CN215951843U - Self-adaptive heat pump remote control system - Google Patents

Abstract

The embodiment of the utility model discloses a self-adaptive heat pump remote control system. The control system comprises a heat pump unit, a controller and a cloud end, wherein the controller comprises a communication module, the heat pump unit is electrically connected with the controller, the controller is used for communicating the communication module with the cloud end, the controller collects state information of the heat pump unit and uploads the state information to the cloud end through the communication module, the cloud end calculates the use habit of a user of the heat pump unit according to the state information, and the heat pump unit is regulated and controlled according to the use habit of the user and the local climate parameter generation regulation and control strategy, so that the heat pump unit meets the use requirement of the user. The technical scheme provided by the embodiment ensures the normal work of the heat pump unit under different climatic parameters, and further meets the use requirements of different users on using the heat pump unit.

Description

Self-adaptive heat pump remote control system

Technical Field

The embodiment of the utility model relates to the technical field of heat pump control, in particular to a self-adaptive heat pump remote control system.

Background

With the rapid development of science and technology, the digital era has been entered, the data processing technology era is advanced from the information technology era, and a large amount of data is accumulated in various industries based on the digitization and informatization of a customer management system.

At present, the heat pump industry uses the operation of a traditional wire controller, an operator needs to use the wire controller to perform parameter checking, parameter regulation and control and other operations on a heat pump unit on site, and when a system fails or is alarmed, the operator needs to consider resetting. How to apply some big data and artificial intelligence methods to the customer relationship management system to meet the customer requirements is the focus and hot spot of the current era.

SUMMERY OF THE UTILITY MODEL

The embodiment of the utility model provides a self-adaptive heat pump remote control system, which is used for meeting different requirements of different users for using a heat pump unit and realizing intelligent service of the heat pump unit.

In a first aspect, an embodiment of the present invention provides a self-adaptive heat pump remote control system, including a heat pump unit, a controller and a cloud, where the controller includes a communication module; the heat pump unit is electrically connected with the controller, and the communication module of the controller is in communication connection with the cloud end;

the controller collects state information of the heat pump unit and uploads the state information to the cloud end through the communication module;

and the cloud end calculates according to the state information to obtain the use habit of a user of the heat pump unit, and generates a regulation and control strategy according to the use habit of the user and the local climate parameters to regulate and control the heat pump unit so that the heat pump unit meets the use requirement of the user.

Optionally, the controller further comprises a control module and a detection module; the control module is respectively and electrically connected with the heat pump unit, the detection module and the communication module;

the detection module detects and acquires state information of the heat pump unit; the control module uploads the state information to the cloud end through the communication module, and the communication module acquires a regulation strategy to regulate and control the heat pump unit.

Optionally, the controller further comprises a parameter module, wherein the parameter module is used for storing safe working parameters of the heat pump unit, and the safe working parameters are matched with initial performance parameters of the heat pump unit;

the control module is also used for comparing the acquired state information with the safe working parameters in real time and uploading the comparison result to the cloud end through the communication module; and the cloud terminal also generates a regulation and control strategy according to the comparison result.

Optionally, the communication module includes a positioning unit, and the communication module further uploads positioning information provided by the positioning unit to the cloud;

and the cloud end acquires local climate parameters according to the positioning information.

Optionally, the state information includes ambient temperature information, exhaust temperature information, and heat dissipation temperature information of the heat pump unit, and operating frequency information of the heat pump unit.

Optionally, the communication module comprises a SIM card and a 4G module, or a SIM card and a 5G module.

Optionally, the cloud end includes a computer, and the computer calculates usage habits of users of the heat pump units according to the state information and generates a regulation and control strategy according to the usage habits of the users and local climate parameters.

Optionally, the cloud further comprises a data center, and the data center is in communication connection with the computer;

and the data center acquires the state information of the heat pump unit in real time or in a historical time period and provides the state information to the computer.

Optionally, the cloud further comprises a server, and the server is in communication connection with the data center;

the server stores real-time state information of the heat pump unit in real time or in historical time periods.

The embodiment of the utility model provides a self-adaptive heat pump remote control system which comprises a heat pump unit, a controller and a cloud end, wherein the controller comprises a communication module, the heat pump unit is electrically connected with the controller, and the communication module of the controller is in communication connection with the cloud end, wherein the controller acquires state information of the heat pump unit and uploads the state information to the cloud end through the communication module, the cloud end calculates the use habit of a user of the heat pump unit according to the state information, and generates a regulation and control strategy to regulate and control the heat pump unit according to the use habit of the user and local climate parameters, so that the heat pump unit meets the use requirement of the user. The controller directly acquires the state information of the heat pump unit and uploads the state information to the cloud end through the communication module in the controller, the cloud end calculates the use habit of a user using the heat pump unit by utilizing a calculation unit arranged in the cloud end according to the acquired state information of the heat pump unit, the cloud end acquires the climate parameters of the environment where the heat pump unit is located through the Internet, the calculation obtains the strategy about regulating and controlling the heat pump unit, the generated regulation and control strategy is issued to the controller through the communication module, the controller directly regulates and controls the heat pump unit in all aspects according to the regulation and control strategy, so that the heat pump unit can normally work under different climate parameters, and different requirements of different users on using the heat pump unit are further met.

Drawings

Other features, objects and advantages of the utility model will become more apparent upon reading of the detailed description of non-limiting embodiments made with reference to the following drawings:

fig. 1 is a schematic structural diagram of an adaptive heat pump remote control system according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a cloud in a remote control system according to an embodiment of the present invention.

Detailed Description

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

It should be further noted that, for the convenience of description, only some but not all of the relevant aspects of the present invention are shown in the drawings.

Fig. 1 is a schematic structural diagram of an adaptive heat pump remote control system according to an embodiment of the present invention. As shown in fig. 1, the control system includes a heat pump unit 110, a controller 120 and a cloud 130, the controller 120 includes a communication module 121, the heat pump unit 110 is electrically connected to the controller 120, the communication module 121 of the controller 120 is in communication connection with the cloud 130, wherein the controller 120 collects state information of the heat pump unit 130 and uploads the state information to the cloud 130 through the communication module 121, the cloud 130 calculates usage habits of users of the heat pump unit 110 according to the state information, and generates a regulation and control strategy to regulate and control the heat pump unit 110 according to the usage habits of the users and local climate parameters, so that the heat pump unit meets the usage requirements of the users.

In the field of air source heat pumps, a heat pump unit 110 applies work through an input motor of electric energy to drive a compressor in the heat pump unit, so that a refrigerant circulates in the system, in the process, a low-temperature low-pressure gaseous refrigerant passes through the compressor and then becomes a high-temperature high-pressure gaseous refrigerant, the high-temperature high-pressure gaseous refrigerant is condensed and released heat through a sleeve heat exchanger and then becomes a high-temperature high-pressure liquid refrigerant, the high-temperature high-pressure liquid refrigerant is throttled and expanded through an expansion valve and becomes a low-temperature low-pressure liquid refrigerant, the low-temperature low-pressure liquid refrigerant passes through a fin heat exchanger, meanwhile, a fan drives continuous air to pass through the outer surface of the fin heat exchanger, the refrigerant is evaporated and absorbs heat and becomes the low-temperature low-pressure gaseous refrigerant, then the refrigerant enters the compressor to perform the next circulation, and heat is continuously transferred from a low-temperature heat source to a high-temperature heat source.

The cloud 130 has the characteristics of high distribution, high virtualization and the like, so that network resources are fully utilized. When the heat pump unit 110 is applied to a hot water system, the internet is used for performing a remote control system, in order to realize all-weather adaptive operation of the remote control system and meet a hot water requirement for a user, in this embodiment, the cloud 130 is used to acquire state information of the heat pump unit 110, and the acquired state information is subjected to high-speed operation in the cloud 110 to obtain a specific service condition of the heat pump unit 110 of the user in a certain time period, and the heat pump unit 110 is regulated according to the service condition, so that the heat pump unit 110 can work more efficiently to meet the service requirement of the user.

Specifically, the heat pump unit 110 is connected to the controller 120, the controller 120 directly obtains status information of the heat pump unit 110 and uploads the status information to the cloud 130 through the communication module 121 in the controller 120, and the cloud 130 calculates a usage habit of a user using the heat pump unit 110 according to the obtained status information of the heat pump unit 110 by using a calculation unit therein. Wherein, the usage habit of the user can be understood as the specific situation that the user using the heat pump unit 110 uses the heat pump unit 110 within a certain time period, wherein, the usage habit includes the usage duration, the usage temperature and the working frequency of the heat pump unit 110, in addition, the cloud 130 obtains the climate parameters of the environment where the heat pump unit 110 is located through the internet, for example, the user uses the heat pump unit 110 in the southern city, the usage temperature of the heat pump unit 110 in summer is higher, the usage frequency is also higher, at this time, the cloud 130 calculates the strategy for regulating and controlling the heat pump unit 110 according to the frequency and the climate parameters where the user uses the heat pump unit 110, it can be known that, when the heat pump unit 110 is used in summer in the southern city, because the usage temperature is higher, the heat pump unit 110 is regulated by regulating the working frequency, the heat dissipation, the heat pump unit 110, the heat dissipation, Defrost performance, etc. to achieve the user needs of the user in the southern city. Similarly, the user uses the heat pump unit 110 in the northern city, the service temperature of the heat pump unit 110 in winter is lower, according to the use habit of the user in the northern city, the frequency of using the heat pump unit 110 is lower, at this moment, the cloud 130 calculates a strategy for regulating and controlling the heat pump unit 110 according to the frequency of using the heat pump unit 110 by the user and the local climate parameters, and because the service temperature is lower, the working frequency of the heat pump unit 110 can be reduced, and the temperature of the heat pump unit 110 is increased to meet the use requirement of the user in the northern city.

Optionally, the status information includes ambient temperature information, exhaust temperature information, and heat dissipation temperature information of the heat pump unit 110, and operating frequency information of the heat pump unit.

Under different environments, the air source heat pump needs different temperatures to adapt to, and the temperature of the environment influences the outlet water temperature of the heat pump unit, and the outlet water temperature also influences the exhaust temperature. The higher the outlet water temperature is, the greater the loss to the heat pump unit is, the higher the water temperature is, the higher the condensation pressure of the heat pump unit is, the excessively increased condensation temperature brings about the temperatures of the excessively high exhaust temperature, the increased exhaust pressure, the obvious reduction of the system efficiency and the like, especially in winter, the problem is more serious, and the problem not only reduces the energy efficiency ratio of the heat pump unit 110, but also causes the viscosity reduction of lubricating oil, serious carbonization occurs, the heat pump unit 110 cannot work normally, and the compressor in the heat pump unit can be damaged.

Therefore, after the environmental temperature information, the exhaust temperature information, the heat dissipation temperature information and the operating frequency information during operation of the heat pump unit 110 obtained by the controller 120 are uploaded to the cloud 130 through the communication module, the cloud 130 calculates the regulation and control strategy to be regulated and controlled by the heat pump unit 110 according to the information and by combining the climate parameters of the environment where the heat pump unit 110 is located, the generated regulation and control strategy comprises regulation and control of the performance of the heat pump unit such as exhaust, heat dissipation and defrosting according to the temperature information, reasonable regulation and control of the opening of the solenoid valve of the heat pump unit 110 according to the operating frequency information during operation, and the generated regulation and control strategy can be sent to the controller 120 through the communication module in a way of being packaged into a protocol, the controller 120 directly regulates and controls the heat pump unit 110 in various aspects according to the regulation and control strategy, so as to ensure the normal operation of the heat pump unit 110 under different climate parameters, further meeting different requirements of different users for using the heat pump unit 110.

The embodiment provides a self-adaptation heat pump remote control system, including heat pump set, controller and high in the clouds, the controller includes communication module, heat pump set and controller electricity are connected, the controller communication module is connected with the high in the clouds communication, wherein, the controller gathers heat pump set's state information and uploads to the high in the clouds through communication module, the high in the clouds obtains heat pump set's user's use habit according to the operation of state information to generate regulation and control strategy according to user's use habit and local climate parameter and regulate and control heat pump set, so that heat pump set satisfies user's user demand. The controller directly acquires the state information of the heat pump unit and uploads the state information to the cloud end through the communication module in the controller, the cloud end calculates the use habit of a user using the heat pump unit by utilizing a calculation unit arranged in the cloud end according to the acquired state information of the heat pump unit, the cloud end acquires the climate parameters of the environment where the heat pump unit is located through the Internet, the calculation obtains the strategy about regulating and controlling the heat pump unit, the generated regulation and control strategy is issued to the controller through the communication module, the controller directly regulates and controls the heat pump unit in all aspects according to the regulation and control strategy, so that the heat pump unit can normally work under different climate parameters, and different requirements of different users on using the heat pump unit are further met.

Optionally, referring to fig. 1, the controller 120 further includes a control module 122 and a detection module 123, the control module 122 is electrically connected to the heat pump unit 110, the detection module 123 and the communication module 121, the detection module 123 detects and obtains status information of the heat pump unit 110, the control module 122 uploads the status information to the cloud 130 through the communication module 121, and the communication module 121 obtains a regulation and control policy to regulate and control the heat pump unit 110.

On the basis of the above embodiment, acquiring the state information of the heat pump unit 110 is completed by the detection module 123 in the controller 120, the detection module 123 detects various parameters during the operation of the heat pump unit and transmits the detected parameters to the control module 122 as the state information during the operation of the heat pump unit 110, wherein the state information acquired by the detection module 123 is the environment temperature information, the exhaust temperature information, the heat dissipation temperature information, and the operation frequency information of the heat pump unit 110 in the above embodiment, the control module 122 uploads the information to the cloud end through the communication module 121, the cloud end 130 calculates the regulation and control policy to be regulated and controlled by the heat pump unit 110 according to the information of the heat pump unit 110 and the climate parameters of the environment where the heat pump unit 110 is located, the cloud end 130 issues the regulation and control policy to the control module 122 through the communication module 121, and the control module 122 controls the heat pump unit 110 to perform related regulation and control actions according to the regulation and control policy, so as to ensure the normal operation of the heat pump unit 110 under different climatic parameters.

It should be noted that, the specific control actions related to the heat pump unit 110 are already described in the above embodiments, and are not described herein again.

In addition, the control module 122 in the controller 120 serves as a main control unit for uploading the state information of the heat pump unit 110 and issuing a regulation and control strategy to the heat pump unit 110. In other embodiments, when the control module 122 controls the heat pump unit 110 to perform relevant regulation and control actions according to the regulation and control strategy, the control module 122 may be in communication with one or more control units of the heat pump unit 110, and the control module 122 may be in butt joint with the one or more control units of the heat pump unit 110, so as to realize relevant regulation and control of the heat pump unit 110 by the controller 120. It should be noted that, regarding the specific regulation principle of the control module 122, the operation principle is similar to the operation principle of the micro control unit in the art, and the operation principle is well known to those skilled in the art, and is not described herein again.

Optionally, with reference to fig. 1, the controller further includes a parameter module 124, the parameter module 124 is configured to store safe operating parameters of the heat pump unit 110, the safe operating parameters are matched with initial performance parameters of the heat pump unit 110, the control module 122 further compares the acquired state information with the safe operating parameters in real time, and uploads a comparison result to the cloud 130 through the communication module 121, and the cloud 130 further generates a regulation and control policy according to the comparison result.

The controller 120 is connected to the heat pump units 110, the initial performance parameters of the heat pump units 110 are preset by a designer before the heat pump units 110 leave a factory, the initial performance parameters may include parameters such as temperature, correction coefficient, water temperature compensation and the like of each heat pump unit 110, the initial performance parameters are stored in a parameter module of the controller 120, and the initial performance parameters are used as safe operating parameters of the heat pump units 110 in a safe operating state.

It can be understood that the initial performance parameter may be a threshold value for determining the state information of the heat pump unit 110 collected by the detection module 123 in the operation process, and in the subsequent operation process of the heat pump unit 110, the detection module 123 in the controller 120 detects the state information of each operation time period, at this time, the collected state information of the heat pump unit 110 in operation may be compared with the safe operating parameters stored in the parameter module 124, and the operation state of the heat pump unit 110 may be further analyzed, so as to ensure that the heat pump unit 110 normally operates under different climate parameters.

Illustratively, when the state acquired by the detection module 123 does not match the safe operating parameters of the heat pump unit pre-stored in the parameter module 124, the control module 122 uploads the state information of the current heat pump unit 110 to the cloud 130 through the communication module 121, the cloud 130 calculates a regulation and control policy that the heat pump unit 110 needs to regulate and control according to the received state information and by combining climate parameters of the environment where the heat pump unit 110 is located, and sends the generated regulation and control policy to the controller 1201 through the communication module 121 in a protocol packaging manner, and the control module 122 directly regulates and controls the heat pump unit in various aspects according to the regulation and control policy, so as to ensure that the heat pump unit 110 normally operates under different climate parameters, and further meet different requirements of different users for using the heat pump unit 110.

Optionally, the communication module includes a positioning unit (not shown in fig. 1), the communication module 121 further uploads positioning information provided by the positioning unit to the cloud 130, and the cloud 130 obtains local climate parameters according to the positioning information.

The heat pump unit 110 is connected with the controller 120, the communication module 121 and the positioning unit therein can be collectively referred to as a terminal similar to a GPS locator, and the positioning data obtained by the positioning unit is uploaded to the cloud 130 through the communication module 121, so that the position of the heat pump unit 110 can be queried, and the position can further acquire the climate parameters of the position where the heat pump unit 110 is located.

The positioning means has functions of immediate positioning and timing positioning.

Optionally, the communication module comprises a SIM card and a 4G module, or a SIM card and a 5G module.

The SIM card is a smart card held by a mobile subscriber of the global system for mobile communications. In this embodiment, the communication module is inserted with an SIM card for storing the state information of the heat pump unit, and the state information is uploaded to the cloud end by using the 4G or 5G module as a communication transmission medium. The 4G or 5G is used as a communication transmission medium for wirelessly receiving and transmitting signals, when the communication module comprises the SIM card and the 5G module, the data transmission rate is 100 times faster than that of the 4G module, and the communication module has lower network delay and super-large network capacity and can meet the communication of the Internet of things. In this embodiment, a specific communication module may be selected according to different heat pump units and status information thereof, which is not limited herein.

Fig. 2 is a schematic structural diagram of a cloud in a remote control system according to an embodiment of the present invention. As shown in fig. 2, the cloud 130 includes a computer 131, and the computer 131 calculates the usage habits of users of the heat pump units according to the state information, and generates the control policy according to the usage habits of the users and the local climate parameters.

The computer 131 in the cloud 130 is good at distributed computing, solves task distribution, merges computing results, can complete processing of tens of thousands of data in a short time, and achieves powerful network service in the cloud 130.

Specifically, the regulation and control strategy that the heat pump unit needs to be regulated and controlled is obtained according to the operation result of the computer 1331, the generated regulation and control strategy comprises regulation and control of performances of exhaust, heat dissipation, defrosting and the like of the heat pump unit according to temperature information, reasonable regulation and control of the opening of an electromagnetic valve of the heat pump unit according to operating frequency information during operation, and startup and shutdown actions of the heat pump unit, the generated regulation and control strategy can be sent to a controller through a communication module in a protocol packaging mode, and the controller directly regulates and controls different parameters of the heat pump unit according to the regulation and control strategy.

It should be noted that the specific operation principle and process of the computer 131 in the cloud 130 are well known to those skilled in the art, and are not described herein.

Optionally, referring to fig. 2, the cloud 130 further includes a data center 132, the data center 132 is in communication connection with the computer 131, and the data center 132 acquires status information of the heat pump units in real time or in a historical time period and provides the status information to the computer 131.

The data center 132 is equivalent to a cloud platform, and has input and output of a large amount of data, developers can monitor the working state of the heat pump unit through the data center 132, the data center 132 guides the collected state information about the heat pump unit into the computer 131 through a formula for operation, and a regulation and control strategy is generated according to an operation result and is issued to a control module in the controller.

It should be noted that the status information of the heat pump units uploaded to the data center 132 may be immediate or within a period of time in the past, so as to facilitate developers to monitor the operating status of the heat pump units.

Optionally, referring to fig. 2, the cloud 130 further includes a server 133, and the server is communicatively connected to the data center 132, and the server 133 stores real-time status information of the heat pump units in real time or in historical time periods.

The server 133 in the cloud 130 may provide a cloud storage service in the form of a cloud disk, and the storage service is an online storage mode, and stores data in a remote database and accesses the remote database through the internet, that is, stores the data in a plurality of virtual servers generally hosted by a third party.

In this embodiment, after the ambient temperature information, the exhaust temperature information, the heat dissipation temperature information, and the operating frequency information during operation, which are obtained during the current operation process of the heat pump unit or in a period of time in the past, are uploaded to the cloud 130 through the communication module, and are stored by the server 133, the storage space is large, and the data center can be more or less immediately restored in an offline state, so that higher reliability is provided.

It is to be noted that the foregoing is only illustrative of the preferred embodiments of the present invention and the technical principles employed. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the utility model. Therefore, although the present invention has been described in greater detail by the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the spirit of the present invention, and the scope of the present invention is determined by the scope of the appended claims.

Claims (9)

1. A self-adaptive heat pump remote control system is characterized by comprising a heat pump unit, a controller and a cloud end, wherein the controller comprises a communication module; the heat pump unit is electrically connected with the controller, and the communication module of the controller is in communication connection with the cloud end;

the controller collects state information of the heat pump unit and uploads the state information to the cloud end through the communication module;

and the cloud end calculates according to the state information to obtain the use habit of a user of the heat pump unit, and generates a regulation and control strategy according to the use habit of the user and the local climate parameters to regulate and control the heat pump unit so that the heat pump unit meets the use requirement of the user.

2. The remote control system of claim 1, wherein the controller further comprises a control module and a detection module; the control module is respectively and electrically connected with the heat pump unit, the detection module and the communication module;

the detection module detects and acquires state information of the heat pump unit; the control module uploads the state information to the cloud end through the communication module, and the communication module acquires a regulation strategy to regulate and control the heat pump unit.

3. The remote control system of claim 2, wherein the controller further comprises a parameter module for storing safe operating parameters of the heat pump unit, the safe operating parameters matching initial performance parameters of the heat pump unit;

the control module is also used for comparing the acquired state information with the safe working parameters in real time and uploading the comparison result to the cloud end through the communication module; and the cloud terminal also generates a regulation and control strategy according to the comparison result.

4. The remote control system according to claim 1, wherein the communication module comprises a positioning unit, and the communication module further uploads positioning information provided by the positioning unit to the cloud;

and the cloud end acquires local climate parameters according to the positioning information.

5. The remote control system of claim 1, wherein the status information includes ambient temperature information, exhaust temperature information, and heat rejection temperature information of the heat pump unit, and operating frequency information of the heat pump unit.

6. The remote control system according to claim 2, wherein the communication module comprises a SIM card and a 4G module, or a SIM card and a 5G module.

7. The remote control system according to claim 1, wherein the cloud comprises a computer, the computer calculates usage habits of users of the heat pump units according to the state information, and generates a regulation and control strategy according to the usage habits of the users and local climate parameters.

8. The remote control system of claim 7, wherein the cloud further comprises a data center, the data center being communicatively coupled to the computer;

and the data center acquires the state information of the heat pump unit in real time or in a historical time period and provides the state information to the computer.

9. The remote control system of claim 8, wherein the cloud further comprises a server, the server being communicatively coupled to the data center;

the server stores real-time state information of the heat pump unit in real time or in historical time periods.

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