EP0481029A1

EP0481029A1 - Device for winding up material webs.

Info

Publication number: EP0481029A1
Application number: EP91907124A
Authority: EP
Inventors: Reinhard Hehner
Original assignee: Jagenberg AG
Current assignee: Jagenberg AG
Priority date: 1990-05-07
Filing date: 1991-03-28
Publication date: 1992-04-22
Anticipated expiration: 2011-03-28
Also published as: FI107602B; DE59106521D1; FI920040A0; ES2080310T3; JP2929505B2; EP0481029B1; ATE128095T1; US5308006A; CA2064076C; CA2064076A1; DE4014512A1; DE4014512C2; WO1991017106A1; JPH05500649A

Abstract

PCT No. PCT/EP91/00604 Sec. 371 Date Jan. 22, 1992 Sec. 102(e) Date Jan. 22, 1992 PCT Filed Mar. 28, 1991 PCT Pub. No. WO91/17106 PCT Pub. Date Nov. 14, 1991.A winding device includes a support roller receiving strips of a material web to be wound up on two coil rollers mounted on respective winding supports flanking the support roller and movable parallel to an axis of the support roller along with respective electric motors actuating respective drive heads and getting cooled by respective flexible carriers movable along with the winding supports.

Description

DESCRIPTION

Device for winding material webs

Technical field

The invention relates to a device for winding material webs, in particular paper or cardboard webs, onto winding cores according to the preamble of patent claim 1.

State of the art

From the article "Roll cutting and rolling machines for paper equipment, part 3" in COATING 1/89, pages 8-12, a generic winding device is known which has a driven support roller and winding stations arranged on both sides of the support roller. Each winding station consists of two swiveling support arms, each of which is equipped with a hydraulic winding drive. The two hydraulic motors of a winding station are connected in parallel and are fed by a hydraulic variable pump.

Although hydraulic drives are relatively small in size at high outputs, it has been shown that their use on winding machines has disadvantages:

Large hydraulic systems are required outside the winding machine, and the adjustment of the winding stations when changing formats creates problems. Due to the high pressure required (e.g. 300 bar) in the supply hoses these are very stiff and are therefore difficult to bring into the required new position when changing the format. In addition, the control required for hydraulic drives is very complex.

Presentation of the invention

The invention has for its object to provide a generic device in which the winding stations can be easily adjusted to different formats, especially very narrow formats.

This object is achieved with the features of patent claim 1.

Liquid-cooled electric motors provide the required acceleration and braking performance with a relatively small size. The size of the motor is important because the support elements (e.g. winding frames) must be kept as close together as possible with the motor for small format widths. Although the liquid-cooled motors also require supply hoses for the coolant, the pressure required in the hoses is significantly lower than in the supply hoses of hydraulic drives. It has been shown that a coolant pressure of 0.1 bar is sufficient. Due to the low pressure, the feed hoses are very flexible and can therefore easily adjust their position when changing formats.

The subclaims contain preferred, since particularly advantageous, embodiments of the invention. In particular, the use of a three-phase asynchronous motor according to claim 3 enables a small motor volume with high output, since in these motors the heat is generated mainly in the stator winding and the control via a frequency converter is the least complex (claim 4) Brief description of the drawing

The drawing serves to explain the invention with reference to an embodiment shown in simplified form.

Fig. 1 shows a side view of a backup roll winding machine according to the invention.

Ways of Carrying Out the Invention

The web of material 1 drawn off from a supply roll (not shown), in the present example a paper web, is guided by guide rollers 2-7 from above to a driven support roller 8. On both sides of the support roller 8 there are winding stations 9, 10, each consisting of two support elements which can be moved parallel to the support roller axis. In the present example, the support elements are winding blocks 11, 12, and the use of pivotable support arms is also possible. Each winding block 11, 12 carries on its upper side a slide 13, 14 which can be moved radially to the support roller 8 and on which a guide head 15, 16 is fastened with its rotary drive 17, 18. The guide heads 15, 16 are retractable for holding and driving the winding roll 19, 20 in its winding tubes.

Three-phase asynchronous motors are used as rotary drives 17, 18, the stator winding of which is cooled with water. Cooling with oil is also possible. For this purpose, the housings of the motors 17, 18 have circumferential cooling channels for the cooling liquid. So that the winding stands 11, 12 can be moved as close as possible to one another for narrow formats, the motors 17, 18 are installed in the longitudinal direction, that is to say in the web running direction, and are connected to the guide heads 15, 16 via an angular gear. The gears are flanged to the motors 17, 18, each flange also having cooling channels. In the flange area, cooling can be increased to also dissipate heat generated in the transmission. A regulating or control device, not shown, regulates or controls the winding hardness of the winding rolls 19, 20 via the torques of the motors 17, 18. In the three-phase asynchronous motors used in the exemplary embodiment, the torque regulation or control is carried out via a frequency converter.

Instead of three-phase asynchronous motors, direct current or servo motors can also be used, the stator winding of which is cooled with water or oil. DC motors, however, require more complex maintenance due to the wear of carbon brushes, and a complex control concept is required for servomotors. The cooling channels of the motors 17, 18 are connected to supply hoses for coolant, which are supplied by a common cooling system outside the winding machine. The supply hoses on each side of the winding machine are combined into tows, due to the low pressure in the hoses (0.1 bar), the hoses are very flexible and can therefore be arranged in a space-saving manner and easily moved with a format adjustment. Furthermore, the risk of leaks is minimal at the low pressure.

A longitudinal cutting device 21 is arranged above the support roller 8 in the area between the guide rollers 6 and 7 and consists of a plurality of pairs of circular knives 21.1, 21.2 which can be adjusted transversely to the running direction to different format widths of the individual webs to be cut. Above the support roller 8, a roller 22 is supported on the side pivot levers 23 against the support roller 8 in the area wrapped by the webs 1. The roller 22 serves, together with the support roller 8, to interrupt the tension of the webs 1 in front of the winding stations 9, 10. The tension behind the nip formed by the roller 22 and the support roller 8 is determined by the torques of the motors 17, 18 by means of a frequency converter regulated to the value required for the desired winding hardness. The tension for each winding roll 19, 20 can be regulated individually via the motors 17, 18, so that each winding station 9, 10 can be operated as an independent winding machine.

The winding machine is preferably used for producing rolls with a large diameter (for example 1.5 m) from HWC (High Weight Coated) papers. These papers are sensitive to marking so that the line force on the support roller 8 should be kept low. Since the tension of the web 1 required for winding is applied by the drives 17, 18, the line force with which the winding rollers 19, 20 are pressed against the support roller 8 can be kept at values less than 30 N / m during winding. The line force should, however, be at least 10 N / m, so that no air is wrapped in and 1 round winding rolls are wound even in the event of profile fluctuations in the web.

Claims

PATENT CLAIMS

1. .

Device for winding material webs (1), in particular paper or cardboard webs, on winding cores with a longitudinal cutting device (21) for dividing the

Material web (1) arranged in single webs and with a driven support roller (8) on both sides

Winding stations (9, 10), each consisting of two support elements that can be moved parallel to the support roller axis

(Winding blocks 11, 12), on which an insertable into the winding sleeves and movable in the direction of the support roller (8)

Guide head (15, 16) is fastened with its rotary drive (17, 18), g e k e n z e i c h n e t d u r c h liquid-cooled electric motors as rotary drives (17, 18) for the guide heads (15, 16).

Second

Apparatus according to claim 1, a control system which regulates or controls the winding hardness of the winding rolls (19, 20) via the torques of the electric motors.

3rd

Apparatus according to claim 1 or 2, gekennzeich¬ net by a rotary tromasynchronous motor, the stator winding is cooled with water or oil.

4th

Apparatus according to claim 3, d a d u r c h g e k e n n¬ z e i c h n e t that the three-phase asynchronous motor is regulated or controlled via a frequency converter.

5th

Apparatus according to claim 1 or 2, g e k e n n z e i c h¬ n e t d u r c h a DC or servo motor, the stator winding is cooled with water or oil.