Collection of models that illustrate model use and test models
Information
This package contains examples for the use of models that can be found in
Buildings.Fluid.SolarCollectors.BaseClasses.
Extends from Modelica.Icons.ExamplesPackage (Icon for packages containing runnable examples).
Package Content
Name |
Description |
ASHRAEHeatLoss
|
Example showing the use of ASHRAEHeatLoss |
ASHRAESolarGain
|
Example showing the use of ASHRAESolarGain |
EN12975HeatLoss
|
Example showing the use of EN12975HeatLoss |
EN12975SolarGain
|
Example showing the use of EN12975SolarGain |
Example showing the use of ASHRAEHeatLoss
Information
This examples demonstrates the implementation of
Buildings.Fluid.SolarCollectors.BaseClasses.ASHRAEHeatLoss.
Extends from Modelica.Icons.Example (Icon for runnable examples).
Parameters
Modelica definition
model ASHRAEHeatLoss
extends Modelica.Icons.Example;
parameter Buildings.Fluid.SolarCollectors.Data.GenericSolarCollector per=
Buildings.Fluid.SolarCollectors.Data.GlazedFlatPlate.FP_SolahartKf()
;
Modelica.Blocks.Sources.Sine TEnv(
freqHz=0.01,
offset=273.15 + 10,
amplitude=7.5) ;
Modelica.Blocks.Sources.Sine T1(
freqHz=0.1,
amplitude=15,
offset=273.15 + 10) ;
Modelica.Blocks.Sources.Sine T2(
freqHz=0.1,
amplitude=15,
offset=273.15 + 15) ;
Modelica.Blocks.Sources.Sine T3(
freqHz=0.1,
amplitude=15,
offset=273.15 + 20) ;
Buildings.Fluid.SolarCollectors.BaseClasses.ASHRAEHeatLoss heaLos(
nSeg=3,
m_flow_nominal=per.mperA_flow_nominal*per.A,
redeclare package Medium =
Buildings.Media.Water,
G_nominal=per.G_nominal,
dT_nominal=per.dT_nominal,
A_c=per.A,
y_intercept=per.y_intercept,
slope=per.slope,
cp_default=4186) ;
equation
connect(TEnv.y, heaLos.TEnv);
connect(T3.y, heaLos.TFlu[3]);
connect(T2.y, heaLos.TFlu[2]);
connect(T1.y, heaLos.TFlu[1]);
end ASHRAEHeatLoss;
Example showing the use of ASHRAESolarGain
Information
This examples demonstrates the implementation of
Buildings.Fluid.SolarCollectors.BaseClasses.ASHRAESolarGain.
Extends from Modelica.Icons.Example (Icon for runnable examples).
Parameters
Modelica definition
model ASHRAESolarGain
extends Modelica.Icons.Example;
parameter Buildings.Fluid.SolarCollectors.Data.GenericSolarCollector per=
Buildings.Fluid.SolarCollectors.Data.GlazedFlatPlate.FP_ThermaLiteHS20()
;
Buildings.Fluid.SolarCollectors.BaseClasses.ASHRAESolarGain solHeaGai(
nSeg=3,
shaCoe=0,
use_shaCoe_in=true,
A_c=per.A,
y_intercept=per.y_intercept,
B0=per.B0,
B1=per.B1,
redeclare package Medium =
Buildings.Media.Water,
til=0.78539816339745) ;
Modelica.Blocks.Sources.Sine HGroDifTil(
amplitude=50,
freqHz=4/86400,
offset=100) ;
Modelica.Blocks.Sources.Ramp incAng(duration=86400, height=60*(2*Modelica.Constants.pi
/360)) ;
Modelica.Blocks.Sources.Sine HDirTil(
offset=400,
amplitude=300,
freqHz=2/86400) ;
Modelica.Blocks.Sources.Sine HSkyDifTil(
freqHz=1/86400,
amplitude=100,
offset=100) ;
Modelica.Blocks.Sources.Ramp shaCoe(
height=-1,
duration=86400,
offset=1) ;
Modelica.Blocks.Sources.Sine T3(
freqHz=2/86400,
amplitude=50,
offset=273.15 + 110);
Modelica.Blocks.Sources.Sine T2(
freqHz=2/86400,
amplitude=50,
offset=273.15 + 100);
Modelica.Blocks.Sources.Sine T1(
freqHz=2/86400,
amplitude=50,
offset=273.15 + 90);
equation
connect(HGroDifTil.y, solHeaGai.HGroDifTil);
connect(shaCoe.y, solHeaGai.shaCoe_in);
connect(incAng.y, solHeaGai.incAng);
connect(HDirTil.y, solHeaGai.HDirTil);
connect(HSkyDifTil.y, solHeaGai.HSkyDifTil);
connect(T3.y, solHeaGai.TFlu[3]);
connect(T2.y, solHeaGai.TFlu[2]);
connect(T1.y, solHeaGai.TFlu[1]);
end ASHRAESolarGain;
Example showing the use of EN12975HeatLoss
Information
This examples demonstrates the implementation of
Buildings.Fluid.SolarCollectors.BaseClasses.EN12975HeatLoss.
Extends from Modelica.Icons.Example (Icon for runnable examples).
Parameters
Modelica definition
model EN12975HeatLoss
extends Modelica.Icons.Example;
parameter Buildings.Fluid.SolarCollectors.Data.GenericSolarCollector per=
Buildings.Fluid.SolarCollectors.Data.Concentrating.C_VerificationModel()
;
Modelica.Blocks.Sources.Sine TEnv(
freqHz=0.01,
offset=273.15 + 10,
amplitude=15) ;
Modelica.Blocks.Sources.Sine T1(
amplitude=15,
freqHz=0.1,
offset=273.15 + 10) ;
Modelica.Blocks.Sources.Sine T2(
freqHz=0.1,
amplitude=15,
offset=273.15 + 15) ;
Modelica.Blocks.Sources.Sine T3(
freqHz=0.1,
amplitude=15,
offset=273.15 + 20) ;
Buildings.Fluid.SolarCollectors.BaseClasses.EN12975HeatLoss heaLos(
nSeg=3,
redeclare package Medium =
Buildings.Media.Water,
C1=per.C1,
C2=per.C2,
m_flow_nominal=per.mperA_flow_nominal*per.A,
G_nominal=per.G_nominal,
dT_nominal=per.dT_nominal,
A_c=per.A,
y_intercept=per.y_intercept,
cp_default=4186) ;
equation
connect(TEnv.y, heaLos.TEnv);
connect(T3.y, heaLos.TFlu[3]);
connect(T2.y, heaLos.TFlu[2]);
connect(T1.y, heaLos.TFlu[1]);
end EN12975HeatLoss;
Example showing the use of EN12975SolarGain
Information
This examples demonstrates the implementation of
Buildings.Fluid.SolarCollectors.BaseClasses.EN12975SolarGain.
Extends from Modelica.Icons.Example (Icon for runnable examples).
Parameters
Modelica definition
model EN12975SolarGain
extends Modelica.Icons.Example;
parameter Buildings.Fluid.SolarCollectors.Data.GenericSolarCollector per=
Buildings.Fluid.SolarCollectors.Data.Concentrating.C_VerificationModel()
;
Buildings.Fluid.SolarCollectors.BaseClasses.EN12975SolarGain solHeaGai(
B0=per.B0,
B1=per.B1,
y_intercept=per.y_intercept,
nSeg=3,
A_c=per.A,
iamDiff=per.IAMDiff,
shaCoe=0,
use_shaCoe_in=true,
redeclare package Medium =
Buildings.Media.Water)
;
Modelica.Blocks.Sources.Ramp incAng(duration=86400,
height=60*(2*Modelica.Constants.pi/360)) ;
Modelica.Blocks.Sources.Sine HDirTil(
offset=400,
amplitude=300,
freqHz=2/86400) ;
Modelica.Blocks.Sources.Sine HDifTil(
amplitude=200,
freqHz=1/86400,
offset=300) ;
Modelica.Blocks.Sources.Ramp shaCoe(
duration=86400,
offset=1,
height=-1) ;
Modelica.Blocks.Sources.Sine T3(
freqHz=2/86400,
amplitude=50,
offset=273.15 + 110);
Modelica.Blocks.Sources.Sine T2(
freqHz=2/86400,
amplitude=50,
offset=273.15 + 100);
Modelica.Blocks.Sources.Sine T1(
freqHz=2/86400,
amplitude=50,
offset=273.15 + 90);
equation
connect(incAng.y, solHeaGai.incAng);
connect(shaCoe.y, solHeaGai.shaCoe_in);
connect(HDirTil.y, solHeaGai.HDirTil);
connect(HDifTil.y, solHeaGai.HSkyDifTil);
connect(T3.y, solHeaGai.TFlu[3]);
connect(T2.y, solHeaGai.TFlu[2]);
connect(T1.y, solHeaGai.TFlu[1]);
end EN12975SolarGain;