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Climate impact of energy retrofitting measures : An analysis of energy and carbon payback times for replacing windowsRosenkvist, Mari January 2022 (has links)
The European Commission has proposed a “renovation wave” to increase energy efficiency in buildings. Retrofitting can decrease operational energy usage but requires material production. Using the concepts of energy payback time and carbon payback time, this thesis aims to analyse under what circumstances operational energy savings from window replacement compensate for the climate impact of producing new windows. The literature review shows that carbon payback times for energy retrofitting measures are often reported to be merely a few years. In some cases, however, carbon payback time exceeds the service life of the added material. In general, diverging results can be attributed to both case specific circumstances and methodological choices. In this thesis, values for the main parameters determining carbon and energy payback time for window replacement are retrieved from environmental product declarations and scientific literature. The analysis shows that, only accounting for operational energy, energy payback times are within the expected service life of the researched windows for all energy saving scenarios and well within the service life for the midrange scenarios. Taking account of primary energy stretches the span of results. The analysis also shows that carbon payback time for window replacement varies by a factor of 38 for the midrange studied scenarios and a factor of almost 4 600 for the most extreme among the studied scenarios. Divergence stems from all investigated parameters: the embodied climate impact of window production, the amount of saved operational energy and the emission factor attributed to saved energy. In countries with mainly renewable operational energy, case studies may arrive at long carbon payback times for window replacement. The result can be altered if saved energy is considered to come from marginal production techniques, a methodological choice made in some case studies. This thesis concludes that if energy and carbon payback time calculations are to be used for comparing retrofit alternatives, the research community needs to address methodological issues. Another conclusion is that the analysis of climate performance needs to include the interconnectedness of different societal sectors. It also needs to include more impact categories than energy and greenhouse gases, for example resource depletion.
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Cost-benefit analysis of a Building Integrated Photovolatic roofing system for a school located in Blacksburg, VirginiaCholakkal, Leena 06 July 2006 (has links)
In the past few years, there has been a growing concern for the impact of non-renewable resource depletion and environmental degradation as a result of energy consumption in buildings. Buildings account for approximately one-half of the total energy consumption in developed countries. As architects and engineers involved with the fast growing building industry, we have the responsibility of exploring and integrating various renewable energy sources into our buildings to help us move towards what we might call "Positive Energy Architecture", where the role of the building shifts from net energy consumer to net energy producer.
The object of this study is to analyze how different parameters namely solar radiation, temperature, solar altitude and solar azimuth affect the power produced by a new thin film photovoltaic panel. Through the application of multiple linear regression, the model developed is then used to evaluate the cost-effectiveness of the building integrated photovoltaic roofing system when connected to the utility grid when compared to a conventional roofing system. The analysis is applied to a school building located in Blacksburg, Virginia. Using the current utility rates and the energy consumption data, the payback period of the system is evaluated for full roof, half roof and quarter roof coverage. / Master of Science
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Sustainable Manufacturing of CIGS Solar Cells for Implementation on Electric VehiclesSamett, Amelia January 2020 (has links)
No description available.
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Simulation and Economic Analysis of a Hybrid Wind Diesel System for Remote Area Power SupplyAbdullah, Jalal 06 September 2010 (has links)
The Kingdom of Saudi Arabia has an area of 1.69 million square kilometers. It is the biggest oil producers in the world, and the electricity industry relies heavily on oil. The annually growth request for electricity is around 5%. The price of electricity will be expensive in the next 30 years and there could be a shortage of electricity supply. It is better to use alternative forms of energy to prolong the life of the oil industry in Saudi Arabia. To reduce dependence on oil, the Kingdom of Saudi Arabia is considering using alternative sources of energy including solar energy and energy wind. Since the wind speed is around 10m/s and in the summer it is full of sunshine; therefore, the renewable energy should play a more important role in future electric power supply of the Kingdom of Saudi Arabia. A hybrid system is proposed in this thesis to study the possible power supply system in the remote areas. Wind information in Dhahran is used in simulations in order to make sure that the system is reliable and appropriate to be used in the remote areas of the country. Economic analysis is also conducted to compare the cost of the hybrid system with that of a 200 km transmission line connected from existing service area.
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Ranking of Energy Saving Devices for Smart Homes according to their Payback TimeFelderer, Astrid, Brandtweiner, Roman, Hoeltl, Andrea January 2018 (has links) (PDF)
This paper discusses the average energy savings of various smart devices in connection with their average price. By calculating the devices' payback times, a ranking of the tools can be given. The whole study focuses on the average household within the EU-28 in terms of climate as well as in terms of user behaviour. The purpose of the research was to provide a win-win situation for users' wallets and the environment by showing the device which suits both players best. As a result of the research, it was found that the greatest reduction in energy consumption can be reached by an interaction of the smart device and the inhabitants of a smart home. By giving users feedback on their energy consumption through smart meters, average savings of 7.5% are reached. As a smart meter is available for about Euro 80, it has a payback time of only 4.24 months.
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Faktorer som bör vägas in vid investering av solceller : Miljöanalys av de vanligaste solcellerna på marknadenOlsson, Lovisa January 2019 (has links)
Four solar cells dominate the Swedish market today and are divided into two groups; first generation and second generation. The first generation involves of two silicone solar cells called mono-and multicrystalline solar cells. These solar cells were, as the name indicates, first on the market and today receive the highest efficiency. Due to high manufacturing costs, the second generation was developed which became thin film solar cells. The two most common solar cells in that generation are CdTe and CIGS, which account for about 20 percent of the solar cell market today while the first-generation accounts for the remaining 80 percent. Going towards a sustainable future it’s important and clear that both companies, cities and countries are ready meet the challenges. The solar cell technology has gained high confidence to bring in sustainable electricity production. Investors in Sweden experience the lack of a valuation concept from an environmental perspective between the solar cells on the Swedish market. The study has examined how the four different solar cells affect different environmental categories and which materials in the solar cells that are the most critical. By simulating the electricity production for a year with Gothenburg's solar radiation, the amount of electricity that could be used or sent to the grid was obtained. Where the silicon solar cells that have the highest efficiency also received the most electricity per square meter of solar cell. After producing electricity production and electricity consumption, the energy repayment period was calculated. Through LCA, 11 different environmental categories were developed to analyze different areas that are affected by solar cell production. Aquatic ecotoxicity of the marine environment was the environmental category that was most affected by the production for all four solar cell types. From the environmental category Global Warming, the amount of carbon dioxide equivalents was studied and then a payback time was calculated. Solar cells generally have three different phases; manufacture, operating and waste. The use phase is considered to be almost emission-free, the waste phase is relatively new for solar cell technologies. This is because no large waste streams have come than when the first major investments took place only in the nineties. The solar cells need different techniques depending on the type. The strategies should be different as different parts should be recycled and reused as far as possible. Due to the fact that there is unstable waste management, this phase has not been studied but only the manufacturing phase. A square metered solar cell was analyzed. For photovoltaic production in Europe, multicrystalline solar cell panels pay back the carbon dioxide equivalents after 11.5 years, while monocrystalline solar cell panels pay again after 14.3 years, ie after about half the life. CdTe paid the carbon dioxide equivalents fastest, after 2.2 years, and CIGS after 3.6 years. This means that the thin-film solar cells have the fastest time to get minus emissions. It is not justified to invest in solar cells manufactured in China when operating in Gothenburg, only after studying solar cell production. When the repayment period for carbon dioxide equivalents has been calculated, a Nordic electricity mix has been calculated with, depending on which electricity mix is chosen, it either gives reasons to not invest or to invest in solar cells. It is therefore important to be clear about what use the solar cells will have and which electricity is actually replaced before investors decide whether solar cells are the right energy source to invest in.
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Analytical Modeling and Optimization of a Thermoelectric Heat Conversion System Operating Betweeen Fluid StreamsTaylor, Stephen H. 13 July 2011 (has links) (PDF)
Analytical, closed-form solutions governing thermoelectric behavior are derived. An analytical model utilizing a thermal circuit is presented involving heat transfer into, through, out of, and around a thermoelectric device. A nondimensionalization of the model is presented. Linear heat transfer theory is applied to the model to obtain a series of closed form equations predicting net power output for the thermoelectric device. Fluid streams flowing through shrouded heat sinks with square pin fins are considered for the thermal pathways to and from the device. Heat transfer and pressure drop are characterized in a manner conducive to an analytical model using previously published experimental results. Experimental data is presented which validates and demonstrates the usefulness of the model in predicting power output for commercially available thermoelectric generators. A specific design for a thermoelectric power harvester is suggested consisting of a pattern of thermoelectric generators. An economic model for calculating payback time is developed. An optimization process is demonstrated that allows for the payback time of such a system to be minimized through optimization of the physical design of the system. It is shown that optimization of the thermal pathways dramatically reduces payback time. Optimized design of a system is discussed in light of theoretical cases with feasible payback times.
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Environmental Impact Assessment of aPhotovoltaic Power Station in Stockholm / Miljöutvärdering av en fotovoltaisk solcellsanläggning i StockholmRaouz, Khalid January 2017 (has links)
The paper at hand presents the environmental impact analysis of a photovoltaic (PV) power station sited in Stockholm, Sweden, using life cycle assessment (LCA). The LCA considers the primary energy return on investment and global warming potential of the PV-station, including; resource extraction, manufacturing, transportation, operation and maintenance, and decommissioning. Other environmental impact indicators are also presented, such as; the eutrophication, acidification, human toxicity, and ozone depletion potentials. The results show that the most critical phase of the lifecycle is the upgrade from metallurgical to solar grade silicon due to the high consumption of energy. The emissions results are compared to the emissions factors used for calculations in Sweden in accordance with the Swedish Energy agency and the European Commission’s directive for emissions calculations. The results for the other environmental indicators showed inconsistencies compared to existing studies, something that is according to the IEA’s guideline for PV-systems LCA caused by data scarcity and the indicators lacking consensus within the PV LCA-community. The studied PV-station is expected to reach energy neutrality after 2,4 years and offset annual GHG emissions of up to18 ton of CO 2 equivalents. / Studien tillhands presenterar miljöutvärderingen av en fotovoltaisk solcellsanläggning i Stockholm. Detta utfördes med hjälp av livscykelanalysverktyget. Analysen använder energiåterbetalningstiden och den globala uppvärmningspotentialen som indikatorer på anläggningens miljöinverkan. Både återbetalningstiden och den globala uppvärmningspotentialen beräknas för gruvarbetet, transporten, drift och underhåll samt avveckling och bortskaffning av anläggningen. Överföringsförluster beräknas också över anläggningens livscykel. Andra indikatorer som beräknas i denna studie är potentialen för försurning, övergödning, ozonnedbrytning och humantoxicitet. Dessa beräknas endast för modulens tillverkningskedja. Studiens resultat visar att den mest kritiska processen under solcellsanläggningens livscykel är kiselmetallens omvandling till solkisel, detta med avseende på energiförbrukningen och utsläpp av växthusgaser. Anläggningens globala uppvärmningspotential uttrycks i växthusgasutsläpp och jämförs med den nordiska elmixens utsläppsfaktor. Jämförelsen görs enligt dem gällande EU-direktiven. Resultaten för dem andraindikatorerna har visat på väsentliga avvikelser jämfört med tidigare studier. Detta beror enligt det internationella energirådet på databrist och på att dessa indikatorer saknar stöd inomLCA samfundet. Solcellsanläggningen beräknas bli energineutral efter 2,4 år samt eutralisera utsläpp på upp till 18 ton koldioxidekvivalenta per år.
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Skogliga biobränslens roll i Stockholm Exergis framtida strategi / The role of woody biomass in the future strategy of Stockholm ExergiDanielsson, Ellinor, Ekman, Jenny January 2021 (has links)
Studien syftade till att ge en rekommendation angående hur fjärrvärmebolaget Stockholm Exergi bör utforma sin framtida strategi beträffande fasta oförädlade skogliga biobräanslen. Genom litteraturstudier och intervjuer utreddes dessa bränslens konkurrenskraft utifrån perspektiven klimatneutralitet, politiska direktiv och styrmedel, leveranssäkerhet samt lönsamhet. Resultatet visade bland annat att användningen av grenar och toppar kan medföra klimatnytta. Vidare framkom att implementeringen av EU:s nya förnybartdirektiv inte kommer att ha storskalig påverkan på Stockholm Exergis framtida användning av dessa bränslen. Gällande leveranssäkerhet och lönsamhet påvisades exempelvis en större framtida efterfrågan på skogliga restprodukter från andra sektorer. Ändock kunde slutsatsen dras att skogliga biobräanslen, under vissa förutsäattningar, har en viktig roll i Stockholm Exergis framtida fjärrvärmeproduktion. / The study aimed to give a recommendation regarding how the district heating company Stockholm Exergi should design their future strategy concerning unprocessed solid woody biofuels. Through literature studies and interviews, the competitiveness of the fuels has been assessed based on climate neutrality, political directives and instruments, security of supply as well as profitability. Among other things, the results showed that the use of tree branches and tops can imply positive climate effects. Furthermore, the implementation of EU's new renewable energy directive will only have a marginal impact on Stockholm Exergi's future use of woody biofuels. Regarding the security of supply and profitability,an increased future demand of forest residues in other sectors have been identified. However, the study concludes that, under certain circumstances, woody biofuels have an important role in Stockholm Exergi's future district heating production.
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Architectural variations in residences and their effects on energy generation by photovoltaicsCaballero, Sandra Catalina 25 July 2011 (has links)
In the current global market, there are plenty solutions for the savings of energy in
the different areas of consumption in buildings: Green roofs and walls, cool roofs,
daylighting, motion sensors, and others but there are very few sources of renewable
energy at the reach of a common person in residential (smaller) scale. Photovoltaic
systems are the most well-know and reliable process of harvesting energy at this small
scale.
The relationship between energy demand and energy production when installing a
photovoltaics system in a residence is one of the main drivers while making a decision at
the time of purchasing a system. However, architectural decisions in early stages may
influence, enhance or even decrease the possible energy generation and interior
performance, thus influencing the possible return of investment. This study evaluates the
possible architectural variations that may be beneficial or disadvantegous at a particular city
and other circumstances.
From, roof, angle, location, roof articulation, layout articulation , shading devices
and others, this paper shows a spectrum of convenient and inconvenient projects due to
current conditions like climate, solar radiation, typical construction, electricity rates and
government incentives. As a conclusion a hierarchy of architectural elements when being
used with photovoltaics is developed to demonstrate that a common user can strategically
play with architectural features of his/her house to take the most out of the system.
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