CN113580727B - Double-layer cloth bonding process - Google Patents

Abstract

The invention relates to the technical field of double-layer cloth, in particular to a double-layer cloth bonding process, which is matched with double-layer cloth bonding equipment. Can high-efficient stable bonding cloth prevents simultaneously that glue from spilling over on the cloth from causing the influence to equipment.

Description

Double-layer cloth bonding process

Technical Field

The invention relates to the technical field of double-layer cloth, in particular to a double-layer cloth bonding process.

Background

The cloth bonding process bonds the cloth and the cloth with an adhesive, instead of sewing the cloth with a needle and a stitch. The cloth bonding process bonds the cloth and the cloth by using an adhesive, so that the seam unevenness generated on the surface of the cloth during sewing caused by the seam can be eliminated, and the surface of the cloth after processing is smooth. Therefore, the cloth bonding process can produce clothes and the like which are not uncomfortable due to concave and convex feeling when being worn.

The glue spraying device used in the conventional cloth bonding process is used for dispensing, and an operator is required to conduct manual alignment for many times, so that the operator is required to be always in concentration and cannot leave a station in the production process, and otherwise, the phenomenon that the glue is not firmly fallen off can occur. And because the cloth is softer, the folding condition appears in the part in the conveying process, and the place bonding dislocation can be caused to produce the waste product, so that there is room for improvement.

Disclosure of Invention

The invention aims at solving the problems in the prior art, and provides a double-layer cloth bonding process which is used for linearly bonding double-layer cloth and has the effects of improving the firmness of the double-layer cloth and reducing the rejection rate of finished products.

In order to achieve the above purpose, the present invention adopts the following technical scheme: the utility model provides a double-deck cloth bonding technology, its cooperation has used a double-deck cloth bonding equipment, this double-deck cloth bonding equipment is including installing subaerial support frame, first belt, output conveyer belt, be equipped with the fixed conveyer of cloth on the support frame, first belt is equipped with the negative pressure device that the cloth cleared up and removes the wrinkle towards the upside of output conveyer belt, be equipped with between first belt and the output conveyer belt and carry out the rubber coating device of linear rubber coating and to double-deck cloth compression forming device.

Preferably, the fixed conveyer of cloth is including installing subaerial support frame, support frame middle part side is equipped with first backup pad, fixed being equipped with first servo motor in the first backup pad, first gear is connected to first servo motor's output, be equipped with the second gear directly over the first gear, first gear and second gear pass through the transmission of third gear meshing, the third gear rotates to be connected on the support frame, the support frame left part is kept away from one side on ground and is equipped with two rows of first driving rollers in parallel, first gear and second gear connection first driving roller on the right, first driving roller one side is equipped with the drive chain of meshing, every row first driving roller on be equipped with first belt, the support frame right side is equipped with the output conveyer belt, be equipped with the work opening between output conveyer belt and the first belt, the work opening below is equipped with glue collecting vat.

Preferably, the output conveyor belt comprises a second supporting plate, a second servo motor is fixedly arranged on the second supporting plate, one side, far away from the ground, of the right part of the supporting frame is provided with a row of second driving rollers, the output end of the second servo motor is connected with the rightmost second driving roller, one side of the second driving roller is provided with a meshed second driving chain, and the second driving roller is provided with a second belt.

Preferably, the negative pressure device comprises a third supporting plate, the opposite one side of first backup pad is set up to the third backup pad on the support frame, the fixed aspiration pump that is equipped with of third backup pad, the gas treatment case is connected to the aspiration pump end, gas treatment case bottom symmetry is equipped with two liquid change switches, gas treatment case left side is connected and is equipped with three first air flue in first belt right side top and output conveyer belt left side top, every first air flue all is connected the arc air suction way, and every arc air suction way lower extreme evenly opens has a plurality of suction hole, and every arc air suction way both ends all set firmly first supporting shoe, first supporting shoe fixed connection is on the support frame.

Preferably, the glue spreading device comprises a fourth supporting plate, the fourth supporting plate is fixedly arranged on the supporting frame and is close to the inner side of the first supporting plate, a third servo motor is arranged on the fourth supporting plate, the output end of the third servo motor is connected with one end of a first rolling shaft, the other end of the first rolling shaft is fixedly connected with a glue storage box cover, the glue storage box cover is fixedly connected with the glue storage box body, two ends of the glue storage box body are semicircular, the middle is in a straight line shape, first sliding grooves are respectively arranged on two semicircular surfaces of the glue storage box cover, a first sliding block is arranged on each first sliding groove, a spring is connected between the inner side of each first sliding groove and the first sliding block, each first sliding groove is provided with a first glue injection channel, two first glue outlet grooves are symmetrically arranged at two ends of the glue storage box body, a partition plate is arranged in the middle of the glue storage box body, four second sliding grooves are respectively symmetrically arranged at two sides of the middle of the glue storage box body, and two heating plates are symmetrically arranged at left and right sides of the middle of the glue storage box body.

Preferably, the glue storage box cover outside is equipped with the injecting glue lid, on injecting glue lid fixed connection injecting glue box, the injecting glue box lower extreme is opened there is the second and goes out the gluey groove, injecting glue lid upper end is equipped with and first spout endocentric second injecting glue passageway, second injecting glue passageway is equipped with the ring channel all around, be equipped with an annular slider on the ring channel, annular slider is close to glue storage box one side and seals, and the opposite side is opened, annular slider is close to glue storage box one side and is equipped with the injecting glue mouth, the symmetry is equipped with two second spouts on the ring channel, every all be equipped with the second slider on the second spout, every be connected with the spring between second spout inboard and the second slider, injecting glue lid fixed connection second supporting shoe, second supporting shoe fixed connection is on the support frame, the opposite side of fourth backup pad is equipped with sixth backup pad and above-mentioned support frame fixed connection, sixth backup pad sets firmly the glue machine, the glue outlet of the glue machine connects out the other end, the second injecting glue passageway is connected to the glue outlet.

Preferably, the press forming device comprises a fifth supporting plate, the fifth supporting plate is arranged at the working opening and fixedly connected with the supporting frame, a fourth servo motor is arranged on the fifth supporting plate, the output end of the fourth servo motor is connected with a fourth gear, a meshed fifth gear is arranged right above the fourth gear, one end of the fourth gear, far away from the fourth servo motor, is fixedly connected with a second rolling shaft, the other end of the second rolling shaft is fixedly connected with a third rolling shaft, one end of the fifth gear on the same side of the second rolling shaft is fixedly connected with a third rolling shaft, the other end of the third rolling shaft is fixedly connected with a concave roller, the convex roller and the concave roller are mutually matched, a plurality of third sliding grooves are symmetrically arranged on the contact surface of the convex roller and the concave roller along the circumferential direction, a first guide rail is arranged on the third guide rail, two second guide rails are symmetrically arranged above the third sliding block, and a fourth sliding block is arranged on the third sliding block.

Preferably, two fourth sliding grooves are symmetrically arranged below the fourth sliding block in a left-right mode, a spring is arranged between each third sliding block and each fourth sliding block, a second air passage is arranged in the middle of each fourth sliding block, two perpendicular third air passages are symmetrically arranged on the upper portion of each second air passage in a left-right mode, a fourth air passage is arranged on the right side of the lower portion of each second air passage, an air pipe is connected to the fourth air passage, a groove is formed in the convex roller in a matched mode along the third sliding groove and the fourth air passage, a fifth air passage is arranged at the axis of the convex roller, one end of each fifth air passage is connected with the air pipe, the other end of each fifth air passage is connected with the first air passage, a fifth sliding groove is arranged below the fourth air passage, a pin is arranged on the fifth sliding groove, the left side of each pin is hemispherical, a spring is connected between each pin and the fourth sliding block, a sixth sliding groove is arranged on the convex roller, the sixth sliding groove is matched with the pin in a non-pressed state, and the upper portion of the sixth sliding groove is a cambered surface.

The double-layer cloth bonding processing technology comprises the following steps:

s1: traction and transportation are carried out, and cloth is pushed into the upper first belt and the lower first belt respectively, so that the cloth moves on the first belts;

s2: cleaning and removing wrinkles, wherein when the cloth reaches the right end of the first belt, the arc-shaped suction channel uniformly sucks the cloth, and the part where the falling fiber and the edge of the opened cloth possibly fold is adsorbed;

s3: linearly gluing, namely injecting glue through the first glue injection channel, pushing the partition plate to move downwards, and uniformly linearly spraying the glue on the upper surface of the lower cloth from the second glue outlet groove, so that the aim that the contact surfaces of the double-layer cloth are coated with the glue is fulfilled;

s4: the fourth sliding block receives a friction force opposite to the rolling direction and a reaction force given by the convex roller when the double-layer cloth is pressed by the convex roller and the concave roller which are matched with each other, so that the fourth sliding block moves along the third sliding groove and drives the adsorbed cloth to be smoothed;

s5: packaging and transporting, namely packaging and transporting the pressed double-layer cloth.

The beneficial effects are that:

1. the linear gluing can be continuously provided for the cloth through the running fit of the glue storage box and the glue injection box, so that the contact surfaces of the double-layer cloth can be uniformly coated with the glue, and the firmness of the double-layer cloth is effectively improved;

2. the folded fabric of the falling fiber and the unfolding part can be adsorbed by the arc-shaped air suction channel, and the folds of the fabric in the pressing process are smoothed by the fourth sliding block, so that the yield of the double-layer fabric is effectively improved;

3. the convex roller and the concave roller which are matched with each other can enable redundant glue on the cloth to flow into the collecting groove at the bottom along the arc surface, so that the accumulation of the glue is avoided and the waste of the glue can be reduced.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a top view of the present invention;

FIG. 3 is a cross-sectional view of the negative pressure system of the present invention;

FIG. 4 is a cross-sectional view of the glue injection box of the present invention;

FIG. 5 is a cross-sectional view of a glue injection cover of the present invention;

FIG. 6 is a front view of the press forming apparatus of the present invention;

fig. 7 is a partial cross-sectional view at a in fig. 6.

In the figure: the cloth fixing transfer apparatus 1, the support frame 101, the first support plate 109, the first servo motor 108, the first gear 107, the second gear 105, the third gear 106, the first driving roller 104, the driving chain 103, the first belt 102, the output conveyor 110, the work opening 111, the glue collecting tank 117, the second support plate 112, the second servo motor 113, the second driving roller 114, the second driving chain 115, the second belt 116, the negative pressure device 2, the third support plate 201, the suction pump 202, the air treatment tank 203, the liquid change switch 204, the first air passage 205, the arc-shaped suction passage 206, the suction hole 207, the first support block 208, the glue applying device 3, the fourth support plate 301, the third servo motor 302, the first rolling shaft 303, the glue storage tank cap 311, the glue storage tank 306, the first chute 312, the first slider 314, the first spring 313, the first glue injection passage 321, the first glue discharge tank 309, the partition plate 307, the second runner 322, the heating plate 308, the glue injection cover 323, the glue injection box 305, the second glue outlet 310, the second glue injection channel 320, the annular groove 319, the annular slider 315, the glue injection port 316, the runner 324, the second slider 317, the second spring 318, the second support block 304, the press molding device 4, the sixth support plate 325, the glue melter 326, the glue outlet 327, the fifth support plate 401, the fourth servo motor 402, the fourth gear 403, the fifth gear 404, the second rolling shaft 405, the male roller 407, the third rolling shaft 406, the female roller 408, the third runner 409, the first guide rail 420, the third slider 421, the second guide rail 424, the fourth slider 410, the fourth runner 423, the third spring 422, the second runner 412, the third runner 411, the fourth runner 414, the air pipe 413, the runner 415, the fifth runner 425, the fifth runner 419, the pin 417, the fourth spring 418, and the sixth runner 416.

Detailed Description

The following are specific embodiments of the present invention and the technical solutions of the present invention will be further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

In the description of the present invention, it should be noted that, the azimuth or positional relationship indicated by the terms "inner", "lower", etc. are based on the azimuth or positional relationship shown in the drawings, or the azimuth or positional relationship that the inventive product is conventionally put in use, are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific azimuth, be configured and operated in a specific azimuth, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used merely to distinguish between descriptions and should not be construed as indicating or implying relative importance.

With reference to fig. 1, a double-layer cloth bonding process is matched with a double-layer cloth bonding device, the double-layer cloth bonding device comprises a support frame 101, a first belt 102 and an output conveyor belt 110, wherein the support frame 101 is provided with a cloth fixing and conveying device 1, the first belt 102 is provided with a cloth cleaning and wrinkle removing negative pressure device 2 towards the upper side of the output conveyor belt 110, and a gluing device 3 for linearly gluing cloth and a double-layer cloth pressing and forming device 4 are arranged between the first belt 102 and the output conveyor belt 110.

Referring to fig. 1 and 2, the cloth fixing and conveying device 1 includes a support frame 101 installed on the ground, a first support plate 109 is arranged on the side surface of the middle of the support frame 101, a first servo motor 108 is fixedly arranged on the first support plate 109, an output end of the first servo motor 108 is connected with a first gear 107, a second gear 105 is arranged right above the first gear 107, the first gear 107 and the second gear 105 are in meshed transmission through a third gear 106, the third gear 106 is rotatably connected on the support frame 101, two rows of first driving rollers 104 are parallelly arranged on one side, far away from the ground, of the left part of the support frame 101, the first driving rollers 104 are connected with the first driving rollers 104 on the right, meshed driving chains 103 are arranged on one side of the first driving rollers 104 on each row, a first belt 102 is arranged on the right side of the support frame 101, a working opening 111 is arranged between the output driving belt 110 and the first belt 102, and a glue collecting groove 117 is arranged below the working opening 111.

The output conveyor belt 110 comprises a second supporting plate 112, a second servo motor 113 is fixedly arranged on the second supporting plate 112, a row of second driving rollers 114 are arranged on one side, far away from the ground, of the right part of the supporting frame 101, the output end of the second servo motor 113 is connected with the rightmost second driving roller 114, a meshed second driving chain 115 is arranged on one side of the second driving roller 114, and a second belt 116 is arranged on the second driving roller 114.

Referring to fig. 2 and 3, the negative pressure device 2 includes a third supporting plate 201, the third supporting plate 201 is disposed on one side opposite to the first supporting plate 109 on the supporting frame 101, an air pump 202 is fixedly disposed on the third supporting plate 201, an air pumping end of the air pump 202 is connected with an air processing box 203, two liquid change switches 204 are symmetrically disposed at the bottom of the air processing box 203, three first air channels 205 are disposed on the right side of the first belt 102 and the left side of the output conveyor belt 110 in a connected manner, each first air channel 205 is connected with an arc air suction channel 206, a plurality of air suction holes 207 are uniformly formed in the lower end of each arc air suction channel 206, first supporting blocks 208 are fixedly disposed at two ends of each arc air suction channel 206, and the first supporting blocks 208 are fixedly connected to the supporting frame 101. The pump 202 is conventional and will not be described in detail herein.

Referring to fig. 2, 4 and 5, the glue spreading device 3 includes a fourth supporting plate 301, the fourth supporting plate 301 is fixedly disposed on the supporting frame 101 and near to the inner side of the first supporting plate 109, a third servo motor 302 is disposed on the fourth supporting plate 301, an output end of the third servo motor 302 is connected with one end of the first rolling shaft 303, the other end of the first rolling shaft 303 is fixedly connected to a glue storage box cover 311, the glue storage box cover 311 is fixedly connected to the glue storage box 306, two ends of the glue storage box 306 are semicircular, a straight line is formed in the middle, first sliding grooves 312 are respectively disposed on two semicircular surfaces of the glue storage box cover 311, a first sliding block 314 is disposed on each first sliding groove 312, a first spring 313 is connected between the inner side of each first sliding groove 312 and the first sliding block 314, each first sliding groove 312 is provided with a first glue injection channel 321, two first glue outlet grooves 309 are symmetrically disposed at two ends of the glue storage box 306, a partition plate 307 is disposed in the middle of the glue storage box 306, four second sliding grooves 322 are respectively disposed on two sides of the glue storage box cover 311 and symmetrically disposed on two sides of the middle of the glue storage box 306 near to the glue storage box cover 311, and two heating plates 308 are symmetrically disposed on the left and right sides of the middle of the glue storage box 306.

Referring to fig. 2, 4 and 5, the outer side of the glue storage box cover 311 is provided with a glue injection cover 323, the glue injection cover 323 is fixedly connected with the glue injection box body 305, the lower end of the glue injection box body 305 is provided with a second glue outlet groove 310, the upper end of the glue injection cover 323 is provided with a second glue injection channel 320 concentric with the first chute 312, the periphery of the second glue injection channel 320 is provided with an annular groove 319, the annular groove 319 is provided with an annular slide block 315, the annular slide block 315 is closed near one side of the glue storage box body 306, the other side is opened, one side of the annular slide block 315 near the glue storage box body 306 is provided with a glue injection opening 316, the upper side and the lower side of the annular groove 319 are symmetrically provided with two chutes 324, each chute 324 is provided with a second slide block 317, a second spring 318 is connected between the inner side of each chute 324 and the second slide block 317, the glue injection cover 323 is fixedly connected with a second support block 304, the second support block 304 is fixedly connected with the support frame 101, the opposite side of the fourth support plate 301 is provided with a sixth support plate 325 fixedly connected with the support frame 101, the sixth support plate 325 is provided with a glue melting machine 326, the glue outlet opening of the glue melting machine 326 is connected with the glue outlet pipe 327, and the glue outlet opening of the second glue injection channel 320 is connected with the second glue injection channel 320. The glue applicator 326 is conventional and will not be described in detail herein.

Referring to fig. 1, 6 and 7, the press forming device 4 includes a fifth supporting plate 401, the fifth supporting plate 401 is disposed at the working opening 111 and is fixedly connected with the supporting frame 101, a fourth servo motor 402 is disposed on the fifth supporting plate 401, an output end of the fourth servo motor 402 is connected with a fourth gear 403, a meshed fifth gear 404 is disposed right above the fourth gear 403, one end of the fourth gear 403 far away from the fourth servo motor 402 is fixedly connected with a second rolling shaft 405, the other end of the second rolling shaft 405 is fixedly connected with a convex roller 407, one end of the fifth gear 404 on the same side of the second rolling shaft 405 is fixedly connected with a third rolling shaft 406, the other end of the third rolling shaft 406 is fixedly connected with a concave roller 408, the convex roller 407 is mutually matched with the concave roller 408, a plurality of third sliding grooves 409 are symmetrically disposed on a contact surface of the convex roller 407 and the concave roller 408 along a circumferential direction, a first guide rail 420 is disposed on the first guide rail 420, two second guide rails 424 are symmetrically disposed above the third sliding block 421, and a fourth sliding block 410 is disposed on the third sliding block 421.

Referring to fig. 1, 6 and 7, two fourth sliding grooves 423 are symmetrically arranged below the fourth sliding block 410 in a left-right direction, a third spring 422 is arranged between each third sliding block 421 and the fourth sliding block 410, a second air passage 412 is arranged in the middle of the fourth sliding block 410, two perpendicular third air passages 411 are symmetrically arranged above the second air passage 412 in a left-right direction, a fourth air passage 414 is arranged on the right side of the lower portion of the second air passage 412, an air pipe 413 is connected to the fourth air passage 414, a groove 415 is arranged along the third sliding groove 409 in a matched manner with the fourth air passage 414, a fifth air passage 425 is arranged at the axial center of the convex roller 407, one end of the fifth air passage 425 is connected with the air pipe 413, the other end of the fifth air passage 425 is connected with the first air passage 205, a fifth sliding block 419 is arranged below the fourth air passage 414, a pin 417 is arranged on the fifth sliding groove 419, the left side of the rectangular body is hemispherical, a fourth spring 418 is connected between the pin 417 and the fourth sliding block 410, a sixth sliding groove 416 is arranged on the right side, a fifth sliding groove 416 is matched with the sixth sliding groove 416 in a non-pressed state, and the upper surface 416 is a lower cambered surface 417.

The double-layer cloth bonding processing technology comprises the following steps:

s1: traction and transportation, namely pushing cloth onto the upper first belt 102 and the lower first belt 102 respectively, so that the cloth moves on the first belts 102;

s2: cleaning and removing wrinkles, wherein when the cloth reaches the right end of the first belt 102, the arc-shaped suction channel 206 uniformly sucks the cloth, and the fiber falling off and the part possibly folded when the edge of the cloth is opened are adsorbed;

s3: linearly gluing, namely injecting glue through the first glue injection channel 321, pushing the partition plate 307 to move downwards, and uniformly linearly spraying the glue on the upper surface of the lower cloth through the second glue outlet groove 310, so that the purpose that the contact surfaces of the double-layer cloth are coated with the glue is achieved;

s4: when the double-layer cloth is pressed by the matched convex roller 407 and concave roller 408, the fourth slider 410 receives a friction force opposite to the rolling direction and a reaction force given by the convex roller 407, so that the fourth slider 410 moves along the third sliding groove 409 and drives the adsorbed cloth to be smoothed;

s5: packaging and transporting, namely packaging and transporting the pressed double-layer cloth.

Working principle: the first servo motor 108 is adjusted to obtain the first belts 102 with different transmission speeds, cloth is pushed onto the upper first belt 102 and the lower first belt 102 respectively, so that the cloth moves on the first belts 102, the suction force of the suction pump 202 reaches the arc-shaped suction channel 206 through the first air channel 205, the suction force is evenly given to the cloth, the part, which possibly folds when the fiber falls off and the edge of the cloth is opened, is adsorbed, a solution capable of dissolving glue is placed in the gas treatment tank 203, the fiber is also left in the solution when passing, and the solution can be replaced through the liquid change switch 204 at the bottom after a period of time.

When the cloth passes through the working opening 111, the first sliding groove 312 is aligned with the second glue injection channel 320, the second spring 318 pushes the second sliding block 317 forward until the second sliding block 317 is pushed onto the glue storage box cover 311, the annular sliding block 315 is driven to enter the first sliding groove 312 to push the first sliding block 314, the glue injection opening 316 is aligned with the first glue injection channel 321, the glue melting machine 326 injects glue into the glue storage box 306 through the glue outlet pipe 327, the separation plate 307 is pushed to move downwards along the second sliding groove 322, and the glue is uniformly sprayed on the cloth linearly from the second glue outlet groove 310. The heating plate 308 may prevent glue from solidifying in the glue reservoir 306. Can continuously provide linear gluing for the cloth, so that the contact surface of the double-layer cloth is uniformly coated with the glue, thereby achieving the purpose of improving the firmness of the double-layer cloth.

The convex roller 407 and the concave roller 408 are matched with each other, so that redundant glue on the cloth can flow into the collecting groove at the bottom along the arc surface, the accumulation of the glue is avoided, and the waste of the glue can be reduced. When the cloth passes through the fourth slider 410, the fourth slider 410 is pressed downwards, and the pin 417 with a semicircular bottom passes through the cambered surface of the sixth chute 416, so that the fourth spring 418 is pushed to compress towards the fifth chute 419, and finally the fourth slider 410 is flush with the convex roller 407. The second air passage 412 on the fourth slider 410 is connected to the first air passage 205 through the air pipe 413 and the fifth air passage 425. The fourth slider 410 receives a frictional force opposite to the rolling direction and a reaction force given by the convex roller 407, so that the fourth slider 410 moves along the third sliding groove 409. The fourth slider 410 adsorbs the cloth to move to two sides, so as to smooth the cloth. When the fourth slider 410 is rotated to a position where it is separated from the cloth, it slides back to the middle of the convex roller 407 due to gravity, and the fourth spring 418 pushes the pin 417 into the sixth runner 416, so that the fourth slider 410 can continue to move only after being pressed down again.

The press formed double layer cloth is finally transported away from the package by the output conveyor 110.

The foregoing description is only illustrative of the present invention and is not intended to limit the scope of the invention, and all equivalent structures or equivalent processes using the descriptions and the drawings of the present invention or directly or indirectly applied to other related technical fields are included in the scope of the invention.

Claims (4)

1. The double-layer cloth bonding equipment is characterized by comprising a support frame (101), a first belt (102) and an output conveyor belt (110), wherein the support frame (101) is provided with a cloth fixing and conveying device (1), the first belt (102) is provided with a negative pressure device (2) for cleaning and removing wrinkles of cloth towards the upper side of the output conveyor belt (110), and a gluing device (3) for linearly gluing the cloth and a double-layer cloth compression forming device (4) are arranged between the first belt (102) and the output conveyor belt (110); the cloth fixing and conveying device (1) further comprises a first supporting plate (109) arranged on the side face of the middle of the supporting frame (101), a first servo motor (108) is fixedly arranged on the first supporting plate (109), the output end of the first servo motor (108) is connected with a first gear (107), a second gear (105) is arranged right above the first gear (107), the first gear (107) and the second gear (105) are in meshed transmission through a third gear (106), the third gear (106) is rotationally connected onto the supporting frame (101), two rows of first transmission rollers (104) are arranged on the left side of the supporting frame (101) far away from the ground in parallel, the first gear (107) and the second gear (105) are connected with the rightmost first transmission rollers (104), a meshed transmission chain (103) is arranged on one side of each row of first transmission rollers (104), a first belt (102) is arranged on the right side of the supporting frame (101), an output transmission belt (110) is arranged on the right side of the supporting frame (101), two rows of first transmission rollers (104) are provided with glue water collecting grooves (111) are formed in the left opening of the first belt (110); the output conveyor belt (110) comprises a second supporting plate (112), a second servo motor (113) is fixedly arranged on the second supporting plate (112), a row of second driving rollers (114) are arranged on one side, far away from the ground, of the right part of the supporting frame (101), the output end of the second servo motor (113) is connected with the rightmost second driving roller (114), a meshed second driving chain (115) is arranged on one side of the second driving roller (114), and a second belt (116) is arranged on the second driving roller (114); the negative pressure device (2) comprises a third supporting plate (201), the third supporting plate (201) is arranged on one side opposite to a first supporting plate (109) on a supporting frame (101), an air suction pump (202) is fixedly arranged on the third supporting plate (201), an air suction end of the air suction pump (202) is connected with a gas treatment box (203), two liquid change switches (204) are symmetrically arranged at the bottom of the gas treatment box (203), three first air passages (205) above the right side of a first belt (102) and above the left side of an output conveyor belt (110) are connected to the left side of the gas treatment box (203), each first air passage (205) is connected with an arc-shaped air suction passage (206), a plurality of air suction holes (207) are uniformly formed in the lower end of each arc-shaped air suction passage (206), first supporting blocks (208) are fixedly arranged at two ends of each arc-shaped air suction passage (206), and the first supporting blocks (208) are fixedly connected to the supporting frame (101); the press forming device (4) comprises a fifth supporting plate (401), the fifth supporting plate (401) is fixedly connected with the supporting frame (101) at the position of the working opening (111), a fourth servo motor (402) is arranged on the fifth supporting plate (401), the output end of the fourth servo motor (402) is connected with a fourth gear (403), a meshed fifth gear (404) is arranged right above the fourth gear (403), one end of the fourth gear (403) far away from the fourth servo motor (402) is fixedly connected with a second rolling shaft (405), the other end of the second rolling shaft (405) is fixedly connected with a third rolling shaft (406) at the same side end of the second rolling shaft (405), the other end of the third rolling shaft (406) is fixedly connected with a concave roller (408), the convex roller (407) is mutually matched with the concave roller (408), a third sliding groove (409) is symmetrically arranged on a contact surface of the concave roller (408) along the left and right directions, a plurality of sliding grooves (420) are symmetrically arranged on the third sliding grooves (420), a plurality of sliding blocks (420) are symmetrically arranged on the third sliding grooves (420), a fourth slider (410) is arranged on the third slider (421); two fourth sliding grooves (423) are symmetrically arranged below the fourth sliding block (410) left and right, the second guide rail (424) is matched with the fourth sliding grooves (423), a third spring (422) is arranged between each third sliding block (421) and the fourth sliding block (410), a second air passage (412) is arranged in the middle of the fourth sliding block (410), two perpendicular third air passages (411) are symmetrically arranged above the second air passage (412), a fourth air passage (414) is arranged on the right side of the lower part of the second air passage (412), an air pipe (413) is connected to the fourth air passage (414), a groove (415) is arranged along the third sliding groove (409) and the fourth air passage (414) in a matched mode, a fifth air passage (425) is arranged at the axle center of the convex roller (407), one end of the fifth air passage (425) is connected with the air pipe (413), the other end of the fourth sliding block (410) is connected with the first air passage (205), a fifth air passage (419) is arranged below the fourth sliding block (414), a fourth sliding groove (417) is connected to the fourth sliding block (417), a hemispherical pin (417) is arranged on the left side of the fourth sliding block (417), the sixth chute (416) is matched with the pin (417) in the non-pressing state, and the upper part of the sixth chute (416) is a plane and the lower part is a cambered surface.

2. The double-layer cloth bonding apparatus according to claim 1, wherein the glue coating device (3) comprises a fourth supporting plate (301), the fourth supporting plate (301) is fixedly arranged on the supporting frame (101) and is close to the inner side of the first supporting plate (109), a third servo motor (302) is arranged on the fourth supporting plate (301), the output end of the third servo motor (302) is connected with one end of a first rolling shaft (303), the other end of the first rolling shaft (303) is fixedly connected to a glue storage box cover (311), the glue storage box cover (311) is fixedly connected to a glue storage box body (306), two ends of the glue storage box body (306) are semicircular, the middle is in a straight line shape, first sliding grooves (312) are respectively arranged on two semicircular surfaces of the glue storage box cover (311), a first sliding block (314) is arranged on each first sliding groove (312), a first spring (313) is connected between the inner side of each first sliding groove (312) and the first sliding block (314), each first sliding groove (321) is fixedly connected to a glue storage box cover (311), two middle glue storage boxes (306) are symmetrically arranged at two sides of the glue storage box cover (306), two middle glue storage boxes (306) are symmetrically arranged at two sides of the two glue storage box bodies (306) respectively, two heating plates (308) are symmetrically arranged in the middle of the glue storage box body (306) in a left-right mode.

3. The double-layer cloth bonding apparatus of claim 2, wherein the outer side of the glue storage box cover (311) is provided with a glue injection cover (323), the glue injection cover (323) is fixedly connected with the glue injection box body (305), the lower end of the glue injection box body (305) is provided with a second glue outlet groove (310), the upper end of the glue injection cover (323) is provided with a second glue injection channel (320) concentric with the first slide groove (312), the periphery of the second glue injection channel (320) is provided with an annular groove (319), the annular groove (319) is provided with an annular slide block (315), one side of the annular slide block (315) close to the glue storage box body (306) is closed, the other side of the annular slide block (315) is provided with a glue injection opening (316), the upper side and the lower side of the annular groove (319) are symmetrically provided with two slide grooves (324), each slide groove (324) is provided with a second slide block (317), the inner side of each slide groove (324) is connected with a second slide block (317), the second slide block (318) is connected with a second support frame (304) on the opposite side of the second support frame (101), the second support frame (325) is fixedly connected with a sixth support frame (101), the sixth supporting plate (325) is fixedly provided with a glue melting machine (326), a glue outlet of the glue melting machine (326) is connected with a glue outlet pipe (327), and the other end of the glue outlet pipe (327) is connected with a second glue injection channel (320).

4. A double-layer cloth bonding apparatus according to any one of claims 1 to 3, wherein the double-layer cloth bonding apparatus processing process comprises the steps of:

s1: traction transportation is carried out, cloth is pushed onto the upper first belt (102) and the lower first belt (102) respectively, and the cloth moves on the first belts (102);

s2: cleaning and removing wrinkles, wherein when the cloth reaches the right end of the first belt (102), the arc-shaped suction channel (206) uniformly sucks the cloth, and the fiber falling off and the part possibly folded when the edge of the cloth is opened are adsorbed;

s3: linear gluing, namely injecting glue through a first glue injection channel (321), pushing the partition plate (307) to move downwards, and uniformly spraying the glue on the upper surface of the lower cloth by a second glue outlet groove (310) in a linear manner, so that the purpose that the contact surfaces of the double-layer cloth are coated with the glue is achieved;

s4: the double-layer cloth is pressed by the matched convex roller (407) and concave roller (408), and the fourth slider (410) receives a friction force opposite to the rolling direction and a reaction force given by the convex roller (407), so that the fourth slider (410) moves along the third sliding groove (409) and drives the adsorbed cloth to be smoothed;

s5: packaging and transporting, namely packaging and transporting the pressed double-layer cloth.