References
- 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).
- Pashynskyi, V. A. (2016). Fundamentals of the theory of reliability of buildings and structures. Kropyvnytskyi: Central Ukrainian National Technical University (in Ukrainian).
- About the energy efficiency of buildings.[Parliamentary paper]. Retrieved July 26, 2019, from https://zakon.rada.gov.ua/laws/show/2118-19 (in Ukrainian).
- Ratushnyak, G. S., & Ratushnyak, O. G. (2006). Management of energy-saving projects by the thermal renovation of buildings [Epub]. Vinnytsia: VNTU (in Ukrainian).
- 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).
- Ratushnyak, G. S., Lyalyuk, A. O., & Biks, Y. S. (2018). 127505. Vinnytsia, Ukraine: State Enterprise “Ukrainian Institute of Intellectual Property” (Ukrpatent) (in Ukrainian).
- 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/
- Asdrubali, F., D’Alessandro, F., & Schiavoni, S. (2015). A review of unconventional sustainable building insulation materials. Sustainable Materials and Technologies, 4, 1–17.
- Biks, Y., Ratushnyak, G., & Ratushnyak, O. (2019). Energy performance assessment of envelopes from organic materials. Architecture Civil Engineering Environment, 12(3), 55–67.
- Vėjelienė, J. (2012). Processed straw as effective thermal insulation for building envelope constructions. Engineering Structures and Technologies, 4(3), 96–103.
- Hens, H. S. (2017). Building physics-heat, air and moisture: fundamentals and engineering methods with examples and exercises. John Wiley & Sons.
- Stazi, F. (2017). Thermal inertia in energy-efficient building envelopes. Butterworth-Heinemann.
- 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.
- 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).
- 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.
- Domínguez-Muñoz, 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.
- Fareniuk, G. P. (2009). Fundamentals of building energy efficiency and thermal reliability of envelopes. Kyiv: Gamma-Print (in Ukrainian).
- Tabunshchikov, Yu. A., & Brodach, M. M. (2012). Mathematical modelling and optimization of thermal efficiency of buildings. Moscow: AVOK (in Russian).
- De Saulles, T. (2009). Thermal mass explained. Concrete Centre.
- Evrard, A. (2013). Thermal Inertia and Moisture Regulation of straw bale buildings with earth plasters. In PLEA.
- 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.
- 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).
- 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).
- Rotshtein, A. P. (2018). Reliability and intelligent calculations. Selected articles. Vinnytsia: Nilan Ltd. (in Russian).
- Polovko, A. M., & Gurov, S. V. (2006). Fundamentals of reliability theory. Moscow: BHV-Petersburg (in Russian).
- Berestov, O. V., Soliterman, Yu. L., & Goman, A. M. (2004). Standardization of technical systems’ reliability. Minsk: Technoprint (in Russian).
- Rotshtein, A. P. (1999). Intelligent identification technologies: fuzzy sets, genetic algorithms, neural networks. Vinnytsia: UNIVERSUM-Vinnytsia (in Russian).
- Saati, T. L. (1993). Decision making. Hierarchy analysis process. Moscow: Radio and communication (in Russian).
- 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).
- 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).
- 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).