CN215894217U - Textile fabric tensile strength detection device - Google Patents

Abstract

The utility model provides a textile fabric tensile strength detection device, which comprises: the top of the bottom plate is respectively and fixedly provided with a hole density detection mechanism, a tensile strength detection mechanism and a data adjusting mechanism, the tensile strength detection mechanism is used for testing the stress strength of the knitting yarn, the hole density detection mechanism is used for testing the qualification degree of the knitting fabric, the tensile strength detection mechanism is arranged to solve the problem that the prior device can only detect the single line in the cloth, increase the detection range of the device, reduce the data deviation, so that a user can better master the damage range of the cloth, the quality of the cloth to be detected is improved by arranging the hole detection mechanism, and the cloth is enabled to have the experience of use by customers after the batch of cloth flows into the market, the tension data are effectively collected and converted by setting data adjustment, so that the device can adjust the telescopic distance according to different cloth materials in the detection process.

Description

Textile fabric tensile strength detection device

Technical Field

The utility model relates to the technical field of knitted fabric detection equipment, in particular to a textile fabric tensile strength detection device.

Background

The textile origin is a general name taken from spinning and weaving, but with the continuous development and perfection of a textile knowledge system and a subject system, particularly after non-woven textile materials and three-dimensional compound weaving and other technologies are produced, the textile is not only produced by traditional hand spinning and weaving, but also produced by non-woven fabric technology, modern three-dimensional weaving technology, modern electrostatic nano-web forming technology and the like, and is used for clothing, industry and decoration. Therefore, modern textile refers to a multi-scale structure processing technology of fiber or fiber aggregate, the ancient textile and printing and dyeing technology of China has a very long history, and as early as in the original society period, ancient people have understood to use local materials in order to adapt to climate change, natural resources are used as raw materials for textile and printing and manufacturing simple hand textile tools, and clothes, airbags and curtain carpets in daily life are all products of the textile and printing and dyeing technology.

The existing textile fabric tensile strength detection device detects the maximum tensile range of the knitted fabric, but the detection range of the existing device is limited, the whole cloth cannot be tested, and the single knitting thread cannot represent the range born by the whole cloth, so that the data deviation is large, the misleading to a user is high, and the use effect in the later period is influenced.

Therefore, it is necessary to provide a device for detecting the tensile strength of textile fabric to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a textile fabric tensile strength detection device.

In order to solve the technical problem, the utility model provides a textile fabric tensile strength detection device, which comprises: the top of the bottom plate is fixedly provided with a hole density detection mechanism, a tensile strength detection mechanism and a data adjusting mechanism respectively;

the hole density detection mechanism is used for testing the qualification degree of the knitted fabric and comprises two support plates A, and a material placing plate A is fixedly arranged between the tops of the two support plates A;

the tensile strength detection mechanism is used for testing the stress strength of knitting yarns and comprises two main supporting plates B, a material placing plate B is fixedly arranged between the tops of the two main supporting plates B, two linking blocks are fixedly arranged on the tops of the material placing plate B, an installation ring B is fixedly arranged on the top of each of the two linking blocks, electric telescopic rods B are fixedly inserted into the inner surface walls of the two installation rings B, U-shaped sleeve frames are fixedly arranged at the output ends of the two electric telescopic rods B, pressure detecting rings are fixedly arranged on the inner surface walls of the two installation rings B, springs are fixedly arranged on the opposite sides of the two U-shaped sleeve frames, and the inner surface wall of each of the two springs is movably sleeved on the output end of the electric telescopic rod B and is in contact with one side of the outer wall of the pressure detecting ring;

the data adjusting mechanism is used for collecting detection information and modifying the elongation data, and comprises a controller, a display screen is fixedly arranged on the front surface of the controller, and a group of operation keys are movably arranged on the front surface of the controller.

Preferably, the top of the material placing plate A is provided with a rectangular groove, one side of the outer wall of the material placing plate A is fixedly provided with an L-shaped frame, and the top of the L-shaped frame is fixedly provided with a mounting ring A.

Preferably, the inner surface wall of the mounting ring A is fixedly inserted with an electric telescopic rod A, the output end of the electric telescopic rod A is fixedly provided with a connecting plate, and the bottom of the connecting plate is fixedly provided with a plurality of detection needles with the same outer wall diameter.

Preferably, two threaded holes are formed in the top of the U-shaped sleeve frame, each threaded hole is connected with a threaded rod in a rotating mode, and a rotating ring is fixedly mounted at the top of each threaded rod.

Preferably, two the outer table wall of every of threaded rod all fixedly overlaps and is equipped with the bearing, two the outer table wall of every of bearing all fixedly overlaps and is equipped with the clamp plate.

Compared with the prior art, the textile fabric tensile strength detection device provided by the utility model has the following beneficial effects:

(1) the problem that the existing device can only detect the single line in the cloth is solved by arranging the tensile strength detection mechanism, the detection range of the device is enlarged, the deviation of data is reduced, and then a user can better master the damage range of the cloth.

(2) The quality of the cloth to be detected is improved by arranging the hole detection mechanism, and the batch of cloth is enabled to flow into the market, so that the experience of the user is good.

(3) The tension data are effectively collected and converted through data setting adjustment, so that the device can adjust the telescopic distance according to different cloth materials in the detection process.

Drawings

FIG. 1 is a schematic front view of a structure of a tensile strength detection device for textile fabric provided by the utility model;

FIG. 2 is a side view of the textile fabric tensile strength detection device provided by the utility model;

fig. 3 is a perspective view of a structure at a position a in fig. 1 of the textile fabric tensile strength detection device provided by the utility model.

Reference numbers in the figures: 1. a base plate; 21. a support plate A; 22. placing a material plate A; 23. a rectangular groove; 24. an L-shaped frame; 25. a mounting ring A; 26. an electric telescopic rod A; 27. a connecting plate; 28. a detection pin; 31. a main supporting plate B; 32. placing a material plate B; 33. a joining block; 34. a mounting ring B; 35. an electric telescopic rod B; 36. a pressure probe ring; 37. a U-shaped sleeve frame; 38. a spring; 39. a threaded hole; 310. a threaded rod; 311. rotating the ring; 312. a bearing; 313. pressing a plate; 41. a controller; 42. a display screen; 43. an operation key.

Detailed Description

The utility model is further described with reference to the following figures and embodiments.

As shown in fig. 1-3, the textile fabric tensile strength detection device comprises: the knitting needle punching and fixing device comprises a bottom plate 1, wherein the top of the bottom plate 1 is fixedly provided with a hole density detection mechanism, a tensile strength detection mechanism and a data adjustment mechanism respectively, the hole density detection mechanism is used for testing the qualification degree of knitting fabrics, the tensile strength detection mechanism is used for testing the stress strength of knitting threads, the tensile strength detection mechanism comprises two main supporting plates B31, a material placing plate B32 is fixedly arranged between the tops of two main supporting plates B31, the top of the material placing plate B32 is fixedly provided with two connecting blocks 33, the top of each of the two connecting blocks 33 is fixedly provided with a mounting ring B34, the inner surface walls of two mounting rings B34 are fixedly inserted with an electric telescopic rod B35, the output ends of the two electric telescopic rods B35 are fixedly provided with U-shaped sleeves 37, the inner surface walls of the two mounting rings B34 are fixedly provided with pressure detecting rings 36, the opposite sides of the two U-shaped sleeves 37 are fixedly provided with springs 38, the inner surface wall of each of the two springs 38 is movably sleeved at the output end of the electric telescopic rod B35 and is contacted with one side of the outer wall of the pressure detecting ring 36, the top parts of the two U-shaped sleeve frames 37 are respectively provided with a threaded hole 39, the inner surface wall of each of the two threaded holes 39 is rotatably connected with a threaded rod 310, the top parts of the two threaded rods 310 are respectively and fixedly provided with a rotating ring 311, the outer surface wall of each of the two threaded rods 310 is respectively and fixedly sleeved with a bearing 312, the outer shaft outer surface wall of each of the two bearings 312 is respectively and fixedly sleeved with a pressing plate 313, when cloth is placed between the U-shaped sleeve frames 37, the rotating ring 311 is rotated to drive the threaded rod 310 to move downwards in the threaded hole 39, the movable connectivity of the bearings 312 and the threaded rods 310 is utilized, so that the pressing plate 313 is finally contacted with the cloth, the cloth is fixed in the U-shaped sleeve frames 37 along with the continuous reduction of the height, after the cloth is fixed, the cloth, the electric telescopic rod B35 fixed in the mounting ring B34 is started, the U-shaped bracket 37 is driven to move towards the direction of the connecting block 33, the spring 38 connected with the U-shaped bracket is driven to move towards the inside of the mounting ring B34 and contact with the pressure detecting ring 36 in the process, the operation is stopped when the U-shaped bracket moves to the point that the internal structure of the cloth is broken, at the moment, pressure data are transmitted into the controller 41 in a physical induction mode for maximum tension conversion, the data adjusting mechanism is used for collecting detection information and modifying tension elongation data, the data adjusting mechanism comprises the controller 41, a display screen 42 is fixedly arranged on the front surface of the controller 41, a group of operation keys 43 are movably arranged on the front surface of the controller 41, the telescopic distance of the electric telescopic rod B35 is adjusted through the operation keys 43 on the controller 41 according to different stress of the cloth, and the transmitted data are displayed through the display screen 42 after being converted by the controller 41.

The problem that the existing device can only detect the single line in the cloth is solved by arranging the tensile strength detection mechanism, the detection range of the device is enlarged, the deviation of data is reduced, and then a user can better master the damage range of the cloth.

The tension data are effectively collected and converted by setting data adjustment, so that the device can adjust the telescopic distance according to different cloth materials in the detection process.

According to the illustration in fig. 1-2, the hole detection mechanism includes two support plates a21, a material placing plate a22 is fixedly installed between the tops of the two support plates a21, a rectangular groove 23 is opened on the top of the material placing plate a22, an L-shaped frame 24 is fixedly installed on one side of the outer wall of the material placing plate a22, an installation ring a25 is fixedly installed on the top of the L-shaped frame 24, an electric telescopic rod a26 is fixedly inserted on the inner surface wall of the installation ring a25, a connection plate 27 is fixedly installed on the output end of the electric telescopic rod a26, a plurality of detection needles 28 with the same outer wall diameter are fixedly installed on the bottom of the connection plate 27, firstly, the cloth to be detected is placed in the rectangular groove 23 on the material placing plate a22, further, the electric telescopic rod a26 in the installation ring a25 is started to drive the connection plate 27 to descend, so that the detection needles 28 in the connection plate 27 are in contact with the weaving gaps on the surface of the cloth, and the areas of the gaps and the detection needles 28 in contact with the surfaces, the cloth enters the controller 41 for analysis in a signal transmission mode, and whether the cloth meets the use standard or not is judged.

Through setting up hole detection mechanism and improving the quality of waiting to detect the cloth, also make this batch of cloth flow into market after, the experience that the customer used feels simultaneously.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (5)

1. The utility model provides a textile fabric tensile strength detection device which characterized in that includes: the top of the bottom plate is respectively provided with a hole density detection mechanism, a tensile strength detection mechanism and a data adjusting mechanism;

the hole density detection mechanism comprises two support plates A, and a material placing plate A is arranged between the two support plates A;

the tensile strength detection mechanism comprises two main supporting plates B, a material placing plate B is arranged between the two main supporting plates B, the material placing plate B is provided with two connecting blocks, the connecting blocks are provided with mounting rings B, electric telescopic rods B are arranged in the two mounting rings B, the two electric telescopic rods B are respectively provided with a U-shaped sleeve frame, pressure detecting rings are respectively arranged in the two mounting rings B, springs are respectively arranged on the opposite sides of the two U-shaped sleeve frames, and the springs are sleeved at the output ends of the electric telescopic rods B and are in contact with the pressure detecting rings;

the data adjusting mechanism comprises a controller, the controller is provided with a display screen, and the controller is provided with an operation key.

2. The textile fabric tensile strength detection device according to claim 1, wherein the material placing plate A is provided with a rectangular groove, one side of the material placing plate A is provided with an L-shaped frame, and the L-shaped frame is provided with an installation ring A.

3. The textile fabric tensile strength detection device according to claim 2, wherein an electric telescopic rod A is arranged in the mounting ring A, the electric telescopic rod A is provided with a connecting plate, and a plurality of detection needles are arranged at the bottom of the connecting plate.

4. The textile fabric tensile strength detection device according to claim 1, wherein threaded holes are formed in the tops of the two U-shaped sleeve frames, threaded rods are connected in the threaded holes, and rotating rings are mounted on the tops of the two threaded rods.

5. The textile fabric tensile strength detection device according to claim 4, wherein the threaded rod sleeves bearings, and the bearings are sleeved with pressure plates.

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