EP2640535B1 - Method and set of components for producing a tubular structural part, in particular a built-up camshaft - Google Patents

Description

The invention relates to a method for producing a tubular member, in particular a built camshaft, by means of hydroforming, wherein a support tube and an end piece are fed, wherein inserted into an opening of the tail an associated end of the support tube and subsequently expanded by the application of a pressurized fluid and is connected to the end piece in a press fit, and wherein the opening before the pressurization with the fluid having a first portion having an inner cross section which is greater than the outer cross section of the associated end of the support tube. The invention also relates to a set of components for the production of a tubular component, which has a carrier tube, an end piece with an opening for the carrier tube and for the arrangement on the carrier tube provided functional elements, such as cams.

Under a built camshaft is understood a camshaft, which is not manufactured in one piece in a Ur- or forming process, but assembled by the combination of several prefabricated parts. Modern built camshafts in addition to cams have additional functional elements, such as tail, sprocket, pulleys, encoder wheels, pump drives, bearings, plain bearings or the like, which must be mounted on a support tube with a suitable joining technology, with very high angular accuracies must be observed.

In practice, hydroforming has proved successful in the manufacture of assembled camshafts, with several cams in one process step and / or other functional elements are simultaneously mounted in a press fit on a support tube. In the hydroforming the cams and optionally provided further functional elements are first pushed onto their hubs with a game on the support tube and positioned, in which case the support tube is subjected to a high internal pressure, whereby the support tube expanded with an elastic and a plastic portion and to the Inner surface of the hubs is created. The cams and optionally provided further functional elements are widened to a certain extent, but this expansion preferably takes place only elastically. After the elimination of pressurization, both the support tube and the elements arranged thereon resiliently spring back, wherein the materials of the joining partners are selected so that the cams and other functional elements are held with an elastic residual stress in a press fit on the support tube.

The hydroforming is usually carried out in a mold, which limits the radial expansion by the pressurization. If according to a preferred embodiment of the hydroforming process, the carrier tube is acted upon over its entire length with a pressurized fluid, a sufficient seal is to ensure. Furthermore, the reliable transmission of high torques should be made possible in the hydroforming with the least possible use of materials and with a lightweight design.

When the hydroforming is carried out in a mold, a pressure source is usually connected to one end of the support tube while the end of the support tube opposite the pressure source must be closed pressure-tight, to which end pieces can be used, which are mounted like a cap. Another variant is the possibility of pressure medium filling through an axial bore in the tail. The tube is sealed pressure-tight on the opposite side. A reliable seal is necessary to avoid the uncontrolled discharge of pressure fluid and thus an impairment of the joining process.

A method for producing a built camshaft with the features described above is known from DE 36 16 901 A known. The production of the tubular component in the form of a built camshaft takes place in a closed mold, wherein a source of the pressurized fluid is connected to one side of the support tube and on the other side an end piece is pressed onto the local end of the support tube during the hydroforming process. In order to achieve a seal, various measures are proposed. The arrangement of a sealing ring in a radial groove or at the bottom of the opening of the tail is expensive, which due to the very high acting pressures during hydroforming typically 2000 to 5000 bar leaks in the polymeric sealing material can not be excluded. Alternatively, it is also proposed to provide the opening in the form of a blind bore at its bottom with a frusto-conical bevel against which the support tube is pressed. In this case, only a linear contact is achieved around the circumference, which can not ensure a reliable seal with dimensional deviations, ovality and local damage. Furthermore, the production of such conical surfaces at the bottom of the opening is expensive.

Against this background, the invention has for its object to provide a method for producing a tubular component, in which by means of hydroforming an end piece can be attached in a simple manner with a high reliability and reproducibility. Furthermore, a set of components is to be specified, which is suitable for carrying out the manufacturing process.

Based on a method with the features described above, the object is achieved in that, starting from the front edge of the opening to the first portion, a second portion having a second inner cross section, which is smaller than the outer cross section of the associated end of the support tube, under training a circumferential edge connects in steps, wherein the support tube is first inserted with its corresponding end in the first section and wherein in a further insertion movement, the edge is cut into the material of the support tube. The usually approximately rectangular step defines a comparatively sharp cutting edge, which engages when inserting the associated end of the support tube in the region of the end face of the support tube and there cuts into the material. In this cutting both a material deformation and a certain Materialabscherung can be done. By the method described process is achieved that a wider sealing area is generated around the circumference, whereby a particularly reliable sealing is ensured. In addition, the end piece is prefixed after insertion of the support tube by the cutting of the edge to a certain extent, so that the support tube with the attached end piece can be handled easily before finally the joining takes place by means of internal high pressure.

While essentially only a bending of the comparatively thin-walled tube takes place in the case of the conical abutment surfaces known from the state of the art due to the oblique introduction of force, according to the present invention, the comparatively sharp edge, usually formed approximately by a right angle, cuts along the edge End face of the support tube, wherein the introduction of force initially has a considerable axial portion, whereby reinforced material deformation or shearing and less bending of the support tube takes place.

The height of the step is selected such that the second internal cross-section provided from the step is greater than the internal cross-section of the associated end of the tube. This difference in diameter results in the joining play for the pre-assembly. Furthermore, the dimensions are preferably also chosen so that despite the formation of the stage, the support tube to a bottom of the opening or at least to just before the bottom of the opening in the region of the second section under deformation and / or shearing of a portion of the tube material can be inserted. In this case, then over the entire length of the second section, which is preferably between 1 mm and 8 mm, preferably about 4 mm, a sealing material contact is achieved, so that local unevenness, imperfections or the like even at a pressure of several 1000 bar not lead to a noticeable reduction of the seal. An extension of the second portion may be useful to compensate for uneven shortening of the tube as a result of forming operations. The fact that the support tube can preferably be inserted with its end to the bottom of the opening, also results in terms of dimensional accuracy of a particular high accuracy and reproducibility, since the bottom of the opening as it serves as a stop for the associated end of the support tube.

The present invention generally relates to a method for manufacturing a tubular member, wherein the cross-sectional shape of the support tube is not initially determined. In principle, square, rectangular, elliptical or other cross-sectional shapes are conceivable, wherein a peripheral edge is always provided at the transition of the first section to the second section within the opening of the end piece, wherein the inner contour of the opening is adapted to the outer contour of the support tube.

However, in particular with regard to built camshafts, a circular cross-section is usually provided, so that the sections of the opening are preferably circular-cylindrical or substantially circular-cylindrical. The details of the dimensions with respect to the inner and outer cross sections relate to a circular configuration according to the inner and outer diameter.

The quality of the seal on the one hand and the force required for insertion of the support tube in the associated end piece on the other hand depend on the determination of the dimensions, the second inner cross section, the length of this section and the outer cross section of the tube. In this context, it is preferred if the first inner cross-section relative to the second inner cross-section in the radial direction has an excess between 0.1 mm and 1 mm, particularly preferably between 0.2 mm and 0.4 mm, which measure the height of the corresponds to a substantially right-angled step between the first section and the second section. The game between the first inner cross section and the outer cross section of the associated end of the support tube is preferably small and usually just chosen so that a jam-free pushing can take place. According to a preferred embodiment of the invention, the first inner cross section with respect to the outer cross section of the associated end of the tube in the radial direction an excess of less than 0.2 mm, more preferably between 0.05 mm and 0.1 mm.

In order to ensure a secure connection to the support tube on the end piece and preferably also to allow the transmission of significant torques, various measures in combination or alternatively to each other are provided.

First, the strength of the connection and thus the torque to be transmitted by the overlap between the support tube and the tubular member dependent. In an embodiment with circular cross-sections, it is therefore provided according to a preferred embodiment of the invention that the opening has a longitudinally extending total length, which is at least 60%, preferably at least 80% of the inner diameter of the first section. Based on the finished component, the length along the longitudinal direction of the support tube is to be determined.

In order to achieve a high joint strength in hydroforming, it is crucial that the outer joining partner has a greater elastic recovery than the inner support tube. Accordingly, a sufficient expansion of the outer joint partner must be carried out beforehand, for which it may have a not too large wall thickness. So is provided according to a preferred embodiment, that the end piece in the region of the first portion of the opening has a wall thickness between 2 mm and 4 mm and so can be expanded elastically in the hydroforming to a sufficient extent.

In order to improve the frictional connection of the end piece on the support tube in an interference fit, the opening of the end piece can be pretreated before insertion of the associated end of the support tube with a particle beam, such as a corundum, a shot blasting, sandblasting or the like. This increases the coefficient of friction between the joining parameters. In order to avoid damage to the invention as sharp as possible edge at the transition from the first portion to the second portion of the opening, this can be covered during the pretreatment by the particle beam.

Even a certain adhesion can contribute to an increased strength of the connection. Thus, prior to insertion of the associated end of the carrier tube into the tail, it is possible to apply adhesive to the outer surface of the end and / or the inner surface of the opening, or to provide the surface of the opening and / or the outer surface of the associated end of the tube with galvanizing , In which the zinc layer is compressed between the two joining partners by the application of pressure to the pressurized fluid during hydroforming, and a force connection is produced by means of press soldering in the transverse compression bandage. Through a dynamic training, the connection strength can be further increased. Training is understood to be the generation of an additional relative movement between the joining partners, for example a twisting or shifting in alternating directions.

In order to further improve the connection between the end piece and the associated end of the support tube, in addition to the previously described frictional connection by a press fit and a certain positive fit can be achieved by at least partially contouring the opening of the tail. The contouring may, for example, have the form of a spiral, a pocket, an inner knurling, a butted inner contour or the like. Contours in which the formations run transversely to the direction of the torque transmission are particularly advantageous. By applying internal high pressure, the pipe material is molded into the corresponding contouring, whereby in addition to the adhesion and a positive connection is formed. However, the formation of a contouring requires a correspondingly high wall thickness of the tail, which counteracts to some extent elastic extensibility.

The hydroforming takes place within the scope of the invention expediently within a mold. Preferably, functional elements such as cams, sensor wheels, bearing rings or the like are threaded onto the carrier tube in the desired sequence, wherein the end piece is also attached at one end of the carrier tube as described above. The support tube and the functional elements threaded thereon are then inserted into a tool mold and thereby aligned with respect to their axial position and rotational angle alignment. After closing the tool mold, a pressure source at the still open end of the support tube using an axial force, which also ensures the sealing function, arranged before the pressure source, such as a plunger is pressurized with a pressurized fluid to perform the hydroforming process. The carrier tube is at a given Pressure as far as required for shaping and fastening required.

During hydroforming, the pressure source may, according to a preferred embodiment, be moved axially to keep the tube tight and to compensate for shortening of the tube due to the bulge. In addition to the fixation of the functional elements in a press fit, hydroforming can also be used to form functional surfaces such as bearing points from the support tube itself. This results in the advantage that due to the plastic deformation up to the tool shape, certain dimensional deviations of the carrier tube originally used are compensated. For the dimensional accuracy, in essence, only the provision of the support tube after elimination of the internal high pressure is decisive. In order to form bearings on sections of the support tube, they may, for example, also be subjected to finish machining and / or coating before hydroforming.

If the carrier tube or the end piece are not completely cleaned, if despite the good seal in the region of the tail at least at the beginning of hydroforming certain amounts of pressure fluid in the joint gap or in the lower mold emulsion residues of previous forming operations, there is a risk that in the joint gap, a liquid film is formed which, as a kind of counter cushion and spacer, counteracts the forces exerted by the internal high pressure. It can then not be ruled out that the interference fit between the joining partners is impaired and / or that certain production fluctuations occur. In order to avoid such an impairment, is provided according to a preferred embodiment of the invention that at the beginning of hydroforming liquid can be removed from the joint gap between the carrier tube and tail. For this purpose, the end piece in the region of the first portion of the opening may have at least one radial discharge channel, for example in the form of a bore and / or at least one groove extending in the longitudinal direction.

In order to avoid hydroforming in the hydroforming, the expanding support tube is damaged at the edge of the opening, there may be provided between the first portion and the edge of the opening, a radius and / or a conical widening. A cutting into the widening support tube can be avoided. The formation of a radius or a conical extension at the edge of the opening also contributes to the fact that the tail can be even more easily placed or preassembled on the associated end of the support tube.

The invention also relates to a set of components for producing a tubular component by means of hydroforming, wherein the component set has at least the carrier tube and end piece described above.

The invention will be explained below with reference to only one embodiment illustrative drawings.

Fig. 1

den Längsschnitt einer gebauten Nockenwelle, die durch Innenhochdruckumformung aus einem Trägerrohr, Funktionselementen und einem Endstück gebildet ist,

Fig. 2

eine Detailansicht des in der Fig. 1 dargestellten Endstücks mit dem zugeordneten Ende des Trägerrohres vor der Innenhochdruckumformung.

Show it:

Fig. 1

the longitudinal section of a built camshaft, which is formed by hydroforming of a support tube, functional elements and an end piece,

Fig. 2

a detailed view of the in the Fig. 1 illustrated end piece with the associated end of the support tube before the hydroforming.

Fig. 1 shows the general structure of a formed by hydroforming camshaft having a support tube 1, at one end of the support tube 1, an end piece 2 and a plurality of functional elements in the form of cam 3 and a thrust bearing 4. The end piece 2 and the functional elements are fixed by hydroforming in a press fit on the support tube 1. As a result of the hydroforming, furthermore, outer contours of the carrier tube 1 are formed, which serve as bearing points 6. Screwdriver release 7 in the camshaft provide access to cylinder head bolts. In order to enable a simple assembly of the assembly formed from the camshaft and cylinder head, a plurality of screwdriver release 7 are introduced into the support tube 1 over the length of the support tube 1.

In the production of the camshaft, the functional elements are first pushed onto the carrier tube 1 and the end piece 2 is preassembled at one end of the carrier tube 1. As described in detail below, the pressing of the end piece 2 on the associated end of the support tube 1 causes a fluid-tight connection, so that the discharge of pressurized fluid in the subsequent hydroforming can be avoided or at least largely avoided. For hydroforming is opposite the end piece 2 a pressure source connected to the support tube 1, wherein the support tube 1 is located with the functional elements in a mold which holds the functional elements in the desired axial position and the angular orientation to each other and limits the extent. There, where the pressure source is connected, after the elimination of the internal high pressure subsequently an end element 8 can be used.

The invention provided for pressure-tight closure end piece 2 and the associated end of the support tube 1 are shown in detail in the Fig. 2 shown, wherein the Fig. 2 shows the two components before their connection and accordingly before forming by means of internal high pressure. In the Fig. 2 It can be seen that the end piece 2 has an opening 9, wherein said opening comprises a first circular cylindrical portion 10a with an inner diameter I _a and a directly adjoining the second portion 10b with a smaller inner diameter I _b. The transition between the first portion 10a and the second portion 10b is step-shaped, wherein the bend defines an edge 11 by about 90 °. The outer diameter A of the support tube 1 is between the first inner diameter I _a and the second inner diameter I _b , so that the support tube 1 can first be easily inserted into the first portion 10 a and then abuts with its end face 12 at the edge 11. In a further insertion movement, the edge 11 cuts into the material of the support tube 1 a. For this purpose, it is important that the material of the end piece 2 is correspondingly stronger or harder than that of the support tube 1.

The height of the step between the first portion 10a and the second portion 10b is chosen so that the support tube 1 can be pushed under partial deformation and / or shearing of the material to the bottom 13 of the opening 9 under increased force. Over substantially the entire measured in the axial direction length x _{b of} the second section is thus a direct material contact and, accordingly, achieved a tight connection. In addition, by cutting the edge 11 into the material of the carrier tube 1, the end piece 2 is already prefixed, so that the carrier tube 1 and the end piece 2 can be handled together. The length x _{b of} the second portion 10b is typically between 1 mm and 8 mm, preferably about 4 mm.

To achieve a good sealing effect as described on the one hand and on the other hand to push the support tube 1 with its end face 12 to the bottom 13 of the opening 9, suitable dimensions for the inner diameter I _a , I _b and the outer diameter A of the associated end of the support tube 1 set. Thus, for example, the first inner diameter I _a by 0.2 mm to 1 mm, preferably between 0.4 mm to 0.8 mm greater than the second inner diameter I _{b of} the second portion 10b.

Between the support tube 1 and the first portion 10 a, only a small radial gap is preferably provided. For example, the inner diameter I _a of the first portion 10a relative to the outer diameter A of the carrier tube 1 may have an excess of as less than 0.2 mm, for example, an excess of between 0.05 mm and 0.1 mm.

In the joint gap between the support tube 1 and the end piece 2, the accumulation of liquid, for example, residual liquid in the tool or a small amount of leaking pressurized fluid, can not be completely excluded in all cases. In order to discharge such liquid at the beginning of the hydroforming, a discharge channel 14 is provided in the form of a bore in the embodiment. In addition or as an alternative, a groove extending in the longitudinal direction can also be introduced into the first section 10a for the removal of fluid.

In order to avoid incision at the front edge of the opening 9 when expanding the support tube 1, a conical widening 15 is provided there at the transition to the first section 10a.

Particularly preferred is an embodiment in which the end piece 2 is not only used for pressure-tight closure, but also has functional features. Thus, in the embodiment, a central portion of the closed end piece 2 is provided with a thread 16 for a central screw.

In order to produce a sufficient joining stress between the support tube 1 and the end piece 2, the total length x _{g of} the entire opening 9 in the illustrated embodiment is at least 80% of the first inner diameter I _a .

An even further increase in the strength of the connection can, for example, by adhesive, galvanizing or at least partially contouring be achieved. For the sake of clarity, these optional measures are not shown in the figures.

Claims (16)

1. A method for manufacturing a pipe-shaped component, in particular an assembled camshaft, by means of internal high-pressure forming, wherein a carrier pipe (1) and an end piece (2) are supplied, wherein an associated end of the carrier pipe (1) is inserted into an opening (9) of the end piece (2) and is then widened through the application of a hydraulic fluid and connected with the end piece (2) by means of a press fit, and wherein the opening (9), prior to the application of the hydraulic fluid, comprises a first portion (10a) with an inner cross-section which is larger than the outer cross-section of the associated end of the carrier pipe (1), characterised in that, starting from the front rim of the opening (9), a second portion (10b) with a second inner cross-section smaller than that of the outer cross-section of the associated end of the carrier pipe (1) adjoins the first portion (10a) in a stepped manner, wherein the carrier pipe (1) with its corresponding end is initially inserted into the first portion (10a) and wherein, when a further insertion movement takes place, the edge (11) cuts into the material of the carrier pipe (1).
2. The method according to claim 1, characterised in that the opening (9) of the end piece (2), prior to inserting the associated end of the carrier pipe (1), is pre-treated with a particle jet.
3. The method according to claim 2, characterised in that the edge (11) is masked by the particle jet during the pre-treatment.
4. The method according to one of claims 1 to 3, characterised in that prior to inserting the associated end of the carrier pipe (1) into the end piece (2), adhesive is applied to the external surface of the end and/or the internal surface of the opening (9).
5. The method according to one of claims 1 to 4, characterised in that the carrier pipe (1), the end piece (2) and further functional elements comprising a hub, respectively, are placed into a tool mould, wherein the hydraulic fluid is applied once the tool mould has been closed.
6. A component set for manufacturing a pipe-shaped component by means of internal high-pressure forming, in particular according to a method as specified in claims 1 to 5, comprising a carrier pipe (1), functional elements provided for arrangement on the carrier pipe (1), as well as an end piece (2) with an opening (9) for the carrier pipe (1),
   wherein the opening (9) comprises a first portion (10a) with a first inner cross-section larger than the outer cross-section of the associated end of the carrier pipe (1) and a second portion (10b) with a second inner cross-section smaller than the outer cross-section of the associated end of the carrier pipe (1),
   wherein, starting from the front rim of the opening (9), the second portion (10b) adjoins the first portion (10a) in a stepped manner, by forming a circumferential edge (11), and
   wherein the second inner cross-section is larger the inner cross-section of the associated end of the carrier pipe (1).
7. The component set according to claim 6, characterised in that the first and the second inner cross-sections as well as the outer cross-section of the associated end of the pipe are circular in shape.
8. The component set according to claim 7, characterised in that the opening (9) comprises an overall length (x_g), which is at least 40%, preferably at least 80% of the inner diameter (I_a) of the first portion (10a).
9. The component set according to one of claims 6 to 8, wherein the second portion (10b) extends over a length (x_b) of between 1mm and 8mm, preferably of approx. 4mm.
10. The component set according to one of claims 6 to 9, wherein the first inner cross-section compared to the second inner cross-section, in radial direction, is oversized by between 0.2 and 1mm, preferably by between 0.4mm and 0.8mm.
11. The component set according to one of claims 6 to 10, wherein the first inner cross-section compared to the outer cross-section of the associated end of the carrier pipe (1), in radial direction, is oversized by less than 0.2mm, preferably by between 0.05mm and 0.1 mm.
12. The component set according to one of claims 6 to 11, wherein provision is made for a radius and/or conical widening between the first portion (10a) and the rim of the opening (9), in order to avoid cutting into the widening carrier pipe (1), while the press fit is being formed through the application of a hydraulic fluid.
13. The component set according to one of claims 6 to 12, characterised in that the surface of the opening (9) and/or the outer surface of the associated end of the carrier pipe (1) is zinc-plated.
14. The component set according to one of claims 6 to 13, wherein the end piece (2), in the area of the first portion (10a) of the opening (9), comprises at least one radial discharge channel (14) and/or a groove extending in longitudinal direction.
15. The component set according to one of claims 6 to 14, wherein the end piece (2), in the area of the first portion (10a) of the opening (9), comprises a wall thickness between 2mm and 4mm.
16. The component set according to one of claims 6 to 15, wherein the end piece (2) comprises functional features.

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