Computational design optimization of low-energy buildings

Vala, Jiří

  • Proceedings of Equadiff 14, Publisher: Slovak University of Technology in Bratislava, SPEKTRUM STU Publishing(Bratislava), page 265-274

Abstract

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European directives and related national technical standards force the substantial reduction of energy consumption of all types of buildings. This can be done thanks to the massive insulation and the improvement of quality of building enclosures, using the simple evaluation assuming the one-dimensional stationary heat conduction. However, recent applications of advanced materials, structures and technologies force the proper physical, mathematical and computational analysis coming from the thermodynamic principles. This paper shows the non-expensive evaluation of energy consumption of buildings with controlled indoor temperature, decomposing a building, considered as a thermal system, into particular subsystems and elements, coupled by interface thermal fluxes. We come to a rather large parabolic system of partial differential equations, containing the nonlinearities i) from the surface Stefan - Boltzmann radiation and ii) from the heating control; this can be handled using some properties of semilinear systems. The Fourier multiplicative decomposition together with the finite element technique enables us to derive a sparse system of ordinary differential equations, appropriate for the input of climatic data (temperature, beam and diffuse solar radiation). For the approximate solutions the spectral analysis is helpful; all nonlinearities can be overcome thanks to quasi-Newton iterations. All above sketched simulations have been implemented in MATLAB. An example shows the validation of this approach, utilizing the time series of measured energy consumption from the real family house in Ostrov u Macochy (30 km northern from Brno). Additional procedures for the support of design of low-energy buildings come namely from the Nelder - Mead optimization algorithm.

How to cite

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Vala, Jiří. "Computational design optimization of low-energy buildings." Proceedings of Equadiff 14. Bratislava: Slovak University of Technology in Bratislava, SPEKTRUM STU Publishing, 2017. 265-274. <http://eudml.org/doc/294886>.

@inProceedings{Vala2017,
abstract = {European directives and related national technical standards force the substantial reduction of energy consumption of all types of buildings. This can be done thanks to the massive insulation and the improvement of quality of building enclosures, using the simple evaluation assuming the one-dimensional stationary heat conduction. However, recent applications of advanced materials, structures and technologies force the proper physical, mathematical and computational analysis coming from the thermodynamic principles. This paper shows the non-expensive evaluation of energy consumption of buildings with controlled indoor temperature, decomposing a building, considered as a thermal system, into particular subsystems and elements, coupled by interface thermal fluxes. We come to a rather large parabolic system of partial differential equations, containing the nonlinearities i) from the surface Stefan - Boltzmann radiation and ii) from the heating control; this can be handled using some properties of semilinear systems. The Fourier multiplicative decomposition together with the finite element technique enables us to derive a sparse system of ordinary differential equations, appropriate for the input of climatic data (temperature, beam and diffuse solar radiation). For the approximate solutions the spectral analysis is helpful; all nonlinearities can be overcome thanks to quasi-Newton iterations. All above sketched simulations have been implemented in MATLAB. An example shows the validation of this approach, utilizing the time series of measured energy consumption from the real family house in Ostrov u Macochy (30 km northern from Brno). Additional procedures for the support of design of low-energy buildings come namely from the Nelder - Mead optimization algorithm.},
author = {Vala, Jiří},
booktitle = {Proceedings of Equadiff 14},
keywords = {Low-energy buildings, heat transfer, computational modelling, optimization techniques, MATLAB software tools},
location = {Bratislava},
pages = {265-274},
publisher = {Slovak University of Technology in Bratislava, SPEKTRUM STU Publishing},
title = {Computational design optimization of low-energy buildings},
url = {http://eudml.org/doc/294886},
year = {2017},
}

TY - CLSWK
AU - Vala, Jiří
TI - Computational design optimization of low-energy buildings
T2 - Proceedings of Equadiff 14
PY - 2017
CY - Bratislava
PB - Slovak University of Technology in Bratislava, SPEKTRUM STU Publishing
SP - 265
EP - 274
AB - European directives and related national technical standards force the substantial reduction of energy consumption of all types of buildings. This can be done thanks to the massive insulation and the improvement of quality of building enclosures, using the simple evaluation assuming the one-dimensional stationary heat conduction. However, recent applications of advanced materials, structures and technologies force the proper physical, mathematical and computational analysis coming from the thermodynamic principles. This paper shows the non-expensive evaluation of energy consumption of buildings with controlled indoor temperature, decomposing a building, considered as a thermal system, into particular subsystems and elements, coupled by interface thermal fluxes. We come to a rather large parabolic system of partial differential equations, containing the nonlinearities i) from the surface Stefan - Boltzmann radiation and ii) from the heating control; this can be handled using some properties of semilinear systems. The Fourier multiplicative decomposition together with the finite element technique enables us to derive a sparse system of ordinary differential equations, appropriate for the input of climatic data (temperature, beam and diffuse solar radiation). For the approximate solutions the spectral analysis is helpful; all nonlinearities can be overcome thanks to quasi-Newton iterations. All above sketched simulations have been implemented in MATLAB. An example shows the validation of this approach, utilizing the time series of measured energy consumption from the real family house in Ostrov u Macochy (30 km northern from Brno). Additional procedures for the support of design of low-energy buildings come namely from the Nelder - Mead optimization algorithm.
KW - Low-energy buildings, heat transfer, computational modelling, optimization techniques, MATLAB software tools
UR - http://eudml.org/doc/294886
ER -

References

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  1. Castro, A. Bermúdez de, Continuum Thermodynamics, , Birkhäuser, Basel, 2005. 
  2. Borwein, J., Lewis, A., Convex Analysis and Nonlinear Optimization, , Springer, New York, 2006. MR2184742
  3. Brigola, R., Fourier-Analysis und Distributionen, (in German), Co-Verlag, Berlin, 2012. 
  4. Carluci, S., Pagliano, L., A review of indices for the long-term evaluation of the general thermal comfort conditions in buildings, , Energy and Buildings, 53 (2012), pp. 194–205. 
  5. Crawley, D. B., Contrasting the capabilities of building energy performance simulation programs, . Building and Environment, 43 (2008), pp. 661–673. 
  6. Davies, M. G., Building Heat Transfer, , J. Wiley & Sons, Chichester, 2004. 
  7. Drábek, P., Milota, J., Lectures on Nolinear Analysis, , University of West Bohemia, Pilsen, 2004. 
  8. Feist, W., Gestaltungsgrundlagen Passivhäuser, (in German), Das Beispiel, Darmstadt, 1999. 
  9. Feist, W., Pfluger, R., Kaufmann, B., Schnieders, J., Kah, O., Passive House Planning Package, , Passive House Institute, Darmstadt, 2004. 
  10. Gao, F., Han, L., Implementing the Nelder-Mead simplex algorithm with adaptive parameters, , Computer Optimizations and Applications, 99 (2010), pp. 111–222. MR2872499
  11. Hudec, M., Johanisová, B., Mansbart, T., Pasivní domy z přírodních materiálů, (in Czech), Grada, Prague, 2012. 
  12. Jarošová, P., Computational approaches to the design of low-energy buildings, , Programs and Algorithms of Numerical Mathematics in Dolní Maxov (Czech Republic), Proceedings, 2014, pp. 92–99, Institute of Mathematics AS CR, Prague, 2015. 
  13. Jarošová, P., Vala, J., On a computational model of building thermal dynamic response, , Thermophysics in Terchová (Slovak Republic), Proceedings, 2016, pp. 40011/1–6, American Institute of Physics, Melville (USA), 2016. 
  14. Jarošová, P., Vala, J., Optimization approaches in the thermal system analysis of buildings, , ICNAAM (International Conference on Numerical Analysis and Applied Mathematics) in Thessaloniki, Proceedings, 2017, 4 pp., American Institute of Physics, Melville (USA),2018, accepted for publication. 
  15. Kämpf, J. H., Robinson, D. A., A simplified thermal model to support analysis of urban resource flows, , Energy and Buildings, 39 (2007), pp. 445–453. 
  16. Lagarias, J. C., Reeds, J. A., Wrigth, M. H., Wrigth, P. E., Convergence properties of the Nelder-Mead simplex method in low dimensions, , SIAM Journal of Optimization, 9 (1998), pp. 112–147. MR1662563
  17. Lagarias, J. C., Poonen, B., Wrigth, M. H., Convergence of the restricted Nelder-Mead algorithm in two dimensions, , SIAM Journal on Optimization, 22 (2012), pp. 501–532. MR2968864
  18. Maz’ya, V. G., Sobolev Spaces with Applications to Elliptic Partial Differential Equations, , Springer, Berlin, 2011. MR2777530
  19. Nelder, J. A., Mead, R., Simplex method for function minimization, , Computer Journal, 7(1965), pp. 308–313. MR3363409
  20. Roubíček, T., Nonlinear Partial Differential Equations with Applications, , Birkhäuser, Basel, 2005. MR2176645
  21. Řehánek, J., Tepelná akumulace budov, (in Czech), ČKAIT, Prague, 2002. 
  22. Shukuya, M., Exergy – Theory and Applications in the Built Environment, , Springer, London, 2013. 
  23. Šťastník, S., Vala, J., On the thermal stability in dwelling structures, , Building Research Journal, 52 (2004), pp. 31–55. 
  24. Underwood, J. C., An improved lumped parameter method for building thermal modelling, , Energy and Buildings, 79 (2014), pp. 191–201. 
  25. Viggers, H., Keall, M., Wickens, K., Howden-Chapman, P., Increased house size can cancel out the effect of improved insulation on overall heating energy requirements, , Energy Policy 107 (2017), pp. 248–257. 
  26. Wright, M. H., Nelder,, Mead, and the other simplex method, , Documenta Mathematica, extra volume Optimization Stories (2012), pp. 271–276. MR2991490
  27. Ženíšek, A., Finite element variational crimes in parabolic-elliptic problems, , Numerische Mathematik, 55 (1989), pp. 343–376. MR0993476
  28. Ženíšek, A., Sobolev Spaces and Their Applications in the Finite Element Method, . Brno University of Technology, 2005. 
  29. HASH(0x191cb68), [unknown], [29] Directive 2010/31/EU of the European Parliament and of the Council on the Energy Performance of Buildings, Official Journal of the European Union, L 153/13 (2010). 

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