RU173663U1 - The unit for the formation and weaving of non-metallic reinforcing mesh to the production line for the manufacture of non-metallic reinforcing mesh - Google Patents

Abstract

The utility model relates to technological equipment for the manufacture of reinforcing mesh for reinforcing concrete products, masonry and brickwork, as well as for attaching arches of shafts. The task set in the utility model is the development of a knot for forming and weaving a mesh for double weaving of longitudinal and transverse roving threads when creating mesh cells. This problem is solved in that the production line for the manufacture of non-metallic reinforcing mesh includes creel for hair with roving reels, leveling device, annealing chamber, impregnating bath with tension device, squeezing device, mesh forming and weaving unit, polymerization chambers, cooling device, pulling device, assembly cutting. The mesh forming and weaving unit is made in the form of n gears with holes for passing two longitudinal roving threads and is installed after the squeezing device. The gears engaged with each other are mounted on the frame by means of shafts and are connected to an electric motor that drives them in a rotational motion. The number n of gears is equal to the number of cells in one row of the grid. 2 ill.

Description

The utility model relates to technological equipment for the manufacture of reinforcing mesh for reinforcing concrete products, masonry and brickwork, as well as for attaching arches of shafts.

A known method of manufacturing a non-metallic reinforcing lattice detachable fastening, for example by knitting annealed metal wire. The strapping is carried out manually or mechanized (see RF patent for the invention No. 2289648 according to class MKI E01C 7/00, 2004).

The disadvantage of this solution is the low productivity in the manufacture of gratings.

A known production line for the manufacture of non-metallic reinforcement, including creel with roving bobbins, leveling device, annealing chamber, impregnation bath with a tension device, squeezing device, molding unit, spiral winding device, polymerization chambers, pulling device, cutting and reeling units, in which the squeezing the device is made in the form of a plate with slots of elastic elastic material and is installed in front of the matrix, and the number of slots is equal to the number of channels of the matrix. To strengthen the mesh, a winding bundle is used (see RF patent for the invention No. 2287646 according to class MKI E04C 5/07, 2005).

The disadvantage is the complex design of the mesh forming unit.

Closest to the technical nature of the claimed utility model is a production line for the manufacture of reinforcing mesh from composite reinforcement, including creel with roving bobbins, leveling device, annealing chamber, impregnating bath with a tension device, squeezing device, molding unit, spiral winding device, polymerization chambers pulling device cutting unit. The mesh forming unit is located after the spiral winding devices and consists of a conveyor, a stacker of longitudinal and transverse mesh rods, a device for compressing intersections, the line comprising spiral winding devices, the number of which is not less than the number of longitudinal rods. In addition, the line contains a cooling device located in front of the pulling device (see patent for the invention of the Russian Federation No. 2394135, according to MKI E04C 5 / 07,2009).

The mesh forming unit provides a simple interweaving of the longitudinal and transverse roving threads when creating mesh cells.

The task set in the utility model is the development of a knot for forming and weaving a mesh for double weaving of longitudinal and transverse roving threads when creating mesh cells.

This problem is solved in that the production line for the manufacture of non-metallic reinforcing mesh includes creel for hair with roving reels, leveling device, annealing chamber, impregnating bath with tension device, squeezing device, mesh forming and weaving unit, polymerization chambers, cooling device, pulling device, assembly cutting. The mesh forming and weaving unit is made in the form of n gears with holes for passing two longitudinal roving threads and is installed after the squeezing device. The gears engaged with each other are mounted on the frame by means of shafts and are connected to an electric motor that drives them in a rotational motion. The number n of gears is equal to the number of cells in one row of the grid.

Distinctive features of the proposed utility model from the above-mentioned known similar line closest to it is that the mesh forming and weaving unit is made in the form of n gears with holes for passing two longitudinal roving threads and is installed after the squeezing device. The gears engaged with each other are mounted on the frame by means of shafts and are connected to an electric motor that drives them in a rotational motion. The number n of gears is equal to the number of cells in one row of the grid.

The technical result consists in the fact that the proposed design of the node forming and weaving the mesh allows you to perform a simple method of forming mesh cells. It is the combination of all the essential features that allows you to double weave the longitudinal and transverse roving threads when creating mesh cells, which allows you to get a mesh with more strength characteristics, which can be used to attach the shaft arches during the construction of tunnels and similar structures.

The proposed production line for manufacturing mesh from composite reinforcement is illustrated by the drawings shown in FIG. 1-2.

In FIG. 1 shows a general view of the production line, in FIG. Figure 2 shows the knot of formation and weaving of the mesh, a series of gears in operation, a pattern of twisting the longitudinal and transverse roving threads.

The technological line for the manufacture of non-metallic reinforcing mesh consists of sequentially installed creel with roving bobbins 1, leveling device 2, annealing chamber 3, impregnation bath 4 with tension device 5, squeezing device 6, mesh forming and weaving unit 7, lay-out 8 of transverse roving threads, a stacker 9 of transverse roving threads, a heating device 10, a cooling device 11, a pulling device 12 and a cutting mechanism 13. The mesh forming and weaving unit 7 is made in the form of n gears 14 with holes for passing two longitudinal threads 15 of the roving and is installed after the squeezing device 6. The gears 14 engaged with each other are mounted on the frame 16 by means of shafts 17 and connected to an electric motor 18, which rotates them. The number n of gears 14 is equal to the number of cells in one row of the grid. Stacker 9 is designed for transverse threads 19 of the roving.

The technological line for the manufacture of non-metallic reinforcing mesh works as follows. Roving from glass, basalt, carbon and other fibers from bobbins 1 (Fig. 1) passes through the rollers of the leveling device 2, which separates the roving sheet into separate bundles, an annealing chamber 3, which removes moisture at a temperature of 100 ° C. Then the roving bundles enter the impregnation bath 4, filled with a polymer binder with a temperature of 40-60 ° C, passes through a tensioner 5 and squeezing device 6, in which excess binder is removed from the fibers.

The longitudinal threads of the roving 15 pass through the holes in the gears 14. The transverse thread of the roving 19 is laid between the longitudinal threads 15 of the roving. The electric motor 18 gears are rotationally driven, the longitudinal threads 15 of the roving are twisted. Then, the pulling device 12 pulls through the mesh web. And then the gears 14 are again rotationally driven, weaving the transverse roving thread 19 between two longitudinal roving threads 15, thereby forming mesh cells.

The heating device 10 is located after the stacker 9 .. As heating elements, heating elements, infrared emitters and other heaters can be used. Next, the polymerized mesh passes through a cooling bath 11, a pulling device 12 and a cutting mechanism 13.

The proposed production line allows to obtain in an automated manner a reinforcing mesh made of composite reinforcement, which has good physical and mechanical properties and a high degree of adhesion to concrete.

Claims (1)

A unit for forming and weaving a non-metallic reinforcing mesh to the production line for manufacturing a non-metallic reinforcing mesh, installed after the squeezing device and made in the form of a stacker of transverse roving threads and in the form of n gears with holes for passing two longitudinal roving threads, the gears meshing with each other another, mounted on the frame by means of shafts and connected to an electric motor that rotates them, while the number n of gears is equal to the number of cells in Mr. row of the grid.

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