JP2004277943A - Spinning machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve efficiency of operation for tightening a loosened yarn, required at piecing of yarns in a spinning machine having many spinning units arranged therein. <P>SOLUTION: A device 10 for tightening the loosened yarn having a loosened yarn-tightening roller 21 on which the yarn is wound, and an unwinding tension-imparting member 22 for imparting the tension to the yarn unwound from the loosened yarn-tightening roller 21 is installed in each spinning unit 2 in the spinning machine 1 having the many spinning units 2. When the piecing operation is finished at one spinning unit 2, a working wagon 3 can be moved while the device 10 for tightening the loosened yarn carries out the unwinding of the yarn to shorten a time to be required for the piecing operation of the many spinning units 2. The member 22 for imparting the unwinding tension of the device for tightening the loosened yarn can impart the proper tension to the yarn at unwinding to eliminate the difference of the yarn tension from that at a normal winding, and to provide a yarn package 16 having good wound state precisely. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a spinning machine in which a plurality of spinning units are provided, the spinning machine including a yarn slack removing device for removing slack of a yarn generated between a spinning device and a winding device.
[0002]
[Prior art]
In a spinning machine (for example, a pneumatic spinning machine) that generates spun yarn from a sliver (fiber bundle) and winds it into a predetermined package, if a yarn defect is detected, the yarn defect is cut with a cutter. Then, the leading end of the yarn successively sent from the spinning device and the yarn end on the package side are spliced by a splicing device. Since the piecing operation is performed in a state where the winding of the yarn is stopped, in order to remove the slack of the yarn continuously fed from the spinning device, for example, a suction tube called a slack tube as described in Patent Document 1 is used. In some cases, a means for sucking excess yarn is employed. However, with the increase in the slack amount due to the recent increase in spinning speed, it has become difficult to cope with the slack removal of the increased amount of yarn with the suction tube method. In addition, the suction tube method has a problem that it is difficult to apply sufficient tension to the yarn at the time of removing the yarn slack because the yarn is pulled only by suction air by a negative pressure.
[0003]
Therefore, as an alternative to the suction pipe system, a roller system that eliminates yarn slack by temporarily winding a yarn fed from a spinning device around a storage roller (slack removal roller) as described in Patent Document 2 A yarn storage device (yarn slack removing device) has been proposed. The yarn storage device is mounted together with a yarn coupling device (yarn splicing device) on a maintenance device (working cart) that can travel along the spinning machine. The yarn storage device is provided with a storage element and a return element formed of a yarn return ring. This return element guides the introduction of the yarn when the yarn is wound around the storage roller at the time of splicing, and when the yarn is unwound from the storage roller after resuming winding into a package, a certain unwinding tension is applied. And a function of guiding the yarn to the winding package while providing the yarn.
[0004]
[Patent Document 1]
JP 2001-159039 A
[Patent Document 2]
Japanese Patent Publication No. 4-13272
[0005]
[Problems to be solved by the invention]
In the technique described in Patent Literature 2, a yarn storage device is loaded on a maintenance device together with a yarn coupling device. Therefore, if a request for a splicing operation is issued from another spinning unit while the maintenance device is moved to one of the spinning units of the spinning machine and the splicing operation is performed, the spinning during the splicing operation is performed. The maintenance device cannot move to another spinning unit unless the yarn splicing operation is completed in the unit and the unwinding of the yarn from the storage roller that is winding up the slack of the yarn is completed. Therefore, there is a problem that the execution time of the piecing operation directly affects the operation time of the spinning operation, and a delay in the piecing operation may cause a delay in the entire spinning operation.
[0006]
Therefore, in the yarn storage device described in Patent Literature 2, in order to increase the yarn unwinding speed from the storage roller after completion of the piecing, it is conceivable to reduce the resistance of the return element that guides the yarn unwinding to the yarn. Can be However, in this case, the yarn tension between the return element and the winding package at the time of unwinding the yarn, ie, the winding tension, is much lower than at the time of normal winding. This causes a difference in winding tension between the time of unwinding and the time of regular winding, which lowers the winding tension when the yarn unwound from the storage roller is wound into the winding package at the same time. Will be done. As a result, the winding state of the winding package becomes non-uniform, and there is a possibility that a stepped shape is formed on the end face of the package due to the difference in the magnitude of the tension.
[0007]
[Means for Solving the Problems]
The present invention provides means capable of solving the problems of the prior art, and is characterized in that a plurality of spinning units are provided, and a work vehicle equipped with a piecing device is provided between each spinning unit. In a spinning machine configured to be movable, a slack removing roller for winding a slack yarn generated due to splicing, and applying a predetermined unwinding tension to the yarn when unwinding the yarn wound from the slack removing roller And a yarn slack removing device having an unwinding tension applying member for performing each of the spinning units.
[0008]
By adopting such a configuration, when the piecing operation is completed in the spinning unit that requires piecing, the work bogie is separated while the yarn is being unwound by the yarn slack removing device of the spinning unit. Can be moved to the spinning unit. Therefore, when the piecing operation is continuously performed on a plurality of spinning units, the stop time of the work cart per spinning unit can be reduced, and the operating efficiency of the spinning machine is improved. Further, since it takes time to unwind the yarn wound from the slack removing roller of the slack removing device, it is easy to apply an appropriate tension to the yarn being unwound. That is, the yarn tension during unwinding can be made to match or approach the yarn tension during regular winding, so that a yarn package with a good winding state can be reliably obtained.
[0009]
In the spinning machine, it is preferable that the unwinding tension applying member is provided with an unwinding tension adjusting mechanism capable of presetting the magnitude of the unwinding tension applied to the yarn unwound from the slack removing roller (claim) Item 2). By employing such an unwinding tension adjusting mechanism, the yarn tension when unwinding from the slack removing roller can be set or adjusted in advance according to the spinning conditions such as the yarn type and the yarn count.
[0010]
Further, it is conceivable that the unwinding tension applying member has a function as a yarn hooking member for introducing the yarn into the slack removing roller. In this case, the advantage that the number of parts of the yarn slack removing device can be reduced and the configuration can be simplified can be obtained.
[0011]
In the spinning machine, the work cart is moved to the position of the corresponding spinning unit based on the splicing request signal output from the spinning unit. When the work vehicle reaches the corresponding spinning unit position, the slack removal is performed based on the arrival detection signal. It is conceivable to set so as to start the rotation of the roller (claim 4). By adopting such a configuration, the operation of the slack removing roller of the thread slack removing device and the operation of the work carriage can be reliably ensured.
[0012]
Further, in the spinning machine, it is preferable that a drive unit is provided for each of the slack removing rollers, so that each slack removing roller can be driven to rotate independently (claim 5). With this configuration, it is possible to independently perform a different thread slack removal operation for each spinning unit.
[0013]
It is also conceivable to adopt a configuration in which the unwinding tension applying member is moved to a position where the unwinding tension applying member does not engage with the yarn after the unwinding of the yarn wound by the slack removing roller is completed. 6). This prevents the unwinding tension applying member from coming into contact friction with the yarn being normally wound after unwinding the yarn, so that it is possible to avoid adversely affecting the yarn quality after resuming winding.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of a spinning machine according to the present invention will be described with reference to the drawings. In the present specification, "upstream / downstream" refers to upstream / downstream with respect to the running direction of the yarn during spinning. Specifically, the spinning device side is upstream and the winding device side is downstream.
[0015]
FIG. 1 is a front view showing an example of a spinning machine 1 to which the present invention is applied, and FIG. 2 is an enlarged view schematically showing a partial internal structure of the spinning machine 1. The spinning machine 1 including, for example, a pneumatic spinning machine includes a control unit 1A, a spinning unit 1B in which a large number of spinning units 2 are arranged side by side, a blower unit 1C, and a piecing device. The work cart 3 which can be run freely is a main component.
[0016]
The control unit 1A is provided for each of the spinning units 2 and the driving motors 31, 32, and 33 of the drive shafts 41, 42, and 43 that apply a driving force in common to all the spinning units 2 constituting the spinning unit 1B. It controls the operations of the motors 34 and 35, the winding device 12, and the like. In the present embodiment, based on various set values (spinning speed, ratio between the spinning speed and the take-up roller speed) input to the input unit a, the arithmetic unit b controls the motors 31 to 34 for the inverter c or The spinning speed information is output via the driver board 30. Further, rotation speed information of a slack removing roller (described later) is output to a motor 35 of the thread slack removing device 10 via a driver board 40.
[0017]
The spinning unit 1B includes a large number of spinning units 2 arranged side by side, and each spinning unit 2 is configured to be independently controllable. The spinning machine 1 according to the present invention is characterized in that a yarn slack removing device 10 is provided for each spinning unit 2 together with the spinning device 5 and the winding device 12. The details of the structure of the spinning unit 2 will be described later.
[0018]
The blower unit 1C accommodates a negative pressure supply unit that applies a negative pressure (suction pressure) to a required portion of the spinning unit 2 through an air duct, and applies a negative pressure to the yarn suction device 7 and the like. .
[0019]
The work vehicle 3 can travel on the rail R, move to a corresponding spinning unit 2 position, and stop based on a splicing request signal transmitted from any spinning unit 2 requiring splicing. As shown in FIG. 3, which is a side cross-sectional view schematically showing the configuration of the spinning section 1B, the end of the yarn formed by the yarn splicing device 17 such as a knotter or a splicer and the spinning device 5 is shown. A suction pipe 18 for sucking and guiding to the piecing device 17, a suction mouth 19 for sucking the yarn end of the package 16 supported by the winding device 12 and guiding to the piecing device 17, and contacting the yarn Y when necessary (FIG. 12) A tension arm 20 for applying a yarn tension is provided.
[0020]
In addition, an example in which the yarn splicing device 17, the suction pipe 18, and the suction mouth 19 are provided for each of the spinning units 2 is also considered. By loading the suction pipe 18 and the suction mouth 19, the yarn splicing operation for all the spinning units 2 can be performed with only one set, so that the structure of the spinning machine 1 can be simplified.
[0021]
The suction pipe 18 for piecing provided in the work cart 3 functions as a suction member at the yarn end on the spinning side, and has a suction port 18a at the tip and rotates around a pivotal support 18b. It is done freely. At the time of the piecing operation, the yarn is rotated upward as shown by the two-dot chain line in FIG. 6 to position the suction port 18a near the yarn discharge port of the spinning device 5, and the yarn Y of the spun yarn Y is spun. After sucking the end, the yarn Y1 on the spinning side is guided to the piecing device 17 by rotating downward to the initial position indicated by the solid line in the same drawing in the suction state. On the other hand, the suction mouth 19 functions as a suction member for the winding-side yarn end, has a suction port 19a at the tip, and is rotatable around a pivot 19b. At the time of the splicing operation, after the package 16 is stopped from rotating, the package 16 is rotated in a direction opposite to the normal direction, and suction is performed at the suction port 19a at the tip of the suction mouth 19 in which the yarn end is rotated downward. After the yarn is caught and threaded out, the yarn Y2 on the package 16 side is guided to the piecing device 17 by rotating upward to the initial position indicated by the solid line in the drawing while maintaining the suction state.
[0022]
Next, the spinning units 2 provided in the spinning section 1B will be described. The spinning unit 2 is one unit for manufacturing the yarn Y from the fiber bundle S of the raw material, and as shown in FIG. 3, a draft device 4, which is arranged in order from the upstream side to the downstream side of the yarn path E, The apparatus includes a spinning device 5, a yarn feeding device 6, a yarn suction device 7, a cutter 8, a yarn defect detector 9, a yarn slack removing device 10, a waxing device 11, and a winding device 12.
[0023]
As the draft device 4, for example, a four-wire type device including a second roller 4d and a front roller 4e having a back roller 4a, a third roller 4b, and an apron 4c stretched from the upstream side is applied. The spinning device 5 is, for example, a pneumatic type that generates a spun yarn Y (hereinafter, simply referred to as “yarn Y”) from a fiber bundle S using a swirling airflow, and has a spinning speed of several hundred m / min. That can perform high-speed spinning is adopted. In addition, the spinning device 5 can be replaced with another structure such as a device that generates a yarn Y by a pneumatic spinning nozzle and a twisted roller pair, or an open-end spinning machine that generates the yarn Y by rotating a rotor. is there. The yarn feeder 6 includes a nip roller 6a and a delivery roller 6b, and holds the yarn Y between the rollers 6a and 6b to feed the yarn Y to the downstream side. The yarn suction device 7 is always in a suction state, and when the yarn defect detector 9 detects a defect of the yarn Y, the yarn suction device 7 sucks and removes a fragment of the yarn Y cut by the cutter 8.
[0024]
The winding device 12 is for winding a yarn Y around a bobbin 15 held on a cradle arm 14 to form a package 16, and includes a rotating drum 13 that rotates in contact with the bobbin 15 or the package 16. The cradle arm 14 is configured to be rotatable so that the bobbin 15 or the package 16 can be moved toward and away from the rotating drum 13.
[0025]
As shown in FIGS. 3 to 5, the yarn slack removing device 10 provided in each of the spinning units 2 includes a slack removing roller 21 for winding and storing the slack yarn Y around the outer peripheral surface 21a (see FIG. 17), and a slack removing roller 21 according to conditions. An unwinding tension applying member 22 that rotates concentrically or independently of the take-up roller 21, an upstream guide 23 that is arranged slightly upstream of the slack-removing roller 21, a stepping motor that drives the slack-removing roller 21 to rotate, and the like. , A driver board 40 (see FIG. 2) for controlling the driving means 35, and a downstream guide 36 provided at a position downstream of the slack removing roller 21 and having a slit 36a. It is fixed to the spinning unit 2 by a bracket 37 or the like.
[0026]
As shown in FIGS. 16 to 18, the slack removing roller 21 is fixed to the drive shaft 35 a of the drive unit 35 and rotates integrally with the drive shaft 35 a. Therefore, the rotation of the slack removing roller 21 can be controlled in accordance with the rotation speed set by the calculation unit b. Further, assuming that the side having the unwinding tension applying member 22 is the distal end P and the side connected to the driving means 35 is the proximal end Q, the outer peripheral surface 21a has the proximal end Q side and the distal end P side facing the end surface. Tapered portions 21b and 21d whose diameters are increased are formed, and a middle portion thereof is a cylindrical portion 21c having the same diameter. At the time of piecing, the yarn Y spun from the spinning device 5 is wound from the base end Q side to the outer peripheral surface 21a, and then unwound from the leading end P side to the winding device 12 side. (See FIGS. 9-11). The tapered portion 21b on the proximal end Q side smoothly moves the supplied and wound yarn Y from the large-diameter portion 21b-1 to the small-diameter portion 21b-2 to reach the intermediate cylindrical portion 21c, thereby causing the yarn Y to move. It has a function of regularly winding around the surface of the cylindrical portion 21c. Further, the tapered portion 21d on the tip P side suppresses the loop detachment phenomenon in which the wound yarn Y comes off at the time of unwinding, and at the same time, moves the yarn Y from the small diameter portion 21d-2 to the large diameter portion 21d-1. It has a function of sending out the wound yarn layer in a progressive manner and ensuring smooth extraction of the yarn Y.
[0027]
As shown in FIG. 18, the unwinding tension applying member 22 provided on the leading end P side of the slack removing roller 21 is configured by attaching a flyer 22a to the roller 21 by a transmission force adjusting mechanism so as to be concentrically rotatable. The configuration of the transmission force adjusting mechanism is as follows. That is, a wheel member 22b is rotatably mounted on a shaft portion 21e protruding from a central portion of the roller 21 via a bearing member 22c such as a bearing, and the base of the flyer 22a is attached to the wheel member 22b. The wheel member 22b is screwed into a bolt portion at the tip of the shaft portion 21e, for example, a transmission force adjusting operation portion 22g including a nut member 22d, a pressing member 22e, and the like. The force applying member 22f is attached by preventing it from coming off. Therefore, the transmission force adjusting mechanism of the present embodiment can adjust the pressing force (frictional force) of the transmission force applying member 22f steplessly by the tightening operation of the transmission force adjusting operation portion 22g screwed into the bolt portion of the shaft portion 21e. And
[0028]
The transmission force adjusting mechanism of this embodiment adjusts the pressing force (frictional force) of the transmission force applying member 22f in a stepless manner by tightening the transmission force adjusting operation portion 22g such as the nut member 22d screwed to the shaft portion 21e. Although not limited to this, instead of the shaft portion 21e, a shaft portion provided with a position regulating portion for positioning the pressing member 22e stepwise at predetermined intervals in the longitudinal direction is provided, and the pressing member for the shaft portion is provided. The mounting position of 22e may be changed stepwise. Alternatively, a plurality of types of holding members 22e having different lengths in the longitudinal direction of the shaft portion may be prepared, and the holding member 22e attached to the shaft portion may be appropriately replaced depending on conditions. Further, in addition to these friction adjusting mechanisms, as a non-contact adjusting mechanism, for example, an electromagnetic clutch system using an electromagnet may be used, and the magnitude of the transmitting force may be adjusted by changing the magnetic attraction force of the magnet. Things are also possible.
[0029]
Note that, as in the present embodiment, the transmission force adjusting mechanism is provided at a connection portion between the slack removing roller 21 and the unwinding tension applying member 22, and the transmission force adjusting operation section 22 g is exposed on the tip P side of the slack removing roller 21. With such a configuration, the transmission force adjustment work by the operator can be easily performed. In order to prevent the transmission force adjusting mechanism from hindering smooth yarn unwinding, the transmission force adjusting mechanism is configured not to interfere with the surface formed by the trajectory of the yarn Y unwound from the slack removing roller 21. It is desirable. In the present embodiment, as shown in the drawing, the tip of the shaft portion 21e is configured to enter the back side of the roller 21 from the roller tip P, so that the shaft portion is formed on the yarn path of the yarn Y unwound from the slack removing roller 21. There is no interference of the transmission force adjustment operation portion 22e and the transmission force adjustment operation portion 22g, and there is no possibility that the smooth yarn unwinding is prevented.
[0030]
The transmission force adjusting mechanism is capable of adjusting the magnitude of the rotational resistance of the flyer 22a with respect to the slack removing roller 21. That is, if the degree of tightening of the pressing member 22e is reduced, the pressing force (or frictional force) of the transmission force applying member 22f to the wheel member 22b is reduced, and the flyer 22a slips by applying a slight load. Then, it becomes possible to rotate independently of the rotation of the slack removing roller 21. Conversely, if the tightening degree of the pressing member 22e is increased, the pressing force of the transmission force applying member 22f against the wheel member 22b is increased, and the flyer 22a does not slip unless a very large load acts. Following the slack removing roller 21, it rotates integrally.
[0031]
Therefore, the unwinding tension applying member 22 of the present embodiment can adjust the degree of tightening of the pressing member 22e to change the behavior of the fryer 22a, which can rotate independently of the loosening roller 21, from the loosening roller 21. It can be adjusted in relation to the tension of the yarn Y to be unwound. That is, the unwinding tension of the yarn Y from the slack removing roller 21 that varies depending on the spinning conditions such as the yarn type and the yarn count can be adjusted in advance by the transmission force adjusting mechanism. The behavior of the fryer 22a is determined by the interaction between the rotational force transmitted from the slack removing roller 21 via the transmitting force imparting member 22f and the tension of the yarn Y unwound from the slack removing roller 21. Conversely, if the behavior of the fryer 22a is adjusted in advance by the transmission force adjusting mechanism, the magnitude of the resistance that the fryer 22a applies to the yarn Y unwound from the slack removing roller 21 can be set in advance. . That is, the transmission force adjusting mechanism functions as an adjusting mechanism of the unwinding tension applied to the yarn Y by the fryer 22a.
[0032]
The flyer 22a of the present embodiment employs a characteristic shape as described below in order to reliably wind the yarn Y around the outer peripheral surface 21a of the slack removing roller 21. That is, the fryer 22a extends from the base attached to the wheel member 22b to a position protruding outward in the radial direction opposite to the rotation direction of the base end Q slightly more than the front end P of the slack removing roller 21, and further. It is set so that it bends at three places of m, l, and k in order from the inside, and the tip end j is located outside the radius of the slack removing roller 21. Of the three bent portions, two bent portions k and l are outside the radius of the roller, and one bent portion m is located within the radius of the large-diameter portion 21d-1 of the roller 21. Then, at the inward bending point m, the flyer 22a bends outward in the radial direction opposite to the rotation direction of the slack removing roller 21 at the time of winding the yarn, and moves toward the base end Q side of the slack removing roller 21 at the next bending point l. It is formed to be bent, and finally to be bent in the rotation direction of the slack removing roller 21 at the outer bent portion k. Accordingly, a thread engaging portion R having an angle that opens outward in the rotation direction of the slack removing roller 21 is formed in the fryer 22a by the distal end portion j, the bent portion k, and the bent portion l. Is opposed to the outer peripheral surface 21a while maintaining a predetermined distance from the outer peripheral surface 21a of the roller between the leading end P and the proximal end Q of the slack removing roller 21. The fryer 22a having such a configuration has a preferable shape in that the yarn Y engaged at the time of slack removal is rotated with the slack removing roller 21 so as to be stably wound around a predetermined position on the slack removing roller outer peripheral surface 21a. ing. Further, it has the effect of reliably preventing the yarn Y from getting stuck in the gap between the slack removing roller 21 and the fryer 22a.
[0033]
The work carriage 3 is provided with advance / retreat means 24 including an air cylinder or the like for driving the upstream guide 23 to advance / retreat, and control means (not shown) for controlling the advance / retreat means 24. That is, the upstream side guide 23 is a yarn moving unit, and the advance / retreat unit 24 is a driving unit thereof. The upstream guide 23, which is driven forward and backward by the forward and backward means 24 such as an air cylinder, is at a position where the yarn Y does not engage with the yarn slack removing device 10 when it is at the forward position (see FIGS. 4 and 5). When the yarn Y is at the retracted position (see FIGS. 7 and 8), the yarn Y is engaged with the flyer 22a of the yarn slack removing device 10 until the yarn Y is wound up by the slack removing roller 21. Is set to move. The fryer 22a is arranged so as to be able to engage with the yarn Y on the yarn path connecting the upstream guide 23 and the downstream guide 36 at the retreat position at the shortest distance. That is, the rotating surface of the fryer 22a that rotates together with the slack removing roller 21 is set so as to intersect the yarn path.
[0034]
The operation of the spinning machine 1 configured as described above will now be described. During normal operation of the spinning unit 2 in a state where the work cart 3 is not stopped, as shown in FIG. 8, the upstream guide 23 of the yarn slack removing device 10 is forcibly moved by a tension member such as a spring (not shown). In the retracted position. In a state where the yarn Y is not wound around the slack removing roller 21 at the time of the normal spinning (winding), no yarn splicing request signal is output from the spinning unit 2 at this time. Is set so that a rotation command is not output to the drive motor 35 via the. In addition, the flyer 22a is stopped at the separated position where it does not come into contact with the yarn path by the control described later (see the two-dot chain line in FIG. 8 and FIGS. 15C and 15D). Further, even if the slack removing roller 21 is rotating and the yarn Y runs on a yarn path that can engage with the yarn slack removing device 10, a certain amount of tension acts on the yarn Y. Thus, there is no possibility that the yarn Y is wound around the slack removing roller 21. Each spinning unit 2 of the spinning machine 1 feeds the fiber bundle S to the spinning device 5 by the draft device 4, and sends the yarn Y spun and generated by the spinning device 5 to the downstream side by the yarn feeding device 6. After passing just before the suction device 7 and the yarn defect detector 9, the yarn Y is sent to the winding device 12 through the upstream guide 23, the downstream guide 36, and the waxing device 11, and the yarn Y is bobbin Then, the package 16 is formed.
[0035]
When the yarn defect detector 9 of any of the spinning units 2 detects a defect such as a slab in the yarn Y, in the spinning unit 2, the cutter 8 cuts the yarn Y, and at the same time, the back roller 4a of the draft device 4 and the third roller 4b stops the rotation, and the cradle arm 14 of the winding device 12 rotates to separate the package 16 from the rotating drum 13 (see FIG. 6). Thereafter, the package 16 stops the rotation naturally or forcibly stops depending on the situation. In addition, the second roller 4d and the front roller 4e continue to rotate.
[0036]
The portion Y2 of the yarn Y cut by the cutter 8 on the winding device 12 side is wound up by the package 16 which continues to rotate by inertia. On the other hand, with respect to the yarn Y1 on the side of the spinning device 5, the rotation of the back roller 4a and the third roller 4b of the draft device 4 is stopped, and the stopped third roller 4b and the second roller 4d continuing to rotate are stopped. In between, the fiber bundle S is pulled and cut. The yarn fragments from the cutting position to the position of the cutter 8 are sent out by the second roller 4d and the front roller 4e which are continuing to rotate, are passed through the spinning device 5, and are sucked and removed by the yarn suction device 7.
[0037]
Based on the splicing request signal output while the spinning unit 2 performs the above operation, the work vehicle 3 travels and moves to the position of the spinning unit 2 requiring splicing. When the work vehicle 3 arrives at the predetermined position, first, as shown in FIG. 4, the upstream guide 23 is moved to the forward position by the reciprocating means 24 of the work vehicle 3, and the yarn path is engaged with the yarn slack removing device 10. It is changed to a position where there is no danger of doing. Next, based on the output arrival detection signal, the corresponding spinning unit 2 outputs a rotation command to the driving motor 35 via the driver board 40, and the spinning roller 21 of the thread slack eliminating device 10 at an appropriate timing. Start rotation.
[0038]
Subsequently, the following piecing operation is performed by the work cart 3. As shown by the two-dot chain line in FIG. 6, the suction pipe 18 is rotated upward to position the suction port 18a near the yarn discharge port of the spinning device 5. At the same time, the spinning unit 2 restarts the back roller 4a and the third roller 4b that have been stopped to bring the draft device 4 into a driving state, sends the fiber bundle S to the spinning device 5, and restarts spinning. After sucking and capturing the yarn end of the yarn Y1 continuously spun from the spinning device 5, the suction pipe 18 turns downward to the initial position shown by the solid line in FIG. . The yarn Y1 is introduced into the yarn feeder 6 from the side of the nip roller 6a. The suction pipe 18 continuously sucks the yarn Y1 generated and sent from the spinning device 5 until the subsequent splicing operation is started.
[0039]
Simultaneously with the rotation of the suction pipe 18 (or after some time), the suction mouth 19 is rotated downward to the position shown by the two-dot chain line in FIG. The yarn end of the yarn Y2 is sucked and captured from the package 16 rotating in the direction opposite to the direction of picking, and the yarn is pulled out. Next, while maintaining the suction state, the suction mouth 19 is rotated upward to the initial position indicated by the solid line in the same figure, and the yarn Y2 on the winding device 12 side is arranged near the yarn joining device 17.
[0040]
Subsequently, the piecing operation by the piecing device 17 is started. As described above, when the yarn Y1 on the spinning device 5 and the yarn Y2 on the winding device 12 are arranged near the yarn splicing device 17, the yarn pulling lever (not shown) provided in the yarn splicing device 17 Then, both the yarns Y1 and Y2 are clamped and taken into the operation execution section of the yarn joining device 17, and the yarn joining operation is executed. Before the start of the yarn splicing operation, the upstream guide 23 of the yarn slack removing device 10 is still in the forward position, and holds the yarn path at a position where it does not engage with the unwinding tension applying member 22.
[0041]
When the yarn splicing device 17 clamps the yarns Y1 and Y2, the suction and collection of the yarn Y1 by the suction pipe 18 becomes impossible, so that the yarn Y1 sent from the spinning device 5 is accumulated upstream of the yarn splicing device 17 as it is. Become. Therefore, immediately before the start of the piecing operation, specifically, immediately before the yarn pulling lever clamps the yarns Y1 and Y2, the advance / retreat means 24 is operated to retreat the upstream side guide 23 again as shown in FIGS. The yarn path is changed to a position where the yarn Y1 can engage with the flyer 22a of the unwinding tension applying member 22. As a result, the fryer 22a rotating together with the slack removing roller 21 catches the yarn Y1 fed from the spinning device 5 and forms a cylindrical portion as a winding surface of the slack removing roller 21 as shown in FIGS. Since the yarn Y1 is introduced into and wound around the yarn 21c, the slack of the yarn Y1 that may occur between the spinning device 5 and the yarn joining device 17 during the yarn joining operation can be eliminated.
[0042]
As described above, the fryer 22a is rotatable independently of the slack removing roller 21, but is integrated with the slack removing roller 21 by the transmission force adjustment by the transmission force adjusting mechanism unless a load equal to or more than a certain value acts. Rotate. During the yarn slack removing operation, the winding speed on the downstream side (winding side) is in a low state of almost zero, and the load applied to the fryer 22 a is small, so that the fryer 22 a rotates integrally with the slack removing roller 21.
[0043]
By forming the fryer 22a as described above, the engagement with the yarn Y is ensured, and the yarn Y does not fit into the gap between the roller 21 and the fryer 22a during winding. Further, the retreating of the upstream guide 23 is an operation in a direction of reducing the yarn tension by shortening the path length of the yarn path (by setting the shortest distance), so that when the yarn Y1 engages with the fryer 22a. The increase in yarn tension is reduced, and the occurrence of yarn breakage is prevented. Patent Document 2 discloses a configuration in which the yarn is bent by rotating the yarn hooking guide and is pushed toward the center of the roller, and the yarn is likely to be stretched. On the other hand, according to the present invention, since there is no tension due to the bending of the yarn as in Patent Document 2, there is no possibility that the yarn may be broken.
[0044]
The rotation speed of the slack removing roller 21 is calculated by the calculation unit b based on the input speed of the input unit a based on the spinning speed of the yarn Y in the spinning device 5 (substantially the yarn feed speed of the yarn feeder 6). Is set so that the thread tension is appropriate. The timing of the movement of the upstream guide 23 to the retreat position is determined in consideration of the spinning speed of the yarn Y1, and is slightly earlier than the time when the yarns Y1 and Y2 are clamped by the piecing device 17. Is set. If the movement time is delayed, the yarn Y1 spun one after another from the spinning device 5 becomes slack, and the slack removing roller 21 may fail to catch the yarn Y1. On the other hand, if the yarn Y1 is excessively faster than the time of clamping the yarns Y1 and Y2, the yarn Y1 disposed in the yarn splicing device 17 is wound by the slack removing roller 21 and the yarn splicing fails. Even if the yarn splicing is successful, if the amount of yarn wound around the slack removing roller 21 becomes excessive and exceeds the storage allowance for winding the slack removing roller 21, the overlapping state of the yarn on the slack removing roller 21 may be reduced. Due to the abnormality, unwinding of the yarn Y does not proceed smoothly, and the yarn splicing operation may be incomplete, for example, the yarn may break.
[0045]
When the piecing by the piecing device 17 is completed, the cradle arm 14 is rotated in the return direction to bring the package 16 into contact with the rotating drum 13 and the winding operation of the yarn Y is restarted. However, since the yarn Y from the yarn slack removing device 10 to the winding device 12 immediately after the completion of the piecing is in a low tension state, when the package 16 is brought into contact with the rotating drum 13 suddenly, the yarn tension suddenly increases. There is a possibility that the fluctuation may occur and the yarn Y may be stretched. Therefore, in the present embodiment, in order to address the above-described problem, as shown in FIG. 12, a tension arm 20 which can apply a tension to the yarn Y and a return speed limit for adjusting the rotation speed of the cradle arm 14. A mechanism 26 is provided. The tension arm 20 has, for example, a lever structure as shown in the drawing. The tension arm 20 is bent by interfering with the yarn Y and increasing the yarn tension in advance just before the contact of the package 16 with the rotary drum 13 is completed. This is for suppressing the fluctuation width of the yarn tension at the time of restart. The speed limiting mechanism 26 is configured using, for example, a cam 26 a and a link 26 b that can be rotated by a drive source (not shown), and is connected to a connection portion 26 c provided on the cradle arm 14 so that the package 16 comes into contact with the rotating drum 13. The rotation speed of the cradle arm 14 immediately before the rotation is limited.
[0046]
The tension arm 20 and the cradle arm 14 operate, for example, as shown in the time chart of FIG. That is, the tension arm 20, the connecting portion 26c, and the cradle arm 14 are commonly driven via the link 26b by the rotational driving of the cam 26a of the speed limiting mechanism 26, so that they operate at appropriate timing with respect to each other. Is set. After the completion of the piecing (time T0), first, the cradle arm 14 starts rotating in the return direction (time T1). The speed limiting mechanism 26 controls the rotation speed (= angular speed) of the cradle arm 14 so as not to exceed a predetermined value (ω). When the package 16 reaches a position very close to the surface of the rotating drum 13, the angular velocity of the cradle arm 14 is reduced to a constant value (ω1) (time T2), and the contact of the package 16 with the rotating drum 13 is completed (time T2). Until T4), this small angular velocity (ω1) is maintained. The driving of the cradle arm 14 at the small angular velocity is referred to as sliding contact driving. By such angular velocity control, the package 16 comes into sliding contact with the surface of the rotary drum 13, so that a sudden rise in tension at the time of contact can be reduced.
[0047]
On the other hand, the tension arm 20 is advanced (time T3) after the sliding contact drive of the cradle arm 14 is started (time T2) and before the package 16 makes sliding contact with the rotating drum 13 (time T4). A tension is applied to the yarn Y. The yarn Y immediately after the completion of the piecing has a low tension, and when the package 16 and the rotating drum 13 come into contact with each other and the normal winding operation is restarted, the yarn tension rapidly increases. Therefore, as in the present embodiment, before the package 16 comes into contact with the rotating drum 13, the yarn tension is slightly increased in advance by the tension arm 20 so that the yarn tension is not suddenly increased. The variation width of the tension can be suppressed to a small value to prevent the yarn from being stretched. Thereafter, as the second stage, the sliding contact is made, and the fluctuation width of the yarn tension is kept small. When the package 16 is completely in contact with the rotating drum 13 and the normal winding operation is resumed, the tension arm 20 is moved. It is retracted and separated from the yarn Y (time T5).
[0048]
When the piecing operation is completed and the winding operation is resumed, the work cart 3 loses the engagement relationship with the yarn Y, and can be freely moved from the spinning unit 2 that has performed the piecing operation. Become. Therefore, when the yarn splicing request signal is output from another spinning unit, the yarn is immediately moved to the target spinning unit position after the resumption of the winding operation without waiting for the yarn to be unwound from the slack removing roller 21. Can be. Therefore, the spinning machine 1 according to the present invention requires only a short time for the work cart 3 to stay in one spinning unit 2 for the splicing operation, so that the work cart 3 is transferred to another splicing request unit faster than before. Can be moved, and the time during which other splicing request units are stopped spinning can be shortened, and as a result, the operating efficiency can be improved.
[0049]
The yarn Y generated and sent out by the spinning device 5 is taken up by the slack removing roller 21 that is continuing to rotate, from the above-described piecing operation to the restart of the winding operation. However, when the winding operation is restarted, the ratio of the winding speed to the spinning speed is set so as to apply an appropriate tension to the yarn. Is increased above a certain value, and an attempt is made to apply a pulling force to the winding device 12 to the yarn Y. As a result, based on the value set by the transmission force adjusting mechanism, when a predetermined load is applied to the fryer 22a by the yarn tension between the yarn slack removing device 10 and the winding device 12, the fryer 22a Shows an independent behavior against the transmission force of the slack removing roller 21 which continues to rotate in the winding direction, and the yarn Y wound and stored by the slack removing roller 21 gradually becomes slack. It is pulled out from the take-up roller 21 via the downstream guide 36 and unwound. At this time, the flyer 22a of the unwinding tension applying member 22 and the roller large-diameter portion 21d-1 prevent the yarn Y from coming off the loop, and guide the yarn Y to be unwound from the slack removing roller 21 on average. The fryer 22a receives the rotational force from the slack removing roller 21 and the transmission force applying member 22f rotating in the opposite direction to the rotational direction in which the fryer 22a rotates to unwind the yarn Y. An appropriate tension is applied to the yarn Y in order to cause the yarn Y to exert a resistance force against the pulling force of the yarn Y to be unwound from the roller 21 to the winding device 12. As a result, the unwinding tension of the yarn Y unwound from the slack removing roller 21 substantially matches the regular winding tension, and the winding state of the package 16 is reduced even during the regular winding. It has the function of uniforming even inside. These effects of the present invention are particularly remarkable because the spinning speed has been increased in recent years, but the higher the spinning speed, the more the amount of slack tends to increase.
[0050]
Here, as shown in FIGS. 7 and 18, the downstream guide 36 needs to be positioned in a so-called axial direction on an extension line of the shaft portion 21 e of the slack removing roller 21 to the roller tip P side. The reason is that, if the yarn Y is unwound from the slack removing roller 21 and the downstream guide 36 is displaced from the extension of the shaft portion 21e, the position at which the yarn Y separates from the slack removing roller 21 This causes the distance between the separation position and the downstream guide 36 to change, thereby changing the unwinding tension. Further, when the position of the downstream guide 36 is extremely displaced from the extension of the shaft portion 21e, the yarn Y to be wound around the package 16 is conversely rotated by the rotational force of the slack removing roller 21. This is because there is a risk that a force that tries to wind the wire may work.
[0051]
As described above, the unwinding tension applying member 22 of the present embodiment has a function as a yarn hooking member in which one member introduces the yarn Y1 to the slack removing roller 21 immediately before the start of the piecing operation. In unwinding the yarn wound around 21, the yarn also has an unwinding tension applying function of applying a predetermined unwinding tension to the yarn. Accordingly, an effect is obtained that the number of components constituting the yarn slack removing device 10 can be reduced.
[0052]
When the winding operation is resumed and the unwinding of the yarn Y from the slack removing roller 21 is completed, the flyer 22a adjusts the rotational force received from the slack removing roller 21 and the tension of the traveling yarn, as shown in FIGS. It is held in the state shown in FIGS. When the yarn Y is not wound around the slack removing roller 21 during normal spinning, if the yarn Y is left as it is, the yarn Y travels while contacting the flyer 22a and is wound around the package 16, so that the yarn quality due to friction with the flyer 22a is increased. As a result, the quality of the package 16 may be adversely affected. Therefore, in the present embodiment, if the yarn Y is unwound from the slack removing roller 21, the slack removing roller 21 is reversed by approximately 180 ° as shown by a two-dot chain line in FIG. 8 and FIGS. By rotating, the position of the flyer 22a was changed to a separation position where the flyer 22a did not contact the yarn Y, and then the slack removing roller 21 was set to stop at the separation position. Thereby, it is possible to avoid a decrease in the quality of the yarn Y.
[0053]
The timing adjustment for rotating the slack removing roller 21 in the reverse direction can be performed, for example, by timer control. That is, if the rotation time of the slack removing roller 10 reaches a predetermined time after starting the slack removing operation in the slack removing device 10, the setting is made so that the slack removing roller 21 is automatically rotated in reverse. Just fine. Alternatively, a tension sensor is arranged at an appropriate position upstream or downstream of the slack removing roller 21 to monitor the yarn tension during unwinding, and when the tension value reaches a certain condition, the yarn Y is completely removed. It is also possible to adopt a configuration in which the slack removing roller 21 is rotated in the reverse direction and stopped assuming that it has been unwound.
[0054]
The embodiment of the present invention is not limited to the mode described above. The above is an application of the present invention to a spinning machine having a specification in which the yarn Y is not wound around the slack removing roller 21 during normal spinning. However, the present invention also adjusts the winding speed as appropriate during normal spinning. Can be used to construct a spinning machine of a specification in which the yarn Y is always wound around the slack removing roller 21. As such an example, when forming a cone-wound package, the yarn Y is always wound around the slack removing roller 21 in order to absorb a winding tension difference due to a difference in winding speed between the large diameter side and the small diameter side. And the like. Further, the yarn slack removing device 10 is not necessarily required because the flyer 22a can rotate independently when a force equal to or more than a predetermined value acts on the slack removing roller 21. In addition, the specific configuration and the shape of the present invention do not prevent an appropriate change according to the situation.
[0055]
【The invention's effect】
A spinning machine according to claim 1, comprising a slack removing roller for winding the slack yarn at the time of splicing, and a unwinding tension applying member for applying a predetermined unwinding tension to the yarn unwound from the slack removing roller. Since the take-up device is provided for each spinning unit, if the piecing operation is completed in one spinning unit, the work carriage is separated while the yarn slack removing device of the spinning unit is performing the yarn unwinding. Can be moved to the spinning unit. Therefore, when the piecing operation of a plurality of spinning units is performed continuously, the stop time of the trolley per spinning unit can be reduced, so that the trolley is moved to another piecing request unit faster than before. In addition to this, the time during which other splicing request units are stopped spinning can be shortened, and as a result, the operating efficiency of the spinning machine can be improved.
[0056]
Further, since it takes a long time to unwind the yarn from the slack removing roller, it is easy to apply an appropriate tension to the yarn being unwound. That is, the yarn tension during unwinding can be made to match or approach the yarn tension during regular winding, so that a yarn package with a good winding state can be reliably obtained.
[0057]
In the spinning machine according to claim 2, since the unwinding tension applying member is provided with the unwinding tension adjusting mechanism, the yarn tension when unwinding from the slack removing roller is adjusted according to the spinning conditions such as the yarn type and the yarn count. Since it can be set or adjusted in advance, it is easy to respond to a change in spinning conditions.
[0058]
In the spinning machine according to the third aspect, since the unwinding tension applying member has a function as a yarn hooking member for introducing the yarn into the slack eliminating roller, the number of components of the yarn slack eliminating device is reduced. Can be simplified, and costs can be reduced.
[0059]
The spinning machine according to claim 4 is configured to start rotation of the slack removing roller based on the arrival detection signal when the work vehicle arrives at the spinning unit position where piecing is required. Since the operation of the slack removing roller and the operation of the work cart are reliably linked, the piecing operation can proceed smoothly, and the loss of operating time of the spinning machine can be suppressed.
[0060]
According to a fifth aspect of the present invention, in the spinning machine, a driving means is provided for each of the slack removing rollers, and each slack removing roller is configured to be able to be independently driven to rotate. Can be set differently, so that it is easy to cope with the production of multi-products.
[0061]
Further, as described in claim 6, after the unwinding of the yarn wound by the slack removing roller is completed, the unwinding tension applying member is repositioned to a position where it does not engage with the yarn. Since the unwinding tension applying member is prevented from being in contact friction with the yarn being normally wound after unwinding, it is possible to avoid adversely affecting the yarn quality after resuming winding.
[Brief description of the drawings]
FIG. 1 is a front view showing an embodiment of a spinning machine including a yarn slack removing device according to the present invention.
FIG. 2 relates to the embodiment and is a front sectional view schematically showing a structure of a main part.
FIG. 3 relates to the embodiment and is a side view showing a schematic configuration of a spinning unit and a work cart during normal spinning.
FIG. 4 is an enlarged side view of the yarn slack removing device during normal spinning according to the embodiment.
FIG. 5 is an enlarged front view of the yarn slack removing device during normal spinning, which relates to the embodiment.
FIG. 6 relates to the embodiment, and is a side view showing a schematic configuration of a spinning unit and a work cart immediately before the start of a piecing operation.
FIG. 7 relates to the embodiment, and is a side view showing a schematic configuration of a spinning unit and a work vehicle at the start of a piecing operation.
FIG. 8 is a side view showing, in an enlarged manner, a schematic configuration of a yarn slack removing device at the start of a piecing operation, which relates to the embodiment.
FIG. 9 relates to the embodiment, and is a side view showing a schematic configuration of a spinning unit and a work cart during a piecing operation.
FIG. 10 relates to the above embodiment, and is a side view showing an enlarged schematic configuration of a yarn slack removing device during a piecing operation.
FIG. 11 relates to the embodiment, and is an enlarged front view showing a schematic configuration of a yarn slack removing device at the start of a piecing operation.
FIG. 12 relates to the embodiment, and is a side view showing a schematic configuration of a spinning unit and a work cart immediately after resuming a winding operation after completion of piecing.
FIG. 13 relates to the embodiment, and is a time chart showing operations of the tension arm and the cradle arm from the end of the piecing until the winding operation is restarted.
FIG. 14 relates to the embodiment, and is a side view showing a schematic configuration of a spinning unit and a work vehicle in a state after resuming winding.
FIG. 15 relates to the embodiment, and FIG. 15A is an enlarged side view showing a schematic configuration of a yarn slack removing device immediately after the yarn is unwound from a roller after the resumption of the winding operation; FIG. (B) is a front view showing the slack removing roller in the same state as viewed from the front end, and FIG. (C) is a view after (A) and (B) above, and the slack removing roller is rotated in reverse to engage with the yarn. FIG. 2D is an enlarged side view showing a schematic configuration of the yarn slack removing device in a state in which the loosening is avoided, and FIG.
FIG. 16 is a perspective view showing an example of a slack removing roller used in the yarn slack removing device according to the embodiment, as viewed from a distal end side.
FIG. 17 shows an example of a slack removing roller used in the yarn slack removing device according to the embodiment, wherein FIG. 17 (A) is a front view as viewed from the front end side, and FIG. 17 (B) is a plan view. .
FIG. 18 is a side sectional view showing an example of a slack removing roller used in the slack removing device according to the embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Spinning machine 2 ... Spinning unit 3 ... Work cart 5 ... Spinning device 10 ... Thread slack removal device 12 ... Winding device 13 ... Rotary drum 14 ... Cradle arm 15 ... Bobbin 16 ... Package 17 ... Thread joining device 18 ... Suction pipe Reference Signs List 19: sansion mouse 20: tension arm 21: slack removing roller 22: unwinding tension applying member 22a: fryer 23: upstream guide 24: advance / retreat means 26: speed limiting mechanism 35: drive motor (for thread slack removing device) 36: Downstream guide E: Yarn path R: Yarn engaging portion S: Fiber bundle Y: Yarn (spun yarn) Y1: Yarn on spinning device Y2: Yarn on winding device side

Claims (6)

In a spinning machine in which a plurality of spinning units are disposed and a work carriage equipped with a yarn splicing device is movable between the spinning units, a slack removing roller for winding a slack yarn generated due to splicing, and a slack removing roller for winding the slack yarn. A yarn slack removing device having an unwinding tension applying member for applying a predetermined unwinding tension to the yarn when unwinding the yarn wound from the take-up roller is provided for each spinning unit. Spinning machine. 2. The spinning machine according to claim 1, wherein the unwinding tension applying member is provided with an unwinding tension adjusting mechanism capable of presetting an unwinding tension applied to the yarn unwound from the slack removing roller. . The spinning machine according to claim 1, wherein the unwinding tension applying member also has a function as a yarn hooking member for introducing the yarn into the slack removing roller. The work vehicle moves to the position of the corresponding spinning unit based on the splicing request signal output from the spinning unit, and when it reaches the relevant spinning unit position, the slack removing roller starts rotating based on the arrival detection signal. The spinning machine according to any one of claims 1 to 3, wherein the spinning machine is set to perform the spinning. The spinning machine according to any one of claims 1 to 4, wherein a driving unit is provided for each of the slack removing rollers, and each of the slack removing rollers can be independently driven to rotate. The drive means may change the position of the unwinding tension applying member to a position separated from the yarn path at the time of regular winding and stop the yarn after the unwinding of the yarn wound on the slack removing roller is completed. The spinning machine according to any one of claims 1 to 5, which is configured.

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