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DC poleHodnotaJazyk
dc.contributor.authorAbushamah, Hussein Abdulkareem Sale
dc.contributor.refereeKrál Vladimír, Doc. Ing. Ph.D.
dc.contributor.refereeMastný Petr, Doc. Ing. Ph.D.
dc.date.accepted2024-3-14
dc.date.accessioned2024-07-12T09:12:21Z-
dc.date.available2022-9-1
dc.date.available2024-07-12T09:12:21Z-
dc.date.issued2024
dc.date.submitted2023-11-9
dc.identifier83909
dc.identifier.urihttp://hdl.handle.net/11025/57062-
dc.description.abstractThe air conditioning sector is one of the major contributors to electricity consumption and carbon emissions in many regions over the world. For example, in hot climate regions such as the Gulf Cooperation Council (GCC), about half of the annual generated electricity is for air-conditioning, leading to significant carbon emissions. The widely adopted scenario is burning the fuel to produce heat, converting the heat to electricity, transporting the electricity through HV/MV/LV grids to supply electric-driven cooling systems. Proceeding in this manner puts pressure on power grids, raises investments for expanding the electrical infrastructure, drives up carbon emissions, and leads to more energy losses due to unwanted energy conversions and transmissions. This study presents a carbon-free thermally driven district cooling system to overcome these issues of the electric-driven cooling scenario. The proposed system here employs a nuclear heat-only reactor called Teplator as a carbon-free primary heat source driving absorption chillers. This idea is techno-economically evaluated from two different perspectives, namely, the energy policy viewpoint and the investor's point of view. First, from an energy policy viewpoint, adopting the proposed system is compared to the electric scenario based on levelized values for cooling demand, costs, and energy consumption without dealing with details of a specific case-based design or operation. From an investor's viewpoint, a detailed method is developed to optimize the proposed system's design and operation, including the heat transmission system and a centralized cooling plant, for supplying an hourly-based demand model. A competition-based optimization process is performed by including several alternative units, such as thermal energy storage, gas boilers, and compression chillers, which simultaneously also checks the electric-driven option. The developed models are coded in MATLAB and simulated. The results confirm the proposed system's superiority in cost, electricity, and carbon emission saving compared with fossil fuel-based electrically driven district cooling systems. However, the performed sensitivity analyses show that this superiority could be limited as the electricity price decreases and heat transmission pipeline length increases.cs
dc.format79
dc.language.isoen
dc.publisherZápadočeská univerzita v Plzni
dc.rightsPlný text práce je přístupný bez omezení
dc.subjectdistrict coolingcs
dc.subjectnuclear heat-only small modular reactorscs
dc.subjectteplatorcs
dc.subjectelectricity and carbon emission savingcs
dc.subjectpower gridcs
dc.subjectoptimization.cs
dc.titleOptimisation of Renewable and SMR Energy Mixcs
dc.title.alternativeOptimisation of Renewable and SMR Energy Mixen
dc.typedisertační práce
dc.thesis.degree-namePh.D.
dc.thesis.degree-levelDoktorský
dc.thesis.degree-grantorZápadočeská univerzita v Plzni. Fakulta elektrotechnická
dc.thesis.degree-programElectrical Engineering and Information Technology 
dc.description.resultObhájeno
dc.description.abstract-translatedThe air conditioning sector is one of the major contributors to electricity consumption and carbon emissions in many regions over the world. For example, in hot climate regions such as the Gulf Cooperation Council (GCC), about half of the annual generated electricity is for air-conditioning, leading to significant carbon emissions. The widely adopted scenario is burning the fuel to produce heat, converting the heat to electricity, transporting the electricity through HV/MV/LV grids to supply electric-driven cooling systems. Proceeding in this manner puts pressure on power grids, raises investments for expanding the electrical infrastructure, drives up carbon emissions, and leads to more energy losses due to unwanted energy conversions and transmissions. This study presents a carbon-free thermally driven district cooling system to overcome these issues of the electric-driven cooling scenario. The proposed system here employs a nuclear heat-only reactor called Teplator as a carbon-free primary heat source driving absorption chillers. This idea is techno-economically evaluated from two different perspectives, namely, the energy policy viewpoint and the investor's point of view. First, from an energy policy viewpoint, adopting the proposed system is compared to the electric scenario based on levelized values for cooling demand, costs, and energy consumption without dealing with details of a specific case-based design or operation. From an investor's viewpoint, a detailed method is developed to optimize the proposed system's design and operation, including the heat transmission system and a centralized cooling plant, for supplying an hourly-based demand model. A competition-based optimization process is performed by including several alternative units, such as thermal energy storage, gas boilers, and compression chillers, which simultaneously also checks the electric-driven option. The developed models are coded in MATLAB and simulated. The results confirm the proposed system's superiority in cost, electricity, and carbon emission saving compared with fossil fuel-based electrically driven district cooling systems. However, the performed sensitivity analyses show that this superiority could be limited as the electricity price decreases and heat transmission pipeline length increases.en
dc.subject.translateddistrict coolingen
dc.subject.translatednuclear heat-only small modular reactorsen
dc.subject.translatedteplatoren
dc.subject.translatedelectricity and carbon emission savingen
dc.subject.translatedpower griden
dc.subject.translatedoptimization.en
Vyskytuje se v kolekcích:Disertační práce / Dissertations (KEE)

Soubory připojené k záznamu:
Soubor Popis VelikostFormát 
Final Thesis Hussein.pdfPlný text práce3,68 MBAdobe PDFZobrazit/otevřít
abushamah_opon.pdfPosudek oponenta práce1,51 MBAdobe PDFZobrazit/otevřít
abushamah_publ.pdfPosudek vedoucího práce608,28 kBAdobe PDFZobrazit/otevřít
abushamah_zapis.pdfPrůběh obhajoby práce734,89 kBAdobe PDFZobrazit/otevřít
Final_Thesis_Hussein.pdfVŠKP - příloha3,68 MBAdobe PDFZobrazit/otevřít  Vyžádat kopii


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