EP0523216B1 - Device for the hydrostatic shaping of hollow bodies of cold-workable metal - Google Patents

Abstract

PCT No. PCT/DE92/00063 Sec. 371 Date Sep. 23, 1992 Sec. 102(e) Date Sep. 23, 1992 PCT Filed Jan. 31, 1992 PCT Pub. No. WO92/13655 PCT Pub. Date Aug. 20, 1992.An apparatus for pressure deforming a hollow workpiece having a tubular end portion has a die formed with a cavity adapted to receive the workpiece with the end portion of the workpiece projecting out of the die and a fitting movable along an axis toward and away from the die and formed with a seat sealingly engageable in a feed position over the projecting end portion of the workpiece. An annular self-tightening gland in the seat circumferentially engages in the feed position around the projecting end portion of the workpiece. A passage opening in the seat into the hollow workpiece when the fitting is engaged over the projecting end portion serves for pressurizing an interior of the workpiece and thereby deforming it outward against an inner surface of the die and for pressing the gland radially tightly against the workpiece and against the fitting.

Description

The invention relates to a device for the hydrostatic shaping of hollow bodies made of cold-formable metal within a mold cavity of a die, with a feed for the pressure fluid into the hollow body in the form of a pressure fluid that can be moved back and forth relative to the hollow body received in the die, and lockable in the feed position leading feed sleeve, which can be pushed with an insertion opening ahead onto a cylindrical support or connection area of the hollow body located outside the mold cavity of the die and which encompasses the support or connection area in the feed position by means of a seal which is automatically sealed by liquid pressure, and wherein the feed opening of the feed sleeve is approximately funnel-shaped and is provided with an axially outwardly opening, approximately frustoconical inner surface, to which there is an essentially circular cylindrical interior mantle surface connects.

The known device described in EP-A-0 347 369 has not been put into practice.

In practice, however, other known devices are common (see Industry Indicator No. 20 of March 9, 1984/106, pp. 16 and 17; DE-U 18 85 909). With In those known devices, tubular hollow parts made of cold-formable metal, for example of 16 MnCr 5, are deformed with the supply of high, hydrostatically generated internal pressure. In addition to the high hydrostatic internal pressure, there is an additional axial pressure that acts on the pipe end faces. This axial pressure and the simultaneous effect of the internal pressure have the consequence that the hollow body wall bears against the engraving of the mold or the die.

In practice, this is such that a straight tube is inserted into the mold parting plane between the upper and lower dies and the die is fed. Between the upper and lower dies, however, there is sufficient space for two diametrically opposed, horizontally arranged press rams, the free end faces of which accommodate the pipe piece to be deformed, which is to be deformed, to be deformed. The reshaping is then carried out by introducing hydraulic fluid into the interior of the pipe, with simultaneous use of the axial pressure, the two press rams being moved towards one another.

With the known hydrostatic shaping, shaped parts with a uniform shape over the circumference, shaped parts with sectoral shaping and finally uniform and sectorial shaping combining shaped parts can be produced.

The advantage of hollow parts produced in this way is, on the one hand, that - e.g. In the case of permanent mold casting - undercut internal cavities can be created, which can either not be machined or only be manufactured with complicated tools (e.g. by spark erosion). In addition, the known hollow parts - in contrast to the hollow parts produced by machining - are relatively light and, as a result of the strain hardening associated with the deformation, with a favorable fiber orientation, which is similar to that of a forged fiber, are very resistant.

In the meantime, the known internal high-pressure forming (see "Industrial Indicator" loc. Cit.; DE-U 18 85 909) is perceived as disadvantageous because a certain minimum thickness of the hollow body wall cannot be undercut. This is essentially due to the fact that the tubular body to be deformed must be suitably dimensionally stable to accommodate the relatively high axial pressure acting on its end faces, which can only be achieved by way of a sufficient wall thickness.

In addition, the known hydroforming is always limited to parts in which the force-acting lines for introducing the axial forces, that is to say the ram and the longitudinal central axis of the tube, exactly coincide. In this way, at most lateral sectoral protuberances for the production e.g. of cross pieces or T pieces. Here, the longitudinal axis of the protuberance, which is sectorally produced to match the die engraving, runs transversely to the force line of the press ram and the tube (see "Industrial Indicator", loc. Cit., P. 17, fig. 4 and 8).

With the known hydroforming, a certain number of shapes can already be produced, but this is always tied to the general condition of a common line of action of the press ram and the pipe to be deformed, that is to say to a basically straight basic shape.

Finally, the known device (see "Industrial indicator" loc. DE-U 18 85 909) is perceived as disadvantageous because of its very high construction costs, in particular due to the press rams for introducing the axial force.

From EP-A-0 347 369 it is already known to accommodate the two-sided support or connection areas of the tubular hollow body to be deformed in feed sleeves. The known feed sleeves have toroidal, tubular, hollow, self-sealing seals which encompass the two support or connection areas of the hollow body. The known tubular seals are pressurized with a pressure medium pressure which is substantially higher than the forming pressure of the pressure medium acting on the interior of the hollow body. On the basis of this pressure relation, the support or connection areas on the hollow body side are held immovably as in a pair of pliers during the forming phase according to EP 0 347 369 A2.

In addition, the handling associated with the device according to EP-A-0 347 369 is quite cumbersome, since the two feed sleeves opposite the end of the hollow body are locked in a rather cumbersome manner against axial displacement after being pushed onto the pipe ends, i.e. onto the support or connection areas have to. In the known device, this is done, for example, by means of tie rods which coaxially penetrate the hollow body.

Starting from the device for hydrostatic shaping of hollow bodies made of cold-formable metal, which is not practical in EP-A-0 347 369, the object of the invention is to design the known device in such a way that not only a faster method of operation, in particular one Workpieces can be changed quickly, but also a long service life of the tool, especially since it is possible with materials that are difficult to form, such as stainless steel.

According to the invention, this object is achieved in that the feed sleeve can be driven back and forth, the seal of which forms a grooved collar made of largely incompressible material, which receives the support or connection area relatively displaceably to it, and that at least the circular cylindrical inner surface, optionally also the frustoconical Inner surface, the insertion opening are provided with a granular hard metal layer.

The device according to the invention allows a high working frequency. This is because only the hollow body to be formed needs to be inserted into the die, which can be done automatically, for example, using a loading robot, whereupon the respective feed sleeve is moved translationally in the direction of the die and is thereby pushed onto the cylindrical support or connection area of the hollow body. As soon as the hydraulic fluid guided by the feed sleeve is pressurized, the grooved ring seal fits snugly against the outer surface of the support or connection area on the hollow body side and tensions itself under the action of the same pressure medium pressure, which also causes the hollow body to be deformed.

As soon as the hydrostatic shaping has ended and the hydrostatic internal pressure has been switched off, the grooved collar is relieved, whereupon the feed sleeve, the deformed hollow body and the handling area on the die can be retracted so that it can be operated.

According to the invention, a self-sealing sleeve seal has been found to be a grooved ring sleeve made of largely incompressible material.

Due to the fact that each support or connection area on the hollow body side is accommodated relatively displaceably in the axial direction by the feed sleeve, only the internal pressure acting through the pressure fluid inside the hollow body to be formed can nestle the hollow body wall against the engraving of the die and in this case material from the support body or connection area on the hollow body side received material "drag" into the mold cavity.

It is particularly important according to the invention that at least the circular cylindrical inner surface of the insertion opening, optionally additionally the frustoconical inner surface, is provided with a granular hard metal layer.

It has been found that the service life of sealing sleeves when processing stainless steels leaves something to be desired. Characterized in that the circular cylindrical inner surface of the insertion opening is provided with a granular hard metal layer and the circular cylindrical inner surface surrounds the circular cylindrical support or connection area of the tubular hollow body with a tight fit, axially extending grooves are generated in the outer surface of the hollow body side support or connection area along its surface line.

This happens while the circular-cylindrical region of the insertion opening, which is equipped with the granular metal layer, is pushed away over the support or connection region. At a forming pressure of more than 800-1000 bar, those axial grooves cause the material of the sleeve seal to lock in the axial grooves formed on the outer surface of the support or connection area. This clawed locking prevents the material of the sleeve seal from creeping at pressures that exceed 800-1000 bar. Such high pressures are required for the hydrostatic forming of stainless steels. Basically, with the aforementioned features of the invention, a hydrostatic internal pressure of more than 3000 bar can be controlled.

In a further embodiment of the invention, the sleeve seal consists of an elastomeric cast polyurethane resin with a hardness of more than 90 Shore-A, preferably a hardness of 93-95 Shore-A.

In a further embodiment of the invention, the insertion opening is part of a union nut spanning a sleeve body, the grooved ring collar is held between the union nut and the sleeve body.

In a further embodiment of the invention, the granular hard metal layer is a spark erosion coating with tungsten carbide particles with a hardness of approximately 80 to approximately 82 HRc.

According to other features of the invention, the feed sleeve is hydraulically and / or pneumatically driven in translation. This is expediently done in that the feed sleeve arranged coaxially to the circular cylindrical support or connection area of the hollow body is held coaxially at the free piston rod end of a pneumatically and / or hydraulically driven piston-cylinder unit.

• Fig.1 ein teilweise im Vertikalschnitt dargestelltes, auf einem Pressentisch angeordnetes Gesenk, welchem eine teilweise im Längsschnitt dargestellte Einspeisungsmuffe zugeordnet ist.
• Fig. 2 eine vergrößerte Detaildarstellung entsprechend der mit II bezeichneten gestrichelten Einkreisung in Fig. 1.

In the drawings, a preferred embodiment according to the invention is shown in more detail, it shows

• 1 shows a die, partially shown in vertical section, arranged on a press table, to which a feed sleeve, partially shown in longitudinal section, is assigned.
• FIG. 2 shows an enlarged detailed representation corresponding to the dashed encirclement indicated by II in FIG. 1.

The device for hydrostatic shaping of hollow bodies, which is partially shown in FIG. 1, is designated overall by reference number 10.

A die 12, which consists of an upper die 13 and a lower die 14, is fastened on a press table 11.

Upper die 13 and lower die 14 form an upper mold cavity 15 and a lower mold cavity 16, which together add up to a common mold cavity 17. The engraving 18 of the mold cavity 17 determines the surface contour of a tubular hollow body 19 as soon as it is hydrostatically deformed within the mold cavity 17 by expansion.

The interior of the hollow body 19 is designated 20.

While the lower die 14 is releasably attached to the press table 11, the upper die 13 can be moved in accordance with the movement arrow denoted by y be moved up and down. For this purpose, the upper die 13 is releasably attached to a press upper part, not shown.

To the left of the dividing line T shown in dashed lines in FIG. 1 are the forming area 21 and to the right of the dividing line T the holding area or supporting or connecting area 22 of the tubular hollow body 19. The cross section of the supporting or connecting area 22 is approximately circular.

An infeed sleeve 23 is arranged coaxially at the end of a piston rod end 24, shown in broken lines, of a hydraulically driven piston-cylinder unit. The entire feed sleeve 23 is essentially rotationally symmetrical, as is the piston rod end 24.

The feed sleeve 23 has a sleeve body 25, the extension 26 pointing to the right has an external thread 27 which is screwed into a corresponding internal thread of the piston rod end 24 in a liquid-tight and pressure-tight manner.

The feed sleeve 23 has an inner channel 28 which is open at both ends and runs coaxially to it for the transmission of hydraulic pressure fluid (for example an emulsion suitable for hydraulic purposes). An angular channel 29 provided inside the piston rod end 24 opens into the channel 28. A tubular high-pressure line 31 connects to the connection 30 of the channel 29 on the piston rod side. which leads to a high pressure generator (not shown) for the hydraulic fluid.

A union nut 32 is screwed onto an external thread of the socket body 25 at 33. The radial inner surface 34 of the union nut 32 and the front end region of the channel 28 of the sleeve body 25 form an annular inner groove 35, in which a sleeve seal, namely a groove ring sleeve 36, is received in a form-fitting manner.

The grooved collar 36 has an annular base body 37, to which two sealing lips 38, 39 are integrally connected, which form an annular groove 40 between them, which backwards, i.e. towards the liquid connection 30, is open.

The radially extending disk-shaped wall 41 of the union nut 32 forms an insertion opening 42 which is composed of a frustoconical inner surface 43 and an adjoining circular cylindrical inner surface 44.

The surfaces 43 and 44 are each provided with a granular hard metal layer 49 and 48, which consists of tungsten carbide particles and has a hardness of approximately 82 HRc. The tungsten carbide particles are applied by electrical discharge and intimately connected to the union nut 32 made of hardened steel.

The function of the device shown in FIGS. 1 and 2 is as follows:

The feed sleeve 23 with the piston rod end 24 is translationally movable back and forth along the movement double arrow denoted by x.

The feed sleeve 23 is shifted to the left along x and first reaches the intermediate position shown in broken lines, according to which the front end of the tubular hollow body 19, which is open at 45, is passed over. The feed sleeve 23 is further shifted to the left along x until the union nut 32 fits snugly in the receiving opening 46 on the die side. Piston rod ends 24 with feed sleeve 23 are then locked in this feed position, not shown, against displacement along the direction x. This is done in a simple manner in that the hydraulic working pressure in the hydraulic cylinder, of which only the piston rod end 24 is shown, remains. Finally, hydraulic fluid is introduced into the interior 20 of the tubular hollow body 19 via the line path 31, 30, 28. The hydrostatic internal pressure builds up via a filling pressure of approximately 65-80 bar to a forming pressure of up to approximately 1500 bar, at which the hydrostatic forming is to be ended in the present application.

During the sliding of the feed sleeve 23 onto the support or connection area 22 of the tubular hollow body 19, the granular hard metal layer present on the circular cylindrical inner surface 44 of the union nut 32 is produced 48 in the outer lateral surface A of the support or connection area 22 of the hollow body 19 axial longitudinal grooves. These axial longitudinal grooves bring about an intimate clawing locking of the grooved collar 36 on the outer lateral surface A of the hollow body 19.

This clawing locking prevents the material of the grooved collar 36 from migrating or creeping along the outer lateral surface A of the tubular hollow body 19. A tendency to creep would occur without the aforementioned measure at pressures above 800-1000 bar. Such pressures, which can easily reach 3000 bar and more, are particularly necessary when forming stainless steels. The frustoconical inner surface 43 serves for self-centering of the holding area 22 within the insertion opening 42. The hard metal layer 49 on the frustoconical inner surface 43 therefore counteracts wear on the union nut 32.

The grooved collar 36 consists of an elastomeric cast polyurethane resin sold under the trademark " Vulkollan " by Bayer AG, DE-5090 Leverkusen, with a hardness of 93 Shore-A.

In addition, it should also be noted that hydraulic fluid can be fed at both ends into a hollow body 19 to be formed, via identical feed sleeves 23. In the case of one-end feed, in addition to the feed sleeve 23, a blind sleeve 23 is used, which has no pressure medium feed, since the channel 28 has an end at 47 at the end. Channel 28 is used in the blind sleeve 23 and in the feed sleeve 23 for the essentially axial force-free sliding seat receptacle of the support or connection area 22 on the hollow body side.

Claims (7)

1. Device (10) for hydrostatically deforming hollow bodies (19) made of cold-workable metal inside a moulding cavity (17) of a die (12), having a device for feeding the pressure fluid into the hollow body (19) in the form of a feed sleeve (23) which may reciprocate relative to the hollow body (19) accommodated in the die (12), is arrestable in the feed position, carries the pressure fluid, may be pushed with a lead-in opening (42) first onto a cylindrical support or connection region of the hollow body situated outside of the moulding cavity (17) of the die (12) and embraces the support or connection region (22) in the feed position by means of a seal (36) which seals automatically as a result of fluid pressure, and wherein the lead-in opening (42) of the feed sleeve (23) is approximately funnel-shaped and is provided with an axially outward-opening, approximately truncated-cone-shaped inner lateral surface (43), adjoining which is a substantially circular-cylindrical inner lateral surface (44), characterized in that the feed sleeve (23) is drivable in a reciprocating manner, its seal is formed by a grooved packing ring (36) made of substantially incompressible material, which receives the support or connection region (22) displaceably relative to itself, and that at least the circular-cylindrical inner lateral surface (44), and possibly also the truncated-cone-shaped inner lateral surface (43), of the lead-in opening (42) are provided with a granular hard metal coating (48, 49).
2. Device according to claim 1, characterized in that the grooved packing ring (36) is made of an elastomeric polyurethane casting resin.
3. Device according to claim 2, characterized in that the hardness of the elastomeric polyurethane casting resin is more than 90 Shore-A, e.g. 93-95 Shore-A.
4. Device according to one of claims 1 to 3, characterized in that the lead-in opening (42) is a component part of a union nut (32) overlapping a sleeve body (25), the grooved packing ring (36) being held between the union nut (32) and the sleeve body (25).
5. Device according to one of claims 1 to 4, characterized in that the hard metal coating (48, 49) is a coating of tungsten carbide particles with a hardness of around 80 - e.g. 82 - HRc which is applied by electrical erosion.
6. Device according to one of claims 1 to 5, characterized in that the feed sleeve (23) is hydraulically and/or pneumatically driven in a translational manner.
7. Device according to claim 6, characterized in that the feed sleeve (23) disposed coaxially relative to the circular-cylindrical support or connection region (22) of the hollow body (19) is held coaxially on the free piston rod end (24) of a pneumatically and/or hydraulically driven piston/cylinder unit.

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