A method, system and apparatus for fastening control of air conditioner components

By combining the MES system and PDA devices with message queues to transmit torque standard information, the problems of inaccurate torque calibration and missing parts during the tightening of air conditioning components were solved, achieving efficient production control and real-time data management, and improving production efficiency and after-sales quality.

CN116728056BActive Publication Date: 2026-06-09GREE TOSOT (SUQIAN) HOME APPLIANCES CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
GREE TOSOT (SUQIAN) HOME APPLIANCES CO LTD
Filing Date
2023-06-19
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Traditional air conditioner component fastening technology suffers from inaccurate torque calibration and missing components, and lacks error-proofing measures, resulting in low production efficiency and after-sales problems.

Method used

The MES system and the torque calibration module transmit torque standard information through a message queue. Combined with PDA scanning of component barcodes, error-proofing and foolproof control of the electric screwdriver are achieved, ensuring the accuracy of torque calibration and the correct tightening of components.

Benefits of technology

It improved the accuracy of torque calibration, reduced the occurrence of missing parts, saved employee time, improved production efficiency, and enabled real-time data transmission and rapid detection of abnormal data through the 5G network.

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Abstract

This invention discloses a method, system, and device for tightening control of air conditioning components, comprising the following steps: receiving torque standard information of the model to be tightened and torque parameters obtained by scanning torque asset codes via a message queue; verifying the torque parameters through the torque standard information to generate verification information to determine the mapping relationship between the torque parameters and the components; obtaining the barcode identifier of the components and inputting it into the torque start module via the message queue to start the electric screwdriver; determining the components and their corresponding torque parameters based on the barcode identifier to enable the electric screwdriver to perform the corresponding tightening operation and outputting the torque execution result. This invention ensures that the standard value of the torque is accurate when calibrating the corresponding components, solving the problems of time-consuming, labor-intensive, and inaccurate traditional manual calibration work involving finding process standards and manually inputting them into a torque calibrator, saving employees a significant amount of time and improving production efficiency.
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Description

Technical Field

[0001] This invention relates to the field of air conditioning component manufacturing technology, and in particular to a method, system and device for fastening control of air conditioning components. Background Technology

[0002] Traditional air conditioner component fastening techniques require manual verification of process standards during torque calibration. Furthermore, the electric screwdrivers lack error-proofing measures during component fastening, and given the significant human factor at play, traditional techniques are prone to inaccurate torque calibration and missing components. Air conditioners require the fastening of numerous and varied components, each with different calibration standards. Current technology involves manual input of process standards into a torque calibrator, leading to inaccuracies in standard value input. In actual production, the electric screwdrivers lack error-proofing; they can be started immediately upon power-on. Due to uncontrollable factors such as production pace and human error, missing components are highly likely, resulting in serious after-sales problems. Summary of the Invention

[0003] To address the aforementioned issues of inaccurate torque calibration and missing parts, this invention provides a method, system, and device for tightening control of air conditioning components. It utilizes message queues to transmit torque standard information between the MES system, the torque calibration module, and the torque result judgment module, ensuring the accuracy of the standard information when calibrating the torque of the corresponding components. Simultaneously, it saves employees significant time and improves production efficiency.

[0004] To achieve the above objectives, the present invention employs the following technical solution: a method for fastening and controlling air conditioning components, comprising the following steps:

[0005] The message queue receives the torque standard information of the model to be tightened and the torque parameters obtained by scanning the torque asset code, respectively.

[0006] The torque parameters are verified using torque standard information, and verification information is generated to determine the mapping relationship between the torque parameters and the components.

[0007] The barcode identifier of the component is obtained and the torque start module is input through the message queue to start the electric screwdriver. The component and the torque parameters that establish the mapping relationship are determined according to the barcode identifier so that the electric screwdriver performs the corresponding tightening operation and outputs the torque execution result.

[0008] As a further improvement to the present invention, the following steps are also included:

[0009] The torque standard information is received via a message queue;

[0010] The torque execution result is determined based on the torque standard information, including:

[0011] If the result is qualified, return to the step of obtaining the barcode identification of the new component to perform the new component fastening operation;

[0012] If the result is unqualified, the production line will stop working and a pop-up window will appear, waiting for a choice: if the option to re-execute is selected, the electric screwdriver will restart with the current torque parameters to perform the corresponding tightening operation; if the option to remove from the line is selected, the production line will continue working to perform the tightening of the next new component.

[0013] As a further improvement of the present invention, the step of receiving torque standard information of the model to be tightened via message queues includes:

[0014] When using it for the first time or when the production line is switching models, enter the model code of the corresponding model in the MES system;

[0015] Based on the model code, obtain the torque standard information of the corresponding component of the model. The torque standard information includes: the model code of the corresponding model, the maximum torque value, and the minimum torque value.

[0016] The MES system transmits the torque standard information to the torque verification module and the torque result determination module through a message queue.

[0017] As a further improvement of the present invention, the fastening control method further includes:

[0018] The torque asset code is scanned using a PDA, and the torque parameters are obtained through the coding information recorded in the torque asset code;

[0019] The torque is transmitted to the torque verification module via a message queue, and the torque parameters are verified according to the torque standard information.

[0020] Generate verification information, which includes the model code of the corresponding model, the maximum torque, the minimum torque, the torque asset code, and the mapping relationship between the corresponding parts;

[0021] The verification information is transmitted to the torque start module.

[0022] As a further improvement of the present invention, the fastening control method further includes:

[0023] Use a PDA to scan the barcode markings on the parts to be fastened;

[0024] The data is transmitted to the torque start module via a message queue.

[0025] The torque parameters are matched according to the corresponding mapping relationship based on the barcode identifier;

[0026] The electric screwdriver is controlled to tighten the parts to be tightened according to the torque parameters.

[0027] As a further improvement of the present invention, the fastening control method further includes: the torque result determination module determines the torque execution result based on torque standard information, and the judgment result data of each qualified and / or unqualified result is automatically saved locally and then transmitted to the MES system through a real-time message queue.

[0028] On the other hand, the present invention adopts the following technical solution: a fastening control system for air conditioning components, comprising:

[0029] The MES system is used to input the model code of the corresponding machine to obtain the torque standard information of the corresponding parts of the machine, and transmit it to the torque verification module and the torque result determination module through the message queue;

[0030] The torque verification module is used to receive torque parameters obtained by scanning with a PDA and verify the torque parameters with torque standard information to generate verification information;

[0031] The torque start module is used to receive the barcode identification of the component scanned by the PDA to start the electric screwdriver to perform a tightening operation on the component according to the torque parameters, and output the torque execution result.

[0032] As a further improvement to the present invention, it also includes:

[0033] The torque result determination module is used to determine the torque execution result based on the torque standard information, obtaining a pass or fail result. If the result is pass, it returns to the step of obtaining the barcode identification of the new component to execute the new component fastening operation; if the result is fail, it controls the production line to stop and a pop-up window awaits selection: if the option to re-execute is selected, it controls the electric screwdriver to restart with the current torque parameters to execute the corresponding fastening operation; if the option to exit the line is selected, it controls the production line to continue working to execute the next new component fastening.

[0034] As a further improvement to the present invention, it also includes:

[0035] The torque control module is used to control the three-color light alarm when the output of the torque result judgment module is a non-conforming judgment result, and to send a signal to the PLC through the IO port to control the production line to stop working.

[0036] It is also used to receive user selections based on pop-up windows, control the three-color lights to reset, and control the electric screwdriver to perform a tightening operation again, or send signals to the PLC via IO ports to control the production line to continue working.

[0037] On the other hand, the present invention adopts the following technical solution: a fastening control device for air conditioning components, including a memory and a processor, wherein the processor executes the fastening control method for air conditioning components as described above by calling the control program stored in the memory.

[0038] Compared with the prior art, the present invention has the following beneficial effects:

[0039] This invention allows users to find the torque standard information of corresponding components by inputting the model code of the corresponding machine into the MES system. This provides the model code, maximum torque, and minimum torque value of the corresponding component, which are then directly transmitted to the torque verification module and torque result judgment module via a message queue. This ensures that the standard value is accurate when calibrating the torque of the corresponding component. It solves the problems of time-consuming, labor-intensive, and inaccurate traditional manual calibration work, which involves manually finding process standards and inputting them into a torque calibrator. This saves employees a lot of time and improves production efficiency.

[0040] This invention uses a PDA to transmit the acquired component barcode identifiers to the torque start module via a message queue, linking the electric screwdriver with the component barcode identifiers. The torque start module will only start the electric screwdriver and perform the corresponding component fastening operation after receiving the component barcode identifier, effectively solving the problem of easily missing components and improving production efficiency. Attached Figure Description

[0041] To more clearly illustrate the technical solution, the accompanying drawings used in the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0042] Figure 1 This is a schematic diagram of the control logic in the embodiment. Detailed Implementation

[0043] In order to clearly and completely understand the technical solution, the present invention will be further described in conjunction with the embodiments and accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention. All other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.

[0044] It should be understood that, when used in this specification and the appended claims, the terms "comprising" and "including" indicate the presence of the described features, integrals, steps, operations, elements and / or components, but do not exclude the presence or addition of one or more other features, integrals, steps, operations, elements, components and / or collections thereof.

[0045] It should also be understood that the terminology used in this specification is for the purpose of describing particular embodiments only and is not intended to limit the invention. As used in this specification and the appended claims, the singular forms “a,” “an,” and “the” are intended to include the plural forms unless the context clearly indicates otherwise.

[0046] It should also be further understood that the term "and / or" as used in this specification and the appended claims refers to any combination of one or more of the associated listed items and all possible combinations, and includes such combinations.

[0047] like Figure 1 As shown, this embodiment provides a method for fastening and controlling air conditioning components, including the following steps:

[0048] Step S100: Receive the torque standard information of the model to be tightened and the torque parameters obtained by scanning the torque asset code using a message queue.

[0049] It should be noted that receiving the torque standard information of the model to be tightened by the message queue includes: step S110, when it is used for the first time or the production line is in the process of switching models, the model code of the corresponding model is entered in the MES system.

[0050] Step S120: Obtain the torque standard information of the corresponding component of the machine model according to the model code. The torque standard information includes: the model code of the corresponding machine model, the maximum torque value, and the minimum torque value.

[0051] In step S130, the MES system transmits the torque standard information to the torque verification module and the torque result determination module through a message queue.

[0052] Through the above steps, employees only need to enter the model code of the corresponding machine in the MES system to find the torque standard information of the corresponding parts. This allows them to obtain the model code, maximum torque, and minimum torque of the corresponding parts. The information is then directly transmitted to the torque verification module and torque result judgment module via a message queue. This ensures that the standard values ​​are accurate when calibrating the torque of the corresponding parts. This solves the problems of time-consuming, labor-intensive, and inaccurate traditional methods of manually finding process standards and then manually entering them into the torque calibrator. It saves employees a lot of time and improves production efficiency.

[0053] Step S200: Verify the torque parameters using torque standard information, and generate verification information to determine the mapping relationship between the torque parameters and the components;

[0054] It should be noted that in this embodiment, the torque parameter is obtained by scanning the torque asset code with a PDA and obtaining the coding information recorded in the torque asset code. The PDA is a handheld device with barcode scanning function.

[0055] In an optional embodiment, verifying the torque parameters using torque standard information includes:

[0056] Step S210: Use a PDA to scan the torque asset code and obtain the torque parameters through the coding information recorded in the torque asset code;

[0057] Step S220: The torque is transmitted to the torque verification module via a message queue, and the torque parameters are verified according to the torque standard information.

[0058] Step S230: Generate verification information, which includes the model code of the corresponding model, the maximum torque, the minimum torque, the torque asset code, and the mapping relationship between the corresponding parts;

[0059] Step S240: Transmit the verification information to the torque start module.

[0060] In this embodiment, the barcode identifiers of the electric screwdriver and the components are linked by a PDA device and a message queue, thereby preventing errors and mistakes in the electric screwdriver and solving the problem of components being easily missed during installation.

[0061] Step S300: Obtain the barcode identifier of the component and input the torque start module into the message queue to start the electric screwdriver. Determine the component and its torque parameters based on the barcode identifier so that the electric screwdriver performs the corresponding tightening operation and outputs the torque execution result.

[0062] To better understand, step S300 above can be executed in multiple ways. In one optional embodiment, it includes:

[0063] Step S310: Use a PDA to scan the barcode markings of the parts to be fastened;

[0064] Step S320: The data is transmitted to the torque start module via a message queue.

[0065] Step S330: Match the torque parameters of the corresponding mapping relationship according to the barcode identifier, and control the electric screwdriver to perform a tightening operation on the parts to be tightened according to the torque parameters.

[0066] It should be noted that in actual production, the electric screwdriver's startup does not prevent errors or mistaken assumptions. This means that the screwdriver can be started immediately upon being powered on. Due to uncontrollable factors such as production cycle time and human error, it is very easy for parts to be missed, leading to serious after-sales problems. In this embodiment, after the torque verification module completes its verification work and generates verification information, the torque starting module does not start the electric screwdriver. At this time, on-site employees need to use a PDA to scan the part's barcode. After scanning, the PDA transmits the obtained part's barcode to the torque starting module via a message queue, linking the electric screwdriver with the part's barcode. Only after receiving the part's barcode will the torque starting module start the electric screwdriver and perform the corresponding part tightening operation, effectively solving the problem of easily missed parts and improving production efficiency.

[0067] Furthermore, the fastening control method further includes the following steps:

[0068] Step S400: Receive the torque standard information via a message queue;

[0069] Step S500: Determine the torque execution result based on the torque standard information, including:

[0070] If the judgment result is qualified, return to step S300 to obtain the new component barcode identification step to perform the new component fastening operation;

[0071] If the result is unqualified, the three-color light alarm will be activated and the production line will stop working, and a pop-up window will be displayed to wait for selection: if the option to re-execute once is selected, step S330 will be executed again, the three-color light alarm will be canceled and the electric screwdriver will be restarted with the current torque parameters to perform the corresponding tightening operation; if the option to remove from the line is selected, the three-color light alarm will be canceled and the production line will continue to work to perform the tightening of the next new part.

[0072] In this embodiment, the torque result determination module judges the torque execution result based on torque standard information. Each pass / fail judgment result is automatically saved locally and then transmitted to the MES system via a real-time message queue. It should be noted that in traditional production processes, both torque calibration data and final component tightening data are initially saved locally, and then retrieved by designated personnel later when needed. This embodiment utilizes a 5G network, leveraging its low latency, high bandwidth, and wide connectivity to achieve efficient data transmission across the entire system within milliseconds, meeting the requirement for real-time data transmission. This eliminates the need for on-site data retrieval; personnel can simply log into the MES system to view data in real time, improving the efficiency of detecting abnormal data and reducing the occurrence of after-sales issues.

[0073] Through the above description of the embodiments, those skilled in the art can clearly understand that the methods according to the above embodiments can be implemented by means of software plus necessary general-purpose hardware platforms. Of course, they can also be implemented by hardware, but in many cases the former is a better implementation method. Based on this understanding, the technical solution of this application, in essence, or the part that contributes to the prior art, can be embodied in the form of a software product. This computer software product is stored in a storage medium (such as read-only memory (ROM), random access memory (RAM), magnetic disk, optical disk), and includes several instructions to cause a terminal device (which may be a mobile phone, computer, server, or network device, etc.) to execute the methods described in the various embodiments of this application.

[0074] This embodiment also provides a fastening control system for air conditioning components, which is used to implement the above embodiments and preferred embodiments; details already described will not be repeated. As used below, the term "module" can refer to a combination of software and / or hardware that performs a predetermined function. Although the systems described in the following embodiments are preferably implemented in software, hardware implementation, or a combination of software and hardware, is also possible and contemplated.

[0075] A fastening control system for air conditioning components, comprising:

[0076] The MES system is used to input the model code of the corresponding machine to obtain the torque standard information of the corresponding parts of the machine, and transmit it to the torque verification module and the torque result determination module through the message queue;

[0077] The torque verification module is used to receive torque parameters obtained by scanning with a PDA and verify the torque parameters with torque standard information to generate verification information;

[0078] The torque start module is used to receive the barcode identification of the parts scanned by the PDA to start the electric screwdriver to perform a tightening operation on the parts according to the torque parameters, and output the torque execution result;

[0079] The torque result determination module is used to determine the torque execution result based on the torque standard information, obtaining a pass or fail result. If the result is pass, it returns to the step of obtaining the barcode identification of the new component to execute the new component fastening operation; if the result is fail, it controls the production line to stop and a pop-up window awaits selection: if the option to re-execute is selected, it controls the electric screwdriver to restart with the current torque parameters to execute the corresponding fastening operation; if the option to exit the line is selected, it controls the production line to continue working to execute the next new component fastening operation.

[0080] The torque control module is used to control the three-color light alarm when the output of the torque result judgment module is unqualified, and to send a signal to the PLC through the IO port to control the production line to stop working; it is also used to receive the user's selection of the corresponding option according to the pop-up window, control the three-color light to reset, and control the electric screwdriver to perform a tightening operation again, or send a signal to the PLC through the IO port to control the production line to continue working.

[0081] With the aforementioned MES system, employees only need to enter the model code of the corresponding machine into the MES system to find the torque standard information of the corresponding parts. This allows them to obtain the model code, maximum torque, and minimum torque of the corresponding parts, which are then directly transmitted to the torque verification module and torque result judgment module via a message queue. This ensures that the standard values ​​are accurate when calibrating the torque of the corresponding parts. It solves the problems of time-consuming, labor-intensive, and inaccurate traditional manual calibration work, which involves manually finding process standards and inputting them into the torque calibrator. This saves employees a lot of time and improves production efficiency.

[0082] Furthermore, the torque start module receives the barcode identifier of the component from the PDA scan to start the electric screwdriver to perform a tightening operation on the component according to the torque parameters. Through the transmission method of the PDA device with an external message queue, the electric screwdriver and the component barcode identifier are linked, thereby realizing error prevention and foolproofing of the electric screwdriver and solving the problem of components being easily missed.

[0083] In other words, after the torque verification module completes its verification work and generates verification information, the torque start module will not start the electric screwdriver. At this point, on-site employees need to use a PDA to scan the component barcode. After scanning, the PDA transmits the obtained component barcode to the torque start module via a message queue, linking the electric screwdriver with the component barcode. Only after receiving the component barcode will the torque start module start the electric screwdriver and perform the corresponding component tightening operation, effectively solving the problem of easily missing components and improving production efficiency.

[0084] Furthermore, the torque result judgment module judges the torque execution result based on torque standard information. Each pass / fail judgment result is automatically saved locally and then transmitted to the MES system via a real-time message queue. It should be noted that in traditional production processes, both torque calibration data and final component tightening data are initially saved locally, and then retrieved by designated personnel later when needed. This embodiment utilizes a 5G network, leveraging its low latency, high bandwidth, and wide connectivity to achieve efficient data transmission across the entire system within milliseconds, meeting the requirement for real-time data transmission. This eliminates the need for personnel to retrieve data on-site; they can simply log into the MES system to view the data in real time, improving the efficiency of detecting abnormal data and thus reducing the occurrence of after-sales issues.

[0085] It should be noted that the above modules can be implemented by software or hardware. For the latter, they can be implemented in the following ways, but are not limited to: all the above modules are located in the same processor; or, the above modules are located in different processors in any combination.

[0086] Embodiments of the present invention also provide a fastening control device for air conditioning components, including a memory and a processor. The processor executes a fastening control method for air conditioning components as described in the above embodiments by calling a control program stored in the memory.

[0087] Optionally, in this embodiment, the fastening control device may be configured to store a control program for performing the following steps:

[0088] Step S100: Receive the torque standard information of the model to be tightened and the torque parameters obtained by scanning the torque asset code using a message queue.

[0089] Step S200: Verify the torque parameters using torque standard information, and generate verification information to determine the mapping relationship between the torque parameters and the components;

[0090] Step S300: Obtain the barcode identifier of the component and input the torque start module into the message queue to start the electric screwdriver. Determine the component and the torque parameters that establish the mapping relationship with it based on the barcode identifier so that the electric screwdriver performs the corresponding fastening operation and outputs the torque execution result.

[0091] Step S400: Receive the torque standard information via a message queue;

[0092] Step S500: Determine the torque execution result based on the torque standard information, including:

[0093] If the judgment result is qualified, return to step S300 to obtain the new component barcode identification step to perform the new component fastening operation;

[0094] If the result is unqualified, the three-color indicator light will be activated to alarm and the production line will be stopped. A pop-up window will then appear, waiting for the user to select an option: if the user selects the option to re-execute once, the three-color indicator light will be deactivated and the electric screwdriver will be restarted with the current torque parameters to perform the corresponding tightening operation; if the user selects the option to remove the product from the production line, the three-color indicator light will be deactivated and the production line will continue to work to perform the tightening of the next new component.

[0095] It is obvious to those skilled in the art that the modules or steps of the present invention described above can be implemented using general-purpose control devices. They can be centralized on a single control device or distributed across a network of multiple control devices. Optionally, they can be implemented using program code executable by the control device, thereby storing them in a storage device for execution by the control device. Furthermore, in some cases, the steps shown or described can be performed in a different order than those described herein, or they can be fabricated as separate integrated circuit modules, or multiple modules or steps can be fabricated as a single integrated circuit module. Thus, the present invention is not limited to any particular hardware and software combination.

[0096] The above disclosures are merely one or more preferred embodiments of the present invention, intended to help understand the inventive concept of the technical solution, and are not intended to limit the present invention in any other way. Any other equivalent or conventional substitution schemes made by those skilled in the art based on the features defined by the present invention shall still fall within the scope of the present invention.

Claims

1. A method for fastening and controlling air conditioning components, characterized in that, Includes the following steps: The message queue receives the torque standard information of the model to be tightened and the torque parameters obtained by scanning the torque asset code, respectively. Torque parameters are verified using torque standard information to generate verification information and determine the mapping relationship between torque parameters and components. This process involves using a PDA to scan torque asset codes and obtaining torque parameters from the coded information recorded in the torque asset codes. The torque parameters are then transmitted to the torque verification module via a message queue and verified according to the torque standard information. Generate verification information, which includes the model code of the corresponding model, the maximum torque, the minimum torque, the torque asset code, and the mapping relationship between the corresponding parts; The verification information is transmitted to the torque start module; The barcode identifier of the component is obtained and the torque start module is input through the message queue to start the electric screwdriver. The component and the torque parameters that establish the mapping relationship are determined according to the barcode identifier so that the electric screwdriver performs the corresponding tightening operation and outputs the torque execution result.

2. The fastening control method for an air conditioning component according to claim 1, characterized in that, It also includes the following steps: The torque standard information is received via a message queue; The torque execution result is determined based on the torque standard information, including: If the result is qualified, return to the step of obtaining the barcode identification of the new component to perform the new component fastening operation; If the result is unqualified, the production line will stop working and a pop-up window will appear, waiting for a choice: if the option to re-execute is selected, the electric screwdriver will restart with the current torque parameters to perform the corresponding tightening operation; if the option to remove from the line is selected, the production line will continue working to perform the tightening of the next new component.

3. A method for fastening and controlling air conditioning components according to claim 1 or 2, characterized in that, The step of receiving torque standard information for the model to be tightened via message queues includes: When using it for the first time or when the production line is switching models, enter the model code of the corresponding model in the MES system; Based on the model code, obtain the torque standard information of the corresponding component of the model. The torque standard information includes: the model code of the corresponding model, the maximum torque value, and the minimum torque value. The MES system transmits the torque standard information to the torque verification module and the torque result determination module through a message queue.

4. The fastening control method for an air conditioning component according to claim 1, characterized in that: The fastening control method further includes: Use a PDA to scan the barcode markings on the parts to be fastened; The data is transmitted to the torque start module via a message queue. The torque parameters are matched according to the corresponding mapping relationship based on the barcode identifier; The electric screwdriver is controlled to tighten the parts to be tightened according to the torque parameters.

5. The fastening control method for an air conditioning component according to claim 2, characterized in that, The fastening control method further includes: the torque result determination module determines the torque execution result based on the torque standard information, and the judgment result data of each qualified and / or unqualified result is automatically saved locally and then transmitted to the MES system through a real-time message queue.

6. A fastening control system for air conditioning components, characterized in that, A method for performing a fastening control of an air conditioning component as described in any one of claims 1-5, comprising: The MES system is used to input the model code of the corresponding machine to obtain the torque standard information of the corresponding parts of the machine, and transmit it to the torque verification module and the torque result determination module through the message queue; The torque verification module is used to receive torque parameters obtained by scanning with a PDA and verify the torque parameters with torque standard information to generate verification information; The torque start module is used to receive the barcode identification of the component scanned by the PDA to start the electric screwdriver to perform a tightening operation on the component according to the torque parameters, and output the torque execution result.

7. A fastening control system for air conditioning components according to claim 6, characterized in that, Also includes: The torque result determination module is used to determine the torque execution result based on the torque standard information to obtain a qualified or unqualified result. If the determination result is qualified, it returns to the step of obtaining the barcode identification of the new component to perform the new component fastening operation. If the result is unqualified, the production line will be stopped and a pop-up window will appear, waiting for a choice: if the option to re-execute is selected, the electric screwdriver will be restarted with the current torque parameters to perform the corresponding tightening operation; if the option to remove from the line is selected, the production line will continue to work and perform the tightening of the next new component.

8. A fastening control system for air conditioning components according to claim 7, characterized in that, Also includes: The torque control module is used to control the three-color light alarm when the output of the torque result judgment module is a non-conforming judgment result, and to send a signal to the PLC through the IO port to control the production line to stop working. It is also used to receive user selections based on pop-up windows, control the three-color lights to reset, and control the electric screwdriver to perform a tightening operation again, or send signals to the PLC via IO ports to control the production line to continue working.

9. A fastening control device for an air conditioning component, comprising a memory and a processor, characterized in that: The processor executes a fastening control method for an air conditioning component as described in any one of claims 1-5 by calling a control program stored in the memory.