The stabilizer is used for limiting the body roll of vehicle. This body roll arises from the centrifugal forces that act on a vehicle while in motion, above all when comering. A stabilizer is a device that links the movement of the springs found on the two wheels of one and the same axle of a vehicle. The stabilizer works so that when the load on the two wheels is uneven, the one with the highest load will be given a stiffer suspension while the one with the lowest load will be given a softer suspension. This possibility of controlling the suspension of a pair of wheels enables the body roll of the vehicle to be reduced.

A stabilizer comprises a rod or tube with essentially straight middle section and angled ends. Each end is fastened to its respective wheel suspension. At or near its middle section, the stabilizer is normally fastened to the body of the vehicle in such a way that it is allowed to turn around its longitudinal axis while the means of fastening offers damping.

All vehicle manufacturers strive to limit the weight of the component parts. One problem with a stabilizer manufactured in steel is that it has a high weight. This problem has been solved by using tube instead. A tube with the same dimensions as a rod has a lower weight thanks to less mass but at the same time has a lower moment of inertia and resistance to torsion and is therefore not as strong or possesses the same characteristics.

Space is often the factor that controls the design of various components used in the manufacture of vehicles and a stabilizer must also be limited in size. To be able to use a tube instead of a rod, the tube must have a greater diameter in order to possess the same moment of inertia as a rod, which often makes the design too bulky.

The object of this invention is to offer a stabilizer with low weight and high strength and a simple and cost-cutting method of manufacturing the same.

The invention is a stabilizer possessing the characteristics specified in claim 1. The invention is also a method of manufacturing a stabilizer with the characteristics specified in claim 15.

One embodiment of the invention with respect to both the stabilizer and the method, plus further advantages of the invention and alternative designs/methods will be described below with references mad to the figures.

Fig. 1 shows a stabilizer according to the invention, fig. 2 shows one embodiment of a section of the stabilizer in accordance with the invention, fig. 3-6 show examples of the various types of cross sections of the stabilizer, which are all included in the idea of the invention, and

fig. 7 shows a flow diagram for the method according to the invention.

Fig. 1 shows a stabilizer according to the invention. The stabilizer 1 comprises a tubular element 2 with a middle section 3 and two end sections 4a and 4b and is essentially U-shaped.

The stabilizer 1 is mounted underneath a vehicle (not shown in the figure) in such a way that the longitudinal axis of the middle section A3 follows the front end of the vehicle transverse to the normal direction of travel of the vehicle (indicated with an arrow in fig. 1).

The end sections 4a and 4b point principally backward in relation to the normal direction of travel of the vehicle. The description of the stabilizer and the method uses directions and locations based on a stabilizer mounted on a vehicle.

The outer end 5a of one end section 4a is fastened to the wheel suspension (not shown in the figure) intended for one of two wheels at each end of the vehicle axle. The outer end 5b of the other end section 4b is fastened to the wheel suspension for the other wheel.

At or near its straight middle section 3, the stabilizer 1 is normally fastened to the body of the vehicle in such a way that it is allowed to turn around its longitudinal axis while the means of fastening offers damping (not shown in the figure).

Fig. 3-6 show imagined cross sections through the stabilizer perpendicular to the longitudinal plane of the stabilizer that create section surfaces of a shape where one of two vectors V1 and V2 in the plane of a section surface is longer than the other, both vectors originating from the centre of gravity of the section surface P, extending to the periphery of the tubular element and being at an angle relative to each other. Vectors V1 and V2 are principally at 90° to each other, one on the X-axis and one on the Y-axis. The origin coincides with the centre of gravity P of the various section surfaces. The section surfaces continue in some direction and their shape is oval. In this document, an oval shape means all shapes that are not round, even irregular shapes such as bean shapes, are included. The section surfaces are oval shaped both at the middle section 3 of the stabilizer and at its end sections 4a and 4b.

An oval-shaped tube provides greater resistance to torsion than a circular tube with the same outside dimensions. This means that a rod of diameter 15 mm with a certain resistance to torsion can be substituted with a tube of oval cross section with dimensions 25*15t=1. 0, where t = wall thickness of tube with retained or equivalent resistance to torsion and lower weight. The properties of an oval tube are similar to that of a plank with respect to bending. An oval tube is easy to bend downward when it is lying so that the longest vector in the oval section surface is horizontal but difficult to bend downward when the tube is lying with the longest vector in the oval section surface vertical. This is the equivalent of a plank lying flat and on its edge respectively. In view of the discussion above, the section surfaces

of the stabilizer can also be rectangular. This shape provides the same characteristics as an oval stabilizer.

The stabilizer end sections 4a and 4b are twisted in relation to the middle section 3.

The end sections 4a and 4b are twisted around their longitudinal axes/centre axes A4, a quarter of a turn to be exact, and also in relation to the longitudinal axis/centre axis of the middle section A3. In the middle section 3, the tubular element 2 is oriented so that the longest vector in the oval section surface is horizontal. In the end sections 4a and 4b, the tubular element 2 is oriented so that the longest vector in an oval section surface in these sections is vertical.

The stabilizer can also be made so that in the middle section 3, the tubular element 2 is oriented so that the longest vector in the oval section surface is vertical. In the end sections 4a and 4b, the tubular element 2 is oriented so that the longest vector in an oval section surface in these sections is horizontal.

The stabilizer end sections 4a and 4b are located at an angle in relation to the middle section 3, as is already known. The end sections 4a and 4b are, based on their longitudinal axes A4, angled/bent at an angle of a in relation to the longitudinal axis of the middle section A3. The angle/bend itself is done in the area Q where the end sections 4a and 4b are twisted in relation to the middle section 3.

As stated earlier, the size a stabilizer can be is limited. The space in which the stabilizer is mounted contains other vehicle components that directly limit the space allowed for the stabilizer. Most often, it is the vertical size, the height, of the stabilizer's middle section and the horizontal size, the breadth, of the end sections that must be limited. That the tube element 2 is oval and lying/horizontal in the middle section 3 and the end sections 4a and 4b are twisted in relation to the middle section 3 and thereby oval and standing/vertical mean that the stabilizer 1 has an appearance that fulfils these requirements. The middle section 3 is relatively low and flat and extends principally along a horizontal axis, while the end sections 4a and 4b are narrow and thin and extend principally along a vertical axis.

A stabilizer with other demands on size can also be included in the idea of the invention. A stabilizer made so that the tubular element 2 in the middle section 3 is oriented so that the longest vector in an oval section surface is this section 3 is in a vertical plane and the tubular element 2 in the end sections 4a and 4b is oriented so that the longest vector in an oval section surface in these section is in a horizontal plane naturally also fulfils other demands on size.

It is also necessary for different parts of the stabilizer to have different degrees of stiffness, above all in different directions. It is already known to use rods of different thickness in different sections along the rod and it is already known to use tubes with different wall thickness in different parts along the tube where the different sections will have

varying properties with regard to ductility and strength. However, these designs usually mean extra weight and/or variations in volume, often in areas where this is not desirable. The design according to this invention offers a stabilizer that at its ends is rigid so that the attachment of the stabilizer retains its shape.

The stabilizer 1 is manufactured of metal, hardened boron steel for example.

The stabilizer 1 can be fitted with a piece of metal/tube, a sleeve, outside the tubular element where it is both twisted and bent (see fig. 2). The sleeve 6 increases the material thickness and thereby reduces the risk of adverse deformation such as cracks and folds when the stabilizer 1 is manufactured. The sleeve 6 can be made of the same material as the rest of the stabilizer 1 and have the same shape as the tubular element 2.

The invention also concerns a method of manufacturing a stabilizer. The final stabilizer 1 comprises a tubular element 2 divided into a middle section 3 and two end sections 4a and 4b and with this method, each end section 4a and 4b is bent at an angle relative the middle section 3 so that the stabilizer 1 attains a U-shape.

A tubular element of a shape with section surfaces perpendicular to the longitudinal axis of the tubular element, both in the middle section 3 and in the end sections 4a and 4b, where one of two vectors V1 and V2 in the plane of a section surface is longer than the other, both vectors V1 and V2 originating from the centre of gravity of the section surface P, extending to the periphery of the tubular element and being at an angle relative to each other is used. Vectors V1 and V2 are located at an angle of 90° to each other.

The tubular element 2 is manufactured in metal and is shaped to form a stabilizer 1 in a thermoforming process. The material is consequently shaped after being heated. The section surfaces of the tubular element are principally oval but can also be rectangular. This shape provides the same characteristics as an oval tubular element. An oval tubular element has the advantage of being easier to bend/twist.

Shaping a tubular element 2 into a finished stabilizer 1 follows the procedure below : The tubular element end sections 4a and 4b are twisted in relation to the middle section 3, more precisely one quarter of a turn. The end sections 4a and 4b are twisted so that the side of the tubular element 2 that is to constitute the front of the stabilizer, the front surface of the stabilizer with respect to the direction of travel, forms the top of the end sections. The end sections 4a and 4b are turned so that a section surface in the tubular element 2, perpendicular to the middle section's longitudinal axis A3, has a horizontal oval shape and a section surface perpendicular to the longitudinal axes A4 of the end sections has a vertical oval shape.

The end sections 4a and 4b are bent/angled in one section Q of the tubular element 2 where the end sections 4a and 4b are twisted in relation to the middle section 3. The

twisting and bending can be done simultaneously or, altematively, the twisting can be done before the bending.

Before shaping, a piece of material/tube, a sleeve 6, is placed around the section of the tubular element 2 where the twisting and/or bending is to be done. The sleeve 6 is shrink- fitted onto the tubular element 2. The sleeve 6 increases the material thickness and thereby reduces the risk of adverse deformation such as cracks and folds when the stabilizer 1 is manufactured.

Instead of increasing the amount of material to avoid undesirable deformation, the section of the tubular element 2 where twisting and/or bending is to take place can be mechanically processed. This mechanical process can be shot peening. Shot peening means that small particles are shot against the surface of the material to generate stress on the surface, which in turn prevents the occurrence of cracks.

Shaping is followed by hardening, where the finished stabilizer 1 is cooled, principally with water, while it is still in the final shaping tool.

This description of the invention is not to be regarded as a limitation but only as an example to facilitate comprehension of the invention. Adaptations of different parts in relation to other component parts, choice of material, size adjustments, shape adjustments and everything else that is evident or presents itself immediately to a technical specialist can naturally be carried out within the idea of the invention.