CN111442346A

CN111442346A - Central heating control method and device, computer equipment and storage medium

Info

Publication number: CN111442346A
Application number: CN202010245448.5A
Authority: CN
Inventors: 金海魁; 王健; 王颖
Original assignee: Architecture Design and Research Institute of Tongji University Group Co Ltd
Current assignee: Architecture Design and Research Institute of Tongji University Group Co Ltd
Priority date: 2020-03-31
Filing date: 2020-03-31
Publication date: 2020-07-24

Abstract

The application relates to a central heating control method, a central heating control device, computer equipment and a storage medium. The method comprises the following steps: receiving heating reservation information sent by a user account; the heating reservation information comprises house information and a non-heating time period corresponding to the user account; generating a first closing instruction corresponding to the house heating controller determined by the house information and a second closing instruction corresponding to the energy supply equipment according to the heating reservation information; respectively sending the first closing instruction and the second closing instruction to a house heating controller and energy supply equipment; the first closing instruction and the second closing instruction are respectively used for indicating the house heating controller and the energy supply equipment to keep a closing state in a non-heating time period in the heating standard time period; and when the heating standard time period is finished, determining the saved resources corresponding to the user account according to the house information and the non-heating time period in the heating reservation information. The method can save cost.

Description

Central heating control method and device, computer equipment and storage medium

Technical Field

The present application relates to the field of central heating technologies, and in particular, to a method and an apparatus for controlling central heating, a computer device, and a storage medium.

Background

With the development of the field of thermal energy, the centralized heating technology is more and more popularized in the life of people. The central heating technology is to preset a central heat source and then transfer the heat in the central heat source to each user through a pipeline. With the expansion of the central heating range in north and even in China, the energy consumption is further increased. The existing central heating mode is generally central heating by coal-fired and gas-fired boilers, wherein more advanced clean heating modes such as cogeneration, waste heat utilization, geothermal energy, air energy and the like are popularized and utilized nationwide.

However, the existing centralized heating mode can provide all-weather heating for users no matter whether the users have all-weather heating requirements or not. Therefore, the existing heating mode has lower automation level, and the problem of high heating cost is caused by overlong heating time.

Disclosure of Invention

In view of the above, it is desirable to provide a central heating control method, a central heating control apparatus, a computer device, and a storage medium that can reduce costs.

A central heating control method, the method comprising:

receiving heating reservation information sent by a user account; the heating reservation information comprises house information and a non-heating time period corresponding to the user account;

generating a first closing instruction corresponding to the house heating controller determined by the house information and a second closing instruction corresponding to the energy supply equipment according to the heating reservation information;

sending the first closing instruction to the house heating controller; the first closing instruction is used for indicating the house heating controller to keep a closing state in the non-heating time period in the heating standard time period;

sending the second closing instruction to the energy supply equipment; the second off instruction is used for instructing the energy supply equipment to keep an off state in the non-heating time period in the heating standard period;

and when the heating standard time period is finished, determining the saved resources corresponding to the user account according to the house information and the non-heating time period in the heating reservation information.

A central heating control apparatus, the apparatus comprising:

the receiving module is used for receiving heating reservation information sent by a user account; the heating reservation information comprises house information and a non-heating time period corresponding to the user account;

the generating module is used for generating a first closing instruction corresponding to the house heating controller determined by the house information and a second closing instruction corresponding to the energy supply equipment according to the heating reservation information;

the sending module is used for sending the first closing instruction to the house heating controller; the first closing instruction is used for indicating the house heating controller to keep a closing state in the non-heating time period in the heating standard time period;

the sending module is further used for sending the second closing instruction to the energy supply equipment; the second off instruction is used for instructing the energy supply equipment to keep an off state in the non-heating time period in the heating standard period;

and the determining module is used for determining the saved resources corresponding to the user account according to the house information and the non-heating time period in the heating reservation information when the heating standard time period is finished.

A computer arrangement comprising a memory having a computer program stored therein and a processor implementing the steps of the above central heating control method when the computer program is executed.

A computer-readable storage medium, on which a computer program is stored which, when being executed by a processor, carries out the steps of the above-mentioned central heating control method.

The central heating control method, the central heating control device, the computer equipment and the storage medium receive the heating reservation information sent by the user account number and determine the non-heating time period of the user. And respectively generating corresponding closing instructions according to the heating reservation information, and sending the closing instructions to the corresponding house heating controllers and energy supply equipment. And the closing instructions sent to the house heating controller and the energy supply equipment are respectively used for indicating the house heating controller and the energy supply equipment to keep in a closing state in a non-heating time period in the heating standard time period. And when the heating standard time period is finished, determining the saved resources corresponding to the user account according to the heating reservation information. Through the mode, the heating time of energy supply equipment can be reduced, so that the heating cost of a user is saved, the self-feedback of the user brings benefits, and the centralized heating control effect of self-driving force is achieved. Meanwhile, each user can be used as the center, and heating is carried out according to the heating requirement of each user in the future time period, so that the decentralized centralized heating control effect is achieved. And the second closing instruction enables the energy supply equipment to stop heating in a time period when the user does not need heating, so that the waste of energy is reduced, and the energy utilization is more reasonable.

Drawings

FIG. 1 is a diagram of an exemplary central heating control system;

FIG. 2 is a schematic flow chart of a central heating control method according to an embodiment;

FIG. 3 is a flowchart illustrating steps of storing heating reservation information in one embodiment;

fig. 4 is a block configuration diagram of a central heating control method in one embodiment;

FIG. 5 is a schematic flow chart of a central heating control method according to another embodiment;

FIG. 6 is a block diagram showing the construction of a central heating control apparatus according to an embodiment;

fig. 7 is a block diagram showing the construction of a central heating control apparatus according to another embodiment;

FIG. 8 is a diagram illustrating an internal structure of a computer device according to an embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The central heating control method provided by the application can be applied to the application environment shown in fig. 1. The terminal 110 communicates with the server 120 through a network, the server 120 communicates with the room heating controller 130 through the network, and the server 120 communicates with the energy supply device 140 through the network. The terminal 110 may be, but not limited to, various personal computers, notebook computers, smart phones, tablet computers, and portable wearable devices, and the server 120 may be implemented by an independent server or a server cluster formed by a plurality of servers. The house heating controller 130 may be specifically implemented by an electronic valve. The energy supply device 140 may be, in particular, an information receiving and processing device installed on the heating machine for controlling the heating. In which the power supply device 140 controls heating on a heating machine, and hot water or steam in the heating machine is introduced into the house through the house heater 130.

It is understood that the server 120 receives heating reservation information transmitted through the user account registered on the terminal 110, wherein the heating reservation information includes house information and a non-heating time period corresponding to the user account registered on the terminal 110. The server 120 generates a first shutdown command corresponding to the room heating controller 130 specified by the room information and a second shutdown command corresponding to the energy supply device 140, in accordance with the heating reservation information. The server 120 transmits a first closing instruction to the room heating controller 130, where the first closing instruction is used to instruct the room heating controller 130 to maintain a closed state in a non-heating period in the heating standard period. The server 120 transmits a second turn-off command to the power supply apparatus 140, the second turn-off command being used to instruct the power supply apparatus 140 to maintain a turn-off state during a non-heating period in the heating standard period. When the heating standard period is over, the server 120 determines the saved resources corresponding to the user account logged in the terminal 110 according to the house information and the non-heating period in the heating reservation information.

In one embodiment, as shown in fig. 2, a central heating control method is provided, which is described by taking the method as an example applied to the server 120 in fig. 1, and the central heating control method includes the following steps:

s202, receiving heating reservation information sent by a user account; the heating reservation information comprises house information and a non-heating time period corresponding to the user account.

The user account is an account used when the user logs in the terminal, and the user account can be specifically associated with a mobile phone number, an identity card number or a house number of the user. The heating reservation information is the reservation information filled by the user according to the future heating demand. The house information is information related to a house where the user lives, such as a house number, a housing area, or house heating controller information corresponding to the house. The non-heating time period is a time period when the user does not need heating.

In one embodiment, a user logs in an Application running on a terminal through a user account, for example, the user logs in an APP (Application) running on a mobile phone through the user account, and fills in heating reservation information on the APP, for example, information such as a house number, a housing area of the house, a non-heating time period, and the like. The heating reservation information filled by the user can be sent to the server through the network, so that the server can receive the heating reservation information sent by the user account for analysis and feedback processing.

In one embodiment, the application program presets a non-heating time period, for example, every four hours is used as a time period, the non-heating time period is set to six time periods of 8:00-12:00, 12:00-16:00, 16:00-20:00, 20:00-24:00, 24:00-4:00, and 4:00-8:00, and the application program is only provided for the user to select the time period. The method comprises the steps that a user logs in an application program on a terminal through a user account, corresponding house information is filled in the application program, a non-heating time period meeting the personal heating requirement is selected from preset non-heating time periods, corresponding heating reservation information is generated according to the filled information, and the heating reservation information is sent to a server through the user account.

And S204, generating a first closing instruction corresponding to the room heating controller determined by the room information and a second closing instruction corresponding to the energy supply equipment according to the heating reservation information.

The house heating controller is installed at a hot water or steam house, and the house heating controller can be an electronic valve. Hot water or steam can enter the user houses through the house heating controllers, and each user house has a corresponding house heating controller.

The first shutdown command is a command generated by the server for shutting down the room heating controller, and the second shutdown command is a command generated by the server for shutting down the power supply device. The energy supply device is a device for controlling heating, and specifically may be an information receiving and processing device installed on a heating machine.

In one embodiment, a user logs in a terminal through a user account, and heating reservation information is sent to a server through the terminal. After receiving the heating reservation information sent by the terminal through the network, the server can send feedback information to the terminal, such as information of successful reservation feedback or failure reservation feedback. When the terminal receives the reservation success information sent by the server, the terminal indicates that the user has successfully reserved the hot water or the steam in the matched time period according to the self heating requirement. When the terminal receives the reservation failure information sent by the server, the user can adjust the corresponding heating reservation information in real time so as to ensure that the user does not perform heating in the non-heating time period.

In one embodiment, after receiving the heating reservation information sent by the terminal through the network, the server may temporarily store the received heating reservation information in the database. The server generates a first closing instruction corresponding to the house heating controller and a second closing instruction corresponding to the energy supply equipment according to the heating reservation information temporarily stored in the database.

In one embodiment, a user logs in a terminal through a user account, and heating reservation information is sent to a server through the terminal. After the server receives the heating reservation information sent by the terminal through the network, the information security system on the server starts to operate, so that the communication security and the storage security of the heating reservation information are guaranteed.

S206, sending the first closing instruction to a house heating controller; the first closing instruction is used for instructing the house heating controller to keep a closing state in a non-heating time period in the heating standard time period.

The heating standard time interval is the length of a standard heating period, and can be specifically determined according to the winter time interval of each region. For example, in most northern areas, central heating can be started from the beginning of 12 months of the year and ended at the end of 3 months of the next year, so that the standard heating period is 4 months, namely, from 1 day at 12 months to 31 days at 3 months of the next year.

In one embodiment, the server sends a first close command to a house heating controller, such as an electronic valve, over the network. The wireless communication equipment is arranged on the electronic valve, and when the wireless communication equipment on the electronic valve receives a first closing instruction fed back by the server, the electronic valve can be automatically closed, so that the inlet of hot water or steam entering the house is cut off.

In one embodiment, the wireless communication device on the electronic valve can automatically close the electronic valve after receiving a first closing instruction fed back by the server, and the electronic valve does not automatically switch to other states before receiving other instructions fed back by the server. That is, the electronic valve will always remain closed during the non-heating period in the heating standard period.

In one embodiment, the heat metering device and the flow rate metering device are installed at the rear side of the room heating controller, such as at the rear side of the electronic valve. The heat metering equipment is mainly used for metering the use condition of hot water or steam of a user, and the flow rate metering equipment is mainly used for counting the flow of the hot water or the steam, and can prevent the user from heating in a non-heating time period. The wireless communication device installed on the electronic valve can send the data collected by the heat metering device and the flow rate metering device to a server for corresponding analysis processing.

S208, sending a second closing instruction to energy supply equipment; the second off command is used to instruct the power supply device to maintain an off state during a non-heating period in the heating standard period.

In one embodiment, the server sends a second shutdown command to a power device, such as an information receiving and processing device installed on the heating machine, via the network. And when the information receiving and processing equipment receives a second closing instruction fed back by the server, the hot water or steam outlet on the heating machine can be automatically closed to stop heating.

In one embodiment, after the information receiving and processing device installed on the heating machine receives the second closing instruction fed back by the server, the hot water or steam outlet on the heating machine can be automatically closed, and the information receiving and processing device does not automatically switch to other states before receiving other instructions fed back by the server. That is, the power supplying device will always be kept in the off state during the non-heating period in the heating standard period.

In one embodiment, when the information receiving and processing device installed on the heating machine receives the second closing instruction fed back by the server, feedback information, such as information of successful reservation or failed reservation, may be sent to the server. And when the server receives the reservation success information sent by the information receiving and processing equipment, the server indicates that the heating machine stops heating in the non-heating time period according to the heating reservation information of the user. When the server receives the reservation failure information sent by the information receiving and processing equipment, the server can check the heating condition of the heating machine in time or adjust corresponding heating reservation information so as to ensure that the heating machine does not heat in a non-heating time period.

And S210, when the heating standard time period is finished, determining saved resources corresponding to the user account according to the house information and the non-heating time period in the heating reservation information.

The saved resources are the expense cost matched with the non-heating time period, which is reduced because the user sends the heating reservation information.

Specifically, the server may perform data analysis on the non-heating time period in the heating reservation information, so as to determine the corresponding total non-heating time period. And the server takes the product of the total non-heating time and the unit heat price as the saved expenditure expense corresponding to the user account.

In one embodiment, at the end of the heating standard time period, such as at the end of 3 months of the next year, the server may count the heating conditions of the users in the heating standard time period. If the heat metering device and the flow rate metering device respectively record the hot water or steam using condition of the user and count the hot water or steam flow of the user, the server receives the data recorded by the heat metering device and the flow rate metering device, so as to determine the heating condition of the user in the heating standard time period.

In one embodiment, at the end of the heating standard period, the server may analyze the non-heating time period in the heating reservation information to determine a daytime non-heating time period and a nighttime non-heating time period in the non-heating time period. And counting the daytime non-heating time period and the night non-heating time period according to the hours to obtain the daytime non-heating total time and the night non-heating total time. And the server adds the total daytime non-heating time and the total night non-heating time to corresponding unit heat prices respectively, and uses the sum as the saved resource corresponding to the user account.

In one embodiment, at the end of the heating standard period, the server analyzes the house information in the heating reservation information to determine the house area in the house information. And calculating the total expenditure resource of the user in the heating standard time period according to the area of the house and the heat price of the unit area. And acquiring the expenditure resources in unit time according to the total expenditure resources and the heating standard time interval. The server can analyze and process the non-heating time period in the heating reservation information and the obtained unit time expenditure resources, so that the saved resources corresponding to the user account are determined.

In one embodiment, the server takes the difference between the total spending resources corresponding to the user account and the saved resources as the actual spending resources corresponding to the user account. The user logs in an Application program running on the terminal through the user account, for example, the user logs in an APP (Application, Application program) running on the mobile phone through the user account, and pays a fee on the APP according to actual payment resources.

According to the central heating control method, the heating reservation information sent by the user account is received, and the non-heating time period of the user is determined. And respectively generating corresponding closing instructions according to the heating reservation information, and sending the closing instructions to the corresponding house heating controllers and energy supply equipment. And the closing instructions sent to the house heating controller and the energy supply equipment are respectively used for indicating the house heating controller and the energy supply equipment to keep in a closing state in a non-heating time period in the heating standard time period. And when the heating standard time period is finished, determining the saved resources corresponding to the user account according to the heating reservation information. Through the mode, the heating time of energy supply equipment can be reduced, so that the heating cost of a user is saved, the self-feedback of the user brings benefits, and the centralized heating control effect of self-driving force is achieved. Meanwhile, each user can be used as the center, and heating is carried out according to the heating requirement of each user in the future time period, so that the decentralized centralized heating control effect is achieved. And the second closing instruction enables the energy supply equipment to stop heating in a time period when the user does not need heating, so that the waste of energy is reduced, and the energy utilization is more reasonable.

Referring to fig. 3, in an embodiment, before step S204, the central heating control method further includes a step of storing heating reservation information, where the step of storing heating reservation information specifically includes:

and S302, respectively verifying the received heating reservation information sent by different user accounts.

In one embodiment, the server receives heating reservation information sent by different user accounts, temporarily stores the heating reservation information into a database for storage and backup, and analyzes the received heating reservation information so as to determine whether the information format, the house information and the like in the heating reservation information are accurate. When the server detects that the heating reservation information does not include the non-heating reservation time period, the server can send feedback information to the corresponding user account to determine whether the user needs heating all day; when the server detects that the house information in the heating reservation information is not matched with the user account, the server can send feedback information to the corresponding user account, so that the user can modify the heating reservation information in time, and the waste of energy is reduced.

In one embodiment, the server receives heating reservation information sent by different user accounts, and when an operating system running on the server detects that house information in the heating reservation information matches the user account and a non-heating reservation time period selected by the user is an effective time period, for example, 8:00-12:00 and 12:00-16:00 are non-heating time periods, the heating reservation information sent by the corresponding account is effective information and can pass verification.

And S304, determining the geographical area to which the user account corresponding to the verified heating reservation information belongs.

In one embodiment, the server may analyze the house information in the verified heating reservation information, such as geographical location information of the house in the house information. And the server determines the geographical area to which the corresponding user account belongs according to the geographical position information of the house, such as determining the provincial region or the urban region in which the user account is located.

And S306, storing the heating reservation information passing the verification to storage equipment corresponding to the geographical area.

In one embodiment, each province is provided with corresponding energy supply equipment and storage equipment corresponding to the energy supply equipment, the server analyzes the house information in the verified heating reservation information, determines the province where the user account number is located, and sends the verified heating reservation information to the storage equipment corresponding to the province where the user account number is located for storage.

In one embodiment, different provinces are provided with corresponding energy supply devices and storage devices corresponding to the energy supply devices. The storage capacities of the storage devices corresponding to different provinces are different, and the storage capacities can be determined by information such as the user account number of the region and the length of the heating standard time period.

In one embodiment, when the heating reservation information is verified, the storage device corresponding to the corresponding geographical area may generate a new block for storing the heating reservation information. The blocks in different storage devices together form a block chain based on the timing of the generation time.

In the embodiment, the received heating reservation information is verified, and the verified heating reservation information is stored in the storage device of the geographical area corresponding to the user account. Different geographical areas correspond to different storage devices, so that the configuration requirements on each storage device are reduced, and the cost of the storage devices and the cost of maintaining the storage devices are reduced.

In one embodiment, the central heating control method further includes: taking the time period within the heating standard time period except the heating time period as the heating time period; generating a first opening instruction corresponding to a house heating controller and a second opening instruction corresponding to energy supply equipment according to the heating reservation information and the heating time period; sending the first opening instruction to a house heating controller; the first opening instruction is used for indicating the house heating controller to keep an opening state in a heating time period in a heating standard time period; sending a second starting instruction to the energy supply equipment; the second turn-on command is used for instructing the energy supply device to keep the turn-on state in the heating time period in the heating standard period.

In one embodiment, the server takes a time period within the heating standard period except for the heating time period as the heating time period. If the heating standard time period is from 12 months to the end of 3 months of the next year, about 4 months, and the non-heating scheduled time period in the heating scheduled information sent by the user account is 8:00-12:00, 12:00-16:00, then the time period from 16: 00-8:00 days of the current day to the end of 3 months of the next year is taken as the heating time period. The server can temporarily store the received heating reservation information and the determined heating time period into the database according to the heating reservation information and the heating time period. The server generates a first opening instruction corresponding to the house heating controller and a second opening instruction corresponding to the energy supply equipment according to the heating reservation information and the heating time period temporarily stored in the database.

In one embodiment, the server sends a first open command to a house heating controller, such as an electronic valve, over a network. When the wireless communication equipment arranged on the electronic valve receives a first opening instruction fed back by the server, the electronic valve can be automatically opened, so that an inlet for hot water or steam to enter the house is opened. And the electronic valve cannot be automatically switched to other states before receiving other instructions fed back by the server. That is, the electronic valve will always remain open during the heating period in the heating standard period.

In one embodiment, the heat metering device and the flow rate metering device can respectively meter the hot water or steam use condition of the user and the hot water or steam flow of the user, and the flow rate metering device can prevent the user from heating in a non-heating time period. The wireless communication device installed on the electronic valve can send the data collected by the heat metering device and the flow rate metering device to a server for corresponding analysis processing.

In one embodiment, the server sends the second activation command to a power supply device, such as an information receiving and processing device installed on the heating machine, via the network. And when the information receiving and processing equipment receives a second starting instruction fed back by the server, a hot water or steam outlet on the heating machine can be automatically started to start heating. And the information receiving and processing equipment cannot be automatically switched to other states before receiving other instructions fed back by the server. That is, the power supplying device will always be kept in the on state during the heating time period in the heating standard period.

In one embodiment, when the information receiving and processing device installed on the heating machine receives the second start instruction fed back by the server, feedback information, such as information of successful reservation or failed reservation, may be sent to the server. And when the server receives the reservation success information sent by the information receiving and processing equipment, the server indicates that the heating machine is to heat in the heating time period according to the heating reservation information of the user. When the server receives the reservation failure information sent by the information receiving and processing equipment, the server can check the heating condition of the heating machine in time or adjust corresponding heating reservation information so as to ensure that the heating machine heats in a heating time period.

In the above embodiment, the server generates the turn-on instructions corresponding to the room heating controller and the energy supply device respectively according to the heating reservation information and the heating time period, and is used for indicating that the room heating controller and the energy supply device keep on states respectively. By the mode, each user is taken as the center, heating can be performed according to the heating requirement of each user in the future time period, and the heating requirement of the user in the heating time period can be met.

In an embodiment, step S210, that is, when the heating standard time period ends, the step of determining the saved resources corresponding to the user account according to the house information and the non-heating time period in the heating reservation information specifically includes: determining a daytime non-heating time period and a night non-heating time period in the non-heating time period according to the non-heating time period in the heating reservation information; determining the total non-heating time in the daytime and the total non-heating time at night according to the heating standard time period, the non-heating time period in the daytime and the non-heating time period at night; multiplying the total non-heating time in the daytime by the daily unit heat price to obtain saved daytime resources, and multiplying the total non-heating time at night by the night unit heat price to obtain saved night resources; and multiplying the sum of the saved daytime resources and the saved nighttime resources by the cost coefficient to obtain the saved resources corresponding to the user account.

In one embodiment, the server may preset the daytime time period and the nighttime time period, such as setting 8:00-18:00 to the daytime time period and 18: 00-the next day 8:00 to the nighttime time period. When the heating standard time period is finished, the server can analyze the non-heating time period in the heating reservation information and determine the daytime non-heating time period and the night non-heating time period in the non-heating time period.

In one embodiment, the server obtains the total non-heating time in the daytime and the total non-heating time in the night by counting the non-heating time in the daytime and the non-heating time in the night according to the hours. The server takes the product of the total non-heating time in the daytime and the heat price of the daytime unit as the saved daytime resource, and takes the product of the total non-heating time at night and the heat price of the night unit as the saved night resource.

In one embodiment, the server multiplies the sum of the saved daytime resources and the saved nighttime resources by a cost coefficient, and the server takes the resulting product as the saved resources corresponding to the user account. The cost coefficient is a numerical value, and the specific cost coefficient can be determined by the resource cost involved in the heating process of the energy supply equipment, such as the resource cost of the energy supply equipment, network communication, manpower and the like.

In one embodiment, the server can build a user-side self-driving force model, which is an important ring in building a central heating system self-driving force model with a block chain technology as a core, so as to realize the efficient operation of the central heating system. The user-side self-driving force model is that when a user reserves the heating requirement of future time through an APP or an applet on a mobile phone, the user can obtain corresponding saved resources, and therefore the self-driving force of the user is obtained.

For example, the self-driving force model on the user side can obtain the resources saved corresponding to the user account by charging the heating fee corresponding to the heating duration. The saved resources can be obtained by the following formula: w_{1 user saving resources}＝[(A_{1 day time unit heat rate}*N_{Total time of non-heating in 1 day})+(A_{1 night Unit Heat price}*N_{1 Total duration of non-heating night})]*i_{1 cost factor}. Wherein A is_{1 day time unit heat rate}And A_{1 night Unit Heat price}Can be 0.45 yuan/kWh (kilo Watt per hour) and 0.5 yuan/kWh, i, respectively_{1 cost factor}May be 0.5, and the specific value may be determined according to the actual situation of each region. The embodiment of the present application does not limit this. Through the formula, the server can construct a self-driving force model of the central heating system with the block chain technology as the core so as to realize the efficient operation of the central heating system. In the above embodiment, when the heating standard time period ends, the server determines the saved resources corresponding to the user account according to the non-heating time period in the heating reservation information. In this way, heating is stopped in a time period when the user does not need heating, thereby reducing waste of energy. And each user is taken as the center, the time for heating by energy supply equipment can be reduced by determining the non-heating time period of the user, so that the heating cost of the user is saved, the self-feedback of the user brings benefits, and the self-driving force set is further achievedAnd (5) a medium heating control effect.

In an embodiment, step S210, that is, when the heating standard time period ends, the step of determining the saved resources corresponding to the user account according to the house information and the non-heating time period in the heating reservation information specifically includes: determining the area of the house in the house information according to the house information in the heating reservation information, and multiplying the area of the house by the heat price of unit area to obtain the total expenditure resource of the heating standard time period; taking the quotient of the total expenditure resource and the heating standard time interval as the expenditure resource of unit time; and when the heating standard time period is finished, determining the saved resources corresponding to the user account according to the resources paid out in unit time and the non-heating time period in the heating reservation information.

In one embodiment, the server may calculate the total expenditure resources as a function of the floor space of the residence and the heating criteria period. For example, the server receives heating reservation information sent by the user account, and analyzes the house information in the heating reservation information, so as to determine the house area in the house information. The server takes the product of the house area and the heat price of the unit area as the total expenditure resource of the user in the heating standard time period, and the server takes the quotient of the total expenditure resource and the heating standard time period as the expenditure resource of the user in unit time.

In one embodiment, at the end of the heating standard time period, the server may analyze and process the non-heating time period in the heating reservation information and the obtained expenditure resources per unit time, so as to determine the saved resources corresponding to the user account.

In the above embodiment, the area of the house of the user is determined from the house information in the heating reservation information, so as to determine the total expenditure resource of the user in the heating standard time period, and the saved resource corresponding to the user account is determined according to the non-heating time period in the heating reservation information and the total expenditure resource of the user. Through the mode, the waste of energy can be reduced, and the heating cost of a user can be saved.

In one embodiment, when the heating standard time period ends, determining the saved resources corresponding to the user account according to the resource paid out per unit time and the non-heating time period in the heating reservation information includes: determining a daytime non-heating time period and a night non-heating time period in the non-heating time period according to the non-heating time period in the heating reservation information; determining the total non-heating time in the daytime and the total non-heating time at night according to the heating standard time period, the non-heating time period in the daytime and the non-heating time period at night; multiplying the unit time expenditure resources by the total daytime non-heating duration and the daytime heating coefficient to obtain saved daytime resources; multiplying the unit time expenditure resources by the total night non-heating time and the night heating coefficient to obtain saved night resources; and multiplying the sum of the saved daytime resources and the saved nighttime resources by the cost coefficient to obtain the saved resources corresponding to the user account.

In one embodiment, the server obtains the total non-heating time in the daytime and the total non-heating time in the night by counting the non-heating time in the daytime and the non-heating time in the night according to the hours. The server takes the product of the unit time expenditure resource, the total daytime non-heating duration and the daytime heating coefficient as the saved daytime resource, and takes the product of the unit time expenditure resource, the total night non-heating duration and the night heating coefficient as the saved night resource. Wherein the daytime heating coefficient is typically a value less than 1, such as 0.8, and the nighttime heating coefficient is typically a value greater than 1, such as 1.2. The specific heating cost coefficient and the operation cost involved in the heating process of the energy supply equipment are determined, and the embodiment of the application does not limit the determination.

For example, the user-side self-driving force model may obtain resources saved corresponding to the user account by charging a heating fee corresponding to a house area. The saved resources can be obtained by the following formula: w_{2-user saving resources}＝(W_{2-user-saving daytime resources}+W_{Night resource saving by 2 users})*i_{2 cost factor}The saved daytime and nighttime resources are respectively W_{2-user-saving daytime resources}＝(A_{Heat rate per unit area of 2}*S_{2 area of house})÷N_{2 standard time interval of heating supply}*A_{Heating coefficient in 2 day}*N_{2 day non-heating total time}，W_{Night resource saving by 2 users}＝(A_{Heat rate per unit area of 2}*S_{2 area of house})÷N_{2 standard time interval of heating supply}*A_{2 heating coefficient at night}*N_{2 total time of non-heating at night}. Wherein A is_{Heat rate per unit area of 2}Is 5 yuan/month square meter, A_{Heating coefficient in 2 day}And A_{2 heating coefficient at night}May be 0.8 and 1.2, respectively. N is a radical of_{2 standard time interval of heating supply}It may be 4 months (from the beginning of 12 months to the end of 3 months of the following year) and about 3000 hours (hours). S_{2 area of house}May be 100. i.e. i_{2 cost factor}May be 0.5. The specific numerical values can be determined according to the actual conditions of each region. The embodiment of the present application does not limit this. Through the formula, the server can construct a self-driving force model of the central heating system with the block chain technology as the core so as to realize the efficient operation of the central heating system.

In the above embodiment, when the heating standard time period is over, the server determines the saved resources corresponding to the user account according to the house information and the non-heating time period in the heating reservation information. In this way, heating is stopped in a time period when the user does not need heating, thereby reducing waste of energy. And each user is taken as the center, and the non-heating time period of the user is determined, so that the heating time of the energy supply equipment can be reduced, the heating cost of the user is saved, the self-feedback of the user brings benefits, and the centralized heating control effect of the self-driving force is further achieved.

In one embodiment, the central heating control method further includes: determining corresponding total saved cost according to the energy cost and the manual operation cost saved by each user account in the non-heating time period; and taking the resources left in the total saved cost except the saved resources corresponding to each user account as the income of the operation manager.

In one embodiment, the server calculates the energy cost and the manual operation cost saved by the user in the non-heating time period respectively, so as to obtain the corresponding total saved cost. Comparing the total saved cost with the saved resources corresponding to each user account, when the total saved cost is greater than the saved resources corresponding to each user account, indicating that the operation manager obtains the income, and taking the resources left after the saved resources corresponding to each user account are removed from the total saved cost as the income of the operation manager; when the total saved cost is less than or equal to the saved resources corresponding to each user account, it indicates that the operation manager does not receive a profit. The operation manager is the operation manager involved in the heating process of the energy supply equipment.

In one embodiment, the server can build a self-driving force model of an operation manager, which is an important ring in building a self-driving force model of a central heating system taking a block chain technology as a core, so as to realize the efficient operation of the central heating system. The self-driving force model of the operation manager is that the operation manager charges less cost for users, but can obtain greater income through the operation management method, so that the self-driving force of the operation manager is obtained. The income of the operation management party mainly comes from the cost saving of primary energy and the cost saving of labor and operation cost. For example, the self-driving force model of the operation manager can be represented by the following formula, such as: w_{3 increased value of income of operation manager}＝W_{3 energy cost saving}+W_{3 saving of laborOperating costs}-W_{3 user-saving resources}. When W is_{3 increased value of income of operation manager}When the value of (b) is positive, it indicates that the operation manager receives a profit, that is, the central heating control system has achieved an effect, and the efficiency of the central heating control is improved. When W is_{3 increased value of income of operation manager}When the value of (d) is negative, it indicates that the operation manager does not receive any profit, that is, the efficiency of the central heating control system still needs to be improved. At this time, W can be made by adjusting the saved energy cost and the labor operation cost in the total saved cost, or adjusting the user-saved resources_{3 increased value of income of operation manager}The value of (d) is positive, thereby improving the efficiency of the central heating control. Through the formula, the server can construct a self-driving force model of the central heating system with the block chain technology as the core so as to realize the efficient operation of the central heating system.

In the above embodiment, the server subtracts the difference obtained by subtracting the saved resources corresponding to each user account from the sum of the saved energy cost and the manual operation cost of each user account in the non-heating time period, and uses the difference as the profit of the operation manager. Through the self-feedback mode of the user, the operation management party can save the energy cost, thereby bringing the environmental benefit. Meanwhile, the operation manager can save the manual operation cost and obtain corresponding economic benefits, so that the efficiency of central heating control is improved.

In a specific application scenario, referring to fig. 4, the central heating control method may be applied to a central heating intelligent management system, and a specific module configuration diagram includes: the system comprises a user side module, a communication module, an energy supply side module and a system side module. By applying the block chain technology to each module of the management system, a centralized heating management system with self-driving force and decentralization is formed.

In one embodiment, the user-side module primarily includes an end-device information receiving and action system, a heat metering and flow rate metering system, and a client information feedback system. The terminal equipment information receiving and action system is mainly a house heating controller, such as an electronic valve. The electronic valve can be installed at a place where hot water or steam enters a house, referring to fig. 5, the electronic valve has a function of wirelessly receiving information and actions, and after receiving information fed back by a system side module through wireless communication equipment installed in the electronic valve, for example, receiving a first opening/closing instruction, the electronic valve is opened or closed, so that the hot water or steam entering the house is cut off or opened. The heat metering and flow rate metering system is mainly a heat metering device and a flow rate metering device which are remotely transmitted to a system side module. The heat metering equipment is mainly used for metering the heat using condition of each household, so that the charging management is convenient; the flow rate metering device is used for flow statistics of hot water or steam and prevents a user from continuously using the hot water or the steam in a non-heating time period. The client information feedback system is usually implemented by an application program running on the terminal, such as an APP or a wechat applet on the mobile phone. The client information feedback system is mainly used for sending user heating reservation information to the system side module, and the user can reserve the heating requirement of the next day in advance through a mobile phone side APP or a small program. In addition, the APP or the small program on the mobile phone can also execute other functions, such as collecting and paying heating fee, property fee and electric fee, providing convenience service and the like.

In one embodiment, the system-side module primarily includes an operating system, a database system, and an information security system. The operating system is mainly a visual operating interface on the terminal or the server. The operating system is mainly used for data analysis, user query and feedback of information of the energy supply side and the user side, and can send corresponding instructions, such as a first opening/closing instruction and a second opening/closing instruction, to the user side module and the energy supply side module. The database system is mainly composed of information collecting and storing equipment and can provide necessary data storage and support for the operating system, and the database system is used for storing, processing and backing up information from the user side module and the energy supply side module. The information security system is mainly used for guaranteeing the security of information communication and the security of data storage among the modules. The energy supply module is an energy supply device control system, such as an information receiving and processing device installed on the heating machine. The energy supply equipment can be composed of various information receiving and processing equipment and is used for receiving a second opening/closing instruction sent by the system side module and adjusting the heating condition of the heating machine in time. The communication module mainly comprises an information transmission system, such as information transmission among the system side module, the user side module and the energy supply side module is realized through a network.

In one embodiment, the central heating control method specifically includes three levels of information transfer: the information transmission from the user side module to the system side module, the information transmission from the system side module to the user side module and the information transmission from the system side module to the energy supply side module. The information transmission from the user side module to the system side module is specifically as follows: and sending services such as heating demand reservation and the like to an operating system on the system side module by a client information feedback system on the user side module, and reserving the heating demand of the next day or several days in advance. And if the user account sends heating reservation information to the server. The operating system may feed back the information of the reservation success or failure to the client information feedback system, such as the server feeding back the information of the reservation success or failure to the user account.

In one embodiment, the step of information transfer from the system side module to the user side module is specifically: the operating system in the system side module can send an instruction for opening and closing the electronic valve to the information receiving and processing equipment of the user side module, and the electronic valve is opened and closed according to future heating reservation information submitted by the user side module. Such as a server, sends a first on/off command to a wireless communication device mounted on the electronic valve. The information receiving and processing device of the user side module can send the information collected by the end device to the operating system, for example, the wireless communication device installed on the electronic valve can send the data recorded by the heat metering device and the flow rate metering device to the server.

In one embodiment, the operating system on the system-side module may send a future power demand command to the power equipment control system in the power-side module, such as the server sending a second on/off command to the information receiving processing equipment on the heating machine. And according to the energy demand submitted by the user side module, the heating machine supplies heat in the user heating time period. The energy supply device control system can send reservation success or failure information to the operating system, for example, the energy supply device feeds back the reservation success or failure information to the server.

In one embodiment, the server may construct a user-side self-driving force model, that is, when the user reserves a heating demand at a future time through an APP or a WeChat applet on a mobile phone, the user may obtain corresponding saved resources, so as to obtain the self-driving force of the user. If the heating fee corresponding to the heating time is collected, the resources saved corresponding to the user account are obtained, and the saved resources can be obtained according to the following formula: w_{1 user saving resources}＝[(A_{1 day time unit heat rate}*N_{Total time of non-heating in 1 day})+(A_{1 night Unit Heat price}*N_{1 Total duration of non-heating night})]*i_{1 cost factor}. Wherein A is_{1 day time unit heat rate}And A_{1 night Unit Heat price}Can be respectively 0.45 yuan/kWh and 0.5 yuan/kWh, i_{1 cost factor}May be 0.5, and the specific value may be determined according to the actual situation of each region. The embodiment of the present application does not limit this. The resources saved corresponding to the user account are also obtained, for example, by charging a heating fee corresponding to the area of the house. Specifically, the saved resources can be obtained by the following formula: w_{2-user saving resources}＝(W_{2-user-saving daytime resources}+W_{Night resource saving by 2 users})*i_{2 cost factor}Wherein the saved daytime and nighttime resources are respectively W_{2-user-saving daytime resources}＝(A_{Heat rate per unit area of 2}*S_{2 area of house})÷N_{2 standard time interval of heating supply}*A_{Heating coefficient in 2 day}*N_{2 day non-heating total time}，W_{Night resource saving by 2 users}＝(A_{Heat rate per unit area of 2}*S_{2 area of house})÷N_{2 standard time interval of heating supply}*A_{2 heating coefficient at night}*N_{2 total time of non-heating at night}. Wherein A is_{Heat rate per unit area of 2}Is 5 yuan/month square meter, A_{Heating coefficient in 2 day}And A_{2 heating coefficient at night}May be 0.8 and 1.2, respectively. N is a radical of_{2 standard time interval of heating supply}It may be 4 months (from the beginning of 12 months to the end of 3 months of the following year) and about 3000 hours (hours). S_{2 area of house}May be 100. i.e. i_{2 cost factor}May be 0.5. The specific numerical values can be determined according to the actual conditions of each region. The embodiment of the present application does not limit this. Through the formula, the server can construct a self-driving force model of the central heating system with the block chain technology as the core so as to realize the efficient operation of the central heating system.

In one embodiment, the server may construct a self-driving force model of the operation manager, that is, the operation manager may charge less for the user, but may obtain more profit through the operation management method, thereby obtaining the self-driving force of the operation manager. Specifically, the self-driving force model of the operation manager can be represented by the following formula, such as: w_{3 increased value of income of operation manager}＝W_{3 energy cost saving}+W_{3 saved manual operation cost}-W_{3 user-saving resources}. When W is_{3 increased value of income of operation manager}When the value of (b) is positive, it indicates that the operation manager receives a profit, that is, the central heating control system has achieved an effect, and the efficiency of the central heating control is improved. When W is_{3 increased value of income of operation manager}When the value of (d) is negative, it indicates that the operation manager does not receive any profit, that is, the efficiency of the central heating control system still needs to be improved. At this time, W can be made by adjusting the saved energy cost and the labor operation cost in the total saved cost, or adjusting the user-saved resources_{3 increased value of income of operation manager}The value of (d) is positive, thereby improving the efficiency of the central heating control. Through the formula, the server can construct a self-driving force model of the central heating system with the block chain technology as the core so as to realize the efficient operation of the central heating system.

It should be understood that although the various steps in the flow charts of fig. 2-5 are shown in order as indicated by the arrows, the steps are not necessarily performed in order as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least some of the steps in fig. 2-5 may include multiple steps or multiple stages, which are not necessarily performed at the same time, but may be performed at different times, which are not necessarily performed in sequence, but may be performed in turn or alternately with other steps or at least some of the other steps.

In one embodiment, as shown in fig. 6, there is provided a central heating control apparatus 600 including: a receiving module 601, a generating module 602, a sending module 603 and a determining module 604, wherein:

the receiving module 601 is configured to receive heating reservation information sent by a user account; the heating reservation information comprises house information and a non-heating time period corresponding to the user account.

The generating module 602 is configured to generate a first closing instruction corresponding to the room heating controller determined by the room information and a second closing instruction corresponding to the energy supply device according to the heating reservation information.

A sending module 603, configured to send the first closing instruction to the room heating controller; the first closing instruction is used for instructing the house heating controller to keep a closing state in a non-heating time period in the heating standard time period.

The sending module 603 is further configured to send a second closing instruction to the energy supply device; the second off command is used to instruct the power supply device to maintain an off state during a non-heating period in the heating standard period.

The determining module 604 is configured to determine, when the heating standard time period ends, the saved resources corresponding to the user account according to the house information and the non-heating time period in the heating reservation information.

Referring to fig. 7, in an embodiment, the central heating control apparatus 600 further includes a storage module 605 configured to verify the received heating reservation information sent by different user accounts respectively; determining a geographical area to which a user account corresponding to the verified heating reservation information belongs; and storing the heating reservation information passing the verification to storage equipment corresponding to the geographical area.

In one embodiment, the generating module 602 is further configured to use a time period within the heating standard time period except for the heating time period as the heating time period; and generating a first opening instruction corresponding to the house heating controller and a second opening instruction corresponding to the energy supply equipment according to the heating reservation information and the heating time period. The sending module 603 is further configured to send the first start instruction to the room heating controller; the first opening instruction is used for indicating the house heating controller to keep an opening state in a heating time period in a heating standard time period; sending a second starting instruction to the energy supply equipment; the second turn-on command is used for instructing the energy supply device to keep the turn-on state in the heating time period in the heating standard period.

In one embodiment, the determining module 604 is further configured to determine a daytime non-heating time period and a night non-heating time period in the non-heating time period according to the non-heating time period in the heating reservation information; determining the total non-heating time in the daytime and the total non-heating time at night according to the heating standard time period, the non-heating time period in the daytime and the non-heating time period at night; multiplying the total non-heating time in the daytime by the daily unit heat price to obtain saved daytime resources, and multiplying the total non-heating time at night by the night unit heat price to obtain saved night resources; and multiplying the sum of the saved daytime resources and the saved nighttime resources by the cost coefficient to obtain the saved resources corresponding to the user account.

In one embodiment, the determining module 604 is further configured to determine a room area in the room information according to the room information in the heating reservation information, and multiply the room area by a heat price per unit area to obtain a total expenditure resource of the heating standard time period; taking the quotient of the total expenditure resource and the heating standard time interval as the expenditure resource of unit time; and when the heating standard time period is finished, determining the saved resources corresponding to the user account according to the resources paid out in unit time and the non-heating time period in the heating reservation information.

In one embodiment, the determining module 604 is further configured to determine a daytime non-heating time period and a night non-heating time period in the non-heating time period according to the non-heating time period in the heating reservation information; determining the total non-heating time in the daytime and the total non-heating time at night according to the heating standard time period, the non-heating time period in the daytime and the non-heating time period at night; multiplying the unit time expenditure resources by the total daytime non-heating duration and the daytime heating coefficient to obtain saved daytime resources; multiplying the unit time expenditure resources by the total night non-heating time and the night heating coefficient to obtain saved night resources; and multiplying the sum of the saved daytime resources and the saved nighttime resources by the cost coefficient to obtain the saved resources corresponding to the user account.

In one embodiment, the determining module 604 is further configured to determine a corresponding total saved cost according to the energy cost and the manual operation cost saved by each user account in the non-heating time period; and taking the resources left in the total saved cost except the saved resources corresponding to each user account as the income of the operation manager.

For specific limitations of the central heating control device, reference may be made to the above limitations of the central heating control method, which are not described herein again. The modules in the central heating control device may be implemented wholly or partially by software, hardware, or a combination thereof. The modules can be embedded in a hardware form or independent from a processor in the computer device, and can also be stored in a memory in the computer device in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, a computer device is provided, which may be a server, and its internal structure diagram may be as shown in fig. 8. The computer device includes a processor, a memory, and a network interface connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device comprises a nonvolatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, a computer program, and a database. The internal memory provides an environment for the operation of an operating system and computer programs in the non-volatile storage medium. The database of the computer device is used for storing central heating control data. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program is executed by a processor to implement a central heating control method.

Those skilled in the art will appreciate that the architecture shown in fig. 8 is merely a block diagram of some of the structures associated with the disclosed aspects and is not intended to limit the computing devices to which the disclosed aspects apply, as particular computing devices may include more or less components than those shown, or may combine certain components, or have a different arrangement of components.

In one embodiment, a computer device is provided, comprising a memory and a processor, the memory storing a computer program which, when executed by the processor, causes the processor to perform the steps of the central heating control method described above. Here, the steps of the central heating control method may be the steps of the central heating control method according to each of the above embodiments.

In one embodiment, a computer readable storage medium is provided, storing a computer program which, when executed by a processor, causes the processor to perform the steps of the central heating control method described above. Here, the steps of the central heating control method may be the steps of the central heating control method according to each of the above embodiments.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by hardware instructions of a computer program, which can be stored in a non-volatile computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. Any reference to memory, storage, database or other medium used in the embodiments provided herein can include at least one of non-volatile and volatile memory. Non-volatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical storage, or the like. Volatile Memory can include Random Access Memory (RAM) or external cache Memory. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), among others.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present application, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A central heating control method, characterized by comprising:

2. The method of claim 1, wherein before generating a first shutdown command corresponding to the room heating controller determined by the room information and a second shutdown command corresponding to the energy supply device according to the heating reservation information, the method further comprises:

respectively verifying the received heating reservation information sent by different user accounts;

determining a geographical area to which a user account corresponding to the verified heating reservation information belongs;

and storing the heating reservation information passing the verification to storage equipment corresponding to the geographical area.

3. The method of claim 1, further comprising:

taking the time period within the heating standard time period except the non-heating time period as a heating time period;

generating a first starting instruction corresponding to the house heating controller and a second starting instruction corresponding to the energy supply equipment according to the heating reservation information and the heating time period;

sending the first opening instruction to the house heating controller; the first opening instruction is used for indicating the house heating controller to keep an opening state in the heating time period in the heating standard time period;

sending the second starting instruction to the energy supply equipment; the second turn-on command is used for instructing the energy supply device to keep a turn-on state in the heating time period in the heating standard period.

4. The method according to claim 1, wherein the determining the saved resources corresponding to the user account according to the house information and the non-heating time period in the heating reservation information at the end of the heating standard time period comprises:

determining a daytime non-heating time period and a night non-heating time period in the non-heating time period according to the non-heating time period in the heating reservation information;

determining the total non-heating time in the daytime and the total non-heating time at night according to the heating standard time period, the non-heating time period in the daytime and the non-heating time period at night;

multiplying the total daytime non-heating time by the daily unit heat price to obtain saved daytime resources, and multiplying the total night non-heating time by the night unit heat price to obtain saved night resources;

and multiplying the sum of the saved daytime resources and the saved nighttime resources by a cost coefficient to obtain saved resources corresponding to the user account.

5. The method according to claim 1, wherein the determining the saved resources corresponding to the user account according to the house information and the non-heating time period in the heating reservation information at the end of the heating standard time period comprises:

determining the area of the house in the house information according to the house information in the heating reservation information, and multiplying the area of the house by the heat price of unit area to obtain the total expenditure resource of the heating standard time period;

taking the quotient of the total expenditure resource and the heating standard time interval as a unit time expenditure resource;

and when the heating standard time period is finished, determining the saved resources corresponding to the user account according to the resources paid out in unit time and the non-heating time period in the heating reservation information.

6. The method according to claim 5, wherein the determining, at the end of the heating standard time period, the saved resources corresponding to the user account according to the unit time expenditure resources and the non-heating time period in the heating reservation information includes:

multiplying the expenditure resources of unit time with the total daytime non-heating time and the daytime heating coefficient to obtain saved daytime resources;

multiplying the expenditure resources in unit time with the total night non-heating time and the night heating coefficient to obtain saved night resources;

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

determining corresponding total saved cost according to the energy cost and the manual operation cost saved by each user account in the non-heating time period;

and taking the resources left in the total saved cost except the saved resources corresponding to each user account as the income of an operation manager.

8. A central heating control apparatus, comprising:

9. A computer device comprising a memory and a processor, the memory storing a computer program, characterized in that the processor, when executing the computer program, implements the steps of the method of any of claims 1 to 7.

10. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 7.