A cutting device
By combining vacuum adsorption and motor-driven fixing components with pattern making and cutting components, the problem of material deviation during the cutting process is solved, thereby improving cutting accuracy and automation.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- XIAN YIYOU CHUANGLIAN TECHNOLOGY CO LTD
- Filing Date
- 2025-07-29
- Publication Date
- 2026-06-05
Smart Images

Figure CN224320283U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of pattern making and cutting technology, specifically a pattern making and cutting device. Background Technology
[0002] Pattern making and cutting are two crucial consecutive steps in the garment manufacturing process. They are key steps in transforming design drawings into physical garments, directly affecting the garment's pattern, dimensional accuracy, and wearing effect. Pattern making and cutting equipment is a system used in the garment and home textile industries to automate or semi-automate the processes of pattern making and cutting. It aims to improve production efficiency, accuracy, and standardization, while reducing errors and labor intensity caused by manual operation. Its core function is to convert design drawings into precise paper patterns (pattern making), and then efficiently cut the fabric according to the paper patterns (cutting). It typically consists of pattern making equipment, cutting equipment, and auxiliary systems.
[0003] Existing publicly available technical solution CN219229128U discloses an intelligent garment pattern making and cutting device, including a placement table. A conveyor rail is machined on the top of the placement table. An electric guide rail is fixedly connected to the top of a conveyor slider on the conveyor rail via a connecting rod. A cutting telescopic rod is fixedly connected inside the electric slider on the electric guide rail. A bearing plate is fixedly connected to the bottom of the telescopic end of the cutting telescopic rod. A stepper motor is fixedly connected to the outer wall of the bottom end of the bearing plate. This invention, through the connection relationship of the limiting connecting rod, limits the extension distance of the telescopic rod by a rotating disk and the limiting connecting rod, preventing the telescopic rod from extending or retracting during rotation, which could lead to inaccurate curved cutting. Simultaneously, adjusting the extension length of the telescopic rod by the limiting telescopic rod further improves the intelligent automation level of the device. The ball bearings on the limiting wheel rotate in the circumferential groove of the rotating disk, reducing friction with the inner wall of the circumferential groove and improving the device's lifespan.
[0004] However, when implementing existing technical solutions, friction causes the cardboard or cut material to shift during cutting, affecting the accuracy of pattern making and cutting. Utility Model Content
[0005] The purpose of this section is to outline some aspects of embodiments of the present invention and to briefly describe some preferred embodiments. Simplifications or omissions may be made in this section, as well as in the abstract and title of this application, to avoid obscuring the purpose of these documents; however, such simplifications or omissions should not be construed as limiting the scope of the present invention.
[0006] Given that the existing technology has the problem that when the cutter head cuts the cardboard or cut material, the friction will cause the cardboard or cut material to shift, affecting the accuracy of pattern making and cutting.
[0007] To achieve the above objectives, this utility model provides the following technical solution:
[0008] A pattern making and cutting device includes: a pattern making and cutting component; an adsorption component for adsorbing the cutting material; and a fixing component for stretching and fixing the pattern paper and the cutting material.
[0009] The pattern making and cutting assembly includes: a worktable; a support rod slidably connected to a slide groove on the left side of the worktable; a first lead screw threadedly connected to the lower part of the support rod; and a first motor keyed to one end of the first lead screw.
[0010] The adsorption assembly includes: adsorption holes formed on the upper surface of the workbench; and a vacuum pump installed on the front left side of the workbench.
[0011] The fixing assembly includes: a second lifting box installed on the right side of the workbench; and a sliding column welded to the top of the second lifting box.
[0012] As a further embodiment of this utility model, the pattern cutting assembly further includes: a first support plate welded to the upper left side of the support rod; a second motor fixed above the first support plate by external bolts; a second slide plate installed above the second motor; and a second lead screw connected to the power output end of the second motor.
[0013] As a further embodiment of this utility model, the pattern cutting assembly further includes: a first connecting block threaded to the surface of the second lead screw; a first lifting box threaded to the surface of the second lead screw; a third sliding plate installed on the rear side of the first lifting box; and a third motor fixed to the inner wall of the first lifting box by external bolts.
[0014] As a further embodiment of this utility model: the pattern cutting assembly further includes: a first gear keyed to the power output end of the third motor; a third lead screw connected to the lower end of the first connecting block via a bearing; a second gear keyed to the upper part of the third lead screw; a telescopic column threaded to the surface of the third lead screw; a stepper motor fixed to the lower side of the telescopic column via external bolts; a second connecting block connected to the power output end of the stepper motor; and a blade welded to the lower part of the second connecting block.
[0015] As a further embodiment of this utility model, the fixing component further includes: a fourth motor fixed to the inner wall of the second lifting box by external bolts; a third gear keyed to the power output end of the fourth motor; and a third connecting block slidably connected to the upper part of the sliding column.
[0016] As a further embodiment of this utility model, the fixing component further includes: a fourth lead screw threaded to the rear of the third connecting block; and a fourth gear keyed to the lower part of the fourth lead screw.
[0017] As a further embodiment of this utility model, the fixing assembly further includes: a second support plate welded to the left side of the third connecting block; a first sliding groove plate installed on the upper right side of the second support plate; a third pressure plate welded to the left side of the second support plate; a fifth motor fixed to the upper front part of the second support plate by external bolts; and a fifth lead screw keyed to the power output end of the fifth motor.
[0018] As a further embodiment of this utility model, the fixing component further includes: a second sliding block threadedly connected to the surface of the fifth lead screw; a first sliding block threadedly connected to the surface of the fifth lead screw; a first pressure plate welded to the lower left end of the second sliding block; and a second pressure plate welded to the lower left end of the first sliding block.
[0019] Compared with the prior art, the beneficial effects of this utility model are:
[0020] 1. This utility model involves turning on the fourth motor, which rotates and drives the third gear, which is keyed to its power output end, to rotate. The third gear meshes with the fourth gear, which in turn drives the fourth lead screw, which is keyed to the fourth gear, to rotate. Since the third connecting block is slidably connected to the sliding column, the third connecting block, which is threaded to the surface of the fourth lead screw, moves downward, thereby driving the second support plate to move downward. The second support plate drives the third pressure plate to move downward, and the second support plate simultaneously drives the first sliding block and the second sliding block, which are slidably connected to its surface, to move downward. Therefore, the first pressure plate and the second pressure plate move downward and stop when they contact the template paper. Then, the fifth motor is turned on, which rotates and drives the fifth lead screw to rotate, thereby driving the first sliding block and the second sliding block to move. Since the first sliding block and the second sliding block are both slidably connected to the first slide plate and their internal threads are opposite, the first sliding block and the second sliding block move in opposite directions at both ends, thereby stretching the template paper flat.
[0021] 2. This utility model, by activating the first motor, drives the first lead screw to rotate, which in turn moves the support rod, indirectly causing the blade to move back and forth. Activating the second motor drives the second lead screw to rotate. Since the first connecting block is threadedly connected to the second lead screw and slidably connected to the third slide plate (110), the third lead screw moves left and right, indirectly causing the blade to move left and right. Activating the third motor drives the first gear to rotate, which in turn drives the second gear meshing with it to rotate, thus driving the third lead screw to rotate. The rotation of the third lead screw drives the telescopic column to move. Since the telescopic column is slidably connected to the third slide plate, the telescopic column moves downward, indirectly causing the blade located below it to move downward. Activating the stepper motor drives the second connecting block to rotate, which in turn drives the blade to rotate, allowing the blade angle to be adjusted. The above methods can achieve plate making at any height on the worktable.
[0022] 3. This utility model uses a vacuum pump to further fix the cut material through the suction hole, and the lower end of the suction hole has a large diameter to avoid blockage during the cutting process. Attached Figure Description
[0023] Figure 1 This is a front view of the pattern making and cutting equipment of this utility model;
[0024] Figure 2 This is a rear view of the pattern making and cutting equipment of this utility model;
[0025] Figure 3 This is a partial sectional view of the pattern making and cutting component of the pattern making and cutting equipment of this utility model;
[0026] Figure 4 This is a partial sectional view of the fixing component of the pattern making and cutting equipment of this utility model;
[0027] Figure 5 This is a partial cross-sectional view of the adsorption component of the pattern making and cutting equipment of this utility model.
[0028] In the diagram: 1. Pattern making and cutting assembly; 101. Workbench; 102. First motor; 103. First lead screw; 104. Support rod; 105. First support plate; 106. Second motor; 107. Second lead screw; 108. Second slide plate; 109. Third lead screw; 110. Third slide plate; 111. First lifting box; 112. First connecting block; 113. First gear; 114. Second gear; 115. Third motor; 116. Telescopic column; 117. Stepper motor; 118. Second connecting block; 119. 1. Blade; 2. Adsorption assembly; 201. Adsorption hole; 202. Vacuum pump; 3. Fixing assembly; 301. Second lifting box; 302. Fourth motor; 303. Third gear; 304. Fourth gear; 305. Fourth lead screw; 306. Fifth lead screw; 307. Fifth motor; 308. First sliding plate; 309. First sliding block; 310. Second sliding block; 311. First pressure plate; 312. Second pressure plate; 313. Sliding column; 314. Third connecting block; 315. Third pressure plate; 316. Second support plate. Detailed Implementation
[0029] To make the above-mentioned objectives, features and advantages of this utility model more readily understood, the specific embodiments of this utility model will be described in detail below with reference to the accompanying drawings.
[0030] Many specific details are set forth in the following description in order to provide a full understanding of the present invention. However, the present invention may also be implemented in other ways different from those described herein. Those skilled in the art can make similar extensions without departing from the spirit of the present invention. Therefore, the present invention is not limited to the specific embodiments disclosed below.
[0031] Secondly, the term "an embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places in this specification does not necessarily refer to the same embodiment, nor is it a single embodiment or an embodiment selectively excluded from other embodiments.
[0032] Example 1:
[0033] Please see Figure 1 - Figure 5 This is the first embodiment of the present invention.
[0034] This embodiment provides a pattern making and cutting device, including a pattern making and cutting component 1; an adsorption component 2 for adsorbing the cutting material; and a fixing component 3 for stretching and fixing the pattern paper and the cutting material.
[0035] The pattern making and cutting assembly 1 includes: a workbench 101; a support rod 104 slidably connected to the left side groove of the workbench 101; a first lead screw 103 threadedly connected to the lower part of the support rod 104; and a first motor 102 keyedly connected to one end of the first lead screw 103.
[0036] The adsorption assembly 2 includes: an adsorption hole 201 formed on the upper surface of the worktable 101; and a vacuum pump 202 installed on the front left side of the worktable 101.
[0037] The fixed component 3 includes: a second lifting box 301 installed on the right side of the workbench 101; and a sliding column 313 welded above the second lifting box 301.
[0038] Specifically, the pattern cutting assembly 1 also includes: a first support plate 105 welded to the upper left side of the support rod 104; a second motor 106 fixed above the first support plate 105 by external bolts; a second slide plate 108 installed above the second motor 106; and a second lead screw 107 connected to the power output end of the second motor 106.
[0039] Furthermore, the second motor 106 is turned on, which drives the second lead screw 107 to rotate. Since the first connecting block 112 is threadedly connected to it and slidably connected to the third slide plate 110, it drives the third lead screw 109 to move left and right.
[0040] Specifically, the pattern cutting assembly 1 also includes: a first connecting block 112 threaded to the surface of the second lead screw 107; a first lifting box 111 threaded to the surface of the second lead screw 107; a third slide plate 110 installed on the rear side of the first lifting box 111; and a third motor 115 fixed to the inner wall of the first lifting box 111 by external bolts.
[0041] Furthermore, the third motor 115 is turned on, which drives the first gear 113 to rotate, and in turn drives the second gear 114 that meshes with it to rotate, thus driving the third lead screw 109 to rotate. The rotation of the third lead screw 109 drives the telescopic column 116 to move. Since the telescopic column 116 is slidably connected to the third slide plate 110, the telescopic column 116 moves down, which can indirectly drive the blade 119 located below it to move down.
[0042] Specifically, the pattern cutting assembly 1 also includes: a first gear 113 keyed to the power output end of the third motor 115; a third lead screw 109 connected to the lower end of the first connecting block 112 via a bearing; a second gear 114 keyed to the upper part of the third lead screw 109; a telescopic column 116 threaded to the surface of the third lead screw 109; a stepper motor 117 fixed to the lower side inside the telescopic column 116 by external bolts; a second connecting block 118 connected to the power output end of the stepper motor 117; and a blade 119 welded to the lower part of the second connecting block 118.
[0043] Furthermore, the third motor 115 is activated, which drives the first gear 113 to rotate, thereby driving the second gear 114, which meshes with it, to rotate. This, in turn, drives the third lead screw 109 to rotate. The rotation of the third lead screw 109 causes the telescopic column 116 to move. Since the telescopic column 116 is slidably connected to the third slide plate 110, the telescopic column 116 moves downward, which indirectly drives the blade 119 located below it to move downward. The stepper motor 117 is activated, which drives the second connecting block 118 to rotate, thereby driving the blade 119 to rotate, which can adjust the angle of the blade 119.
[0044] In use, the first motor 102 is turned on, driving the first lead screw 103 to rotate, which in turn drives the support rod 104 to move, indirectly driving the blade 119 to move back and forth. The second motor 106 is turned on, driving the second lead screw 107 to rotate. Since the first connecting block 112 is threadedly connected to it and slidably connected to the third slide plate 110, it drives the third lead screw 109 to move left and right, thereby indirectly driving the blade 119 to move left and right. The third motor 115 is turned on, driving the first gear 113 to rotate, which in turn drives the gear meshing with it. The rotation of the second gear 114 causes the third lead screw 109 to rotate, which in turn causes the telescopic column 116 to move. Since the telescopic column 116 is slidably connected to the third slide plate 110, the telescopic column 116 moves downward, which in turn indirectly causes the blade 119 located below it to move downward. The stepper motor 117 is then turned on, and the rotation of the stepper motor 117 causes the second connecting block 118 to rotate, which in turn causes the blade 119 to rotate. This allows the blade 119 to adjust its angle, thus enabling the blade 119 to print at any height on the worktable 101.
[0045] In summary, this utility model, by activating the first motor 102, drives the first lead screw 103 to rotate, thereby moving the support rod 104 and indirectly driving the blade 119 to move back and forth. Activating the second motor 106 drives the second lead screw 107 to rotate. Since the first connecting block 112 is threadedly connected to the second lead screw 107 and slidably connected to the third sliding plate 110, it drives the third lead screw 109 to move left and right, thereby indirectly driving the blade 119 to move left and right. Activating the third motor 115 drives the first gear 113 to rotate, thereby driving the gear meshing with it... The second gear 114 rotates, which in turn drives the third lead screw 109 to rotate. The rotation of the third lead screw 109 drives the telescopic column 116 to move. Since the telescopic column 116 is slidably connected to the third slide plate 110, the telescopic column 116 moves downward, which in turn indirectly drives the blade 119 located below it to move downward. The stepper motor 117 is turned on, and the rotation of the stepper motor 117 drives the second connecting block 118 to rotate, which in turn drives the blade 119 to rotate. The blade 119 can be adjusted in angle. The above can realize the plate making at any position and height of the blade 119 on the worktable 101.
[0046] Example 2:
[0047] Please see Figure 1 - Figure 5 This is the second embodiment of the present utility model.
[0048] Specifically, the fixing component 3 also includes: a fourth motor 302 fixed to the inner wall of the second lifting box 301 by external bolts; a third gear 303 keyed to the power output end of the fourth motor 302; and a third connecting block 314 slidably connected to the upper part of the sliding column 313.
[0049] Furthermore, the fourth motor 302 is activated, and the fourth motor 302 rotates, which in turn drives the third gear 303, which is keyed to its power output end, to rotate.
[0050] Specifically, the fixing component 3 also includes: a fourth lead screw 305 threadedly connected to the rear of the third connecting block 314; and a fourth gear 304 keyedly connected to the lower part of the fourth lead screw 305.
[0051] Furthermore, the third gear 303 meshes with the fourth gear 304, thereby driving the fourth lead screw 305 connected to the fourth gear 304 to rotate.
[0052] Specifically, the fixing component 3 also includes: a second support plate 316 welded to the left side of the third connecting block 314; a first slide plate 308 installed on the upper right side of the second support plate 316; a third pressure plate 315 welded to the left side of the second support plate 316; a fifth motor 307 fixed to the upper front part of the second support plate 316 by external bolts; and a fifth lead screw 306 connected to the power output end of the fifth motor 307.
[0053] Furthermore, the fifth motor 307 is activated, and the fifth motor 307 rotates, driving the fifth lead screw 306 to rotate, which in turn drives the first sliding block 309 and the second sliding block 310 to move.
[0054] Specifically, the fixing component 3 also includes: a second sliding block 310 threadedly connected to the surface of the fifth lead screw 306; a first sliding block 309 threadedly connected to the surface of the fifth lead screw 306; a first pressure plate 311 welded to the lower left end of the second sliding block 310; and a second pressure plate 312 welded to the lower left end of the first sliding block 309.
[0055] Furthermore, the first pressure plate 311 and the second pressure plate 312 move downwards and stop when they contact the template paper. The fifth motor 307 is then activated, and the fifth motor 307 rotates, driving the fifth lead screw 306 to rotate. This, in turn, causes the first sliding block 309 and the second sliding block 310 to move. Since both the first sliding block 309 and the second sliding block 310 are slidably connected to the first slide plate 308 and their internal threads are opposite, the first sliding block 309 and the second sliding block 310 move in opposite directions to both ends, thereby flattening the template paper. When the first sliding block 309 and the second sliding block 310 reach both ends, they stop, thus fixing the template paper.
[0056] In use, the worker first places the sample paper on the workbench 101, then writes the pattern data into the external control unit, and turns on the fourth motor 302. The fourth motor 302 rotates, which in turn drives the third gear 303, which is keyed to its power output end, to rotate. The third gear 303 meshes with the fourth gear 304, which in turn drives the fourth lead screw 305, which is keyed to the fourth gear 304, to rotate. Since the third connecting block 314 is slidably connected to the sliding column 313, the third connecting block 314, which is threaded to the surface of the fourth lead screw 305, moves downward, which in turn drives the second support plate 316 to move downward. 16 drives the third pressure plate 315 to move downwards, and the second support plate 316 simultaneously drives the first sliding block 309 and the second sliding block 310, which are slidably connected to its surface, to move downwards. Therefore, the first pressure plate 311 and the second pressure plate 312 move downwards and stop when they contact the sample paper. The fifth motor 307 is then turned on, and the fifth motor 307 rotates, driving the fifth lead screw 306 to rotate, which in turn drives the first sliding block 309 and the second sliding block 310 to move. Since the first sliding block 309 and the second sliding block 310 are both slidably connected to the first slide plate 308, and their internal threads are opposite, the first sliding block 309 and the second sliding block 310 move towards both ends. The reverse motion stretches the template paper flat. It stops when the first sliding block 309 and the second sliding block 310 reach both ends, fixing the template paper and preventing it from shifting during the printing process. At this time, the first motor 102 is activated, driving the first lead screw 103 to rotate, which in turn moves the support rod 104, indirectly causing the blade 119 to move back and forth. The second motor 106 is activated, driving the second lead screw 107 to rotate. Since the first connecting block 112 is threadedly connected to it and slidably connected to the third slide plate 110, it drives the third lead screw 109 to move left and right, indirectly causing the blade 119 to move left and right. The third motor 115 is activated, and the third... Motor 115 drives the first gear 113 to rotate, which in turn drives the second gear 114 meshing with it to rotate, thus driving the third lead screw 109 to rotate. The rotation of the third lead screw 109 drives the telescopic column 116 to move. Since the telescopic column 116 is slidably connected to the third slide plate 110, the telescopic column 116 moves down, which in turn indirectly drives the blade 119 located below it to move down. Stepper motor 117 is turned on, and the rotation of stepper motor 117 drives the second connecting block 118 to rotate, which in turn drives the blade 119 to rotate. The blade 119 can be adjusted in angle. The above can realize the plate making of the blade 119 at any position and height on the worktable 101.After pattern making is completed, the fourth motor 302 is turned on and reversed, thereby lifting the first pressure plate 311, the second pressure plate 312, and the third pressure plate 315. The fifth motor 307 is then turned on and reversed, restoring the first pressure plate 311 and the second pressure plate 312 to their original positions. The template paper and the cut material are then placed together on the worktable 101. The fixing steps are repeated until the first pressure plate 311, the second pressure plate 312, and the third pressure plate 315 flatten and fix the cut material. At this point, the vacuum pump 202 is turned on. The vacuum pump 202 further fixes the cut material through the suction hole 201, and the lower diameter of the suction hole 201 is relatively large to prevent blockage during the cutting process. The pattern making steps are then repeated to ensure stable cutting of the material.
[0057] In summary, this utility model, by activating the fourth motor 302, causes the fourth motor 302 to rotate, which in turn drives the third gear 303, which is keyed to its power output end, to rotate. The third gear 303 meshes with the fourth gear 304, thereby driving the fourth lead screw 305, which is keyed to the fourth gear 304, to rotate. Since the third connecting block 314 is slidably connected to the sliding column 313, the third connecting block 314, which is threaded to the surface of the fourth lead screw 305, moves downward, thereby driving the second support plate 316 to move downward. The second support plate 316 then drives the third pressure plate 315 to move downward. Simultaneously, the second support plate 316... The first sliding block 309 and the second sliding block 310, which are slidably connected to its surface, move downwards, so the first pressure plate 311 and the second pressure plate 312 move downwards. When they come into contact with the template paper, they stop, and the fifth motor 307 is turned on. The fifth motor 307 rotates, which drives the fifth lead screw 306 to rotate, thereby driving the first sliding block 309 and the second sliding block 310 to move. Since the first sliding block 309 and the second sliding block 310 are both slidably connected to the first slide plate 308, and their internal threads are opposite, the first sliding block 309 and the second sliding block 310 move in opposite directions at both ends, thereby stretching the template paper flat.
[0058] It is important to note that the constructions and arrangements of this application shown in several different exemplary embodiments are merely illustrative. Although only a few embodiments are described in detail in this disclosure, those who consult this disclosure will readily understand that many modifications are possible (e.g., changes in the size, dimensions, structure, shape, and proportions of various elements, as well as parameter values (e.g., temperature, pressure, etc.), mounting arrangements, use of materials, color, orientation, etc.) without substantially departing from the novel teachings and advantages of the subject matter described in this application). For example, an element shown as integrally formed may be composed of multiple parts or elements, the position of elements may be inverted or otherwise altered, and the nature or number or position of discrete elements may be changed or altered. Therefore, all such modifications are intended to be included within the scope of this utility model. The order or sequence of any process or method steps may be changed or rearranged according to alternative embodiments. In the claims, any "device plus function" clause is intended to cover the structure described herein that performs the function, and not only structural equivalents but also equivalent structures. Without departing from the scope of this invention, other substitutions, modifications, alterations, and omissions may be made in the design, operation, and arrangement of the exemplary embodiments. Therefore, this invention is not limited to the specific embodiments, but extends to various modifications that still fall within the scope of the appended claims.
[0059] Furthermore, in order to provide a concise description of exemplary embodiments, not all features of actual embodiments (i.e., those features that are not relevant to the best mode of carrying out the present invention as currently considered, or those features that are not relevant to implementing the present invention) may be omitted.
[0060] It should be understood that numerous specific implementation decisions can be made during the development of any actual implementation method, and in any engineering or design project. Such development efforts may be complex and time-consuming, but for those of ordinary skill in the art who benefit from this disclosure, the development effort will be a routine work of design, manufacturing, and production without requiring much experimentation.
[0061] It should be noted that the above embodiments are only used to illustrate the technical solution of this utility model and are not intended to limit it. Although this utility model has been described in detail with reference to preferred embodiments, those skilled in the art should understand that modifications or equivalent substitutions can be made to the technical solution of this utility model without departing from the spirit and scope of the technical solution of this utility model, and all such modifications or substitutions should be covered within the scope of the claims of this utility model.
Claims
1. A pattern-making and cutting device, characterized in that: include: Pattern making and cutting component (1); Adsorption component (2) for adsorbing the cut material. Fixing components (3) for stretching and fixing the sample paper and the cut material; The pattern making and cutting assembly (1) includes: a workbench (101); a support rod (104) slidably connected to the left side groove of the workbench (101); a first lead screw (103) threadedly connected to the lower part of the support rod (104); and a first motor (102) keyed to one end of the first lead screw (103). The adsorption assembly (2) includes: an adsorption hole (201) formed on the upper surface of the workbench (101); and a vacuum pump (202) installed on the front left side of the workbench (101). The fixing component (3) includes: a second lifting box (301) installed on the right side of the workbench (101); and a sliding column (313) welded to the top of the second lifting box (301).
2. The pattern making and cutting equipment according to claim 1, characterized in that: The pattern cutting assembly (1) further includes: a first support plate (105) welded to the upper left side of the support rod (104); a second motor (106) fixed above the first support plate (105) by external bolts; a second slide plate (108) installed above the second motor (106); and a second lead screw (107) connected to the power output end of the second motor (106).
3. The pattern making and cutting equipment according to claim 2, characterized in that: The pattern cutting assembly (1) further includes: a first connecting block (112) threaded to the surface of the second lead screw (107); a first lifting box (111) threaded to the surface of the second lead screw (107); a third slide plate (110) installed on the rear side of the first lifting box (111); and a third motor (115) fixed to the inner wall of the first lifting box (111) by external bolts.
4. The pattern making and cutting equipment according to claim 3, characterized in that: The pattern cutting assembly (1) further includes: a first gear (113) keyed to the power output end of the third motor (115); a third lead screw (109) connected to the lower end of the first connecting block (112) via a bearing; a second gear (114) keyed to the upper part of the third lead screw (109); a telescopic column (116) threaded to the surface of the third lead screw (109); a stepper motor (117) fixed to the lower side of the telescopic column (116) via external bolts; a second connecting block (118) keyed to the power output end of the stepper motor (117); and a blade (119) welded to the lower part of the second connecting block (118).
5. The pattern making and cutting equipment according to claim 1, characterized in that: The fixing component (3) further includes: a fourth motor (302) fixed to the inner wall of the second lifting box (301) by external bolts; a third gear (303) connected to the power output end of the fourth motor (302); and a third connecting block (314) slidably connected to the upper part of the sliding column (313).
6. The pattern making and cutting equipment according to claim 5, characterized in that: The fixing component (3) further includes: a fourth lead screw (305) threaded to the rear of the third connecting block (314); and a fourth gear (304) keyed to the lower part of the fourth lead screw (305).
7. The pattern making and cutting equipment according to claim 6, characterized in that: The fixing assembly (3) further includes: a second support plate (316) welded to the left side of the third connecting block (314); a first slide plate (308) installed on the upper right side of the second support plate (316); a third pressure plate (315) welded to the left side of the second support plate (316); a fifth motor (307) fixed to the upper front part of the second support plate (316) by external bolts; and a fifth lead screw (306) connected to the power output end of the fifth motor (307).
8. The pattern making and cutting equipment according to claim 7, characterized in that: The fixing component (3) further includes: a second sliding block (310) threaded to the surface of the fifth lead screw (306); a first sliding block (309) threaded to the surface of the fifth lead screw (306); a first pressure plate (311) welded to the lower left end of the second sliding block (310); and a second pressure plate (312) welded to the lower left end of the first sliding block (309).