dc.contributor.author	Mohammad Rozali, Nor Erniza
dc.date.accessioned	2024-05-19T07:08:20Z
dc.date.available	2024-05-19T07:08:20Z
dc.date.issued	2014
dc.description	Thesis (PhD. (Chemical Engineering))
dc.description.abstract	The International Energy Agency has estimated a renewable power escalation of 40% in the next five years, and expected the renewable energy (RE) to make up almost a quarter of global power mix. Hybrid Power Systems (HPS) comprising RE sources can provide an effective safeguard while enhancing energy security and efficiency. Systematic methods to design and perform optimal power allocation in HPS are required in order to maximise power recovery as well as profitability. In this study, new algebraic and graphical Process Integration tools based on the Pinch Analysis concept have been developed for the optimal design as well as allocation of power for a HPS. The new Power Pinch Analysis (PoPA) techniques introduced in this study complement the modeling tools, particularly in offering visualisation advantages as well as vital insights on the network design, and providing designers with better control over the design decisions. Important decision variables during various design stages including the real-time amount of electricity transfer, stored and outsourced were established prior to the in-depth analysis. The new framework proposed in this research consisted of five key components. The first component introduced new systematic techniques to integrate the HPS both graphically and algebraically. Targets for first day and continuous 24 hours operations had been established to achieve 96.94% reduction in the conventional electricity requirement for the studied wind-solar system in Case Study 1. Consideration of energy losses during conversion, storage and transfer processes were incorporated into the second technique in order to reflect the actual HPS performance. Incorporation of the losses into the method leads to 31.26% reduction in the storage capacity as presented in the case study. The third technique presented a handy sizing method to achieve optimal configuration in a HPS with multiple generators. The studied system showed that the minimum payback period of 11.78 years was obtained for the optimal configuration. Effects of peak-off-peak electricity pricing were taken into account in the load shifting procedure as proposed in the fourth technique. Application on case study gave electricity cost savings of RM 80,881. The final component was developed to guide the designers to decide on the most cost-effective storage scheme for their HPS considering storage types, efficiencies, costs and power trends factor. The costeffective storage for the investigated household system was the superconducting magnetic storage with capacity of 26.12 kWh, while the Lead-Acid battery storage of 15.38 MWh capacity was best applied in the presented industrial case study
dc.description.sponsorship	Faculty of Chemical Engineering
dc.identifier.uri	http://openscience.utm.my/handle/123456789/1165
dc.language.iso	en
dc.publisher	Universiti Teknologi Malaysia
dc.subject	Hybrid power systems
dc.subject	Electric power production
dc.subject	Electric power distribution—Design and construction
dc.title	New power pinch analysis techniques for optimal design of hybrid power systems
dc.type	Thesis
dc.type	Dataset

New power pinch analysis techniques for optimal design of hybrid power systems

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