Abstract
A groundswell of opinion in utilizing environmentally friendly energy technologies has been put forth worldwide. In this paper, we consider an energy generation plant distribution and allocation problem under uncertainty to get the utmost out of available developments, as well as to control costs and greenhouse emissions. Different clean and traditional energy technologies are considered in this paper. In particular, we present a risk-averse stochastic mixed-integer linear programming (MILP) model to minimize the total expected costs and control the risk of CO2 emissions exceeding a certain budget. We employ the conditional value-at-risk (CVaR) model to represent risk preference and risk constraint of emissions. We prove that our risk-averse model can be equivalent to the traditional risk-neutral model under certain conditions. Moreover, we suggest that the risk-averse model can provide solutions generating less CO2 than traditional models. To handle the computational difficulty in uncertain scenarios, we propose a Lagrange primal-dual learning algorithm to solve the model. We show that the algorithm allows the probability distribution of uncertainty to be unknown, and that desirable approximation can be achieved by utilizing historical data. Finally, an experiment is presented to demonstrate the performance of our method. The risk-averse model encourages the expansion of clean energy plants over traditional models for the reduction CO2 emissions.
Highlights
With more and more severe challenges resulting from environmental issues, energy generation has been attracting increased attention in society
The above results imply that the risk-averse model is able to provide solutions that are more friendly to the environment than risk-neutral model
To make a proper planning of multimodal energy generation technologies to meet uncertain more friendly to the environment than risk-neutral model. This means that the risk-averse model can demand, we present a risk-averse stochastic programming based on conditional value-at-risk (CVaR) to minimize total costs contribute more tothe reducing
Summary
With more and more severe challenges resulting from environmental issues, energy generation has been attracting increased attention in society. It is projected that by 2035 nuclear energy will increase by 12.2%, natural gas by 46%, and the growth of renewable energy supply by 41% [1]. If this prediction comes true, increasing CO2 emissions will lead to an inestimable impact on climate change. Clean energy generation technologies have been greatly developed over the past decades. Many new technologies involving environmentally friendly or clean energy generation infrastructures have emerged to meet industrial or domestic demands (e.g., nuclear energy, solar photovoltaic energy, hydroelectric energy and wind turbine energy, etc.). There is a Energies 2019, 12, 2275; doi:10.3390/en12122275 www.mdpi.com/journal/energies
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