KR101456146B1 - The yarn feeder with automatic tension control for braid machine - Google Patents

Abstract

A yarn feeder with an automatic tension control for a braid machine includes a shaft (100) formed with a male threaded portion and a fitting portion; a housing (200), in which the shaft penetrates the housing; a spring (231) interposed between first and second bearings (211, 221), with an outer end of the spring being fixed to the inside of the housing (200); first and second linings (310, 320), a disc (410), a compression plate (321), and a coil spring (322) which are assembled to the shaft (100), in which a plurality of long bolts (430) penetrate the disc (410), and then are fastened by nuts, thereby integrating the disc (410) and a cover (420) in parallel; and a bobbin (500) having protrusions at both cylindrical ends, in which a magnet (530) is fitted on the outer surface of one protrusion, so that the bobbin (500) supplying the yarn to the braid machine is engaged to a rotary portion (300) connected to the housing (200) with respect to the central axis by a magnetic force, thereby easily detaching the bobbin. When a special fabric applied to military uniforms or a hot wave transmission structural material, such as a cover material for an antiaircraft weapon, or braid of small quantity batch production is manufactured, it is possible to easily change the bobbin according to the use of a small quantity of yarn (600).

Description

Technical Field [0001] The present invention relates to an automatic tension control type yarn feeder,

The present invention relates to a yarn feeder, and more particularly, to a yarn feeder for winding a yarn applied to a high-temperature electrical wave transmission structural member for a uniform, an aircraft, or an inorganic cover material, To an automatic tension control yarn feeder for a braid machine.

Generally, in the production of fiber products, the yarn is supplied to the bobbin to produce the fiber product, and the yarn of the yarn wound on the bobbin is wound in various forms, It is made in the form of wrapping yarn.

In practice, many complex and diverse devices are used together to produce products using fibers. For example, a loom, an air-jet loom, or a water-jet loom may be used as the weaving machine. Examples of the knitting machine include a circular knitting machine and a warping machine. Examples of devices suitable for use with the apparatus include a radiator, an air blower, and a stretcher, and examples of the apparatuses for processing a manufactured product.

In addition, tension devices are commonly applied to the various stages of production of textile products, so that the tension of the yarn fed in any form can be kept constant.

As described above, the reason why the tension regulating device is applied is that when the tension of the yarn is not constant or non-uniform when the product is made of fiber, the product is defective and continuous operation is difficult in each device.

Especially. If a certain tension can not be controlled in a weaving process using a loom and a knitting process using a knitting machine, defects of the fabric occur on the surface before and after the post-processing, and in the process of producing the fiber, Efficiency, continuity, and the like, which inevitably affect the quality of the textile product.

Generally, a process for weaving a product such as a shoelace is a two-dimensional braiding process in which a yarn is fed out from a plurality of bobbins. Such a two-dimensional braiding process is a method in which carriers are twisted, .

To this end, in the two-dimensional braiding process, when the bobbin moves outward from the center of the carrier, the yarn tension is maintained, and when the bobbin moves from the outer side to the center of the carrier, the bobbin is wound in the opposite direction.

Therefore, the tensile force of the yarn fed out in the two-dimensional braiding process or the three-dimensional braiding process is instantaneously changed in accordance with the diameter of the carrier, so that not only the thread tension of the two-dimensional braiding process is maintained, but also the three- It is very important to maintain the tension of the yarn.

Korean Patent Publication No. 10-2010-0006691 (Jan. 21, 2010)

In this patent document, a bobbin thread feeding device is provided which feeds a yarn by rotation of a bobbin in which a bobbin with a yarn wound thereon is sandwiched by a central shaft, and vertically feeds the yarn of the bobbin by using a guide, In which the tension of the yarn fed to the bobbin can be easily controlled and the tension can be maintained by fast winding of the winding yarn using the bobbin and the spring.

However, the yarn feeder for a blade shown in the patent document includes a plurality of technical limitations in addition to the vertical feed of the yarn and the usefulness of maintaining the tension of the yarn.

For example, the pusher and the upper housing and the lower housing are assembled on both sides of the bobbin, so that the pusher and the upper housing must be separated during the bobbin exchange, and the pusher and the upper housing need to be reassembled after the bobbin is replaced. It is inevitable to bring down.

In addition, there is a great concern that the rotation of the bobbin may not be smooth due to the bending of the central axis due to the use of the long central axis of rotation of the bobbin. In particular, there is a limit to the thread winding performance of the bobbin by connecting the bobbin to the guide bar.

And, in the manufacture of small quantities of braids for special applications or samples, such as fabrics applied to high-temperature radiation transmissive structural materials for military uniforms or anti-aircraft or inorganic cover materials, the long bobbin of thread feeders with complex structures, There are inconveniences that the bobbin must be exchanged frequently in manufacturing a few kinds of braids in small quantities of small quantities for specially used or samples.

In addition, if the thread of the bobbin is completely used in a state where the winding of the winding thread is fastened to maintain the tension by swinging the winding thread rapidly, even if the winding speed is very fast, the rotation of the shaft is continued with inertia, Can be wound in the opposite direction, and in particular, the reversely wound spring is a cause of malfunction and malfunction.

In view of the above, the present invention is applied to a high-temperature radio wave transmission structural member for a military uniform, an air conditioner, or an inorganic cover material in a braid by being coupled to a rotating portion connected to a housing via a bobbin The bobbin can be easily removed from the bobbin, and the bobbin can be easily removed from the bobbin, thereby improving the convenience of the bobbin replacement operation. Further, In particular, it is possible to change the vertical direction of the yarn feed direction using the joining structure. In particular, the one-way bearing that automatically maintains the tension of the yarn is free from the center axis when the bobbin is completely loosened, The blade is prevented from being reversely wound around the central axis by the inertia due to the internal connection It aims to provide for automatic tension control type yarn feeding apparatus.

In order to accomplish the above object, according to the present invention, there is provided an automatic tension adjusting yarn feeder for a blade, wherein a shaft having a key seat, a male screw, and a fitting portion is protruded through the inside of the housing; Wherein a spring is located between the first and second bearings assembled to the shaft at a predetermined distance from the housing in a width direction of the housing and a spring fastener is disposed inside the spring, An outer end of the spring is fixed to the inside of the housing while an inner end of the spring is fixed to the spring fastener; A disk-shaped first lining having a keyhole, a disk having a central hole having a diameter larger than the diameter of the shaft, a plate-shaped second lining having a keyhole, a compression plate having a keyhole, and a coil spring are sequentially positioned on the shaft, A spring-like spring fixing member in the form of a nut is assembled to the shaft in a compressed state of the coil spring; And a plurality of long bolts are inserted along the edge of the cover to be passed through the disk and then fixed with a nut. And the disk and the cover are integrated in parallel; Wherein a magnet is inserted into the center of the outer surface of one of the projecting portions to integrate with the bobbin, and the magnetic force of the magnet is transmitted to the bobbin, And an adhesive force of the cover.

A one-way bearing is further provided between the spring fastener and the shaft, and the one-way bearing prevents the spring from being reversely wound.

The housing is divided into an upper housing and a lower housing, and the upper housing and the lower housing are bolted together; The head of the long bolt of the cover protrudes; Wherein a groove or through-receiving portion corresponding to the position of the long bolt is formed in a protruding portion of the bobbin with a magnet seat, and a gap retaining groove is disposed in the long bolt, and the gap retaining groove is formed in a pipe shape, , The head of the long bolt is inserted into the receiving portion to easily fix the bobbin, and the gap between the disk and the cover is maintained by the gap holding tool.

The spacing member is formed in a pipe shape.

The housing is mounted to a bracket, and the bracket is passed through an edge of the cover to fix a pin so as to be protruded or a plurality of bobbin fixing holes to which bolts are coupled. In the bobbin, Hole or a female thread is formed at a position corresponding to the position of the hole and a plurality of through holes penetrating through the two surfaces are formed in an L-shaped cross-section, and a female screw is formed on the bottom surface of the housing to fix the bobbin.

In the present invention, the bobbin supplying the yarn to the blade unit is coupled to the rotating unit connected to the housing through the center shaft, through the magnetic force, so that the convenience of replacing the bobbin can be greatly improved by easy detachment and attachment, High-temperature radio wave transmission for rehearsal. It is easy to change the bobbin according to the use of a small amount of yarn when manufacturing a small quantity of various kinds of braids for a special purpose or a sample such as a fabric applied to a structural material.

Further, since the rotation of the bobbin does not directly use the center axis, the present invention has the effect of eliminating the adverse effect due to the warping of the central axis causing the non-smooth bobbin rotation.

In addition, the present invention has an effect that the bobbin can be prevented from rotating in place by being connected to a bolt or a fitting structure of a bolt, a groove, and a pin applied to the housing.

Further, according to the present invention, the tension of the yarn is automatically maintained by being connected to the inside of the housing and the one-way bearing in which the spring is free from the central axis when the bobbin is completely loosened, When the spring is released, the effect that the central axis reversely winds the spring is also prevented by the inertia.

In addition, the present invention has the effect that the yarn feeding direction is simply changed in the vertical direction only by changing the joining direction of the housing and the bracket by coupling the housing to which the bobbin is coupled by using the bracket.

2 is an exploded perspective view of an automatic tension-adjusting yarn feeder for a braid according to the present invention, FIG. 3 is a perspective view of the automatic tension adjusting yarn feeder for a braid according to the present invention, 4 is a cross-sectional view of a yarn feeder for a braid yarn according to the present invention, and Fig. 5 is a perspective view of a yarn feeder for a yarn tensioner according to the present invention, FIG. 6 is a side view showing a state in which the bobbin is coupled to the automatic tension-adjusting yarn feeder for a braid according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which illustrate exemplary embodiments of the present invention. The present invention is not limited to these embodiments.

Fig. 1 shows a schematic configuration of an automatic tension adjusting yarn feeder for a braid according to the present embodiment.

As shown in the figure, the automatic tension adjusting type yarn feeder includes a housing 200, a lining unit 300, a rotation unit 400, a bobbin 500, and a bracket 700.

The housing 200 is mounted on the bracket 700 so that the bobbin 500 can be installed horizontally or vertically. The lining part 300 and the rotation part 400 are sequentially coupled to the housing 200. The bobbin 500 is easy to be detached and attached by winding the yarn and forming a fixing force using the magnetic force with the rotary part 400. The brackets 700 may have different orientations of the yarns escaping from the bobbin 500 by differently mounting the housings 200.

Therefore, the automatic tension adjusting yarn feeder is installed directly on the blade unit through the female screw formed on the housing 200 or on the blade unit through the bracket 700. [

2 to 6 show a detailed structure of the housing 200, the lining part 300, the rotation part 400, the bobbin 500, and the bracket 700 constituting the automatic tension adjusting yarn feeding device for the braid device .

As shown in the figure, the shaft 100 has a shaft length considering the length of the housing 200 and the rotation unit 400 as a general shaft.

In this embodiment, a seat for a pair of first and second bearings 211 and 221 and a one-way bail 233 installed on the shaft 100 is formed on one side of the shaft 100. In addition, when the pair of first and second bearings 211 and 221 are fixed by the first, second, and third snap rings 212 and 212 'and 222, (212 ') 222 are machined.

The first and second lining parts 310 and 320 constituting the lining part 300 and the key seat 110 and the spring fixing part 323 for fitting the compression plate 321 are formed on the other side of the shaft 100, Are formed.

The end of the shaft 100 is formed of a small-diameter fitting portion 120 so that the receiving portion 421 of the cover 420 constituting the rotation portion 400 is fitted.

The housing 200 includes a pair of first and second bearings 211 and 221 installed therein, a spring 231, a spring fastener 232, and a one-way bearing 233.

To this end, the housing 200 comprises upper and lower cylindrical bearing seat portions 210 and 220, respectively, and a cylindrical spring seat 230 is formed in the middle.

The first and second bearings 211 and 221 are positioned on the first and second bearing seats 210 and 220, respectively. In particular, the first and second bearings 211 and 221 may be configured with first, second, and third retaining rings 212 and 212 'and 222 for fixing the first and second bearings 211 and 221. In this case, Two bearing seats 210 and 220 are further formed with a snapping seat in the periphery.

For example, a snap ring seat can be formed in which the second snap ring 212 " can be assembled to the inner periphery of the lower side of the first upper bearing seat 210, or the lower side of the lower second bearing seat 220 A snap ring seat (not shown) due to the first snap ring 212 or the third snap ring 222 can be configured on the inner periphery of the second housing 200. [ Therefore, the shaft 100 is inserted into each of the first and second bearing seats 210 and 220, and the first and second bearings 211 and 221 are assembled together.

A spring 230 is further formed in the housing 200 and a spring 231, a one-way bearing 233, and a spring fastener 232 are integrally formed with the spring 230.

The one-way spring 233 is a circular multiple-folded normal winding structure, and the one-way bearing 233 and the spring fastener 232 are coupled to the inside of the spring 231. In particular, the one-way bearing 233 is of a type that is locked in one direction and free in the opposite direction, and is fitted into the shaft 100 and assembled. The spring fastener 232 is coupled between the inside of the spring 231 and the one way bearing 233.

Therefore, it is fixed to the inner periphery of the spring 230 by the outer end of the spring 231, which is formed by sequentially assembling the spring fastener 232 and the one-way bearing 233, And the end is fixed to the spring fastener 232. In particular, the handwheel 231 is placed in the handwheel 230 in a state where no force is applied and the handwheel 233 and the handwheel 232 are rotated about the shaft 100 to rotate the handwheel 231 The winding direction can be the direction in which the one-way bearing 233 is locked.

When the shaft 100 rotates, the way-way bearings 211 and 221 and the spring fastener 232 rotate together to wind the spring 231 while the spring 231, The shaft 100 rotating in the opposite direction in which the lock is applied may be in a state free only of the shaft 100 when no force is applied.

In this embodiment, the housing 200 has a structure in which the shaft 100 is inserted into the housing 200, and a portion of the shaft 100 having the male thread 110 formed therein and the male thread 110 is protruded above the housing 200 And a one way bearing 233, a spring fastener 232 and a spring 231 are installed in the housing 200 between the first and second bearings 211 and 221 arranged up and down .

Particularly, since the housing 200 is divided into an upper housing 200 'and a lower housing 200', it is easy to assemble and disassemble by a method such as bolting.

However, the housing 200 may be separated and configured in various ways to further improve the convenience of disassembly and assembly.

The upper portion of the first and second bearings 211 and 221 may be assembled to the upper housing 200 'of the housing 200 and the lower housing (not shown) of the housing 200 The first and second bearings 211 and 221 are assembled to the upper and lower housings 200 and 200 and the lower housing 200 is formed with a plurality of female threads 223 for fixing the thread feeder .

The lining part 300 includes a pair of first and second lining parts 310 and 320, a compression plate part 321, a coil spring 322 and a spring fixing part 323. ).

The first and second lining units 310 and 320 are formed in the shape of a circular plate having first and second keyholes 310 'and 320' 'penetrating the center of the first and second lining units 310 and 320. The first and second keyholes 310' 320 "has a shape corresponding to the end surface of the shaft 100 on which the key seat 110 is formed.

The compression plate 321 has an area slightly larger than the area of the lining 320, and a keyhole 321 'is formed at the center thereof. The keyhole 321 'is formed in a shape corresponding to the end surface of the shaft 100 having the key seat 110, like the second keyhole 320' of the lining 320.

The coil spring 322 is a general compression coil spring.

The spring retainer 323 has a nut-like structure having a female screw at the center so as to be installed on the male screw of the shaft 100. However, in this embodiment, as shown in FIGS. 2 and 3, the external thread portion 323 'is formed on the side surface of the spring fastener 323 and the hole 323' passing through the thread portion 323 ' ') Or a female thread. Therefore, the spring fixture 323 can be more firmly fixed by securing the bolt 324 (or the bolt and the nut) to the female screw or the hole 323 '.

The rotation unit 400 includes a disk 410, a cover 420, a long bolt 430, a spacing holder 440, and a nut 450.

The disk 410 has a plate shape having a center hole 411 penetrating the center thereof. The cross-sectional size of the center hole 411 is formed to be larger than the cross-sectional size of the portion where the key seat 110 of the shaft 100 is formed, and a plurality of fixing holes 412 penetrating along the edge thereof are formed at the periphery thereof.

The cover 420 is made of a steel plate having a receiving portion 421 formed at the center thereof. The holding portion 421 is formed with a fixing hole 422 formed through the edge of the cover 420 so that the fitting portion 120 of the shaft 100 can be fitted. For this purpose, the fixing holes 422 are formed at positions corresponding to the fixing holes 412 of the disk 410 and the positions thereof. At this time, when the long bolt is assembled to the fixing hole 422, the fixing hole 422 is counter-boring so that a part or whole of the head does not protrude above the cover.

Particularly, a plurality of bobbin fixing holes 423 are formed in the cover 420 to extend along the edge of the cover 420. The fixing member 424 such as a pin or a bolt is used for fixing the bobbin 500 to the bobbin fixing hole 423 to prevent the bobbin 500 installed in the cover 420 from rotating, Can be prevented.

For example, as shown in FIG. 6, the bobbin 500 can be fitted to the bobbin fixing hole 423 by fitting the pin with the fixing member 424.

3 to 5, the bobbin 500 is fixed to the cover (not shown) through the fixing member 424 by fixing the bobbin 500 to the fixing member 424 with the bolt through the bobbin fixing hole 423, 420 in the circumferential direction and at the same time can be prevented from being separated.

On the other hand, the long bolt 430 is a bolt having a general structure in which a general head and a male screw are integrally formed, and at the same time, is formed of a relatively long long bolt. The gap retaining hole 440 is formed in a pipe shape having an appropriate length to be inserted into the elongated bolt 430. Particularly, the long bolt 430 and the gap retaining hole 440 may be integrally formed in consideration of the assembled state. The nut 450 is screwed at the end of the long bolt 430 and can be assembled together with the washer.

In the present embodiment, the long bolt 430, the spacing holder 440, and the nut 450 are spaced apart from each other by a predetermined distance in parallel to the disk 410 and the cover 420, Lt; / RTI > However, the long bolt 430, the spacing holder 440, and the nut 450 may be deformed so that the disk 410 and the cover 420 are spaced apart from each other by a predetermined distance, Other parts may be substituted or other methods may be applied.

Meanwhile, the bobbin 500 has a general bobbin structure capable of winding the yarn 600 and has a cylindrical shape having an appropriate diameter. Particularly, at both ends of the bobbin 500, the first and second protrusions 510 and 520 protruded in the circumferential direction prevent the thread 600 wound on the bobbin 500 from coming off, 2 protrusions 510 and 520 are formed on the inner side of the outer surface thereof.

A magnet 530 is inserted into the magnet seat 510 and integrated with the bobbin 500. In this embodiment, the magnet 530 is made of a magnet having a relatively large magnetic force, and the magnet 530 is press-fit or interference-fit into the magnet seat 510, so that the magnet 530 is not detached and maintained in the engaged state.

A plurality of accommodating portions 512 and lock portions 513 are formed along edges of the first and second protrusions 510 and 520 where the magnet seat 510 is formed.

The accommodating portion 512 is formed at a position corresponding to the fixing hole 422 of the cover 420. Therefore, when the receiving portion 512 is protruded above the cover 420, the bobbin 500 is prevented from slipping with respect to the cover 420 by fitting the head of the long bolt 430 when assembled.

The lock portion 513 is a hole that allows the pin to be inserted when the fixing member 424 protruding from the bobbin fixing hole 423 of the cover 420 is a pin or a bolt and a hole when the fixing member 424 is a bolt. And may be constituted by a female screw fastened with a screw.

The bobbin 500 may be attached to the cover 420 by fitting the lock portion 513 of the bobbin 500 to the pin of the cover 420 or by bolting the bobbin 500 through the bobbin fixing hole 423. [ Can be prevented from being attracted to the cover 420 in the circumferential direction while being prevented from being separated.

The bracket 700 includes an automatic tension adjusting yarn feeder including a housing 200, a lining unit 300, a rotating unit 400, and a bobbin 500. The automatic tension adjusting yarn feeder includes a housing 200, Or to vertically change the direction in which the yarn 600 of the bobbin 500 escapes.

For this purpose, the bracket 700 is formed to have an L-shaped cross section having an appropriate width. Particularly, a plurality of through holes 710 are formed on one side of the bracket 700 so as to be able to be bolted with the thread feeding device, and a plurality of through holes 720 are formed on the other side of the bracket 700, do.

Particularly, the bracket 700 is fastened to the bracket 700 by the bolt 224 of the lower housing 200 'of the housing 200 having the plurality of female threads 223, The direction can be changed in the vertical direction with respect to the direction. However, the bracket 700 may be a bracket of a type that can adjust the height of the yarn feeder according to the present embodiment.

5 shows a state in which the housing 200 is assembled to the bracket 700 and the lining part 300 and the rotation part 400 are assembled to the housing 200 and the bobbin 500 having the magnet 530 is rotated 400 before being assembled to the yarn feeder. 6 shows an automatic tension adjusting yarn feeder in a fully assembled state.

Such an assembled state is realized by assembling the rotating part 400 and the lining part 300 to the housing 200 using the projected shaft 100.

Specifically, the first lining 310, the disk 410, the second lining 320, the compression plate 321, and the coil spring 322 are fixed to the shaft 100 protruding toward the upper side of the upper housing 200 ' Assemble them sequentially. At this time, the coil spring 322 is suitably compressed while the spring fixing member 323 is screwed onto the shaft 100, so that the first and second lining 310 and 320 are separated from the disk 410 through the compression plate 321, .

The cover 420 is assembled to the end of the shaft 100 so that the fitting part 120 at the end of the shaft 100 is inserted into the receiving part 421 at the center of the cover 420, And the fixing holes 422 of the cover 420 are aligned with each other. The long bolt 430 is inserted into the fixing hole 412 of the cover 420, the gap holding hole 440, and the fixing hole 422 of the cover 420 with the gap maintaining hole 440 therebetween Then, the end of the long bolt 430 is fastened with the washer and the nut 450.

The disk 410 and the cover 420 are composed of the rotary part 400 having a structure integrally formed with the long bolt 430 while keeping a distance spaced apart in parallel by the gap holding tool 440. [

The lining part 300 is formed by pressing the compression plate 321 assembled on the upper part of the disk 410 with the coil spring 322 on both sides of the assembled disk 410. [

Further, the bobbin 500 is assembled by being bolted to the fixing member 424 through the bobbin fixing hole 423. [ Then, the bobbin 500 can prevent the bobbin 500 from slipping in the circumferential direction with respect to the cover 420 through the fixing member 424, and can also prevent the bobbin 500 from deviating. However, as shown in FIG. 6, the bobbin fixing hole 423 may be formed with the pin protruded by the fixing member 424, so that the bobbin 500 can be fitted to the pin.

Therefore, the automatic tension adjusting yarn feeder for a blade according to the present embodiment includes a bobbin 500 to which a housing 200, a lining unit 300, and a rotation unit 400 are coupled to one shaft 100, .

The yarn feeder of the automatic tension control type is provided as much as necessary for the carrier of the yarn feeder except for the bobbin 500. For example, the bobbin 500 is installed in the cover 420 with the yarn 600 wound thereon. In this case, the magnet 530 of the cover 420 is fitted to the magnet seat 510 of the bobbin 500, so that the magnet 530 is attached by the magnetic force. In this state, a pin or the like which is further assembled to the bobbin fixing hole 423 A fixing member 424 such as a bolt prevents the bobbin 500 from coming off.

On the other hand, when the operation of the blade unit is performed, the automatic tension adjusting yarn feeder is moved by the carrier. Then, as the yarn 600 of the bobbin 500 is loosened, a plurality of yarns 600 are twisted so that the braid is woven.

The rotation of the bobbin 500 is released to supply the yarn 600 and at the same time the rotational force of the bobbin 500 is transmitted to the rotation unit 400, the lining unit 300, and the shaft 100. Then, as the shaft 100 is rotated, the one-way bearing 233 and the spring fastener 232 are rotated by the shaft 100 to wind the spring 231.

When the thread feeder 231 is moved in the center direction from the outer position of the carrier in a state where the spring 231 is wound, the spring 231 is released and the spring fastener 232 and the one-way bearing 233 are rotated in opposite directions do. Rotation of the lining part 300, the rotation part 400 and the bobbin 500 by the rotation of the shaft 100 rewinds the yarn 600 again.

At this time, in the process of rewinding the yarn 600 of the bobbin 500 by the spring 231, the one-way bearing 233 is kept locked in the direction in which the tension of the spring 231 is applied, (100) are rotated together to wind the yarn (600) of the bobbin (500).

On the other hand, when the yarn feeding device moves outward from the center position of the carrier and the winding spring 231 is wound, the shaft 100 is no longer moved. Then, the first and second lining 310, 320, the compression plate 321, the spring and the spring fixture 323 are not moved, but the thread 600 of the bobbin 500 continues to be disengaged, The rotation is maintained so that the rotation part 400 can be maintained in a rotating state. At this time, the disk 410 of the rotation unit 400 is rotated between the moving lining.

As described above, the automatic tension adjusting yarn feeder according to the present embodiment has a structure in which the housing 200, the lining unit 300, and the rotation unit 400 are compact by the shaft 100, It is easy to maintain the tension of the belt 600. Particularly, the bobbin 500 can be easily replaced by the magnet 530, and the bobbin 500 can be more firmly fixed by bolting.

When the thread 600 of the bobbin 500 is used for weaving the braid base, the thread 600 wound around the bobbin 500 is loosened and loosened when the thread 231 is wound to some extent, It tends to return to its original position (state) as soon as it is released.

In this state, when the one-way bearing 233 is absent, the thread of the bobbin 500 is loosened in the state that the spring 231 is wound, so that the spring 231 quickly returns to its original state, I can not help but stop. Therefore, the inertia of the axis 100 to continue to rotate acts on the axis 100 to reverse the spring 231.

However, in this case, in the automatic tension adjusting yarn feeder according to the present embodiment, the one-way bearing 233 is free with respect to the shaft 100, so that only the shaft 100 can be rotated. Therefore, the inertia of the shaft 100 can prevent the spring 231 from being reversely wound.

As described above, in the automatic tension adjusting yarn feeder for a blade according to the present embodiment, the shaft 100 having the key seat, the male screw, and the fitting portion passes through the upper portion of the housing 200, And the coil spring 322 are fixed to the inside of the housing 200 and the first and second lining 310 and 320, the disk 410, the compression plate 321, and the coil spring 322 are fixed to the inside of the housing 200, A plurality of long bolts 430 are inserted into the shaft 100 and are passed through the disk 410 and fixed with a nut so that the disk 410 and the cover 420 are integrated in parallel, A magnet 530 is inserted into the center of the outer surface of the bobbin 500 forming the protrusion at both ends of the cylindrical shape and integrated with the bobbin 500 so that the bobbin 500, And is connected to the rotary part 300 connected to the rotor 300 through magnetic force, The convenience of empty replacement operations is greatly improved and the use of a small amount of yarns (600) when manufacturing small quantities of braids for special applications or samples, such as fabrics applied to high-temperature radiation transmission structural materials, So that the bobbin exchange operation can be facilitated.

100: Axis 200: Housing
200 ': upper housing 200'': lower housing
211, 221: first and second bearings 231:
232: Spring fastener 233: One way bearing
300: lining part 310, 320: first and second lining
321: compression plate 322: coil spring
323: Spring clamp 323 '
400: rotating part 410: disk
420: cover 430: long bolt
440: space retaining hole 450: nut
500: Bobbin 530: Magnet
600: room 700: bracket

Claims (6)

A shaft having a key seat, a male screw, and a fitting portion is protruded through the inside of the housing;
Wherein a spring is located between the first and second bearings assembled to the shaft at a predetermined distance from the housing in a width direction of the housing and a spring fastener is disposed inside the spring, An outer end of the spring is fixed to the inside of the housing while an inner end of the spring is fixed to the spring fastener;
A disk-shaped first lining having a keyhole, a disk having a central hole having a diameter larger than the diameter of the shaft, a plate-shaped second lining having a keyhole, a compression plate having a keyhole, and a coil spring are sequentially positioned on the shaft, A spring-like spring fixing member in the form of a nut is assembled to the shaft in a compressed state of the coil spring;
And a plurality of long bolts are inserted along the edge of the cover to be passed through the disk and then fixed with a nut. And the disk and the cover are integrated in parallel;
Wherein a magnet is inserted into the center of the outer surface of one of the projecting portions to integrate with the bobbin, and the magnetic force of the magnet is transmitted to the bobbin, And an adhesive force of the cover.
[2] The apparatus according to claim 1, further comprising a one-way bearing between the spiral fastener and the shaft, wherein the one-way bearing prevents the spool from being reversely wound.
[3] The apparatus of claim 1, wherein the housing is divided into an upper housing and a lower housing, and the upper housing and the lower housing are bolted together; The head of the long bolt of the cover protrudes; Wherein a groove or through-receiving portion corresponding to the position of the long bolt is formed in a protruding portion of the bobbin with a magnet seat, and a gap retaining groove is disposed in the long bolt, and the gap retaining groove is formed in a pipe shape, , The head of the long bolt is fitted in the receiving portion to easily fix the bobbin, and the clearance between the disk and the cover is maintained by the gap holder. Device.
The automatic tension adjusting yarn feeder according to claim 3, wherein the gap maintaining member is formed in a pipe shape. The automatic tension control yarn feeder according to any one of claims 1 to 4, wherein the housing is mounted on the bracket.
[7] The bobbin according to claim 5, wherein the bracket is formed with a plurality of bobbin fixing holes formed through the edges of the cover to fix the pins in a protruding manner or to which bolts are coupled, And a plurality of through-holes penetrating through the two surfaces are formed in an L-shaped cross-section, and a female thread is formed on the bottom surface of the housing to fix the bobbin. Automatic tension control yarn feeder for braiding machine.

Images