Heat and Moisture Modeling Using COMSOL

dr.ir.ing. Jos van Schijndel

Presented at the COMSOL Conference 2008 Hannover

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Multiphysics Contents

• Introduction • Heat and Moisture Transport• Verification • Application• Conclusions

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WHAT? Multiscale couplingtime, geometry

Whole Building (scale 10 m)Detail (scale 0.01 m)

ConstructionLocal

Systems & ControlLocal

Coupled

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WHAT? Multiphysics couplingheat, air, moisture, …

heat

air

moisture

0)( =∇⋅+∇−⋅∇+∂∂ TCTtTC pp uρλρ

0)( =∇⋅+∇−⋅∇+∂∂

vvv ppDtp u

[Tariku 2008]

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WHY?

GoalImprove building and systems performances

durability, comfort, economics

ScienceModeling is an essential and inseparable part of all

scientific activity [wikipedia]

Design Application of Knowledge to Control

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HOW? Modeling based on physicsOptimal Abstraction level

Multi Buildings(HAMBase)

Multi PDEMulti

ODE

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HOW? ImplementationMatLab/SimuLink/COMSOL

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Multiphysics 3D Heat

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Multiphysics 2D heat & air & vapour

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Multiphysics 2D wind & driving rain

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Multiphysics 2D wind & driving rain

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3D thermal2D heat & air & vapour

MultiphysicsEducation

• Master Course, 2 ECTS• Exemplary results• Course Available at http://sts.bwk.tue.nl/7s532/

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Multiphysics Modeling Validated

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Guidelines FEM Heat and Moisture Modeling (1) Use LPc as potential

)(

)(

2221

1211

LPcKTKtLPcC

LPcKTKtTC

LPc

T

∇+∇⋅∇=∂

∂

∇+∇⋅∇=∂∂

,

,

,

)log(

21

22

12

11

10

TPsatK

RTM

PsatLPcPc

LPcPcKK

LPcPc

PcwC

RTM

PsatLPcPclK

KcCPcLPc

p

a

wp

LPc

a

wplv

T

∂∂⋅⋅=

⋅⋅∂∂

⋅⋅−∂∂

⋅−=

∂∂

⋅∂∂

=

⋅⋅∂∂

⋅⋅⋅−=

=⋅=

=

φδ

ρφδ

ρφδ

λρ

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Material Function in MatLab(2) Calculate PDE coeffients fun(Lpc,T)

)(

)(

2221

1211

LPcKTKtLPcC

LPcKTKtTC

LPc

T

∇+∇⋅∇=∂

∂

∇+∇⋅∇=∂∂

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Material Function in MatLab(2) Calculate PDE coefficients fun(LPc,T)

)(

)(

2221

1211

LPcKTKtLPcC

LPcKTKtTC

LPc

T

∇+∇⋅∇=∂

∂

∇+∇⋅∇=∂∂

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VerificationHAMSTAD Benchmark no 1

)()()(

ppgpplTThq

i

ilvii

−⋅=−⋅⋅+−⋅=

ββ

0)(

=−⋅=

gTThq ee

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VerificationHeat & Moisture

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VerificationHeat

COMSOL Reference

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VerificationMoisture

COMSOL Reference

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Step 1Measurements, sensors

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Step 2: Modeling & ValidationSimulation vs Measurements

Ti RHi

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Step 3: Application of the model

• Evaluation of the moisture damageMoisture damage not caused by moisture through the constructionMoisture damage not caused by condensation at the insideConfirmation of leakages

• Evaluation of a new design:Effect of partly removing the concrete

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ConclusionMulti(building)physics & COMSOL

• COMSOL is a state-of-art Multiphysics modeling tool for doing research in the area of building physics

• High performance on• 1,2 & 3D capabilities• Grid & solvers techniques• Visualisation• Flexibility due to PDE abstraction level

• Also a excellent tool for education • Our models are available at http://sts.bwk.tue.nl/hamlab/

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• Thank you

• Questions ?