EP0503016A1 - Device for the automatic handling of bobbin cases and completely wound bobbins in spinning machines. - Google Patents

Abstract

Reel handling equipment is partly automatic when removing yarn reels from winders. The equipment is based on one frame to enable interchange of full and empty reels, with the ability to move the full reel into a transport position. - The swivel mechanism (7) which is driven from the unit (16) can put the spindles (6,8) into the direction (X, Y or Z) within the framework (12). The ends of the spindles (6a, 8a) are capable of being positioned with exactitude. A torsion unit (11) is based on the frame (12) to give added flexibility.

Description

 "Device for the automatic handling of bobbin tubes and ready-wound bobbins from spinning machines"

The invention is directed to a device for at least partially automatic handling of bobbin tubes and fully wound bobbins of spinning machines.

There is an abundance of fibers, threads and the like which are wound from spinning machines into bobbins, be it storage bobbins as intermediate storage, be it finished bobbins for further processing and the like. The focus here is on the winding of plastic fibers into bobbins in general . The mentioned invention can of course also be used for the manipulation of textile bobbins of synthetic origin, for wire bobbins or for bobbins made of hemp or the like or the like.

Some of these coils are so heavy that they can only be handled with difficulty by people, ie the removal of completely wound bobbins from the winders or from the bobbins can be very difficult. In addition, the exposed mandrels must be re-populated with empty tubes made of paper or plastic as quickly as possible. These empty tubes have to be removed from a reservoir and put on the winding tubes, the removed finished coils have to be transported further stored elsewhere.

The object of the invention is to provide a solution with which the manipulations of finished bobbins as well as empty tubes are simplified, a particular object of the invention being to automate the removal and plug-on operations as comprehensively as possible.

With a device of the type mentioned, this object is achieved according to the invention in that a takeover / transfer arm for empty tubes, a takeover / transfer arm for coils and an actuating and pivoting mechanism for moving the arms from a working position on a common device frame a transport position is provided.

With the invention it is achieved that the loading with empty tubes, the removal of coils and the transport, be it the empty tubes or the coils can be carried out by a single device, since the takeover and transfer arms then for the empty tubes or the coils can work automatically after positioning the device.

In an embodiment, the invention provides that the takeover / transfer arms are pivotally mounted about at least one common axis of rotation via the pivot mechanism, it can be provided in a further embodiment that the takeover / transfer arms are pivotally mounted within the device frame about all three spatial axes.

The advantage of this embodiment is in particular that the device can be designed as a very compact device, since the pivotability of the arms about the same spatial axis enables a compact construction.

It is advantageous if the actuation swivel mechanism is designed to drive the arms at least in regions synchronously, as is also provided by the invention, whereby an asynchronous swiveling is also possible, albeit around the same spatial axis.

The invention also provides that the takeover / transfer arms are equipped at their free ends with positioning heads to compensate for slight positioning inaccuracies, and in order to compensate for positioning inaccuracies, in addition to the measures just mentioned according to the invention, the actuating and swiveling mechanism and αamit can also be provided the takeover / transfer arms are mounted on the device frame by means of a torsion bar suspension.

In AusgestaItung can also be provided according to the invention that the torsion bar suspension itself on Vorricntuncs frame is mounted by means of a swivel mechanism. This pivoting mechanism can also be used to be able to pivot the working position in the horizontal plane of the takeover / transfer arms by at least 90 °.

In order to enable essentially fully automatic work, the invention also provides that the takeover / transfer arms are each equipped with a device for pushing off and pushing on the sleeves or coils.

In a preferred embodiment of the invention, it is also provided that the device frame is equipped with a chassis, it being possible in particular for the chassis to be provided with all-wheel steering.

These designs make it possible to use the entire device fully automatically as a manipulation robot, if necessary using microprocessors, since it can work fully automatically with the aid of the positioning device, with the aid of the all-wheel steering and, if appropriate, the driver's own drive, without the need to involve personnel.

Further refinements and advantages of the invention result from the further subclaims, it being particularly advantageous here if the chassis is designed as a tricycle fan frame with a driven single wheel, which can be provided according to the invention in a modification.

The takeover / transfer arms can advantageously be designed to receive and deliver a plurality of elements, the device being able to be such that a transfer or takeover or pushing movement can be controlled in such a way that the sleeves or coils are close to one another and / or can be positioned at a distance from one another.

All movements of the device, such as those for the takeover / transfer arms and those for the pushing up and pushing off movements, can each be provided with magnetic couplings and / or magnetic brakes for the purpose of positioning the movements at the different positions of the working cycle.

Furthermore, hysteresis clutches can be provided in the drives in order to give each movement an adjustable force limitation, which also allows each movement to be driven against fixed stops at end points. Touching or non-contact limit switches are only provided at the respective starting point (Kull ref.).

Positioning of the drives can be carried out by digital pulse counters, since the movement is positioned at the desired position by means of their magnetic coupling and / or magnetic brake if the actual value is equal to the target value. The invention is explained below with reference to the drawing, for example. This shows in:

Fig. 1 shows a simplified spatial representation of the

 Devices in front of the coil heads

 Spinning machine,

Fig. 2 is an enlarged view of elements of the

 Contraption,

3 shows a representation similar to FIG. 2 with slightly enlarged further details of the drives,

Fig. 4 is a partial view of a sleeve or Low-thrust,

Fig. 5 a further partial view of a takeover /

 handover arms,

Fi g. 6 is a partial view of a chassis of the front

Contraption,

Fig. 7 shows an enlarged representation of the torsional

Suspension of the takeover / low fork, 8 is a plan view of the travel path of a fully automatically controlled pre-device according to the invention in the area of the bobbin heads of several spinning machines

9 to 12 different positions of a coil mandrel relative to a sleeve mandrel,

13 shows a detailed longitudinal section through the positioning head of a coil mandrel and in

14 shows a section along line XIV-XIV in FIG. 13.

In FIG. 1, the device according to the invention, generally designated 1, is shown in simplified form in front of bobbins designated by 2a and 2b of spinning machines, not shown. The coil heads 2a and 2b have winding mandrels labeled 3a, 3a 'and 3b, 3b'. In the example shown, two coils 4 and correspondingly two empty tubes 5 are provided on the mandrels 3.

The handling device 1 according to the invention has a push-on and push-off mandrel 6 which can be pivoted about a horizontal axis "X" and a push-on and push-off mandrel 8 which can be pivoted about the same horizontal axis "X" for sleeves, which is pivotally mounted on a turret 9. The revolver heads 7 and 8 can be seen mounted uniaxially on the device 1 on a support element 10.

The support element 10 is in turn fastened by means of a torsion bar suspension 11 to the device frame denoted by 12, the device frame 12 with a chassis generally denoted by 13, possibly with its own drive, only indicated in FIG. 1 and equipped with 14.

In the following, the mandrel for loading and unloading the coils is referred to as "spool arm 6", the mandrel for the empty tubes as "sleeve arm 8".

From Fig. 1 it follows that the coil arm 6 and αer sleeve arm 8 by their coaxial arrangement on the spatial axis "X" sweep over a common circular arc denoted by 15, which is geometrically designed so that when positioned in front of a spinning head both at a distance from each other arranged mandrels 3a and 3a 'or 3b and 3b' can be started one after the other.

In Fig. 1, the spatial axis "Y" is still drawn in the area of the torsion bar 11 and the spatial axis "Z" in the area of the turret 9. The support plate 10 can about the spatial axis "Y" can be pivoted in the region of the torsion axis 11, as can be seen somewhat more clearly from FIG. 7. The brackets of the coil arm 6 and the sleeve arm 8 are designed so that the arms can also be pivoted, the spatial axis "Z" being mentioned here only as an example. This pivoting option is clearly shown in FIG. 2.

Finally, in Fig. 1 (only indicated as boxes) a drive 16 for the turret heads 7 and 9 with the sleeve arms 6 and 8, a rotary swivel drive 17 for the sleeve arm 6 and a rotary swivel drive 18 on the arm 8 are shown. Details of these drives result from the other figures, in particular from FIG. 3.

From Fig. 2 it can be seen that the coil arm 6 from the position shown in Fig. 1 already e.g. has moved upwards by 135 ° after taking over two coils 4. From this position shown in solid lines, the coil arm 6 can be pivoted upwards by 90 °.

This position is indicated by a coil 4 'and by a further 90 ° this position is indicated by a coil 4' '. The pivoting circle bears the reference number 19.

As indicated above, the pivot axis is essentially designated with the spatial axis "Z", and pivoting can also be carried out in other positions of the spatial axis "Z". The upward-pointing position "4 '" represents a transport position for the bobbins 4, the position "4"' can represent the push-off position of the full bobbins in a storage or the like (not shown).

The sleeve arm 8 can be pivoted in the same way. The position pointing upwards by 90 ° is designated by 8 ', the position pivoted by 180 ° is also shown in dashed lines and is identified by 8' '. The pivoting circle bears the reference number 20, the position of the sleeve arm 8 shown also being pivoted by 90 compared to the position shown in FIG. 1.

As can be seen from both FIG. 1 and FIG. 2, there is a push-on and push-out device 21 arranged parallel to the sleeve arm 8 with clamping and pushing arms 22 for manipulating the empty sleeves positioned there, a somewhat more precise illustration results from this Fig. 3.

For a description of the torsion bar suspension shown in FIG. 3 in the lower imaging area, generally designated 11, reference is made to FIG. 7 to be described below.

As can be seen from FIG. 3, the spool arm 6 is attached to the rotary or turret head 7 by means of a cooling device 23 Swivel axis "X" rotatably mounted. The rotary drive takes place via an internal electric motor 24.

The rotary movement about the spatial axis "X" of the sleeve arm 8 takes place in a similar manner, the sleeve arm 8 being fastened to the turret 9 via a support element 25.

The control and thus the synchronous or asynchronous rotational movement about the axis "X" of the arms 6 and 8 takes place by means of worm gears 26 and a V-belt drive 27, which is only indicated here, as well as the associated electromagnetic clutches and brakes, which are only used for example are designated by 28.

The pivoting movements according to the radius 19 of the coil arm 6 is effected by a drive, generally designated 29, with an electric motor 30, gears, brakes and the like. also with electric motor 33, a hysteresis clutch 34 with toothed belt drive and the like.

The pivoting movement according to radius 20 (FIG. 2) of the sleeve arm is brought about by the rotation of a toothed wheel 35 with rolling on a fastening element which is stationary on the turret 9. sprocket 36 (Fig. 4).

The clamping control of the clamping jaws 22 takes place via a lever drive 40, again by means of corresponding motors and clutches as well as a four-link chain 37, with reference to FIG. 4, the lift or push-out movement, for example via a toothed belt drive, generally designated 38 in FIG. 4, can be done.

In Fig. 5 shows a possible, soft-spring-centered centering of the sleeves in order to center them to the much smaller sleeve mandrel 8. These centering cams 39 are pressed radially outwards by a spring arranged in the interior of the sleeve mandrel 8 until the cam lugs abut the inner diameter of the mandrel 8 and thus ensure a small play between the sleeves and the centering cam.

When the sleeves are pushed onto the winder mandrel by means of linear unit 21, the soft sleeve centering permits considerable relative movements of the sleeves in order to avoid misalignments to the winder mandrel.

In Fig. 6 shows a possible type of all-wheel steering of the chassis 13, the drive motor itself not being shown there, only the steering motor denoted by 43. There are a swivel lever system 42 there also applied to the rear rollers 43 in such a way that a corresponding all-wheel steering can be carried out. Of course, depending on the design and type of use, the swivel lever system can be dispensed with.

7 shows the suspension via a torsion bar system. This torsion bar suspension 11 consists essentially of a torsion bar 45 which is fixedly mounted at the top in a bearing bush 44 and which is held at the bottom in the worm wheel of the gear 47A, the position of which is adjustable according to the double arrow 48 via an actuator 47 relative to the stationary support frame 10, which is only hinted at here . This arrangement firstly allows the entire device 1 with the support frame 10 fastened to the bearing bush 44 to be pivoted horizontally by means of a servomotor 47 if the bobbin bearing for the bobbin removal and the sleeve magazine requires this orientation.

The fork 46 encompasses the nose of the support frame 10 with a play of, for example, approximately 2 mm and serves only as a swiveling aid in order not to leave the torsion bar 45 here. Second, the arrangement enables the torsion bar 45 to compensate for inaccuracies in the aligned positions of the transfer / take-over of spools and sleeves in each horizontal position of the pivoting 48. The function or mode of operation of the device is explained as follows with reference to FIG. 1 in conjunction with FIG. 8:

8, two rows of spinning machines are set up with bobbin heads 2 pointing to a gear designated 52 or 53, the winding mandrels 3 of which are aligned in the direction of the gears 52 and 53. In order to remove the coils 4 which have been completely wound on the winding mandrels, the device 1 according to the invention is used which, for example, automatically controls every position of a spinning machine in the region of, controlled by ground contact lines

Is able to start winding heads 2. It is assumed that, starting from a transfer station denoted by 54, a device 1 equipped with empty sleeves travels through the passage 52 into position la, shown in FIG. 8. Here, the device la is positioned so that the mandrels 3b and 3b 'can be swept over the swivel radius 15 (FIG. 1). For precise positioning or alignment relative to the winding mandrels 3, both the coil arm 6 and the sleeve arm 8 have corresponding positioning heads 6a and 8a, respectively, which enable precise alignment. A slight twisting is also possible through the torsion bar suspension 11. This supports positioning in the event of minor malpositions. In addition, repositioning of the device 1 can be carried out electronically, for example via a force measurement or a torsion measurement, be it that the drive moves the device 1 for a short distance on the floor surface of the workshop, ie via the swivel fork 46 (FIG. 7), that is, the suspension 10 is adjusted accordingly by means of the servomotor 47.

If the device 1 is in position, the coil arm 6 swivels onto a winding mandrel which is filled with one or more coils 4. Now the full bobbins 4 are pushed onto the bobbin mandrel 6 by means of a fork G via a winder-own linear drive, as shown in Fig. 1 for winder 2b.

If the bobbins 4 are pushed on, the bobbin arm 6 can first be moved into the pivoted-up position denoted by 4 'in FIG. 2. The sleeve arm 8 is then pivoted into the corresponding aligned position with the winding mandrel which has just been emptied, and the empty sleeves 5 are pushed onto the empty winding mandrel via the extension mechanism.

Now the mandrel 8 can also be swung open, the coils 4 can be moved with the device 1 for delivery to the station 54, as can also be seen in FIG. 8. In the Fig. 9 to 12 show different starting positions between a coil mandrel 6 and a winding mandrel 3, in particular with respect to the positioning head 6a of the coil mandrel 6.

An embodiment of the positioning head 6a is shown in more detail in FIGS. 13 and 14.

The alignment of the device 1 with the winding mandrels 3 or 3b or 3b 'already mentioned above can be carried out as shown in FIGS. 9 to 12. The sleeve 5 of the front coil 4 abuts against the conical positioning head 6a on the coil mandrel 6, as shown in FIG. 9. The positioning head 6a is fastened in the interior of the coil mandrel 6 by means of a bending rod and bends slightly in the direction B of an alignment error Pv and thus closes an electrical contact inside the positioning head 6a, thus initiating a repositioning of the device 1 for errors Pv.

This tracking is ended when the front edge of the sleeve 5 abuts the end face of the push-off sleeve 31 and the positioning head 6a has reached the center of the bore of the sleeve 5 and the electrical contact opens, since there is no longer any bending of the positioning head Ga, as in FIG Fig. 10 shown.

This causes the push-off fork 31 to move back and the full bobbins to be pushed onto the bobbin mandrel 6 by means of the fork 6, the four electrical contacts in the positioning head 6a being deactivated in order to avoid false signals due to relative movements of the bobbin (FIG. 11).

Four electrical contacts are provided in the positioning head, one each for:

- Position error vertical ± P _v , which can be caused by

 Forward / return of the turret drive motor 24 can be compensated

- Postionεfehler Horizontal ± P _h , which, for example, by

 Forward / reverse of the drive motor 41a can be compensated.

This caching of the device in both planes can be carried out either individually or synchronously, since the positional head 6a has a slight bending caused by the position error and is vectorial in both planes.

If the bobbin delay is incomplete due to a malfunction or the last bobbin due to thread entanglement For example, when the fork 6 is pulled back again, as shown in FIG. 11, the coil arm cannot be moved into the position denoted by 4 'in FIG. 2, but is stopped by slight bending of the positioning head 6a when the electrical contacts are reactivated.

In the normal case, the sleeve arm 8 is then pivoted into the corresponding aligned position with the winding mandrel that has just been emptied, and the empty sleeves 5 are pushed onto the empty winding mandrel via the extension mechanism.

10 and 11 show a preferred embodiment of the positioning head 6a. The positioning head 6a is connected to the coil mandrel 6 by means of a bending rod 6c and holder 6b.

Four electrical contacts 6g, each with a wire shoe 6e, are fastened to the holder 6b in an electrically insulated manner with a leaf spring 6d.

These four electrical contacts face a contact ring 6f in the positioning head 6a with a slight gap S.

The vectorial bending of the positioning head 6a on the bending rod 6c caused by misalignment ± P _v and ± P _h brings the contact ring 6f into contact with one or two of the electrical contacts 6g and causes the device 1 to track in order to compensate for vertical and / or horizontal position errors.

At this point it should be noted that the entire device can also be designed as a tandem device IAB, in each case for the synchronous handling of two adjacent pairs of Spuien spinning heads, this is also indicated in FIG. 8.

Of course, the described embodiment of the invention can be modified in many ways without departing from the basic idea. So instead of the design elements specified here, such as linear drives, clamping jaws for inside and outside clamping of elements, clamping sleeves for gripping the free ends of the coil sleeves and the like.

more. Other constructive elements can be used. For example, the inner centering of the paper sleeves can be carried out by means of inflatable pneumatic elements, the control can take place via contactless or touch-sensitive limit switches and immediately.

It is also essential for the invention that the paper sleeves and / or the coils can be pushed on or pushed off close to each other. However, this can also be done at a distance to each other, elements can be retained via corresponding brakes and the like. More.

Claims

Expectations:

1. Device for at least partially automatic handling of empty bobbins and finished coils of spinning machines,

 characterized,

 that on a common device frame (12) a takeover / transfer arm (8) for empty tubes (5), a takeover / transfer arm (6) for spools (4) and an actuating and pivoting mechanism (16-18) for moving the arms (6,8) is provided from a locking position to a transport position.

2. Device according to claim 1,

 characterized,

 that the takeover / transfer arms (6, 8) about the pivot mechanism (7, 9) about at least one common axis of rotation ("X"), in particular within the device frame (12) about all three spatial axes (X, Y, Z) pivotally mounted are.

3. Device according to one of the preceding,

 characterized,

that the actuating swivel mechanism (7, 9, 16) is designed to drive the transfer / transfer arms (6, 8) synchronously at least in some areas.

4. Device according to one of the preceding claims,

 characterized,

 that the takeover / transfer arms (6, 8) are equipped at their free ends with positioning heads (6a, 8a) to compensate for minor positioning inaccuracies.

5. Device according to one of the preceding claims,

 characterized,

 that the actuating and pivoting mechanism (16-18) and thus also the takeover / transfer arms (6, 8) are mounted on the device frame (12) by means of a torsion bar suspension (11).

6. The device according to claim 5,

 characterized,

 that the torsion bar suspension (11) itself on the device frame (12) by means of a pivot mechanism (47, 47A) is mounted.

7. Device according to one of the preceding claims,

 characterized,

 that the takeover / transfer arms (6,8) are each equipped with a device for pushing and pushing (38,22) each of one or more sleeves (5) or spools (4).

8. The device according to claim 7, characterized,

 that the takeover / transfer arms (6,8) are set up with a device for transferring or taking over such that the sleeves (5) or coils (4) can be positioned close to one another and / or at a distance from one another, in particular the Takeover / transfer arms (6, 8) are equipped with a holding brake for sleeves (5) or spools (4) that cannot be extended.

9. Device according to one of the preceding claims,

 characterized,

 that the device frame (12) is provided with a chassis (13), in particular with all-wheel steering.

10. Device according to one of the preceding claims,

 characterized,

 that the drives (16-18) are provided with hysteresis clutches (34) and / or magnetic clutches (28) and / or magnetic orems.

11. The device according to one of the preceding claims,

 characterized,

 that linear drives (38) are provided for making the up and down movement.

12. Device according to one of the preceding claims, characterized,

 that touch-sensitive or non-contact switches are provided for limiting and / or triggering the rotating / pivoting / pushing or pulling movements.

13. Device according to one of the preceding claims,

 characterized,

 that the takeover / transfer arms (6, 8) are equipped with diameter compensation cams (39) (Fig. 5) for the sleeves (5).