WO1993019234A1 - Textile machine - Google Patents

Abstract

A textile machine has at least one individually driven and controllable operational element capable of moving beyond the production zone of the machine. In order to obtain an operational element with a simple design and capable of being very accurately positioned, a driving motor arranged on each operating element (6, 7) is used as driving element.

Description

 Textile machine

The invention relates to a textile machine with at least one functional element that can be moved across the machine production area. that is individually driven and / or controlled.

Textile machines of this type are from DE-A 33 30 lδO and the flat knitting machine model INS 40 from the company

10 Mitsuboshi Seisakusho Ltd., Tokyo, Japan. The functional elements, for example thread guides, are firmly connected to a drive belt which is driven out by a motor at a point remote from the functional elements. The drive devices provided for this purpose are disadvantageous in terms of both production and assembly and maintenance costs. In addition, the precise control of the functional elements at a desired point is only possible with a • high control effort, because the rope and the belt

20 has a certain elasticity due to its length.

The object of the invention is to create a textile machine. which does not have the disadvantages of conventional machines, is both manufacturing and 2δ maintenance and assembly simple and allows safe, reliable control of the functional elements with exact adherence to the predetermined holding positions.

Starting from the known textile machine mentioned at the outset, the object is achieved according to the invention in that a drive motor attached to the functional element is provided as the drive device.

This feature according to the invention enables individual control and movement of the individual functional elements without additional drive devices having to be provided on the machine. This simplifies both - *> -

the manufacture as well as the assembly and maintenance of the machine are essential. In addition, the direct, direct control of the drive motor attached to the functional element makes it possible to position the functional element directly, very precisely, which is only possible to a limited extent in conventional devices with a rope or belt drive. In the event of a failure or malfunction of a functional element or a drive motor attached to it, the radio

10 element in contrast to the conventional devices in a simple manner, so that the textile machine can go back into operation immediately after the replacement process. In contrast to the conventional textile machines, in which malfunctions of drive devices for the functional elements lead to a longer failure of the machine, the productivity with the textile machine according to the invention is significantly increased.

• The functional element is preferably held and / or guided on at least one rail. However, the rail can also be designed in such a way that a plurality of functional elements are guided and held, for example, on different sides of the rail.

The drive device can preferably be a linear motor, the rail itself being used as part of the linear motor. In connection with a further embodiment of the invention, the respective rail has current-carrying rails that run in the longitudinal direction of the rail

30 contact strips for power supply to the functional element drive motor. The drive motor can be a servo, stepper or linear motor, for example. Each functional element preferably has a drive control for the drive motor. The drive control includes

35 preferably a microprocessor.

In the case of a textile machine with at least one functional function that can be moved across the machine production area. element. which is individually driven and controlled, wherein for the drive of each functional element a rope or belt revolves, which is driven by at least one drive device δ independent of the functional element, the object is alternatively also achieved in that at least one functional element has its own coupling device with which the function element can be controllably coupled to or decoupled from the rope or the belt for entrainment in one or the other direction of movement.

For this purpose, the functional element can have, for example, a controllable clamping device. Since the functional element can engage in both directions of pull of the rope or belt, it is possible to bring the functional element to any desired position by maintaining the coupling of the functional element on the rope in a corresponding period of time. During the knitting process, the respective functional element can be in synchronous movement with other machine parts, e.g. Knitted locks to be moved.

As an alternative to the individual control circuits provided for each functional element, its drive control circuits for the drive motor or coupling control circuits for mechanically coupling the functional element to a rope or a belt, according to a further embodiment, the invention is one Central control circuit provided for the individual control of several functional elements. The central control circuit preferably generates, using a control computer, individual control signals for the individual functional elements for their movement or for the movement of their functional parts. According to a further embodiment of the invention, this central control circuit is provided with information regarding the current position of the functional element. Each functional element receives the information required for movement or coupling control via signals. The information to be supplied to the functional element or that which must be provided to it when using a central control circuit include the position to be approached and / or the accelerations of the thread guide box and / or the position, for example the angular position of the thread guide, if that Functional element is a thread guide box.

The signals with which the information is transmitted are preferably electromagnetic signals, for example infrared or laser signals, but also pulse code modulated (PCM) signals which are transmitted by corresponding transmitters, such as infrared transmitters, light emitting diodes, laser diodes, etc are emitted and recorded on the functional element with corresponding receivers. The corresponding transmitters can be on the left, right, side, above and / or below the functional elements or the rails, but also on or on other movable or immovable machine parts, for example on the lock slide, the slide bracket and / or the lock case in the case of a knitting machine to be appropriate. The same applies to the recipient if information from the functional elements e.g. to be transmitted to a central control circuit.

According to a particularly advantageous embodiment of the invention, the rail has a signal-carrying contact strip for signal transmission that runs in the longitudinal direction of the thread guide rail.

In particular, if a contact strip for supplying power to a functional element is already present, this current-carrying contact strip can also be used for the transmission of signals, in that the signals of the supply voltage to be transmitted are connected to the current-carrying Overlying contact strip, for example, be modulated.

In order to determine the current position of the functional element on the δ rail, the rail is provided with a decremental scale for taking the current position of the functional element on the rail; the absolute position of the functional element on the rail can thus be determined directly. As an alternative to this, the rail is provided with an incremental scale, the control circuit calculating the current position of the functional element based on the information removed from the incremental scale.

5 The features according to the invention can advantageously be used in a knitting machine, in particular a flat knitting machine. In this case, the functional element is preferably a thread guide box and the rail is one. Thread guide rail. 0

According to a further very advantageous embodiment of the invention, the thread guide box is coupled to the lock slide for a movement synchronous with the lock slide of a knitting machine during the knitting process.

A further embodiment consists in that the thread guide box is taken along by the lock carriage during the knitting process. 0

The entrainment can take place by a mechanical coupling, but also with a signal coupling.

In the case of a mechanical coupling, it is not only possible, for example, to take the thread guide box with the lock slide via the mechanical coupling, but the mechanical coupling can also disengage or drive the drive motor of the thread guide box, for example. influence its torque. During the knitting process and during the mechanical coupling of the thread guide box with the lock slide, the thread guide box is prevented from rushing away from the lock slide. With this embodiment, the synchronous movement of the thread guide box with the lock carriage is ensured during the knitting process.

The alternative possibility of making a signal coupling of the thread guide box to the lock slide during the control process is possible, for example, with a transmitter which is moved synchronously with the knitting process with the lock slide, but alternatively also independently of it. The transmitter emits a coupling beam which strikes the thread guide box and there a corresponding receiver, so that the output signal of the coupling beam receiver controls the control circuit of the thread guide box in such a way that the thread guide box automatically adjusts the coupling beam and thus the transmitter in synchronism with the knitting process follows. The coupling beam is preferably a laser beam, an infrared beam or a light beam. Depending on the selection of the beam type, the transmitter can be a light-emitting or laser diode.

Due to the movement of the thread guide boxes independently of a lock slide, it is possible to provide an optimal control movement for each thread guide box, and not only to ensure a synchronous movement of the thread guide with the lock slide during the knitting process, but in particular also outside the knitting process of each individual Bring the thread guide box to the specified optimal position in a simple manner and without additional slide stroke movement. Since the carriage no longer needs to take the thread guide boxes with it, no bracket is required. This has the essential advantage that the threads are guided directly to the thread guide without deflection at the ends of the machine. can, so that the thread tension is more constant and thus the stitch pattern is better. Since the thread guide boxes and thus the thread guides can be moved independently of the position of the carriage, it is also possible to set an optimum distance δ between the thread guides and the knitting organs, for example between the nut and the knitting needle. For example, when the thread is floated, it is advantageous to provide a greater distance between the straight knitting needle and nut, so that the thread lying floating can be gripped more securely.

Another advantage of thread guide boxes / which are moved and controlled independently of slides is that the rails can be arranged closer or even staggered, because driver pins and their corresponding arrangement are not required. In this way, the machine can be made more compact, and in particular the thread guide arms are also for the

20 furthest outer thread guide boxes only slightly bent, which improves the knitting process i.e. the insertion angle becomes smaller. In addition, the number of rails and thus the thread guide boxes to be used can be increased considerably.

2δ

Due to the individual control and movement of the thread guide boxes, idle strokes of the slide can be avoided, for example in the case of inlaid knitting, which were required in the known textile machines, since the thread guide boxes

30 could only be moved with the lock carriage.

The features according to the invention also make different thread guide boxes superfluous depending on the fineness 3δ to be knitted.

The thread guide box was previously given as an example of a functional element. The functional element can be trained for numerous other applications. For example, the functional element can have scissors and can be designed as a scissor device in order to cut a thread or even the knitted fabric itself at a specific point in the production area. The functional element can also have a thread clamp for clamping a thread or a knotting device for tying threads, for example for sewing open threads in intarsia. The functional element can also be designed as a material insertion device, with which materials or threads can be inserted at specific, predetermined locations across the width of the textile to influence the optics of the knitted fabric.

δ In particular in connection with flat knitting machines, it is particularly advantageous if the functional element has a coating element or a device for transferring stitches, a so-called decker.

An embodiment of the invention is explained below with reference to the single drawing.

The figure shows a flat knitting machine with a view from above, in a schematic representation. The rear needle bed 3 and the front needle bed 4 are located in a distance δ below two thread guide rails 1, 2. A lock slide δ can be moved over the flat knitting machine.

For the sake of clarity, a thread guide box 6, 7 is arranged on each of the thread guide rails 1, 2 in different positions along the flat knitting machine. Of course, more than two thread guide rails can also be provided, and each thread guide rail can also have at least two thread guides. In the illustrated embodiment of the invention, transmitters 8, 9 are arranged to the side of the thread guide rail and at the ends of the same, the signals, for example infrared or laser signals. These signals contain the information required for controlling the thread guide boxes 6, 7. The signals emitted by the transmitters 8, 9 arrive at a δ corresponding receiver 10 or 11 attached to the thread guide boxes 6, 7. In the case of infrared, light or laser signal transmission, the corresponding receivers 10, 11 convert the signal into an electrical signal which is fed to a control circuit provided in the thread guide box 6, 7.

On the basis of the features according to the invention, it is possible to control the thread guide boxes and / or the (angular) position of the thread guides themselves independently of the lock slide. As far as taking the thread guide boxes with you is concerned, according to the present invention, slide brackets are unnecessary. From this point of view it is therefore possible, without disadvantages, to independently control the front and rear slides or the front and rear lock systems.

20 to operate and control.

As stated above, it is also possible to couple the thread guide boxes to the lock carriage during the knitting process, be it mechanically or by signal.

2δ ßig to achieve a synchronous run between the selected thread guide box and the lock slide during the knitting process. The thread guide boxes are then in this embodiment of the invention only in the manner according to the invention regardless of the lock slide.

30 moves and controls when a knitting process with the respective thread guide box is not carried out. In this way it is possible to bring the thread guide boxes into a suitable, optimal position for the next use, for example, without a slide movement.

3δ This means that no slide stroke movement is required for the optimal positioning of the respective thread guide boxes, which increases the productivity of the flat knitting machine.

Claims

Claims 1. Textile machine with at least one movable element across the machine manufacturing area δ on element (6, 7) which is individually driven and controlled, characterized in that a drive motor provided on the functional element (6, 7) is provided as the drive device. 0 2. Textile machine according to claim 1, characterized gekenn¬ characterized in that the drive motor is a linear motor. 3. Textile machine according to claim 1 or 2, characterized ge indicates that the functional element (6, 7) on at least 5 at least one rail (1, 2) is held and / or leads. 4. Textile machine according to one of the preceding claims, characterized in that at least one rail (1, 2) has at least one current-carrying contact strip for supplying power to at least one functional element drive motor. δ. Textile machine according to one of the preceding claims, characterized in that each functional element (6, 7) has a drive control circuit for controlling the drive motor. 6. Textile machine with at least one functional element that can be moved over the machine production area and is individually driven and controlled, wherein for the drive of each functional element {6, 7) a rope or belt rotates, that of at least one δ-dependent drive device is driven by the functional element (6, 7), characterized in that at least one functional element (6, 7) has its own coupling device with which the functional element (6, 7) can be carried in , one or the other direction of movement can be controlled and uncoupled from the rope or the belt. 7. Textile machine according to claim 6, characterized in that a rope or belt is provided for each direction of movement. 8. Textile machine according to one of the preceding claims, characterized in that a central control circuit for the individual control of a plurality of functional elements (6, 7) is provided. 9. Textile machine according to one of the preceding claims, characterized in that the at least 5 one functional element (6, 7) receives the information required for movement or coupling control via signals. 10. Textile machine according to one of the preceding claims, characterized in that the information includes the position to be approached and / or the accelerations of the functional element (6, 7). 11. Textile machine according to one of the preceding claims 5, characterized. that the information is transmitted by means of electromagnetic signals. 12. Textile machine according to one of the preceding claims. characterized in that the information is transmitted by means of infrared signals. 13. Textile machine according to one of claims 1 to 14 da¬ characterized in that the information is transmitted by means of 5 laser signals. 14. Textile machine according to one of the preceding claims, characterized in that the signals are pulse code modulated. δ lδ. Textile machine according to one of the preceding claims, characterized in that the rail (1, 2) has a signal-carrying, contact strip for signal transmission. 10. 16. Textile machine according to one of claims 1 to 6 and 10 to 18, characterized in that the signals of the supply voltage are superimposed on the contact strip for the power supply. Iδ 17. Textile machine according to one of the preceding claims, characterized in that the thread guide rail (1, 2) is provided with a decremental scale for taking the current position of the functional element (6, 7) on the rail (1, 2) is. 20th 18. Textile machine according to one of claims 1 to 19, characterized in that the rail (1, 2) with an incremental scale for calculating the current 2δ rush position of the functional element (6, 7) on the rail (1, 2) is provided. 19. Textile machine according to one of the preceding claims, characterized in that at least one of the 30 functional elements (6, 7) is a thread guide box. 20. Textile machine according to claims 19, characterized gekenn¬ characterized in that the functional element (6, 7) a An¬ drive device for the movement or the Lagever- 3δ change of a thread guide. 21- Textile machine according to one of the preceding claims, characterized in that the textile machine is a knitting machine. δ 22. Textile machine according to one of the preceding claims, characterized in that the thread guide box (6, 7) is coupled to the lock slide (δ) during its knitting process in synchronism with its movement to the lock slide (δ). 10 23. Textile machine according to claim 22, characterized in that the thread guide box (6, 7) is taken along by the lock carriage (δ) during the knitting process. lδ 24. Textile machine according to claim 22 or 23, characterized in that a mechanical coupling of the thread guide box (6, 7) to the lock slide (δ) is provided during the knitting process. 20th 25. Textile machine according to claim 22 or 23, characterized ge indicates that a signal coupling of the thread guide box (6, 7) with the lock carriage (δ) is provided during the knitting process. 2δ 26. Textile machine according to one of claims 22, 23 or 25, characterized in that a transmitter which is moved synchronously to the knitting process emits a coupling beam to which the thread guide box (6, 30 7) follows automatically. 27. Textile machine according to one of claims 22, 23, 2δ or 26, characterized in that the thread guide box (6, 7) is a receiver for the 3δ coupling beam and a tracking control circuit. 28 .. Textile machine according to one of claims 22, 23 or 2δ to 27, characterized in that the coupling beam is a light beam. δ 29. Textile machine according to one of claims 22, 23 and 2δ to 28, characterized in that the coupling beam is a laser beam. 30. Textile machine according to one of the preceding claims. characterized in that the transmitter is a light emitting diode. 31. Textile machine according to one of claims 1 to 29, characterized in that the transmitter is a laser diode 5. 32. Textile machine according to one of the preceding claims, characterized in that the functional element (6, 7) has scissors. 0 33. Textile machine according to one of the preceding claims, characterized in that the functional element (6, 7) has a thread clamp. 5 34. Textile machine according to one of the preceding claims, characterized in that the functional element (6, 7) has a knotting device. 35. Textile machine according to one of the preceding claims 0, characterized in that the functional element (6, 7) has a material loading device. 36. Textile machine according to one of the preceding claims, characterized in that the functional element 5 has a coating element. 37 .. Textile machine according to one of the preceding claims, characterized in that the functional element has a decker device. δ 38. Textile machine according to one of the preceding claims, characterized in that the functional element is a thread feeding device. 39. Textile machine according to one of the preceding claims 0, characterized in that the functional element is a feeder.