KR20160067557A - Branch sleeve for electric wire connection and manufacturing method therefor - Google Patents

Abstract

According to one aspect of the present invention, a manufacturing method of a branch sleeve for electric wire connection comprises: a step of forming a virtual longitudinal line of first and second pillar units; a step of forming an outline of a first curved wing unit; a step of forming an internal 1/4 circumferential line of the first curved wing unit; a step of forming the first curved wing unit; a step of forming an outline of a second curved wing unit; a step of forming an internal 1/4 circumferential line of the second curved wing unit; and a step of forming the second curved wing unit. The purpose of the present invention is to provide a manufacturing method of a branch sleeve for electric wire connection, capable of maintaining a circular structure of an electric wire cross-section and reducing a gap between connection parts.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a branch sleeve for electric wire connection,

The present invention relates to a branch sleeve for wire connection and a manufacturing method thereof.

Generally, the branch sleeve is made of a material such as aluminum or a copper alloy that can be electrically connected.

Fig. 1 shows a structure of a conventional branching sleeve for wire connection. Fig. 2 shows a state in which a wire is inserted into a conventional branching sleeve for wire connection, and is connected and compressed.

1, a conventional branch sleeve is provided with a fixing piece 2 suitable for the thickness of the main electric wire 6 and the branch connection electric wire 7 on the sleeve main body 1, 4 and inserted into the vertical groove 3 of the main wire 6 and then the one side of the space on both sides separated by the fixing piece 2 is inserted into the spiral portion of the main wire 6, The peeled end portion is inserted into the other space portion.

Then, when the left and right sides are compressed by the compressor, both side wires are compression-connected as shown in Fig.

Referring to FIG. 2, the hanging jaw 4 having the vertical grooves 3 is formed on the left and right side of the sleeve main body 1, So that the compression connection connection of the branch sleeve is completed.

However, the final shape of the connecting portion that has been conventionally compressed and connected is not a circular shape but a distorted shape.

In the conventional branch sleeve, the shape of the end surface of the sleeve main body 1 on the left and right sides is semicircular.

Therefore, it is inevitable that the connecting portions of the connecting portions become distorted when they are brought into contact with each other by the compressive force applied by the compressor, and the electric wires 6 and 7 connected to the left and right sleeve main bodies 1, An excessive gap 301 is generated.

When such a gap is generated, flammable dust or the like, moisture and moisture may permeate into the gap, and corrosion may be generated and heat may be generated.

Therefore, a branching sleeve which can be compression-connected without a gap between the wire and the branch sleeve when crimping the wires of different thicknesses and capable of maintaining the circular structure of the wire after compression is required.

Korean Utility Model Publication No. 1994-0013719 [Branch Sleeve for Connecting Low Voltage Cables]

The present invention relates to a wire connecting branch capable of reducing the occurrence of a gap in a contact portion while maintaining a circular structure of a cross section of a wire at the time of compression connection using a compressor by using a plurality of branched wires having the same diameter or different diameters, Sleeve and a method of manufacturing the same.

According to one aspect of the present invention, in the step of designing a section of a branch sleeve connecting first and second wires (the diameter of the first wire is equal to or larger than the diameter of the second wire), the longitudinal center line Y A vertical line forming step of forming a first and a second column virtual line in a vertical direction at an interval corresponding to the thickness t of the curved wing portion of the branch sleeve from the left to the right of the axis line; A length corresponding to the diameter of the first wire is defined as a first blade center point along the X axis from the first column vertical line and the thickness t is set to a radius of the first wire about the first blade center point Forming an outer contour of the first curved wing portion formed with a vertical semicircle directed to the first direction side with the additional length as a radius; Forming an inner 1/4 circle forming line of a first curved wing portion formed at an upper limit 1/4 circle from the first wing center point toward a first direction in a radial direction of the first electric wire; Forming a first protrusion formed in a semicircular shape between an upper end of the outline of the first curved wing and an upper end of the inner circumferential line of the first curved wing; A length corresponding to the diameter of the second wire is defined as a second wing center point along the X axis from the second column vertical line and the thickness t is added to the radius of the second wire about the second wing center point Forming an outer contour of a second curved wing portion formed with a vertical semicircle directed to a second direction side with a length as a radius; Forming an inner quarter circular line of a second curved wing portion formed at an upper-limit 1/4 circle from the second wing center point to a radial length of the second wire in a second direction; And forming a second protrusion formed as a semicircle between the upper end of the outer contour of the second curved wing and the upper end of the inner 1/4 circumferential of the second curved wing to form a second curved wing step; The method of manufacturing a branch sleeve is provided.

After the step of forming the second curved wing portion, a line extending horizontally at the lowermost portion of the outline of the first curved wing portion is formed as a lower boundary line so that the lowermost portions of the first and second curved wing portions are connected to each other on the lower boundary line. Forming a horizontal base lower line; Forming a horizontal base portion first and second upper lines formed on the lower portion of the base portion with a width of the thickness t; A step of forming an upper part of a protrusion of a central column having a portion corresponding to a vertical line section of the first and second post portions as an upper boundary on a line horizontally extending the uppermost portion of the outline of the first curved wing; Forming an inclined portion that is inclined inward from an end of the upper line of the projection; Forming a protrusion concave portion formed at a lower portion of the inclined portion; And forming a central column under the ridge groove; And a control unit.

The horizontal base first upper line forming step may include forming a virtual first circle having a diameter equal to the diameter of the first wire so as to come into contact with a virtual line of the first column on the horizontal center line (X axis) step; Forming a hypothetical second circle with a diameter equal to the diameter of the first wire, the first circle being perpendicular to the first direction so as to overlap the circumference at the center of the imaginary first circle; And connecting the lower horizontal tangent line of the virtual first circle to the lower horizontal tangent line of the virtual second circle.

The step of forming the concave grooves may include a step of forming a virtual third circle having a center of the imaginary first circle as a center and a length obtained by adding the thickness t to a radius of the imaginary first circle as a radius, Forming a circle; And forming a semicircular portion inwardly concave between a point at which the imaginary third circle meets the virtual line of the first column portion and a circumference of the imaginary first circle; And a control unit.

In addition, the step of forming the central column may include: And a line connecting the portion of the hypothetical first circle contacting the concave semicircular portion and the lower horizontal tangential portion.

In addition, the diameter and the radius of the first and second wires are calculated to be 104 to 106% of the actual size.

The thickness t is 2 to 6 mm.

According to another aspect of the present invention, First and second bent wing portions formed in a part of the cross section of the first and second wires for compressively connecting the first and second connecting wires from the left and right sides of the center column; A horizontal base portion connecting and supporting a lower portion of the central column and a lower portion of the first and second curved wings; Wherein the first and second curved wings are formed with first and second protrusions formed in an outward semi-circular shape at an upper end of the first and second curved wings, the center column is formed to include a protrusion formed on an upper portion thereof, First and second ridge grooves formed at the left and right sides of the protruding portion and formed of the first and second ridge grooves formed in the inward side semicircle, Wherein the branch sleeve is formed with a groove.

The outline of the first curved wing portion may be formed so that when a virtual center is a point spaced apart from the center point of the center column by a thickness of the first curved wing portion with respect to a diameter of the first wire along the X axis, And is formed as a semicircle directed in a first direction having a radius obtained by adding the thickness to the radius of the first electric wire.

The outline of the second curved wing portion may be formed such that when a virtual center is defined by a point at a distance from the center point of the center column along the X axis by the thickness of the second curved wing portion to the diameter of the second wire, And is formed as a semicircle which is a center point and which is directed in a second direction in which a length obtained by adding the thickness to the radius of the second wire is a radius.

The gap between the first protrusion groove and the first protrusion is 104 to 106% of the diameter of the first wire.

Further, the first and second protruding concave grooves are filled with a conductive compound.

The length from the lower portion of the horizontal base portion to the upper portion of the protrusion is formed by a length of the first wire plus twice the thickness of the first curved wing portion.

According to an embodiment of the present invention, when a plurality of branched electric wires having the same diameter or different diameters on the connection portion are compression-connected by using a compressor, the circular structure of the electric wire is maintained as it is compared with the conventional compression sleeve And it is possible to reduce the generation of a gap.

According to an embodiment of the present invention, the protruding portion of the wire connecting wing portion and the recessed portion for making the protruding portions mutually connected are formed on the upper portion of the sleeve central body of the branch sleeve body, The main wire and the branch wire of the electric wire are brought into close contact with the branch sleeve completely while the electric wire connection part keeps the circular shape of the original cross section of the electric wire and at the same time the deterioration phenomenon due to the gap generated by the connection part and corrosion is prevented, . ≪ / RTI >

Fig. 1 shows a structure of a conventional branching sleeve for wire connection.
Fig. 2 shows a state in which a wire is inserted into a conventional branching sleeve for wire connection and is compressed and connected.
3 shows an outer structure of a branching sleeve for wire connection according to an embodiment of the present invention.
4 is a cross-sectional view of a branching sleeve for wire connection according to an embodiment of the present invention.
5 shows a state in which main wires and branch wires are inserted into a branch sleeve for wire connection according to an embodiment of the present invention, and the branch wires are compressed and connected.
FIGS. 6 to 18 illustrate the step of performing the step of designing the cross section during the manufacturing process of the branch sleeve for wire connection according to the embodiment of the present invention.

While the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and similarities.

It is also to be understood that the terms first, second, etc. used hereinafter are merely reference numerals for distinguishing between identical or corresponding components, and the same or corresponding components are defined by terms such as first, second, no.

It is to be understood that the specific embodiments are not intended to limit the invention to the specific embodiments, but are to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, detailed description of known related arts will be omitted when it is determined that the gist of the present invention may be unnecessarily obscured.

In the following description, the same reference numerals are used for similar parts throughout the specification.

FIG. 3 illustrates an outer structure of a branching sleeve for wire connection according to an embodiment of the present invention, and FIG. 4 illustrates a cross section of a branching sleeve for wire connection according to an embodiment of the present invention.

3 and 4, a branching sleeve 100 for wire connection according to an embodiment of the present invention includes a center column 112 formed at the center of a branch sleeve 100, First and second bent wings 152 and 151 formed in the shape of a part of the cross section of the first and second wires for compressively connecting the first and second wires for connection at the left and right sides of the center column 112, And a horizontal base portion 171 for connecting and supporting the lower portion of the first and second curved wings 152 and 151.

The upper and lower end portions of the first and second curved wings 152 and 151 have protrusions 117 formed in an outward semi-circular shape.

The central column body 112 is formed to include a protrusion 113 formed on the upper portion thereof. The first and second protrusions 113 and 114 are formed in the inward semicircular shape for recessing the outward semicircular shape on the left and right sides of the protrusion, A concave groove 114 is formed.

First and second tilted inclined portions 193 and 192 inclined inward are formed from the upper end of the protrusion 113 to the protrusion groove 114.

The open spacing between the end portions 117 of the first and second curved wings 151 and 152 formed on the left and right sides of the central column body 112 of the branch sleeve 100 and the central column body 112, It is the entrance of the wire. The distance between the entrance and exit is about 104 to 106% in the outer diameter of the connection wire.

If the distance between the entrance and exit is smaller than 104%, the entry and exit of the electric wire becomes difficult. When the distance is larger than 106%, a gap may be generated at the time of compression connection.

The width of the inside of the left and right curved surfaces of the space formed by the center column 112 of the branch sleeve 100 and the first and second curved wings 151 and 152 according to an embodiment of the present invention is smaller than the width of the applied wires And the thickness t of the curved wings 151 and 152 is added to 1.5 times the outer diameter of the main wire or branch wire.

The thickness of the left and right curved surfaces 115 and 116 formed at the center of the central column body 112 is determined to be twice the reference thickness t of the curved wings 151 and 152. [

Inwardly inclined tilting slopes 193 and 192 are formed between both end points of the upper portion of the protrusion 113 and the left and right trough grooves 124 and 114.

4 and 5, in a state in which the first and second electric wires 118 and 119 are disposed in the branch sleeve 100, the first and second curved wings (not shown) 151 and 152 and the protrusions 127 and 117 of the first and second bent wings are slid along the inclined slopes continuously from the state of abutting against the upper ends of the protrusions 113, The compression connection is completed while being in close contact with the concave grooves 114 formed around the left and right sides of the tread.

5, when the wires are connected, the first and second bent wings 151 and 152 are pinched by the compressive force, and the protrusions 127 and 127 of the first and second bent wings 151 and 152, 117 are closely contacted to the concave grooves 114.

According to another embodiment of the present invention, the ridge grooves 114 are filled with a conductive compound.

It is possible to prevent foreign matter such as moisture, moisture, dust and the like from flowing from the outside of the first and second bent wings which are closely connected by the conductive compound.

Referring to FIG. 5, the branch sleeve according to an embodiment of the present invention can reduce the occurrence of a gap between the branch sleeve and the connection wire while maintaining the original shape without distorting the circular cross-section of the wire connected at the time of compression connection.

A branch sleeve according to an exemplary embodiment of the present invention includes: designing a contour of a branch sleeve; Forming a press mold according to the outer shape of the designed branch sleeve; and compressing and cutting the raw plate material with the press mold to produce a branch sleeve.

In the designing step of the branch sleeve according to an embodiment of the present invention, the CAD program of the computer can be designed.

FIGS. 6 to 18 illustrate the step of performing the step of designing the cross section during the manufacturing process of the branch sleeve for wire connection according to the embodiment of the present invention.

The design process of the branch sleeve according to an embodiment of the present invention is performed according to the following steps.

First, a step of forming imaginary column vertical lines 12, 11 is performed.

6, imaginary first and second column vertical lines 12, 12 are spaced by a reference thickness (t = 4 mm), which is the thickness of the curved wing portion of the branch sleeve, to the left and right with respect to the vertical center line Y, 11).

The reference thickness of the curved wing portion of the branch sleeve according to an embodiment of the present invention is described with reference to 4 mm.

In another embodiment of the present invention, the thickness of the curved wing can be adjusted within a range of 2 to 6 mm according to the thickness of the wire.

The next step is to form the outline of the curved wing.

As a result of many compression tests according to an embodiment of the present invention, the curved blade has a semi-circular shape having a diameter of 1.5 times the diameter of the connection wire when the connection wire placed in the branch sleeve is bent by compression, It could be close without.

The outline 52 of the curved wing portion 152 of the main wire 118 is spaced from the virtual first column vertical line 12 (or a point corresponding to the reference thickness at the center point) along the X axis to the diameter of the main wire And is formed as a semicircle which is directed in a first direction having a radius of the main wire + the reference thickness as a radius centering the corresponding point.

That is, the outline 52 of the curved wing 152 of the main wire 118 has a point which is along the X-axis at the center point by a distance corresponding to the diameter of the main wire 118 by a reference thickness, ) ≪ / RTI > plus a reference thickness as a radius.

The diameter of the outline 52 of the curved wing portion 152 of the main wire 118 becomes +2t of the diameter of the main wire 118 (reference thickness).

A line connected by the X axis on the uppermost side of the outline 52 of the curved wing 152 of the main wire 118 is an upper horizontal boundary line 32 on which the upper part of the protruding portion is located, A line connecting the lowermost side of the outline 52 of the curved wing 152 with the X axis becomes a hypothetical lower horizontal boundary line 31 in which the lower portion of the horizontal base portion 171 is located.

The outline 51 of the curved wing 151 of the branch wire 119 extends from the imaginary second column vertical line 11 along the X axis to the center of a point corresponding to the diameter of the branch wire 119, And is formed in a semicircle which is directed in a second direction in which the radius of the wire 119 + the reference thickness is a radius.

That is, a point at a center point of the curved wing and a radius of the branch wire 119 plus the reference thickness t as a radius is defined as a point spaced from the center point by the reference thickness t with respect to the diameter of the branch wire 119 along the X- Direction.

The diameter of the outline 51 of the curved wing portion 151 of the branching wire 119 becomes the diameter of the branching wire 119 + 2t.

In the present invention, the main wire 118 refers to a wire having a large diameter among the wires connected to the branch sleeve 100, and the branch wire 119 refers to a wire having a small diameter among the wires connected to the branch sleeve 100.

In addition, according to an embodiment of the present invention, the first and second wires seated on the branch sleeve mean a wire without an insulation sheath.

The diameter (D) for the thickness (cross-sectional area) of the coin to be interconnected by the applied branch sleeve is calculated according to an embodiment of the present invention.

In an embodiment of the present invention, a manufacturing method of a branch sleeve that interconnects wire diameters of 150 mm < 2 > and 100 mm < 2 >

First, the cross-sectional areas of the illustrated wires are 150 mm 2 and 100 mm 2, respectively.

A (sectional area of the circle) = πr ² (radius of r) = πD 2/4, the diameters of 150 mm 2 and 100 mm ² are calculated, and the outer diameters of the respective coin wires are calculated as 13.82 mm and 11.29 mm.

Since the diameter of the electric wire is a calculated diameter, in order to actually insert the electric wire into the entrance of the branch sleeve, the electric wire must be inserted smoothly into the inside of the branch sleeve. Consider the elasticity of the material when compressing the branch sleeve. Calculate the value by considering the allowance of 4 ~ 6%.

In describing an embodiment of the present invention, the first wire means a main wire and the second wire means a branch wire.

Considering the margin of 5% of the cable entry / exit gap of the branch sleeve to be used in manufacturing the branch sleeve, the cross sectional area of the coin wire is calculated as 150 mm 2 = 13.82 x (1 + 0.05) = 14.511. Actually, .

The cross sectional area of the coin wire is calculated as 100 mm 2 = 11.29 x (1 + 0.05) = 11.85, which is actually applied as 12.0 mm considering the error.

Next, in order to make a branch sleeve to be inserted into the right side by inserting the first wire 150 mm 2 into the left side and the second electric wire 100 mm 2 into the right side, the left and right sides of the hypothetical first and second post 12, The first and second circles 25 and 21 having diameters of 14.5 mm and 12 mm are formed in contact with the left and right thickness lines at the center of the transverse center line X, respectively. Next, two imaginary third and fourth circles 26 and 22, which overlap one imaginary circle of the same size in the left and right at the center of the first circle, are formed as shown in FIG.

8, imaginary circles 27 and 23 of 22.5 mm and 20 mm are formed in contact with the left and right thickness lines with respect to the vertical center line Y, respectively.

Referring to FIG. 8, when the thickness of the branch sleeve surrounding the electric wire to be connected is 4 mm, the diameter of the left and right electric wire application fifth, circles 27 and 33 for applying the thickness according to an embodiment of the present invention, Is set to 22.5 mm and 20 mm, which is the diameter of the wire + 2t.

Next, the upper and lower surfaces of the imaginary fifth circle 27 to which the main wire (thick wire) is applied among the imaginary fifth and sixth circles 27 and 23 are extended in the X axis and the upper and lower virtual The horizontal boundary lines 32 and 31 are formed as shown in Fig.

Next, referring to Fig. 10, a reference thickness (t = 4 mm) is spaced from the lines 41 and 42 contacting with the left and right imaginary third and fourth left and right outermost surfaces, Thereby forming left and right vertical boundary lines 42, 44.

11, a virtual line parallel to the longitudinal axis (Y axis) is formed in the left and right circumferences of the first and second circles 25 and 21 formed in contact with the left and right thickness lines at the center of the transverse center line X, Third and fourth internal vertical lines 46,

The virtual third and fourth inner vertical lines 46 and 45 become the borders of the curved portion of the entrance of the branch sleeve.

Next, a step of forming the outline of the first and second fan wings is performed.

12, the imaginary third and fourth inner vertical lines 46 and 45 are radially arranged with respect to the left and right vertical boundary lines 42 and 44 about a point where the imaginary third and fourth inner vertical lines 46 and 45 cross the center line (X axis) First and second half-circular lines 52 and 51 are formed to the imaginary first and second inner vertical lines 46 and 45, respectively.

Next, the reference thickness t is calculated at the virtual left and right vertical boundary lines 42 and 44 around a point at which the imaginary third and fourth inner vertical lines 46 and 45 cross the horizontal center line (X axis) The inner quarter circular lines 61 and 62 are formed to the upper side by the imaginary first and second inner vertical lines 46 and 45 with the removed distance as a radius.

After the step of forming the outline of the curved wings of the main wires and the branch wires, a step of designing the shapes of the horizontal base portion 171 and the center column body 112 is performed.

First, the horizontal base portion 171 is formed.

Referring to FIG. 13, the imaginary first and second inner vertical lines 46 and 45 and the imaginary lower horizontal boundary line 31 are connected to form a horizontal base lower line 71.

Next, the lower tangent lines of the imaginary first and third circles (25, 26) are connected to form the horizontal upper base first upper line (76).

Next, the lower tangent lines of the imaginary second and fourth circles (21, 22) are connected to form a horizontal second base second upper line (75).

Next, a step of forming protrusions 117 for forming projections formed in the outward semicircular shape is performed on the upper end portions of the first and second bent wings 151 and 152. [

14, a line connecting a half point between the center points of the hypothetical first and third circles 25 and 26 and the first inner quarter circular line 62 is defined by the first semicircular line 52 The intersection passing through the first inner quarter line is defined as the diameter between the first half circle main line 52 and the inner quarter circular line 62 so that the boundary of the circumference is in contact with the first and second inner vertical lines 46 Thereby forming a first protrusion 82.

The second projecting portion 81 is formed on the right curved wing 151 by the above-described method.

Next, a step of forming semicircular first and second groove lines 86 and 85 for forming the ridge grooves 114 formed on the central column body 112 is performed.

15, an upper side point and an upper side point where the virtual first and second column vertical lines 12 and 11 meet the imaginary fifth and sixth circles 27 and 23 and the imaginary fifth and sixth circles A line connecting the center points of the circles 27 and 23 forms first and second semicircular first and second groove lines 86 and 85 with the diameters at which the virtual first and second circles 25 and 21 meet.

The semicircular first and second groove line portions are portions where the thickness portions of the left and right branch sleeves come into contact with each other while facing each other when the branch sleeves are compressed.

Next, the step of forming the protrusion 113 formed on the central column body 112 is performed.

16, the imaginary first and second column vertical lines 12 and 11 and the imaginary upper horizontal boundary line 32 are connected to each other to form the top portion 91 of the trench.

Next, a line connecting the center point of the X and Y axes at both ends of the projection top upper line 91 is formed with dendrite inclined portions 93 and 92 connecting the intersection point of contact with the semicircular first and second groove lines 86 and 85 do.

In other words, the inclination of the protruding inclined portions 93 and 92 is such that an imaginary line extending from both ends of the upper surface of the protruding upper portion to the center point where the longitudinal center line and the transverse center line cross each other passes through the upper boundary of the protruded concave groove .

17 and 18, the design of the cross-sectional shape of the branch sleeve according to the embodiment of the present invention is completed.

The function of the projecting portion inclined portions 93 and 92 of the present invention is such that when the branch sleeve is compressed, the thickness portions of the left and right branch sleeves slip in on the inclined oblique lines, The concave grooves of the central column of the sleeve and the protrusions of the curved blade portions of the left and right sides meet to obtain a perfect connection and a strong connecting force.

As described above, the E type branch sleeve according to the present invention can be mass-produced by mass production of branch sleeves for connecting wires of various specifications, and can be provided at a very low cost. In addition, It is possible to prevent an economic loss by preventing the generation of a gap and the occurrence of a power failure due to deterioration due to corrosion of a connection portion caused by a foreign matter introduced into the gap and melting of the connection portion due to generation of heat, The maintenance cost can be reduced.

The E-type branch sleeve according to an embodiment of the present invention changes the outer diameter of a circle made according to the thickness (cross-sectional area) of the main wires and branch lines of the electric wires to be connected to the left and right sides of the branch sleeve, It is possible to manufacture a branch sleeve which is completely compression-connected regardless of the size and the size of the wire.

A branch sleeve according to an embodiment of the present invention is a branch sleeve which is constituted by a branch connection between a high voltage wire and a high voltage wire, a branch connection between a neutral wire and a neutral wire, a connection between a low voltage insulated wire and a low voltage wire connected to low voltage side terminals of a transformer installed in the pole, It can be used for branch connection between low-voltage wire and low-voltage wire.

According to an embodiment of the present invention, when a plurality of branched electric wires having the same diameter or different diameters on the connection portion are compression-connected by using a compressor, the circular structure of the electric wire is maintained as it is compared with the conventional compression sleeve And it is possible to reduce the generation of a gap.

100: Branch sleeve
112: central column
113:
114, < / RTI > 124:
117, 127: protrusion
151, 152: Curved wing portion
192, 193:

Claims (14)

In the step of designing a section of the branch sleeve which connects the first and second wires (the diameter of the first wire is equal to or larger than the diameter of the second wire)
A first and a second column virtual line forming step formed vertically at left and right sides of the vertical center line at intervals corresponding to the thickness t of the curved wing portion of the branching sleeve;
A length of the first wing center point is set to a length corresponding to the diameter of the first wire along the transverse center axis from the first column vertical line, and the thickness t is set to a radius of the first wire about the first wing center point, Forming an outer contour of the first curved wing portion, the contour of the first curved wing portion being formed by a vertical semicircle directed to the first direction side, the length being added by the radius
Forming an inner 1/4 circle forming line of a first curved wing portion formed at an upper limit 1/4 circle from the first wing center point toward a first direction in a radial direction of the first electric wire;
Forming a first protrusion formed in a semicircular shape between an upper end of the outline of the first curved wing and an upper end of the inner circumferential line of the first curved wing;
(T) is set to a radius of the second wire around the second center point of the wing, and a length of the second wing center point is set to a length corresponding to the diameter of the second wire along the transverse center axis from the second column vertical line, Forming an outer contour of the second curved wing portion formed by a vertical semicircle directed to the second direction side with a length obtained by adding the length of the second curved wing portion as a radius;
Forming an inner quarter circular line of a second curved wing portion formed at an upper-limit 1/4 circle from the second wing center point to a radial length of the second wire in a second direction; And
Forming a second protrusion part formed as a semicircle between the upper end of the outer contour of the second curved wing part and the upper end of the inner 1/4 circumferential line of the second curved wing part to form a second curved wing ; Wherein the sleeve sleeve has a first end and a second end,
The method according to claim 1,
After the step of forming the second curved wing,
A horizontal base lower line forming step of connecting a lowermost portion of the first and second curved wing portions on the lower boundary line with a line horizontally extending the lowermost portion of the outline of the first curved wing portion as a lower boundary line;
Forming a horizontal base portion first and second upper lines formed on the lower portion of the base portion with a width of the thickness t;
A step of forming an upper part of a protrusion of a central column having a portion corresponding to a vertical line section of the first and second post portions as an upper boundary on a line horizontally extending the uppermost portion of the outline of the first curved wing;
Forming a tapered inclined portion inclined inward at an end of the upper line of the projection;
Forming a protruding concave portion formed at a lower portion of the protruding inclined portion; And
Forming a central columnar body below the ridge groove; Wherein the sleeve sleeve has a first end and a second end,
The method according to claim 1,
The horizontal base first upper line forming step may include:
Forming an imaginary first circle having a diameter equal to the diameter of the first wire so as to come into contact with a virtual line of the first column on the transverse center line;
Forming a hypothetical second circle with a diameter equal to the diameter of the first wire, the first circle being perpendicular to the first direction so as to overlap the circumference at the center of the imaginary first circle; And
Connecting the lower horizontal tangent of the imaginary first circle and the lower horizontal tangent of the imaginary second circle; Wherein the step of forming the branch sleeve comprises the steps of:
The method of claim 3,
The method of claim 1,
Forming a hypothetical third circle with the center of the hypothetical first circle as a center and the radius of the hypothetical first circle plus the thickness t as a radius; And
Forming a half-circle recessed inward between a point where the imaginary third circle meets a vertical line of the first post part virtual and a circumference of the imaginary first circle; Wherein the sleeve sleeve has a first end and a second end,
5. The method of claim 4,
The forming of the central column may include:
And a line connecting the portion where the concave semicircular portion is in contact with the lower horizontal tangential portion of the imaginary first circle.
The method according to claim 1,
Wherein the diameter and the radius of the first and second electric wires are calculated to be 104 to 106% of the actual size.
3. The method of claim 2,
Wherein an inclination of the ridge inclined portion is formed by an inclination of an imaginary line extending from both ends of the ridge upper portion line to a center point where the longitudinal center line and the transverse center line intersect each other passes through an upper boundary portion of the ridge grooved groove
The method according to claim 1,
Wherein the thickness t is 2 to 6 mm.
A center column vertically formed at a central portion;
First and second bent wing portions formed in a part of the cross section of the first and second wires for compressively connecting the first and second connecting wires from the left and right sides of the center column;
A horizontal base portion connecting and supporting a lower portion of the central column and a lower portion of the first and second curved wings; ≪ / RTI >
The first and second curved wing portions have first and second protrusions formed at an upper end of the wing,
Wherein the center column body is formed to include a protruding portion formed on an upper portion thereof, and first and second protruding concave grooves formed in the inward semicircular shape are formed on the left and right sides of the protruding portion, Wherein the first and second protrusions have first and second tapered inclined portions inclined inwardly to the first and second protrusions.
10. The method of claim 9,
The outline of the first curved wing portion
Wherein a center point of the imaginary center is set to a radius of the first wire when a point spaced apart from the center point of the center column by a thickness of the first curved wing portion is defined as a virtual center along the X- The half sleeve is formed in a semicircle extending in a first direction having a length obtained by adding thickness to a radius.
10. The method of claim 9,
The outline of the second curved wing portion
And a center point of the imaginary center is set to a radius of the second wire when a point spaced apart from the center point of the center column by a thickness of the second curved wing portion is defined as a virtual center along the X- And a semicircle extending in a second direction having a length obtained by adding the thickness to the radius.
11. The method of claim 10,
And the distance between the first protrusion groove and the first protrusion is 104 to 106% of the diameter of the first wire.
10. The method of claim 9,
Characterized in that the first and second protruding concave grooves are filled with a conductive compound,
10. The method of claim 9,
Wherein the length from the lower portion of the horizontal base portion to the upper portion of the protruding portion is formed by a length of the first electric wire plus twice the thickness of the first curved wing portion.

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