DEVELOPMENT OF A METHODOLOGY FOR MODELING ENERGY SUPPLY OF ENTERPRISES BASED ON RENEWABLE ENERGY SOURCES
Abstract
We outline a potential scenario of energy consumption transition to renewables for the bakery industry of Ukraine where the total electricity demand is satisfied by solar energy. We simulate such a transition using parametric models combined with the Cobb-Douglas production function. We have selected 15 companies, which are ranked into three groups using cluster analysis. Geographically, the production facilities are located in Mykolaiv, Kherson and Zaporizhzhia regions, and the solar radiation in these territories is identical. For the three groups of bakeries in Southern Ukraine, the SAM program calculated the key projection feasibility indicators for the transition of enterprises to renewable sources, considering economic indices. This enabled us to calculate the positive effects of such transformation processes for both an enterprise and the industry as a whole.
References
Kantor C., Mclean E., Kantor M. (2017) Climate Change Influence on Agriculture and the Water-Energy-Food Nexus in Central and Eastern European Countries. Not Sci Biol, no. 4, pp. 449–459. DOI: https://doi.org/10.15835/nsb9410193
Morin Chasse R. (2016) Essays in environmental and energy economics. 81p. Available at:https://search.proquest.com/docview/1836101104/previewPDF/871AD1FCAE514F45PQ/3?accountid=11004 (accessed 11 May 2020).
Xing J. (2018) Three Essays on the Economic Impact of Fuel Economy Policies. (PhD Thesis) Cornell University Graduate School, USA New York. Cornell University Graduate School. 190 p.
Solomon Edwin Dale (2016) “The Mass Flux of Non-renewable Energy for Humanity” (PhD Thesis) USA. Arkansas. University of Arkansas.
Lee S., Prabhu, V. V. (2015) Energy-aware feedback control for production scheduling and capacity control. International Journal of Production Research, no. 53(23), pp. 7158-7170.
Fullerton D., Ta, C. L. (2019). Environmental policy on the back of an envelope: A Cobb-Douglas model is not just a teaching tool. Energy Economics, 84, 104447.
Samuelson, P., & Nordhaus, W. (2009). Economics (Publishing). 744 p
Muellbauer, J. (1990). Aggregate Production Functions and Productivity Measurement: A New Look (pp. 157–218). https://doi.org/10.1016/b978-0-444-88515-9.50013-2
Samuelson, P. A. (Paul A. (1983). Foundations of economic analysis. Harvard University Press. 632 p.
Bekirov E. A., Voskresenskaya S. N., Khimich A. P. (2010) Raschet sistemy avtonomnogo energosnabzheniya s ispol’zovaniyem fotoelektricheskikh preobrazovateley. Metod. posobiye dlya dipl. proyektirovaniya. Simferopol’: NAPKS, 83 p. (in Ukrainian
Schaltegger, S., Buser, H., & Sturm, A. (1998). Eco-efficiency by eco-controlling : on the implementation of EMAS and ISO 14001. Published in 1998 in Zürich by VDF Hochschulverlag AG. pp 151-167.
Tascheev Y. V. Ekonomichnyj mekhanizm zabezpechennja efektyvnogho vykorystannja vidnovljuvanykh dzherel energhiji na pidpryjemstvakh [The economic mechanism to ensure the efficient use of renewable energy in enterprises]. Manuscript. Dissertation for the scientific degree of a Candidate of Economic Sciences (Ph.D.) specialty 08.00.04 economics and management of enterprises (according to the types of economic activities). Odessa National Economic University, Odessa, 2019. [in Ukrainian]. 296 p.
State Statistics Service of Ukraine. (2020). Site of State Statistics Service of Ukraine. Available at::http://www.ukrstat.gov.ua/ (accessed: 08 May 2020)
Kantor C., Mclean E., Kantor M. Climate change influence on agriculture and the water-energy-food nexus in central and eastern european countries. Notulae Scientia Biologicae. 2017. Vol. 9. № 4. P. 449 – 459.
Chassé R. M. Essays in Environmental and Energy Economics. University of Wyoming, 2016. 81 p. URL: https://search.proquest.com/docview/1836101104/previewPDF/ 871AD1 FCAE5 14F45PQ/3?accountid=11004 (дата звернення: 11.05. 2020)
Xing, J. Three Essays on the Economic Impact of Fuel Economy Policies. (PhD Thesis) Cornell University Graduate School, USA. New York. Cornell University Graduate School, 2016. 190 p.
Solomon, Edwin Dale, “The Mass Flux of Non-renewable Energy for Humanity” (PhD Thesis) USA. Arkansas. University of Arkansas, 2016 50 p.
Lee S., Prabhu V. V. Energy-aware feedback control for production scheduling and capacity control. International Journal of Production Research, 2015. Vol. 53. №. 23. P. 7158 – 7170.
Fullerton D., Ta C. L. Environmental policy on the back of an envelope: A Cobb-Douglas model is not just a teaching tool. Energy Economics, 2019. Vol. 84. P. 104447.
Samuelson P., Nordhouse V. Economics: a textbook. Irwin, 2009.744 p.
Muellbauer J. Aggregate Production Functions and Productivity Measurement: A New Look. Contributions to Economic Analysis. Elsevier, 1990. – Vol. 195. P. 157 –218.
Samuelson P. A. Foundations of Economic Analysis (Harvard University Press, 1947). Samuelson. The Foundations of Economic Analysis, 1945. 632 p.
Бекиров Э. А., Воскресенская С. Н., Химич А. П. Расчет системы автономного энергоснабжения с использованием фотоэлектрических преобразователей. Метод. пособие для дипл. проектирования. Симферополь: НАПКС, 2010. 83 c.
Schaltegger S. et al. Eco-efficiency by Eco-controlling: On the Implementation of EMAS and ISO 14001: Including Company Applications at Flumroc Ltd., Ciba-Geigy Ltd., Bank Sarasin & Cie. – Vdf Hochschulverlag ETHZ, 1998. P. 151-167
Тащеєв Ю. В. Економічний механізм забезпечення ефективного використання відновлюваних джерел енергії на підприємствах : дис… канд. економ. наук: 08.00.04 Одеський національний економічний університет, 2018. 296 с.
Державна служба статистики України. Сайт Державної служби статистики України. URL: http://www.ukrstat.gov.ua/ (дата звернення: 10.05. 2020)