Telescopic steering shaft with a pull-out safeguard

What is claimed is: 1. A steering shaft for a motor vehicle, comprising: an outer shaft, and an inner shaft disposed in the outer shaft in a torque-locking and axially displaceable manner, the inner shaft having an axial inner stop that projects radially outwards from an outer face of the inner shaft and which, when the inner shaft is pulled out of the outer shaft, is positioned to strike against an axial outer stop that projects radially inwards from an inner face of the outer shaft to delimit the travel of the inner shaft in the outer shaft in a pull-out direction, wherein the axial outer stop is disposed at a front face and an outer periphery of the outer shaft, wherein at least one planar surface of the axial inner stop projects towards an axial end of the outer shaft through which the inner shaft extends. 2. A steering shaft for a motor vehicle, comprising: an outer shaft, and an inner shaft disposed in the outer shaft in a torque-locking and axially displaceable manner, the inner shaft having an axial inner stop that projects radially outwards from an outer face of the inner shaft and which, when the inner shaft is pulled out of the outer shaft, is positioned to strike against an axial outer stop that projects radially inwards from an inner face of the outer shaft to delimit the travel of the inner shaft in the outer shaft in a pull-out direction, wherein the axial outer stop is disposed at a front face and an outer periphery of the outer shaft, wherein at the axial outer stop the front face of the outer shaft is disposed at an angle of at least 20° but less than 80° relative to a radial direction of the outer shaft. 3. A steering shaft comprising: an outer shaft; an inner shaft disposed in the outer shaft in a torque-locking and axially displaceable manner, the inner shaft having an axial inner stop that projects radially outwards from an outer face of the inner shaft and which, when the inner shaft is pulled out of the outer shaft, is positioned to strike against an axial outer stop that projects radially inwards from an inner face of the outer shaft to delimit the travel of the inner shaft in the outer shaft in a pull-out direction; and an overmolding comprised of plastic disposed on an outer surface of the inner shaft, wherein the overmolding cooperates with a longitudinal toothing of the outer shaft, wherein on an outer periphery of the outer shaft the axial outer stop projects away from a longitudinal axis of the outer shaft such that two surfaces of the axial outer stop form an acute angle relative to one another. 4. A method for producing a pull-out safeguard of a steering shaft that includes an outer shaft and an inner shaft disposed in the outer shaft in a torque-locking and axially displaceable manner, the inner shaft having an axial inner stop that projects radially outwards from an outer face of the inner shaft and which, when the inner shaft is pulled out of the outer shaft, is positioned to strike against an axial outer stop that projects radially inwards from an inner face of the outer shaft to delimit the travel of the inner shaft in the outer shaft in a pull-out direction, wherein the axial outer stop is disposed at a front face and an outer periphery of the outer shaft, the method comprising: forming, on the inner shaft, the axial inner stop, inserting the inner shaft into the outer shaft, and forming with a first forming tool after said inserting step, on the outer shaft, the axial outer stop, wherein the axial outer stop is introduced by a forming process into an end portion of the outer shaft in a direction, wherein an axis of the direction of introduction forms an angle of more than 20° but less than 80° relative to a radial direction of the outer shaft. 5. The method of claim 4 , including forming two outer stops arranged in a peripheral direction at a spacing of 180° onto the outer shaft. 6. The method of claim 4 , wherein the first forming tool acts on a front face of the outer shaft, wherein the axis of the direction of introduction is located in a plane enclosing a rotational axis of the outer shaft. 7. The method of claim 4 wherein the first forming tool acts on an outer periphery of the outer shaft, wherein the axis of the direction of introduction is located in a plane enclosing a rotational axis of the outer shaft. 8. The method of claim 4 wherein the first forming tool acts on a region of the outer shaft enclosing an outer periphery and a front face of the outer shaft, wherein the axis of the direction of introduction is located in a plane enclosing a rotational axis of the outer shaft.