JP3097550B2 - Lifting control method and lifting device for spinning machine - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lifting control method and a lifting apparatus for a spinning machine such as a ring spinning machine and a ring twisting machine, and more particularly, a lifting drive system is driven by a motor different from a roller part and a spindle drive system. The present invention relates to a lifting control method and a lifting device for a spinning machine.

[0002]

2. Description of the Related Art In this type of spinning machine, a lifting device for raising and lowering a ring rail gradually while repeating a raising and lowering movement of a ring rail during machine operation for forming a yarn, and thereby raising and lowering a lappet angle and the like. Has been adopted. In the case of performing a filling building, the lifting drive system is driven by a motor different from the roller part and the spindle drive system in order to easily change the amount by which the ring rail moves up and down each time and the amount of winding up once. An arrangement has been proposed. However, the moment of inertia differs greatly between the roller part and the spindle drive system and the lifting drive system, and the inertia moment of the lifting drive system is considerably smaller than the inertia moment of the spindle drive system. As a result, if the power supply to the spindle drive system and the motor for the lifting drive system are simultaneously stopped at the time of a power failure, the spindle drive system continues to operate for a while even after the lift drive system is stopped. Then, the yarn is wound for a long time at the same position of the tube yarn, and there is a disadvantage that the yarn is frequently broken at the time of restarting, or the loop is missed at the time of rewinding in the winding process.

[0003] In order to solve this problem, 3-4
No. 8223 discloses that a lifting drive system, a roller part and a spindle drive system can be independently driven by a drive motor, and both drive systems are connected via a clutch so that the clutch is connected only when a power failure occurs. There is disclosed an apparatus provided with a control mechanism. In this device, during normal operation, the lifting drive system is driven by a drive motor different from the drive motors of the draft part and the spindle drive system. During the operation of the machine stand, when the power supply to the lifting drive system and the spindle drive system is stopped due to a power failure, both drive systems are connected by a clutch. Both drive systems are driven in synchronization with each other even after the drive motor has been coasted until it stops.

Japanese Patent Laid-Open Publication No. Sho 60-246826 discloses a spinning machine in which a draft part drive system, a lifting drive system, and a spindle drive system are driven by separate motors. In the event of a power failure, each motor is driven by a backup power supply. There is disclosed an apparatus for stopping each drive system in a synchronized state. Also disclosed is a device in which the motor of the spindle drive system is coasted and the other drive system motors are driven by a backup power supply.

Japanese Patent Laid-Open Publication No. Sho 62-215022 discloses a ring spinning machine in which a spindle drive system, a draft part drive system, and a lifting drive system are driven by separate drive motors. A method of synchronizing and stopping each drive system using regenerative power of a drive motor of the drive system is disclosed.

[0006]

Problems to be Solved by the Invention
In the device disclosed in the above publication, a transmission mechanism for connecting the spindle drive system and the lifting drive system at the time of a power failure and transmitting the rotational force of the motor of the spindle drive system to the lifting drive system is required. When the rotation of the spindle drive system is transmitted to the lifting drive system, a large deceleration is required, and the space for the speed reduction mechanism is increased. as a result,
It is necessary to arrange a transmission mechanism that connects the spindle drive system and the lifting drive system on the gear end side during a power failure,
The degree of freedom of the device layout is reduced.

On the other hand, in the apparatus disclosed in Japanese Patent Application Laid-Open No. 60-246826, power is supplied from a backup power supply to each motor at the time of a power failure, and each drive system is led to a stopped state in a synchronized state, thereby causing the above disadvantage. There is no. However, driving a spindle drive motor or a lifting drive system with a backup power supply requires a backup power supply having a large capacity, and there is a problem that the backup power supply becomes large and the cost increases.

Further, there is a problem that it is difficult to control when using the regenerative power of the drive motor of the spindle drive system disclosed in Japanese Patent Laid-Open No. 62-21502. SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and an object thereof is to provide a spinning machine in which a lifting drive system is driven by a separate motor from a roller part and a spindle drive system. An object of the present invention is to provide a lifting control method and a lifting apparatus for a spinning machine that can operate a lifting drive system with a simple configuration and with less power consumption than during normal operation until the operation is stopped or almost stopped.

[0009]

According to a first aspect of the present invention, there is provided a spinning machine wherein a lifting drive system is driven by a separate motor from a roller part and a spindle drive system. A first drive motor and a second drive motor that can be driven with less power consumption than the first drive motor are provided in the system, and the lifting drive system is driven by the first drive motor during normal operation;
In the event of a power failure, the lifting drive system is driven by the second drive motor using the backup battery as a power source until the inertia rotation of the spindle drive system stops or almost stops.

In the spinning machine in which the lifting drive system is driven by a separate motor from the roller part and the spindle drive system, the first drive motor drives the lifting drive system during normal operation; A second drive motor capable of driving the lifting drive system with a smaller power consumption than the first drive motor, and a second drive motor until the inertial rotation of the spindle drive system stops or almost stops during a power failure. Control means for performing control;
A power failure detection means for detecting the occurrence of a power failure and outputting a power failure detection signal to the control means, and a battery for supplying power to the second drive motor and the control means at the time of a power failure.

According to a third aspect of the present invention, in the second aspect of the present invention, the control means detects the second drive state based on an output signal of a spindle drive system operation detecting means for detecting an operation state of the spindle drive system. Control the drive motor of

According to a fourth aspect of the present invention, in the second or third aspect of the present invention, the second drive motor is configured to be capable of normal and reverse rotation drive, and the control means controls the position of the ring rail. The rotation direction of the second drive motor is determined based on the position of the ring rail at the time of the power failure detected by the detected ring rail position detecting means.

According to the first aspect of the present invention, during normal operation, the lifting drive system is driven by the first drive motor with power supplied from the normal power supply. If a power failure occurs during operation, the spindle drive system is coasted, and the lifting drive system is driven by the second drive motor that is supplied with power from the backup battery until the coasting of the spindle drive system is stopped or almost stopped. Driven. The second drive motor is driven with less power consumption (power consumption) than the first drive motor.

According to the second aspect of the present invention, during normal operation, the drive motors for driving the respective drive systems are driven by the power supplied from the normal power supply, and the lifting drive system is driven by the first drive motor. When a power failure occurs, a power failure detection signal is output from the power failure detection means to the control means. When a power failure occurs, power is supplied from the battery to the second drive motor and the control means, respectively. The drive of the second drive motor is controlled by the control unit until the inertial rotation of the spindle drive system stops or almost stops, and the lifting drive system is driven by the second drive motor. The second drive motor is driven with less power consumption than the first drive motor during normal operation.

According to a third aspect of the present invention, in the second aspect of the present invention, the control means checks an operation state of the spindle drive system based on an output signal of the spindle drive system operation detection means, The second drive motor is driven until the inertial rotation of the motor stops or almost stops.

According to a fourth aspect of the present invention, in the second or third aspect of the present invention, the control means recognizes the position of the ring rail when a power failure occurs based on a detection signal of the ring rail position detecting means. I do. Then, it is determined whether to drive the ring rail to the ascending side or the descending side based on the position of the ring rail. And the second drive motor is rotationally driven in the determined direction until the inertia rotation of the spindle drive system stops or almost stops,
The ring rail is stopped within a predetermined lifting range.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of the present invention embodied in a ring spinning machine having a lifting device configured to vertically move a ring shaft and a lappet angle by rotating a line shaft forward and backward will be described. This will be described with reference to FIGS.

As shown in FIG. 1, a driving shaft 1 extends along the longitudinal direction of a spinning frame (not shown).
Is rotationally driven by a main motor M via a belt transmission mechanism 2, and a spindle 3 (only one weight is shown) is rotationally driven via a spindle tape 5 wound around a chin pulley 4 fixed to the driving shaft 1. It is supposed to be. A variable speed motor driven via an inverter 6 is used for the main motor M, and a rotary encoder 7 as a spindle drive system operation detecting means is used for the main motor M.
Is provided. The rotating shaft 8a of the front roller 8 constituting the draft part as a roller part is a gear train 9
And is connected to the driving shaft 1 through the shaft. A draft part drive system is constituted by the main motor M, the belt transmission mechanism 2, the driving shaft 1, the gear train 9, and the rotating shaft 8a, and the main motor M, the belt transmission mechanism 2, the driving shaft 1, the chin pulley 4 and the spindle tape 5 form a spindle. A drive system is configured. That is, the draft part drive system and the spindle drive system are driven by the common main motor M. Although the draft part and the spindle 3 are arranged on both the left and right sides of the spinning frame, only one side is shown in FIG.

A line shaft 10 (only one side is shown) is rotatably disposed along a longitudinal direction of a spindle rail (not shown), that is, in parallel with the driving shaft 1. Each of the line shafts 10 has a ring rail 1
Elevating units 13 for raising and lowering the lappet angle 1 and the lappet angle 12 are arranged at predetermined intervals (only one is shown).
The lifting unit 13 includes a screw gear 14 fitted and fixed to the line shaft 10 so as to be integrally rotatable, and the poker pillar 1 supporting the ring rail 11 or the wrappet angle 12.
And a nut body 16 which is screwed into a screw portion 15a formed at a lower portion of the nut 5. The poker pillar 15 is supported by a machine frame (not shown) so as to be vertically movable. The nut body 16 is rotatably supported at a predetermined height position of the machine frame via a bracket (not shown), and a screw gear 16a meshing with each other is integrally formed on the outer periphery thereof. Two poker pillars 15 supporting the ring rail 11 or the lappet angle 12 are provided adjacent to each other, and the screw gears 16a of the nut bodies 16 provided corresponding to the respective poker pillars 15 mesh with each other and one of the screw gears 16a. Are also meshed with the screw gear 14. These configurations are basically the same as those of the device disclosed in Japanese Patent Application Laid-Open No. 2-277826, for example.

Rotary shaft 1 constituting a line shaft drive system
7 is rotatably disposed in parallel with both line shafts 10, and a gear 18 is fixed to a rotating shaft 17 so as to be integrally rotatable. The gear 18 is an output shaft 19 of a first drive motor 19
a meshes with a gear 20 fixed so as to be integrally rotatable with a. As the first drive motor 19, an AC servomotor driven by a commercial AC power supply is used. Line shafts 1 are located at positions corresponding to the ends of both line shafts 10.
The rotating shaft 21 is arranged in a state orthogonal to 0. A worm 23 that meshes with a worm wheel 22 that is integrally rotatably fixed to the end of the line shaft 10 is fixed to both ends of the rotating shaft 21 so as to be integrally rotatable. Rotating shaft 17
A bevel gear 24 is fixed so as to be integrally rotatable, and the bevel gear 24 is meshed with a bevel gear 25 fixed to an intermediate portion of the rotating shaft 21 so as to be integrally rotatable. An absolute type rotary encoder 26 as a ring rail position detecting means is connected to an end of the line shaft 10 via a gear. The line shaft 10 is driven to rotate forward and backward with the forward and reverse rotation of the first drive motor 19. The rotating shafts 17 and 21 and the gears 18 and 2
0, worm wheel 22, worm 23, bevel gear 2
A line shaft drive system is configured by the drive motors 19 and 20 and the drive motor 19. Ring rail 1 by line shaft 10, lifting unit 13 and line shaft drive system
A lifting drive system for raising and lowering the lappet angle 1 and the lappet angle 12 is configured.

The lifting drive system is provided with a gear 27 that meshes with the gear 18. The gear 27 is rotatably supported by an output shaft 28a of a second drive motor 28 via an electromagnetic clutch 29 which constitutes a control means. The second drive motor 28 includes the first drive motor 19
Those with lower power consumption (power consumption) are used. In this embodiment, as the second drive motor 28, a DC geared motor that can be driven forward and reverse is used. The power used by the first drive motor 19 is about several hundred W when performing a normal lifting motion, and about 1 kW when raising the ring rail 11 at high speed. on the other hand,
The power used by the second drive motor 28 is about several tens of watts.
The electromagnetic clutch 29 has a gear 27 and an output shaft 28 in an excited state.
The structure that connects the device a with the device a is used.

Next, an electrical configuration for driving the above-described drive system will be described with reference to FIG. In FIG. 2, a line without an arrow indicates a power supply line, and a line with an arrow indicates a signal line. The drive of the first drive motor 19 is controlled by a control device 30 constituting control means via a servo driver 31, and the drive of the main motor M is controlled by the control device 30 via the inverter 6. The input device 32 is connected to the control device 30. The first drive motor 19 is equipped with a rotary encoder 33 as ring rail position detecting means for detecting the position of the ring rail 11.

The main motor M is connected to the first
Are connected to a power supply 34 via a servo driver 31. The power supply unit 34 supplies a commercial AC power supply (for example, 400 VAC) to the inverter 6 without transforming the power, and supplies the servo driver 31 with 200 VAC transformed by the transformer. The power supply unit 34 converts the commercial AC power supply to a low voltage (in this embodiment, 2 V).
An AC / DC (AC / DC) converter 35 for converting the voltage to 4 V) DC is provided. The power supply switching device 36 is a power supply device 34
And a backup battery 37. Second drive motor 28, electromagnetic clutch 2
9, control device 30 and rotary encoders 7, 26, 3
3 is connected to the output terminal of the power supply switching device 36. The power supply switching device 36 includes a power failure detection means 38 so that the power supply switching device 36 can be switched to a state in which the DC power from the power supply device 34 is supplied to the load in the non-power failure state, and to a state in which the DC power from the battery 37 is supplied to the load in the power failure state. It has become. The power failure detection means 38 detects the DC voltage supplied from the power supply device 34, and outputs a power failure detection signal when the voltage drops below a set value. The power supply switching device 36 switches the power supply by a relay based on the power failure detection signal of the power failure detection means 38. The power failure detection signal is also output to the control device 30. As the battery 37, a reversible storage battery having the same electromotive force as the DC voltage of the power supply device 34 is used, and the battery 37 is connected to an AC power supply via a charger 39 as a charging circuit.

The control device 30 includes a central processing unit (hereinafter, referred to as a CPU) 40 as control means and arithmetic means. The control device 30 includes a program memory 41 as storage means, a work memory 42 as storage means, an input interface 43, an output interface 44, a main motor drive circuit 45, and motor drive circuits 46 and 47. The CPU 40 is connected to the input device 32, the rotary encoders 7, 26, 33, and the power failure detection means 38 via the input interface 43. The CPU 40 is connected to the inverter 6 via the output interface 44 and the main motor drive circuit 45, and to the servo driver 31 via the output interface 44 and the motor drive circuit 46, respectively. The CPU 40 controls the second drive motor 28 via the output interface 44 and the motor drive circuit 47.
Are connected to the electromagnetic clutch 29 via an output interface 44 and an electromagnetic clutch excitation / demagnetization circuit 48, respectively.

The CPU 40 operates based on predetermined program data stored in the program memory 41. The program memory 41 is a read-only memory (ROM), and stores the program data and various data necessary for executing the program data. The working memory 42 is a readable and rewritable memory (RAM), and temporarily stores data input by the input device 32, results of arithmetic processing in the CPU 40, and the like. The input device 32 includes a key switch, and inputs spinning condition data such as the number of spindle revolutions during spinning operation, spinning length, lift length, and chase length. Further, the reference position L _S of the ring rail 11 to be used in determining the direction of rotation of the second drive motor 28 at the time of a power failure by the input device 32 is inputted.

The CPU 40 calculates the position of the ring rail 11 based on the output signal from the rotary encoder 26 at the time of startup, and thereafter calculates the moving amount and position of the ring rail 11 based on the output signal from the rotary encoder 33. That is, the absolute type rotary encoder 26 is used for confirming the position of the ring rail 11 at the time of startup, and is not used during operation. And CP
During normal operation, U40 calculates the reversal timing of the ring rail 11, which is the lifting condition input by the input device 32, based on the moving amount and the position of the ring rail 11, so that the ring rail 11 and the like perform a predetermined elevating movement. The drive of the first drive motor 19 is controlled via a servo driver 31.

The CPU 40 controls the ring rail 1 when a power failure occurs.
The rotation direction of the second drive motor 28 is determined by the position 1. That is, the CPU 40 drives the lifting drive system in a direction to lower the ring rail 11 when the position of the ring rail 11 at the time of the power failure is higher than the reference position, and to raise the ring rail 11 when the position is lower than the reference position. A control signal for rotating the second drive motor 28 is output. When a power failure detection signal is input from the power failure detection means 38, the CPU 40 outputs an excitation signal for the electromagnetic clutch 29 and a drive control signal for the second drive motor 28. The CPU 40 stops the excitation of the electromagnetic clutch 29 and the drive of the second drive motor 28 when the coasting of the spindle drive system is almost stopped based on the output signal of the rotary encoder 7. I have.

Next, the operation of the device configured as described above will be described. Prior to the operation of the machine stand, first, spinning condition data such as the spindle speed, spinning length, lift length, and chase length during spinning operation are input by the input device 32. Also,
The input device 32 inputs the reference position data of the ring rail 11 necessary for determining the rotation direction of the second drive motor 28 at the time of the power failure. As the reference position L _S , for example, when the ring rail 11 is moved down from the reference position during a power failure, the yarn is not wound around the reduced diameter portion 51 below the body 50 of the tube thread 49 shown in FIG. The lower limit position of the position to be in the state is adopted. Then, the main motor M and the first drive motor 19 are driven by a command from the control device 30 when the machine is started.

When the first drive motor 19 is driven, the line shaft 10 is rotated via the rotating shafts 17 and 21 and the worm 23 and the like, and the nut body 16 is rotated via the screw gear 14.
Is rotated. Then, the poker pillar 15 screwed to the nut body 16 is moved up or down, and the ring rail 11 and the like are moved up and down. The ring rail 11 and the like are moved up when the first drive motor 19 rotates forward, and are moved down when rotating reversely. The yarn sent from the front roller 8 is wound on a bobbin via a snell wire and a traveler.

The CPU 40 calculates the position of the ring rail 11 at the time of starting based on the output signal from the rotary encoder 26, and corrects the reference value of the rotary encoder 33 based on the calculated value. During the operation, the movement amount and the position of the ring rail 11 are calculated based on the output signal from the rotary encoder 33 provided in the first drive motor 19. The CPU 40 controls the first drive motor 19 to change the rotation direction of the first drive motor 19 when the ring rail 11 moves by a distance corresponding to the amount of rise or fall of one chase input in advance. 31
Drive control via.

When the power supply to the power supply unit 34 is cut off due to an abnormal situation such as a power failure during operation, the power supply to the main motor M and the first drive motor 19 and the like is stopped, and the main motor M and the first drive motor are stopped. The motor 19 rotates by inertia. When the power supply to the power supply device 34 is cut off, the power supply switching device 36 is operated based on the power failure detection signal from the power failure detection means 38, and the second drive motor 28, the electromagnetic clutch 29, the control device 30, and the rotary encoder 7 , 26, 33 are switched to a battery 37. The battery 37 is sufficiently charged via the charger 39 during a non-power failure, and necessary power is reliably supplied to the second drive motor 28 and the control device 30 at the time of a power failure. Therefore, in the power failure state, the second drive motor 28, the electromagnetic clutch 29, the control device 30, and the rotary encoders 7, 26, 33 function normally.

Next, the control procedure of the lifting drive system during a power failure will be described with reference to the flowchart of FIG. CPU4
0 is a power failure detection signal input from the power failure detection means 38,
The second drive motor 28 according to the power failure stop program
And the electromagnetic clutch 29 is controlled. That is, the CPU 40 determines in step S1 the position L of the ring rail 11 when a power failure occurs.
₀ is calculated based on the output signal of the rotary encoder 33, and the electromagnetic clutch 29 is excited in step S2. Next, in step S3, the CPU 40 compares the position L ₀ of the ring rail 11 at the time of the occurrence of the power failure with the reference position L _S. When the position L ₀ of the ring rail 11 is higher than the reference position L _S (L ₀ > L _S ), the process proceeds to step S4, where a control signal for lowering the ring rail 11 is provided, and the position L ₀ is the reference position L _S If (L ₀ ≦ L _S ), the process proceeds to step S5, and control signals for raising the ring rail 11 are output to the servo driver 31, respectively. As a result, the ring rail 11 is moved by the second drive motor 28 in a predetermined direction at a lower speed than during normal operation.

Next, the CPU 40 determines the operating state of the draft part and the spindle drive system, that is, the state of coasting rotation, based on the output signal of the rotary encoder 7. Specifically, the inertial rotation speed of the spindle drive system is calculated in step S6, and it is determined in step S7 whether the inertial rotation speed is equal to or less than a predetermined speed. The inertial rotation of the spindle drive system gradually slows down and eventually stops. When the spindle drive system is almost stopped, that is, when the inertia rotation speed calculated in step S6 becomes equal to or less than the predetermined speed, the CPU 40 proceeds to step S6.
Proceeding to S8, a stop signal for the second drive motor 28 is output, and a demagnetization signal is output to the electromagnetic clutch 29 to end a series of controls. As a result, the driving force to the lifting drive system is cut off, the lifting drive system is stopped, and the spindle drive system is also stopped a little later. The spindle drive system stops slightly later than the stop of the lifting drive system. However, the amount of rotation of the spindle 3 after the lifting drive system stops and before the spindle drive system stops stops is less than one rotation. There is no problem if the system stops first.

The time during which the inertia rotation of the spindle drive system is continued during a power failure depends on the spinning conditions. Since the second drive motor 28 is driven at a constant speed, the distance that the ring rail 11 moves during the spinning conditions also depends on the spinning conditions. Depends on In a configuration in which the ring rail 11 simply moves in a fixed direction from the time of the power outage, depending on the spinning conditions and the position of the ring rail 11 at the time of the power outage, the ring rail 11 may extend beyond the yarn winding range of the tube thread 49. What happens when you move. As a result, a trouble occurs at the time of restarting after the blackout of the power supply or at the time of rewinding in the winder process.

For example, when the moving direction of the ring rail 11 is limited to the ascending direction, if a power failure occurs near the end of the ascending of the ring rail 11 due to the thread 49 of eight minutes or longer, the ring rail 11 is stopped when doffing is stopped. There is a case where the top bunch is moved to a position higher than the winding position. In addition, ring rail 1
In the case where the moving direction of 1 is limited to the descending direction, if a power failure occurs at a stage where the winding amount of the yarn is small, inconvenience occurs. In other words, if a power failure occurs at a stage where the winding amount of the yarn is extremely small and near the end of the lowering of the ring rail 11, the ring rail 11 may move below the yarn winding range of the tube thread 49. Further, as shown in FIG. 4, the tube thread 49 formed by the filling building has a reduced diameter portion 51 whose diameter is reduced toward the lower side below a so-called trunk portion 50 in which a portion having a predetermined diameter is continuous. Therefore, even after the winding amount of the yarn has been secured to some extent, if a power failure occurs at a stage where the length of the body 50 of the tube thread 49 is short, the ring rail 11 is moved to the reduced diameter portion below the body 50. The thread moves to a position corresponding to 51 and the thread is wound around the reduced diameter portion 51.
If the yarn is wound around the reduced diameter portion 51 after the body portion 50 is formed, it becomes easy to unwind when the yarn is unwound in the winding process.

However, in this embodiment, the rotation direction of the second drive motor 28, that is, the moving direction of the ring rail 11 at the time of power failure is determined based on the position of the ring rail 11 at the time of power failure, and the spindle drive at the time of power failure. The yarn wound around the tube thread 49 while the inertia rotation of the system is continued can be surely wound to a position where the above-mentioned inconvenience does not occur.

When the power failure is resolved, the CPU 40 calculates the position of the ring rail 11 from the rotary encoder 26. If the stop position of the ring rail 11 is outside the chase at the time of the power failure, the ring rail is moved to a position where the ring rail 11 reverses to the rising position in the chase movement following the chase movement at the time of the power failure. The drive of the first drive motor 19 is controlled so as to continue the elevating movement interrupted by the occurrence. If the stop position of the ring rail 11 is within the chase at the time of the occurrence of the power failure, the CPU 40 controls the drive of the first drive motor 19 so as to continue the elevating movement interrupted by the occurrence of the power failure after restarting the machine. .

This embodiment has the following effects. (A) As a driving source for driving the lifting drive system during a power failure, the second drive motor that consumes less power than the first drive motor 19 that normally drives the lifting drive system and is driven by the backup battery 37 28 are used. Therefore, the mechanism is simpler than when a rotation transmission mechanism is provided between the lifting drive system and the spindle drive system. As a result, the first drive motor 19 and the second drive motor 28, which are the driving sources of the lifting device,
It is easy to dispose on the out end side, not only on the gear end side of the spinning machine stand, and the degree of freedom of the layout of the lifting device is increased.

(B) Since the power supply to the second drive motor 28 is stopped shortly before the inertial rotation of the spindle drive system is completely stopped at the time of a power failure, the second drive motor 28 is stopped when the inertia rotation of the spindle drive system is stopped. The power consumption is smaller than when the second drive motor 28 is stopped.

(C) The state of the inertia rotation of the spindle drive system is determined based on the output signal of the rotary encoder 7 serving as the spindle drive system operation detecting means provided in the main motor M. , The lifting drive system can be easily and reliably stopped shortly before the inertial rotation of the spindle drive system stops. In addition, the rotation speed of the power failure motor can be changed regardless of the rotation speed of the spindle.For example, the speed should be high when spinning thick yarn, and slow when spinning fine yarn. Can be.

(D) The second drive motor 28 is configured to be capable of normal and reverse rotation drive, and the rotation direction of the second drive motor 28 is determined based on the position of the ring rail 11 when a power failure occurs. As a result, the yarn wound during the inertia rotation of the spindle drive system is prevented from being broken at the time of restarting the machine stand regardless of the amount of the yarn wound around the tube yarn 49, and the yarn is wound in the winding process. Is wound around the tube 49 in a state that does not hinder rewinding.

(E) As a reference position for determining the rotation direction of the second drive motor 28, the ring rail 11
Is lowered from the reference position, the lower limit position of the position where the yarn is not wound around the reduced diameter portion 51 of the tube thread 49 is adopted. Therefore, the ring rail 11
Is often located above the reference position. As a result, the second drive motor 28 often drives the lifting drive system in the direction in which the ring rail 11 is lowered, and the power consumption is reduced.

(F) Since the battery 37 is connected to the AC power source via the charger 39, the battery
9 and sufficient power is reliably supplied to the second drive motor 28 and the control device 30 at the time of a power failure.

(G) Since a geared motor is used as the second drive motor 28, it is more compact than when a speed reduction mechanism is provided between the second drive motor 28 and the rotary shaft 17. In addition,
The present invention is not limited to the above embodiment, and may be embodied as follows, for example.

(1) The second drive motor 28 may be stopped at the same time as the inertia rotation of the spindle drive system is stopped. Also in this case, the same effects as in the above-described embodiment are exerted except for (b).

(2) The drive stop timing of the second drive motor 28 is determined by the rotary encoder 7 mounted on the main motor M.
Of the second drive motor 28 after a predetermined time from the output of the power failure occurrence detection signal,
To stop. The predetermined time is set based on spinning conditions and a spindle rotation speed at the time of occurrence of a power failure. In this case, it is not necessary to detect the operation state of the spindle drive system after starting the control of the second drive motor 28.

(3) The reference position for determining the rotation direction of the second drive motor 28 is such that when the ring rail 11 is moved down from the reference position during a power failure, the yarn is wound around the reduced diameter portion 51 of the tube thread 49. The lower limit position of the position where it will not be taken,
When the ring rail 11 is moved upward from the reference position, it may be between the upper limit position where the yarn does not exceed the winding range of the tube thread 49.

(4) A configuration in which the position of the ring rail 11 when a power failure occurs is compared with a reference position to determine the rotation direction of the second drive motor 28 at the time of the power failure, and the ring rail 11 is moved in a fixed direction until the stop. Instead of the second drive motor 2 so as to continue the chase movement before the power failure occurs.
8 may be driven. In this case, since the ring rail 11 moves so as to continue the predetermined chase movement only by slowing down its moving speed, the input of the reference position becomes unnecessary, and when the operation of the machine base is restarted after the blackout of the power failure, There is no need to move the ring rail 11 to a predetermined position.

(5) Instead of using a DC motor capable of normal and reverse rotation as the second drive motor 28, a non-reversible DC motor is used, and as shown in FIG. 17, two sets of gear trains 52 and 53 for raising and lowering are provided. The ascending gear train 52 includes the gear 18 and the gear 27 of the above embodiment, and a descending gear train 53 is newly added. The torque of the output shaft 28 a is transmitted to the gear train 53 via an electromagnetic clutch 54. In this device, when only the electromagnetic clutch 29 is excited during a power failure, the rotating shaft 17 is driven in a direction to raise the ring rail 11 via a gear train 52, and when only the electromagnetic clutch 54 is excited, the rotating shaft 17 is driven via a gear train 53. 17 is driven in a direction to lower the ring rail 11. Therefore,
Even if the second drive motor 28 is a motor that cannot be driven in reverse rotation, the direction of movement of the ring rail 11 can be freely changed by controlling the excitation and demagnetization of the electromagnetic clutches 29 and 54 by the control device 30. And the control of (4) can be performed.

(6) Instead of a configuration in which the ring rail 11 can be moved in either the upward or downward direction during a power failure,
It is configured to be movable only in one of the ascending and descending directions. Then, when the ring rail 11 reaches the boundary of the predetermined winding range of the thread 49, the second drive motor 28 is stopped even if the inertial rotation of the spindle drive system is not substantially stopped. In this case, driving the second drive motor 28 in the direction in which the ring rail 11 is lowered reduces power consumption.

(7) In the embodiment, a so-called spring-closed electromagnetic clutch is used as the electromagnetic clutch 29, which connects the output shaft 28a and the gear 27 during a power failure and separates the output shaft 28a from the gear 27 during energization. May be. In this case, the electromagnetic clutch 29 is automatically connected at the same time as the power failure, and the excitation of the electromagnetic clutch 29 by the battery 37 becomes unnecessary, and the consumption of the battery 37 is reduced.

(8) A DC servomotor may be used as the first drive motor 19 instead of an AC servomotor, and a corresponding servo driver may be used. In addition, a variable speed motor whose speed is controlled through an inverter is used in place of the servo motor, and the rotation direction of the line shaft 10 is changed between the output shaft and the line shaft 10 by demagnetizing a pair of electromagnetic clutches. A mechanism may be provided. Further, a constant speed motor may be used as the main motor M.

(9) As a spindle drive system operation detecting means for detecting an operation state of the spindle drive system, a rotary encoder is attached to a portion rotated in synchronization with the main motor M, for example, the driving shaft 1 instead of the main motor M. Is also good. Further, a tacho generator may be attached instead of the rotary encoder. When a tachogenerator is mounted, unlike a rotary encoder, a pulse signal proportional to the number of revolutions is output without power backup, thereby simplifying wiring. Alternatively, a dog may be provided at a position rotated by the main motor, and rotation of the dog may be detected by a proximity switch.

(10) The second drive motor 28 may have a different operating voltage from that of the control device 30, and different batteries may be used for the control device 30 and the second drive motor 28. Alternatively, the battery 37 may not be connected to an AC power supply via the charger 39, and may be replaced with a charged battery when the charged amount decreases to a predetermined value or less.

(11) The power failure detecting means 38 is not provided in the power supply switching device 36, and the power supply to the power supply device 34 can be detected at a position where interruption of the power supply can be detected, or the power supply to the main motor M or the first drive motor 19 can be detected. May be provided at a position where the cutoff of the vehicle can be detected.

(12) Other than the rotary encoder, a means for detecting the position of the ring rail 11 may be used. For example, a so-called magnet scale having a large number of permanent magnets in which N poles and S poles are alternately arranged near a lifting range of the ring rail is provided, and its detection unit is fixed to the ring rail 11 so as to be integrally movable. An apparatus having the above configuration may be employed. Further, a linear potentiometer may be used as the position detecting means. The mounting position of the rotary encoder may be a suitable position as long as the component is rotated in synchronization with the rotation of the line shaft 10.

(13) Instead of providing the charger 39,
A charging circuit may be incorporated in the power supply device 34 so that the battery 37 can be charged via the charging circuit. (14) Instead of a configuration in which the spindle 3 is driven by the spindle tape 5 wound around the chin pulley 4, a configuration in which the spindle 3 is driven by a tangential belt may be adopted. Moreover, you may apply to a ring twisting machine.

The inventions other than those described in the claims which can be grasped from the embodiment and the modified examples will be described below together with their effects. (1) In the invention described in claim 2 or 3,
The second drive motor is configured to be capable of normal and reverse rotation drive, and the control means is configured to continue the chase movement before the power failure based on the detection signal of the ring rail position detection means for detecting the position of the ring rail. Controls the drive motor. In this case, it is not necessary to input the reference position, and it is not necessary to move the ring rail 11 to a predetermined position when restarting the operation of the machine after the blackout. Also, when a power failure occurs, regardless of the amount of yarn wound around the yarn, the yarn does not hinder the yarn until the inertia rotation of the spindle drive system stops, and does not hinder the restart of the machine stand. The yarn is wound so as not to hinder the winding of the yarn in the winding process.

(2) In any one of claims 1 to 4 and (1), the battery is connected to an AC power supply via a charging circuit. In this case, the battery is sufficiently charged via the charging circuit during a non-power failure, and the necessary power is reliably supplied to the second drive motor and the control means during a power failure. (3) In the invention according to claim 4, when the ring rail is moved down from the reference position at the time of a power failure, the lower limit position of the position where the yarn is not wound around the lower reduced diameter portion of the tube thread is set. Set as the reference position. In this case, the ring rail is often located above the reference position during a power failure,
In many cases, the drive motor drives the lifting drive system in the direction of lowering the ring rail, and the power consumption is reduced.

(4) Claims 1 to 4 and (1) to
In the invention according to any one of (3), a DC geared motor is used as the second drive motor. In this case, it is not necessary to newly provide a speed reduction mechanism between the lifting drive system and the lifting drive system, and the lifting drive system is driven at a low speed in a compact state.

[0061]

As described in detail above, claims 1 to 4 are provided.
According to the invention described in (1), the lifting drive system can be operated with a simple configuration and with less power consumption than during normal operation until the inertia rotation of the spindle drive system stops or almost stops at the time of a power failure. Further, the degree of freedom of the layout of the lifting device is increased.

According to the third aspect of the present invention, the lifting drive system can be reliably driven until the inertial rotation of the spindle drive system is stopped or almost stopped irrespective of the spinning conditions and the rotational speed of the spindle when a power failure occurs.

According to the fourth aspect of the present invention, it is possible to prevent the yarn from being broken when the machine is restarted after the blackout and turn off the yarn in the winding process so as not to hinder the winding of the yarn. it can.

[Brief description of the drawings]

FIG. 1 is a schematic perspective view of a drive system according to an embodiment.

FIG. 2 is a block diagram showing an electrical configuration of the control device.

FIG. 3 is a flowchart showing an operation at the time of a power failure.

FIG. 4 is a schematic view showing the shape of a tube thread being wound;

FIG. 5 is a partial schematic perspective view of a drive system according to a modification.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Driving shaft which comprises a draft part and a spindle drive system, 7 ... Rotary encoder as a spindle drive system operation detection means, 8 ... Front roller which comprises a draft part as a roller part, 10 ...
Line shafts constituting a lifting drive system, 11 ...
Ring rail, 13 ... an elevating unit constituting a lifting drive system, 19 ... a first drive motor, 28 ... a second drive motor, 29 ... an electromagnetic clutch constituting control means, 3
0: control device constituting control means, 26, 33 ... rotary encoder as ring rail position detecting means, 34
... power supply device, 36 ... power supply switching device, 37 ... battery, 3
8 ... power failure detection means, 40 ... CPU as calculation means and control means, M ... main motor.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-8-3823 (JP, A) JP-A-60-246826 (JP, A) JP-A-4-214425 (JP, A) JP-A 62 215022 (JP, A) Jiko 3-48223 (JP, Y2) (58) Field surveyed (Int. Cl. ⁷ , DB name) D01H 1/36 D01H 1/16

Claims (4)

(57) [Claims] 1. A spinning machine in which a lifting drive system is driven by a motor separate from a roller part and a spindle drive system, wherein the lifting drive system has a first drive motor and a smaller power consumption than the first drive motor. Drivable second
The first drive motor drives the lifting drive system during normal operation. During a power failure, the backup drive battery is used as a power source until the inertia rotation of the spindle drive system is stopped or almost stopped. A lifting control method for a spinning machine in which a motor drives a lifting drive system. 2. A spinning machine in which a lifting drive system is driven by a separate motor from a roller part and a spindle drive system, wherein the first drive motor drives the lifting drive system during normal operation; A second drive motor that can be driven with a smaller power consumption than the first drive motor, and control means for controlling the second drive motor until the inertial rotation of the spindle drive system stops or almost stops during a power failure; A lifting device for a spinning machine, comprising: a power failure detection unit that detects the occurrence of a power failure and outputs a power failure detection signal to the control unit; and a battery that supplies power to the second drive motor and the control unit during a power failure. 3. The lifting device for a spinning machine according to claim 2, wherein said control means controls said second drive motor based on an output signal of a spindle drive system operation detection means for detecting an operation state of said spindle drive system. . 4. The second drive motor is configured to be capable of forward and reverse rotation drive, and the control means controls the position of the ring rail at the time of power failure detected by the ring rail position detection means detecting the position of the ring rail. The lifting device for a spinning machine according to claim 2 or 3, wherein a rotation direction of the second drive motor is determined based on the rotation direction.