CN111687350B - Weaving module of metal net processing device - Google Patents

Abstract

The invention provides a weaving module of a metal net processing device, which comprises a weaving module, wherein the rear part of the weaving module is provided with a warp feeding module, the side edge of the weaving module is provided with a weft feeding module, the warp feeding module supplies more than three parallel warps which move forwards to the weaving module, and the weft feeding module supplies weft which moves transversely to the weaving module; the weaving module comprises an upper block and a lower block which are assembled in parallel up and down, and a working interval is designed between the upper block and the lower block; a thread cutting module for cutting off the weft is assembled between the weft feeding module and the weaving module, and a winding module for winding the formed metal mesh forwards is assembled at the front part of the weaving module. The metal mesh processed by the device has a structure completely different from that of the traditional metal mesh, and even if the metal mesh is broken at one position, other parts cannot be influenced, so that the using effect is better.

Description

Weaving module of metal net processing device

Technical Field

The invention belongs to the technical field of machining, and particularly relates to a weaving module of a metal mesh machining device.

Background

The net is a product which is often used in production and life of people. The net can be further used for manufacturing articles in daily life according to the difference of materials, namely nylon net, metal net and the like, wherein the nylon net can be used for manufacturing various net bags, and the metal net can be used for manufacturing fences, separation nets, safety nets and the like. The existing metal net is manufactured by welding metal wires which are arranged in parallel and have different directions in the front and the back. The strength of the metal net is determined by the welding strength of the front and rear metal wires, meanwhile, the traditional metal net is only fixedly connected by simply depending on welding, metal wires in different directions of the metal net are positioned on two sides and are easily torn apart, and the metal wires are easily separated if the metal net is welded and damaged. In addition, the traditional metal net processing equipment has a complex structure and higher processing cost of the metal net.

Disclosure of Invention

In view of the above problems, the present invention provides a weaving module of a metal mesh processing apparatus, which can process a metal mesh in a weaving manner, so that the metal mesh is firmer.

The technical scheme adopted by the invention for solving the technical problems is as follows: the metal net processing device comprises a weaving module, wherein the rear part of the weaving module is provided with a warp feeding module, the side edge of the weaving module is provided with a weft feeding module, the warp feeding module supplies more than three parallel warps which move forwards to the weaving module, and the weft feeding module supplies weft which move transversely to the weaving module; the warp and weft are made of metal materials, the weaving module comprises an upper block and a lower block which are assembled in parallel up and down, and a working interval is designed between the upper block and the lower block; the upper block is internally provided with an upper pressing block which extends out of the lower surface of the upper block downwards, the lower end of the upper pressing block is provided with a downward convex block, the upper part of the lower block is provided with a lower forming groove corresponding to the convex block at the lower end of the upper pressing block, the lower block is internally provided with a lower pressing block which extends out of the upper surface of the lower block upwards, the upper end of the lower pressing block is provided with an upward convex block, and the cross section of the convex block is in a semicircular shape in the embodiment. The lower part of the upper block is provided with an upper forming groove corresponding to the upper end of the lower pressing block; the upper pressing blocks and the lower pressing blocks are assembled in an array in the overlooking direction, the upper pressing blocks and the lower pressing blocks are arranged at intervals in the overlooking direction, namely the lower pressing blocks are assembled between the two adjacent upper pressing blocks, the upper pressing blocks are assembled between the two adjacent lower pressing blocks, the warp yarns extend into the working interval between the upper pressing blocks and the lower pressing blocks and penetrate through the upper pressing blocks, the lower forming grooves and the lower pressing blocks and the upper forming grooves, when the upper pressing blocks move downwards, the warp yarns are pressed in the lower forming grooves by the bumps at the lower ends of the upper pressing blocks, when the lower pressing blocks move upwards, the warp yarns are pressed in the upper forming grooves by the bumps at the upper ends of the lower pressing blocks, and when the upper pressing blocks and the lower pressing blocks return to the positions before the warp yarns are extruded, the parallel warp yarns are staggered in the transverse direction to form downward grooves and upward grooves, namely the downward grooves formed on the two adjacent warp yarns are adjacent to the upward grooves in the transverse section, the woof passes through from ascending recess and the decurrent recess of each warp that parallels in proper order for form the structure of weaving of longitude and latitude between woof and the warp, be equipped with between latitude feed module and the weaving module with the tangent line module that the woof cut off, the front portion of weaving the module is equipped with the rolling module that batches the fashioned metal mesh forward.

Preferably, the weft feeder module supplies two or more weft yarns moving in the transverse direction to the weaving module.

Preferably, a welding module is assembled between the weaving module and the winding module, and welding guns corresponding to the intersections of the warp yarns and the weft yarns are arrayed on the welding module.

Preferably, a pressing module is assembled between the welding module and the rolling module.

Preferably, the pressing module comprises two pressing rollers which are horizontally arranged in parallel up and down, and the welded metal mesh is pressed and passed through the two pressing rollers.

The invention has the beneficial effects that: when the metal net processing device is used, the warp feeding module feeds the weaving module, when parallel warps pass through the weaving module, an upper pressing block of the weaving module moves downwards, and the lower pressing block moves upwards, so that upward grooves and downward grooves which are arranged at intervals are formed in the warp direction, and grooves which are arranged at intervals can be formed in the cross section of the weaving module. The weft threads supplied by the weft feeder module can then pass through the grooves of the individual warp threads, so that the warp threads and the weft threads form a woven structure, completing the weaving of the metal mesh in the weaving module. The structure through last briquetting and briquetting down can form the groove structure that makes weft can pass through on the warp like this, makes simultaneously to close on the recess about opposite direction, just can form when weft passes like this and weave the structure for the silk thread firm of metal mesh is in the same place. The structure not only greatly simplifies the weaving process of the metal silk thread, but also can limit the weft thread by the groove structure of the warp thread, so that the fixation of the weft thread can be ensured even if the weft thread is not welded. The metal mesh processed by the device has a structure completely different from that of the traditional metal mesh, and even if the metal mesh is broken at one position, other parts cannot be influenced, so that the using effect is better.

Drawings

Fig. 1 is a schematic structural view in a plan view of a metal mesh processing apparatus.

Figure 2 is a schematic view of the structure of the weaving module in the direction of a-a in figure 1.

FIG. 3 is a schematic structural diagram of the weaving module B-B of FIG. 2 without the upper and lower pressing blocks for grooving the warp yarn.

FIG. 4 is a schematic structural diagram of the weaving module B-B in FIG. 2 when the upper pressing block and the lower pressing block press the groove on the warp.

FIG. 5 is a schematic structural diagram of the weaving module B-B in FIG. 2 when the upper pressing block and the lower pressing block press the warp threads and the weft threads to pass through after the groove is pressed.

Fig. 6 shows the structure of the expanded metal processed by the expanded metal processing apparatus.

Detailed Description

The invention is further illustrated by the following examples:

as shown in the embodiment of fig. 1 to 5, the metal mesh processing device comprises a weaving module 1, wherein the rear part of the weaving module 1 is provided with a warp feeding module 2, the side edge of the weaving module 1 is provided with a weft feeding module 3, the warp feeding module 2 supplies more than three parallel warp yarns 21 moving forwards to the weaving module 1, and the weft feeding module 3 supplies weft yarns 31 moving transversely to the weaving module 1. Both the warp threads 21 and the weft threads 31 are made of metal material, and in this embodiment, the metal threads as the weft threads 31 have a certain rigidity so that they can be directly threaded forward from the rear. In the specific design, the weaving module 1 comprises an upper block 11 and a lower block 12 which are assembled in parallel up and down, in this embodiment, the upper block 11 and the lower block 12 are both designed to be assembled up and down in a square shape, and a working interval is designed between the upper block 11 and the lower block 12; the size of the working interval can be adjusted by the up-and-down movement of the upper block 11 and the lower block 12, so that the warp and the formed metal mesh can pass through the working interval conveniently. An upper pressing block 13 which extends downwards from the lower surface of the upper block 11 is assembled in the upper block 11, a downward convex block is designed at the lower end of the upper pressing block 13, a lower forming groove 121 which corresponds to the convex block at the lower end of the upper pressing block 13 is designed at the upper part of the lower block 12, a lower pressing block 14 which extends upwards from the upper surface of the lower block 12 is assembled in the lower block 12, an upward convex block is designed at the upper end of the lower pressing block 14, and an upper forming groove 111 which corresponds to the upper end of the lower pressing block 14 is designed at the lower part of the upper block 11; the upper pressing blocks 13 and the lower pressing blocks 14 are assembled in an array in the top view direction, the upper pressing blocks 13 and the lower pressing blocks 14 are arranged at intervals in the top view direction, that is, the lower pressing blocks 14 are assembled between two adjacent upper pressing blocks 13, and the upper pressing blocks 13 are assembled between two adjacent lower pressing blocks 14. The warp yarn 21 extends into the working space between the upper block 11 and the lower block 12 and passes through the upper pressing block 13, the lower forming groove 121, the lower pressing block 14 and the upper forming groove 111. The upper pressing block 13 and the lower pressing block 14 are connected into a whole through a lifting structure respectively, and can move up and down relative to the upper pressing block and the lower pressing block respectively, so that the lower end part of the upper pressing block 13 and the upper end part of the lower pressing block 14 extend into the working interval. When the upper pressing block 13 moves downwards, the warp 21 is pressed in the lower forming groove 121 by the lug at the lower end of the upper pressing block 13, when the lower pressing block 14 moves upwards, the lug at the upper end of the lower pressing block 14 presses the warp 21 in the upper forming groove 111, when the upper pressing block 13 and the lower pressing block 14 return to the positions before the warp yarns 21 are pressed, the parallel warp yarns 21 are staggered in the transverse direction to form a downward groove and an upward groove, i.e. two adjacent warp threads 21 forming a downward groove adjacent to an upward groove in transverse cross-section, the weft 31 passes through the upward grooves and the downward grooves of the parallel warps 21 in sequence, so that a warp and weft knitting structure is formed between the weft 31 and the warps 21, between the weft feeder module 3 and the weaving module 1 is fitted a thread cutting module 4 for cutting the weft threads 31, the front part of the weaving module 1 is provided with a rolling module 5 for rolling the formed metal net forwards. And the winding module 5 pulls the warp yarn forwards while winding the formed metal mesh.

When the metal net processing device is used, the warp feeding module 2 feeds materials to the weaving module 1, when parallel warp yarns 21 pass through the weaving module 1, the upper pressing block 13 of the weaving module 1 moves downwards, and the lower pressing block 14 moves upwards. Not only as shown in fig. 3 and 4, so that upward grooves and downward grooves are formed at intervals in the direction of the warp yarn 21, but also as shown in fig. 2 in the cross section of the weaving module. The weft threads 31 supplied by the weft feeder module 3 can then pass through the grooves of the respective warp threads 21, so that the warp threads 21 and the weft threads 31 form a weaving structure, as shown in fig. 1 and 5, completing the weaving of the metal mesh in the weaving module 1. The woven wire mesh structure is shown in fig. 6. Thus, the groove structure allowing the weft 31 to pass through can be formed on the warp 21 by the structure of the upper pressing block 13 and the lower pressing block 14, and the upper direction and the lower direction of the adjacent grooves are opposite, so that a weaving structure can be formed when the weft 31 passes through, and the wires of the metal mesh are firmly bonded together. The structure not only greatly simplifies the weaving process of the metal silk thread, but also can limit the weft thread by the groove structure of the warp thread 21, so that the fixation of the weft thread 31 can be ensured even if the welding is not carried out. The metal mesh processed by the device has a structure completely different from that of the traditional metal mesh, and even if the metal mesh is broken at one position, other parts cannot be influenced, so that the using effect is better.

In a particular design, as shown in fig. 1 and 5, the weft feeder module 3 supplies two or more weft threads 31 moving in the transverse direction to the weaving module 1. This allows a faster supply of weft threads, when the weft feeder module 3 supplies a plurality of weft threads 31 simultaneously, if it is desired to form the same wire mesh warp and weft structure in the weaving module, an even number of weft threads 31 need to be supplied simultaneously.

In specific design, as shown in fig. 1, a welding module 6 is assembled between the weaving module 1 and the winding module 5, and a welding gun corresponding to a junction point of the warp filaments 21 and the weft filaments 31 is arrayed on the welding module 6. The device during operation, through rolling module 5 for warp 21 periodic indirect motion, at every turn rolling module 5's rolling volume just equals weave the metal mesh length of accomplishing in the module 1, simultaneously welding module 6 goes up the welder volume of array with weave in the module 1 briquetting 13, the briquetting 14 is the same in overlooking the ascending structure of arranging and quantity of orientation down, like this welding module 6 just can be with every turn weave the metal mesh that module 1 woven and accomplish and heat at the node and melt, make warp and weft fuse the welding as an organic whole. The metal net processed and molded by the device is firmer.

As shown in fig. 1, a pressing module 7 is mounted between the welding module 6 and the winding module 5. The pressing module can further press the warp yarns 21 and the weft yarns 31 of the welded and fused metal mesh together. In the specific design, the pressing module 7 comprises two pressing rollers which are horizontally parallel up and down, and the welded metal mesh is pressed between the two pressing rollers to pass through. When the device works specifically, metal wires with different thicknesses can be selected as the warp 21 and the weft 31 according to requirements, and the distance between the two pressing rollers of the pressing module 7 should be greater than the diameter of the thick wires in the warp 21 and the weft 31 and smaller than the sum of the diameters of the warp 21 and the weft 31, so that the welded warp 21 and weft 31 can be firmly pressed into a whole.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (5)

1. A weaving module of a metal mesh processing apparatus, the rear of the weaving module (1) being equipped with a warp feeding module (2), the sides of the weaving module (1) being equipped with a weft feeding module (3), the warp feeding module (2) supplying the weaving module (1) with three or more parallel warp threads (21) moving forward, the weft feeding module (3) supplying the weaving module (1) with weft threads (31) moving transversely; the method is characterized in that: the warp yarns (21) and the weft yarns (31) are made of metal materials, the weaving module (1) comprises an upper block (11) and a lower block (12) which are assembled in parallel, and a working interval is designed between the upper block (11) and the lower block (12); an upper pressing block (13) extending downwards out of the lower surface of the upper block (11) is assembled in the upper block (11), a downward convex block is designed at the lower end of the upper pressing block (13), a lower forming groove (121) corresponding to the convex block at the lower end of the upper pressing block (13) is designed at the upper part of the lower block (12), a lower pressing block (14) extending upwards out of the upper surface of the lower block (12) is assembled in the lower block (12), an upward convex block is designed at the upper end of the lower pressing block (14), and an upper forming groove (111) corresponding to the upper end of the lower pressing block (14) is designed at the lower part of the upper block (11); the upper pressing block (13) and the lower pressing block (14) are assembled in an array mode in the overlooking direction, the upper pressing block (13) and the lower pressing block (14) are arranged at intervals in the overlooking direction, the warp yarn (21) extends into a working interval between the upper block (11) and the lower block (12) and penetrates through the upper pressing block (13), the lower forming groove (121), the lower pressing block (14) and the upper forming groove (111), when the upper pressing block (13) moves downwards, the warp yarn (21) is pressed in the lower forming groove (121) by a bump at the lower end of the upper pressing block (13), when the lower pressing block (14) moves upwards, the warp yarn (21) is pressed in the upper forming groove (111) by a bump at the upper end of the lower pressing block (14), and when the upper pressing block (13) and the lower pressing block (14) return to the position before the warp yarn (21) is extruded, the parallel warp yarns (21) are staggered to form a downward groove and an upward groove in the transverse direction, the weft (31) passes through from the ascending recess and the decurrent recess of each warp (21) that parallel in proper order for form the structure of weaving of longitude and latitude between weft (31) and warp (21), be equipped with between latitude feed module (3) and the weaving module (1) with tangent line module (4) that weft (31) cut off, the front portion of weaving module (1) is equipped with rolling module (5) of batching forward with the fashioned metal mesh.

2. The weaving module of the metal mesh processing apparatus according to claim 1, characterized in that: the weft feeder module (3) supplies the weaving module (1) with two or more weft threads (31) that move in the transverse direction.

3. The weaving module of the metal mesh processing apparatus according to claim 1, characterized in that: weaving module (1) with be equipped with welding module (6) between rolling module (5), array has on welding module (6) with warp (21) and weft (31) handing-over point correspond welder.

4. The weaving module of the metal mesh processing apparatus according to claim 3, characterized in that: a pressing module (7) is assembled between the welding module (6) and the rolling module (5).

5. The weaving module of the metal mesh processing apparatus according to claim 4, characterized in that: the pressing module (7) comprises two pressing rollers which are horizontally parallel up and down, and the welded metal net is pressed and passed through between the two pressing rollers.

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