Stabilizer for a motor vehicle and method for producing the same

1 - 17 . (canceled) 18 . A method of producing a stabilizer ( 10 ) of a motor vehicle such that the stabilizer includes a torsion bar ( 11 ) and longitudinal links ( 12 , 13 ), and the longitudinal links ( 12 , 13 ) being, in each case, connected to the torsion bar ( 11 ) by welding, the method comprising: heat-treating the longitudinal links ( 12 , 13 ) and the torsion bar ( 11 ) before welding and, after the heat treatment, welding the longitudinal links to the torsion bar welding each longitudinal link ( 12 , 13 ) at one end to the torsion bar ( 11 ) on both sides, in each case, by respective multilayer weld seams ( 14 ), and making each of the weld seams ( 14 ) with unequal widths such that a width of the weld seam ( 14 ) adjacent to the torsion bar ( 11 ) is shorter than a width of the weld seam adjacent to the respective longitudinal link ( 12 , 13 ). 19 . The method according to claim 18 , further comprising making each of the weld seams ( 14 ) with unequal widths such that a ratio (X=I/L) between the width (I) of the respective weld seam ( 14 ) adjacent to the torsion bar ( 11 ) and the width (L) of the weld seam ( 14 ) adjacent to the longitudinal link ( 12 , 13 ) concerned has a value of between 0.36 and 0.8. 20 . The method according to claim 19 , further comprising making each of the weld seams such that the ratio (X=I/L) between the width (I) of the respective weld seam ( 14 ) adjacent to the torsion bar ( 11 ) and the width (L) of the weld seam ( 14 ) adjacent to the longitudinal link ( 12 , 13 ) concerned has a value of between 0.5 and 0.8. 21 . The method according to claim 20 , further comprising making each of the weld seams such that the ratio (X=I/L) between the width (I) of the respective weld seam ( 14 ) adjacent to the torsion bar ( 11 ) and the width (L) of the weld seam ( 14 ) adjacent to the longitudinal link ( 12 , 13 ) concerned has a value of between 0.6 and 0.7. 22 . The method according to claim 18 , further comprising making each of the weld seams ( 14 ) with a root layer ( 15 ), at least one intermediate layer ( 16 ) and a covering layer ( 17 ), such that the root layer ( 15 ), the at least one intermediate layer ( 16 ) and the covering layer ( 17 ) are produced using individual welding parameters. 23 . The method according to claim 22 , further comprising producing each of the root layer ( 15 ), the at least one intermediate layer ( 16 ) and the covering layer by metal-active-gas welding such that the resulting weld seam has a hardness between 200 and 300 HV1 both in a weld metal area and in a heat-affected zone. 24 . The method according to claim 23 , further comprising operating a fixed welding torch with a welding current between 240 and 340 amperes and a welding voltage between 29 and 33 volts, and moving the longitudinal links and the torsion bar to be welded relative to the fixed welding torch at a speed between 0.30 and 0.50 m/min to produce the root layer ( 15 ). 25 . The method according to claim 24 , further comprising operating the fixed welding torch with a welding current between 230 and 340 amperes and a welding voltage between 28 and 31 volts, and moving the longitudinal links and the torsion bar to be welded relative to the fixed welding torch at a speed between 0.25 and 0.40 m/min, and the welding torch undergoing an oscillation movement of relatively small amplitude perpendicularly to the movement of the longitudinal links and the torsion bar to produce the at least one intermediate layer ( 16 ). 26 . The method according to claim 25 , further comprising operating the fixed welding torch with a welding current between 210 and 315 amperes and a welding voltage between 27 and 31 volts, and moving the longitudinal links and the torsion bar to be welded relative to the fixed welding torch at a speed between 0.20 and 0.55 m/min, and the welding torch undergoing an oscillation movement of relatively large amplitude perpendicularly to the movement of the longitudinal links and the torsion bar to produce the covering layer ( 17 ). 27 . The method according to claim 22 , further comprising interposing a welding interval of between 20 and 120 seconds between the welding of the root layer ( 15 ), the at least one intermediate layer ( 16 ) and the covering layer ( 17 ). 28 . The method according to claim 18 , further comprising preheating the longitudinal links ( 12 , 13 ) and the torsion bar ( 11 ) to a temperature of between 120° and 150° C. immediately before welding. 29 . The method according to claim 18 , further comprising subjecting the longitudinal links ( 12 , 13 ) and the torsion bar ( 11 ) to a shot peening treatment after welding thereof to increase a strength thereof. 30 . The method according to claim 18 , further comprising using an alloy containing at least manganese, nickel and molybdenum as a welding filler. 31 . A stabilizer ( 10 ) for a motor vehicle, the stabilizer comprising: a torsion bar ( 11 ) and longitudinal links ( 12 , 13 ), the longitudinal links ( 12 , 13 ) being connected to the torsion bar ( 11 ) in each case by welding, each of the longitudinal links ( 12 , 13 ) being welded to a section of the torsion bar ( 11 ) on both sides by a respective multilayer weld seam ( 14 ), and each weld seam ( 14 ) being made with unequal widths such that a width of the respective weld seam ( 14 ) adjacent to the torsion bar ( 11 ) is shorter than its width adjacent to the longitudinal link ( 12 , 13 ) concerned. 32 . The stabilizer according to claim 31 , wherein a ratio (X=I/L) between the width (I) of each weld seam ( 14 ) adjacent to the torsion bar ( 11 ) and the width (L) of the weld seam ( 14 ) adjacent to the longitudinal link ( 12 , 13 ) concerned has a value between 0.36 and 0.8. 33 . The stabilizer according to claim 31 , wherein at least a covering layer ( 17 ) of the respective weld seam ( 14 ) merges tangentially into the torsion bar ( 11 ) and also tangentially into the longitudinal link ( 12 , 13 ) concerned. 34 . The stabilizer according to claim 31 , wherein each of the weld seams is made with a root layer ( 15 ), at least one intermediate layer ( 16 ) and a covering layer ( 17 ), and the root layer ( 15 ), the at least one intermediate layer ( 16 ) and the covering layer ( 17 ) are made such that the weld seam ( 14 ) concerned has in each case a hardness between 200 and 300 HV1 both in a weld material area and also in a heat-affected zone. 35 . A method of producing a motor vehicle stabilizer that includes a torsion bar and first and second longitudinal links, the first and the second longitudinal links are each connected to the torsion bar by welding, the method comprising: heat-treating the first and the second longitudinal links and the torsion bar before welding the first and the second longitudinal links to the torsion bar, each of the first and the second longitudinal links has an inner side and an opposite outer side and the torsion bar has opposed first and second ends; welding the first end of the torsion bar to the first longitudinal link with a multilayer weld seam formed on each of the inner and the outer sides of the first longitudinal link, and welding the second end of the torsion bar to the second longitudinal link with a multilayer weld seam formed on each of the inner and the outer sides of the second longitudinal link; forming the multilayer weld seam between the first end of the torsion bar and the outer side of the first longitudinal link such that a width of the multilayer weld seam along the torsion bar is shorter t