CN111380148A - Multi-split debugging method - Google Patents

Abstract

The application provides a multi-split debugging method, which comprises the following steps: firstly, acquiring a current debugging result of a unit, and determining whether the current debugging result is in a healthy state or not based on a preset health parameter table; secondly, if the current debugging result is determined to be in a healthy state, acquiring an evaluation instruction input by a user, and responding to the evaluation instruction to acquire a current boot code randomly sent by a server; and finally, acquiring a boot code verification instruction input by a user based on the current boot code, responding to the boot code verification instruction and determining whether the boot code input by the user is correct or not so as to determine whether the unit is booted successfully or not. By adopting the method, the debugging of the user control unit is realized, so that the debugging quality is improved, and the hidden trouble is reduced; meanwhile, the interactive experience of the user can be improved.

Description

Multi-split debugging method

Technical Field

The application relates to the technical field of multi-split air conditioners, in particular to a multi-split air conditioner debugging method.

Background

With the continuous development of economy, the requirements of people on the living environment are continuously improved. The multi-split central air conditioner is widely applied to the application scenes of multi-split units such as civil houses, commercial buildings, high-grade office buildings, multifunctional comprehensive buildings, public places and the like. The multi-split central air conditioner is a type of household central air conditioner, commonly called as 'one split multiple air conditioner', and refers to that one outdoor unit is connected with two or more indoor units through a pipe. The primary refrigerant air conditioning system adopts an air cooling heat exchange mode at the outdoor side and a direct evaporation heat exchange mode at the indoor side.

Due to the fact that a refrigerant system and a communication network of the multi-split air conditioner are complex, a professional installer needs to debug the multi-split air conditioner in an engineering mode after installation, and the multi-split air conditioner can be delivered to a user after debugging ensures that the unit runs without errors. At present, an installer can debug the multi-connected unit after installing the unit to detect whether each parameter of the unit is normal.

However, when some faults occur in the debugging stage, part of installers cannot feed back the faults to the client for maintenance in order to complete the task quickly, and the client is directly allowed to be started for normal use, so that the debugging of the multi-connected unit is uncontrollable, and the problem of low debugging quality exists.

Disclosure of Invention

Therefore, the multi-connected unit debugging method is needed to solve the problems that when the existing multi-connected unit is debugged, an installer cannot feed back a fault to a client for maintenance in order to quickly complete a task, and the client is directly allowed to be started for normal use, so that the debugging of the multi-connected unit is uncontrollable, and the debugging quality is low.

A multi-split commissioning method, comprising:

acquiring a current debugging result of the unit, and determining whether the current debugging result is in a healthy state or not based on a preset health parameter table;

if the current debugging result is determined to be in a healthy state, acquiring an evaluation instruction input by a user, and responding to the evaluation instruction to acquire a current boot code randomly sent by a server;

and acquiring a boot code verification instruction input by a user based on the current boot code, responding to the boot code verification instruction and determining whether the boot code input by the user is correct or not so as to determine whether the unit is booted successfully or not.

In one embodiment, the step of obtaining a boot code verification instruction input by a user based on the current boot code, responding to the boot code verification instruction and determining whether the boot code input by the user is correct to determine whether the unit is booted successfully comprises:

acquiring a boot code verification instruction input by a user based on the current boot code;

responding to the boot code verification instruction to obtain the boot code input by the user, and judging whether the boot code input by the user is the same as the current boot code;

if the starting code input by the user is the same as the current starting code, determining that the unit is started successfully;

and if the boot code input by the user is different from the current boot code, re-acquiring the boot code verification instruction input by the user based on the current boot code.

In one embodiment, after the step of determining that the unit is booted successfully if the boot code input by the user is the same as the current boot code, the method further includes:

and if the boot code input by the user is different from the current boot code, re-acquiring the current boot code randomly sent by the server.

In one embodiment, the step of obtaining a current debugging result of the unit and determining whether the current debugging result is in a healthy state based on a preset health parameter table includes:

acquiring a current debugging result of the unit, and judging whether a unit parameter value corresponding to the current debugging result is in a value range corresponding to the preset health parameter table;

if the unit parameter value corresponding to the current debugging result is judged to be in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a health state;

and if the unit parameter value corresponding to the current debugging result is judged not to be in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a non-health state, and debugging the unit again at the moment.

In one embodiment, the current boot code is at least four character combinations of a plurality of keys randomly arranged on the line controller.

In one embodiment, before the step of obtaining a current debugging result of the unit and determining whether the current debugging result is in a healthy state based on a preset health parameter table, the method further includes:

and debugging the unit according to a preset debugging flow, sending the unit parameters obtained in the debugging process to a server, and responding the unit parameters and feeding back the current debugging result by the server.

In one embodiment, before the steps of obtaining an evaluation instruction input by a user and obtaining a current boot code randomly sent by a server in response to the evaluation instruction if it is determined that the current debugging result is in a healthy state, the method further includes:

and if the current debugging result is determined to be in a healthy state, acquiring user data information, wherein the user data information comprises the mobile phone number currently used by the user and the fine address information of the user.

A multi-split commissioning method, comprising:

acquiring unit parameters of a unit during debugging, and decrypting the unit parameters to obtain unit parameter values;

generating a current debugging result based on the unit parameter value, and sending the current debugging result to a terminal;

if the terminal determines that the current debugging result is in a healthy state, a starting code request instruction sent by the terminal is obtained, and a current starting code is randomly generated in response to the starting code request instruction;

and sending the current starting code to the terminal so that the terminal verifies whether the unit is started successfully.

In one embodiment, after the steps of obtaining a boot code request instruction sent by the terminal and randomly generating a current boot code in response to the boot code request instruction if the terminal determines that the current debugging result is in a healthy state, the method further includes:

and if the terminal determines that the current debugging result is in an unhealthy state, re-acquiring the unit parameters of the unit during debugging.

In one embodiment, after the steps of obtaining a boot code request instruction sent by the terminal and randomly generating a current boot code in response to the boot code request instruction if the terminal determines that the current debugging result is in a healthy state, the method further includes:

and acquiring user data information input by the terminal, wherein the user data information comprises a mobile phone number currently used by a user and fine address information of the user.

Compared with the prior art, the multi-split debugging method comprises the steps of firstly, obtaining a current debugging result of a unit, and determining whether the current debugging result is in a healthy state or not based on a preset health parameter table; secondly, if the current debugging result is determined to be in a healthy state, acquiring an evaluation instruction input by a user, and responding to the evaluation instruction to acquire a current boot code randomly sent by a server; and finally, acquiring a boot code verification instruction input by a user based on the current boot code, responding to the boot code verification instruction and determining whether the boot code input by the user is correct or not so as to determine whether the unit is booted successfully or not. By adopting the method, the debugging of the user control unit is realized, so that the debugging quality is improved, and the hidden trouble is reduced; meanwhile, the interactive experience of the user can be improved.

Drawings

Fig. 1 is a flowchart of a multi-split debugging method according to an embodiment of the present application;

fig. 2 is a flowchart illustrating that a boot code verification instruction input by a user is obtained based on the current boot code, and whether the boot code input by the user is correct is determined in response to the boot code verification instruction to determine whether the unit is booted successfully according to an embodiment of the present application;

fig. 3 is a flowchart for acquiring a current debugging result of a unit and determining whether the current debugging result is in a healthy state based on a preset health parameter table according to an embodiment of the present application;

fig. 4 is a flowchart of a multi-split debugging method according to another embodiment of the present application.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present application more comprehensible, embodiments accompanying the present application are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. This application is capable of embodiments in many different forms than those described herein and those skilled in the art will be able to make similar modifications without departing from the spirit of the application and it is therefore not intended to be limited to the embodiments disclosed below.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1, an embodiment of the present application provides a multi-split commissioning method, including:

s102: the method comprises the steps of obtaining a current debugging result of the unit, and determining whether the current debugging result is in a healthy state or not based on a preset health parameter table.

In one embodiment, the current debugging result of the unit can be obtained through a terminal, and whether the current debugging result is in a healthy state or not is determined based on a preset health parameter table. In one embodiment, the preset health parameter table is a parameter table set in advance when the unit leaves a factory. Different sets correspond to different parameter tables. In one embodiment, the terminal may be a crew commissioning terminal. In one embodiment, the terminal may also be an intelligent terminal such as a mobile phone and a tablet.

In one embodiment, the current debugging result includes a unit parameter value of the unit in each operation mode. Specifically, the operation mode may include a cooling operation mode, a heating operation mode, a dehumidifying operation mode, a blowing operation mode, and the like. The unit parameters may include compressor shell top temperature, compressor discharge temperature, subcooler inlet/outlet temperature, subcooled liquid inlet/outlet temperature, and the like. In one embodiment, the health value corresponding to the same unit parameter may be different in different operation modes.

For example, when the unit is started to be debugged, the air-conditioning operation mode may be set as the cooling operation mode, the unit is kept operating for at least 4 hours, the unit parameter value corresponding to the cooling operation mode is recorded, and the unit parameter value is compared with the value corresponding to the preset health parameter table to obtain the debugging result of the cooling operation mode. And repeating other air conditioner operation modes (such as a heating operation mode, an air supply operation mode and the like), wherein the operation duration can be changed according to different modes, and finally, all unit debugging results are fed back to the terminal for the user to check and accept.

In an embodiment, after obtaining the current debugging result, the terminal may determine whether a unit parameter value corresponding to the current debugging result is within a value range corresponding to the preset health parameter table in different operation modes. And if the unit parameter values corresponding to the current debugging result in different operation modes are judged to be in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a health state. And if any one of the unit parameter values corresponding to the current debugging result in different operation modes is judged not to be in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a non-health state, and debugging the unit again at the moment.

S104: and if the current debugging result is determined to be in a healthy state, acquiring an evaluation instruction input by a user, and responding to the evaluation instruction to acquire the current boot code randomly sent by the server.

In one embodiment, if the terminal determines that the current debugging result is in a healthy state, an evaluation instruction input by a user is acquired, and a current boot code randomly sent by a server is acquired in response to the evaluation instruction. Specifically, when the terminal determines that the current debugging result is in a healthy state, the user can input the evaluation instruction through the terminal. The evaluation instruction may be that the debug acceptance is acceptable.

In one embodiment, after acquiring the evaluation instruction input by the user, the terminal may respond to the evaluation instruction and generate a boot code request instruction. And the terminal sends the starting code request instruction to a server, the server responds to the starting code request instruction and randomly generates a current starting code, and the current starting code is sent to the terminal. And the terminal executes the step S106 after acquiring the current boot code randomly sent by the server.

In one embodiment, the user can also enter the small program by scanning the two-dimensional code on the wire controller, and the evaluation instruction is input by the small program. Specifically, after entering the applet by scanning the two-dimensional code on the line controller, the user can authorize to log in the applet. After logging in the applet, the evaluation instructions may be entered on the applet. Meanwhile, the applet can acquire information such as the number and the detailed address of the current user mobile phone through authorized login, and accordingly data support is provided for services such as follow-up one-key fault dispatching. In one embodiment, after the user inputs the evaluation instruction on the applet, the applet may respond to the evaluation instruction and obtain the current boot code randomly sent by the server (the specific logic is the same as the logic for obtaining the current boot code by the terminal). By adopting the method, the interactive experience of the user can be improved.

S106: and acquiring a boot code verification instruction input by a user based on the current boot code, responding to the boot code verification instruction and determining whether the boot code input by the user is correct or not so as to determine whether the unit is booted successfully or not.

In one embodiment, the terminal obtains a boot code verification instruction input by a user based on the current boot code, responds to the boot code verification instruction and determines whether the boot code input by the user is correct, so as to determine whether the unit is booted successfully. Specifically, after the terminal acquires the current boot code randomly sent by the server, the user may sequentially input the corresponding boot codes on the line controller according to the current boot code acquired by the terminal, and click a confirmation key. At this time, the terminal can obtain the boot code verification instruction corresponding to the boot codes sequentially input by the user on the online controller, and simultaneously respond to the boot code verification instruction and determine whether the boot codes input by the user are correct or not.

And if the boot code input by the user is determined to be correct, the unit is booted successfully. If the starting code input by the user is determined to be incorrect, the unit is not started successfully, and the user can input the corresponding starting code again on the online controller at the moment. Or the terminal may re-execute step S106 until the unit is successfully powered on.

In one embodiment, the current boot code is at least four character combinations of a plurality of keys randomly arranged on the line controller. For example, the current boot code may be a combination of four characters, such as a temperature key, a mode key, etc., on the line controller.

By adopting the method, the user directly or indirectly participates in the health state of the control unit in the whole debugging and starting process, and the situation that the fault is hidden by an installer intentionally is avoided, so that the debugging quality is improved, and the fault hidden danger is reduced. Meanwhile, the method can improve the interaction experience of the user.

Referring to fig. 2, in an embodiment, the steps of obtaining a boot code verification instruction input by a user based on the current boot code, responding to the boot code verification instruction and determining whether the boot code input by the user is correct to determine whether the unit is booted successfully include:

s202: acquiring a boot code verification instruction input by a user based on the current boot code;

s204: responding to the boot code verification instruction to obtain the boot code input by the user, and judging whether the boot code input by the user is the same as the current boot code;

s206: if the starting code input by the user is the same as the current starting code, determining that the unit is started successfully;

s208: and if the boot code input by the user is different from the current boot code, re-acquiring the boot code verification instruction input by the user based on the current boot code.

In one embodiment, the boot code verification instruction input by the user can be obtained by the terminal based on the current boot code. Specifically, the user can sequentially input the corresponding boot codes on the line controller according to the current boot code acquired by the terminal, and click the enter key. At this time, the terminal can obtain the boot code verification instruction corresponding to the boot codes sequentially input by the user on the online controller, and simultaneously respond to the boot code verification instruction and determine whether the boot codes input by the user are the same as the current boot codes. If the two are the same, the starting code input by the user is correct, and the unit can be determined to be started successfully at the moment; if the two are different, the starting code input by the user is wrong, and the unit starting is determined to be unsuccessful.

In an embodiment, if it is determined that the boot code input by the user is not the same as the current boot code, the terminal may further re-acquire the current boot code randomly sent by the server, and re-execute steps S202 to S208. By the method, a user can directly or indirectly participate in the health state of the control unit in the whole debugging and starting process, so that the situation that an installer intentionally hides a fault can be avoided, the debugging quality is improved, and the hidden trouble is reduced.

Referring to fig. 3, in an embodiment, the step of obtaining a current debugging result of the unit and determining whether the current debugging result is in a healthy state based on a preset health parameter table includes:

s302: acquiring a current debugging result of the unit, and judging whether a unit parameter value corresponding to the current debugging result is in a value range corresponding to the preset health parameter table;

s304: if the unit parameter value corresponding to the current debugging result is judged to be in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a health state;

s306: and if the unit parameter value corresponding to the current debugging result is judged not to be in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a non-health state, and debugging the unit again at the moment.

In one embodiment, the current debugging result of the unit can be obtained through the terminal, and whether the unit parameter value corresponding to the current debugging result is in the value range corresponding to the preset health parameter table or not is judged. Specifically, the current debugging result of the unit sent by the server can be obtained through the terminal. And the terminal can be used for judging whether the unit parameter value corresponding to the current debugging result is in the value range corresponding to the preset health parameter table in different operation modes.

And if the unit parameter values corresponding to the current debugging result in different operation modes are judged to be in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a health state. And if any one of the unit parameter values corresponding to the current debugging result in different operation modes is judged not to be in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a non-health state, and debugging the unit again at the moment.

That is, in different operation modes, if any one of the unit parameter values corresponding to the current debugging result is not within the value range corresponding to the preset health parameter table, it can be determined that the current debugging result is in a non-health state; and only when the unit parameter values corresponding to the current debugging result are all in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a health state, namely, the step S104 can be executed at the moment.

In one embodiment, before the step of obtaining a current debugging result of the unit and determining whether the current debugging result is in a healthy state based on a preset health parameter table, the method further includes: and debugging the unit according to a preset debugging flow, sending the unit parameters obtained in the debugging process to a server, and responding the unit parameters and feeding back the current debugging result by the server.

In one embodiment, the preset debugging process may include: the method comprises the steps that the unit is debugged in different operation modes (a refrigeration operation mode, a heating operation mode, a dehumidification operation mode, an air supply operation mode and the like), unit parameters of the unit in the different operation modes are obtained respectively and are sent to a server through a Data Transfer Unit (DTU), and the server decrypts the unit parameters according to a preset algorithm after obtaining the unit parameters, so that the unit parameter values of the unit in the different operation modes are obtained, the current debugging result is generated, and the current debugging result is fed back to the terminal.

In an embodiment, before the step of acquiring an evaluation instruction input by a user and acquiring a current boot code randomly sent by a server in response to the evaluation instruction if it is determined that the current debugging result is in a healthy state, the method further includes: and if the current debugging result is determined to be in a healthy state, acquiring user data information, wherein the user data information comprises the mobile phone number currently used by the user and the fine address information of the user. By collecting the user data information in the mode, the data support is provided for subsequently providing accurate and efficient service.

Referring to fig. 4, an embodiment of the present application provides a multi-split commissioning method, including:

s402: the method comprises the steps of obtaining unit parameters of a unit during debugging, and decrypting the unit parameters to obtain unit parameter values.

In one embodiment, the server may obtain the unit parameter of the unit during debugging through the DTU, and decrypt the unit parameter to obtain a unit parameter value. In one embodiment, the server may obtain the unit parameters in different operation modes of the unit during debugging through the DTU, and decrypt the obtained unit parameters according to a preset algorithm to obtain the unit parameter values. In an embodiment, the preset algorithm may adopt a conventional decryption algorithm, as long as it is ensured that the server can obtain the unit parameter value based on the unit parameter. In one embodiment, the unit parameters may include compressor shell top temperature, compressor discharge temperature, subcooler inlet/outlet temperature, subcooled liquid inlet/outlet temperature, and the like.

S404: and generating a current debugging result based on the unit parameter value, and sending the current debugging result to a terminal.

In one embodiment, after obtaining the unit parameter values, the server may generate a current debugging result based on the unit parameter values, and send the current debugging result to the terminal. Specifically, the server may send the current debugging result to the terminal in a form of a report through a wireless network, so that the terminal may perform steps S102 to S106.

S406: and if the terminal determines that the current debugging result is in a healthy state, acquiring a starting code request instruction sent by the terminal, and responding to the starting code request instruction to randomly generate a current starting code.

In one embodiment, if the terminal determines that the current debugging result is in a healthy state, the server obtains a boot code request instruction sent by the terminal, and randomly generates a current boot code in response to the evaluation instruction. Specifically, the server may obtain a boot code request instruction sent by the terminal, decrypt the boot code request instruction according to a preset decryption algorithm, and randomly generate a current boot code based on the decrypted boot code request instruction. In one embodiment, the preset instruction decryption algorithm may adopt a conventional decryption algorithm, as long as it is ensured that the server can decrypt the boot code request instruction and generate the corresponding current boot code.

S408: and sending the current starting code to the terminal so that the terminal verifies whether the unit is started successfully.

In one embodiment, after the server generates the current boot code, the server may send the current boot code to the terminal, so that the terminal verifies whether the unit is booted successfully. In an embodiment, the method for the terminal to verify whether the unit is successfully started may be the method described in the above embodiment, which is not described herein again.

In an embodiment, the server may encrypt the current boot code according to a preset encryption algorithm and then send the current boot code to the terminal, and the terminal may decrypt the current boot code according to a corresponding preset decryption algorithm after obtaining the encrypted current boot code, so as to obtain the current boot code, and verify whether the unit is booted successfully based on the current boot code. By adopting the method, the interactive experience of the user can be improved.

In one embodiment, after the steps of obtaining a boot code request instruction sent by the terminal and randomly generating a current boot code in response to the boot code request instruction if the terminal determines that the current debugging result is in a healthy state, the method further includes: and if the terminal determines that the current debugging result is in an unhealthy state, re-acquiring the unit parameters of the unit during debugging. That is, when the terminal determines that the current debugging result is in the unhealthy state, the server needs to re-acquire the unit parameters of the unit during debugging, and re-execute steps S402 to S408.

In one embodiment, after the steps of obtaining a boot code request instruction sent by the terminal and randomly generating a current boot code in response to the boot code request instruction if the terminal determines that the current debugging result is in a healthy state, the method further includes: and acquiring user data information input by the terminal, wherein the user data information comprises a mobile phone number currently used by a user and fine address information of the user. In one embodiment, the server can also obtain user data information input by the terminal, so as to provide data support for services such as follow-up fault one-key dispatch and the like.

In summary, the present application first obtains a current debugging result of the unit, and determines whether the current debugging result is in a healthy state based on a preset health parameter table; secondly, if the current debugging result is determined to be in a healthy state, acquiring an evaluation instruction input by a user, and responding to the evaluation instruction to acquire a current boot code randomly sent by a server; and finally, acquiring a boot code verification instruction input by a user based on the current boot code, responding to the boot code verification instruction and determining whether the boot code input by the user is correct or not so as to determine whether the unit is booted successfully or not. By adopting the method, the debugging of the user control unit is realized, so that the debugging quality is improved, and the hidden trouble is reduced; meanwhile, the interactive experience of the user can be improved.

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

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

Claims (10)

1. A multi-split debugging method is characterized by comprising the following steps:

acquiring a current debugging result of the unit, and determining whether the current debugging result is in a healthy state or not based on a preset health parameter table;

if the current debugging result is determined to be in a healthy state, acquiring an evaluation instruction input by a user, and responding to the evaluation instruction to acquire a current boot code randomly sent by a server;

and acquiring a boot code verification instruction input by a user based on the current boot code, responding to the boot code verification instruction and determining whether the boot code input by the user is correct or not so as to determine whether the unit is booted successfully or not.

2. The multi-split debugging method as claimed in claim 1, wherein the step of obtaining a boot code verification instruction input by a user based on the current boot code, responding to the boot code verification instruction and determining whether the boot code input by the user is correct to determine whether the unit is booted successfully comprises:

acquiring a boot code verification instruction input by a user based on the current boot code;

responding to the boot code verification instruction to obtain the boot code input by the user, and judging whether the boot code input by the user is the same as the current boot code;

if the starting code input by the user is the same as the current starting code, determining that the unit is started successfully;

and if the boot code input by the user is different from the current boot code, re-acquiring the boot code verification instruction input by the user based on the current boot code.

3. The multi-split commissioning method as recited in claim 2, wherein after the step of determining that the unit is successfully booted if the boot code entered by the user is the same as the current boot code, said method further comprises:

and if the boot code input by the user is different from the current boot code, re-acquiring the current boot code randomly sent by the server.

4. The multi-split air conditioner debugging method of claim 1, wherein the step of obtaining a current debugging result of the unit and determining whether the current debugging result is in a healthy state based on a preset health parameter table comprises:

acquiring a current debugging result of the unit, and judging whether a unit parameter value corresponding to the current debugging result is in a value range corresponding to the preset health parameter table;

if the unit parameter value corresponding to the current debugging result is judged to be in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a health state;

and if the unit parameter value corresponding to the current debugging result is judged not to be in the value range corresponding to the preset health parameter table, determining that the current debugging result is in a non-health state, and debugging the unit again at the moment.

5. The multi-online debugging method as claimed in any one of claims 1 to 4, wherein the current boot code is at least four character combinations of a plurality of keys randomly arranged on the line controller.

6. The multi-split air conditioner debugging method of claim 1, wherein before the step of obtaining a current debugging result of the unit and determining whether the current debugging result is in a healthy state based on a preset health parameter table, the method further comprises:

and debugging the unit according to a preset debugging flow, sending the unit parameters obtained in the debugging process to a server, and responding the unit parameters and feeding back the current debugging result by the server.

7. The multi-split debugging method according to claim 1, wherein before the step of obtaining the evaluation instruction input by the user and obtaining the current boot code randomly sent by the server in response to the evaluation instruction if it is determined that the current debugging result is in a healthy state, the method further comprises:

and if the current debugging result is determined to be in a healthy state, acquiring user data information, wherein the user data information comprises the mobile phone number currently used by the user and the fine address information of the user.

8. A multi-split debugging method is characterized by comprising the following steps:

acquiring unit parameters of a unit during debugging, and decrypting the unit parameters to obtain unit parameter values;

generating a current debugging result based on the unit parameter value, and sending the current debugging result to a terminal;

if the terminal determines that the current debugging result is in a healthy state, a starting code request instruction sent by the terminal is obtained, and a current starting code is randomly generated in response to the starting code request instruction;

and sending the current starting code to the terminal so that the terminal verifies whether the unit is started successfully.

9. The multi-online debugging method according to claim 8, wherein after the steps of obtaining a boot code request instruction sent by the terminal and randomly generating a current boot code in response to the boot code request instruction if the terminal determines that the current debugging result is in a healthy state, the method further comprises:

and if the terminal determines that the current debugging result is in an unhealthy state, re-acquiring the unit parameters of the unit during debugging.

10. The multi-online debugging method according to claim 8, wherein after the steps of obtaining a boot code request instruction sent by the terminal and randomly generating a current boot code in response to the boot code request instruction if the terminal determines that the current debugging result is in a healthy state, the method further comprises:

and acquiring user data information input by the terminal, wherein the user data information comprises a mobile phone number currently used by a user and fine address information of the user.

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