KR790001581B1 - Anti-breaking device of cheese's ends on the spinning m/c - Google Patents

Abstract

A device for preventing a ballooning of cheese layer formed in a spinning machine such as OE spinning machine where yarn was positively delivered and taken-up to the chesse was described. A thension of taking-up yarn C yarn of delivery roller(5) and driving roller(6) was controlled according to the process of chess forming by clutching driving axes (5a,6a) of delivery roller and driving drum during operation.

Description

Cheese cross-section expansion prevention device in spinning machine

單位)의 예를 표시하는 사시도,1 is the radiation unit of an "open end" spinning machine

A perspective view showing an example of vi)

2 is a front view showing a "cheese" cross-sectional expansion state,

3 is a partial front view of a conventional device,

4 and 5 are some front views respectively showing an embodiment of the present invention,

6 is a winding tension diagram of a thread according to the present invention.

The present invention relates to an apparatus for preventing swelling of a cheese cross section formed in a spinning machine in which a yarn is wound around a cheese while actively pulling out a thread such as an open end spinning machine. It is about.

When winding the bobbin and winding it to form a cheese by reciprocating (Traverse), the cross section of the cheese is swelled, the size of the swelling is the type of thread, thickness, degree of wool, Although it varies greatly depending on the winding tension and the cheese press welding, in the past maritime machines, efforts have been made to reduce the expansion of this cheese section by gradually decreasing the winding tensions of the initial winding and the winding boil.

In the winding machine, since the thread was wound around the cheese and passively drawn out, the tensioning force could be easily adjusted by a device for applying tension, but the fiber in the rotor rotating at a constant speed In the open end spinning machine in which the yarn is focused and flamed to form a thread, the yarn is wound up in the cheese while the yarn is actively drawn out, so that the number and the thickness of the yarn are kept constant. Since the speed must be kept constant, this open and spinning machine is used as a measure to reduce the swelling of the cheese section in the past, and is wound from the initial winding when the cheese is pressed against the electric drum that drives the cheese. The pressure was gradually reduced until the end of the boil, but did not have enough effect. Especially when using thick cotton yarns, there was a tendency for bundles to break.

The present invention has been made in view of this point and the gear is formed by adjusting the drive shaft of the roller which draws out the thread and the drive shaft of the electric drum during operation, so that the tension of the thread between the draw roller and the electric drum, that is, the wound coil, is formed. It is characterized in that it is adjusted according to the process.

)장치(1)로부터 실(9)로 만들어지며 이 실(9)은 모우터(11)에 의해 감속장치(12)를 거쳐서 회전 구동되는 축(5a)에 고착된 구동인출로울러(5)와, 이 구동로울러(5)에 압접되어 있는 종동(從動) 인출로울러(4)에 의해서 파지(把持)되고, 양 로울러(4),(5)의 회전에 따라 방사장치(1)로부터 인출된다. 종동 인출로울러(4)는 스프링(도시안함)에 의해서 구동인출로울러(5)에 압접하는 방향으로 부세되어 있다. 전동드럼(6)은 그 드럼에 파진 트레버어스(Traverse)홈(6')에 의하여 옆으로 왕복 운동시키면서 크레이들(18)에 회전자재롭게 지지되고, 드럼(6)에 압접하는 방향으로 부세되어 있는 보빈(7)을 전동시킴으로써 실(9)을 보빈(7)에 권취해서 치이즈(8)를 만든다.Next, an embodiment of the present invention will be described. In the drawing, the sliver 3 contained in the can 2 is radiated.

And a drive take-out roller (5) secured to a shaft (5a) which is rotationally driven by a motor (11) via a reduction gear (12) by a motor (11). The rollers are gripped by the driven take-out rollers 4 which are pressed against the drive rollers 5, and are taken out from the radiator 1 as the two rollers 4 and 5 rotate. . The driven pull-out roller 4 is urged in the direction which press-contacts the drive pull-out roller 5 with a spring (not shown). The electric drum 6 is rotatably supported by the cradle 18 while being reciprocated laterally by the traverse groove 6 'which is crushed in the drum, and is urged in the direction in which the drum 6 is pressed against. The bobbin 7 is wound around the bobbin 7 by rolling the bobbin 7 to make the cheese 8.

6a is a shaft to which the electric drum 6 is fixed, and is driven via the gear mechanism 13 by the shaft 5a of the drive take-out roller 5. 13a is a drive gear fixed to the shaft 5a, a gear 13b is a flow gear, and 13c is a driven gear detachably fixed to the shaft 6a. By using (13a) or (13c), the rotational speed ratio of the shaft 5a and the shaft 6a can be changed. At this time, the interaxial distance adjustment can be easily adjusted by changing the attachment position of the gear 13b. Ratio of the peripheral diameter of the drive take-out roller 5 x the peripheral speed of the take-out roller 5 and the peripheral speed of the electric drum 6 x the peripheral speed of the drum 6 According to this, the tension of the thread between the take-out roller 5 and the electric drum 6, that is, the winding tension, is determined.

Many spinning units are arranged in single or multiple lines as shown in FIG. 3, and the drive take-out roller 5 is fixed to the axis 5a common to each of the spinning unit rows, and driven The drawing roller 4 is arranged for each radiation unit.

In addition, the electric drum 6 is fixed to the shaft 6a common to each radiation unit row. In recent years, the doping of cheeses is often performed in one unit of each radiation unit in view of power saving. At this time, the cheeses of each unit are made almost the same in each unit of radiation unit, and at the same time, do. In the embodiment of Fig. 4, the transmission 14 is provided between the take-out roller 5a and the drive drum shaft 6a, and the electric drum shaft 6a is driven through this.

The rotational speed ratio between the input shaft 15 of the transmission 14, that is, the take-out roller shaft 5a, and the output shaft 16, that is, the electric drum shaft 6a, can be adjusted by moving the transmission lever 17 of the transmission. One end of the link 22 is connected to the arm 19 of the cradle 18 with a pin 21, and one end of the lever 23 that is swingable around the point 23 'is connected to the arm 19 of the cradle 18. And the other end of the lever 23 is connected to the shift lever 17 again.

Therefore, as the thread 9 is wound around the bobbin 7 and the cheese 8 is formed, the cradle 18 which fixes the bobbin 7 freely and rotates is rotated around the rotation shaft 20. When the position is changed, the speed ratio of the take-out roller shaft 5a and the electric drum shaft 6a is changed, so that the tension of the thread 9 between the take-out roller 5 and the electric drum 6, that is, the winding tension of the thread 9, is increased. Different.

If the link mechanism is made so that the relationship between the rotation angle of the cradle 18 and the transmission ratio of the transmission 14 according to the diameter of the gear can be appropriately determined, the expansion of the cheese can be prevented.

As described above, the open end is provided with a counter 27 that can return to zero to calculate the cumulative number of rotations of the electric drum shaft 6a in order to perform the doping work in unison. There is a spinning machine, and an example suitable for such spinning machine is shown in FIG. In the figure, the counter 27 is set to zero at the start of the doping operation, and the counter 27 is doped at the time when the counter 27 displays a predetermined coefficient. The counter 27 operates the limit switch 31 whenever the projection 30 of the cam 29 provided on the motorized drum shaft 6a rotates one rotation of the shaft 6a. Counting operation is performed by a pulse signal. In the embodiment of Fig. 5, this pulse signal is used as an input to a rotary pulse compensator 24 provided separately. That is, the rotary pulse compensator 24 rotates the output shaft 25 by a predetermined angle each time a pulse signal is input as an input, and a deceleration mechanism is attached to a known stepping motor. In the period from the beginning to the end of the period when the cheese is formed, the motor rotates by a predetermined angle within a range not exceeding one revolution on the basis of the number of pulses before sweating. Reference numeral 28 denotes a direct current power source.

The lever 26 is fixed to the output shaft 25 and connected to the shift lever 17. As the seal 9 is wound around the bobbin 7, and the cheese 8 is formed, the limit switch 31 is applied to the protrusion 30 of the cam 29 whenever the electric drum shaft 6a rotates once. By sending a pulse signal, the position of the shift lever 17 is sequentially changed through the oscillation device 24 and the lever 26 by this pulse, and the input shaft 15 of the speed change device 14, that is, the drawing roller shaft ( The speed ratio between 5a) and the output shaft 16, i.e., the electric drum shaft 6a, is sequentially changed, so that the tension of the thread between the take-out roller 5 and the electric drum, i.e., the winding tension of the thread, is changed sequentially.

The return of the output shaft 25 of the rotary pulse compensator 24 to the original position is electrically connected to return the counter 27 at the same time when the counter 27 is returned to zero.

That is, the output shaft 25 is biased in the original position by a spring not shown in the drawing, and a clutch is attached between the stepping motor of the rotary propulsion device 24 and the output shaft 25 and turned to an electrical signal when turned to zero. By briefly disconnecting the clutch, the clutch returns to its original position.

By changing the relative dimensions of the link mechanism 23 and the shift lever 17 or the dimensions of the relative positions of the lever 26 and the shift lever 17, or making the lever 26 a cam, the shape of the cam is changed. As a result, the rate of change of the winding tension of the yarn 9 can be easily adjusted. The transmission 14 may be of any type, and is not limited to the continuously variable transmission, but may be a step shifting operation. In addition, as a means of detecting the process of making cheese, in Example 1, an arm 19 of a cradle that directly detects the cheese diameter as in the fourth degree was used. Although a rotary pulse oscillation device 24 that integrates the number of revolutions of the drive shaft 6a of the electric drum 6 was used, the same procedure as in Example 1 was used to directly detect the cheese forming process, or as in Example 2 As long as it detects and estimates the formation process of indirectly, any may be sufficient. In the second embodiment, the pulse compensator 24 may be operated by the rotation of the drawing roller shaft 5a instead of the electric drum drive shaft 6a. In this case, the transmission device 14 and Of course, it is necessary to modify the program by modifying the interlocking relationship with the rotary pulse compensator.

According to the present invention, it is easy to change the winding tension of the thread gradually according to the process of creating the cheese, and since the program for decreasing the tension is decided more broadly and freely by the link mechanism or the transmission, the advantage of setting the most appropriate tension change is advantageous. have.

6 shows an example of the change curve of the winding tension according to the present invention, where the horizontal axis A represents the cheese diameter and the vertical axis B the tension of the yarn. As shown in this curve (C), it is ideal to become a tension change curve that gradually decreases with the diameter of the yarn and convex downwardly.

Claims (1)

Withdrawal roller 5, which is used to wind the drawn yarn 5 and the drawn yarn to form a cheese 8 by winding the drawn yarn, is drawn out in a spinning machine equipped with an electric drum 6; A transmission 14 is provided between the drive shaft 5a of (5) and the drive shaft 6a of the electric drum 6, and the means for integrating the rotational speeds of either drive shaft and the integration means Means for returning to the gearbox and a means for operating the transmission 14 in association with the integrating means, and the rotation ratio between the take-out roller 5 and the electric drum 6 in accordance with the process in which the teeth 8 are formed. The expansion preventing device of the cross section of the cheese (8) characterized by adjusting ().

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