Please use this identifier to cite or link to this item: https://hdl.handle.net/10321/5485
Title: Sustainable energy transition and optimization of grid electricity generation and supply
Authors: Kabeyi, Moses Jeremiah Barasa 
Issue Date: May-2024
Abstract: 
Clean and low-carbon energy sources and technologies have emerged as a critical driver in
delivering the energy transition and achieving net zero-carbon emissions. All energy sources
and power systems produce greenhouse gases (GHGs) and hence they contribute to
anthropogenic greenhouse gas emissions and resultant climate change besides contributing to
other negative environmental impacts. Energy sustainability remains a major challenge
globally due to current heavy reliance on depletable and polluting fossil fuels for most of
global energy needs. This study examines the energy transition strategies and proposes a
roadmap for sustainable energy transition for sustainable energy planning and grid electricity
generation and supply in wake of commitments made by the world community to the Paris
Agreement aimed at reducing greenhouse gas emissions and limiting the rise in global average
temperature to 2oC and preferably 1.5oC above the preindustrial level and realisation of the
sustainable development goal of the United Nations. The sustainable transition strategies
typically consist of three major technological changes namely, energy savings on the demand
side, generation efficiency at production level and fossil fuel substitution by various renewable
energy sources and low carbon non-renewable sources like nuclear power and carbon emission
reduction strategies like carbon capture and sequestration and a conversion from high carbon
fossil fuels like coal and oil to natural gas which remains the cleanest fossil fuel. The study
demonstrated that decentralised generation with application of both demand side management
and behind the meter management (BTM) strategies are effective measures to increase the use
of renewable energy resources which are often locally available leading to higher uptake of
renewable energy sources and conversion of consumers to prosumers making the transition
economically sustainable. Waste to energy options have a significant potential to contribute to
the energy transition e.g. use of biowaste for biogas production, slaughterhouse waste biodigestion for biogas and electricity generation and waste treatment and disposal, waste heat
recovery from used geothermal for extra power generation and reinjection to improve the
reservoir sustainability and use of bagasse and sugarcane trash for grid-based power
production in sugar factories. Therefore, domestic, and industrial scale waste to energy
conversion can enhance the economic sustainability of waste management process by offering
useful energy substitutes for fossil fuels and enhanced energy security through decentralisation
of generation. Whereas sustainable development has social, economic, and environmental pillars, energy sustainability is best analysed by five-dimensional approach consisting of
environmental, economic, social, technical, and institutional/political sustainability to
determine energy resource sustainability. The study recommends the adoption of
sustainability-based planning for energy development and optimisation of electricity
generation and supply where energy sources are analysed and ranked based on the five
dimensions of energy sustainability instead of Least Cost Development Planning (LCDP)
often applied by many countries. On this basis, the sustainable energy transition and
optimisation of power generation will rely on both renewable and non-renewable energy since
both have an important role in the realisation of the energy transition plans even though the
desire is to shift entirely to renewable energy sources by the year 2050. The sustainability of
various energy sources was assessed with hydrogen, wind, solar, sugarcane bagasse and cane
trash, biogas and ocean energy technologies proving to be among the most sustainable
renewable energy and sustainable sources. The study also examined various power plants and
energy conversion systems for electricity generation in terms of their specific role and
potential in grid-based power generation with hydro power plants, geothermal, nuclear, fuel
cells, raking high on performance indicators like load and capacity factors making them ideal
for base load power supply. Diesel engines and gas turbines using cogeneration and dual cycle
systems powered by cleaner fuels like natural gas, hydrogen and biomethane will play an
important role in supplying intermediate and peak load power. The study highlighted enabling
technologies and concepts in the energy transition which include decentralisation of
generation, cogeneration and trigeneration, demand side and behind the meter management
microgrids and smart grid technologies, energy and generation planning and optimisation
models, energy storage, electrification of transport and use of electric cars as decentralised
electricity sources through the V2X technologies like the G2V and V2G, and carbon capture
and sequestration for emissions reduction in fossil fuel power plants making them more
sustainable. The study classifies electric vehicles as distributed power plants and variable
loads with extensive use of energy storage while sugar cane bagasse is noted as a sustainable
energy resource for power generation by cane sugar factories by application of more efficient
grid connected cogeneration power plants. The study identified long project gestation period
as the main factor limiting nuclear and geothermal energy deployment and recommends the
adoption of modularised wellhead generators and small modular nuclear reactors (SMRs) as a solution to enhance exploitation of these sustainable energy and technologies through faster
deployment with high degree of flexibility. Biogas and biomethane demonstrated significant
potential as renewable energy sources for power generation and substitute fuels in all
applications of fossil natural gas. The study recommends sustainability-based planning for the
energy sector and power generation and use of both renewable and non-renewable but
sustainable sources of energy, adoption of smart energy concept by all sectors and investment
in energy technology and infrastructure development for hydrogen and other promising
energy sources like ocean thermal, wave and tidal energy and the conversion of the transition
from the traditional to smart grid systems and a shift from centralised to decentralised power
generation. Since the transport sector accounts for a significant portion of the global
greenhouse gas emissions, electrification of the transport sector and coupling with the power
sector is a key strategy recommended for the transition with the smart grid and microgrids
playing an enabling role. Since energy sources and generation technologies have associated
emissions occurring at different sections of the lifecycle, the use of lifecycle costs and
emissions are helpful in long term energy and generation planning which demonstrate that
renewable sources and nuclear are the most sustainable when analysed within the five
dimensions of energy sustainability, but with the non-renewable sources playing a critical role
as dispatchable sources for sustainable grid power generation, while the smart grids and use of
energy storage can increase the uptake of variable renewables to as high as 95% to 100% up
from a low of 20-25% uptake of variable renewables with the traditional grid. This will
significantly help the world in achieving the global emissions and climate targets as. stipulated
in the Paris Agreement as well as the sustainable development goals (SDGs).
Graphical Abstract
The overall objective of the study was to provide solutions to build global energy systems
based on renewable and sustainable energy resources and optimise power generation and
consumption by use of sustainable energy resources and generation technologies based on the
five dimensions of energy sustainability. A sustainable energy system should intergrade
electricity and other sectors through smart electricity grids, smart gas grids and smart heat
grids as demonstrated below.
Description: 
Thesis submitted in fulfillment of the requirements for the award of the degree of Doctor of Engineering in Industrial Engineering, Durban University of Technology, Durban, South Africa, 2023.
URI: https://hdl.handle.net/10321/5485
DOI: https://doi.org/10.51415/10321/5485
Appears in Collections:Theses and dissertations (Engineering and Built Environment)

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