JPH0641826A - Spinning machine - Google Patents

Abstract

PURPOSE: To reduce a waste time not producing a spun yarn by driving an additional motor for a bobbin-exchanging device even during a main period. CONSTITUTION: This spinning machine is provided by adjusting the number of rotation of a spindle with supplying electricity by a main frequency converter 4 to a main motor 1 through a closed switch 7. The converter 4 connects an additional frequency converter 5 with an additional motor 2 of the bobbin- exchanging device for accelerating a doffing process.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spinning machine, such as a ring spinning machine, which is shown in the general concept of claim 1.

[0002]

In the case of known spinning machines of this type (German Patent Application DE 36 10 838 A1), the spindle is fed by a frequency converter with at least one feed current of adjustable frequency. It is driven by the main motor. During the main period, an empty bobbin fitted on the spindle is wound with spun yarn. The main period starts with the spinning bobbin winding of the empty bobbin, and ends when the bobbin after the spinning bobbin winding has finished feeding the bobbin for the purpose of replacing the subsequent bobbin. Each time the main period is followed by an intermediate period, during which the spun yarn-filled bobbin is replaced with an empty bobbin during the preceding main period. Therefore, after the empty bobbin is loaded, the actual spinning process is started, that is, the main period is followed again.

The bobbin exchange during the intermediate period is carried out using a bobbin exchange device having a doffer beam. Due to the scissor-like drive mechanism of the bobbin changer and due to the comparatively complex trajectory curve of the doffer beam, a variable speed control of the doffer motor is required. Thus, DE-A 36 10 838 shows a configuration in which the frequency converter of the main motor is used for powering the motor of the bobbin exchanging device during the intermediate period. When the wound body wound around the bobbin reaches the predetermined target amount during the main period, the main motor is shut off and the frequency converter of the main motor is switched to the motor of the bobbin exchanging device. The program controller is then used to control the motor speed of the bobbin changer as follows: the doffer beam is raised from its initial position to the spinning station and the wound bobbin is removed from the spindle, Lower it again, place the filling bobbin on the bobbin transfer device, hold the empty bobbin waiting here, and then mount the empty bobbin after ascending to the spinning station on the spindle, Controlled. Following this, the doffer beam is raised again, swiveled and lowered further down. As a result, the frequency converter is switched back to the main motor and the main period begins in the original spun yarn production. According to the arrangement also shown in DE-A 36 10 838, the frequency converter is first switched to the motor of the ring rail just before the end of the main period. As a result, with the switching of the frequency converter to the motor of the bobbin exchanging device, one has to wait until the spun yarn produced during the slowdown of the main motor is wound onto the preliminary winding point of the spindle. . Only then can the frequency converter be switched to the motor of the bobbin changer.

When a pole number switching type AC motor is used to control the motor for the bobbin exchanging device, the speed of the doffer beam is significantly increased due to the scissor-like drive mechanism. It is non-uniform and may vary, for example, between the factors 1-10. Therefore, a relatively long time is required for the entire Duffer beam process, for example, 3 minutes.

[0005]

SUMMARY OF THE INVENTION It is an object of the present invention to provide an apparatus and method for accelerating the doffing process for the purpose of reducing dead time during which spun yarn is not produced.

[0006]

According to the invention, the object is to provide a spinning machine of the type indicated in the preamble of claim 1 in which the additional motor for the bobbin exchanging device is driven during the main period as well. Has been resolved by

According to the structure of the present invention, the main frequency converter is provided for the main motor, and the additional frequency converter unique to the additional motor of the bobbin exchanging device is provided. This additional frequency converter can also be used for powering another additional motor, for example for a ring frame motor or a bobbin carrier motor.
The main frequency converter supplies a current having a frequency of, for example, up to 108 Hz, while the additional frequency converter has a frequency of, for example, 3 Hz.
It can supply currents with frequencies up to 7 Hertz. A program controller is assigned to the main frequency converter and the additional frequency converter. The control device switches the main frequency converter to the additional motor of the bobbin exchanging device after the end of the main period. Therefore, the motor of the bobbin exchanging device is supplied with the supply current by the main frequency converter during the intermediate period. The program controller controls the main frequency converter such that the doffer beam is moved at a substantially constant velocity during the doffering process. Before the end of the main period, the program controller ensures that the additional frequency converter is controlled as follows. First, during the main period, the additional motor of the bobbin exchanging device, which is connected to the additional frequency converter, raises the doffer beam from its initial position to the expected position. The wound bobbin is then removed from the spinning station immediately after the main motor is shut off and the entire doffering process is wound with the high output of the main frequency converter. This doffering process is also a substantially constant dofferer.
It is controlled by a program controller that sets the beam velocity. After mounting the new empty bobbin, the main frequency converter is additionally connected to the main motor again by the program controller. Therefore, the production of spun yarn is restarted immediately after the empty bobbin is placed. The doffer beam is returned to its initial position by means of an additional frequency converter which is additionally connected.

[0008]

The advantage of the invention is that the doffering process is already carried out during the main period, i.e. during the production process, so that only the steps of the doffering process which are to be carried out when the spinning machine is stopped are produced. Interrupt the process. In addition, during this part of the doffering process, the motor of the bobbin exchanging device is supplied with supply current by the main frequency converter. So the higher power of the frequency converter is available for the quick doffering process. The program controller controls the output frequency of the main transducer so that the doffer beam is moved at a substantially constant velocity. This allows the duration of the doffering process to be reduced, for example from 3 minutes to 1 minute.

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

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT As shown in FIG. 1, a program controller 6 is connected to a main frequency converter 4 and an additional frequency converter 5. The main frequency converter 4 is connected via a switch 7 to a main motor 1 for driving a spindle 18 of the ring spinning machine, which is not shown in FIG. The main frequency converter 4 is further connected via a changeover switch 8 to an additional motor 2 for operating a bobbin exchanging device 26 of the ring spinning machine, which is also not shown in FIG.
The additional frequency converter 5 is connected to the additional motor 3 for driving the ring frame via the switch 9, and further operates the bobbin transfer device 24 (FIG. 3) of the ring spinning machine via the switch 35. Additional motor 36 for
, And can be connected to the additional motor 2 via the changeover switch 8. Switches 7, 8, 9 and 35
Is also undertaken by the program controller 6, which is indicated by a broken line.

FIG. 2 shows a doffer beam 1 of a ring spinning machine.
Part of 0 is shown with the associated scissor-like lifting mechanism 11. The elevating mechanism 11 includes a plurality of support arms 30 and a pulling arm 32. Support arm 30
Are pivotally connected to the doffer beam 10 via pivot axes 29 extending perpendicularly to the longitudinal direction of the doffer beam 10. Further, the lower ends of the support arms are respectively provided with shafts 31 extending parallel to the swivel axis 29,
It engages with a spindle nut 27 provided on a screw spindle 13 extending in the longitudinal direction of the spinning machine. The towing arms 32 are ring-coupled to the support arms 30 at their upper ends, respectively, approximately centrally. The lower ends of the towing arms 32 are each fixedly mounted at the height of the screw spindle 13 via a spindle sleeve 28. The screw spindle 13 is the additional motor 2
Rotatably driven by the screw spindle 13
It is connected to the spindle nut 27 via the screw 12 as follows. That is, the rotational movement of the screw spindle 13 is converted into a vertical movement of the doffer beam 10, whereby the doffer beam is combined so as to be raised from the lowered position to the raised position or lowered from the raised position to the lowered position. ing.

Further, the doffer beam 10 is expanded and contracted in a direction transverse to the longitudinal direction of the spinning machine. Lifting mechanism 1 for this purpose
1 can be swiveled around a screw spindle 13, which means for example a lever 34 reaching the interior of the spinning machine.
(Fig. 3).

The function of accepting the doffer beam 10 is to use a gripper (not shown) to pull the wound bobbin 20 out of the spindle 18 and carry it downward to the bobbin transfer device 24, and on the other hand, the bobbin transfer function. The empty bobbin 19 guided by the device 24 is conveyed upward to the spinning station 25 where it is fitted onto the spindle.

Since the vertical movement of the doffer beam 10 is transmitted through the scissor-like lifting mechanism 11, when the rotation speed of the screw spindle 13 is constant, the movement of the doffer beam 10 is extremely non-uniform. Will be given.
The ratio of different velocities of the doffer beam 10 is 1:10.
Can be reached. This means an extension of the doffing process of only about 2 seconds, which in itself is not avoided.
By feeding the additional motor 2 with a variable-frequency feeding current via the main frequency converter 4 or the additional frequency converter 5, the rotation speed of the additional motor 2 can be continuously changed. In this case, the program controller 6 controls the main frequency converter 4 and the additional frequency converter 5 as follows. That is, the additional motor 2 is moved according to the gear ratio of the scissor-like lifting mechanism so that the doffer beam is moved at a substantially constant speed.
Control to adjust the rotation speed of.

FIG. 3 is a sectional view showing the entire operation sequence of the spinning machine described above. In this case, the sequence consists of a main period 14-when the original production of spun yarn takes place during this period-and an intermediate period 17-of the doffing process during this period.
Partial steps to be carried out when the main motor 1 is stopped are carried out.

During the main period 14, the main motor 1 is fed by a main frequency converter 4 via a closed switch 7 (FIG. 1) with a feed current whose frequency is adjustable. The purpose is to make a variable speed adjustment of the main motor 1 and thus of the spindle 18. The converter 8 connects the additional frequency converter 5 with the additional motor 26 of the bobbin exchanging device 26 during the main period 14. Similarly, the additional motor 3 is connected to the additional frequency converter 5 via the closed switch 9.

When the main period 14 approaches the end range 16, that is, when the empty sleeve 19 is almost completely wound with the spun yarn, the additional motor 2 is driven by the power supply current supplied from the additional frequency converter 5. It is driven under the control of the program controller 6. This allows the doffer beam 10
Moves from the initial position 21 to the standby position 22 in the vicinity of the almost completely wound sleeve. The spindle 18 supporting the bobbin is constantly driven by the main motor 1 which is fed via the main frequency converter 4.

When the bobbin is completely wound, the main motor 11 is shut off by using the switch 7, and the intermediate period 1
7 is started. The switch 8 is switched so that the additional motor 2 of the bobbin exchanging device 26 is supplied with its power supply current from the main frequency converter 4. Program control device 6
Under the control of (1), the gripper of the doffer beam 10 is placed above the wound bobbin 20 (a), and the wound bobbin 20 is gripped by the doffer beam 10 (b) and pulled out from the spindle 18 ( c), placed on the bobbin transport device 24 (d, e). The movement of the doffer beam 10 is controlled by the program controller 6 so that the doffer beam 10 is moved at a substantially constant velocity.

After the wound bobbin is placed on the bobbin transfer device 24, the bobbin is removed from the doffer beam 10 (f). The bobbin transport device 24 is then moved (g) until a new empty bobbin 19 is positioned just below the gripper of the doffer beam 10. The bobbin transfer device 24 is driven by an additional motor 36. in this case,
The additional motor is supplied with power supply current from the additional frequency converter 5, and is further controlled by the program controller 6. The opening and closing of the switch 35 is also controlled by the program controller 6. However, when the additional motor 3
Can also be used to control As a result, the ring frame and the bobbin transfer device 24 are driven by the same additional motor 3.

Next, the empty bobbin 19 is moved to the doffer beam 10.
It is gripped (h), conveyed to the spinning station 25 (i, j), and placed on the unloaded spindle 18 (k). Also in this case, the main frequency converter 4 is controlled by the program controller 6 so that the doffer beam 10 driven by the additional motor 2 is moved at a substantially constant speed.

Empty bobbin 19 from doffer beam 10
(L) and turning of the doffer beam (m) terminates the intermediate period 17, and the main motor 1 switches the switch 7 again.
Is connected to the main frequency converter 4 via. As a result, the production process can be restarted immediately after the empty bobbin 19 is placed on the spindle 18 (n).

The main frequency converter 4 is then again required for powering the main motor 1. Therefore, the changeover switch 8 is changed over so that the additional motor 2 is connected to the additional frequency converter 5. At the beginning 15 of this new main period 14, the program controller 6 drives the additional frequency converter 5 and thus the additional motor 2 connected to it.
The doffer beam 10 is controlled to return to its initial position 21. Again, the program in the program controller 6 is adjusted so that the doffer beam 10 is moved at a substantially constant speed.

[Brief description of drawings]

FIG. 1 is a block diagram of a drive unit of a spinning machine constructed according to the present invention.

FIG. 2 is a scissor-like lifting mechanism for a doffer beam.

FIG. 3 is a shown doffing process of individual instant actions.

[Explanation of symbols]

 1 main motor 2,3 additional motor 4 main frequency converter 5 additional frequency converter 6 program controller 7,8,9 switch 10 doffer beam 11 lifting mechanism 13 screw spindle 14 main time interval 17 intermediate time interval 18 spindle 19 empty Bobbin 20 Winded bobbin 21 Initial position 22 Standby position 24 Bobbin transfer device 25 Spinning station 26 Bobbin changing device 35 Switch

Claims (17)

[Claims] 1. At least a group of spinning stations (2)
5), and the main period (1
The empty bobbin (19) is wound with spun yarn each time during the period (4), and further wound during the intermediate period (17) provided between the plurality of main periods (14). Finished bobbin (2
0) is exchanged for an empty bobbin (19) by a bobbin exchanging device (26) having a doffer beam (10), and at least one bobbin exchanging device (24) is provided by the bobbin exchanging device. Or the wound bobbin (20) is guided to the spinning station (25) or is carried away from the spinning station and is further attached to the spinning station (25).
8) is provided with at least one main motor (1) used for driving during the main period (14), said main motor being fed by a main frequency converter (4) with a feed current of adjustable frequency. And further comprising at least one additional motor (2) for driving the bobbin exchanging device (26) during the intermediate period (17), wherein at least one of the main frequency converters (4) is An additional motor (2) for the bobbin exchanging device (26) in a spinning machine of the type in which at (17) is switched to at least one additional motor (2) to supply the motor with an adjustable supply current. Is driven during the main period (14) as well. 2. At least one additional motor (2) for the bobbin exchanging device (26) is supplied at a frequency adjustable by at least one additional frequency converter (5) during the main period (14). The spinning machine according to claim 1, which is powered by. 3. At least one additional frequency converter (5)
The two second additional motors (3), for example the motors of the ring frame of the spinning machine, are fed with a feed current of adjustable frequency both during the main period (14) and during the intermediate period (17). The spinning machine according to claim 2. 4. At least one main frequency converter (4)
4. A program controller (6) is assigned to the program controller, which program-controls the output frequency of the main frequency converter (4) during at least the intermediate period (17). The spinning machine according to any one of 1. 5. A program controller (6) is assigned to at least one additional frequency converter (5),
5. The spinning machine according to claim 1, wherein the program controller controls the output frequency of the additional frequency converter (5) during at least the main period (14). 6. The spinning machine according to claim 4, wherein the output frequency of the main frequency converter (4) and the output frequency of the additional frequency converter (5) are controlled by the same program controller (6). 7. A program controller (6) controls the output frequency of the main frequency converter (4) during an intermediate period (17) as follows: substantially the doffer beam (10). 50-70 at a constant speed of 40-80 mm / s
Spinning machine according to any one of claims 1 to 6, controlled to move at mm / s, preferably at 60 mm / s. 8. The program controller (6) moves the output frequency of the additional frequency converter (5) during the main period so that the doffer beam (10) is moved at a substantially constant velocity. The spinning machine according to any one of claims 1 to 7, which is controlled. 9. At least one additional motor (2) for the bobbin exchanging device (26) is an electric motor whose polarity is switched, the rotational speed of the motor being active during the main period (14). 9. The spinning machine according to claim 1, wherein the setting is adjusted by switching from 2 poles to 6 poles, for example. 10. The spinning machine according to claim 1, wherein the main frequency converter (4) provides a higher maximum output frequency than the additional frequency converter (5). 11. The spinning according to claim 1, wherein the main frequency converter (4) supplies a maximum output frequency of 88-128 Hz, for example 98-118 Hz, preferably 108 Hz. Machine. 12. Spinning machine according to claim 1, wherein the additional frequency converter (5) supplies a maximum output frequency of 27-47 Hz, for example 32-42 Hz, preferably 37 Hz. 13. The spinning according to claim 1, wherein the additional motor (2) for the bobbin exchanging device (26) is operated in two connections, for example a star connection and a delta connection. Machine. 14. A method of controlling a bobbin exchanging device (26) for a spinning machine, wherein the doffer beam (10) of the bobbin exchanging device (26) is already fed into the additional frequency converter (5) during the main period (14). ) Is used to move to the standby position near the spinning station (25), and after the main motor (1) is shut off, that is, after the main period (14) ends, the bobbin changing device (2)
6) The additional motor (2) for the main frequency converter (4)
The wound bobbin (20) is removed from the spindle (18) by the power feeding, the doffer beam (10) is lowered to the vicinity of the bobbin transfer device (24), and the wound bobbin (20) is removed. The bobbin transfer device (24) is placed on the bobbin transfer device (24) and the empty bobbin (1
9), the doffer beam (10) is newly raised to the vicinity of the spinning station (25), the empty bobbin (19) is fitted onto the spindle (18), and this empty bobbin is fitted onto the spindle (18). After fitting, i.e. after the end of the intermediate period (17), the main motor (1) is again fed by the main frequency converter (4) and the doffer beam (10) is further supplied with the additional frequency converter (5), Bobbin exchange of the spinning machine, characterized in that it moves away from the spinning station (25) during this new main period (14) and then moves to its initial position (21) in the vicinity of the bobbin transport device (24). Device control method. 15. Raising the doffer beam (10) at the end (16) of the main period (14) using an additional frequency converter (5) as follows: the doffer beam (10) is the main 15. Method according to claim 14, characterized in that it is carried out just before the end of the period (14) so as to reach a waiting position (22) in the vicinity of the spinning station (25). 16. The return of the doffer beam (10) to its initial position (21) is performed at the beginning (15) of the main period (14) by means of an additional frequency converter (5).
The method according to 5 or 16. 17. When switching the main frequency converter (4) from the main motor (1) to the additional motor (2), the main frequency converter (4) is switched to another voltage by using the program controller (6). 17. A method according to any one of claims 14 to 16, wherein switching to a frequency ratio.