阅读说明：本技术 一种纺织印花用布料抖动式免粘连加工工艺 (Cloth shaking type adhesion-free processing technology for textile printing ) 是由 王飞 于 2021-09-10 设计创作，主要内容包括：本发明公开了一种纺织印花用布料抖动式免粘连加工工艺,涉及纺织生产用布料压花装置技术领域,解决了纺织生产用布料压花装置由于是热压工艺,模具在抽离布料时,温度过高直接与布料相互连接,可能模具抬起时会将布料的部分位置损伤,导致该装置出现不良的问题。一种纺织印花用布料抖动式免粘连加工工艺,包括底座、支撑架和热压板,所述底座的一端设置支撑架,所述支撑架的下端连接有热压板,所述热压板的一端固定安装有钢条。本发明通过支撑板的摆动带动布料上下移动,使其热压板下端的模具与布料在上下抖动的情况下两者加速分离,且能更好避免粘连问题,提高加工质量。(The invention discloses a cloth shaking type adhesion-free processing technology for textile printing, relates to the technical field of cloth embossing devices for textile production, and solves the problem that due to the hot pressing technology, when a mould is pulled away from cloth, the mould is directly connected with the cloth at an overhigh temperature, and possibly damages part of the cloth when the mould is lifted, so that the device is poor. The utility model provides an adhesion processing technology is exempted from to cloth shake formula for textile printing, includes base, support frame and hot pressboard, the one end of base sets up the support frame, the lower extreme of support frame is connected with the hot pressboard, the one end fixed mounting of hot pressboard has the billet. The cloth is driven to move up and down by the swinging of the supporting plate, so that the die at the lower end of the hot pressing plate and the cloth are separated from each other at an accelerated speed under the condition of vertical shaking, the adhesion problem can be better avoided, and the processing quality is improved.)

1. The utility model provides an adhesion processing technology is exempted from to weaving cloth shake formula for stamp which characterized in that: comprises the following steps of (a) carrying out,

s1, pretreating gray fabric: the grey cloth is placed in a singeing machine for singeing, fluff on the cloth surface is removed, the cloth surface is bright and clean and attractive, uneven dyeing and printing defects caused by the fluff during dyeing and printing are prevented, desizing is performed subsequently, the grey cloth is placed in a elutriation machine for desizing and boiling, the glue on the grey cloth is removed, and uneven coloring during the dyeing step is prevented;

s2, bleaching: placing the grey cloth into a bleaching machine, wherein the pH value of bleaching liquid for bleaching by using sodium hypochlorite is 10, and bleaching at normal temperature;

s3, dyeing: placing the grey cloth into a dyeing tank, gradually heating to 98 ℃ after the dye and the sodium sulfide are added, carrying out heat preservation dyeing for 15-20min, stopping heating, reducing the temperature in the tank to 80-85 ℃ while dyeing, continuously dyeing for about 20min, discharging liquid, washing with cold water and oxidizing, and keeping the speed of adding the cold water slow;

s4, printing: cloth is placed on a supporting plate (7) in a base (1), the hot pressing plate (3) is buckled downwards for printing, and when the hot pressing plate (3) is lifted, the supporting plate (7) drives the cloth to vibrate, so that the cloth is prevented from being adhered to the hot pressing plate (3);

s5, packaging: and winding the printed cloth together through a winding machine.

2. The textile printing cloth shaking type adhesion-free processing technology comprises a support frame (2) arranged at one end of a base (1), wherein the support frame (2) is connected with a hot pressing plate (3), and the textile printing cloth shaking type adhesion-free processing technology is characterized in that: a steel bar (4) is fixedly mounted at one end of the hot pressing plate (3), sliding strips (5) are fixedly mounted on two sides of the steel bar (4), a rack plate (6) is fixedly mounted on one side of one of the sliding strips (5), a gear (36) is meshed and connected with one side of the rack plate (6), a transmission shaft (13) is connected to the inner side of the gear (36), the base (1) is connected with the gear (36) through the transmission shaft (13), and a belt (9) is connected to one end of the transmission shaft (13);

the utility model discloses a take-out device, including base (1), inboard fixed mounting of base (1) has sealed shell (11), the inboard swing joint of sealed shell (11) has spinning wheel (10), the one end and transmission shaft (13) of spinning wheel (10) pivot are connected through belt (9), the up end of backup pad (7) is provided with a plurality of and inhales hole (8), the below of backup pad (7) is provided with extraction tube (12), extraction tube (12) are linked together with inhaling hole (8), the lower extreme of extraction tube (12) extends to one side of sealed shell (11), extraction tube (12) are linked together with sealed shell (11), the inside of extraction tube (12) is provided with first check valve (14), the position that the inner wall of extraction tube (12) is close to first check valve (14) lower extreme is provided with second check valve (15).

3. The cloth shaking type adhesion-free processing technology for textile printing according to claim 2, characterized in that: the novel gear transmission mechanism is characterized in that a rotating shaft (19) is movably connected to one end inside the base (1), a second bevel gear (18) is fixedly mounted at one end of the rotating shaft (19), a second bevel gear (18) is fixedly mounted at the top end of the transmission shaft (13), and the second bevel gear (18) is meshed with the first bevel gear (17) in a connected mode.

4. The cloth shaking type adhesion-free processing technology for textile printing according to claim 3, characterized in that: backup pad (7) have six, per two be provided with strip shaped plate (31) between backup pad (7), strip shaped plate (31) extrudes backup pad (7) of both sides, just the up end of strip shaped plate (31) with the up end parallel and level of backup pad (7), one side fixed mounting of rotation axis (19) has fixed cover (30), one side of fixed cover (30) is in strip shaped plate (31) fixed connection.

5. The cloth shaking type adhesion-free processing technology for textile printing according to claim 4, characterized in that: the utility model discloses a support structure, including base (1), the up end of base (1) is provided with six circular slots (20), the inboard swing joint of circular slot (20) has ball (23), the upper end fixed mounting of ball (23) has round cover (27), the inboard sliding connection of round cover (27) has supporting shaft pole (88), the up end of supporting shaft pole (88) and the lower terminal surface fixed connection of backup pad (7), round cover (27) are connected through third spring (26) with supporting shaft pole (88).

6. The cloth shaking type adhesion-free processing technology for textile printing according to claim 5, characterized in that: one end of the circular groove (20) is fixedly provided with a welding steel plate (25), the inner side of the welding steel plate (25) is provided with a limit groove (21), the lower end of the supporting shaft lever (88) is fixedly provided with an extension plate (77), one end of the extension plate (77) penetrates through one end of the round ball (23), the extending plate (77) extends to the lower end of the limit groove (21), the extending plate (77) is also provided with an inserting column (22), the inserted column (22) is connected inside the limit groove (21) in a sliding way, the axis of the inserted column (22) and the axis of the limit groove (21) are in the same position, one side of the supporting shaft lever (88) is movably connected with a clamping plate (28), the clamping plate (28) penetrates through one side of the round ball (23), the inner wall of the round ball (23) is provided with a short shaft (29), and the clamping plate (28) is connected with the round ball (23) through the short shaft (29).

7. The cloth shaking type adhesion-free processing technology for textile printing according to claim 6, characterized in that: one side of cardboard (28) is the inclined plane, the lower extreme fixed mounting of strip shaped plate (31) has clamp plate (33), the up end of clamp plate (33) personally submits forty-five degrees contained angles with the lower extreme of strip shaped plate (31), the lower extreme fixed mounting of clamp plate (33) has and presses briquetting (37), the lower terminal surface of pressing briquetting (37) is contradicted at the up end of cardboard (28).

8. The cloth shaking type adhesion-free processing technology for textile printing according to claim 7, characterized in that: the upper end of sealed shell (11) is connected with conveyer pipe (16), conveyer pipe (16) are linked together with sealed shell (11), conveyer pipe (16) extend to the lateral wall of base (1) and highly and backup pad (7) parallel and level, the surface of ball (23) is connected through first spring (24) of ball (23) both sides with the inboard of circular slot (20).

9. The cloth shaking type adhesion-free processing technology for textile printing according to claim 8, characterized in that: card square board (32) are installed to the one end of clamp plate (33), card square board (32) are the U type, the opposite side buckle of card square board (32) is connected with transmission frame (38), transmission frame (38) are connected through activity groove (35) with card square board (32), one side fixed mounting of transmission frame (38) has connecting strip (34).

Technical Field

The invention relates to the technical field of cloth embossing devices for textile production, in particular to a cloth shaking type adhesion-free processing technology for textile printing.

Background

With the rapid development of social economy, the embossing machine is mainly used for edge seaming, welding, melt cutting and embossing of synthetic fiber cloth. For example: hemming the three-dimensional non-woven fabric bag; pressing the patterns on the upper end and the edge of the non-woven bag; melting and cutting the magic tape; embossing of PVC material; embossing and welding on the garment, etc.

However, because the existing cloth embossing device for textile production is a hot-pressing process, when a mold is pulled away from cloth, the mold is directly connected with the cloth at an overhigh temperature, and the position of the cloth can be damaged when the mold is lifted, so that the device is easy to have the bad conditions; therefore, the existing production equipment is difficult to meet the existing requirements, and a cloth shaking type adhesion-free processing technology for textile printing is provided for the reason.

Disclosure of Invention

The invention aims to provide a dithering type adhesion-free processing technology for cloth for textile printing, which aims to solve the problems that the cloth embossing device for textile production provided in the background technology is poor due to the fact that the mould is in a hot pressing technology, when the mould is pulled away from the cloth, the mould is directly connected with the cloth at an overhigh temperature, and the mould can damage the position of part of the cloth when lifted possibly.

In order to achieve the purpose, the invention provides the following technical scheme: a cloth shaking type adhesion-free processing technology for textile printing comprises the following steps,

s1, pretreating gray fabric: the grey cloth is placed in a singeing machine for singeing, fluff on the cloth surface is removed, the cloth surface is bright and clean and attractive, uneven dyeing and printing defects caused by the fluff during dyeing and printing are prevented, desizing is performed subsequently, the grey cloth is placed in a elutriation machine for desizing and boiling, the glue on the grey cloth is removed, and uneven coloring during the dyeing step is prevented;

s2, bleaching: placing the grey cloth into a bleaching machine, wherein the pH value of bleaching liquid for bleaching by using sodium hypochlorite is 10, and bleaching at normal temperature;

s3, dyeing: placing the grey cloth into a dyeing tank, gradually heating to 98 ℃ after the dye and the sodium sulfide are added, carrying out heat preservation dyeing for 15-20min, stopping heating, reducing the temperature in the tank to 80-85 ℃ while dyeing, continuously dyeing for about 20min, discharging liquid, washing with cold water and oxidizing, and keeping the speed of adding the cold water slow;

s4, printing: the cloth is placed on a supporting plate in the base, the hot pressing plate is buckled downwards for printing, and when the hot pressing plate is lifted, the supporting plate drives the cloth to vibrate, so that the cloth is prevented from being adhered to the hot pressing plate;

s5, packaging: and winding the printed cloth together through a winding machine.

The invention also provides a cloth processing device, which comprises a support frame arranged at one end of the base, wherein the support frame is connected with a hot pressing plate, and the cloth processing device is characterized in that: a steel bar is fixedly mounted at one end of the hot pressing plate, sliding strips are fixedly mounted on two sides of the steel bar, a rack plate is fixedly mounted on one side of one sliding strip, a gear is meshed and connected with one side of the rack plate, a transmission shaft is connected to the inner side of the gear, the base is connected with the gear through the transmission shaft, and a belt is connected to one end of the transmission shaft;

the inboard fixed mounting of base has a sealed shell, the inboard swing joint of sealed shell has the spinning wheel, the one end and the transmission shaft of spinning wheel pivot pass through the belt and are connected, the up end of backup pad is provided with a plurality of and inhales the hole, the below of backup pad is provided with takes out the pipe, take out the pipe and inhale the hole and be linked together, the lower extreme of taking out the pipe extends to one side of sealed shell, take out the pipe and be linked together with sealed shell, the inside of taking out the pipe is provided with first check valve, the position that the inner wall of taking out the pipe is close to first check valve lower extreme is provided with the second check valve.

Preferably, one end inside the base is movably connected with a rotating shaft, one end of the rotating shaft is fixedly provided with a second bevel gear, the top end of the transmission shaft is fixedly provided with a second bevel gear, and the second bevel gear is meshed with the first bevel gear.

Preferably, the backup pad has six, per two be provided with the bar shaped plate between the backup pad, the backup pad of bar shaped plate extrusion both sides, just the up end of bar shaped plate with the up end parallel and level of backup pad, one side fixed mounting of rotation axis has fixed cover, bar shaped plate fixed connection is in one side of fixed cover.

Preferably, the upper end face of the base is provided with six circular grooves, the inner sides of the circular grooves are movably connected with balls, the upper ends of the balls are fixedly provided with circular sleeves, the inner sides of the circular sleeves are connected with supporting shaft rods in a sliding mode, the upper end faces of the supporting shaft rods are fixedly connected with the lower end faces of the supporting plates, and the circular sleeves are connected with the supporting shaft rods through third springs.

Preferably, the one end fixed mounting of circular slot has the welding steel sheet, the inboard of welding steel sheet is provided with the spacing groove, the lower extreme fixed mounting of bracing axle pole has the board of stretching out, the one end of stretching out the board runs through the one end of ball, just stretch out the lower extreme that the board extended to the spacing groove, it still installs on the board and inserts the post, insert post sliding connection in the inside of spacing groove, insert the axis of post and the axis of spacing groove in same position, one side swing joint of bracing axle pole has the cardboard, the cardboard runs through one side of ball, the inner wall of ball is provided with the minor axis, the cardboard passes through the minor axis with the ball and is connected.

Preferably, one side of cardboard is the inclined plane, the lower extreme fixed mounting of strip shaped plate has the clamp plate, the up end of clamp plate personally submits forty-five degrees contained angle with the lower extreme of strip shaped plate, the lower extreme fixed mounting of clamp plate presses the briquetting, press the lower terminal surface of briquetting and contradict at the up end of cardboard.

Preferably, the upper end of sealed shell is connected with the conveyer pipe, the conveyer pipe is linked together with sealed shell, the conveyer pipe extends to the lateral wall of base and highly and backup pad parallel and level, the surface of ball and the inboard first spring coupling through the ball both sides of circular slot.

Preferably, the card square plate is installed to the one end of clamp plate, the card square plate is the U type, the opposite side buckle of card square plate is connected with the transmission frame, the transmission frame passes through the movable groove with the card square plate and is connected, one side fixed mounting of transmission frame has the connecting strip.

Compared with the prior art, the invention has the beneficial effects that:

1. the invention sucks air from the outside through the suction holes and conveys the air to the inner side of the sealing shell through the suction pipe, because the outside air temperature is lower than the surface temperature of the cloth, the air is pumped by the rotary wheel to pass through the cloth and enter the sealing shell to cool the cloth on the upper end surface of the supporting plate, the cloth and the die at the lower end of the hot pressing plate are cooled, the cloth is not softened and can be effectively prevented from being adhered when being adhered to the die, the processing quality is improved, when the separation is finished, the processed cloth is conveyed away, the unprocessed cloth is placed at the upper end of the supporting plate, when the hot pressing plate is pressed down, the sliding strip drives the rack plate to rotate reversely, so that the rack plate is conveyed to the suction pipe for discharging from the air draft of the conveying pipe, but the inner side of the pumping pipe is provided with a first one-way valve and a second one-way valve of a single valve, the pumping pipe is sealed by the first one-way valve, and the second one-way valve is ejected and discharged by gas, so that the normal use is not influenced;

2. the conveying pipe is pulled to stretch by the round sleeve, so that the conveying pipe pulls the supporting plate to swing up and down, the round groove at the lower end of the conveying pipe drives the inserting column to be taken out from the inner side of the limiting groove when the conveying pipe descends, the round ball of the conveying pipe is not limited and fixed on the inner side of the round groove and can swing freely, the cloth is rotated by the rotating wheel to draw air and is adsorbed on the upper end surface of the supporting plate, the cloth is driven to move up and down by the swinging of the supporting plate, the mold at the lower end of the hot pressing plate and the cloth are separated in an accelerated manner under the condition of vertical shaking, the adhesion problem can be better avoided, and the processing quality is improved.

Drawings

FIG. 1 is a frame diagram of a cloth shaking type adhesion-free processing technology for textile printing according to the present invention;

FIG. 2 is a schematic structural view of the present invention as a whole;

FIG. 3 is a front cross-sectional view of the present invention as a whole;

FIG. 4 is a partial schematic view of the structure of FIG. 3A according to the present invention;

FIG. 5 is a schematic view of the base and support plate of the present invention;

FIG. 6 is a partial schematic view of the structure of FIG. 5B in accordance with the present invention;

FIG. 7 is a partial structural view of the ball of the present invention.

In the figure: 1. a base; 2. a support frame; 3. hot pressing plate; 4. a steel bar; 5. a slide bar; 6. a rack plate; 7. a support plate; 8. sucking holes; 9. a belt; 10. rotating the wheel; 11. sealing the shell; 12. drawing a pipe; 13. a drive shaft; 14. a first check valve; 15. a second one-way valve; 16. a delivery pipe; 17. a first bevel gear; 18. a second bevel gear; 19. a rotating shaft; 20. a circular groove; 21. a limiting groove; 22. inserting a column; 23. a ball; 24. a first spring; 25. welding a steel plate; 26. a third spring; 27. a round sleeve; 28. clamping a plate; 29. a minor axis; 30. fixing a sleeve; 31. a strip plate; 32. a card square plate; 33. pressing a plate; 34. a connecting strip; 35. a movable groove; 36. a gear; 37. a pressing block; 38. a transmission frame; 77. extending the plate; 88. supporting the shaft.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1 to 7, an embodiment of the present invention includes: a cloth shaking type adhesion-free processing technology for textile printing comprises the following steps,

s1, pretreating gray fabric: the grey cloth is placed in a singeing machine for singeing, fluff on the cloth surface is removed, the cloth surface is bright and clean and attractive, uneven dyeing and printing defects caused by the fluff during dyeing and printing are prevented, desizing is performed subsequently, the grey cloth is placed in a elutriation machine for desizing and boiling, the glue on the grey cloth is removed, and uneven coloring during the dyeing step is prevented;

s2, bleaching: placing the grey cloth into a bleaching machine, wherein the pH value of bleaching liquid for bleaching by using sodium hypochlorite is 10, and bleaching at normal temperature;

s3, dyeing: placing the grey cloth into a dyeing tank, gradually heating to 98 ℃ after the dye and the sodium sulfide are added, carrying out heat preservation dyeing for 15-20min, stopping heating, reducing the temperature in the tank to 80-85 ℃ while dyeing, continuously dyeing for about 20min, discharging liquid, washing with cold water and oxidizing, and keeping the speed of adding the cold water slow;

s4, printing: the cloth is placed on a supporting plate 7 in the base 1, the hot pressing plate 3 is buckled downwards for printing, and when the hot pressing plate 3 is lifted, the supporting plate 7 drives the cloth to vibrate, so that the cloth is prevented from being adhered to the hot pressing plate 3;

s5, packaging: and winding the printed cloth together through a winding machine.

The invention also provides a cloth processing device, which comprises a support frame 2 arranged at one end of the base 1, wherein the support frame 2 is connected with a hot pressing plate 3, and the cloth processing device is characterized in that: a steel bar 4 is fixedly installed at one end of the hot pressing plate 3, sliding strips 5 are fixedly installed on both sides of the steel bar 4, a rack plate 6 is fixedly installed at one side of one sliding strip 5, a gear 36 is engaged and connected to one side of the rack plate 6, a transmission shaft 13 is connected to the inner side of the gear 36, the base 1 is connected with the gear 36 through the transmission shaft 13, and a belt 9 is connected to one end of the transmission shaft 13;

base 1's inboard fixed mounting has sealed shell 11, the inboard swing joint of sealed shell 11 has spinning wheel 10, the one end and the transmission shaft 13 of spinning wheel 10 pivot are connected through belt 9, the up end of backup pad 7 is provided with a plurality of and inhales hole 8, the below of backup pad 7 is provided with exhaust tube 12, exhaust tube 12 is linked together with inhaling hole 8, exhaust tube 12's lower extreme extends to one side of sealed shell 11, exhaust tube 12 is linked together with sealed shell 11, the inside of exhaust tube 12 is provided with first check valve 14, the position that the inner wall of exhaust tube 12 is close to first check valve 14 lower extreme is provided with second check valve 15.

According to the figures 3 and 4, the cloth for textile production is placed on the upper end face of the supporting plate 7, the hot press plate 3 drives the lower die to press downwards, and the hot press plate 3 is heated, which is a traditional hot press process, the lower end face of the hot press plate 3 is abutted against the upper end face of the cloth to extrude patterns on the surface of the cloth for textile production, so that the device completes the embossing, due to the hot press process, when the die at the lower end of the hot press plate 3 is pulled away from the cloth, the temperature is too high and is directly connected with the cloth, and the local part of the cloth can be damaged when the hot press plate 3 is lifted, therefore, the embossed cloth needs to be cooled, according to the figure 4, by utilizing the lifting of the hot press plate 3, the hot press plate 3 drives the steel bar 4 to be lifted, the steel bar 4 pulls the sliding bars 5 at two sides to be lifted, the rack plate 6 at one side of the sliding bar 5 drives the gear 36 to rotate, and the gear 36 drives the transmission shaft 13 to rotate, the transmission shaft 13 drives the rotary wheel 10 to rotate for corotation through the belt 9, because the outer surface of the rotary wheel 10 is contacted with the inner wall of the sealing shell 11, the rotary wheel 10 pumps air, because the support plate 7 is connected with the sealing shell 11 through the pumping pipe 12, the support plate 7, the pumping pipe 12 and the sealing shell 11 are communicated, the air is sucked from the outside through the suction hole 8 and is conveyed to the inner side of the sealing shell 11 through the pumping pipe 12, because the temperature of the outside air is lower than the temperature of the surface of the cloth, the temperature of the cloth on the upper end surface of the support plate 7 is reduced by the process that the pumped air of the rotary wheel 10 penetrates the cloth and enters the sealing shell 11, the temperature of the cloth on the lower end surface of the support plate 7 is reduced, the cloth is not softened and is adhered to the mould, the problem of adhesion can be effectively avoided, the processing quality is improved, after the separation is completed, the processed cloth is conveyed away, and the unprocessed cloth is placed on the upper end of the support plate 7, when hot pressboard 3 pushed down, slide 5 drove the reversal of rack board 6, made it carry the extraction tube 12 discharge from 16 convulsions of conveyer pipe, but the inboard of extraction tube 12 is provided with the first check valve 14 of single-phase valve and second check valve 15, utilizes the sealed extraction tube 12 of first check valve 14, and gaseous ejecting discharge with second check valve 15 can not influence normal use.

Further, a rotating shaft 19 is movably connected to one end inside the base 1, a second bevel gear 18 is fixedly mounted at one end of the rotating shaft 19, a second bevel gear 18 is fixedly mounted at the top end of the transmission shaft 13, and the second bevel gear 18 and the first bevel gear 17 are meshed and connected with each other.

Further, backup pad 7 has six, is provided with bar 31 between per two backup pads 7, and bar 31 extrudes the backup pad 7 of both sides, and the up end parallel and level of bar 31 and backup pad 7, and one side fixed mounting of rotation axis 19 has fixed cover 30, and bar 31 fixed connection is in one side of fixed cover 30.

According to fig. 5, the first bevel gear 17 on the top end is driven to rotate by the rotation of the transmission shaft 13, the first bevel gear 17 drives the second bevel gear 18 to rotate, the second bevel gear 18 drives the rotating shaft 19 to rotate, the rotating shaft 19 drives the fixing sleeve 30 to rotate, the fixing sleeve 30 drives the strip-shaped plate 31 to be taken out from between the two support plates 7, a gap is formed between the two support plates 7, and the support plates 7 can swing conveniently without mutual collision.

Further, the upper end surface of the base 1 is provided with six circular grooves 20, the inner sides of the circular grooves 20 are movably connected with a round ball 23, the upper end of the round ball 23 is fixedly connected with a circular sleeve 27, the inner side of the circular sleeve 27 is slidably connected with a supporting shaft rod 88, the upper end surface of the supporting shaft rod 88 is fixedly connected with the lower end surface of the supporting plate 7, and the circular sleeve 27 is connected with the supporting shaft rod 88 through a third spring 26.

Further, a welding steel plate 25 is fixedly installed at one end of the circular groove 20, a limiting groove 21 is formed in the inner side of the welding steel plate 25, an extending plate 77 is fixedly installed at the lower end of the supporting shaft rod 88, one end of the extending plate 77 penetrates through one end of the round ball 23, the extending plate 77 extends to the lower end of the limiting groove 21, an inserting column 22 is further installed on the extending plate 77, the inserting column 22 is slidably connected inside the limiting groove 21, the axis of the inserting column 22 and the axis of the limiting groove 21 are located at the same position, a clamping plate 28 is movably connected to one side of the supporting shaft rod 88, the clamping plate 28 penetrates through one side of the round ball 23, a short shaft 29 is arranged on the inner wall of the round ball 23, the clamping plate 28 and the round ball 23 are connected through the short shaft 29, one side of the clamping plate 28 is an inclined plane, a pressing plate 33 is fixedly installed at the lower end of the strip-shaped plate 31, an included angle of forty-five degrees is formed between the upper end face of the pressing plate 33 and the lower end of the strip-shaped plate 31, a pressing block 37 is fixedly installed at the lower end of the pressing plate 33, the lower end surface of the pressing block 37 abuts against the upper end surface of the chucking plate 28.

Spacing is relieved, and the swing is convenient: according to the illustration in fig. 7, the strip-shaped plate 31 is driven to press downwards by the rotation of the fixing sleeve 30, a gap is formed between every two support plates 7, so that the support plates 7 can swing conveniently, and cannot collide with each other, then the strip-shaped plate 31 can drive the press plate 33 at the lower end to press downwards, the press plate 33 drives the press block 37 to press downwards, because the lower end of the press block 37 abuts against the upper end face of the clamp plate 28, the press block 37 is not abutted against the clamp plate 28 by pressing downwards of the press block 37, as illustrated in fig. 7, the tilt range of the press block 37 and the press plate 33 is large, so that the press plate 33 cannot be touched when the inserted column 22 bounces, then the clamp plate 28 is connected with the support shaft lever 88 through the short shaft 29, after the clamp plate 28 loses the limit, the support shaft lever 88 loses the limit, and then descends by pushing 23 through the outer surface of the support 88, because the third spring 26 has elastic potential energy, the support shaft lever 88 can pull the support plate 7 to swing upwards and downwards through the third spring 26, when the supporting shaft lever 88 descends, the circular groove 20 at the lower end of the supporting shaft lever 88 drives the inserting column 22 to be taken out from the inner side of the limiting groove 21, the round ball 23 is not fixed in the limiting position on the inner side of the circular groove 20 and can swing freely, the cloth is rotated by the spinning wheel 10 to suck air on the upper end face of the supporting plate 7, the cloth is driven to move up and down through the swinging of the supporting plate 7, the mold and the cloth at the lower end of the hot pressing plate 3 are enabled to be separated from each other at an accelerated speed under the condition that the mold and the cloth shake up and down, the adhesion problem can be better avoided, and the processing quality is improved.

Further, the card square plate 32 is installed to the one end of clamp plate 33, and card square plate 32 is the U type, and the opposite side buckle of card square plate 32 is connected with transmission frame 38, and transmission frame 38 is connected through movable groove 35 with card square plate 32, and one side fixed mounting of transmission frame 38 has connecting strip 34.

Wave-like swing: according to fig. 7, by pressing down the pressing plate 33 in sequence near the first bevel gear 17, the pressing plate 33 will also drive the card square plate 32 to move, since the other end of the square clamping plate 32 is located at the inner side of the transmission frame 38, only after the square clamping plate 32 slides for a period of time at the inner side of the transmission frame 38, the square clamping plate will contact the transmission frame 38, so that the transmission frame 38 is driven to move, however, a rotating shaft 19 is connected to one side of the transmission frame 38, the rotating shaft 19 is connected to the other pressing plate 33, the connecting strip 34 is driven to move through the movement of the transmission frame 38, the connecting strip 34 drives the other pressing plate 33 to press down, the clamping plate 28 is not sequentially bounced at the limiting clamping plate 28, the six supporting shaft rods 88 are sequentially released to be limited to move up and down, the frequency of the up and down movement of each supporting shaft rod 88 is different, the supporting shaft rods are similar to a wave type and do not swing up and down together in a common mode, and the cloth can be better swung to separate from the die.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.