CN114460874B - 5GAAU equipment remote monitoring energy-saving control method and system - Google Patents

Abstract

The invention discloses a 5GAAU equipment remote monitoring energy-saving control method and a system, wherein the method comprises the following steps: the intelligent ammeter acquires actual power of the terminal equipment through a pre-configured communication connection, and uploads the actual power to the cloud server; the cloud server analyzes the actual power to obtain the working power-on state of the terminal equipment; the cloud server side sends a working instruction to the intelligent ammeter according to the working power-on state of the terminal equipment and the time stage of the cloud server side; and the intelligent ammeter controls the terminal equipment according to the working instruction. The intelligent ammeter is used for controlling the timing power failure or power-on of the terminal equipment according to the working instruction by combining the working power-on state of the terminal equipment and the time stage of the terminal equipment, solving the technical problem of power consumption waste caused by the fact that the terminal equipment keeps working in idle time, ensuring the normal operation of the terminal equipment and timely feedback when the problem occurs, saving energy, being safe and having strong practicability.

Description

5GAAU equipment remote monitoring energy-saving control method and system

Technical Field

The invention relates to the technical field of energy-saving control, in particular to a 5GAAU equipment remote monitoring energy-saving control method and system.

Background

In a mobile telephone system, indoor distribution system equipment is installed in weak wells or pipe wells in a building (wherein, the indoor distribution system is a successful scheme for improving mobile communication environment in a building aiming at indoor user groups, and is characterized in that signals of a mobile communication base station are uniformly distributed at each corner of the room by using related technical means, so that an indoor area is ensured to have ideal signal coverage).

With the arrival of 5G, 5G base station is gradually integrated into our life like water and electricity, and is not serving us at any time, 5G base station is the core equipment of 5G network, provides wireless coverage, realizes wireless signal transmission between wired communication network and wireless terminal, AAU equipment is a device for transmitting signals to 5G base station, and is formed by fusing RRU and antenna.

For example, when the indoor distribution system device is specifically a 5GAAU device, the indoor distribution system device is typically provided with a common electric meter by the owner and is free to supply power and manually meter-check and charge.

Under normal conditions, after work and at night, working office staff in a building are greatly reduced, idle time appears at night, and communication requirements are greatly reduced, but the 5GAAU equipment still keeps working normally, so that the 5GAAU equipment keeps working normally in the idle time, and electricity waste is easily caused.

Accordingly, there is a need in the art for improvement.

Disclosure of Invention

The problem of power consumption waste is easily caused by the fact that the 5GAAU equipment in the prior art keeps working normally in idle time.

The present invention aims to at least partially alleviate or solve at least one of the above mentioned problems. In one aspect, the invention provides a 5GAAU device remote monitoring energy-saving control method, wherein the method comprises the following steps:

the intelligent ammeter acquires actual power of the terminal equipment through a pre-configured communication connection, and uploads the actual power to the cloud server;

the cloud server analyzes the actual power to obtain the working power-on state of the terminal equipment;

the cloud server side sends a working instruction to the intelligent ammeter according to the working power-on state of the terminal equipment and the time stage of the cloud server side;

and the intelligent ammeter controls the terminal equipment according to the working instruction.

In an embodiment, the step of obtaining the actual power of the terminal device by the smart meter through a preconfigured communication connection and uploading the actual power to the cloud server includes:

the intelligent ammeter samples the current and voltage of the terminal equipment and converts signals to obtain sampling data;

the intelligent ammeter performs electric energy metering on the sampling data to obtain actual power;

and uploading the actual power to the cloud server by the intelligent ammeter.

In one embodiment, the step of analyzing the actual power consumption by the cloud server to obtain the working power-on state of the terminal device includes:

presetting the minimum working power of terminal equipment on a cloud server side;

comparing and analyzing the lowest working power of the terminal equipment with the actual power;

and obtaining the working power-on state of the terminal equipment according to the comparison analysis result.

In one embodiment, in the step of obtaining the operation power-on state of the terminal device according to the comparison analysis result, the operation power-on state includes: an operating state, an energized inactive state, and a de-energized state;

when the actual power is greater than or equal to the minimum power, the terminal equipment is in a working state;

when the actual power is smaller than the minimum working power and the actual power is larger than zero, the terminal equipment is in a power-on non-working state;

when the actual power is equal to zero, the terminal device is in a power-off state.

In one embodiment, the step of sending, by the cloud server, a working instruction to the smart meter according to the working power-on state of the terminal device and in combination with the time period in which the cloud server is located includes:

judging the time stage of the terminal equipment, wherein the time stage comprises a working time stage and a non-working time stage;

if the terminal equipment is in the non-working time stage, and when the working power-on state of the terminal equipment is the power-on non-working state, the cloud server side sends a power-off working instruction to the intelligent ammeter.

In one embodiment, the step of determining a time period in which the terminal device is located, where the time period includes an active time period and an inactive time period further includes:

if the terminal equipment is in the non-working time stage, and when the working power-on state of the terminal equipment is the power-off state, the cloud server side sends a power-off working instruction to the intelligent ammeter;

if the terminal equipment is in the non-working time stage, and when the working power-on state of the terminal equipment is the working state, the cloud server side sends a power-on working instruction to the intelligent ammeter.

In one embodiment, the step of determining a time period in which the terminal device is located, where the time period includes an active time period and an inactive time period further includes:

if the terminal equipment is in the working time stage, and when the working power-on state of the terminal equipment is in the power-off state, the cloud server side sends a power-on instruction to the intelligent ammeter.

On the other hand, the invention also provides a 5GAAU equipment remote monitoring energy-saving control system for realizing the 5GAAU equipment remote monitoring energy-saving control method, wherein the system comprises:

the intelligent ammeter is used for collecting and recording electricity consumption data of the terminal equipment, uploading the electricity consumption data of the terminal equipment to the cloud server and executing a working instruction issued by the cloud server;

the gateway is used for communication connection between the intelligent ammeter and the cloud server;

and the cloud server side is used for reading and storing the electricity consumption data uploaded by the intelligent electric meter, analyzing the electricity consumption data and sending a working instruction to the intelligent electric meter in combination with the time stage of the terminal equipment.

In one embodiment, the smart meter includes: the system comprises a CPU, an electric energy metering chip, a communication module, a data memory and a relay switch, wherein the electric energy metering chip, the communication module, the data memory and the relay switch are connected with the CPU;

the information acquisition module is used for sampling the current and the voltage of the terminal equipment and converting signals to obtain sampling data;

the electric energy metering chip is used for metering the electric energy of the sampled data;

the communication module is used for communication connection between the CPU and the cloud server;

the data storage is used for storing electricity consumption data of the terminal equipment;

the relay switch is used for the CPU to conduct power utilization control on the terminal equipment according to the working instruction.

In one embodiment, the system comprises an intelligent device terminal, wherein the intelligent device terminal is connected with the cloud server, and the intelligent device terminal is used for acquiring electricity utilization data of the terminal device and sending a working instruction to the intelligent ammeter through the cloud server.

The invention has the beneficial effects that: the invention discloses a 5GAAU equipment remote monitoring energy-saving control method and a system, wherein the method comprises the following steps: the intelligent ammeter acquires actual power of the terminal equipment through a pre-configured communication connection, and uploads the actual power to the cloud server; the cloud server analyzes the actual power to obtain the working power-on state of the terminal equipment; the cloud server side sends a working instruction to the intelligent ammeter according to the working power-on state of the terminal equipment and the time stage of the cloud server side; and the intelligent ammeter controls the terminal equipment according to the working instruction. The intelligent ammeter is used for controlling the timing power failure or power-on of the terminal equipment according to the working instruction by combining the working power-on state of the terminal equipment and the time stage of the terminal equipment, solving the technical problem of power consumption waste caused by the fact that the terminal equipment keeps working in idle time, ensuring the normal operation of the terminal equipment and timely feedback when the problem occurs, saving energy, being safe and having strong practicability.

Drawings

Fig. 1 is a schematic flow chart of a method for remotely monitoring and controlling energy saving of 5GAAU equipment.

Fig. 2 is a schematic flow chart of obtaining actual power by the smart meter.

Fig. 3 is a schematic flow chart of a cloud server for acquiring a working power-on state of a terminal device.

Fig. 4 is a schematic structural diagram of a 5GAAU device remote monitoring energy-saving control system provided by the invention.

Fig. 5 is a schematic structural diagram of the smart meter provided by the invention.

Reference numerals:

100. a smart meter; 200. a gateway; 300. cloud server end; 400. a platform intelligent terminal; 500. and (5) a mobile intelligent terminal.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clear and clear, the present invention will be further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and rear … …) are included in the embodiments of the present invention, the directional indications are merely used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present invention.

In a mobile telephone system, indoor distribution system equipment is installed in weak wells or pipe wells within a building. Under normal conditions, after working and at night, working office staff in a building are greatly reduced, idle time appears at night, communication requirements are greatly reduced, but indoor distributed system equipment (such as 5GAAU equipment) still keeps working normally, so that the 5GAAU equipment keeps working normally in the idle time, and electricity consumption is easy to cause.

Based on the problems existing in the prior art, the embodiment provides a 5GAAU equipment remote monitoring energy-saving control method, which obtains the actual power of the terminal equipment through a smart electric meter and uploads the actual power to a cloud server; the cloud server analyzes the actual power to obtain the working power-on state of the terminal equipment; the cloud server side sends a working instruction to the intelligent ammeter according to the working power-on state of the terminal equipment and the time stage of the cloud server side; the intelligent ammeter controls the terminal equipment according to the working instruction, namely, the intelligent ammeter controls the timing power failure or power-on of the terminal equipment according to the working instruction.

Various non-limiting embodiments of the present invention are described in detail below with reference to the attached drawing figures.

Referring to fig. 1, fig. 1 shows a method for remotely monitoring and controlling energy saving of a 5GAAU device according to an embodiment of the present invention, where the method includes:

s100, the intelligent ammeter acquires actual power of the terminal equipment through a pre-configured communication connection, and uploads the actual power to the cloud server.

In order to realize the remote monitoring energy-saving control of the 5GAAU equipment, the embodiment of the invention adopts the intelligent ammeter to acquire the actual power of the terminal equipment through the pre-configured communication connection and upload the actual power to the cloud server. For example, the smart meter is electrically connected with the 5GAAU device (terminal device), and the actual power consumption of the 5GAAU device is obtained through the smart meter. And the actual power consumption of the 5GAAU equipment is uploaded to the cloud server side.

Referring to fig. 2, step 100 specifically includes:

s110, the intelligent ammeter samples the current and voltage of the terminal equipment and converts signals to obtain sampling data;

s120, the intelligent ammeter measures electric energy of the sampled data to obtain actual power;

s130, the intelligent ammeter uploads the actual power to the cloud server.

For example, the intelligent ammeter is used for sampling the current and the voltage of the terminal equipment and converting signals to obtain sampling data, then the intelligent ammeter is used for measuring the electric energy of the sampling data to obtain actual electric power, and then the intelligent ammeter is used for uploading the actual electric power to the cloud server.

S200, the cloud server analyzes the actual power to obtain the working power-on state of the terminal equipment.

In the embodiment of the invention, the cloud server side analyzes the actual power to obtain the working power-on state of the terminal equipment.

The step can obtain the working power-on state of the terminal equipment by analyzing the actual power.

Referring to fig. 3, step 200 specifically includes:

s210, presetting the minimum working power of terminal equipment on a cloud server side;

s220, comparing and analyzing the lowest working power of the terminal equipment with the actual power;

s230, working power-on states of the terminal equipment are obtained according to the comparison analysis result.

For example, the minimum working power of the terminal equipment, that is, the minimum power when the terminal equipment (5 GAAU equipment) works, is preset on the cloud server side, then the minimum working power of the terminal equipment (5 GAAU equipment) and the actual power are subjected to comparison analysis, and then the working power-on state of the terminal equipment (5 GAAU equipment) is obtained according to the comparison analysis result.

In the normal operating state of the terminal device (5 GAAU device), the terminal device (5 GAAU device) has an operating power-on state of 3, that is, the operating power-on state includes: an active state, an on-state, and an off-state.

When the actual electric power is greater than or equal to the lowest working power, the terminal equipment (5 GAAU equipment) is in a working state;

when the actual electric power is smaller than the minimum working power and the actual electric power is larger than zero, the terminal equipment (5 GAAU equipment) is in a power-on non-working state;

when the actual power is equal to zero, the terminal device (5 GAAU device) is in the power-off state.

And S300, the cloud server side sends a working instruction to the intelligent ammeter according to the working power-on state of the terminal equipment and the time stage of the terminal equipment.

According to the embodiment of the invention, the cloud server side sends the working instruction to the intelligent ammeter according to the working power-on state of the terminal equipment and the time stage of the terminal equipment.

The step 300 specifically includes:

judging the time stage of the terminal equipment, wherein the time stage comprises an operating time stage and a non-operating time stage, the operating time stage is when the terminal equipment normally operates, the non-operating time stage is the idle time of the terminal equipment, for example, the operating time stage is set to be 6:00-22:00, and the non-operating time stage is set to be 22:00-6:00.

If the terminal equipment is in the non-working time stage, and when the working power-on state of the terminal equipment is the power-on non-working state, the cloud server side sends a power-off working instruction to the intelligent ammeter;

if the terminal equipment is in a non-working time stage, and when the working power-on state of the terminal equipment is in a power-off state, the cloud server side sends a power-off working instruction to the intelligent electric meter, namely the server side sends a power-off maintenance working instruction to the intelligent electric meter;

if the terminal equipment is in the non-working time stage, and when the working electrifying state of the terminal equipment is the working state, the cloud server side sends an electrifying working instruction to the intelligent electric meter, namely the cloud server side sends an electrifying maintaining working instruction to the intelligent electric meter;

if the terminal equipment is in the working time stage, and when the working electrifying state of the terminal equipment is the electrifying non-working state, the cloud server side sends an instruction for maintaining electrifying to the intelligent ammeter;

if the terminal equipment is in the working time stage, and when the working power-on state of the terminal equipment is in the power-off state, the cloud server side sends a power-on working instruction to the intelligent ammeter;

if the terminal equipment is in the working time stage, and when the working electrifying state of the terminal equipment is the working state, the cloud server side sends an electrifying working instruction to the intelligent electric meter, namely the cloud server side sends a power-on maintaining working instruction to the intelligent electric meter.

S400, the intelligent ammeter controls the terminal equipment according to the working instruction.

In the embodiment of the invention, the intelligent ammeter controls the terminal equipment according to the working instruction.

For example, if the terminal device is in the non-working time stage, and when the working power-on state of the terminal device is the power-on non-working state, the cloud server side sends a power-off working instruction to the intelligent electric meter, and the intelligent electric meter controls the terminal device to power off according to the power-off working instruction, so that the electricity waste of the terminal device in the non-working time stage is avoided.

If the terminal equipment is in the working time stage, and when the working electrifying state of the terminal equipment is in the power-off state, the cloud server side sends an electrifying working instruction to the intelligent ammeter, and the intelligent ammeter controls the terminal equipment to electrify according to the electrifying working instruction, so that the automatic electrifying in the working time stage is realized.

Example 1:

the AAU device is a device for transmitting signals to the 5G base station, and is mainly formed by fusing RRU and an antenna, in this embodiment, the terminal device is specifically a 5GAAU device, the smart meter obtains actual power of the 5GAAU device through a preconfigured communication connection, and uploads the actual power to the cloud server, the lowest working power of the 5GAAU device is preset on the cloud server, and then the lowest working power of the 5GAAU device and the actual power are compared and analyzed, and the working power-on state of the terminal device is obtained according to the comparison and analysis result.

When the actual electric power is greater than the lowest working power of the 5GAAU equipment, the 5GAAU equipment is in use, namely a working state; when the actual electric power is smaller than the lowest working power of the AAU device, the 5GAAU device is not currently in use, namely in a power-on and power-off state (starting from the power-on state of the 5GAAU device, namely without considering the power-off condition of the 5GAAU device), and when the actual electric power is equal to zero, the AAU device is in the power-off state, namely in the power-off state.

And then judging the time stage of the 5GAAU equipment, wherein the time stage comprises an operating time stage and a non-operating time stage, for example, the operating time stage is set to be 6:00-22:00, and the non-operating time stage is 22:00-6:00. It should be appreciated that the above-described setup period of operation is not limited to the above-described 6:00-22:00, i.e., the period of operation may be set otherwise, and is not limited thereto.

When the time stage of the 5GAAU equipment is a non-working time stage, namely the time of the 5GAAU equipment is 22:00-6:00, and at this time, when the actual power of the 5GAAU equipment is smaller than the lowest working power of the AAU equipment, the situation that no user is in use, namely in a power-on non-working state, is indicated, at this time, the cloud server side sends a power-off working instruction to the intelligent electric meter, and the intelligent electric meter controls the 5GAAU equipment to power off according to the power-off working instruction.

When the time period of the 5GAAU equipment reaches the working time period, namely when the time of the AAU equipment reaches 6:00-22:00, for example, when the time reaches 6:00, and the actual power of the AAU equipment is zero, namely in a power-off state, the cloud server side sends an electrifying working instruction to the intelligent electric meter, and the intelligent electric meter controls the 5GAAU equipment to be electrified according to the electrifying working instruction. The embodiment realizes the timing power failure or power-on of the intelligent ammeter according to the working instruction control terminal equipment (5 GAAU equipment), realizes the real-time monitoring, saves energy, is safe and has strong practicability.

On the other hand, referring to fig. 4, the present invention further provides a 5GAAU device remote monitoring energy saving control system for implementing the 5GAAU device remote monitoring energy saving control method according to the foregoing embodiment, where the system includes:

the smart meter 100 is configured to collect and record power consumption data of a terminal device (5 GAAU device), upload the power consumption data of the terminal device (5 GAAU device) to the cloud server 300, and execute a working instruction issued by the cloud server 300;

the gateway 200 is used for communication connection between the smart meter 100 and the cloud server, and the gateway 200 comprises a LoRa 4G gateway, a LoRa wann gateway and a LoRa wann 4G gateway; namely, the smart meter 100 is in communication connection with the cloud server 300 through the LoRa 4G gateway or the LoRa wann 4G gateway, so as to realize data transmission.

The cloud server 300 is configured to read and store the electricity consumption data uploaded by the smart meter 100, analyze the electricity consumption data, and send a working instruction to the smart meter 100 in combination with a time period in which the terminal device is located. The power consumption data comprise real-time current, real-time voltage and actual power consumption of the terminal equipment.

In one embodiment, referring to fig. 5, the smart meter 100 includes: the system comprises a CPU, an electric energy metering chip, a communication module, a data memory and a relay switch, wherein the electric energy metering chip, the communication module, the data memory and the relay switch are connected with the CPU;

the information acquisition module is used for sampling the current and the voltage of the terminal equipment and converting signals to obtain sampling data;

the electric energy metering chip is used for metering the electric energy of the sampled data;

the communication module is used for communication connection between the CPU and the cloud server 300;

the data storage is used for storing electricity consumption data of the terminal equipment;

the relay switch is used for the CPU to conduct power utilization control on the terminal equipment according to the working instruction.

In this embodiment, the communication module includes 485 communication, infrared communication and carrier communication, can directly accurately measure the electric energy and the electric quantity of terminal equipment through information acquisition module and electric energy metering chip, if sample terminal equipment's current and voltage through information acquisition module, and signal conversion obtains sampling data, then electric energy metering chip is used for carrying out electric energy metering to sampling data, combines 485 communication, infrared communication, can realize long-range meter reading, establishes the table.

In one embodiment, the system includes an intelligent device terminal, where the intelligent device terminal is connected to the cloud server 300, and the intelligent device terminal is configured to obtain electricity consumption data of a terminal device, and send a working instruction to the smart meter 100 through the cloud server 300.

In this embodiment, the power consumption data of the terminal device may be obtained through the intelligent device terminal, so as to achieve real-time monitoring, for example, the power consumption of the terminal device (5 GAAU device) in one day, the degree of the power consumption of the device terminal may be uploaded to the cloud server 300, and the user or the staff may read through the intelligent device terminal. The intelligent device terminal comprises a mobile intelligent terminal 500 and a platform intelligent terminal 400, wherein the mobile intelligent terminal 500 is connected with the platform intelligent terminal 400, the mobile intelligent terminal 500 is, for example, a mobile phone APP, electricity consumption data of the cloud server 300 about the terminal device is obtained through the mobile phone APP, or the cloud server 300 sends the electricity consumption data of the terminal device to the platform intelligent terminal 400, and the platform intelligent terminal 400 sends the electricity consumption data of the terminal device to the mobile phone APP, so that real-time monitoring is achieved. Or directly issuing a working instruction to the cloud server 300 through the mobile phone APP or the platform intelligent terminal 400 so as to control the working power-on state of the terminal equipment.

To sum up: the invention provides a 5GAAU equipment remote monitoring energy-saving control method and a system, wherein the method comprises the following steps: the intelligent ammeter acquires actual power of the terminal equipment through a pre-configured communication connection, and uploads the actual power to the cloud server; the cloud server analyzes the actual power to obtain the working power-on state of the terminal equipment; the cloud server side sends a working instruction to the intelligent ammeter according to the working power-on state of the terminal equipment and the time stage of the cloud server side; and the intelligent ammeter controls the terminal equipment according to the working instruction. The intelligent ammeter is used for controlling the timing power failure or power-on of the terminal equipment according to the working instruction by combining the working power-on state of the terminal equipment and the time stage of the terminal equipment, solving the technical problem of power consumption waste caused by the fact that the terminal equipment keeps working in idle time, ensuring the normal operation of the terminal equipment and timely feedback when the problem occurs, saving energy, being safe and having strong practicability.

It is to be understood that the invention is not limited in its application to the examples described above, but is capable of modification and variation in light of the above teachings by those skilled in the art, and that all such modifications and variations are intended to be included within the scope of the appended claims.

Claims (7)

1. A 5GAAU device remote monitoring energy saving control method, the method comprising:

the intelligent ammeter acquires actual power of the terminal equipment through a pre-configured communication connection, and uploads the actual power to the cloud server;

the cloud server analyzes the actual power to obtain the working power-on state of the terminal equipment;

the cloud server side sends a working instruction to the intelligent ammeter according to the working power-on state of the terminal equipment and the time stage of the cloud server side, and the cloud server side comprises: judging the time stage of the terminal equipment, wherein the time stage comprises a working time stage and a non-working time stage;

if the terminal equipment is in the non-working time stage, and when the working power-on state of the terminal equipment is the power-on non-working state, the cloud server side sends a power-off working instruction to the intelligent ammeter;

the cloud server side sends a power-off working instruction to the intelligent ammeter when the working power-on state of the terminal equipment is a power-off state if the terminal equipment is in a non-working time stage;

if the terminal equipment is in a non-working time stage and the working electrifying state of the terminal equipment is a working state, the cloud server side sends an electrifying working instruction to the intelligent ammeter, or if the terminal equipment is in a working time stage and the working electrifying state of the terminal equipment is a power-off state, the cloud server side sends an electrifying instruction to the intelligent ammeter;

and the intelligent ammeter controls the terminal equipment according to the working instruction.

2. The method for remotely monitoring and controlling energy saving of 5GAAU equipment according to claim 1, wherein the step of obtaining the actual power of the terminal equipment by the smart meter through a pre-configured communication connection and uploading the actual power to the cloud server comprises:

the intelligent ammeter samples the current and voltage of the terminal equipment and converts signals to obtain sampling data;

the intelligent ammeter performs electric energy metering on the sampling data to obtain actual power;

and uploading the actual power to the cloud server by the intelligent ammeter.

3. The method for remotely monitoring and controlling energy saving of 5GAAU equipment according to claim 1, wherein the step of analyzing the actual power consumption by the cloud server to obtain the working power-on state of the terminal equipment includes:

presetting the minimum working power of terminal equipment on a cloud server side;

comparing and analyzing the lowest working power of the terminal equipment with the actual power;

and obtaining the working power-on state of the terminal equipment according to the comparison analysis result.

4. The method for remotely monitoring and controlling energy saving of 5GAAU equipment according to claim 3, wherein in the step of obtaining the working power-on state of the terminal equipment according to the comparison analysis result, the working power-on state includes: an operating state, an energized inactive state, and a de-energized state;

when the actual power is greater than or equal to the minimum power, the terminal equipment is in a working state;

when the actual power is smaller than the minimum working power and the actual power is larger than zero, the terminal equipment is in a power-on non-working state;

when the actual power is equal to zero, the terminal device is in a power-off state.

5. A 5GAAU equipment remote monitoring energy saving control system for implementing the 5GAAU equipment remote monitoring energy saving control method of any one of claims 1-4, the system comprising:

the intelligent ammeter is used for collecting and recording electricity consumption data of the terminal equipment, uploading the electricity consumption data of the terminal equipment to the cloud server and executing a working instruction issued by the cloud server;

the gateway is used for communication connection between the intelligent ammeter and the cloud server;

and the cloud server side is used for reading and storing the electricity consumption data uploaded by the intelligent electric meter, analyzing the electricity consumption data and sending a working instruction to the intelligent electric meter in combination with the time stage of the terminal equipment.

6. The 5GAAU equipment remote monitoring energy saving control system of claim 5, wherein the smart meter comprises: the system comprises a CPU, an electric energy metering chip, a communication module, a data memory and a relay switch, wherein the electric energy metering chip, the communication module, the data memory and the relay switch are connected with the CPU;

the information acquisition module is used for sampling the current and the voltage of the terminal equipment and converting signals to obtain sampling data;

the electric energy metering chip is used for metering the electric energy of the sampled data;

the communication module is used for communication connection between the CPU and the cloud server;

the data storage is used for storing electricity consumption data of the terminal equipment;

the relay switch is used for the CPU to conduct power utilization control on the terminal equipment according to the working instruction.

7. The system of claim 5GAAU equipment remote monitoring and energy saving control system, wherein the system comprises an intelligent equipment terminal, the intelligent equipment terminal is connected with the cloud server, and the intelligent equipment terminal is used for acquiring electricity consumption data of the terminal equipment and sending a working instruction to the intelligent ammeter through the cloud server.