Steel brake piston for a hydraulic brake

The invention claimed is: 1. A cold-formed steel brake piston for a hydraulic disk brake, constructed as a pot which is open on one side comprising: a base, and a wall including an inner wall and an outer wall, having a directed substantially rotational symmetry with respect to a piston longitudinal axis (A) and with a wall thickness (s) varied in sections with a differently varied inner diameter (di), wherein the wall sections, which are formed in a directional manner by ironing substantially parallel to the piston longitudinal axis (A), adjoin the base configured orthogonally, wherein the outer wall has, on an end-side wall section, a radially inwardly groove which is open in a radially outward direction and which forms, radially at the inside, a groove bead projection, wherein the open side of the pot ends as a bearing for a friction pad backplate, and the bearing extends as a planar piston end surface orthogonally with respect to the piston longitudinal axis (A), and having integrated interfaces which serve a) for the fixing between friction pad and steel brake piston and b) as support bearing for spring mounting of the friction pad, wherein, proceeding from the piston end surface, a minimum piston inner diameter (d imin ) is axially set back in the direction of the base by a multiple of a minimum piston wall thickness (s min ), and the minimum piston inner diameter (d imin ) is formed by the groove bead projection, wherein a quotient of a wall thickness (s b ) of the base in relation to the minimum piston wall thickness (s min ) of a base-side wall section, (s b /s min ), is provided so as to have a value of 1.4-2.1, and wherein the end-side wall section has a uniform inner diameter between the piston end surface and the groove bead projection. 2. The cold-formed steel brake piston as claimed in claim 1 , wherein the minimum piston inner diameter (d imin ), projected in a axial direction (ax), is provided so as to be offset radially inward in relation to the piston end surface. 3. The cold-formed steel brake piston as claimed in claim 1 , wherein the groove bead projection connects the two differently stepped, and cylindrically formed, wall sections to one another. 4. The cold-formed steel brake piston as claimed in claim 1 , wherein the end-side wall section has a smaller piston inner diameter d i than the base-side wall section, and wherein the groove bead projection defines the minimum piston inner diameter (d imin ). 5. The cold-formed steel brake piston as claimed in claim 1 , wherein the base-side wall section has a reduced wall thickness (s) in relation to the end-side wall section. 6. The cold-formed steel brake piston as claimed in claim 1 , wherein the base-side wall section has a radially outwardly directed groove which is provided with axial spacing to the groove bead projection. 7. A cold-formed steel brake piston for a hydraulic disk brake, constructed as a pot which is open on one side comprising: a base, and a wall including an inner wall and an outer wall, having a directed substantially rotational symmetry with respect to a piston longitudinal axis (A) and with a wall thickness (s) varied in sections with a differently varied inner diameter (di), wherein the wall sections, which are formed in a directional manner by ironing substantially parallel to the piston longitudinal axis (A), adjoin the base configured orthogonally, wherein the outer wall has, on an end-side wall section, a radially inwardly groove which is open in a radially outward direction and which forms, radially at the inside, a groove bead projection, wherein the open side of the pot ends as a bearing for a friction pad backplate, and the bearing extends as a planar piston end surface orthogonally with respect to the piston longitudinal axis (A), and having integrated interfaces which serve a) for the fixing between friction pad and steel brake piston and b) as support bearing for spring mounting of the friction pad, wherein, proceeding from the piston end surface, a minimum piston inner diameter (d imin ) is axially set back in the direction of the base by a multiple of a minimum piston wall thickness (s min ), and the minimum piston inner diameter (d imin ) is formed by the groove bead projection, wherein a quotient of a wall thickness (s b ) of the base in relation to the minimum piston wall thickness (s min ) of a base-side wall section, (s b /s min ), is provided so as to have a value of 1.4-2.1, and wherein a diameter difference between the minimum inner diameter (d imin ) and a maximum inner diameter (d imax ) is at least approximately 2 mm. 8. A cold-formed steel brake piston for a hydraulic disk brake, constructed as a pot which is open on one side comprising: a base, and a wall including an inner wall and an outer wall, having a directed substantially rotational symmetry with respect to a piston longitudinal axis (A) and with a wall thickness (s) varied in sections with a differently varied inner diameter (di), wherein the wall sections, which are formed in a directional manner by ironing substantially parallel to the piston longitudinal axis (A), adjoin the base configured orthogonally, wherein the outer wall has, on an end-side wall section, a radially inwardly groove which is open in a radially outward direction and which forms, radially at the inside, a groove bead projection wherein the open side of the pot ends as a bearing for a friction pad backplate, and the bearing extends as a planar piston end surface orthogonally with respect to the piston longitudinal axis (A), and having integrated interfaces which serve a) for the fixing between friction pad and steel brake piston and b) as support bearing for spring mounting of the friction pad, wherein, proceeding from the piston end surface, a minimum piston inner diameter (d imin ) is axially set back in the direction of the base by a multiple of a minimum piston wall thickness (s min ), and the minimum piston inner diameter (d imin ) is formed by the groove bead projection, wherein a quotient of a wall thickness (s b ) of the base in relation to the minimum piston wall thickness (s min ) of a base-side wall section, (s b /s min ), is provided so as to have a value of 1.4-2.1, and wherein an elongated length of the end-side wall section amounts to at least approximately 5 mm.