Amasonen : A Design Proposal for a Mixed-Use Building with Integrated Solar Cells / Amasonen : Ett gestaltningsförslag för en multifunktionell byggnad med integrerade solceller

Gros, Ellinor

January 2018

With the growing energy consumption in the world today, the decreasing amount of fossil fuels and their negative impact on the environment, developments and greater use of renewable energy resources is crucial. One of the promising environmentally friendly energy resources is solar power. The technology for producing electricity from the use of solar cells is continuously developing and is growing on the market. The objective of this master thesis is to illustrate how solar panels can be integrated into a building’s design, and what value this gives to the building. The purpose is also to give an indication of whether an integrated solar panel installation is profitable, and what is required for more building developers to invest in solar power. A study on solar cells was conducted to gain knowledge of the different types of solar cells and systems and their possible integration into buildings. The study also included research on why solar cell installations are not more common today. Case Studies were also conducted on projects with integrated solar cells. This was done to gain an understanding of how solar panels can be used as design elements. The study was done as a systematic literature study through a qualitative method. City and site analyses were carried out as a first step in the design process. The analyses focused on the movements, green spaces, climates, functions and architectural character of the city and site. The analyses were done to attain an impression of the environment the building would be placed in, and its requisites. These analyses were followed by volume and solar studies to come up with a building design that would fulfill the requirements of the client, while creating good areas for placement of the solar panels. The master thesis resulted in a design proposal for a mixed-use building with integrated solar cells. The resulting two buildings are located in the outskirts of the city center of Linköping. The buildings are designed to interact with the surrounding buildings and the remaining city, while at the same time bringing something new and exciting to the mix. The buildings’ placement and height were decided by the combination of the movement of the sun over the plot, so as to create good areas for the solar panels, and the requisites of the site. The integrated solar panels are placed on the roofs and facades of the buildings. The possibilities of semitransparent solar cells in windows and glass railings is also examined. The solar panels on the roof consist of solar roof tiles and are placed on the east side of the north building’s roof and the west side of the south building’s roof. These tiles have matching roof tiles without solar cells inside, on the other side of the roofs, meaning that no difference can be seen between the two sides. The façade panels are placed to cover the entire protruding stairwells of the buildings. Panels are also placed on remaining parts of the south-east and south-west facing facades but are here placed in a pattern as though they are trickling down the walls. The panels are placed to avoid shade as shading of the panels reduces their effect. The solar cells are smooth, black, thin-film solar cells and the panels have matching glass panes that are placed were the design opted for panels, but the placement was not good out of a solar irradiation perspective. The results of the rough calculations on the project’s solar panel installation’s profitability shows that the investment would have a payback time of approximately 15 years. This, when counting in a government support of 1.2 million kroners and the reduced cost for the building cover material that the solar panels replace. The solar panels in the design proposal are not in standard sizes. Would they have been so the investment cost would have been lower and the payback time, according to the rough calculations, would be around 10 years. The produced electricity constitutes around 60 percent of the operational electricity for the buildings. If semitransparent solar cells are included the value goes up to 80 percent. Although the produced electricity does not cover the complete electricity needs of the buildings, it still reduces the amount of bought electricity. Electricity that would most likely not come from a renewable source. The conclusion is, therefore, that an integrated solar cell installation is economically profitable. The solar panels contribute both the aesthetics of the building and building functions, as well as electricity from a renewable source. Investing in a solar cell installation also sets a good example and will lead to more investors taking a chance on solar power. Getting more building developers to invest in solar cells systems can be done by increasing the, today lacking, knowledge of solar energy and solar cells, the process for designing and installing a solar cell system, as well as the laws regarding solar power and solar power investments. Another obstacle for solar power is the high costs of the installations. The prices on solar cells are, however, continuously dropping, because of the development in technology and the manufacturing process, as well as the growing number of manufacturers. To increase the speed of this process more building developers should invest in solar cells, as a higher demand will lead to more manufacturers, which will then lead to reduced prices. The government can also help by offering research support and for example tax subventions to make an investment in solar power seem more worthwhile.

PV-cells

PV-System

Integrated Solar Cells

Renewable Energy Resources

Integrerade Solceller

Solcellssystem

Förnybar Energi

Architecture

Arkitektur

Hosting Capacity of a Low-Voltage Grid : Development of a Simplified Model to be used in future Solar Roadmaps

Andersson, Jonas, Bernström, Vendela, Törnqvist, Joacim

January 2017

The purpose of this bachelor thesis is to assess whether it is possible to create a simplified model that estimates the hosting capacity of a low-voltage grid. The Simplified model is compared with a more elaborate model created by the Built Environment Energy Systems Group (BEESG) at Uppsala University. The Simplified model takes three easily obtainable variables into account. The model created by BEESG allows us to observe both the amount of photovoltaic (PV) power that is installed as well as the voltages in each bus in a grid. The hosting capacity is found by gradually increasing the amount of PV power installed in a low-voltage grid until overvoltage is reached. Simulations with BEESG’s model are done for a week in July when the PV generation has its peak and the load is generally low. The Simplified model is created using linear regression with the calculated values from the BEESG’s model as a reference. The report shows that the Simplified model will give an estimation of the low-voltage grid’s hosting capacity that is comparable to the value calculated with BEESG’s model. The results show that it is rarely the low-voltage grid that restricts the installation of PV facilities and that a high self-consumption is advantageous regarding to the grids hosting capacity.

solar roadmap

hosting capacity

PV power

PV system

overvoltage

low-voltage grid

self-consumption

Energy Systems

Energisystem

Investigation of the Performance of a Large PV system

Solanes Bosch, Júlia

January 2017

One of the main social challenges that society is facing nowadays is the energy crisis. So, head towards renewable energy resources such as solar, hydraulic, wind, geothermal and biomass, could be the best solution. Solar photovoltaic is one of the most promising sources to produce electricity due to its cleanness, noiselessness and sustainability, and the fact that it is inexhaustible. However, the power output of the PV systems varies notably because of the ambient conditions: temperature and solar radiation. The main aim of this thesis is to study if the PV system installed on the wall of the new football arena Gavlehov in Gävle is providing the amount of power promised before the installation. To achieve reliable results, the first step is to develop and install a monitoring system for recording the real power of the system and the ambient conditions at the same time. After that, an evaluation of the performance of the system during one week will be done, comparing the theoretical power and the real power obtained. The theoretical power will be calculated in two ways: using the data from a pyranometer and on the other hand, from a reference solar cell. This will permit to compare which one matches better with the reality. Different factors such as the temperature, the irradiance and the angle of incidence are studied to know the real influence that they have on the performance of a PV installation. The results obtained show that the measurement system installed is reliable and that the model used to evaluate the system is correct. It can be concluded that using a reference solar cell to calculate the theoretical power of the system is easier to align and it has the same angular behaviour as a PV module than employing a pyranometer. Regarding the installation, all the panels work similarly and the system works at nominal power. So, it provides the amount of power promised before the installation. Key words: Renewable energy, PV system, solar radiation, nominal power, pyranometer, solar cell.

Renewable energy

PV system

solar energy

pyranometer

solar cell

Elektroteknik och elektronik

Energy Systems

Energisystem

Návrh systémové elektroinstalace rodinného domu s FV systémem a jeho ekonomické zhodnocení / Draft of intelligent wiring for a house with a PV system and its economic evaluation

Brtnický, Pavel

January 2017

This master´s thesis applies to design of power and data wiring controlle by an intelligent wiring. The aim is to get to know the issue and design a project for family house that includes fhotovoltaic power station. In the introduction is a description of the inteligent wirings, its potential, topology, advantages or disadvantages towards standard electroinstallations,it also presents an overview of widely used intelligent wiring, especially Foxtrot. What follows is the subject itself for what is the project designated for. The next topic will be a presentation of complete electroinstallation and photovoltaic power station. It all ends with an economic evaluation of the whole project.

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

Solcellsanläggningars kostnadseffektivitet för elkrävande verksamhet : Lönsamhet, miljöavtryck och självförsörjningsgrad för solcellssystem med olika orientering

Jensen, Henrik

January 2016

The primary aim of this thesis was to use the calculation instrument for the solar energy potential map of Landskrona to simulate several PV systems to a sanitation company. The calculation tool is designed to calculate the profitability and environmental benefits of installing solar panels. The calculation tool was adapted in order to compare cost efficiency, environmental benefit and degree of self-sufficiency and self- consumption for the solutions. The PV system was planned to a company, Landskrona Svalöv Renhållning (LSR). Furthermore, four different ways to construct the PV system were investigated; flat against the roof, tilted with respect to the roof, tilted with respect to the roof and oriented (azimuth angle), as well as an installation with a string of tilted PV modules together with PV modules mounted flat against the roof. Variation of the system configurations was achieved by changing the parameters tilt and azimuth angle. The capacity was adjusted so that the annual production would be 83 500 kWh for all the studied systems. The different systems were optimized in two ways; first for the most output per module, and secondly for the greatest self-sufficiency in order to minimize the losses of excess production. PV modules optimally oriented for production per module provides the highest profitability and lowest payback period. The study suggests that photovoltaic systems are a competitive installation for LSR even without subsidies. The degree of self-consumption was 11 %. Simulation results showed that the degree of self-sufficiency could only be increased marginally by simply changing the orientation of solar cells (with power adapted to maintained production level). There was no significant benefit from tilting the solar cells by 90 ° to increase self-sufficiency in the winter. The simulations showed that almost all of the produced electricity was used to LSR 's internal load. This high degree of self-consumption showed very little excess electricity was produced. LSR is connected to the medium voltage power grid via two transformers. The surplus production covered only part of the no-load losses in transformers. Surplus electricity could therefore not be sold, but the high self-consumption rate limited this loss of revenue. The solar electricity from crystalline silicon cells, results in slightly higher greenhouse gas emissions than wind power but much lower than the production mix of electricity available in the market. The self-produced solar electricity contributed to the environment because LSR did not have to buy the contracted wind electricity, which then became available for others. The study's conclusions are that a PV system is likely to be profitable for LSR. Self-sufficiency would be about 11%, and the self-consumption rate of 98%. The environmental benefit consisted of the contribution of renewable energy in the mix of electricity generation on the market. / Huvudsyftet med denna rapport var att simulera olika solcellsanläggningar med ett beräkningsverktyg till en renhållningsverksamhet. Beräkningsverktyget är framtaget till solpotentialkartan över Landskrona för att beräkna lönsamheten och miljönyttan av att installera solceller. Beräkningsverktyget anpassades för att jämföra kostnadseffektiviteten, självförsörjningsgraden, självkonsumtionsgraden och miljönyttan med olika systemlösningar på solcellsanläggningar. Landskrona Svalövs Renhållning (LSR) var den renhållningsverksamhet de simulerade solcellsanläggningarna anpassades till. Först antogs fyra olika sätt att anlägga solcellerna på; platt, uppvinklat från tak, uppvinklat från tak och riktat (azimutvinkeln) samt en systemlösning med en sträng solceller som var uppvinklade tillsammans med en grupp platt anlagda solceller. Sedan utfördes simuleringar genom att ändra parametrarna vinkel och azimutvinkel. Effekten anpassades så att årsproduktionen var 83 500 kWh för alla de studerade systemen. Dessa olika systemlösningar optimerades på två sätt. För det första, till största produktion per modul, för det andra till största självförsörjningsgrad. Den högsta lönsamheten och lägsta återbetalningstiden gav den solcellsanläggning vars moduler var optimalt orienterad för produktion per modul. Studien pekar mot att en solcellsanläggning för LSR är en konkurrenskraftig installation utan statligt stöd. I de simulerade fallen täckte den egenanvända elen den totala elanvändningen till ca 11 %.  Simuleringsresultaten visade att denna självförsörjningsgrad endast gick att höja marginellt genom att ändra på orienteringen (med effekt anpassad så att produktionsnivån bibehölls). Det fanns ingen signifikant nytta av att anlägga solceller i 90° för att öka självförsörjningen under vintern. Simuleringarna visade att nästan all egen elproduktion användes till LSR:s interna last. Denna höga självkonsumtionsgrad visade att mycket lite överskott av el producerades. LSR är anslutna till högspänningsnätet via två transformatorer. Överskottsproduktionen täckte bara en del av tomgångsförlusterna i transformatorerna. Överskottselen kunde därmed inte säljas, men den höga självkonsumtionsgraden begränsade denna förlust av intäkter. Solkraft från solceller av kristallina solceller har något högre växthusgasutsläpp än vindkraftsel men mycket lägre än den produktionsmix av el som finns på marknaden. Egen solelproduktion bidrog till miljönyttan eftersom LSR inte behövde köpa den kontrakterade vindkraften då de använde egen solel och elen från vindkraft blev tillgänglig för andra. Studiens slutsatser är att en solcellsanläggning sannolikt skulle vara lönsam för LSR. Självförsörjningsgraden skulle bli ca 11 % och självkonsumtionsgraden över 98 %. Miljönyttan bestod i tillskott av förnybar el i den mix av elproduktion som fanns på marknaden.

PV-system

self-sufficiency

self-consumption

orientation

Life Cycle Assessment

simulation

solar calculation tool

solar cells

cost efficiency

solcellssystem

simulering

orientering optimering

självförsörjning

självkonsumtion

solberäkningsverktyg

solceller

Maximizing Solar Energy Production for Västra Stenhagenskolan : Designing an Optimal PV System

Kristofersson, Filip, Elfberg, Sara

January 2019

Skolfastigheter is a municipality owned real estate company that manages most of the buildings used for lower education in Uppsala. The company is working in line with the environmental goals of the municipality by installing photovoltaic systems in schools and other educational buildings. Skolfastigheter are planning to install a photovoltaic system in a school in Stenhagen. The purpose of this study is to optimally design the proposed system. The system will be maximized, which in this study entails that the modules will be placed on every part of the roof where the insolation is sufficient. The system will also be grid connected. The design process includes finding an optimal placement of the modules, matching them with a suitable inverter bank and evaluating the potential of a battery storage. Economic aspects such as taxes, subsidies and electricity prices are taken into account when the system is simulated and analyzed. A sensitivity analysis is carried out to evaluate how the capacity of a battery bank affects the self-consumption, self-sufficiency and cost of the system. It is concluded that the optimal system has a total peak power of almost 600 kW and a net present value of 826 TSEK, meaning that it would be a profitable investment. A battery bank is excluded from the optimal design, since increasing the capacity of the bank steadily decreased the net present value and only marginally increased the self-consumption and self-sufficiency of the system.

Energy systems

energy system

photovoltaic system

photovoltaic systems

Stenhagen

Västra Stenhagenskolan

Uppsala

solar energy

PV system

PV systems

PV

Energy Systems

Energisystem

Bifacial photovoltaic systems established in a Nordic climate : A study investigating a frameless bifacial panel compared to a monofacial panel

Boman, Kristin, Adolfsson, Ida, Ekbring, Sofia

January 2019

The aim with this project was to study the power output from a frameless bifacial photovoltaic (PV) system relative to a traditional monofacial PV system with a frame. A general overview of how the geographical conditions affects the energy utilization of different PV systems is investigated throughout the project. Also, the study examined if further comparisons and evaluations, between PV systems, can be better established. The two examined solar parks, installed under different conditions, are located in Uppsala and Enköping, Sweden. In order to fulfill the aim and compare the different PV systems, three cases were analyzed. To increase the credibility of a comparison between the two cities, a sensitivity analysis considering the weather condition was executed. In case one, the result indicates that a bifacial panel is 5.2% and 3.6% more advantageous than a traditional monofacial panel during summer and winter, respectively. In case two, the frameless, more tilted and elevated bifacial panel is 58% and 680% more advantageous than a traditional monofacial panel during summer and winter, respectively. Also, in case three, the frameless, more tilted and elevated bifacial panel is 19% and 76% more advantageous than a bifacial panel with frame during summer and winter, respectively. When installing a new solar park, it is important to consider the location’s specific features since these affects the energy yield of the PV system. Future installations, which are installed with the intention to evaluate certain properties, is suggested to be installed with more initially comparable conditions in mind.

Bifacial

Photovoltaic

PV

PV system

Monofacial

Frameless

Nordic

Nordic climate

Sweden

Uppsala

Enköping

Snow

Frame

solar parks

solar park

solar energy

Engineering and Technology

Teknik och teknologier

An Economic Analysis of Grid-tie Residential Photovoltaic System and ?Oil Barrel Price Forecasting: A Case Study of Saudi Arabia

Mutwali, Bandar

08 January 2013

The demand for electricity is increasing daily due to technological advancement, and ?luxurious lifestyles. Increasing utilization of electricity means the depletion of fossil fuel ?reserves. Thus, governments around the world are seeking alternative and sustainable ?sources of energy such as the solar powered system. The main purpose of this research is ?to develop a knowledge base on residential electric generation from the grid and solar ?energy. This paper examined the economic feasibility of using grid-tied residential ?photovoltaic (GRPV) system in Saudi Arabia with the HOMER software. Models ?forecasting the price of oil barrels through artificial neural networks (ANN) were also ?employed in the analysis. The study shows that an oil-rich country like Saudi Arabia has ?potential to utilize the GRPV system as an alternative source of energy. / This paper examined the economic feasibility of using grid-tied residential photovoltaic ??(GRPV) system in Saudi Arabia with the HOMER software. Models forecasting the ?price of oil barrels through artificial neural networks (ANN) were also employed in the ?analysis. The study shows that an oil-rich country like Saudi Arabia has potential to ?utilize the GRPV system as an alternative source of energy. This study provides a ?discussion of the potential for applying solar-powered and an assessment of the ?performance of existing systems based on collecting output data.?

solar system

Artificial Neural Network

Grid-tie Residential Photovoltaic System

Oil Barrel Price Forecasting

Saudi Arabia

Oil Barrel Price prediction

Design a PV – system for a large building

Martinovic, Zarko

January 2014

This study presents the complete design of a photovoltaic system in commercial buildings. PV installation for Multiarena was primary used for internal consumption, rest of production will be sent according intentions in grid. Project presents theoretical demand calculations for building consumptions. According to the theoretical calculations numerical study has been provided by software Indoor Climate and Energy program. Detailed electric optimization strategy can be founded in project description, as well as the sizing of the photovoltaic installation and economic and financial issues related to it. Study presents several models for photovoltaic system and their economic analysis. Environmental issues can be founded at the end of the study.

ventilation

air – conditioning