CN116317113B - Intelligent power distribution cabinet based on Internet of things - Google Patents

Abstract

The application provides an intelligent power distribution cabinet based on the Internet of things, which comprises a control host used for the power distribution cabinet to work, wherein the control host is provided with a control system and a communication system, and the communication system is connected with a control computer; wherein the control system comprises: a plurality of memory units, each of the memory units for storing a control mode; and an execution controller configured to read a control mode in one of the storage units based on a control instruction of the control computer, and control the operation of the power distribution cabinet based on the control mode. The application is characterized in that a plurality of storage units are arranged in a control host of a power distribution cabinet, and each storage unit is used for storing a control mode; and a plurality of corresponding execution controllers are provided and are configured to read a control mode in one of the storage units based on a control instruction of the control computer, and control the operation of the power distribution cabinet based on the control mode.

Description

Intelligent power distribution cabinet based on Internet of things

Technical Field

The application relates to the field of power distribution cabinets, in particular to an intelligent power distribution cabinet based on the Internet of things.

Background

The types of the power distribution cabinets are many, the power distribution cabinets can work in different environments, and when the power distribution cabinets are set, the work of the power distribution cabinets is generally controlled by setting a fixed control mode based on environmental factors; however, all working environments can be changed along with external factors, so that when the working environments are changed, the basic operation mode of the power distribution cabinet needs to be regulated and controlled; the load connected with the power distribution cabinet is not fixed, and when the load end is changed to a certain extent, the operation mode of the power distribution cabinet needs to be regulated and controlled correspondingly.

However, the existing technical means can only realize manual adjustment, and the manual adjustment requires professional technicians to rewrite the set operation mode, and in the process, shutdown maintenance is required, so that the load end cannot work normally.

Disclosure of Invention

In view of this, the application is realized by the following technical scheme:

an intelligent power distribution cabinet based on the Internet of things comprises

A control host machine for the power distribution cabinet to work,

the control host is provided with a control system and a communication system, and the communication system is connected with the control computer; wherein the control system comprises:

a plurality of memory units, each of the memory units for storing a control mode;

and an execution controller configured to read a control mode in one of the storage units based on a control instruction of the control computer, and control the operation of the power distribution cabinet based on the control mode.

Preferably, the execution controller includes:

an event monitoring unit;

an evaluation unit; and

at least comprising a first actuator and a second actuator;

the first executor is used for reading a first control mode in the corresponding storage unit based on a first control instruction of the control computer, and controlling a first running state of the power distribution cabinet based on the first control mode;

when the second executor reads the second control mode in the corresponding storage unit to replace the first control mode based on the second control instruction of the control computer, the event monitoring unit is used for calling the operation parameters of all the components in the power distribution cabinet, the evaluation unit is used for evaluating the operation parameters of all the components in the power distribution cabinet in the first operation state, and if the operation parameters of all the components in the power distribution cabinet in the first operation state are in the set threshold value, the second executor reads the second control mode in the corresponding storage unit to control the second operation state of the power distribution cabinet based on the second control instruction of the control computer.

Preferably, when the first executor reads the first control mode from the corresponding storage unit, the first executor correspondingly provides an activated first control signal, and enables a first multi-thread driver under the first control signal, wherein each component of the driving power distribution cabinet corresponding to the first multi-thread driver works according to the first operation mode;

the first multithreading driver is internally provided with a first task manager module, the first task manager module is provided with a plurality of first task management units, each first task management unit is used for providing a corresponding first control circuit for each component, and the first control circuit is used for providing voltage, current, power signals and activity signals for the corresponding component, wherein the voltage, current, power signals and activity signals work in a first operation mode.

Preferably, the event monitoring unit is connected to the first task manager modules, and is configured to monitor a voltage, a current, a power signal and an activity signal provided by the first control circuit under each first task manager unit for the corresponding component to operate in the first operation mode.

Preferably, the second actuator correspondingly provides an activated second control signal when the corresponding memory cell reads the second control pattern, the second control signal enabling the evaluation unit driver and the second multithreaded driver in accordance with a set timing,

the evaluation unit driver is used for driving the evaluation unit, wherein the event monitoring unit is used for calling voltage, current, power signals and activity signals of all parts of the power distribution cabinet working in a first operation mode;

the evaluation unit is used for evaluating whether the voltage, the current, the power signals and the activity signals of all the components in the power distribution cabinet in the first running state are all within a set threshold value, if so, a feedback signal is sent to the event monitoring unit, and the event monitoring unit starts all the components of the power distribution cabinet corresponding to the second multithreading driver to work according to a second running mode;

the second multithreading driver is internally provided with a second task manager module, the second task manager module is provided with a plurality of second task management units, each second task management unit is used for providing a corresponding second control circuit for each component, and the second control circuit is used for providing voltage, current, power signals and activity signals for the corresponding component, wherein the voltage, current, power signals and activity signals work in a second operation mode.

Preferably, the event monitoring unit is connected to the second task manager module, and is configured to monitor a voltage, a current, a power signal and an activity signal provided by the second control circuit under each second task management unit for the corresponding component to operate in the second operation mode.

The application is characterized in that a plurality of storage units are arranged in a control host of a power distribution cabinet, and each storage unit is used for storing a control mode; and a plurality of corresponding execution controllers are provided and are configured to read a control mode in one of the storage units based on a control instruction of the control computer, and control the operation of the power distribution cabinet based on the control mode.

The application can correspondingly preset a control mode in each storage unit, and can correspondingly rewrite the voltage, current, power signals and activity signals which work in the running mode for corresponding components in each control mode through a control computer.

Drawings

FIG. 1 is a schematic general diagram of the framework of the present application;

fig. 2 is a schematic diagram of a detailed framework of an embodiment of the present application.

Detailed Description

The present application will be further described in detail with reference to the following examples, which are only for the purpose of illustrating the application and are not to be construed as limiting the scope of the application.

Example 1

Referring to fig. 1, the application provides an intelligent power distribution cabinet based on the internet of things, which comprises

A control host machine for the power distribution cabinet to work,

the control host is provided with a control system and a communication system, and the communication system is connected with the control computer; wherein the control system comprises:

a control computer, the storage unit for storing a first control mode;

an execution controller configured to read a first control pattern in a storage unit therein based on a control instruction of a control computer, and control operation of the power distribution cabinet based on the first control pattern.

In the above, the execution controller includes:

an event monitoring unit;

an evaluation unit; and

at least a first actuator;

the first executor is used for reading a first control mode in the corresponding storage unit based on a first control instruction of the control computer, and controlling a first running state of the power distribution cabinet based on the first control mode;

when the first executor reads the first control mode from the corresponding storage unit, the first executor correspondingly provides an activated first control signal, and enables a first multithreading driver under the first control signal, wherein each component of the driving power distribution cabinet corresponding to the first multithreading driver works according to the first operation mode;

the first multithreading driver is internally provided with a first task manager module, the first task manager module is provided with a plurality of first task management units, each first task management unit is used for providing a corresponding first control circuit for each component, and the first control circuit is used for providing voltage, current, power signals and activity signals for the corresponding component, wherein the voltage, current, power signals and activity signals work in a first operation mode.

The event monitoring units are connected to the first task manager modules and are used for monitoring voltage, current, power signals and activity signals which are provided by the first control circuits under each first task management unit for corresponding components and work in a first operation mode.

The application can correspondingly preset a first control mode in the storage unit, and can correspondingly rewrite the voltage, current, power signals and activity signals which work in the operation mode for corresponding components in the first control mode through the control computer.

Example 2

Referring to fig. 1 and 2, the application provides an intelligent power distribution cabinet based on the internet of things, comprising

A control host machine for the power distribution cabinet to work,

the control host is provided with a control system and a communication system, and the communication system is connected with the control computer; wherein the control system comprises:

a first storage unit for storing a first control mode;

a second storage unit for storing a second control mode;

an execution controller configured to read a first control mode in the first storage unit based on a first control instruction of the control computer, and control operation of the power distribution cabinet based on the first control mode;

or, an execution controller configured to read a second control mode in the second storage unit based on a second control instruction of the control computer, and control the operation of the power distribution cabinet based on the second control mode;

in the above, the execution controller includes:

an event monitoring unit;

an evaluation unit; and

at least comprising a first actuator and a second actuator;

the first executor is used for reading a first control mode in the corresponding storage unit based on a first control instruction of the control computer, and controlling a first running state of the power distribution cabinet based on the first control mode;

when the second executor reads the second control mode in the corresponding storage unit to replace the first control mode based on the second control instruction of the control computer, the event monitoring unit is used for calling the operation parameters of all the components in the power distribution cabinet, the evaluation unit is used for evaluating the operation parameters of all the components in the power distribution cabinet in the first operation state, and if the operation parameters of all the components in the power distribution cabinet in the first operation state are in the set threshold value, the second executor reads the second control mode in the corresponding storage unit to control the second operation state of the power distribution cabinet based on the second control instruction of the control computer.

When the first executor reads the first control mode from the corresponding storage unit, the first executor correspondingly provides an activated first control signal, and enables a first multithreading driver under the first control signal, wherein each component of the driving power distribution cabinet corresponding to the first multithreading driver works according to the first operation mode;

the first multithreading driver is internally provided with a first task manager module, the first task manager module is provided with a plurality of first task management units, each first task management unit is used for providing a corresponding first control circuit for each component, and the first control circuit is used for providing voltage, current, power signals and activity signals for the corresponding component, wherein the voltage, current, power signals and activity signals work in a first operation mode.

The event monitoring units are connected to the first task manager modules and are used for monitoring voltage, current, power signals and activity signals which are provided by the first control circuits under each first task management unit for corresponding components and work in a first operation mode.

The second actuator correspondingly provides an activated second control signal when the corresponding memory cell reads the second control mode, the second control signal enables the evaluation unit driver and the second multithread driver according to a set time sequence,

the evaluation unit driver is used for driving the evaluation unit, wherein the event monitoring unit is used for calling voltage, current, power signals and activity signals of all parts of the power distribution cabinet working in a first operation mode;

the evaluation unit is used for evaluating whether the voltage, the current, the power signals and the activity signals of all the components in the power distribution cabinet in the first running state are all within a set threshold value, if so, a feedback signal is sent to the event monitoring unit, and the event monitoring unit starts all the components of the power distribution cabinet corresponding to the second multithreading driver to work according to a second running mode;

the second multithreading driver is internally provided with a second task manager module, the second task manager module is provided with a plurality of second task management units, each second task management unit is used for providing a corresponding second control circuit for each component, and the second control circuit is used for providing voltage, current, power signals and activity signals for the corresponding component, wherein the voltage, current, power signals and activity signals work in a second operation mode.

Preferably, the event monitoring unit is connected to the second task manager module, and is configured to monitor a voltage, a current, a power signal and an activity signal provided by the second control circuit under each second task management unit for the corresponding component to operate in the second operation mode.

At least two storage units are arranged in a control host of the power distribution cabinet, and each storage unit is used for storing a control mode; and a plurality of corresponding execution controllers are arranged and are configured to read the control mode in one storage unit based on the control instruction of the control computer, the operation of the power distribution cabinet is controlled based on the control mode, one control mode can be correspondingly preset in each storage unit, and the voltage, the current, the power signal and the activity signal which work in the operation mode can be provided for the corresponding component in each control mode through corresponding overwriting of the control computer, so that the corresponding operation mode can be provided when the working environment and the load of the power distribution cabinet change.

Among other things, the components can be understood as various electronic components, monitoring elements, transformers, circuit breakers, and monitoring devices within the power distribution cabinet.

The foregoing has shown and described the basic principles, principal features and advantages of the application. It will be understood by those skilled in the art that the present application is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present application, and various changes and modifications may be made without departing from the spirit and scope of the application, which is defined in the appended claims. The scope of the application is defined by the appended claims and equivalents thereof.

Claims (3)

1. Intelligent power distribution cabinet based on thing networking, its characterized in that: comprising

A control host machine for the power distribution cabinet to work,

the control host is provided with a control system and a communication system, and the communication system is connected with the control computer; wherein the control system comprises:

a plurality of memory units, each of the memory units for storing a control mode;

an execution controller configured to read a control mode in one of the storage units based on a control instruction of the control computer, and control operation of the power distribution cabinet based on the control mode;

the execution controller includes:

an event monitoring unit;

an evaluation unit; and

at least comprising a first actuator and a second actuator;

the first executor is used for reading a first control mode in the corresponding storage unit based on a first control instruction of the control computer, and controlling a first running state of the power distribution cabinet based on the first control mode;

when the second executor reads a second control mode in the corresponding storage unit to replace the first control mode based on a second control instruction of the control computer, the event monitoring unit is used for calling the operation parameters of all the components in the power distribution cabinet, the evaluation unit is used for evaluating the operation parameters of all the components in the power distribution cabinet in the first operation state, and if the operation parameters of all the components in the power distribution cabinet in the first operation state are in a set threshold value, the second executor reads the second control mode in the corresponding storage unit to control the second operation state of the power distribution cabinet based on the second control instruction of the control computer;

when the first executor reads the first control mode from the corresponding storage unit, the first executor correspondingly provides an activated first control signal, and enables a first multithreading driver under the first control signal, wherein each component of the driving power distribution cabinet corresponding to the first multithreading driver works according to the first operation mode;

the first multithreading driver is internally provided with a first task manager module, the first task manager module is provided with a plurality of first task management units, each first task management unit is used for providing a corresponding first control circuit for each component, and the first control circuit is used for providing voltage, current, power signals and activity signals for the corresponding component, wherein the voltage, current, power signals and activity signals work in a first operation mode;

the event monitoring units are connected to the first task manager modules and are used for monitoring voltage, current, power signals and activity signals which are provided by the first control circuits under each first task management unit for corresponding components and work in a first operation mode.

2. The intelligent power distribution cabinet based on the internet of things according to claim 1, wherein: the second actuator correspondingly provides an activated second control signal when the corresponding memory cell reads the second control mode, the second control signal enables the evaluation unit driver and the second multithread driver according to a set time sequence,

the evaluation unit driver is used for driving the evaluation unit, wherein the event monitoring unit is used for calling voltage, current, power signals and activity signals of all parts of the power distribution cabinet working in a first operation mode;

the evaluation unit is used for evaluating whether the voltage, the current, the power signals and the activity signals of all the components in the power distribution cabinet in the first running state are all within a set threshold value, if so, a feedback signal is sent to the event monitoring unit, and the event monitoring unit starts all the components of the power distribution cabinet corresponding to the second multithreading driver to work according to a second running mode;

the second multithreading driver is internally provided with a second task manager module, the second task manager module is provided with a plurality of second task management units, each second task management unit is used for providing a corresponding second control circuit for each component, and the second control circuit is used for providing voltage, current, power signals and activity signals for the corresponding component, wherein the voltage, current, power signals and activity signals work in a second operation mode.

3. The intelligent power distribution cabinet based on the internet of things according to claim 2, wherein: the event monitoring units are connected to the second task manager modules and are used for monitoring voltage, current, power signals and activity signals which are provided by the second control circuits under each second task management unit for corresponding components and work in a second operation mode.