DE1084111B - Device for stretch forging - Google Patents

Description

Device for stretch forging There are devices for stretch forging and other deformation of rod-shaped goods made of malleable, mainly metallic Known material in which the same cross-sectional area of the stretched material acting, symmetrically movable in opposite directions to one another by means of crank or eccentric drives Vibrating jaws are provided during the effective part of their approach moving the exit side of the device, thereby removing the material to be stretched Push forward, then swing back on the other side of the entrance. Among these devices, those are also known whose vibrating jaws in each Deformation stroke with parts of their each lying in the same cross-sectional plane Work surfaces a closed, moving along their length and thereby increasing limit narrowing caliber opening.

The known devices of this type are suitable - provided their tool jaws Form a closed caliber - only for the production of workpieces with a round Cross-section, whereby the workpiece is also continuously rotated during the deformation must, -da moving in opposite directions to each other in the same plane of oscillation Tools only exerted an unequal deformation pressure over the circumference of the workpiece can be, and if the workpiece is not rotated in the course of the plane in that touch the edges of the working surfaces of the opposing tools, would form an undesirable ridge.

About the formation of a pronounced, harmful burr on round workpieces to avoid, but above all to also right-edged workpieces with the help of devices To be able to generate the aforementioned type is proposed according to the invention, at least two synchronously driven pairs of oscillating jaws moving in opposite directions evenly distributed around the tool axis.

Such evenly distributed around the tool axis, i.e. intersecting Pairs of vibrating jaws moving in opposite directions result in an over the Perimeter of the workpiece much more uniform deformation pressure, which is a considerable smaller width of the workpiece and accordingly also a considerably smaller one Results in burr formation.

In addition, two planes that cross each other at right angles allow working Pairs of oscillating jaws with work surfaces that are straight in cross-section, the production of right-edged workpieces, e.g. B. of square or flat iron.

There are also the deformation of workpieces from bildsämem Material serving forging devices known that several evenly around the Have workpiece axis distributed pairs of mutually opposite moving tools.

These devices, which are usually designed as hammer mills, are used however, the tools in contrast to devices that work with vibrating jaws moved in a straight line to the workpiece, so that this over the entire length of the tools is deformed at the same time. In addition, there is not only a considerably greater expenditure of work energy required, but as a result of the resulting strong expansion of the workpiece between two opposing tools is created between the work surfaces Adjacent tools have a differently pronounced ridge. These forging machines although they have been known for a long time, have not given the professional world any suggestion, even with stretching devices working with oscillating jaws several in different Levels to use vibrating jaw pairs acting on the workpiece at the same time.

If, according to a further feature of the invention, of two in itself perpendicular two pairs of vibrating jaws swing the working surfaces of one of the two directions Swing jaw pair on the work surfaces of the other swing jaw pair Rolling off bounding surfaces, workpieces with a rectangular cross-section result with sharp, frying-free edges and smooth surfaces that do not require any rework.

In the drawings, in Fig. 1 and 2, a known device operating with two oppositely driven oscillating jaws is shown schematically in two working positions, with the aid of which a workpiece can be stretched by tools acting on two opposing workpiece surfaces. On both sides against the workpiece 1 to be deformed, here to be flat-stretched, are the oscillating jaws 2, 2 ', the ends of which are located on the pull-in side are each supported directly on an eccentric 3, 3' and the other ends via push rods 6 articulated on bolts 5, 5 ' , .6 'moved by the eccentrics 4, 4' -, verden. The eccentrics 3, 4 and 3, 4 'are offset from one another about their axes in such a way that the eccentrics 3, 3' located on the pull-in sleeve lead the other, 4, 4 'by 90 °. In the eccentric position according to Fig. 1, the vibrating jaws 2, 2 'have grasped the workpiece with their work surface parts located between the eccentrics 3, 3' under deformation pressure and pushed some material in front of them against the discharge end. The entire workpiece has also been pulled a little further between the jaws 2, 2 '. In the further course of the eccentric rotation, the jaws 2, 2 'settle first between the eccentrics 3, 3' and then between the bolts 5, 5 'from the workpiece 1 and, after passing through the eccentric position shown in Fig. 2, capture new material parts in the between the eccentrics 3, 3 'area.

It has been shown that devices of the type described here are extremely effective and strong deformations in a tool set and at Allow a single pass with the least amount of manpower.

An embodiment of the forming the subject of the invention Device with two mutually perpendicular planes in opposite directions vibrating tool pairs are shown in Fig. 3 to B.

The device is particularly suitable for deforming rod-shaped Work pieces of any kind, not excluding wires and pipes. The swing jaws are designed so that their working surfaces are each in a cross-sectional plane complement each other to form a closed caliber, which during each working stroke of the intake side to the discharge side migrates over the length of the work surfaces. More than two pairs of vibrating jaws - only in exceptional cases, namely for deforming of workpieces with tangled cross-sections. Just like of the device with only one pair of vibrating jaws, all eccentrics are also here driven at the same speed, but the eccentrics can be different from each other Eccentricity as well as leading or lagging one another. It is only important that all movements are coordinated in such a way that there is an even consumption of material and result in constant workpiece deformation. Both will almost always be the case be when all opposing work surface parts at all times though perform opposite but otherwise identical movements and if the eccentrics on the Feed side lead those on the output side, advantageously by about 45 °.

As important as it is, with opposing vibrating jaws to pay attention to the uniformity and regularity of the movements, it is not necessary that the type and extent of the deformation work performed by the remaining pairs of jaws are always the same. Rather, it is quite possible to use a rod of z. B. square cross-section thereby to a reduced rectangular cross-section give that there is a stronger deformation pressure on two opposite sides exercises than on the other. The degree of deformation can be changed by changing the course of the work surface on the oscillating jaws (greater or lesser curvature) as well as by changing the eccentricity, to some extent also by changing affect the eccentric advance.

Figures 3, 4, 5 and 6 illustrate the subject matter of the invention forming device in principle. The evenly around the longitudinal axis of the workpiece 1 distributed pairs of vibrating jaws 2, 2 'and 12, 12' are here at 90 ° to each other offset around the @ # workpiece axis and form with those facing the workpiece l Work surfaces in one cross-sectional plane each have a closed caliber of flat rectangular shape. The oscillating jaws 2, 2 'are on the intake side (Fig. 3, 4) mounted on the eccentrics 3, 3 ', on the discharge side (Fig. 2, 4) via push rods 6 suspended from the eccentrics 4, 4 '. Belong to the second pair of oscillating jaws 12, 12 ' the bearing eccentrics 13, 13 ', the push rods 16, 16' and the control eccentrics 14, 14 '. The 'opposing surface lines 9, 9' of the jaws 2, 2 'and the lines 19, 19 'of the jaws 12, 12' lead in operation in a mirror-inverted manner equal movements.

The not easy, precise coordination of the movement processes on the otherwise simple and clear device requires care in the construction of the Drives. Although single drive of all eccentrics is quite conceivable and also practical is possible, e.g. B. by synchronous motors or synchronous motors of others Art, it is recommended to use the eccentrics belonging to an oscillating jaw to drive only one and to let the other take away from the driven one. Through this it is not only guaranteed that the selected lead or lag of the eccentric in any case is maintained, but also the number of drives on the Half decreased. For reasons of space and in the interest of unhindered material tracking It is recommended to drive the eccentrics on the output side and the eccentrics to be taken away by the former on the intake side. This entrainment can, for. B. over Spur gears or coupling rods are made. The best guarantee of the required Synchronization and the maintenance of the sequence of movements set once for all Parts, however, offers the use of a comb mill, which is from a single Motor is driven and in which the driving force of the motor on the individual to be driven shafts is distributed.

A cross-section through a stretch forging device with drive Fig. 6 shows schematically about a pin rolling stand, namely the one shown here Section through the eccentric shafts 4, 4 'located on the output side; 14.14 '. The oscillating jaws 2, 2 'and 12, 12' are articulated by bolts 5, 5 'and 15, 15', respectively connected to the push rods 6, 6 'and 16, 16', which in turn have the eccentric 4, 4 'and 14, 14' are mounted in bearing blocks 35. The drive of the four eccentric shafts takes place from, the motor 23, which via a coupling 22 initially the pin rolling stand 21 drives. From there, the driving force is distributed to the intermediate shafts 39, the partly directly, partly via bevel gears 25, 25 'with the eccentrics 4, 4'; 14, 14 'are connected. Couplings 20 are used to absorb any bending forces that may occur and the prevention of breakage in the event of any inhibitions. In the bearing blocks 35 are In addition to the eccentrics 4, 4 'and 14, 14' shown, the shafts of the associated Eccentric 3, 3 'or 13, 13' on the intake side, mounted, the, how in Fig. 5 for. the pair of jaws 12, 12 'indicated, with the driven eccentrics 14, 14 'via the spur gears 34, 34', intermediate gears 44, 44 'and the spur gears 24, 24 'connected.

The bearing blocks 35 for the eccentrics of both pairs of jaws are common held in an annular vibrating frame 36, in such a way that they radially against the workpiece can be adjusted so that workpieces within a framework different cross-sections machined and eccentric shafts of different eccentricity can be used.

The bearing blocks 35 can also be attached to slide guides as shown in FIG. 7 Attach 18, which is carried by a common base plate 17 so as to be radially displaceable will. In each case two opposite slide guides 18 are expediently through Armature 18a braced, which serve to better absorb the working pressure. the Side view in Fig. 7 above also shows for the pair of jaws 2, 2 '(analogous to Fig. 5) the transmission of the power drive from the directly driven eccentrics 4, 4 'on the eccentrics 3, 3' on the feed side via the ones on the eccentric shafts seated spur gears 24, 24 'or 34, 34' via the intermediate gears 44, 44 '.

To achieve even stronger deformations than you can with one of these described devices are possible, can-exactly as it is with rolling mills It is common practice to connect several oscillating frames one behind the other. It can also do that in each case first - or only - scaffolding the workpiece directly from an extruder or a continuous caster G - as shown in Fig. 8. Provided that it can be wound Exits well from the last oscillating frame, e.g. B. thin tape or wire, can Downstream a reel device of a known and suitable design.

Claims (7)

PATENT CLAIMS: 1. Device for, stretch forging or other Deform rod-shaped goods made of malleable, primarily metallic material between acting on the same cross-sectional area of the stretched material, by means of crank or eccentric drives symmetrically oppositely movable oscillating jaws, which during the effective part of their approach to the exit side of the device to move, pushing the material to be stretched forward, then opening up swing back again on the input side and with each deformation stroke with each parts of their working surfaces lying in the same cross-sectional plane have a closed, Limit caliber openings that migrate along their length and thereby increasingly narrow, characterized in that at least two synchronously moving pairs of vibrating jaws are arranged evenly around the workpiece axis. 2. Device according to claim 1, characterized in that of two mutually perpendicular directions vibrating pairs of vibrating jaws the working surfaces of one pair of vibrating jaws on the surfaces delimiting the working surfaces of the other pair of oscillating jaws _ pass on. 3. Apparatus according to claim 1 and 2, characterized in that all eccentrics or cranks on the pull-in side of the pairs of oscillating jaws the output side lying ahead or behind by the same amount, preferably to advance. 4. Apparatus according to claim 1 to 3, characterized in that the Axes of all eccentrics are individually driven. 5. Apparatus according to claim 1 to 3, characterized in that only the waves of all lying on the discharge side Eccentrics are driven and their movements on the associated eccentric on the feed side, e.g. B. be transmitted via spur gears or coupling rods. 6. Apparatus according to claim 1 to 5, characterized in that all to be driven shafts are driven by a comb stand, which in turn is driven by a single motor is driven. 7. Apparatus according to claim 1 to 6, characterized in that that the driven shafts are held in bearing blocks that are within a than closed ring body formed framework are arranged. B. Device according to claim 7, characterized in that the bearing blocks are radial to the workpiece are adjustable in the scaffolding. Publications considered: German U.S. Patent No. 325,985; Swiss Patent No. 139 885; U.S. Patents No. 2 247 863, 2 114 302, 1 549 527, 1 180 296.