KR101663360B1 - Electric wire coating layer mole to change inner diameter - Google Patents

Abstract

The present invention relates to an electric wire-coated metal mold, comprising: an outer nipple installed in a supply direction of a wire, an insulating material flowing inside and an open end; A wire guide pipe arranged inside the outer nipple so as to be axially aligned with the supply direction of the wire to guide movement of the wire; An inner elastic guide pipe coupled to a distal end of the outer nipple and elastically deformed radially outward of the wire according to the diameter of the wire and having a plurality of inner elastic wings guiding movement of the wire via the wire guide pipe; An insulating elastic member disposed outside the inner elastic guide pipe and discharging the electric wire coated with a certain thickness of insulating material supplied to the space separated from the inner elastic guide pipe and having a plurality of elastically deformed radially outward according to the diameter of the electric wire; Wherein the inner elastic guide pipe is connected to the inside of the outer nipple and is formed in the shape of a trunk tube whose diameter gradually becomes smaller, and the inner elastic guide pipe is formed in the circumferential direction And a plurality of inner elastic wings are integrally provided along the inner circumferential surface of the outer circumferential surface of the flexible wire guide hole, Is resiliently deformed in an allowable range from the reference diameter by elastic deformation of the plurality of inner elastic blades radially outwardly, Wherein the outer elastic discharge tube includes an outer coupling ring coupled to the outside of the inner elastic guide tube and having the plurality of outer elastic blades at a lower portion thereof, And a flexible wire outlet hole formed by adding a coating thickness of the insulation to the reference diameter is formed.

Description

{ELECTRIC WIRE COATING LAYER MOLE TO CHANGE INNER DIAMETER}

More specifically, the present invention relates to an inner diameter variable wire covering mold which is used for covering an outer surface of an electric wire and which has an inner diameter that varies depending on the diameter of the wire, thereby preventing the wire from being caught.

The cable for electric wire protects the electric wire buried in the inside, and the outer surface of the electric wire is covered with an insulating material to prevent a short circuit due to external contact and an electric shock accident. The cable for forming the sheath in this manner is manufactured by using a wire covering mold.

An example of such a wire covering mold is disclosed in Japanese Patent No. 10-1348066 entitled " Cover-covered cable manufacturing nipple ".

Fig. 1 is a schematic view schematically showing the configuration of a conventional wire-coated metal mold 10. Fig. As shown in the drawings, a conventional wire-covered mold 10 includes an outer mold 13 and an inner mold 11 disposed inside the outer mold 13 and on which the wire 21 is moved. A guide hole 11a through which the wire 21 is guided is formed at the tip end of the inner mold 11 and an outlet hole 13a through which the wire cable 20 having the coating layer 23 formed at the tip end of the outer mold 13 is discharged Is formed. A liquid insulating material A for forming the coating layer 23 is supplied between the outer mold 13 and the inner mold 11 and the insulating material A is supplied to the gap between the discharge hole 13a and the wire 21 As shown in FIG.

At this time, the diameter h1 of the guide hole 11a is fixed to correspond to the reference diameter d1 of the electric wire 21. The diameter h1 of the discharge hole 13a is designed to be a value obtained by adding the reference thickness m of the coating layer 23 to the reference diameter d1 of the electric wire 21. [

Here, the diameter of the wire 21 changes depending on the pressure at which the wire coil 21b is wound around the iron core 21a. For example, when the reference diameter d1 is 40 cm, the diameter of the actual wire 21 is within an error range of 39 cm to 41 cm.

Since the diameter of the guide hole 11a of the inner mold 11 is fixed to 40 cm which is the reference diameter of the wire 21 when the wire 21 having a diameter of 41 cm is moved to the guide hole 11a, The wire coil 21b forming the wire 21 may be cut off or the wire 21 may be caught. Generally, the wire cable 20 is formed to have a length of several hundreds of meters depending on the use purpose. If the wire coil 21b is broken in a specific region, the wire can not be connected and used. Accordingly, there is a problem that the manufacturing cost is increased because the wire cable must be manufactured again.

In order to solve this problem, when the guide hole 11a of the inner mold 11 is made larger than the reference diameter, there is no problem in covering the large diameter wire, but when the wire 21 smaller than the reference diameter is introduced, 21 generate a flow in the guide hole 11a in the up, down, left, and right directions.

That is, when the guide hole 11a is formed to be 41 cm larger than the reference diameter 40 cm and the wire 21 flows into the guide hole 11a at 39 cm smaller than the reference diameter of 40 cm, The wire 21 is not moved in the centered state but is moved vertically and horizontally and is eccentrically moved in one direction.

In this case, when the coating layer 23 is formed on the outside of the electric wire 21, the coating layer 23 is not formed uniformly along the circumferential direction of the electric wire 21 but is formed non-uniformly. That is, when the reference thickness of the coating layer 23 is 1.7 cm or more, a portion of the wire 21 is 1.5 cm smaller than the reference thickness, and the other region is 2.2 cm larger than the reference thickness.

Since the flame retardant polyethylene which is usually used for the coating layer 23 is expensive, there is a problem that the manufacturing cost is increased when it is coated with a thickness larger than the reference thickness.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems, and an object of the present invention is to solve the above-mentioned problems, and an object of the present invention is to provide a wire- Thereby providing a coated mold.

Another object of the present invention is to provide an inner diameter variable wire covering mold capable of forming a coating with a uniform thickness on the outer circumferential surface of a wire even if the diameter of the wire is smaller than a reference diameter by moving the wire to the inside of the mold with the centers thereof aligned will be.

The above objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention by those skilled in the art.

The object of the present invention can be attained by a wire covering mold which covers the surface of the electric wire with an insulating material. The wire covering mold of the present invention comprises: an outer nipple which is installed in a direction of supplying a wire and in which an insulating agent flows and whose tip is opened; A wire guide pipe arranged inside the outer nipple so as to be axially aligned with the supply direction of the wire to guide movement of the wire; An inner elastic guide pipe coupled to a distal end of the outer nipple and elastically deformed radially outward of the wire according to the diameter of the wire and having a plurality of inner elastic wings guiding movement of the wire via the wire guide pipe; An insulating elastic member disposed outside the inner elastic guide pipe and discharging the electric wire coated with a certain thickness of insulating material supplied to the space separated from the inner elastic guide pipe and having a plurality of elastically deformed radially outward according to the diameter of the electric wire; Wherein the inner elastic guide pipe is connected to the inside of the outer nipple and is formed in the shape of a trunk tube whose diameter gradually becomes smaller, and the inner elastic guide pipe is formed in the circumferential direction And a plurality of inner elastic wings are integrally provided along the inner circumferential surface of the outer circumferential surface of the flexible wire guide hole, Is resiliently deformed in an allowable range from the reference diameter by elastic deformation of the plurality of inner elastic blades radially outwardly, Wherein the outer elastic discharge tube includes an outer coupling ring coupled to the outside of the inner elastic guide tube and having the plurality of outer elastic blades at a lower portion thereof, And a flexible wire outlet hole formed by adding a coating thickness of the insulation to the reference diameter is formed.
According to an embodiment of the present invention, there is further provided a coupling plate for coupling the wire guide pipe and the outer nipple to each other and fixing the inner elastic guide pipe and the outer elastic discharge pipe to the outer nipple, A wire outlet hole for discharging the wire to the inner elastic guide pipe is formed coaxially with the wire guide pipe; And a body coupling rib extending in the radial direction at predetermined angular intervals along the circumferential direction of the shield plate to fix the shield plate to the external nipple.
According to one embodiment, the outer coupling ring further includes a plurality of leakage preventing vanes coupled to the inner side of the outer elastic vanes, wherein the plurality of leakage preventing vanes and the plurality of outer elastic vanes are coupled to the outer coupling ring The positions can be intermittently arranged in an intermittent manner and the external leakage of the insulator flowing inside can be blocked.
On the other hand, the object of the present invention can be achieved by a wire covering mold which covers the surface of the wire with an insulating material. An outer nipple which is installed in a direction of supplying a wire and whose tip is opened and a wire insertion tube for inserting a wire at a rear end and aligning the center of the wire is integrally formed; An inner elastic guide pipe coupled to a distal end of the outer nipple and elastically deformed radially outwardly of the wire according to a diameter of the wire and having a plurality of inner elastic wings for guiding the wire so as to correspond to the diameter of the wire; A plurality of external elastic wings disposed outside the internal elastic guide tube and discharging the electric wire coated with a certain thickness of insulation material supplied to the space separated from the internal elastic guide tube to the outside and being elastically deformed according to the diameter of the electric wire, Wherein the inner elastic guide pipe is formed inside the outer nipple and is formed in the shape of a trunk tube having a gradually decreasing diameter, Wherein a lower portion of the plurality of inner elastic wings forms a variable electric wire guide hole corresponding to a reference diameter of the electric wire, and the variable electric wire guide hole has a plurality of inner elastic wings, Is elastically deformed radially outwardly of the inner elastic blade so as to be elastically expanded within a permissible range from the reference diameter, Wherein the outer elastic discharge tube includes an outer coupling ring coupled to the outside of the inner elastic guide tube and having the plurality of outer elastic blades at a lower portion thereof, And a variable-wire-wire-discharging hole to which the thickness of the covering wire is added.

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In the wire-covered mold according to the present invention, the diameter of the variable wire guide hole of the inner elastic guide pipe can be varied to the maximum allowable range according to the diameter of the wire. Therefore, when the diameter of the wire is large, it is prevented that the wire is caught or the wire is cut, so that the coating of the wire can be stably performed. Therefore, the defective rate can be reduced and the manufacturing cost can be reduced.

Further, since the wire guide tube holds the center of the wire, the wire can be eccentrically unidirectional so that the thickness of the cover layer can be prevented from becoming uneven. Thus, the material cost for forming the coating layer can be saved.

Further, according to the wire covering mold according to the present invention, the elastic guide pipe and the elastic discharge pipe are elastically juxtaposed with each other according to the thickness of the electric wire, and the electric wires are caught, so that the electric wire is eccentric and the coating layer is unevenly formed.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view schematically showing an operation process of a conventional wire-
Fig. 2 is a perspective view showing a configuration of a wire-covered mold according to the present invention,
Fig. 3 is an exploded perspective view of the wire-covered mold according to the present invention,
4 is a cross-sectional view showing a cross-sectional structure taken along the line AA in Fig. 2,
FIG. 5 is a view illustrating an operation process when a wire having a diameter larger than a reference diameter is moved to the wire covering mold according to the present invention.
6 is a perspective view showing a configuration of a wire-covered mold according to another embodiment of the present invention,
7 is a cross-sectional view illustrating a cross-sectional configuration of a wire-coating mold according to another embodiment of the present invention.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Detailed descriptions of well-known functions and constructions which may be unnecessarily obscured by the gist of the present invention are omitted.

Fig. 2 is a perspective view showing the construction of the wire covering mold 100 according to the present invention, Fig. 3 is an exploded perspective view explaining the structure of the wire covering mold 100, Figs. 4 and 5 are cross- (100) according to an embodiment of the present invention.

As shown in the drawing, the wire covering mold 100 according to the present invention includes an outer nipple 110 through which an insulating material A flows, An inner elastic guide pipe 130 coupled to the distal end of the outer nipple 110 to guide the wire 21 and a guide member 130 connected to the outer elastic member 130 to surround the inner elastic guide pipe 130, And an external elastic discharge pipe 140 coupled to the tip of the electric wire 21 to support the coating layer 23 in a uniform thickness.

Here, the electric wire 21 is supplied to the electric wire guide pipe 120 through a wire supplying part (not shown) through electric wire supplying process. The insulating material A is supplied between the outer nipple 110 and the wire guide tube 120 in a molten liquid state.

The outer nipple 110 accommodates the wire guide tube 120. The inner elastic guide tube 130 and the external elastic discharge tube 140 are coupled to the tip of the outer nipple 110 to form a coating layer 23 on the outside of the wire 21 . In the figure, the rear end of the outer nipple 110 is shown as being open, but this is for the sake of illustration and is associated with a cylindrical casing (30 of FIG. 1).

The outer nipple 110 is formed so that its diameter becomes gradually smaller toward the front end. The insulating material A flows into the outer nipple 110 and is moved between the inner elastic guide pipe 130 and the outer elastic discharge pipe 140.

The wire guide pipe 120 is coupled to the inside of the outer nipple 110 so that the coating proceeds in a state where the center of the wire 21 is aligned with the diameter change of the wire 21. The wire guide tube 120 is disposed in the middle region of the outer nipple 110. The inner diameter (d2) of the wire guide tube (120) is set in consideration of the maximum allowable diameter of the wire (21). The wire guide pipe 120 is designed to have a maximum allowable diameter d2 of the electric wire 21 in consideration of elasticity of the inner elastic guide pipe 130 and the outer elastic discharge pipe 140. [

For example, when the reference diameter of the wire 21 is 40 cm and the maximum allowable diameter of the variable wire guide hole 135 of the inner elastic guide pipe 130 is 42 cm, the inner diameter of the wire guide pipe 120 is formed to be 42 cm .

Here, when the diameter of the wire 21 is smaller than the reference diameter, the wire guide tube 120 aligns the center of the wire 21 by holding the movement of the wire 21 vertically and horizontally. As a result, the electric wire 21 is eccentrically inserted into the variable electric wire guide hole 135 to prevent the thickness of the coating layer 23 from becoming uneven.

The inner elastic guide tube 130 and the outer elastic discharge tube 140 are connected to the distal end of the outer nipple 110 and are connected to the variable wire guide hole 135 and the variable wire outlet hole 145 in correspondence with the diameter change of the wire 21, So that the coating layer 23 can be stably formed without breaking or catching the electric wire 21.

The inner elastic guide tube 130 includes an inner coupling ring 131 coupled to the coupling plate 150 and a plurality of inner elastic blades 133 extending downward along the circumferential direction of the inner coupling ring 131 do. The inner coupling ring 131 and the inner resilient vane 133 are formed in the shape of a trunk tube which gradually becomes smaller in diameter as a whole. At this time, an internal incision 134 is formed on the circumferential surface of the fallopian tube at a predetermined angular interval to form a plurality of internal elastic wings 133.

The initial diameter r1 of the variable electric wire guide hole 135 formed by the plurality of internal elastic wings 133 is formed to correspond to the reference diameter d1 of the electric wire 21. [ However, when the wire 21 having a diameter larger than the reference diameter is introduced into the variable wire guide hole 135, the inner elastic wing 133 is elastically deformed outward in the radial direction as shown by the dotted line in FIG. 3, .

The diameter r2 of the maximum variable cable guide hole 135 that can be formed by elastic deformation of the inner elastic blade 133 is determined by the length of the inner section 134 and the thickness and material of the inner elastic blade 133 The diameter of the wire 21 can be limited within the permissible range.

The outer elastic discharge tube 140 is coupled to the tip of the outer nipple 110 such that the inner elastic guide tube 130 is received therein. The outer elastic discharge pipe 140 limits the coating thickness of the insulating material A so that the covering layer 23 having a uniform thickness is formed on the outer circumferential surface of the electric wire 21 moved through the variable electric wire guide hole 135.

The outer elastic discharge tube 140 includes an outer coupling ring 141 coupled to the tip of the outer nipple 110 and a plurality of outer elastic blades 143 extending downward along the circumferential direction of the outer coupling ring 141 . A plurality of external elastic wings 143 are elastically deformed radially outwardly in the external elastic discharge pipe 140 in the same manner as the internal elastic guide pipe 130. As a result, the diameter of the flexible wire discharge hole 145 formed by the lower portion of the plurality of external elastic wings 143 is increased within the allowable range.

The initial diameter r3 of the variable wire discharge hole 145 is set to a size obtained by adding the reference thickness of the coating layer 23 to the reference diameter of the electric wire 21. [ The maximum allowable diameter r4 of the variable wire discharge hole 145 may be set to a size obtained by adding the reference thickness of the coating layer 23 to the maximum allowable diameter r2 of the variable wire guide hole 135. [

The external elastic discharge pipe 140 may be fixed to the tip of the outer nipple 110 by a joining method such as welding, soldering, bonding, pressure welding, or the like, or may be fixed by a fastening member such as a bolt.

On the other hand, a plurality of leakage preventing vanes 147 are coupled to the outer coupling ring 141 on the inner side of the plurality of outer elastic vanes 143. The plurality of leakage preventing blades 147 are provided so as to be elastically spread by the second section cut-off 148. Here, the second section improvement 148 is formed in a position shifted from the section reduction 144. In other words, when four external elastic wings 143 are formed on the external coupling ring 141 at intervals of 90 degrees, four second wales 148 of the plurality of leakage preventing wings 147 are formed at intervals of 90 degrees And the outer elastic blade 143 are formed to have a phase difference.

The outer elastic wing 143 and the leakage preventing wing 147 are vertically arranged by bisecting the entire thickness of the outer joining ring 141. 3, the external elastic wing 143 and the leakage preventing wing 147 are shown as spaced apart from each other for the sake of convenience of explanation. Actually, the external elastic wing 143 and the leakage preventing wing 147, as shown in FIG. 4, So that they remain in close contact with each other. Even if the outer elastic blade 143 and the leakage preventing blade 147 are elastically deformed according to the diameter change of the electric wire 21 because the section reduction 144 and the second section improvement 148 are alternately arranged, (A) is prevented from leaking to the outside.

The coupling plate 150 fixes the positions of the outer nipple 110, the wire guide pipe 120, and the inner elastic guide pipe 130. The coupling plate 150 includes a shield plate 151 having a wire discharge hole 157 for guiding the electric wire 21 to the variable electric wire guide hole 135; And a body coupling rib 153 formed on the outer periphery of the blocking plate 151 and coupled to an inner wall surface of the outer nipple 110.

4, the insulating plate A is moved between the outer elastic discharge pipe 140 and the inner elastic guide pipe 130 and flows between the outer nipple 110 and the wire guide pipe 120, . The insulating material A is moved into the space 155 between the blocking plate 151 and the main body coupling rib 153.

Here, the back surface of the inner elastic guide pipe 130 is fixed to the blocking plate 151. The blocking plate 151 and the inner elastic guide pipe 130 may be fixed by a joining method such as welding, brazing, bonding, pressure welding, or the like, or may be fixed by a fastening member such as a bolt.

The operation of the wire covering mold 100 according to the present invention having such a configuration will be described with reference to FIGS. 1 to 5. FIG.

The electric wire 21 is moved to the electric wire covering mold 100 of the present invention by a wire supplying member (not shown). The electric wire 21 is manufactured by winding a wire coil 21b in a spiral shape on the outside of the iron core 21a. The wire 21 is moved into the outer nipple 110. At this time, the wire 21 is slightly different in diameter depending on the pressure and shape when the wire coil 21b is engaged.

The wire 21 is moved to the wire covering mold 100 along the wire guide pipe 120. Since the wire guide pipe 120 is formed to have a diameter corresponding to the maximum allowable diameter of the wire 21, the wire 21 can be smoothly moved. The wire 21 is moved from the tip of the wire guide pipe 120 to the inner elastic guide pipe 130 through the wire discharge hole 157 of the coupling plate 150.

The inner elastic guide pipe 130 is coupled to the coupling plate 150 such that the variable cable guide hole 135 is positioned coaxially with the wire guide pipe 120. Accordingly, the electric wire 21 is moved along the inner elastic guide pipe 130 in a state where the center line is aligned. The electric wire 21 moved along the inner elastic guide pipe 130 flows into the variable electric wire guide hole 135.

At this time, the inner elastic blade 133 which is in contact with the outer circumferential surface of the electric wire 21 is elastically deformed according to the diameter of the electric wire 21, and the diameter of the variable electric wire guide hole 135 is changed. When the wire 21 is a reference diameter, as shown in FIG. 4, the inner elastic blade 133 is not elastically deformed, and the variable wire guide hole 135 also maintains the initial diameter r1.

The front end of the electric wire 21 via the variable electric wire guide hole 135 is moved to the variable electric wire outlet hole 145 of the external elastic discharge pipe 140. At this time, the insulating material (A) flowing between the inner elastic guide tube (130) and the outer elastic discharge tube (140) is applied to the outer peripheral surface of the electric wire (21). The electric wire 21 coated with the insulating material A is discharged to the external elastic discharge pipe 140 and the coating layer 23 is formed by the diameter difference between the diameter of the variable electric wire guide hole 135 and the variable electric wire discharge hole 145 do.

Meanwhile, when the diameter d2 of the wire 21 is larger than the reference diameter d1, it is guided along the wire guide pipe 120 as shown in FIG. 5 and flows into the variable wire guide hole 135. The plurality of inner elastic wings 133 contact the surface of the electric wire 21 and are elastically bent and deformed radially outward. Accordingly, the diameter of the variable wire guide hole 135 becomes larger than the initial diameter (r2 > r1). The wire coil 23b on the surface of the wire 21 is not cut so that the wire 21 is not stuck but is stably moved to the side of the variable wire discharge hole 145. [

A plurality of external elastic wings 143 are also brought into contact with the surface of the electric wire 21 coated with the insulating material A so that the insulating material A is coated with a uniform thickness to form the coating layer 23. [

When the diameter of the electric wire 21 is smaller than the reference diameter d1, the electric wire 21 is moved along the electric wire guide pipe 120, And is moved to the inner elastic guide pipe 130 and the outer elastic discharge pipe 140. Therefore, the coating layer 23 can be formed on the outer circumferential surface of the electric wire 21 with a uniform thickness.

6 and 7 are a perspective view and a sectional view showing a wire-covered mold 100a according to another embodiment of the present invention.

In the wire covering mold 100 according to the preferred embodiment of the present invention, the wire guide pipe 120 is separately provided in the outer nipple 110. On the other hand, in the wire covering mold 100a according to another embodiment, the wire guide pipe is integrally coupled to the outer nipple 160. [

The outer nipple 160 according to another embodiment has a wire guiding curved surface 163 formed on the rear surface of the outer nipple body 161 in the form of a trunk tube and a wire guide pipe 165 is integrally formed therebetween. The electric wire 21 whose center passes through the wire guide pipe 165 is moved to the inner elastic guide pipe 130.

As described above, the diameter of the variable wire guide hole of the inner elastic guide pipe can be varied to the maximum allowable range according to the diameter of the wire, in the wire-covered mold according to the present invention. Therefore, when the diameter of the wire is large, it is prevented that the wire is caught or the wire is cut, so that the coating of the wire can be stably performed. Therefore, the defective rate can be reduced and the manufacturing cost can be reduced.

Further, since the wire guide tube holds the center of the wire, the wire can be eccentrically unidirectional so that the thickness of the cover layer can be prevented from becoming uneven. Thus, the material cost for forming the coating layer can be saved.

Further, according to the wire covering mold according to the present invention, the elastic guide pipe and the elastic discharge pipe are elastically juxtaposed with each other according to the thickness of the electric wire, and the electric wires are caught, so that the electric wire is eccentric and the coating layer is unevenly formed.

The embodiments of the inner diameter variable wire covering mold of the present invention described above are merely illustrative and those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. You will know very well. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

100: wire covering mold 110: outer nipple
111: guide tube fitting member 120: wire guide tube
130: Inner elastic guide tube 131: Inner coupling ring
133: Inner elastic wing 134: Internal reduction
135: Variable wire guide hole 140: External elastic discharge pipe
141: outer coupling ring 143: outer elastic blade
145: Variable wire discharge hole 147: Leakage prevention blade
148: Section 2 Improvement 150: Coupling plate
151: blocking plate 153: body coupling rib
155: insulator supply hole 157: wire discharge hole

Claims (6)

1. A wire-covered mold for covering an insulating material on a surface of a wire,
An outer nipple which is installed in a supply direction of the wire and in which an insulating material flows and whose tip is opened;
A wire guide pipe arranged inside the outer nipple so as to be axially aligned with the supply direction of the wire to guide movement of the wire;
An inner elastic guide pipe coupled to a distal end of the outer nipple and elastically deformed radially outward of the wire according to the diameter of the wire and having a plurality of inner elastic wings guiding movement of the wire via the wire guide pipe;
An insulating elastic member disposed outside the inner elastic guide pipe and discharging the electric wire coated with a certain thickness of insulating material supplied to the space separated from the inner elastic guide pipe and having a plurality of elastically deformed radially outward according to the diameter of the electric wire; And an outer elastic discharge tube having outer elastic blades,
Wherein the inner elastic guide tube comprises:
An inner coupling ring formed inside the outer nipple and formed in the shape of a trunk tube having a gradually decreasing diameter and integrally formed with the plurality of inner elastic wings along the circumferential direction by internal folding on the plate surface,
Wherein a lower portion of the plurality of inner elastic wings forms a variable electric wire guide hole corresponding to a reference diameter of the electric wire and the variable electric wire guide hole is formed by elastic deformation of the plurality of inner elastic wings radially outwardly, So as to be elastically large within an allowable range,
The external elastic discharge pipe
And an outer coupling ring coupled to the outside of the inner elastic guide pipe and having a plurality of external elastic blades at a lower portion thereof,
Wherein a lower portion of each of the plurality of external elastic wings forms a variable electric wire discharge hole in which a thickness of a coating reference thickness of the insulating material is added to a reference diameter of the electric wire.
The method according to claim 1,
And a coupling plate connecting the electric wire guide pipe and the outer nipple to each other and fixing the inner elastic guide pipe and the outer elastic discharge pipe to the outer nipple,
The coupling plate
A shield plate having a wire discharge hole for discharging the electric wire to the inner elastic guide pipe and coaxial with the electric wire guide pipe;
And a main body coupling rib extending in a radial direction at predetermined angular intervals along the circumferential direction of the shield plate to fix the shield plate to the external nipple.
3. The method of claim 2,
Further comprising a plurality of leakage preventing blades coupled to the outer coupling ring to the inside of the outer elastic wings,
Wherein the plurality of leakage preventing blades and the plurality of external elastic vanes are disposed in an unequally alternate manner in coupling positions to the external coupling rings to block external leakage of the insulating material flowing inside.
1. A wire-covered mold for covering an insulating material on a surface of a wire,
An outer nipple which is installed in a supply direction of the wire and has a front end opened and a wire insertion tube for inserting a wire into the rear end and aligning the center of the wire,
An inner elastic guide pipe coupled to a distal end of the outer nipple and elastically deformed radially outwardly of the wire according to a diameter of the wire and having a plurality of inner elastic wings for guiding the wire so as to correspond to the diameter of the wire;
A plurality of external elastic wings disposed outside the internal elastic guide tube and discharging the electric wire coated with a certain thickness of insulation material supplied to the space separated from the internal elastic guide tube to the outside and being elastically deformed according to the diameter of the electric wire, And an outer elastic drain pipe
Wherein the inner elastic guide tube comprises:
An inner coupling ring formed inside the outer nipple and formed in the shape of a trunk tube having a gradually decreasing diameter and integrally formed with the plurality of inner elastic wings along the circumferential direction by internal folding on the plate surface,
Wherein a lower portion of the plurality of inner elastic wings forms a variable electric wire guide hole corresponding to a reference diameter of the electric wire and the variable electric wire guide hole is formed by elastic deformation of the plurality of inner elastic wings radially outwardly, So as to be elastically large within an allowable range,
The external elastic discharge pipe
And an outer coupling ring coupled to the outside of the inner elastic guide pipe and having a plurality of external elastic blades at a lower portion thereof,
Wherein a lower portion of each of the plurality of external elastic wings forms a variable electric wire discharge hole in which a thickness of a coating reference thickness of the insulating material is added to a reference diameter of the electric wire. delete delete

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