KR20200144485A - Yarn tension adjusting device - Google Patents

Abstract

The present invention provides a yarn tension adjusting device capable of allowing movement in both directions in which a facing surface of one side is folded with respect to a facing surface of the other side when increasing pressing force of a coil spring to be compact, performing compact movement by a cheap composition, suppressing enlargement of a device, and reducing costs. In the yarn tension adjusting device (2) for adjusting tension applied to a yarn (Y) which is inserted between facing surfaces (211, 221) of first and second disks (21, 22) facing each other, the first disk (21) is folded on a same shaft (23) with respect to the second disk (22). A permanent magnet (24) is installed in the first disk (21), and an electromagnet (25) for changing stimulation in power or changing an amount of electrical current is installed in the second disk (22). To bring the facing surface (211) of the first disk (21) closer to the facing surface (221) of the second disk (22), a pressing coil spring (27) is mounted to be contracted between a screw member (28) which is attached by being screw-connected to one end of the shaft (23) and the other surface of the facing surface (211) of the first disk (21).

Description

Thread tension adjustment device{YARN TENSION ADJUSTING DEVICE}

The present invention relates to a yarn tension adjusting device configured to adjust the tension applied to a yarn sandwiched between mutually opposed mating surfaces.

In general, this kind of thread tension adjusting device is installed in the top tension device of a flat knitting machine so that the yarn from the yarn cone is not drawn out more than necessary. And a suitable tension is applied to the thread sandwiched between the facing surfaces of both facing each other. Of the two facing surfaces, one of the facing surfaces is configured to be folded with respect to the other facing surface, and a coil spring installed on the opposite facing surface is always used to the other facing surface It is being pressurized. In addition, the coil spring has a screw member screwed and attached to the shaft end extending in the expansion and contraction direction, and as the length in the expansion and contraction direction is changed by the tightening and loosening operation of the screw member, the opposite face of the other side By increasing or decreasing the pressing force of one opposing surface to the side, the tension applied to the yarn between the opposing surfaces is adjusted.

In addition, as this type of thread tension adjusting device, the tension imparted to the upper thread is adjusted on the feed path of a sewing machine that supplies the upper thread from the bobbin stand to the needle. It is known (see Patent Document 1). This thread tension adjusting device is provided with a coil spring that constantly pressurizes on one of the facing surfaces of both facing each other so as to be close to the other facing surface, and a plunger that is pressed by an electromagnetic solenoid, By adding the pressing force of the plunger to the pressing force of the coil spring, the tension of the upper thread is adjusted over a wide range while a pressure that cannot be supplied by the pressing force of the coil spring is applied to the opposite side of the other side.

: Japanese Unexamined Patent Application Publication No. 2002-210279

However, in the conventional thread tension adjusting device, since the pressing force of the pressing means such as a coil spring is increased by the pressing force of the plunger, the pressing force of the pressing means cannot be attenuated. Therefore, in order to attenuate the pressing force of the pressing means, it is necessary to newly add a mechanism including a plunger that presses and moves one opposing surface by an electromagnetic solenoid in a direction to separate from the other opposing surface. However, in increasing or decreasing the pressing force of the pressurizing means, if two mechanisms having plungers pressed by an electronic solenoid are installed in both directions in which one facing surface is folded against the other facing surface, the device itself becomes very large. Also, the cost increases.

The present invention has been made in consideration of these points, and its object is to provide two electronic solenoids and a plunger to move one facing surface to be folded with respect to the other facing surface when increasing or decreasing the pressing force of the pressing means. The objective is to provide a thread tension adjusting device capable of reducing the cost while suppressing an increase in the size of the device itself, which can be implemented without using each mechanism.

In order to achieve the above object, the present invention is premised on a thread tension adjusting device including a thread tension adjusting device main body that adjusts the tension applied to a thread sandwiched between opposite facing surfaces. In addition, one of the two facing surfaces is configured to be folded with respect to the other facing surface, and a permanent magnet is installed on the side of the other facing surface, while a magnetic pole can be changed for the power source on the other facing surface side. Also, a connected electromagnet is installed to change the amount of energization. Further, it is characterized in that a pressing means for always elastically pressing the one facing surface is provided on the one facing surface side so that the one facing surface is brought closer to the other facing surface side.

Further, the pressing means may include pressing force changing means for changing the pressing force of the pressing means.

Further, an operation of changing the pressing force of the pressing means by the pressing force changing means may be performed electrically by means of an electric motor.

Further, the body of the thread tension adjusting device may be applied to a top tension device of a flat knitting machine.

As described above, a permanent magnet is installed on the opposite face side of the opposite side with the thread interposed therebetween, and a pressurizing means for constantly pressing one facing surface to the other facing side is installed, while the magnetic pole can be changed on the other facing surface side. When the magnetic pole of the electromagnet is changed by installing an electromagnet, the attraction and repulsion force for the polarity of the permanent magnet is obtained. For this reason, the pressing force of the pressurizing means is increased by the attraction force when the magnetic pole of the electromagnet is changed to a polarity different from that of the permanent magnet, while it is attenuated by the repulsive force when the magnetic pole of the electromagnet is changed to the same polarity as the permanent magnet. In this way, the thread tension adjustment device is constituted by a permanent magnet on one opposing surface side and an electromagnet capable of changing the magnetic pole of the other opposing surface side and the magnetic pole of the other opposing surface side, thereby increasing or decreasing the pressing force of the pressing means. Bidirectional movement of one opposing surface to the other facing surface is carried out according to the magnitude of the attraction force and repulsion force due to the transfer of the attraction force and repulsion force by the change of the magnetic pole of the electromagnet and the amount of energization to the electromagnet. It is not necessary to each use a mechanism with an electronic solenoid and plunger. Accordingly, it is possible to reduce the cost while suppressing the enlargement of the thread tension adjusting device itself.

In addition, when the pressing force of the pressing means faces each other without depending on the magnetic force, it is possible to apply a certain tension to the threads sandwiched between each other, thereby reducing power consumption.

In addition, a permanent magnet is installed on one opposing surface side that moves with respect to the other opposing surface while the pressing means is provided, but the other opposing surface side with an electromagnet is also lightweight, so the mechanism for increasing or decreasing the pressing force of the pressing means is lightweight. do. Accordingly, it is possible to exhibit high responsiveness of one opposing surface according to the attraction force and repulsion force due to the change of the magnetic pole of the electromagnet or the change of the electric current.

Further, by providing the pressing force changing means for changing the pressing force in the pressing means, the pressing force can be changed without depending on the magnetic force of the permanent magnet and the electromagnet, so that tension to the yarn can be arbitrarily applied. Further, based on the pressing force by the pressing means, it is suitable for tension schedule control or control such as applying tension at an arbitrary timing, and power consumption can be further reduced.

In addition, by installing an electric means for changing the pressing force of the pressing means by electric transmission in the pressing force changing means, the pressing force of the pressing means of each thread tension adjusting device can be changed by electric transmission, eliminating the work of artificially changing the pressing force of the pressing means. I can. At this time, since the changing of the pressing force of the pressing means by the electric means is carried out based on the tension value detected by the tension sensor, it is also possible to monitor the tension of the thread by the tension sensor, thereby preventing external factors such as seam deposition. It can also cope with tension fluctuations caused by.

In addition, by applying the main body of the thread tension adjusting device to the top tension device, it can be installed without difficulty in lieu of the existing thread tension adjusting device, which pressurizes each other with only the pressing force of the pressing means when facing each other to the individual top tension devices with relatively space. have.

[Fig. 1] A perspective view of a top tension device provided with a thread tension adjusting device according to an embodiment of the present invention.
[Fig. 2] A perspective view of the thread tension adjusting device of Fig. 1;
[Fig. 3] A cross-sectional view of the thread tension adjusting device of Fig. 2;

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

Fig. 1 is a perspective view of a top tensioning device provided with a yarn tensioning device according to an embodiment of the present invention. As shown in Fig. 1, a plurality of top tension devices 1 are installed in a flat knitting machine not shown in the drawing, and are attached to a yarn Y drawn out from each yarn package. A thread tension adjusting device 2 for individually adjusting the applied tension is provided. This thread tension adjusting device 2 is attached to the base end side (upstream side of the feed path) of the frame 10 of the top tension device 1.

On the side surface of this flat knitting machine, a plurality of side tensioners are installed to remove loosening, etc. when the yarn Y tensioned by the top tension device 1 is fed to a knitting needle. A number of sudden death paths are concentrated by the side tensioner.

In addition, the top tension device 1 is provided with a tension arm 11 extending toward the upper end of the frame 10. In addition, reference numerals 12 to 17 denote a guiding section that guides and passes through the thread Y. And the yarn (Y) drawn out from the yarn package, in a state in which tension is applied by the yarn tension adjusting device (2), passes through the yarns (12 to 15), the yarn (16) of the tension arm (11) and the yarn It feeds from the part 17 to the carriage (not shown) side. At this time, the guiding section 13 is installed at the tip of the arm that swings up and down with the vicinity of the base end side of the frame 10 as a rotation axis, so when the thread Y is broken, the arm swings and the thread is broken. Can be detected.

Fig. 2 is a perspective view of the thread tension adjusting device 2 of Fig. 1, and Fig. 3 is a cross-sectional view of the thread tension adjusting device 2 of Fig. 2, respectively. As shown in Figs. 2 and 3, the thread tension adjusting device 2 is provided between the facing surfaces 211 and 221 of the first and second discs 21 and 22 facing each other. A thread tension adjusting device main body 20 is provided for adjusting by applying tension to the thread Y inserted in the thread Y.

The first and second disks 21 and 22 are installed on the same shaft 23, and of the two disks 21 and 22, the second disk 22 is located on the other end of the shaft 23 ( In Fig. 3, it is fixed to the right end side). Meanwhile, the first disk 21 is installed to be movable on the shaft 23. That is, in the first disk 21, the facing surface 211 (one facing surface) should be folded with respect to the facing surface 221 of the second disk 22 (the facing surface of the other side). It is installed on the shaft 23 to be able to.

The first disk 21 is provided with a substantially annular permanent magnet 24 on the rear side of the mating surface 211. On the other hand, in the second disk 22, an electromagnet 25 is provided on the rear side of the mating surface 221. This electromagnet 25 can change magnetic poles and change the amount of energization through a converter (not shown in the figure) that changes the direction of current and the amount of energization for a power source not shown in the figure. It is connected so that the change is controlled by the controller of the flat knitting machine not shown in the drawing.

The electromagnet 25 includes an iron core 251 and a coil 252 wound around the iron core 251, and the opposing surface 221 side of the second disk 22 becomes a magnetic pole surface. have. The first and second disks 21 and 22 are formed of a non-magnetic material such as stainless steel. The other end of the shaft 23 is fitted and attached to the iron core 251.

In addition, a substantially circular insertion hole 231 is formed at the corresponding position of the shaft 23 located between the opposing surfaces 211 and 221 of the first and second disks 21 and 22. have. In the insertion hole 231, a communication groove 232 communicating with the outer direction is formed, and a thread (Y) inserted and passed through the communication groove 232 into the insertion hole 231 In contrast, tension is applied between the opposing surfaces 211 and 221 of the first and second disks 21 and 22.

In addition, the first disk 21 is provided with a coil spring 27 as a pressing means for elastically pressing the opposite surface 211 at all times so that the opposite surface 211 becomes close to the opposite surface 221 of the second disk 22. Has been. The coil spring 27 is a screw member attached by screwing to one end (the left end in Fig. 3) of the shaft 23 in a state in which the expansion and contraction direction thereof is aligned on the shaft 23 ( 28) and the rear side of the opposite surface 211 of the first disk 21 so as to be contracted. In this case, the screw member 28 moves on the shaft 23 in the direction of expansion and contraction of the coil spring 27 by a manual tightening/unlocking operation (change operation), thereby changing the pressing force of the coil spring 27 It has a function as a pressing force changing means.

Therefore, in this embodiment, while the permanent magnet 24 is provided on the first disk 21 that is opposed to each other with the thread Y interposed therebetween, the opposed surface 211 of the first disk 21 is replaced with the second disk. A coil spring 27 that constantly pressurizes toward the opposite surface 221 of (22) is installed, while an electromagnet 25 capable of changing magnetic poles is installed on the second disk 22, so the magnetic pole of the electromagnet 25 When is changed by the converter, the attraction force and repulsion force for the polarity of the permanent magnet 24 are obtained. Further, since the electromagnet 25 is connected so that the amount of energization can be changed with respect to the power source, the attraction force and the repulsion force for the permanent magnet 24 are variable depending on the amount of energization.

Therefore, the pressing force of the coil spring 27 is increased by the suction force when the magnetic pole of the electromagnet 25 is changed to a polarity different from that of the permanent magnet 24, while the magnetic pole of the electromagnet 25 is reduced by a permanent magnet ( It is attenuated by the repulsive force when it is changed to the same polarity as 24). In this way, the permanent magnet 24 of the first disk 21, the coil spring 27, and the second disk 22 can change the magnetic poles and the electromagnet 25 capable of changing the amount of energization. When (2) is configured, when the pressing force of the coil spring 27 is increased or decreased, the facing surface 211 of the first disk 21 is moved in a bidirectional direction to be folded with respect to the facing surface 221 of the second disk 22 This, it is carried out according to the magnitude of the suction force and the repulsion force due to the transfer of the attraction force and the repulsion force by the change of the magnetic pole of the electromagnet 25 and the amount of energization to the electromagnet 25, and two electronic solenoids and a plunger are provided. There is no need to use one instrument each. Accordingly, it is possible to reduce the cost while suppressing the increase in size of the thread tension adjusting device 2 itself.

In addition, it is not dependent on the magnetic force by the pressing force of the coil spring 27, and it is possible to apply a constant tension to the thread Y sandwiched between the opposing surfaces 211 and 221 of the first and second disks 21 and 22. As a result, it is possible to eliminate the need for constant supply of power to the electromagnet 25, thereby reducing power consumption.

In addition, a permanent magnet 24 is installed on the first disk 21 that moves with respect to the opposing surface 221 of the second disk 22 in the state provided with the coil spring 27, but an electromagnet 25 is provided. Since it is lighter than the second disk 22, the mechanism for increasing or decreasing the pressing force of the coil spring 27 becomes lighter. Accordingly, in a flat knitting machine, for example, when the timing of switching the tension of the yarn by push knitting and pull knitting, that is, the timing at which the carriage is inverted, is required, the electromagnet 25 It is possible to exhibit high responsiveness of the first disk 21 according to the suction force and repulsion force due to the change of magnetic poles.

In addition, since the screw member 28 for mounting the coil spring 27 to be contracted between the first disk 21 functions as a pressing force changing means for changing the pressing force of the coil spring 27 by fastening and releasing, Since the pressing force can be changed without depending on the magnetic force of the permanent magnet 24 and the electromagnet 25, the tension to the yarn Y can be arbitrarily applied. Further, based on the pressing force by the coil spring 27, it is suitable for control such as tension schedule control or applying tension at an arbitrary timing, and power consumption can be further reduced.

In addition, since the thread tension adjusting device main body 20 is applied to the top tension device 1 of the flat knitting machine, it is more spatial than the area where a plurality of feed paths are concentrated by a plurality of side tensioners such as the side of the flat knitting machine. As a result, it can be installed without unreasonableness on the individual top tension devices 1 on the upper side with relatively sufficient margin, instead of the existing thread tension adjusting device that pressurizes each other only with the pressing force of the pressing means when facing each other.

In addition, the present invention is not limited to the above embodiment, and includes various modifications other than that. For example, in the above embodiment, when the pressing force of the coil spring 27 is changed, the screw member 28 is manually tightened and released, but the screw member is tightened and released by means of a motor such as a motor. It may be carried out as. Accordingly, it is possible to change the pressing force of the coil spring of the individual thread tension adjusting device by electric power, and it is possible to eliminate an artificial fastening/unlocking operation of the screw member. In addition, since the changing of the pressing force of the coil spring by the electric means is carried out based on the tension value detected by the tension sensor, it is possible to monitor the tension of the thread by the tension sensor, thereby preventing external factors such as seam deposition. It becomes possible to cope with the tension fluctuation caused by it.

At this time, it is not during knitting by the flat knitting machine that the pressing force of the coil spring is changed by the tightening and loosening operation of the screw member according to the rotation amount of the motor, but at the timing before knitting, and from this point, knitting A compact and inexpensive motor is being used because it is not required to control the tension as fast as the middle.

Further, in the above embodiment, the coil spring 27 was used as the pressing means, but an N-shaped leaf spring or an M-shaped leaf spring may be used, and these leaf springs are the screw member at one end of the shaft and the rear side of the opposing surface of the first disk. It is good if it is installed so that it contracts between the department.

Further, in the above embodiment, the yarn tension adjusting device 2 is installed in the top tension device 1 of the weft knitting machine, but if it is a feed path until the yarn drawn from the yarn package is fed to the knitting needle, in the side surface of the weft knitting machine It may be installed while avoiding each side tensioner, and of course, the thread tension adjustment device may be installed anywhere in any place.

1: Top tension device
2: thread tension adjusting device 20: thread tension adjusting device main body
211: facing surface of the first disk (one facing surface)
221: facing surface of the second disk (the facing surface of the other side)
24: permanent magnet 25: electromagnet
27: coil spring (pressing means) 28: screw member (pressing force changing means)
Y: thread

Claims (4)

A thread tension adjusting device provided with a main body of a yarn tension adjusting device that adjusts the tension applied to the yarn sandwiched between the opposite facing surfaces,
Of the two facing surfaces, one facing surface is configured to be folded with respect to the other facing surface,
Permanent magnets are installed on the one facing side, while on the other side, an electromagnet is connected so that the magnetic pole can be changed with respect to the power source and the amount of energization can be changed. Installed,
The one opposing surface side is provided with a pressurizing means for always elastically pressing the one opposing surface so as to be close to the other opposing surface side.
Thread tension adjustment device characterized by.
The method of claim 1,
The pressurizing means includes a pressing force changing means for changing the pressing force of the pressing means.
The method of claim 2,
The thread tension adjusting device, wherein the pressing force changing operation of the pressing means by the pressing force changing means is performed by electric means by means of electric power.
The method according to any one of claims 1 to 3,
The thread tension adjusting device main body is applied to a top tension device of a flat knitting machine.

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