partial model FluidInterface "Partial class for fluid interface that can be coupled to BCVTB" extends Buildings.BaseClasses.BaseIcon; replaceable package Medium = Modelica.Media.Interfaces.PartialMedium "Medium model within the source"; parameter Integer nPorts=0 "Number of ports"; Modelica.Blocks.Interfaces.RealInput m_flow_in if use_m_flow_in "Prescribed mass flow rate"; Modelica.Blocks.Interfaces.RealInput T_in "Prescribed boundary temperature"; parameter Boolean use_m_flow_in = false "Get the mass flow rate from the input connector"; parameter Modelica.SIunits.MassFlowRate m_flow = 0 "Fixed mass flow rate going out of the fluid port"; parameter Modelica.SIunits.MassFlowRate m_flow_nominal(min=0) "Nominal mass flow rate, used for regularization near zero flow"; parameter Modelica.SIunits.MassFlowRate m_flow_small(min=0) = 1E-4*m_flow_nominal "For bi-directional flow, temperature is regularized in the region |m_flow| < m_flow_small (m_flow_small > 0 required)"; Buildings.Fluid.Sensors.EnthalpyFlowRate totEntFloRat[nPorts]( redeclare final package Medium = Medium, each final m_flow_nominal=m_flow_nominal) "Total enthalpy flow rate (sensible plus latent)"; Modelica.Fluid.Interfaces.FluidPorts_b ports[ nPorts]( redeclare each package Medium = Medium, each m_flow(max=if flowDirection==Modelica.Fluid.Types.PortFlowDirection.Leaving then 0 else +Modelica.Constants.inf, min=if flowDirection==Modelica.Fluid.Types.PortFlowDirection.Entering then 0 else -Modelica.Constants.inf)); Modelica.Blocks.Math.Sum sumHTot_flow(nin=nPorts) "Sum of total enthalpy flow rates"; Modelica.Blocks.Interfaces.RealOutput HSen_flow(unit="W") "Sensible enthalpy flow rate, positive if flow into the component"; Buildings.Fluid.Sources.MassFlowSource_T bou( redeclare package Medium = Medium, final use_T_in=true, final nPorts=nPorts, use_X_in=false, use_C_in=false, final use_m_flow_in=true); protected parameter Modelica.Fluid.Types.PortFlowDirection flowDirection= Modelica.Fluid.Types.PortFlowDirection.Bidirectional "Allowed flow direction"; Modelica.Blocks.Sources.Constant m_flow_par(final k=m_flow) "Mass flow rate if set as a parameter"; equation if use_m_flow_in then connect(m_flow_in, bou.m_flow_in); else connect(m_flow_par.y, bou.m_flow_in); end if; connect(totEntFloRat.port_b, bou.ports); connect(sumHTot_flow.u, totEntFloRat.H_flow); connect(bou.T_in, T_in); end FluidInterface;

function closeClientSocket "Closes the socket for the inter process communication" input Integer socketFD "Socket file descripter, or a negative value if an error occurred"; output Integer retVal "Return value of the function that closes the socket connection"; external "C" retVal=closeModelicaClient(socketFD); end closeClientSocket;

  xmlFileName="C:\\examples\\dymola-room\\socket.cfg"

function establishClientSocket "Establishes the client socket connection" input String xmlFileName = "socket.cfg" "Name of xml file that contains the socket information"; output Integer socketFD "Socket file descripter, or a negative value if an error occurred"; external "C" socketFD=establishModelicaClient(xmlFileName); end establishClientSocket;

function exchangeReals "Exchanges values of type Real with the socket" input Integer socketFD(min=1) "Socket file descripter"; input Integer flaWri "Communication flag to write to the socket stream"; input Modelica.SIunits.Time simTimWri "Current simulation time in seconds to write"; input Real[nDblWri] dblValWri "Double values to write"; input Integer nDblWri "Number of double values to write"; input Integer nDblRea "Number of double values to read"; output Integer flaRea "Communication flag read from the socket stream"; output Modelica.SIunits.Time simTimRea "Current simulation time in seconds read from socket"; output Real[nDblRea] dblValRea "Double values read from socket"; output Integer retVal "The exit value, which is negative if an error occurred"; external "C" retVal=exchangeModelicaClient(socketFD, flaWri, flaRea, simTimWri, dblValWri, nDblWri, simTimRea, dblValRea, nDblRea); end exchangeReals;