CN113777946A - Intelligent building control method, device and system - Google Patents

Abstract

The application provides a smart building method, a device and a system, at least one subsystem for assisting in supporting smart building control is accessed into a main system, so that monitoring data acquired by each subsystem is displayed in a control page of the smart building, a worker can directly execute a control function corresponding to any subsystem on the control page, and when the control function is realized, the monitoring data acquired by other subsystems are combined according to corresponding control rules and sent to the corresponding subsystems after a control instruction is generated, control over target control equipment is realized, the subsystems are not required to be switched and logged in to check the monitoring data and execute the control instruction aiming at the control equipment, the control steps of the smart building are greatly simplified, and the control efficiency is improved.

Description

Intelligent building control method, device and system

Technical Field

The application mainly relates to the technical field of the Internet of things, in particular to an intelligent building control method, device and system.

Background

Smart buildings or Smart buildings (Smart Building) are indispensable important components of Smart cities, and can integrate structures, systems, services, management and optimized combinations thereof, so that the buildings have special effects of safety, convenience, high efficiency and energy conservation.

The intelligent office building is taken as an example for explanation, and the control system can be introduced into an air conditioner control system, an intelligent security system, a personnel access system and other auxiliary systems, so that a more comfortable, safe and efficient office place is created.

However, in the operation process of the intelligent building control system integrating a plurality of auxiliary systems, in the face of a plurality of task control requirements, a worker needs to continuously switch to enter a control interface of the corresponding auxiliary system, so that the auxiliary system can be controlled or required control information can be inquired. If the air conditioner of the whole office place needs to be adjusted, the adjustment can be finished only by logging in an air conditioner control system; if the monitoring video of a specific office area needs to be checked, the intelligent security system needs to be logged in, and then the monitoring interface of the specific office area can be called out, so that the process is very complicated, and the control requirement of a scene on the intelligent building cannot be met.

Disclosure of Invention

In view of the above, the present application provides an intelligent building control method, which includes

Responding to a control request aiming at the intelligent building, and outputting a control page aiming at the intelligent building; the control page comprises a main control area and at least one sub control area of the intelligent building, and different control areas can present monitoring data of corresponding control functions;

responding to the input operation of a target sub-control area in the control page, and calling corresponding target monitoring data from a database according to a target control rule corresponding to a target control function of the target sub-control area; the target monitoring data comprises first monitoring data corresponding to the target control function and second monitoring data for assisting in realizing the control of the target control function;

generating a control instruction aiming at the target control function according to the first monitoring data and the second monitoring data;

and sending the control instruction to target control equipment corresponding to the target sub-control area, executing the control instruction by the target control equipment, and updating the first monitoring data.

Optionally, the generating a control instruction for the target control function according to the first monitoring data and the second monitoring data includes:

responding to the instruction input operation aiming at the target control function to obtain a control instruction aiming at the target control function; the instruction input operation is performed based on the first monitoring data and the second monitoring data;

or,

generating a control instruction aiming at the target control function by utilizing the first monitoring data and the second monitoring data according to the target control rule;

or,

analyzing the first monitoring data and the second monitoring data to obtain operation habit information of a user on the target control function in a target office area;

and generating a control instruction aiming at the target control function according to the target control rule and the operation habit information.

Optionally, if the target sub-control area is an air-conditioning control area, the first monitoring data includes environment data of a target office area, and the second monitoring data includes conference reservation information for the target office area; the conference reservation information comprises reserved conference time and the number of participants;

generating a control instruction for the target control function by using the first monitoring data and the second monitoring data according to the target control rule, and sending the control instruction to target control equipment corresponding to the target sub-control area, wherein the method comprises the following steps:

generating a starting instruction for the air conditioning equipment in the target office area according to the number of participants and the environment data;

and according to the reserved meeting time, at the first time before the meeting begins, the starting instruction is sent to the air-conditioning subsystem corresponding to the air-conditioning control area, and the air-conditioning subsystem responds to the starting instruction to start the air-conditioning equipment of the target office area to enter a working state.

Optionally, the generating, according to the target control rule, a control instruction for the target control function by using the first monitoring data and the second monitoring data, and sending the control instruction to the target control device corresponding to the target sub-control area further includes:

detecting a meeting ending instruction, sending a closing instruction aiming at the air conditioning equipment of the target office area to the air conditioning subsystem, and controlling the air conditioning equipment to end working by the air conditioning subsystem in response to the closing instruction; the conference ending instruction is generated based on conference ending notification information sent by a client or generated based on conference ending time in the reserved conference time;

or,

under the condition that the second monitoring data further comprises user access record information, updating the number of the participants according to the user access record information;

sending a temperature adjusting instruction aiming at the air conditioning equipment of the target office area to the air conditioning subsystem according to the updated number of participants and the latest obtained environmental data, and adjusting the temperature parameter of the air conditioning equipment by the air conditioning subsystem in response to the temperature adjusting instruction;

and sending a closing instruction aiming at the air conditioning equipment of the target office area to the air conditioning subsystem when the number of the participants is detected to be zero in the first time period.

Optionally, the sending the control instruction to the target control device corresponding to the target sub-control area includes:

sending the control instruction to a subsystem corresponding to the target sub-control area, so that the subsystem determines that the received control instruction is different from a locally stored control instruction, updates the locally stored control instruction, and responds to the received control instruction to adjust the working state of target control equipment in the subsystem;

receiving control response information fed back by the subsystem, and recording the control response information; wherein the control response information is determined based on a comparison of the control instructions with locally stored control instructions of the subsystem.

Optionally, the method further includes:

according to monitoring data aiming at different control functions obtained by a database, establishing control rules corresponding to the different control functions respectively;

or,

responding to rule input operation of the target sub-control area to obtain the target control rule; wherein the rule input operation is performed based on the monitoring data presented by the control page.

Optionally, the monitoring data of the corresponding control function acquired by the subsystem corresponding to the sub-control area is forwarded to the database for storage through the message proxy server;

and the monitoring data aiming at the same control function in the database is stored in a message queue mode.

Optionally, the responding to the control request for the smart building and outputting a control page for the smart building includes:

responding to a control request aiming at the intelligent building, and performing identity verification on request account information contained in the control request;

determining identity authority information of the request account according to the identity verification result;

acquiring control information which is matched with the identity authority information and aims at the intelligent building; the control information comprises control area information aiming at the intelligent building and monitoring data of control functions corresponding to different control areas;

and sending the control information to a client, outputting a control page aiming at the intelligent building by the client, and presenting corresponding monitoring data in different control areas of the control page.

This application has still provided an wisdom building controlling means, the device includes:

the control page output module is used for responding to a control request aiming at the intelligent building and outputting a control page aiming at the intelligent building; the control page comprises a main control area and at least one sub control area of the intelligent building, and different control areas can present monitoring data of corresponding control functions;

the data calling module is used for responding to input operation of a target sub-control area in the control page and calling corresponding target monitoring data from a database according to a target control rule corresponding to a target control function of the target sub-control area; the target monitoring data comprises first monitoring data corresponding to the target control function and second monitoring data for assisting in realizing the control of the target control function;

a control instruction generating module, configured to generate a control instruction for the target control function according to the first monitoring data and the second monitoring data;

and the control module is used for sending the control instruction to target control equipment corresponding to the target sub-control area, and the target control equipment executes the control instruction and updates the first monitoring data.

The present application further proposes a smart building control system, the system including a main system and at least one subsystem for smart building, and a message proxy server for implementing data transmission between the main system and the subsystem, wherein:

the main system comprises a client, a main server and a database, wherein the main server comprises at least one memory and at least one processor;

the memory is used for storing programs for realizing the intelligent building control method;

the processor is used for loading and executing the program stored in the memory to realize the intelligent building control method;

the subsystem comprises a sub-server and at least one control device;

and the sub-server receives a control instruction which is forwarded by the message proxy server and is generated by the main server and aims at the target control equipment, sends the control instruction to the target control equipment for execution, and updates the first monitoring data.

Therefore, the method, the device and the system for the intelligent building are provided, at least one subsystem for assisting in supporting the control of the intelligent building is connected to the main system, so that monitoring data obtained by each subsystem is displayed in one control page of the intelligent building, a worker can directly execute a corresponding control function of any subsystem on the control page, and when the control function is realized, the control command is generated and sent to the corresponding subsystem according to the corresponding control rule and the monitoring data obtained by other subsystems, so that the control on target control equipment is realized, the switching, logging in of each subsystem, checking of the monitoring data and execution of the control command aiming at the control equipment are not needed, the control steps of the intelligent building are greatly simplified, and the control efficiency is improved.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, it is obvious that the drawings in the following description are only embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an alternative example of a smart building control system suitable for the smart building control method proposed in the present application;

fig. 2 is a schematic diagram of a hardware structure of an embodiment of a main server in the intelligent building control system according to the present invention;

FIG. 3 is a schematic flow chart illustrating an alternative example of the intelligent building control method proposed in the present application;

FIG. 4 is a schematic flow chart illustrating another alternative example of the intelligent building control method proposed in the present application;

FIG. 5 is a schematic flow chart illustrating another alternative example of the intelligent building control method proposed in the present application;

FIG. 6 is a schematic flow chart illustrating another alternative example of the intelligent building control method proposed in the present application;

fig. 7 is a schematic structural diagram of an alternative example of the intelligent building control device provided by the present application.

Detailed Description

The technical problems described in the background art are solved by analyzing that the control systems of different intelligent buildings are independent from the auxiliary systems, and the data generated by the auxiliary systems are relatively independent, so that various control data cannot be integrated for comprehensive analysis. For example, the air conditioner control system adjusts the temperature of the air conditioner according to the collected current environmental data such as temperature, humidity and the like, so that the temperature of the air conditioner is controlled within a certain fixed range; because it is independent each other with other auxiliary systems, can't combine the demand of people's activity under the current environment, for example whether personnel density in the office area, whether someone is using in office areas that can seal such as meeting room, whether personnel manually control action data such as air conditioner, reduced air conditioner control accuracy, also cause the energy waste easily.

In contrast, for the above example, the present application expects that the air conditioners in the office areas such as the idle meeting rooms can be turned off in combination with the above behavior data, thereby avoiding energy waste; the air conditioner temperature adjusting range configured for the office area with dense personnel is low, on the contrary, the air conditioner temperature adjusting range configured for the office area with sparse personnel is high, dynamic configuration of the air conditioner temperature adjusting range is achieved, and therefore accurate control of the air conditioner system is achieved, and the purposes of energy conservation and emission reduction are achieved while a more comfortable and humanized office environment is provided.

Based on the analysis, the method provides that the main system and each auxiliary system of the intelligent building communicate with each other in a RabbitMQ mode to realize mutual data transmission, for example, various auxiliary data acquired by each auxiliary system are transmitted to a database of the main system to be stored through a RabbitMQ server, so that a worker of the intelligent building starts the main system and can directly present each auxiliary data sent by each auxiliary system on a control interface aiming at the intelligent building, and thus, the worker can complete various kinds of work on the control interface without continuously switching and logging in each auxiliary system, the work flow is simplified, and when any control task is executed, the large data analysis mode can be used for realizing, the control precision is improved, and the energy consumption in air conditioner control application is reduced.

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

Referring to fig. 1, a schematic structural diagram of an alternative example of a smart building control system suitable for the smart building control method provided in the present application is shown in fig. 1, and the system may include: a main system 100 and at least one sub-system 200 for the intelligent building, and a message proxy server 300 for enabling data transmission between the main system 100 and the sub-system 200.

In the embodiment of the present application, the host system 100 may be a basic control architecture for implementing intelligent building control, which may include a client 110, a host server 120 and a database 130. The client 110 may be an application program for a worker to log in the smart building control platform, so as to conveniently implement basic control of the smart building. In practical applications, the client 110 may be a dedicated application program on the terminal device or a web application program, and the application category of the client 110 is not limited in the present application and may be determined as the case may be.

Based on this, the staff can start the client 110 for realizing the intelligent building control on the terminal device in the control room of the office building, or input the website of the intelligent building control platform through the browser to enter the control page of the web client 110, so that the intelligent building control method provided by the application can realize the control of different aspects of the intelligent building.

The main server 120 may be a service device supporting implementation of a smart building control function of a client, may be an independent physical server, may also be a server cluster integrated by multiple physical servers, and may also be a cloud server supporting a cloud computer function, and may implement data interaction with a terminal device through a wired communication network or a wireless communication network, so as to meet application requirements.

The database 130 may be a data storage device, such as a database server, for storing various data obtained during the operation of the system, and the application does not limit the category of the database 130 and the storage manner of the received data.

In some embodiments, as shown in fig. 2, the main server 120 may include at least one memory 121 and at least one processor 122, where the memory 121 may be used to store a program for implementing the intelligent building control method proposed in the present application; the processor 122 may be configured to load and execute the program stored in the memory to implement the intelligent building control method proposed in the present application, and the implementation process may refer to, but is not limited to, the description of the corresponding parts of the method embodiments below.

In practical applications, the memory 121 may include a high-speed random access memory, and may also include a non-volatile memory, such as at least one magnetic disk storage device or other volatile solid-state storage device. The processor 122 may be a Central Processing Unit (CPU), an application-specific integrated circuit (ASIC), a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), an off-the-shelf programmable gate array (FPGA) or other programmable logic device.

It is understood that the main server 120 may further include other components such as various types of communication interfaces, and is not limited to the hardware structure of the main server shown in fig. 2, and this is not a list in this application. Moreover, the composition structure of the main system is not limited to the system structure shown in fig. 1, and the main system may also have more or fewer devices than those shown in fig. 1 according to application requirements, which is not listed in this application.

The above subsystem 200 may be an auxiliary function module for enriching the control function of the intelligent building and not sensed by the user, such as one or more subsystems of an air conditioning control system, an intelligent security system, a user access system, etc., so as to create a more comfortable, safe and efficient office environment. The application does not limit the category and the structure of the subsystem 200, and can flexibly adjust according to the scene requirements.

For the data communication between each subsystem 200 and the main system 100, the present application proposes to use the message proxy server 300 to implement, so that, for any subsystem 200, after obtaining the monitoring data of the corresponding control function of the whole monitored area (such as the whole office area, etc.), the monitoring data can be sent to the message proxy server 300, and the message proxy server 300 forwards the received monitoring data to the database 130 in the main system 100 for storage. Therefore, the message transmission mode does not need to embed each subsystem into the main system, and reduces the consumed resources for updating the whole architecture of the main system.

Optionally, the message proxy server 300 may be a RabbitMQ, that is, an open-source message proxy software, which may receive a message (e.g., detected monitoring data, environment data such as temperature and humidity, user access record information, and the like) issued by a producer (i.e., an application sending the message, such as any subsystem in the present application) and send the message to a consumer (i.e., an application receiving the message, such as a host system in the present application), and the message proxy server 300 plays a role as a middleman, and may be used to reduce load and delay of a web server due to sending the message. The working principle of the RabbitMQ is not detailed in the application.

The message proxy server 300 may be a physical server or a cloud server, or may be a virtual server, and may be determined according to a scene application requirement.

For any subsystem 200, a sub-server 210 and at least one control device 220 may be included. It will be appreciated that the number of control devices 200 and their product categories will often be different in different subsystems 200 as listed above, which may be determined by the control function category to which the subsystem 200 corresponds.

For example, for an air conditioning control system, the control devices 220 included therein may include various categories, temperature adjusting devices such as air conditioning devices located at different locations of a controlled area, humidity adjusting devices, and the like; for the user access system, the control device 220 included therein may include a camera, a door access device installed at the door, an infrared scanning device, etc.; for the intelligent security system, the control device 220 included therein may include various monitoring devices, alarm devices, etc., which are not listed herein, and may be determined according to the situation.

In practical application of the present application, the main server generates a control instruction for a target control device of a certain subsystem based on received various monitoring data, transmits the control instruction to the sub-server 210 of the subsystem through the message proxy server 300, and the sub-server 210 sends the control instruction to the target control device for execution, adjusts the working parameters of the target control device, and updates corresponding monitoring data.

It should be understood that for the structure of different subsystems, including but not limited to the system structure shown in fig. 1, in practical applications, the corresponding subsystems may include more devices than those shown in fig. 1 for different control function requirements, and this application is not limited to this.

Referring to fig. 3, a flow chart of an alternative example of the intelligent building control method proposed by the present application, which may be executed by the client, as shown in fig. 3, may include:

step S11, responding to the control request aiming at the intelligent building and outputting a control page aiming at the intelligent building;

in combination with the above description of the intelligent building control system, the application provides that each subsystem of the auxiliary support office building such as an air conditioner control system, an intelligent security system and a user access system is accessed into the main system, so that the front-end interface of the main system can present control areas for workers to complete different control functions in the main system, and thus, under the condition that a certain control function needs to be executed, the monitoring data presented by a plurality of control areas can be combined, more reasonable control is realized, frequent switching is not needed, the intelligent building control system enters different auxiliary systems, the operation steps are greatly simplified, and the workload of the workers is reduced.

Therefore, when the staff starts the client of the main system, the control request aiming at the intelligent building is responded, the control page aiming at the intelligent building can be output on the display screen of the terminal device, the control page can comprise a main control area of the intelligent building and at least one sub-control area, such as an air conditioner control area, a security control area, a user access control area and the like, different control areas can present monitoring data with corresponding control functions, the monitoring data can be acquired by subsystems corresponding to the corresponding control areas, and the application does not limit the content of the monitoring data and the acquisition implementation method thereof.

Still taking the above listed subsystems as examples, the monitoring data of the air conditioning control system may include temperature data, humidity data, etc. of different office areas; the monitoring data of the security control system can comprise information such as whether potential safety hazards exist in different office areas or not, whether network potential safety hazards exist in equipment in different office areas or not and the like; the monitoring data of the user access control system can comprise monitoring images at different positions, access/exit card-punching record information (such as fingerprints and face images) of the access control device and the like, and can be determined according to scene requirements, and detailed description is not given here.

Step S12, responding to the input operation of the target sub-control area in the control page, and calling corresponding target monitoring data from the database according to the target control rule corresponding to the target control function of the target sub-control area;

by means of the above analysis, the staff can simultaneously check the monitoring data of the subsystems in one control page, so that the staff can conveniently and comprehensively analyze data of personnel density, temperature and humidity, personnel automatic control air conditioning systems and the like in different areas, and a set of control rules of the indoor environment can be formulated and dynamically corrected. Based on this, the worker determines the control function to be adjusted this time through the monitoring data in many aspects viewed on the control page, and records it as the target control function, and may record its corresponding sub-control area as the target sub-control area, and if the indoor temperature needs to be dynamically adjusted, the target sub-control area may be an air conditioner control area, but is not limited thereto.

The target control rule can be configured by the staff according to the control requirements and the monitoring data contents of all aspects shown by the control page, and the target control rule contents can be dynamically adjusted when the control requirements and/or the monitoring data change. In still other embodiments, the target control rule may also be a control rule for different control functions, or the like, constructed or updated according to each monitoring data newly acquired by the host system, and the acquisition manner of the control rule is not limited in the present application.

In some embodiments, a worker may directly input a control parameter or click a control button or other input operations in a target sub-control area in a control page, so that a client responds to the input operations to invoke a target control rule configured in advance for the target control function, and thus, according to the target control rule, target monitoring data required for implementing control of the target control function at this time is retrieved from a database, and if indoor temperature needs to be adjusted, information such as user access data and conference data can be retrieved, and the category of the target monitoring data can be determined according to the content of the target control rule, which is not limited in the present application.

Therefore, the target monitoring data may include first monitoring data corresponding to the target control function and second monitoring data for assisting in implementing control of the target control function. Still taking the indoor temperature control function as an example for explanation, the first monitoring data may include environmental data such as temperature data and humidity data of a target office area (i.e., an office area whose temperature is to be adjusted); the second monitoring data may include meeting reservation information for the target office area, such as a reserved meeting time and number of participants, etc., from which a start time and an end time of the reserved meeting, a density of people in the meeting room, etc., may be determined. It should be noted that, for different target control functions, the contents of the corresponding called target monitoring data may be different, and the application does not limit the contents of the first monitoring data and the second monitoring data and the obtaining manner thereof.

Step S13, generating a control instruction for the target control function according to the first monitoring data and the second monitoring data;

in combination with the above description of the monitoring data, based on the above described target control rule, a control instruction for a target control function, such as a start instruction (close instruction) for starting (closing) the target control function, may be generated according to the first monitoring data and the second monitoring data that are obtained latest; and an adjustment instruction for adjusting an operating parameter of a target control device that executes a target control function, and the like, and the content and the generation manner of the control instruction are not limited in the present application.

For example, if the temperature of the target office area needs to be adjusted, an adjustment instruction for increasing/decreasing the temperature of the air conditioning equipment in the target office area may be generated according to the acquired monitoring data such as the temperature data of the target office area, the personnel density data (which may be obtained based on the user entrance/exit record data of the target office area), and the like. The dynamic control implementation processes of other control functions are similar, and detailed description is not given in the application.

Step S14, sending the control instruction to the target control device corresponding to the target sub-control area, and the target control device executing the control instruction and updating the first monitoring data.

In this embodiment of the application, after the client generates the control instruction, the control instruction may be sent to the main server through a wireless communication network or a wired communication network, and then forwarded to the sub server in the target subsystem corresponding to the target sub control area through the message proxy server, the sub server adjusts the working parameters of the target control device according to the control instruction, and updates the first monitoring data in the environment where the target control device is located, for example, reduces the output temperature of the air conditioning device in the target office area, thereby reducing the ambient temperature, so that the air conditioning control subsystem may send the latest detected ambient data to the database of the main system for storage in the manner described above, and update the corresponding monitoring data presented by the control page.

Therefore, for any control function of the intelligent building, the intelligent building control method and the intelligent building control system can directly perform adjustment operation on the control page, adjust the working parameters of corresponding target control equipment, meet application requirements, do not need to continuously switch and log in each subsystem, achieve function control of each subsystem, greatly simplify control steps of the intelligent building, and improve control efficiency.

Referring to fig. 4, a flow chart of another optional example of the intelligent building control method proposed in the present application is schematically illustrated, and the present embodiment may be an optional detailed implementation method of the intelligent building control method described in the above embodiments, but is not limited to the detailed implementation method described in the present embodiment, and as shown in fig. 4, the method may include:

step S21, responding to the control request aiming at the intelligent building and outputting a control page aiming at the intelligent building;

step S22, responding to the input operation of the target sub-control area in the control page, and calling corresponding target monitoring data from the database according to the target control rule corresponding to the target control function of the target sub-control area;

regarding the implementation process of step S21 and step S22, reference may be made to the description of the corresponding parts above, and this embodiment is not described in detail.

Step S23, analyzing the first monitoring data and the second monitoring data to obtain the operation habit information of the user to the target control function in the target office area;

step S24, generating a control instruction aiming at the target control function according to the target control rule and the operation habit information;

the monitoring data sent by each subsystem can also comprise historical data of each control device manually controlled by a user, and in order to realize humanized control of the office area, the acquired monitoring data can be analyzed to obtain the operation habit information of the user on the target control function in the target office area, such as the use habit of the staff in the target office area on the temperature of the air conditioner, so that the generated control instruction content can be determined by combining the use habit in the process of remotely and dynamically adjusting the temperature of the air conditioner.

It can be understood that the use habits of staff in different time periods in the same office area on the air conditioner may be different, and the temperature adjustment ranges of the air conditioning equipment in the office area are different; similarly, the staff in different office areas have different habits on the use of the air conditioner temperature, and the temperature adjustment ranges of the air conditioning equipment in the office areas are different, and the temperature adjustment ranges can be analyzed and determined according to the above-described mode, and the application does not limit the temperature adjustment ranges.

Therefore, compared with the fixed adjustment range of the air conditioning equipment in each office area, the implementation mode for dynamically configuring the temperature adjustment range of the air conditioning equipment aiming at the use habits of different users in different office areas on the air conditioning temperature better meets the requirements of the users in the corresponding office areas on the air conditioning temperature, and the users do not need to manually adjust the air conditioning temperature.

The operation habit information may include working parameters of different control devices in different working periods, working durations of control devices in different office areas, and the like, the content of the operation habit information is not limited in the present application, and for different control functions, modes indicating operation habits of users on corresponding control devices may be different, including but not limited to the use habits of the air conditioning devices listed above.

Step S25, sending the control command to the subsystem corresponding to the target sub-control area;

with regard to the transmission process of the control command, reference may be made to the description of the corresponding parts of the above embodiments. In practical application, the control instruction may be a start instruction of the control device, an adjustment instruction of the working parameter, a close instruction, a start instruction of a certain protection function, and the like, and for different control application requirements, the content of the control instruction may be different, and detailed description is not given in this application.

After the subsystem receives the control instruction generated by the main system forwarded by the message proxy server, the corresponding control of the target control device can be realized accordingly, the specific control process can be determined according to the content of the control instruction, and the application is not limited. In some embodiments, before executing the control instruction, the subsystem may compare the received control instruction with a locally stored control instruction, and if the two are different, may update the locally stored control instruction of the subsystem, and adjust the operating state of the target control device in the subsystem in response to the received control instruction, so as to update the first monitoring data.

And step S26, receiving the control response information fed back by the subsystem and recording the control response information.

In an embodiment of the present application, the control response information may be determined based on a comparison of the control command with a locally stored control command of the subsystem. As described above, after the subsystem executes the control instruction, the execution result may be fed back to the main system record for subsequent query of the control history. Through the comparison, if the working parameters of the target control equipment are not changed, the working state of the target control equipment can be updated without adjusting the working parameters, and in this case, the comparison result can also be fed back to the main system, and the response result of the generated corresponding control instruction is recorded.

The target sub-control area described in the above embodiments is an air-conditioning control area, the first monitoring data includes environment data of the target office area, and the second monitoring data includes conference reservation information and user access record information for the target office area; the conference booking information can explain the intelligent building control process under the conditions of booking conference time, the number of participants and the like, namely how to realize dynamic adjustment of the air conditioner temperature of the target office area, and the purposes of energy conservation and emission reduction are achieved while the temperature adjustment requirement of the target office area is met.

As shown in fig. 5, a flow chart of another optional example of the intelligent building control method provided in the present application is mainly described in the present embodiment, and for other control steps of the intelligent building control method, reference may be made to the description of corresponding parts in the above embodiments, which is not repeated in this embodiment. The method may be implemented by a host system, such as a client and a host server, in cooperation with each other. As shown in fig. 5, the method may include:

step S31, responding to the control request aiming at the intelligent building and outputting a control page aiming at the intelligent building;

step S32, responding to the input operation of the air conditioner control area in the control page, and calling environmental data, meeting reservation information and user access record information for realizing the air conditioner temperature control of the target office area from the database according to the target control rule of the air conditioner temperature control;

step S33, generating a starting instruction of the air conditioning equipment aiming at the target office area according to the number of participants and the environmental data contained in the conference reservation information;

step S34, according to the conference booking time contained in the conference booking information, at the first time before the conference starts, sending a starting instruction to an air-conditioning subsystem corresponding to the air-conditioning control area;

in the embodiment of the application, in air conditioner temperature control application, in order to realize more detailed control of different office areas, for different target office areas, the application will combine the density of people in the target office area, the humiture data, the data such as the use habit of the user to the air conditioning equipment, and preset the target control rule of configuration, send the control command to the air conditioning equipment in the target office area to the air conditioning subsystem, this control command can be sent according to certain time frequency, after the air conditioning subsystem receives each control command, can handle according to the mode that above-mentioned described.

The generation and transmission processes of the control instruction can be determined according to a preset target control rule, and the target control rule can be constructed according to monitoring data of different personnel densities, different temperatures and humidities, different use habits of air-conditioning equipment and the like in different office areas or data obtained based on monitoring data analysis and the like.

In the air conditioner temperature control application provided by the embodiment of the application, when a target office area is a conference room, the reserved conference information of the conference room can be called, at a certain fixed time point (marked as the first time, the difference value between the first time and the conference start time can be determined according to a target control rule, and the size of the difference value is not limited by the application) before the conference starts, a starting instruction generated according to the number of participants and environmental data is sent to an air conditioner subsystem, the air conditioner subsystem responds to the starting instruction to start the air conditioner equipment of the target office area to enter a working state, and the specific working temperature can be determined according to the number of participants and the environmental data and is added into the starting instruction to be sent.

In still other embodiments, a start instruction may be directly generated and sent to the air conditioning subsystem, the air conditioning equipment in the target office area is started to enter the default temperature for operation, and then the air conditioning temperature is dynamically adjusted in the manner described above, and the implementation process is not described in detail.

Step S35, updating the number of participants according to the latest obtained user access record information;

step S36, according to the updated number of participants and the latest obtained environmental data, sending a temperature adjusting instruction aiming at the air-conditioning equipment in the target office area to the air-conditioning subsystem;

in practical application of the method, each subsystem can acquire corresponding monitoring data in real time or periodically and send the latest acquired monitoring data to the main system so as to update the monitoring data in the corresponding control area in the control page of the main system and ensure the control reliability.

Therefore, in the air conditioner temperature control process, after the air conditioner in the target office area is started to enter the working state, the temperature in the target office area changes, and the air conditioner subsystem can send the newly acquired environmental data to the main system. In addition, in the process of a conference, members may leave or join, which causes the number of participants to change, but the space of the target office area is not changed, so that the density of the personnel in the target office area changes, the corresponding target control rule may change, the temperature requirement of the target office area changes, and the output temperature of the air conditioning equipment needs to be readjusted.

Under the circumstance, the main system can determine the output temperature of the target control equipment to be adjusted according to the updated number of participants and the latest acquired environmental data and the target control rule, can send corresponding temperature adjustment instructions to the air conditioning subsystem, and the air conditioning subsystem responds to the temperature adjustment instructions to adjust the temperature parameters of the air conditioning equipment in the target office area, and the implementation method of the temperature adjustment is not described in detail in the application.

And step S37, sending a closing instruction aiming at the air conditioning equipment of the target office area to the air conditioning subsystem when detecting that the number of participants in the first time period is zero.

After the above analysis, if the number of participants is zero within a certain time, that is, the number of people leaving the conference room is the same as the number of people entering the conference room and does not change within a certain time, the conference can be considered to be finished. The number of people leaving the conference room and the number of people entering the conference room can be determined through user access information sent by the user access subsystem, and details about the working process of the user access subsystem are not described in the application.

According to the mode, under the condition that the meeting is automatically judged to be finished, the main system can send a closing instruction to the air conditioning subsystem to automatically close the air conditioning equipment in the meeting room, and the technical problem that the user forgets to close the air conditioning equipment when leaving the meeting and energy is wasted is solved.

In some embodiments, when the meeting is determined to be ended, a closing instruction may be sent to the air-conditioning subsystem after a second duration; or judging whether a new booked conference exists in the second time length by combining the booked conference information, and if so, not sending a closing instruction; if not, a closing instruction is sent to save energy consumption.

In still other embodiments, the main system may also send a shutdown instruction for the air-conditioning equipment in the target office area to the air-conditioning subsystem when detecting the meeting ending instruction, and the air-conditioning subsystem controls the air-conditioning equipment to end the operation in response to the shutdown instruction. In this case, the conference end instruction may be generated based on the conference end notification information sent by the client, such as a conference end instruction submitted by the conference applicant on the system; or the conference end time in the reserved conference time is generated, that is, when the system time is detected to reach the conference end time, a conference end instruction is generated; or after the second time length, a conference ending instruction is generated, and the like.

To sum up, the intelligent building system is started in the application, the control area comprising the main system and at least one subsystem is displayed in the control area in the output control page, and therefore the working personnel do not need to open a plurality of systems for completing different works at the same time, can directly complete various works in one control page, and the intelligent building system is very convenient.

In addition, in the air conditioner temperature control application, the environment temperature and humidity data, the density of personnel in a target office area, the use habit of the personnel on the air conditioner and other data can be combined, the control equipment in the corresponding office area can be finely controlled, the temperature control requirement of the target office area is met, and the purposes of energy conservation and emission reduction are achieved.

Referring to fig. 6, a flow chart of yet another alternative example of the intelligent building control method proposed by the present application, which may be executed by a host server, as shown in fig. 6, may include:

step S41, receiving a control request for the intelligent building sent by the client;

step S42, carrying out identity verification on the request account information contained in the control request;

step S43, determining the identity authority information of the request account according to the identity authentication result;

step S44, acquiring control information for the intelligent building matched with the identity authority information;

in the embodiment of the application, the main system can assign the authority according to different roles of the staff, so that the staff can execute the control work under the authority. If it is determined that one or more workers have control authority of some subsystems, then, in the process of logging in the intelligent building control system, the workers perform identity authentication to determine that the workers have the control authority, and further determine control information matched with the authority, that is, determine which subsystems the workers have control authority, and obtain control information of the subsystems, for example, control area information for the intelligent building, monitoring data of control functions corresponding to different control areas, and the like.

And step S45, sending the control information to the client, outputting a control page for the intelligent building by the client, and presenting corresponding monitoring data in different control areas of the control page.

It can be seen that, for workers with different authorities logging in the intelligent building control system, the content of the control page output by the client may be different, the control area with the control authority can be displayed on the control page, and corresponding monitoring data is presented in the control area, and the description of the above embodiments may be referred to for the implementation method of the display of the control page.

In conclusion, in the process that a worker executes the control work of a certain subsystem, the control accuracy of the control work is improved by combining the monitoring data obtained by other subsystems, the control requirement of the worker is met, and meanwhile, the energy conservation and emission reduction of air conditioner control are realized; in the control process, a worker can check the monitoring data of the subsystems in one control page output by the client, the monitoring data required by the subsystems are not required to be checked by switching and logging in the subsystems, and the control efficiency is improved. In addition, to the control of wisdom building, this application has configured corresponding control authority to the staff of different identities, avoids unauthorized control, causes the control confusion, has improved wisdom building's control reliability and security.

Referring to fig. 7, a schematic structural diagram of an alternative example of the intelligent building control device provided in the present application may include:

the control page output module 11 is used for responding to a control request aiming at the intelligent building and outputting a control page aiming at the intelligent building; the control page comprises a main control area and at least one sub control area of the intelligent building, and different control areas can present monitoring data of corresponding control functions;

the data calling module 12 is configured to respond to an input operation to a target sub-control area in the control page, and call corresponding target monitoring data from a database according to a target control rule corresponding to a target control function of the target sub-control area; the target monitoring data comprises first monitoring data corresponding to the target control function and second monitoring data for assisting in realizing the control of the target control function;

a control instruction generating module 13, configured to generate a control instruction for the target control function according to the first monitoring data and the second monitoring data;

and the control module 14 is configured to send the control instruction to a target control device corresponding to the target sub-control area, and the target control device executes the control instruction to update the first monitoring data.

Optionally, the control instruction generating module 13 may include:

a control instruction obtaining unit, configured to obtain a control instruction for the target control function in response to an instruction input operation for the target control function; the instruction input operation is performed based on the first monitoring data and the second monitoring data;

or,

a first generating unit, configured to generate a control instruction for the target control function according to the target control rule by using the first monitoring data and the second monitoring data;

or,

an operation habit obtaining unit, configured to analyze the first monitoring data and the second monitoring data, and obtain operation habit information of a user on the target control function in a target office area;

and the second generating unit is used for generating a control instruction aiming at the target control function according to the target control rule and the operation habit information.

Based on the analysis, the target sub-control area is an air-conditioning control area, the first monitoring data comprises environment data of a target office area, and the second monitoring data comprises conference reservation information aiming at the target office area; in the case that the conference reservation information includes a reserved conference time and a number of participants, the control instruction generating module 13 may further include:

the starting instruction generating unit is used for generating a starting instruction aiming at the air conditioning equipment in the target office area according to the number of participants and the environment data;

accordingly, the control module 14 may include:

and the starting instruction sending unit is used for sending the starting instruction to the air-conditioning subsystem corresponding to the air-conditioning control area at the first time before the meeting starts according to the reserved meeting time, and the air-conditioning subsystem responds to the starting instruction to start the air-conditioning equipment in the target office area to enter a working state.

Optionally, the control instruction generating module 13 may further include:

the closing instruction generating unit is used for detecting a conference ending instruction and generating a closing instruction aiming at the air conditioning equipment of the target office area; the conference ending instruction is generated based on conference ending notification information sent by a client or generated based on conference ending time in the reserved conference time;

accordingly, the control module 14 may include:

and the closing instruction transmission unit is used for sending a closing instruction aiming at the air conditioning equipment in the target office area to the air conditioning subsystem, and the air conditioning subsystem responds to the closing instruction and controls the air conditioning equipment to finish working.

Optionally, the control instruction generating module 13 may also include:

the participant number updating unit is used for updating the participant number according to the user access record information under the condition that the second monitoring data further comprises the user access record information;

the temperature adjusting instruction generating unit is used for generating a temperature adjusting instruction aiming at the air conditioning equipment in the target office area according to the updated number of participants and the latest obtained environmental data;

the closing instruction generating unit may be further configured to detect that the number of participants is zero within the first time period, and generate a closing instruction, so that the closing instruction transmitting unit of the trigger control module 14 may send a closing instruction for the air conditioning device in the target office area to the air conditioning subsystem.

Accordingly, the control module 14 may include:

and the temperature adjusting instruction sending unit is used for sending a temperature adjusting instruction aiming at the air conditioning equipment in the target office area to the air conditioning subsystem, and the air conditioning subsystem responds to the temperature adjusting instruction to adjust the temperature parameter of the air conditioning equipment.

In still other embodiments, the control module 14 may include:

a control instruction sending unit, configured to send the control instruction to a subsystem corresponding to the target sub-control area, so that the subsystem determines that the received control instruction is different from a locally stored control instruction, updates the locally stored control instruction, and adjusts a working state of a target control device in the subsystem in response to the received control instruction;

a control response information receiving unit, configured to receive control response information fed back by the subsystem, and record the control response information; wherein the control response information is determined based on a comparison of the control instructions with locally stored control instructions of the subsystem.

In still other embodiments, the apparatus may include:

the control rule building module is used for building control rules corresponding to different control functions according to the monitoring data aiming at the different control functions obtained by the database;

or,

a target control rule obtaining module, configured to obtain the target control rule in response to a rule input operation to the target sub-control area; wherein the rule input operation is performed based on the monitoring data presented by the control page.

Optionally, the monitoring data of the corresponding control function acquired by the subsystem corresponding to the sub-control area is forwarded to the database for storage through the message proxy server; and the monitoring data aiming at the same control function in the database is stored in a message queue mode.

In still other embodiments, the control page output module 11 may include:

the identity authentication unit is used for responding to a control request aiming at the intelligent building and authenticating the identity of the request account information contained in the control request;

the identity authority information determining unit is used for determining the identity authority information of the request account according to the identity verification result;

the control information acquisition unit is used for acquiring control information which is matched with the identity authority information and aims at the intelligent building; the control information comprises control area information aiming at the intelligent building and monitoring data of control functions corresponding to different control areas;

and the control information transmission unit is used for sending the control information to a client, outputting a control page aiming at the intelligent building by the client, and presenting corresponding monitoring data in different control areas of the control page.

It should be noted that, various modules, units, and the like in the embodiments of the foregoing apparatuses may be stored in the memory as program modules, and the processor executes the program modules stored in the memory to implement corresponding functions, and for the functions implemented by the program modules and their combinations and the achieved technical effects, reference may be made to the description of corresponding parts in the embodiments of the foregoing methods, which is not described in detail in this embodiment.

The application also provides a storage medium, which stores a program, and the program is executed by a processor to realize the steps of the intelligent building control method.

Finally, it should be noted that, in the embodiments, relational terms such as first, second and the like may be used solely to distinguish one operation, unit or module from another operation, unit or module without necessarily requiring or implying any actual such relationship or order between such units, operations or modules. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, or system. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method or system that comprises the element.

The embodiments in the present description are described in a progressive or parallel manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. The device, the equipment and the system disclosed by the embodiment correspond to the method disclosed by the embodiment, so that the description is relatively simple, and the relevant points can be referred to the method part for description.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present application. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the application. Thus, the present application is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. An intelligent building control method is characterized by comprising

Responding to a control request aiming at the intelligent building, and outputting a control page aiming at the intelligent building; the control page comprises a main control area and at least one sub control area of the intelligent building, and different control areas can present monitoring data of corresponding control functions;

responding to the input operation of a target sub-control area in the control page, and calling corresponding target monitoring data from a database according to a target control rule corresponding to a target control function of the target sub-control area; the target monitoring data comprises first monitoring data corresponding to the target control function and second monitoring data for assisting in realizing the control of the target control function;

generating a control instruction aiming at the target control function according to the first monitoring data and the second monitoring data;

and sending the control instruction to target control equipment corresponding to the target sub-control area, executing the control instruction by the target control equipment, and updating the first monitoring data.

2. The method of claim 1, wherein generating control instructions for the target control function based on the first monitoring data and the second monitoring data comprises:

responding to the instruction input operation aiming at the target control function to obtain a control instruction aiming at the target control function; the instruction input operation is performed based on the first monitoring data and the second monitoring data;

or,

generating a control instruction aiming at the target control function by utilizing the first monitoring data and the second monitoring data according to the target control rule;

or,

analyzing the first monitoring data and the second monitoring data to obtain operation habit information of a user on the target control function in a target office area;

and generating a control instruction aiming at the target control function according to the target control rule and the operation habit information.

3. The method of claim 2, wherein if the target sub-control area is an air-conditioning control area, the first monitoring data comprises environment data of a target office area, and the second monitoring data comprises conference reservation information for the target office area; the conference reservation information comprises reserved conference time and the number of participants;

generating a control instruction for the target control function by using the first monitoring data and the second monitoring data according to the target control rule, and sending the control instruction to target control equipment corresponding to the target sub-control area, wherein the method comprises the following steps:

generating a starting instruction for the air conditioning equipment in the target office area according to the number of participants and the environment data;

and according to the reserved meeting time, at the first time before the meeting begins, the starting instruction is sent to the air-conditioning subsystem corresponding to the air-conditioning control area, and the air-conditioning subsystem responds to the starting instruction to start the air-conditioning equipment of the target office area to enter a working state.

4. The method according to claim 3, wherein the generating a control instruction for the target control function by using the first monitoring data and the second monitoring data according to the target control rule, and sending the control instruction to a target control device corresponding to the target sub-control area further includes:

detecting a meeting ending instruction, sending a closing instruction aiming at the air conditioning equipment of the target office area to the air conditioning subsystem, and controlling the air conditioning equipment to end working by the air conditioning subsystem in response to the closing instruction; the conference ending instruction is generated based on conference ending notification information sent by a client or generated based on conference ending time in the reserved conference time;

or,

under the condition that the second monitoring data further comprises user access record information, updating the number of the participants according to the user access record information;

sending a temperature adjusting instruction aiming at the air conditioning equipment of the target office area to the air conditioning subsystem according to the updated number of participants and the latest obtained environmental data, and adjusting the temperature parameter of the air conditioning equipment by the air conditioning subsystem in response to the temperature adjusting instruction;

and sending a closing instruction aiming at the air conditioning equipment of the target office area to the air conditioning subsystem when the number of the participants is detected to be zero in the first time period.

5. The method according to claim 1, wherein the sending the control instruction to the target control device corresponding to the target sub-control area includes:

sending the control instruction to a subsystem corresponding to the target sub-control area, so that the subsystem determines that the received control instruction is different from a locally stored control instruction, updates the locally stored control instruction, and responds to the received control instruction to adjust the working state of target control equipment in the subsystem;

receiving control response information fed back by the subsystem, and recording the control response information; wherein the control response information is determined based on a comparison of the control instructions with locally stored control instructions of the subsystem.

6. The method according to any one of claims 1 to 5, further comprising:

according to monitoring data aiming at different control functions obtained by a database, establishing control rules corresponding to the different control functions respectively;

or,

the monitoring data presented by the control page is executed.

7. The method according to any one of claims 1 to 5, characterized in that the monitoring data of the corresponding control function acquired by the subsystem corresponding to the sub-control area is forwarded to the database for storage through a message proxy server;

and the monitoring data aiming at the same control function in the database is stored in a message queue mode.

8. The method according to any one of claims 1 to 5, wherein the outputting a control page for the smart building in response to a control request for the smart building comprises:

responding to a control request aiming at the intelligent building, and performing identity verification on request account information contained in the control request;

determining identity authority information of the request account according to the identity verification result;

acquiring control information which is matched with the identity authority information and aims at the intelligent building; the control information comprises control area information aiming at the intelligent building and monitoring data of control functions corresponding to different control areas;

and sending the control information to a client, outputting a control page aiming at the intelligent building by the client, and presenting corresponding monitoring data in different control areas of the control page.

9. An intelligent building control device, the device comprising:

the control page output module is used for responding to a control request aiming at the intelligent building and outputting a control page aiming at the intelligent building; the control page comprises a main control area and at least one sub control area of the intelligent building, and different control areas can present monitoring data of corresponding control functions;

the data calling module is used for responding to input operation of a target sub-control area in the control page and calling corresponding target monitoring data from a database according to a target control rule corresponding to a target control function of the target sub-control area; the target monitoring data comprises first monitoring data corresponding to the target control function and second monitoring data for assisting in realizing the control of the target control function;

a control instruction generating module, configured to generate a control instruction for the target control function according to the first monitoring data and the second monitoring data;

and the control module is used for sending the control instruction to target control equipment corresponding to the target sub-control area, and the target control equipment executes the control instruction and updates the first monitoring data.

10. An intelligent building control system, comprising a main system and at least one subsystem for intelligent building, and a message proxy server for enabling data transmission between the main system and the subsystem, wherein:

the main system comprises a client, a main server and a database, wherein the main server comprises at least one memory and at least one processor;

the memory is used for storing a program for realizing the intelligent building control method according to any one of claims 1-8;

the processor is used for loading and executing the program stored in the memory to realize the intelligent building control method according to any one of claims 1-8;

the subsystem comprises a sub-server and at least one control device;

and the sub-server receives a control instruction which is forwarded by the message proxy server and is generated by the main server and aims at the target control equipment, sends the control instruction to the target control equipment for execution, and updates the first monitoring data.

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