CN115673394A - Key cutting method, key cutting device, key cutting machine, and storage medium - Google Patents

Abstract

The application relates to a key cutting method, a key cutting device, a key cutting machine and a storage medium. The method comprises the following steps: displaying a key cutting control interface; the key cutting control interface comprises a movement control for representing an orientation; and responding to the triggering operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the target position represented by the triggered mobile control. By adopting the method, customization can be realized in a time-saving and labor-saving manner.

Description

Key cutting method, key cutting device, key cutting machine, and storage medium

Technical Field

The application relates to the technical field of key processing, in particular to a key cutting method, a key cutting device, a key cutting machine and a storage medium.

Background

The key cutting mode generally includes a manual cutting mode and an automatic cutting mode. The manual cutting mode is flexible to operate but is time-consuming and labor-consuming. The automatic cutting mode has the condition judgment on various key blanks, cannot meet the requirements under special conditions, and has poor universality. The traditional key cutting mode can not take the advantages of the two modes into consideration.

Disclosure of Invention

In view of the above, it is necessary to provide a key cutting method, a key cutting device, a key cutting machine, and a storage medium, which can achieve customization in a time-saving and labor-saving manner.

A key cutting method, the method comprising:

displaying a key cutting control interface; the key cutting control interface comprises a movement control for representing an orientation;

and responding to the triggering operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the target position represented by the triggered mobile control.

A key cutting device, the device comprising:

the display module is used for displaying a key cutting control interface; the key cutting control interface includes a movement control for representing an orientation;

and the control module is used for responding to the triggering operation of the mobile control, and controlling the cutting tool to cut the key to be processed according to the target position represented by the triggered mobile control.

A key cutting machine for implementing the steps of each key cutting method embodiment.

A computer-readable storage medium, on which a computer program is stored which, when being executed by a processor, carries out the steps of the respective key cutting method embodiment.

According to the key cutting method, the key cutting device, the key cutting machine and the storage medium, the mobile control used for representing the position is arranged on the key cutting control interface, the cutting tool is controlled to cut the key to be processed in response to the triggering operation of the mobile control, the target position represented by the triggered mobile control is used for controlling the cutting tool to cut, then the user can trigger the mobile control to control the trend of the cutting tool, semi-automatic self-defined cutting of the key to be processed is achieved, compared with a manual cutting mode and an automatic cutting mode, customization can be achieved in a time-saving and labor-saving mode, and the universality is high.

Drawings

FIG. 1 is a diagram of an environment in which a key cutting method according to one embodiment may be used;

FIG. 2 is a schematic flow chart diagram of a key cutting method in one embodiment;

FIG. 3 is a schematic interface diagram of a key cutting control interface in one embodiment;

FIG. 4 is a schematic interface diagram of an orientation in one embodiment;

FIG. 5 is a schematic interface diagram of a step speed modification interface in one embodiment;

FIG. 6 is a schematic diagram of a single-step movement distance modification interface in one embodiment;

fig. 7 is a block diagram of a key cutting device according to an embodiment.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The technical solutions in the embodiments of the present application will be described clearly and completely with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without inventive step, are within the scope of the present disclosure.

It should be noted that all directional indicators (such as upper, lower, left, right, front and rear \8230;) in the embodiments of the present application are only used for explaining the relative positional relationship between the components, the motion situation, etc. in a specific posture (as shown in the attached drawings), and if the specific posture is changed, the directional indicators are correspondingly changed, and the connection can be a direct connection or an indirect connection.

It is to be understood that "connection" in the following embodiments is to be understood as "electrical connection", "communication connection", and the like if the connected circuits, modules, units, and the like have communication of electrical signals or data with each other.

The key cutting method provided by the application can be applied to the application environment as shown in fig. 1. FIG. 1 is a diagram of an embodiment of a key cutting method. Included in fig. 1 are a key cutter 100 and a key 110 to be processed. The key cutting machine 100 includes a display screen 101 and a cutting tool 102. The display screen 101 may be embedded in the key cutting machine 100 or may be vertically disposed. The cutting tool 102 may be a milling cutter, a diamond cutter, a laser, or the like. The following embodiments are described with the cutting tool 102 as a milling cutter.

In one embodiment, as shown in fig. 2, a key cutting method is provided, which is described by taking the application of the key cutting method to a key cutting machine as an example, and comprises the following steps:

step 202, displaying a key cutting control interface; the key cutting control interface includes a movement control for representing an orientation.

The control can be a key used for controlling on the interface of the touch screen. The key cutting control interface comprises a mobile control display area. The movement control display area includes a movement control for representing an orientation. The movement control is used to control the movement of the cutting tool.

The movement control may be a circle, and the user moves towards the control cutting tool through the touch circle. The movement control may also be a button on the screen of the key cutter to indicate orientation. The orientations are specifically orientations on three-dimensional coordinate axes, namely two orientations of an X axis, two orientations of a Y axis, and two orientations of a Z axis. For example, the movement controls include an X-axis negative direction control, an X-axis positive direction movement control, a Y-axis negative direction movement control, a Y-axis positive direction movement control, a Z-axis negative direction control, and a Z-axis positive direction movement control. Or moving controls include moving controls left, moving controls right, moving controls forward, moving controls backward, moving controls up, moving controls down, and the like.

Specifically, in response to a triggering operation on the manual cutting control, the key cutting machine displays a key cutting control interface. The key cutting control interface includes a movement control for representing an orientation. The key cutting control interface may also include an initialization control.

And 204, responding to the triggering operation of the mobile control, and controlling the cutting tool to cut the key to be processed according to the target position represented by the triggered mobile control.

The triggering operation can be realized by touching the interface of the key cutting machine. When the movement control is displayed as a circle, the triggering operation may also be an operation by sliding or scrolling around the movement control.

The target orientation refers to the orientation represented by the triggered movement control. If the right movement control is triggered, then the cutting tool moves to the right.

The key to be processed can be a key blank, a key with damage or a normally used key.

Specifically, the milling cutter is controlled to rotate in response to an operation to start the spindle. Wherein the operation of starting the spindle is used to control the rotation of the milling cutter to cut the key to be processed. The milling cutter rotates by taking a main shaft of the milling cutter as an axis. The user clicks the move control. And responding to the triggering operation of the movable control, and controlling the rotating milling cutter to move according to the target position represented by the triggered movable control by the key cutting machine so as to cut the key to be processed. For example, if the user clicks the right shift control, the milling cutter cuts the key to be processed to the right.

In the embodiment, the mobile control used for representing the direction is arranged on the key cutting control interface, the triggering operation of the mobile control is responded, the cutting tool is controlled to cut the key to be processed according to the target direction represented by the triggered mobile control, and then the user can trigger the mobile control to control the trend of the cutting tool, so that the semi-automatic self-defined cutting of the key to be processed is realized, compared with the manual cutting and automatic cutting modes, the customization can be realized in a time-saving and labor-saving manner, and the universality is strong.

In one embodiment, in response to the triggering operation on the moving control, the cutting tool is controlled to cut the key to be processed in the target position represented by the triggered moving control, and the method includes:

displaying a parameter setting area on a key cutting control interface; the parameter setting area comprises a parameter modification control;

responding to the triggering operation of the parameter modification control, and displaying a parameter modification interface;

acquiring an input target cutting parameter in a parameter modification interface;

and responding to the triggering operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the target cutting parameters by using the target position represented by the triggered mobile control.

Wherein the parameter setting area may be a portion of a key cutting control interface. The parameter modification control is used for entering a parameter modification interface. The parameter modification interface is used for modifying cutting parameters of the key cutting machine. The cutting parameters include stepping speed, single step moving distance, etc.

Specifically, a key cutting control interface comprises a parameter setting area; the parameter setting area includes a parameter modification control. And responding to the triggering operation of the parameter modification control, and entering a parameter modification interface. And acquiring the input target cutting parameters in the parameter modification interface. The input mode can be input through a keyboard or corresponding preset options are selected.

And controlling the milling cutter to rotate in response to the operation of starting the spindle. And in response to the triggering operation of the mobile control, the key cutting machine controls the rotary milling cutter to move according to the target position represented by the triggered mobile control and the target cutting parameters so as to cut the key to be processed.

In the embodiment, the parameter modification control enters the parameter modification interface, the input target cutting parameter is obtained in the parameter modification interface, the triggering operation of the mobile control is responded, the cutting tool is controlled to cut the key to be processed according to the target cutting parameter in the target direction represented by the triggered mobile control, the user can adjust to the more appropriate parameter, the key cutting efficiency is improved, and meanwhile the user experience is improved.

In one embodiment, the parameter modification control comprises a step speed modification control.

Responding to the triggering operation of the parameter modification control, and displaying a parameter modification interface, wherein the parameter modification interface comprises:

responding to the trigger operation of the stepping speed modification control, and displaying a stepping speed modification interface;

displaying step speed options of each axis on a step speed modification interface, wherein the step speed options of each axis comprise at least one of an X-axis step speed option, a Y-axis step speed option and a Z-axis step speed option;

responding to the selection operation of the stepping speed in the stepping speed option, and acquiring an X-axis stepping speed, a Y-axis stepping speed and a Z-axis stepping speed;

responding to the triggering operation of the mobile control, controlling a cutting tool to cut the key to be processed according to the target cutting parameters by using the target position represented by the triggered mobile control, and comprising the following steps:

and responding to the triggering operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the X-axis stepping speed, the Y-axis stepping speed and the Z-axis stepping speed by using the target position represented by the triggered mobile control.

Specifically, the step speed refers to a moving speed of the stepping motor. And the step speed modification control is used for triggering to enter a step speed modification interface. And responding to the triggering operation of the stepping speed modification control, and entering a stepping speed modification interface. And displaying the step speed options of all the axes on the step speed modification interface. The step speed option includes at least one of an X-axis step speed option, a Y-axis step speed option, and a Z-axis step speed option. The X-axis step speed options include low, medium, and high speed. Likewise, the Y-axis step speed option and the Z-axis step speed option may each include a low speed, a medium speed, and a high speed.

In response to a selection operation of the step speed in the step speed option, such as selection of a low speed, the key cutting machine acquires the X-axis step speed, the Y-axis step speed, and the Z-axis step speed after confirmation of the step speed. It will be appreciated that the user selects only the X-axis step speed to be the low speed, and that the key cutting machine can still obtain the X-axis step speed, the Y-axis step speed, and the Z-axis step speed due to the existence of the default step speed.

And controlling the milling cutter to rotate in response to the operation of starting the spindle. And responding to the triggering operation of the mobile control, and controlling the stepping motor according to the X-axis stepping speed, the Y-axis stepping speed and the Z-axis stepping speed by using the target position represented by the triggered mobile control, so as to control the rotary milling cutter to move and cut the key to be processed.

In this embodiment, step speed options of each axis are displayed on a step speed modification interface, the step speed options of each axis include an X-axis step speed option, a Y-axis step speed option, and a Z-axis step speed option, and the X-axis step speed, the Y-axis step speed, and the Z-axis step speed are obtained in response to a step speed selection operation in the step speed options; the method has the advantages that the triggering operation of the movable control is responded, the cutting tool is controlled to cut the key to be processed according to the target position represented by the triggered movable control and the stepping speed of each shaft, cutting related parameters can be modified according to requirements, the use is more convenient, and the key cutting efficiency is improved.

In one embodiment, the parameter modification control comprises a single step movement distance modification control;

responding to the triggering operation of the parameter modification control, and displaying a parameter modification interface, wherein the parameter modification interface comprises:

responding to the triggering operation of the single-step movement distance modification control, and displaying a single-step movement distance modification interface;

displaying single-step movement distance options of each axis on a single-step movement distance modification interface, wherein the single-step movement distance options of each axis comprise at least one of X-axis single-step movement distance options, Y-axis single-step movement distance options and Z-axis single-step movement distance options;

acquiring an X-axis single step movement distance, a Y-axis single step movement distance and a Z-axis single step movement distance in response to the operation of selecting the single step movement distance in the single step movement distance option;

responding to the triggering operation of the mobile control, controlling a cutting tool to cut the key to be processed according to the target cutting parameters by using the target position represented by the triggered mobile control, and comprising the following steps:

the cutting tool is controlled to rotate in response to operation of the start spindle. And in response to the triggering operation of the mobile control, controlling the rotary cutting tool to move according to the X-axis single step movement distance, the Y-axis single step movement distance and the Z-axis single step movement distance in the target position represented by the triggered mobile control so as to cut the key to be processed.

Specifically, the single step movement distance refers to the distance the cutting tool moves each time the movement control is triggered. The single step distance modification control is used for triggering the entering of the single step movement distance modification interface. And displaying a single-step movement distance option of each axis on the single-step distance modification interface. The step movement distance option includes at least one of an X-axis step movement distance option, a Y-axis step movement distance option, and a Z-axis step movement distance option. The X-axis single step distance options may include 5, 10, 15, 20, etc. Likewise, the Y-axis step distance option and the Z-axis step distance option may each include 5, 10, 15, 20, etc.

In response to the selection operation of the single step movement distance in the single step movement distance option, if the Z-axis single step movement distance is selected to be 5, after the confirmation of the step speed, the key cutting machine acquires the X-axis single step movement distance, the Y-axis single step movement distance, and the Z-axis single step movement distance. It can be appreciated that the user only selects the Z-axis single step movement distance to be 5, and the key cutting machine can still obtain the X-axis single step movement distance, the Y-axis single step movement distance and the Z-axis single step movement distance due to the existence of the default single step movement distance.

And responding to the triggering operation of the movement control, and controlling the stepping motor according to the X-axis single-step movement distance, the Y-axis single-step movement distance and the Z-axis single-step movement distance by using the target position represented by the triggered movement control, so as to control the movement of the cutting tool to cut the key to be processed.

In the embodiment, single-step moving distance options of each axis are displayed on the single-step moving distance modification interface, the single-step moving distance options comprise an X-axis moving distance option, a Y-axis moving distance option and a Z-axis moving distance option, the cutting tool is controlled to cut the key to be processed according to the single-step moving distance of each axis by responding to the triggering operation of the moving control and the target position represented by the triggered moving control, and cutting related parameters can be modified according to requirements, so that the use is more convenient for a user, and the key cutting efficiency is improved.

In one embodiment, the key cutting method further comprises: displaying a recovery default control in the parameter setting area; and setting the parameters as default cutting parameters in response to the triggering operation of the recovery default control.

Specifically, the restore default control is used to set the parameters to default cutting parameters. And the key cutting machine displays the recovery default control in the parameter setting area. In response to a triggering operation of the restoration default control, the key cutting machine sets the parameters to default cutting parameters. And responding to the triggering operation of the movable control, and cutting the key to be processed by the key cutting machine according to the default cutting parameters in the target direction represented by the triggered movable control.

In this embodiment, a recovery default control is displayed in the parameter setting area, and when the recovery default control is triggered, the parameter is set as a default cutting parameter, so that initialization of the parameter and the like can be realized, and the key to be processed is cut according to the default cutting parameter in response to the triggering operation of the mobile control and the target position represented by the triggered mobile control.

In one embodiment, as shown in FIG. 3, a schematic interface diagram of a key cutting control interface in one embodiment is shown. A key cutting interface 300 is included in fig. 3. The key cutting interface includes a parameter setting area 310 and a movement control display area 320. The parameter settings area 310 includes a step speed modification control 311, a restore default control 312, a single step movement distance modification control 313, a restore default control 314. The movement control display area 320 includes an X-axis negative direction movement control 321, an X-axis positive direction movement control 322, a Y-axis negative direction movement control 323, a Y-axis positive direction movement control 324, a Z-axis positive direction movement control 325, and a Z-axis negative direction movement control 326. The parameter settings area 310 also includes a reset control, an initialize control, and a start spindle control. And responding to the starting of the spindle control, starting to rotate the cutting tool, and controlling the cutting tool to move towards the corresponding direction by triggering the moving control so as to control the cutting tool to cut the key to be processed. And setting parameters as default cutting parameters in response to the triggering operation of the recovery default control. The orientation diagram of fig. 4 is displayed by a trigger operation on the small graph showing XYZ axes in fig. 3. FIG. 4 is an interface diagram of an orientation in one embodiment. In fig. 4 is a key holder. The directions of the X, Y and Z axes are shown in FIG. 4.

In response to the triggering operation of step speed modification control 311 in fig. 3, a step speed modification interface is displayed. FIG. 5 is a schematic interface diagram of a step speed modification interface in one embodiment. Including an X-axis step speed option 501, an X-axis step speed option 502, and an X-axis step speed option 503; a Y-axis step speed option 511, a Y-axis step speed option 512, and a Y-axis step speed option 513; a Z-axis step velocity option 521, a Z-axis step velocity option 522, and a Z-axis step velocity option 523. FIG. 5 also includes a determine control and a cancel control. Fig. 5 the user has selected the X-axis step speed option 502, the Y-axis step speed option 512, and the Z-axis step speed option 522, i.e., medium, and low. Then the X-axis stepping speed is medium, the Y-axis stepping speed is medium, and the Z-axis stepping speed is low. After the determination control is triggered, a spindle control can be triggered to start to control the cutting tool to rotate. And responding to the triggering operation of the mobile control, and controlling the rotating cutting tool to move according to the intermediate speed of the X-axis stepping speed, the intermediate speed of the Y-axis stepping speed and the low speed of the Z-axis stepping speed by using the target position represented by the triggered mobile control so as to cut the key to be processed.

In response to the triggering operation of the single-step movement distance modification control 313 in fig. 3, a single-step movement distance modification interface is displayed. FIG. 6 is a schematic diagram of a single-step movement distance modification interface in one embodiment. The X-axis single step movement distance option 601, the X-axis single step movement distance option 602, the X-axis single step movement distance option 603, and the X-axis single step movement distance option 604 are included; a Y-axis single step movement distance option 611, a Y-axis single step movement distance option 612, a Y-axis single step movement distance option 613, and a Y-axis single step movement distance option 614; a Z-axis step distance option 621, a Z-axis step distance option 622, a Z-axis step distance option 623, and a Z-axis step distance option 624. FIG. 6 also includes a determine control and a cancel control. The user selects the X-axis single step movement distance 601, the Y-axis single step movement distance 613, and the Z-axis single step movement distance 622, i.e., 5, 20 (default), and 10 (default), in fig. 6. After the determination control is triggered, in response to the triggering operation on the movement control, the cutting tool is controlled to cut the key to be processed according to the X-axis single-step movement distance of 5, the Y-axis single-step movement distance of 20 and the Z-axis single-step movement distance of 10 in the target position represented by the triggered movement control.

The embodiment aims to provide a feasible method for the user to custom-machine the key, and secondary custom-machining is carried out on the key blank according to the requirements of the user under the condition that the functions of the key are not influenced. And a user sets the stepping speed and the single-step moving distance of the stepping motor according to actual requirements, and then controls the trend of the cutting tool through the button to perform custom processing. For example, the key cutting method in the embodiment of the present application may be used for cutting different key blanks to cut different types of keys, such as outer milled keys, inner milled keys, and the like; the method can be used for further processing of damaged keys and can also be used for customization operations such as lettering on the keys. Other utensils are cut to very easily mistake to simple manual cutting, and this embodiment can accomplish to restrict the range of motion of cutting means and protect anchor clamps.

In one embodiment, in response to the triggering operation on the moving control, the cutting tool is controlled to cut the key to be processed in the target position represented by the triggered moving control, and the method includes:

and responding to the triggering operation of the mobile control, and controlling the cutting tool to continuously cut the key according to the triggering duration corresponding to the triggered mobile control and the target position represented by the triggered mobile control.

Specifically, in response to the triggering operation on the mobile control, the target position represented by the triggered mobile control is used for controlling the cutting tool to continuously move according to the triggering duration corresponding to the triggered mobile control, so that the key is continuously cut. If the triggering time of the control part moving to the right is 2 seconds, the cutting tool is controlled to move to the right for 2 seconds. Or the triggering time of the control moving rightwards is 2 seconds, the corresponding click times are 5 times, the cutting tool is controlled to move rightwards 5 times, and the moving distance is 5 times the single-step moving distance.

In the embodiment, in response to the triggering operation on the mobile control, the cutting tool is controlled to continuously cut the key according to the triggering duration corresponding to the triggered mobile control and the target position represented by the triggered mobile control, so that the smoothness of key cutting can be improved.

In one embodiment, the key cutting method further comprises: detecting a boss of a clamp for clamping a key to be processed; determining the range of the clamp by taking the boss as a reference position; when the cutting tool moves to the edge of the range, a prompt message that the boundary has been reached is displayed, and the cutting tool movement is restricted.

Specifically, the boss of the jig is higher than the jig for positioning the position of the jig. The key cutting machine detects the boss of the clamp for clamping the key to be processed through the probe. And determining the range of the clamp by taking the boss as a reference position and combining the related sizes of the clamp stored in the key cutting machine. It is understood that the range of the clamp may refer to the clamping range of the clamp, or may refer to the range of the outer frame where the clamp itself is located. When the cutting tool moves to the edge of the range, a prompt message that the boundary has been reached is displayed on the display screen, and the cutting tool is restricted from moving within the range beyond the range.

In the embodiment, other appliances are easily mistakenly cut during semi-automatic control cutting, the range of the clamp is determined by detecting the boss, and when the cutting tool moves to the edge of the range, a prompt message that the cutting tool reaches the boundary is displayed to limit the movement of the cutting tool, so that the clamp can be protected.

In one embodiment, a key cutting method includes:

and (a 1) displaying a key cutting control interface. The key cutting control interface includes a movement control for representing an orientation.

And (a 2) displaying a parameter setting area on a key cutting control interface. The parameter setting area includes a parameter modification control.

And (a 3) detecting a boss of a clamp for clamping the key to be processed.

And (a 4) determining the range of the clamp by taking the boss as a reference position.

And (a 5) responding to the triggering operation of the parameter modification control, and displaying a parameter modification interface.

And (a 6) responding to the triggering operation of the stepping speed modification control, and displaying a stepping speed modification interface.

And (a 7) displaying step speed options of each axis on a step speed modification interface, wherein the step speed options of each axis comprise at least one of an X-axis step speed option, a Y-axis step speed option and a Z-axis step speed option.

And (a 8) responding to the selection operation of the stepping speed in the stepping speed option, and acquiring an X-axis stepping speed, a Y-axis stepping speed and a Z-axis stepping speed.

And (a 9) displaying a single step movement distance modification interface in response to the triggering operation of the single step movement distance modification control.

And (a 10) displaying single-step movement distance options of each axis on a single-step movement distance modification interface, wherein the single-step movement distance options of each axis comprise at least one of an X-axis single-step movement distance option, a Y-axis single-step movement distance option and a Z-axis single-step movement distance option.

And (a 11) acquiring the X-axis single step movement distance, the Y-axis single step movement distance and the Z-axis single step movement distance in response to the selection operation of the single step movement distance in the single step movement distance option.

And (a 12) in response to the triggering operation of the mobile control, controlling the cutting tool to cut the key to be processed according to the X-axis stepping speed, the Y-axis stepping speed, the Z-axis stepping speed, the X-axis single-step moving distance, the Y-axis single-step moving distance and the Z-axis single-step moving distance by using the target position represented by the triggered mobile control.

And (a 13) displaying a prompt message that the boundary has been reached when the cutting tool moves to the edge of the range, and restricting the cutting tool from moving.

In the embodiment, the mobile control used for representing the direction is arranged on the key cutting control interface, the cutting tool is controlled to cut the key to be processed in response to the triggering operation of the mobile control and the target direction represented by the triggered mobile control, so that a user can control the trend of the cutting tool by triggering the mobile control, semi-automatic self-defined cutting of the key to be processed is realized, compared with manual cutting and automatic cutting, customization can be realized in a time-saving and labor-saving manner, and the universality is strong; the clamp may be protected by limiting the movement of the cutting tool.

It should be understood that, although each of the above-described steps (a 1) to (a 13) is sequentially displayed as indicated by a reference numeral, the steps are not necessarily sequentially performed in the order indicated by an arrow or a numeral. The steps are not limited to being performed in the exact order illustrated and, unless explicitly stated herein, may be performed in other orders. Moreover, at least a part of the steps (a 1) to (a 13) may include a plurality of steps or a plurality of stages, which are not necessarily performed at the same time, but may be performed at different times, and the order of performing the steps or stages is not necessarily sequential, but may be performed alternately or alternately with other steps or at least a part of the steps or stages in other steps.

In one embodiment, as shown in FIG. 7, a block diagram of a key cutting device in one embodiment is shown. Fig. 7 provides a key cutting device, which may be a software module or a hardware module, or a combination of both, as a part of a key cutting machine, specifically comprising: a display module 702 and a control module 704, wherein:

a display module 702, configured to display a key cutting control interface; the key cutting control interface comprises a movement control for representing the orientation;

and the control module 704 is configured to, in response to the triggering operation on the mobile control, control the cutting tool to cut the key to be processed in the target orientation represented by the triggered mobile control.

In the embodiment, the mobile control used for representing the position is arranged on the key cutting control interface, the triggering operation of the mobile control is responded, the cutting tool is controlled to cut the key to be processed according to the target position represented by the triggered mobile control, and then the user can trigger the mobile control to control the trend of the cutting tool, so that the semi-automatic user-defined cutting of the key to be processed is realized, compared with the manual cutting and automatic cutting modes, the customization can be realized in a time-saving and labor-saving manner, and the universality is strong.

In one embodiment, the display module 702 is configured to: displaying a parameter setting area on a key cutting control interface; the parameter setting area comprises a parameter modification control; responding to the triggering operation of the parameter modification control, and displaying a parameter modification interface; acquiring an input target cutting parameter in a parameter modification interface; the control module 704 is configured to: and responding to the triggering operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the target cutting parameters by using the target position represented by the triggered mobile control.

In the embodiment, the parameter modification control enters the parameter modification interface, the input target cutting parameter is obtained in the parameter modification interface, the triggering operation of the mobile control is responded, the cutting tool is controlled to cut the key to be processed according to the target cutting parameter in the target direction represented by the triggered mobile control, the user can adjust to the more appropriate parameter, the key cutting efficiency is improved, and meanwhile the user experience is improved.

In one embodiment, the parameter modification control comprises a step speed modification control. The display module 702 is configured to: responding to the triggering operation of the stepping speed modification control, and displaying a stepping speed modification interface; displaying step speed options of each axis on a step speed modification interface, wherein the step speed options of each axis comprise at least one of an X-axis step speed option, a Y-axis step speed option and a Z-axis step speed option; responding to the selection operation of the stepping speed in the stepping speed option, and acquiring an X-axis stepping speed, a Y-axis stepping speed and a Z-axis stepping speed; the control module 704 is configured to: and responding to the triggering operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the X-axis stepping speed, the Y-axis stepping speed and the Z-axis stepping speed by using the target position represented by the triggered mobile control.

In this embodiment, step speed options of each axis are displayed on a step speed modification interface, the step speed options of each axis include an X-axis step speed option, a Y-axis step speed option, and a Z-axis step speed option, and in response to a step speed selection operation in the step speed options, an X-axis step speed, a Y-axis step speed, and a Z-axis step speed are obtained; the method has the advantages that the triggering operation of the movable control is responded, the cutting tool is controlled to cut the key to be processed according to the target position represented by the triggered movable control and the stepping speed of each shaft, cutting related parameters can be modified according to requirements, the use is more convenient, and the key cutting efficiency is improved.

In one embodiment, the parameter modification control comprises a single step movement distance modification control. The display module 702 is configured to: responding to the triggering operation of the single-step movement distance modification control, and displaying a single-step movement distance modification interface;

displaying single-step movement distance options of each axis on a single-step movement distance modification interface, wherein the single-step movement distance options of each axis comprise at least one of X-axis single-step movement distance options, Y-axis single-step movement distance options and Z-axis single-step movement distance options;

responding to the selection operation of the single-step moving distance in the single-step moving distance option, and acquiring the X-axis single-step moving distance, the Y-axis single-step moving distance and the Z-axis single-step moving distance;

the control module 704 is configured to: the cutting tool is controlled to rotate in response to the operation of the start spindle. And in response to the triggering operation of the mobile control, controlling the rotary cutting tool to move according to the X-axis single step movement distance, the Y-axis single step movement distance and the Z-axis single step movement distance in the target position represented by the triggered mobile control so as to cut the key to be processed.

In the embodiment, single-step moving distance options of each axis are displayed on the single-step moving distance modification interface, the single-step moving distance options comprise an X-axis moving distance option, a Y-axis moving distance option and a Z-axis moving distance option, the cutting tool is controlled to cut the key to be processed according to the single-step moving distance of each axis by responding to the triggering operation of the moving control and according to the target position represented by the triggered moving control, cutting related parameters can be modified according to requirements, the use of a user is more convenient, and the key cutting efficiency is improved.

In one embodiment, the display module 702 is further configured to display a restore default control in the parameter setting area; and setting the parameters as default cutting parameters in response to the triggering operation of the recovery default control.

In this embodiment, a recovery default control is displayed in the parameter setting area, and when the recovery default control is triggered, the parameter is set as a default cutting parameter, so that initialization of the parameter and the like can be realized, and the key to be processed is cut according to the default cutting parameter in response to the triggering operation of the mobile control and the target position represented by the triggered mobile control.

For specific limitations of the key cutting device, reference may be made to the above limitations of the key cutting method, which are not described in detail herein. The various modules in the key cutting apparatus described above may be implemented in whole or in part by software, hardware, and combinations thereof. The modules can be embedded in a hardware form or independent from a processor in the key cutting machine, and can also be stored in a memory in the key cutting machine in a software form, so that the processor can call and execute operations corresponding to the modules.

In one embodiment, a key cutting machine is provided for carrying out the steps of the above-described method embodiments.

In one embodiment, a computer-readable storage medium is provided, on which a computer program is stored which, when being executed by a processor, carries out the steps of the above-mentioned method embodiments.

In one embodiment, a computer program product or computer program is provided that includes computer instructions stored in a computer readable storage medium. The computer instructions are read by a processor of the computer device from the computer-readable storage medium, and the computer instructions are executed by the processor to cause the computer device to perform the steps in the above-mentioned method embodiments.

It will be understood by those skilled in the art that all or part of the processes of the methods of the above embodiments may be implemented by hardware related to instructions of a computer program, which may be stored in a non-volatile computer readable storage medium, and when executed, may include the processes of the above embodiments of the methods. Any reference to memory, storage, database or other medium used in the embodiments provided herein can include at least one of non-volatile and volatile memory. Non-volatile Memory may include Read-Only Memory (ROM), magnetic tape, floppy disk, flash Memory, optical Memory, or the like. Volatile Memory can include Random Access Memory (RAM) or external cache Memory. By way of illustration and not limitation, RAM can take many forms, such as Static Random Access Memory (SRAM) or Dynamic Random Access Memory (DRAM), among others.

The above description is only a preferred embodiment of the present application, and not intended to limit the scope of the present application, and all modifications of equivalent structures and equivalent processes, which are made by the contents of the specification and the drawings of the present application, or which are directly or indirectly applied to other related technical fields, are also included in the scope of the present application.

Claims (10)

1. A key cutting method, characterized in that the method comprises:

displaying a key cutting control interface; the key cutting control interface includes a movement control for representing an orientation;

and responding to the triggering operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the target position represented by the triggered mobile control.

2. The method of claim 1, wherein the controlling a cutting tool to cut the key to be processed in the target position represented by the triggered moving control in response to the triggering operation of the moving control comprises:

displaying a parameter setting area on the key cutting control interface; the parameter setting area comprises a parameter modification control;

responding to the triggering operation of the parameter modification control, and displaying a parameter modification interface;

acquiring input target cutting parameters in the parameter modification interface;

and responding to the triggering operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the target cutting parameters by using the target position represented by the triggered mobile control.

3. The method of claim 2, wherein the parameter modification control comprises a step speed modification control;

the responding to the triggering operation of the parameter modification control, and displaying a parameter modification interface, including:

responding to the triggering operation of the stepping speed modification control, and displaying a stepping speed modification interface;

displaying step speed options of each axis on the step speed modification interface, wherein the step speed options of each axis comprise at least one of an X-axis step speed option, a Y-axis step speed option and a Z-axis step speed option;

responding to the selection operation of the stepping speed in the stepping speed option, and acquiring an X-axis stepping speed, a Y-axis stepping speed and a Z-axis stepping speed;

the step of responding to the trigger operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the target cutting parameter by using the target position represented by the triggered mobile control, includes:

and responding to the triggering operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the X-axis stepping speed, the Y-axis stepping speed and the Z-axis stepping speed by using the target position represented by the triggered mobile control.

4. The method of claim 2, wherein the parameter modification control comprises a single step movement distance modification control;

the responding to the triggering operation of the parameter modification control, and displaying a parameter modification interface, including:

responding to the triggering operation of the single step movement distance modification control, and displaying a single step movement distance modification interface;

displaying single-step movement distance options of each axis on the single-step movement distance modification interface, wherein the single-step movement distance options of each axis comprise at least one of an X-axis single-step movement distance option, a Y-axis single-step movement distance option and a Z-axis single-step movement distance option;

acquiring an X-axis single step movement distance, a Y-axis single step movement distance and a Z-axis single step movement distance in response to the operation of selecting the single step movement distance in the single step movement distance option;

the step of responding to the trigger operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the target cutting parameter by using the target position represented by the triggered mobile control, includes:

and responding to the triggering operation of the mobile control, and controlling a cutting tool to cut the key to be processed according to the X-axis single step movement distance, the Y-axis single step movement distance and the Z-axis single step movement distance by using the target position represented by the triggered mobile control.

5. The method of claim 2, further comprising:

displaying a default restoring control in the parameter setting area;

and setting parameters as default cutting parameters in response to the triggering operation of the recovery default control.

6. The method of claim 1, wherein the controlling the cutting tool to cut the key to be processed in response to the triggering operation on the mobile control at the target orientation represented by the triggered mobile control comprises:

and responding to the triggering operation of the mobile control, and controlling a cutting tool to continuously cut the key according to the triggering duration corresponding to the triggered mobile control and the target position represented by the triggered mobile control.

7. The method of any of claims 1 to 6, further comprising:

detecting a boss of a clamp for clamping the key to be processed;

determining the range of the clamp by taking the boss as a reference position;

when the cutting tool moves to the edge of the range, a prompt message that a boundary has been reached is displayed and the cutting tool is restricted from moving.

8. A key cutting device, characterized in that the device comprises:

the display module is used for displaying a key cutting control interface; the key cutting control interface comprises a movement control for representing an orientation;

and the control module is used for responding to the triggering operation of the mobile control, and controlling the cutting tool to cut the key to be processed according to the target position represented by the triggered mobile control.

9. A key cutting machine characterized by the steps of implementing the method of any one of claims 1 to 7.

10. A computer-readable storage medium, on which a computer program is stored which, when being executed by a processor, carries out the steps of the method according to any one of claims 1 to 7.

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