Smart Transition to Climate Management of the Green Energy Transmission Chain

Climate challenges in recent decades have forced a change in attitude towards forms of environmental interaction. The International Climate Conference COP26 evidences the relevance of the climate issue at the global level in Glasgow (November 2021). A decrease in natural energy resources leads to a...

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Bibliographic Details
Published in:Sustainability 2022-09, Vol.14 (18), p.11449
Main Authors: Borysiak, Olena, Wołowiec, Tomasz, Gliszczyński, Grzegorz, Brych, Vasyl, Dluhopolskyi, Oleksandr
Format: Article
Language:English
Subjects:
Algorithms
Alternative energy sources
Biodiesel fuels
Biofuels
Carbon
Carbon sources
Chains
Clean energy
Climate change
Consumers
Cooling
Cooperation
COVID-19
Electric power transmission
Emissions
Energy conservation
Energy consumption
Energy efficiency
Energy industry
Energy resources
Energy transmission
Environmental policy
Environmental protection
Force and energy
Geospatial data
Global temperature changes
Green market
Green technology
Heat
Hydroelectric power
Indicators
Industrial plant emissions
Linear programming
Methods
Modelling
Natural gas
Partnerships
Petroleum industry
Petroleum products
Power plants
Raw materials
Renewable resources
Resource conservation
Supply chains
Sustainable development
Technology application
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Summary:Climate challenges in recent decades have forced a change in attitude towards forms of environmental interaction. The International Climate Conference COP26 evidences the relevance of the climate issue at the global level in Glasgow (November 2021). A decrease in natural energy resources leads to a search for alternative energy sources. Given this, this article is devoted to studying the peculiarities of the transition to climate management of the green energy transmission chain based on the circular economy and smart technologies. This paper has used simulation modeling to develop an algorithm for applying a smart approach to climate management of the green energy transmission chain based on the work of Industry 4.0 technologies. The result of this modeling will be the importance of strengthening the ability to develop intersectoral partnerships to create climate-energy clusters based on a closed cycle of using energy resources and developing smart technologies. At the same time, it has been found that COVID-19 has changed the behaviour of energy consumers towards the transition to the use of energy from renewable sources that are carbon neutral. With this in mind, this article has assessed the climate capacity of industries to use green energy from renewable sources based on resource conservation (rational use of energy resources) and climate neutrality. The industries of Ukraine, which are the largest consumers of energy and, at the same time, significantly affected by climate change, were taken for the study: industry, transport, and agriculture. The methodology for determining the indicator of the climate capacity of sectors in the transition to green energy has been based on the correlation index (ratio) of the consumption indicator of various types of energy by industries (petroleum products; natural gas; biofuels and waste; electricity) and the indicator of gross value added of industries in pre-COVID-19 and COVID-19 conditions. The results have indicated that the use of energy from renewable sources (biofuels and waste) for the production of goods and services, as well as the economical nature of the provision of raw materials (biomass and faeces) are factors that ensure climate industry neutrality and enhance its climate capability. The prospects of such effects of assessing the climate capacity of sectors will be the basis for the rationale to develop intersectoral partnerships to create climate-energy clusters based on a closed cycle of using e
ISSN:2071-1050
2071-1050
DOI:10.3390/su141811449