Energy efficiency assessment of heat insulation building products: fuzzy-probabilistic approach

• Autorzy: Biks Yuriy , Lyalyuk Olena , Ratushnyak Georgiy , Ratushnyak Olga , Lyalyuk Andriy

Identyfikatory

DOI

10.21307/ACEE-2021-006

• Języki publikacji: EN

Abstrakty

EN

The expediency of using heat-insulating construction products from a straw at the erecting of energy-efficient envelope constructions is considered in the paper. The hierarchical model in the form of an inference tree of the factors influencing the target function - reliability of energy efficiency of heat-insulating building products made of straw has resulted. A fuzzy matrix of knowledge is proposed which reflects the influence of thermophysical, physic-mechanical and durability parameters on the target function. The hierarchical connections between classified factors proceeded by apparatus of fuzzy logic and linguistic variables. A system of fuzzy logical equations which describes linguistic expressions of input variables according to the corresponding terms is proposed. In the research the expressions which describe the objective function - reliability of energy efficiency of heat-insulating construction products made of straw were obtained. It was made with the of membership functions following linguistic variables, by taking into account both qualitative as well as quantitative factors of influence. Represented in the paper model can be used as the design and engineering tool for the prediction of thermal performance of any multilayered wall assembly at the design stage of the project to assess complex energy efficiency parameters, which could be applied in practice during the decision-making process.

Słowa kluczowe

EN

modelling; reliability; energy efficiency; thermal insulation; linguistic variable; fuzzy logic; construction product

PL

modelowanie; niezawodność; efektywność energetyczna; izolacja termiczna; zmienna lingwistyczna; logika rozmyta; wyrób budowlany

• Wydawca: Silesian University of Technology
• Czasopismo: Architecture Civil Engineering Environment
• Rocznik: 2021
• Tom: Vol. 14, no. 1
• Strony: 59--68
• Opis fizyczny: Bibliogr. 31 poz.

Twórcy

autor

Biks Yuriy

• PhD; Department of Construction, Architecture and Municipal Economy, Vinnytsia National Technical University, Voiniv Internatsionalistiv, 7. Vinnytsia, 21000 Ukraine

autor

Lyalyuk Olena

• PhD; Department of Construction, Architecture and Municipal Economy, Vinnytsia National Technical University, Voiniv Internatsionalistiv, 7. Vinnytsia, 21000 Ukraine

autor

Ratushnyak Georgiy

• PhD; Department of Construction, Architecture and Municipal Economy, Vinnytsia National Technical University, Voiniv Internatsionalistiv, 7. Vinnytsia, 21000 Ukraine

autor

Ratushnyak Olga

• PhD, Associated Prof.; Department of Enterprise Economics and Production Management, Vinnytsia National Technical University, Khmelnyts’ke shosse, 95. Vinnytsia, 21000 Ukraine

autor

Lyalyuk Andriy

• Master’s student; Department of Construction, Architecture and Municipal Economy, Vinnytsia National Technical University, Voiniv Internatsionalistiv, 7. Vinnytsia, 21000 Ukraine

Bibliografia

• [1] Hovanov, N. V., & Fedotov, Yu. V. (2006).Models for uncertainty accounting when constructing summary indicators of the effectiveness of complex production systems. In Scientific reports, 28R-2006, 37 (in Russian).
• [2] Pashynskyi, V. A. (2016). Fundamentals of the theory of reliability of buildings and structures. Kropyvnytskyi: Central Ukrainian National Technical University (in Ukrainian).
• [3] About the energy efficiency of buildings. [Parliamentary paper]. Retrieved July 26, 2019, from https://zakon.rada.gov.ua/laws/show/2118-19 (in Ukrainian).
• [4] Ratushnyak, G. S., & Ratushnyak, O. G. (2006). Management of energy-saving projects by the thermal renovation of buildings [Epub]. Vinnytsia: VNTU (in Ukrainian).
• [5] Ukrainian National Standard. DSTU B.V. 2.6-189: 2013. (2014). Methods of choosing insulation material for insulation of buildings. Kyiv, Ukraine: Ministry of Regional Development, Construction and Housing and Communal Services of Ukraine (in Ukrainian).
• [6] Ratushnyak, G. S., Lyalyuk, A. O., & Biks, Y. S. (2018). 127505. Vinnytsia, Ukraine: State Enterprise “Ukrainian Institute of Intellectual Property” (Ukrpatent) (in Ukrainian).
• [7] Biks, Y., & Aleksishin, K. (2020, November 15). The assessment of envelopes energy efficiency by multicriteria decision analysis methods. Retrieved December 30, 2020. from https://isg-konf.com/uk/about-the-problems-of-science-and-practice-tasks-and-ways-to-solve-them/
• [8] Asdrubali, F., D’Alessandro, F., & Schiavoni, S. (2015). A review of unconventional sustainable building insulation materials. Sustainable Materials and Technologies, 4, 1-17.
• [9] Biks, Y., Ratushnyak, G., & Ratushnyak, O. (2019). Energy performance assessment of envelopes from organic materials. Architecture Civil Engineering Environment, 12(3), 55-67.
• [10] Vėjelienė, J. (2012). Processed straw as effective thermal insulation for building envelope constructions. Engineering Structures and Technologies, 4(3), 96-103.
• [11] Hens, H. S. (2017). Building physics-heat, air and moisture: fundamentals and engineering methods with examples and exercises. John Wiley & Sons.
• [12] Stazi, F. (2017). Thermal inertia in energy-efficient building envelopes. Butterworth-Heinemann.
• [13] Brojan, L., Petric, A., & Clouston, P. L. (2013). A comparative study of brick and straw bale wall systems from environmental, economic and energy perspectives. ARPN Journal of Engineering and Applied Science, 8, 920-926.
• [14] Semko, O. V., Filonenko, O. I., & M’yakyi, E. I. (2013). The building of low residential houses consisting of straw packs and determination of their thermal characteristics. Bulletin of Prydniprovs’ka State Academy of Civil Engineering and Architecture, 8, 47-52 (in Ukrainian).
• [15] Stankevičius, V., & Kairys, L. (2005). The Effect of stochastically dependent physical parameters on the materials’ thermal receptivity coefficient. Materials science (Medžiagotyra), 11(2), 188-192.
• [16] Domínguez-Muńoz, F., Anderson, B., Cejudo-López, J. M., & Carrillo-Andrés, A. (2010). Uncertainty in the thermal conductivity of insulation materials. Energy and Buildings, 42(11), 2159-2168.
• [17] Fareniuk, G. P. (2009). Fundamentals of building energy efficiency and thermal reliability of envelopes. Kyiv: Gamma-Print (in Ukrainian).
• [18] Tabunshchikov, Yu. A., & Brodach, M. M. (2012). Mathematical modelling and optimization of thermal efficiency of buildings. Moscow: AVOK (in Russian).
• [19] De Saulles, T. (2009). Thermal mass explained. Concrete Centre.
• [20] Evrard, A. (2013). Thermal Inertia and Moisture Regulation of straw bale buildings with earth plasters. In PLEA.
• [21] Labat, M., Magniont, C., Oudhof, N., & Aubert, J. E. (2016). From the experimental characterization of the hygrothermal properties of straw-clay mixtures to the numerical assessment of their buffering potential. Building and Environment, 97, 69-81.
• [22] Biks, Y. S. (2017). Prospects for the use of straw products in low-rise construction. Modern Technology, Materials and Design in Construction, 22(1), 75-83 (in Ukrainian).
• [23] Kuznetsova, A. (2010). The use of straw in Ukraine - opportunities and prospects. URL: http://www.ier.com.ua/files/publications/Policy_papers/Agriculture_dialogue/2010/AgPP_31_ukr.pdf (in Ukrainian).
• [24] Rotshtein, A. P. (2018). Reliability and intelligent calculations. Selected articles. Vinnytsia: Nilan Ltd. (in Russian).
• [25] Polovko, A. M., & Gurov, S. V. (2006). Fundamentals of reliability theory. Moscow: BHV-Petersburg (in Russian).
• [26] Berestov, O. V., Soliterman, Yu. L., & Goman, A. M. (2004). Standardization of technical systems’ reliability. Minsk: Technoprint (in Russian).
• [27] Rotshtein, A. P. (1999). Intelligent identification technologies: fuzzy sets, genetic algorithms, neural networks. Vinnytsia: UNIVERSUM-Vinnytsia (in Russian).
• [28] Saati, T. L. (1993). Decision making. Hierarchy analysis process. Moscow: Radio and communication (in Russian).
• [29] Ratushnyak, G. S., & Biks, Y. S. (2018). Factors of reliability of ensuring the energy efficiency of multilayered heat-insulating construction products using a straw. Modern Technology, Materials and Design in Construction, 25(2), 25-30. https://doi.org/10.31649/2311-1429-2018-2-25-30 (in Ukrainian).
• [30] Ukrainian National Standard. DSTU-N B.V. 2.6-190: 2013. (2014). Instruction on the estimated estimation of heat resistance and heat recovery of envelope structures. Kyiv, Ukraine: Ministry of Regional Development, Construction and Housing and Communal Services of Ukraine (in Ukrainian).
• [31] Averkin, A. N., Batyrshin, I. Z., Blishun, A. F., Silov, V. B., & Tarasov, V. B. (1986). Fuzzy sets in control and artificial intelligence models. Moscow: Science (in Russian).