CN118010520A - Raw material tensile resistance detection device in sock production process and application method thereof - Google Patents

Abstract

The invention discloses a raw material tensile resistance detection device in a sock production process and a use method thereof, and relates to the field of sock production. According to the invention, the sock raw material fiber silk yarn to be detected is clamped on the clamping assembly, so that the repeated feeding time is effectively reduced, the clamping assembly realizes simple feeding of fiber silk yarns with different lengths, and the fiber silk yarns can be automatically adjusted by only placing the fiber silk yarns on the clamping assembly, so that the fiber silk yarns are in a straightened state, and the feeding time of the fiber silk yarns is further reduced.

Description

Raw material tensile resistance detection device in sock production process and application method thereof

Technical Field

The invention relates to the field of sock production, in particular to a raw material tensile resistance detection device in the sock production process and a use method thereof.

Background

The socks are clothing articles worn on feet, play roles of protecting feet and preventing foot odor, are made of cotton yarn socks, wool socks, silk socks, various chemical fiber socks and the like according to raw materials, are made of stocking, middle stocking, ship socks, panty-hose and the like according to the shape, and also have various patterns and varieties such as plain ends, rib ends, heels, jacquard patterns, knitting patterns and the like, and are one of the most important textiles in life of people, so that the socks are necessary for life of people.

The raw materials of the sock mainly comprise the following components: natural fiber: such as cotton, hemp, wool, etc., which has good moisture absorption and breathability and is suitable for personal wear, wherein cotton is the most widely used natural fiber because of its better softness and warmth, and relatively low cost, chemical fiber: such as terylene, chinlon, acrylon, etc., which have better elasticity and durability, therefore, the fiber is often used for manufacturing sports socks or socks with special functions, and elastic fiber: such as spandex, the fiber has excellent elasticity, can increase the stretchability of the sock, and can improve the comfort and wear resistance of the sock.

The above-mentioned fibers constitute the main component of the sock, but before the fibers are woven to form the sock, the fiber raw material needs to be detected, and the detection items are: the physical property detection of the raw materials comprises the stretching property of the raw materials, and the reason for detecting the stretching property of the raw materials of the socks is mainly to ensure that the raw materials have enough elasticity and extensibility to meet the requirements and comfort level of the wearer.

The tensile property detection of the existing sock raw materials is realized through a tensile force detector, the fiber raw materials to be detected are placed on a pneumatic clamp of the tensile force detector, after the fixation is completed, the pneumatic clamp applies tensile force to the fiber raw materials, data such as deformation condition, tensile strength and elongation of a sample are recorded, tensile property indexes of the sample are calculated according to the detected data, and result analysis and evaluation are carried out, but the pneumatic clamp is required to be controlled to move to a section with the same length as the fiber raw materials when the sock raw materials are fed by the tensile force detector, feeding work can be carried out, and for the sock raw material detection device with multiple sample comparison, the feeding mode is time-consuming and labor-consuming, and staff operation is complex.

Disclosure of Invention

Based on the above, the invention aims to provide a raw material tension resistance detection device in the production process of socks and a use method thereof, so as to solve the technical problem that the existing raw material tension detection device for socks is not particularly convenient for detecting a plurality of samples.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a raw materials tensile resistance detection device in socks production process, includes mount and installing frame, the motor is installed to one side of installing frame, the output of motor runs through one side of installing frame and is connected with the mounting disc, and the rotational motion is made to motor control mounting disc, the inside of mounting disc is provided with a plurality of bi-directional screw rods, the surface of bi-directional screw rod all is provided with clamping assembly, clamping assembly includes slip table, pneumatic clamp splice, induction part and adsorption assembly, a set of the slip table rotates to be connected in bi-directional screw rod's surface, the top of slip table is adsorbed with pneumatic clamp splice through adsorption assembly, the surface mounting of slip table has induction part, rack and pinion structure is installed respectively to the both sides of mounting disc, and the opening and the combination of control slip table.

Through adopting above-mentioned technical scheme, the staff only need to wait to detect the fibre silk thread and place in the top of clamping assembly, does not need to adjust the interval between the pulling force chuck, and fibre silk thread automatic positioning, automatic centre gripping labour saving and time saving.

The clamping assembly further comprises a fixed block and an air bag, wherein the fixed block is fixedly arranged on the surface of the sliding table, the air bag is arranged on the inner wall of the fixed block, the air bag pre-clamps the fiber threads, and clamping teeth are arranged on the inner wall of the pneumatic clamping block.

By adopting the technical scheme, the air bag can pre-clamp the fiber yarns, so that the follow-up positioning treatment is facilitated.

The invention is further arranged that the adsorption component comprises an iron column and an electromagnet adsorption part, the iron column is connected with the pneumatic clamping block through a spring, the electromagnet adsorption part is arranged on the surface of the sliding table, and the electromagnet adsorption part is used for fixing the pneumatic clamping block through adsorption of the iron column.

Through adopting above-mentioned technical scheme, the electro-magnet adsorption part can adsorb by the iron prop, realizes the fixed to pneumatic clamp splice.

The invention further provides that the gear rack structure comprises a first gear, a first rack, a second gear, a second rack and a telescopic cylinder, wherein the first gear and the second gear are respectively positioned at two ends of the mounting plate, the first gear and the second gear are mounted at two ends of the bidirectional screw rod, the first rack is mounted on the inner wall of the mounting frame at one side of the mounting plate, which is provided with the first gear, the first gear is meshed with the first rack, the telescopic cylinder is mounted on the inner wall of the mounting frame at one side of the mounting plate, which is provided with the second gear, the output end of the telescopic cylinder is connected with the second rack, and the second rack is meshed with the second gear.

By adopting the technical scheme, the sliding table is controlled to be opened and combined.

The invention is further arranged that the first gear comprises a fixed wheel, a rotating wheel, a groove, an elastic sheet and a fixed groove, wherein the fixed wheel is fixedly arranged at one end of the bidirectional screw rod, the outer wall of the fixed wheel is rotationally connected with the rotating wheel, the rotating wheel is meshed with the first rack, the groove is formed in the outer wall of the fixed wheel, the elastic sheet is arranged on the inner wall of the groove, and the fixed groove is formed in the inner wall of the rotating wheel.

Through adopting above-mentioned technical scheme, can guarantee that first gear can walk the whole journey of first rack smoothly after the slip table merges.

The invention further provides that both sides of each bidirectional screw rod are fixedly provided with a guide rod and a power supply rod.

Through adopting above-mentioned technical scheme, the guide bar is spacing for the motion of slip table, and the power supply pole is the inside electronic component of centre gripping subassembly and supplies power.

The invention is further characterized in that a pushing cylinder is arranged on the inner wall of the fixing frame, the output end of the pushing cylinder is connected with a mounting table, and a tension detection mechanism is arranged on the surface of the mounting table.

By adopting the technical scheme, the tension detection mechanism can be pushed to the detection position.

The invention further provides that the tension detection mechanism is a group of linear guide rails, a tension sensor and an infrared sensor are arranged on the surface of a mounting block of each linear guide rail, and an electromagnet adsorption mechanism is arranged in each linear guide rail.

By adopting the technical scheme, the tension detection can be carried out on the fiber silk thread.

The invention is further arranged that the adsorption position of the electromagnet adsorption mechanism is provided with a chute.

By adopting the technical scheme, the iron pillar is convenient to insert into the electromagnet adsorption mechanism.

The invention also provides the following technical scheme: the application method of the raw material tensile resistance detection device in the sock production process comprises the following specific operation steps:

step one: placing the raw silk yarn of the sock to be detected on a clamping assembly, and pre-clamping by an air bag;

Step two: starting a motor, wherein the motor drives the mounting disc to rotate, the sliding table is opened to two sides along the bidirectional screw rod in the rotating process, the opening action is stopped until the sensing part cannot sense the silk thread, the silk thread is in a straightened state at the moment, and the mounting disc is waited to rotate the sliding table to a tension detection position;

Step three: when the wire to be detected in tension reaches the detection position, a pushing cylinder is started to push the mounting table forwards, so that the surface of the linear guide rail is in contact with the surface of the pneumatic clamping block, the electromagnet adsorption part stops adsorption, an electromagnet adsorption mechanism on the linear guide rail starts working adsorption, and the pneumatic clamping block is adsorbed to the linear guide rail to prepare for tension detection;

step four: one of the two linear guide rails is in a stop state, the other linear guide rail moves outwards, and corresponding tension change detection is carried out through a tension sensor;

Step five: when the silk thread breaks, the tension detection is stopped, the linear guide rail is reset, the electromagnet adsorption mechanism on the linear guide rail stops adsorbing, and the electromagnet adsorption part starts working and adsorbing, so that the pneumatic clamping block returns to the sliding table again, and a tension detection period is completed.

In summary, the invention has the following advantages: according to the invention, the sock raw material fiber silk yarn to be detected is clamped on the clamping assemblies, the motor is started, the mounting plate is driven to rotate by the motor, the sliding table is opened along the bidirectional screw rod, when the sensing part cannot sense the fiber silk yarn, namely, the fiber silk yarn is in a straight state, the sliding table stops opening until the mounting plate conveys the fiber silk yarn to the detection position for detection, and as each bidirectional screw rod is provided with the clamping assembly, when the fiber silk yarn on one clamping assembly is placed and transferred away, the next clamping assembly reaches the feeding position, so that the repeated feeding time is effectively reduced, the clamping assemblies realize simple and convenient feeding of the fiber silk yarn with different lengths, and the fiber silk yarn can be automatically adjusted only by being placed on the clamping assemblies, so that the fiber silk yarn is in the straight state, and the feeding time of the fiber silk yarn is further reduced.

Drawings

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

FIG. 2 is a schematic diagram of the overall structure of the present invention;

FIG. 3 is a schematic view of a clamping assembly according to the present invention;

FIG. 4 is a schematic view showing the internal structure of the mounting frame of the present invention;

FIG. 5 is a schematic view of the internal structure of the mounting plate of the present invention;

FIG. 6 is a schematic diagram showing a structure of the tension detecting state according to the present invention;

FIG. 7 is a schematic view of a first gear according to the present invention;

fig. 8 is an enlarged view of the structure of fig. 7 at a in accordance with the present invention.

In the figure: 1. a fixing frame; 2. a mounting frame; 3. a motor; 4. a mounting plate; 5. a bidirectional screw; 6. a clamping assembly; 601. a sliding table; 602. a fixed block; 603. an air bag; 604. pneumatic clamping blocks; 605. clamping teeth; 606. an iron column; 607. an electromagnet adsorption part; 608. an induction unit; 7. a first gear; 701. a fixed wheel; 702. a rotating wheel; 703. a groove; 704. an elastic sheet; 705. a fixing groove; 8. a first rack; 9. a second gear; 10. a second rack; 11. a telescopic cylinder; 12. a pushing cylinder; 13. a mounting table; 14. a linear guide rail; 15. a guide rod; 16. and a power supply rod.

Detailed Description

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. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

Hereinafter, an embodiment of the present invention will be described in accordance with its entire structure.

Before the sock is woven by the fibers, the physical performance of the fiber raw material, namely the tensile performance, also called tensile resistance, of the fiber silk yarn is detected, and the reason for detecting the tensile resistance of the sock raw material is mainly to ensure that the sock raw material has enough elasticity and extensibility.

The motor 3 is installed to one side of installing frame 2, the output of motor 3 runs through one side of installing frame 2 and is connected with mounting plate 4, when motor 3 starts, mounting plate 4 takes place to rotate thereupon, the inside activity of mounting plate 4 is provided with a plurality of bi-directional screw rods 5, and the contact position of bi-directional screw rod 5 and mounting plate 4 is provided with the damping layer, the surface of bi-directional screw rod 5 all is provided with clamping assembly 6, and when mounting plate 4 is rotatory, bi-directional screw rod 5 and clamping assembly 6 take place rotatoryly thereupon too, after the detection personnel will wait to detect the fibre silk thread and place clamping assembly 6 and carry out the centre gripping, motor 3 drive mounting plate 4 is rotatory, and then with clamping assembly 6 and fibre silk thread rotatory to wait to detect the position and prepare to carry out tensile testing work.

The clamping assembly 6 comprises a group of sliding tables 601 which are rotationally connected to the surface of the bidirectional screw 5, a pre-clamping part and a firm clamping part are arranged at the top of the sliding tables 601, the pre-clamping part comprises a fixed block 602 and an air bag 603, the fixed block 602 is fixedly arranged on the surface of the sliding tables 601, the air bag 603 is arranged on the inner wall of the fixed block 602, the air bag 603 can pre-clamp fiber threads, a micro air pump is arranged in the fixed block 602 and is used for supplying air to the air bag 603, when the fiber threads are positioned between the air bags 603, the air bag 603 is inflated to pre-clamp the fiber threads, the top of the sliding tables 601 is provided with a pneumatic clamping block 604 which is fixedly adsorbed by the adsorption assembly, the inner wall of the pneumatic clamping block 604 is provided with clamping teeth 605, and the pneumatic clamping block 604 firmly clamps the fiber threads by the clamping teeth 605;

The adsorption component comprises an iron pillar 606 and an electromagnet adsorption part 607, the iron pillar 606 is connected with the pneumatic clamping block 604 through a spring, the electromagnet adsorption part 607 is arranged on the surface of the sliding table 601, and the electromagnet adsorption part 607 is used for fixing the pneumatic clamping block 604 through the adsorption of the iron pillar 606.

Based on the structure, the clamping assemblies 6 in the initial state are in a combined state, namely the sliding tables 601 are contacted with each other, at the moment, the sock fiber yarns to be detected are placed on the sliding tables 601, so that the air bags 603 are inflated to pre-clamp the fiber yarns, but the fiber yarns are not in a straightened state at the moment and are unfavorable for subsequent tension detection, so that after the pre-clamping is finished, the motor 3 is started, and under the condition that the mounting plate 4 rotates, the sliding tables 601 are controlled to be opened through the rack-and-pinion structures at two sides of the mounting plate 4, and the fiber yarns are pulled to the straightened state;

The gear rack structure is composed of two parts, namely a control sliding table 601 is opened and the control sliding table 601 is combined, the two parts are respectively positioned at two sides of a mounting disc 4, the structure for controlling the sliding table 601 to be opened comprises a second gear 9 arranged at one end of a bidirectional screw 5, a telescopic cylinder 11 is arranged on the inner wall of a mounting frame 2 at one side of the mounting disc 4 provided with the second gear 9, the output end of the telescopic cylinder 11 is connected with a second rack 10, the second rack 10 is meshed with the second gear 9, namely when the sliding table 601 needs to be opened, the telescopic cylinder 11 is started, the telescopic cylinder 11 pushes the second rack 10 forwards, at the moment, the second gear 9 and the second rack 10 generate meshing motion, and then the bidirectional screw 5 is driven to rotate, meanwhile, one side of the bidirectional screw 5 is fixedly provided with a guide rod 15, the guide rod 15 is used, when the bidirectional screw 5 rotates, a group of sliding tables 601 can be opened outwards to start stretching work on the fiber threads, when the fiber threads are located on the sliding tables 601 in an initial state and the air bags 603 are used for pre-clamping, the sensing parts 608 on the surfaces of the sliding tables 601 can sense the fiber threads, the sensing parts 608 are infrared sensing, two ends of the fiber threads can be gradually separated from the sensing parts 608 along with the opening of the sliding tables 601, after the sensing parts 608 sense the fiber threads, the pneumatic clamping blocks 604 firmly clamp the fiber threads, namely, after the air bags 603 shrink, the fiber threads are still in a stretched state, the telescopic cylinder 11 shrinks to pull back the second rack 10, and the follow-up mounting disc 4 can not rotate the bidirectional screw 5 any more and is ready for follow-up tension detection work.

The inner wall of the fixing frame 1 is provided with a pushing cylinder 12, the output end of the pushing cylinder 12 is connected with a mounting table 13, the surface of the mounting table 13 is provided with a tension detection mechanism, the tension detection mechanism is a group of linear guide rails 14, the surface of a mounting block of the linear guide rails 14 is provided with a tension sensor and an infrared sensor, the inside of the linear guide rails 14 is provided with an electromagnet adsorption mechanism, when the mounting plate 4 carries the fiber threads to the detection position, the motor 3 stops, the pushing cylinder 12 is started, the pushing cylinder 12 pushes the mounting table 13 outwards, a group of linear guide rails 14 are arranged on the surface of the mounting table 13, an infrared sensor is arranged on the surface of the linear guide rails 14, a structure matched with the infrared sensor is also arranged on the sliding table 601, therefore, when the sliding table 601 reaches the detection position, the infrared sensor sends a signal to the controller to control the linear guide rail 14 to perform translational motion so as to lead the linear guide rail 14 to be aligned with the sliding table 601, at the moment, the electromagnet adsorption part 607 is closed, the electromagnet adsorption mechanism arranged inside the linear guide rail 14 is started, the iron columns 606 are adsorbed, so that the iron columns 606 are inserted into the linear guide rails 14 along the inclined grooves at the adsorption positions, the inclined grooves can facilitate the insertion positions of the iron columns 606 to be more accurate, at the moment, the pneumatic clamping blocks 604 are adsorbed onto the linear guide rails 14 from the sliding table 601, then the pushing cylinder 12 contracts a part, a traversing space of the linear guide rails 14 is reserved, one linear guide rail 14 moves outwards, the other linear guide rail 14 is not moved, the tension applied to the fiber yarn is detected by a tension sensor on the linear guide 14 mounting block, a specific tension detecting component is not a main innovation point of the application, the figures are therefore not shown in detail, but only in outline, and the person skilled in the art can simply derive the corresponding structures from the prior art.

When the wire breaks, the tension detection is stopped, the linear guide rail 14 is reset, the pushing cylinder 12 is ejected and returns to the position of the sliding table 601 again, at the moment, the electromagnet adsorption mechanism is closed, the electromagnet adsorption part 607 is started, the pneumatic clamping block 604 is adsorbed onto the sliding table 601 again, at the moment, the pushing cylinder 12 is contracted, and the mounting table 13 and the tension detection mechanism on the surface are synchronously retracted.

At this time, the motor 3 is started, the mounting plate 4 is controlled to continue rotating, the sliding table 601 is controlled to be combined, the combined structure of the sliding table 601 comprises a first gear 7 at the other end of the bidirectional screw 5 and a first rack 8 arranged on the inner wall of the mounting frame 2 at one side of the mounting plate 4 and provided with the first gear 7, namely when the mounting plate 4 continues rotating, the first gear 7 contacts with the first rack 8, the first gear 7 meshed with the first rack 8 rotates, the bidirectional screw 5 rotates reversely, and at this time, the sliding table 601 moves inwards to be combined;

Further, because the lengths of different fiber threads are different, and the length of the first rack 8 is fixed, after the sliding table 601 is reset, the first gear 7 may not completely run through the whole process of the first rack 8, and then the first gear 7 may be blocked, in order to prevent this situation, the first gear 7 is in a separable structure, including the fixed wheel 701 and the rotating wheel 702, the fixed wheel 701 is mounted at one end of the bidirectional screw 5, the outer wall of the fixed wheel 701 is rotationally connected with the rotating wheel 702, and the rotating wheel 702 is mutually meshed with the first rack 8, the outer wall of the fixed wheel 701 is provided with the groove 703, the inner wall of the groove 703 is provided with the elastic piece 704, the inner wall of the rotating wheel 702 is provided with the fixed groove 705, after the sliding table 601 is completely combined and reset, the elastic piece 704 is extruded by the fixed groove 705 inside the rotating wheel 702, and the fixed wheel 701 can continue to rotate along the fixed wheel 701, and the bidirectional screw 5 cannot rotate at this moment, so that the first gear 701 can smoothly run through the one end of the bidirectional screw 5, the clamping assembly 6 is located right above the whole process, and the work can be continued.

In the above-mentioned structural flow, the staff only need to wait to detect the fibre silk thread and place in the top of clamping component 6, need not adjust the interval between the pulling force chuck, and fibre silk thread automatic positioning, automatic centre gripping labour saving and time saving.

The power supply of the electronic components on the clamping assembly 6 is provided by a power supply rod 16. The power supply rod 16 is similar to a trolley line structure, is a set of power transmission devices for supplying power to the moving equipment, and is of the prior art, and therefore is not described in detail.

Although embodiments of the invention have been illustrated and described, the specific embodiments are illustrative of the invention and are not to be construed as limiting the invention, as the specific features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Claims (10)

1. Raw materials tensile strength detection device in socks production process, including mount (1) and installing frame (2), its characterized in that: the utility model discloses a motor, including installation frame (2), motor (3) are installed to one side of installation frame (2), one side of installation frame (2) is run through to the output of motor (3) and be connected with mounting disc (4), and rotary motion is made to motor (3) control mounting disc (4), the inside of mounting disc (4) is provided with a plurality of bi-directional screw rods (5), the surface of bi-directional screw rods (5) all is provided with clamping assembly (6), clamping assembly (6) include slip table (601), pneumatic clamp splice (604), induction part (608) and adsorption component, a set of slip table (601) rotate and are connected in the surface of bi-directional screw rods (5), the top of slip table (601) is adsorbed with pneumatic clamp splice (604) through adsorption component, the surface mounting of slip table (601) has induction part (608), rack and pinion structure is installed respectively to the both sides of mounting disc (4), controls the opening and the combination of slip table (601).

2. The raw material tension resistance detection device in the production process of socks according to claim 1, which is characterized in that: the clamping assembly (6) further comprises a fixed block (602) and an air bag (603), the fixed block (602) is fixedly arranged on the surface of the sliding table (601), the air bag (603) is arranged on the inner wall of the fixed block (602), the air bag (603) is used for pre-clamping fiber threads, and clamping teeth (605) are arranged on the inner wall of the pneumatic clamping block (604).

3. A sock production process raw material tension resistance detection device according to claim 2, characterized in that: the adsorption component comprises an iron column (606) and an electromagnet adsorption part (607), the iron column (606) is connected with a pneumatic clamping block (604) through a spring, the electromagnet adsorption part (607) is arranged on the surface of the sliding table (601), and the electromagnet adsorption part (607) is used for fixing the pneumatic clamping block (604) through adsorption of the iron column (606).

4. The raw material tension resistance detection device in the production process of socks according to claim 1, which is characterized in that: the gear rack structure comprises a first gear (7), a first rack (8), a second gear (9), a second rack (10) and a telescopic cylinder (11), wherein the first gear (7) and the second gear (9) are respectively located at two ends of a mounting disc (4), the first gear (7) and the second gear (9) are mounted at two ends of a bidirectional screw (5), the mounting disc (4) is provided with the first rack (8) mounted on the inner wall of a side mounting frame (2) of the first gear (7), the first gear (7) is meshed with the first rack (8) in an intermeshing manner, the telescopic cylinder (11) is mounted on the inner wall of a side mounting frame (2) of the second gear (9), and the output end of the telescopic cylinder (11) is connected with the second rack (10), and the second rack (10) is meshed with the second gear (9) in an intermeshing manner.

5. The sock production process raw material tensile resistance detection device according to claim 4, wherein: the first gear (7) comprises a fixed wheel (701), a rotating wheel (702), a groove (703), an elastic sheet (704) and a fixed groove (705), wherein the fixed wheel (701) is fixedly arranged at one end of a bidirectional screw rod (5), the rotating wheel (702) is rotatably connected with the outer wall of the fixed wheel (701), the rotating wheel (702) is meshed with a first rack (8) mutually, the groove (703) is formed in the outer wall of the fixed wheel (701), the elastic sheet (704) is arranged on the inner wall of the groove (703), and the fixed groove (705) is formed in the inner wall of the rotating wheel (702).

6. The raw material tension resistance detection device in the production process of socks according to claim 1, which is characterized in that: both sides of each bidirectional screw rod (5) are fixedly provided with a guide rod (15) and a power supply rod (16).

7. The raw material tension resistance detection device in the production process of socks according to claim 1, which is characterized in that: the inner wall of the fixing frame (1) is provided with a pushing cylinder (12), the output end of the pushing cylinder (12) is connected with an installation table (13), and the surface of the installation table (13) is provided with a tension detection mechanism.

8. The sock production process raw material tensile resistance detection device according to claim 7, wherein: the tension detection mechanism is a group of linear guide rails (14), a tension sensor and an infrared sensor are arranged on the surface of a mounting block of each linear guide rail (14), and an electromagnet adsorption mechanism is arranged in each linear guide rail (14).

9. The sock production process raw material tensile resistance detection device according to claim 8, wherein: and a chute is arranged at the adsorption position of the electromagnet adsorption mechanism.

10. A method for using the raw material tensile resistance detection device in the production process of socks, which adopts the raw material tensile resistance detection device in the production process of socks according to any one of claims 1 to 9, and is characterized in that: the specific operation steps are as follows:

step one: placing a sock raw material silk thread to be detected on a clamping assembly (6), and pre-clamping by an air bag (603);

step two: starting a motor (3), wherein the motor (3) drives a mounting disc (4) to rotate, and opening a sliding table (601) to two sides along a bidirectional screw rod (5) in the rotating process until an induction part (608) can not induce a silk thread, stopping opening the sliding table, and at the moment, the silk thread is in a straightened state, and waiting for the mounting disc (4) to rotate the sliding table (601) to a tension detection position;

Step three: when the wire to be detected in tension reaches the detection position, a pushing cylinder (12) is started, the mounting table (13) is pushed forwards, the surface of the linear guide rail (14) is in contact with the surface of the pneumatic clamping block (604), the electromagnet adsorption part (607) stops adsorption, an electromagnet adsorption mechanism on the linear guide rail (14) starts to work and adsorb, and the pneumatic clamping block (604) is adsorbed on the linear guide rail (14) to prepare for tension detection;

step four: one of the two linear guide rails (14) is in a stop state, the other linear guide rail moves outwards, and corresponding tension change detection is carried out through a tension sensor;

Step five: when the silk thread breaks, tension detection is stopped, the linear guide rail (14) is reset, the electromagnet adsorption mechanism on the linear guide rail (14) stops adsorbing, and the electromagnet adsorption part (607) starts working and adsorbing, so that the pneumatic clamping block (604) returns to the sliding table (601) again, and a tension detection period is completed.