Method for operating a test bench in order to determine a torque and a speed

The invention claimed is: 1. Method for operating a test bench with a test object having at least two rotating masses which are connected in a rotationally fixed manner and each have a mass moment of inertia (J1, J2), with at least one of the at least two rotating masses being connected by means of a loading shaft to a loading machine for driving or loading the test object, the loading machine being controlled by a loading machine control unit, the method including the following steps: applying loads to the test object on the test bench, estimating an internal test object torque (MP_int) and based upon the internal test object torque, determining a target loading machine speed (NB_soll) that is adjusted by the loading machine control unit, determining a shaft torque (MW) acting in the loading shaft for the loading shaft, determining acceleration torques (MB 1 , MB 2 ) for accelerating the at least two rotating masses, adding the shaft torque with the correct sign to the acceleration torques, to form a corrected internal effective test object torque (MP_int_korr), and determining the target loading machine speed (NB_soll) from the corrected internal effective test object torque (MP_int_korr) or a torque derived therefrom (, , ,), a specified target test object torque (MW_soll) and from the mass moments of inertia (J 1 , J 2 ) or simulated mass moments of inertia (J 1 _sim, J 2 _sim) of the at least two rotating masses. 2. The method according to claim 1 , further comprising measuring the shaft torque (MW) acting in the loading shaft by means of a torque measuring device on the loading shaft. 3. The method according to claim 1 , wherein the at least two rotating masses, which are connected in a rotationally fixed manner are formed by a dual-mass flywheel and/or in that the at least two rotating masses, which are connected in a rotationally fixed manner, are connected by a connecting shaft, a belt or a chain. 4. The method according to claim 1 , further comprising: determining the target loading machine speed (NB_soll) by adding the corrected internal effective test object torque (MP_int_korr) and the specified target test object torque (MW_soll), with the correct sign, to form a first differential torque (MP_Diff) and multiplying the first differential torque (MP_Diff) by the reciprocal of a sum of the mass moments of inertia (J 1 , J 2 ) or simulated mass moments of inertia (J 1 _sim, J 2 _sim) of the at least two rotating masses and integrate over time. 5. The method according to claim 1 , further comprising: determining the target loading machine speed (NB_soll) by adding the specified target test object torque (MW_soll), a simulated connecting element torque (MVW_sim) of a virtual connecting element that represents the rotationally fixed connection of the at least two rotating masses and an estimated internal torque ( ) of the second rotating mass of the at least two rotating masses connected to the loading shaft ( 6 ), with the correct sign, to form a third differential torque (M″P_Diff) and multiplying the third differential torque (M″P_Diff) by the reciprocal of the mass moment of inertia (J 2 ) or a simulated mass moment of inertia (J 2 _sim) of the second rotating mass connected to the loading shaft and integrate over time, the at least one simulated connecting element torque (MVW_sim) being determined from the mass moment of inertia (J 1 ) or a simulated mass moment of inertia (J 1 _sim) of the first rotating mass of the at least two rotating masses, from the fed-back target loading machine speed (NB_soll), from mechanical properties of the virtual connecting element and from an estimated internal torque of the first rotating mass which is formed from a sum, with the correct sign, of the corrected internal effective test object torque (MP_int_korr) and an estimated internal torque ( ) of the second rotating mass connected to the loading shaft. 6. The method according to claim 1 , that further comprising: determining the target loading machine speed (NB_soll) by adding the specified target test object torque (MW_soll), at least one simulated connecting element torque (MVW_sim) of a virtual connecting element that represents the rotationally fixed connection of the at least two rotating masses and an oscillating estimated internal torque ( ) of a second rotating mass of the at least two rotating masses connected to the loading shaft ( 6 ), with the correct sign, to form a fourth differential torque (M′″P_Diff) and multiplying the fourth differential torque (M′″P_Diff) by the reciprocal of the mass moment of inertia (J 2 ) or a simulated mass moment of inertia (J 2 _sim) of the second rotating mass connected to the loading shaft and integrate over time, the at least one simulated connecting element torque (MVW_sim) being determined from the mass moment of inertia (J 1 ) or a simulated mass moment of inertia (J 1 _sim) of a first mass of the at least two rotating masses, from the fed-back target loading machine speed (NB_soll), from mechanical properties of the virtual connecting element and from an estimated average internal torque of the first rotating mass which is formed by a filtered sum, with the correct sign, of the corrected internal effective test object torque (MP_int_korr) and the estimated internal torque ( ) of the second rotating mass connected to the loading shaft, the oscillating estimated internal torque ( ) of the second rotating mass connected to the loading shaft being formed from a sum, with the correct sign, of the corrected internal effective test object torque (MP_int_korr) and the estimated average internal torque of the first rotating mass. 7. The method according to claim 1 , wherein at least one of the at least two rotating masses is a torque generator controlled by means of a test object control unit. 8. The method according to claim 7 , wherein the torque generator is an internal combustion engine controlled by an internal combustion engine control unit, or an electric motor controlled by an electric motor control unit. 9. The method according to claim 1 , further comprising: determining the acceleration torque (MB 1 , MB 2 ) of at least one rotating mass of the at least two rotating masses from a speed (N 1 , N 2 ) of the relevant rotating mass and from the mass moment of inertia (J 1 , J 2 ) of the relevant rotating mass. 10. The method according to claim 9 , further comprising: measuring the speed (N 1 , N 2 ) of the at least one rotating mass of the at least two rotating masses for which the acceleration torque (MB 1 , MB 2 ) is measured, by means of a speed measuring device on the test bench. 11. The method according to claim 10 , further comprising: filtering the measured speed (N 1 , N 2 ), an angular acceleration calculated therefrom or at least one acceleration torque (MB 1 , MB 2 ) by means of a filter. 12. The method according to claim 1 , further comprising: determining the target loading machine speed (NB_soll) by adding the corrected internal effective test object torque (MP_int_korr), the specified target test object torque (MW_soll) and at least one simulated connecting element torque (MVW_sim) of a virtual connecting element that represents the rotationally fixed connection of the at least two rotating masses (1, 2), with the correct sign, to form a second differential torque (M′P_Diff) and multiplying the second differential torque (M′P_Diff) by the reciprocal of the mass moment of inertia (J 2 ) or a simulated mass moment of inertia (J 2 _sim) of the second rotating mass of the at least two rotating masses connected to the loading shaft and integrate over time, the at least one simulated connecting element torque (MVW_sim)