Method for producing an axle housing of a vehicle axle, and axle housing of a vehicle axle

Abstract

The invention relates to a method for producing an axle housing of a vehicle axle, by means of integrally connecting an axle tube (1) to an axle shaft (2) which is positioned on the longitudinal axis (L) of the axle tube, is equipped with bearing surfaces (3) for mounting a vehicle wheel, and has a tube cross-section facing said axle tube (1) which is substantially the same as the tube cross-section of the axle tube. In order to develop a welding method for the production of an axle housing that consists of an axle tube and an axle shaft secured thereto, which method is optimised in terms of the dynamic loads to which the axle housing is typically subjected in a driving operation, the method comprises the following steps: •—arranging the axle tube (1) and the axle shaft (2), with the abutting surfaces of their tube cross-sections positioned coaxially to one another, in a workpiece receiving portion of a welding installation (10), said welding installation additionally comprising an arc welding device (11) and a laser welding device (12) which is operated in parallel, •—continuously miming a weld seam (20) in the peripheral direction of the tube cross-sections, both welding devices (11, 12) being directed, actively and from the outside, onto substantially the same peripheral section of the abutting surfaces, wherein the laser beam (S) meets the outside (14) of the tube at right angles, and intersects the longitudinal axis (L) of the axle tube (1), and •—stopping running the weld seam (20) once this has passed over a peripheral angle of at least 360°. A corresponding axle housing is also disclosed.

Claims

1. An axle housing of a vehicle axle comprised of an axle tube (1) and an axle stub, wherein the axle stub is provided with mounting surfaces (3) for the mounting of a respective vehicle wheel and has a first tube cross-section, facing the axle tube (1), wherein the axle tube (1) has a second tube cross-section that has the same cross-section shape as the first tube cross-section wherein the first and second tube cross-sections are positioned against each other and connected integrally to each other via a weld seam (20), wherein the weld seam (20) extends from the outside of the first and second tube cross-sections to an inside of the first and second tube cross-sections and extends completely over a circumference of the axle housing with a first weld seam section passing over approximately half of the circumference of the axle housing and a second weld seam section passing over the remainder of the circumference of the axle housing, and wherein the weld seam has a ridge (21) of melted material, projecting from the inside of the first and second tube cross-sections into the interior of the axle housing along the first weld seam section, and wherein the weld seam is homogenized and smoothed along the second weld seam section in comparison to the ridge (21) of melted material of the first weld seam section; wherein the first weld seam section and the second weld seam section are welded in a single path around the circumference in a welding operation, and wherein the second weld seam section is homogenized and smoothed at the inside of the first tube cross-section and of the second tube cross-sections in comparison to the ridge (21) of melted material of the first weld seam section by a secondary energy of the welding operation impinging on the inside of the first tube cross-section and the second tube cross-section opposite a welding location of the welding operation.

2. The axle housing as claimed in claim 1, characterized in that the first weld seam section passes over a circumferential length of 170° to 180°, and the second weld seam section over a circumferential length of 180° to 190°.

3. The axle housing as claimed in claim 1, characterized in that the axle housing is provided on the outside with at least one marking which can be clearly associated with the circumferential section on which the first weld seam section is situated, and/or with the circumferential section on which the second weld seam section is situated.

4. The axle housing as claimed in claim 3, characterized in that the marking is the end crater remaining at the completion of a welding method.

5. The axle housing as claimed in claim 3, characterized in that the marking, as a word or symbol, can represent “up” and/or “down”.

6. The axle housing as claimed in claim 1, characterized in that the axle housing is provided with a ventilation opening (4) for the welding process.

7. The axle housing as claimed in claim 6, characterized in that the ventilation opening (4) is sealed by a sealing element.

8. The axle housing as claimed in claim 1, characterized in that the axle tube (1) and the axle stub (2) are additionally connected to each other via tack-welding points.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Other advantages and details are explained below with the aid of an exemplary embodiment. Reference is made here to the drawings, in which:

(2) FIG. 1 shows an axle housing in a highly shortened view, as used in a non-driven commercial vehicle axle of a commercial vehicle trailer;

(3) FIG. 2 shows, in a highly simplified overview, a dual welding assembly for producing the axle housing, the individual objects being shown in the welding plane;

(4) FIG. 2a shows the objects according to FIG. 2 with additional details;

(5) FIGS. 3a-3c show individual method stages of the welding process in the welding plane, and

(6) FIG. 4 shows a cross-section through the axle housing along its longitudinal extent, here in the region of the welded joint produced between the axle tube and the axle stub.

DESCRIPTION OF PREFERRED EMBODIMENTS

(7) The axle housing depicted in FIG. 1, here configured as a continuous axle housing for a non-driven commercial vehicle axle, consists of a total of three longitudinal sections. An axle tube 1 made of steel forms the central longitudinal section. In each case one axle stub 2 is fastened to both open ends of the axle tube 1 by means of a welding method which is described in detail below. Each axle stub 2 is preferably made of steel and is provided with mounting surfaces 3 for mounting components, for example for the roller bearings of the respective vehicle wheel and/or for mounting a brake drum of a disk brake. A brake carrier of a drum brake or a disk brake can moreover be fastened to the axle stub 2.

(8) The length of the axle tube 1 is set by sawing. The saw cut is made at right angles to the longitudinal extent of the axle tube. This results in a sawed contact surface which is suitable for the subsequent welding process without any further treatment.

(9) As preparation for welding, the axle tube 1 is moreover provided with a bore 4 of preferably 4 to 10 mm. The bore 4 connects the interior of the axle tube to the outside. It serves as a ventilation opening for welding gases that occur during the welding process.

(10) The bore 4 is no longer required on the later finished product. It is therefore sealed later so that moisture and dirt cannot get into the interior of the axle tube. The bore or the ventilation opening 4 can be made in the axle stub 2 instead of the axle tube 1.

(11) Each axle stub 2 also has a tube cross-section on its end facing the axle tube 1. This tube cross-section is essentially the same as the tube cross-section of the axle tube 1 and is arranged on the same longitudinal axis L. Because the axle stub 2 is a cast or forged part, the open tube cross-section of the axle stub 2 is prepared by a machining method such as, for example, by turning. The annular end surface of the axle stub 2 is thus a surface which is prepared in a machining method.

(12) The axle stub 2 is provided with bores for subsequent fastening of an ABS holder even before the welding process.

(13) If, as shown, the two tube cross-sections are round, the internal diameter D.sub.Si of the tube cross-section on the axle stub 2 is approximately the same as the internal diameter D.sub.Ri of the axle tube 1. The external diameter D.sub.Sa of the tube cross-section on the axle stub 2 is likewise approximately the same as the external diameter D.sub.Ra of the axle tube 1.

(14) In the joint region 5, the tube cross-sections involved are integrally connected and hence the axle stub 2 is permanently fastened to the respective end of the axle tube 1. The connection takes place with the aid of a dual welding method. In order to perform said method, the welding assembly 10 used has a workpiece holder (not illustrated in FIG. 2) in which the axle tube end and the axle stub 2 can be fixed on the longitudinal axis L in a coaxial orientation, and moreover by means of an arc welding device 11 and lastly by means of a laser welding device 12 which can be operated in parallel, i.e. simultaneously.

(15) The two welding devices 11 and 12 are preferably fastened on a common workpiece carrier relative to which the workpiece holder can be rotated about the longitudinal axis L of the axle housing.

(16) The axle tube end and the axle stub 2 are first tack-welded in their coaxial orientation to the contact surfaces involved. The tack welding takes place at at least three tack-welding points, and preferably six tack-welding points, distributed over the circumference.

(17) According to FIG. 2, the arc welding device 11 and the laser welding device 12 are oriented approximately in the same welding position from the outside against the opposing contact surfaces of the two tube cross-sections which are to be connected. However, the two working axes are preferably configured such that the treatment location of the arc welding device 11 is in advance of the location at which the laser beam S simultaneously strikes the tube outside 14, wherein the advance V is preferably no more than 5 mm, and particularly preferably no more than 3 mm.

(18) The energy beam S of the laser welding device strikes the outside 14 of the tube cross-sections at right angles. The beam direction of the laser beam S is such that the laser beam S is perpendicular to the longitudinal extent of the axle tube 1 and it consequently, according to FIG. 4, strikes the longitudinal extent of the tube outside 14 at right angles.

(19) The working axis of the arc welding device 11 has an angle W with respect to the axis S of the energy beam of the laser which is 25° to 30° with respect to the axis S of the energy beam, and preferably 27°. However, both axes, i.e. the working axis of the arc welding device 11 and the axis S of the energy beam of the laser, are situated in the welding plane 17 defined by the contact surfaces of the tube ends (FIG. 4). The axis S of the laser beam preferably intersects the longitudinal axis L of the axle tube 1 at right angles.

(20) The arc welding device 11 is designed, for example, for performing a MAG (metal active gas) welding method and operates preferably with an electronically controlled pulse current source. The welding device generates an arc between the preferably nickel-containing welding wire, fed in from outside, and the outside 14 of the connecting region 5. The arc welds the contact surfaces to the tube ends and the fed-in welding wire, the weld seam 20 being created. This process goes to a depth of only approximately 4 mm. During the welding process, a wire feeder feeds the welding wire continually through the welding torch to the welding point. The welding torch moreover supplies the weld seam 20 with the metal active gas involved in the welding process.

(21) The welding wire should be a nickel alloy one with a 1.5 to 5% nickel content and preferably 2 to 3% percent by volume.

(22) However, the arc welding device 11 can also be configured for other welding methods which use a welding wire.

(23) The laser welding device 12 is preferably a fiber laser. However, the connecting method can also be performed using a diode laser with pulsed diodes. The laser welding device operates with an energy beam with a high energy density which is focused on a specific focal point. This focus F is preferably situated at a location which lies between the tube outside 14 and a third of the wall thickness D of the axle tube 1. The focus F is therefore preferably situated at a location which is at a smaller distance from the tube outside 14 than from the tube inside.

(24) The width of the laser bean initially tapers, from where it emerges from the laser welding device 12 to the focus F. After the focus F, the laser beam widens again such that energy from the laser beam strikes the opposite tube inside at a surface A. The melting energy which is thus available on the opposite tube inside in the zone A is very important as part of the method described here.

(25) FIG. 3a shows the situation in the first part of the procedure. As a result of parallel, i.e. simultaneous operation of both welding devices 11, 12, the weld seam in FIG. 3a is already run over a partial circumference which is approximately a third of the total circumference. The starting position of the welding, i.e. the start of the already run weld seam 20, has the reference numeral 25. The direction of rotation of the workpiece comprised of the axle tube 1 and axle stub 2 relative to the welding devices is referenced with the arrow R. A zero gap sensor is used for the accuracy of the process. This guides and positions the welding processes.

(26) The weld seam 20 is continuous in the radial direction, as shown in the upper part of the longitudinal section in FIG. 4. Melted material thus extends from the tube outside 14 to the weld seam root on the tube inside. The energy of the laser assists the formation of the weld seam 20. At the same time, part of the laser energy reaches as far as the internally opposite zone A as secondary energy. This zone A is therefore already preheated, which has a positive effect on the microstructure and specifically the hardness profile.

(27) However, running the weld seam 20 has the consequence that material is raised on the tube inside. A weld seam root in the form of a ridge 21 of melted material is formed here which projects significantly into the tube interior 15 in the manner of an unevenly shaped rib.

(28) The dual welding method, in which the weld seam is formed using the arc welding method, is responsible for forming the weld seam 20 but it is assisted by the energy applied by means of the laser beam (primary energy of the laser beam). This energy results in homogenization and improves the structure of the weld seam as a whole. In particular, the latter has a clean, flat seam surface on the tube outside.

(29) FIG. 3b shows a more advanced stage of the method, in which the weld seam 20 already extends over a circumferential segment which is approximately two-thirds of the total circumference.

(30) As soon as the weld seam is run over a circumferential angle of 180°, as shown at the bottom in FIG. 3b, the ridge 21 comprised of melted material of the root reaches into the region of that area A which is affected by the energy of the laser beam S beyond its focus F, i.e. by the secondary energy of the laser beam. The energy density in the zone A is still sufficient to melt and break down the ridge 21 and homogenize the zone around the ridge such that a smoothed root 22 results. The advantage of the weld seam root 22 smoothed in this way is an improvement to the material structure and hence to the quality of this section of the weld seam.

(31) Lastly, FIG. 3c shows the situation at the completion of the welding method. The weld seam 20 is run over 360° to 370° and preferably over a circumferential angle of 365°. This process takes approximately 15 seconds. Two circumferential segments or partial circumferences of approximately the same size result. The circumferential segment which is welded only later and is shown on the right-hand side in FIG. 3c has the inwardly projecting ridge 21 on the weld root. In contrast, the circumferential segment which is welded first and is shown on the left-hand side in FIG. 3c has undergone the smoothing of the ridge later owing to the energy density of the laser beam. The circumferential length welded only later here extends over a partial circumference of 170° to 180°, and the circumferential length welded first over a part circumference of 180° to 190°.

(32) The gases which occur during the inert gas welding and could otherwise lead to an elevated pressure can escape from the tube interior via the already described ventilation opening 4. The latter is then sealed by a sealing element.

(33) When used later in practise, the axle housing is installed in the vehicle axle and in particular the commercial vehicle axle such that the partial circumference with the smoothed weld seam root is situated at the bottom and is hence subjected to particularly critical tensile loads during driving. This rotated position of the axle housing, which needs to be ensured during subsequent mounting of the axle, is shown in longitudinal section in FIG. 4.

(34) For correct mounting of the axle, the completed axle housing can be provided on the outside with at least one marking which can be clearly associated with the two circumferential sections or circumferential segments, i.e. with either the first circumferential section or circumferential segment and/or with the second circumferential section or circumferential segment. The marking should represent “up” or “down” in the form of words or symbols. For this purpose, the marking can be fastened on the outside of the axle housing or engraved permanently in its material.

(35) Alternatively, the end crater remaining at the completion of the welding method can serve as a marking.

(36) As a whole, an axle housing is provided which can be produced relatively quickly and with few manufacturing steps. The dual welding takes place only over a total angle of 360° or somewhat more than 360° and results on the outside of the tube ends in a clean, flat seam surface and takes places just “in one go”. Nevertheless, two different circumferential sections result in which the weld root is formed differently on the inside of the connected tube ends.

(37) Using the method, the two axle stubs 2 can simultaneously be welded to both axle tube ends as long as two welding assemblies 10 are also present. Treatment time is saved as a result.

(38) However, if using just one welding assembly 10, first just one axle stub 2 is connected to the axle tube 1, and then the other.

(39) The welding method described is therefore optimized in terms of the typical vehicle dynamic loading to which an axle housing is exposed during driving. Account is taken of the circumstance in which during driving the loading situation which exists in an axle housing is different in the upper half of the axle housing, where primarily compressive loads prevail in comparison to the lower half where primarily tensile loads prevail.

LIST OF REFERENCE SYMBOLS

(40) 1 axle tube 2 axle stub 3 mounting surface 4 bore, ventilation opening 5 connecting region 10 welding assembly 11 arc welding device 12 laser welding device 14 tube outside 17 welding plane 20 weld seam 21 ridge of melted material 22 smoothed weld seam root 25 starting welding position A area, zone D wall thickness D.sub.Ra outer diameter D.sub.Ri inner diameter D.sub.Sa outer diameter D.sub.Si inner diameter F focus L longitudinal axis of the axle housing R direction of rotation S laser beam V advance W angle between the welding devices