CN113176925B - Method, device and equipment for controlling processing equipment and storage medium - Google Patents

Abstract

The application provides a method, a device, equipment and a storage medium for controlling processing equipment, wherein the method is applied to terminal equipment, a graphical user interface is provided on the terminal equipment, and the graphical user interface comprises the following steps: a control area and a display area, the control area including: a first control region, a second control region, and a third control region, the display region including: a state display area and a processing progress display area, the method comprising: in the processing progress display area, dynamically displaying the processing progress of the processing equipment on the target device; in the machining process, responding to a machining operation instruction of the machining equipment acting on a second control area, and controlling the machining equipment to execute a machining function matched with the machining operation instruction; and responding to the change of the equipment state parameters of the processing equipment after the processing function is executed, and displaying the changed equipment state parameters in the state display area. The user operation can be simplified, and the control efficiency of the processing equipment is improved.

Description

Method, device and equipment for controlling processing equipment and storage medium

Technical Field

The invention relates to the technical field of device processing, in particular to a method, a device, equipment and a storage medium for controlling processing equipment.

Background

When a processing device processes a target device, an operator often needs to configure processing parameters for instructing the processing device to perform a processing operation on a remote control device of the processing device, for example: cutting speed, cutting power, gas pressure during processing, processing time delay and the like of processing equipment. Because the processing parameters corresponding to the plates made of different materials are different, the operating personnel is required to debug the processing parameters of the processing equipment again when one plate is replaced. Meanwhile, because the processing shape of the target device is generally an irregular figure, in the processing process, an operator needs to adjust the processing position of the processing equipment in time through the remote control equipment so as to ensure the processing precision of the target device.

The current methods for controlling the processing equipment are generally implemented by control software configured on a remote control device. In the existing processing equipment control software, a main interface of the software is a drawing interface of a target device, an operator draws a processing part drawing of the target device on the drawing interface, and controls the processing equipment to process the target device according to the drawn processing part drawing, and in the processing process, the operator can automatically search a modification tool of a processing parameter to be debugged from a toolbar of the software to modify the processing parameter; or a modification tool of the position parameter needing to be adjusted is searched from the tool bar to control the processing equipment to move. Therefore, due to the fact that various modifying tools in the software toolbar are arranged in a messy manner, on one hand, the requirement on the operation experience of operators is high, and the operators are inconvenient to operate and use; on the other hand, when the remote control device of the processing device is a handheld device, the position of the toolbar is limited, the tool arrangement is complex, the operation of an operator is not facilitated, the operator can easily click adjacent tools mistakenly, and the control efficiency of the operator on the processing device is reduced.

Disclosure of Invention

In view of the above, an object of the present invention is to provide a method, an apparatus, a device and a storage medium for controlling a processing device, so as to simplify the control operation of a user on the processing device and improve the control efficiency of the user on the processing device during the device processing process.

In a first aspect, an embodiment of the present application provides a method for controlling a processing device, where the method is applied to a terminal device, and a graphical user interface is provided on the terminal device, where the graphical user interface includes: a control area and a display area, the control area including: a first control region, a second control region, and a third control region, the display region including: a status display area and a machining progress display area, the method comprising:

dynamically displaying the processing progress of the processing equipment on a target device in the processing progress display area, wherein the dynamically displayed processing progress is displayed according to the triggering operation of a user on the first control area and/or the third control area, the first control area is used for controlling the starting, stopping and debugging of the processing progress and processing parameters used when the processing equipment processes the target device, and the third control area is used for controlling the position of the processing equipment relative to the target device to move in the processing progress;

in the machining process, responding to a machining operation instruction of the machining equipment acting on the second control area, and controlling the machining equipment to execute a machining function matched with the machining operation instruction, wherein the second control area contains a preset threshold number of function controls, and the function controls are configured according to an operation habit of a user;

and responding to the change of the equipment state parameters of the processing equipment after the processing function is executed, and displaying the changed equipment state parameters in the state display area, wherein the equipment state parameters are used for representing the current equipment state of the processing equipment.

Optionally, the first control region and the third control region are arranged in the control region in an axisymmetrical manner, and both the first control region and the third control region are located at an edge position of the terminal device;

the second control region is located between the first control region and the third control region, and a spacing between the second control region and the first control region is a first distance threshold and a spacing between the second control region and the third control region is a second distance threshold.

Optionally, the controlling, by the response to the processing operation command of the processing device, the processing device to execute the processing function matched with the processing operation command includes:

responding to an operation instruction acting on a designated function control in the second control area, and controlling the processing equipment to execute a processing function corresponding to the designated function control;

the designated function controls are function controls designated by a user from the function controls displayed in the second control area, each function control corresponds to an independent machining function, and the function controls are arranged in the second control area in an array form.

Optionally, the size of the array of the functionality controls arranged in the second control area is configured according to the screen size of the graphical user interface.

Optionally, after the response acts on the operation instruction of the designated function control in the second control area, the method further includes:

judging whether the specified function control is configured with a parameter dialog box pop-up function or not by using the function parameter configuration information of the specified function control;

if the specified function control is determined to be configured with the parameter dialog box popup function, after responding to an operation instruction acting on the specified function control, popping up a function parameter configuration interface of the specified function control;

responding to a functional parameter modification instruction acting on the functional parameter configuration interface, and reconfiguring the functional parameters of the specified functional control;

and responding to the finishing modification instruction acting on the functional parameter configuration interface, and controlling the processing equipment to execute the processing function corresponding to the specified functional control according to the reconfigured functional parameters.

Optionally, the status display area includes: the processing equipment comprises a first parameter display area, a second parameter display area, a third parameter display area, a fourth parameter display area and a fifth parameter display area, wherein the first parameter display area is used for displaying parameters representing the working state of the processing equipment and displaying position parameters representing the position movement of the processing equipment, and the position parameters are obtained after responding to a movement operation instruction which acts on the third control area and aims at the processing equipment;

the second parameter display area is used for displaying processing parameters used when the processing equipment processes the target device, wherein the processing parameters are obtained after responding to a parameter debugging instruction acting on the first control area;

the third parameter display area is used for displaying parameters representing the processing progress of the target device;

the fourth parameter display area is used for displaying equipment parameters related to a height adjuster in the processing equipment;

the fifth parameter display area is used for displaying and representing state parameters for judging whether the processing equipment has faults or not, wherein the first parameter display area, the second parameter display area, the third parameter display area, the fourth parameter display area and the fifth parameter display area are switched and displayed by responding to an interface switching instruction acting on the state display area.

Optionally, after responding to the change of the device state parameter of the processing device after the processing function is executed, the method further includes:

judging whether the equipment state of the processing equipment fails or not according to the changed equipment state parameters;

if the equipment state of the processing equipment is determined to be in fault, responding to a stop instruction which acts on the first control area and aims at the processing equipment, and pausing the processing progress of the processing equipment on the target device;

responding to a parameter debugging instruction which acts on the first control area and aims at the processing parameters, and displaying the debugged processing parameters on the state display area;

and responding to a starting instruction which acts on the first control area and aims at the processing equipment, and controlling the processing equipment to continuously process the target device according to the debugged processing parameters.

In a second aspect, an embodiment of the present application provides an apparatus for controlling a processing device, where a graphical user interface is provided, and the graphical user interface includes: a control area and a display area, the control area including: a first control region, a second control region, and a third control region, the display region including: a state display area and a machining progress display area, the apparatus comprising:

the display module is used for dynamically displaying the processing progress of the processing equipment on a target device in the processing progress display area, wherein the dynamically displayed processing progress is displayed according to the triggering operation of a user on the first control area and/or the third control area, the first control area is used for controlling the starting, stopping and debugging of the processing progress on the processing parameters used when the processing equipment processes the target device, and the third control area is used for controlling the position of the processing equipment relative to the target device to move in the processing progress;

a first response module, configured to, in the processing process, respond to a processing operation instruction of the processing device that acts on the second control area, and control the processing device to execute a processing function that matches the processing operation instruction, where the second control area includes a preset threshold number of function controls, and the function controls are configured according to an operation habit of a user;

and the second response module is used for responding to the change of the equipment state parameter of the processing equipment after the processing function is executed, and displaying the changed equipment state parameter in the state display area, wherein the equipment state parameter is used for representing the current equipment state of the processing equipment.

Optionally, the first control region and the third control region are arranged in the control region in an axisymmetrical manner, and both the first control region and the third control region are located at an edge position of the terminal device;

the second control region is located between the first control region and the third control region, and a spacing between the second control region and the first control region is a first distance threshold and a spacing between the second control region and the third control region is a second distance threshold.

Optionally, the first response module is further configured to:

responding to an operation instruction acting on a designated function control in the second control area, and controlling the processing equipment to execute a processing function corresponding to the designated function control;

the designated function controls are function controls designated by a user from the function controls displayed in the second control area, each function control corresponds to an independent machining function, and the function controls are arranged in the second control area in an array form.

Optionally, the size of the array of the functionality controls arranged in the second control area is configured according to the screen size of the graphical user interface.

Optionally, after the response is applied to the operation instruction of the specified function control in the second control area, the first response module is further configured to:

judging whether the specified function control is configured with a parameter dialog box pop-up function or not by using the functional parameter configuration information of the specified function control;

if the specified function control is determined to be configured with the parameter dialog box popup function, after responding to an operation instruction acting on the specified function control, popping up a function parameter configuration interface of the specified function control;

responding to a functional parameter modification instruction acting on the functional parameter configuration interface, and reconfiguring the functional parameters of the specified functional control;

and responding to the finishing modification instruction acting on the functional parameter configuration interface, and controlling the processing equipment to execute the processing function corresponding to the specified functional control according to the reconfigured functional parameters.

Optionally, the status display area includes: the processing equipment comprises a first parameter display area, a second parameter display area, a third parameter display area, a fourth parameter display area and a fifth parameter display area, wherein the first parameter display area is used for displaying parameters representing the working state of the processing equipment and displaying position parameters representing the position movement of the processing equipment, and the position parameters are obtained after responding to a movement operation instruction which acts on the third control area and aims at the processing equipment;

the second parameter display area is used for displaying processing parameters used when the processing equipment processes the target device, wherein the processing parameters are obtained after responding to a parameter debugging instruction acting on the first control area;

the third parameter display area is used for displaying parameters representing the processing progress of the target device;

the fourth parameter display area is used for displaying equipment parameters related to a height adjuster in the processing equipment;

the fifth parameter display area is used for displaying and representing state parameters for judging whether the processing equipment has faults or not, wherein the first parameter display area, the second parameter display area, the third parameter display area, the fourth parameter display area and the fifth parameter display area are switched and displayed by responding to an interface switching instruction acting on the state display area.

Optionally, after responding to the change of the device state parameter of the processing device after the processing function is executed, the second response module is further configured to:

judging whether the equipment state of the processing equipment fails or not according to the changed equipment state parameters;

if the equipment state of the processing equipment is determined to be in fault, responding to a stop instruction which acts on the first control area and aims at the processing equipment, and pausing the processing progress of the processing equipment on the target device;

responding to a parameter debugging instruction which acts on the first control area and aims at the processing parameters, and displaying the debugged processing parameters on the state display area;

and responding to a starting instruction which acts on the first control area and aims at the processing equipment, and controlling the processing equipment to continuously process the target device according to the debugged processing parameters.

In a third aspect, an embodiment of the present application provides a computer device, which includes a memory, a processor, and a computer program stored on the memory and executable on the processor, and when the processor executes the computer program, the steps of the method for controlling a processing device are implemented.

In a fourth aspect, the present application provides a computer-readable storage medium, on which a computer program is stored, the computer program, when being executed by a processor, executing the steps of the method for controlling a processing apparatus.

The technical scheme provided by the embodiment of the application can have the following beneficial effects:

firstly, in the existing processing equipment control software, the main interface of the software is the drawing interface of the target device, and an operator needs to search the target device from a toolbar located at the edge position on the right side of the main interface of the software to control the processing equipment to process the target device according to the drawn processing graph. Compared with the existing processing equipment control software, the method and the device only reserve the control area for controlling the processing equipment and the display area for monitoring the working state of the processing equipment in the graphical user interface, and a user can directly import the drawn processing file of the target device on the current graphical user interface. Therefore, only by paying attention to the control of the user on the processing equipment and the equipment state change of the processing equipment in the processing process, the drawing interface and the control toolbar can be prevented from being displayed on the graphical user interface at the same time, the interface operation is simplified on the basis of ensuring the comprehensive control function, the operation efficiency of the user on the terminal equipment is improved, and meanwhile, the control efficiency of the user on the processing equipment is improved.

Further, in order to solve the problems that toolbars are narrow in distribution and various tools are distributed in a messy manner and are not beneficial to searching by a user in the existing processing equipment control software, the application classifies control tools in a control area according to the use characteristics of the control tools, and divides the control area into a first control area, a second control area and a third control area, wherein the first control area is used for controlling the starting and stopping of a processing process and debugging processing parameters used when the processing equipment processes the target device; the second control area contains a preset threshold number of functional controls, and the functional controls are configured according to the operation habits of a user; the third control area is used for controlling the position movement of the processing equipment relative to the target device in the processing process. Therefore, the machining function realized by the function control in the second control area is not directly connected with the first control area and the third control area, and the function control commonly used by the user is configured in the second control area, so that the one-key operation of the user can be facilitated, the time for the user to search from the toolbar is saved, and the control efficiency of the user on the machining equipment is improved.

In order to make the aforementioned and other objects, features and advantages of the present invention comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic flow chart illustrating a method for controlling a processing apparatus according to an embodiment of the present disclosure;

FIG. 2 is a schematic diagram of a graphical user interface provided by an embodiment of the present application;

FIG. 3 is a schematic diagram of a second control area provided by an embodiment of the present application;

FIG. 4 is a flowchart illustrating a method for modifying a function parameter of a function control in a second control area according to an embodiment of the present application;

FIG. 5 is a schematic diagram of a status display area provided by an embodiment of the present application;

fig. 6 is a schematic structural diagram illustrating an apparatus for controlling a processing device according to an embodiment of the present disclosure;

fig. 7 is a schematic structural diagram of a computer device 700 according to an embodiment of the present application.

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 of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

Embodiments of the present invention provide a method, an apparatus, a device, and a storage medium for controlling a processing device, which are described below by way of embodiments.

Example one

Fig. 1 is a schematic flow chart illustrating a method for controlling a processing device according to an embodiment of the present application, where the method is applied to a terminal device, and a graphical user interface is provided on the terminal device, where the graphical user interface includes: a control area and a display area, the control area including: a first control region, a second control region, and a third control region, the display region including: a state display area and a processing progress display area, wherein the method comprises the steps of S101-S103; specifically, the method comprises the following steps:

and S101, dynamically displaying the processing progress of the processing equipment to the target device in the processing progress display area.

Specifically, the machining process that is dynamically displayed is displayed according to a trigger operation of a user on the first control area and/or the third control area, the first control area is used for controlling starting, stopping and debugging of the machining process, and the third control area is used for controlling the position of the machining equipment to move relative to the target device in the machining process.

As an alternative embodiment, fig. 2 shows a schematic diagram of a graphical user interface provided in an embodiment of the present application, and referring to fig. 2, in a graphical user interface 200, a display area 201 is located in an upper half of the graphical user interface 200, and a control area 202 is located in a lower half of the graphical user interface 200; in the display area 201, the state display area 206 and the processing progress display area 207 divide the display area 201 into two independent sub-display areas, and a certain spacing distance exists between the state display area 206 and the processing progress display area 207, so that a user can conveniently view the display area; in the control area 202, a first control area 203, a second control area 204, and a third control area 205 are arranged in sequence and spaced apart from each other by a certain distance for user operation.

In an exemplary description, taking a laser cutting machine as a processing device as an example, the controlled parts of the laser cutting machine are mainly: the laser cutting machine comprises an x axis, a y axis, a z axis and a laser, wherein the terminal device controls the x axis to move transversely corresponding to a machine tool for controlling the laser cutting machine, the terminal device controls the y axis to move longitudinally corresponding to the machine tool for controlling the laser cutting machine, the terminal device controls the z axis to move up and down corresponding to a laser for controlling the laser cutting machine, and the terminal device can also control an f axis in the laser to move the focal position of the laser.

If the gui 200 shown in fig. 2 is used to control the laser cutting machine to process a target device, a processing file of the target device is imported in response to a file import operation performed by a user on the first control area 203, a processing pattern of the target device in the processing file is imported into the processing progress display area 207 for display, and initial values are configured for the same processing parameters in the state display area 206 according to each processing parameter included in the processing file;

after the file import operation is finished, continuously responding to the processing starting operation acted on the first control area 203 by the user, controlling the laser cutting machine to process the target device according to the processing parameters and the processing graph, and dynamically displaying the processing progress of the laser in the laser cutting machine on the target device on the displayed processing graph in the processing progress display area 207;

in the process of processing by the laser cutting machine, the axis movement operation acted on the second control area 204 by a user can be responded, and the appointed controlled part is controlled to move correspondingly according to the X-axis, the Y-axis and the Z-axis which are appointed by the user to move or the controlled part of processing equipment such as a laser and the like;

in the processing process of the laser cutting machine, the processing stopping operation acted on the first control area 203 by a user can be responded, and after the processing is stopped, the processing parameters used when the laser cutting machine processes the target device are modified in response to the parameter debugging operation acted on the first control area 203 by the user; after the modification, in response to a machining start operation applied to the first control area 203 by the user, the laser cutting machine is controlled to continue machining the target device according to the debugged machining parameters.

Specifically, in this embodiment of the present application, as an optional embodiment, the first control region and the third control region are arranged in the control region in an axisymmetric manner, and both the first control region and the third control region are located at an edge position of the terminal device;

the second control region is located between the first control region and the third control region, and a spacing between the second control region and the first control region is a first distance threshold and a spacing between the second control region and the third control region is a second distance threshold.

For exemplary illustration, referring to fig. 2, the first control region 203 and the third control region 205 are in the control region 202, and are symmetrical about the central axis of the control region 202; meanwhile, considering that a user needs to frequently operate and control the processing equipment in the processing process, as shown in fig. 2, the first control area 203 and the third control area 205 which need to be frequently used in the operation and control process can be respectively placed at the left edge and the right edge of the terminal equipment and correspond to the left hand and the right hand of the user, so that the operation of the user is facilitated, and the control efficiency of the user on the processing equipment is further improved;

the second control area 204 is placed between the third control areas 205 of the first control area 203, the interval between the second control area 204 and the first control area 203 is a first distance threshold, and the interval between the second control area 204 and the third control area 205 is a second distance threshold, so that the user can operate the processing equipment conveniently, wrong clicking of the user on the related control due to too short distance is avoided, and therefore the operation efficiency of the user on the processing equipment is improved.

It should be noted that the first distance threshold and the second distance threshold do not have a restriction condition of relative size, and may be configured according to actual operation habits of a user, or may be modified in real time according to a screen size of a graphical user interface, which is not limited in the present application.

And S102, in the machining process, responding to a machining operation instruction of the machining equipment acting on the second control area, and controlling the machining equipment to execute a machining function matched with the machining operation instruction.

Specifically, the second control area includes a preset threshold number of function controls, and the function controls are configured according to an operation habit of a user.

For exemplary illustration, fig. 3 shows a schematic diagram of a second control area provided in the embodiment of the present application, and referring to fig. 3, if the preset threshold number is 16, according to the operation habit of the user, 16 function controls A, B, C … P with top-ranked use frequencies are extracted from the data of the use frequencies of the function controls of the user, and the extracted 16 function controls are configured in the second control area 204.

In this embodiment, as an optional embodiment, the controlling, by the response to the processing operation command of the processing device, the processing device to execute the processing function matched with the processing operation command, where the response is applied to the second control area, includes:

responding to an operation instruction acting on a designated function control in the second control area, and controlling the processing equipment to execute a processing function corresponding to the designated function control;

the designated function controls are function controls designated by a user from the function controls displayed in the second control area, each function control corresponds to an independent machining function, and the function controls are arranged in the second control area in an array form.

It should be noted that each of the function controls corresponds to an independent processing function, for example, the function controls may be: the spot shooting function control, the servo calibration function control, the idle-walking frame function control and the like correspond to controls of an independent machining function, the machining function realized by the function control is not directly connected with the first control area and the third control area, the function control commonly used by a user is configured in the second control area, one-key operation of the user can be facilitated, the time of searching from a toolbar by the user is saved, and the control efficiency of the user on machining equipment is improved.

For example, referring to fig. 3, 16 function controls A, B, C … P are arranged in the second control area 204 in a 4 × 4 array, and if the function control a is a shot-shooting control, in the machining process, in response to an operation instruction applied to the function control a by a user, the machining apparatus is controlled to perform a shot-shooting operation at the current machining position.

Specifically, as another optional embodiment, the size of the array of the functionality controls arranged in the second control area is configured according to the screen size of the graphical user interface.

Illustratively, as shown in fig. 3, currently in the second control area 204, the function controls are arranged in a 4 × 4 array, if the preset screen size threshold is 16:9, when it is detected that the screen size of the graphical user interface is greater than or equal to the preset screen size threshold, the array size of the arrangement of the function controls may be adjusted from 4 × 4 to 4 × 6, at this time, since the configurable number of function controls is increased from 16 to 24 after the size adjustment, as an optional embodiment, 24 function controls with a top usage frequency may be extracted from the data of the usage frequency of the function controls of the user again, and the function controls may be uniformly arranged in the second control area 204 in the adjusted 4 × 6 array form.

It should be noted that the screen size threshold 16:9, the array size 4 × 4, the array size 4 × 6, the number of function controls 16, the number of function controls 24, and the like mentioned in the embodiments of the present application are all examples listed for explanation, and specific values of the screen size threshold, the array size, and the number of function controls are not limited in the present application.

And S103, responding to the change of the equipment state parameters of the processing equipment after the processing function is executed, and displaying the changed equipment state parameters in the state display area.

Specifically, the device state parameter is used to characterize a current device state of the processing device.

For example, in the case of a laser cutting machine, the device status parameter may be a parameter related to an increaser in a processing device; or a state parameter for judging whether the laser cutting machine has a fault; for example, the parameters may be whether the power source under-voltage is normal, whether the logic limit is normal, and the like, which are related to the current status indication of the IO device in the processing device.

In this embodiment, as an optional embodiment, after the responding to the change of the device state parameter of the processing device after the processing function is executed, the method further includes:

judging whether the equipment state of the processing equipment fails or not according to the changed equipment state parameters;

if the equipment state of the processing equipment is determined to be in fault, responding to a stop instruction which acts on the first control area and aims at the processing equipment, and pausing the processing progress of the processing equipment on the target device;

responding to a parameter debugging instruction which acts on the first control area and aims at the processing parameters, and displaying the debugged processing parameters on the state display area;

and responding to a starting instruction which acts on the first control area and aims at the processing equipment, and controlling the processing equipment to continuously process the target device according to the debugged processing parameters.

For example, referring to fig. 3, if the function control a is a spot shooting control, in the machining process, in response to an operation instruction applied to the function control a by a user, the machining device is controlled to perform a spot shooting operation at the current machining position, if after the spot shooting operation is performed, the power supply under-voltage button in the device state parameter changes from a green light indicating normal to a red light indicating abnormal, it is determined that the device state of the machining device is faulty, the user is prompted to interrupt the machining operation, and in response to a stop instruction applied to the first control region 203 and directed to the machining device, the machining operation of the machining device is suspended; then, responding to a parameter debugging instruction which is acted on the first control area 203 and aims at the processing parameters, responding to a starting instruction which is acted on the first control area 203 and aims at the processing equipment after a user debugs the processing parameters, controlling the processing equipment to continuously process the target device according to the debugged processing parameters, detecting whether a power supply under-voltage button in equipment state parameters is normal or not, and if the power supply under-voltage button is still abnormal, repeating the steps until the processing equipment state is normal.

In a possible implementation, fig. 4 shows a flowchart of a method for modifying a function parameter of a function control in a second control area according to an embodiment of the present application, and as shown in fig. 4, after the response is applied to an operation instruction of a function control specified in the second control area when step S103 is executed, the method further includes S401-S404; specifically, the method comprises the following steps:

s401, judging whether the specified function control is configured with a parameter dialog box pop-up function or not by using the function parameter configuration information of the specified function control.

Specifically, considering that a user often needs to debug a processing parameter of a processing device during a processing process of the processing device, in the existing processing device control software, if the user wants to modify a target parameter, the user needs to search a parameter modification tool from a toolbar and enter a parameter modification interface, and then needs to find the target parameter from the parameter modification interface for modification, and after modification, quits the parameter modification interface and returns to a control main interface. And the second control area which can be controlled by one key of the user is configured, so that the function parameter configuration information can be set for each function control in the second control area in advance, the parameter dialog box popup function is configured for the function control frequently needing parameter debugging, and the parameter dialog box popup function can be configured for the function control not needing parameter debugging, so that the time required for the user to search by himself is saved, the user operation is simplified, and the control efficiency of the user on the processing equipment is improved.

S402, if the specified function control is determined to be configured with the parameter dialog box popup function, after responding to an operation instruction acting on the specified function control, popping up a function parameter configuration interface of the specified function control.

For an exemplary description, taking the point shooting function control as an example, if the point shooting function control configures the parameter dialog box popup function, after the user clicks the point shooting function control, a function parameter configuration interface of the point shooting function control pops up, so that the user can debug the target parameters related to the point shooting function, and the parameter debugging efficiency of the user is improved.

And S403, responding to the function parameter modification instruction acting on the function parameter configuration interface, and reconfiguring the function parameters of the specified function control.

In an exemplary description, still taking the shot firing function control as an example, after a function parameter configuration interface of the shot firing function control is popped up, if a user takes shot firing time as a target parameter to be debugged, the user is accepted to modify the shot firing time, and the modified shot firing time is saved.

And S404, responding to the finishing modification instruction acting on the functional parameter configuration interface, and controlling the processing equipment to execute the processing function corresponding to the specified functional control according to the reconfigured functional parameters.

Illustratively, still taking the above example as an example, if the user modifies the shot-shooting time from 10000 milliseconds to 8000 milliseconds, the modified shot-shooting time is saved, and the processing equipment is controlled to be at the current processing position to perform the shot-shooting operation according to the shot-shooting time of 8000 milliseconds in response to the modification instruction for the end of the user.

In one possible implementation, fig. 5 shows a schematic diagram of a status display area provided in an example of the present application, and as shown in fig. 5, the status display area 206 includes: a first parameter display area 501, a second parameter display area 502, a third parameter display area 503, a fourth parameter display area 504, and a fifth parameter display area 505, specifically:

the first parameter display area 501 is used for displaying parameters representing the working state of the processing equipment; for example, the operating frequency, peak power, etc. of the processing equipment; and a display unit for displaying a position parameter indicating a position movement of the processing device, wherein the position parameter is obtained in response to a movement operation command for the processing device, which is applied to the third control region; for example: responding to an x-axis movement operation instruction, which is acted on the third control area by a user and aims at a machine tool in the machining equipment, and displaying the current x-axis coordinate of the machine tool after movement, wherein the position parameter can be the x-axis coordinate and the y-axis coordinate of the current machine tool, the z-axis coordinate of a laser in the machining equipment, a focus coordinate and the like;

a second parameter display area 502 is used for displaying processing parameters used when the processing equipment processes the target device, wherein the processing parameters are obtained after responding to a parameter debugging instruction acting on the first control area; for example, the cutting speed of the processing equipment, the gas pressure at the time of processing, etc.;

the third parameter display area 503 is used for displaying parameters representing the processing progress of the target device; for example, the predicted machining time, the machining elapsed time, the predicted number of machining cycles, and the like;

a fourth parameter display area 504 for displaying equipment parameters related to a height adjuster in the processing equipment; for example, if the height adjuster is a capacitive height adjuster, the fourth parameter display area may display a current capacitance value, a current height of the height adjuster, a following error, and the like, where an equipment parameter related to the height adjuster may also be an indicative parameter such as whether the height adjuster returns to an original point or whether the height adjuster follows in place, and when a fault occurs in the machining process or the machining equipment, a user may quickly determine a fault location and a fault cause according to whether an indicator lamp of the indicative equipment parameter is normal, so as to improve debugging efficiency of the machining equipment by the user;

a fifth parameter display area 505 is used for displaying state parameters for judging whether the processing equipment has a fault or not; for example, the parameters may be whether the power source under-voltage is normal, whether the logic limit is normal, and the like, which are related to the current status indication of the IO device in the processing device.

Illustratively, as an alternative embodiment, as shown in fig. 5, in the status display area 206, a first parameter display area 501, a second parameter display area 502, a third parameter display area 503, a fourth parameter display area 504 and a fifth parameter display area 505 are displayed in a switched manner in response to an interface switching instruction applied to the status display area 206. For example, the main display interface of the current state display area 206 is the first parameter display area 501, and if the user responds to the interface switching instruction applied to the second parameter display area 502 in fig. 5, the main display interface of the current state display area 206 is switched from the first parameter display area 501 to the second parameter display area 502.

Example two

Fig. 6 is a schematic structural diagram illustrating an apparatus for controlling a processing device, on which a graphical user interface is provided, according to an embodiment of the present application, where the graphical user interface includes: a control area and a display area, the control area including: a first control region, a second control region, and a third control region, the display region including: a state display area and a machining progress display area, the apparatus comprising:

a display module 601, configured to dynamically display a processing progress of a target device by a processing apparatus in the processing progress display area, where the dynamically displayed processing progress is displayed according to a trigger operation of a user on the first control area and/or the third control area, the first control area is used to control starting, stopping, and debugging of the processing progress of the processing apparatus on the target device, and the third control area is used to control a position of the processing apparatus relative to the target device to move in the processing progress;

a first response module 602, configured to, in the processing process, respond to a processing operation instruction, which is applied to the second control area, of the processing device, and control the processing device to execute a processing function matched with the processing operation instruction, where the second control area includes a preset threshold number of function controls, and the function controls are configured according to an operation habit of a user;

a second responding module 603, configured to respond to a change of an equipment status parameter of the processing equipment after the processing function is executed, and display the changed equipment status parameter in the status display area, where the equipment status parameter is used to represent an equipment status of the processing equipment at present.

Optionally, the first control region and the third control region are arranged in the control region in an axisymmetrical manner, and both the first control region and the third control region are located at an edge position of the terminal device;

the second control region is located between the first control region and the third control region, and a spacing between the second control region and the first control region is a first distance threshold and a spacing between the second control region and the third control region is a second distance threshold.

Optionally, the first response module 602 is further configured to:

responding to an operation instruction acting on a designated function control in the second control area, and controlling the processing equipment to execute a processing function corresponding to the designated function control;

the designated function controls are function controls designated by a user from the function controls displayed in the second control area, each function control corresponds to an independent machining function, and the function controls are arranged in the second control area in an array form.

Optionally, the size of the array of the functionality controls arranged in the second control area is configured according to the screen size of the graphical user interface.

Optionally, after the responding is performed on the operation instruction of the designated function control in the second control area, the first responding module 602 is further configured to:

judging whether the specified function control is configured with a parameter dialog box pop-up function or not by using the function parameter configuration information of the specified function control;

if the specified function control is determined to be configured with the parameter dialog box popup function, after responding to an operation instruction acting on the specified function control, popping up a function parameter configuration interface of the specified function control;

responding to a functional parameter modification instruction acting on the functional parameter configuration interface, and reconfiguring the functional parameters of the specified functional control;

and responding to the finishing modification instruction acting on the functional parameter configuration interface, and controlling the processing equipment to execute the processing function corresponding to the specified functional control according to the reconfigured functional parameters.

Optionally, the status display area includes: the processing equipment comprises a first parameter display area, a second parameter display area, a third parameter display area, a fourth parameter display area and a fifth parameter display area, wherein the first parameter display area is used for displaying parameters representing the working state of the processing equipment and displaying position parameters representing the position movement of the processing equipment, and the position parameters are obtained after responding to a movement operation instruction which acts on the third control area and aims at the processing equipment;

the second parameter display area is used for displaying processing parameters used when the processing equipment processes the target device, wherein the processing parameters are obtained after responding to a parameter debugging instruction acting on the first control area;

the third parameter display area is used for displaying parameters representing the processing progress of the target device;

the fourth parameter display area is used for displaying equipment parameters related to a height adjuster in the processing equipment;

the fifth parameter display area is used for displaying and representing state parameters for judging whether the processing equipment has faults or not, wherein the first parameter display area, the second parameter display area, the third parameter display area, the fourth parameter display area and the fifth parameter display area are switched and displayed by responding to an interface switching instruction acting on the state display area.

Optionally, after responding to the change of the device state parameter of the processing device after the processing function is executed, the second responding module 603 is further configured to:

judging whether the equipment state of the processing equipment fails or not according to the changed equipment state parameters;

if the equipment state of the processing equipment is determined to be in fault, responding to a stop instruction which acts on the first control area and aims at the processing equipment, and pausing the processing progress of the processing equipment on the target device;

responding to a parameter debugging instruction which acts on the first control area and aims at the processing parameters, and displaying the debugged processing parameters on the state display area;

and responding to a starting instruction which acts on the first control area and aims at the processing equipment, and controlling the processing equipment to continuously process the target device according to the debugged processing parameters.

EXAMPLE III

As shown in fig. 7, an embodiment of the present application provides a computer device 700 for executing the method for controlling a processing device in the present application, the device includes a memory 701, a processor 702, and a computer program stored in the memory 701 and executable on the processor 702, wherein the processor 702 implements the steps of the method for controlling a processing device when executing the computer program.

Specifically, the memory 701 and the processor 702 may be general-purpose memory and processor, which are not limited in particular, and when the processor 702 runs the computer program stored in the memory 701, the method for controlling the processing device can be executed.

Corresponding to the method for controlling the processing equipment in the application, the embodiment of the application also provides a computer readable storage medium, wherein a computer program is stored on the computer readable storage medium, and the computer program is executed by a processor to execute the steps of the method for controlling the processing equipment.

In particular, the storage medium can be a general-purpose storage medium, such as a removable disk, a hard disk, or the like, on which a computer program can be executed when executed to perform the above-described method of controlling a processing apparatus.

In the embodiments provided in the present application, it should be understood that the disclosed system and method may be implemented in other ways. The above-described system embodiments are merely illustrative, and for example, the division of the units is only one type of logical functional division, and other divisions may be realized in practice, and for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection of systems or units through some communication interfaces, and may be in an electrical, mechanical or other form.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, functional units in the embodiments provided in the present application may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit.

The functions, if implemented in the form of software functional units and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present application or portions thereof that substantially contribute to the prior art may be embodied in the form of a software product stored in a storage medium and including instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present application. And the aforementioned storage medium includes: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus once an item is defined in one figure, it need not be further defined and explained in subsequent figures, and moreover, the terms "first", "second", "third", etc. are used merely to distinguish one description from another and are not to be construed as indicating or implying relative importance.

Finally, it should be noted that: the above-mentioned embodiments are only specific embodiments of the present application, and are used for illustrating the technical solutions of the present application, but not limiting the same, and the scope of the present application is not limited thereto, and although the present application is described in detail with reference to the foregoing embodiments, those skilled in the art should understand that: any person skilled in the art can modify or easily conceive the technical solutions described in the foregoing embodiments or equivalent substitutes for some technical features within the technical scope disclosed in the present application; such modifications, changes or substitutions do not depart from the spirit and scope of the present disclosure, which should be construed in light of the above teachings. Are intended to be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (10)

1. A method of controlling a processing apparatus, the method being applied to a terminal device on which a graphical user interface is provided, the graphical user interface comprising: a control area and a display area, the control area including: a first control region, a second control region, and a third control region, the display region including: a status display area and a machining progress display area, the method comprising:

dynamically displaying the processing progress of the processing equipment on a target device in the processing progress display area, wherein the dynamically displayed processing progress is displayed according to the triggering operation of a user on the first control area and/or the third control area, the first control area is used for controlling the starting, stopping and debugging of the processing progress and processing parameters used when the processing equipment processes the target device, and the third control area is used for controlling the position of the processing equipment relative to the target device to move in the processing progress;

in the machining process, responding to a machining operation instruction of the machining equipment acting on the second control area, and controlling the machining equipment to execute a machining function matched with the machining operation instruction, wherein the second control area contains a preset threshold number of function controls, and the function controls are configured according to an operation habit of a user;

and responding to the change of the equipment state parameters of the processing equipment after the processing function is executed, and displaying the changed equipment state parameters in the state display area, wherein the equipment state parameters are used for representing the current equipment state of the processing equipment.

2. The method of claim 1, wherein the first control region and the third control region are arranged in an axisymmetric manner in the control region, and the first control region and the third control region are both located at edge positions of the terminal device;

the second control region is located between the first control region and the third control region, and a spacing between the second control region and the first control region is a first distance threshold and a spacing between the second control region and the third control region is a second distance threshold.

3. The method of claim 1, wherein the controlling the processing tool to perform a processing function matching a processing operation command for the processing tool in response to the processing operation command acting on the second control area comprises:

responding to an operation instruction acting on a designated function control in the second control area, and controlling the processing equipment to execute a processing function corresponding to the designated function control;

the designated function controls are function controls designated by a user from the function controls displayed in the second control area, each function control corresponds to an independent machining function, and the function controls are arranged in the second control area in an array form.

4. The method of claim 3, wherein the size of the array of functionality controls arranged in the second control region is configured according to the screen size of the graphical user interface.

5. The method according to claim 3, wherein after the responding acts on the operation instruction of the designated function control in the second control area, the method further comprises:

judging whether the specified function control is configured with a parameter dialog box pop-up function or not by using the function parameter configuration information of the specified function control;

if the specified function control is determined to be configured with the parameter dialog box popup function, after responding to an operation instruction acting on the specified function control, popping up a function parameter configuration interface of the specified function control;

responding to a functional parameter modification instruction acting on the functional parameter configuration interface, and reconfiguring the functional parameters of the specified functional control;

and responding to the finishing modification instruction acting on the functional parameter configuration interface, and controlling the processing equipment to execute the processing function corresponding to the specified functional control according to the reconfigured functional parameters.

6. The method of claim 1, wherein the status display area comprises: the processing device comprises a first parameter display area, a second parameter display area, a third parameter display area, a fourth parameter display area and a fifth parameter display area, wherein the first parameter display area is used for displaying parameters representing the working state of the processing device and position parameters representing the position movement of the processing device, and the position parameters are obtained after responding to a movement operation instruction which acts on the third control area and aims at the processing device;

the second parameter display area is used for displaying processing parameters used when the processing equipment processes the target device, wherein the processing parameters are obtained after responding to a parameter debugging instruction acting on the first control area;

the third parameter display area is used for displaying parameters representing the processing progress of the target device;

the fourth parameter display area is used for displaying equipment parameters related to a height adjuster in the processing equipment;

the fifth parameter display area is used for displaying and representing state parameters for judging whether the processing equipment has faults or not, wherein the first parameter display area, the second parameter display area, the third parameter display area, the fourth parameter display area and the fifth parameter display area are switched and displayed by responding to an interface switching instruction acting on the state display area.

7. The method of claim 1, wherein after said responding to a change in a device state parameter of said processing device after performing said processing function, said method further comprises:

judging whether the equipment state of the processing equipment fails or not according to the changed equipment state parameters;

if the equipment state of the processing equipment is determined to be in fault, responding to a stop instruction which acts on the first control area and aims at the processing equipment, and pausing the processing progress of the processing equipment on the target device;

responding to a parameter debugging instruction which acts on the first control area and aims at the processing parameters, and displaying the debugged processing parameters on the state display area;

and responding to a starting instruction which acts on the first control area and aims at the processing equipment, and controlling the processing equipment to continuously process the target device according to the debugged processing parameters.

8. An apparatus for controlling a processing tool, wherein a graphical user interface is provided on the apparatus, the graphical user interface comprising: a control area and a display area, the control area including: a first control region, a second control region, and a third control region, the display region including: a state display area and a machining progress display area, the apparatus comprising:

the display module is used for dynamically displaying the processing progress of the processing equipment on a target device in the processing progress display area, wherein the dynamically displayed processing progress is displayed according to the triggering operation of a user on the first control area and/or the third control area, the first control area is used for controlling the starting, stopping and debugging of the processing progress on the processing parameters used when the processing equipment processes the target device, and the third control area is used for controlling the position of the processing equipment relative to the target device to move in the processing progress;

a first response module, configured to, in the processing process, respond to a processing operation instruction of the processing device that acts on the second control area, and control the processing device to execute a processing function that matches the processing operation instruction, where the second control area includes a preset threshold number of function controls, and the function controls are configured according to an operation habit of a user;

and the second response module is used for responding to the change of the equipment state parameter of the processing equipment after the processing function is executed, and displaying the changed equipment state parameter in the state display area, wherein the equipment state parameter is used for representing the current equipment state of the processing equipment.

9. An electronic device, comprising: a processor, a memory and a bus, the memory storing machine-readable instructions executable by the processor, the processor and the memory communicating over the bus when the electronic device is operating, the machine-readable instructions when executed by the processor performing the steps of the method of controlling a process plant according to any one of claims 1 to 7.

10. A computer-readable storage medium, characterized in that the computer-readable storage medium has stored thereon a computer program which, when being executed by a processor, carries out the steps of the method of controlling a processing device according to any one of claims 1 to 7.

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