KR20110078673A - It pruduct and method for manufacturing resin coated wire-screening for sorting aggregate - Google Patents

Abstract

PURPOSE: A prefabricated screen wire net manufacturing method for aggregate sorting and a product thereof are provided to improve the aggregate sorting efficiency by increasing the elasticity of steel wire through synthetic resin ejected in the outer side of the steel wire. CONSTITUTION: The prefabricated screen wire net manufacturing method for aggregate sorting iis as follows. The wire rod is iron material and is cut in the fixed length. The cut wire rod(2a) is bent by using the folding machine. The steel wire preforms injection molding the urethane layer (2b) in the surface of the bent wire with the synthetic material. The frame(3) performs injection molding in the both sides of lines(2) with the synthetic material.

Description

Method for manufacturing prefabricated screen wire mesh for aggregate selection and its products {IT PRUDUCT AND METHOD FOR MANUFACTURING RESIN COATED WIRE-SCREENING FOR SORTING AGGREGATE}

The present invention relates to screen screen for screening aggregate, more specifically screen screen screen, as well as greatly increasing the life of the vibrating screen used screen screen screen, and also increase the elasticity of the wire through the guide formed on the frame aggregate aggregation efficiency The present invention relates to a method for manufacturing prefabricated screen wire mesh for screening aggregates, and a product thereof.

Mortar, which is poured and cured in order to be constructed as a concrete building, is formed by mixing cement, sand, and aggregate with water. Particularly, in the case of aggregate, gravel is mainly used as an essential factor to determine the rigidity of the concrete building.

Such aggregates are screened for particle size to suit their purpose, depending on the building. Such sorting is usually done by vibrating the wire mesh to move the pile of aggregates placed on the wire mesh to select the appropriate size aggregate. .

On the other hand, since the size and output of the selected aggregate is determined by the wire mesh, research efforts to improve the wire mesh into various forms in order to increase the selective output of the aggregate are in progress.

1 is an example of a wire mesh produced and manufactured as described above, and the "applicant screen screen for screening aggregate" of the domestic patent registration No. 0497499 registered and filed by the applicant of the present application, briefly looked at the waveform inside the frame 15 A plurality of steel wires 20 formed in a wave shape, that is, in a wave shape, are arranged in parallel and closely arranged at regular intervals to form a rhombus sorting hole 25, and the steel wires 20 are prevented from sagging due to the load of aggregate. The joints 30 are formed at both ends of the steel wire 20 so as to be firmly bonded to the frame 15.

According to the above configuration, in the case of screening the aggregates such as gravel or crushed crushed stone on the screen wire mesh, the aggregates pass through the screening hole 25 by the vibration and vibration of the screen wire mesh, thereby to select the aggregate by a predetermined size It becomes possible.

However, the above-described invention of the present invention has caused a problem that the welded joint 30 falls due to repeated shaking and impact despite the above advantages. That is, the screen wire mesh 10 is repeated for a long time (stress) such as the impact and trembling caused by the aggregate in the process of screening the aggregate, the fatigue such as impact and tremor is the steel wire 20 of the welded joint 30 ) As the main factor to drop.

Therefore, the central portion of the screen wire mesh 10 is severely sag due to the weight of the steel wire 20 and the shaking phenomenon, and also the difference between the central portion of the screen wire mesh 10 and the vibration of the outer portion is much different. There is a serious problem that the sorting efficiency is lowered, such as not able to select the aggregate of a certain size.

Figure 2 is for "aggregate screening screen for screening aggregate" of the National Registered Utility Model Publication No. 0312568 registered and filed by the applicant in advance to solve the problems as described above, forming a joint in a portion of the steel wires 70 However, the joining reinforcement 80 is formed in a portion where the joining portion is formed to prevent the steel wires 70 of the joining portion from falling due to the impact and fatigue generated during the sorting operation.

That is, since the plurality of steel wires 70 are integrally joined through the joint reinforcing bar 80 formed of urethane, even if long-term fatigue occurs in the steel wires 70 due to the aggregate sorting operation, the steel wires 70 are firmly bonded. It can be maintained.

However, the screen wire mesh described above is suitable for a large-size integrated wire mesh, and there is a problem in that it is not suitable to form a joint reinforcing bar in a prefabricated wire mesh type that uses a combination of several wire meshes instead of an integrated one.

That is, in the case of prefabricated wire mesh, as many small wire meshes are used in the longitudinal direction or the width direction as necessary, if any part of the assembled wire mesh is damaged, only the damaged wire mesh part should be separated and replaced. Therefore, when the joint reinforcing bar is formed on the steel wires by tying several steel wires together, there is a closed end that is not easy to replace the wire mesh.

Figure 3 is a "screen wire mesh with a reinforcing bar is formed" of the domestic published utility model publication No. 2009-0002232 invented by the present applicant to solve the problems as described above, aggregates such as gravel or crushed stone Short steel wires 120 formed in a wave form (wave shape) between both sides of the frame 110 so as to be sorted, and the reinforcing rod 140 at the bottom of the steel wire 120 to prevent sagging of the steel wires 120 Install.

That is, since the frame is formed on both sides of the screen wire mesh, and can be used as a prefabricated by connecting with other screen wire mesh through the frame, if the screen wire mesh is damaged and needs to be replaced, only the damaged screen wire mesh can be easily replaced. It is.

However, in the case of the screen wire mesh described above, since the steel wire is formed of steel, the steel wire is easily corroded, which greatly shortens the life of the screen wire mesh, and the weight of the steel wire is relatively heavy to increase the overall weight of the screen wire mesh. As a result, an excessive force is applied to the vibrating separator equipped with the screen wire mesh, thereby reducing the life of the vibrating separator.

Moreover, the aggregates placed on the steel wires are sorted by the vibration of the steel wires, and due to the characteristics of the steel wires made of steel, the elasticity is greatly reduced, so that the aggregates are not easily pulled out between the steel wires or the aggregates are not smoothly made. There was also a problem that the screening efficiency is greatly reduced.

In addition, the aggregates are raised and moved on the upper surface of both frames by the vibration of the vibrating separator as well as the upper surfaces of the aggregates during the aggregate sorting operation. The upper surface of the frame is formed flat so that the aggregate moving along the frame is crazy. There was also a problem that could not be achieved.

The present invention has been made in order to solve the conventional problems as described above, the aggregate screening to greatly increase the life of the screen separator is used by the injection molding of a synthetic resin outside the steel wire, the screen separator is used. The present invention provides a method for manufacturing prefabricated screen wire mesh and a product thereof.

It is another object of the present invention to provide a method for manufacturing prefabricated screen wire mesh for screening aggregates and their products to increase the screening efficiency of aggregates by increasing the elasticity of the wires through the synthetic resin injected outside the steel wires.

It is still another object of the present invention to provide a method for manufacturing prefabricated screen wire mesh for screening aggregates and its products, which enables screening of aggregates supplied to the screen wire mesh without omission.

Screen wire mesh manufacturing method of the present invention for achieving the above object, a method of manufacturing a prefabricated screen wire mesh by installing the steel wires formed in a wave (wave) between the two frames so as to select aggregates such as gravel or crushed stone In the step of: cutting the wire of iron material to a predetermined length; Bending the cut wire into waveforms using a bending machine; Manufacturing a steel wire by injection molding a urethane layer with a synthetic resin on the surface of the bent wire; Injection molding the frame with a synthetic resin material on both sides of the steel wires.

Here, the injection molding is performed to project the guide on the upper surface of the frame together with the injection of the frame.

Then, the frame is injection molded by sandwiching a reinforcing bar between the two frames.

On the other hand, the structure of the screen wire mesh of the present invention, in the prefabricated screen wire mesh provided with steel wires formed in the form of a wave between the two frames so that the aggregates such as gravel or crushed stone, and a reinforcing rod is provided below the steel wire , The steel wire is formed by injection molding a urethane layer with a synthetic resin on the surface of the bent iron wire.

Here, the guide is protruded to be inclined upwardly outward in the center of the upper surface of both frames.

The present invention through the above problem solving means, by injecting a frame on both ends of the steel wires injected with a urethane layer on the surface to produce a screen wire mesh, there is an effect that can be more simply and conveniently manufactured screen wire mesh, The urethane layer on the surface prevents corrosion of the steel wire, which can significantly increase the life of the screen wire mesh.

Furthermore, since the resin material is injected onto the steel wire surface, the weight of the steel wire is reduced by the thickness of the synthetic resin material, thereby reducing the load of the vibration screening device, and thus, the life of the screening device can be greatly increased, and the urethane layer is made of soft material. Since it is molded into, the aggregate can be more smoothly passed through the screening hole has the effect of increasing the aggregate screening efficiency.

In addition, since the guide is formed on both sides of the upper frame, aggregates moving along the upper surface of the guide during the sorting operation can be dropped on the steel wire, thereby further increasing the sorting efficiency of the aggregates.

When described in detail with reference to the accompanying drawings a preferred embodiment of the present invention.

4 to 8 illustrate the prefabricated screen wire mesh for screening aggregates of the present invention, and includes a steel wire 2, a frame 3, and reinforcing bars 4a and 4b.

Specifically, first, the steel wire (2) is formed in a substantially wave shape, that is, a wave shape, and a plurality of the sorting holes 75 having a rhombic shape close to a square are formed by a plurality of closely arranged inside the two frames (3). do.

The steel wire 2 is composed of a wire rod 2a made of iron so as to have abrasion resistance at the inner center thereof, and is bent to form a corrugation as described above in the form of a round bar. Then, the urethane layer 2b of the synthetic resin material is injection molded to the surface of the bent wire 2a to form a steel wire 2.

At this time, both ends of the steel wire (2) is injection-molded to be inserted into the both sides of the frame (3), and the urethane layer (2b) is not injected to a part of the end of the steel wire (2) to increase the bonding force with the frame (3). It is preferable not to. The reason for coating the urethane layer 2b on the steel wire 2 is to improve the elasticity of the steel wire 2 due to the excellent elasticity of the urethane material.

In addition, the frame 3 is injection molded at both ends of the individual steel wires 2 and the reinforcing bars 4a and 4b to be described later, and manufactured using a hard synthetic resin material. The frame 3 is formed in the center of the upper surface of the guide (3a) formed in a substantially triangular shape, the guide (3a) is formed to be inclined upward toward the outside.

That is, when aggregate moving along the frame 3 is in contact with the guide 3a, the guide 3a is formed to be inclined toward the steel wire 2 of the screen wire mesh 1 so that the aggregate falls on the screen wire mesh 1. Will be. Here, the shape of the guide (3a) is formed in a triangular shape, but is not limited to such a shape, it will be fine if the guide (3a) is formed to be inclined upward toward the outside.

The reinforcing bars 4a and 4b are installed at the lower end of the steel wire 2 to prevent the steel wire 2 from sagging. A straight reinforcing bar 4a or a wavy reinforcing bar 4b may be installed. .

The reinforcing bar 4 is inserted between the two frames 3 during injection molding of the frame 3. First, the linear reinforcing bar 4a is formed in the shape of a round bar as illustrated in FIGS. 5A, 6A and 7A. It is to be installed to be spaced apart approximately 5 ~ 6mm above the steel wires (2), provided with a plurality of spaced at equal intervals.

In addition, as shown in Figures 5b, 6b, 7b of the corrugated reinforcement (4b) is formed in the same waveform shape as the steel wire (2), it is installed to be connected to the lower end of the steel wire (2), which is also equally spaced It is provided with a plurality in the spaced apart state.

Referring to the operation and effects of the present invention configured as described above in detail.

In order to manufacture the screen wire mesh 1 of the present invention, first, the wire rod 2a made of iron is cut by a predetermined length, and the cut wire rod 2a is bent and formed into a wave shape using a bending machine. Then, the steel wires 2 are manufactured by injection molding the urethane layer 2b of the synthetic resin material on the surface of the bent wire 2a using the injection machine.

Subsequently, injection molding of the frame 3 is made of synthetic resin on both sides of the steel wires 2, and when the frame 3 is injected, both frames are inserted with reinforcing bars 4a and 4b together with the steel wires 2. The reinforcing rods 4a and 4b are provided between the three, and the injection molding of the guide 3a on the upper surface of the frame 3 together with the injection of the frame 3 protrudes to form the screen wire mesh 1 of the present invention. It can be prepared.

Then, by assembling the screen wire mesh (1) and the other screen wire mesh (1) manufactured as described above by the desired size in the longitudinal direction or the width direction using the connecting frame (3), the screen screen mesh (1) assembled by vibration screening It can be used for.

As described above, the present invention can be used to assemble the screen screen mesh (1) with each other and vibration screening, when the screen wire mesh 1 is damaged as shown in Figure 8 can be easily replaced by separating only the damaged screen wire mesh (1) Also, by injecting a urethane layer (2b) on the surface of the steel wires (2), and by injecting the frame (3) on both ends of the steel wires (2) to produce a screen wire mesh (1), further screen wire mesh (1) It is possible to manufacture simply and conveniently.

In particular, the present invention injection molding the synthetic resin material to have a predetermined thickness on the surface of the steel wires (2) to form a screening hole, to prevent corrosion of the steel wire (2) to extend the life of the screen wire mesh (1) 1.5 to 2 times or more It can be greatly increased.

Furthermore, since the synthetic resin material is injected onto the surface of the steel wire 2 as described above, the weight of the steel wire 2 is reduced by the injection thickness of the synthetic resin material, thereby greatly reducing the load of the vibrating screening device on which the screen wire mesh 1 is installed. Can also significantly increase the lifespan.

In addition, since the urethane layer 2b of the synthetic resin material injected into the steel wire 2 is formed of a soft material having a certain elasticity, the aggregates can be more smoothly passed through the sorting hole, thereby increasing the aggregate sorting efficiency.

And, since the guide (3a) is formed on the upper surface of the both sides frame 3, the aggregates moving along the upper surface of the guide (3a) during the sorting operation can be dropped on the steel wire (2), it is possible to sort the aggregates without missing .

On the other hand, the present invention has been described in detail only with respect to the specific examples described above it will be apparent to those skilled in the art that various modifications and variations are possible within the technical scope of the present invention, it is natural that such variations and modifications belong to the appended claims. .

1 is a perspective view of a screen wire mesh registered first application by the applicant,

2 is a perspective view of another screen wire mesh registered in advance by the applicant;

3 is a bottom perspective view of another screen wire mesh invented and filed by the applicant;

4 is a perspective view of a screen wire mesh according to the present invention,

5a, 5b is a bottom perspective view of a screen wire mesh having different reinforcement bars according to the present invention,

Figure 6a, 6b is a side cross-sectional view of the screen wire mesh having different reinforcement according to the present invention,

7a, 7b is a front sectional view of the screen wire mesh having different reinforcing bars according to the present invention,

8 is a perspective view showing a coupling and separation state of the screen wire mesh and other screen wire mesh according to the present invention.

* Description of the major symbols in the drawings *

1: screen wire mesh 2: steel wire

2a: wire rod 2b: urethane layer

3: frame 3a: guide

4a, 4b: reinforcement

Claims (5)

In the method of manufacturing a prefabricated screen wire mesh by installing steel wires formed in a wave form between the two frames so that the aggregate such as gravel or crushed stone, Cutting the wire rod 2a of iron material to a predetermined length; Bending the cut wire (2a) into a waveform using a bending machine; Manufacturing a steel wire (2) by injection molding the urethane layer (2b) with a synthetic resin on the surface of the bent wire (2a); Method for producing a prefabricated screen wire mesh for screening aggregates, characterized in that the steel wire (2) on the sides of the injection molding the frame (3) with a synthetic resin material. The method according to claim 1, wherein the injection molding of the guide (3a) on the upper surface of the frame (3) together with the injection of the frame (3). The method of claim 1, wherein the frame (3) is injection molded by sandwiching a reinforcing rod (4a) (4b) between the two frames (3). In the prefabricated screen wire mesh with corrugated steel wires formed between the two frames to screen the aggregates such as gravel or crushed stone, and a reinforcing bar is installed below the steel wire, A prefabricated screen wire screen for aggregate screening, characterized in that the steel wire (2) is formed by injection molding a urethane layer (2b) with a synthetic resin on the surface of a bent iron wire (2a). 5. The prefabricated screen wire mesh for screening aggregate according to claim 4, wherein the guides (3a) are protruded to be inclined upwardly outward in the center of the upper surfaces of the both side frames (3).

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