KR20020002140A - Tetra twister - Google Patents

Abstract

PURPOSE: A tetra braiding machine is provided, which is characterized by forming various twist structures of the respective steel cords, increasing braiding speed and improving productivity of steel cord by convert of rotating direction and speed of an internal face disc and an external face disc. CONSTITUTION: The tetra braiding machine is comprised of: a bed frame(31); two posts(32) installed on both ends of the bed frame; a bracket(33A) attached to the outside of the one post; a driving motor(33) installed on the bracket; a main rotary axis(34) delivering rotatory force of the driving motor to a rotary axis(35) of a pair of external face disc(36); the rotary axis(35) rotated by the main rotary axis(34); a connecting part perforated into the internal face disc and the external face disc; two rotating and speed converting parts(37) installed on the connecting part; a rotary axis(38) of the internal face disc connected to the same axis as the rotary axis of the external face disc and a bearing; a pair of internal face disc(39) perforated and inserted by the rotary axis(38) of the internal face disc; and a cradle(30) installed between one end of the rotary axis(38) and installed many guide rollers(30A).

Description

Tetra twister

The present invention relates to a stranded twister for forming a twisted structure of a steel cord used for rubber reinforcement, and more particularly, it is connected on the same axis by the rotation and speed converter, and the rotation directions are different from each other but the rotation speeds are different. The centerline of the steel cord twisted while traveling from the wire feeder outside the twister to the cradle which is the wire feeder for the outer layer wire of the steel cord provided between the inner boards of the twister is connected by the pair of inner and outer faceboards. While twisting the twisted wire during the outward movement of the twisted pair in line with the outer layer of the cord, it returns to the original straight state, while the strands for outer layer wire supplied from the cradle twist the outer circumferential surface of the center line where the twist is released and straightened. The twisting speed of the outer layer wire is mutually rotated compared to the conventional twisted wire speed. Tetra stranded wire, which is basically doubled by the inner and outer faceboards in opposite directions, and the final twisted wire speed is (2 times) × (gear ratio) according to the gear ratio between the replaceable gears constituting the rotation and speed converter of the two faceplates. It is about the flag.

Steel cords used to reinforce rubbers that are less durable in various rubber products for industrial use are widely used as reinforcement materials for automobile tire rubber, which is directly related to human life. Generally, after forming a plating layer of copper or zinc having a thickness of 1 to 4 µm on a wire having a diameter of 0.9 to 2.0 mm, which is made of carbon steel having a carbon content of 0.6 to 0.85 wt%, it is cold drawn again. One wire is twisted into various structures such as 1 × 2, 1 × 3, 1 × 4, 2 + 2.

1 and 2 show schematic views of a conventional stranding machine for manufacturing the wires having the plating and cold drawing processes completed with steel cords.

Referring to FIG. 1, the element wire 12 for the outer layer wire of the steel cord supplied from the outside of the twisted pair 1 passes through the guide roller 14 and then is supplied from the inside of the twisted pair by the face plate 13 of the twisted pair 1. It is twisted by the outer peripheral surface of the element wire 11 for steel cord centerlines.

In addition, FIG. 2 is a form in which the steel cord centerline element wires 21 are provided outside the stranded wires 2 and the steel cord outer layer wires 22 are supplied in the twisted wire device unlike the stranded wire method of FIG. 1. Therefore, the steel cord centerline element wire 21 is twisted first by the face plate 23 and at the same time passing through the face plate 23 again, the primary twist structure of the center line is released and becomes the original untwisted state. Inside the machine is rotated with the rotation of the face plate and the outer wire of the outer layer wire 22 is twisted on the outer peripheral surface of the center line.

In order to increase the twisted wire speed of the conventional twisted pair machine as described above, the speed of the surface plate must be increased, and the increase in the rotational speed is limited, and thus the production improvement is inevitably limited.

Therefore, in order to solve the above problems, a twisted pair having two pairs of face plates along the direction of rotation are disclosed in Korean Patent Publication No. 00-14432, but the connection structure of two pairs of face shafts is unclear. Patents 3,956,875 and 4,328,599 and the like also disclose a twisted pair having two pairs of face plates, but two pairs of face half shaft connection structures are complicated.

In addition, the stranded wires may be stranded only in a single-layered steel cord in which a cradle, which is a supply wire of the element wire constituting the steel cord, is provided between the pair of inner face plates and is stranded by the element wires supplied from the cradle. There is a disadvantage in that the steel cord of the multilayer structure consisting of the center line and the outer layer line cannot be stranded.

The present invention was devised to solve the above-mentioned problems, and the two pairs of surface connection structure is simple, and the rotation speed ratio of the inner and outer surface half shafts can be easily adjusted, thereby making it possible to vary the stranded wire structure of the steel cord as well as productivity. The purpose of the present invention is to provide a twisted pair that can improve significantly.

1 is a configuration diagram of a conventional twisted pair of wires for the center line of the steel cord is supplied in the twisted pair.

2 is a configuration diagram of a conventional twisted pair of wires for the center line of the steel cord is supplied from the outside of the twisted pair.

Figure 3 is a perspective view of the present invention tetra twisted pair.

Figure 4 is a front view of the present invention tetra twisted pair.

Figure 5 is a front view of the rotation and speed conversion unit constituting the present invention tetra twisted pair.

Figure 6 is a cross-sectional structure diagram of the rotation and speed conversion unit constituting the present invention tetra twisted pair.

7 is a progress diagram of the element wire passing through the present invention tetra twisted pair.

((Explanation of symbols for main part of drawing))

13,23. Face plate 31. Bed frame

33. Drive motor 34. Main axis of rotation

36. External face board 37. Rotation and speed converter

39. Inner face board 30. Cradle

51. Converter Case 52. Drive Gear

53. Manual Gear 54. First Gear

55. Second gear speed 56. Driven gear

The above object of the present invention is achieved by a rotation and speed converter provided in the connection portion of the two pairs of inner and outer face plates and the two pairs of inner and outer face shafts.

In the present invention, the inner and outer face plates of the tetra-twist twister are rotated in opposite directions by the rotation and speed converter, and the speed difference between the inner and outer face plates is determined by the gear ratio of the gear constituting the converter. Rotating shafts are separate shafts, not integral ones, but are connected by bearings, so that they can be rotated backwards without mutual interference, and each shaft is hollowed through, and a plurality of elementary through holes penetrating between the outer peripheral surface and the hollow of each shaft are formed. There is a technical feature in that the steel wire constituting the steel cord and the structure that can pass through the stranded steel cord.

Tetra stranded wire of the present invention is provided with an outer layer wire supply cradle between the inner face plate, the center element wire is a structure that is supplied from the outside of the stranded wire, the steel cord of the single-layer structure is twisted with only the element wire supplied from the cradle without supplying the center wire When stranded and a center element wire is supplied from the outside of a stranded machine, a steel cord of a multi-layered structure, ie, a two-layer structure, is stranded.

In addition, the twisting speed of the element wire supplied from the cradle is basically doubled by the inner and outer surface boards in which the mutual rotation directions are opposite to each other, and the gear ratio between the interchangeable gears constituting the rotating shaft connection portion of the two surface plates. Therefore, the final twisted wire speed is 2 × (gear ratio) times the conventional twisted wire twisted wire speed.

The purpose and detailed technical features and operational effects of the present invention will be clearly understood by the following detailed description with reference to the drawings showing preferred embodiments of the present invention.

3 is a perspective view of the tetra-stranded machine of the present invention, and FIG. 4 is a front view thereof.

As shown, the tetra-stranded machine 3 of the present invention is mounted to the bed frame 31, two posts 32 placed on both ends of the bed frame, and a bracket 33A attached to the outside of one post. A drive motor 33, a main rotary shaft 34 which transmits the rotational force of the drive motor to the pair of external face plate rotary shafts 35, and a pair of external face plates which are extrapolated through the external face plate rotary shaft rotated by the main rotary shaft. (36) and a rotation and speed conversion unit (37) provided at the engaging portion of the inner and outer surface plate rotating shaft ends penetrating the inner and outer surface plates to change the relative rotation direction and rotation speed of the inner and outer surface disk rotating shafts, In the inner face plate (39) and a pair of inner face is penetrated through the center by the inner face plate rotating shaft 38 connected to the same axis so as to be mutually rotatable by the outer face plate rotating shaft and the bearing in the The connection between the one end of the rotating shaft that is advised free rotation relative to the inner rotary shaft myeonban between the rotating and the speed conversion section and an opposite end to allow the strand supply comprises a delivery cradle 30, which is a plurality of guide rollers (30A) mounted.

The drive of the tetra twisted pair of the present invention configured as described above is made as follows.

When the drive motor rotates, the main axis of rotation connected to the belt and pulley on the drive motor rotates. The rotation of the main rotating shaft is transmitted to the two outer surface rotating shafts connected to the belt and the pulley at both ends of the main rotating shaft so that the pair of outer surface rotating in the same direction and speed with each other.

One end of the outer face plate rotating shaft penetrating the outer face plate extends to the inside of the rotation and speed conversion unit and is bearing-bonded on one axis with one end of the inner face plate rotating shaft extending from the opposite direction to the inside of the rotation and speed conversion unit. It is possible to form a connection structure that does not interfere with each other's rotation.

Therefore, the rotation of the outer surface plate rotation shaft extending to the inside of the rotation and speed conversion unit is converted into the rotation direction and speed through the gear inserted into the front end of the rotation shaft and the gear inserted into the inner gear and the inner end of the rotation plate rotation shaft The direction of rotation of the faceplate is opposite to the direction of rotation of the faceplate, and the speed is accelerated and decelerated by the gear ratio of the gears inside the transducer.

In addition, the cradles mounted between the rotation and speed converter and the inner face plate are all connected to bearings so as to be stable without being rotated even when the respective rotation shafts rotate.

When the twisted twister of the present invention is the same rotation direction of the inner and outer face plate and the direction is different, the twisting speed is basically twice the normal twisted twister. Moreover, the twisting speed can be sharply increased according to the gear ratio of the gears inside the rotational and speed converters, and the rotational and speed converters, which play such a role, will be described in detail as follows.

6 is a sectional view showing the connection state of the power transmission means in FIG. 5 and a front view of the rotation and speed converter in a state in which the chain or the belt which is the power transmission means is removed.

As shown, the rotation and speed conversion unit 37 includes a conversion unit case 51, a manual gear 53 and a drive gear 52 attached to one end of each of the inner and outer surface plate rotating shafts 38 and 35; , A first speed increasing gear 54 for increasing the rotational speed of the drive gear, a second speed increasing gear 55 for increasing the rotational speed of the manual gear, and a power for transmitting rotation of the second speed increasing gear to the manual gear. It consists of a driven gear 56 which serves as a support for the transmission means.

As described above, the inner and outer face plate rotating shafts are connected inside the converter case, but have mutually independent rotation, and the two speed increasing gear shafts and the driven gear shafts are single shafts, respectively.

Referring to the operation principle of the rotary mill speed converter configured as described above on the basis of Figure 6, the drive gear 52 driven by the main rotary shaft to the first speed transmission gear 54 through the first power transmission means (61) At this time, since the diameter of the first speed increasing gear is smaller than the diameter of the driving gear, the rotation speed of the first speed increasing gear is increased, and the rotation speed of the second speed increasing gear 55 mounted on the same shaft is also increased. .

In addition, since the diameter of the manual gear 53 connected to the second speed gear and the driven gear 56 by other power transmission means 62 is smaller than the diameter of the second speed gear, the rotation speed of the manual gear is the rotation of the drive gear. It is very fast after two speed increases from speed.

In addition, the connection method of the power transmission means connected to the second speed gear is connected in such a way as to contact and pass through a portion of the outer peripheral surface of the gear, without enclosing the gear, such as connected to other gears. The gear ratio of the gears constituting the converter is different from the direction of rotation, and the gear ratio of each gear constituting the converter can be adjusted by replacing the gears as necessary, so that the rate of increase of the relative rotational speed between the inner and outer surface rotating shafts can be freely controlled.

When the ratio of the drive gear diameter to the first manual gear diameter, and the ratio of the second manual gear diameter and the manual gear diameter is 2: 1: 2: 1, the rotation speed of the manual gear becomes four times the rotation speed of the driving gear and is mutually reverse rotation. Therefore, considering the direction of rotation, the rotation of the manual gear relative to the drive gear is eight times.

That is, the basic twisting speed is doubled by the reverse rotation than the twisting speed of the twisted direction in one direction, and multiplied by the gear ratio results in the final twisting speed. Therefore, the twist speed obtained at the gear ratio of 2: 1: 2: 1 is 8 times that of 2x4 (total gear ratio of the entire converter) of the one-way twist speed.

The process of forming the twisted structure in the present invention, the tetra-strand twister as described above is as follows.

The element wires 71 supplied from the external high band, such as the movement paths of the element wires passing through the tetra-strand strand of the present invention shown in FIG. 7, are formed through the hollow holes at the outer circumferential surface of the outer surface plate rotation shaft through the outer surface plate rotation shaft hollow 35A. (35B) through the through hole (35C) formed on the other outer face plate rotating shaft through one outer face plate and the other outer face plate, the hollow 35F of the other outer face plate rotating shaft and the hollow 34A of the one side inner plate rotating shaft and one side inner face plate The cradle 30 reaches the cradle 30 through the hollow 34F of the other inner surface plate rotating shaft through the inner surface plate and the other inner surface plate by passing through the through hole 34B formed in the outer surface of the surface plate rotating shaft.

The externally fed wires that reach the cradle have twice the twisted structure compared to the one-way strands, passing through the inner and outer faceplates with different rotation directions. However, as the external supply line is associated with the element wire 73 supplied from the cradle, one inner face plate rotating shaft hollow 34A → one inner face plate rotating shaft outer circumferential surface passing hole 34D → one inner face plate → the other inner face plate → the other inner face plate rotating shaft Passing hole (34E) → other inner face plate rotating shaft hollow (34F) → one outer face plate rotating shaft hollow (35A) → one outer face plate rotating shaft passing hole (35D) → one outer face plate → the other outer face plate → the other outer face plate rotating shaft passing hole (35E) ) → proceeds in the path of the winding bobbin 72 and a twist structure in the opposite direction to the twist structure formed when the external supply element is drawn in is formed.

Therefore, the twisted structure of the external supply line formed at the time of pulling is completely released, thereby forming a structure in which the strands supplied from the cradle are twisted around the external supply element. That is, as a result, the outer layer strands form a twisted structure on the center element outer circumferential surface having no twisted structure.

As described above, the tetra-strand of the present invention is a steel structure of the steel cord because it can effectively increase the twisted wire speed compared to the one-way twister by the conversion of the rotation direction and the speed of the inner and outer surface rotation axis by the rotation and speed converter of the special structure Productivity can be significantly improved.

In addition, since the gear ratio of the rotation and the speed converter can be freely adjusted, there is an advantage in that the twisted structure suitable for the steel cord-specific characteristics can be effectively coped with.

Claims (2)

A twisted pair that forms a twisted structure of a steel cord, comprising: a pair of bed frames, two posts placed on both ends of the bed frame, a drive motor mounted on a bracket attached to an outer side of one post, and a rotational force of the drive motor. An inner and outer surface rotating shaft provided at a coupling portion of the main rotating shaft to be transmitted to the outer surface rotating shaft of the inner surface, a pair of outer surface disks penetrated by the outer surface rotating disk rotated by the main rotating shaft, and an inner and outer surface disk rotating shaft passing through the inner and outer surface disks. The center is penetrated and extrapolated by a rotation and speed conversion unit for changing the rotation direction and the rotation speed of the inner surface and an inner surface rotation axis connected to the same axis so as to be mutually rotatable by the outer surface rotation axis and the bearing in the rotation and speed conversion unit. Inner face between a pair of inner facets and one end of a pair of inner facet axis of rotation The connection is free to be rotated relative to the rotation axis, and tetra-stranded group, characterized by consisting of a wire feed delivery cradle which the plurality of guide rollers mounted. According to claim 1, wherein the rotation and the speed converter is a conversion unit case, a drive gear and a manual gear attached to each one end of the inner and outer face plate rotating shaft, a first speed increasing gear for increasing the rotational speed of the drive gear, manual And a second gear for increasing the rotational speed of the gear and a driven gear serving as a support for the power transmission means for transmitting the rotation of the second gear to the manual gear.