CN111735176A - Debugging terminal based on image recognition and debugging method of electrical equipment - Google Patents

Abstract

The invention belongs to the field of debugging terminals, and particularly relates to a debugging method of a debugging terminal and electric equipment based on image recognition, which comprises the following steps: the storage module is used for recording the preset image symbols and the debugging interface associated with the preset image symbols; and the preset image symbols are image symbols formed after the corresponding combination keys are pressed. The perception module is used for perceiving the image symbols formed after the different combination keys are pressed; the matching module is used for acquiring the image symbol sensed by the sensing module and matching the image symbol with a preset image symbol to find the preset image symbol matched with the image symbol; and the output module is used for outputting the debugging interface corresponding to the preset image symbol. The invention enters the corresponding debugging interface by pressing the combination key with the same track as the preset image symbol without memorizing a plurality of keys entering different debugging interfaces, thereby improving the debugging efficiency of the electrical equipment.

Description

Debugging terminal based on image recognition and debugging method of electrical equipment

Technical Field

The invention belongs to the field of debugging terminals, and particularly relates to a debugging terminal based on image recognition and a debugging method of electrical equipment.

Background

Large-scale electrical equipment such as a multi-split air conditioner is widely applied to engineering and various occasions, so that the installation and use conditions of the large-scale central air conditioning engineering and the small-scale household multi-split electrical equipment are complicated and changeable. Therefore, when the electrical equipment has problems, different operation parameters of the electrical equipment need to be debugged. In the existing debugging method, a group of combination keys is often pressed by a debugging terminal to enter a corresponding debugging interface, but different debugging interfaces correspond to different combination keys, each combination key has different key compositions and different key numbers, so that a debugging person is required to fully know the different combination keys and the corresponding debugging interfaces, the debugging difficulty of the debugging person in debugging the electrical equipment is undoubtedly increased, and the working efficiency is reduced.

The present invention has been made in view of the above circumstances.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a debugging terminal and a method for debugging electric equipment by adopting the debugging terminal, wherein the corresponding debugging interface is accessed by pressing a plurality of keys with the same track with the preset image symbols, and the plurality of keys accessed to different debugging interfaces are not required to be memorized, so that the debugging efficiency of the electric equipment is improved.

In order to solve the technical problem, the invention discloses a debugging terminal based on image recognition, which comprises

The storage module is used for recording the preset image symbols and the debugging interface associated with the preset image symbols;

and the preset image symbols are image symbols formed after the corresponding combination keys are pressed down.

The perception module is used for perceiving the image symbols formed after the different combination keys are pressed;

the matching module is used for acquiring the image symbol sensed by the sensing module and matching the image symbol with a preset image symbol to find the preset image symbol matched with the image symbol;

and the output module is used for outputting the debugging interface corresponding to the preset image symbol.

Further optionally, the character symbol is one of a number symbol, an alphabet symbol or a graphic symbol.

Further optionally, the combination key includes a reference key, and the combination key is configured by taking the reference key as a start key and arranging a predetermined number of keys on the debugging terminal according to a track of predetermined character symbols.

Further optionally, the debugging terminal has a plurality of debugging interfaces, different debugging interfaces correspond to different image symbols, different image symbols correspond to different combination keys, and reference keys of the combination keys entering different debugging interfaces are the same or different.

Further optionally, the combination key is formed by arranging a plurality of keys with the same color on the debugging terminal according to a track of a predetermined image symbol.

Further optionally, the keys comprising different combination keys are different in color.

Further optionally, the corresponding debugging interface is entered after the combination key is continuously pressed for the set number of times through the debugging terminal.

Further optionally, the corresponding debugging interface is entered after the combination key is continuously pressed for the set number of times within the set time through the debugging terminal.

Further optionally, the key is one of a mechanical key, a touch key, and a virtual key.

The invention also provides a method for debugging the electric equipment by adopting the debugging terminal, the electric equipment comprises a plurality of operation parameters, each operation parameter corresponds to a debugging interface of the debugging terminal, each debugging interface corresponds to a preset image symbol, and the debugging method comprises the following steps:

determining operating parameters needing debugging;

determining a debugging interface for debugging the operation parameters;

determining a preset image symbol corresponding to the debugging interface;

pressing a combination key corresponding to the predetermined character symbol;

and entering a debugging interface corresponding to the preset image symbol.

Further alternatively, the presses of the combination keys may be pressed in any order.

After adopting the technical scheme, compared with the prior art, the invention has the following beneficial effects: the invention enters the corresponding debugging interface by pressing the plurality of keys with the same track as the preset image symbols without memorizing the plurality of keys entering different debugging interfaces, thereby reducing the difficulty of entering the debugging interface and improving the debugging efficiency of the electrical equipment.

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention, are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention without limiting the invention to the right. It is obvious that the drawings in the following description are only some embodiments, and that for a person skilled in the art, other drawings can be derived from them without inventive effort. In the drawings:

FIG. 1: the method is an arrangement mode of different combined keys on the debugging terminal of the embodiment;

FIG. 2: the other arrangement mode of different combination keys on the debugging terminal of the embodiment is shown;

FIG. 3: the debugging flow chart of the electrical equipment is shown in the embodiment of the invention.

It should be noted that the drawings and the description are not intended to limit the scope of the inventive concept in any way, but to illustrate it by a person skilled in the art with reference to specific embodiments.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and the following embodiments are used for illustrating the present invention and are not intended to limit the scope of the present invention.

In the description of the present invention, it should be noted that the terms "inside", "outside", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, which are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and operate, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," "contacting," and "communicating" are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The embodiment provides a debugging terminal based on image recognition, which comprises a storage module, a plurality of combination keys, a sensing module, a matching module and an output module. The preset image symbol and a debugging interface associated with the preset image symbol are recorded in the storage module; the debugging terminal is provided with a plurality of combination keys, different combination keys correspond to different debugging interfaces, and the preset image symbol is an image symbol formed after the corresponding combination key is pressed; after debugging personnel press different combination keys through a debugging terminal, the perception module perceives the image symbols formed after the different combination keys are pressed; the matching module acquires the image symbol sensed by the sensing module and matches the image symbol with a preset image symbol to find the preset image symbol matched with the image symbol; the output module outputs a debugging interface corresponding to the preset image symbol. Preferably, the character symbol may be selected from one of a number symbol, an alphabet symbol or a graphic symbol. Preferably, the key constituting the combination key is one of a mechanical key, a touch key, and a virtual key.

Taking the debugging of the air conditioning unit as an example, as shown in fig. 1 and fig. 2, the operation parameter of the air conditioner includes at least one of a compressor operation frequency coefficient, a compressor up-down rate coefficient, a damper coefficient, and an electronic expansion valve control coefficient. When the operation parameters are debugged through the debugging terminal, each operation parameter corresponds to a debugging interface, the preset image symbol entering the debugging interface of the compressor frequency coefficient is set to be F, the preset image symbol entering the debugging interface of the compressor frequency-up and frequency-down rate coefficient is set to be V, the preset image symbol entering the debugging interface of the windshield coefficient is set to be R, the preset image symbol entering the debugging interface of the electronic valve control coefficient is set to be P, and the storage module stores the preset image symbols associated with different debugging interfaces. Different combination keys correspond to different debugging interfaces, for example: the combined key corresponding to the debugging interface of the compressor frequency coefficient is a first combined key (such as 1+2+3+4+5), and when the keys of the first combined key are pressed simultaneously or sequentially, the formed image symbol is a preset image symbol F related to the compressor frequency coefficient.

The combined key corresponding to the debugging interface of the up-down frequency rate coefficient of the compressor is a second combined key (such as 1+6+7), and when the keys of the second combined key are pressed simultaneously or sequentially, the formed image symbol is a preset image symbol V related to the up-down frequency rate coefficient of the compressor. When the debugging personnel presses different combination keys, the sensing module senses the image symbol formed by the pressed combination key, the matching module matches the image symbol formed by the pressed combination key with a preset image symbol (F/V/R/P) to find out the preset image symbol matched with the image symbol, and if the matching is successful, the output module outputs a debugging interface corresponding to the preset image symbol. For example, when the user presses the 1+2+3+4+5 keys, the character symbols formed by the keys are just the same as the predetermined character symbol F, the debugging terminal outputs the compressor frequency coefficient debugging interface corresponding to F, and the debugging personnel debugs the compressor frequency coefficient through the debugging keys (such as the left and right keys or the up and down keys) on the debugging terminal.

Therefore, by adopting the debugging terminal of the embodiment, a debugging person does not need to memorize the keys entering the debugging interface, only needs to record the preset image symbols corresponding to the debugging interface, and can enter the debugging interface by pressing the corresponding keys according to the track of the preset image symbols, thereby reducing the entering difficulty of the debugging interface and improving the debugging efficiency.

One way of implementation is that, as shown in fig. 1, the combination key includes a reference key, and the combination key is configured by using the reference key as a start key and arranging a predetermined number of keys on the debugging terminal according to a track of predetermined character symbols.

In order to further locate the position of the combination key on the debugging terminal, in this embodiment, a reference key is set as a start key of the combination key, and when a debugging person inputs the combination key, the debugging person sequentially presses or simultaneously presses a certain number of keys with the reference key as a start point according to a track of a predetermined image symbol. For example, the combination key entering the compressor frequency coefficient debugging interface is 1+2+3+4+5, and if a 1-bit reference key is designated, the key 1 is used as the start key, and the remaining 4 keys are pressed sequentially or simultaneously according to the predetermined image trajectory F of the compressor frequency coefficient. The reference key is designated when the combination key is customized. The keys that are used as reference keys are preferably highlighted with a distinctive color (e.g., red) or symbol to facilitate quick positioning by the commissioning personnel.

On the basis of the above scheme, further optionally, the debugging terminal has a plurality of debugging interfaces, different debugging interfaces correspond to different image symbols, different image symbols correspond to different combination keys, and reference keys of the combination keys entering different debugging interfaces are the same or different. In order to avoid that the debugger remembers different reference keys, it is preferred that the reference keys of different combination keys are the same. For example, if the combination key entering the compressor frequency coefficient debugging interface is 1+2+3+4+5, and the combination key entering the compressor frequency rate increasing and decreasing coefficient is 1+6+7, it can be specified that key 1 is the reference key of the two combination keys at the same time.

Another practical way is that, as shown in fig. 2, the combination key is a plurality of keys with the same color arranged on the debugging terminal according to the track of the predetermined image symbol. For example, the combination keys 1+2+3+4+5 corresponding to the frequency coefficient of the compressor are arranged according to the same color and the track of the F, so that debugging personnel can find the corresponding combination keys intuitively and quickly, and the debugging efficiency is greatly improved.

On the basis of the above scheme, further optionally, the keys composing different combination keys are different in color. For example, the combination keys 1+2+3+4+5 corresponding to the frequency coefficient of the compressor are arranged in black according to the track of F, and the combination keys of the frequency up-down rate coefficient of the compressor are

The keys are arranged according to the V track in white, so that debugging personnel can be helped to quickly distinguish different combination keys, and the error probability when the combination keys are input is reduced.

Further optionally, the corresponding debugging interface is entered after the combination key is continuously pressed for the set number of times through the debugging terminal. Preferably, the corresponding debugging interface is entered after the debugging terminal continuously presses the combination key for the set times within the set time. The setting can avoid the misoperation of the user from causing the error entering of the parameter adjusting interface, thereby causing the error adjustment of the operating parameters of the electrical equipment and adjusting the normal machine to be a fault.

The invention also provides a method for debugging the electric appliance by adopting the debugging terminal, and the electric appliance of the embodiment can be an air conditioner, a washing machine, a refrigerator, a water heater or a dish washing machine and the like, and comprises both household electric appliances and public electric appliances. The electrical equipment comprises a plurality of operation parameters, each operation parameter corresponds to a debugging interface of the debugging terminal, each debugging interface corresponds to a preset image symbol, and the debugging method comprises the following steps:

s1, acquiring abnormal state information of the electrical equipment; determining whether the operation parameters of the electrical equipment need to be debugged according to the abnormal state information; if judging that the operation parameters of the electrical equipment need to be debugged, determining the operation parameters needing to be debugged;

s2, determining a debugging interface for debugging the operation parameters;

s3, determining the preset image symbol corresponding to the debugging interface;

s4, pressing the combined key corresponding to the preset image symbol;

and S5, entering a debugging interface corresponding to the preset image symbol.

The method specifically comprises the following steps:

1. when a user feels that the air conditioner is not good in use experience, an engineer eliminates abnormal conditions according to the actual running state of the electrical equipment fed back by the user, and determines whether debugging is needed or not according to the abnormal conditions. In the process of judging the abnormality of the electrical equipment, an engineer needs to analyze according to actual abnormal conditions, can judge on the premise of having a certain professional level, and can judge after performing technical analysis on the abnormal conditions if the engineer cannot judge on site.

2. And if the operating parameters of the electrical equipment need to be adjusted are judged, determining the coefficient of a certain operating parameter needing to be adjusted through abnormal analysis. The abnormity analysis is to analyze and judge based on the fault code or the abnormal phenomenon displayed by the electrical equipment, and analyze from a professional perspective to obtain the coefficient of the operating parameter needing to be adjusted.

3. And an engineer adjusts the operating parameters of the electrical equipment through the debugging terminal. The debugging terminal can be selected from at least one of a remote controller, a manual operator and an intelligent terminal. The debugging data can be displayed on display panels of electrical equipment, manual operators, remote controllers, mobile terminals and the like. The debugging terminal of the embodiment is preferably a remote controller carried by the purchasing machine. When the mobile terminal is selected as the debugging terminal, the mobile terminal downloads the corresponding app and then is in communication connection with the electrical equipment, and under the condition that the user opens the communication permission, an engineer can also realize remote debugging. The debugging terminal of the embodiment does not need to correspond to the electrical equipment one to one, is not limited to one electrical equipment, can be applied to different electrical equipment, only needs to ensure the consistency of communication, and can be used for electrical equipment with the adjusting function.

In this embodiment, the debugging interfaces corresponding to the operation parameters of the debugging terminal are entered by using the combination keys, each debugging interface corresponds to a predetermined image symbol, and the image symbols formed after the combination keys are pressed are matched with the predetermined image tracks. When debugging the electric equipment through a debugging terminal, firstly determining a debugging interface for debugging the operation parameters; then determining a preset image symbol corresponding to the debugging interface; pressing a combination key corresponding to the preset image symbol by a debugging person; and finally, entering a debugging interface corresponding to the preset image symbol through a debugging terminal for debugging.

And setting a combination key mode in the regulation terminal in advance to enter an adjustable mode corresponding to the parameters to be regulated, and writing the parameters to be changed into the chip. After entering the corresponding parameter adjustment interface through the combination key, the size of the operation parameter can be adjusted through the up-down key of the control terminal, and parameter adjustment confirmation is carried out, or the value of the adjustment parameter is directly input.

4. After the operation parameters are adjusted, whether the feedback problem of the client is solved or not is confirmed, and in the process, an engineer judges according to the operation state of the electrical equipment after actual adjustment. And if the fault code is cancelled or the prototype can run normally, judging that the problem of customer feedback is solved.

In this embodiment, the technical solution of this embodiment is described in detail by taking the example of adjusting the operation parameters of the compressor, the external fan, the electronic expansion valve/throttling device, and the two-way valve of the air conditioner external unit. The debugging flow chart is shown in FIG. 3:

1. according to the actual running state of the electrical equipment fed back by the user, an engineer eliminates the abnormity and determines whether debugging is needed;

2. and if the debugging operation parameters are analyzed, confirming that a certain system coefficient needs to be adjusted through abnormal analysis.

3. Through a remote controller and a manual operator; and setting a combined key mode by wi f i + app software, entering an adjustable mode corresponding to the parameters to be adjusted, and writing the parameters to be changed into the chip.

For example:

A. in N seconds, simultaneously pressing the first combination key M times to enter a compressor frequency adjustable mode and adjust the frequency coefficients FA and FB of the compressor; the arrangement mode of the combination key on the debugging terminal is the image symbol F, the debugging interface corresponding to the image symbol F is entered, and the coefficients FA and FB are adjusted through left and right keys.

B. In N seconds, a frequency-up and frequency-down rate adjustable mode is entered by simultaneously pressing a second group of combination keys for M times, and frequency-up and frequency-down rates VA and VB are adjusted; the arrangement mode of the combination key on the debugging terminal is an image symbol V; entering a debugging interface corresponding to the image symbol V, and adjusting the coefficients VA and VB through the left key and the right key.

C. In N seconds, simultaneously pressing a third combination key M times to enter a gear coefficient adjustable mode, and adjusting gear coefficients RA and RB; the arrangement mode of the combination key on the debugging terminal is an image symbol R; and entering a debugging interface corresponding to the image symbol R, and adjusting coefficients RA and RB through left and right keys.

D. And in N seconds, simultaneously pressing the fourth combination key M times to enter an electronic expansion valve control coefficient adjustable mode, wherein the electronic expansion valve controls coefficients PA and PB. The arrangement mode of the combination key on the debugging terminal is an image symbol P; entering a debugging interface corresponding to the image symbol P, and adjusting the coefficients PA and PB through left and right keys.

……

4. After debugging the operation parameters, determining whether the problem of customer feedback is solved;

5. and confirming to solve the client feedback problem when the abnormal code is cancelled or the electrical equipment normally runs.

Further alternatively, the presses of the combination keys may be pressed in any order.

For example, when debugging of the compressor frequency coefficient is required, a combination key 1+2+3+4+5 is pressed, and the character symbol of the combination key pressed corresponds to a predetermined character symbol F of the compressor frequency coefficient. In the actual operation process, the sequence of the keys pressed by the debugger can be 1 → 2 → 3 → 4 → 5, 2 → 3 → 5 → 1, or 3 → 4 → 5 → 2 → 1, as long as five keys 1, 2, 3, 4, 5 are pressed, the character symbols formed when the five keys are pressed all correspond to the preset character symbol F, and the compressor frequency coefficient debugging interface can be entered.

Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. A debugging terminal based on image recognition is characterized by comprising

The storage module is used for recording the preset image symbols and the debugging interface associated with the preset image symbols;

the preset image symbols are image symbols formed after the corresponding combination keys are pressed;

the perception module is used for perceiving the image symbols formed after the different combination keys are pressed;

the matching module is used for acquiring the image symbol sensed by the sensing module and matching the image symbol with a preset image symbol to find the preset image symbol matched with the image symbol;

and the output module is used for outputting the debugging interface corresponding to the preset image symbol.

2. The character recognition-based debugging terminal according to claim 1, wherein said character symbol is one of a numeric symbol, an alphabetic symbol or a graphic symbol.

3. The character recognition-based debugging terminal according to claim 1, wherein said combination key comprises a reference key, said combination key is a start key for arranging a predetermined number of keys on said debugging terminal according to a predetermined character symbol trajectory.

4. The image recognition-based debugging terminal of claim 3, wherein said debugging terminal has a plurality of debugging interfaces, different debugging interfaces correspond to different image symbols, different image symbols correspond to different combination keys, and the reference keys of the combination keys entering different debugging interfaces are the same or different.

5. The character recognition-based debugging terminal of claim 1, wherein the combination key is a plurality of keys with the same color arranged on the debugging terminal according to the track of the predetermined character symbol.

6. The image recognition-based debugging terminal of claim 5, wherein the keys constituting different combination keys are different in color.

7. The character recognition-based debugging terminal of any one of claims 1-6, wherein the corresponding debugging interface is entered after the debugging terminal continuously presses the combination key for a set number of times.

8. The character recognition-based debugging terminal of claim 7, wherein the corresponding debugging interface is entered after the debugging terminal continuously presses the combination key for a set number of times within a set time.

9. A method for debugging an electrical device using the debugging terminal of any one of claims 1-8, wherein the electrical device comprises a plurality of operating parameters, each operating parameter corresponding to a debugging interface of the debugging terminal, and each debugging interface corresponding to a predetermined character symbol, the debugging method comprising:

determining operating parameters needing debugging;

determining a debugging interface for debugging the operation parameters;

determining a preset image symbol corresponding to the debugging interface;

pressing a combination key corresponding to the predetermined character symbol;

and entering a debugging interface corresponding to the preset image symbol.

10. Method of commissioning an electrical device according to claim 9, the pressing of said combination key can be pressed in any order.

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