CN113089300A - Processing technology of waterproof breathable functional sports fabric - Google Patents

Abstract

The invention provides a processing technology of a waterproof breathable functional fabric for sports, which comprises the following steps: the method comprises the following steps: clamping and hoisting one end of the stacked multilayer fabrics by using a hoisting part in the forming device; step two: flattening the bending among the stacked multiple layers of fabrics, and removing impurities among the multiple layers of fabrics; step three: clamping and keeping the whole multilayer fabric by using a shaping part in a shaping device, and shaping the multilayer fabric; the invention is convenient for removing sundries mixed among the multiple layers of fabrics; the forming device comprises a hoisting part and a shaping part, wherein the hoisting part is used for hoisting the multilayer fabric after one end of the multilayer fabric is clamped tightly, the shaping part is used for shaping the fabric, the hoisting part comprises a fixed clamping plate and a movable clamping plate, and the fixed clamping plate is matched with the movable clamping plate to clamp one end of the multilayer fabric tightly.

Description

Processing technology of waterproof breathable functional sports fabric

Technical Field

The invention relates to the technical field of fabric processing equipment, in particular to a processing technology of a waterproof breathable sports functional fabric.

Background

For example, the utility model discloses a surface fabric dust collector for surface fabric processing, this utility model discloses a surface fabric dust collector for surface fabric processing, including the base, the first fixed column of left side fixedly connected with at base top, there is the first material cylinder of receiving through first pivot swing joint at the back of first fixed column, this utility model discloses a through setting up base, first fixed column, first material cylinder of receiving, surface fabric, the second material cylinder of receiving, the second fixed column, first carousel, belt, second carousel, first motor, dead lever, fixed plate, rose box, second motor, brush board, filter, dust absorption mechanism, pipeline one, second air exhauster, pipeline two, suction nozzle, first air exhauster and first fixed block cooperation use, solved present in the processing production of surface fabric its surface extremely easily glue dust, batting etc. in time, if do not in time with the dust on the surface fabric, The removal of the catkin affects the processing quality of the fabric, and can cause the problems of poor environmental quality of a production workshop and influence on the body health of workers; but the utility model is not convenient for removing the sundries between the multi-layer fabrics.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides the processing technology of the waterproof breathable sports functional fabric, and the processing technology has the beneficial effect that sundries among multiple layers of fabrics are convenient to remove.

The technical scheme adopted by the invention for solving the technical problems is as follows:

a processing technology of a waterproof breathable functional fabric for sports comprises the following steps:

the method comprises the following steps: clamping and hoisting one end of the stacked multilayer fabrics by using a hoisting part in the forming device;

step two: flattening the bending among the stacked multiple layers of fabrics, and removing impurities among the multiple layers of fabrics;

step three: the whole multilayer fabric is clamped and held by a shaping part in a shaping device, and shaping treatment is carried out on the multilayer fabric.

The forming device comprises a hoisting part and a shaping part, the hoisting part is used for hoisting the multilayer fabric after clamping one end of the multilayer fabric, and the shaping part is used for shaping the fabric.

The multi-layer waterproof breathable functional fabric is stacked together, one end of the multi-layer fabric is clamped through the hoisting part, and the end which is not clamped by the hoisting part freely hangs down, so that the multi-layer fabric is hoisted.

The hoisting part comprises a fixed clamping plate and a movable clamping plate, and the fixed clamping plate is matched with the movable clamping plate to clamp one end of the multilayer fabric.

The fixed clamping plate and the movable clamping plate are controlled to move towards the direction close to or away from each other, so that the fixed clamping plate and the movable clamping plate can respectively clamp the two sides of the multilayer fabric.

Install anti-skidding subassembly on the hoist and mount portion and be used for improving the antiskid effect of clamping in-process.

The anti-skidding assembly improves the anti-skidding effect when the fixed clamping plate and the movable clamping plate clamp the multilayer fabrics by increasing the friction force between the fixed clamping plate and the movable clamping plate when matching, so that the state of stacking and placing among the multilayer fabrics cannot be disordered when the multilayer fabrics are smoothed or sundries among the multilayer fabrics are removed.

The anti-slip assembly comprises anti-slip blocks, and a plurality of anti-slip blocks are arranged on one side of the mutually matched fixed clamping plate and the movable clamping plate.

The design of non slipping spur can reduce the area of contact with the multilayer surface fabric when cooperateing between solid fixed splint and the activity splint to make the clamp force degree between solid fixed splint and the activity splint the same, intensity of pressure is bigger.

The processing technology of the waterproof breathable sports functional fabric has the beneficial effects that:

the invention is convenient for removing sundries among the multiple layers of fabrics.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a first schematic structural view of a hoisting part according to a first embodiment of the present invention;

FIG. 2 is a schematic structural view of a first hoisting part according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a second embodiment of the hoisting part of the present invention;

FIG. 4 is a schematic structural view of a bonded panel according to the present invention;

FIG. 5 is a schematic view of the construction of the gear of the present invention;

FIG. 6 is a schematic structural view of the fixing frame of the present invention;

FIG. 7 is a schematic view of the construction of the platen of the present invention;

FIG. 8 is a schematic structural view of the rack of the present invention;

FIG. 9 is a schematic structural view of the interposer of the present invention;

FIG. 10 is a schematic view of the structure of the liquid storage tank of the present invention;

fig. 11 is a schematic structural view of the mounting plate of the present invention.

In the figure:

a fixed clamp plate 101;

a movable clamp plate 102;

anti-slip blocks 103;

a sliding column I104;

a locking tab 105;

the lifting anti-slip column 106;

a connecting plate 107;

a strut II 108;

a push plate 201;

an adjustment post 202;

an adjusting plate 203;

a stopper 204;

a pasting plate 301;

a sliding column III 302;

a sliding column IV 303;

a hinged seat I304;

a gear 305;

a hinge base II 306;

a fixed frame 401;

a rotary post 402;

a press plate 501;

a slot frame 502;

a stepped hole 503;

a carriage 504;

a moving block 601;

a slip sheet 602;

a locking post 603;

a rack 604;

an insert plate 605;

a liquid storage tank 701;

a tab 702 is mounted.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

A processing technology of a waterproof breathable functional fabric for sports comprises the following steps:

the method comprises the following steps: clamping and hoisting one end of the stacked multilayer fabrics by using a hoisting part in the forming device;

step two: flattening the bending among the stacked multiple layers of fabrics, and removing impurities among the multiple layers of fabrics;

step three: the whole multilayer fabric is clamped and held by a shaping part in a shaping device, and shaping treatment is carried out on the multilayer fabric.

The following detailed description is made with reference to the accompanying drawings 1-2:

stacking a plurality of waterproof breathable sports functional fabrics together, clamping one end of a multilayer fabric through a hoisting part, and enabling the end which is not clamped by the hoisting part to hang down freely, thereby realizing the effect of hoisting the multilayer fabric;

one end of the multilayer fabric is clamped, and the other end of the multilayer fabric hangs down freely, so that the bending among the multilayer fabrics is smoothed when the multilayer fabrics are kept in a laminated state;

furthermore, one end of the multilayer fabric is clamped and the other end of the multilayer fabric hangs down freely, so that sundries among the multilayer fabric can be removed, and the effect of the shaping part in shaping the multilayer fabric is improved.

The fixed clamping plate 101 and the movable clamping plate 102 are controlled to move towards the direction close to or away from each other, so that the fixed clamping plate 101 and the movable clamping plate 102 can respectively clamp two sides of the multilayer fabric;

and moving the fixed clamping plate 101 and the movable clamping plate 102 to the edge of the multilayer fabric, and controlling the fixed clamping plate 101 and the movable clamping plate 102 to move towards the direction close to each other, so that one end of the multilayer fabric is clamped.

The anti-slip assembly improves the anti-slip effect when the fixed clamping plate 101 and the movable clamping plate 102 clamp the multilayer fabrics by increasing the friction force when the fixed clamping plate 101 and the movable clamping plate 102 are matched, so that the state of stacking among the multilayer fabrics cannot be disturbed when the multilayer fabrics are smoothed or sundries among the multilayer fabrics are removed.

The design of non-slip block 103 can reduce the area of contact with the multilayer surface fabric when coordinating between solid splint 101 and the activity splint 102 to make the clamp force degree between solid splint 101 and the activity splint 102 the same, intensity of pressure is bigger, improves the anti-skidding effect when solid splint 101 and activity splint 102 press from both sides tightly the multilayer surface fabric then.

The following detailed description is made with reference to fig. 3:

the anti-slip assembly comprises a plurality of lifting anti-slip columns 106 and a connecting plate 107, the plurality of lifting anti-slip columns 106 are connected to the movable clamping plate 102 in a sliding mode, and the connecting plate 107 is fixedly connected with the plurality of lifting anti-slip columns 106.

When the device clamps thicker multilayer fabrics through the fixed clamping plate 101 and the movable clamping plate 102, the clamping force between the fixed clamping plate 101 and the movable clamping plate 102 is increased due to the increase of the thickness of the multilayer fabrics, and once the clamping force for clamping the multilayer fabrics is too high, the skid-proof blocks 103 leave marks on the multilayer fabrics;

the lifting anti-skid column 106 can move on the movable clamping plate 102, so that when the force for clamping the multilayer fabrics by the fixed clamping plate 101 and the movable clamping plate 102 is too large, the depth of the lifting anti-skid column 106 at the position of the movable clamping plate 102 is changed, and marks left on the multilayer fabrics are reduced;

the design of the connecting plate 107 facilitates the uniform adjustment of the depth of the lifting anti-slip column 106 at the movable clamping plate 102.

The following detailed description is made with reference to the accompanying drawings 1-2:

hoisting portion still includes traveller I104, and traveller I104 installs on fixed splint 101, traveller I104 and movable splint 102 sliding connection, traveller I104 is provided with two at least.

The slide column I104 is designed to enable the fixed clamping plate 101 and the movable clamping plate 102 to be always kept in an aligned state when moving towards the direction close to or away from each other, so that the fixed clamping plate 101 and the movable clamping plate 102 are prevented from deviating when clamping or loosening multiple layers of fabrics;

the design of the at least two sliding columns I104 can improve the stable clamping effect when the fixed clamping plate 101 and the movable clamping plate 102 clamp the multilayer fabrics;

further, the design of at least two sliding columns I104 enables the cross-sectional shape of the sliding columns I104 to have more selectivity, and therefore part adaptability in the actual installation process of the device is improved.

The fixed clamping plate 101 and the movable clamping plate 102 are both fixedly connected with locking sheets 105, and the two locking sheets 105 are locked through fasteners.

The locking piece 105 is designed to facilitate the locking of the fixed clamping plate 101 and the movable clamping plate 102;

furthermore, because the locking sheet 105 and the fixed clamping plate 101 and the movable clamping plate 102 are respectively provided with a certain distance, when the fixed clamping plate 101 and the movable clamping plate 102 clamp the multilayer fabrics, a part of the edge of the multilayer fabrics is reserved on the other side of the clamping part, so that the firmness of clamping the multilayer fabrics is improved;

the two locking sheets 105 are locked through the fasteners, so that the firmness of clamping the multilayer fabrics by the fixed clamping plate 101 and the movable clamping plate 102 can be improved;

the fastener can adopt a stud and a nut to suit and lock the two locking sheets 105;

furthermore, a spring washer is arranged between the nut and the locking sheet 105 attached to the nut, so that the locking effect can be further improved;

furthermore, the stud can be a T-shaped stud, and an outer hexagonal stud is selected, so that when the nut is locked, the stud cannot rotate relatively, and at the moment, an anti-slip groove with a hexagonal cross section is processed in advance on one side of the locking sheet 105 matched with the stud.

The following detailed description is made with reference to fig. 3:

and a sliding column II 108 is arranged on the connecting plate 107.

The design of the sliding column II 108 can improve the guidance of the lifting anti-skid column 106 in the moving process.

The following detailed description is made with reference to fig. 4 and 7:

the shaping part comprises a laminating plate 301 and a pressing plate 501, the laminating plate 301 is fixedly connected with the fixed clamping plate 101, and the laminating plate 301 is matched with the pressing plate 501 to shape the fabric.

The bending among the stacked multilayer fabrics is smoothed, impurities among the multilayer fabrics are removed, and then the laminating plate 301 is matched with the pressing plate 501 to clamp and hold the multilayer smooth fabrics, so that the multilayer fabrics are shaped.

The following detailed description is made with reference to fig. 3:

the forming device further comprises a push plate 201, adjusting columns 202, adjusting plates 203 and limiting columns 204, the adjusting columns 202 are fixedly connected to the two ends of the push plate 201, the two adjusting columns 202 are fixedly connected with the movable clamping plate 102, the adjusting plates 203 are connected with the two adjusting columns 202 in a sliding mode, the adjusting plates 203 are locked between the two adjusting columns 202 through fasteners, the limiting columns 204 of at least one lower portion of the adjusting plates 203 are fixedly connected with the connecting plates 107, the adjusting plates 203 are connected with the sliding columns II 108 in a sliding mode, and springs are fixedly connected between the adjusting plates 203 and the connecting plates 107.

The push plate 201 is designed to facilitate the movable clamping plate 102 to move towards the fixed clamping plate 101, so that the effect of clamping the multilayer fabric is realized;

the push plate 201 can be designed into an arc shape, the multilayer fabric is erected, two hands of an operator respectively grasp two ends of the upper part of the multilayer fabric, the lower end of the multilayer fabric is controlled to move to the middle position between the fixed clamping plate 101 and the movable clamping plate 102, then the multilayer fabric is controlled to descend, the fixed clamping plate 101 and the movable clamping plate 102 are aligned to the upper end of the multilayer fabric, then the operator can press the arc-shaped push plate 201 through the belly, and therefore the movable clamping plate 102 is controlled to move towards the fixed clamping plate 101, and the push plate 201 is arranged into the arc shape, so that the operator cannot be injured;

the device can reduce marks left on the multilayer fabric under the condition of using larger clamping force on the multilayer fabric through the elasticity of the spring;

by changing the relative position of the adjusting plate 203 on the adjusting column 202, the depth of the connecting plate 107 at the movable clamping plate 102 can be adjusted when the device clamps the multilayer fabrics with the same thickness with the same force, so that the clamping effect is controlled;

the limiting column 204 plays a limiting role, and can prevent the spring from being damaged when the adjusting plate 203 is attached to the connecting plate 107.

The following detailed description is made with reference to fig. 6:

the forming device further comprises a hinge seat II 306, a fixing frame 401 and a rotating column 402, wherein the laminating plate 301 is fixedly connected with at least one hinge seat II 306, the fixing frame 401 is fixedly connected with the rotating column 402, and the rotating column 402 is hinged with the hinge seat II 306.

Fixing the fixing frame 401, then enabling the attaching plate 301 to rotate by taking the axis of the rotating column 402 as an axis, enabling the shaping part to clamp the erected multilayer fabric, and then flatly placing the multilayer fabric, so that the waterproof coating can be conveniently infiltrated into the multilayer fabric when the multilayer fabric is punctured, and the waterproof effect and the air permeability of the fabric are improved;

when the rotating column 402 directly rotates with the attaching plate 301, the attaching plate 301 needs to be thickened, so that a hinge base ii 306 is designed, and the hinge base ii provides a rotating space for the rotating column 402;

further, the design of at least one hinge seat II can improve the supporting effect of the rotating column 402 on the attaching plate 301.

The following detailed description is made with reference to the accompanying figures 7-9:

the forming device further comprises sliding columns III 302, sliding columns IV 303, a slot frame 502, a sliding frame 504, a moving block 601, sliding pieces 602, locking columns 603 and a inserting plate 605, two sliding columns III 302 are fixedly connected to the laminating plate 301, the sliding frame 504 is hinged to the pressing plate 501, the sliding frame 504 is connected with the two sliding columns III 302 in a sliding mode, two sliding columns IV 303 are fixedly connected to the laminating plate 301, the slot frame 502 is fixedly connected to the pressing plate 501, slots are formed in the slot frame 502, two sliding pieces 602 are symmetrically and fixedly connected to the moving block 601, the two sliding pieces 602 are respectively connected with the two sliding columns IV 303 in a sliding mode, the locking columns 603 are connected to the moving block 601 in a sliding mode, sliding grooves are formed in the moving block 601, the locking columns 603 penetrate through one side of the sliding grooves, the inserting plate 605 is connected to the locking columns 603 in a sliding mode.

By inserting the inserting plate 605 into the slot on the slot frame 502 and locking the moving block 601 and the inserting plate 605 through the locking column 603, when the pressing plate 501 moves towards the direction far away from or close to the attaching plate 301, the side where the pressing plate 501 and the attaching plate 301 are matched with each other is always kept in a parallel state, so that the shaping effect of the device on the multilayer fabric is improved, and at the moment, the two sliding columns IV 303 are respectively connected in the two sliding pieces 602 in a sliding manner;

the sliding of the carriage 504 on the two sliding columns iii 302 allows the press plate 501 and the fitting plate 301 to cooperate to perform a sizing process on multi-layer fabrics with various thicknesses.

The following detailed description is made with reference to fig. 5 and 8:

the forming device further comprises a hinged seat I304, a gear 305 and a rack 604, the laminating plate 301 is fixedly connected with the hinged seat I304, the hinged seat I304 is hinged with the gear 305, the eccentric position of the gear 305 is fixedly connected with a rotating handle, the rack 604 is fixedly connected to the moving block 601, and the rack 604 is in transmission connection with the gear 305.

By adjusting the rotating handle, the gear 305 can rotate by taking the axis of the gear as the axis, so that the rack 604 is driven to move, the moving block 601 is driven to move, and at the moment, the two sliding sheets 602 respectively slide on the two sliding columns iv 303.

The following detailed description is made with reference to fig. 7 and fig. 10-11:

the forming device further comprises a stepped hole 503, a liquid storage tank 701 and an installation piece 702, wherein a plurality of stepped holes 503 are uniformly formed in one side, away from the attaching plate 301, of the pressing plate 501, the liquid storage tank 701 is installed on each stepped hole 503, a sliding rod is fixedly connected to one side of the installation piece 702, a conical head rod is fixedly connected to the other side of the installation piece 702, a cover plate is hinged to the liquid storage tank 701, the sliding rod and the conical head rod are connected to the cover plate and the liquid storage tank 701 in a sliding mode respectively, the installation piece 702 is located on the inner side of the liquid storage tank 701, and the axis of the conical head rod is collinear with the axis of the stepped hole 503.

The waterproof material is filled in the liquid storage tank 701, the sliding rod is controlled to be lifted upwards after the pressing plate 501 is placed flat, a certain gap is formed between the end part of the conical rod and the liquid storage tank 701, at the moment, the waterproof material flows into the stepped hole 503 from the gap, the sliding rod is controlled to be pressed downwards, the end part of the conical rod pricks the multilayer fabric, and the waterproof material penetrates into the deep part of the multilayer fabric, so that the waterproofness and the air permeability of the multilayer fabric are improved;

finally, the laminating plate 301 is kept in a flat state, the pressing plate 501 is controlled to rotate by taking the axis of the pin shaft on the sliding frame 504 as a shaft, then the multilayer fabric is taken down, the clamped multilayer fabric is taken down by replacing a vertical state with the flat state, and the fabric can be prevented from being deformed;

the pressing plate 501 can rotate around the axis of the pin shaft on the carriage 504, so that convenience in taking and placing multiple layers of fabrics is improved.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (10)

1. A processing technology of a waterproof breathable sports functional fabric is characterized by comprising the following steps: the method comprises the following steps:

the method comprises the following steps: clamping and hoisting one end of the stacked multilayer fabrics by using a hoisting part in the forming device;

step two: flattening the bending among the stacked multiple layers of fabrics, and removing impurities among the multiple layers of fabrics;

step three: the whole multilayer fabric is clamped and held by a shaping part in a shaping device, and shaping treatment is carried out on the multilayer fabric.

2. The processing technology of the waterproof breathable functional sports fabric according to claim 1, characterized in that: the forming device comprises a hoisting part and a shaping part, the hoisting part is used for hoisting the multilayer fabric after clamping one end of the multilayer fabric, and the shaping part is used for shaping the fabric.

3. The processing technology of the waterproof breathable functional sports fabric according to claim 2, characterized in that: the hoisting part comprises a fixed clamping plate (101) and a movable clamping plate (102), and the fixed clamping plate (101) and the movable clamping plate (102) are matched to clamp one end of the multilayer fabric.

4. The processing technology of the waterproof breathable functional sports fabric according to claim 3, characterized in that: install anti-skidding subassembly on the hoist and mount portion and be used for improving the antiskid effect of clamping in-process.

5. The processing technology of the waterproof breathable functional sports fabric according to claim 4, is characterized in that: the anti-slip assembly comprises anti-slip blocks (103), and a plurality of anti-slip blocks (103) are mounted on one sides of the fixed clamping plate (101) and the movable clamping plate (102) which are matched with each other.

6. The processing technology of the waterproof breathable functional sports fabric according to claim 4, is characterized in that: the anti-slip assembly comprises lifting anti-slip columns (106) and a connecting plate (107), the movable clamping plate (102) is connected with the lifting anti-slip columns (106) in a sliding mode, and the connecting plate (107) is fixedly connected with the lifting anti-slip columns (106).

7. The processing technology of the waterproof breathable functional sports fabric according to any one of claims 4 to 6, characterized in that: hoisting portion still includes traveller I (104), and traveller I (104) are installed on fixed splint (101), and traveller I (104) and activity splint (102) sliding connection, traveller I (104) are provided with two at least.

8. The processing technology of the waterproof breathable functional sports fabric according to claim 7, is characterized in that: the fixed clamping plate (101) and the movable clamping plate (102) are fixedly connected with locking sheets (105), and the two locking sheets (105) are locked through fasteners.

9. The processing technology of the waterproof breathable functional sports fabric according to claim 8, characterized in that: and a sliding column II (108) is arranged on the connecting plate (107).

10. The processing technology of the waterproof breathable functional sports fabric according to claim 9, characterized in that: the shaping part comprises a laminating plate (301) and a pressing plate (501), the laminating plate (301) is fixedly connected with the fixed clamping plate (101), and the laminating plate (301) is matched with the pressing plate (501) to carry out shaping processing on the fabric.

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