CN111913395A - Intelligent building energy-saving control method and system - Google Patents

Abstract

The invention provides an intelligent building energy-saving control method and system, wherein the method comprises the following steps: monitoring a target area corresponding to a target intelligent building in real time, and judging whether a target user exists in the target area according to a monitoring result; if so, controlling the target intelligent building corresponding to the target area to be in a working state; otherwise, controlling the target intelligent building corresponding to the target area to be in a dormant state. Whether a user exists or not is judged conveniently, intelligent control is further carried out on the target intelligent building, and energy conservation is facilitated.

Description

Intelligent building energy-saving control method and system

Technical Field

The invention relates to the technical field of energy-saving control, in particular to an intelligent building energy-saving control method and system.

Background

At present, a control system of each equipment terminal, for example, an illumination control system, an air-conditioning heating and ventilation control system, an elevator control system and the like, is arranged in an intelligent building system, and most of the control systems are constructed by a professional software platform based on a standard protocol, each control system is deployed on a specific server, and the control process of the control system for the corresponding equipment terminal is generally controlled in a linkage manner according to preset control logic and by combining equipment terminal data, but if the equipment is not used, the equipment is still in a working state all the time, more electric energy is consumed, so the invention provides an intelligent building energy-saving control method and system.

Disclosure of Invention

The invention provides an intelligent building energy-saving control method and system, which are used for solving the technical problems.

The invention provides an intelligent building energy-saving control method, which comprises the following steps:

monitoring a target area corresponding to a target intelligent building in real time, and judging whether a target user exists in the target area according to a monitoring result;

if so, controlling the target intelligent building corresponding to the target area to be in a working state;

otherwise, controlling the target intelligent building corresponding to the target area to be in a dormant state.

In one possible way of realisation,

the in-process of carrying out real-time supervision to the target area that target intelligence building corresponds still includes:

obtaining a set of intelligent devices associated with the target intelligent building;

recording device information of each intelligent device in the intelligent device set, wherein the device information comprises: the device name and the device model of the intelligent device;

counting actual electric energy consumption information and actual flow consumption information of the intelligent device within a preset time period based on the device information;

performing data analysis on the actual electric energy consumption information and the actual current consumption information based on a data consumption model to obtain an electric energy consumption value and a current consumption value;

judging whether the electric energy consumption value is in a first consumption range or whether the current consumption value is in a second consumption range;

if yes, controlling the corresponding intelligent device to be in a dormant state, and meanwhile, controlling the intelligent device in the dormant state to work according to a dormancy alternation rule.

In one possible way of realisation,

controlling the target intelligent building corresponding to the target area to be in a working state process, comprising the following steps:

monitoring and acquiring current position information of a target user in the target area, wherein the current position information comprises: current position coordinates, a current orientation of the target user;

monitoring and acquiring user information of a target user in the target area, wherein the user information comprises: the height information of the target user and the vision information of the target user;

based on the current position information and the user information, adjusting the working power of the intelligent device in the working state corresponding to the target intelligent building;

and meanwhile, adjusting the intelligent device in the working state to an angle position and a height position corresponding to the target user of the target area.

In one possible way of realisation,

in the process of controlling the target intelligent building corresponding to the target area to be in the working state, the method further comprises the following steps:

acquiring and acquiring a first working temperature of a first device which is continuously in a working state, a second working temperature of a second device which is continuously in a dormant state and a third working temperature of a third device which is converted between the working state and the dormant state in the target intelligent building within the current time period, and storing the acquired first working temperature, second working temperature and third working temperature based on a distributed storage structure;

performing linear analysis on the first working temperature, the second working temperature and the third working temperature based on the linear time sequence to obtain a temperature linear analysis result;

acquiring a first attribute of the first device, a second attribute of the second device and a third attribute of the third device, and correcting a temperature linear analysis result based on the first attribute, the second attribute and the third attribute to obtain a corrected temperature result;

judging whether the temperature correction result is within a preset temperature range, if so, controlling each device to work according to a preset working mode;

and otherwise, acquiring the weight value of each device and sequencing the devices from large to small, and meanwhile, controlling the fourth device to be in a dormant state continuously according to a preset regulation and control proportion and based on the weight value sequencing result until the corrected temperature result is smaller than the minimum temperature value in the preset temperature range.

In one possible way of realisation,

before controlling the target intelligent building corresponding to the target area to be in a working state, the method further comprises the following steps:

judging whether an external instruction is received before the target intelligent building is in a working state;

if yes, crawling the external instruction, judging the instruction type of the external instruction based on an instruction database, and determining the to-be-converted state of the target intelligent building according to the instruction type;

meanwhile, monitoring the current conversion state of the target intelligent building;

if the current conversion state is inconsistent with the state to be converted, indicating that the intelligent device in the target intelligent building is damaged, sending a plurality of groups of control instructions to the target intelligent building, and collecting control information of the target intelligent building based on the plurality of groups of control instructions;

and screening damaged intelligent devices in the target intelligent building according to the control information.

In one possible way of realisation,

the in-process of carrying out real-time supervision to the target area that target intelligence building corresponds still includes:

monitoring the target intelligent building based on a monitoring end to obtain a first data capacity of the monitoring end based on a monitoring result;

transmitting the monitoring result of the target intelligent building monitored by the monitoring end to a target terminal based on a preset gateway, and meanwhile, acquiring transmission flow and transmission electric energy consumed by the preset gateway for transmitting the monitoring result;

counting a second data capacity of the monitoring result received by the target terminal based on a data statistical model of the target terminal;

collecting working logs of the target intelligent building in real time, and counting the first log capacity of the working logs in the collecting process;

transmitting the collected working logs to a target terminal based on a preset gateway, and counting the second log capacity of the working logs based on the data statistical model;

judging whether the first data capacity, the second data capacity, the transmission flow, the transmission electric energy, the first log capacity and the second log capacity meet the energy-saving control condition, and if not, extracting the unsatisfied index;

and carrying out network migration on the target intelligent building under the preset gateway based on the unsatisfied index, and reducing the current working power of the target intelligent building.

In one possible way of realisation,

before controlling the target intelligent building corresponding to the target area to be in a working state, the method comprises the following steps:

establishing a network connection node between an intelligent device in the target intelligent building and an external network based on a pre-deployed network connection logic, wherein the network connection node is in network connection with at least one intelligent device;

acquiring historical operation data reports of intelligent devices connected with the same network connection node, constructing device characteristic vectors of the intelligent devices connected with the same network connection node based on the historical operation data reports, and acquiring corresponding device characteristic values based on the device characteristic vectors;

calculating a node loss value P of the same network connection node based on the device characteristic value and according to the following formula;

wherein r is_iThe loss value of the ith intelligent device connected with the network connection node is represented; a represents the total number of intelligent devices connected with the same network connection node; f. of_iRepresenting the connection loss value of the ith intelligent device and the network connection node thereof under the same network connection node; g_iThe same network connection node is based on the energy distribution factor of the ith intelligent device;

representing the device characteristic value difference between the ith intelligent device and other intelligent devices under the same network connection node;

representing an average network loss value when data transmission is performed based on the same network connection node;

judging whether the node loss value exceeds a preset loss range, if so, calculating to obtain a total device loss value of the intelligent device connected with the same network connection node according to the following formula;

G＝max{r_i*f_iwhere i ═ 1,2, 3.., a;

acquiring a maximum loss value in the total device loss values, and taking the intelligent device corresponding to the maximum loss value as an intelligent device to be adjusted;

selecting a new network connection node from the established network connection nodes of the intelligent device in the target intelligent building and the external network based on the device attribute of the intelligent device to be adjusted and the device energy-saving rule;

and establishing the network connection relationship between the intelligent device to be adjusted and the new network connection node.

The invention provides an intelligent building energy-saving control system, which comprises:

the monitoring module is used for monitoring a target area corresponding to the target intelligent building in real time;

the control module is used for judging whether a target user exists in the target area according to the monitoring result;

if so, controlling the target intelligent building corresponding to the target area to be in a working state;

otherwise, controlling the target intelligent building corresponding to the target area to be in a dormant state.

In one possible implementation manner, the method further includes:

an acquisition module for acquiring a set of intelligent devices associated with the target intelligent building;

a recording module, configured to record device information of each smart device in the set of smart devices, where the device information includes: the device name and the device model of the intelligent device;

the statistical module is used for counting the actual electric energy consumption information and the actual flow consumption information of the intelligent device in a preset time period based on the device information;

the analysis module is used for carrying out data analysis on the actual electric energy consumption information and the actual current consumption information based on a data consumption model to obtain an electric energy consumption value and a current consumption value;

the control module is further used for judging whether the electric energy consumption value is within a first consumption range or whether the current consumption value is within a second consumption range;

if yes, controlling the corresponding intelligent device to be in a dormant state, and meanwhile, controlling the intelligent device in the dormant state to work according to a dormancy alternation rule.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a flow chart of an intelligent building energy-saving control method according to an embodiment of the present invention;

FIG. 2 is a block diagram of an intelligent building energy-saving control system according to an embodiment of the present invention;

fig. 3 is another structural diagram of an intelligent building energy-saving control system according to an embodiment of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

The invention provides an intelligent building energy-saving control method, as shown in figure 1, comprising the following steps:

step 1: monitoring a target area corresponding to a target intelligent building in real time, and judging whether a target user exists in the target area according to a monitoring result;

step 2: if so, controlling the target intelligent building corresponding to the target area to be in a working state;

and step 3: otherwise, controlling the target intelligent building corresponding to the target area to be in a dormant state.

In this embodiment, a target intelligent building, for example, is a lighting control system, and when a target user exists in a lighting area corresponding to the lighting control system, the lighting control system is controlled to operate, otherwise, the lighting control system is in a dormant state, so that not only is energy-saving control achieved, but also the service life of the lighting control system is effectively prolonged.

In this embodiment, the target user is, for example, a human.

The beneficial effects of the above technical scheme are: whether a user exists or not is judged conveniently, intelligent control is conducted on the target intelligent building, and energy-saving control is achieved.

The invention provides an intelligent building energy-saving control method, which is used for monitoring a target area corresponding to a target intelligent building in real time and further comprises the following steps:

obtaining a set of intelligent devices associated with the target intelligent building;

recording device information of each intelligent device in the intelligent device set, wherein the device information comprises: the device name and the device model of the intelligent device;

counting actual electric energy consumption information and actual flow consumption information of the intelligent device within a preset time period based on the device information;

performing data analysis on the actual electric energy consumption information and the actual current consumption information based on a data consumption model to obtain an electric energy consumption value and a current consumption value;

judging whether the electric energy consumption value is in a first consumption range or whether the current consumption value is in a second consumption range;

if yes, controlling the corresponding intelligent device to be in a dormant state, and meanwhile, controlling the intelligent device in the dormant state to work according to a dormancy alternation rule.

In this embodiment, for example, the target intelligent building is a related lighting system, and the intelligent devices may be corresponding lamp devices, and each lamp device needs to consume a flow during the intelligent control process, so that the actual flow consumption information of the lamp device is obtained, and the lamp device needs to support its operation with electric energy during the intelligent control process, so that the actual electric energy consumption information of the lamp device is obtained.

The first consumption range and the second consumption range may be set according to the property of the lamp itself, for example.

The beneficial effects of the above technical scheme are: through the electric energy loss information and the flow loss information of obtaining every device to through carrying out data analysis to it, be convenient for obtain relevant consumption value, and then carry out the scale comparison through the range of taking a value with corresponding, control the state of device, be convenient for improve its energy-conserving efficiency, and through dormancy rule of turns, be convenient for improve the life-span of its device, and indirect realization energy-saving control.

The invention provides an intelligent building energy-saving control method, which comprises the following steps of controlling a target intelligent building corresponding to a target area to be in a working state:

monitoring and acquiring current position information of a target user in the target area, wherein the current position information comprises: current position coordinates, a current orientation of the target user;

monitoring and acquiring user information of a target user in the target area, wherein the user information comprises: the height information of the target user and the vision information of the target user;

based on the current position information and the user information, adjusting the working power of the intelligent device in the working state corresponding to the target intelligent building;

and meanwhile, adjusting the intelligent device in the working state to an angle position and a height position corresponding to the target user of the target area.

In this embodiment, for example, the user is at the position of point a of the lighting area corresponding to the lighting system, at this time, the lighting lamps 1,2 and 3 in the lighting area turn on the lighting, but at this time, the user faces the direction of the lighting lamp 1, and the position a is closest to the lighting lamp 1, and the height of the user is 1.5m, the eyesight information is good, at this time, the lighting lamps 2 and 3 may be turned off, the lighting lamp 1 continues to be turned on, and the height of the lighting lamp 1 is adjusted downward, and the working power of the lighting lamp 1 is increased.

The beneficial effects of the above technical scheme are: through obtaining target user's current position information, user information, be convenient for carry out the regulation of power, height and angle to intelligent in the building during intelligence, can improve the work pertinence of intelligent device, effectively avoid the possibility of other devices and this device simultaneous working, realize energy-conserving control, and be convenient for satisfy user's demand.

The invention provides an intelligent building energy-saving control method, which further comprises the following steps of in the process of controlling a target intelligent building corresponding to a target area to be in a working state:

acquiring and acquiring a first working temperature of a first device which is continuously in a working state, a second working temperature of a second device which is continuously in a dormant state and a third working temperature of a third device which is converted between the working state and the dormant state in the target intelligent building within the current time period, and storing the acquired first working temperature, second working temperature and third working temperature based on a distributed storage structure;

performing linear analysis on the first working temperature, the second working temperature and the third working temperature based on the linear time sequence to obtain a temperature linear analysis result;

acquiring a first attribute of the first device, a second attribute of the second device and a third attribute of the third device, and correcting a temperature linear analysis result based on the first attribute, the second attribute and the third attribute to obtain a corrected temperature result;

judging whether the temperature correction result is within a preset temperature range, if so, controlling each device to work according to a preset working mode;

and otherwise, acquiring the weight value of each device and sequencing the devices from large to small, and meanwhile, controlling the fourth device to be in a dormant state continuously according to a preset regulation and control proportion and based on the weight value sequencing result until the corrected temperature result is smaller than the minimum temperature value in the preset temperature range.

In this embodiment, since the intelligent building includes a plurality of intelligent devices, for example, a lighting system includes a plurality of lighting lamps, the lighting lamps need to be controlled, a part of the lighting lamps are continuously in a working state, at this time, the first device is used, a part of the lighting lamps are continuously in a dormant state, at this time, the second device is used; the rest illuminating lamps are in a working state and a dormant state and are switched back and forth, and the rest illuminating lamps are third devices.

In the embodiment, the working temperatures of different types of devices are obtained, so that the linear time series analysis can be conveniently carried out, the linear analysis result can be obtained, and the linear analysis result can be corrected according to the attribute of the corresponding device, so that the corrected temperature result can be obtained.

The operation mode of the device is controlled by judging whether the temperature is within a preset temperature range (preset), and the operation mode is, for example, based on the continuous operation of the device in intervals of time between the sleep mode and the operation mode.

In this embodiment, the weight values of the devices are sorted from large to small, such as: the sequencing result comprises 8 devices, the working time of the first 2 devices is 1 hour, the working time of the middle 3 devices is 40 minutes, and the rest 3 devices are in a dormant state, so that the regulation ratio of 2:3:3 is obtained.

At this time, the fourth period is the device corresponding to the rest 3 devices in the sleep state.

The beneficial effects of the above technical scheme are: the temperature of the intelligent device in different states is obtained, linear analysis and correction processing are carried out on the temperature, the reliability of the intelligent device is improved, the intelligent device is convenient to control to be in a dormant state in the fourth period by combining the weight value of the intelligent device, and therefore energy-saving control is effectively achieved.

The invention provides an intelligent building energy-saving control method, which comprises the following steps before controlling a target intelligent building corresponding to a target area to be in a working state:

judging whether an external instruction is received before the target intelligent building is in a working state;

if yes, crawling the external instruction, judging the instruction type of the external instruction based on an instruction database, and determining the to-be-converted state of the target intelligent building according to the instruction type;

meanwhile, monitoring the current conversion state of the target intelligent building;

if the current conversion state is inconsistent with the state to be converted, indicating that the intelligent device in the target intelligent building is damaged, sending a plurality of groups of control instructions to the target intelligent building, and collecting control information of the target intelligent building based on the plurality of groups of control instructions;

and screening damaged intelligent devices in the target intelligent building according to the control information.

In this embodiment, the external command is, for example, a test command for the smart device;

in this embodiment, the instruction types include, for example: the test type of the intelligent device, the test type of the network connection between the intelligent device and the outside, and the like.

In this embodiment, multiple sets of control instructions, for example, multiple test instructions, are used to test the smart device.

The beneficial effects of the above technical scheme are: through comparing whether the current conversion state is consistent with the state to be converted or not, the damaged intelligent device is convenient to screen, and the reliability of energy-saving control is improved.

The invention provides an intelligent building energy-saving control method, which is used for monitoring a target area corresponding to a target intelligent building in real time and further comprises the following steps:

monitoring the target intelligent building based on a monitoring end to obtain a first data capacity of the monitoring end based on a monitoring result;

transmitting the monitoring result of the target intelligent building monitored by the monitoring end to a target terminal based on a preset gateway, and meanwhile, acquiring transmission flow and transmission electric energy consumed by the preset gateway for transmitting the monitoring result;

counting a second data capacity of the monitoring result received by the target terminal based on a data statistical model of the target terminal;

collecting working logs of the target intelligent building in real time, and counting the first log capacity of the working logs in the collecting process;

transmitting the collected working logs to a target terminal based on a preset gateway, and counting the second log capacity of the working logs based on the data statistical model;

judging whether the first data capacity, the second data capacity, the transmission flow, the transmission electric energy, the first log capacity and the second log capacity meet the energy-saving control condition, and if not, extracting the unsatisfied index;

and carrying out network migration on the target intelligent building under the preset gateway based on the unsatisfied index, and reducing the current working power of the target intelligent building.

In the embodiment, the energy-saving control condition is judged by acquiring the capacity before and after transmission, wherein the first data capacity and the second data capacity are acquired at the monitoring end directly based on the monitoring result, and the second data capacity is acquired at the target terminal according to the monitoring result after transmission;

in this embodiment, the first log capacity is obtained before transmission based on the predetermined gateway, and the second log capacity is obtained after transmission based on the predetermined gateway.

In this embodiment, the network moves forward, such as the intelligent building connected L1 gateway, where it is migrated to the L2 gateway.

The beneficial effects of the above technical scheme are: by measuring and comparing the data capacity of the monitoring result, the data capacity of the working log, the transmission flow and the transmission electric energy, whether network migration is needed or not is effectively determined, the working power is reduced, and energy-saving control is further achieved.

The invention provides an intelligent building energy-saving control method, which comprises the following steps of before controlling a target intelligent building corresponding to a target area to be in a working state:

establishing a network connection node between an intelligent device in the target intelligent building and an external network based on a pre-deployed network connection logic, wherein the network connection node is in network connection with at least one intelligent device;

acquiring historical operation data reports of intelligent devices connected with the same network connection node, constructing device characteristic vectors of the intelligent devices connected with the same network connection node based on the historical operation data reports, and acquiring corresponding device characteristic values based on the device characteristic vectors;

calculating a node loss value P of the same network connection node based on the device characteristic value and according to the following formula;

wherein r is_iThe loss value of the ith intelligent device connected with the network connection node is represented; a represents the total number of intelligent devices connected with the same network connection node; f. of_iRepresenting the connection loss value of the ith intelligent device and the network connection node thereof under the same network connection node; g_iThe same network connection node is based on the energy distribution factor of the ith intelligent device;

representing the device characteristic value difference between the ith intelligent device and other intelligent devices under the same network connection node;

representing an average network loss value when data transmission is performed based on the same network connection node;

judging whether the node loss value exceeds a preset loss range, if so, calculating to obtain a total device loss value of the intelligent device connected with the same network connection node according to the following formula;

G＝max{r_i*f_iwhere i ═ 1,2, 3.., a;

acquiring a maximum loss value in the total device loss values, and taking the intelligent device corresponding to the maximum loss value as an intelligent device to be adjusted;

selecting a new network connection node from the established network connection nodes of the intelligent device in the target intelligent building and the external network based on the device attribute of the intelligent device to be adjusted and the device energy-saving rule;

and establishing the network connection relationship between the intelligent device to be adjusted and the new network connection node.

The beneficial effects of the above technical scheme are: by deploying the network connection nodes, energy-saving control of each intelligent device is facilitated, device characteristic values under the same network connection node are facilitated to be obtained by obtaining historical operation data reports of the intelligent devices, node loss values are calculated, whether the loss of the node is reasonable or not is conveniently and effectively determined, when the node is unreasonable, the intelligent device corresponding to the maximum loss value is obtained, a new network connection node is selected to be connected, loss of the network connection node is reduced, load balancing is facilitated, and effective energy-saving control is achieved.

The invention provides an intelligent building energy-saving control system, as shown in fig. 2, comprising:

the monitoring module is used for monitoring a target area corresponding to the target intelligent building in real time;

the control module is used for judging whether a target user exists in the target area according to the monitoring result;

if so, controlling the target intelligent building corresponding to the target area to be in a working state;

otherwise, controlling the target intelligent building corresponding to the target area to be in a dormant state.

The beneficial effects of the above technical scheme are: whether a user exists or not is judged conveniently, intelligent control is conducted on the target intelligent building, and energy-saving control is achieved.

The invention provides an intelligent building energy-saving control system, as shown in fig. 3, further comprising:

an acquisition module for acquiring a set of intelligent devices associated with the target intelligent building;

a recording module, configured to record device information of each smart device in the set of smart devices, where the device information includes: the device name and the device model of the intelligent device;

the statistical module is used for counting the actual electric energy consumption information and the actual flow consumption information of the intelligent device in a preset time period based on the device information;

the analysis module is used for carrying out data analysis on the actual electric energy consumption information and the actual current consumption information based on a data consumption model to obtain an electric energy consumption value and a current consumption value;

the control module is further used for judging whether the electric energy consumption value is within a first consumption range or whether the current consumption value is within a second consumption range;

if yes, controlling the corresponding intelligent device to be in a dormant state, and meanwhile, controlling the intelligent device in the dormant state to work according to a dormancy alternation rule.

The beneficial effects of the above technical scheme are: through the electric energy loss information and the flow loss information of obtaining every device to through carrying out data analysis to it, be convenient for obtain relevant consumption value, and then carry out the scale comparison through the range of taking a value with corresponding, control the state of device, be convenient for improve its energy-conserving efficiency, and through dormancy rule of turns, be convenient for improve the life-span of its device, and indirect realization energy-saving control.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (9)

1. An intelligent building energy-saving control method is characterized by comprising the following steps:

monitoring a target area corresponding to a target intelligent building in real time, and judging whether a target user exists in the target area according to a monitoring result;

if so, controlling the target intelligent building corresponding to the target area to be in a working state;

otherwise, controlling the target intelligent building corresponding to the target area to be in a dormant state.

2. The intelligent building energy-saving control method according to claim 1, wherein in the process of monitoring the target area corresponding to the target intelligent building in real time, the method further comprises:

obtaining a set of intelligent devices associated with the target intelligent building;

recording device information of each intelligent device in the intelligent device set, wherein the device information comprises: the device name and the device model of the intelligent device;

counting actual electric energy consumption information and actual flow consumption information of the intelligent device within a preset time period based on the device information;

performing data analysis on the actual electric energy consumption information and the actual current consumption information based on a data consumption model to obtain an electric energy consumption value and a current consumption value;

judging whether the electric energy consumption value is in a first consumption range or whether the current consumption value is in a second consumption range;

if yes, controlling the corresponding intelligent device to be in a dormant state, and meanwhile, controlling the intelligent device in the dormant state to work according to a dormancy alternation rule.

3. The intelligent building energy-saving control method according to claim 1, wherein the controlling the target intelligent building corresponding to the target area to be in the working state comprises:

monitoring and acquiring current position information of a target user in the target area, wherein the current position information comprises: current position coordinates, a current orientation of the target user;

monitoring and acquiring user information of a target user in the target area, wherein the user information comprises: the height information of the target user and the vision information of the target user;

based on the current position information and the user information, adjusting the working power of the intelligent device in the working state corresponding to the target intelligent building;

and meanwhile, adjusting the intelligent device in the working state to an angle position and a height position corresponding to the target user of the target area.

4. The intelligent building energy-saving control method according to claim 1, wherein in the process of controlling the target intelligent building corresponding to the target area to be in the working state, the method further comprises:

acquiring and acquiring a first working temperature of a first device which is continuously in a working state, a second working temperature of a second device which is continuously in a dormant state and a third working temperature of a third device which is converted between the working state and the dormant state in the target intelligent building within the current time period, and storing the acquired first working temperature, second working temperature and third working temperature based on a distributed storage structure;

performing linear analysis on the first working temperature, the second working temperature and the third working temperature based on the linear time sequence to obtain a temperature linear analysis result;

acquiring a first attribute of the first device, a second attribute of the second device and a third attribute of the third device, and correcting a temperature linear analysis result based on the first attribute, the second attribute and the third attribute to obtain a corrected temperature result;

judging whether the temperature correction result is within a preset temperature range, if so, controlling each device to work according to a preset working mode;

and otherwise, acquiring the weight value of each device and sequencing the devices from large to small, and meanwhile, controlling the fourth device to be in a dormant state continuously according to a preset regulation and control proportion and based on the weight value sequencing result until the corrected temperature result is smaller than the minimum temperature value in the preset temperature range.

5. The intelligent building energy-saving control method according to claim 1, wherein before controlling the target intelligent building corresponding to the target area to be in the working state, the method further comprises:

judging whether an external instruction is received before the target intelligent building is in a working state;

if yes, crawling the external instruction, judging the instruction type of the external instruction based on an instruction database, and determining the to-be-converted state of the target intelligent building according to the instruction type;

meanwhile, monitoring the current conversion state of the target intelligent building;

if the current conversion state is inconsistent with the state to be converted, indicating that the intelligent device in the target intelligent building is damaged, sending a plurality of groups of control instructions to the target intelligent building, and collecting control information of the target intelligent building based on the plurality of groups of control instructions;

and screening damaged intelligent devices in the target intelligent building according to the control information.

6. The intelligent building energy-saving control method according to claim 1, wherein in the process of monitoring the target area corresponding to the target intelligent building in real time, the method further comprises:

monitoring the target intelligent building based on a monitoring end to obtain a first data capacity of the monitoring end based on a monitoring result;

transmitting the monitoring result of the target intelligent building monitored by the monitoring end to a target terminal based on a preset gateway, and meanwhile, acquiring transmission flow and transmission electric energy consumed by the preset gateway for transmitting the monitoring result;

counting a second data capacity of the monitoring result received by the target terminal based on a data statistical model of the target terminal;

collecting working logs of the target intelligent building in real time, and counting the first log capacity of the working logs in the collecting process;

transmitting the collected working logs to a target terminal based on a preset gateway, and counting the second log capacity of the working logs based on the data statistical model;

judging whether the first data capacity, the second data capacity, the transmission flow, the transmission electric energy, the first log capacity and the second log capacity meet the energy-saving control condition, and if not, extracting the unsatisfied index;

and carrying out network migration on the target intelligent building under the preset gateway based on the unsatisfied index, and reducing the current working power of the target intelligent building.

7. The intelligent building energy-saving control method according to claim 1, wherein before controlling the target intelligent building corresponding to the target area to be in the working state, the method comprises:

establishing a network connection node between an intelligent device in the target intelligent building and an external network based on a pre-deployed network connection logic, wherein the network connection node is in network connection with at least one intelligent device;

acquiring historical operation data reports of intelligent devices connected with the same network connection node, constructing device characteristic vectors of the intelligent devices connected with the same network connection node based on the historical operation data reports, and acquiring corresponding device characteristic values based on the device characteristic vectors;

calculating a node loss value P of the same network connection node based on the device characteristic value and according to the following formula;

wherein r is_iThe loss value of the ith intelligent device connected with the network connection node is represented; a represents the total number of intelligent devices connected with the same network connection node; f. of_iRepresenting the connection loss value of the ith intelligent device and the network connection node thereof under the same network connection node; g_iThe same network connection node is based on the energy distribution factor of the ith intelligent device;

representing the device characteristic value difference between the ith intelligent device and other intelligent devices under the same network connection node;

representing an average network loss value when data transmission is performed based on the same network connection node;

judging whether the node loss value exceeds a preset loss range, if so, calculating to obtain a total device loss value of the intelligent device connected with the same network connection node according to the following formula;

G＝max{r_i*f_iwhere i ═ 1,2, 3.., a;

acquiring a maximum loss value in the total device loss values, and taking the intelligent device corresponding to the maximum loss value as an intelligent device to be adjusted;

selecting a new network connection node from the established network connection nodes of the intelligent device in the target intelligent building and the external network based on the device attribute of the intelligent device to be adjusted and the device energy-saving rule;

and establishing the network connection relationship between the intelligent device to be adjusted and the new network connection node.

8. An intelligent building energy-saving control system is characterized by comprising:

the monitoring module is used for monitoring a target area corresponding to the target intelligent building in real time;

the control module is used for judging whether a target user exists in the target area according to the monitoring result;

if so, controlling the target intelligent building corresponding to the target area to be in a working state;

otherwise, controlling the target intelligent building corresponding to the target area to be in a dormant state.

9. The intelligent building energy conservation control system of claim 8, further comprising:

an acquisition module for acquiring a set of intelligent devices associated with the target intelligent building;

a recording module, configured to record device information of each smart device in the set of smart devices, where the device information includes: the device name and the device model of the intelligent device;

the statistical module is used for counting the actual electric energy consumption information and the actual flow consumption information of the intelligent device in a preset time period based on the device information;

the analysis module is used for carrying out data analysis on the actual electric energy consumption information and the actual current consumption information based on a data consumption model to obtain an electric energy consumption value and a current consumption value;

the control module is further used for judging whether the electric energy consumption value is within a first consumption range or whether the current consumption value is within a second consumption range;

if yes, controlling the corresponding intelligent device to be in a dormant state, and meanwhile, controlling the intelligent device in the dormant state to work according to a dormancy alternation rule.

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