KR101989845B1 - Install structure of water dam in cooling water tank for extruded cable - Google Patents

Abstract

The present invention relates to a water film installation structure of an extruded cable cooling water tank, and more particularly, to a water tank installation structure of an extruded cable cooling water tank in which an electric wire cable coated with an insulation layer through an extruder is moved along a longitudinal direction, And a water tank installed at both ends of the tank at a predetermined height to determine the water level of the cooling water contained in the cooling water tank, the water tank installation structure of the extruded cable cooling water tank for cooling the extruded cable, Wherein the metal plate is spaced apart by an interval corresponding to the thickness of the sliding rail, and a receiving space is formed on the inner side, and the metal plates are inserted into the sliding rail along both the vertical and longitudinal directions on both sides of the sliding rail. A sliding groove is formed, A case having a predetermined elasticity and being inserted into the receiving space of the case and having a predetermined length downwardly formed on the upper surface thereof so as to have a size corresponding to the outer diameter of the cable, The outer surface of the wire cable is brought into contact with the guide hole exposed through the cut-out portion of the case, when the guide body is inserted into the accommodation space.
According to the present invention, the sliding rails are provided on both sides along the longitudinal direction of the cooling water tank, and the sliding grooves formed on the water film are coupled to the sliding rails to provide a water film inside the cooling water tank. It has a very convenient effect.
In addition, it is possible to adjust the height accurately by using the upper, lower case and height adjustment case to set the water level differently for each zone requiring a specific cooling method in the cooling water tank, thereby maximizing the cooling efficiency even in a short section of the cooling water tank It is effective.

Description

{Install structure of water tank for extruded cable}

The present invention relates to a water film installation structure of an extruded cable cooling water tank. More particularly, the present invention relates to a water tank installation structure of an extruded cable cooling water tank, The present invention relates to a water film installation structure of an extruded cable cooling water tank in which a height of a water tray is set differently for each specific section in a bath to maximize cooling efficiency.

Generally, the cooling water tank of the extruded cable is formed by cooling the insulation layer by making the insulation layer coated on the wire material come into contact with the cooling water through the extruder, and is formed in the rear end of the extruder along the longitudinal direction to have a certain length according to the standard of the insulation layer .

In this cooling water tank, a cooling water supply valve for supplying cooling water from the lower end to the inside is provided, cooling water is supplied from the lower part of the cooling water tank, and a water film is installed on both sides of the cooling water tank, so that the cooling water overflows.

1 is a view showing the structure of a water film installed in a conventional cooling water tank.

Referring to the drawings, a water tray installed in a conventional cooling water tank is formed by inserting two U-shaped metal plates 30 at both ends of a cooling water tank 100 into the inside of a cooling water tank 100 at regular intervals to insert the sponge 40 A sponge 40 having an opening cut in a predetermined size corresponding to the outer diameter of the wire cable is inserted between the two metal plates 30 using a mechanism such as scissors so that the wire cable can pass therethrough. The surface of the insulating layer is brought into contact with the cut surface of the sponge 40 and is moved along the longitudinal direction of the cooling water tank 100 so that cooling is performed.

In order to immerse the electric cable in the cooling water supplied from the bottom surface of the cooling water tank 100, the water film installed on both sides of the cooling water tank 100 should be blocked so that water does not flow down to a predetermined height, And the upper surface of the sponge 40 is cut open.

Thus, the extra sponge or cloth left over by the operator is sandwiched between the upper surface of the wire cable and the opening portion of the sponge 40, so that the height of the water tray is roughly set as a temporary measure, And in some cases, the portion blocked by the temporary device is blown by the pressure, so that the water level control is not easy.

This is because it is not necessary to accurately adjust the water level for immersing the cooling water tank 100 in order to cool the surface of the insulating layer in the related art, and the operator can arbitrarily set the height of the water tray according to various conditions of the cable.

However, in recent years, studies on a polypropylene (PP) material having an isotactic structure that can replace polyethylene (PE), which has been conventionally used as an insulating layer, are underway, and the use of such a polypropylene However, polypropylene (PP) having an isotactic structure is extruded at an extrusion temperature of about 220 ° C. at a temperature higher than that of conventional polyethylene (PE) And it is difficult to quench after extrusion due to the characteristics of the material, thereby causing a problem of slow cooling at a low speed.

Therefore, when extruding a wire cable using such a polypropylene (PP), a cooling process becomes a very important problem.

In order to increase the cooling efficiency, there are a dropping type cooling system in which water droplets are dropped onto the surface of the insulating layer, a half-injection type in which the insulating layer is partially immersed in the cooling water and the cooling water is injected at a predetermined pressure, In order to apply various cooling methods such as immersion in which the entire insulation layer is immersed in the cooling water, it is necessary to be able to precisely control the water level of the cooling water tank, but such a precise height control as described above can not be performed with the conventional watertight structure.

Therefore, by improving the water film structure of the conventional cooling water tank, it is possible to control the water level in the cooling water tank precisely according to the standard of the cable, and when polypropylene (PP) is used as the insulating layer, There is an increasing demand for a watertight installation structure of an extruded cable cooling water tank that allows various cooling methods to be applied along the direction of the watertight installation.

Korean Patent No. 1531570

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a cooling water tank, So that the water film can be easily installed in the cooling water tank by the sliding fastening method.

According to an aspect of the present invention, there is provided a cooling water system including a cooling water tank in which an electric wire cable coated with an insulation layer through an extruder moves along a longitudinal direction and is in contact with cooling water on a surface of the electric wire cable, And the water level of the cooling water accommodated in the cooling water tank is determined so as to cool the extruded cable. In the waterwall installation structure of the extruded cable cooling water tank, the both side walls facing the longitudinal direction of the cooling water tank are vertically Wherein the metal plate is spaced apart by an interval corresponding to the thickness of the sliding rail and a receiving space is formed on the inner side of the sliding rail and a sliding groove is formed on both sides of the sliding rail to be inserted into the sliding rail along the vertical direction, Is formed on the upper surface of the metal plate A guide body having a predetermined elasticity and inserted into the receiving space of the case, the guide body being cut downward at a predetermined length so that a guide hole having a size corresponding to the outer diameter of the wire cable is formed on the upper surface, The outer surface of the wire cable is brought into contact with the guide hole exposed through the cut-out portion of the case, when the guide body is inserted into the accommodation space.

The case includes a first and a second metal plate formed at an upper end thereof with incisions cut downward at a predetermined curvature and spaced a predetermined distance from both front and rear sides of the case, A sliding surface which is spaced apart from both side end surfaces of the first and second metal plates so as to form a sliding groove on both sides of the first and second metal plates and which is installed in the vertical direction, And a seating plate spaced upward from a lower end surface of the second metal plate and bent inward from a lower end of the sliding surface to form a seating surface on which the lower end of the guide body is seated.

In addition, the case may include a lower case provided with a lower end portion of the first and second metal plates facing the lower surface of the cooling water tank, and the wire cable is received in the cut-off portion, And an upper case coupled to an upper surface of the lower case, wherein a lower end of the second metal plate is disposed above the cooling water tank, wherein a curved surface center of the cut portion formed in the lower case is located below the upper surface of the lower case So as to be spaced apart from each other by a predetermined distance.

And a height adjustment case formed on both sides of the bottom surface of the cooling water tank, the height adjustment case having a sliding groove formed in the sliding rail to be inserted into the sliding rail, So that the height of the water film can be adjusted.

Wherein the height adjusting case is formed to have a width corresponding to the interval between the sliding rails provided on both side walls of the cooling water tank and formed at a predetermined height upward and a width larger than the width of the height adjusting body, And third and fourth metal plates detachably coupled to the front and rear surfaces of the height adjusting body and having sliding grooves formed at both ends of the height adjusting body.

According to the present invention, the sliding rails are provided on both sides along the longitudinal direction of the cooling water tank, and the sliding grooves formed on the water film are coupled to the sliding rails to provide a water film inside the cooling water tank. It has a very convenient effect.

In addition, it is possible to adjust the height accurately by using the upper, lower case and height adjustment case to set the water level differently for each zone requiring a specific cooling method in the cooling water tank, thereby maximizing the cooling efficiency even in a short section of the cooling water tank It is effective.

1 is a view showing the structure of a water film installed in a conventional cooling water tank.
2 is a perspective view showing a state in which a water film according to the present invention is installed in an extruded cable cooling water tank.
3 is a front view showing a state where a water film according to the present invention is installed in an extruded cable cooling water tank.
4 is a view showing a decomposition state of a water film according to the present invention installed in an extruded cable cooling water tank.
FIG. 5 is a side cross-sectional view of a drip-type cooling water tank using a water film according to the present invention.
FIG. 6 is a detailed view of a portion A in FIG.
FIG. 7 is a detailed view of a portion B in FIG. 5; FIG.
8 is a side cross-sectional view of a half-injection-type cooling water tank using a water film according to the present invention.
9 is a side cross-sectional view of the half-injection type cooling water tank provided at the rear end of FIG.
FIG. 10 is a detailed view of a portion C in FIG. 9; FIG.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a perspective view showing a state in which a water film according to the present invention is installed in an extruded cable cooling water tank, FIG. 3 is a front view showing a state in which a water film according to the present invention is installed in an extruded cable cooling water tank, Fig. 5 is a view showing the decomposition state of the water film according to the present invention.

Referring to the drawings, an extruded cable cooling water tank according to the present invention includes guide frames 110 having a U-shaped cross-section in a vertical direction on both side walls corresponding to the longitudinal direction of a cooling water tank 100 along a longitudinal direction of a cooling water tank 100 The sliding rail 120 is fastened to the guide frame 110 in the vertical direction by bolts in a section where a water tank 200 having a specific height is required and an appropriate cooling method is determined according to the specification or material of the electric cable, The water film 200 according to the present invention is inserted into the rail 120 so that the cooling water can be maintained at a certain water level by the water film 200. In addition, the sliding rail 120 is made of a plastic material having a certain elasticity, not a metal material, so that the sliding movement of the water tank 200 is facilitated.

The water dam 200 according to the present invention includes a case 210 in which both ends are inserted into the sliding rails 120 on both sides and a guide body 220 installed inside the case 210.

In the case 210, two metal plates are spaced apart from each other by a predetermined distance, and a receiving space for inserting the guide body 220 is formed. On both sides of the case 210, a sliding groove 214 inserted into the sliding rail 120 is provided. And a cutout portion 215 for receiving the wire cable is provided at the center portion.

4, a cutout 215 is formed to be cut at a distance corresponding to the thickness of the sliding rail 120 and curved at a predetermined curvature from the upper end to the lower end of the case 210 The first and second metal plates 211 and 212 and the seating surface 213b are coupled to inner surfaces of the first and second metal plates 211 and 212 facing each other to receive the guide body 220 And a mounting plate 213 for mounting the mounting plate.

The seating plate 213 is bent in a curved shape so that the sliding grooves 214 are formed on both side surfaces of the first and second metal plates 211 and 212. [ A sliding surface 213a spaced apart from the lower surface of the sliding surface 213a by a predetermined distance and spaced upward from the lower ends of the first and second metal plates 211 and 212, Thereby forming the seating surface 213b. The seating plate 213 includes a guide body 220 installed on both sides of the first and second metal plates 211 and 212 so as to face each other and inserted into the receiving space of the first and second metal plates 211 and 212, So that the lower end of the plate 213 is seated on the seating surface 213b of the seating plate 213.

The guide body 220 is formed of a soft elastic material such as a sponge and is cut downward at a predetermined length so as to form a guide hole 221 having a size corresponding to the outer diameter of the wire cable on the upper surface of the guide body 220 use.

When the guide body 220 having the guide hole 221 cut is inserted into the housing space of the case 210, the guide hole 221 is exposed to the outside through the cutout 215 of the case 210 So that the outer surface of the wire cable is brought into contact with the guide hole 221.

The case 210 includes a lower case 210a disposed on the lower side of the cooling water tank 100 and an upper case 210b coupled to an upper portion of the lower case 210a. The cable is positioned and the cutout 215 of the lower case 210a is covered with the upper case 210b so that the entire surface of the cable is cooled down in a state in which it is completely immersed in the cooling water.

The lower case 210a is provided with a cutout 215 formed on the upper side of the lower case 210a so that the lower ends of the first and second metal plates 211 and 212 face the lower surface of the cooling water tank 100, And the upper case 210b is installed on the upper surface of the lower case 210a such that the lower ends of the first and second metal plates 211 and 212 are directed to the upper side of the cooling water tank 100, The cutout portion 215 of the upper case 210b faces the cutout 215 of the lower case 210a.

Here, the cut-out portion 215 formed in a curved surface in the lower case 210a is not formed on the upper surface of the lower case 210a, but the cut-out portion 215 is formed in a U- The center of the wire cable inserted into the portion 215 is set to be lower center of gravity on the lower side of the lower case 210a. In addition, a cutout 215 formed in the upper case 210b has a cut surface formed in a semicircular shape with a curved surface center of the cutout 215 on the upper surface of the lower case 210a.

The guide body 220 inserted into the lower case 210a is cut downward to form a guide hole 221 in which the wire cable is received and inserted into the guide body 220 inserted into the upper case 210b Is provided on one side of the upper surface of the upper case 210b without separately cutting the guide hole 221 so that the electric cable is positioned on the lower side of the lower case 210a to facilitate immersion by the cooling water .

When the position of the other wire cable is to be immersed in the upper part of the cooling water tank 100, the guide body 220 inserted into the upper case 210b may be cut and used.

In addition, a height control case 300 installed at a lower portion of the lower case 210a and capable of variously adjusting the height of the water film 200 may be further provided, so that precise control is possible.

The height adjustment case 300 includes a height adjustment body 310 and third and fourth metal plates 321 and 322 provided on the front and rear surfaces of the height adjustment body 310.

The height adjusting body 310 is formed of a resin material such as EV to have a width corresponding to the interval formed by the sliding rails 120 provided on both side wall surfaces of the cooling water tank 100 and a thickness corresponding to the thickness of the sliding rail 120 And is formed at a predetermined height upward.

The third and fourth metal plates 321 and 322 are detachably coupled to the front and rear surfaces of the height adjusting body 310 with a width larger than the width of the height adjusting body 310, The sliding grooves 323 are formed by the third and fourth metal plates 321,

The height adjustment case 300 is inserted into the sliding rail 120 and installed first on the bottom surface of the cooling water tank 100 and then inserted into the sliding rail 120 to connect the lower case 210a to the lower case 210a. The height of the water tray 200 including the lower case 210a or the upper case 210b is adjusted by the height adjusting case 300 so that the seating surface 213b is seated on the upper surface of the height adjusting body 310 do.

The height adjustment case 300 is formed to have a predetermined height according to the arrangement shape of the wire cable disposed in the cooling water tank 100. The height adjustment case 300 has a height adjustment body having various heights so as to adaptively cope with the standard of the wire cable, And the height adjusting body 310 having a predetermined height may be bolted to the third and fourth metal plates 321 and 322 to be used.

Hereinafter, a method for implementing various cooling methods using the water film according to the present invention will be described in detail.

When polypropylene (PP) having an isotactic structure is used as an insulating layer coating of a wire cable, the cooling efficiency must be higher than that of the prior art, and polypropylene (PP) The chemical crosslinking heat treatment is not required, so that the insulating layer is covered with the extruder and the cooling process can be performed immediately.

In order to increase the cooling efficiency and increase the production rate of the cable, the wire rod is arranged in a horizontal line, and the wire rod coated with the insulating layer through the extruder by the suspension curve control has a maximum interval of contact with the bottom surface of the cooling water tank 100 So that the wire cable can be continuously produced at a high speed.

The shape of the wire cable disposed in the cooling water tank 100 is set in advance so that the water tank 200 is used for each section of the cooling water tank 100 using the water tank 200 according to the present invention. So that the cooling efficiency is maximized by different cooling methods.

FIG. 5 is a side sectional view showing a side sectional structure of a drip-type cooling water tank using a water damper according to the present invention. FIG. 6 is a detailed view of a portion A of FIG. 5, and FIG. 7 is a detail view of a portion B of FIG.

Referring to the drawings, a dropping cooling water tank 100 is provided at the rear end of an extruder and cools the surface of the insulating layer heated to a high temperature with hot water having a temperature equal to or higher than a predetermined temperature. The longitudinal direction of the cooling water tank 100 is defined as A plurality of droplets of cooling water are dropped onto the surface of the insulating layer by a plurality of dropping means 10 provided. The dropping type cooling water tank 100 does not immerse the cooling water in the cooling water immediately when the electric cable is drawn out so that only the lower case 210a is installed at the front end of the cooling water tank 100 and the guide body 220 inserted into the lower case 210a ) Are not cut separately.

Since the surface of the insulating layer is cooled to some extent by the dropping means 10 to some extent at the rear end of the dropping type cooling water tank 100, The height adjustment case 300 is first inserted and the lower case 210a having the guide body 220 cut thereon is inserted thereinto so that the surface of the insulation layer of the cable is inserted into the guide body 220). That is, the wire cable is partially immersed in the cooling water at the downstream end of the dropping cooling water tank

FIG. 8 is a side cross-sectional view of a half-injection-type cooling water tank using a water jacket according to the present invention, FIG. 9 is a side cross-sectional view of a semi-injected cooling water tank provided at the rear end of FIG. 8, Fig.

The half-injection type cooling water tank 100 is installed at the rear end of the dropping type cooling water tank 100. Cooling water is supplied to the lower portion of the cooling water tank 100 through the circulation pipe so that the electric wire cable is partially immersed in the cooling water. 20 so that the cooling efficiency is enhanced by the convection.

The water tray 200 installed at both ends of the half-injection type cooling water tank 100 is provided with a height adjustment case 210 on the bottom surface of the cooling water tank 100, a lower case 210a on the top thereof, In the lower case 210a, a guide body 220 into which a guide hole 221 for receiving a wire cable is cut is inserted.

The guide hole 221 formed in the water tray 200 of the half-needle injection type cooling water tank 100 is formed in a U-shaped shape as in the above-described dropping cooling water tank 100 without the upper and lower portions being cut into the same width, And the outer surface of the wire cable is brought into close contact with the inside of the guide hole 221 by inserting the wire cable whose surface is hardened to some extent into the guide hole 221. [ With this structure, even if a flow such as a convection phenomenon occurs in the cooling water, the wire cable can be prevented from being easily released upward from the guide hole 221.

In the case where the electric wire cables arranged in the shape of a constant suspension curve in the cooling water tank 100 are arranged in a state of being stuck to the lower end of the cooling water tank 100, as shown in FIG. 7, The height adjustment case 210, the lower case 210a and the upper case 210b may be disposed in order so that the wire cable can be completely immersed in the cooling water so that the wire cable can be immersed in the same cooling water tank 100. [

Further, when the electric wire cable is disposed at the upper side of the cooling water tank 100 by the shape of a constant hanging curve at the rear end of the half-injection type cooling water tank 100, as shown in the figure, the height adjustment case 210 The higher height adjustment body 310 may be engaged to maintain the wire cable in a constant configuration within the cooling water bath 100.

As described above, the height of the water jacket 200 can be set differently according to the position where the electric cable is disposed in the cooling water tank 100, and various cooling methods can be adopted to maximize the cooling efficiency.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it is possible to make various modifications and variations without departing from the spirit and scope of the invention. Accordingly, the scope of the appended claims should include all such modifications and changes as fall within the scope of the present invention.

100: cooling water tank 110: guide frame
120: sliding rail
200: water film 210: case
210a: Lower case 210b: Upper case
211: first metal plate 212: second metal plate
213: seat plate 213a: sliding surface
213b: seat surface 214: sliding groove
215: incision
220: guide body 221: guide ball
300: height adjusting case 310: height adjusting body
321: third metal plate 322: fourth metal plate
323: Sliding groove

Claims (5)

A cooling water tank in which an electric wire cable coated with an insulation layer through an extruder moves along a longitudinal direction and is brought into contact with cooling water on the surface of the electric wire cable and a cooling water tank installed at both ends of the cooling water tank at a predetermined height, A water film installation structure of an extruded cable cooling water tank for cooling an extruded cable including a determined water film,
Sliding rails are provided on both side walls facing the longitudinal direction of the cooling water tank in the vertical direction,
Wherein the metal plate has two metal plates spaced apart from each other by a distance corresponding to the thickness of the sliding rail, a receiving space formed on the inner side, a sliding groove inserted into the sliding rail along the longitudinal direction of the metal plate, A case having a predetermined elasticity and being inserted into the receiving space of the case and having a guide hole having a size corresponding to the outer diameter of the wire cable, The outer surface of the wire cable is brought into contact with the guide hole exposed to the outside through the cut-out portion of the case, and when the guide body is inserted into the receiving space,
The case
A lower case having a lower end portion of the metal plate facing the lower surface of the cooling water tank and receiving a wire cable in the cut portion,
And an upper case installed on an upper surface of the lower case so that a lower end of the metal plate is directed upward of the cooling water tank and coupled to an upper surface of the lower case,
Wherein a curved surface center of a cut portion formed in the lower case is formed in a U-shape so as to be spaced downward from an upper surface of the lower case by a predetermined distance.
The method according to claim 1,
The case
A first and a second metal plate formed at an upper end thereof with incisions cut downward at a predetermined curvature,
The first metal plate and the second metal plate are coupled to inner surfaces of the first metal plate and the second metal plate facing each other so that sliding surfaces are formed on both sides of the first and second metal plates. And a seating surface which is spaced upward from the lower end surface of the first and second metal plates and is bent inward at a lower end of the sliding surface and on which the lower end of the guide body is seated, And an installation plate formed on the bottom surface of the extrusion cable cooling water tank.
3. The method of claim 2,
Further comprising a height adjusting case formed on both sides of the sliding rail, the sliding groove being inserted into the sliding rail, the height adjusting case being installed on a bottom surface of the cooling water tank along the sliding rail,
Wherein a seating surface of the lower case is seated on an upper surface of the height adjusting case to adjust a height of the water film.
The method of claim 3,
The height adjustment case
A height adjusting body formed to have a width corresponding to a gap between the sliding rails provided on both side walls of the cooling water tank and having a predetermined height upward;
And third and fourth metal plates detachably coupled to the front and rear surfaces of the height adjusting body at a width greater than the width of the height adjusting body and having sliding grooves formed at both ends of the height adjusting body Of the extrusion cable cooling water tank.
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