CN117109130A - Automatic energy supply method and device based on indoor temperature time-sharing partition - Google Patents

Abstract

The invention relates to an automatic energy supply method and device based on indoor temperature time-sharing partition, wherein the method comprises the steps of determining a temperature compensation coefficient and floors; acquiring an upper limit value/a lower limit value of indoor/outdoor temperature, outdoor real temperature, an underground/overground outdoor temperature compensation coefficient and an underground/overground indoor temperature compensation coefficient; inputting the upper limit value/lower limit value of the indoor and outdoor temperatures, the outdoor real temperature, the temperature compensation coefficient, the underground/overground outdoor temperature compensation coefficient and the underground/overground indoor temperature compensation coefficient into the first/second temperature prediction model so that the first/second temperature prediction model outputs the underground/overground required temperature; the underground/above-ground indoor temperature and the above-ground indoor temperature are adjusted according to the required underground/above-ground temperature. The indoor temperature is automatically regulated according to the calculated underground/overground required temperature, so that the problem that the indoor temperature on the ground and the indoor temperature in the underground are simultaneously regulated at a low speed is solved, and the effect of regulating the indoor temperature on the ground/underground with high efficiency is achieved.

Description

Automatic energy supply method and device based on indoor temperature time-sharing partition

Technical Field

The invention relates to the technical field of autonomous control/regulation energy, in particular to an automatic energy supply method and device based on indoor temperature time-sharing partition.

Background

Energy is the basis of economic and social development, and the energy consumption gradually goes from rough, low-efficiency to saving and high-efficiency. The continuous trend of energy conservation and high efficiency are often realized by means of active energy supply.

For example, when indoor temperature is adjusted in a room, the indoor temperature is usually adjusted directly to the room according to different outdoor temperatures so that the indoor temperature reaches a comfortable state. However, in the prior art, the building comprises a basement and an overground indoor, and the closed environment in the basement and the overground indoor and the speed of transferring and consuming energy are inconsistent, so that the indoor temperature is actively regulated only by relying on the outdoor temperature, and the problem that the indoor temperature is too small when the indoor temperature is proper on the ground is caused; or the problem of overlarge temperature in the ground room when the temperature in the basement is proper can be caused.

In the prior art, for the above-mentioned problems, the above-mentioned regulation of the above-ground indoor temperature and the regulation of the basement indoor temperature are separately managed, that is, personnel are required to set the above-ground indoor temperature and the basement indoor temperature, so that the speed of simultaneously regulating the above-ground indoor temperature and the basement indoor temperature is low.

Disclosure of Invention

The invention aims to provide an automatic energy supply method based on indoor temperature time-sharing partition, which has the characteristic of efficiently adjusting the temperature in the ground/basement.

The first object of the present invention is achieved by the following technical solutions:

an automatic energy supply method based on indoor temperature time-sharing partition comprises the following steps:

determining a temperature compensation coefficient and floors of a building, wherein the floors comprise underground floors and overground floors;

acquiring an upper limit value of indoor temperature, a lower limit value of indoor temperature, an upper limit value of outdoor temperature, a lower limit value of outdoor temperature and outdoor real temperature;

determining an outdoor temperature compensation coefficient of the basement, an indoor temperature compensation coefficient of the basement, an outdoor temperature compensation coefficient of the ground and an indoor temperature compensation coefficient of the ground according to the basement and the ground floors respectively;

inputting the upper limit value of the indoor temperature, the lower limit value of the indoor temperature, the upper limit value of the outdoor temperature, the lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the basement exterior temperature compensation coefficient and the basement interior temperature compensation coefficient into a first temperature prediction model so that the first temperature prediction model outputs the underground required temperature, and the first temperature prediction model is used for outputting the basement required temperature;

Inputting the upper limit value of the indoor temperature, the lower limit value of the indoor temperature, the upper limit value of the outdoor temperature, the lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient and the above-ground indoor temperature compensation coefficient into a second temperature prediction model so that the second temperature prediction model outputs an above-ground required temperature, and the second temperature prediction model is used for outputting the above-ground indoor required temperature;

and adjusting the temperature in the basement and the temperature in the overground according to the underground required temperature and the overground required temperature respectively.

By adopting the technical scheme, the underground indoor temperature and the overground indoor temperature are independently adjusted according to the calculated underground required temperature and the overground required temperature respectively, the problem that the speed of simultaneously adjusting the overground indoor temperature and the overground indoor temperature is lower is solved, and the effect of efficiently adjusting the overground/underground indoor temperature is achieved.

The present invention may be further configured in a preferred example, wherein the temperature compensation coefficient includes: a first temperature compensation coefficient and a second temperature compensation coefficient;

the determining a temperature compensation coefficient includes:

Dividing a first time period and a second time period according to international time;

and determining a first temperature compensation coefficient according to the first time period, and determining a second temperature compensation coefficient according to the second time period.

By adopting the technical scheme, according to the fact that the international time is divided into the first time period and the second time period, the indoor temperature of the building can be controlled in a partitioning mode (namely, the overground indoor and the basement are distinguished), and further the time-sharing indoor temperature of the building can be controlled on the basis of the temperature control in the partitioning mode; the suitability of adjusting the indoor temperature of the building is improved, so that the indoor temperature of the building is more suitable for the comfort of the human body in the time of distinguishing.

The present invention may be further configured in a preferred example, such that the inputting of the upper limit value of the indoor temperature, the lower limit value of the indoor temperature, the upper limit value of the outdoor temperature, the lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the basement exterior temperature compensation coefficient, and the basement interior temperature compensation coefficient into a first temperature prediction model, such that the first temperature prediction model outputs a desired temperature of the basement, includes:

acquiring the current time of the building in real time, and determining whether the current time is in the first time period or the second time period;

When the current time is within the first time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the first temperature compensation coefficient, the basement exterior temperature compensation coefficient and the basement interior temperature compensation coefficient into a first temperature prediction model so that the first temperature prediction model outputs a basement required temperature of the first time period;

when the current time is in the second time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the second temperature compensation coefficient, the basement exterior temperature compensation coefficient and the basement interior temperature compensation coefficient into a first temperature prediction model so that the first temperature prediction model outputs a basement required temperature of the second time period.

By adopting the technical scheme, the first temperature compensation coefficient and the second temperature compensation coefficient which are opposite to each other in the first time period and the second time period are different, so that when the current time of the building is in the first time period, the first temperature compensation coefficient is selected by the temperature compensation coefficient; when the current time of the building is within a second time period, the temperature compensation coefficient selects a second temperature compensation coefficient; the calculation of the underground required temperature of the building is more accurate.

The present invention may be further configured in a preferred example, such that the upper limit value of the indoor temperature, the lower limit value of the indoor temperature, the upper limit value of the outdoor temperature, the lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient, and the above-ground indoor temperature compensation coefficient are input to a second temperature prediction model for outputting an above-ground required temperature, the second temperature prediction model for outputting an above-ground indoor required temperature, comprising:

acquiring the current time of the building in real time, and determining whether the current time is in the first time period or the second time period;

when the current time is within the first time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the first temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient and the above-ground indoor temperature compensation coefficient into a second temperature prediction model, so that the second temperature prediction model outputs an above-ground required temperature for the first time period;

When the current time is within the second time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the second temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient and the above-ground indoor temperature compensation coefficient into a second temperature prediction model, so that the second temperature prediction model outputs an above-ground required temperature for the second time period.

By adopting the technical scheme, similarly, as the first temperature compensation coefficient and the second temperature compensation coefficient which are relative to each other in the first time period and the second time period are different, when the current time of the building is in the first time period, the temperature compensation coefficient selects the first temperature compensation coefficient; when the current time of the building is within a second time period, the temperature compensation coefficient selects a second temperature compensation coefficient; the calculation of the temperature required on the ground of the building is more accurate.

The present invention may be further configured in a preferred example, wherein the first temperature prediction model is:

wherein,to the desired temperature in the basement,is the lower limit value of the indoor temperature, Is the upper limit value of the indoor temperature,is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,is a temperature compensation coefficient outside the basement,is a temperature compensation coefficient in the basement.

The second temperature prediction model is:

wherein,in order to meet the indoor demand temperature on the ground,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature,is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,for the above-ground outdoor temperature compensation coefficient,is an above-ground indoor temperature compensation coefficient.

By adopting the technical scheme, the underground/overground outdoor temperature compensation coefficient and the underground/overground indoor temperature compensation coefficient are used for calculating heat transfer compensation amounts of the outdoor temperature and the indoor temperature, so that the outdoor temperature and the indoor temperature are closer to the actual outdoor temperature and the indoor temperature, a first temperature prediction model and a second temperature prediction model are constructed by using the lower limit value of the indoor temperature, the upper limit value of the indoor temperature, the outdoor temperature true value, the upper limit value of the outdoor temperature, the temperature compensation coefficient, the lower limit value of the outdoor temperature, the outdoor temperature compensation coefficient and the indoor temperature compensation coefficient, and the underground required temperature and the overground required temperature which are respectively output by the first temperature prediction model and the second temperature prediction model are more accurately controlled.

The present invention may be further configured in a preferred example, wherein the outdoor temperature compensation coefficient is:

the temperature compensation coefficient in the basement is as follows:

wherein,for the temperature compensation coefficient in the basement,in order to be able to take time,compensating constants for the basement.

By adopting the technical scheme, the ventilation performance in the basement is weak, so that the ventilation performance in the basement is not strong, the temperature in the basement is always higher or lower than the temperature outside the basement after or before a certain temperature and a certain time, and therefore the temperature compensation coefficient in the basement is set to be an inverse function look-ahead relationship, and the temperature compensation coefficient outside the basement is set to be 0.05; thereby improving the accuracy of the first temperature prediction model.

The present invention may be further configured in a preferred example, wherein the above-ground outdoor temperature compensation coefficient is:

wherein,for the number of sets of historical outdoor temperature data, the historical outdoor temperature data of a set includes the outdoor predicted temperature and the corresponding outdoor actual temperature at the same time,as the outdoor predicted temperature in the i-th group of the historical outdoor temperature data, Outdoor real temperatures in group i that are historical outdoor temperature data;

the above-ground indoor temperature compensation coefficient is as follows:

wherein,for the number of sets of historical indoor temperature data, the historical indoor temperature data of a set includes an indoor predicted temperature and a corresponding indoor true temperature at the same time,as the indoor predicted temperature in the i-th group of the historical indoor temperature data,is the indoor real temperature in the i-th group of the historical outdoor temperature data.

By adopting the technical scheme, the outdoor temperature compensation coefficient is regulated by using the corresponding data of the historical outdoor temperature and the outdoor real temperature corresponding to the historical outdoor temperature, namely, the average difference value between the historical outdoor temperature and the real outdoor temperature corresponding to the historical outdoor temperature is calculated, and the average difference value is used as the outdoor temperature compensation coefficient, so that the outdoor temperature compensation coefficient tends to be accurate infinitely, and the accuracy of the second temperature prediction model is further improved; similarly, the corresponding data of the historical indoor temperature and the corresponding indoor real temperature of the historical indoor temperature are used for adjusting the indoor temperature compensation coefficient, namely, the average difference value of the historical indoor temperature and the corresponding real indoor temperature is calculated, and the average difference value is used as the indoor temperature compensation coefficient, so that the indoor temperature compensation coefficient tends to be accurate in an infinite way, and the accuracy of the second temperature prediction model is further improved.

The invention also aims to provide an automatic energy supply device based on indoor temperature time-sharing partition, which has the characteristic of efficiently adjusting the temperature in the ground/basement.

The second object of the present invention is achieved by the following technical solutions:

an automatic energy supply device based on indoor temperature time-sharing partition, comprising:

the first determining module is used for determining the temperature compensation coefficient and floors of the building, wherein the floors comprise underground floors and overground floors;

the acquisition module is used for acquiring an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature and the outdoor real temperature;

the second determining module is used for determining an outdoor temperature compensation coefficient of the basement, an indoor temperature compensation coefficient of the basement, an outdoor temperature compensation coefficient of the ground and an indoor temperature compensation coefficient of the ground according to the underground floor and the above-ground floor respectively;

a first input/output module for inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the basement exterior temperature compensation coefficient, and the basement interior temperature compensation coefficient into a first temperature prediction model for outputting a basement required temperature, such that the first temperature prediction model outputs the basement required temperature;

A second input/output module for inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient, and the above-ground indoor temperature compensation coefficient into a second temperature prediction model for outputting an above-ground required temperature, such that the second temperature prediction model outputs the above-ground required temperature;

and the adjusting module is used for adjusting the indoor temperature of the basement and the indoor temperature of the ground according to the underground required temperature and the above-ground required temperature respectively.

The present invention may be further configured in a preferred example, wherein the temperature compensation coefficient includes: a first temperature compensation coefficient and a second temperature compensation coefficient;

the first determining module includes:

a dividing unit for dividing the first time period and the second time period according to the international time;

and the determining unit is used for determining a first temperature compensation coefficient according to the first time period and determining a second temperature compensation coefficient according to the second time period.

The present invention may be further configured in a preferred example, wherein the first input/output module includes a first real-time acquisition unit and a first input/output unit:

The first real-time acquisition unit is used for acquiring the current time of the building in real time and determining whether the current time is in the first time period or the second time period;

a first input/output unit for inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the first temperature compensation coefficient, the basement exterior temperature compensation coefficient, and the basement interior temperature compensation coefficient into a first temperature prediction model when the current time is within the first period of time, such that the first temperature prediction model outputs a basement required temperature of the first period of time;

the first input/output unit is further configured to input, when the current time is in the second time period, an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the second temperature compensation coefficient, the basement exterior temperature compensation coefficient, and the basement interior temperature compensation coefficient to a first temperature prediction model, so that the first temperature prediction model outputs a basement required temperature of the second time period.

The present invention may be further configured in a preferred example, wherein the second input/output module includes: a second real-time acquisition unit and a second input/output unit.

The second real-time acquisition unit is used for acquiring the current time of the building in real time and determining whether the current time is in the first time period or the second time period;

a second input/output unit for inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the first temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient, and the above-ground indoor temperature compensation coefficient into a second temperature prediction model when the current time is within the first time period, such that the second temperature prediction model outputs an above-ground required temperature for the first time period;

the second input/output unit is further configured to input, when the current time is within the second time period, an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the second temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient, and the above-ground indoor temperature compensation coefficient to a second temperature prediction model, so that the second temperature prediction model outputs an above-ground required temperature for the second time period.

The present invention may be further configured in a preferred example, wherein the first temperature prediction model is:

wherein,to the desired temperature in the basement,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature,is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,is a temperature compensation coefficient outside the basement,is a temperature compensation coefficient in the basement.

The present invention may be further configured in a preferred example, wherein the second temperature prediction model is:

wherein,in order to meet the indoor demand temperature on the ground,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature,is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,for the above-ground outdoor temperature compensation coefficient,is an above-ground indoor temperature compensation coefficient.

The present invention may be further configured in a preferred example, wherein the outdoor temperature compensation coefficient is:

the temperature compensation coefficient in the basement is as follows:

wherein,for the temperature compensation coefficient in the basement,in order to be able to take time,compensating constants for the basement.

The present invention may be further configured in a preferred example, wherein the above-ground outdoor temperature compensation coefficient is:

Wherein,for the number of sets of historical outdoor temperature data, the historical outdoor temperature data of a set includes the outdoor predicted temperature and the corresponding outdoor actual temperature at the same time,as the outdoor predicted temperature in the i-th group of the historical outdoor temperature data,outdoor real temperatures in group i that are historical outdoor temperature data;

the above-ground indoor temperature compensation coefficient is as follows:

wherein,for the number of sets of historical indoor temperature data, the historical indoor temperature data of a set includes an indoor predicted temperature and a corresponding indoor true temperature at the same time,as the indoor predicted temperature in the i-th group of the historical indoor temperature data,is the indoor real temperature in the i-th group of the historical outdoor temperature data.

The invention aims at providing an automatic energy supply device based on indoor temperature time-sharing partition, which has the characteristic of efficiently adjusting the temperature in the ground/basement.

The third object of the present invention is achieved by the following technical solutions:

an automatic energy supply device based on indoor temperature time-sharing partition comprises a memory and a processor, wherein the memory is stored with a computer program which can be loaded by the processor and execute the automatic energy supply method based on indoor temperature time-sharing partition.

A fourth object of the present invention is to provide a computer storage medium capable of storing a corresponding program, which has a feature of facilitating realization of efficient adjustment of the above-ground/below-ground indoor temperature.

The fourth object of the present invention is achieved by the following technical solutions:

a computer readable storage medium storing a computer program capable of being loaded by a processor and executing any one of the above automatic energy supply methods based on indoor temperature time division partitioning.

In summary, the present invention includes at least one of the following beneficial technical effects:

1. determining a temperature compensation coefficient and a floor; acquiring an upper limit value/a lower limit value of indoor/outdoor temperature, outdoor real temperature, an underground/overground outdoor temperature compensation coefficient and an underground/overground indoor temperature compensation coefficient; inputting the upper limit value/lower limit value of the indoor and outdoor temperatures, the outdoor real temperature, the temperature compensation coefficient, the underground/overground outdoor temperature compensation coefficient and the underground/overground indoor temperature compensation coefficient into the first/second temperature prediction model so that the first/second temperature prediction model outputs the underground/overground required temperature; regulating the indoor temperature of the underground/overground and the indoor temperature of the overground according to the required temperature of the underground/overground; the temperature in the basement and the temperature in the basement are adjusted independently according to the calculated temperature needed in the basement and the calculated temperature needed in the basement, so that the problem that the speed of adjusting the temperature in the basement and the temperature in the basement is low is solved, and the effect of adjusting the temperature in the basement/the basement with high efficiency is achieved.

2. According to the method, the international time is divided into a first time period and a second time period, the indoor temperature of the building can be controlled in a partitioning mode (namely, the overground indoor and the basement are distinguished), and further the time-sharing indoor temperature of the building is controlled on the basis of the temperature control in the partitioning mode; the suitability of adjusting the indoor temperature of the building is improved, so that the indoor temperature of the building is more suitable for the comfort of the human body in the time of distinguishing.

Drawings

Fig. 1 is a schematic flow chart of an automatic energy supply method based on indoor temperature time-sharing partition according to an embodiment of the application.

Fig. 2 is a schematic flow chart of an automatic energy supply method based on indoor temperature time division and partition according to an embodiment of the application.

FIG. 3 is a flow chart of an embodiment of an automatic power supply method based on time-division partitioning of indoor temperature.

FIG. 4 is a schematic flow chart of an embodiment of the automatic power supply method based on the time-division partition of the indoor temperature.

Detailed Description

In order to make the technical solutions in the present specification better understood by those skilled in the art, the technical solutions in the embodiments of the present specification will be clearly and completely described below with reference to the drawings in the embodiments of the present specification, and it is obvious that the described embodiments are only some embodiments of the present application, not all embodiments.

The present application will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1, an embodiment of an automatic energy supply method based on indoor temperature time-sharing partition according to an embodiment of the present application includes steps S1-S6.

S1, determining a temperature compensation coefficient and floors of a building, wherein the floors comprise underground floors and overground floors, and the temperature compensation coefficient comprises a first temperature compensation coefficient and a second temperature compensation coefficient.

In the embodiment of the application, an air conditioner-steam system is used for supplying energy to a building, namely, when the current indoor temperature corresponding to the building is lower than the indoor required temperature, the steam system is used for supplying energy to the indoor of the building; when the current indoor temperature corresponding to the building is higher than the indoor required temperature, the indoor temperature of the building is cooled by the air conditioning system.

Determining a temperature compensation coefficient between calculating indoor required temperatures corresponding to a building, wherein the temperature compensation coefficient comprises a first temperature compensation coefficient and a second temperature compensation coefficient; and because the ventilation of the overground indoor and the underground indoor of the building is inconsistent, the energy consumption rates of the overground indoor and the underground indoor are inconsistent, the floors of the building, including the underground floors and the overground floors, need to be further determined.

For example, a user inputs the number of floors of a building, and which floors are the underground floors included in the floors, and which floors are the above-ground floors, to an automatic power supply device through an input device; for example, the number of floors of the total building is 33, the underground three floors are underground floors, and the above-ground 30 floors are above-ground floors.

In the embodiment of the application, the automatic energy supply device can acquire the floors of the building through the input equipment; the floors of the building can also be directly obtained from a local database; the floors of the building can also be acquired at the cloud, and the specific method is not particularly limited.

In one possible embodiment, as shown in FIG. 2, the steps include S11-S12.

S11, dividing a first time period and a second time period according to the international time.

The temperature compensation coefficient is determined by dividing an international time, typically expressed in 24 hours, into a first time period and a second time period, wherein the division is started from 08:00, and since the building may start to have a person active at 08:00, in order to ensure that the person active in the building is in a corresponding comfortable temperature, 08:00-17:00 is set as the first time period; however, after 17:00, there is little activity in the building, then 17:00-08:00 is set to the second time period.

In the present embodiment, the first time period and the second time period are divided by the time period corresponding to the activity of the presence/absence person in the building; the device can also be set by the staff, and the specific place is not particularly limited.

S12, determining a first temperature compensation coefficient according to the first time period, and determining a second temperature compensation coefficient according to the second time period.

After the first time period and the second time period are determined, a first temperature compensation coefficient corresponding to the first time period is determined according to the first time period, and a second temperature compensation coefficient corresponding to the second time period is determined according to the second time period. Because the indoor temperature corresponding to the 08:00-17:00 time period is continuously increased, and the indoor temperature corresponding to the 17:00-08:00 time period is continuously decreased, the first temperature compensation coefficient needs to be set to be larger than the second temperature compensation coefficient. In the embodiment of the application, the first temperature compensation coefficient is 0.7, and the second temperature compensation coefficient is 0.2.

S2, acquiring an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature and the outdoor real temperature.

The user can input the upper limit value of the indoor temperature and the lower limit value of the indoor temperature set by the user into the automatic energy supply device through the input equipment; determining the position of a building according to the GPS, constructing an API request for acquiring weather forecast according to the address, and acquiring weather data by sending an HTTP request to the URL of the API; the API will return a response in JSON, XML or other data format; this response is parsed to extract the required weather data such as temperature, humidity, wind speed, etc., and the upper and lower values of the outdoor temperature are filtered out. And finally, acquiring the outdoor temperature true value of the building through an outdoor temperature sensor.

S3, determining an outdoor temperature compensation coefficient, an indoor temperature compensation coefficient, an outdoor temperature compensation coefficient and an indoor temperature compensation coefficient according to the underground floors and the above-ground floors respectively.

Since the air flow rate in the basement of the building is different from the air flow rate in the ground, the temperature in the basement is generally higher or lower than the temperature outside the basement after or before a certain temperature and a certain time, the temperature compensation coefficient in the basement is set as an inverse function look-ahead relationship, and the temperature compensation coefficient outside the basement is set as 0.05. In order to determine the predicted desired underground temperature and the desired above-ground temperature more accurately, it is necessary to determine the corresponding underground outside temperature compensation coefficient, underground inside temperature compensation coefficient, above-ground outside temperature compensation coefficient, and above-ground inside temperature compensation coefficient.

In the embodiment of the application, the temperature compensation coefficient outside the basement is as follows:

the temperature compensation coefficient in the basement is:

wherein,for the temperature compensation coefficient in the basement,in order to be able to take time,compensating constants for the basement.

The above-ground outdoor temperature compensation coefficient is:

Wherein,for the number of sets of historical outdoor temperature data, the historical outdoor temperature data of a set includes the outdoor predicted temperature and the corresponding outdoor actual temperature at the same time,as the outdoor predicted temperature in the i-th group of the historical outdoor temperature data,outdoor real temperatures in group i that are historical outdoor temperature data;

the above-ground indoor temperature compensation coefficient is as follows:

wherein,for the number of sets of historical indoor temperature data, the historical indoor temperature data of a set includes an indoor predicted temperature and a corresponding indoor true temperature at the same time,as the indoor predicted temperature in the i-th group of the historical indoor temperature data,is the indoor real temperature in the i-th group of the historical outdoor temperature data.

S4, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the basement outer temperature compensation coefficient and the basement inner temperature compensation coefficient into a first temperature prediction model so that the first temperature prediction model outputs the needed temperature of the basement, and the first temperature prediction model is used for outputting the needed temperature of the basement.

Since the underground required temperature and the above-ground required temperature are not identical and the above-ground indoor temperature and the below-ground indoor temperature are managed at the same time for better, the first temperature prediction model is set to calculate and output the below-ground indoor required temperature in the present embodiment.

The first temperature prediction model is as follows:

wherein,to the desired temperature in the basement,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature,is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,is a temperature compensation coefficient outside the basement,is a temperature compensation coefficient in the basement.

In the present embodiment, the temperature compensation coefficientMay be 0.7 or 0.2, and is not particularly limited herein.

In one possible embodiment, as shown in FIG. 3, the steps include S41-S43.

S41, acquiring the current time of the building in real time, and determining whether the current time is in the first time period or the second time period.

In this embodiment, since the first time period and the second time period are set, and the first temperature compensation coefficient and the second temperature compensation coefficient corresponding to the first time period and the second time period are inconsistent, it is necessary to determine where the current time of the building is, and specifically determine the corresponding temperature compensation coefficient.

Specifically, the position of the building is obtained through GPS, the position is analyzed into longitude/latitude to be represented, the longitude/latitude is used for calling Nominatim API to inquire the current time of the position, and the current time is further extracted. When the current time is extracted, judging whether the current time is in the first time period or the second time period.

For example, if the current time is within the 08:00-17:00 time period, then the current time is indicated to be within the first time period; and if the current time is within the 17:00-08:00 time period, indicating that the current time is within the second time period.

S42, when the current time is within the first time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, a first temperature compensation coefficient, an outdoor temperature compensation coefficient and an indoor temperature compensation coefficient into the first temperature prediction model, so that the first temperature prediction model outputs the underground required temperature in the first time period.

When the current time of the building is within the first time period, the temperature compensation coefficient is determined to be a first temperature compensation coefficient, namely, the first temperature compensation coefficient is 0.7. At this time, the required temperature in the basement of the first time period is calculated through a first temperature prediction model, wherein the first temperature prediction model is as follows:

at this time, the liquid crystal display device,for a desired temperature in the basement for a first period of time,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature,is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature, Is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,is a temperature compensation coefficient outside the basement,is a temperature compensation coefficient in the basement.

That is, the first temperature prediction model outputs the subsurface required temperature for the first period of time, providing a data basis for step S6.

S43, when the current time is in the second time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, a second temperature compensation coefficient, an outdoor temperature compensation coefficient and an indoor temperature compensation coefficient into the first temperature prediction model, so that the first temperature prediction model outputs the underground required temperature in the second time period.

When the current time of the building is within the second time period, the temperature compensation coefficient is determined to be a second temperature compensation coefficient, namely, the second temperature compensation coefficient is 0.2. At this time, the required temperature in the basement of the second time period is calculated through a first temperature prediction model, wherein the first temperature prediction model is as follows:

at this time, the liquid crystal display device,for a desired temperature in the basement for a second period of time,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature,is a true value of the outdoor temperature, Is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,is a temperature compensation coefficient outside the basement,is a temperature compensation coefficient in the basement.

That is, the first temperature prediction model outputs the subsurface required temperature for the second period of time, providing a data basis for step S6.

S5, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the overground outdoor temperature compensation coefficient and the overground indoor temperature compensation coefficient into a second temperature prediction model so that the second temperature prediction model outputs overground required temperature, and the second temperature prediction model is used for outputting overground indoor required temperature.

Since the underground required temperature and the above-ground required temperature are not identical and the above-ground indoor temperature and the below-ground indoor temperature are managed at the same time for better, a second temperature prediction model is provided in the present embodiment to calculate and output the above-ground indoor required temperature.

Wherein the second temperature prediction model is:

wherein,in order to meet the indoor demand temperature on the ground,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature, Is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,for the above-ground outdoor temperature compensation coefficient,is an above-ground indoor temperature compensation coefficient.

In the present embodiment, the temperature compensation coefficientMay be 0.7 or 0.2, and is not particularly limited herein.

In one possible embodiment, as shown in FIG. 4, the steps include S51-S53.

S51, acquiring the current time of the building in real time, and determining whether the current time is in the first time period or the second time period.

In the embodiment of the present application, step S51 is similar to step S41 described above, and is not repeated here.

S52, when the current time is within the first time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the first temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient and the above-ground indoor temperature compensation coefficient into the second temperature prediction model, so that the second temperature prediction model outputs the above-ground required temperature in the first time period.

When the current time of the building is within the first time period, the temperature compensation coefficient is determined to be a first temperature compensation coefficient, namely, the first temperature compensation coefficient is 0.7. At the moment, calculating the temperature required in the overground room in the first time period through a second temperature prediction model, wherein the second temperature prediction model is as follows:

At this time, the liquid crystal display device,for a first time period the above ground indoor demand temperature,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature,is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,for the above-ground outdoor temperature compensation coefficient,is an above-ground indoor temperature compensation coefficient.

That is, the second temperature prediction model outputs the above-ground required temperature for the first period of time, providing a data basis for step S6.

And S53, when the current time is within the second time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, an outdoor real temperature, a second temperature compensation coefficient, an overground outdoor temperature compensation coefficient and an overground indoor temperature compensation coefficient into the second temperature prediction model so that the second temperature prediction model outputs overground required temperature in the second time period.

When the current time of the building is within the second time period, the temperature compensation coefficient is determined to be a second temperature compensation coefficient, namely, the second temperature compensation coefficient is 0.2. At the moment, calculating the temperature required in the overground room in a second time period through a second temperature prediction model, wherein the second temperature prediction model is as follows:

At this time, the liquid crystal display device,for a second time period the above ground indoor demand temperature,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature,is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,for the above-ground outdoor temperature compensation coefficient,is an above-ground indoor temperature compensation coefficient.

That is, the second temperature prediction model outputs the above-ground required temperature for the second period of time, providing a data basis for step S6.

S6, adjusting the indoor temperature of the underground and the indoor temperature of the ground according to the underground required temperature and the ground required temperature respectively.

When the building is powered by an air-conditioning-steam system and the underground required temperature and the overground required temperature are calculated, judging whether the underground required temperature is equal to the current indoor temperature or not, if not, judging whether the underground required temperature is greater than the current indoor temperature or not, and if so, cooling the indoor temperature through the underground building air-conditioning system; otherwise, the opening proportion of the primary side electric valve of the plate change equipment of the underground building steam system is adjusted, so that the temperature in the basement is increased.

Similarly, judging whether the ground required temperature is equal to the current ground indoor temperature, if not, judging whether the ground required temperature is greater than the current ground indoor temperature, and if so, cooling the ground indoor temperature through a ground building air conditioning system; otherwise, the opening proportion of the primary side electric valve of the plate replacement equipment of the above-ground building steam system is adjusted, so that the temperature in the above-ground room is increased.

The beneficial effects achieved by the embodiment of the application include:

1. the temperature in the basement and the temperature in the basement are adjusted independently according to the calculated temperature needed in the basement and the calculated temperature needed in the basement, so that the problem that the speed of adjusting the temperature in the basement and the temperature in the basement is low is solved, and the effect of adjusting the temperature in the basement/the basement with high efficiency is achieved.

2. According to the method, the international time is divided into a first time period and a second time period, the indoor temperature of the building can be controlled in a partitioning mode (namely, the overground indoor and the basement are distinguished), and further the time-sharing indoor temperature of the building is controlled on the basis of the temperature control in the partitioning mode; the suitability of adjusting the indoor temperature of the building is improved, so that the indoor temperature of the building is more suitable for the comfort of the human body in the time of distinguishing.

3. The first temperature compensation coefficient is different from the second temperature compensation coefficient in the first time period and the second time period, so that when the current time of the building is in the first time period, the first temperature compensation coefficient is selected by the temperature compensation coefficient; when the current time of the building is within a second time period, the temperature compensation coefficient selects a second temperature compensation coefficient; the calculation of the underground required temperature of the building is more accurate. Similarly, since the first temperature compensation coefficient and the second temperature compensation coefficient are different in the first time period and the second time period, when the current time of the building is in the first time period, the temperature compensation coefficient selects the first temperature compensation coefficient; when the current time of the building is within a second time period, the temperature compensation coefficient selects a second temperature compensation coefficient; the calculation of the temperature required on the ground of the building is more accurate.

The embodiment of the application also provides an automatic energy supply device based on indoor temperature time-sharing partition, which comprises a first determining module, an acquiring module, a second determining module, a first input/output module, a second input/output module and an adjusting module.

In this embodiment, the first determining module may determine the temperature compensation coefficient and floors of the building, the floors including underground floors and above-ground floors, and send the temperature compensation coefficient to the first input/output module and the second input/output module, and send the underground floors and the above-ground floors to the second determining module.

The acquisition module acquires an upper limit value of an indoor temperature, a lower limit value of an indoor temperature, an upper limit value of an outdoor temperature, a lower limit value of an outdoor temperature and an outdoor real temperature, and transmits the upper limit value of the indoor temperature, the lower limit value of the indoor temperature, the upper limit value of the outdoor temperature, the lower limit value of the outdoor temperature and the outdoor real temperature to the first input/output module and the second input/output module.

The second determining module determines an outdoor temperature compensation coefficient, an indoor temperature compensation coefficient, and an outdoor temperature compensation coefficient and an indoor temperature compensation coefficient according to the underground floor and the above-ground floor, respectively.

The first input/output module inputs an upper limit value of an indoor temperature, a lower limit value of an indoor temperature, an upper limit value of an outdoor temperature, a lower limit value of an outdoor temperature, an outdoor real temperature, a temperature compensation coefficient, an outdoor temperature compensation coefficient and an indoor temperature compensation coefficient into the first temperature prediction model so that the first temperature prediction model outputs a required underground temperature and sends the required underground temperature to the adjusting module, and the first temperature prediction model is used for outputting the required underground temperature.

The second input/output module inputs the upper limit value of the indoor temperature, the lower limit value of the indoor temperature, the upper limit value of the outdoor temperature, the lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient and the above-ground indoor temperature compensation coefficient into the second temperature prediction model so that the second temperature prediction model outputs the above-ground required temperature and sends the above-ground required temperature to the adjusting module, and the second temperature prediction model is used for outputting the above-ground indoor required temperature.

The adjusting module adjusts the indoor temperature of the basement and the indoor temperature of the ground according to the underground required temperature and the above-ground required temperature.

In one possible implementation, the temperature compensation coefficient includes: a first temperature compensation coefficient and a second temperature compensation coefficient.

The first determining module comprises a dividing unit and a determining unit:

the dividing unit divides the first time period and the second time period according to the international time and sends the first time period and the second time period to the determining unit; the determining unit determines a first temperature compensation coefficient according to the first time period and a second temperature compensation coefficient according to the second time period.

In one possible implementation manner, the first input/output module includes a first real-time acquisition unit and a first input/output unit:

the first real-time acquisition unit acquires the current time of the building in real time and determines whether the current time is in a first time period or a second time period.

When the current time is within the first period of time, the first input/output unit inputs an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the first temperature compensation coefficient, the basement exterior temperature compensation coefficient, and the basement interior temperature compensation coefficient into the first temperature prediction model so that the first temperature prediction model outputs a basement required temperature for the first period of time.

When the current time is in the second time period, the first input/output unit inputs an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the second temperature compensation coefficient, the basement exterior temperature compensation coefficient, and the basement interior temperature compensation coefficient into the first temperature prediction model so that the first temperature prediction model outputs a basement required temperature in the second time period.

The first temperature prediction model is as follows:

wherein,to the desired temperature in the basement,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature,is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,is a temperature compensation coefficient outside the basement,is a temperature compensation coefficient in the basement.

The temperature compensation coefficient outside the basement is as follows:

the temperature compensation coefficient in the basement is:

wherein,for the temperature compensation coefficient in the basement,in order to be able to take time,compensating constants for the basement.

In one possible implementation, the second input/output module includes: a second real-time acquisition unit and a second input/output unit.

The second real-time acquisition unit acquires the current time of the building in real time and determines whether the current time is in the first time period or the second time period.

When the current time is within the first period, the second input/output unit inputs an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the first temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient, and the above-ground indoor temperature compensation coefficient into the second temperature prediction model, so that the second temperature prediction model outputs the above-ground required temperature for the first period.

When the current time is within the second time period, the second input/output unit inputs an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the second temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient, and the above-ground indoor temperature compensation coefficient into the second temperature prediction model so that the second temperature prediction model outputs the above-ground required temperature for the second time period.

Wherein the second temperature prediction model is:

wherein,in order to meet the indoor demand temperature on the ground,is the lower limit value of the indoor temperature,is the upper limit value of the indoor temperature,is a true value of the outdoor temperature,is an upper limit value of the outdoor temperature,is a lower limit value of the outdoor temperature,for the temperature compensation coefficient to be a function of the temperature,for the above-ground outdoor temperature compensation coefficient,is an above-ground indoor temperature compensation coefficient.

The above-ground outdoor temperature compensation coefficient is:

wherein,for the number of sets of historical outdoor temperature data, the historical outdoor temperature data of a set includes the outdoor predicted temperature and the corresponding outdoor actual temperature at the same time,as the outdoor predicted temperature in the i-th group of the historical outdoor temperature data,outdoor real temperatures in group i that are historical outdoor temperature data;

The above-ground indoor temperature compensation coefficient is as follows:

wherein,for the number of sets of historical indoor temperature data, the historical indoor temperature data of a set includes an indoor predicted temperature and a corresponding indoor true temperature at the same time,as the indoor predicted temperature in the i-th group of the historical indoor temperature data,is the indoor real temperature in the i-th group of the historical outdoor temperature data.

It should be noted that: in the device provided in the above embodiment, when implementing the functions thereof, only the division of the above functional modules is used as an example, in practical application, the above functional allocation may be implemented by different functional modules according to needs, that is, the internal structure of the device is divided into different functional modules, so as to implement all or part of the functions described above. In addition, the embodiments of the apparatus and the method provided in the foregoing embodiments belong to the same concept, and specific implementation processes of the embodiments of the method are detailed in the method embodiments, which are not repeated herein.

The embodiment of the application provides an automatic energy supply device based on indoor temperature time-sharing partition. The automatic energy supply device based on indoor temperature time-sharing partition can comprise: at least one processor, at least one network interface, a user interface, a memory, at least one communication bus.

The processor is configured to invoke the method of automatically powering the time-division partition based on the indoor temperature stored in the memory, which when executed by the one or more processors, causes the apparatus of automatically powering the time-division partition based on the indoor temperature to perform the method as described in one or more of the embodiments described above.

The embodiment of the application also provides a computer readable storage medium, on which a computer program is stored, which when executed by a processor, implements the automatic energy supply method based on indoor temperature time-sharing partition in the above embodiment, and is not repeated here.

It should be noted that, for simplicity of description, the foregoing method embodiments are all described as a series of acts, but it should be understood by those skilled in the art that the present application is not limited by the order of acts described, as some steps may be performed in other orders or concurrently in accordance with the present application. Further, those skilled in the art will also appreciate that the embodiments described in the specification are all of the preferred embodiments, and that the acts and modules referred to are not necessarily required for the present application.

The present embodiment is only for explanation of the present application and is not to be construed as limiting the present application, and modifications to the present embodiment, which may not creatively contribute to the present application as required by those skilled in the art after reading the present specification, are all protected by patent laws within the scope of claims of the present application.

Claims (10)

1. An automatic energy supply method based on indoor temperature time-sharing partition is characterized by comprising the following steps:

determining a temperature compensation coefficient and floors of a building, wherein the floors comprise underground floors and overground floors;

acquiring an upper limit value of indoor temperature, a lower limit value of indoor temperature, an upper limit value of outdoor temperature, a lower limit value of outdoor temperature and outdoor real temperature;

determining an outdoor temperature compensation coefficient of the basement, an indoor temperature compensation coefficient of the basement, an outdoor temperature compensation coefficient of the ground and an indoor temperature compensation coefficient of the ground according to the basement and the ground floors respectively;

inputting the upper limit value of the indoor temperature, the lower limit value of the indoor temperature, the upper limit value of the outdoor temperature, the lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the basement exterior temperature compensation coefficient and the basement interior temperature compensation coefficient into a first temperature prediction model so that the first temperature prediction model outputs the underground required temperature, and the first temperature prediction model is used for outputting the basement required temperature;

inputting the upper limit value of the indoor temperature, the lower limit value of the indoor temperature, the upper limit value of the outdoor temperature, the lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient and the above-ground indoor temperature compensation coefficient into a second temperature prediction model so that the second temperature prediction model outputs an above-ground required temperature, and the second temperature prediction model is used for outputting the above-ground indoor required temperature;

And adjusting the temperature in the basement and the temperature in the overground according to the underground required temperature and the overground required temperature respectively.

2. The automatic power supply method according to claim 1, wherein the temperature compensation coefficient includes: a first temperature compensation coefficient and a second temperature compensation coefficient;

the determining a temperature compensation coefficient includes:

dividing a first time period and a second time period according to international time;

and determining a first temperature compensation coefficient according to the first time period, and determining a second temperature compensation coefficient according to the second time period.

3. The automatic power supply method according to claim 2, wherein the inputting the upper limit value of the indoor temperature, the lower limit value of the indoor temperature, the upper limit value of the outdoor temperature, the lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the basement exterior temperature compensation coefficient, and the basement interior temperature compensation coefficient into a first temperature prediction model so that the first temperature prediction model outputs a desired temperature of the basement comprises:

acquiring the current time of the building in real time, and determining whether the current time is in the first time period or the second time period;

When the current time is within the first time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the first temperature compensation coefficient, the basement exterior temperature compensation coefficient and the basement interior temperature compensation coefficient into a first temperature prediction model so that the first temperature prediction model outputs a basement required temperature of the first time period;

when the current time is in the second time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the second temperature compensation coefficient, the basement exterior temperature compensation coefficient and the basement interior temperature compensation coefficient into a first temperature prediction model so that the first temperature prediction model outputs a basement required temperature of the second time period.

4. The automatic power supply method according to claim 2, wherein the inputting of the upper limit value of the indoor temperature, the lower limit value of the indoor temperature, the upper limit value of the outdoor temperature, the lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient, and the above-ground indoor temperature compensation coefficient into a second temperature prediction model for outputting an above-ground required temperature, the second temperature prediction model for outputting an above-ground indoor required temperature, comprises:

Acquiring the current time of the building in real time, and determining whether the current time is in the first time period or the second time period;

when the current time is within the first time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the first temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient and the above-ground indoor temperature compensation coefficient into a second temperature prediction model, so that the second temperature prediction model outputs an above-ground required temperature for the first time period;

when the current time is within the second time period, inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the second temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient and the above-ground indoor temperature compensation coefficient into a second temperature prediction model, so that the second temperature prediction model outputs an above-ground required temperature for the second time period.

5. The automated power supply method of claim 1, wherein the first temperature prediction model is:

；

wherein,for the temperature required in the basement, < > is->Is the lower limit value of indoor temperature, +.>Is the upper limit value of indoor temperature, +.>Is the outdoor temperatureTrue value->Is the upper limit value of the outdoor temperature, +.>Is the lower limit value of the outdoor temperature, +.>For the temperature compensation coefficient>For the temperature compensation coefficient outside the basement, < >>Is a temperature compensation coefficient in the basement.

6. The automated power supply method of claim 1, wherein the second temperature prediction model is:

；

wherein,for the indoor demand temperature on the ground, < > is->Is the lower limit value of indoor temperature, +.>Is the upper limit value of indoor temperature, +.>Is the real value of the outdoor temperature, < >>Is at the outside temperatureUpper limit value of degree,/>Is the lower limit value of the outdoor temperature, +.>For the temperature compensation coefficient>Is the above-ground outdoor temperature compensation coefficient->Is an above-ground indoor temperature compensation coefficient.

7. The automatic power supply method according to claim 1, wherein the basement exterior temperature compensation coefficient is:

；

the temperature compensation coefficient in the basement is as follows:

；

wherein,for the temperature compensation coefficient in the basement, < >>For time (I) >Compensating constants for the basement.

8. The automatic power supply method according to claim 1, wherein the above-ground outdoor temperature compensation coefficient is:

；

wherein,for the number of groups of historical outdoor temperature data, the historical outdoor temperature data of a group comprises the outdoor predicted temperature and the corresponding outdoor real temperature at the same moment, +.>Outdoor predicted temperature in group i, historical outdoor temperature data, +.>Outdoor real temperatures in group i that are historical outdoor temperature data;

the above-ground indoor temperature compensation coefficient is as follows:

；

wherein,for the number of groups of historical indoor temperature data, the historical indoor temperature data of one group comprises indoor predicted temperature and corresponding indoor real temperature at the same moment, +.>Indoor predicted temperature in group i, historical indoor temperature data, +.>Is the indoor real temperature in the i-th group of the historical outdoor temperature data.

9. An automatic energy supply device based on indoor temperature timesharing subregion, characterized by comprising:

the first determining module is used for determining the temperature compensation coefficient and floors of the building, wherein the floors comprise underground floors and overground floors;

the acquisition module is used for acquiring an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature and the outdoor real temperature;

The second determining module is used for determining an outdoor temperature compensation coefficient of the basement, an indoor temperature compensation coefficient of the basement, an outdoor temperature compensation coefficient of the ground and an indoor temperature compensation coefficient of the ground according to the underground floor and the above-ground floor respectively;

a first input/output module for inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the basement exterior temperature compensation coefficient, and the basement interior temperature compensation coefficient into a first temperature prediction model for outputting a basement required temperature, such that the first temperature prediction model outputs the basement required temperature;

a second input/output module for inputting an upper limit value of the indoor temperature, a lower limit value of the indoor temperature, an upper limit value of the outdoor temperature, a lower limit value of the outdoor temperature, the outdoor real temperature, the temperature compensation coefficient, the above-ground outdoor temperature compensation coefficient, and the above-ground indoor temperature compensation coefficient into a second temperature prediction model for outputting an above-ground required temperature, such that the second temperature prediction model outputs the above-ground required temperature;

And the adjusting module is used for adjusting the indoor temperature of the basement and the indoor temperature of the ground according to the underground required temperature and the above-ground required temperature respectively.

10. The automatic power supply device according to claim 9, wherein the temperature compensation coefficient includes: a first temperature compensation coefficient and a second temperature compensation coefficient;

the first determining module includes:

a dividing unit for dividing the first time period and the second time period according to the international time;

and the determining unit is used for determining a first temperature compensation coefficient according to the first time period and determining a second temperature compensation coefficient according to the second time period.