Monitoring a hydrodynamic clutch

What is claimed is: 1. A method for determining a fill level of a hydrodynamic clutch with a hydraulic fluid, the clutch including an input side and an output side, rotational motions of the input side and the output side being coupled to one another by the hydraulic fluid, the method comprising the steps of: periodical sensing of a fluid temperature of the hydraulic fluid; determining a thermal output supplied to the clutch using the fluid temperature; determining a lambda value using the thermal output; determining the fill level using the lambda value; and determining a power supplied to the clutch, the step of determining the power supplied to the clutch including the sub-steps of: determining a maximum permissible temperature of the clutch; determining an ambient temperature of an area surrounding the clutch; and determining a power that is being transferred via the clutch using the fluid temperature and the ambient temperature. 2. The method according to claim 1 , wherein the method includes the step of determining a remaining life span of the hydraulic fluid, the step of determining the remaining life span of the hydraulic fluid including: determining loads on the hydraulic fluid using the fluid temperature and the ambient temperature; determining a sum of the loads; and determining the remaining life span using the sum. 3. The method according to claim 1 , wherein the method is carried out using a computer program running on a processor or stored on a computer-readable data medium having a program code. 4. A method for determining a fill level of a hydrodynamic clutch with a hydraulic fluid, the clutch including an input side and an output side, rotational motions of the input side and the output side being coupled to one another by the hydraulic fluid, the method comprising the steps of: periodical sensing of a fluid temperature of the hydraulic fluid; determining a thermal output supplied to the clutch using the fluid temperature; determining a lambda value using the thermal output; determining the fill level using the lambda value; and determining a remaining life span of an antifriction bearing for mounting of the input side relative to the output side, the step of determining the remaining life span of the antifriction bearing including the sub-steps of: determining loads on the antifriction bearing using the fluid temperature; determining a sum of the loads; and determining the remaining life span using the sum. 5. The method according to claim 4 , further comprising a step of determining an increase in a speed differential of the antifriction bearing from a standstill to a rated speed thereby defining a start, and determining the remaining life span of the antifriction bearing dependent upon a frequency of the starts. 6. The method according to claim 4 , further comprising a step of determining a slippage between the input side and the output side thereby defining a slippage factor, and calculating the remaining life span of the antifriction bearing dependent upon the slippage factor. 7. A control unit for determining an operating status of a hydrodynamic clutch, having an input side and an output side, rotational motions of the input side and the output side being coupled to one another by a hydraulic fluid, the control unit comprising: an interface for connecting with a temperature sensor equipped for periodic sensing of a temperature of the hydraulic fluid; and a processor arranged for determining a thermal output supplied to the clutch using the temperature of the hydraulic fluid, determining a lambda value using the thermal output, and determining a fill level using the lambda value the processor additionally executing a method that includes the step of determining a power supplied to the clutch, the step of determining the power supplied to the clutch including the sub-steps of: determining a maximum permissible temperature of the clutch; determining an ambient temperature of an area surrounding the clutch; and determining a power that is being transferred via the clutch using the fluid temperature and the ambient temperature. 8. A clutch system comprising: a hydrodynamic clutch having an input side and an output side, rotational motions of the input side and the output side being coupled to one another by a hydraulic fluid; a temperature sensor equipped for periodic sensing of a temperature of the hydraulic fluid; and a control unit for determining an operating status of the hydrodynamic clutch, the control unit comprising: an interface for connecting with the temperature sensor; and a processor arranged for determining a thermal output supplied to the clutch using the temperature of the hydraulic fluid, determining a lambda value using the thermal output, and determining a fill level using the lambda value; the processor additionally executing a method that includes the step of determining a power supplied to the clutch, the step of determining the power supplied to the clutch including the sub-steps of: determining a maximum permissible temperature of the clutch; determining an ambient temperature of an area surrounding the clutch; and determining a power that is being transferred via the clutch using the fluid temperature and the ambient temperature.