EP0768126A1 - Method and device for minimizing the height of wire bundles - Google Patents

Abstract

The process minimises the height of a wire bundle (2) which is formed in a chamber (3) from a sequence of wire coils. The individual coils are first transferred from a roughly horizontal transportation direction, into an intake housing (4), and are then brought into a roughly vertical fall direction, prior to transfer to the chamber. The coils are subjected to an additional horizontal centrifugal motion during the fall motion, and the centrifugal force may be transmitted at least partially to the individual coils. The extent of the centrifugal motions which are exerted on the coils, may also have inner and outer limits.

Description

• bei welchem die einzelnen Drahtwindungen zunächst aus einer im wesentlichen horizontalen Transportrichtung an ein Einlaufgehäuse übergeben,
• dann von diesem unter Ablenkung in eine im wesentlichen vertikale Fallrichtung gebracht und daraufhin an die Bundbildekammer übergeben werden.

The invention relates to a method for minimizing the height of wire bundles formed by successively collecting a large number of wire windings in a bundle formation chamber.

• in which the individual wire windings initially pass from an essentially horizontal transport direction to an inlet housing,
• then deflected by the latter in a substantially vertical direction of fall and then transferred to the bundling chamber.

• bei welcher sich an eine Drahtwindungs-Transportvorrichtung über ein vertikal ausgerichtetes Einlaufgehäuse für aufeinanderfolgende Drahtwindungen eine darunterliegende Bundbildekammer anschließt.

The invention also relates to a device for performing this method,

• in which an underneath bundle forming chamber is connected to a wire winding transport device via a vertically aligned inlet housing for successive wire windings.

In the previously customary procedure for the formation of wire coils, the wire windings coming from the transport device are successively transferred to a stationary inlet housing and thereby deflected in an essentially vertical direction of fall, so that they are then in turn located below it Fall bundle chamber. The coil formation chamber is designed with a larger diameter than the inlet housing located at a distance above it.

If, for example, the inner diameter of the inlet housing is between 1080 mm and 1100 mm, the downstream bundle forming chamber is designed in such a way that it has an inner diameter of approximately 1250 mm. This is to ensure that the winding packages collected within the bundle formation chamber can subsequently be transferred without difficulty to a bundle storage plate below the bundle formation chamber.

However, it has been shown in practical use that the differences in diameter between the inlet housing and the bundle forming chamber lead to the fact that the wire windings located within a wire bundle can assume a varying, eccentric and, at the same time, circumferentially displaced position relative to one another. From this, however, there arises the disadvantage that only relatively loosely packed turn packages are created as wire bundles, within which considerable space remains between adjacent wire turns. The consequence of this is not only that a relatively large storage space is required for each individual coil of wire. Rather, the existence of the many free spaces within the wire bundle also results in poor stackability and security for them.

The aim of the invention is therefore to show a possibility by which the height of wire coils can be minimized and at the same time the tightest possible packing of the wire windings contained therein can be brought about.

This object is achieved according to the invention in terms of process technology mainly in that the wire windings are subjected to an additional horizontal centrifugal movement during their essentially vertical falling movement.

The result of the centrifugal movement acting on the individual wire windings leaving the inlet housing is that these wire windings are pushed outwards to a larger diameter than that determined by the inlet housing and are consequently pushed either against the inner circumference of the bundle forming chamber or against one another. This results in the bundle formation chamber in a simple manner very densely packed and consequently minimized in height and stabilized winding packages or wire bundles.

According to the invention it is provided that the centrifugal forces are at least partially transmitted or exerted on the individual wire windings and that the extent of the centrifugal movements exerted on the wire windings is limited outwards and inwards.

In a device for carrying out this method, a wire winding transport device is connected via a vertically aligned inlet housing for successive wire windings to an underlying bundle formation chamber. According to the invention, it is essentially constructed in such a way that a wire guide housing is additionally located in a height area between the inlet housing and the bundle forming chamber, and that this wire guide housing is movably drivable on a self-contained, horizontal path curve surrounding the longitudinal axis of the inlet housing and the bundle forming chamber.

The course and the maximum distance of the movement path curve of the wire guide housing relative to the longitudinal axis of the inlet housing and According to the invention, the bundle formation chamber is essentially determined by the difference in diameter between the inlet housing and the bundle formation chamber.

It has proven itself according to the invention if the drive for the wire guide housing comprises at least two synchronously running crank drives. Of course, eccentric drives can also be used instead of crank drives.

It is also important according to the invention, however, that the speed of the drive for the wire guide housing is provided in a controllable manner, because this can have a decisive influence on the density of the wire windings formed within a winding package or wire bundle. It can also be advantageous for this to make the effective crank radii of the crank drives variable. According to the invention, each crank mechanism can also be equipped with its own electric motor, with the proviso that all electric motors are then electrically synchronized with one another.

It is also important for the permanently correct operation of the device according to the invention that the inlet housing, wire guide housing and bundle forming chamber each have a cylindrically delimited jacket section for the wire winding system, which is followed by a funnel-shaped inlet extension section for the wire windings.

In the crank drives that are preferably used as the drive for the wire guide housing, it has proven to be particularly advantageous if the drive crank of each crank drive consists of two crank arms, if the second crank arm is also at least to a limited extent displaceable and lockable or lockable to the crank pin of the first crank arm, and when the second crank arm is held with its crank pin in rotary joint engagement with a drive arm which acts fixedly on the wire guide housing.

Due to the special type of interaction of both crank cheeks of each crank drive, the effective crank radius can be matched to the most varied of needs in the formation of wire bundles in a simple manner.

In the simplest case, both crank arms of each crank mechanism should have an identical overall length, the second crank arm being adjustable around the crank pin of the first crank arm over an angular range which exceeds an angle of 45 ° and falls below an angle of 90 °. With this configuration of the crank drives, it is possible to vary the extent of the centrifugal movement, which is brought into effect with the help of the wire guide housing on the individual wire windings, from the value 0 to a predetermined maximum value and thereby to influence the formation of the respective wire bundles or winding packages.

Figur 1

in schematisch vereinfachter Seitenansicht eine Vorrichtung zur Minimierung der Höhe von durch Zusammenführen von Drahtwindungen gebildeten Drahtbunden in einer Grund-Funktionsstellung,

Figur 2

eine der Figur 1 entsprechende Darstellung der Vorrichtung, jedoch in einer gegenüber Figur 1 um 90° phasenverschobenen Betriebslage,

Figur 3

eine der Figur 1 entsprechende Darstellung der Vorrichtung, jedoch in einer um 270° verschobenen Betriebslage,

Figur 4

eine Draufsicht auf die Vorrichtung nach Figur 1,

Figur 5

eine Draufsicht auf die Vorrichtung nach Figur 2,

Figur 6

eine Draufsicht auf die Vorrichtung nach Figur 3 und

Figur 7

in vergrößertem Maßstab eine den Figuren 4 bis 6 ähnliche Darstellung der Vorrichtung, jedoch in einer weitergebildeten Ausführungsvariante.

The invention is described in detail below with reference to exemplary embodiments shown in the drawing. Show

Figure 1

in a schematically simplified side view, a device for minimizing the height of wire coils formed by merging wire windings in a basic functional position,

Figure 2

2 shows a representation of the device corresponding to FIG. 1, but in an operating position that is 90 ° out of phase with respect to FIG. 1,

Figure 3

2 shows a representation of the device corresponding to FIG. 1, but in an operating position shifted by 270 °,

Figure 4

2 shows a plan view of the device according to FIG. 1,

Figure 5

2 shows a plan view of the device according to FIG. 2,

Figure 6

a plan view of the device of Figure 3 and

Figure 7

on an enlarged scale a representation of the device similar to Figures 4 to 6, but in a further developed embodiment.

First of all, it should be noted here that in the explanatory drawing, the structural and functional parts of a device for minimizing the height of winding packages or wire bundles collected and collated from a large number of wire windings are only shown in a purely schematic representation.

It can be seen, in particular in FIGS. 1 to 3, that the device 1 for collecting and collapsing winding packages or wire bundles 2 essentially consists of three basic components, namely a bundle forming chamber 3, an inlet housing 4 and a wire guide housing 5.

The collar formation chamber 3 consists of a cylindrical jacket section 6, for example in the form of a tube section which is provided with an inlet extension section 7 which widens upwards in a funnel shape. The inlet housing 4 also has a cylindrical jacket section 8, for. B. in the form of a pipe section, to which or a funnel-shaped upwardly extending inlet extension section 9 is firmly connected.

Finally, the wire guide housing 5 is also formed by a cylindrical jacket section 10, for example a pipe section, and is equipped with a conically widening inlet extension section 11 adjoining it at the top.

The entire device 1 is the rear end of a wire winding transport device (not shown in the drawing) assigned, which has an at least substantially horizontal transport plane.

The bundle forming chamber 3 and the inlet housing 4 of the device 1 are mounted in a fixed position relative to the wire winding transport device and have a common, vertical alignment axis 12-12.

The wire guide housing 5 also has a vertical alignment axis 13-13, which is indicated in FIGS. 2 and 3, but which assumes a more or less large lateral offset position or eccentricity 14 with respect to the vertical alignment axis 12-12.

In contrast to the bundle formation chamber 3 and the inlet housing 4, the wire guide housing 5 is not provided to be stationary. Rather, with the lateral offset position or eccentricity 14 of its vertical alignment axis 13-13, it is arranged or housed so as to be drivable around the vertical alignment axis 12-12 in a height region located between the inlet housing 4 and the bundle forming chamber 3.

It is also important in the device 1 that the inside diameter 15 of the cylindrical jacket section 6 of the bundle forming chamber 3 is larger than the inside diameter 16 of the cylindrical jacket section 8 on the inlet housing 4. It has been proven, for example, the diameter ratios 15:16 1.14: 1 to 1.16: 1.

It has proven to be useful to have the inside diameter 17 of the cylindrical jacket section 10 on the wire guide housing 5 at least approximately the inside diameter 16 of the cylindrical jacket Part 8 to adjust the inlet housing 4 and to adjust the lateral offset or eccentricity 14 between the two vertical alignment axes 12-12 and 13-13 to the existing difference between the clear diameters 15 and 16.

The drive for the wire guide housing 5 of the device 1 is effected in the exemplary embodiment of FIGS. 4 to 6 by at least two synchronously running crank drives 18a and 18b which engage diametrically opposite on the circumference of the wire guide housing 5.

Instead of the crank drives 18a and 18b, appropriately designed eccentric drives can also be used.

A construction has proven itself in which each crank mechanism 18a and 18b is equipped with its own electric motor 19a and 19b and which in turn works on its own reduction gear 20a or 20b. The electric motors 19a and 19b are not only electrically synchronized with one another, but are also designed to be controllable in terms of their drive speed.

With the help of the crank drives 18a and 18b or the like, the wire guide housing 5 is displaced in a circular manner relative to the bundle forming chamber 3 and the inlet housing 4 at adjustable speed along the path curve 21 around the vertical alignment axis 12-12, three different movement phases of this circular displacement movement in FIGS. 5 and 6 of the drawing are recognizable. Under the action of the circular movement of the wire guide housing 5, the wire windings emitted from it into the bundle forming chamber 3 are subjected to a radial centrifugal movement and are consequently accelerated and pushed in the direction of the inner periphery of the bundle forming chamber 3. Due to this spinning movement, the individual wire windings endeavor to be within the winding packages or Place wire bundles 2 as close together as possible. Due to the close packing of the adjacent wire turns, the height of the winding packs or wire bundles 2 is minimized.

While a device for minimizing the height of wire coils 2 was described above with reference to FIGS. 1 to 6, in which the drive for the wire guide housing 5, for example formed by crank drives, runs through a fixed or unchangeable path curve 21, a drive is shown in FIG. 7 as an example to see, in which the movement path 21 described by the wire guide housing 5 can be changed with simple means.

In Figure 7 it can be seen that the drive crank 22 of each crank drive 18a and 18b consists of two crank arms 23 and 24. The crank arm 24 is held on the crank pin 25 of the crank arm 23. With the help of a clamping device 26, the crank arm 24 can be fixed and locked relative to the crank arm 23 in different angular positions, so that the crank pin 27, which it in turn supports, can rotate on the drive shaft 28 of the respective drive crank 22 on correspondingly different crank radii. Since the crank pin 27 of both crank drives 18a and 18b is each held in rotary joint engagement with a drive arm 29 which rigidly engages the wire guide housing 5, the wire guide housing 5 is imparted a displacement movement along a path curve 21 about the vertical alignment axis 12-12, which is dependent on the respective eccentricity the crank pin 27 is dependent on the drive shaft 28 of both crank drives 18a and 18b.

Due to the adjustable eccentricity 14 of the crank drives 18a and 18b according to FIG. 7, the diameter of the winding package or wire bundle 2 formed in each case can be varied within certain limits. The density of the winding layers within the winding package or wire bundle 2 can be varied by varying the speed affect the crank mechanisms 18a and 18b.

Since the individual wire windings in the bundle forming chamber 3, in the inlet housing 4 and also in the wire guide housing 5 can only come into contact with cylindrical wall surfaces, the individual wire windings are treated gently when the winding packages or wire bundles 2 are formed.

The smooth-cylindrical design of the inner periphery of the bundle forming chamber 3, inlet housing 4 and wire guide housing 5 excludes that any built-in parts have to be removed in a time-consuming manner in the event of malfunctions.

In the device 1 described above, it is possible - as with the devices of the known type - to provide the bundle forming chamber with a plurality of separating finger stages arranged at different heights. These can be cascaded into and out of the active position by special control means, in order to be able to transfer several winding packages or wire bundles 2 successively to a subsequent bundle storage plate.

The device 1 described above in detail for minimizing the height of wire coils 2 also has the advantage that it can be easily retrofitted into existing systems.

List of reference numbers

1.

contraption

2nd

Wire bundle

3rd

Bundbildekammer

4th

Inlet housing

5.

Wire guide housing

6.

Cylindrical shell section

7.

Inlet extension section

8th.

Cylindrical shell section

9.

Inlet extension section

10th

Cylindrical shell section

11.

Inlet extension section

12-12

Vertical alignment axis

13-13

Vertical alignment axis

14.

Lateral offset / eccentricity

15.

Lights diameter

16.

Lights diameter

17th

Lights diameter

18a, 18b

Crank drives

19a, 19b

Electric motor

20a, 20b

Reduction gear

21.

Trajectory

22.

Drive crank

23.

Crank arm

24th

Crank arm

25th

Crank pin

26.

Clamping device

27.

Crank pin

28

drive shaft

29.

Drive arm

Claims (12)

Method for minimizing the height of wire bundles (2) formed by successively collecting a plurality of wire windings in a bundle formation chamber (3), - in which the individual wire windings initially pass from an essentially horizontal transport direction to an inlet housing (4), - Then brought by this inlet housing (4) under deflection in a substantially vertical direction of fall - and then handed over to the Bundbildekammer (3), characterized, - That the wire windings are subjected to an additional horizontal centrifugal movement (5; 18a, 18b) during their essentially vertical falling movement. Method according to claim 1,
characterized,
that the centrifugal forces are at least partially transferred or exerted on the individual wire turns (5; 18a, 18b). Method according to one of claims 1 and 2,
characterized,
that the extent of the centrifugal movements (5; 18a, 18b) exerted on the wire windings is limited outwards and inwards (21). Device for carrying out the method according to one or more of claims 1 to 3, - In which a wire winding transport device is connected via a vertically aligned inlet housing (4) for successive wire windings, an underlying coil formation chamber (3), characterized, - That there is an additional wire guide housing (5) in a height area between the inlet housing (4) and the bundle forming chamber (3), - And that this wire guide housing (5) on a common longitudinal axis (12-12) of the inlet housing (4) and fret chamber (3) surrounding, closed horizontal path curve (21) is movably driven (18a, 18b). Device according to claim 4,
characterized,
that the course and the maximum distance (14) of the movement path curve (21) of the wire guide housing (5) relative to the common longitudinal axis (12-12) of the inlet housing (4) and the bundle forming chamber (3) from the diameter difference (16/15 ) between the inlet housing (4) and the bundle formation chamber (3). Device according to one of claims 4 and 5,
characterized,
that the drive for the wire guide housing (5) comprises at least two synchronously running crank drives (18a and 18b). Device according to one of claims 4 to 6,
characterized,
that the speed of the drive (18a, 18b) is adjustable. Device according to one of claims 4 to 7,
characterized,
that the effective crank radii of the crank mechanisms (18a, 18b) can be varied (22 to 27; Figure 7). Device according to one of claims 4 to 8,
characterized,
that each crank mechanism (18a and 18b) is equipped with its own electric motor (19a and 19b) and that all electric motors (19a and 19b) are electrically synchronized with one another. Device according to one of claims 4 to 9,
characterized,
that inlet housing (4), wire guide housing (5) and bundle forming chamber (3) each have a cylindrically limited jacket section (8, 10 and 6) as a wire winding system, to which a funnel-shaped widening inlet extension section (9, 11 and 7) is connected is. Device according to claim 8,
characterized,
that the drive crank (22) of each crank drive (18a and 18b) consists of two crank cheeks (23 and 24), that the second crank cheek (24) on the crank pin (25) of the first crank cheek (23) is at least limited angularly displaceable and lockable is held (26),
and that the second crank arm (24) is held with its crank pin (27) in rotary joint engagement with a drive arm (29) which acts fixedly on the wire guide housing (5) (FIG. 7). Device according to claims 8 and 11,
characterized,
that both crank arms (23 and 24) of the drive cranks (22) have a matching overall length and the second crank arm (24) around the crank pin (25) of the first crank arm (23) is adjustable over an angular range that exceeds an angle of 45 ° and falls below an angle of 90 °.

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