KR20220075464A - Alloy stranded conductor manufacturing method - Google Patents

Abstract

The present invention relates to an apparatus for manufacturing an alloy stranded conductor, and more particularly, to an apparatus for manufacturing an alloy stranded conductor with improved progress of an alloy stranded conductor in which a plurality of alloy solid wires having high tensile strength are aggregated.
In the apparatus for manufacturing an alloy stranded conductor of the present invention, a plurality of alloy single wires extruded into the assembly die and in contact with each other are twisted with each other at a greater angle than the twist angle at the collector through the over-twist unit before entering the collector, so each alloy during the assembly process in the collector There is an advantage that production efficiency can be improved because the occurrence of loosening or twisting is prevented even when the elastic restoring force of the disconnection acts.
In addition, in the apparatus for manufacturing an alloy stranded conductor of the present invention, a plurality of twist rollers are arranged in the longitudinal direction of the twist shaft so that the inlet grooves of the plurality of twist rollers coincide on the through line of the extrusion hole of the assembly die, can be mutually twisted, and since the rotation radius of the twist shaft is reduced, there is an advantage in that the power loss of the driving motor can be reduced.

Description

Alloy stranded conductor manufacturing method

The present invention relates to a method for manufacturing an alloy stranded conductor, and more particularly, it is possible to draw a plurality of alloy solid wires having high tensile strength at the same time, and to assemble a plurality of alloy solid wires concentrated in one wire rod form by twisting them in advance before putting them into an assembly machine It relates to a method for manufacturing an alloy stranded conductor that can improve straightness during the process.

BACKGROUND ART In recent years, high-performance automobiles are rapidly progressing, and with the increase in various electric devices and control devices mounted on vehicles, the number of wires used in these devices tends to increase. On the other hand, in recent years, weight reduction is strongly calculated|required so that the fuel efficiency of conveyance apparatuses, such as an automobile, can be improved for environmental response.

In order to reduce the weight of an electric wire, the electric wire of the wire diameter of 0.5 mm or less is calculated|required, for example. The ultra-fine wire may be disconnected due to an impact or the like during routing. Accordingly, it is required to develop a copper alloy wire having high strength and high conductivity, excellent in elongation, and having characteristics suitable for wire conductors used for routing in automobiles and the like in a good balance.

Accordingly, a copper alloy wire that is an ultra-fine wire and has high strength and high conductivity and excellent elongation is being developed, and a method of manufacturing a copper alloy strand formed by twisting a plurality of these copper alloy wires together is being developed.

In general, the method for drawing metal wires is to draw wire rods with a diameter of 9.5 to 18 mm manufactured by hot rolling after continuous casting in a continuous casting machine to a Drawn wire diameter of 2.05 mm (Large diameter). wire drawing) and medium diameter wire drawing from a wire diameter of 2.05mm to a wire diameter of 0.60~0.80mm and fine diameter wire drawing from a wire diameter of 0.60~0.80mm to a wire diameter of 0.085mm. , Oil-soluble drawing lubricant, etc. is applied to the fresh oil applied to this drawing process.

By the way, a single drawing machine is mainly used for the manufacture of a Taeshin wire, and a continuous drawing machine is used for the manufacture of a fine wire drawing machine. That is, since there is no technology for a separate dedicated drawing machine for the medium drawing machine, and the medium drawing machine is manufactured by combining a single drawing machine and a continuous drawing machine, many difficulties follow in the manufacturing process. In addition, it takes a lot of time to manufacture a large amount of the drawing material, and there is a difficulty in manufacturing a uniform drawing material.

On the other hand, in a copper alloy strand in which a plurality of copper alloy wires are twisted, elastic restoring force acts in the opposite direction to the spiral twisting direction of a plurality of copper alloy wires due to the high tensile strength of the copper alloy wire, so that a plurality of disconnections or twists may occur, If the assembly speed of the copper alloy wire is increased, the elastic restoring force is increased.

In order to solve this problem, a plurality of copper alloy wires are twisted more than the spiral direction to be twisted in the aggregator, and an over-twist device is installed to prevent loosening or twisting after assembling.

However, the overall assembly speed may be reduced due to the over-twisting device, so a device with improved over-twisting efficiency while maintaining or improving the overall assembly process speed is required.

Republic of Korea Patent Registration No. 10-0623049: Aluminum tube bundle automatic drawing device Republic of Korea Patent Publication No. 10-0279564 : Over-twist driving device of wire twisting machine

The present invention is to solve the above problems, and it is possible to uniformly manufacture a plurality of alloy single wires (wires) with various diameters such as thin wire, middle wire, and Taeshin wire at the same time, thereby shortening the manufacturing time and improving the working efficiency An object of the present invention is to provide a method for manufacturing an alloy stranded conductor.

In addition, the present invention provides an apparatus for manufacturing an alloy stranded conductor that can be expected to improve the overall assembly speed by improving the over-twist efficiency while having a simple over-twist structure applied before the assembly machine applied to improve straightness when assembling a large number of single alloy wires. would like to provide

According to the method for manufacturing an alloy stranded conductor of the present invention for achieving the above object, a plurality of alloy wires are drawn in multiple stages at the same time using an alloy wire multi-drawing device, and then formed into a plurality of single alloy wires with uniformly reduced outer diameters. A multi-drawing step of winding on a single reel; After arranging a plurality of single alloy wires in a certain pattern, an aggregation step of twisting them in a compressed state into one wire rod shape;

The assembling step includes: an alloy single wire arranging step of unwinding a plurality of the single alloy wires wound in the multi-drawing step and passing them through an array plate spaced apart from each other at regular intervals; an alloy single wire compression step of passing a plurality of the arranged single alloy wires through a set die and compressing them to be concentrated in a single wire rod shape; A plurality of alloy broken wires concentrated in the aggregation die enter the over-twist unit to extend in the collector direction, move away from the direction crossing the through-line of the extrusion hole of the assembling die, and then change their direction to be adjacent again, and then in the collector direction an over-twisting step of extending the over-twisting unit so that a plurality of the alloy single wires are twisted in a helical direction when the twist shaft of the over-twist unit rotates; As the twist shaft is rotated, a plurality of single alloy wires twisted together in the form of a single alloy stranded wire are transferred into the collector and twisted again inside the collector to be wound on a second take-up reel provided inside the collector. It is characterized in that it includes a winding step.

The over-twist unit includes a housing having an inner space so that the twist shaft is mounted, a shaft driving unit mounted on the housing and rotating the twist shaft, and a plurality of the twist shafts when the twist shaft rotates by changing the direction of movement of the plurality of alloy wires. and a plurality of twist rollers disposed in the twist shaft longitudinal direction in the twist shaft so that the alloy single wire is twisted, the twist shaft extending longitudinally from the assembly die in the collector direction and rotatably mounted on both sides to the housing and the inner side is penetrated along the through extension line of the extrusion hole, and a plurality of twist rollers are respectively installed to be deflected to one side in the width direction of the twist shaft, and the plurality of disconnected alloy wires introduced into the twist shaft in the width direction of the twist shaft A first twist roller for changing the direction, a second twist roller for changing the direction of the plurality of broken wires of the alloy changed in the first twist roller toward the center of the twist width; It is preferable to include a third twist roller for inducing movement toward the collector by changing the direction of the alloy disconnection in the longitudinal direction of the twist axis.

The multi-drawing step is an alloy wire supply step of moving a plurality of alloy wires in parallel in one direction, and a plurality of alloy wires are arranged on each outer circumferential surface of a plurality of drawing drums spaced apart from each other in one direction of the multi-drawing device for alloy wires. After being wound at least once in the circumferential direction and then extended, a plurality of wire drawing drums are rotated in the same direction at the same time, and a plurality of the alloy wire rods pass through a plurality of drawing dies positioned between the adjacent wire drawing drums. It is preferable to include a winding step of winding the plurality of alloy wire rods formed while the plurality of alloy wires are drawn while passing through the plurality of drawing dies.

The alloy wire multi-drawing device includes an alloy wire supply unit for feeding a plurality of alloy wires in parallel in one direction, and the drawing dice positioned between the mutually adjacent wire drawing drums and drawing one alloy wire with a small diameter. an alloy wire wire drawing portion having a plurality of die support portions each arranged in plurality in a direction crossing the longitudinal direction of the alloy wire rod; a wire-drawing part winding part for winding each of the plurality of wire-drawing materials manufactured while the plurality of alloy wires pass through the wire-drawing part; A plurality of the drawing drums are mutually connected so that one of the drawing drums rotates at a slower speed than the other drawing drum adjacent to the direction in which the alloy wire is moved so as to reduce the slip of the alloy wire extending in length while being drawn. It is preferable to include; a rotation driving unit for rotating at different rotational speeds.

According to the method of manufacturing an alloy stranded conductor of the present invention, a plurality of alloy single wires extruded into the aggregation die and in contact with each other are twisted with each other at a greater angle than the twist angle at the collector through the over-twist unit before entering the collector. There is an advantage that production efficiency can be improved because the occurrence of loosening or twisting is prevented even when the elastic restoring force of the disconnection acts.

In addition, in the method of manufacturing an alloy stranded conductor of the present invention, a plurality of twist rollers are arranged in the longitudinal direction of the twist axis so that the inlet grooves of the plurality of twist rollers are aligned on the through line of the extrusion hole of the assembly die, and a plurality of alloy single wires with a simple structure can be mutually twisted, and since the rotation radius of the twist shaft is reduced, there is an advantage in that the power loss of the driving motor can be reduced.

In addition, in the method for manufacturing an alloy stranded conductor of the present invention, the distance between the first to third twist rollers and the length of the alloy single wire extended in the width direction of the twist axis by the second twist roller according to the material or tensile strength of the alloy single wire can be adjusted, there is an advantage that the use efficiency of the over-twist unit can be improved.

1 is a block diagram of a method for manufacturing an alloy conductor stranded wire according to a first embodiment of the present invention;
2 is a schematic view of an alloy wire multi-drawing device of the alloy stranded conductor manufacturing system applied to the alloy conductor stranded wire manufacturing method of FIG. 1;
3 is a partial cross-sectional view showing a state in which the alloy wire is drawn through the die of the multi-drawing device for the alloy wire of FIG. 2;
4 is a partially enlarged perspective view of the metal wire drawing part of FIG. 3;
5 is a partial side view of the alloy stranded conductor manufacturing apparatus of the alloy stranded conductor manufacturing system applied to the alloy conductor stranded conductor manufacturing method of FIG. 1;
6 is a partial perspective view of an over-twisted unit of the apparatus for manufacturing an alloy conductor stranded wire of FIG. 5;
7 is a partial longitudinal sectional view of the twist axis of the apparatus for manufacturing an alloy stranded wire conductor according to a second embodiment of the present invention;
8 is a partial perspective view of an over-twist unit of an apparatus for manufacturing an alloy stranded conductor according to a second embodiment of the present invention;
9 is a perspective view showing an arranged state of the first to third twist rollers of FIG. 8;
10 to 12 are views of the first to third twist rollers viewed in the direction in which a plurality of alloy disconnections proceed.

Hereinafter, a method for manufacturing an alloy stranded conductor according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

The method for manufacturing an alloy stranded conductor of the present invention largely consists of a multi-drawing step (S1) and an assembling step (S10).

The multi-drawing step (S1) is a step of winding a plurality of alloy wires 1 at the same time after drawing with a uniform force. In the aggregation step (S10), a plurality of alloy wires (1') produced by drawing a plurality of alloy wires (1) in the multi-drawing step (S1) are unwound, arranged in a certain pattern, and then concentrated again by twisting the alloy It is a step of manufacturing a stranded wire (1").

Before describing the multi-drawing step (S1) in detail, an alloy wire multi-drawing device 5 capable of drawing a plurality of alloy wires 1 will be described.

The alloy wire rod is a linear member made of an alloy material made of copper and tin having ductility that can be stretched in length and reduced in diameter when pressed and drawn through a drawing die 73 to be described later.

The alloy wire multi-drawing device 5 includes an alloy wire supply unit 10 for transferring a plurality of alloy wires in parallel in one direction, and an alloy wire drawing portion 60 for simultaneously drawing a plurality of transferred alloy wires with a uniform force, and , a plurality of alloy wires (1) is provided with a winding unit (100) is wound a plurality of alloy single wire (1') is wound.

Referring to FIG. 2, the alloy wire supply unit 10 is a plurality of wire rod loading frames 20 in which each alloy wire 1 is loaded in a circular shape and spaced apart from each other in the left and right directions and in one direction in which the plurality of alloy wires 1 are moved. )class; Although not shown, it is located between the wire rod loading frames 20 spaced apart in the left and right directions and is spaced apart from each other in one direction to guide the alloy wire 1 of the wire loading frame 20 to be transported in one direction. A guide frame unit (30) is provided.

The wire loading frame 20 has a circular base plate 21, extending vertically upward from the edge of the base plate, spaced apart from each other in the circumferential direction and extending in the circumferential direction, and the loading outer diameter of the alloy wire 1 loaded with a plurality of It includes an outer diameter guide bar 23 and a plurality of inner diameter guide bars 25 spaced apart from each other in the inner side of the base plate 21 with respect to the plurality of outer diameter guide bars 23 and spaced apart from each other in a circumferential direction.

The plurality of wire loading frames 20 are positioned on both sides of a plurality of transport guide frame units 30 to be described later and are disposed at positions spaced apart from each other at regular intervals in one direction.

Although not specifically shown, the plurality of transfer guide frame units 30 include first and second vertical bars (not shown), first and second rotating bars 34 and 41 , and first and second guides. Rollers (37, 43), first to third auxiliary rollers (38, 39, 40), fourth to sixth auxiliary rollers (44, 45, 46), and third and fourth guide rollers (47, 49) ) are provided respectively.

The first and second vertical bars (not shown) extend vertically longer than the wire loading frame 20 , and both sides of the horizontal bar 33 are connected to each other at each upper end and are spaced apart from each other in the left and right directions.

The first pivot bar 34 is mounted on an upper end of the first vertical bar so as to be able to rotate horizontally with respect to the first vertical bar. One end of the second pivot bar 41 is mounted on the upper end of the second vertical bar 32 to be horizontally rotatable with respect to the second vertical bar 32 .

The first guide roller 37 is mounted rotatably up and down on the upper portion of the first vertical plate 35 mounted on each other end of the first rotation bar 34 , and the alloy wire rod 1 loaded on the wire rod loading frame 20 . ) is guided in the direction of one side of the first rotation bar (34). The first to third auxiliary rollers 38 , 39 , 40 are vertically spaced apart from the lower portion of the first vertical plate 35 so that the alloy wire 1 is staggered to maintain tension when transporting the alloy wire 1 . mounted in contact with

The second guide roller 43 is mounted rotatably up and down on the upper portion of the second vertical plate 42 mounted on each other end of the second rotation bar 41 , and the alloy wire rod 1 loaded on the wire rod loading frame 20 . ) is guided in the direction of one side of the second rotating bar (41). The fourth to sixth auxiliary rollers 44, 45 and 46 are vertically spaced apart from the lower portion of the second vertical plate 42 so that the alloy wire 1 is staggered to maintain tension when the alloy wire 1 is transported. mounted in contact with

The third guide roller 47 is rotatably mounted on one end of the first rotation bar 34 to guide the alloy wire 1 to the horizontal bar 33 , and penetrates one end of the first rotation bar 34 . It is rotatably mounted on the upper end of the first rotation shaft (34a). The fourth guide roller 49 is horizontally rotatably mounted on one end of the second rotation bar 41 to pass through one end of the second rotation bar 41 to guide the alloy wire 1 to the horizontal bar 33 . It is rotatably mounted on the upper end of the second rotation shaft (41a).

In addition, although not shown, the transport guide frame unit 30 is mounted on a horizontal bar connecting the first vertical bar and the second vertical bar, and is mounted on the horizontal bar and extends in a direction in which the first and second vertical bars are spaced apart from each other. It may be provided with a wire guide plate through which a plurality of wire through-holes (not shown) are formed, which are penetrated through the upper side protruding to each other and are spaced apart from each other in the longitudinal direction, through which a plurality of alloy wires are extended and transported.

The alloy wire 1 may be transferred by a pulling force from the alloy wire wire drawing unit 60 to be described later. Although not shown, the first and second vertical plates 35 and 42 have a first guide roller 37 . Alternatively, an auxiliary feeding force providing driving motor may be mounted to rotate the second guide roller 43 to assist the movement of the alloy wire 1 .

The alloy wire drawing unit 60 includes a housing (not shown), a plurality of drawing drums 66 , a plurality of dies 73 , a plurality of dice support parts 75 , and a rotational driving part (not shown). .

The housing has an inner space open to one side, and a wire through hole (not shown) through which a plurality of alloy wires 1 can be penetrated and extended is formed on one side and the other side of the direction intersecting the inner space on the open side, respectively, It is formed so that a plurality of drawing drums 66 and a plurality of die support parts 75 can be mounted on the inner side.

The plurality of drawing drums 66 are spaced apart from each other in one direction, and the plurality of alloy wires 1 introduced from the alloy wire supply unit 10 are wound at least once along the circumferential direction on the outer circumferential surface, respectively, and then extend to the same. While rotating in the direction, a plurality of alloy wires 1 are pressed or pulled in one direction.

The drawing drum 66 includes a first housing coupling part 71 bolted to the housing, and a drum body 67 extending from the first housing coupling part 71 to an open side of the inner space of the housing.

The drum body 67 protrudes along the circumferential direction on the outer circumferential surface so that the plurality of alloy wires 1 wound on the outer circumferential surface do not come into contact with each other, and is spaced apart from each other at regular intervals in the longitudinal direction to form a plurality of partition grooves 69 together. A plurality of auxiliary partitions protruding lower than the main partition 68 on the central side of the partition groove 69 formed between the main partition 68 and the adjacent main partitions 68 and extending in the circumferential direction. (70) is provided. The drum body 67 is coated with ceramic to reduce friction with the alloy wire 1 on the outer peripheral surface to which the alloy wire 1 is in contact.

The plurality of die support parts 75 are located between the mutually adjacent drawing drums 66 and the dice 73 for drawing one alloy wire 1 with a small diameter intersect in the longitudinal direction of the alloy wire 1 . As a result, multiple dogs are mounted in an array.

The die support part 75 includes a second housing coupling part 77 that is bolted to the housing, and the inner space 62 of the housing 61 is extended from the second housing coupling part 77 to the side to which the wire drawing drum 66 is opened. ) and a die support body 76 extending in length in parallel with it.

In addition, the dice support part 75 includes a plurality of first dice support protrusions 81 , a plurality of second dice support protrusions 84 , a plurality of third dice support protrusions 88 , and a vertical jaw 78 . be prepared

The plurality of first die support protrusions 81 protrude upwardly on the upper portion of the die support body 76 and are spaced apart from each other in the longitudinal direction of the die support body 76 so that the alloy wire 1 penetrates through the plurality of first die support protrusions 81 . As the first group 83 forming the one-wire through portion 82 , one side or the other side of the die 73 is supported.

The plurality of second dice support protrusions 84 are a second group 86, which protrude upward on the upper part of the dice support body 76, and are spaced apart from each other in the longitudinal direction of the die support body so that the alloy wire 1 is penetrated. to form a plurality of second wire rod through portions 85 . The plurality of second dice support protrusions 84 are spaced apart from the first dice support protrusions 81 in the through-extending direction of the alloy wire 1, that is, in the pulling direction, with respect to the facing first dice support protrusions 81 and Together, the first die receiving portion 87 in which the die 73 can be accommodated is formed. One side or the other side of the plurality of second dice support protrusions 84 is supported on one face facing the first dice support protrusion 81 and the other face of the dice 73 accommodated in the first dice receiving part 87, respectively.

The plurality of third dice support protrusions 88 are the third group 91, which protrude upward on the upper part of the dice support body 76, and the length of the die support body 76 so that the alloy wire 1 is penetrated. are spaced apart from each other in the direction to form the third wire rod through portion 90 . The plurality of third dice support protrusions 88 are spaced apart from each other in the penetration direction of the alloy wire 1 with respect to the second dice support protrusions 84 to accommodate the dice 73 together with the plurality of second dice support protrusions 84 . A second dice accommodating part 92 that can be formed is formed. One side or the other side of the plurality of third dice support protrusions 88 is supported on one face facing the second dice support protrusion 84 and the other face of the dice 73 accommodated in the second dice accommodating part 92, respectively.

The first to third die support protrusions 81, 84, and 88 have a constant width in the direction through which the alloy wire 1 passes, but the width in the longitudinal direction of the die support body 76 is close to the die support body 76. Each is formed to expand as it increases.

In addition, the second and third dice support protrusions 84 and 88 are provided on the upper ends of each surface so that the dice 73 accommodated in the first dice accommodating part 87 or the second dice accommodating part 92 are prevented from being separated upward. Departure bumps 89 are formed, respectively.

The vertical jaw 78 extends upwardly from the end of the dice support body 76 in parallel with the housing coupling part 77, and the dice 73 accommodated in the first or second dice accommodating parts 87 and 92 is prevent escaping.

And, the dice support part 75 is formed on the vertical jaw 78 so that the dice 73 into which the first dice accommodating part 78 and the second dice accommodating part 87 are inserted on the edge side can be mounted at alternating positions. A first support groove 79 that is drawn into the vertical jaw 78 side of the second dice accommodating part 92 and opened upward, and a first dice accommodating part corresponding to the first dice accommodating part 87 side ( 87) and a second support groove 80 that is opened upwardly is formed.

Although not shown, the rotation driving unit includes a plurality of rotating motors (not shown) for rotating each wire drawing drum 66 , a control unit for controlling the driving of the rotating motor, and an operation unit for transmitting a driving command of the rotating motor to the control unit can be provided A plurality of rotating motors may be mounted on the outer side of the housing, and each driving shaft may be extended into the inner space of the housing to be coupled to a single drawing drum 66 .

The controller controls the rotating motor so that the plurality of drawing drums 66 are rotated at different rotational speeds. The control unit allows one drawing drum 66 to reduce the slip of the alloy wire 1 extending in length while being drawn at a slower speed than the other drawing drum 66 adjacent to the direction in which the alloy wire 1 is moved. Drive the rotary motor to rotate.

In addition, the drawing dies 73 having smaller through holes 74 in the direction in which the alloy wire 1 is drawn are seated on the plurality of die support portions 75 .

Referring to FIG. 3 , the first dice accommodating part 87 or the second dice accommodating part 92 of one dice support part 75 so that the alloy wire 1 can be extended in length while the diameter is reduced as the drawing is moved. The through-holes 74' of the plurality of drawing dies 73' seated in the dies are the first dice receiving part 87 or the second dice of the other dice support part 75 adjacent to the side where the alloy wire 1 flows in. It is formed to be smaller than the through-holes 74 of the plurality of drawing dies 73 seated in the receiving portion 92 .

Referring to FIG. 1 , the wire winding unit 100 is a first plurality of wire rods 1 each winding a plurality of wire rods 1 ′ manufactured while passing through the alloy wire drawing unit 60 . A winding reel 101 and a winding motor (not shown) for rotating the plurality of winding drums 101 are provided.

Meanwhile, the manipulation unit 98 may include a plurality of buttons or levers. A plurality of buttons or levers may drive or stop the rotation driving unit and the driving motor.

In the multi-drawing step (S1) using the multi-alloy wire drawing device 5 as described above, as the plurality of alloy wires 1 are unwound from the wire loading frame 20, the plurality of transfer guide frame units 30 are The alloy wire supply step (S2) of moving the alloy wire drawing unit 60 through the alloy wire drawing unit 60, and the plurality of alloy wire rods 1 in the plurality of drawing drums 66 provided in the alloy wire drawing unit 60 are rotated by one rotation, respectively. The alloy wire drawing step (S4) of continuously drawing a plurality of alloy wires 1 by passing them through the dies 73 positioned between the plurality of drawing drums 66 while conveying them side by side, and the alloy wire drawing step It includes a winding step (S6) of winding a plurality of the completed alloy disconnection wire (1') through the wire winding unit (100).

The alloy wire 1 is a linear conductor containing copper and tin, and may be formed into a single alloy wire 1' having a diameter of 0.13 to 0.17 mm through a multi-drawing step (S1).

On the other hand, the aggregation step (S10) is a step of forming a stranded alloy conductor by compressing and aggregating a plurality of freshly drawn alloy wires 1 ′ and twisting them.

Prior to describing the aggregation step (S10), an apparatus for manufacturing an alloy stranded conductor 201 for manufacturing a stranded alloy conductor by twisting a plurality of single alloy wires 1 ′ will be described.

The apparatus 201 for manufacturing an alloy stranded conductor of the present invention manufactures an alloy stranded conductor by twisting a plurality of alloy solid wires 1 ′, and a plurality of alloy single wires 1 ′ supplied from at least one first winding reel 101 . ) and an arrangement plate 220 for arranging; an assembly die 230 for concentrating and extruding a plurality of single alloy wires 1' supplied from the arrangement plate; an over-twist unit 240 for extending a plurality of alloy single wires 1 ′ concentrated while being drawn out from the assembly die 230 while twisting the spiral direction; It includes a;

A plurality of single alloy wires 1 ′ are concentrated in the form of one wire rod through the assembly die 30 , and then twisted while passing through the over-twist unit 40 to form a stranded wire 1 ″.

The alloy stranded conductor manufacturing apparatus 201 of the present invention has one end fixedly mounted on a twisted housing 241 of an over-twisted unit 240 to be described later and extended in a direction away from the collector 300, and includes an arrangement plate 220 and , the assembly die 230 is provided with a compression position adjustment frame 210 to which the position adjustment is mounted.

Compression position adjustment frame 210 is formed with a plurality of scales spaced apart in the longitudinal direction on the upper surface.

The apparatus 2011 for manufacturing an alloy stranded conductor of the present invention includes a first position adjusting member 224 that supports an arrangement plate 220 and is movably mounted on a compression position adjustment frame 210, and a set die 230. It supports and further includes a second position adjustment member 234 movably mounted on the compression position adjustment frame 210 .

The first position adjusting member 224 is movably moved in the longitudinal direction of the compression position adjusting frame 210 through which the compression position adjusting frame 210 passes, and a first through hole 226 having one side open is formed and arranged on the upper portion The first position adjustment body 225 to which the plate 220 is mounted, and the first through hole 226 are screwed to the first position adjustment body 225 to cross the open side of the first through hole 226, the first through hole 226 By adjusting the width of the open side of the first position adjustment body 225 is provided with a first fixed adjustment lever 228 to be fixed or movably adjusted on the compression position adjustment frame 210.

The arrangement plate 220 extends upwardly on the upper portion of the first position adjustment body 225 and has a width in a direction crossing the longitudinal direction of the compression position adjustment frame 210, and a plurality of single alloy wires 1 ′ are arranged at regular intervals. A plurality of single wire guide holes 221 are formed at regular intervals in the circumferential direction around the center side and the center side so as to be spaced apart from each other and penetrate therethrough.

The second positioning member 234 is movable in the longitudinal direction of the compression positioning frame 210 on the compression positioning frame 210 between the first positioning member 224 and the over-twist unit 240 . The compression position adjustment frame 210 passes through the second position adjustment body 235 in which a second through hole 236 having one open side is formed, and the second position adjustment body 235 to cross the open side of the second through hole 236 . The second position adjustment body 235 is fixed or movable on the compression position adjustment frame 210 by adjusting the width of the open side of the second through hole 236 by being screwed to the position adjustment body 235 . and a second fixed control lever 238, and a lower portion mounted on the upper portion of the second position adjustment body 235, extending upward, and provided with an aggregate die mounting plate 239 on which the aggregate die 230 is mounted on the upper portion. .

The assembling die 230 has a narrower width in the direction of the over-twist unit 240 from the arrangement plate 220 so that a plurality of single alloy wires 1 ″ can be extruded while being mutually concentrated, and then an expanded extrusion hole 231 is formed. It is mounted on the assembly die mounting plate 239 so that the alloy single wire 1 ′ passing through the center of the arrangement plate 220 and the extrusion hole 231 are positioned on the same horizontal line.

The over-twist unit 240 includes a twist housing 241 having an inner space (not shown), a length extension from the assembly die 230 to the collector 300, and is rotatably mounted on both sides to the housing 241, A twist shaft 245 through which the inner side passes along the diameter line (a) of the extrusion hole 231 of the assembly die 230, a shaft drive unit 260 for rotating the twist shaft 245, and an alloy wire (1') A plurality of twist rollers 251,254 and 257 disposed in the twist shaft 245 longitudinal direction are provided in the twist shaft 245 so that a plurality of alloy single wires are twisted with each other when the twist shaft 245 rotates by changing the direction of their extension.

Both ends of the twist shaft 245 are mounted through the plurality of bearings 243 mounted on both sides of the housing 241 in the direction of the collector 300 in the arrangement plate 220 . A driven pulley 267 of the shaft driving unit 260 to be described later is mounted on the twist shaft 245 on one side in the longitudinal direction adjacent to the collector 250 .

Twisted shaft 245 connects a plurality of bearing parts 246 to which bearings are mounted on both sides in the longitudinal direction, and a shaft body part 249 that connects the plurality of shaft parts 246 and has an outer diameter larger than that of the shaft part 246 . be prepared The shaft body portion 249 is opened on both sides in the width direction and extends in the longitudinal direction to mount a plurality of twist rollers 251,254 and 257, and a plurality of alloy single wires 1 ′ change the direction to the first to third twist rollers 251,254 and 257. The twist space 250 is formed while extending in the direction of the collector 300 and twisting each other.

Each bearing portion 246 of the twist shaft 245 is formed through a through-line (a) of the extrusion hole 231, and a single wire entry hole 247 or a single wire withdrawal hole 248 communicating with the twist space 250 is provided. is formed (see Fig. 7).

The plurality of twist rollers are respectively installed to be deflected to one side in the width direction of the twist shaft 245, and the plurality of alloy wires 1 ′ introduced into the twist shaft 245 are turned in the width direction of the twist shaft 245. The first twist roller 251 and the second twist roller 254 for changing the direction of the plurality of alloy single wires 1 ′ changed in the first twist roller 251 toward the width center side of the twist shaft 245 and, It is divided into a third twist stroller 257 that induces movement toward the collector 300 by changing the direction of a plurality of alloy single wires 1 ′ changed in the second twist roller 254 in the longitudinal direction of the twist shaft 245 . do.

The first to third twist rollers 251,254 and 257 are rotatably mounted in the twist space 250, and lead-in grooves 252, 255, and 258 introduced along the circumferential direction to accommodate a large number of concentrated alloy disconnection wires 1 ′ are respectively formed. .

The first to third twist rollers 251,254 and 257 are mounted to be deflected to one side in the width direction of the twist shaft 245 so that each inlet groove 252 , 255 , 258 is positioned on the through extension line of the extrusion hole 231 .

Referring to FIG. 4 , the respective inlet grooves 252,255,258 of the first to third twist rollers 251,254 and 257 are formed to become narrower toward the center of the first, second or third twist rollers 251,254,257. Both sides of the first, second or third twist rollers 251,254 and 257 are respectively formed in such a way that they have the same slope on the diameter line.

The shaft driving unit 260 includes a driving motor 261 mounted on the housing 240 to be positioned in the inner space of the housing 40, and a driving pulley 265 mounted on the driving shaft 263 of the driving motor 261, A driven pulley 267 mounted on one side bearing portion 246 of the twist shaft, and a driving belt 269 connecting the driving pulley 265 and the driven pulley 267 are provided. However, unlike shown, the shaft driving unit 260 includes a driving motor 261, a first gear (not shown) mounted on the driving shaft 263 of the driving motor 261, and one side bearing 246 of the twist shaft. A second gear (not shown) which is mounted and meshed with the first gear may be provided.

Although not shown, the over-twist unit 240 is mounted on the outside of the housing 240 and connected to the driving motor 261, and a knob switch for driving and stopping the driving motor 261, and stopping the driving motor in case of emergency An emergency stop button for the may be provided.

The aggregation step (S10) using the alloy stranded conductor manufacturing apparatus 201 having the structure as described above includes an alloy single wire arrangement step (S12), an alloy single wire compression step (S14), an over-twist step (S16), and aggregation It includes a winding step (S18).

In the alloy disconnection arrangement step (S12), one alloy disconnection wire 1' among the alloy disconnection wires 1' to be unwound from the first winding reel 101 is passed to the center side of the arrangement plate 220, and the remaining alloy The single wires 1 ′ are a step of passing through the array plate 220 to be spaced apart from each other in a circumferential direction with a single alloy wire 1 ′ passing through the center of the array plate 220 .

The single alloy wire compression step (S14) is to pass the single alloy wire 1', which has passed through the arrangement plate 220, through the extrusion hole 231 of the assembly die 230 to be compressed while being in close contact with each other to concentrate it into a single wire rod shape. is a step The extrusion hole 231 of the assembly die 230 is formed to have a narrow inner diameter from both sides parallel to the penetration direction toward the center, and a plurality of single alloy wires 1' are compressed and aggregated to obtain a diameter of 0.42 to 0.51 mm. To achieve this, it is preferable that the smallest inner diameter is formed through 0.42 to 0.51 mm.

The over-twisting step (S16) is assembling the broken alloy wires 1 ′ that have entered the twist shaft 245 of the over-twist unit 240 from the assembling die 230 while being guided to the first to third twist rollers 251,254 and 257 while being guided. This is a step of twisting a plurality of single alloy wires 1 ′ by rotating the twist shaft 45 after moving away from and adjacent to each other in a direction perpendicular to the through line of the extrusion hole 231 of the die.

As the twist shaft 245 is rotated, an external force is applied to the broken alloy wires 1' in a direction perpendicular to the through line of the extrusion hole 231, so that the single alloy wires 1' are one alloy stranded wire (1") are intertwined in the form.

In the collective winding step (S18), the single alloy stranded wires (1") twisted in the form of alloy single wires 1' are transferred to the collector 300 and twisted inside the collector 300 while being twisted inside the collector 300. It is a step to be wound on the second winding reel (not shown) provided in. The collector 300 is not specifically shown, but as a general one, a single alloy wire (1') twisted in the form of a single alloy stranded wire (1"). ) is not limited as long as it has a structure that can be wound while twisting.

In the method for manufacturing an alloy stranded conductor according to the first embodiment of the present invention, a plurality of extrusion dies 73 having different inner diameters of through-holes for wire drawing are mounted on the die support part 75 between the plurality of wire drawing drums 66, respectively. Therefore, a plurality of alloy wire rods 1 can be manufactured with wire rods of various diameters, such as thin wire, middle wire, and Taeshin wire, so that manufacturing efficiency can be improved.

In addition, in the method for manufacturing an alloy stranded conductor according to the first embodiment of the present invention, a plurality of alloy single wires that are extruded to the aggregation die 330 and are in contact with each other enter the aggregator 300 before entering the aggregator 300 through an over-twisted unit. Since the twist angle is greater than the twist angle in the aggregator 300, even if the elastic restoring force of each alloy disconnection 1 ' acts during the assembly process in the collector 300, the occurrence of loosening or twisting is prevented, so there is an advantage that production efficiency can be improved. .

In addition, in the method of manufacturing an alloy stranded conductor according to the first embodiment of the present invention, a plurality of twist rollers are twisted shaft ( 345), it is possible to mutually twist a plurality of alloy single wires 1' with a simple structure, and since the rotation radius of the twist shaft 345 is reduced, there is an advantage of reducing power loss of the driving motor .

11 shows an over-twisted unit 340 according to a second embodiment of the present invention. The over-twisted unit 340 according to the second embodiment of the present invention is an over-twisted unit 240 according to the first embodiment of the present invention, except that it further includes first and second tension adjusting units 280 and 290 . has the same structure as

In the over-twist unit 340, the inlet groove 255 of the second twist roller 254 is located on the diameter line of the inlet grooves 252 and 258 and the extrusion hole 231 of the first and third twist rollers 251,257, or the first With respect to the first tension adjusting unit 280 and the second twisting roller 254, the second twist roller 254 moves to protrude outward on the extension line through the extrusion hole 231 in the width direction of the twist shaft 245 A second tension adjusting unit 290 capable of adjusting the separation distance between the first and third twist rollers 251,254 may be further provided.

The first tension control unit 280 is mounted on the other side in the width direction of the twist space 250 from the longitudinal center side of the twist space 250 and extends in the direction of the second twist roller 254. The first pressure cylinder 281 And, a rod 283, one side of which is movably received in the direction of the second twist roller 254 in the first addition cylinder 281, and a second twist roller 254 rotatably mounted to the end of the rod 283 ) and a pressure roller 285 in contact with it.

The second twist roller 254 is mounted so that both sides of the second roller shaft 256 are movable in the width direction of the twist shaft 245 to be movable in the width direction of the twist space 250 .

Twisted shaft 245 is a second roller shaft insertion hole (not shown) into which both sides of the second roller shaft 256 are inserted, extending in the width direction in the form of a long hole, and inserted into the second roller shaft insertion hole, the second roller An elastic member (not shown) for elastically supporting the shaft 256 is mounted.

The second tension control unit 290 is mounted on both sides of the twist space 250 in the longitudinal direction, and the second and third pressurizing cylinders 291,293 extending in the second twist roller 254 direction, and the second or third Each side of the subscription cylinders 291,293 is accommodated in a forward and backward direction in the second twist roller 254 direction, and the first roller shaft 253 of the first twist roller 254 or the second roller of the second twist roller 254 The shaft 256 has second and third rods 292 and 294 through it.

In the twist shaft 245, second and third roller shaft insertion holes into which both sides of the first and second roller shafts 253 and 259 are inserted extend in the longitudinal direction in the form of a long hole.

In addition, the over-twist unit 340 includes a fluid storage tank for supplying fluid to the first to third pressurized cylinders 281,291 and 293, and the first to third pressurized cylinders 281,291,293 branched from the main fluid supply pipe extending from the fluid storage tank. ), a fluid supply pump mounted on one side of the fluid main supply pipe to pump the fluid of the fluid storage tank, and a plurality of on-off valves respectively mounted on the plurality of branch fluid supply pipes.

In the method for manufacturing an alloy stranded conductor according to a third embodiment of the present invention, the first to third twist rollers 251,254 and 257 are spaced apart from each other according to the material or tensile strength of the alloy single wire, and the twist shaft 245 is twisted by the second twist roller. ), since the length of the single alloy wire extending in the width direction can be adjusted, the application range of the over-twisted unit is expanded, so there is an advantage that the application efficiency can be improved.

Meanwhile, FIGS. 8 to 12 show an over-twisted unit according to a third embodiment of the present invention. In the drawings shown above, components having the same function are denoted by the same reference numerals.

The over-twist unit 440 according to the third embodiment of the present invention is located on the through-line of the extrusion hole 31 on one side of each of the first to third twist rollers 251,254,257, and the other side is mounted to be staggered, The lower portion of the twist space 450 extends in parallel on the through-line of the extrusion hole 31 so that the first to third twist rollers 251,254 and 257 are mounted on the twist shaft 245 at different inclinations, and the upper portion is the extrusion hole 31 ) is the same as the structure of the over-twisted unit 240 according to the first embodiment of the present invention, except that it is formed apart in a step form on the through line of the present invention.

In the first twist roller 251 , an inlet groove 252 on one side is positioned on a through extension line of the extrusion hole 31 , and the other end is positioned in the radial direction of the twist shaft 245 .

10 to 12 , the inlet groove 255 of the second twist stroller 254 has an angle formed by the opposite side surfaces f' ₁ , f' ₂ of the first twist roller 251 in the inlet groove of the first twist roller 251 . The both sides of the 253 (f ₁ , f ₂ ) are formed to form an angle (c) equal to the angle formed, and the second twist roller 254 is rotated by the twist shaft 245 with respect to the first twist roller 251. One side (f' ₁ ) of the inlet groove 255 on the upper end side of the second twist roller 254 is inclined in the direction to be It has a higher slope than the one side (f ₁ ).

In addition, the inlet groove 258 of the third twist roller 257 is formed by the opposite side surfaces f" ₁ , f" ₂ , the opposite side surfaces f of the inlet groove 253 of the first twist roller 251 . ₁ , f ₂ ) is formed to form the same angle (c) as the angle formed, the third twist roller 257 is inclined in the direction in which the twist shaft 245 is rotated with respect to the second twist roller 254, The other side surface (f" ₂ ) of the inlet groove 258 on the lower end side of the third twist roller 257 has an inclination in the rotational direction of the twist axis.

10 to 12, the method for manufacturing an alloy stranded conductor according to a third embodiment of the present invention is the other surface of the upper end side inlet groove 255 of the second twist roller 254 when the twist shaft 245 rotates ( f' ₁ ) and the other surface (f" ₂ ) of the lower end side inlet groove 258 of the third twist roller 257 are twisted by easy pressing of the alloy single wires 1' in the twist shaft 245 rotation direction. There is an advantage that efficiency can be improved.

As mentioned above, the method for manufacturing an alloy stranded conductor of the present invention has been described with reference to the embodiment shown in the drawings, but this is only an example, and a person skilled in the art may make various modifications and equivalent other embodiments therefrom. You will understand that it is possible. Accordingly, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

5: alloy wire multi-drawing device 10: alloy wire supply unit
20: wire loading frame 30: transport guide frame
60: alloy wire drawing section 66: drawing drum
73: fresh die 100: winding part
201: alloy stranded conductor manufacturing device 220: array plate
230: assembly die 231: extrusion hole
240: over-twist unit 241: housing
245: twist axis 250: twist space
251: first twist roller 254: second twist roller
257: third twist roller 300: aggregator
S1: Multi-drawing stage S2: Alloy wire supply stage
S4: alloy wire drawing step S6: winding step
S10: aggregation step S12: alloy single wire arrangement step
S14: alloy breakage compression step S16: over-twist step
S18: collective winding step

Claims (7)

a multi-drawing step of simultaneously drawing a plurality of alloy wires in multi-stage using an alloy wire multi-drawing device, forming a plurality of single alloy wires with uniformly reduced outer diameters, and then winding them on a first winding reel; After arranging a plurality of single alloy wires in a certain pattern, an aggregation step of twisting them in a compressed state into one wire rod shape;
The aggregation step is
an alloy single wire arranging step of unwinding a plurality of the single alloy wires wound in the multi wire drawing step and passing them through an array plate spaced apart from each other at regular intervals;
an alloy single wire compression step of passing a plurality of the arranged single alloy wires through a set die and compressing them to be concentrated in a single wire rod shape;
A plurality of alloy broken wires concentrated in the aggregation die enter the over-twist unit to extend in the collector direction, move away from the direction crossing the through-line of the extrusion hole of the assembling die, and then change their direction to be adjacent again, and then in the collector direction an over-twisting step of extending the over-twisting unit so that a plurality of the alloy single wires are twisted in a helical direction when the twist shaft of the over-twist unit rotates;
As the twist shaft is rotated, a plurality of single alloy wires twisted together in the form of a single alloy stranded wire are transferred into the collector and twisted again inside the collector to be wound on a second take-up reel provided inside the collector. A method for manufacturing an alloy stranded conductor comprising a winding step. The method of claim 1, wherein the over-twist unit
a housing having an inner space to which the twist shaft is mounted;
a shaft driving unit mounted on the housing and rotating the twist shaft;
A plurality of twist rollers disposed in the twist axis longitudinal direction in the twist shaft so that the plurality of alloy single wires are twisted when the twist shaft rotates by changing the traveling direction of a plurality of the alloy wires,
The twist shaft lengthwise extends from the assembly die in the collector direction, both sides are rotatably mounted to the housing, and the inner side is penetrated along the through extension line of the extrusion hole,
A plurality of twist rollers
A first twist roller that is installed to be deflected to one side in the width direction of the twist shaft, and converts the direction of a plurality of the alloy disconnections introduced into the twist shaft in the width direction of the twist shaft, and a plurality of directions changed in the first twist roller A second twist roller for changing the direction of the single alloy wire of A method of manufacturing an alloy stranded conductor comprising a third twist roller. 3. The method of claim 2, wherein the twist axis is
At least one side in the width direction is opened and extended in the longitudinal direction to mount the first to third twist rollers, and a twist space is formed in which a plurality of disconnected alloy wires extend while changing directions on the first to third twist rollers,
The first to third twist rollers are
Alloy stranded wire, characterized in that it is rotatably mounted in the twist space, and is rotatably mounted so that each inlet groove drawn in along the circumferential direction to accommodate a plurality of concentrated alloy disconnections is positioned on the through extension line of the extrusion hole A method for manufacturing a carcass. According to claim 1, wherein the multi-drawing step
An alloy wire supply step of moving a plurality of alloy wires side by side in one direction;
A plurality of the alloy wire rods are wound at least once along the circumferential direction in parallel on each outer circumferential surface of the plurality of wire drawing drums spaced apart from each other in one direction of the alloy wire multi wire drawing device and then extended, and then the plurality of wire drawing drums are simultaneously the same an alloy wire drawing step of drawing a plurality of the alloy wires passing through a plurality of drawing dies positioned between the drawing drums adjacent to each other by rotating in the direction;
A method for manufacturing an alloy stranded conductor comprising a winding step of winding a plurality of alloy single wires formed while a plurality of alloy wires are drawn while passing through a plurality of the drawing dies. According to claim 4, wherein the alloy wire multi wire drawing device
An alloy wire supply unit for feeding a plurality of alloy wires in parallel in one direction;
An alloy wire rod having a plurality of dice support parts positioned between the mutually adjacent wire drawing drums and each of which the drawing dies for drawing one alloy wire rod with a small diameter are arranged in a direction crossing the longitudinal direction of the alloy wire rod with the freshman;
a wire-drawing part winding part for winding each of the plurality of wire-drawing materials manufactured while the plurality of alloy wires pass through the wire-drawing part;
A plurality of the drawing drums are mutually connected so that one of the drawing drums rotates at a slower speed than the other drawing drum adjacent to the direction in which the alloy wire is moved so as to reduce the slip of the alloy wire extending in length while being drawn. A method of manufacturing an alloy stranded conductor comprising a; a rotation driving unit for rotating at different rotational speeds. 4. The method of claim 3, wherein the over-twist unit
The inlet groove of the second twist roller is positioned on the inlet groove of the first and third twist rollers and the diameter line of the extrusion hole, or the second twist roller moves to protrude outward on the extension line through the extrusion hole in the width direction of the twist axis 1 a tension control unit;
The method for manufacturing a stranded alloy conductor according to claim 1, further comprising a second tension adjusting unit capable of adjusting a separation distance between the first and third twist rollers with respect to the second twist roller. 4. The method of claim 3, wherein the first twist roller
One side is located on the extension line through the extrusion hole and the other side is located in the radial direction of the twist shaft,
One side of the second twist roller is located on the through line of the extrusion hole and is inclined in a direction in which the twist shaft rotates with respect to the first twist roller,
Wherein one side of the third twist roller is positioned on the through-line of the extrusion hole, and the twist axis is inclined in a direction in which the twist axis is rotated with respect to the second twist roller.

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