Method for determining a contact force on a utility vehicle

The invention claimed is: 1. A method for determining a contact force on a utility vehicle having a suspended front wheel axle with a left front wheel and a right front wheel and an unsuspended rear wheel axle with a left rear wheel and a right rear wheel, comprising: determining a total drive force of a drive train of the utility vehicle; determining a left front drive force of the left front wheel and a right front drive force of the right front wheel based on a torque measurement at the front wheel axle; determining a rear drive force of the rear wheel axle based on the total drive force and the front drive force; determining a left front contact force of the left front wheel and a right front contact force of the right front wheel based on a sum of a spring force at the front wheel axle measured by a sensor and the weight force of the unsuspended axle mass with respect to the front axle; determining a left front traction coefficient for the left front wheel based upon the left front drive force and the left front contact force; determining a right front traction coefficient for the right front wheel based upon the right front drive force and the right front contact force; determining a left front drive slip of the left front wheel based on a speed of the utility vehicle, an rpm of the left front wheel, and a rolling radius of the left front wheel; determining a right front drive slip of the right front wheel based on the speed of the utility vehicle, an rpm of the right front wheel, and a rolling radius of the right front wheel; determining a left rear drive slip of the left rear wheel based on the speed of the utility vehicle, an rpm of the left rear wheel, and a rolling radius of the left rear wheel; determining a right rear drive slip of the right rear wheel based on the speed of the utility vehicle, an rpm of the right rear wheel, and a rolling radius of the right rear wheel; determining a left front base characteristic curve for the left front wheel, the left front base characteristic curve representing the left front traction coefficient as a function of the left front drive slip; determining a right front base characteristic curve for the right front wheel, the right front base characteristic curve representing the right front traction coefficient as a function of the right front drive slip; deriving a left rear determination characteristic curve for the left rear wheel from the left front base characteristic curve and a right rear determination characteristic curve for the right rear wheel from the right front base characteristic curve based on at least one of the speed of the utility vehicle, a steering status of the utility vehicle, a driving track of the front wheels, a driving track of the rear wheels, the rolling radius of the front wheels, and the rolling radius of the rear wheels; determining a left rear contact force of the left rear wheel as a function of the left rear drive slip according to the left rear determination characteristic curve; and determining a right rear contact force of the right rear wheel as a function of the right rear drive slip according to the right rear determination characteristic curve; wherein an all-wheel clutch is actuated as a function of the determined front and rear contact forces. 2. The method of claim 1 , wherein the rolling radius of the front wheels is different from the rolling radius of the rear wheels. 3. The method of claim 1 , wherein the rolling radius of the front wheels is smaller than the rolling radius of the rear wheels. 4. The method of claim 1 , wherein deriving the left rear determination characteristic curve and the right rear determination characteristic curve is based on the speed of the utility vehicle, the steering status of the utility vehicle, the driving track of the front wheels, the driving track of the rear wheels, the rolling radius of the front wheels, and the rolling radius of the rear wheels. 5. The method of claim 1 , wherein the rear determination characteristic curves are the same as the respective front base characteristic curves when the rear wheels use a different driving track than the front wheels. 6. The method of claim 1 , wherein the rear determination characteristic curves are adjusted from the front base characteristic curves when the rear wheels use the same driving track as the front wheels. 7. The method of claim 1 , further comprising: actuating the all-wheel clutch as a function of the determined front and rear contact forces; transferring a torque from one of the wheel axles to another of the wheel axles via the all-wheel clutch; controlling the all-wheel clutch so that the transferred torque does not exceed a predefined maximum torque; and determining the maximum torque in dependence on a maximum braking torque. 8. The method of claim 7 , further comprising: determining the maximum braking torque dependent on a maximum traction coefficient. 9. The method of claim 8 , further comprising: determining the maximum traction coefficient from maximum values of the front base characteristic curves and the rear determination characteristic curves. 10. A method for determining a contact force on a utility vehicle having a suspended front wheel axle with a left front wheel and a right front wheel and an unsuspended rear wheel axle with a left rear wheel and a right rear wheel, comprising: determining a total drive force of a drive train of the utility vehicle; determining a left front drive force of the left front wheel and a right front drive force of the right front wheel based on a torque measurement at the front wheel axle; determining a rear drive force of the rear wheel axle based on the total drive force and the front drive force; determining a left front contact force of the left front wheel and a right front contact force of the right front wheel based on a sum of a spring force at the front wheel axle measured by a sensor and the weight force of the unsuspended axle mass with respect to the front axle; determining a left front traction coefficient for the left front wheel based upon the left front drive force and the left front contact force; determining a right front traction coefficient for the right front wheel based upon the right front drive force and the right front contact force; determining a left front drive slip of the left front wheel based on a speed of the utility vehicle, an rpm of the left front wheel, and a rolling radius of the left front wheel; determining a right front drive slip of the right front wheel based on the speed of the utility vehicle, an rpm of the right front wheel, and a rolling radius of the right front wheel; determining a left rear drive slip of the left rear wheel based on the speed of the utility vehicle, an rpm of the left rear wheel, and a rolling radius of the left rear wheel; determining a right rear drive slip of the right rear wheel based on the speed of the utility vehicle, an rpm of the right rear wheel, and a rolling radius of the right rear wheel; determining a left front base characteristic curve for the left front wheel, the left front base characteristic curve representing the left front traction coefficient as a function of the left front drive slip; determining a right front base characteristic curve for the right front wheel, the right front base characteristic curve representing the right front traction coefficient as a function of the right front drive slip; deriving a left rear determination characteristic curve for the left rear wheel from the left front base characteristic curve and a right rear determination characteristic curve for the right rear wheel from the right front base characteristic curve based on at leas