International Transaction Journal of Engineering, Management, & Applied Sciences & Technologies

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:: International Transaction Journal of Engineering, Management, & Applied Sciences & Technologies

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ISSN 2228-9860
eISSN 1906-9642
CODEN: ITJEA8


FEATURE PEER-REVIEWED ARTICLE

Vol.11(16) (2020)

  • Dynamic Economic Emission Dispatch Optimization Integrated Wind and Solar Energy Systems

    Ismail Marouani, Chefai Dhifaoui, and Hsan Hadj Abdallah (Control & Energies Management (CEM-Lab), National Engineering, School of Sfax, ENIS Sfax, TUNISIA).

    Disciplinary: Electrical Engineering Technology, Energy Technology Management, Renewable Energy, Sustainability.

    ➤ FullText

    DOI: 10.14456/ITJEMAST.2020.324

    Keywords: DEEDP; Ramp rate; Solar power; MOALO; Wind power; Transmission losses; Valve point effect.

    Abstract
    This paper focuses on economic emission dispatch, this dispatching is able to determine the optimum operating strategy to minimize energy costs, enable reduced emissions, and better utilization of renewable energy resources such as wind and solar power. Many countries have made great efforts to save energy and make efficient use, by the development and exploitation of renewable energy such as wind and solar energy, which is a very important alternative to reduce gas emissions, reduce the bill for power generation. In this paper an algorithm (MOALO) called multi-objective ant lion optimizer, is used to solve the dynamic economic environmental dispatch problems with and without ramp rate considering the integration of wind and solar energy. This applied approach is used optimal solutions for power generations and then calculates emission and cost functions. The combined dynamic economic emission dispatch problem (Combined dynamic economic emission dispatch problem ) is employed as a muti-objectives problem in this work, respecting many equality and inequality constraints. The proposed algorithm was applied to a 10-units test power system including wind and solar power. A comparison of the results is made with those in literature. The simulations are executed in MATLAB®-Simulink.

    Paper ID: 11A16O

    Cite this article:

    Marouani, I., Dhifaoui, C., and Abdallah, H. H. (2020). Dynamic Economic Emission Dispatch Optimization Integrated Wind and Solar Energy Systems. International Transaction Journal of Engineering, Management, & Applied Sciences & Technologies, 11(16), 11A16O, 1-18. http://doi.org/10.14456/ITJEMAST.2020.324



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Other issues:
Vol.11(16)(2020)
Vol.11(15)(2020)
Vol.11(14)(2020)
Vol.11(13)(2020)
Vol.11(12)(2020)
Vol.11(11)(2020)
Vol.11(10)(2020)
Vol.11(9)(2020)
Vol.11(8)(2020)
Vol.11(7)(2020)
Vol.11(6)(2020)
Vol.11(5)(2020)
Vol.11(4)(2020)
Vol.11(3)(2020)
Vol.11(2)(2020)
Vol.11(1)(2020)
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