EP0665317A1 - Feed mechanism for machine tools, in particular sewing machines - Google Patents

Abstract

The workpiece feed mechanism (2), esp. at a sewing machine (1), has a main feed (3) to move the workpiece (W) longitudinally and a further feed (5) working laterally to align the workpiece (W). The feed assembly (6) for the additional feed unit (5) has a roller-shaped rotor (8) with a number of belts (10) passing round, with a setting drive (14) for them independent of the rotor rotation, and the belt levels of the belts (10) form part of the rotor mantle. The rotor (8) axis (A) is parallel to the feed path (9).

Description

The invention relates to a feed device for machine tools, in particular sewing machines, consisting of a main conveyor for longitudinally conveying the workpiece to be machined in the feed direction and an additional conveyor for aligning transverse conveyance of the workpiece, which additional conveyor is arranged upstream or downstream of the main conveyor and guided along a guideway Has workpiece attachable conveyor with transversely drivable conveyors.

In order not only to give a workpiece a straight, but also an arc-shaped feed for machining, or to move the workpiece forward parallel to an edge, an edge, a hem or the like, it is known to machine tools, in particular sewing machines, with one To equip the main conveyor and the additional conveyor composing feed device, the main conveyor moving the workpiece in a straight line in the feed direction and the additional conveyor, if necessary, ensuring a transverse movement of the workpiece which is normal to the feed direction, so that, depending on the use and direction of conveyance of the additional conveyor, there is a straight line or arcuate, parallel to the edges or edges Can achieve feed movement. As EP-B 0 383 045 shows, there are already additional conveyors which have a conveyor device which can be placed on the workpiece in the form of a conveyor Have conveyor chain revolving transversely to the feed direction, which conveyor chain carries rotatable rolling elements. When the conveyor chain is placed on the workpiece, these rolling elements can roll on the workpiece in the feed direction and thereby enable a straight workpiece feed, but they act as a driver transversely to the feed direction when the conveyor chain is driven and ensure transverse conveyance of the workpiece. However, there is only point-to-point contact between the rolling elements and the workpiece and the transverse movement of the rolling elements must be superimposed on the rolling movement in the feed direction, which often leads to difficulties in the aligning transverse conveyance of the workpiece, which difficulties arise especially with soft, collapsible workpieces, such as Textiles, particularly noticeable. In addition, the rolling elements must sit securely on the chain and rotate smoothly at the same time, which means a corresponding amount of construction work and a high level of maintenance.

According to CH-A-650.293, for sewing machines for processing tubular workpieces, clamping devices with two rotatable clamping parts for the workpiece holder and straightening members assigned to the clamping parts for the precise alignment of the workpiece edges are already known, the straightening members being used in the clamping parts or in their own cylindrical bearing parts. Gears located in axial planes to the clamping or bearing part axes of rotation serve as directional organs, which can be driven via a worm gear independently of the respective clamping or bearing part, so that the workpiece placed on the clamping parts can also be moved via these gears during a clamping part rotation in the axial direction of the clamping parts move and align. Here, too, there is only point contact between the workpiece and the straightening element, and the straightening elements can also touch the workpiece do not grasp and guide in the immediate edge area, which means that such straightening elements are not very suitable for straightening transverse demands on flat workpieces.

The invention is therefore based on the object of eliminating these deficiencies and creating a feed device of the type described which is distinguished by its comparatively simple and robust construction and by its particular functional reliability.

The invention solves this problem in that the conveying device of the additional conveyor, as known per se, is mounted in a roller-shaped rotor, which is used as a conveying means, about an axis of rotation which is normal to the feed direction and parallel to the guide track and can be driven with a circumferential speed adapted to the conveying speed of the main conveyor the conveyor device accommodates a plurality of conveyor belts or the like which are arranged symmetrically around the axis of rotation of the rotor and which rotate in the direction of the axis of rotation of the rotor and can be driven by an actuator independently of the rotor rotation, the conveyor strands of the conveyor belts forming parts of the rotor jacket. The rotor running on the workpiece not only helps to move the workpiece forward together with the main conveyor in the feed direction, but also unrolls the conveyor on the workpiece, which thus remains in relation to the workpiece without any relative movement during placement in the feed direction. By actuating this conveying device, the workpiece is therefore also moved transversely without such a relative movement, which ensures a perfect transverse conveying of the workpiece and leads to the desired exact alignment possibility. The clear separation between longitudinal feed and cross feed allows the desired precise workpiece guidance during machining, with a suitable speed adjustment between Main conveyor and rotor of the additional conveyor, the workpiece can be subjected to a certain tensile stress, which in the case of textiles or the like. Flexible workpieces brings about a substantial improvement in the workpiece feed. Conveyor belts are used as conveying means for the conveying device, since they not only result in a relatively simple and robustly constructed, low-maintenance and failure-prone conveying device, but above all also lead to a flat contact between their conveying dreams and the workpiece, which result in a flawless, even with very flexible and flexible workpieces problem-free cross-conveyance of the workpiece is guaranteed. This also makes it possible to force the workpiece onto a transverse motion component that is strong in comparison to the longitudinal motion component and to achieve relatively narrow feed movements of the workpiece, whereby due to the conveyor belts extending over the respective workpiece edges or the like, a corresponding workpiece guidance is always provided in the immediate edge or seam area is ensured.

An expedient construction for such a rotor is obtained if the rotor forms a cage with the number of conveyor belts corresponding to many axially parallel supporting bars, which have an approximately trapezoidal, sector-oriented cross section and each have receptacles on a radial longitudinal side for the storage and guidance of the conveyor belts. The support rods and the conveyor belts arranged therebetween can also be accommodated in larger numbers in a rotor of relatively small diameter, so that the overall dimensions of the additional conveyor remain relatively small and this additional conveyor can be used to save space in a wide variety of machine tools.

In principle, any suitable actuating drive could be used to actuate the conveying device in the rotor if it enables the necessary driving movement of the conveying means during the rotor rotation. A particularly advantageous drive, however, arises from the fact that the actuating drive is designed in a manner known per se as a screw gear, which comprises a screw spindle projecting coaxially into the rotor and rotatably mounted relative to the rotor, which screw screw can be driven via a stepper motor with the empty spaces and preferably a tooth profile having conveyor belts or the like. A fairly simple and functionally reliable drive is achieved, in which all conveyor belts can be operated synchronously with a screw spindle. If the screw spindle is driven at the same speed as the rotor via its stepper motor, there is no relative movement between the rotor and conveyor belts and the workpiece is moved in a straight line by the rotor. If, on the other hand, there is a speed difference between the spindle and the rotor, the conveyor belts are rotated and the workpiece is transversely conveyed, the direction of the transverse movement and the speed of this movement depending on whether the screw spindle runs faster or slower than the rotor or how big the wire number difference is. The screw spindle could also interact with flat conveyor belts solely due to the frictional connection, but a toothed profile of the conveyor belts ensures positive interlocking with the screw spindle, which leads to an exact conveying movement. In addition, a better conveying effect can be exerted on the workpiece by the tooth profile.

According to a further embodiment of the invention, two are arranged one above the other, each with a conveyor equipped rotors are provided, between which a guide plate can be inserted. This means that two workpieces can be guided one above the other for joint processing and aligned with each other, which significantly extends the area of application of the feed device. The rotors each work for themselves and can move the layers of fabric or the like independently of one another, so that an automatic sewing process is ensured.

Fig. 1 und 2

eine Nähmaschine mit einer erfindungsgemäßen Vorschubeinrichtung in Seitenansicht bzw. in Stirnansicht,

Fig. 3

die Nähmaschine mit einem anderen Ausführungsbeispiel einer erfindungsgemäβen Vorschubeinrichtung in Stirnansicht sowie die

Fig. 4 und 5

eine erfindungsgemäβe Vorschubeinrichtung in teilgeschnittener Draufsicht bzw. im vergrößerten Querschnitt nach der Linie V-V der Fig. 4.

The subject matter of the invention is illustrated in the drawing, for example, and shows

1 and 2

a sewing machine with a feed device according to the invention in side view or in front view,

Fig. 3

the sewing machine with another embodiment of a feed device according to the invention in front view and

4 and 5

an inventive feed device in a partially sectioned plan view or in an enlarged cross section along the line VV of FIG. 4th

In order to be able to sew on a sewing machine 1 fully automatically in a straight line or in an arc shape or parallel to the edge and / or edge, a feed device 2 is provided, which consists of a main conveyor 3 for longitudinally conveying the workpiece W to be machined in the feed direction, that is to say the machine-own workpiece conveyor installed in the machine table 4 , and an additional conveyor 5 arranged upstream of the main conveyor 3 for aligning transverse conveying of the workpiece W. The additional conveyor 5 has a conveyor device 6 which can be placed on the workpiece W and which can be driven transversely to the feed direction, which conveyor device 6 is mounted in a rotor 8 which can be driven via a stepping motor 7. The rotor 8 has a normal to the feed direction, to the through the machine table 4 formed guideway 9 for the workpiece W parallel axis of rotation A and is supported together with its drive on a lifting and lowering support frame 9. Conveyor belts 10 arranged symmetrically about the axis of rotation A and guided in the direction of the axis of rotation of the rotor are provided as conveying means of the conveying device 6, each rotating around deflection rollers 11 and forming parts of the rotor shell with their conveying strands 10a. The roller-shaped rotor 8 is produced as a cage with supporting rods 12 arranged parallel to the axis, which have a trapezoidal cross-section and are aligned sector-wise towards the axis of rotation A. The support rods 12 each have receptacles 13 for mounting and guiding the deflection rollers 11 or conveyor belts 10 on one of the radial longitudinal sides, so that a plurality of such conveyor belts 10 can be accommodated in the rotor 8. An actuator 14 for driving the conveyor device 6 comprises a screw gear 15 with a screw spindle 16 projecting coaxially into the rotor 8, which cooperate with the empty runs 10b of the conveyor belts 10, which conveyor belts 10 have a corresponding tooth profile 17. The screw spindle 16 is driven by a stepper motor 18, whereby a mutual standstill between the rotor rotation and the screw spindle rotation during the rotor rotation can bring the conveyor belts 10 to a standstill or move.

With the usual straight feed, the rotor 8 placed on the workpiece W is driven at a circumferential speed adapted to the conveying speed of the main conveyor 4, the screw spindle 16 also rotating at the same speed at the same time, so that the conveyor belts 10 have no relative movement with respect to the rotor 8. Thus, the conveyor belts 10 roll with their conveyor strands 10a on the workpiece without subjecting it to a transverse feed. However, the command for a transverse feed is given by a control device (not shown) issued what is done according to a certain sewing program or according to an edge-parallel guidance by scanning the edges by means of only indicated sensors 19, the speed of the screw spindle 16 is changed relative to the rotor speed via the servomotor 18, so that the conveyor belts 10 change due to the interaction with the screw spindle 16 move in one direction or the other and thus move it across the workpiece W during placement. The desired cross feed occurs and the required alignment movement is guaranteed. The cross feed takes place as long as there is a speed difference between the spindle and the rotor, which means that there is extensive freedom in terms of the feed options. As soon as the speed of the screw spindle 16 is again adjusted to the rotor speed, the transverse feed is also ended, and depending on whether the speed is selected to be lower or higher than the rotor speed, there is a transverse movement in one direction or the other.

3, the sewing machine 1 is equipped with an additional conveyor 5 which has two rotors 8 arranged one above the other, each with its own conveying device 6, it is not only possible to grasp a workpiece W between the rotors interacting in pairs, but above all to guide two workpieces W, W1 on top of each other and sew them together with the correct edges. For this purpose, a guide plate 20 then only needs to be inserted between the rotors 8, as a result of which the two layers of material W, W1 are each guided between the guide plate 20 and the associated rotor 8 and can each be aligned individually via the rotor 8 and the associated conveying device 6. Of course, corresponding drive and control devices are required for each of the rotors 8.

Claims (4)

Feed device (2) for machine tools, in particular sewing machines (1), consisting of a main conveyor (3) for longitudinally conveying the workpiece (W) to be machined in the feed direction and an additional conveyor (5) for aligning transverse conveyance of the workpiece (W), which additional conveyor (5 ) has a conveyor device (6), which can be placed in front of or behind the main conveyor (3) and placed on the workpiece (W) guided along a guideway (9), with conveyor means which can be driven transversely to the feed direction, characterized in that the conveyor device (6) of the additional conveyor ( 5), as is known per se, is mounted in a roller-shaped rotor (8) which is rotatable about an axis of rotation (A) which is normal to the feed direction and parallel to the guideway (9) and can be driven with a peripheral speed adapted to the conveying speed of the main conveyor (3) as conveying means of the conveying device (6), several are distributed symmetrically around the rotor axis of rotation (A) dnete, rotating in the direction of the rotor axis and driven by an actuator (14) independently of the rotor rotation conveyor belts (10) or the like. The conveyor strands (10a) of the conveyor belts (10) form parts of the rotor jacket. Feed device according to claim 1, characterized in that the rotor (8) forms a cage with the number of conveyor belts (10) corresponding to many axially parallel supporting bars (12), which have an approximately trapezoidal, sector-oriented cross section and each have receptacles on a radial longitudinal side ( 13) for storing and guiding the conveyor belts (10). Feed device according to Claim 1 or 2, characterized in that the actuating drive (14) is designed in a manner known per se as a screw gear (15) which has a screw spindle (coaxially projecting into the rotor (8) and rotatable relative to the rotor (8)). 16) which, via a stepper motor (18), drives a screw spindle (16) which interacts with the empty runs (10b) of the conveyor belts (10) or the like, which preferably have a tooth profile (17). Feed device according to one of Claims 1 to 3, characterized in that two rotors (8), one above the other and each equipped with a conveying device (6), are provided, between which a guide plate (20) can be inserted.

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