CN117896965A - Temperature self-adaptive optimizing method, device and medium for high-efficiency machine room of digital platform - Google Patents

Abstract

The application relates to the technical field of temperature regulation, and discloses a temperature self-adaptive optimizing method, a device and a medium for a high-efficiency machine room of a digital platform, wherein the temperature self-adaptive optimizing method for the high-efficiency machine room of the digital platform comprises the following steps: acquiring the preset temperature of an operating indoor air conditioner, the current temperature of the indoor air conditioner and the current temperature of a machine room; confirming total pre-change heat in a machine room based on the current indoor air conditioner temperature and the preset temperature; and confirming an adjusting signal based on the total pre-change heat, the current machine room temperature and a preset target temperature range, and adjusting a machine room air conditioner based on the adjusting signal so as to adjust the temperature in the machine room. Therefore, the problem that the traditional constant temperature control can occur beyond the preset range, so that the constant temperature control cannot be effectively performed in the machine room is solved.

Description

Temperature self-adaptive optimizing method, device and medium for high-efficiency machine room of digital platform

Technical Field

The application relates to the technical field of temperature regulation, in particular to a temperature self-adaptive optimizing method, device and medium for a high-efficiency machine room of a digital platform.

Background

With the development of technology, air conditioning equipment is indispensable in people's life, wherein equipment such as an air conditioner external unit is placed in a machine room, and temperature control is performed with respect to the machine room.

The traditional automatic control method for the temperature of the machine room is constant temperature control, and when the temperature sensor detects the high temperature and the preset range in real time, the operation speed of the radiator is adjusted, so that the temperature in the machine room is kept within the constant temperature range.

However, in practical application, the temperature in the machine room exceeds the preset range, so that the traditional constant temperature control method cannot effectively perform constant temperature control in the machine room.

Disclosure of Invention

The application mainly aims to provide a temperature self-adaptive optimizing method, device and medium for a high-efficiency machine room of a digital platform, and aims to solve the problem that the traditional constant temperature control can exceed a preset range, so that the temperature control cannot be effectively performed in the machine room.

In order to achieve the above purpose, the present application provides a machine room temperature adjusting device, and the high-efficiency machine room temperature adaptive optimizing method of the digital platform includes:

acquiring the preset temperature of an operating indoor air conditioner, the current temperature of the indoor air conditioner and the current temperature of a machine room;

confirming total pre-change heat in a machine room based on the current indoor air conditioner temperature and the preset temperature;

And confirming an adjusting signal based on the total pre-change heat, the current machine room temperature and a preset target temperature range, and adjusting a machine room air conditioner based on the adjusting signal so as to adjust the temperature in the machine room.

Optionally, the step of acquiring the preset temperature of the running indoor air conditioner and the current temperature of the indoor air conditioner based on the communication module includes:

acquiring the current ambient temperature, and detecting whether the ambient temperature is within a preset ambient temperature range, wherein the preset ambient temperature range is an ambient temperature range in which the regulating signal is zero;

And if the ambient temperature is not in the preset ambient temperature range, acquiring the preset temperature of the running indoor air conditioner and the current indoor air conditioner temperature.

Optionally, the adjusting signal includes: the step of confirming the adjusting signal based on the total pre-change heat, the current machine room temperature and a preset target temperature range comprises the following steps:

confirming the temperature to be regulated and the time to be regulated based on the total pre-change heat, the current machine room temperature and a preset target temperature range;

Confirming an adjustment strategy table based on the temperature to be adjusted and the time to be adjusted, wherein the adjustment strategy table at least comprises a group of adjustment strategies, and the adjustment strategies are a temperature adjustment signal and a wind speed adjustment signal;

and confirming a temperature adjusting signal and a wind speed adjusting signal with the lowest energy consumption in the adjusting strategy table, and adjusting a machine room air conditioner based on the temperature adjusting signal and the wind speed adjusting signal so as to adjust the temperature in the machine room.

Optionally, after the step of adjusting the air conditioner of the machine room based on the adjustment signal to adjust the temperature in the machine room, the method further includes:

Detecting whether the current machine room temperature exceeds the target temperature range;

and updating the temperature to be regulated and the time to be regulated based on the total pre-change heat, the current machine room temperature and a preset target temperature range when the current machine room temperature is confirmed to exceed the target temperature range, and executing the step of confirming the regulation strategy table based on the updated temperature to be regulated and the updated time to be regulated.

Optionally, after the step of sending the adjustment signal to the room air conditioner to adjust the room air conditioner, the method further includes:

Detecting whether the current machine room temperature exceeds the target temperature range;

and outputting an alarm signal to preset terminal equipment when the current machine room temperature is confirmed to exceed the target temperature range.

Optionally, after the step of adjusting the air conditioner of the machine room based on the adjustment signal to adjust the temperature in the machine room, the method further includes:

When the updated preset temperature of the indoor air conditioner is detected, acquiring the updated preset temperature and the updated current temperature of the indoor air conditioner;

and executing the step of confirming the total pre-change heat in the machine room based on the updated preset temperature and the updated current indoor air conditioner temperature.

Optionally, the step of adjusting the air conditioner of the machine room based on the adjusting signal to adjust the temperature in the machine room further includes:

Detecting whether the adjustment signal is zero;

and if the adjusting signal is confirmed to be not zero, adjusting the air conditioner of the machine room based on the adjusting signal so as to adjust the temperature in the machine room.

In order to achieve the above object, the present application further provides a machine room temperature adjusting device, including:

the communication module is used for receiving and outputting the started current indoor air conditioner temperature and the preset indoor air conditioner temperature;

The temperature sensor is used for collecting the current temperature of the machine room and outputting the current temperature;

The control module is respectively connected with the communication module and the temperature sensor, and is used for acquiring the current indoor air conditioner temperature, the preset temperature and the current machine room temperature, confirming the pre-change heat based on the current indoor air conditioner temperature and the preset temperature, confirming the adjusting signal based on the pre-change heat, the current machine room temperature and the preset target temperature range and outputting the adjusting signal;

the machine room air conditioner is connected with the control module and is used for receiving the adjusting signal and adjusting the temperature in the machine room based on the adjusting signal.

In order to achieve the above objective, the present application further provides a storage medium, which is a computer readable storage medium, and the computer readable storage medium includes the temperature adaptive optimizing method for the high-efficiency machine room of the digital platform.

The application provides a temperature self-adaptive optimizing method of a high-efficiency machine room of a digital platform, which comprises the following steps: acquiring the preset temperature of an operating indoor air conditioner, the current temperature of the indoor air conditioner and the current temperature of a machine room; confirming total pre-change heat in a machine room based on the current indoor air conditioner temperature and the preset temperature; and confirming an adjusting signal based on the total pre-change heat, the current machine room temperature and a preset target temperature range, and adjusting a machine room air conditioner based on the adjusting signal so as to adjust the temperature in the machine room. The application confirms the pre-change heat quantity in the machine room through the current indoor air conditioner temperature and the preset temperature, further confirms the specific adjusting signal of the machine room air conditioner through the pre-change heat quantity, the current machine room temperature and the preset target temperature range, and sends the adjusting signal to the machine room air conditioner for adjustment. Therefore, the temperature in the machine room is adjusted before exceeding the highest temperature or the lowest temperature, and the technical problem that the traditional constant temperature control can exceed the preset range and the constant temperature control cannot be effectively performed in the machine room is solved.

Drawings

Fig. 1 is a schematic structural diagram of hardware operation of a terminal device according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart of an embodiment of a temperature adaptive optimizing method for a high-efficiency machine room of a digitizing platform according to the invention;

FIG. 3 is a schematic flow chart of a second embodiment of a temperature adaptive optimizing method for a high-efficiency machine room of a digitizing platform according to the invention;

FIG. 4 is a schematic flow chart of a third embodiment of a temperature adaptive optimizing method for a high-efficiency machine room of a digitizing platform according to the invention;

fig. 5 is a schematic diagram of a logic frame of a room temperature adjusting apparatus according to an embodiment of the application.

The achievement of the objects, functional features and advantages of the present application will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

As shown in fig. 1, fig. 1 is a schematic structural diagram of a hardware running environment related to a terminal device according to an embodiment of the present invention.

The terminal device in the embodiment of the invention can be a device for integrating the high-efficiency machine room temperature self-adaptive optimizing method of the digital platform, and the terminal device can be a mobile terminal, a data storage control terminal, a PC or a portable computer and other terminals.

As shown in fig. 1, the terminal device may include: a processor 1001, such as a CPU, a network interface 1004, a user interface 1003, a memory 1005, a communication bus 1002. Wherein the communication bus 1002 is used to enable connected communication between these components. The user interface 1003 may include a Display, an input unit such as a Keyboard (Keyboard), and the optional user interface 1003 may further include a standard wired interface, a wireless interface. The network interface 1004 may optionally include a standard wired interface, a wireless interface (e.g., WI-FI interface). The memory 1005 may be a nonvolatile memory (e.g., flash memory), a high-speed RAM memory, or a stable memory (non-volatile memory), such as a disk memory. The memory 1005 may also optionally be a storage device separate from the processor 1001 described above.

It will be appreciated by those skilled in the art that the terminal device structure shown in fig. 1 is not limiting of the terminal device and may include more or fewer components than shown, or may combine certain components, or a different arrangement of components.

As shown in fig. 1, a memory 1005, which is a computer storage medium, may include an operating system, a network communication module, a user interface module, and a temperature adaptive optimization program for the high-efficiency machine room of the digitizing platform. The operating system is a program for managing and controlling hardware and software resources of the sample terminal equipment, and supports the operation of a temperature self-adaptive optimizing program and other software or programs of the high-efficiency machine room of the digital platform.

In the terminal device shown in fig. 1, the user interface 1003 is mainly used for data communication with each terminal; the network interface 1004 is mainly used for connecting a background server and carrying out data communication with the background server; and the processor 1001 may be configured to invoke the digitizing table efficient room temperature adaptive optimization program stored in the memory 1005.

With the development of technology, air conditioning equipment is indispensable in people's life, wherein equipment such as an air conditioner external unit is placed in a machine room, and temperature control is performed with respect to the machine room. The traditional automatic control method for the temperature of the machine room is constant temperature control, and when the temperature sensor detects the high temperature and the preset range in real time, the operation speed of the radiator is adjusted, so that the temperature in the machine room is kept within the constant temperature range. However, in practical application, the temperature in the machine room exceeds the preset range, so that the traditional constant temperature control method cannot effectively perform constant temperature control in the machine room.

In this regard, the application provides a high-efficiency machine room temperature self-adaptive optimizing method for a digital platform, a machine room temperature adjusting device, terminal equipment and a storage medium.

Based on the terminal equipment, the embodiments of the high-efficiency machine room temperature self-adaptive optimizing method of the digital platform are provided.

Referring to fig. 2, fig. 2 is a flow chart of a first embodiment of a temperature adaptive optimizing method for a high-efficiency machine room of a digitizing platform according to the present invention. In a first embodiment of the temperature adaptive optimizing method for the high-efficiency machine room of the digital platform, the temperature adaptive optimizing method for the high-efficiency machine room of the digital platform comprises the following steps:

Step S10: acquiring the preset temperature of an operating indoor air conditioner and the current indoor air conditioner temperature based on the communication module, and acquiring the current machine room temperature based on the temperature sensor;

Step S20: confirming total pre-change heat in a machine room based on the current indoor air conditioner temperature and the preset temperature;

step S30: and confirming an adjusting signal based on the total pre-change heat, the current machine room temperature and a preset target temperature range, and sending the adjusting signal to the machine room air conditioner so as to adjust the machine room air conditioner.

In this embodiment, the pre-change heat in the machine room is determined by the current indoor air conditioner temperature and the preset temperature, and further, a specific adjusting signal of the machine room air conditioner is determined by the pre-change heat, the current machine room temperature and a preset target temperature range, and the adjusting signal is sent to the machine room air conditioner for adjustment. Therefore, the temperature in the machine room is adjusted before exceeding the highest temperature or the lowest temperature, and the technical problem that the traditional constant temperature control can exceed the preset range and the constant temperature control cannot be effectively performed in the machine room is solved. Therefore, the constant temperature regulation in the machine room in the real sense is realized.

For example, if the number of effective air-conditioning external units in the machine room is 10, the air-conditioning external units correspond to the indoor air-conditioners, the current machine room temperature is 29 ℃, at this time, the first indoor air-conditioner A1 to the fourth indoor air-conditioner A4 are turned on, and the preset temperature is set to 27 ℃, at this time, the temperatures of the first indoor air-conditioner A1 to the fourth indoor air-conditioner A4 are 29 ℃, the control module obtains that the temperatures of the indoor air-conditioners are 29 ℃ and the preset temperature is set to 27 ℃ based on the communication module, calculates the temperatures of the first indoor air-conditioner A1 to the fourth indoor air-conditioner A4 at 29 ℃ and the preset temperature 27 ℃ based on the preset regulation model, so as to cause the pre-change heat of the air-conditioning external units in the machine room, and it is required to be explained that the air-conditioning external units release heat when the indoor air-conditioner is in the cooling operation, and the air-conditioning external units absorb heat when the indoor air-conditioner is in the heating operation. Because the indoor air conditioner is in cooling operation, the corresponding air conditioner external unit releases heat in the machine room, namely the control module calculates the pre-release heat as the pre-change amount, calculates an adjusting signal based on the pre-release heat, the current machine room temperature and the target temperature range, and sends the adjusting signal to the machine room air conditioner and adjusts the machine room air conditioner. That is, if the total pre-change heat may cause the temperature of the machine room to rise by 2 degrees celsius, that is, the temperature of the machine room changes to 31 degrees celsius, the calculated adjustment signal reduces the temperature of the machine room by 2 degrees celsius, so that the temperature in the machine room is kept at 29 degrees celsius, and it should be noted that the temperature of the machine room is within the target range at this time.

It is worth to say that each preset temperature of each running indoor air conditioner is obtained, each current indoor air conditioner temperature corresponding to each preset temperature and the current machine room temperature are obtained, each pre-change heat is confirmed based on each preset temperature and each corresponding current indoor air conditioner temperature, and finally, the total pre-change heat is obtained after adding each pre-change heat. Assuming that the amount of heat released during command generation is positive, the amount of heat absorbed during heating is negative. In combination with the above embodiment, each pre-change heat of the first indoor air conditioner A1 to the fourth indoor air conditioner A4 that is turned on is calculated, and the total pre-change heat is obtained after adding the pre-change heat of the first indoor air conditioner A1 to the fourth indoor air conditioner A4.

Optionally, based on the first embodiment of the temperature adaptive optimizing method for the high-efficiency machine room of the digital platform, a second embodiment of the temperature adaptive optimizing method for the high-efficiency machine room of the digital platform is provided. Referring to fig. 3, fig. 3 is a flow chart of a second embodiment of the temperature adaptive optimizing method for the high-efficiency machine room of the digitizing platform according to the application.

In some possible embodiments, step S10 may include the steps of:

Step S11: acquiring the current ambient temperature, and detecting whether the ambient temperature is within a preset ambient temperature range, wherein the preset ambient temperature range is an ambient temperature range in which the regulating signal is zero;

step S12: and if the ambient temperature is not in the preset ambient temperature range, acquiring the preset temperature of the running indoor air conditioner and the current indoor air conditioner temperature.

In this embodiment, when the current ambient temperature is within the preset ambient temperature range, for example, when the outdoor ambient temperature accords with the comfort temperature of the user, such as 23 degrees to 28 degrees, the probability of starting the indoor air conditioner by the user is low, or when the ambient temperature is not different from the comfort temperature of the user, the total pre-change heat in the machine room does not cause the temperature in the machine room to exceed the preset ambient temperature threshold, at this time, the pre-adjustment is not needed for the machine room temperature, and when the outdoor ambient temperature is not within the preset ambient temperature range, such as high as 35 degrees, the probability of starting the indoor air conditioner by the user is high, at this time, the temperature in the machine room easily exceeds the preset ambient temperature threshold, and the pre-adjustment is needed for the temperature in the machine room, that is, the preset temperature of the running indoor air conditioner and the current indoor air conditioner temperature are acquired based on the communication module, and the current temperature is acquired based on the temperature sensor, so as to calculate the adjustment signal. Therefore, the temperature in the machine room is adjusted before exceeding the highest temperature or the lowest temperature, and the technical problem that the traditional constant temperature control can exceed the preset range and the constant temperature control cannot be effectively performed in the machine room is solved.

In this embodiment, model training is further performed based on the ambient temperature, the indoor air conditioner temperature, the preset temperature of the indoor air conditioner, the machine room temperature, and the target temperature range to obtain an ambient temperature adjustment model, and the ambient temperature with the adjustment signal zero is output in the ambient temperature adjustment model, that is, the machine room air conditioner is not required to be adjusted, the machine room temperature is kept within the range of the preset target temperature range, and the range of the ambient temperature with the adjustment signal zero is set as the preset ambient temperature range. When the current ambient temperature is within the preset ambient temperature range, the air conditioner of the machine room is adjusted based on the temperature of the machine room acquired by the current temperature sensor.

For example, if the target temperature range of the machine room is 18 to 28 degrees celsius, the adjustment signals output by the environmental temperature adjustment model are zero if the current environmental temperature is 22 to 26 degrees celsius, that is, the temperature and the wind speed do not need to be adjusted. Then the preset ambient temperature range is identified as 22 degrees celsius to 26 degrees celsius.

Optionally, based on the first embodiment and/or the second embodiment of the temperature adaptive optimizing method for the high-efficiency machine room of the digital platform, a third embodiment of the temperature adaptive optimizing method for the high-efficiency machine room of the digital platform is provided. Referring to fig. 4, fig. 4 is a flow chart of a third embodiment of the temperature adaptive optimizing method for the high-efficiency machine room of the digitizing platform according to the application.

Optionally, in some possible embodiments, the adjustment signal includes: the step of confirming the adjustment signal based on the total pre-change heat, the current room temperature, and the preset target temperature range in step S30 may further include the steps of:

Step S31: confirming the temperature to be regulated and the time to be regulated based on the total pre-change heat, the current machine room temperature and a preset target temperature range;

For example, when the target temperature range of the machine room is 18 degrees celsius to 28 degrees celsius, the total pre-change amount causes the machine room temperature to rise from 25 degrees celsius to 30 degrees outside the target temperature range in the future 30 minutes, the adjustment signal is that the machine room temperature is reduced from 25 degrees celsius to 20 degrees in the future 30 minutes, at which time the belt adjustment temperature is reduced by 5 degrees, and the waiting adjustment time is 30 minutes, so that the temperature in the future 30 minutes is maintained near 25 degrees, and it is ensured that the machine room temperature does not exceed the target temperature range.

Step S32: confirming an adjustment strategy table based on the temperature to be adjusted and the time to be adjusted, wherein the adjustment strategy table at least comprises a group of adjustment strategies, and the adjustment strategies are a temperature adjustment signal and a wind speed adjustment signal;

In this embodiment, the adjustment strategy table is output based on the temperature to be adjusted and the time to be adjusted, and the adjustment strategy table includes one or more groups of adjustment strategies, i.e., each group of adjustment strategies includes a temperature adjustment signal and a wind speed adjustment signal. Therefore, the temperature in the machine room is adjusted before exceeding the highest temperature or the lowest temperature, and the technical problem that the traditional constant temperature control can exceed the preset range and the constant temperature control cannot be effectively performed in the machine room is solved.

It should be noted that if the regulation strategy table includes multiple sets of regulation strategies, each set of regulation strategies may have a 5 degree temperature drop within 30 minutes of the future, and each set of regulation strategies includes energy consumption.

Step S33: and confirming a temperature adjusting signal and a wind speed adjusting signal with the lowest energy consumption in the adjusting strategy table, and adjusting a machine room air conditioner based on the temperature adjusting signal and the wind speed adjusting signal so as to adjust the temperature in the machine room.

In this embodiment, if the adjustment policy table includes only one set of adjustment policies, the unique set of adjustment policies is identified as an adjustment signal, and if the adjustment policy table includes multiple sets of adjustment policies, the adjustment policy with the lowest energy consumption is identified as an adjustment signal in each adjustment policy, so that the air conditioner in the machine room is adjusted based on the temperature adjustment signal with the lowest energy consumption and the wind speed adjustment signal, so as to adjust the temperature in the machine room.

In some possible embodiments, the adjustment signal comprises: the step of adjusting the air conditioner of the machine room based on the adjustment signal to adjust the temperature in the machine room in the step S30 may further include the steps of:

step S34: detecting whether the adjustment signal is zero;

step S35: and if the adjusting signal is confirmed to be not zero, the adjusting signal is sent to the machine room air conditioner so as to adjust the machine room air conditioner.

In this embodiment, after the adjustment signal is determined based on the total pre-change heat, the current machine room temperature and the preset target temperature range, whether the adjustment signal is zero is further detected, which means that the temperature in the machine room does not exceed the target temperature range when no pre-adjustment is performed. Thus, when the detected adjustment signal is zero, the adjustment signal does not need to be sent to the air conditioner of the machine room. Therefore, the temperature in the machine room is adjusted before exceeding the highest temperature or the lowest temperature, and the technical problem that the traditional constant temperature control can exceed the preset range and the constant temperature control cannot be effectively performed in the machine room is solved.

Optionally, in some possible embodiments, after the step of sending the adjustment signal to the room air conditioner to adjust the room air conditioner in step S30, the method for adaptive optimizing temperature of a high-efficiency room of the digital platform according to the present application may further include the following steps:

step S40: detecting whether the current machine room temperature exceeds the target temperature range;

Step S50: and updating the temperature to be regulated and the time to be regulated based on the total pre-change heat, the current machine room temperature and a preset target temperature range when the current machine room temperature is confirmed to exceed the target temperature range, and executing the step of confirming the regulation strategy table based on the updated temperature to be regulated and the updated time to be regulated.

In this embodiment, the built adjusting model has a self-learning function, and adjusts the air conditioner of the machine room according to the adjusting signal, so as to continuously detect whether the current temperature of the machine room exceeds the target temperature range after adjusting the temperature in the machine room, if the current temperature of the machine room exceeds the target temperature range, the adjusting signal output by the adjusting model is confirmed to be inaccurate, and may be subjected to additional environmental factors, such as increased energy consumption caused by the failure of the air conditioner, the air outlet of the air conditioner of the machine room being blocked or influenced by the humidity of the machine room, etc., thereby updating the confirmed temperature to be adjusted and the confirmed time to be adjusted, so that the temperature in the machine room cannot exceed the target temperature range by the updated adjusting signal output by the temperature to be adjusted and the time to be adjusted.

For example, in combination with the above embodiment, if it is detected that the current machine room temperature exceeds the target temperature range, that is, exceeds 28 degrees celsius, based on the confirmed to-be-adjusted temperature of 5 degrees and to-be-adjusted time of 30 minutes, the to-be-adjusted temperature and to-be-adjusted time are updated such that the updated to-be-adjusted temperature is 7 degrees and to-be-adjusted time is 20 minutes, thereby avoiding the temperature in the machine room from exceeding the target temperature range. It should be noted that the updated temperature to be adjusted and the time to be adjusted are set in advance.

Optionally, in some possible embodiments, after the step of sending the adjustment signal to the room air conditioner to adjust the room air conditioner in step S30, the method for adaptive optimizing temperature of a high-efficiency room of the digital platform according to the present application may further include the following steps:

step S60: detecting whether the current machine room temperature exceeds the target temperature range;

Step S70: and outputting an alarm signal to preset terminal equipment when the current machine room temperature is confirmed to exceed the target temperature range.

In this embodiment, the air conditioner of the machine room is adjusted according to the adjustment signal, so that after the temperature in the machine room is adjusted, whether the current temperature of the machine room exceeds the target temperature range is continuously detected, and if the current temperature of the machine room is confirmed to exceed the target temperature range, an alarm signal is output to the connected preset terminal equipment. The user can look over the real-time state of temperature in the computer lab on terminal device, for example, when temperature in the computer lab is higher than target temperature range continuously, can have the emergency such as computer lab air conditioner trouble or conflagration to remind the user to go to the computer lab and examine the reason. Therefore, the temperature in the machine room is adjusted before exceeding the highest temperature or the lowest temperature, and the technical problem that the traditional constant temperature control can exceed the preset range and the constant temperature control cannot be effectively performed in the machine room is solved.

Optionally, in some possible embodiments, after the step of sending the adjustment signal to the room air conditioner to adjust the room air conditioner in step S30, the method for adaptive optimizing temperature of a high-efficiency room of the digital platform according to the present application may further include the following steps:

Step S80: when the updated preset temperature of the indoor air conditioner is detected, acquiring the updated preset temperature and the updated current temperature of the indoor air conditioner;

step S90: and executing the step of confirming the total pre-change heat in the machine room based on the updated preset temperature and the updated current indoor air conditioner temperature.

In this embodiment, if the user adjusts the preset temperature after turning on the indoor air conditioner so that the preset temperature is updated, the updated preset temperature and the updated current indoor air conditioner temperature are re-acquired, and the total pre-change heat in the machine room is confirmed based on the updated preset temperature and the updated current indoor air conditioner temperature, so that an adjustment signal is confirmed based on the total pre-change heat, the current machine room temperature and a preset target temperature range, and the machine room air conditioner is adjusted based on the adjustment signal, so as to adjust the temperature in the machine room. Therefore, the temperature in the machine room is adjusted before exceeding the highest temperature or the lowest temperature, and the technical problem that the traditional constant temperature control can exceed the preset range and the constant temperature control cannot be effectively performed in the machine room is solved.

Optionally, based on the first embodiment, the second embodiment and/or the third embodiment of the method for adaptively optimizing the temperature of the high-efficiency machine room of the digital platform, each embodiment of the temperature adjusting device of the machine room of the application is provided. Referring to fig. 5, fig. 5 is a schematic diagram of a logic frame of a room temperature adjusting device according to an embodiment of the application.

The communication module 10 is used for receiving and outputting the started current indoor air conditioner temperature and the preset indoor air conditioner temperature;

the temperature sensor 20 is used for acquiring the current machine room temperature and outputting the current machine room temperature;

The control module 30 is respectively connected with the communication module 10 and the temperature sensor 20, and is used for acquiring the current indoor air conditioner temperature, the preset temperature and the current machine room temperature, confirming total pre-change heat based on the current indoor air conditioner temperature and the preset temperature, confirming an adjusting signal based on the total pre-change heat, the current machine room temperature and a preset target temperature range and outputting the adjusting signal;

The machine room air conditioner 40 is connected with the control module 30, and is used for receiving the adjusting signal and adjusting the temperature in the machine room based on the adjusting signal.

In this embodiment, the adjustment model is integrated in the control module 30, so that the digital platform efficient machine room temperature self-adaptive optimizing method is realized based on the communication module 10, the temperature sensor 20, the control module 30 and the machine room air conditioner 40.

The application is characterized in that the communication module 10 is used for receiving and outputting the started current indoor air conditioner temperature and the preset indoor air conditioner temperature through the communication module 10; the temperature sensor 20 is used for acquiring the current machine room temperature and outputting the current machine room temperature; the control module 30 is respectively connected with the communication module 10 and the temperature sensor 20, and is used for acquiring the current indoor air conditioner temperature, the preset temperature and the current machine room temperature, confirming total pre-change heat based on the current indoor air conditioner temperature and the preset temperature, confirming an adjusting signal based on the total pre-change heat, the current machine room temperature and a preset target temperature range and outputting the adjusting signal; the machine room air conditioner 40 is connected with the control module 30, and is used for receiving the adjusting signal and adjusting the temperature in the machine room based on the adjusting signal. Therefore, the temperature in the machine room is adjusted before exceeding the highest temperature or the lowest temperature, and the technical problem that the traditional constant temperature control can exceed the preset range and the constant temperature control cannot be effectively performed in the machine room is solved.

Optionally, the control module 30 includes:

acquiring the current ambient temperature, and detecting whether the ambient temperature is within a preset ambient temperature range, wherein the preset ambient temperature range is an ambient temperature range in which the regulating signal is zero;

And if the ambient temperature is not in the preset ambient temperature range, acquiring the preset temperature of the running indoor air conditioner and the current indoor air conditioner temperature based on the communication module.

Optionally, the control module 30 further includes:

confirming the temperature to be regulated and the time to be regulated based on the total pre-change heat, the current machine room temperature and a preset target temperature range;

Confirming an adjustment strategy table based on the temperature to be adjusted and the time to be adjusted, wherein the adjustment strategy table at least comprises a group of adjustment strategies, and the adjustment strategies are a temperature adjustment signal and a wind speed adjustment signal;

and confirming a temperature adjusting signal and a wind speed adjusting signal with the lowest energy consumption in the adjusting strategy table, and adjusting a machine room air conditioner based on the temperature adjusting signal and the wind speed adjusting signal so as to adjust the temperature in the machine room.

Optionally, the control module 30 further includes:

Detecting whether the current machine room temperature exceeds the target temperature range;

and when the current machine room temperature is confirmed to exceed the target temperature range, updating the temperature to be regulated and the time to be regulated based on the total pre-change heat, the current machine room temperature and the preset target temperature range, and confirming the regulation strategy table based on the updated temperature to be regulated and the updated time to be regulated.

Optionally, the control module 30 further includes:

Detecting whether the current machine room temperature exceeds the target temperature range;

and outputting an alarm signal to preset terminal equipment when the current machine room temperature is confirmed to exceed the target temperature range.

Optionally, the control module 30 further includes:

When the updated preset temperature of the indoor air conditioner is detected, acquiring the updated preset temperature and the updated current temperature of the indoor air conditioner;

and executing the step of confirming the total pre-change heat in the machine room based on the updated preset temperature and the updated current indoor air conditioner temperature.

Optionally, the control module 30 further includes:

Detecting whether the adjustment signal is zero;

and if the adjusting signal is confirmed to be not zero, adjusting the air conditioner of the machine room based on the adjusting signal so as to adjust the temperature in the machine room.

In addition, the embodiment of the invention also provides a computer storage medium which is applied to a computer and can be a nonvolatile computer readable computer storage medium, wherein the computer storage medium is stored with a digital platform high-efficiency machine room temperature self-adaptive optimizing program, and the digital platform high-efficiency machine room temperature self-adaptive optimizing program is executed by a processor to realize the steps of the digital platform high-efficiency machine room temperature self-adaptive optimizing method.

The steps implemented when the temperature adaptive optimizing program of the high-efficiency machine room of the digital platform running on the processor is executed may refer to various embodiments of the temperature adaptive optimizing method of the high-efficiency machine room of the digital platform of the present invention, which are not described herein.

The foregoing description is only of the preferred embodiments of the present application and is not intended to limit the scope of the application, and all equivalent structural changes made by the specification and drawings of the present application or direct/indirect application in other related technical fields are included in the scope of the present application.

Claims (9)

1. The temperature self-adaptive optimizing method for the high-efficiency machine room of the digital platform is characterized by comprising the following steps of:

acquiring the preset temperature of an operating indoor air conditioner, the current temperature of the indoor air conditioner and the current temperature of a machine room;

confirming total pre-change heat in a machine room based on the current indoor air conditioner temperature and the preset temperature;

And confirming an adjusting signal based on the total pre-change heat, the current machine room temperature and a preset target temperature range, and adjusting a machine room air conditioner based on the adjusting signal so as to adjust the temperature in the machine room.

2. The method for adaptively optimizing the temperature of the high-efficiency machine room of the digital platform according to claim 1, wherein the step of acquiring the preset temperature, the current temperature and the current temperature of the indoor air conditioner based on the obtained operation comprises the following steps:

acquiring the current ambient temperature, and detecting whether the ambient temperature is within a preset ambient temperature range, wherein the preset ambient temperature range is an ambient temperature range in which the regulating signal is zero;

And if the ambient temperature is not in the preset ambient temperature range, acquiring the preset temperature of the running indoor air conditioner and the current indoor air conditioner temperature.

3. The method for adaptively optimizing the temperature of a high-efficiency machine room of a digital platform according to claim 2, wherein the adjusting signal comprises: the step of confirming the adjusting signal based on the total pre-change heat, the current machine room temperature and a preset target temperature range comprises the following steps:

confirming the temperature to be regulated and the time to be regulated based on the total pre-change heat, the current machine room temperature and a preset target temperature range;

Confirming an adjustment strategy table based on the temperature to be adjusted and the time to be adjusted, wherein the adjustment strategy table at least comprises a group of adjustment strategies, and the adjustment strategies are a temperature adjustment signal and a wind speed adjustment signal;

and confirming a temperature adjusting signal and a wind speed adjusting signal with the lowest energy consumption in the adjusting strategy table, and adjusting a machine room air conditioner based on the temperature adjusting signal and the wind speed adjusting signal so as to adjust the temperature in the machine room.

4. A method for adaptive optimization of temperature in a high-efficiency machine room of a digital platform as set forth in claim 3, wherein after the step of adjusting the air conditioner of the machine room based on the adjustment signal to adjust the temperature in the machine room, the method further comprises:

Detecting whether the current machine room temperature exceeds the target temperature range;

and updating the temperature to be regulated and the time to be regulated based on the total pre-change heat, the current machine room temperature and a preset target temperature range when the current machine room temperature is confirmed to exceed the target temperature range, and executing the step of confirming the regulation strategy table based on the updated temperature to be regulated and the updated time to be regulated.

5. The method for adaptive optimization of temperature in a high-efficiency machine room for a digital platform as set forth in claim 1, wherein after the step of sending the adjustment signal to the machine room air conditioner to adjust the machine room air conditioner, the method further comprises:

Detecting whether the current machine room temperature exceeds the target temperature range;

and outputting an alarm signal to preset terminal equipment when the current machine room temperature is confirmed to exceed the target temperature range.

6. The method for adaptively optimizing the temperature of a high-efficiency machine room of a digital platform according to claim 1, wherein after the step of adjusting the air conditioner of the machine room based on the adjustment signal to adjust the temperature in the machine room, the method further comprises:

When the updated preset temperature of the indoor air conditioner is detected, acquiring the updated preset temperature and the updated current temperature of the indoor air conditioner;

and executing the step of confirming the total pre-change heat in the machine room based on the updated preset temperature and the updated current indoor air conditioner temperature.

7. The method for adaptively optimizing temperature in a high-efficiency machine room of a digital platform according to claim 1, wherein the step of adjusting an air conditioner in the machine room based on the adjustment signal to adjust the temperature in the machine room further comprises:

Detecting whether the adjustment signal is zero;

and if the adjusting signal is confirmed to be not zero, adjusting the air conditioner of the machine room based on the adjusting signal so as to adjust the temperature in the machine room.

8. The utility model provides a computer lab temperature regulating device which characterized in that, computer lab temperature regulating device includes:

the communication module is used for receiving and outputting the started current indoor air conditioner temperature and the preset indoor air conditioner temperature;

The temperature sensor is used for collecting the current temperature of the machine room and outputting the current temperature;

The control module is respectively connected with the communication module and the temperature sensor, and is used for acquiring the current indoor air conditioner temperature, the preset temperature and the current machine room temperature, confirming the pre-change heat based on the current indoor air conditioner temperature and the preset temperature, confirming the adjusting signal based on the pre-change heat, the current machine room temperature and the preset target temperature range and outputting the adjusting signal;

the machine room air conditioner is connected with the control module and is used for receiving the adjusting signal and adjusting the temperature in the machine room based on the adjusting signal.

9. A readable storage medium, characterized in that the readable storage medium is a computer readable storage medium, the computer readable storage medium stores a temperature adaptive optimizing program of a high-efficiency machine room of a digital platform, and the temperature adaptive optimizing program of the high-efficiency machine room of the digital platform realizes the steps of the temperature adaptive optimizing method of the high-efficiency machine room of the digital platform according to any one of claims 1 to 7 when being executed by a processor.