CN214271448U - Slitting and transverse cutting mechanism and chemical fiber fabric composite slitting and transverse cutting integrated machine - Google Patents

Abstract

The application relates to a slitting and transverse cutting mechanism and a chemical fiber fabric composite slitting and transverse cutting integrated machine, which comprises a slitting mechanism and a transverse cutting mechanism, wherein the slitting mechanism comprises a plurality of slitting cutter heads, the slitting cutter heads are distributed on a rack along the width direction of a fabric, and each slitting cutter head is correspondingly provided with a slitting transducer; the transverse cutting mechanism comprises a transverse cutting head and a transverse cutting transducer corresponding to the transverse cutting head, the transverse cutting head is arranged on the rack in a sliding mode through a cutting head connecting seat, and the transverse cutting transducer is arranged on the rack in a sliding mode through a transducer connecting seat; the cutter head connecting seat and the transducer connecting seat are driven to synchronously move along the width direction of the fabric by the transverse cutting transmission mechanism. The material is through cutting the tool bit and cut and carry out the ultrasonic wave between the transducer and cut to drive crosscut tool bit, crosscut transducer motion through crosscut drive mechanism and carry out the ultrasonic wave crosscut to the surface fabric, it is efficient to cut, and the incision high quality, and the length of tool bit, width can freely be adjusted and change, and the length of crosscut is adjustable.

Description

Slitting and transverse cutting mechanism and chemical fiber fabric composite slitting and transverse cutting integrated machine

Technical Field

The application relates to the technical field of compound machines, in particular to a slitting and transverse cutting mechanism and a chemical fiber fabric compound slitting and transverse cutting all-in-one machine.

Background

The fabric compounding machine is a processing technology for mutually combining and synthesizing two or more layers of materials such as textiles, foam, leather and the like into a material, the compounding machine needs to cut the material after compounding the material, and the cutting of the compounded material at present mainly adopts a slitting knife and a slitting roller to cut.

In view of the above-mentioned related art, the inventors consider that the slitting mechanism in the related art has a poor quality of slitting, is prone to burrs, and the like.

SUMMERY OF THE UTILITY MODEL

In order to improve the quality of cutting, this application provides a crosscut mechanism and chemical fiber surface fabric compound cutting crosscut all-in-one.

In a first aspect, the present application provides a slitting and transversely cutting mechanism, which adopts the following technical scheme:

a slitting and transversely cutting mechanism comprises a slitting mechanism and a transversely cutting mechanism, wherein the slitting mechanism comprises a plurality of slitting knife heads, the slitting knife heads are distributed on a rack along the width direction of a fabric, and each slitting knife head is correspondingly provided with a slitting transducer; the transverse cutting mechanism comprises a transverse cutting head and a transverse cutting transducer corresponding to the transverse cutting head, the transverse cutting head is arranged on the rack in a sliding mode through a cutting head connecting seat, and the transverse cutting transducer is arranged on the rack in a sliding mode through a transducer connecting seat; the cutter head connecting seat and the transducer connecting seat are driven to synchronously move along the width direction of the fabric by the transverse cutting transmission mechanism.

Through above-mentioned technical scheme, the material is through cutting the tool bit and cut and carry out the ultrasonic wave between the transducer and cut to drive crosscut tool bit, crosscut transducer motion through crosscut drive mechanism and carry out the ultrasonic wave crosscut to the surface fabric, such mode, cutting efficiency is high, and the incision high quality.

Optionally, the transverse cutting transmission mechanism comprises a transverse cutting head transmission mechanism and an energy transducer transmission mechanism, wherein the transverse cutting head transmission mechanism comprises cutting head transmission belt pulleys arranged on two sides of the frame, the two cutting head transmission belt pulleys are connected by a cutting head transmission belt, the cutting head connecting seat is fixedly connected with the cutting head transmission belt, and the cutting head transmission belt rotates to drive the cutting head connecting seat to move along the width direction of the fabric; the energy converter transmission mechanism comprises energy converter transmission belt wheels arranged on two sides of the frame, the two energy converter transmission belt wheels are connected through an energy converter transmission belt, the energy converter connecting seat is fixedly connected with the energy converter transmission belt, and the energy converter transmission belt rotates to drive the energy converter connecting seat to move along the width direction of the fabric.

Through above-mentioned technical scheme, drive the tool bit connecting seat through tool bit driving belt and remove along the width direction of surface fabric with the crosscut tool bit, drive the transducer connecting seat through transducer driving belt and remove along the width direction of surface fabric with the crosscut transducer, realize the ultrasonic wave crosscut of surface fabric through the synchronous motion of crosscut tool bit and crosscut transducer.

Optionally, the two sides of the frame are provided with side plates, a transducer slide rail and a cutter head slide rail are arranged between the two side plates, the cutter head connecting seat is arranged on the cutter head slide rail, and the transducer connecting seat is arranged on the transducer slide rail.

Through above-mentioned technical scheme, through setting up the tool bit connecting seat on the tool bit slide rail, the tool bit connecting seat can slide on the tool bit slide rail, through setting up the transducer connecting seat on the transducer slide rail, the transducer connecting seat can slide on the transducer slide rail.

Optionally, at least two groups of side plates are arranged in the vertical height direction of the rack, a transverse cutting mechanism is arranged between each group of side plates, and at least one group of side plates in each group of side plates has adjustable height.

Through the technical scheme, at least two groups of side plates are arranged, and one transverse cutting mechanism is arranged between each group of side plates, so that the transverse cutting efficiency can be improved by arranging a plurality of transverse cutting mechanisms; by providing the side panels in a height adjustable configuration, the direction of the transverse length can be adjusted.

Optionally, an adjusting mechanism is arranged between the side plates on the same side of the frame and used for adjusting the distance between the side plates from top to bottom, the adjusting mechanism comprises connecting blocks arranged on the side plates, connecting screws are used for connecting the connecting blocks on the same side, and the lower ends of the connecting blocks are connected with the connecting screws through adjusting nuts and used for supporting the connecting blocks.

Through the technical scheme, the height position of the connecting block on the connecting screw rod can be adjusted through the adjusting nut, so that the height position of the side plate can be adjusted, and the height of each transverse cutting mechanism can be adjusted.

Optionally, a transverse cutting clamping mechanism is arranged on the machine frame, and the transverse cutting clamping mechanism includes at least two groups of clamping roller mechanisms.

Through the technical scheme, by arranging the transverse cutting clamping mechanism, the fabric is clamped by the transverse cutting clamping mechanism when the transverse cutting is carried out, so that the transverse cutting quality is ensured.

Optionally, the cutter head transmission belt pulleys on each group of transverse cutter head transmission mechanisms are driven by a cutter head transmission shaft, and the transducer transmission belt pulleys on each group of transducer transmission mechanisms are driven by a transducer transmission shaft; the cutter head transmission shaft and the transducer transmission shaft are connected by a synchronous transmission mechanism to synchronously rotate.

Through the technical scheme, the synchronous transmission mechanism drives the cutter head transmission shaft and the transducer transmission shaft to synchronously rotate, so that the cutter head transmission belt pulley and the transducer transmission belt pulley can be driven to synchronously move, the transverse cutting cutter head and the transverse cutting transducer are driven to synchronously move, and transverse cutting of the fabric is realized.

Optionally, the slitting cutter head is connected with the slitting cutter head cylinder; the transverse cutter head is connected with the transverse cutter head cylinder.

Through the technical scheme, the distance between the slitting cutter head and the slitting transducer can be adjusted through the slitting cutter head cylinder, and the distance between the transverse cutter head and the transverse transducer can be adjusted through the transverse cutter head cylinder, so that the slitting and transverse cutting of the composite fabric with different thicknesses are adapted.

Optionally, the slitting knife head can move along the width direction of the fabric on the frame and is locked.

Through above-mentioned technical scheme, through dividing the cutter head and removing in frame surface fabric width direction, can adjust the distance of cutting.

In a second aspect, the application also provides a chemical fiber fabric composite slitting and transversely cutting integrated machine which comprises a material discharging mechanism for discharging materials, a composite mechanism for compounding the materials and a slitting and transversely cutting mechanism for slitting and transversely cutting the fabric after compounding; the slitting and transversely cutting mechanism is the slitting and transversely cutting mechanism.

According to the technical scheme, materials are discharged through the discharging mechanism, and after the composite mechanism is compounded, the compounded materials are cut and transversely cut through the cutting and transversely cutting mechanism; cut the material through cutting the tool bit and cut and carry out the ultrasonic wave between the transducer and cut to drive crosscut tool bit, crosscut transducer motion through crosscut drive mechanism and carry out the ultrasonic wave crosscut to the surface fabric, such mode, the cutting is efficient, and the incision high quality.

In summary, the present application includes at least one of the following beneficial technical effects:

1. this application is through cutting the tool bit and cut and carry out the ultrasonic wave between the transducer and cut to drive crosscut tool bit, crosscut transducer motion through crosscut drive mechanism and carry out the ultrasonic wave crosscut to the surface fabric, such mode, the cutting is efficient, and the incision high quality.

2. By arranging at least two groups of side plates, and arranging one transverse cutting mechanism between each group of side plates, a plurality of transverse cutting mechanisms are arranged, so that a plurality of groups of transverse cutting can be carried out at one time, and the efficiency of the transverse cutting can be improved; by providing the side panels in a height adjustable configuration, the direction of the transverse length can be adjusted.

3. The distance between the slitting cutter head and the slitting transducer can be adjusted through the slitting cutter head cylinder, and the distance between the transverse cutter head and the transverse transducer can be adjusted through the transverse cutter head cylinder, so that the slitting and transverse cutting of composite fabrics with different thicknesses are adapted.

Drawings

Fig. 1 is a schematic structural view of a slitting and transverse cutting mechanism according to an embodiment of the present application.

Fig. 2 is a schematic structural diagram of a slitting and transverse cutting mechanism embodying the slitting mechanism according to the embodiment of the present application.

FIG. 3 is a schematic structural diagram of a cross cutting mechanism in an embodiment of the slitting and cross cutting mechanism of the present application.

FIG. 4 is a schematic structural diagram of the chemical fiber fabric composite slitting and transverse cutting integrated machine.

The reference number indicates, 1, a discharging mechanism; 2. a compounding mechanism; 3. a slitting mechanism; 4. a transverse cutting mechanism; 5. a crosscut bit drive mechanism; 6. a transducer drive mechanism; 7. a traction motor; 8. a frame; 9. a traction roller; 10. an upper pinch roller; 11. an upper pinch roller sliding seat; 12. an upper pinch roller cylinder; 13. a cutter head transmission shaft; 14. a transducer drive shaft; 15. a motor; 16. a speed reducer; 17. a synchronizing wheel; 18. a synchronous belt; 19. an offset detection mechanism; 20. connecting blocks; 21. connecting a screw rod; 22. adjusting the nut; 23. an upper sleeve body; 24. a lower sleeve body; 25. an upper clamping roller gear; 101. a discharge base; 102. a material placing frame; 103. a discharging groove; 104. a discharge carrier roller; 105. a slide rail; 106. a feed screw nut drive mechanism; 301. a slitting cutter head; 302. a slitting transducer; 303. a slitting cutter head cylinder; 304. slitting the transducer slide rail; 305. a cutter dividing seat; 306. slitting chain wheels; 307. a slitting cutter head driving roller; 308. a slitting tool bit slide rail; 309. a slitting transducer seat; 401. a crosscut cutter head; 402. a transverse cutting transducer; 403. a cutter head connecting seat; 404. a transducer connecting seat; 405. a transverse cutter head cylinder; 406. a tool bit slide rail; 407. a side plate; 408. a transducer slide rail; 409. a pinch roller; 410. a sliding seat; 411. a pinch roll cylinder; 412. a gear; 501. a cutter head transmission belt pulley; 502. a cutter head transmission belt; 601. a transducer drive pulley; 602. the transducer drives a belt.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

Example 1:

referring to fig. 1, the embodiment of the application discloses a splitting and transversely cutting mechanism, which comprises a frame 8, and a splitting mechanism 3, a traction mechanism and a transversely cutting mechanism 4 which are arranged on the frame 8, wherein the splitting mechanism 3 is used for splitting fabrics, the traction mechanism is used for traction of the fabrics, and the transversely cutting mechanism 4 is used for transversely cutting the split fabrics.

With reference to fig. 2 and 3, the slitting mechanism 3 comprises a plurality of slitting knives 301 and slitting transducers 302 corresponding to the slitting knives 301. Every cutter head 301 of cutting all fixes on a cutter seat 305 of cutting, and every cutter head 301 of cutting all is connected with a cutter head driving roller 307 of cutting through a sprocket 306 and chain of cutting, also sets up the sprocket on cutter head driving roller 307 of cutting and is connected with each sprocket 306 of cutting, just so can drive cutter head 301 of cutting through cutter head driving roller 307 of cutting and rotate, cuts cutter head 301 and cuts transducer 302 cooperation realization ultrasonic wave and cut. A slitting tool bit cylinder 303 is further arranged on the slitting tool base 305 and connected with the slitting tool bit 301, the distance between the slitting tool bit 301 and the slitting transducer 302 is adjusted, and the distance that the slitting tool bit cylinder 303 drives the slitting tool bit 301 to move is compensated through the tightness of a chain between the slitting chain wheel 306 and a chain wheel on the slitting tool bit driving roller 307.

Each slitting cutter seat 305 is arranged on a slitting cutter head sliding rail 308, and each slitting cutter seat 305 can slide and be locked on the slitting cutter head sliding rail 308, so that the width specification of fabric slitting can be adjusted. The same dividing transducer 302 is fixed to a dividing transducer holder 309, and the respective dividing transducer holder 309 can be slid and locked on the dividing transducer slide 304, so that the dividing transducer 302 can be adjusted correspondingly to the position of the dividing cutter head 301.

The surface fabric is cut through cutting between tool bit 301 and the transducer 302 of cutting, and the surface fabric after cutting is sent into crosscut mechanism 4 through drive mechanism traction and is crosscut, and drive mechanism includes a pair of carry over pinch rolls 9, and carry over pinch rolls 9 is connected with traction motor 7 through sprocket and chain, still drives through sprocket and chain and cuts tool bit driving roller 307 rotation on carry over pinch rolls 9.

With continued reference to fig. 2 and 3, the cross-cutting mechanisms 4 are provided in 3 groups, each group of cross-cutting mechanisms 4 being disposed in an up-down direction on the frame 8, each group of cross-cutting mechanisms 4 including a cross-cutting head 401 and a cross-cutting transducer 402. The transverse cutter head 401 is fixed on a cutter head connecting seat 403, and a transverse cutter head air cylinder 405 is further arranged on the cutter head connecting seat 403, and the transverse cutter head air cylinder 405 is connected with the transverse cutter head 401 and used for adjusting the distance between the transverse cutter head 401 and the transverse transducer 402. The cutter head connecting seat 403 is disposed on the cutter head slide rail 406 and can slide on the cutter head slide rail 406 along the width direction of the fabric. The two ends of the cutter head slide rail 406 are respectively fixed on the side plates 407 at the two sides of the frame 8.

The transverse transducer 402 is fixed on a transducer connecting seat 404, the transducer connecting seat 404 is arranged on a transducer sliding rail 408 and can slide on the transducer sliding rail 408, two ends of the transducer sliding rail 408 are respectively fixed on side plates 407 on two sides of the frame 8, and the transducer sliding rail 408 is arranged in parallel with the cutter head sliding rail 406.

A pair of pinch rollers 409 is also provided between the two side plates 407 of the same crosscutting mechanism 4, the height of the pinch rollers 409 being lower than the height of the crosscutting head 401. Two ends of one clamping roller 409 are fixed on the side plate 407 through fixing seats, and the other clamping roller 409 is connected through a sliding seat 410 and a clamping roller air cylinder 411. The two pinch rollers 409 are driven by the meshing of gears 412. A pair of upper pinch rollers 10 is further arranged above the first transverse cutter head 401, the two upper pinch rollers 10 are meshed through an upper pinch roller gear 25 for transmission, two ends of one upper pinch roller 10 are fixed on the machine frame 8 through fixed seats, and the other upper pinch roller 10 is connected through an upper pinch roller sliding seat 11 and an upper pinch roller cylinder 12.

Under the condition of normal transmission, the two upper clamping rollers 10 and the two clamping rollers 409 play a role in pulling the fabric, and when crosscutting is required, the upper clamping roller cylinder 12 drives the upper clamping roller sliding seat 11 to move so as to tightly abut against the two upper clamping rollers 10; the clamping roller cylinder 411 drives the sliding seat 410 to move, and the two clamping rollers 409 are tightly abutted, so that the fabric is clamped, and transverse cutting is performed.

The cutter head attachment base 403 is driven by the cross-cutter drive 5 to slide on the cutter head slide rail 406, and the transducer attachment base 404 is driven by the transducer drive 6 to slide on the transducer slide rail 408.

With continued reference to fig. 2 and 3, the transverse cutting head transmission mechanism 5 includes two cutting head transmission belt pulleys 501 arranged on two sides of the frame 8, the two cutting head transmission belt pulleys 501 are connected by a cutting head transmission belt 502, the cutting head connection seat 403 is fixedly connected with the cutting head transmission belt 502, and the rotation of the cutting head transmission belt 502 can drive the cutting head connection seat 403 to move on the cutting head slide rail 406.

The transducer transmission mechanism 6 comprises transducer transmission belt pulleys 601 arranged on two sides of the frame 8, the two transducer transmission belt pulleys 601 are connected through a transducer transmission belt 602, the transducer connection seat 404 is fixedly connected with the transducer transmission belt 602, and the transducer transmission belt 602 rotates to drive the transducer connection seat 404 to move along the width direction of the fabric.

The 3 cutter head transmission belt pulleys 501 on the same side of the frame 8 are connected through a cutter head transmission shaft 13, and the cutter head transmission belt pulleys 501 are fixed on the cutter head transmission shaft 13 through screws. The 3 transducer driving belt pulleys 601 on the same side of the frame 8 are connected through a transducer driving shaft 14, and the transducer driving belt pulleys 601 are fixed on the transducer driving shaft 14 through screws. The cutter head transmission shaft 13 is driven to rotate by a motor 15 and a speed reducer 16, and the cutter head transmission shaft 13 also drives the transducer transmission shaft 14 to synchronously rotate by a synchronous wheel 17 and a synchronous belt 18.

Referring to fig. 4, the embodiment also discloses a chemical fiber fabric composite slitting and transversely cutting all-in-one machine, which comprises a material discharging mechanism 1 for discharging materials, an offset detection mechanism 19, a composite mechanism 2 and a slitting and transversely cutting mechanism 3. The discharging mechanism 1 comprises a discharging base 101, and a discharging frame 102 is arranged on the discharging base 101. The bottom of the material placing frame 102 is connected with the material placing base 101 through a sliding rail 105 and a screw nut driving mechanism 106, and the material placing frame 102 can be driven to move back and forth on the material placing base 101 through the driving of the screw nut driving mechanism 106.

An arc-shaped discharging groove 103 is arranged on the discharging frame 102, a discharging carrier roller 104 is arranged on the surface of the arc-shaped discharging groove 103, and a material roll is placed on the discharging carrier roller 104 for discharging. The deviation detection mechanism 19 is used for detecting whether the material on the side deviates, and if the material deviates, a signal is sent to the controller, and the controller controls the screw nut driving mechanism 106 to act to drive the discharging frame 102 to move reversely to the side on which the material deviates so as to correct the deviation.

The materials are fed into a compound mechanism 2 for compounding after being discharged and rectified, and are fed into a slitting and transverse cutting mechanism 3 for slitting and transverse cutting after being compounded, wherein the slitting and transverse cutting mechanism 3 adopts the slitting and transverse cutting mechanism described in the figures 1-3.

The working principle of the embodiment is as follows:

the method comprises the steps of firstly selecting a proper number of discharging mechanisms 1 according to the number of layers of the fabric to be compounded, if the two layers are compounded, selecting two discharging mechanisms 1, feeding the two discharging mechanisms 1 into a compounding mechanism 2 to compound the two layers of fabric together after discharging and deviation rectifying respectively, and then feeding the two layers of fabric into a slitting and transverse cutting mechanism 3 to perform slitting and transverse cutting.

The working process of the slitting and transversely cutting mechanism 3 is as follows:

the position of the respective slitting tool seat 305 on the slitting tool slide 308 is first adjusted and locked, while the position of the respective slitting transducer seat 309 on the slitting transducer slide 304 is adjusted so that the slitting tool 301 corresponds to the position of the slitting transducer 302 and is locked. The compounded fabric is fed between the slitting tool bit 301 and the slitting transducer 302 and is fed to the transverse cutting mechanism 4 through a traction mechanism, the fabric passes through a pair of traction rollers 9, a pair of upper clamping rollers 10 and clamping rollers on each group of transverse cutting mechanisms 4, and the fabric is also distributed between the transverse cutting tool bit 401 and the transverse cutting transducer 402.

The traction mechanism acts to traction the fabric, and the slitting tool bit driving roller 307 drives the slitting tool bit 301 to rotate to slit the fabric. The surface fabric after cutting is through drawing the back, get into crosscut mechanism 4 and carry out the crosscut, the in-process of crosscut, through a pair of pinch rolls 409 on every crosscut mechanism 4, and a pair of pinch rolls 10 clamp tightly on the frame 8, tighten the surface fabric, then pass through the motor again, the speed reducer, the synchronizing wheel, the hold-in range, drive tool bit transmission shaft 13 and 14 synchronous rotations of transducer transmission shaft, drive tool bit transmission pulley 501 and transducer transmission pulley 601 synchronous rotation, and then drive crosscut tool bit 401 and crosscut transducer 402 synchronous motion, realize the crosscut of surface fabric, this process can once only carry out the crosscut of 3 swords, the efficiency of crosscut has been improved by a wide margin.

Example 2:

the rest of this embodiment is the same as embodiment 1, except that, in this embodiment, the 3 transverse cutting mechanisms 4 distributed in the up-down direction of the rack 8 are not adjustable according to the height position of the side plate 407 of the uppermost transverse cutting mechanism 4 and the rack 8, and the height positions of the middle and lowermost transverse cutting mechanisms 4 on the rack are adjustable, and the specific structure is as follows:

the side plates 407 of the middle and lowest transverse cutting mechanisms 4 are arranged on the frame 8 through slide rails, each side plate 407 is provided with a connecting block 20, the connecting blocks 20 on the same side are connected through connecting screws 21, the lower ends of the connecting blocks 20 are connected with the connecting screws 21 through adjusting nuts 22 and are used for supporting the connecting blocks 20, the upper ends of the connecting screws 21 are connected with an upper sleeve body 23, and the upper sleeve body 23 is fixed on the side plate 407 of the uppermost transverse cutting mechanism 4; the lower end of the connecting screw 21 is connected to a lower sleeve 24, and the lower sleeve 23 is fixed to the frame 8, so that the distance between the respective traverse mechanisms 4 can be adjusted by turning the adjusting nut 22. So that the fabric can be cut into different specifications.

The embodiments of the present invention are preferred embodiments of the present application, and the scope of protection of the present application is not limited by the embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (10)

1. The utility model provides a cut crosscut mechanism which characterized in that: the fabric slitting machine comprises a rack (8), a slitting mechanism (3) and a transverse cutting mechanism (4), wherein the slitting mechanism (3) is arranged on the rack (8), the slitting mechanism comprises a plurality of slitting knife heads (301), each slitting knife head (301) is distributed on the rack (8) along the width direction of fabric, and each slitting knife head (301) is correspondingly provided with a slitting transducer (302); the transverse cutting mechanism (4) comprises a transverse cutting head (401) and a transverse cutting transducer (402) corresponding to the transverse cutting head (401), the transverse cutting head (401) is arranged on the rack (8) in a sliding mode through a cutting head connecting seat (403), and the transverse cutting transducer (402) is arranged on the rack (8) in a sliding mode through a transducer connecting seat (404); the cutter head connecting seat (403) and the transducer connecting seat (404) are driven by a transverse transmission mechanism to synchronously move along the width direction of the fabric.

2. A slitting and crosscutting mechanism according to claim 1, characterized in that: the transverse cutting transmission mechanism comprises a transverse cutting head transmission mechanism (5) and a transducer transmission mechanism (6), wherein the transverse cutting head transmission mechanism (5) comprises cutting head transmission belt wheels (501) arranged on two sides of a rack (8), the two cutting head transmission belt wheels (501) are connected through a cutting head transmission belt (502), a cutting head connecting seat (403) is fixedly connected with the cutting head transmission belt (502), and the cutting head transmission belt (502) rotates to drive the cutting head connecting seat (403) to move along the width direction of the fabric; transducer drive mechanism (6) including setting up transducer drive belt pulley (601) in frame (8) both sides, adopt transducer drive belt (602) to connect between two transducer drive belt pulleys (601), transducer connecting seat (404) and transducer drive belt (602) fixed connection, the width direction removal that can drive transducer connecting seat (404) along the surface fabric is rotated to belt transducer drive belt (602).

3. A slitting and crosscutting mechanism according to claim 2, characterized in that: the utility model provides a pair of tool bit, including frame (8) the both sides be provided with curb plate (407), be provided with transducer slide rail (408) and tool bit slide rail (406) between two curb plates (407), tool bit connecting seat (403) set up tool bit slide rail (406) on, transducer connecting seat (404) set up transducer slide rail (408) on.

4. A slitting and crosscutting mechanism according to claim 3, characterized in that: at least two groups of side plates (407) are arranged in the vertical height direction of the frame (8), a transverse cutting mechanism (4) is arranged between each group of side plates (407), and the height of at least one group of side plates (407) in each group of side plates (407) can be adjusted.

5. A slitting and crosscutting mechanism according to claim 4, characterized in that: an adjusting mechanism is arranged between the side plates (407) on the same side of the rack (8) and used for adjusting the distance between the upper side and the lower side of each side plate (407); the adjusting mechanism comprises connecting blocks (20) arranged on the side plates (407), connecting screws (21) are adopted to connect the connecting blocks (20) on the same side, and the lower ends of the connecting blocks (20) are connected with the connecting screws (21) through adjusting nuts (22) and used for supporting the connecting blocks (20).

6. A slitting and crosscutting mechanism according to claim 4, characterized in that: the frame (8) is provided with a transverse cutting clamping mechanism which comprises at least two groups of clamping roller mechanisms.

7. A slitting and crosscutting mechanism according to claim 4, characterized in that: the cutter head transmission belt pulleys (501) on each group of transverse cutter head transmission mechanisms (5) are driven by a cutter head transmission shaft (13), and the transducer transmission belt pulleys (601) on each group of transducer transmission mechanisms (6) are driven by a transducer transmission shaft (14); the cutter head transmission shaft (13) is connected with the transducer transmission shaft (14) by a synchronous transmission mechanism to enable the cutter head transmission shaft and the transducer transmission shaft to synchronously rotate.

8. A slitting and crosscutting mechanism according to claim 1, characterized in that: the slitting cutter head (301) is connected with the slitting cutter head cylinder (303); the transverse cutter head (401) is connected with a transverse cutter head cylinder (405).

9. A slitting and crosscutting mechanism according to claim 1, characterized in that: the slitting cutter head (301) can move along the width direction of the fabric and be locked by the frame (8).

10. The utility model provides a crosscut all-in-one is cut to chemical fiber surface fabric complex which characterized in that: the device comprises a feeding mechanism (1) for feeding materials, a composite mechanism (2) for compounding the materials and a slitting and transverse cutting mechanism for slitting and transversely cutting the compounded fabric; the slitting and transverse cutting mechanism is as claimed in any one of claims 1-9.

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