阅读说明：本技术 一种木工加工系统及其多面木工加工方法 (Woodworking processing system and multi-surface woodworking processing method thereof ) 是由 余锦坤 张弢 陈小龙 于 2021-08-16 设计创作，主要内容包括：本发明公开了一种木工加工系统及其多面木工加工方法,多面木工加工方法包括：步骤A、检测木工加工模式启动时,获取待加工工件所需加工的面和槽类型的参数,生成对应面、槽的槽数据文件；步骤B、检测加工时,控制木工加工设备夹紧待加工的工件,调用所述槽数据文件对所需加工的面进行槽加工。能同时对工件的所有平面进行加工,且每个平面均可选择所需的加工形状,通过槽类型的参数对加工形状进行调节,实现了多平面的自主形状设计加工。(The invention discloses a woodworking processing system and a multi-surface woodworking processing method thereof, wherein the multi-surface woodworking processing method comprises the following steps: step A, when detecting the start of a woodworking processing mode, acquiring parameters of a surface and a groove type to be processed of a workpiece to be processed, and generating a groove data file corresponding to the surface and the groove; and B, detecting and processing, controlling woodworking processing equipment to clamp the workpiece to be processed, and calling the groove data file to perform groove processing on the surface to be processed. All planes of the workpiece can be machined simultaneously, required machining shapes can be selected for each plane, the machining shapes are adjusted through parameters of groove types, and the multi-plane autonomous shape design machining is achieved.)

1. A multi-facet woodworking method for a woodworking processing system, comprising:

step A, when detecting the start of a woodworking processing mode, acquiring parameters of a surface and a groove type to be processed of a workpiece to be processed, and generating a groove data file corresponding to the surface and the groove;

and B, detecting and processing, controlling woodworking processing equipment to clamp the workpiece to be processed, and calling the groove data file to perform groove processing on the surface to be processed.

2. The multi-faced woodworking method of a woodworking processing system as claimed in claim 1, wherein said step a specifically comprises:

step A1, displaying a woodworking processing interface when detecting the start of a woodworking processing mode, and selecting a workpiece graph to be processed;

and A2, acquiring input parameters and generating a groove data file corresponding to each plane according to the selected groove type and the processing plane pop-up surface groove setting interface.

3. A multi-faced woodworking method for a woodworking processing system as claimed in claim 1, further comprising, prior to said step a: and (3) placing the workpiece to be processed in woodworking processing equipment, popping up a zero-returning interface to display each zero-returning axis when the zero-returning icon is detected to be clicked, and returning to zero on any axis or all axes according to selection.

4. The multi-faceted woodworking tooling method of a woodworking tooling system of claim 2, wherein in said step a2, said step of interfacing with a work plane pop-up face slot according to the selected slot type and the work plane pop-up face slot specifically comprises: after detecting that an editing slot icon in the toolbar is clicked, popping up an editing interface and displaying a slot type list and a plane list; and popping up a corresponding face slot setting interface according to the slot type selected in the slot type list and the plane selected in the plane list after detecting that the adding slot icon is clicked.

5. The multi-faced woodworking method of a woodworking processing system as claimed in claim 2, wherein in step a2, said obtaining input parameters and generating groove data files corresponding to respective planes specifically comprises: and when a determined icon in the face slot setting interface is clicked, acquiring all parameters of the face slot setting interface, associating with corresponding setting items, generating a corresponding slot data file, automatically exiting the face slot setting interface, returning to the woodworking processing interface, and displaying slot items below the plane.

6. The multi-faced woodworking method of a woodworking processing system as claimed in claim 1, wherein said step B specifically comprises:

b1, popping up a processing interface when detecting that the right processing icon or the left processing icon is clicked;

and step B2, when the clamping icon is detected to be clicked, controlling a clamp on the woodworking processing equipment to clamp the workpiece to be processed, and calling the hooked slot data file to control the cutter to process the plane of the workpiece.

7. A multi-facer woodworking process according to claim 1, wherein after step B, further comprising:

and step C, when the detection generated NC icon is clicked, acquiring the groove data files of the currently selected planes, and generating and storing corresponding processing programs.

8. The multi-faceted woodworking process of a woodworking process system of claim 1, wherein when a detection is made that a flag on the woodworking process interface is clicked on, switching to a system menu; the functions of the system menu include: language switching, setting the working states of lubricating oil and chip removal, positioning the original point of a workpiece, and determining the offset of the left station and the right station on X, Y, Z three axes, exiting a woodworking processing mode, checking a processing log, verifying user authority, and reconnecting the system.

9. A woodworking processing system for implementing the multi-faced woodworking processing method of claim 1, comprising: woodworking processing equipment and controllers;

when the controller detects the start of the woodworking processing mode, the controller acquires parameters of the type of a surface and a groove to be processed of a workpiece to be processed, and generates a groove data file corresponding to the surface and the groove; and when detecting and processing, controlling the woodworking processing equipment to clamp the workpiece to be processed, and calling the slot data file to carry out slot processing on the surface to be processed by the main program segment number and the subprogram segment number.

Technical Field

The invention relates to the technical field of woodworking processing systems, in particular to a woodworking processing system and a multi-surface woodworking processing method thereof.

Background

The existing woodwork processing in the market basically only has a plane (often referred to as a top surface) processing function, can not process other surfaces (such as front, back, left and right side surfaces and bottom surfaces) and can not process drilling and sawing on the corresponding surfaces according to the shape required by a user.

Accordingly, the prior art is yet to be improved and developed.

Disclosure of Invention

In view of the defects of the prior art, the invention aims to provide a woodworking processing system and a multi-surface woodworking processing method thereof, which can process different planes of a workpiece, wherein each plane can be provided with a processing pattern by a user, and the problems that the existing woodworking processing cannot process other planes and cannot drill and saw on the corresponding plane according to the shape required by the user are solved. In order to achieve the purpose, the invention adopts the following technical scheme:

a multi-faceted woodworking process for a woodworking process system, comprising:

step A, when detecting the start of a woodworking processing mode, acquiring parameters of a surface and a groove type to be processed of a workpiece to be processed, and generating a groove data file corresponding to the surface and the groove;

and B, detecting and processing, controlling woodworking processing equipment to clamp the workpiece to be processed, and calling the groove data file to perform groove processing on the surface to be processed.

In the multi-surface woodworking processing method of the woodworking processing system, the step A specifically comprises the following steps:

step A1, displaying a woodworking processing interface when detecting the start of a woodworking processing mode, and selecting a workpiece graph to be processed;

and A2, acquiring input parameters and generating a groove data file corresponding to each plane according to the selected groove type and the processing plane pop-up surface groove setting interface.

In the multi-surface woodworking processing method of the woodworking processing system, before the step a, the method further includes: and (3) placing the workpiece to be processed in woodworking processing equipment, popping up a zero-returning interface to display each zero-returning axis when the zero-returning icon is detected to be clicked, and returning to zero on any axis or all axes according to selection.

In the multi-facet woodworking processing method of the woodworking processing system, in the step a2, the step of setting the interface according to the selected slot type and the processing plane pop-up face slot specifically includes: after detecting that an editing slot icon in the toolbar is clicked, popping up an editing interface and displaying a slot type list and a plane list; and popping up a corresponding face slot setting interface according to the slot type selected in the slot type list and the plane selected in the plane list after detecting that the adding slot icon is clicked.

In the multi-surface woodworking processing method of the woodworking processing system, in the step a2, the acquiring input parameters and generating the groove data files corresponding to the planes specifically includes: and when a determined icon in the face slot setting interface is clicked, acquiring all parameters of the face slot setting interface, associating with corresponding setting items, generating a corresponding slot data file, automatically exiting the face slot setting interface, returning to the woodworking processing interface, and displaying slot items below the plane.

In the multi-surface woodworking processing method of the woodworking processing system, the step B specifically comprises the following steps:

b1, popping up a processing interface when detecting that the right processing icon or the left processing icon is clicked;

and step B2, when the clamping icon is detected to be clicked, controlling a clamp on the woodworking processing equipment to clamp the workpiece to be processed, and calling the hooked slot data file to control the cutter to process the plane of the workpiece.

In the multi-surface woodworking processing method of the woodworking processing system, after the step B, the method further comprises:

and step C, when the detection generated NC icon is clicked, acquiring the groove data files of the currently selected planes, and generating and storing corresponding processing programs.

In the multi-surface woodworking processing method of the woodworking processing system, when the mark on the woodworking processing interface is clicked, the system menu is switched to; the functions of the system menu include: language switching, setting working states of lubricating oil and chip removal, positioning of the original point of the workpiece, and offset of the left and right stations on X, Y, Z three axes.

A woodworking processing system for implementing the multi-facet woodworking processing method comprises: woodworking processing equipment and controllers;

when the controller detects the start of the woodworking processing mode, the controller acquires parameters of the type of a surface and a groove to be processed of a workpiece to be processed, and generates a groove data file corresponding to the surface and the groove; and when detecting and processing, controlling the woodworking processing equipment to clamp the workpiece to be processed, and calling the slot data file to carry out slot processing on the surface to be processed by the main program segment number and the subprogram segment number.

In the woodworking processing system and the multi-surface woodworking processing method thereof, when a woodworking processing mode is started, parameters of a surface and a groove type to be processed of a workpiece to be processed are obtained, and a groove data file corresponding to the surface and the groove is generated; and during detection and processing, controlling woodworking processing equipment to clamp a workpiece to be processed, and calling the groove data file to perform groove processing on the surface to be processed. All planes of the workpiece can be machined simultaneously, required machining shapes can be selected for each plane, the machining shapes are adjusted through parameters of groove types, and the multi-plane autonomous shape design machining is achieved.

Drawings

FIG. 1 is a flow chart of a multi-faceted woodworking processing method for a woodworking processing system according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of an operation interface provided in an embodiment of the present invention;

FIG. 3 is a schematic view of a processing interface provided in an embodiment of the present invention;

FIG. 4 is a diagram of an editing interface provided by an embodiment of the present invention;

FIG. 5 is a schematic diagram of a tool magazine interface provided by an embodiment of the present invention;

FIG. 6 is a schematic diagram of a zeroing interface provided in an embodiment of the present invention;

FIG. 7 is a schematic view of a top-round slot set interface provided by an embodiment of the present invention;

FIG. 8 is a schematic view of a woodworking processing interface provided in accordance with an embodiment of the invention;

FIG. 9 is a schematic diagram of a top-square groove set interface provided by an embodiment of the present invention;

FIG. 10 is a schematic view of a top-waisted slot set-up interface provided by an embodiment of the present invention;

FIG. 11 is a schematic view of a top-side-saw setting interface provided by an embodiment of the present invention;

FIG. 12 is a schematic diagram of a top-NC setup interface provided by an embodiment of the invention;

fig. 13 is a schematic diagram illustrating a slot item or a hollow item generated in a plane list according to an embodiment of the present invention;

FIG. 14 is a schematic view of a manual interface provided in an embodiment of the present invention;

FIG. 15 is a diagram illustrating a system menu according to an embodiment of the present invention;

FIG. 16 is a schematic diagram of an interface provided by an embodiment of the present invention;

FIG. 17 is a diagram illustrating an input point parameter interface according to an embodiment of the present invention;

FIG. 18 is a schematic diagram of a time parameter interface provided by an embodiment of the present invention;

FIG. 19 is a schematic view of an axis parameter interface provided by an embodiment of the present invention;

FIG. 20 is a schematic diagram of a zeroing parameter interface provided by an embodiment of the present invention;

FIG. 21 is a schematic view of a gap compensation parameter interface provided in accordance with an embodiment of the present invention;

FIG. 22 is a schematic view of a handwheel simulation parameter interface provided in accordance with an embodiment of the present invention;

fig. 23 is a schematic diagram of an IO name parameter interface according to an embodiment of the present invention;

FIG. 24 is a block diagram of a woodworking processing system according to an embodiment of the invention;

FIG. 25 is a schematic diagram of an advanced menu provided by an embodiment of the present invention;

fig. 26 is a schematic diagram of a setting interface of a lubrication pump, chip removal, a workpiece origin and left and right stations according to an embodiment of the invention.

Detailed Description

In view of the problems that the existing woodworking processing can not process other surfaces and can not perform drilling and sawing processing on the corresponding surfaces according to the shape required by a user, the invention aims to provide a woodworking processing system and a multi-surface woodworking processing method thereof, which can process different planes of a workpiece, and each plane can be provided with a processing figure by the user. In order to make the objects, technical solutions and effects of the present invention clearer and clearer, the present invention is further described in detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Please refer to fig. 1, which is a flowchart illustrating an intelligent woodworking processing method according to an embodiment of the present invention. As shown in fig. 1, the intelligent woodworking processing method comprises the following steps:

s10, when detecting the start of the woodworking processing mode, acquiring parameters of the type of a surface and a groove to be processed of a workpiece to be processed, and generating a groove data file corresponding to the surface and the groove;

and S20, detecting and processing, controlling the woodworking processing equipment to clamp the workpiece to be processed, and calling the groove data file to perform groove processing on the surface to be processed.

On the basis of the existing woodworking plane machining process, a woodworking machining program and a corresponding woodworking machining interface are added in a CNC (computer numerical control) system, existing woodworking machining equipment is combined to machine multiple surfaces of a workpiece (namely a wood part), each plane can select a required machining shape, and the machining shape is adjusted by inputting various parameters; the processing modes of milling, grooving, sawing, drilling and the like can be selected, the input parameters and the processing modes are obtained to generate a groove data file for processing the selected plane in a corresponding shape, and the groove data file is operated to finish the processing of the wood part.

In this embodiment, as shown in fig. 2 to 4, the woodworking processing interface mainly includes four controls, which are switched by operation icons, processing icons, editing icons, and tool magazine icons displayed on the upper left portion, and workpiece processing is mainly executed through interfaces corresponding to the 4 icons. Meanwhile, auxiliary control can be performed by combining each icon in the toolbar.

When the CNC control system detects that the operation icon is clicked, an operation interface pops up, the operation interface is a soft operation panel designed according to the operation habit and the requirement of a carpenter, and the functions executed on the operation interface comprise: setting a mechanical coordinate and a relative coordinate, selecting a mode, controlling the movement of a shaft, and performing specific operations such as bag drilling operation, milling cutter operation, saw cutting operation, lower transverse drilling operation, lower vertical drilling operation and the like; icons corresponding to the functions are arranged on the operation interface, as shown in fig. 2.

And popping up a processing interface when the processing icon is clicked, wherein the processing interface is mainly used for displaying common processing information, such as workpiece coordinates, residual coordinates, NC program display, tool number display, processing time, accumulated time, workpiece count, compensation data and the like, and is shown in figure 3.

As shown in fig. 4, the editing interface is mainly used for displaying and switching 7 planes (such as top, front, right, bottom, rear, left, and side planes arranged from top to bottom) of a workpiece to be processed, selecting a processing graph from a woodworking graph library, inputting a required processing size on each plane to be processed, generating an NC (Numerical Control) program (i.e., a processing program) by one key, and optionally saving the NC program or directly operating the NC program for processing.

And popping up a tool magazine interface when the tool magazine icon is clicked, wherein the tool magazine interface is mainly used for displaying tool magazine data including tool types, tool lengths, tool diameters, tool compensation values and the like, and is shown in fig. 5.

When DOUBLE-click of a DOUBLE icon on any interface is detected, popping up a high-level menu, as shown in fig. 25, a column displayed on the left is the high-level menu, when the high-level icon in the high-level menu is detected to be clicked, popping up a password input box, when a certain icon in the password input box is detected to be clicked, acquiring an input password and checking whether the input password is the same as a pre-stored password, and if the input password is the same as the pre-stored password, popping up a debugging interface, as shown in fig. 17 to 23.

In the debugging interface, an input point interface is displayed by default, as shown in fig. 17, in the input point interface, each point and the opening and closing of the corresponding overload can be controlled, and the PLC input point is switched to be normally open or normally closed according to the setting. When the user clicks the time icon on the upper left side of the debugging interface, the time interface is displayed, as shown in fig. 18, the time of lifting and extending back of various cutters can be modified, and the PLC performs delay processing. The user clicks on the axis icon at the top left of the debug interface, and an axis interface is displayed, which may set X, Y, Z, C various parameters of the axis, as shown in FIG. 19. When the user clicks the zero-returning icon on the upper left of the debugging interface, the zero-returning interface is displayed, and as shown in fig. 20, parameters such as a first-segment front offset, a second offset, and a length limit of the X, Y, Z, C axis can be set. The user clicks on the gap compensation icon at the top left of the debug interface, which displays a gap compensation interface, which may set the gap compensation value for the X, Y, Z, C axis, as shown in FIG. 21. When the user clicks the handwheel simulation icon on the upper left of the debugging interface, the handwheel simulation interface is displayed, and as shown in fig. 22, the values of the three rates can be set. When the user clicks the IO name icon on the upper left of the debugging interface, the IO name interface is displayed, as shown in fig. 23, the name of each pin of the input (in) output (out) can be set, and monitoring of the IO pin is increased.

Before the step S10, that is, before the woodworking is performed, it is necessary to return the machine tool to zero and place the workpiece at the left or right station of the woodworking equipment (the specific positions of the left and right stations are prior art). When the zeroing icon positioned at the upper left part is detected to be clicked, popping up a zeroing interface to display zeroing axes (including an X axis, a Y axis, a Z axis, an A axis and all axes), wherein all axes are selected to be zeroed, popping up a confirmation window when all axis icons are detected to be clicked, and zeroing the coordinates of all axes of the machine tool when a 'yes' option is detected to be clicked, as shown in fig. 6. Optionally, during machining, zeroing of either axis is also possible.

In this embodiment, the step S10 specifically includes:

step 110, displaying a woodworking processing interface when detecting the start of a woodworking processing mode, and selecting a workpiece graph to be processed;

the user clicks the woodworking icon to start the woodworking processing mode and display the woodworking processing interface. Clicking the edit icon on the woodworking interface pops up the edit interface, as shown in fig. 4. Clicking to create a new processing file when new, deleting slot data in the current working area (for example, popping up a dialog box for deleting all slots), and clicking to open can select a processing file which is edited previously (the file type is slot data ([ mdp ])).

Step 120, according to the selected groove type and the processing plane pop-up surface groove setting interface, acquiring input parameters and generating groove data files corresponding to each plane;

after the CNC control system detects that the edit slot icon in the toolbar is clicked, the CNC control system pops up an edit interface, as shown in fig. 4. The left side of the editing interface shows a list of groove types and a list of planes from which the user can click on the desired groove type and the desired machined plane, respectively. The groove types include circular groove, square groove, waist circular groove, hollowed circle, hollowed square, hollowed waist circle, hollowed ellipse, etc. The plane includes top, front, right, bottom, back, left, side, and the like. For example, clicking the top surface and the circular groove, and popping up the surface groove setting interface after the detection adding groove icon is clicked, as shown in fig. 7, this indicates that a circular groove is formed on the top surface of the workpiece. The user can see the graph and important labels (such as point a, diameter D) of the circular groove in the upper left corner of the top surface-circular groove setting interface, and the setting items and the corresponding numerical values are in other boxes. The setting items comprise a tool number, a tool type, a tool diameter, a tool length, a safety distance Z, a deceleration distance Z, a groove depth increment, a processing speed F, a workpiece surface Z coordinate, an (A point) X coordinate, an (A point) Y coordinate, a circular groove diameter D, a circular groove depth, diameter compensation, groove depth compensation and the like. When the CNC system detects that a determined icon in the surface groove setting interface is clicked, all parameters of the surface groove setting interface are obtained and are associated with corresponding setting items, a corresponding groove data file is generated, the surface groove setting interface is automatically withdrawn, and the surface groove data file returns to a woodworking processing interface. As shown in fig. 8, a circular slot entry is now created below the top surface, indicating that a circular slot is currently being machined in the top surface. The setting interface of the hollow circle and the circular groove is similar, the shape of the hollow circle is the upper left corner, and the name in the parameter setting item is the replacement of the circular groove into the hollow circle.

If a plurality of surfaces need to be processed simultaneously, the editing groove icon can be clicked again, after an editing interface is entered, if the top surface and the square groove are clicked (the hollow-out side is similar to the square groove interface, and only the shape and the name of the upper left corner are correspondingly replaced), the adding groove is clicked, as shown in fig. 9, corresponding parameters are input on the popped top surface-square groove setting interface, and the determined icon is clicked to generate a groove data file of the top surface-square groove. And clicking an editing slot icon, clicking a top surface and a waist circular slot (the interface of the hollow waist circle is similar to the interface of the waist circular slot, and only the shape and the name of the upper left corner are correspondingly replaced), clicking an adding slot, inputting corresponding parameters on the top surface-waist circular slot setting interface, and clicking a determined icon to generate a slot data file of the top surface-waist circular slot, as shown in fig. 10. And then clicking an editing slot icon, entering an editing interface, clicking the top surface and saw cutting, clicking an adding slot, inputting corresponding parameters in a top surface-saw cutting setting interface, and clicking a determined icon to generate a top surface-saw cutting slot data file as shown in fig. 11. The top surface can be replaced by other planes, and the operation is repeated, so that different or same grooves, routing, cutting and the like can be processed on a plurality of surfaces. If the edit slot icon is clicked, after the edit interface is entered, the top surface and the NC are clicked, the add slot is clicked, as shown in FIG. 12, corresponding parameters are input in the top surface-NC setting interface, and the icon is clicked to determine, so that a slot data file of the top surface-NC is generated.

In the above steps, each time a slot data file is generated, the slot data file automatically exits from the surface slot setting interface and returns to the woodworking processing interface, so that the slot icon can be conveniently clicked and edited next time. Each slot data file is reflected at the lower level of each plane, as shown in fig. 13, and at this time, a corresponding slot entry or hollow entry is generated below each plane. Clicking each item and a square frame on the left side of the plane, generating a hook in the square frame to represent selection, and performing corresponding engraving and groove processing on the plane; the unhooked representation is not selected and is not processed, so that the function of selectively processing a plurality of planes is realized.

It should be understood that the CNC control system can directly process according to the slot data file, and the step S20 specifically includes:

and step 210, popping up a processing interface when detecting that the right processing icon or the left processing icon is clicked.

Because the material loading time is time consuming, in order to save time, the woodworking processing equipment is designed into two processing areas, namely a left station and a right station. When one station is processing, an operator can clamp the wood at the other station, and when the processing of one station is completed, the operator can immediately process the other station. The left station and the right station can respectively process different patterns.

When detecting that the right machining icon or the left machining icon in the toolbar of the woodworking machining interface is clicked, the CNC control system indicates to enter a machining stage and pop up a machining interface (the machining interface can also be popped up when the machining icon is clicked), as shown in fig. 3, here, the machining is right machining.

And step 220, when the clamping icon is detected to be clicked, controlling a clamp on the woodworking processing equipment to clamp the workpiece to be processed, and calling the hooked slot data file to control the cutter to process the plane of the workpiece.

Therefore, the clamping icon in the right station column needs to be clicked, when the clamping icon is detected to be clicked, the CNC control system can control the clamp on the woodworking processing equipment to clamp the workpiece to be processed, and the hooked slot data file is called to control the drill cutter on the woodworking processing equipment to process the plane of the workpiece.

And clicking the starting icon after clicking the hand wheel simulation icon by the user, and then shaking the hand wheel by the operator to call the machining program generated in the step S10 and start trial machining. If a plurality of processing programs exist, slotting or hollowing operations of different planes can be sequentially executed according to the arrangement sequence of each plane.

After the machining is finished, the user can save the current machining scheme, and when the NC icon generated in the detection tool bar of the CNC control system is clicked, the groove data files of the current selected planes are obtained and corresponding machining programs are generated (self-fetching of saving names). For example, the parameters in fig. 7 are acquired and stored as a top surface-circular groove data file, and the machining program generated according to the content in fig. 8 indicates that circular groove machining is performed on the top surface of the workpiece this time, and the top surface-circular groove data file is called during circular groove machining; the other planes are not machined. Clicking the storage in the toolbar, inputting the file name in the popup storage window, and clicking the storage to store the generated machining program.

For the multiple slot data files, when the CNC system detects that the icon of the deleted slot is clicked, the CNC system has multiple slot data files (namely, multiple slot items or hollow items), sequentially pops up dialog boxes from top to bottom, displays the names of the slot data files and prompts a user whether to delete the data files.

In specific implementation, the manual operation can also be performed, and the operation icon of fig. 2 is clicked to switch to a manual operation page, where the manual operation interface is shown in fig. 14. The function of each icon in the manual operation interface is shown in table 1 below.

TABLE 1

In any of the above steps, when the move-up icon or the move-down icon in the toolbar is clicked, indicating that the plane needs to be moved up/down (i.e. the sequence of the current planes is changed) and the slot data file of the plane (the order of the positions of the planes is not directly adjusted), a pop-up prompt box prompts the user whether to determine that the plane needs to be moved, and if so, the plane is correspondingly moved up/down by one position. When the origin icon in the toolbar is clicked, the display origin or the hiding origin may be switched. When the graphical display is not refreshed, the graphical display may be refreshed when the refresh icon is clicked.

At any time, when the CNC control system detects that the LOGO in the upper right corner of the woodworking processing interface is clicked, the system menu is switched to, as shown in fig. 15, in the system menu, a language icon can be clicked to perform language switching (select characters of each country). And clicking the setting icon to pop up a setting interface. Referring to fig. 26, the working state (such as lubrication interval and lubrication time) of the lubrication pump, the working state (such as chip removal interval and chip removal time) of chip removal, the workpiece origin location, the offset of the left station on the three axes X, Y, Z, and the offset of the right station on the three axes X, Y, Z are set. As shown in fig. 15, click close CNC icon to exit woodworking processing mode, click log icon to view processing log, click user authority icon to enter password for authority verification, click minimize icon to minimize CNC control system interface. When the interface is disconnected from the system, the reconnect icon is clicked, and the interface and the system are reconnected. When the IO monitoring icon is clicked, an interface as shown in FIG. 16 can be popped up, and the input and output working states of the IO board are displayed. And returning to the woodworking processing interface when clicking to return. In the woodworking processing interface, when an English icon DOUBLE at the upper left corner is clicked, a high-level menu pops up, a parameter interface can be entered after a password is input, as shown in FIG. 17, various parameters are displayed, and each icon at the upper left corner can be clicked to be switched to a corresponding parameter interface, wherein parameters of an input point (as shown in FIG. 17), time (as shown in FIG. 18), an axis (as shown in FIG. 19), a return zero (as shown in FIG. 20), gap supplement (as shown in FIG. 21), a hand wheel simulation (as shown in FIG. 22) and an IO name (as shown in FIG. 23) can be modified.

Based on the above multi-facet woodworking processing method, an embodiment of the present invention further provides a woodworking processing system for implementing the multi-facet woodworking processing method, please refer to fig. 24, where the woodworking processing system includes: woodworking processing equipment 10 and controller 20 (desktop or laptop may be used); when the controller 20 detects the start of the woodworking processing mode, parameters of the type of the surface and the groove to be processed of the workpiece to be processed are obtained, and a groove data file corresponding to the surface and the groove is generated; and during detection and processing, controlling woodworking processing equipment to clamp a workpiece to be processed, and calling the groove data file to perform groove processing on the surface to be processed.

In summary, in the woodworking processing system and the multi-surface woodworking processing method thereof provided by the present invention, during processing, each program segment is decoded by the decoding ring to generate a corresponding main program segment number, sub program segment number and graphic information, and the main program segment number, sub program segment number and graphic information are stored in the data buffer area; in each interpolation period, the interpolation ring reads the primary program segment number, the subprogram segment number, the graphic information and the position information fed back by the position ring once, records the position information as breakpoint information and stores the breakpoint information into a storage area with battery protection; when the breakpoint continuous mode is started, the decoding ring reads breakpoint information from the storage area, identifies the program segment where the breakpoint is located according to the main program segment number and the sub program segment number in the breakpoint information, generates a continuous program segment by combining the position information of the breakpoint, and restarts processing from the breakpoint position. The continuous cutting function of the breakpoint can be realized under the emergency conditions of manual control or accidental power failure of the machine tool and the like, the position of the breakpoint is fed back by the position ring in real time, the position precision of the breakpoint is high, and the real-time performance is good.

Of course, 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 instructing relevant hardware (such as a processor, a controller, etc.) through a computer program, and the program may be stored in a computer readable storage medium, and when executed, may include the processes of the above method embodiments. The storage medium may be a memory, a magnetic disk, an optical disk, etc.

The division of the functional modules is only used for illustration, and in practical applications, the functions may be distributed by different functional modules according to needs, that is, the functions may be divided into different functional modules to complete all or part of the functions described above.

It is to be understood that the invention is not limited to the examples described above, but that modifications and variations may be effected thereto by those of ordinary skill in the art in light of the foregoing description, and that all such modifications and variations are intended to be within the scope of the invention as defined by the appended claims.