The invention relates to a method of manufacturing hollow composite structural elements, preferably designed for use in vehicles.
Many fields today require weight-optimized products without sacrificing function or strength. This is particularly true of forged products, which can be heavy and difficult to optimize due to limitations of the tools used for manufacture.
One example is front axle beams for heavy vehicles. These beams are typically forged as an I-profile, where the web or core in the beam cross-section has very little effect on the torsional rigidity. With strength calculations it can be shown that a tubular cross-section, with a material moved radially outwards as far as possible, is optimal for such a structure. This is particularly true of the so-called “swan neck” on the front axle beam, between its central portion and a king pin support. With conventional forging technology it is, however, difficult to achieve this. EP-A2-0 059 038 shows a front axle beam forged lying in a conventional manner, i.e. the blank lies with its final vertical plane (after mounting) in the horizontal plane during working. The specification describes how a blank is pre-shaped by means of rolling and is then moved between a number of presses, which forge the entire blank or portions thereof to the desired shape. The disadvantage of this method is, as was described above, that the web of the beam is largely located centrally, which has very little effect on the torsional rigidity.
An alternative solution is shown in EP-A1-0 015 648, which describes the forging of a rectangular hollow front axle beam, starting from a tubular blank. While it is true that it is possible to obtain a beam with higher torsional rigidity with this method, it involves a number of problems. To produce the tapered ends of the beam these must be pulled through a die. Even if the material is distributed radially further out from the centre of the beam, the possibility of controlling the thickness of the material is very limited. This also applies to the other parts of the beam, since the starting material is a tube with constant thickness. Quite some work is required on the ends of the beam to provide king pin supports and the mounting of separate mounts for air bellows, for example.
Another solution is revealed in U.S. Pat. No. 6,122,948, which shows a hydroformed front axle beam. In this case as well one starts from a tubular blank, which is first bent to the desired basic shape and is then hydroformed to its final shape. The disadvantage of this solution is firstly that, as in the example above, it is not possible to control the distribution of material along the length of the profile. One must also provide the profile with a number of separate mounts, not only for the air bellows but also for the king pins. The latter must be welded on, for example, which provides the beam with a natural weak point susceptible to corrosion.
Finally, it is also possible to cast hollow front axle beams as is shown in JP-A-11-011105. For reasons of casting technology, there are, however, limits as to the greatest and smallest thickness and requirements for reinforcing ribs, complicated casting cores and the like, to permit casting of such an advanced profile. Beyond this, there are additional limits as regards which materials are practically possible and the economic consequences on the piece price of the axle beams due to the great increase in costs which a casting process would involve.
Most of the above mentioned problems can be solved by the manufacturing method according to the invention. This method makes it much more possible to achieve exact control of the distribution of material around and along a forged profile.
The invention relates to a method of manufacturing a hollow, elongated structural element in accordance with claim 1 and its subclaims.
The method comprises the following steps:
a) a first blank is led through an oven for heating to working temperature,
b) the first blank is led through a pair of rollers with profiled surfaces, the blank being preformed in one or more steps to an intermediate with a predetermined profile along its length,
c) the first blank is placed in a forging press with a number of cooperating dies, the blank being worked in a plurality of steps to a first half of an essentially finished product, having a cross-section substantially in the shape of a U-profile with a predetermined varying height, width and thickness of material along its length,
d) a second blank is led through an oven for heating to working temperature,
e) the second blank is led between a pair of rollers with profiled surfaces, the blank being preformed in one or more steps to an intermediate with a predetermined profile along its length,
f) the second blank is placed in a forging press with a number of cooperating dies, the blank being worked in a plurality of steps to a second half of an essentially finished product, having a cross-section substantially in the shape of a U-profile with a predetermined varying height, width and thickness of material along its length, the second blank being essentially a copy of the first blank,
g) the first and the second blank are joined in a last step, at least along their respective edges, into a composite hollow structural element.
In contrast to known technology, the first and second blanks are forged horizontally; i.e. the horizontal dividing plane of the blank during processing coincides essentially with the vertical plane in which the construction element is intended to be mounted.
The starting material can, for example, be a round, square or rectangular blank, which is cut to the desired length and is then heated in an oven to a working temperature suitable to the material. When using air-tempered micro-alloyed steel, for example, the blank is heated to 1250-1300° C., preferably to 1280° C. In a first step, the blank is given a suitable cross-section with the aid of a pair of rotating rollers, which can be made profiled. The rolled blank is thereafter moved to a forging press for working to the final shape.
The forging operation includes a first step, where a pair of first cooperating dies shapes the material in the first blank so that it is provided with a predetermined, varying height in a vertical plane along its length. The blank is provided with its essential basic shape in this plane. The blank is thereafter moved to a new forging press or is worked by a new die, which carries out a second step where a pair of cooperating dies shapes the material in the first blank so that it is given a predetermined varying thickness along one or more of the side surfaces, bottom surface or upper edge surfaces of the profile along its length. This second step is repeated one or more times in additional forging presses or additional dies, the sequential dies shaping the blank until it has obtained its final shape. In this manner it is possible to redistribute the material in the blank, both cross-sectionally and along its length. By using suitable dies, the blank can be freely shaped as far as the forging process permits along both its inner and outer periphery.
To achieve a closed profile, the first blank must be joined to a second blank. The second blank is made of the same starting material as the first blank. The second blank is preformed and finally formed in the same manner as the first blank, in a separate forging operation in the same press or in a separate press, to essentially the same profile as the first blank relative to the dividing plane of the dies. A particularly advantageous embodiment is to make both of the blanks with identical profiles in the same press tool, with one blank being turned so that the edges of the blanks in the dividing plane can be placed against each other.
Before joining the first and second blanks into a common structural element, there is an additional heating of at least the outer edges of each blank. According to a preferred embodiment the joining is done by means of flash butt welding. Flash butt welding is a process intended to achieve a butt weld with the same strength as a corresponding forged blank. This is suitably done by securing the blanks in contact with each other and pressing them together in a controlled manner while a welding current is applied to melt the material in the joint between them.
According to an alternative embodiment, the joining together can be effected by heating the joint edges of the first and second blanks with an induction loop, whereafter they are placed between a pair of cooperating dies in a press and are joined by means of forge welding. Alternatively, the joint edges of the first and second blanks can be heated at the same time by a heating means inserted between the first and second blanks. The blanks are held between a pair of cooperating dies in a press and are thereafter joined together by forge welding. Said heating means can be induction elements, gas flames or the like.
In a final operation, flash is trimmed off along the joint edges of the profile. This can either be done in the same pressing operation where the first and second blanks are joined together, or by separate trimming of the outer edges of the joined profile. The profile is thereby provided along its length with a predetermined varying height, as seen in the plane in which the structural element is intended to be mounted.
The final result will be an elongated structural element with a hollow, closed cross-sectional profile. The element comprises a first part with a cross-section essentially in the shape of a U-profile which has a predetermined varying width, height and thickness of material along its length, and a second part which has an essentially identical U-profile. The two U-profiles are turned with their open portions facing each other and are joined together at least along their edge surfaces. The expressions “edge surfaces” or “joining surfaces” include all those surfaces where the U-profiles are in contact with each other at or near the dividing plane. Examples of such surfaces are the outer peripheral limiting surface of each profile, and other surfaces where the edge surfaces of a U-profile are joined to a surface, or where surfaces spaced from the edge surfaces are located at or near the dividing plane.
The joined U-profiles have an essentially vertical dividing plane with regard to the main plane in which the structural element is designed to be used. The edge surfaces of the U-profiles facing each other are essentially located in this plane. It is also possible to provide the respective edge surfaces with cooperating projections and cavities. Such projections and cavities contribute, firstly, to simplify the positioning of the U-profiles relative to each other when they are to be joined and, secondly, to the strength of the assembled structural element after joining.
The embodiments described above increase the possibilities of optimizing the thickness of material of the structural element over known technology. Firstly, the material can be distributed so that the greatest thickness is obtained where the loads on the structural element are greatest and, secondly, material is moved towards the periphery of the structural element which increases the torsional rigidity of the element. A hollow profile of this type also provides significant weight-savings over a corresponding product forged in a conventional manner.
In order to further increase strength, the structural element can be manufactured of air-hardening, micro-alloyed steel. Thus the product does not need to be tempered or heat-treated in any other manner after the two parts are joined together. It is, of course, possible to use steel of another quality but in that case, an additional cost-increasing heat treatment or other treatment may be necessary to achieve the desired strength.
A structural element which is suitable to manufacture in this manner is a front axle beam. By using the above method, it is possible to manufacture such a beam with 30% lower weight than a conventionally forged beam (see e.g. EP-A2-0 059 038 above).
As was mentioned above, it is possible to optimize the manufacturing method so that the greatest material thickness of the front axle beam occurs at the mounting points and the areas which are to be loaded with external forces and bending moment. The method also makes it possible to adapt the cross-section of the front axle beam in such a way that it is given essentially the same outer contours, in both the vertical and horizontal plane as a conventionally forged solid beam. By giving the outer contours of the beam the same shape and the same so-called “offset” (the vertical height of the king pin supports relative to the spring elements) and “drop” (the vertical vertical height of the upper midpoint of the beam relative to the mounting points of the spring elements) as a standard beam in a certain vehicle, it can be used without having to make any changes in existing vehicles. It is also possible to retain the existing mounting points and mechanical interfaces for wheel holders, springs and the like.
The invention will be described in more detail in the following description of a preferred embodiment, shown as an example with reference to the accompanying schematic drawings, of which:
A first blank 1, which has been cut to a predetermined length, is led through an induction oven 2, where it is heated to working temperature. When using, for example, air-hardening micro-alloyed steel, the blank is heated to 1250-1300° C., preferably to 1280° C. When the correct temperature has been reached, the blank is led through a pair of profiled rollers 3, 4, which are profiled to impart a suitable starting cross-section to the blank 1 along its length. By suitable design of the respective profiles of the rollers 3, 4, an intermediate is obtained, the cross-section and material thickness of which vary along the length of the blank in a manner which at least partially corresponds to the finished product or a rough approximation of the final U-profile thereof. In this stage, the blank 1 is still essentially straight, at least along the peripheral edges, with a number of depressions along the central portion.
In the next step, the pre-shaped blank is moved to a first forging press 5 with upper and lower cooperating dies 6, 7. In this forging press 5, the shaping of the blank 1 is started, and its cross-section is given a more pronounced U-profile in certain predetermined areas where high torsional resistance is desired. Examples of such areas are the so-called swan necks 23, 24 at the outer ends of the front axle beam. These swan necks connect a pair of king pin supports 19, 20 with the central section 25 of the beam. In other areas, where high bending resistance is desired, the transverse ribs are retained between the opposing vertical sides of the profile. Examples of such areas are the mounting points 21, 22 for the spring elements (not shown) which are placed between the vehicle chassis and the front axle beam. Such spring elements can be, for example, air bellows. In addition to the shaping of the cross-section of the blank 1, there is also initiated a horizontal and vertical deformation to provide the beam with the desired width and vertical height, also called the drop, along its length. As seen in the dividing plane of the dies, this shaping gives the blank a varying height as measured in the vertical plane and a varying distance from a horizontal plane through the outer ends of the blank 1. Relative to said dividing plane, the greatest vertical height of the finished beam and the greatest distance from the horizontal plane coincide with the beam mountings for spring elements. The horizontal dividing plane of the dies will thus coincide with a vertical plane through a joined hollow front axle beam in the position in which the beam is intended to be used.
In the subsequent steps, the blank is moved to a second and a third forging press 8, 11 with respective upper and lower dies 9, 10; 12, 13. When the blank leaves the third forging press 11, it has been given its final shape and is ready to be joined together with a second blank 14 to a composite hollow beam.
The forging process above is described and illustrated, for the sake of clarity, as using a number of presses placed after each other. It is, of course, possible to shape the blanks in a single forging press, changing only the dies after each working step. The invention per se is not limited to any of these forging processes.
The number of steps required to obtain the desired shape of the blank can of course be varied within the scope of the invention, since the number is directly dependent on the properties of the starting material and the degree of deformation which is desired.
The second blank 14 can start from the same starting material as the first blank. The second blank can be pre-shaped and finally shaped in the same manner as the first blank 1 in a separate forging operation, and possibly in a separate press, into essentially the same profile as the first blank relative to the dividing plane of the dies.
According to a preferred embodiment, two identical blanks are manufactured, the first blank being turned to face the other so that their opposing edges are placed against each other during the joining operation. In this manner, the two blanks can be formed in the same press tool, which reduces the manufacturing cost.
In order to join the first and the second blanks 1, 14, they are led to a flash butt welding machine 15 with cooperating fixing plates or dies 16, 17, with the two blanks 1, 14 being positioned in their respective fixing plates 16, 17. Prior to working and joining, the first blank 1 and the second blank 14 must be brought into contact with each other along their respective edge surfaces.
The blanks are fixed into contact with each other and are then pressed together in a controlled manner while a welding current from a current source, such as a welding transformer, is applied to melt a controlled amount of material in the joint between the edges of the blanks. The molten material will be pressed out of the joint, and forms a flash, there being at the same time a corresponding reduction of the width of the blanks. This will be described in more detail in connection with
According to an alternative embodiment, it is also possible to heat the cooperating edges of the two blanks 1, 14 separately, before they are joined together by means of forge welding along all their surfaces where the first and second blanks are in contact with each other. The heating of the two blanks can also be effected with the aid of gas flames or the like. In connection with the forged welding together of the first and second blanks, trimming or removal of superfluous material (e.g. flash) around the edges of the workpiece can be carried out. According to an additional alternative embodiment, it is also possible to weld together the two blanks 1, 14.
When the front axle beam is finally welded together, there is a final machining phase where mounting holes are drilled for the spring elements and king pin supports are processed to their final shape and tolerance.
This preferred embodiment shows a front axle beam composed of a pair of essentially symmetrical blanks 1, 14, the vertical dividing plane X of the front axle beam running along the joint in the middle of the front axle beam. The finished front axle beam will have the same outer dimensions as a conventionally forged front axle beam, and therefore it can be mounted in an existing vehicle without the necessity of making any further modifications in the vehicle.
Alternative embodiments with dividing planes which are displaced from the vertical plane of symmetry of the front axle beam are of course also possible.
The invention is not limited to the embodiments described above but can be applied to all types of structural elements which can be manufactured with the aid of the method described above.
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