.IBPSA.Fluid.Interfaces.UsersGuide

Information

The package IBPSA.Fluid.Interface consists of basic classes that can be used by developers to create new component models.

The classes whose name contains TwoPort or FourPort can be used for components with two or four fluid ports, respectively. If a class name contains Static, then it can only be used for a steady-state model. Otherwise, it may be used for a steady-state or a dynamic model.

The most basic classes are the records IBPSA.Fluid.Interfaces.TwoPortFlowResistanceParameters, IBPSA.Fluid.Interfaces.FourPortFlowResistanceParameters and IBPSA.Fluid.Interfaces.LumpedVolumeDeclarations. These define parameters that are needed by many fluid flow components.

Next, we describe the basic classes. For a more detailed description, see the info section of the class.

IBPSA.Fluid.Interfaces.ConservationEquation

This is a basic model for an ideally mixed fluid volume. It implements conservation equations for mass and energy. The conservation equations can be dynamic or steady-state. The model can have an arbitrary number of fluid ports. Models that instanciate this model need to define the input fluidVolume, which is the actual volume occupied by the fluid. For most components, this can be set to a parameter. However, for components such as expansion vessels, the fluid volume can change in time.

The model has the following input connectors:
  • Q_flow, which is the sensible plus latent heat flow rate added to the medium, and
  • mXi_flow, which is the species mass flow rate added to the medium.

Models that instanciate this model can used these connectors to interface with the conservation equations.

IBPSA.Fluid.Interfaces.StaticTwoPortConservationEquation

This is a basic model for steady-state conservation equations for mass and energy of a component with two fluid ports.

The model has the following input connectors:
  • Q_flow, which is the sensible plus latent heat flow rate added to the medium, and
  • mXi_flow, which is the species mass flow rate added to the medium.

Models that instanciate this model can used these connectors to interface with the conservation equations.

Compared to IBPSA.Fluid.Interfaces.ConservationEquation this model provides a more efficient implementation of the steady-state conservation equations for models with two fluid ports.

IBPSA.Fluid.Interfaces.PartialFourPort This model defines an interface for components with four ports. Only parameters and fluid definitions are provided, but no equations. The model is identical to Modelica.Fluid.Interfaces.PartialTwoPort, except that it has four ports.
IBPSA.Fluid.Interfaces.PrescribedOutlet This model calculates a prescribed heat flow (e.g. for an ideal heater or cooler), depending on a set temperature TSet.
IBPSA.Fluid.Interfaces.PartialTwoPortInterface This model defines the interface for component models that transport fluid, and that can exchange heat and mass. It also defines the port pressure difference as Δp = pa-pb. However, no equation is implemented to compute Δp(⋅) as a function of the mass flow rate. The model also implements equations to obtain the thermodynamic state at the ports.
IBPSA.Fluid.Interfaces.PartialFourPortInterface This model is identical to IBPSA.Fluid.Interfaces.PartialTwoPortInterface but it can be used for components with four fluid ports.
IBPSA.Fluid.Interfaces.StaticTwoPortHeatMassExchanger This model implements the pressure drop as a function of the mass flow rate. It also implements the steady-state energy and mass conservation equations. However, it does not implement an equation that computes Q_flow, the sensible and latent heat transfer to the medium flow, nor does it implement an equation for mXi_flow, the species mass flow rate added to or removed from the medium. Models that extend this model need to provide equations for Q_flow and mXi_flow.
IBPSA.Fluid.Interfaces.StaticFourPortHeatMassExchanger This model is identical to IBPSA.Fluid.Interfaces.StaticTwoPortHeatMassExchanger except that it has four ports.
IBPSA.Fluid.Interfaces.TwoPortHeatMassExchanger This model implements the pressure drop as a function of the mass flow rate. It also implements the energy and mass conservation equations, which may be configured as steady-state or dynamic balances based on a parameter.
IBPSA.Fluid.Interfaces.FourPortHeatMassExchanger This model is identical to IBPSA.Fluid.Interfaces.TwoPortHeatMassExchanger except that it has four ports.

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