ANALYSIS OF THE PROSPECTS OF ENERGY-ECONOMIC ASSESSMENT OF AGRICULTURAL TECHNOLOGIES

The paper shows that a comprehensive intersectoral approach is needed to address the issues of systematic management of energy saving in agriculture and to justify rational measures of economic support for the state-initiated introduction of energy-saving technologies, machines, and projects. Such requirements are met by the energy-economic (bioenergy) assessment method. The energy-economic assessment consists in comparing the costs of cultivating plants or servicing animals in single units of measurement with the production results and is mainly of national strategic importance. On the basis of such assessment, economic guidelines and incentives for the introduction of new energy-efficient technologies, machines and projects, including the use of renewable energy sources, can be developed. The author presents an approach to improving the methodology of energy-economic assessment of agricultural technologies and projects when using renewable energy sources in technological processes. It is proved that in order to ensure the reliability of the energy-economic assessment associated with permanent technological and organizational changes and the digitalization of technology and economy, it is necessary to continue research to improve the assessment methodology, as well as clarify and regularly update energy equivalents.

1. Pelletier N., Adsli E., Brodt S. et al. Energy intensity of Agriculture and food systems. Annual Review of Environment and Resources, 2011; 36: 223-246. URL: https://doi.org/10.1146/annurev-environ-081710-161014.

2. Woods J., Williams A., Hughes J.K. et al. Energy and food systems. Philosophical transactions of the Royal society B: Biological Sciences, 2010; 365 (1554): 2991-3006. URL: https://doi.org/10.1098/rstb.2010.0172.

3. Pelletier N., Audsley E., Brodt S. et al. Energy intensity of agriculture and food systems. Annual Review of Environment and Resources, 2011; 36: 223-246. DOI:10.1146/ annurev-environ-081710-161014

4. Овчинников О.Г. Влияние научно-технического прогресса на продовольственную безопасность (на примере развития биоэнергетики в сельском хозяйстве США) // США и Канада: экономика, политика, культура. 2017. № 1. С. 54-74.

5. Широков Ю.А. Анализ возможностей по управлению себестоимостью продукции растениеводства // Аграрная Россия. 2020. № 2. С. 32-39. DOI: 10.30906/1999-5636-2020-2-32-39.

6. Smith L., Williams A., Pearce B. (2015). The energy efficiency of organic agriculture: A review. Renewable Agriculture and Food Systems, 30 (3), 280-301. DOI:10.1017/S1742170513000471.

7. Pickova A., Vilhelm V Aspects of energy intensity of agriculture. Ekonomika a Management, Prague University of Economics and Business, 2009 (4). RePEc: prg: jnleam: v: 2009: y:2009: i:4: id:82.

8. Самойлова Н.В. Методика энергоэкономической оценки сельскохозяйственного производства через энергетические эквиваленты стоимости продукции отраслей // Известия ТСХА. 2013. № 6. С. 94-101

9. Qin J., Tao H., Cheng Ch. et al. (2020): Analysis of factors influencing carbon emissions to the energy base. Xinjiang Autonomous region, China. P. 1-15. RePEc: gam: jsusta: v:12: y:2020: i:3: p:1089-: d:316066.

10. Базаров Е.И., Широков Ю.А. Управление энергетическим балансом в интегрированной биотехнической системе // Вестник сельскохозяйственной науки. 1986. № 9. С. 101.

11. Pimentel D., Berardi G., Fast S. Energy efficiency of farming systems: organic and traditional agriculture. Agriculture, ecosystems and environment, 1983; 9(4): 359-372. URL: https://doi.org/10.1016/0167-8809(83)90021-X.

12. Широков Ю.А., Смирнов Г.Н. Технология производства целлюлозо-масляных топливных суспензий // Инновационные направления развития технологий и технических средств механизации сельского хозяйства. Воронеж: Воронежский государственный аграрный университет им. Императора Петра I, 2015. С. 330-333.