Modelling and Analysis of Mobile Energy Transmission for Offshore Wind Power : An analysis of flow batteries as an energy transmission system for offshore wind power

Lundin, Rasmus, Beitler-Dorch, Benjamin

January 2018

A comparison between a traditional fixed high voltage direct current energy transmission system and a mobile transmission system utilizing vanadium redox flow batteries has been conducted in this degree work.  The purpose of this comparison was to evaluate if a mobile energy transmission system could be competitive in terms of energy efficiency and cost-effectiveness for use in offshore wind power applications. A literary study was made to fully grasp the various technologies and to create empirical ground of which cost estimation methods and energy calculations could be derived. A specific scenario was designed to compare the two transmission systems with the same conditions. To perform the comparison, a model was designed and simulated in MATLAB. The results from the model showed that the flow battery system fell behind in energy efficiency with a total energy loss of 33.3 % compared to the 11.7 % of the traditional system, future efficiency estimations landed it at a more competitive 17.5 %. The techno-economic results proved that a mobile flow battery system would be up to nine times more expensive in comparison to a traditional transmission system, with the best-case scenario resulting in it being roughly two times more expensive. The main cause of this was found out to be the expensive energy subsystem, specifically the electrolyte, used in the flow battery system. Several environmental risks arise when using a flow battery system with this electrolyte as well which could harm marine life severely. In conclusion; with further development and cost reductions, a case could be made for the advantages of a truly mobile energy transmission system. Specifically, in terms of the pure flexibility and mobility of the system, allowing it to circumvent certain complications. The mobility of the system gives the possibility of selling energy where the spot prices are at their highest, providing a higher revenue potential compared to a traditional fixed system. As for now though, it is simply too expensive to be a viable solution.

Offshore Wind

High Voltage Direct Current

Vanadium Redox Flow Battery

Techno-economic

Transmission

Levelized Cost of Energy

Efficiency.

Energy Systems

Energisystem

Applications of Traditional and Concentrated Photovoltaic Technologies for Reducing Electricity Costs at Ontario Data Centers

Tomosk, Steven

January 2016

Demand for cloud-based applications and remote digital storage is increasing. As such, data center capacities will need to expand to support this shift in computing. Data centers consume substantial amounts of electricity in support of their operations, and larger data centers will mean that more energy is consumed. To reduce electricity bills, data center operators must explore innovative options, and this thesis proposes leveraging solar technology for this purpose. Three different photovoltaic and concentrated photovoltaic costing scenarios, as well as four different Ontario-based electricity tariff scenarios – time-of-use, feed-in tariff, power purchase agreement, and a peak-dependent electricity charge involving the province’s global adjustment fee – will be used to determine if there is a business case for using solar technology at data centers in Ontario to reduce energy costs. Discounted net present value, return on investment, internal rate of return, and levelized cost of electricity will be calculated to determine the economic viability of solar for this application, and both deterministic and stochastic results will be provided. Sensitivity of the four metrics to variability from energy yield, operations and maintenance costs, as well as system prices will also be presented.

Data center

Economic analysis

Feed-in Tariff

Global Adjustment

Internal rate of return

Levelized Cost of Electricity

Offsetting

Ontario

Photovoltaics

Solar

Developing a holistic framework to investigate the environmental, social, and economic suitability of tidal stream energy in British Columbia’s remote coastal diesel reliant First Nations Communities

Richardson, Riley L.

06 January 2021

This thesis holistically examines the potential for tidal stream turbine (TST) integration to displace diesel generated electricity in remote coastal First Nations communities within the Marine Plan Partnership for the North Pacific Coast region of British Columbia. This thesis utilizes a combination of spatial analysis (GIS Multi-Criteria Decision Analysis) to identify sites; stakeholder engagement to assess TST suitability, bridge knowledge gaps, and understand desired characteristics of community energy systems; and Levelized Cost of Energy (LCOE) analyses for existing diesel and externality included scenarios along with potential TST costs in a candidate community. Results illustrate the need for information within these communities, from resource quantification to characteristics of renewable energy technologies and system feasibility; self-sufficiency as being the primary transition driver; and funding/human resource capacity as being substantial barriers. Within the study region ≈89.8 km2 of feasible resource was identified, with ≈22 km2 of potentially suitable tidal resource in proximity to nine communities. The COVID-19 pandemic resulted in difficulties contacting and arranging interviews with the most suitable communities. Driven by the holistic research mandate requiring community stakeholder engagement to occur in tandem with the economic analyses, Queen Charlotte Village and Skidegate Landing on Haida Gwaii were chosen as the candidate communities, despite not being the most suitable identified communities. The community interviews revealed TSTs as being an acceptable renewable energy technology. Furthermore, the identified site in Skidegate Inlet (SI) was found to have favourable Marine Spatial Planning (MSP) for TST development. Existing diesel generation carries a LCOE of $0.63/kWh, being $0.08-0.14 more per kWh than the literature cited LCOE range for TSTs. The LCOE for CO2 equivalent externalities at current carbon tax prices was found to be an additional $0.02/kWh. Despite having a technically viable peak spring current speed, the SI site was financially unviable for 284 kW of rated capacity across all diesel LCOE scenarios driven by capacity factor (1.62%), high cabling costs (approximately one third of capital costs), and outdated data/assumptions within the Natural Resources Canada Tidal Project Cost Estimation tool used in the tidal LCOE calculations. This work contributes to the progression of tidal energy development on BCs coast along with demonstrating the utility of holistic assessment frameworks for RETs across environmental, social, and economic considerations. The results of this thesis can inform existing MSP efforts in the Marine Plan Partnership for the North Pacific region and the framework developed can be built upon and altered for global use in pursuit of sustainable energy transitions. / Graduate

Tidal energy

Multi-Criteria Decision Analysis

Coastal British Columbia

Levelized Cost of Energy Analysis

Stakeholder engagement

GIS

Renewable energy

Design optimization of utility-scale PV power plant

Farzaneh Kaloorazi, Meisam, Ghaneei Yazdi, Marzieh

January 2021

Solar energy market has been rapidly growing in Sweden over the past few years. Älvdalen municipality in central Sweden is investigating the possibility of installing a utility-scale solar power plant. In the present work, we investigate technical design and economic viability of a utility-scale solar power plant in Älvdalen. Several photovoltaics (PV) designs on a 6.6-hectar land are modeled and analyzed. The installation capacity depends on design parameters, such as inter-row spacing distance and orientation.PVsyst simulation tool is used to model several PV system configurations, consisting of both mono- and bifacial PV modules. An extensive sensitivity analysis is performed to get a deep understanding of different design parameters and their effects on performance and production yield of the plant.For PV systems consisting of monofacial PV panels, a set of parameters is investigated, namely, tilt angle of PV arrays, space between rows of the plant. It is observed that an optimized design requires a careful consideration of the two parameters, since they considerably affect the amount of self-shading (shading of PV rows on each other).The optimum design generates more than 5000 MWh electricity annually.Bifacial configurations are designed in two forms: tilted (south or south-east facing) and vertical (east-west oriented). Tiled bifacial systems are basically similar to the monofacial ones. A comparison between the two systems shows that the bifacial gain is between 3 % to 10 %, depending on the tilt angle, inter-row spacing, and PV array height above the ground. Electricity generation per surface area of the vertical east-west bifacial configuration is significantly lower compared to the others and therefore, it is only economically viable together with other land applications, such as agricultural usage.Economical evaluation indicates that for the optimum design the levelized cost of energy (LCOE) is 0.67 SEK/MWh and 0.72 SEK/MWh for monofacial and bifacial system, respectively. Such financial figures are subject to change, depending on the design and financial parameters.

Utility-scale

PV power plant

Design

Optimization

financial analysis

Bifacial PV system

Levelized cost of energy

Energy Engineering

Energiteknik

Data Mining for Accurately Estimating Residential Natural Gas Energy Consumption and Savings Using a Random Forest Approach

Naji, Adel Ali

30 May 2019

No description available.

Mechanical Engineering

Economics

Energy

Random Forest

Building Energy Efficiency

Data Mining

Levelized Cost of Fuel Saving

Worst-to-First Strategy

A techno-economic analysis of a residential solar Photovoltaic system installed in 2010 : A comparative case study between California and Germany

Ravi Kumar, Swetha

January 2012

With environmental concerns and energy needs increasing, many regions in the world are promoting renewable energy technologies making use of various policy instruments. Although today the PV systems price is decreasing, which gives it a competitive edge; we see the technology still being dependent on policy instruments for its dissemination.   The aim of this study is to research on whether or not a solar PV system is economically viable under certain circumstances. The study analyzes this by performing a cost beneficial analysis for the lifetime of the solar PV system making use of a discounted savings model. The systems being considered in this study are from California and Germany as these regions are leading in solar PV dissemination in their respective regions. The policies that are aiding the deployment of solar PV technologies are varied and thus this study compares benefits from different policy instrument for a residential customer investing in a solar PV system.   The research objectives in this study are pursued making use of major concepts such as Grid Parity, Levelized Cost of Electricity and financial methods such as discounting.  Further, to understand how the different independent variables such as retail electricity prices, PV system pricing, WACC, self-consumption rate and storage availability are having an impact and how the results change with variation in these variables, a sensitivity analysis is conducted.   The results obtained in this study show that a solar PV system installed in California and Germany both make net benefits over their lifetime. When compared, the Californian solar PV system under the Net Energy Metering policy is making more net economic benefits in the range of $ 40,351 in Eureka and $53,510 in San Francisco; when compared to the German solar PV systems under the Feed in Tariff ranging $4,465 in Berlin and $11,769 in Munich. Furthermore the Californian solar PV systems still prove to be more beneficial even when compared to the German solar PV systems under the self-consumption law of the Feed in Tariff ranging $ 6,443 in Berlin and $ 13,141 in Munich.  But when the self-consumption rate is increased in the German case, it is noted that the associated benefits increase.   The study at hand thus results in the California Net Energy Meter policy instrument proving to be more beneficial to a residential customer than the German Feed in tariff with and without self-consumption. Another important finding made in this study is that despite the German solar PV system making lesser benefits than the Californian ones, they attain Grid Parity before the ones in California.

Solar PV

Grid Parity

Levelized Cost of Electricity

Discounted Savings

Energy Engineering

Energiteknik

Electricity generation from hybrid PV-wind-bio-mass system for rural application in Brazil

SONG, CONGCONG

January 2017

Electrification of households in rural area and isolated regions plays a significant impact on the balanced economic development. Brazil grows with a high population growth rate, but still parts of rural area and isolated regions do not have the accessibility of electric power. This study focuses on the feasibility study of a hybrid PV-wind-biomass power system for rural electrification at Nazaré Paulista in southeast Brazil. This study was performed by using the hybrid renewable energy system software HOMER. The wind and solar data was collected from Surface meteorology and Solar Energy-NASA, and the biomass data was collected and estimated from other previous studies. The result shows, the hybrid PV-wind-biomass renewable system can meet 1,601 kWh daily demands and 360 kW peak load of the selected rural area. The power system composed of 200 kW PV panels, 200 kW biomass generator, 400 battery banks, and 200 kW converter. All the calculations were performed by Homer and the selection were based on the Net Present Cost (NPC) and Levelized cost of energy (COE). Because of the fossil fuels’ negative impacts on human health and environment, all the energy sources for this system are renewable energies which have less pollution.

Hybrid system

Renewable energy systems

PV

Wind

Biomass

Levelized cost of energy

Net present cost

Mechanical Engineering

Maskinteknik

Techno economic study of high PV penetration in Gambia in 2040

Jarjusey, Alieu

January 2023

Meeting electricity demand and power shortage remains as a challenge to the people of the Gambia. As the country is undergoing tremendous electricity accessibility expansion [1], to secure the environment for the future generation, it is necessary to consider renewable energy to be the major source of electricity production, to be specific, solar energy. This is because the country experiences the radiation from the sun throughout the year, it is sustainable not only to our environment for the future generations, but also economically. However, due to the intermittent nature of most renewable energy technologies, it is cumbersome to rely on them 100 % as a primary source of electricity production. Nonetheless, with suitable storage technologies, combination of different renewable sources, and intercountry grid connections can enhance to overcome this challenge. In this thesis work, designed and techno economic evaluation was carried out for high PV penetration that will meet 50 % electricity demand of the Gambia in year 2040. Three scenarios were considered in this study, based on the Strategic Electricity Roadmap 2020 to 2040 [1]. These scenarios are high, universal access (AU), and low electricity demand. Economically, 50 % electricity supply to meet the demand is possible for all the three cases. Consideration was mainly put on four key figures, thus, levelized cost of electricity (LCOE), payback period (PBP), net present cost (NPC) and solar fraction (SF). To achieve 50 % SF for the high electricity demand scenario, LCOE and PBP are 0.129 $/kWh and 12 years respectively. As for AU electricity demand case, 50 % SF is achieved with 0.126 $/kWh and 10 years for LCOE and PBP respectively. For low electricity demand scenario, 0.127 $/kWh and 10 years for LCOE and PBP respectively for 50 % SF. However, the optimum design recommended by HomerPro were 45 % SF with LCOE of 0.126 $/kWh and PBP of 9 years for high electricity demand scenario. As for the AU electricity demand case, the optimum design is 48 % SF, LCOE of 0.125 $/kWh, and PBP of 9 years. In the last scenario, which is low electricity demand case, 46 % SF, 0.124 $/kWh LCOE, and 9 years PBP.

Large scale grid connected PV

Photovoltaics

levelized cost of electricity (LCOE)

Gambia high solar PV penetration

PVsyst

HomerPro

Energy Engineering

Energiteknik

Scenarios for the decarbonization of district heating: the case of Leipzig

Specht, Karl, Kondziella, Hendrik, Bruckner, Thomas, Scheller, Fabian

13 October 2023

This study derives the levelized cost of heat (LCOH) for exemplary post-fossil district heating (DH) scenarios. The DH system of Leipzig in 2040 under the assumption of a completely climate-neutral heat supply is considered. Accordingly, four generation scenarios (GS) are proposed based on different energy carriers that are characterized as follows: (1) natural gas with carbon capture and storage, (2) hydrogen, (3) diversified mix of biomass, waste heat and solar, and (4) electricity. In addition, the scenarios’ robustness toward commodity prices is investigated using a sensitivity analysis. A modeling environment was used to optimize the hourly economic dispatch. Based on this, levelized costs are determined. For the reference case, the LCOH of the GS 1 and 2 exceeds the LCOH of GS 3 and 4. Furthermore, the results indicate that relying on singular energy carriers as opposed to diversified generation portfolios leads to less robust LCOH regarding price sensitivities.

info:eu-repo/classification/ddc/330

ddc:330

Feasibility analysis of upgrading the cogeneration unit of George Washington sugar mill in Cuba / Genomförbarhetsanalys av uppgradering av kraftvärmeenheten i sockerbruket George Washington i Kuba

Ginste, Joakim, Partanen, Sascha

January 2020

Cuba’s government has set a goal to generate 24 percent of the country’s electricity from renewable sources by 2030. The country’s many sugar mills have been identified as key contributors to reach this goal as their cogeneration units have the potential to significantly increase Cuba’s electricity production from biomass by upgrading them to bioelectric plants. This study evaluates the feasibility of upgrading the cogeneration unit of George Washington sugar mill in the province of Villa Clara, Cuba. An energy balance of the proposed upgraded scheme is done to deduce its feasibility from an energy perspective. To deduce the project’s feasibility from a financial standpoint its net present value (NPV), internal rate of return (IRR), discounted payback period (DPP) and levelized cost of energy (LCOE) are calculated. The spared CO2 emissions by integrating more biopower in the Cuban electricity system are calculated from the avoided burning of diesel for electricity production. The impact on Cuba’s energy independence is quantified by calculating the avoided diesel imports. The NPV of the proposed scheme is 64.9 MUSD, the IRR is 25.6 percent which is significantly higher than the set discount rate of 6.5 percent, the DPP is 5.3 years and the LCOE is 0.0533 USD/kWh which is lower than the maximum LCOE set by AZCUBA to 0.14 USD/kWh. The avoided CO2 emissions and imported diesel are estimated to be 110,173 tonnes CO2 and 36,724 tonnes diesel each year, respectively. These indicators suggest that the upgrade of George Washington’s cogeneration unit is feasible.​ / Kubas regering har satt som mål att generera 24 procent av landets elektricitet från förnyelsebara källor till år 2030. Landets många sockerbruk har identifierats som nyckelaktörer för att nå detta mål då sockerbrukens kraftvärmeenhet har potential att öka Kubas elproduktion från biomassa genom att uppgradera dem till bioelektriska kraftverk. Denna studie utvärderar möjligheten att uppgradera kraftvärmeenheten på sockerbruket George Washington i provinsen Villa Clara, Kuba. Först görs en energibalans på det föreslagna uppgraderade systemet för att utläsa dess genomförbarhet ur ett energiperspektiv. För att utvärdera projektets genomförbarhet ur ett finansiellt perspektiv beräknas investeringens nettonuvärde (NPV), interna avkastningsgrad (IRR), diskonterade återbetalningstid (DPP) och energiproduktionskostnad (LCOE). De undvikta CO2 utsläppen genom integrering av mer biokraft i det kubanska elsystemet beräknas från den uteblivna förbränningen av diesel för elproduktion i landet. Effekterna på Kubas energioberoende kvantifieras genom att man beräknar den minskade dieselimporten. NPV i det föreslagna uppgraderade systemet är 64,9 MUSD, IRR är 25,6 procent vilket är betydligt högre än den fastställda diskonteringsräntan på 6,5 procent, DPP är 5,3 år och LCOE är 0,0533 USD/kWh vilket är lägre än det maximala LCOE som fastställts av AZCUBA till 0,14 USD/kWh. De uteblivna CO2-utsläppen och minskningen av importerad diesel beräknas uppgå till 110 173 ton CO2 respektive 36 724 ton diesel varje år. Dessa indikatorer tyder på att uppgraderingen av George Washingtons kraftvärmeenhet är genomförbar.​

CEST

cogeneration

levelized cost of energy

net present value

sugar mill

CEST

kraftvärmeverk

energiproduktionskostnad

nettonuvärde

sockerbruk

Energy Systems

Energisystem