EP1502669B1 - Wire drawing apparatus and drawing block for a wire drawing apparatus - Google Patents

Description

The invention relates to a wire drawing apparatus with a ceiling, wherein above the ceiling a drawing disk drum is arranged with a cooling and further a drawing disk drum drive motor and supply and disposal lines are provided for cooling.

A pulling device equipped with draw-off drums in straight-pull version results from the prospectus cook "machines for the wire industry", 2.98. The drawing disk drums is ever assigned a gear in the underfloor area of the same. The gearbox is connected via V-belts as a transmission means, each with a laterally remote drive motor in combination. The sits adjustable mounted on a supporting wall of the wire drawing device. This limits the space for the necessary supply and disposal lines, suction pipes for drawing powder, etc., and their accessibility for maintenance considerably and, moreover, has an influence on the overall height.

The DE-PS 25 53 215 Further details of the drawing disc drum, or wire drawing device can be removed, such as a liquid-conducting internal cooling and cooling air leading external cooling.

From the US 6,116,068 In principle, it is also known, though for the drawing of copper wires in relatively small systems with relatively small pulling forces, to connect a drawing wheel drive motor without gear and coaxially with the drawing wheel drum.

At one of the GB 1 390 070 A1 known wire drawing apparatus, which discloses the preamble of claim 1, or drawing disk drum is arranged below the ceiling serving for driving unit.

The object of the invention is to improve a wire drawing device as indicated with regard to the drive / structural means. This object is achieved in a wire drawing apparatus with the features of claim 1, wherein it is geared to that the transmission-free and coaxial with the drawing disk drum connected draw-sheet drum drive motor is disposed below the ceiling, wherein at the same time below the ceiling on both sides, on the operating side and the back , Supply and disposal lines are housed.

It is therefore essential that the below the ceiling, which divides the wire drawing device of the type considered here horizontally arranged, arranged pulley drum drive motor is arranged such that both sides, on the operating side and the back of the device, supply and disposal lines are housed. This arrangement of the gearless and coaxially connected draw-plate drum drive motor provides a much more favorable overall arrangement of the wire drawing apparatus.

With regard to the implementation of the supply lines through the drawing disk drum drive motor can under certain circumstances, as will be explained below, the bushings be given by the designed as a hollow shaft rotor of the target disk drum drive motor. On the other hand, it may also be a solid shaft in this respect, which has corresponding holes or passages. A synchronous motor as referred to herein is marketable and in the required performance ranges reliable. It results in a more compact design. This creates space not only for the aforementioned lateral areas, but for the underfloor area par excellence. Also with regard to a required drawing powder suction device. The depth of the wire drawing device is smaller. Measures, such as the Wiederanschweißen cracked wires, thereby significantly facilitated.

It proves to be beneficial that the storage of the drawing disk drum is taken over by direct connection to the rotor of the synchronous motor of this. The use of the bearing of the addition part proves to be economical, and it may also be useful in the case of high-performance wire drawing devices that the bearing of the rotor of the synchronous motor is reinforced in view of the simultaneous storage of the pulley drum. Moreover, it is advantageous that the drawing disk drum by means of a flanged to the synchronous motor disk head is driven. It proves to be structurally favorable if the disk head is flanged by means of a neck bearing to the rotor of the synchronous motor. In addition, an advantageous feature is that the synchronous motor, at least partially, is flanged in radial overlap to the drawing wheel drum. A solution of even independent significance also results from the fact that the drawing disk drum is cup-shaped in cross section with a pot base facing the synchronous motor. So you get an open-top structure, but can optionally be closed by a revision cover. If necessary, the inspection cover which unfolds a practical protection can be removed, so that functional parts accommodated in the pot space can be easily accessed quickly. For example. Wear parts can be exchanged immediately. The bottom of the pot can then fulfill an additional function by at the same time serving to transmit the drive torque from the synchronous motor to the drawing wheel drum. He takes over flange function. The bottom of the pot can at the same time be carriers of parts of a cooling device. The preferably has a closed coolant circuit. The connection to a supply source can go through the rotor when the rotor of the synchronous motor is designed as a hollow shaft. Accordingly, supply lines of the cooling device can be guided through the axial center cavity of the hollow shaft. A particularly space-saving solution is achieved when the synchronous motor extends into the interior of the cup-like drawing wheel drum. Such a partially drawn into the drawing wheel drum engine body can take over the function of a central Aussteifkernes for the relatively thin-walled drawing disk drum.

Fig. 1

die weitestgehend schematisch dargestellte Ziehscheibentrommel im Vertikalschnitt mit unterseitig angedocktem Synchronmotor, gemäß Grundversion,

Fig. 2

eine der Fig. 1 entsprechende Darstellung unter Anwendung eines Halslagers, eine erste Variante verkörpernd,

Fig. 3

in Darstellung wie Fig. 2 eine zweite Variante, wobei der Synchronmotor teilweise in den Topfraum der Ziehscheibentrommel eingezogen eingebaut ist,

Fig. 4

den elektrischen Synchronmotor in isolierter, perspektivischer Wiedergabe.

The object of the invention is explained in more detail below with reference to an exemplary embodiment illustrated in the drawing. It shows:

Fig. 1

the largely schematically illustrated drawing-disk drum in vertical section with the synchronous motor docked on the underside, according to the basic version,

Fig. 2

one of the Fig. 1 corresponding representation using a neck bearing, embodying a first variant,

Fig. 3

in representation like Fig. 2 a second variant, wherein the synchronous motor is incorporated incorporated in part in the pot chamber of the drawing wheel drum,

Fig. 4

the electric synchronous motor in isolated, perspective reproduction.

The shown drawing disk drum 1 is arranged in a perforation region 2 of a wire drawing apparatus 3.

The opening area 2 is located in a ceiling 4 of a bed 5 of the wire drawing device 3. The has several drawing stations.

The connecting part is a base support 6. The has a peripheral flange 7. The latter engages over the upper-side hole edge of the opening region 2 and is fixed there.

The fastening point bears the reference numeral 8. It may be a screw ring.

The standing above the ceiling 4 drawing disk drum 1 is arranged by a arranged below the ceiling 4 drawing disk drum drive motor. 9 infinitely rotated or braked. The rotation takes place around a geometric axis xx. The axis xx can be vertically aligned. Preferably there is a tendency lying in the direction of wire draw. In addition, a frontal tilt can be granted. Frontal means a control page 10 of the system.

The drawing-disk drum drive motor 9 is designed as a synchronous electric motor. It is gear-free and connected to the drawing-disk drum 1. This is done according to the basic version in the area of the ceiling 4 and the base support 6. This attachment point is denoted by 11. It connects the rotating part of the synchronous motor, the rotor 12 so, with the cup-shaped drawing disk drum 1. The latter closes the mounting side with a pot bottom 13. On its underside extends an annular disk-shaped rotor flange 14, which passes through an opening 15 of the base support 6 free.

Between the pot bottom 13 and the rotor flange 14, the aforementioned attachment point 11 is formed, for example. Realized as a screw ring.

The stator 16 of the electric synchronous motor is in firm connection with the base support 6. The relevant attachment point carries the reference numeral 17 and in turn consists of a screw ring.

Visible, the storage of the drawing disk drum 1 is taken over by direct connection to the rotor 12 of the synchronous motor of this. The bearing means of the synchronous motor are generally designed to be correspondingly powerful. If the standard equipment is not sufficient, it makes sense to reinforce the mounting of the rotor 12 of the synchronous motor in view of the simultaneous storage of the drawing disk drum 1. It works advantageous that the bottom of the pot 13 at the same time, and so on the shortest route, the transmission of the drive torque from the synchronous motor on the drawing wheel drum 1 is used. That already results in mutual stabilization.

The bottom of the pot 13 merges peripherally into the substantially cylindrical pot wall 18. This starts at a peripheral annular step 19 of the pot bottom 13. The relevant end is formed thickened and is otherwise included by a freestanding ring collar 20 of the base support 6. Here is a foot near winding point 21 for the wire. It is a rotationally symmetrical cone flank, proportionately formed by the front end of the annular collar 20 and said, radially outward Verdikkung. Here, a wire spiral builds up from below, going up to an upper unwinding point on the drawing disk drum 1.

The synchronous motor is flanged, at least in partial radial overlap to the drawing wheel drum 1. The cross section of the synchronous motor is compared to the pot-shaped cross-section of the drawing disk drum 1 realiter slightly back. Even that gives sufficient docking area.

The general use of an electric synchronous motor, its compact allocation to the drawing wheel drum 1 create in the underfloor area and on both sides, ie on the operating side 10 as the back 22, space 23 for the various supply and disposal lines for the cooling provisions, as well as for a suction pipe for the resulting drawing powder. Incidentally, the height can be reduced.

The rear side 22 is bounded by a wall 24 of the wire drawing device 3.

The drawing disk drum 1 has a liquid-carrying internal cooling, referred to as a cooling device 25. It consists of a chambered annular gap 26, which is supplied via an inlet 27 and a drain 28.

The means isolating the annular gap 26 towards the interior of the pot 29 are common and will not be discussed further here, only that the cooling device 25 has a closed coolant circuit. On the other hand, in the precursor mentioned, the technique is practiced such that the cooling device 25, with respect to the annular gap, leaves a gap reduced in cross-section for the coolant to drain off and catch in a channel 30. In the first variant (FIG. Fig. 2 ) and can also be used for the second variant ( Fig. 3 ) be provided.

Coming back to the basic version remains to be noted that the bottom of the pot 13 carrier in any case of parts of the cooling device 25. The bottom side are formed as centrally located rotary guides 31, 32, subsequently standing to the mentioned wall-side inlet 27 and drain 28. The latter are provided according to the number of annular gaps 26 and chambers connection moderately and co-rotating. The supply happens from the underfloor area. Please refer to the connection 33 there. From here, supply lines go to the cooling device 25, extending through the axis-central cavity 34 of the designed as a hollow shaft rotor 12. The corresponding hollow shaft motor is clear Fig. 4 out.

The upwardly opening pot interior 29 of the drawing disk drum 1 offers a convenient for assembly purposes and for maintenance access. The opening can be closed by a revision cover 35.

Now to the first variant ( Fig. 2 ): This is in principle the same structure in terms of motorization. The reference numbers are, as far as necessary for understanding, transferred analogously, this in part without textual repetition.

However, a structural difference discernible in the cited figure results from the fact that the drawing disk drum 1 is driven by means of a disk head 36 flanged to the synchronous motor, ie from above. The latter is connected via a central neck bearing 37 with the rotor 12 of the synchronous motor in combination. The rotor flange 14 of the rotor 12 continues centrally in the interior of the pot 29 as a shaft piece 38 in the direction of the disk head 36 continues. In the opposite direction, a central connecting piece 39 discharges. The sits cone-centered and screwed on the shaft piece 38 firmly. The connection of the disk head 36 to the pot wall 18 of the drawing disk drum 1 goes through an attachment point 40. These can also be realized as a screw ring.

The pot-internal conclusion of the annular gap 26 of the cooling device 25 here is an inner, upwardly directed annular wall 41 of the base support 6. The latter goes outward into a groove 30 with forming indentation 42, at which the lower end of the basically cylindrical pot wall 18th the drawing disk drum 1 rotates.

The second variant according to Fig. 3 differs from the aforementioned object structurally in that the synchronous motor extends into the interior of the pot 29 of the drawing wheel drum 1. Here, about half the vertical height of the pot interior 29 is used. The corresponding overlap to the upwardly extending annular wall 41 allows the cross-section adapted contour of the synchronous motor to act as a central support core.

The annular wall 41 sets in the in Fig. 2 shown way upwards away. A Einsteckbegrenzung is achieved by an inwardly directed horizontal annular shoulder 43, to which the attachment point 17 is located to the stator 16 out. The rotor connection is as to Fig. 2 portrayed.

The wire tension is self-regulating. This is possible via a speed control. Corresponding tap can take place on an arc zone of the wire acting as the encoder, as it results at the near-end unwinding location of the drawing wheel drum 1, and be converted into control pulses for the synchronous motor. Thus, the thinner by wire wire stationwise increasing speeds of the drums are exactly brought about, d. H. it adjusts the appropriate pulley speed.

Claims (14)

1. Wire-drawing apparatus comprising a surface (4), a capstan drum (1) that comprises a cooling system being arranged above the surface (4) and a capstan drum drive motor (9) and supply and discharge lines for the cooling system being further provided, characterised in that the capstan drum drive motor (9), which is coaxially connected to the capstan drum (1) in a gear-free manner, is arranged below the surface (4), supply and discharge lines also being located below the surface (4) on either side, i.e. on the operating side and on the rear side.
2. Wire-drawing apparatus (3) according to claim 1, characterised in that a cooling device is provided with the supply lines relating to the inlet and outlet, and in that the supply lines are guided through the capstan drum drive motor (9), which is designed as a synchronous electric motor.
3. Wire-drawing apparatus (3) according to either of the preceding claims, characterised in that the capstan drum drive motor (9) is arranged below the capstan drum (1).
4. Wire-drawing apparatus (3) according to either claim 2 or claim 3, characterised in that a cooling device is provided with the supply lines relating to the inlet and outlet, and in that the supply lines are guided through the capstan drum drive motor (9).
5. Wire-drawing apparatus (3) according to claim 4, characterised in that the mounting of the rotor (12) of the synchronous motor is reinforced in view of the simultaneous mounting of the capstan drum (1).
6. Wire-drawing apparatus (3) according to any of claims 2 to 5, characterised in that the capstan drum (1) is driven by means of a wheel head (36) that is flange-mounted on the synchronous motor.
7. Wire-drawing apparatus (3) according to claim 6, characterised in that the wheel head (36) is flange-mounted on the rotor (12) of the synchronous motor by means of a collar bearing (37).
8. Wire-drawing apparatus (3) according to any of claims 2 to 7, characterised in that the synchronous motor is flange-mounded to the capstan drum (1) so as to cover said capstan drum radially at least in part.
9. Wire-drawing apparatus (3) according to any of claims 2 to 8, characterised in that the capstan drum (1) has a pot-shaped cross section and a pot base (13) that faces the synchronous motor.
10. Wire-drawing apparatus (3) according to claim 9, characterised in that the pot base (13) is also used to transmit the driving torque from the synchronous motor to the capstan drum (1).
11. Wire-drawing apparatus (3) according to either claim 9 or claim 10, characterised in that the pot base (13) supports at least parts of a cooling apparatus (25).
12. Wire-drawing apparatus (3) according to any of claims 2 to 11, characterised in that the cooling apparatus (25) comprises a closed coolant circuit.
13. Wire-drawing apparatus (3) according to any of claims 2 to 12, characterised in that the rotor (12) of the synchronous motor is designed as a hollow shaft.
14. Wire-drawing apparatus (3) according to claim 13, characterised in that the supply lines of the cooling apparatus (25) are guided through the axially central hollow space (34) of the hollow shaft, and/or in that the synchronous motor extends as far as the interior (29) of the pot-shaped capstan drum (1).

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