling out a control module without installing a webcam from the monitoring center 300, where the control module may install embedded software, and the control module with installed embedded software is used as the main controller 110.

Specifically, the lamplight remote control system 100 is applied to a transformer substation, so that the transformer substation lamplight remote control system 10 is suitable for night video monitoring inspection, night fault processing and accident judgment of the transformer substation, and can be popularized and applied to the transformer substation without on-site person on duty and video monitoring application.

More specifically, the operating personnel remotely controls the lighting in the transformer substation through the local network monitoring center 300, and the lighting is turned on at the first time to realize the remote control lighting, so that the problem of remote control lighting is effectively solved, and night video inspection and fault and accident handling are clearer and more clear. The method can prevent potential safety hazards and accident hazards caused by the fact that lamplight illumination cannot keep pace, and prevent large-area power failure accidents caused by expansion of power failure range due to insufficient illumination judgment.

Fig. 7 is a schematic diagram of the remote control system for substation lamplight provided by the implementation shown in fig. 6. Fig. 8 is a schematic diagram illustrating the composition of a remote control system for substation light provided by another implementation shown in fig. 6. Fig. 9 is a schematic diagram illustrating the composition of a substation light remote control system provided by the implementation shown in fig. 8. As shown in fig. 7 and 8, in one possible implementation, the substation light remote control system 10 further includes a switch 400 and a video server 500, with which the video server 500 is communicatively connected.

The switch 400 is communicatively connected to the monitoring center 300, wherein the switch 400 is a network device for forwarding electrical signals, and is capable of sending out a first control command inputted through the monitoring center 300.

Specifically, as shown in fig. 8, the communication module 120 is disposed on the video server 500, the communication module 120 is respectively connected with the monitoring center 300 and the switch 400 in a communication manner, and the video server 500 is provided with a downlink 485 control port connected with the control circuit 130.

More specifically, the video server 500 is an embedded device for compressing and processing video and audio data, and is used for acquiring video images shot by shooting devices arranged in a transformer substation, and transmitting the video images to the monitoring center 300 through an in-office network and an exchange. The operator can observe the fault condition at the monitoring center 300, thereby realizing the lighting or turning off of the lighting assembly 200 in the remote control substation. In addition, the video server 500 is provided with a 485 control port, and can perform data transmission, so that a second control command can be sent to the control loop 130. By transmitting the second control command by using the communication module 120 provided on the existing video server 500, the structural setup of the substation light remote control system is simplified.

The substation lamplight remote control system 100 has a remote control function, and the control mode is intelligent and flexible, so that a good energy-saving effect is achieved, management and maintenance are convenient, and the working environment and the working efficiency can be improved. In addition, the remote control system 100 of the transformer substation lamplight also ensures the frequent and stable power consumption demands of the power consumer and ensures the safe, stable and reliable operation of the company power grid.

More specifically, the video server 500 is externally connected with an intermediate relay for controlling the illumination power supply through a downlink 485 control port, so as to control the illumination power supply.

As shown in fig. 9, the lighting power switch in the station is a second lighting switch 210, and the load side of the second lighting switch 210 is added with a power line of the control circuit 130, and the phase line of the power line is consistent with the positive and negative poles and the lighting power switch in the station, so that interphase short circuit and non-lighting of the same pole are not caused.

The control power supply of the intermediate relay is connected with the power supply side of the remote control lighting master switch, wherein the remote control lighting master switch is a first lighting switch 135, the first lighting switch 135 is a normally closed remote control lighting master switch, and the total loop of the load sides of the emergency lamp 230 for emergency lighting and the lighting lamp 220 for original lighting in the station is connected with the load side of the remote control lighting master switch.

After the circuits and elements of the light remote control system 100 are connected, a network video monitoring system of an in-office network substation opens a page of the substation, selects an illumination control unit, clicks a control button, and the control button comprises an opening button and a closing button, then reaches a video server 500 of the substation through an optical cable through an in-office network control center converter, and is connected with an intermediate relay through a downlink 485 control port.

The power line controlled by the intermediate relay reaches the normally closed remote control lighting master switch, the emergency lighting and power supply is connected with the lighting assembly 200 at the load side of the original lighting switch in the station, so that all lighting in the station is instantly turned on, and the whole transformer substation is bright like a daytime. Therefore, the intelligent centralized management and control of the lighting equipment in the transformer substation are realized, the remote control function is realized, the control mode is intelligent and flexible, the good energy-saving effect is achieved, the intelligent illumination system can provide scientific management for the modern intelligent illumination industry, saves energy and reduces emission, can simplify personnel, saves operation cost, improves service quality, and is a complete informationized construction and intelligent control system solution. In addition, the power demand of the power consumer and the economic and social benefits of the company are effectively maintained on the whole, and the firm, safe, stable and reliable operation of the power grid is ensured.

Fig. 10 is a flowchart of a remote control method for substation lamplight according to some embodiments of the present application. Some implementations of the application provide a remote control method for substation lamplight, which is used for realizing remote control of a lighting assembly 200 in a substation, so that potential safety hazards and accident hazards caused by incapacitation of lamplight illumination in the substation can be prevented, and further accidents of large-area power failure caused by continuous expansion of a power failure range due to influence on judging the power failure range caused by insufficient illumination can be prevented.

As shown in fig. 10, the remote control method for the substation light includes:

step 101: the first control instruction is acquired, wherein the first control instruction can be acquired through a manual input mode. The first control instruction comprises a closing instruction or an opening instruction, and the response can be quickly and conveniently carried out. After the first control instruction is acquired, step 103 may be performed.

Step 103: and generating and sending a second control instruction according to the first control instruction. After the first control instruction is acquired, the first control instruction is processed to generate information which can be transmitted, namely a second control instruction, wherein the second control instruction comprises lamp on information or lamp off information. And if the first control instruction is a closing instruction, the generated second control instruction is the lamp closing information. If the first control instruction is an on instruction, the second control instruction is the on information. Therefore, step 105 can be executed according to the generated second control instruction, the method is simple, and the response speed is high.

Step 105: the lighting assembly is turned on or off according to the second control instruction. The control loop can be powered on or off according to the second control instruction, so that the lighting assembly 200 can be correspondingly turned on or off according to the second control instruction.

Fig. 11 is a flowchart of a remote control method for substation lamplight according to another embodiment of the present application. As shown in fig. 11, in one possible implementation, the lighting assembly is turned on or off according to the second control instruction, and specifically includes the following steps:

step 201: and generating a control signal according to the second control instruction. The second control command is further processed to generate a control signal, and the control signal can be a voltage to switch on the power supply of the control loop, so that the response speed of the control loop can be further improved, and the aim of quickly switching on or off the power supply is achieved.

Step 203: the control loop is turned on according to the control signal to turn on the lighting assembly. The control loop turns on the power according to the control signal so that the lighting assembly 200 can be turned on. Or (b)

Step 205: the control loop is cut off according to the control signal to turn off the lighting assembly, wherein the control loop is cut off according to the control signal to turn off the lighting assembly 200 in time, so as to achieve the purpose of saving electricity.

More specifically, the remote control method for the transformer substation lamplight is based on a control management system formed by multiple aspects of computer technology, automatic control, network communication, embedded software and the like, and the system adopts a modularized structural design, so that the system is simple, flexible and convenient to install. Through the monitoring software setting of the local network monitoring center, the intelligent centralized management and control of the lighting equipment can be realized by switching, remote control and the like.

The foregoing is only illustrative of the present application and is not to be construed as limiting thereof, but rather as presently claimed, and is intended to cover all modifications, alternatives, and equivalents falling within the spirit and scope of the application.

Claims (6)

1. A light remote control system for remotely controlling illumination or shut down of an illumination assembly, the light remote control system comprising:

the main controller is configured to acquire a first control instruction and acquire and send a second control instruction according to the first control instruction;

the communication module is in communication connection with the main controller and is configured to acquire and send the second control instruction sent by the main controller;

the control loop is connected with the communication module and is electrically connected with the lighting assembly;

the control loop is configured to receive the second control instruction sent by the communication module and turn on or off the lighting assembly according to the second control instruction;

a power supply;

a switching element connected to the power supply;

the first lighting switch is connected with the switch conversion element and connected with the lighting assembly, and the first lighting switch is formed by connecting an air switch with rated current with a leakage protector in series;

the light controller is in communication connection with the communication module and is electrically connected with the switch conversion element, so that the light controller is configured to receive the second control instruction, generate and send a control signal according to the second control instruction, the switch conversion element is configured to open the switch conversion element through the control signal to switch on the power supply or close the switch conversion element to switch off the power supply, and the switch conversion element is a relay;

a second illumination switch;

the lighting lamp is connected with the second lighting switch;

and the emergency lamp is electrically connected with the first lighting switch and the second lighting switch respectively.

2. A light remote control system as recited in claim 1 wherein said master controller comprises:

an internal processor;

and the display device is in communication connection with the internal processor.

3. A substation light remote control system, comprising:

a monitoring center;

a light remote control system as claimed in any one of claims 1 to 2;

wherein, the main controller is arranged in the monitoring center.

4. A substation light remote control system according to claim 3, characterized in that the substation light remote control system further comprises:

the switch is in communication connection with the monitoring center;

the video server is in communication connection with the switch;

the communication module is arranged on the video server, the communication module is respectively in communication connection with the monitoring center and the switch, and the video server is provided with a downlink 485 control port connected with the control loop.

5. A substation light remote control method, which adopts the substation light remote control system according to claim 3 or 4, characterized in that the substation light remote control method comprises:

acquiring the first control instruction;

generating and sending the second control instruction according to the first control instruction;

and switching on or switching off the lighting assembly according to the second control instruction.

6. The substation light remote control method according to claim 5, wherein the lighting assembly is turned on or off according to the second control command, specifically comprising:

generating a control signal according to the second control instruction;

switching on a control loop according to the control signal to turn on the lighting assembly; or (b)

And cutting off the control loop according to the control signal to turn off the lighting assembly.