CN117686338A - An elasticity detection device and method for textile production - Google Patents

Abstract

The invention discloses an elasticity detection device and method for textile production, which belongs to the technical field of textile detection equipment. It includes a base, a support column is fixedly installed on the top of the base, and a side plate is fixedly connected to the top of the support column. A test assembly is adjustably connected to one side of the board, and winding assemblies for receiving the textile body are adjustably connected to both ends of one side of the side plate, and the winding assemblies on both sides are located on both sides of the test assembly. In the present invention, the pressure system between the textile body and the pressing roller is tested through a pressure sensor connected to the shaft body on one side of the pressing roller to determine the elastic coefficient of the textile body. The pressure system of the textile body can be realized through the pressing rollers arranged oppositely on both sides. Quickly judge the bidirectional tensile elasticity coefficient. When the pressing roller is reset after the test, the rear winding mechanism synchronously re-winds the tested textile body to avoid affecting the continuous production of the textile body and realize the control of the production process. Random detection of textile elasticity.

Description

An elasticity detection device and method for textile production

Technical field

The invention belongs to the technical field of textile testing equipment, and in particular relates to an elasticity testing device and method for textile production.

Background technique

With the development of science and technology, textile testing technology has gradually developed during the production process of textile products. In order to ensure the final effect of textile products, it is necessary to sample products from each process section during the textile production process for performance testing. Textile products The performance tests include stain resistance, tensile elasticity and corresponding retraction properties, etc. The most important one is the test of the elastic properties of textile products.

The invention patent with Chinese patent document publication number CN111751205B discloses a random detection device for fabric lateral tensile properties for fabric textile processing, including a first bracket, a second bracket, a telescopic rod and a motor. One side of the first bracket A second bracket is provided. One end of the screw rod penetrates the first bracket and the second bracket and is connected to a guide shaft through a belt. One end of the guide shaft penetrates the first bracket and the second bracket and has a docking groove on its outside. A motor is embedded inside the top of the first bracket. One end of the screw rod is connected to a telescopic plate. One end of the telescopic plate penetrates the telescopic groove and is located outside the mounting base. One end of the guide rod is fixed with a guide ball. The splint shaft is connected to the outside of the mounting base. This device, through the use of a single motor, clamps and pulls fabrics of different thicknesses from both sides to detect their tensile resistance. The above solution requires the fabric to be clamped and then conduct a transverse tensile test. Its detection When textiles are continuously produced through the production line, if the stretched fabric cannot be retracted in time, it will affect the subsequent winding production and processing, and when the front-end and rear-end winding mechanisms are working during transverse clamping and stretching, it is easy to cause the fabric to Being pulled too much affects the measurement accuracy and adaptability to large-scale production, and cannot well meet the elasticity testing of textiles during the production process.

Contents of the invention

The purpose of this invention is to solve the problem that when textiles are continuously produced through the production line, if the stretched fabric cannot be retracted in time, the subsequent winding production and processing will be affected, and the winding mechanisms at the front and rear ends are working during transverse clamping and stretching. Under such circumstances, it is easy to cause the fabric to be excessively pulled, which affects the measurement accuracy and the adaptability to large-scale production. An elasticity detection device and method for textile production are proposed.

In order to achieve the above objects, the present invention adopts the following technical solutions:

An elasticity detection device for textile production, including a base. A support column is fixedly installed on the top of the base. A side plate is fixedly connected to the top of the support column. One side of the side plate is adjustable and connected with a test component. The side Both ends of one side of the board are adjustable and connected with winding components for receiving the textile body, and the winding components on both sides are located on both sides of the test assembly. Both ends of one side of the side plate are connected to support components in a driving manner, and the two sides are supported The components are respectively located on both sides of the support component. The side of the side plate away from the winding component is movably connected with a transmission mechanism, and the transmission mechanism is fixedly connected to one side of the winding component.

As a further description of the above technical solution:

The test assembly includes a test clamp seat, a screw seat is fixedly connected to the rear side of the test clamp seat, a linear module is fixedly installed on the outer wall of the screw seat, and the linear module is fixedly installed on one side of the side plate, so An adjusting motor is fixedly installed on the bottom side of the linear module, and the adjusting motor is fixedly connected to one side of the outer wall of the support column. There are pressure rollers slidingly connected to both sides of the inner cavity of the test clamp, and the pressure rollers on both sides face each other. Pressure sensors are fixedly installed on both sides.

As a further description of the above technical solution:

The test assembly includes a test clamp seat, a screw seat is fixedly connected to the rear side of the test clamp seat, a linear module is fixedly installed on the outer wall of the screw seat, and the linear module is fixedly installed on one side of the side plate, so An adjusting motor is fixedly installed on the bottom side of the linear module, and the adjusting motor is fixedly connected to one side of the outer wall of the support column. There are pressure rollers slidingly connected to both sides of the inner cavity of the test clamp, and the pressure rollers on both sides face each other. Pressure sensors are fixedly installed on both sides.

As a further description of the above technical solution:

The test assembly includes a test clamp seat, a screw seat is fixedly connected to the rear side of the test clamp seat, a linear module is fixedly installed on the outer wall of the screw seat, and the linear module is fixedly installed on one side of the side plate, so An adjusting motor is fixedly installed on the bottom side of the linear module, and the adjusting motor is fixedly connected to one side of the outer wall of the support column. There are pressure rollers slidingly connected to both sides of the inner cavity of the test clamp, and the pressure rollers on both sides face each other. Pressure sensors are fixedly installed on both sides.

As a further description of the above technical solution:

A guide sleeve is fixedly connected to the rear side of the transmission plate, and a guide rod is slidably connected to the inner cavity of the guide sleeve, and both ends of the guide rod are fixedly connected to corresponding positions on both sides of the inner cavity of the pressing roller.

As a further description of the above technical solution:

The winding assembly includes a pressing roller and a winding frame. The shaft body on one side of the pressing roller is rotatably connected to one side of the side plate through a rotating shaft and a bearing. A cutting blade for sampling is adjustably connected to the top of the winding frame, so The winding frame is slidingly connected to the groove opened on one side of the side plate and is fixedly connected to one side of the transmission mechanism. An extrusion cover is fixedly connected between both sides of the bottom of the winding frame through a connecting block for pressing down the winding frame. The extrusion cover is driven to limit the surface textile body of the pressing roller.

As a further description of the above technical solution:

The cross-sectional shape of the extrusion cover is arc-shaped, and a plurality of friction pads are fixedly connected to the inner cavity of the extrusion cover. The friction pads are flexible plastic pads.

As a further description of the above technical solution:

There is a knife groove on the top of the winding frame, and the cutting blade is slidingly connected in the knife groove. The top of the cutting blade is fixedly connected with a bottom plate. The top of the bottom plate is fixedly connected with a fixing plate. One side of the bottom of the fixed plate is fixedly connected with The second electric push rod, the bottom end of the second electric push rod is fixedly connected to the top of the winding frame, and the top of the extrusion cover is provided with a through slot for the cutting blade to pass through.

As a further description of the above technical solution:

The transmission mechanism includes a mounting plate, which is fixedly connected to the top of the side plate. A third electric push rod is fixedly connected to one side of the bottom of the installation plate, and a connecting rod is fixedly connected to the bottom end of the third electric push rod. Both ends of the connecting rod are fixedly connected to one side of the winding frame through moving blocks.

As a further description of the above technical solution:

The support assembly includes a support base, a slider is fixedly connected to one side of the support base, the slider is slidingly connected in a chute provided on one side of the side plate, a screw hole is provided on one side of the slider, and A transmission screw is threaded in the screw hole, and the other end of the transmission screw extends to one side of the side plate and is fixedly connected with a handle. The inner cavity of the support seat is slidingly connected to a connecting seat, and the inner cavity of the connecting seat is rotationally connected. There are contact rollers, and second sliding rods are fixedly connected to both sides of the bottom of the connecting seat. The second sliding rods are slidingly connected to the bottom of the inner cavity of the support seat, and the limiting plates are fixedly connected between the second sliding rods on both sides. , a spring is set on the outer wall of the second sliding rod, and both ends of the spring are fixedly connected to the limiting plate and the bottom side of the support base respectively.

In summary, due to the adoption of the above technical solutions, the beneficial effects of the present invention are:

1. In the present invention, by moving the side panels to the front of the textile fabric winding section of the production line, the textile body is wound from the winding components on both sides and then threaded between the test components. When an elasticity test is required, pass The control transmission mechanism drives the winding assembly to synchronously limit both ends of the winding fabric. At the same time, the bottom side adjustment motor can drive the screw rod in the linear module to rotate through the rotation of the output shaft and drive the screw rod seat on one side to move. The movement can pull the two pressing rollers on one side to move upward or downward. When the two pressing rollers move sufficiently, the pressing rollers can contact the textile body through contact with the surface of the textile body, and after moving to the measurement position, The pressure system between the textile body and the pressing roller can be tested through the pressure sensor connected to the shaft body on one side of the pressing roller to determine the elastic coefficient of the textile body, and the two-way pulling of the textile body can be achieved through the pressing rollers set oppositely on both sides. The elongation coefficient can be quickly judged, and when the pressing roller is reset after the test, the rear winding mechanism synchronously re-winds the tested textile body to avoid affecting the continuous production of the textile body, and realize the control of the textile body during the production process. Random detection of textile elasticity.

2. In the present invention, by controlling the pressing roller to move downward so that the pressing roller at the top is in contact with the surface of the fabric, the first electric push rod is extended to drive the extrusion cam to squeeze the triangle plates on both sides, and the triangle plates can be squeezed. When the force drives the transmission plates on both sides to move to the surface of the pressing roller, the driving motor drives the driving wheel and the transmission belt to drive the driven wheel and one side of the pressing roller to rotate. The rotation of the pressing roller can drive the surface transmission plate and the laminated textile body The surface is fully contacted, and the transmission energy is applied to the surface of the textile body through the rotation and extrusion of the transmission plate. It can be used in conjunction with the stop of the external textile winding mechanism to test the tensile durability of the textile body, which is conducive to improving the quality of the textile body. The performance testing effect in the overall production process is achieved through diversified testing directions to meet the effective monitoring and processing of product quality in the large-scale production process.

3. In the present invention, through the designed winding assembly, when the third electric push rod is extended to drive the bottom connecting rod to drive the winding frame to move downward, the winding frame can fully contact the surface of the pressing roller through the bottom side extrusion cover. When contacting and detecting, limit the positions on both sides of the textile body to prevent the rear winding mechanism and the feeding end support from affecting the measurement accuracy and improve the accuracy of the detection process. When the winding assembly seals the textile bodies on both sides, the corresponding The contact roller in the position can be forced to reset under the reaction force of the bottom spring. At this time, the reset contact roller can exert a contact effect with the textile body in surface contact, improving the limit of the winding assembly on the textile body. The contact support ability of the extended parts on both sides of the rear position meets the support processing during the normal winding process of the textile body, and the relative lateral position of the slider can be controlled by turning the transmission screw rod in the screw hole on the inside of the slider, improving the Adaptive adjustment of different elastic textile bodies to improve processing adaptability.

4. In the present invention, when the third electric push rod extends to drive the bottom connecting rod to pull the winding frame and the pressing roller to fit and limit the position, after the production plan reaches the end, the operation of the second electric push rod on the top of the winding frame can be controlled. The extension drives the fixed plate to move downward, and the downward movement of the fixed plate can drive the base and the cutting blade to move downward. The movement of the cutting blade can cut the fabric passing by the surface of the pressing roller, so that the textile trapped on the surface of the pressing rollers on both sides The body can be reserved as a sample for backup testing. The current batch of fabrics can be intercepted during the shutdown stage and then tested for elastic properties. This prevents the high-strength damage test samples from flowing into the subsequent product production section and improves the efficiency of measurement processing. Compatibility and adjustability.

Description of the drawings

Figure 1 is a schematic diagram of the overall structure of an elasticity detection device for textile production proposed by the present invention;

Figure 2 is an enlarged structural schematic diagram of part A of an elasticity detection device for textile production proposed by the present invention;

Figure 3 is an enlarged structural schematic diagram of part B of an elasticity detection device for textile production proposed by the present invention;

Figure 4 is a schematic diagram of the exploded disassembly structure of an elasticity detection device for textile production proposed by the present invention;

Figure 5 is a schematic diagram of the split structure of the pressing roller of an elasticity testing device for textile production proposed by the present invention;

Figure 6 is a schematic diagram of the assembly structure of the pressing roller of an elasticity detection device for textile production proposed by the present invention;

Figure 7 is a schematic structural diagram of the support assembly of an elasticity detection device for textile production proposed by the present invention;

Figure 8 is a schematic rear structural view of an elasticity detection device for textile production proposed by the present invention;

Figure 9 is a schematic structural diagram from another angle of an elasticity detection device for textile production proposed by the present invention.

illustration:

1. Base; 2. Support column; 3. Side plate; 4. Test component; 401. Test clamp; 402. Pressure roller; 403. Moving groove; 404. Cover plate; 405. First slide rod; 406. Connecting plate; 407, first electric push rod; 408, extrusion cam; 409, triangular plate; 410, transmission plate; 411, guide rod; 412, driven wheel; 413, transmission belt; 414, driving wheel; 415, drive motor; 416. Fixed seat; 5. Winding component; 501. Winding frame; 502. Cutting blade; 503. Base plate; 504. Fixed plate; 505. Second electric push rod; 506. Connection block; 507. Extrusion cover; 508 , friction pad strip; 509, through groove; 510, pressure roller; 6, support component; 601, support seat; 602, limit plate; 603, spring; 604, second slide rod; 605, connecting seat; 606, Contact roller; 607, slider; 608, screw hole; 7, transmission mechanism; 701, mounting plate; 702, third electric push rod; 703, connecting rod; 8, adjusting motor; 9, screw seat.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. Obviously, the described embodiments are only some of the embodiments of the present invention, rather than all the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative efforts fall within the scope of protection of the present invention.

Please refer to Figures 1-9. The present invention provides a technical solution: an elasticity detection device for textile production, including a base 1, a support column 2 fixedly installed on the top of the base 1, and a support column 2 fixedly connected to the top of the base 1. Side plate 3, one side of the side plate 3 is adjustablely connected with a test assembly 4, and both ends of the side plate 3 are adjustablely connected with a winding assembly 5 for receiving the textile body, and the two sides of the side plate 3 have a winding assembly 5 Located on both sides of the test assembly 4, support assemblies 6 are connected to both ends of one side of the side plate 3, and the support assemblies 6 on both sides are respectively located on both sides of the support assembly 6. The side plate 3 is away from the side of the winding assembly 5. A transmission mechanism 7 is movably connected to the side, and the transmission mechanism 7 is fixedly connected to one side of the winding assembly 5;

The test assembly 4 includes a test clamp 401, a screw seat is fixedly connected to the rear side of the test clamp 401, a linear module is fixedly installed on the outer wall of the screw seat, and the linear module is fixedly installed on the side plate 3 On one side, an adjusting motor 8 is fixedly installed on the bottom side of the linear module. The adjusting motor 8 is fixedly connected to one side of the outer wall of the support column 2. Pressure rollers 402 are slidingly connected to both sides of the inner cavity of the test clamp 401. , and pressure sensors are fixedly installed on the opposite sides of the pressing rollers 402 on both sides. Moving grooves 403 are provided on both sides of the inner cavity of the pressing roller 402, and the inner cavity of the moving groove 403 is slidingly connected with a transmission plate 410, and Triangular plates 409 are fixedly connected to opposite sides of the transmission plates 410 on both sides, and an extrusion cam 408 is fitted between the triangular plates 409 on both sides. A first sliding rod 405 is fixedly connected to one side of the extrusion cam 408. A cover plate 404 is slidably connected to the outer wall of the first slide rod 405. The cover plate 404 is fixedly connected to the end side of the pressing roller 402. The other end of the first slide rod 405 is fixedly connected to a connecting plate 406. The connecting plate A first electric push rod 407 is fixedly installed at the bottom of the other side of 406. The other end of the first electric push rod 407 is fixedly connected to one side of the cover plate 404. The shaft body on one side of the pressing roller 402 is connected to the test through bearing rotation. On one side of the inner cavity of the clamp seat 401, one end of the pressing roller 402 is fixedly connected to a driven wheel 412, one side of the driven wheel 412 is connected to a driving wheel 414 through a belt drive, and the top of the test clamp seat 401 is fixedly connected to a fixed seat. 416. A driving motor 415 is fixedly connected to one side of the fixed base 416, the output shaft of the driving motor 415 is fixedly connected to one side of the driving wheel 414, a guide sleeve is fixedly connected to the rear side of the transmission plate 410, and the inner cavity of the guide sleeve is fixedly connected. A guide rod 411 is slidingly connected, and both ends of the guide rod 411 are fixedly connected to corresponding positions on both sides of the inner cavity of the pressing roller 402. Through the designed guide rod 411, the guide rod can be limited by the guide sleeve on the rear side of the transmission plate 410. The sliding guide position outside 411 avoids shaking and deflection when the transmission plate 410 moves.

The specific implementation method is: when the elasticity test of the textile body is required, by moving the side panel 3 to the front side of the textile cloth winding section of the production line, the textile body is wound from the winding components 5 on both sides and then threaded into the test component. 4, when an elastic force test is required, the winding assembly 5 is driven by the control conduction mechanism to synchronously limit both ends of the winding cloth, and the bottom side adjustment motor 8 can drive the inner wire of the linear module through the rotation of the output shaft. The rod rotates and drives the screw seat on one side to move. The movement of the screw seat can pull the two pressing rollers 402 on one side to move upward or downward. When the two pressing rollers 402 move fully, the pressing roller 402 can pass through the textile The body surface contacts the textile body, and after moving to the measurement position, the pressure system between the textile body and the pressing roller 402 can be tested through the pressure sensor connected to the shaft body on one side of the pressing roller 402 to determine the elasticity of the textile body. coefficient, and can quickly judge the bidirectional stretch elastic coefficient of the textile body through the pressing rollers 402 arranged oppositely on both sides, and after the test is completed, the adjustment motor 8 can be controlled to drive the pressing roller 402 to reset, and the rear side is wound The mechanism synchronously rewinds the tested textile body to avoid affecting the continued production of the textile body, and to achieve random detection of the elasticity of the textile body during the production process. At the same time, when the durability test of the fabric is required, the pressure is controlled. The closing roller 402 moves downward so that the pressing roller 402 at the top contacts the surface of the cloth. At this time, the first electric push rod 407 on one side is extended to drive the connecting plate 406 to move. The connecting plate 406 moves to pull the first slider on one side. The rod 405 moves, and the first sliding rod 405 moves to drive the extrusion cam 408 on one side to squeeze the triangular plates 409 on both sides. The triangular plates 409 can be squeezed and driven by force to drive the transmission plates 410 on both sides inwardly in the moving groove 403 on the surface of the pressing roller 402. When the end of the transmission plate 410 moves to the surface of the pressing roller 402, it can drive the driving wheel 414 to rotate by controlling the driving motor 415. The rotation of the driving wheel 414 can drive the driven wheel 412 and one side of the pressing roller 402 to rotate through the transmission belt 413. The transmission belt 413 is a flexible plastic belt. The flexibility of the transmission belt 413 can match the displacement stroke of the driven wheel 412 when the pressing roller 402 moves, ensuring transmission stability. The rotation of the pressing roller 402 can drive the surface transmission plate 410 and the fitting. The surface of the textile body is fully contacted, and the transmission energy is applied to the surface of the textile body through the rotation and extrusion of the transmission plate 410, so that the test of the tensile durability of the textile body can be carried out in conjunction with the stop of the external textile winding mechanism. It is beneficial to improve the performance testing effect during the textile production process.

The winding assembly 5 includes a pressing roller 402 and a winding frame 501. The shaft body on one side of the pressing roller 402 is rotatably connected to one side of the side plate 3 through a rotating shaft and a bearing. The top of the winding frame 501 is adjustable and connected for use. The cutting blade 502 for sampling, the winding frame 501 is slidingly connected to the groove opened on one side of the side plate 3 and is fixedly connected to one side of the transmission mechanism 7, and the two sides of the bottom of the winding frame 501 are fixedly connected through a connecting block 506. The extrusion cover 507 is used to drive the extrusion cover 507 to limit the textile body on the surface of the pressing roller 402 by pressing down the winding frame 501. The cross-sectional shape of the extrusion cover 507 is arc-shaped, and the inner cavity of the extrusion cover 507 is A plurality of friction pad strips 508 are fixedly connected, and the friction pad strips 508 are flexible plastic pad strips.

The implementation is specifically as follows: through the designed winding assembly 5, when the third electric push rod 702 is extended to drive the bottom connecting rod 703 to drive the winding frame 501 to move downward, the winding frame 501 can be connected to the winding frame 501 through the bottom side extrusion cover 507. The surface of the pressing roller 402 is in full contact, so that both sides of the textile body can be limited during detection, avoiding the contact between the rear winding mechanism and the feeding end support from affecting the measurement accuracy, improving the accuracy of the detection process, and through the designed extrusion Pressure cover 507, the arc-shaped extrusion cover 507 can fully contact the surface of the pressing roller 402, thereby improving the contact pressing effect on the textile body, and through the designed friction pad 508, the contact pressure with the textile body can be improved. Combined sealing effect.

A knife slot is provided on the top of the winding frame 501, and a cutting blade 502 is slidably connected in the knife slot. A bottom plate 503 is fixedly connected to the top of the cutting blade 502, and a fixing plate 504 is fixedly connected to the top of the bottom plate 503. The fixing plate A second electric push rod 505 is fixedly connected to one side of the bottom of 504. The bottom end of the second electric push rod 505 is fixedly connected to the top of the winding frame 501, and the top of the extrusion cover 507 has a through slot 509 for the cutting blade 502 to pass through. , the transmission mechanism 7 includes a mounting plate 701, which is fixedly connected to the top of the side plate 3, and a third electric push rod 702 is fixedly connected to one side of the bottom of the installation plate 701. The third electric push rod 702 A connecting rod 703 is fixedly connected to the bottom end, and both ends of the connecting rod 703 are fixedly connected to one side of the winding frame 501 through moving blocks.

The implementation is specifically as follows: through the designed transmission mechanism 7, when the third electric push rod 702 extends to drive the bottom connecting rod 703 to pull the winding frame 501 and the pressing roller 402 to fit and limit, after the production plan reaches the end, it can Control the extension of the second electric push rod 505 on the top of the winding frame 501 to drive the fixed plate 504 to move downward. The downward movement of the fixed plate 504 can drive the base 1 and the cutting blade 502 to move downward. The movement of the cutting blade 502 can press the pressing roller 402 The fabric passing through the surface is cut, so that the textile body trapped on the surface of the pressing rollers 402 on both sides can be reserved as a sample for backup testing, so that the current batch of fabrics can be intercepted during the shutdown stage and then tested for elastic properties. With the designed cutting blade 502, the sliding of the cutting blade 502 in the knife groove is more stable, which can improve the cutting processing ability of the textile body at the contact position.

The support assembly 6 includes a support base 601. One side of the support base 601 is fixedly connected with a slider 607. The slider 607 is slidingly connected in a slide groove provided on one side of the side plate 3. One side of the slider 607 A screw hole 608 is provided, and a transmission screw is threadedly connected to the screw hole 608. The other end of the transmission screw extends to one side of the side plate 3 and is fixedly connected with a handle. The inner cavity of the support base 601 is slidably connected with a The connecting seat 605 has abutting rollers 606 rotatably connected to the inner cavity of the connecting seat 605. Second sliding rods 604 are fixedly connected to both sides of the bottom of the connecting seat 605. The second sliding rods 604 are slidingly connected to the supporting seat 601. The bottom of the inner cavity and the limiting plate 602 are fixedly connected between the second sliding rods 604 on both sides. A spring 603 is set on the outer wall of the second sliding rod 604. Both ends of the spring 603 are respectively connected with the limiting plate 602 and the support. One side of the bottom of the seat 601 is fixedly connected;

The specific implementation method is as follows: after the winding assembly 5 seals the textile bodies on both sides, since the winding mechanism on the rear side is still working and winding, and the traction force of the textile body at the end far away from the winding mechanism is missing, the textile body is prone to entanglement or Bending, at this time, the contact roller 606 at the corresponding position can be driven to reset by the reaction force of the bottom spring 603. At this time, the reset contact roller 606 can exert a contact effect with the textile body in contact with the surface. , improve the contact and support ability of the extended parts on both sides of the textile body after the winding component 5 limits the position of the textile body, meet the support processing during the normal winding process of the textile body, and can twist the transmission screw rod inside the slider 607 Rotation in the hole 608 controls the relative lateral position of the slider 607 to improve the adaptability to different elastic textile bodies and improve processing adaptability. The reaction force of the spring 603 is passed through the connecting seat when the textile body contacts the surface of the contact roller 606. 605 and the movement of the second slide rod 604 on the bottom side.

Working principle: During use, when the elasticity test of the textile body needs to be carried out, the side panel 3 is moved to the front of the textile fabric winding section of the production line, and the textile body is wound from the winding components 5 on both sides and then put through the test Between the components 4, the winding component 5 is driven by the control transmission mechanism to synchronously limit both ends of the winding cloth. The bottom side adjustment motor 8 drives the screw rod in the linear module to rotate through the rotation of the output shaft and drives the screw rod on one side. The seat moves, and the movement of the screw seat pulls the two pressing rollers 402 on one side to move upward or downward. When the two pressing rollers 402 move fully, the pressing rollers 402 abut the textile body through contact with the surface of the textile body. After moving to the measurement position, the pressure system between the textile body and the pressing roller 402 is tested through the pressure sensor connected to the shaft body on one side of the pressing roller 402 to determine the elastic coefficient of the textile body. After the test is completed, the regulating motor 8 is controlled to work. The pressing roller 402 is driven to reset, and the rear winding mechanism simultaneously winds the tested textile body again;

When testing the durability of the cloth, control the pressing roller 402 to move downward so that the pressing roller 402 at the top contacts the surface of the cloth. At this time, the first electric push rod 407 on one side is extended to drive the connecting plate 406 to move, and the connecting plate 406 is connected. The movement of the plate 406 pulls the first slide bar 405 on one side to move, and the movement of the first slide bar 405 drives the extrusion cam 408 on one side to squeeze the triangle plates 409 on both sides. After the triangle plates 409 are squeezed, they are forced to drive the transmission plates 410 on both sides to press together. The moving groove 403 on the surface of the roller 402 moves from the inside to the outside. When the end of the transmission plate 410 moves to the surface of the pressing roller 402, the driving motor 415 is controlled to drive the driving wheel 414 to rotate. The driving wheel 414 rotates to drive the driven wheel 412 and the side pressure through the transmission belt 413. The closing roller 402 rotates, and the pressing roller 402 rotates to drive the transmission plate 410 on the surface to fully contact the surface of the attached textile body. Through the rotation and extrusion of the transmission plate 410, the transmission energy is applied to the surface of the textile body, and cooperates with the external textile body roll. Testing the tensile durability of the textile body by stopping the winding mechanism;

When the third electric push rod 702 is extended to drive the bottom connecting rod 703 to drive the winding frame 501 to move downward, the winding frame 501 fully contacts the surface of the pressing roller 402 through the bottom extrusion cover 507, and the textile body is inspected during detection. Position limits are provided on both sides to prevent the rear winding mechanism and the feeding end support from affecting the measurement accuracy. When the third electric push rod 702 extends, it drives the bottom connecting rod 703 to pull the winding frame 501 and the pressing roller 402 to fit the limit. After the production plan reaches the end, the extension of the second electric push rod 505 on the top of the winding frame 501 is controlled to drive the fixed plate 504 to move downward. The fixed plate 504 moves downward to drive the base 1 and the cutting blade 502 to move downward, cutting. The blade 502 moves to cut the fabric passing through the surface of the pressing roller 402, so that the textile body trapped on the surface of the pressing roller 402 on both sides is retained as a sample for backup testing. When the third electric push rod 702 extends, it drives the bottom connecting rod 703 Pull the winding frame 501 and the pressing roller 402 to fit into position.

The above are only preferred specific embodiments of the present invention, but the protection scope of the present invention is not limited thereto. Any person familiar with the technical field can, within the technical scope disclosed in the present invention, implement the technical solutions of the present invention. Equivalent substitutions or changes of the inventive concept thereof shall be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides an elasticity detection device is used in textile production, includes base (1), base (1) top fixed mounting has support column (2), support column (2) top fixedly connected with curb plate (3), a serial communication port, curb plate (3) one side adjustable connection has test module (4), curb plate (3) one side both ends all adjustable connection have wire-wound module (5) that are used for accepting the textile, and both sides wire-wound module (5) are located test module (4) both sides, curb plate (3) one side both ends all transmission are connected with supporting component (6), and both sides supporting component (6) are located supporting component (6) both sides respectively, one side swing joint that wire-wound module (5) was kept away from to curb plate (3) has drive mechanism (7), drive mechanism (7) and wire-wound module (5) one side fixed connection.

2. The elastic detection device for textile production according to claim 1, wherein the test assembly (4) comprises a test clamping seat (401), a screw rod seat is fixedly connected to the rear side of the test clamping seat (401), a linear module is fixedly arranged on the outer side wall of the screw rod seat and fixedly arranged on one side of the side plate (3), an adjusting motor (8) is fixedly arranged on the bottom side of the linear module, the adjusting motor (8) is fixedly connected on one side of the outer wall of the support column (2), pressing rollers (402) are slidably connected to two sides of an inner cavity of the test clamping seat (401), and pressure sensors are fixedly arranged on one side of opposite surfaces of the pressing rollers (402).

3. The elastic detection device for textile production according to claim 2, wherein the two sides of the inner cavity of the pressing roller (402) are provided with moving grooves (403), the inner cavity of the moving grooves (403) is slidably connected with a transmission plate (410), two opposite sides of the transmission plate (410) are fixedly connected with triangular plates (409), an extrusion cam (408) is attached between the triangular plates (409), one side of the extrusion cam (408) is fixedly connected with a first sliding rod (405), the outer side wall of the first sliding rod (405) is slidably connected with a cover plate (404), the cover plate (404) is fixedly connected to one side of the tail end of the pressing roller (402), the other end of the first sliding rod (405) is fixedly connected with a connecting plate (406), the bottom of the other side of the connecting plate (406) is fixedly provided with a first electric push rod (407), and the other end of the first electric push rod (407) is fixedly connected with one side of the cover plate (404).

4. The elastic detection device for textile production according to claim 2, wherein a side shaft body of the pressing roller (402) is rotatably connected to one side of an inner cavity of the test holder (401) through a bearing, one end of the pressing roller (402) is fixedly connected with a driven wheel (412), one side of the driven wheel (412) is connected with a driving wheel (414) through belt transmission, the top of the test holder (401) is fixedly connected with a fixing seat (416), one side of the fixing seat (416) is fixedly connected with a driving motor (415), and an output shaft of the driving motor (415) is fixedly connected with one side of the driving wheel (414).

5. The elastic detection device for textile production according to claim 3, wherein a guide sleeve is fixedly connected to the rear side of the transmission plate (410), a guide rod (411) is slidably connected to the inner cavity of the guide sleeve, and two ends of the guide rod (411) are fixedly connected to two corresponding positions of two sides of the inner cavity of the pressing roller (402) respectively.

6. The elastic detection device for textile production according to claim 5, wherein the winding assembly (5) comprises a pressing roller (402) and a winding frame (501), a shaft body of the pressing roller (402) is rotationally connected to one side of a side plate (3) through a rotating shaft and a bearing, a cutting blade (502) for sampling is connected to the top of the winding frame (501) in an adjustable manner, the winding frame (501) is slidably connected to a groove body formed in one side of the side plate (3), an extrusion cover (507) is fixedly connected between two sides of the bottom of the winding frame (501) through a connecting block (506), the surface textile of the pressing roller (402) is driven by pressing the winding frame (501), the transmission mechanism (7) comprises a mounting plate (701), the mounting plate (701) is fixedly connected to the top of the side plate (3), a third electric push rod (702) is fixedly connected to one side of the bottom of the mounting plate (701), and two ends of the connecting rod (703) are fixedly connected to one side of the winding frame (501) through a moving block.

7. The elastic detection device for textile production according to claim 6, wherein the cross section of the extrusion cover (507) is arc-shaped, a plurality of friction cushion strips (508) are fixedly connected to the inner cavity of the extrusion cover (507), and the friction cushion strips (508) are flexible plastic cushion strips.

8. The elastic detection device for textile production according to claim 7, wherein a knife slot is formed in the top of the winding frame (501), the cutting blade (502) is slidably connected in the knife slot, the top of the cutting blade (502) is fixedly connected with a bottom plate (503), the top of the bottom plate (503) is fixedly connected with a fixing plate (504), one side of the bottom of the fixing plate (504) is fixedly connected with a second electric push rod (505), the bottom of the second electric push rod (505) is fixedly connected with the top of the winding frame (501), and a through slot (509) for the cutting blade (502) to pass through is formed in the top of the extrusion cover (507).

9. The elastic detection device for textile production according to claim 8, wherein the supporting component (6) comprises a supporting seat (601), a sliding block (607) is fixedly connected to one side of the supporting seat (601), the sliding block (607) is slidingly connected to the bottom of the inner cavity of the supporting seat (601), a screw hole (608) is formed in one side of the sliding block (607), a transmission screw is connected to the screw hole (608) in an internal thread manner, the other end of the transmission screw extends to one side of the side plate (3) and is fixedly connected with a handle, a connecting seat (605) is slidingly connected to the inner cavity of the supporting seat (601), a second sliding rod (604) is fixedly connected to two sides of the bottom of the connecting seat (605), a limiting plate (602) is fixedly connected to the bottom of the inner cavity of the supporting seat (601), two ends of the spring (603) are sleeved with a limiting plate (603) respectively, and two ends of the spring (603) are fixedly connected to the bottom of the limiting plate (601) and one side of the supporting seat (601).

10. A method of an elasticity detection device for textile production, applied to the elasticity detection device for textile production of claim 9, characterized by comprising the following steps:

s1, when the elasticity test is carried out on the textile body, the side plate (3) is moved to the front side of the winding section of the textile cloth of the production line, and the textile body is wound from the two side winding assemblies (5) and then penetrates between the test assemblies (4);

s2, driving a wire-wrapping assembly (5) to synchronously limit two ends of cloth in winding through a control transmission mechanism, when a third electric push rod (702) works and stretches to drive a bottom connecting rod (703) to drive a winding frame (501) to move downwards, the winding frame (501) fully contacts with the surfaces of the pressing rollers (402) through a bottom extrusion cover (507), limiting two sides of a textile during detection, driving a screw rod in a linear module to rotate through rotation of an output shaft by a bottom side regulating motor (8) and driving a screw rod seat on one side to move, and the screw rod seat moves to pull two pressing rollers (402) on one side to move upwards or downwards, when the two pressing rollers (402) move fully, the pressing rollers (402) contact the textile through contact with the surfaces of the textile, and after the textile moves to a measuring position, a pressure system between the textile and the pressing rollers (402) is tested through a pressure sensor connected with a shaft body on one side of the pressing rollers (402) to judge the elasticity coefficient of the textile;

s3, when durability test is carried out on cloth, the pressing roller (402) is controlled to move downwards so that the pressing roller (402) positioned at the top is in contact with the surface of the cloth, at the moment, the connecting plate (406) is driven to move through the working extension of the first electric push rod (407) at one side, the connecting plate (406) is driven to move by moving the first slide rod (405) to drive the extrusion cam (408) at one side to extrude the triangular plates (409) at two sides, the triangular plates (409) are driven to move outwards in the surface moving groove (403) of the pressing roller (402) under the stress of the extruded triangular plates (409), when the tail end of the driving plate (410) moves to the surface of the pressing roller (402), the driving motor (415) is controlled to drive the driving wheel (414) to rotate, the driving wheel (412) and the pressing roller (402) at one side are driven to rotate through the driving belt (413), the driving plate (410) at the rotating to drive the surface of the driving wheel and the surface of the textile body to be fully contacted, reset effect after continuous stretching is observed, and the durability of the textile body is judged through the front and back change of the reading of the overpressure sensor;

s4, after the test is finished, the regulating motor (8) is controlled to work to drive the laminating roller (402) to reset, the rear winding mechanism synchronously winds the tested textile body again, when the production plan is finished and the preparation is stopped, the second electric push rod (505) at the top of the winding frame (501) is controlled to work to stretch to drive the fixing plate (504) to move downwards, the fixing plate (504) moves downwards to drive the base (1) and the cutting blade (502) to move downwards, the cutting blade (502) moves to cut cloth passing by the surface of the laminating roller (402), and a sample is trapped for backup test.