Designing of a Feasible Low Pollutant Grid Integrated System for Steel Plant
DOI:
https://doi.org/10.30732/CSVTURJ.20211002007Keywords:
Pollutant Emission, , Net Present Cost,, Levelized Cost of Energy, , Photovoltaic system, , GridAbstract
This paper presents system architecture with low pollutant emission for application in Bhilai Steel Plant (BSP) located in Bhilai, Chhattisgarh, India. Chhattisgarh is very rich in terms of renewable resources like solar, wind and biomass. The availability of solar radiation in this region is significantly rich for any kind of solar generation options. The government provides widespread support for the use of renewable energy, particularly solar and wind which provide power without additional pollutants. These natural energy sources can be harnessed for electricity generation which depends upon the cost and efficiency of technology that is constantly improving to reduce the costs per kWh on the source. Solar energy utilization becomes complex due to supply and demand logic. Also, a backup generating capacity is required due to its intermittent nature, escalating the cost of the system with an increasing proportion of variable renewable sources. Many countries including India, have policies to support renewable to confer priority in the grid system by subsidizing them. The analysis is carried out by investigating the potential of solar energy and collecting data from BSP. In this paper, the existing system is modeled with one option of solar grid integrated system so as to have a low pollutant emission system, together with cost-saving. The existing system is taking power from the power plant(PP) and grid NTPC-SAIL Power Corporation Limited (NSPCL) whereas a solar grid integrated system is also modeled as an option for future energy sources.
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