DE1072216B - - Google Patents

Description

GERMAN

Straight-drawing machines are understood to be slideless multiple wire drawing machines in which the wire length changes from drawing disk to drawing disk, caused by various cross-sectional reductions in the drawing nozzle or natural opening of the drawing nozzles due to wear, compensated for by means of stepless speed regulation of the drawing disks will. The wire runs in one plane from drawing pulley to drawing pulley either over pendulum rollers or directly.

Compared to sliding multiple wire drawing machines with accumulation of the wire on the drawing drums and wire transfer over the head of the drawing drums, the straight-line drawing machine has the advantage of simple wire guide, which has a beneficial effect at high drawing speeds. Another The advantage is the production of twist-free wire.

Despite the considerable advantages of the straight pull is in the wire drawing mills of European countries this type of drawing is seldom found. The reason lies in the high acquisition costs for straight-line drawing machines, caused by the stepless regulation of high drive powers of over 100 kW and the mostly required direct current generation system.

The usual wire drawing machines with individual drive of the drawing disks, be it by DC motors, by hydraulic gears with three-phase motors or similar and speed control of the drawing disks dancer rollers have the disadvantage that a control process triggered on a loop develops like a chain reaction affects the upstream and downstream drums. With each of these drawing pulleys control processes that run one after the other are triggered that affect the entire machine comes into restlessness.

Other known straight-pulling machines have a central drive from which, for example, a Main shaft continuously variable gears of the drawing pulleys are driven. The change in speed As already explained above, a pulling disk acts like a chain reaction on the upstream or downstream one Pulling disk off. The fixed input speeds of the infinitely variable speed specified by the main shaft Gearboxes result in a relatively narrow control range, which is often the cause of wire breaks.

. In particular, in both of the above-mentioned types of machines, the drawing in of the wire is associated with great difficulties. These consist in the control of the wire tension, which is constantly changing during the pulling in, which is determined by two influences. Once with the coordination of the speed on the drawing pulley, the wire tension and thus also the movement of the associated
skidless multi-filament wire drawing machine

Applicant:

VEB wire drawing machine factory Grüna,
Grüna (Kr.Karl-Marx-Stadt),
Mittelbadier Str. 12

Walter Hösel, Auerswalde (district Karl-Marx-Stadt),
has been named as the inventor

Neten rule role influenced. On the other hand, the wire tension is also due to the variable Speed of the previous drawing pulley loaded. This speed change takes place through the to this The associated control roller, which oscillates in constant movements around its central position, and the adjustment of the speed the drawing wheel is carried out via a continuously variable transmission.

The regulation of the speeds of the two drawing disks can work together in such a way that the wire, which is guided over the regulating roller, either relieved too quickly or is also strongly tensioned, d. H., the regulating roll comes into abutment to the rear and wire casting occurs or the regulating roll closes forward quickly, which leads to wire breakage, if not the limit switch of the whole machine beforehand turns off. Due to the small pendulum distance available for the regulating roller, the high wire speeds as well as the inertia of the variators are these unpleasant effects on machines unavoidable with a parallel gearbox. Except for the influences that occur when drawing in Gearboxes connected in parallel also have a very detrimental effect on the drawing process. When rising a drawing die, e.g. B. by nätürliqhen wear, must with the previous target discs Speed can be increased. However, since every gearbox receives the same constant drive speed, each must Gear can be adjusted. This is done by tensioning the wire over the regulating rollers.

The opening of a drawing die would therefore have all of the rule roles that existed before due to the twofold influence move into further additional mobility. The additional and actual movements overlap the rule roles such that an addition

909 707/121

Claims (6)

ι υ / ζ zio occurs, as already described, wire breaks or slips. There are also other known wire drawing machines that do not belong to the class of non-sliding straight-line drawing machines. One of these machines, which works by collecting the wire and diverting it overhead, is provided with a gearbox that is used to increase or decrease the speed of the pulling drums. The purpose of this gear is to readjust the accumulation of the wire on the respective drawing drum. As a result of this, as in the case of the invention, the speeds of the drums located in front of them in the pulling direction are also changed due to the series connection of the drums. This change depends on the amount of the accumulated wire, but not - as here - on the size of the wire tension. The object of the invention is to restrict a control process triggered at a specific point on the machine essentially to this point and not necessarily to trigger secondary control processes on other drums. It is also a matter of increasing the control range of the machine without additional gear effort. This is essentially achieved in that the continuously variable gears of the drawing disks are connected one behind the other so that the output speed of one is the input speed of the other, and that the drive of an adjustable drawing disk is derived from the output side of each transmission. If there is now a control process on the machine in which, for example, the incoming branch of a loop is increased by increasing the speed of the upstream drawing pulley, then the basic speeds of all the drawing pulleys upstream of the control point increase at the same time while maintaining their specified speed ratio, without thereby affecting the control range this continuously variable transmission is used. An exemplary embodiment is shown in the drawing to explain the concept of the invention. The illustration shows the transmission diagram of a machine, the drive of which is initiated between the third and fourth drawing pulley. A gearbox 2 is connected to a three-phase motor 1. A drive shaft 3 of the same ends between a third and fourth pulley in a bevel gear 4 of a transmission. An associated bevel gear 5 is fastened on a main shaft 13. A main shaft 11, 12, 13, 14, 15 is arranged after each disk 6, 7, 8, 9, 10, so that the first main shaft 11 is located behind the first drawing disk 6. Since four pulling disks 6, 7, 8, 9 and one finishing disk 10 were chosen, there are five main shafts 11, 12, 13, 14, 15. At the two ends of each main shaft 11, 12, 13, 14, 15 there is one Pulley 16 continuously variable transmission 17 is provided. The first, 11, and fifth main shafts 15 only have a pulley 16 at one end. The adjustment of the continuously variable gears 17 connecting the main shafts takes place by means of small electric motors 18 Drive shafts 21 of the drawing or finishing disks connected. The translations of the gear pairs 19, 20 are designed according to the underlying normal drawing sequence of the machine. A transmission ratio of the continuously variable transmission 17 of 1: 1 is assumed. The normal drawing sequence of the machine is understood to mean the normal cross-sectional reduction of the wire 22 from drawing nozzle to drawing nozzle 23. In addition to each of the drawing disks, compensating rollers 25 are rotatably attached to a pivotable, one-armed lever 24. The one-armed levers 24 are always pivoted away from the pulling disks 6, 7, 8, 9 by springs 26 or conventional hydraulic units. Inadmissible movements of the compensating rollers 25 are transmitted electrically to the small electric motors 18 of the adjustable gears 17. A wire 22 runs in the usual way through a drawing nozzle 23 onto the first drawing disk 6 and is circulated on it with six to seven turns. Then it runs on the rotatable compensating roller 25 via a diverting roller 27 through the second drawing nozzle 23 to the second drawing disk 7, also in six to seven turns to the compensating roller and so on up to the finished disk 10, where it is wound into wire ties. The compensating rollers 25 pivotable on a one-armed lever 24 serve to adjust the revolutions of the first to fourth drawing disks 6,7,8,9 and the finishing disk 10 so that they correspond to the changes in wire length from drawing nozzle to drawing nozzle. For example, if the withdrawal from the first, 6, to the second drawing pulley 7 is faster, for example due to natural wear on the second drawing nozzle 23, the tension of the wire 22, which runs over the compensating roller 25, increases, so that it is pivoted towards the drawing disk 6. As a result, a contact (not shown) is switched on, which adjusts the continuously variable transmission 17 between the first, 11, and second main shaft 12 by means of the small electric motor 18 so that the first drawing pulley 6 runs a little faster, corresponding to the change in cross section in the second drawing nozzle 23 When one of the small electric motors 18 is controlled, the speed of the corresponding dial is regulated, and the withdrawal of the remaining disks remains unaffected. The series connection of the continuously variable gears only has an effect on the wire tension. The coordination of the speed on the drawing pulley 6 does not affect the adjustment of the continuously variable transmission 17 of the drawing pulley 7 located downstream. If, however, the vote takes place on the pulling disk 8, z. B. if the wire tension is too great, the control element 25 of the pulling disk 7 is moved towards this. This results in an adjustment of the continuously variable transmission 17, which increases the speed of the drawing pulley 7. As a result of the series connection, the speed of the drawing pulley 6 is increased by the same amount as the drawing pulley 7 without adjusting the associated control gear 17. Accordingly, there is only one influence on the wire tension between the drawing disk 7 and the following drawing nozzle 23, namely the change in speed of the drawing disk 7. Furthermore, the possibility of providing two drive units, which are connected by an electric shaft, is also included. The drive then takes place, for example, in such a way that the power of one drive unit is introduced into the fourth main shaft 14 and the other into the second main shaft 12. The third main shaft 13 must be interrupted. It will be advantageous to use such a drive arrangement only when the installed power is very high. Patent claims: 1. Slideless multiple wire drawing machine working in a straight line with the individual drawing disk acting and adjustable by the wire tension, stepless gears, as well as with a guide pulley driven at a fixed speed, characterized in that the stepless variable gears are connected in series, so that the output speed of one of the input speed of the other, and that on the output side of each gear, the drive of a controllable drawing pulley is derived. 2. Multiple wire drawing machine according to claim 1, in which to regulate the loop size continuously variable transmission and in which the directions of the wire run and the power flow match, characterized in that the size of the running branch of the loop can be influenced by changing the speed of the drawing disk following in the direction of the power flow is. 3. Multiple wire drawing machine according to claim 1, wherein the ao to regulate the loop size continuously variable transmission and in which the directions of the wire run and the power flow are opposite, characterized in that the size of the tapering branch of the Loop by changing the speed of the pulling disc following in the direction of the power flow can be influenced. Considered publications: German Patent Nos. 936 861, 35 287; German patent application Sch3864 Ib / 70a
(announced 6/11/1953); British Patent No. 186949; British Patent No. 27485 of 1908; French Patent No. 491,745; U.S. Patent Nos. 1 951 722, 1 905 803,
1534998, 1518 714; "Draht" magazine, 1956, No. 3, p. 17; No. 4, p. 29; No. 5, p. 10; No. 6, p. 16. 1 sheet of drawings O 909 707/121 12:59