Lighting device for a vehicle

The invention claimed is: 1 . A lighting device ( 1 ) for a motor vehicle, the lighting device ( 1 ) comprising: at least one light source ( 10 ) which is set up to emit light; a transparent light guide body ( 100 ); a light coupling area ( 101 ), which is set up to couple light emitted by the at least one light source ( 10 ) into the light guide body ( 100 ); and a projection optics device ( 200 ) with an optical axis (X) and a focal point (F), wherein the light guide body ( 100 ) comprises a light exit surface ( 104 ) and a lower light deflection surface ( 103 ), the lower light deflection surface ( 103 ) and the light exit surface ( 104 ) converging in a common edge ( 105 ) which runs transversely to the optical axis (X) of the projection optics device ( 200 ), wherein light emitted by the at least one light source ( 10 ) and coupled into the light guide body ( 100 ) via the light coupling region ( 101 ) propagates in the light guide body ( 100 ) to the light exit surface ( 104 ), emerges from the light guide body ( 100 ), passes through the projection device ( 200 ), and is imaged from the projection optics device ( 200 ) as a light distribution (LV) with a cut-off line (HDG) in a region in front of the projection optics device ( 200 ), the common edge ( 105 ) being imaged as a cut-off line (HDG) in the light distribution (LV), wherein at least part of the light propagating in the light guide body ( 100 ) is totally reflected at the lower light deflection surface ( 103 ) before it emerges from the light guide body ( 100 ) through the light exit surface ( 104 ), wherein the shape of the lower light deflection surface ( 103 ) deviates in a region of deviation (BER) from the shape of a base surface ( 500 ′), and wherein said region of deviation (BER) is located laterally of a longitudinal center plane (LE) of the lighting device ( 1 ), which contains the optical axis (X) of the projection optics device ( 200 ), wherein in the region of deviation (BER) the lower light deflection surface ( 103 ), deviating from the shape of the base surface ( 500 ′) is shaped in the form of a first facet ( 501 ), wherein said first facet ( 501 ) is a first surface element ( 501 ′) of the deflection surface ( 103 ) which, starting at the common edge ( 105 ) or in a defined distance from the common edge ( 105 ), extends in a direction that is away from and opposed to the direction of the optical axis (X wherein the shape of the base surface ( 500 ′) is such that in the case that the lower light deflection surface would not deviate from the shape of the base surface ( 500 ′) in form of the first facet ( 501 ), the light reflected from the base surface ( 500 ′) would be projected from the projection optics device ( 200 ) into a non-deviation region (NDV) of the light distribution (LV), wherein the non-deviation region (NDV) contains a defined point (50L) of the light distribution (LV), wherein the defined point (50L) lies below the cut-off line (HDG) of the light distribution (LV), and wherein a normal vector (n1) of the first surface element ( 501 ′) is inclined to a normal vector (n0) of the base surface ( 500 ′) in the region of deviation (BER) by an angle, the first angle (δ1), unequal to zero, wherein said first angle (δ1) is selected such that at least a portion of the light incident on the first surface element ( 501 ′) is totally reflected, strikes the projection optics device ( 200 ) and is imaged in the light distribution (LV) by the projection optics device ( 200 ) into a region (ERA), the so-called “eraser region”, which: is located below the defined point (50L), such that at least a portion of the light, which is totally reflected by the first surface element ( 501 ′), is projected into an area outside the defined point (50L) in the light distribution (LV), or contains the defined point (50L) and is located lower in the light distribution (LV) compared to the non-deviating region (NDV), such that the luminous intensity in the defined point (50L) is reduced compared to the case of the lower surface not deviating in the form of the first facet ( 501 ). 2 . The lighting device according to claim 1 , wherein in the region of deviation (BER) a second facet ( 502 ) is provided, which is a second surface element ( 502 ′) of the light deflecting surface ( 103 ), which second surface element ( 502 ) extends, adjacent to the first surface element ( 501 ′), counter to the direction of the optical axis (X), wherein the second surface element ( 502 ′) is inclined by a second angle ( 82 ) to the normal vector (n0) of the base surface ( 500 ′) in the region of deviation (BER), wherein said second angle ( 82 ) is unequal to zero, and wherein said second angle ( 82 ) is selected such that at least a portion of the light (S5″) incident on the second surface element ( 502 ′) is totally reflected, strikes the projection optics device ( 200 ) and is imaged in the light distribution (LV) by the projection optics device ( 200 ) into a region (BOO1), the so-called “booster region”, wherein said booster area (BOO1) is located below the defined point (50L) and above a non-booster region (NBO1), into which non-booster region (NBO1) light would be projected in the case that the lower light deflecting surface would not deviate in the form of the second facet ( 502 ) from the base surface ( 500 ′). 3 . The lighting device according to claim 1 , wherein at least one further facet ( 503 , 504 ) in the form surface element ( 503 ′, 504 ′) is provided laterally on at least one side of the first and/or the second surface element ( 501 ′, 502 ′). 4 . The lighting device according to claim 3 , wherein a normal vector (n3, n4) of the at least one further surface element ( 503 ′, 504 ′) is inclined by at least one further angle (δ3, δ4) to the normal vector (n0) of the base surface ( 500 ′) in the region of deviation (BER), wherein said at least one further angle (δ3, δ4) is unequal to zero, wherein the further angle (δ3, δ4) of a further surface element ( 503 ′, 504 ′) is selected such that at least a portion of the light (S5″) incident on the further surface element ( 503 ′, 504 ′) is totally reflected, passes through the projection optics device ( 200 ) and is imaged in the light distribution (LV) by the projection optics device ( 200 ) into a further region (BOO2, BOO3), the so-called “further booster region”, wherein said further booster area (BOO2, BOO3) is located above a non-booster region (NBO2, NBO3), into which non-booster region (NBO2, NBO3) light would be projected in the case that the lower light deflecting surface would not deviate in the form of the further facet ( 503 , 504 ) from the base surface ( 500 ′). 5 . The lighting device according to claim 3 , wherein the at least one further booster region (BOO2, BOO3) is located to the side of the defined point (50L) and does not contain said defined point (50L). 6 . The lighting device according to claim 3 , wherein at least one further facet ( 503 , 504 ) is provided on each side of the first and/or the second facet ( 501 , 502 ), wherein said further facets ( 503 , 504 ) have identical orientation. 7 . The lighting device according to claim 1 , wherein at least one of the first facet, the second facet, or the at least one further facet ( 501 , 502 , 503 , 504 ) is in the form of a planar surface element ( 501 ′, 502 ′, 503 ′, 504 ′). 8 . The lighting device according to claim 1 , wherein the light guide body ( 100 ) comprises an upper light deflection surface ( 102 ), and wherein at least a part of the light emitted by the at least one light source ( 10 ) and coupled into the light guide body ( 100 ) via the light coupling region ( 101 ) is totally reflected at the upper light deflection surface ( 102 )