CN116991293B - Multi-head worm processing parameter setting interface display method and related equipment - Google Patents

Abstract

The invention provides a display method and related equipment for a multi-head worm processing parameter setting interface, and relates to the technical field of interface display of worm processing equipment. The multi-head worm processing parameter setting interface display method comprises the following steps: acquiring the number of worm heads of a worm to be processed and a plurality of processing parameters; according to the number of worm heads, obtaining the correlation among all the processing parameters; after the equipment enters a processing parameter setting mode, a first processing parameter setting interface is adjusted according to the correlation among the processing parameters, so that the correlated processing parameters are simultaneously displayed in the same first processing parameter setting interface. The multi-head worm processing parameter setting interface display method can ensure that the associated processing parameters are displayed in the same interface in a concentrated mode, and is convenient for a user to set, modify and confirm the processing parameters.

Description

Multi-head worm processing parameter setting interface display method and related equipment

Technical Field

The invention relates to the technical field of interface display of worm processing equipment, in particular to a multi-head worm processing parameter setting interface display method and related equipment.

Background

When the worm is manufactured, because various types of worm exist, such as a single-head worm, a double-head worm, a triple-head worm and the like, the more the number of worm heads is, the more machining parameters are required to be set, such as the more the number of worm heads is, the more the spindle angle increment value is required to be set; meanwhile, because part of machining parameters are related, for example, the spindle angle increment value is calculated by the workpiece tooth length and the workpiece lead, so that the number of worm heads is increased, the workpiece tooth length and the workpiece lead which are required to be set are correspondingly increased (each head of the worm corresponds to one set of machining parameters), the interface of the control panel of the machining equipment is limited in size, and excessive machining parameters cannot be simultaneously arranged in one interface, so that the interface is designed to be capable of sliding display generally, however, because of the mutual correlation between the machining parameters, when one machining parameter is changed, the other machining parameter is changed, the user needs to slide back and forth to confirm when modifying the machining parameters in a sliding display mode, and the operation is very inconvenient.

In view of the above problems, no effective technical solution is currently available.

Disclosure of Invention

The invention aims to provide a display method and related equipment for a processing parameter setting interface of a multi-head worm, which can ensure that the related processing parameters are displayed in the same interface in a concentrated manner, and are convenient for a user to set, modify and confirm the processing parameters.

In a first aspect, the present invention provides a method for displaying a processing parameter setting interface of a multi-start worm, which is applied to a multi-start worm processing device, and includes the following steps:

s1, obtaining the number of worm heads of a worm to be processed and a plurality of processing parameters;

s2, acquiring the correlation among the machining parameters according to the number of worm heads;

s3, after the equipment enters a processing parameter setting mode, a first processing parameter setting interface is adjusted according to the correlation among the processing parameters, so that the related processing parameters are simultaneously displayed in the same first processing parameter setting interface.

According to the display method of the multi-head worm processing parameter setting interface, provided by the invention, the correlation among the processing parameters is judged in advance, and the content in the first processing parameter setting interface is adjusted according to the correlation, so that the correlated processing parameters are simultaneously displayed in the same first processing parameter setting interface, and the change of other processing parameters related to the processing parameters can be straightly and clearly seen when a user fills the processing parameters.

Further, the first processing parameter setting interface is divided into a filling area and a display area;

the specific steps in the step S3 include:

S3A1, discharging the processing parameters in the display area and displaying the processing parameters simultaneously;

and S3A2, arranging the processing parameters selected by the cursor and other processing parameters related to the processing parameters in a filling area for display.

The processing parameters can be set only in the filling area by the constraint user, so that the processing parameters can be set quickly by a new hand, and the time for the user to adapt to the parameter setting interface of the equipment is reduced.

Further, the specific steps in step S3A2 include:

S3A2A1, transferring the processing parameters selected by the cursor and other processing parameters related to the processing parameters from the display area to a filling area;

S3A2, adjusting the display areas of the filling area and the display area according to the display quantity of the processing parameters in the filling area and the display quantity of the processing parameters in the display area.

The area of the two areas is dynamically adjusted according to the display quantity, so that each processing parameter can be clearly displayed, and the processing parameters can be set by a user.

Further, the display area of the filling area and the display area of the display area are fixed, and the display area of the filling area is smaller than the display area of the display area;

The specific steps in step S3A2 include:

S3A2B1, acquiring a first total number of other processing parameters related to the processing parameters selected by the cursor;

S3A2B2, when the first total number is smaller than or equal to a preset first threshold value, arranging the processing parameters selected by the cursor and all other related processing parameters thereof in a filling area for display;

and S3A2B3, when the first total number is larger than a preset first threshold value, arranging the processing parameters which are selected by the cursor and are required to be filled in other processing parameters related to the processing parameters in a filling area, displaying the processing parameters in the display area, and marking the processing parameters which are not required to be filled in other processing parameters related to the processing parameters selected by the cursor in the display area.

In a limited area, the processing parameters needing to be filled in are highlighted, firstly, convenience is brought to the user to set the processing parameters needing to be filled in, then, the user is reminded of paying attention to the processing parameters selected by the cursor and all other related processing parameters are ensured by means of marking at the display area.

Further, the method further comprises the steps of:

s41, obtaining a processing drawing of the worm to be processed;

s42, acquiring a processing parameter table according to the processing drawing;

S43, acquiring filling sequences of all the processing parameters according to the processing parameter table;

s44, after one processing parameter is filled in each time, the cursor is controlled to automatically jump according to the filling sequence, and the next processing parameter is selected.

The processing device does not need manual operation of a user, improves the efficiency of setting the processing parameters and is beneficial to using processing equipment by novices.

Further, the method further comprises the steps of:

s51, acquiring first modification times of each processing parameter;

s52, according to the first modification times, taking the processing parameter corresponding to the maximum value of the first modification times as a third target parameter;

s53, when the first processing parameter setting interface is switched to each time, the cursor is controlled to be automatically selected on the third target parameter.

Further, the specific steps in step S53 include:

S53A1, obtaining second modification times of each digit of the numerical value of the third target parameter;

S53A2, taking the digit corresponding to the maximum value of the second modification times as a target digit according to the second modification times;

S53A3, controlling a cursor to be automatically selected on the target digit.

In a second aspect, the present invention provides a display device for a multi-start worm processing parameter setting interface, which is applied to multi-start worm processing equipment, and includes:

The acquisition module is used for acquiring the number of worm heads of the worm to be processed and a plurality of processing parameters;

the judging module is used for acquiring the correlation among the processing parameters according to the number of the worm heads;

and the adjusting module is used for adjusting the first processing parameter setting interface according to the correlation among the processing parameters after the equipment enters the processing parameter setting mode so that the related processing parameters are simultaneously displayed in the same first processing parameter setting interface.

The multi-head worm processing parameter setting interface display device provided by the invention can facilitate a user to intuitively see the change of other related processing parameters when setting or modifying the processing parameters, is beneficial to the user to confirm the processing parameters and ensures the production to be correct.

In a third aspect, the present invention provides an electronic device comprising a processor and a memory storing computer readable instructions which, when executed by the processor, perform the steps in the method for displaying a multi-start worm processing parameter setting interface as provided in the first aspect above.

In a fourth aspect, the present invention provides a computer-readable storage medium having stored thereon a computer program which, when executed by a processor, performs the steps in the multi-start worm processing parameter setting interface display method as provided in the first aspect above.

Therefore, according to the multi-head worm processing parameter setting interface display method provided by the invention, as the number of worm heads and part of processing parameters are in complete set relation and the relation exists between the processing parameters, after the relation among the processing parameters is determined, the content in the first processing parameter setting interface can be adjusted in a targeted manner, so that the related processing parameters are simultaneously displayed in the same first processing parameter setting interface under the condition of limited interface size, the inconvenience caused by back and forth sliding is avoided, the user can clearly know the change among the processing parameters, and the user can set, modify and determine the processing parameters conveniently.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be apparent from the description, or may be learned by practice of the embodiments of the invention. The objects and other advantages of the invention may be realized and obtained by means of the instrumentalities particularly pointed out in the written description and the appended drawings.

Drawings

Fig. 1 is a flowchart of a method for displaying a processing parameter setting interface of a multi-start worm according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of an interface using a popup window display in an embodiment of the present invention.

Fig. 3 is a schematic diagram of an interface for displaying a first processing parameter setting interface divided into a filling area and a display area according to an embodiment of the present invention.

Fig. 4 is a process of adjusting display areas of a filling area and a display area according to the display number of processing parameters in an embodiment of the present invention.

Fig. 5 is a display diagram of other processing parameters associated with one of the processing parameters selected when the display areas of the filling area and the display area are fixed in an embodiment of the present invention.

Fig. 6 is a schematic diagram of an interface for displaying after hiding the second target parameter according to an embodiment of the present invention.

FIG. 7 is a schematic diagram of an interface for displaying a process parameter that is not related to any other process parameter after transferring to a second process parameter setting interface according to an embodiment of the present invention.

FIG. 8 is a process of controlling cursor jumping according to the filling order of processing parameters on a processing parameter table in a processing drawing in an embodiment of the present invention.

Fig. 9 is a schematic structural diagram of a display device for a processing parameter setting interface of a multi-start worm according to an embodiment of the present invention.

Fig. 10 is a schematic structural diagram of an electronic device according to an embodiment of the present invention.

Description of the reference numerals:

100. an acquisition module; 200. a judging module; 300. an adjustment module; 13. an electronic device; 1301. a processor; 1302. a memory; 1303. a communication bus.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. The components of the 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 invention, as 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 made by a person skilled in the art without making any inventive effort, are intended to be within the scope of the present invention.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures. Meanwhile, in the description of the present invention, the terms "first", "second", and the like are used only to distinguish the description, and are not to be construed as indicating or implying relative importance.

As shown in fig. 2, 3 and 4, the diagonal line filling pattern indicates the processing parameter selected by the cursor (actually selected is the filling frame corresponding to the processing parameter).

Fig. 2-8 are schematic diagrams of processing parameter setting interfaces, which are illustrated by processing a double-ended worm, wherein the normal modulus, the axial modulus, the lead angle, the workpiece tooth number, the workpiece tooth length, the workpiece tooth pitch, the workpiece lead, and the spindle angle increment values each represent two columns of filling boxes, and each head of the worm corresponds to a column of filling boxes (e.g., a first column of filling boxes corresponds to a parameter of a first head of the worm, and a second column of filling boxes corresponds to a parameter of a second head of the worm).

In fig. 2 and 5, the cross-hatching pattern indicates highlighting.

In fig. 8, (1) indicates a first jump of the cursor, (2) indicates a second jump of the cursor, and (3) indicates a third jump of the cursor.

Referring to fig. 1, fig. 1 is a flowchart of a method for displaying a processing parameter setting interface of a multi-start worm. The multi-head worm processing parameter setting interface display method is applied to multi-head worm processing equipment and comprises the following steps:

s1, obtaining the number of worm heads of a worm to be processed and a plurality of processing parameters;

S2, acquiring the correlation among all processing parameters according to the number of worm heads;

s3, after the equipment enters a processing parameter setting mode, according to the correlation among the processing parameters, adjusting a first processing parameter setting interface so that the related processing parameters are simultaneously displayed in the same first processing parameter setting interface.

The machining parameters can be generally divided into two types, namely workpiece parameters and cutter parameters, and for machining the worm, the workpiece parameters comprise a normal modulus, an axial modulus, a helix angle, workpiece tooth number, workpiece tooth length, workpiece tooth pitch and workpiece lead; the cutter parameters comprise Z-axis moving speed, cutter shaft rotating speed, cutter tooth number, cutter diameter, linear speed, per-rotation per-tooth feeding amount and spindle angle increment value.

According to a well-known calculation formula, the following relationship exists between the above processing parameters:

1. the axial modulus can be calculated by the normal modulus and the helix angle;

2. the tooth distance of the workpiece can be calculated by the tooth number of the workpiece and the axial modulus;

3. the workpiece lead can be calculated by the workpiece tooth pitch and the workpiece tooth number;

4. the feed quantity of each tooth of each rotation can be calculated by the normal modulus, the helix angle and the workpiece tooth number;

5. The spindle angle increment value can be calculated by the tooth length of the workpiece and the lead of the workpiece;

therefore, a certain correlation exists between part of processing parameters, so that when a user sets a certain processing parameter, other processing parameters related to the processing parameters are changed, and the processing parameters determine the quality of a finished product, so that the user must know the change of the processing parameters to confirm and ensure that the production is correct.

In addition, besides the relation among the machining parameters, for the multi-head worm, the more the number of worm heads is machined (the number of worm heads refers to the number of spiral lines), the more the spindle angle increment value is required to be set, and based on the relation among the machining parameters, it can be known that one set of parameters such as workpiece tooth length, workpiece tooth number, normal modulus and spiral angle is required to be set correspondingly for each multiple head, and because each set of parameters is set correspondingly for one head, part of machining parameters also have a certain correlation with each head of the worm.

In this embodiment, the content of the first processing parameter setting interface is adjusted according to the correlation, so that in order to enable the associated processing parameters to be displayed in the same first processing parameter setting interface at the same time, a user can intuitively see the changes of other related processing parameters when setting or modifying the processing parameters, which is favorable for confirming the processing parameters by the user, ensuring that production is error-free, and in particular is favorable for setting the processing parameters in a debugging stage.

In some embodiments, the relevant process parameters may be separately exhausted in one interface.

For example, the axial modulus, the normal modulus and the lead angle are independently arranged in a third processing parameter setting interface; for example, the spindle angle increment value, the workpiece tooth length, the workpiece tooth number, the normal modulus and the helix angle are independently arranged in a fourth processing parameter setting interface; for example, taking a double-ended worm as an example, the workpiece parameter and the spindle angle increment value corresponding to the first head are discharged in a fifth processing parameter setting interface, and the workpiece parameter and the spindle angle increment value corresponding to the second head are discharged in a sixth processing parameter setting interface.

In some embodiments, all of the process parameters may also be exhausted in the same interface.

For example, a group of related processing parameters are placed, and the processing parameters are arranged in groups in a first processing parameter setting interface; for example, taking a double-ended worm as an example, the workpiece parameter and the spindle angle increment value corresponding to the first head are taken as one group, the workpiece parameter and the spindle angle increment value corresponding to the second head are taken as the other group, and the two groups of processing parameters are arranged in the first processing parameter setting interface.

In some embodiments, referring to fig. 2, other processing parameters associated with the selected processing parameters may be discharged into the popup window by popup window sideways according to the processing parameters selected by the cursor, where the other processing parameters associated with the selected processing parameters may be directly transferred from the processing parameter setting interface to the popup window for display (i.e., the processing parameter setting interface is no longer displayed), or may be displayed in both the processing parameter setting interface and the popup window, and corresponding filling boxes in the processing parameter setting interface are marked.

In some embodiments, other processing parameters associated with the selected processing parameters may also be marked based on the processing parameters selected by the cursor.

For example, when the user selects the normal modulus, the font color of the lead angle and the axial modulus is changed from a preset white color to a red color, or the lead angle and the axial modulus are highlighted, or the font of the lead angle and the axial modulus is thickened, enlarged, underlined, etc. The other processing parameters are highlighted, so that the user is reminded of paying attention, the user can conveniently determine the processing parameters, and errors are reduced.

Further, the degree of association between the processing parameters may also be obtained; setting marks of different grades according to the association degree; and distinguishing the processing parameters with different association degrees by using marks with different grades according to the processing parameters selected by the cursor.

For example, the marks are classified into 3 levels, namely, a red highlight, a yellow highlight and a cyan highlight, wherein the red highlight represents the highest association degree, the yellow highlight and the cyan highlight represent the lowest association degree; for the workpiece tooth number, the workpiece tooth number can be calculated by the axial modulus and the workpiece tooth pitch, so that the axial modulus and the workpiece tooth pitch are directly related to the workpiece tooth number, the association degree is highest, the workpiece tooth number is set to be red highlighting, and the axial modulus can be calculated by the normal modulus and the helix angle, so that the normal modulus and the helix angle are also equivalent to the association degree with the workpiece tooth number, but the association degree is inferior to the axial modulus and the workpiece tooth pitch, and the workpiece tooth number is set to be yellow highlighting. The method can highlight other related processing parameters, simultaneously can enable a user to quickly distinguish the degree of association among the processing parameters, reminds the user of taking care, is convenient for the user to determine the processing parameters, reduces errors and is beneficial to a novice to correctly set the processing parameters.

The existing equipment parameter setting interface is generally a preset discharge position of each machining parameter, and cannot be adaptively adjusted according to actual filling operation of a user, which clearly causes the user (especially a novice) to spend more time on the parameter setting interface of the adapting equipment (for example, the novice is not familiar with the parameter setting interface, it is unclear which row of machining parameters are associated with which head of the worm, and it is unclear which machining parameters are associated with which machining parameters, for example).

In certain preferred embodiments, and referring to FIG. 3, the first process parameter setting interface is divided into a fill area and a display area;

the specific steps in the step S3 include:

S3A1, arranging the processing parameters in a display area and simultaneously displaying the processing parameters;

and S3A2, arranging the processing parameters selected by the cursor and other processing parameters related to the processing parameters in a filling area for display.

For ease of understanding, the processing parameter selected by the cursor is hereinafter referred to as a first target parameter, and other processing parameters associated with the first target parameter are referred to as associated parameters, i.e., the first target parameter and the associated parameter are placed in the filling area and simultaneously displayed.

In this embodiment, the display area is only used for displaying, so that the user can check the information such as the category and the number of the processing parameters related to the current processing; the filling area is used for a user to set specific numerical values for each processing parameter.

In order to facilitate the operation, the embodiment splits the filling area in the first processing parameter setting interface, when the user moves the cursor to select the first target parameter (as shown in fig. 3, the diagonal filling pattern indicates the normal modulus of the cursor to be selected at the first head of the worm), the filling area will display the first target parameter and the associated parameter associated with the first target parameter, so that the user is restricted to set the processing parameter only in the filling area.

Furthermore, after each processing parameter is set in the filling area by the user, the cursor automatically selects the next unset processing parameter in the filling area, so that manual operation of the user is not needed, the efficiency of setting the processing parameter is improved, and the processing equipment is beneficial to a novice.

In certain preferred embodiments, referring to fig. 4, the specific steps in step S3A2 include:

S3A2A1, transferring the processing parameters selected by the cursor and other processing parameters related to the processing parameters from the display area to the filling area;

S3A2, adjusting the display areas of the filling area and the display area according to the display quantity of the processing parameters in the filling area and the display quantity of the processing parameters in the display area.

In this embodiment, in order to ensure that the filling area can display the first target parameter and the associated parameter at the same time, after the user selects the first target parameter, the first target parameter and the associated parameter are transferred from the display area to the filling area, and then the display area is more free for further compression and utilization, for example, in fig. 4, after the normal modulus of the second head of the worm is selected, a column of associated parameters related to the second head of the worm is transferred to the filling area together (a column of parameters related to the first head of the worm is still remained in the display area), so as to enlarge the display area of the filling area, thereby meeting the requirement of simultaneously displaying the first target parameter and the associated parameter.

The more the display quantity of the first target parameters and the associated parameters is, the more display areas are needed for the filling area to display the first target parameters and the associated parameters at the same time, so that the display areas of the filling area and the display area can be dynamically adjusted according to the display quantity of the processing parameters in the filling area and the display quantity of the processing parameters in the display area.

Furthermore, the font size and/or the line spacing of the filling area can be properly adjusted to be larger than the display area, so that a user can conveniently set various processing parameters in the filling area.

In certain embodiments, the specific steps in step S3A2 include:

S3A2C1, displaying the processing parameters selected by the cursor and other processing parameters related to the processing parameters in a filling area;

S3A2C2, adjusting the display areas of the filling area and the display area according to the display quantity of the processing parameters in the filling area and the display quantity of the processing parameters in the display area.

In this embodiment, during practical application, the processing parameters displayed in the display area are kept unchanged, and by reducing the font size and/or the line spacing of the display area, more free display area in the display area can be further compressed and utilized, so that the display area of the filling area is enlarged, and the first target parameter and the related parameter are simultaneously displayed.

In certain preferred embodiments, and referring to FIG. 5, the display area of the fill-out area and the display area of the display area are fixed and the display area of the fill-out area is smaller than the display area of the display area;

the specific steps in step S3A2 include:

S3A2B1, acquiring a first total number of other processing parameters related to the processing parameters selected by the cursor;

S3A2B2, when the first total number is smaller than or equal to a preset first threshold value, arranging the processing parameters selected by the cursor and all other related processing parameters thereof in a filling area for display;

and S3A2B3, when the first total number is larger than a preset first threshold value, arranging the processing parameters which are selected by the cursor and are required to be filled in other processing parameters related to the processing parameters in a filling area for display, and marking the processing parameters which are not required to be filled in other processing parameters related to the processing parameters selected by the cursor in a display area.

Because part of the processing parameters are directly calculated by the program, the part of the parameters are not actually required to be filled by a user, for example, the axial modulus is calculated by the normal modulus and the helix angle, and the user only needs to fill the normal modulus and the helix angle.

In this embodiment, when the first total number is less than or equal to the preset first threshold, it indicates that the filling area can display the first target parameter and all the associated parameters at the same time, where the first target parameter and the associated parameters may be transferred from the display area to the filling area for display, or may be retained in the display area and displayed in the filling area.

Furthermore, the font size and/or the line spacing of the filling area can be properly adjusted to be larger than the display area, so that a user can conveniently set various processing parameters in the filling area.

When the first total quantity is larger than a preset first threshold value, the filling area can not display the first target parameters and the associated parameters at the same time, at the moment, only the processing parameters which need to be filled in the first target parameters and the associated parameters are transferred to the filling area for users to fill in numerical values, and the processing parameters which do not need to be filled in the first target parameters and the associated parameters are reserved in the display area and marked (such as highlighting, changing font colors, thickening and the like), so that the user can conveniently set the processing parameters and notice the change of other associated processing parameters.

Further, if all the processing parameters to be filled in the first target parameter and the associated parameters still cannot be simultaneously displayed in the filling area, the first target parameter and the associated parameters can be simultaneously displayed in the filling area by reducing the font size and/or the line spacing of the filling area.

In certain embodiments, the specific steps in step S3 include:

S3C1, changing the layout format of the first processing parameter setting interface according to the second total number of the processing parameters to be set, so that all the processing parameters are simultaneously displayed in the same first processing parameter setting interface.

Further, the layout format includes font size and line space;

the specific steps in the step S3C1 include:

S3C11, when the second total number of machining parameters required to be set is increased, reducing the font size and/or reducing the line spacing;

s3c12. when the second total number of machining parameters to be set is reduced, the font size is enlarged and/or the line space is increased.

In this embodiment, since the number of worm heads affects the second total number of machining parameters to be set, the more the second total number is, the font size is correspondingly reduced and/or the line spacing is reduced, so that the first machining parameter setting interface can display all the machining parameters simultaneously.

Further, the digital font in the processing parameter is smaller in reduction than the text font.

In this embodiment, whether the processing parameters are set correctly or not is actually whether the specific numerical value is correct, and in order to ensure that the user can see the inputted numerical value, when the font size in the first processing parameter setting interface needs to be reduced, the reduction amplitude of the digital font is controlled to be smaller than the reduction amplitude of the text font, for example, the text font is reduced by 3 times, and the digital font is reduced by only 1.5 times.

In certain embodiments, the specific steps in step S3 include:

S3D1, acquiring a processing parameter selected by a cursor as a fourth target parameter;

and S3D2, hiding other processing parameters which are not related to the fourth target parameter.

In this embodiment, when the user sets the value of the fourth target parameter, other processing parameters associated with the fourth target parameter are retained and displayed in the first processing parameter setting interface simultaneously with the fourth target parameter, and other processing parameters not related to the fourth target parameter are hidden; in this way, it is possible to avoid that the other processing parameter not related to the fourth target parameter interferes with the user's view of the change of the other processing parameter related to the fourth target parameter, which is beneficial for the user to know and confirm the other processing parameter related to the fourth target parameter.

Further, in combination with the above embodiment, after hiding other processing parameters that are not related to the fourth target parameter, the font of the related other processing parameters and the fourth target parameter may be appropriately enlarged and/or the line space may be increased, so that the user may more clearly see the change of the related other processing parameters.

In certain preferred embodiments, referring to FIG. 6, the specific steps in step S3 include:

S3B1, hiding a second target parameter with a set value, wherein the second target parameter is a processing parameter which is irrelevant to any other processing parameter.

In this embodiment, for the processing worm, the second target parameters are, for example, the Z-axis moving speed, the arbor rotational speed, the number of cutter teeth, the cutter diameter, the linear speed, and the per-revolution per-tooth feed amount. The second target parameter actually belongs to the tool parameter, which is generally unchanged after the machining device is equipped with the tool. When the user sets the value for the second target parameter and confirms that the value is correct, the second target parameter with the set value is hidden, so that on one hand, the user can be prevented from being interfered by other irrelevant machining parameters to view the change of the relevant machining parameter, on the other hand, more space can be made in the first machining parameter setting interface, and further, in combination with the embodiment, the font of the relevant machining parameter (namely, the content still displayed) can be properly enlarged and/or the line spacing is increased, so that the user can more clearly see the change of the relevant machining parameter.

Further, when the second total number of the processing parameters is greater than a preset second threshold, the user is prompted to set the second target parameters preferentially.

In this embodiment, when the second total number of processing parameters is too large, the font size is reduced and/or the line spacing is reduced so that all the processing parameters are simultaneously displayed in the same first processing parameter setting interface, however, when the font size is too small or the line spacing is too narrow, the user can be influenced to view the processing parameters, so that when the second total number of processing parameters is larger than the second threshold, it is indicated that all the processing parameters can not be simultaneously displayed in the same first processing parameter setting interface by reducing the font size and/or reducing the line spacing any more, and then the user is required to set all the second target parameters preferentially.

In certain embodiments, the specific steps in step S3 include:

S3E1, acquiring a processing parameter selected by a cursor as a fifth target parameter;

S3E2, transferring other processing parameters which are not related to the fifth target parameter to a third processing parameter setting interface, wherein the third processing parameter setting interface is mutually independent of the first processing parameter setting interface.

In this embodiment, when the user sets the value of the fifth target parameter, other processing parameters associated with the fifth target parameter are retained and displayed in the first processing parameter setting interface simultaneously with the fifth target parameter, and other processing parameters not related to the fifth target parameter are transferred to the third processing parameter setting interface; in this way, it is possible to avoid that the other processing parameter not related to the fifth target parameter interferes with the user's view of the change of the other processing parameter related to the fifth target parameter, which is advantageous for the user to know and confirm the other processing parameter related to the fifth target parameter.

In certain preferred embodiments, referring to FIG. 7, the specific steps in step S3 include:

S3F1, transferring the processing parameters which are not related to any other processing parameters to a second processing parameter setting interface, wherein the second processing parameter setting interface is mutually independent of the first processing parameter setting interface.

In this embodiment, a machining parameter that is not related to any of the other machining parameters is used as the second target parameter, and for the machining worm, the second target parameter is, for example, a Z-axis moving speed, a arbor rotating speed, a cutter tooth number, a cutter diameter, a linear speed, and a per-rotation per-tooth feeding amount. The second target parameter actually belongs to the tool parameter, which is generally unchanged after the machining device is equipped with the tool. When the method is actually applied, a user can be prompted to set the second target parameter preferentially, and after the user sets a numerical value for the second target parameter and confirms that no error exists, the second target parameter is transferred to a second processing parameter setting interface; the second target parameter may also be transferred directly to the second process parameter setting interface before the second target parameter is not set to a value.

Transferring the second target parameter to the second processing parameter setting interface can avoid that other processing parameters which are not related interfere with the user to view the change of the related processing parameter, and can make the first processing parameter setting interface make more space.

Further, when the second total number of processing parameters is greater than the preset second threshold, the processing parameters (i.e., the second target parameters) that are not related to any one of the other processing parameters are transferred to the second processing parameter setting interface.

In this embodiment, when the second total number of processing parameters is too large, the font size is reduced and/or the line spacing is reduced so that all the processing parameters are simultaneously displayed in the same first processing parameter setting interface, however, when the font is too small or the line spacing is too narrow, the user can be influenced to view the processing parameters, so that when the second total number of processing parameters is larger than the second threshold, it is indicated that all the processing parameters can not be simultaneously displayed in the same first processing parameter setting interface by reducing the font size and/or the line spacing.

In some embodiments, referring to fig. 8, the multi-start worm processing parameter setting interface display method further comprises the steps of:

s41, obtaining a processing drawing of a worm to be processed;

S42, acquiring a processing parameter table according to the processing drawing;

s43, acquiring filling sequences of all processing parameters according to the processing parameter table;

s44, after one processing parameter is filled in each time, the cursor is controlled to automatically jump according to the filling sequence, and the next processing parameter is selected.

In actual production, because different engineers have different personal habits, certain differences exist in processing drawings presented by the different engineers, for example, the design of a processing parameter table is adopted, and the filling sequence of each processing parameter in the processing parameter table is more determined manually, so that the filling sequence of each processing parameter in the processing parameter table may be different in different processing drawings, for this reason, when a user sets the processing parameters on a processing device, in order to reduce errors (for example, missing a certain processing parameter or setting an error of the processing parameters), the processing parameters are generally filled in the processing device according to the filling sequence of the processing parameter table on the processing drawing, however, the position distribution, the arrangement sequence and the like of the processing parameters displayed by an operation interface in the processing device are preset, the user cannot generally perform operations such as position adjustment or sequence adjustment on the content displayed by the operation interface, which leads to that the user needs to carefully search and determine specific positions of each processing parameter on the operation interface before correctly selecting the processing parameters when setting the processing parameters according to the filling sequence of the processing parameter table, which definitely reduces efficiency of setting the processing parameters by the user and is unfavorable for new use of the processing device.

In this embodiment, after the user sets the first processing parameter, the cursor is controlled to automatically select the next processing parameter according to the filling sequence of each processing parameter in the processing parameter table on the processing drawing; specifically, for example, the order of the processing parameters in the processing parameter table is: ABCDE, when the user writes the processing parameter C, the cursor is selected to the processing parameter D; in this way, the user does not need to manually operate, the efficiency of setting the processing parameters is improved, and the processing equipment is beneficial to new hands.

In certain embodiments, step S43 further comprises:

s45, when all the processing parameters are not set, controlling a cursor to automatically select the processing parameters of the first position of the filling sequence.

In this embodiment, after the user starts the processing device for the first time or manually clears all the processing parameters, in order to facilitate the user to set the processing parameters, the cursor will automatically select the processing parameters at the first position of the filling sequence, and at this time, the user can directly start setting the processing parameters according to the processing parameter table, without carefully searching the processing parameters at the first position of the filling sequence in the operation interface of the processing device.

In some embodiments, the method for displaying the processing parameter setting interface of the multi-start worm further comprises the steps of:

S51, acquiring first modification times of each processing parameter;

s52, according to the first modification times, taking the processing parameter corresponding to the maximum value of the first modification times as a third target parameter;

s53, when the first processing parameter setting interface is switched to each time, the cursor is controlled to be automatically selected on the third target parameter.

In actual production, for new product development, debugging of processing equipment and the like, processing parameters are generally modified for many times, for example, the worm is changed from steel to copper, and then the processing parameters such as the Z-axis moving speed, the cutter shaft rotating speed and the linear speed may need to be changed, and the processing parameters often need to be changed for many times to find the most suitable values, so that the user can modify the processing parameters relatively more frequently.

In the prior art, when the interface is switched, the default selected position of the cursor is generally preset, for example, the first machining parameter is always selected, and when the machining parameter to be modified by the user is different from the machining parameter selected by the default of the cursor, the user often needs to press the forward key or the backward key for multiple times to select the machining parameter to be modified (for the touch screen, the user needs to manually click to select the machining parameter to be modified), which is obviously inconvenient.

In contrast, in this embodiment, the processing parameter (i.e., the third target parameter) that is frequently modified by the user is determined according to the first modification number, and each time the user switches to the first processing parameter setting interface, the cursor is controlled to be automatically selected on the third target parameter, so that the number of times that the user manually selects the processing parameter (i.e., the number of times that the forward key or the backward key is pressed) can be effectively reduced, thereby reducing the user operation and facilitating the user to set the processing parameter.

Further, the specific steps in step S53 include:

S53B1, acquiring third modification times of integer digits and fourth modification times of decimal places of the third target parameter;

S53B2, when the third modification times are larger than the fourth modification times, controlling a cursor to be selected at the last bit of the integer bits of the third target parameters;

S53B3, when the third modification times are smaller than or equal to the fourth modification times, controlling the cursor to select the last bit of the decimal places of the third target parameters.

In real world production, a user may modify integer and decimal places of a portion of the processing parameters, such as workpiece tooth length, lead angle, workpiece tooth pitch, workpiece lead, line speed, etc., while a portion of the user may modify only integer or decimal places.

In the prior art, when the user sets the processing parameter, the default selected position of the cursor is often the last decimal place, and when the user wants to modify the digits and the last decimal place are separated by a plurality of digits, the user often needs to press the forward key or the backward key for multiple times to select the digits to be modified (for the touch screen, the user needs to manually and precisely click to select the digits to be modified), which is obviously inconvenient.

In contrast, in the embodiment, the third modification times and the fourth modification times are compared to determine whether the user frequently modifies the integer digits or the decimal digits, and when the user switches to the first processing parameter setting interface or selects the third target parameter, the cursor is controlled to be automatically selected on the last digit of the integer digits or the last digit of the decimal digits of the third target parameter, so that the number of times of manually adjusting the digits (i.e. the number of times of pressing the forward key or the backward key) by the user can be effectively reduced, the user operation is reduced, and the user is facilitated to set the processing parameters.

Further, the specific steps in step S53 include:

S53A1, obtaining second modification times of each digit of the numerical value of the third target parameter;

S53A2, taking the digit corresponding to the maximum value of the second modification times as the target digit according to the second modification times;

S53A3, controlling the cursor to be automatically selected on the target digit.

In real production, the worm belongs to a high-precision workpiece, the precision of part of processing parameters can reach 4 decimal places or 5 decimal places, for example, the precision of a normal modulus generally reaches 5 decimal places, the precision of a helix angle and a workpiece tooth length generally reaches 4 decimal places, and the precision of a spindle angle increment value generally reaches 9 decimal places because the spindle angle increment value is related to the normal modulus, the helix angle and the workpiece tooth length (can be obtained according to the calculation relation mentioned in the embodiment).

In the prior art, when the user sets the processing parameter, the default selected position of the cursor is often the last decimal place, and when the user wants to modify the digits and the last decimal place are separated by a plurality of digits, the user often needs to press the forward key or the backward key for multiple times to select the digits to be modified (for the touch screen, the user needs to manually and precisely click to select the digits to be modified), which is obviously inconvenient.

In contrast, in the present embodiment, the number of times the user manually adjusts the number of times (i.e. the number of times the forward key or the backward key is pressed) can be further effectively reduced, so that the user operation is further reduced, and the user can set the processing parameters further conveniently.

Referring to fig. 9, fig. 9 is a display device for a multi-start worm processing parameter setting interface in some embodiments of the present invention, which is applied to a multi-start worm processing apparatus and is integrated in a back-end control apparatus in the form of a computer program, and includes:

an acquisition module 100, configured to acquire the number of worm heads of a worm to be processed and a plurality of processing parameters;

the judging module 200 is used for acquiring the correlation among the processing parameters according to the number of worm heads;

the adjustment module 300 is configured to adjust the first processing parameter setting interface according to the correlation between the processing parameters after the equipment enters the processing parameter setting mode, so that the associated processing parameters are simultaneously displayed in the same first processing parameter setting interface.

In some embodiments, the first process parameter setting interface is divided into a fill area and a display area;

the adjustment module 300 is configured to adjust the first processing parameter setting interface according to the correlation between the processing parameters, so that the associated processing parameters are simultaneously displayed in the same first processing parameter setting interface, and perform:

S3A1, arranging the processing parameters in a display area and simultaneously displaying the processing parameters;

And S3A2, arranging the processing parameters selected by the cursor and other processing parameters related to the processing parameters in a filling area for display.

In some embodiments, adjustment module 300 performs when displayed in the fill-out field for arranging the processing parameters selected by the cursor and their associated other processing parameters:

S3A2A1, transferring the processing parameters selected by the cursor and other processing parameters related to the processing parameters from the display area to the filling area;

S3A2, adjusting the display areas of the filling area and the display area according to the display quantity of the processing parameters in the filling area and the display quantity of the processing parameters in the display area.

In some embodiments, the display area of the fill-out area and the display area of the display area are fixed and the display area of the fill-out area is smaller than the display area of the display area;

the adjustment module 300 performs when it is used to display the processing parameters selected by the cursor and their associated other processing parameters in the fill-out area:

S3A2B1, acquiring a first total number of other processing parameters related to the processing parameters selected by the cursor;

S3A2B2, when the first total number is smaller than or equal to a preset first threshold value, arranging the processing parameters selected by the cursor and all other related processing parameters thereof in a filling area for display;

And S3A2B3, when the first total number is larger than a preset first threshold value, arranging the processing parameters which are selected by the cursor and are required to be filled in other processing parameters related to the processing parameters in a filling area for display, and marking the processing parameters which are not required to be filled in other processing parameters related to the processing parameters selected by the cursor in a display area.

In some embodiments, the adjustment module 300 is configured to adjust the first process parameter setting interface based on the correlation between the process parameters such that the associated process parameters are simultaneously displayed in the same first process parameter setting interface when:

S3B1, hiding a second target parameter with a set value, wherein the second target parameter is a processing parameter which is irrelevant to any other processing parameter.

In some embodiments, the adjustment module 300 is configured to adjust the first process parameter setting interface based on the correlation between the process parameters such that the associated process parameters are simultaneously displayed in the same first process parameter setting interface when:

S3F1, transferring the processing parameters which are not related to any other processing parameters to a second processing parameter setting interface, wherein the second processing parameter setting interface is mutually independent of the first processing parameter setting interface.

In some embodiments, the multi-start worm processing parameter setting interface display device further comprises a first control module for performing:

s41, obtaining a processing drawing of a worm to be processed;

s42, acquiring a processing parameter table according to the processing drawing;

s43, acquiring filling sequences of all processing parameters according to the processing parameter table;

s44, after one processing parameter is filled in each time, the cursor is controlled to automatically jump according to the filling sequence, and the next processing parameter is selected.

In some embodiments, the multi-start worm processing parameter setting interface display device further comprises a second control module for performing:

s51, acquiring first modification times of each processing parameter;

s52, according to the first modification times, taking the processing parameter corresponding to the maximum value of the first modification times as a third target parameter;

s53, when the first processing parameter setting interface is switched to each time, the cursor is controlled to be automatically selected on the third target parameter.

In some embodiments, the second control module, each time for switching to the first process parameter setting interface, performs when the control cursor is automatically selected on the third target parameter:

S53A1, obtaining second modification times of each digit of the numerical value of the third target parameter;

S53A2, taking the digit corresponding to the maximum value of the second modification times as the target digit according to the second modification times;

S53A3, controlling the cursor to be automatically selected on the target digit.

Referring to fig. 10, fig. 10 is a schematic structural diagram of an electronic device according to an embodiment of the present invention, and the present invention provides an electronic device 13, including: processor 1301 and memory 1302, processor 1301 and memory 1302 being interconnected and in communication with each other by a communication bus 1303 and/or other form of connection mechanism (not shown), memory 1302 storing computer readable instructions executable by processor 1301, which when the electronic device is running, processor 1301 executes the computer readable instructions to perform the multi-start worm machining parameter setting interface display method in any of the alternative implementations of the above embodiments when executed to implement the following functions: acquiring the number of worm heads of a worm to be processed and a plurality of processing parameters; according to the number of worm heads, obtaining the correlation among all the processing parameters; after the equipment enters a processing parameter setting mode, a first processing parameter setting interface is adjusted according to the correlation among the processing parameters, so that the correlated processing parameters are simultaneously displayed in the same first processing parameter setting interface.

The embodiment of the invention provides a computer readable storage medium, when a computer program is executed by a processor, the method for displaying a multi-start worm processing parameter setting interface in any optional implementation manner of the above embodiment is executed, so as to realize the following functions: acquiring the number of worm heads of a worm to be processed and a plurality of processing parameters; according to the number of worm heads, obtaining the correlation among all the processing parameters; after the equipment enters a processing parameter setting mode, a first processing parameter setting interface is adjusted according to the correlation among the processing parameters, so that the correlated processing parameters are simultaneously displayed in the same first processing parameter setting interface.

The computer readable storage medium may be implemented by any type or combination of volatile or non-volatile Memory devices, such as static random access Memory (Static Random Access Memory, SRAM), electrically erasable Programmable Read-Only Memory (EEPROM), erasable Programmable Read-Only Memory (Erasable Programmable Read Only Memory, EPROM), programmable Read-Only Memory (PROM), read-Only Memory (ROM), magnetic Memory, flash Memory, magnetic disk, or optical disk.

In the embodiments provided in the present invention, it should be understood that the disclosed apparatus and method may be implemented in other manners. The above-described apparatus embodiments are merely illustrative, for example, the division of the units is merely a logical function division, and there may be other manners of division in actual implementation, and for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be through some communication interface, device or unit indirect coupling or communication connection, which may be in electrical, mechanical or other form.

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

Furthermore, functional modules in various embodiments of the present invention may be integrated together to form a single portion, or each module may exist alone, or two or more modules may be integrated to form a single portion.

In this document, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions.

The above description is only an example of the present invention and is not intended to limit the scope of the present invention, and various modifications and variations will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The display method of the multi-head worm processing parameter setting interface is applied to multi-head worm processing equipment and is characterized by comprising the following steps of:

s1, obtaining the number of worm heads of a worm to be processed and a plurality of processing parameters;

s2, acquiring the correlation among the machining parameters according to the number of worm heads;

s3, after the equipment enters a processing parameter setting mode, a first processing parameter setting interface is adjusted according to the correlation among the processing parameters, so that the related processing parameters are simultaneously displayed in the same first processing parameter setting interface;

The first processing parameter setting interface is divided into a filling area and a display area;

the specific steps in the step S3 include:

S3A1, discharging the processing parameters in the display area and displaying the processing parameters simultaneously;

S3A2, arranging the processing parameters selected by the cursor and other processing parameters related to the processing parameters in a filling area for display;

the display area of the filling area and the display area of the display area are fixed, and the display area of the filling area is smaller than the display area of the display area;

the specific steps in step S3A2 include:

S3A2B1, acquiring a first total number of other processing parameters related to the processing parameters selected by the cursor;

S3A2B2, when the first total number is smaller than or equal to a preset first threshold value, arranging the processing parameters selected by the cursor and all other related processing parameters thereof in a filling area for display;

and S3A2B3, when the first total number is larger than a preset first threshold value, arranging the processing parameters which are selected by the cursor and are required to be filled in other processing parameters related to the processing parameters in a filling area, displaying the processing parameters in the display area, and marking the processing parameters which are not required to be filled in other processing parameters related to the processing parameters selected by the cursor in the display area.

2. The method for displaying a multi-start worm machining parameter setting interface according to claim 1, further comprising the steps of:

s41, obtaining a processing drawing of the worm to be processed;

s42, acquiring a processing parameter table according to the processing drawing;

s43, acquiring filling sequences of all the processing parameters according to the processing parameter table;

s44, after one processing parameter is filled in each time, the cursor is controlled to automatically jump according to the filling sequence, and the next processing parameter is selected.

3. The method for displaying a multi-start worm machining parameter setting interface according to claim 1, further comprising the steps of:

s51, acquiring first modification times of each processing parameter;

s52, according to the first modification times, taking the processing parameter corresponding to the maximum value of the first modification times as a third target parameter;

s53, when the first processing parameter setting interface is switched to each time, the cursor is controlled to be automatically selected on the third target parameter.

4. The method for displaying a multi-start worm processing parameter setting interface according to claim 3, wherein the specific steps in step S53 include:

S53A1, obtaining second modification times of each digit of the numerical value of the third target parameter;

S53A2, taking the digit corresponding to the maximum value of the second modification times as a target digit according to the second modification times;

S53A3, controlling a cursor to be automatically selected on the target digit.

5. The utility model provides a multi-start worm processing parameter sets up interface display device, is applied to multi-start worm processing equipment, characterized in that includes:

the acquisition module is used for acquiring the number of worm heads of the worm to be processed and a plurality of processing parameters;

the judging module is used for acquiring the correlation among the processing parameters according to the number of the worm heads;

the adjusting module is used for adjusting a first processing parameter setting interface according to the correlation among the processing parameters after the equipment enters a processing parameter setting mode so that the related processing parameters are simultaneously displayed in the same first processing parameter setting interface;

the first processing parameter setting interface is divided into a filling area and a display area;

the adjustment module is used for adjusting the first processing parameter setting interface according to the correlation among the processing parameters, so that the associated processing parameters are simultaneously displayed in the same first processing parameter setting interface and executed:

S3A1, arranging the processing parameters in a display area and simultaneously displaying the processing parameters;

S3A2, arranging the processing parameters selected by the cursor and other processing parameters related to the processing parameters in a filling area for display;

the display area of the filling area and the display area of the display area are fixed, and the display area of the filling area is smaller than the display area of the display area;

the adjustment module performs when the processing parameters selected by the cursor and other processing parameters associated therewith are arranged to be displayed in the fill-in area:

S3A2B1, acquiring a first total number of other processing parameters related to the processing parameters selected by the cursor;

S3A2B2, when the first total number is smaller than or equal to a preset first threshold value, arranging the processing parameters selected by the cursor and all other related processing parameters thereof in a filling area for display;

and S3A2B3, when the first total number is larger than a preset first threshold value, arranging the processing parameters which are selected by the cursor and are required to be filled in other processing parameters related to the processing parameters in a filling area for display, and marking the processing parameters which are not required to be filled in other processing parameters related to the processing parameters selected by the cursor in a display area.

6. An electronic device comprising a processor and a memory storing computer readable instructions that, when executed by the processor, perform the steps of the method of displaying a multi-start worm process parameter setting interface of any one of claims 1-4.

7. A computer readable storage medium having stored thereon a computer program, which when executed by a processor performs the steps of the method for displaying a multi-start worm machining parameter setting interface according to any one of claims 1-4.