This is a model of a radiator that can be used as a dynamic or steady-state model.
The required parameters are data that are typically available from
manufacturers that follow the European Norm EN 442-2.
However, to allow for varying mass flow rates, the transferred heat is computed
using a discretization along the water flow path, and heat is exchanged between
each compartment and a uniform room air and radiation temperature.
This discretization is different from the computation in EN 442-2, which
may yield water outlet temperatures that are below
the room temperature at low mass flow rates.
Furthermore, rather than using only one room temperature, this model uses
a room air and room radiation temperature.
The default parameters for the heat capacities are valid for a flat plate radiator without fins,
with one plate of water carying fluid, and a height of 0.42 meters.
| Type | Name | Default | Description |
|---|
| replaceable package Medium | PartialMedium | Medium in the component |
| Integer | nEle | 5 | Number of elements used in the discretization |
| Real | fraRad | 0.35 | Fraction radiant heat transfer |
| Real | n | 1.24 | Exponent for heat transfer |
| Nominal condition |
| MassFlowRate | m_flow_nominal | abs(Q_flow_nominal/cp_nomina... | Nominal mass flow rate [kg/s] |
| Power | Q_flow_nominal | | Nominal heating power (positive for heating) [W] |
| Temperature | T_a_nominal | | Water inlet temperature at nominal condition [K] |
| Temperature | T_b_nominal | | Water outlet temperature at nominal condition [K] |
| Temperature | TAir_nominal | 293.15 | Air temperature at nominal condition [K] |
| Temperature | TRad_nominal | TAir_nominal | Radiative temperature at nominal condition [K] |
| Initialization |
| MassFlowRate | m_flow.start | 0 | Mass flow rate from port_a to port_b (m_flow > 0 is design flow direction) [kg/s] |
| Pressure | dp.start | 0 | Pressure difference between port_a and port_b [Pa] |
| Assumptions |
| Boolean | allowFlowReversal | true | = true to allow flow reversal, false restricts to design direction (port_a -> port_b) |
| Advanced |
| MassFlowRate | m_flow_small | 1E-4*abs(m_flow_nominal) | Small mass flow rate for regularization of zero flow [kg/s] |
| Boolean | homotopyInitialization | true | = true, use homotopy method |
| Diagnostics |
| Boolean | show_T | true | = true, if actual temperature at port is computed |
| Dynamics |
| Equations |
| Dynamics | energyDynamics | Modelica.Fluid.Types.Dynamic... | Formulation of energy balance |
| Dynamics | massDynamics | energyDynamics | Formulation of mass balance |
| Real | mSenFac | 1 + 500*mDry/(VWat*cp_nomina... | Factor for scaling the sensible thermal mass of the volume |
| Volume | VWat | 5.8E-6*abs(Q_flow_nominal) | Water volume of radiator [m3] |
| Mass | mDry | 0.0263*abs(Q_flow_nominal) | Dry mass of radiator that will be lumped to water heat capacity [kg] |
| Initialization |
| AbsolutePressure | p_start | Medium.p_default | Start value of pressure [Pa] |
| Temperature | T_start | Medium.T_default | Start value of temperature [K] |
| MassFraction | X_start[Medium.nX] | Medium.X_default | Start value of mass fractions m_i/m [kg/kg] |
| ExtraProperty | C_start[Medium.nC] | fill(0, Medium.nC) | Start value of trace substances |
| ExtraProperty | C_nominal[Medium.nC] | fill(1E-2, Medium.nC) | Nominal value of trace substances. (Set to typical order of magnitude.) |
model RadiatorEN442_2
"Dynamic radiator for space heating"
extends Buildings.Fluid.Interfaces.PartialTwoPortInterface(
showDesignFlowDirection = false,
show_T=true,
m_flow_nominal=
abs(Q_flow_nominal/cp_nominal/(T_a_nominal-T_b_nominal)));
extends Buildings.Fluid.Interfaces.LumpedVolumeDeclarations(
final X_start = Medium.X_default,
final C_start =
fill(0, Medium.nC),
final C_nominal =
fill(1E-2, Medium.nC),
final mSenFac = 1 + 500*mDry/(VWat*cp_nominal*
Medium.density(
Medium.setState_pTX(Medium.p_default, Medium.T_default, Medium.X_default))));
parameter Integer nEle(min=1) = 5
"Number of elements used in the discretization";
parameter Real fraRad(min=0, max=1) = 0.35
"Fraction radiant heat transfer";
// Assumptions
parameter Modelica.SIunits.Power Q_flow_nominal
"Nominal heating power (positive for heating)";
parameter Modelica.SIunits.Temperature T_a_nominal
"Water inlet temperature at nominal condition";
parameter Modelica.SIunits.Temperature T_b_nominal
"Water outlet temperature at nominal condition";
parameter Modelica.SIunits.Temperature TAir_nominal = 293.15
"Air temperature at nominal condition";
parameter Modelica.SIunits.Temperature TRad_nominal = TAir_nominal
"Radiative temperature at nominal condition";
parameter Real n = 1.24
"Exponent for heat transfer";
parameter Modelica.SIunits.Volume VWat = 5.8E-6*
abs(Q_flow_nominal)
"Water volume of radiator";
parameter Modelica.SIunits.Mass mDry = 0.0263*
abs(Q_flow_nominal)
"Dry mass of radiator that will be lumped to water heat capacity";
parameter Boolean homotopyInitialization = true
"= true, use homotopy method";
// Heat flow rates
Modelica.SIunits.HeatFlowRate QCon_flow = heatPortCon.Q_flow
"Heat input into the water due to convective heat transfer with room air";
Modelica.SIunits.HeatFlowRate QRad_flow = heatPortRad.Q_flow
"Heat input into the water due to radiative heat transfer with room";
Modelica.SIunits.HeatFlowRate Q_flow = QCon_flow + QRad_flow
"Heat input into the water";
// Heat ports
Modelica.Thermal.HeatTransfer.Interfaces.HeatPort_a heatPortCon
"Heat port for convective heat transfer with room air temperature";
Modelica.Thermal.HeatTransfer.Interfaces.HeatPort_a heatPortRad
"Heat port for radiative heat transfer with room radiation temperature";
Fluid.MixingVolumes.MixingVolume[nEle] vol(
redeclare each package Medium =
Medium,
each nPorts = 2,
each V=VWat/nEle,
each final m_flow_nominal = m_flow_nominal,
each final energyDynamics=energyDynamics,
each final massDynamics=massDynamics,
each final p_start=p_start,
each final T_start=T_start,
each final X_start=X_start,
each final C_start=C_start,
each final mSenFac=mSenFac)
"Volume for fluid stream";
protected
parameter Modelica.SIunits.SpecificHeatCapacity cp_nominal=
Medium.specificHeatCapacityCp(
Medium.setState_pTX(Medium.p_default, T_a_nominal, Medium.X_default))
"Specific heat capacity at nominal conditions";
parameter Modelica.SIunits.HeatFlowRate QEle_flow_nominal[nEle](
each fixed=false,
each start=Q_flow_nominal/nEle)
"Nominal heating power of each element";
parameter Modelica.SIunits.Temperature TWat_nominal[nEle](
each fixed=false,
start={T_a_nominal - i/nEle * (T_a_nominal-T_b_nominal)
for i
in 1:nEle})
"Water temperature in each element at nominal conditions";
parameter Modelica.SIunits.TemperatureDifference[nEle] dTRad_nominal(
each fixed=false, start={T_a_nominal - i/nEle * (T_a_nominal-T_b_nominal) - TRad_nominal
for i
in 1:nEle})
"Temperature difference for radiative heat transfer at nominal conditions";
parameter Modelica.SIunits.TemperatureDifference[nEle] dTCon_nominal(
each fixed=false, start={T_a_nominal - i/nEle * (T_a_nominal-T_b_nominal) - TAir_nominal
for i
in 1:nEle})
"Temperature difference for convective heat transfer at nominal conditions";
parameter Modelica.SIunits.ThermalConductance UAEle(fixed=false, min=0,
start=Q_flow_nominal/((T_a_nominal+T_b_nominal)/2-((1-fraRad)*TAir_nominal+fraRad*TRad_nominal))/nEle)
"UA value at nominal condition for each element";
final parameter Real k =
if T_b_nominal > TAir_nominal
then 1
else -1
"Parameter that is used to compute QEle_flow_nominal for heating or cooling mode";
Buildings.HeatTransfer.Sources.PrescribedHeatFlow[nEle] preCon
"Heat input into radiator from convective heat transfer";
Buildings.HeatTransfer.Sources.PrescribedHeatFlow[nEle] preRad
"Heat input into radiator from radiative heat transfer";
Modelica.SIunits.TemperatureDifference dTCon[nEle] = heatPortCon.T .- vol.T
"Temperature difference for convective heat transfer";
Modelica.SIunits.TemperatureDifference dTRad[nEle] = heatPortRad.T .- vol.T
"Temperature difference for radiative heat transfer";
Modelica.Blocks.Sources.RealExpression QCon[nEle](y=
if homotopyInitialization
then homotopy(actual=(1 - fraRad) .* UAEle .* dTCon .*
Buildings.Utilities.Math.Functions.regNonZeroPower(
x=dTCon,
n=n - 1,
delta=0.05), simplified=(1 - fraRad) .* UAEle .*
abs(dTCon_nominal) .^ (
n - 1) .* dTCon)
else (1 - fraRad) .* UAEle .* dTCon .*
Buildings.Utilities.Math.Functions.regNonZeroPower(
x=dTCon,
n=n - 1,
delta=0.05))
"Convective heat flow rate";
Modelica.Blocks.Sources.RealExpression QRad[nEle](y=
if homotopyInitialization
then homotopy(actual=fraRad .* UAEle .* dTRad .*
Buildings.Utilities.Math.Functions.regNonZeroPower(
x=dTRad,
n=n - 1,
delta=0.05), simplified=fraRad .* UAEle .*
abs(dTRad_nominal) .^ (n - 1)
.* dTRad)
else fraRad .* UAEle .* dTRad .*
Buildings.Utilities.Math.Functions.regNonZeroPower(
x=dTRad,
n=n - 1,
delta=0.05))
"Radiative heat flow rate";
Buildings.HeatTransfer.Sources.PrescribedHeatFlow preSumCon
"Heat input into radiator from convective heat transfer";
Modelica.Blocks.Math.Sum sumCon(nin=nEle, k=-
ones(nEle))
"Sum of convective heat flow rate";
Modelica.Blocks.Math.Sum sumRad(nin=nEle, k=-
ones(nEle))
"Sum of radiative heat flow rate";
Buildings.HeatTransfer.Sources.PrescribedHeatFlow preSumRad
"Heat input into radiator from radiative heat transfer";
initial equation
if T_b_nominal > TAir_nominal
then
assert(T_a_nominal > T_b_nominal,
"In RadiatorEN442_2, T_a_nominal must be higher than T_b_nominal.");
assert(Q_flow_nominal > 0,
"In RadiatorEN442_2, nominal power must be bigger than zero if T_b_nominal > TAir_nominal.");
else
assert(T_a_nominal < T_b_nominal,
"In RadiatorEN442_2, T_a_nominal must be lower than T_b_nominal.");
assert(Q_flow_nominal < 0,
"In RadiatorEN442_2, nominal power must be smaller than zero if T_b_nominal < TAir_nominal.");
end if;
TWat_nominal[1] = T_a_nominal - QEle_flow_nominal[1]/m_flow_nominal/
Medium.specificHeatCapacityCp(
Medium.setState_pTX(Medium.p_default, T_a_nominal, Medium.X_default));
for i
in 2:nEle
loop
TWat_nominal[i] = TWat_nominal[i-1] - QEle_flow_nominal[i]/m_flow_nominal/
Medium.specificHeatCapacityCp(
Medium.setState_pTX(Medium.p_default, TWat_nominal[i-1], Medium.X_default));
end for;
dTRad_nominal = TWat_nominal .- TRad_nominal;
dTCon_nominal = TWat_nominal .- TAir_nominal;
Q_flow_nominal =
sum(QEle_flow_nominal);
for i
in 1:nEle
loop
QEle_flow_nominal[i] = k * UAEle * (fraRad *
Buildings.Utilities.Math.Functions.powerLinearized(x=k*dTRad_nominal[i],
n=n,
x0=0.1*k*(T_b_nominal-TRad_nominal))
+ (1-fraRad) *
Buildings.Utilities.Math.Functions.powerLinearized(x=k*dTCon_nominal[i],
n=n,
x0=0.1*k*(T_b_nominal-TAir_nominal)));
end for;
equation
connect(preCon.port, vol.heatPort);
connect(preRad.port, vol.heatPort);
connect(port_a, vol[1].ports[1]);
connect(vol[nEle].ports[2], port_b);
for i
in 1:nEle-1
loop
connect(vol[i].ports[2], vol[i+1].ports[1]);
end for;
connect(QCon.y, preCon.Q_flow);
connect(sumCon.u, QCon.y);
connect(sumCon.y, preSumCon.Q_flow);
connect(preSumCon.port, heatPortCon);
connect(QRad.y, preRad.Q_flow);
connect(QRad.y, sumRad.u);
connect(sumRad.y, preSumRad.Q_flow);
connect(preSumRad.port, heatPortRad);
end RadiatorEN442_2;
RadiatorEN442_2
Examples
Buildings.Fluid.HeatExchangers.Radiators.RadiatorEN442_2