Mathematical Models for Determination of Specific Energy Need for Heating and Cooling of the Administrative Building
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2018-09-15 
https://doi.org/10.14419/ijet.v7i4.3.19826
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cooling, climatic data, dynamic modes, energy need, energy efficiency indicators, heating, heat losses, mathematical model, solar heat gains. -
According to the building energy balance, most of the resources are spent on maintaining a comfortable indoor microclimate. To estimate the energy resources rational use and to determine building energy efficiency, specific indicators are used per unit area and/or volume.
In this paper, a comparative analysis of various approaches to determination of energy need for heating and cooling that have been used or are introduced in Ukraine and the peculiarities of different climatic data application is carried out. The differences in application of considered methods are established. The analysis of various averaging time intervals (monthly, daily average and hourly) for climatic parameters change in dynamic models during the heating period application influence on heating and cooling load change is carried out. Specific energy need has been established according to different methods and a comparison with the current normative values in Ukraine has been made.
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References
[1] Zakon Ukrainy «Pro enerhetychnu efektyvnist budivel» [Law of Ukraine "Buildings Energy Efficiency"]. Information from the Verkhovna Rada of Ukraine No. 2118-VIII. 2017. 359 p. (ukr.)
[2] Normy ta vkazivky po normuvannyu vytrat palyva ta teplovoyi enerhiyi na opalennya zhytlovykh ta hromads'kykh sporud, a takozh na hospodars'ko-pobutovi potreby v Ukrayini [The norms and guidelines for the standardization of fuel and heat energy costs for the heating of residential and public buildings, as well as for household and domestic needs in Ukraine] KTM-204 Ukrayina 244-94. Approved by the State Committee for Housing and Communal Services of Ukraine on December 14, 1993. - K .: ZAT "VIPOL". 2001. 376 p. (ukr)
[3] Mizhhaluzevi normy spozhyvannya elektrychnoyi ta teplovoyi enerhiyi dlya ustanov i orhanizatsiy byudzhetnoyi sfery Ukrayiny [Intersectoral norms of electric and heat energy consumption for institutions and organizations of the budgetary sphere of Ukraine]. Approved by the State Committee of Ukraine for Energy Saving 25.10.99. - K .: ZAT "VIPOL". 2000. - 104 p.
[4] DSTU N B A.2.2.5: 2007. Proektuvannya. Nastanova z rozroblennya ta skladannya enerhetychnoho pasporta budynkiv pry novomu budivnytstvi ta rekonstruktsiyi [Designing. Guidelines for the development and assembly of energy passports for buildings under new construction and reconstruction]. K.: Minrehionbud Ukrayiny, 2008. 44 p. (ukr)
[5] DBN V.2.6_31:2006. Konstruktsiyi budynkiv ta sporud. Teplova izolyatsiya budivel' [Construction of buildings and structures. Insulation of buildings]. K.: Minbud Ukrayiny. 2006. 64 p. (ukr)
[6] EN 13790:2008. Energy performance of buildings – Calculation of energy use for space heating and cooling. — CEN. European Committee for Standardization, 2008. — 53 р.
[7] DSTU B A.2.2-12:2015. Enerhetychna efektyvnist' budivel'. metod rozrakhunku enerhospozhyvannya pry opalenni, okholodzhenni, ventylyatsiyi, osvitlenni ta haryachomu vodopostachanni [Energy efficiency of buildings. Method of calculation of energy heating, cooling, ventilation, lighting and hot water]. K.: Minrehion Ukrayiny. 2015. 205 p. (ukr)
[8] DBN V.2.6-31:2016. Teplova izolyatsiya budivel' [Thermal insulation of buildings]. K.: Derzhavne pidpryyemstvo "Ukrarkhbudinform". 2016. 33 p. (ukr)
[9] EN ISO 13786:2007. Thermal performance of building component - Dynamic thermal characteristics - Calculation methods. — CEN. European Committee for Standardization, 2007. — 27 р.
[10] J. Vivian, A. Zarrella, G. Emmi, M. De Carli. An evaluation of the suitability of lumped-capacitance models incalculating energy needs and thermal behaviour of buildings. Energy and Buildings. № 150 (2017). Рр. 447–465.
[11] EnergyPlus Energy Simulation Software. http://apps1.eere.energy.gov/buildings/energyplus.
[12] Winkelmann F.C. Modeling Windows in EnergyPlus // Seventh International IBPSA Conference Rio de Janeiro, Brazil August 13-15, 2001. Building Simulation. Pp. 457 – 464.
[13] Krarti M., Chuangchid P., Ihm P. Foundation heat transfer module for EnergyPlus program // Seventh International IBPSA Conference, Rio de Janeiro, Brazil August 13-15, 2001. p. 931 – 938.
[14] German Association of Engineers, Calculation of transient thermal response of rooms and buildings − modelling of rooms. 91.140.10 (VDI 6007-1), BeuthVerlag GmbH, Düsseldorf, 2012.
[15] International Weather for Energy Calculations: https://energyplus.net/weather-location/europe_wmo_region_6/UKR
[16] Tabunschikov Yu.A. Matematicheskoe modelirovanie i optimizatsiya teplovoy effektivnosti zdaniy [Analysis of Mathematical modeling and optimization of buildings thermal efficiency]. Moscow: AVOK–PRES, 2002. 194 p. (rus)
[17] Saeed Sayadi, George Tsatsaronisb, Tatiana Morosuk. A New Approach for Applying Dynamic Exergy Analysis and Exergoeconomics to a Building Envelope // Proceedings Of Ecos 2016 - The 29th International Conference On Efficiency, Cost, Optimization, Simulation And Environmental Impact Of Energy Systems June 19-23, 2016, Portorož, Slovenia.
[18] DSTU-N B V.1.1-27:2010. Budvel'na klimatolohiya [Construction climatology]. K.: Minrehion Ukrayiny. 2010. 127 p. (ukr)
[19] J. Duffie, W. Beckman. Solar Engineering of Thermal Processes. Wiley-interscience. Wiley. 2013. - 928 p.
[20] Deshko V.I., Bilous I.Yu., Hetmanchuk H.O. Bazy klimatolohii dlia vyznachennia enerhetychnykh kharakterystyk budivel [Climatology bases for determining the energy characteristics of buildings]. Energy: economics, technology, ecology. 2017. No. 4. Pp. 67-73. (ukr)
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How to Cite
I. Deshko, V., & Yu. Bilous, I. (2018). Mathematical Models for Determination of Specific Energy Need for Heating and Cooling of the Administrative Building. International Journal of Engineering & Technology, 7(4.3), 325-330. https://doi.org/10.14419/ijet.v7i4.3.19826
