CN221094479U - Template machine for processing non-fixed mould - Google Patents

Abstract

The utility model provides a template machine for non-fixed mold processing.A feeding part capable of accurately moving along the X-axis direction is arranged at the top of a support frame, a cloth pressing part for pressing cloth is arranged in the middle of the upper surface of the feeding part, a programming part capable of accurately moving along the Y-axis direction is arranged in the middle of the support frame through a portal frame, and a programming controller is electrically connected with the feeding part and the programming part; the programming controller is used for programming the programming patterns, the programming controller is used for controlling the feeding part and the programming part, the cloth assembly is used for compressing cloth, the middle of the cloth is tensed, the cloth is programmed through the programming part, the feeding part is used for reciprocating motion of the cloth in the X-axis direction of the programming area of the programming part through reciprocating motion of the feeding part, at the moment, the programming part is used for reciprocating motion in the Y-axis direction on the portal frame, different patterns are programmed through controlling the X-axis direction and the Y-axis motion direction, and template-free programming is realized.

Description

Template machine for processing non-fixed mould

Technical Field

The utility model relates to the field of template machines, in particular to a template machine for processing a non-fixed die.

Background

When the patterns are woven in the garment processing and production process, pattern plate making is needed; the existing template machine needs to manufacture templates when the patterns are woven, and then the template patterns are woven on cloth through the template machine, so that a template machine for processing a non-fixed die is provided, and the problem is solved.

Disclosure of utility model

In order to solve at least one technical disadvantage, the utility model provides a template machine for non-fixed mold processing, which comprises: the support frame, the support frame top is equipped with the feeding part that can prolong the accurate motion of X axis direction, and feeding part upper surface middle part is equipped with the cloth pressing part that is used for compressing tightly the cloth, and the support frame middle part is equipped with the establishment part that can prolong the accurate motion of Y axis direction through the portal frame can compile the design, programming controller and feeding part and establishment part electric connection.

Further, the feeding component includes two conveyer belts that are located the support frame both ends and extend support frame middle part symmetry, one outside one end of conveyer belt is all fixed through the feeding pivot, the feeding pivot both ends are all installed in the support frame both sides through the installation piece one that personally submits the L style of calligraphy, support frame one side is equipped with feeding motor, feeding pivot one end of front end is equipped with two gears, feeding pivot one end of rear end is equipped with a gear, feeding motor's output shaft is equipped with the gear, the gear of two feeding pivots passes through the chain to be connected, feeding motor passes through the chain with the gear in the feeding pivot outside of front end and is connected, one inboard one end of conveyer belt is all fixed through fixed plate one, one both ends of fixed plate are all connected with the support frame, one side surface that two fixed plates are close to evenly is equipped with a plurality of T type connecting block one, one outside one end middle part of T type connecting block all is connected with feeding roller through hole axle fit mode, feeding roller external diameter is greater than the thickness of fixed plate one and T type connecting block one.

Further, a feeding sliding groove is formed in the middle of the mounting block, which is used for being connected with the feeding rotating shaft, a feeding sliding block is connected inside the feeding sliding groove in a sliding mode, a bolt hole is formed in one end, perpendicular to the feeding rotating shaft, of the feeding sliding groove, and a bolt is arranged in the bolt hole.

Further, the cloth pressing component comprises two conveying belts II which are located above the fixing plate I and are symmetrical to the middle of the supporting frame, the outer sides of the conveying belts II are fixed through cloth pressing rotating shafts, two ends of each cloth pressing rotating shaft are connected with cloth pressing mounting plates in a control matching mode, the cloth pressing mounting plates are connected with two sides of the middle of the supporting frame through threads and bolts, a plurality of cloth pressing rollers I are fixedly connected to the cloth pressing rotating shafts, T-shaped connecting blocks II are arranged between two ends of each cloth pressing roller I and a gap, L-shaped bottom plates I with L-shaped cross sections are arranged at the other ends of the T-shaped connecting blocks II, L-shaped bottom plates II are arranged at inner side relative positions of the L-shaped bottom plates II, pressing plates used for stretching the conveying belts II are arranged on the upper surfaces of the L-shaped bottom plates II, one sides of the L-shaped bottom plates II, which are far away from the pressing plates, a plurality of T-shaped connecting blocks III are uniformly arranged, a plurality of T-shaped connecting blocks III are connected with fixing shafts in a matching mode, the outer walls of the fixing shafts between the two T-shaped connecting blocks III are all provided with cloth pressing rollers, the two ends of each conveying belt are internally supported through the cloth pressing rollers I, the two ends of each conveying belt II are internally supported through the cloth pressing rollers, one end of each conveying belt is close to one end of a feeding motor, and the conveying shaft is connected with the two wedge-shaped pressing plates through the corresponding to the pressing plates, and the two pressing plates are fixedly connected with the pressing plates through the pressing plates.

Further, the establishment part is including the portal frame that the ㄩ template that the cross-section personally submits ㄩ style of calligraphy constitutes, the middle part of portal frame still is equipped with ㄩ template, the opening direction of the ㄩ template at portal frame top and middle part sets up relatively, the opening edge of the ㄩ template at portal frame top and middle part all is equipped with the slide rail, equal sliding connection is equipped with the slider on the slide rail, two slide rails that same ㄩ template was gone out all are equipped with ball screw sliding seat through the slider, the ㄩ template middle part at portal frame top and middle part is equipped with the lead screw, both ends of the lead screw all are connected with ㄩ template hole axle cooperation in portal frame both sides, be located the lead screw one end of top and be equipped with the gear, be located two gears of lead screw one end of below, be connected through the establishment toothed belt between two gears, one side of ㄩ template of regulating motor, the output shaft of regulating motor's gear and the gear that is located the lead screw one end of below are connected through the toothed belt, the ball screw sliding seat lower surface that is located the top is equipped with the aircraft nose, the ball sliding seat upper surface that is located the below is equipped with vice aircraft nose, two conveyer and two pairs of conveyor pass between the clearance between two pairs of conveyor belts of machine head, the clearance alignment.

Further, a programming motor is arranged on one side of the ball screw sliding seat above, the programming motor drives the machine head through a toothed belt and a gear, and the feeding motor, the adjusting motor and the programming motor are connected with a programming controller.

Further, the gear is an M2 synchronous wheel, and the screw rod is connected with the ball screw sliding seat through a precise ball sleeve.

The beneficial effects are that: 1. the programming controller is used for programming the programming patterns, the programming controller is used for controlling the feeding part and the programming part, the cloth assembly is used for compressing cloth, the middle of the cloth is tensed, the cloth is programmed through the programming part, the feeding part is used for reciprocating motion of the cloth in the X-axis direction of the programming area of the programming part through reciprocating motion of the feeding part, at the moment, the programming part is used for reciprocating motion in the Y-axis direction on the portal frame, different patterns are programmed through controlling the X-axis direction and the Y-axis motion direction, and template-free programming is realized.

The realization, functional characteristics and advantages of the present utility model are further described with reference to the accompanying drawings in combination with the embodiments.

Drawings

Fig. 1 is an overall isometric view of the present utility model.

Fig. 2 is an isometric view of a feed member and cloth pressing member of the present utility model.

Fig. 3 is an isometric view of a feed member of the present utility model.

Fig. 4 is an isometric view of a mounting plate of the present utility model.

Fig. 5 is an isometric view of a first mounting plate of the present utility model.

Fig. 6 is an isometric view of a cloth pressing assembly of the present utility model.

Fig. 7 is an isometric view of a cloth pressing assembly of the present utility model.

Fig. 8 is an isometric view of a platen of the present utility model.

Fig. 9 is an isometric view of a braided component of the present utility model.

Fig. 10 is an overall exploded view of the present utility model.

FIG. 11 is an isometric view of a feed shoe of the present utility model.

Fig. 12 is a conveyor belt one and conveyor belt two axis view of the present utility model.

In fig. 1 to 12, the correspondence between the component names or lines and the drawing numbers is: support frame 1, feeding member 2, belt one 201, feeding shaft 202, mounting block one 203, feeding motor 204, chain 205, fixing plate one 206, T-shaped connection block one 207, feeding roller 208, feeding slider 209, feeding chute 210, bolt hole 211, cloth pressing member 3, belt two 301, cloth pressing shaft 302, cloth pressing mounting plate 303, cloth pressing roller one 304, T-shaped connection block two 305, L-shaped bottom plate one 306, platen 307, L-shaped bottom plate two 308, T-shaped connection block three 309, cloth pressing roller two 310, fixing shaft 311, braiding member 4, ㄩ template 401, L-shaped connection plate 402, slide rail 403, ball screw slide 404, screw 441, gear 442, braiding toothed belt 443, adjusting motor 444, handpiece 405, sub handpiece 406, braiding motor 407, slider 408.

Detailed Description

Please refer to fig. 1 to 6;

The embodiment provides a template machine for non-fixed mold processing, referring to fig. 1, including: the device comprises a support frame 1, wherein a feeding part 2 capable of accurately moving along the X-axis direction is arranged at the top of the support frame 1, a cloth pressing part 3 for pressing cloth is arranged in the middle of the upper surface of the feeding part 2, a programming part 4 capable of accurately moving along the Y-axis direction is arranged in the middle of the support frame 1 through a portal frame, and a programming controller is electrically connected with the feeding part 2 and the programming part 4;

In the concrete implementation, before programming, programming a programming pattern by a programming controller, during programming, controlling a feeding part 2 and a programming part 4 by the programming controller to enable the feeding part 2 to reciprocate in an X-axis direction, enabling the programming part 4 to reciprocate in a Y-axis direction, simultaneously programming the programming part 4, compacting cloth by a cloth compacting part 3, feeding the cloth by the feeding part 2, compacting the middle part of the cloth by the cloth compacting part 3, programming the cloth by the programming part 4, enabling the feeding part 2 to reciprocate in the X-axis direction of a programming area of the programming part 4, at the moment, enabling the programming part 4 to reciprocate in the Y-axis direction on a portal frame, and programming different patterns by controlling the X-axis direction and the Y-axis direction, thereby realizing template-free programming;

the programming controller includes, but is not limited to: and a PLC controller.

Further, referring to fig. 2 to 5, the feeding member 2 includes two symmetrical conveyor belts one 201 located at two ends of the support frame 1 and extending along the middle of the support frame 1, one end of the outer side of the conveyor belt one 201 is fixed by a feeding rotating shaft 202, two ends of the feeding rotating shaft 202 are mounted at two sides of the support frame 1 by a mounting block one 203 with an L-shaped cross section, one side of the support frame 1 is provided with a feeding motor 204, one end of the feeding rotating shaft 202 at the front end is provided with two gears, one end of the feeding rotating shaft 202 at the rear end is provided with a gear, an output shaft of the feeding motor 204 is provided with a gear, the gears of the two feeding rotating shafts 202 are connected by a chain 205, the feeding motor 204 is connected with the gears at the outer side of the feeding rotating shaft 202 at the front end by a chain, one end of the inner side of the conveyor belt one 201 is fixed by a fixing plate one 206, two ends of the fixing plate one 206 are connected with the support frame 1, one side surface of the two fixing plates one 206 close to each of the T-shaped connecting block one 207 is uniformly provided with a plurality of connecting blocks 207, one end of the middle of the outer side of the T-shaped connecting blocks is connected by a hole shaft, and the outer diameter of the feeding roller 208 is greater than the thickness of the fixing plate one 206 and the T-shaped connecting block 207;

In particular, when the cloth reciprocates in the X direction, the feeding motor 204 drives the two feeding rotating shafts 202 to synchronously rotate, so that the two conveyor belts one 201 synchronously move, and the cloth on the surface of the conveyor belt one 201 reciprocates in the X direction.

Further, referring to fig. 11, the middle parts of the first mounting blocks 203, which are used for being connected with the feeding rotating shaft 202, are respectively provided with a feeding chute 210, a feeding sliding block 209 is slidably connected inside the feeding chute 210, one end of the feeding chute 210, which is perpendicular to the feeding rotating shaft 202, is provided with a bolt hole 211, and a bolt is arranged in the bolt hole 211;

In particular, when the tightening degree of the first conveyor belt 201 is adjusted, the bolt is engaged with the screw hole 211 by screwing the bolt, the feeding slide 209 is pushed by the bolt, and the position of the feeding rotating shaft 202 is adjusted by the movement of the feeding slide 209, so that the tightening degree of the first conveyor belt 201 is adjusted.

Further, referring to fig. 6 to 8, the cloth pressing member 3 includes two conveyor belts two 301 located above the fixing plate one 206 and symmetrical along the middle of the supporting frame 1, the outer sides of the conveyor belts two 301 are all fixed by the cloth pressing rotating shaft 302, two ends of the cloth pressing rotating shaft 302 are all connected with the cloth pressing mounting plate 303 in a control fit manner, the cloth pressing mounting plate 303 is connected with two sides of the middle of the supporting frame 1 through threads and bolts, a plurality of cloth pressing rollers one 304 are fixedly connected to the cloth pressing rotating shaft 302, T-shaped connecting blocks two 305 are arranged between two ends of the plurality of cloth pressing rollers one 304 and gaps, L-shaped bottom plates 306 with L-shaped cross sections are arranged at the other ends of the plurality of the T-shaped connecting blocks two 305, L-shaped bottom plates two 308 are arranged at opposite positions on the inner sides of the L-shaped bottom plates 306, pressing plates 307 for supporting the conveyor belts two 301 are arranged on the upper surfaces of the L-shaped bottom plates two 306, one side of the L-shaped bottom plates two 308 away from the pressing plates 307 is uniformly provided with a plurality of T-shaped connecting blocks three 309, the other end holes of the T-shaped connecting blocks three 309 are connected with a fixed shaft 311 in a fit manner, the outer wall of the fixed shaft 311 between the two T-shaped connecting blocks three 309 is provided with a cloth pressing roller one end 310, the two end of the fixed cloth pressing rollers one end 205 is provided with a conveying belt one end of the conveying roller two 306, which is provided with a conveying belt one end of a conveying roller 301 with a conveying belt one end 301 with a conveying belt one end 301 with a conveying roller 301 with a bearing roller, which is driven a conveying end 310, which is in which a conveying end, and is connected to a conveying belt two end, and is connected to a conveying device, and is connected;

In a specific implementation, when the cloth is fixed through the cloth pressing component 3, the cloth is positioned on the surface of the first conveyor belt 201 and is pressed on the lower surface of the second conveyor belt 301, when the feeding motor 204 works, when the feeding motor 204 rotates clockwise, the two feeding rotating shafts 202 drive the two first conveyor belts 201 to rotate clockwise, at the moment, the cloth moves backwards, meanwhile, the chain 205 drives the two cloth pressing rotating shafts 302 through gears to rotate clockwise, so that the cloth pressing rotating shafts 302 at the front end drive the two wedge blocks to rotate clockwise, the pressing plate 307 at the front end is pressed downwards, the pressing plate 307 at the rear end is driven by the two wedge blocks at the rear end to move upwards, so that the pressing plate 307 at the rear end is lifted upwards, and at the moment, the cloth moves from the front end to the rear end, so that the rear end of the cloth is pressed, the front end is relaxed, and the cloth can be kept tight;

when the feeding motor 204 rotates anticlockwise, the two feeding rotating shafts 202 drive the two conveying belts 201 to rotate anticlockwise, at this time, the cloth moves forwards, meanwhile, the chain 205 drives the two cloth pressing rotating shafts 302 through gears to rotate anticlockwise, so that the cloth pressing rotating shafts 302 at the front end drive the two wedge blocks to rotate anticlockwise, the pressing plate 307 at the front end is lifted upwards, the pressing plate 307 at the rear end is driven by the two wedge blocks at the rear end to rotate downwards, the pressing plate 307 at the rear end is pressed downwards, at this time, the cloth moves forwards from the rear end, the front end of the cloth is pressed, the rear end is loose, and the cloth can be kept tight.

Further, referring to FIG. 9, the braiding part 4 comprises a portal frame formed by ㄩ templates 401 with a ㄩ -shaped cross section, a ㄩ template 401 is arranged in the middle of the portal frame, the opening directions of ㄩ templates 401 at the top and the middle of the portal frame are opposite, sliding rails 403 are arranged at the opening edges of ㄩ templates 401 at the top and the middle of the portal frame, sliding blocks 408 are arranged on the sliding rails 403 in a sliding connection manner, two sliding rails 403 which are arranged at the opening of the same ㄩ template 401 are respectively provided with a ball screw sliding seat 404 through the sliding blocks 408, a screw rod 441 is arranged in the middle of ㄩ templates 401 at the top and the middle of the portal frame, two ends of the screw rod 441 are respectively connected with ㄩ template 401 holes at two sides of the portal frame in a shaft fit manner, one end of the screw rod 441 positioned above is provided with a gear 442, one end of the screw rod 441 positioned below is arranged on the two gears 442, the two gears 442 are connected through a braiding toothed belt 443, an adjusting motor 444 is arranged on one side of the ㄩ template 401 on one side of the portal frame, a gear 442 is arranged on an output shaft of the adjusting motor 444, the gear 442 of the output shaft of the adjusting motor 444 is connected with the gear 442 positioned at one end of the screw rod 441 positioned below through the toothed belt, the gears 442 at one end of the two screw rods 441 are connected through the braiding toothed belt 443, a machine head 405 is arranged on the lower surface of the ball screw sliding seat 404 positioned above, a subsidiary machine head 406 is arranged on the upper surface of the ball screw sliding seat 404 positioned below, a machine needle of the machine head 405 passes through a gap between the first two conveying belts 201, and a rotary lock of the gap subsidiary machine head 406 between the second conveying belts 301 is aligned;

In the implementation, when moving in the Y-axis direction, the adjusting motor 444 drives the screw rods 441 to rotate, the two screw rods 441 synchronously rotate through the braiding toothed belt 442, so that the two ball screw sliding seats 404 synchronously move, the sliding blocks 408 synchronously move on the sliding rails 403, the machine head 405 and the auxiliary machine head 406 synchronously move, meanwhile, the machine needle of the machine head 405 passes through cloth to carry out braiding, and after the machine needle meets the spin lock of the auxiliary machine head 406, the machine needle contracts;

At this time, the cloth reciprocates in the X-axis direction, and the head 405 and the sub-head 406 reciprocate in the Y-axis direction, thereby creating patterns of different designs.

Further, a programming motor 407 is arranged on one side of the upper ball screw sliding seat 404, the programming motor 407 drives the machine head 405 through a toothed belt and a gear, and the feeding motor 204, the adjusting motor 444 and the programming motor 407 are connected with a programming controller;

In specific implementation, the feeding motor 204, the adjusting motor 444 and the programming motor 407 are controlled by a program through the braiding controller, so that the feeding motor 204, the adjusting motor 444 and the programming motor 407 can perform programming operation according to the program, and template-free programming is realized;

The feed motor 204, the adjustment motor 444, and the braiding motor 407 include, but are not limited to: a servo motor.

As a preferred embodiment of the present embodiment, the gear 442 is an M2 synchronizing wheel, the screw rod 441 is connected to the ball screw sliding seat 404 through a precision ball sleeve, and the transmission precision is improved through the M2 synchronizing wheel and the precision ball sleeve, so as to provide the machining precision.

Claims (7)

1. A template machine for non-stationary mold processing, comprising: support frame (1), its characterized in that: the top of the support frame (1) is provided with a feeding part (2) capable of accurately moving along the X-axis direction, the middle part of the upper surface of the feeding part (2) is provided with a cloth pressing part (3) for pressing cloth, the middle part of the support frame (1) is provided with a programming part (4) capable of accurately moving along the Y-axis direction through a portal frame, and a programming controller is electrically connected with the feeding part (2) and the programming part (4).

2. The non-stationary mold processing template machine of claim 1, wherein: the feeding component (2) comprises two conveying belts I (201) which are located at two ends of a supporting frame (1) and are symmetrical in the middle of the supporting frame (1), one end of the outer side of each conveying belt I (201) is fixed through a feeding rotating shaft (202), two ends of each feeding rotating shaft (202) are mounted on two sides of the supporting frame (1) through mounting blocks I (203) with L-shaped cross sections, a feeding motor (204) is arranged on one side of the supporting frame (1), two gears are arranged at one end of each feeding rotating shaft (202) at the front end, one gear is arranged at one end of each feeding rotating shaft (202) at the rear end, the output shaft of each feeding motor (204) is provided with one gear, the gears of the two feeding rotating shafts (202) are connected through a chain (205), the gears of the outer sides of each feeding rotating shaft (202) at the two feeding rotating shafts (204) are connected through a chain, one end of each inner side of each conveying belt I (201) is fixed through a fixing plate I (206), a plurality of T-shaped I (207) are uniformly arranged on one side surface, close to each fixing plate I (206) is connected with the supporting frame (1) through a hole 208), and one end middle part of each T-shaped connecting block I (207) is connected with one feeding roller (206) in a mode of large-shaped connecting block (206) through a matching mode.

3. The non-stationary mold processing template machine of claim 2, wherein: the first mounting block (203) is used for being connected with the feeding rotating shaft (202), the middle part of the first mounting block is provided with a feeding chute (210), the feeding chute (210) is internally connected with a feeding sliding block (209) in a sliding mode, one end of the feeding chute (210) perpendicular to the feeding rotating shaft (202) is provided with a bolt hole (211), and a bolt is arranged in the bolt hole (211).

4. A non-stationary tooling stencil machine as set forth in claim 3, wherein: the cloth pressing component (3) comprises two conveying belts II (301) which are positioned above the fixed plate I (206) and are symmetrical along the middle of the supporting frame (1), the outer sides of the conveying belts II (301) are fixed through cloth pressing rotating shafts (302), two ends of the cloth pressing rotating shafts (302) are connected with cloth pressing mounting plates (303) in a control fit mode, the cloth pressing mounting plates (303) are connected with two sides of the middle of the supporting frame (1) through threads and bolts, a plurality of cloth pressing rollers I (304) are fixedly connected to the cloth pressing rotating shafts (302), T-shaped connecting blocks II (305) are arranged between two ends and gaps of the cloth pressing rollers I (304), L-shaped bottom plates I (306) with L-shaped cross sections are arranged at the other ends of the T-shaped connecting blocks II (305), L-shaped bottom plates II (308) are arranged at the inner side opposite positions of the L-shaped bottom plates I (306), pressing plates (307) used for stretching the conveying belts II (301) are arranged on the upper surfaces of the L-shaped bottom plates II (308), a plurality of T-shaped three (309) are uniformly arranged on one sides of the side of the L-shaped bottom plates, which is far away from the supporting plates (307), T-shaped three (309) are connected with the fixing shafts (311) and are connected with the T-shaped connecting blocks II (311) through the fixing shafts, the inside cloth pressing roller I (304) that is supported of conveyer belt II (301) outer end, the inside cloth pressing roller II (310) that is supported of conveyer belt II (301) other end, the one end that cloth pressing pivot (302) is close to pay-off motor (204) is connected with chain (205) through the gear, the wedge that is used for driving clamp plate (307) motion is all fixedly connected with at cloth pressing pivot (302) both ends.

5. The non-stationary mold processing template machine of claim 4, wherein: the braiding part (4) comprises a portal frame formed by ㄩ templates (401) with the cross sections being ㄩ, ㄩ templates (401) are further arranged in the middle of the portal frame, the opening directions of ㄩ templates (401) at the top and the middle of the portal frame are opposite, sliding rails (403) are arranged at the opening edges of ㄩ templates (401) at the top and the middle of the portal frame, sliding blocks (408) are arranged on the sliding rails (403) in a sliding connection mode, ball screw sliding seats (404) are arranged on the two sliding rails (403) which are arranged on the opening of the same ㄩ template (401) through the sliding blocks (408), screw rods (441) are arranged in the middle of ㄩ templates (401) at the top and the middle of the portal frame, two ends of each screw rod (441) are connected with holes of ㄩ templates (401) on two sides of the portal frame in a shaft fit mode, one end of each screw rod (441) located above is provided with a gear (442), one end of each screw rod (441) located below is arranged on two gears (442), one side of each ㄩ (401) on one side of the portal frame is provided with an adjusting motor (444) through a braiding toothed belt (443), the two ends of the gears (441) are connected with one end of each gear (442) of the gears (442) through the toothed belt (442) of the gears (442), the lower surface of the ball screw sliding seat (404) positioned above is provided with a machine head (405), the upper surface of the ball screw sliding seat (404) positioned below is provided with a subsidiary machine head (406), and the machine needle of the machine head (405) passes through the gap between the two first conveyor belts (201) and the screw lock of the subsidiary machine head (406) of the gap between the two second conveyor belts (301) to be aligned.

6. The non-stationary mold processing template machine of claim 5, wherein: one side of the ball screw sliding seat (404) positioned above is provided with a programming motor (407), the programming motor (407) drives the machine head (405) through a toothed belt and a gear, and the feeding motor (204), the adjusting motor (444) and the programming motor (407) are connected with a programming controller.

7. The non-stationary mold processing template machine of claim 6, wherein: the gear (442) is an M2 synchronous wheel, and the screw rod (441) is connected with the ball screw sliding seat (404) through a precise ball sleeve.