Abstract: Aspects of the present disclosure are directed to a method for controlling the torque of a drive unit on a test stand. Accordingly, one embodiment of the present disclosure is a method for controlling an inner effective torque of the drive unit via a unit controlling unit, wherein an inner effective desired torque is determined from the given courses of the rotational speed and the torque of the drive unit and a known mass inertia of the drive unit, and an inner effective actual torque is determined during the operation of the drive unit on the test stand from measured values of the load machine and/or of the drive unit and/or of the connecting shaft and/or of a known mass inertia of the drive unit.

Abstract: Aspects of the present disclosure are directed to controlling an inner effective torque or an effective torque of a drive unit via a unit controlling unit. In some embodiments, the control method may include providing desired values for the inner effective torque or the effective torque and determining actual values for the inner effective torque or the effective torque during operation of the drive unit on a test stand, and in that actuating dynamics of the drive unit are taken into account in the control by means of a transfer function by correcting the desired values of the control with the transfer function or in that for controlling the inner effective torque or the effective torque of the drive unit, a feed forward control of a manipulated variable of the drive unit is used.

Abstract: A method for diagnosing a lack of coolant includes: (a) determining whether a target revolution per minute (RPM) of a coolant pump is set to be constantly maintained for a first time, which is preset, or more, (b) calculating an actual average RPM and an actual average driving current of the coolant pump for a second time, which is preset to be shorter than the first time, when the target RPM is set to be constantly maintained for the first time, and (c) determining whether the coolant to be supplied to the coolant pump is insufficient, based on the actual average RPM and the actual average driving current.

Abstract: A nacelle test apparatus for testing a wind turbine nacelle is provided. The test apparatus includes a physical tower model apparatus realized to model the behavior of a wind turbine tower and/or a physical rotor model apparatus realized to model the behavior of a wind turbine rotor, and an exciter apparatus for exciting a physical model apparatus. Also provided is a method of testing a wind turbine nacelle, which method includes mounting the nacelle onto a physical tower model apparatus of a nacelle test apparatus, which physical tower model apparatus is realized to model the behavior of a wind turbine tower, and/or mounting a physical rotor model apparatus of the nacelle test apparatus to a hub of the nacelle, which physical rotor model apparatus is realized to model the behavior of a wind turbine rotor, and exciting the physical tower model apparatus and/or the physical rotor model apparatus.

Abstract: The invention relates to a method for damping vibrations while checking a drivetrain which has at least one shaft and to a device for carrying out the method. The shaft is connected to at least one drive or load machine for adjustment of a drive or load torque, a target value of the drive or load torque being specified for said machine. A shaft torque which is dependent on the relative rotation between two points on the shaft is measured, and the measured shaft torque as such is applied to the target value of the drive or load torque.

Abstract: The invention relates to a method for predetermining a motion state (BZn+1) of a drive shaft (222) of an internal combustion engine (210) on the basis of previous motion states (BZn, BZn?2) of the drive shaft (222), wherein properties (tn?2, ?n?2) allocated to a first previous motion state (BZn?2) and properties (tn, ?n) allocated to a second previous motion state (BZn) are used and the drive shaft (222) assumes periodically recurring angular positions (?n?2, ?n, ?n+2; ?n?1, ?n+1). The invention is characterized in that a future motion state (BZn+1) and the properties (tn?1, ?n+1) allocated thereto of the drive shaft (222) are determined in an angular position on the basis of the first evaluated previous motion state (BZn?2) and the second evaluated previous motion state (BZn), wherein the angular position (?n+1) of the determined future motion state (BZn+1)of the drive shaft (222) is not equal to an angular position (?n?2, ?n) of the first and second previous motion state (BZn, BZn?2).

Abstract: The present invention relates to a dynamometer test unit for use in dynamometer testing of a vehicle, where the vehicle includes at least a first wheel shaft and at least one first vehicle power source for providing power to said first wheel shaft. Said first wheel shaft is, during testing, connected to said dynamometer test unit, said dynamometer test including: a first individually controllable dynamometer power source for applying a first power to said first wheel shaft, a second individually controllable dynamometer power source for applying a second power to said first wheel shaft, wherein—during testing, said first and said second dynamometer power source apply a controllable power to said first wheel shaft. The invention also relates to a dynamometer test system.

Abstract: The invention relates to a method for determining a rotational speed (nX) of a driveshaft (13) of an internal combustion engine (10) at at least one later point in time (tX), wherein the rotating driveshaft (13) assumes different rotary positions (PHI 11, PHI 12; PHI 21, PHI 22) at different times (t11, t12; t21, t22), wherein from at least two rotary positions (phi11, phi12; phi21, phi22) a past average rotary behaviour (m1; m2; mi) can be determined and from this an average rotational speed (nX) at at least one later point in time (tX) is inferred.

Abstract: The invention relates to a method for predetermining a motion state (BZn+1) of a drive shaft (222) of an internal combustion engine (210) on the basis of previous motion states (BZn, BZn?2) of the drive shaft (222), wherein properties (tn?2, ?n?2) allocated to a first previous motion state (BZn?2) and properties (tn, ?n) allocated to a second previous motion state (BZn) are used and the drive shaft (222) assumes periodically recurring angular positions (?n?2, ?n, ?n+2; ?n?1, ?n+1). The invention is characterized in that a future motion state (BZn+1) and the properties (tn?1, ?n+1) allocated thereto of the drive shaft (222) are determined in an angular position on the basis of the first evaluated previous motion state (BZn?2) and the second evaluated previous motion state (BZn), wherein the angular position (?n+1) of the determined future motion state (BZn+1)of the drive shaft (222) is not equal to an angular position (?n?2, ?n) of the first and second previous motion state (BZn, BZn?2).

Abstract: A driveshaft assembly that includes a first shaft member, a second shaft member, a bearing assembly and a sensor. The first shaft member has a magnetically encoded zone with a magnetic field that varies as a function of the torque that is transmitted through the first shaft member. The second shaft member is coupled for rotation with the first shaft member. The bearing assembly comprises a bearing support, which is configured to be coupled to a vehicle structure, and a bearing that is housed in the bearing support. The bearing journally supports the first shaft member for rotation about a first axis. The sensor is coupled to the bearing assembly. The sensor is arranged to sense the magnetic field of the magnetically encoded zone and responsively produce an electrical signal.

Abstract: The course of torque transmitted though a driving shaft (3) between torque generating device (1) to be tested and a driving or loading mechanism (2) is determined during an identification phase in the completely constructed test bench with the use of a rotating driving or loading mechanism (2) at pseudo-stochastic rotational speeds. Determined are thereby parameters describing in a real and current manner the dynamic behavior of the driving shaft (3) whereby the parameters are used as an influence in further testing.