Fixed-displacement hydraulic motor with externally specified mechanical and volumetric efficiencies
Pumps and Motors
The Fixed-Displacement Motor (External Efficiencies) block represents a fixed-displacement hydraulic motor with both mechanical and volumetric efficiencies provided through the external physical signal ports. Hydraulic losses are implemented as a leakage between hydraulic ports, while mechanical losses are introduced through the friction imposed on the driving shaft. Both the leakage and the friction are determined by the efficiency values. The ideal hydraulic motor is described with the following equations:
|qid||Ideal volumetric flow rate|
|p||Pressure differential across the motor|
When accounting for mechanical and hydraulic losses, the flow rate through the motor is increased by the leakage value
and output torque becomes lower due to mechanical losses simulated with the friction torque
|qleak||Leakage flow through the motor|
For numerical stability purposes, the friction torque is implemented as
where ωth is
the threshold angular velocity, a parameter that specifies how steeply
tanh function changes in the vicinity of zero
Connections A and B are hydraulic conserving ports associated with the motor inlet and outlet, respectively. Connection S is a mechanical rotational conserving port associated with the motor shaft. Physical signal ports EV and EM import volumetric and mechanical efficiencies, respectively. Use a separate block to compute these efficiencies. The block positive direction is from port A to port B. This means that the flow rate flowing through the motor from A to B rotates the shaft in positive direction, and positive pressure differential creates positive torque at the motor shaft.
Fluid compressibility is neglected.
Hydraulic loss is simulated as leakage through the motor.
Mechanical loss is represented with the friction torque applied to the motor shaft.
Motor displacement. The default value is
This parameter specifies how steeply the
changes in the vicinity of zero velocity. It is introduced to avoid
sharp change in the friction torque. The default value is
The block has the following ports:
Hydraulic conserving port associated with the motor inlet.
Hydraulic conserving port associated with the motor outlet.
Mechanical rotational conserving port associated with the motor shaft.
Physical signal port that imports the motor volumetric efficiency.
Physical signal port that imports the motor mechanical efficiency.