Information

This information is part of the Modelica Standard Library maintained by the Modelica Association.

This model demonstrates how to model the dissipated power of a Translational model, by enabling the heatPort of all components and connecting these heatPorts via a convection element to the environment. The total heat flow generated by the elements and transported to the environment is present in variable convection.fluid.

Components (19)

	mass1	Type: Mass Description: Sliding mass with inertia
	springDamper	Type: SpringDamper Description: Linear 1D translational spring and damper in parallel
	damper	Type: Damper Description: Linear 1D translational damper
	elastoGap	Type: ElastoGap Description: 1D translational spring damper combination with gap
	fixed1	Type: Fixed Description: Fixed flange
	force	Type: Force Description: External force acting on a drive train element as input signal
	sine1	Type: Sine Description: Generate sine signal
	mass2	Type: Mass Description: Sliding mass with inertia
	supportFriction	Type: SupportFriction Description: Coulomb friction in support
	spring	Type: Spring Description: Linear 1D translational spring
	mass3	Type: Mass Description: Sliding mass with inertia
	brake	Type: Brake Description: Brake based on Coulomb friction
	sine2	Type: Sine Description: Generate sine signal
	massWithStopAndFriction	Type: MassWithStopAndFriction Description: Sliding mass with hard stop and Stribeck friction
	convection	Type: Convection Description: Lumped thermal element for heat convection (Q_flow = Gc*dT)
	const	Type: Constant Description: Generate constant signal of type Real
	TAmbient	Type: FixedTemperature Description: Ambient temperature
	fixed2	Type: Fixed Description: Fixed flange
	springDamper1	Type: SpringDamper Description: Linear 1D translational spring and damper in parallel

HeatLosses

Diagram

Wolfram Language

Information

Components (19)