Environmental Life Cycle Costing (ELCC) für Produkte der Solarenergie

Krause, Marcus

17 April 2013

Vor dem Hintergrund der zukünftigen Notwendigkeit einer nachhaltigen Energieversorgung beschäftigt sich die vorliegende Arbeit mit Technologien der regenerativen Energiequelle Solarenergie, insbesondere Photovoltaik (PV). Systeme zur Nutzung der unerschöpflich verfügbaren, sauberen und im Prinzip “frei Haus” gelieferten Energie der Sonne können eine bedeutsame Rolle in einer umweltverträglicheren Zukunft spielen. Allerdings ist die Herstellung der erforderlichen Komponenten heute i.d.R. noch energie- und kostenintensiv, weshalb für eine korrekte Bewertung dieser Technologien der gesamte Lebenszyklus betrachtet werden muss. Zur tieferen Analyse der PV wird die Methodik des Environmental Life Cycle Costing (ELCC) auf der Grundlage von drei Grundideen eingeführt. Konkret sind dies die Ausgangspunkte: Nachhaltigkeit, Lebenszyklusdenken und die Drei-Dimensionalität dieses Instrumentes durch die gemeinsame Betrachtung ökologischer, ökonomischer und technischer Aspekte in ihrem Zusammenspiel. Ausgehend von theoretischen Elementen der Ökobilanzierung (Life Cycle Assessment) und des Life Cycle Costings, verbunden mit den technischen Eigenschaften der Photovoltaik werden wichtigste Anforderungen und Schritte für die Durchführung eines ELCC für PV beschrieben. Mittels einer softwaregestützten Inhaltsanalyse wird im Anschluss der definierte Rahmen für ein ELCC für PV getestet (und modifiziert) gegen eine Auswahl von 135 bereits existierender Studien, die sich mit dem Lebenszyklus von PV-Technologien aus ökologischer und ökonomischer Sicht beschäftigen. Im Ergebnis hieraus können die wichtigsten Elemente eines ELCC für PV, wie beispielsweise ökologische Wirkungskategorien oder ökonomische Indikatoren, identifiziert werden (methodisches Feedback). In einem nächsten Schritt werden die Studien hinsichtlich ihrer “Qualität” bezogen auf ökologische, ökonomische und übergreifende Inhalte eines ELCC für PV bewertet. Auf diese Weise kann ein Inventar von Lebenszyklusanalysen für PV erstellt werden, das nach den Technologien und der inhaltlichen Qualität bezüglich eines ELCC strukturiert ist und für weitere Analysen als Grundlage dienen kann. Aus den bisherigen Ergebissen kann eine erste Einschätzung zum aktuellen Stand des ELCC für PV in der Literatur vorgenommen werden: Es existiert bereits ein großer Pool von Studien, die sich mit dem Lebenszyklus der PV beschäftigen. Mit Blick auf die Anforderungen eines ELCC für PV besteht jedoch Nachholbedarf in der Verbindung und gemeinsamen Betrachtung von hot spots und trade offs aus ökologischer und ökonomischer Perspektive. Der definierte theoretische Rahmen für ein ELCC für PV, die kodierten Studien sowie das erstellte Inventar von Lebenszyklusanalysen der PV können nun als Grundlage für weitere Analysen dienen. Insbesondere eine inhaltliche Auswertung der konkreten Ergebnisse von Studien kann so einen Benchmark und Orientierung für neue Lebenszyklusanalysen für PV-Technologien liefern. / The special need of a sustainable energy supply in mind the technologies of the renewable source solar energy, especially photovoltaics (PV) is main subject of the present thesis. Using the inexhaustible, clean and “freely delievered” power from the sun solar devices may play a major role in a cleaner future, but, on the other hand, they are still energy consuming and expensive in their production which consequently demands a whole life cycle perspective when assessing this technology. For a closer look at PV the methodology of Environmental Life Cycle Costing (ELCC) is introduced by following three theoretical points of view. Namely these are sustainability, life cycle thinking and the three dimensional nature of this tool by regarding environmental, economic and technical aspects in their interaction. Based on theoretical elements of Life Cycle Assessment and Life Cycle Costing in combination with the technical background of photovoltaics main requirements and steps for performing an ELCC for PV are described. By executing software based content analysis the defined framework is checked (and modified) against a choice of 135 existing studies analyzing the life cycle of PV technologies from an environmental or economic perspective. As a result the main elements of an ELCC for PV, e.g. environmental impact categories and economic indicators, are identified (methodological feedback). Within the next step the existing studies are rated by their “quality” regarding the environmental, economic and more general parts of an ELCC for PV in order to create an inventory of life cycle studies for PV. This inventory is structured by technologies as well as quality of content respecting ELCC and might be used for further analyses. At this stage the results propose the possibility of a first estimate of the present status of ELCC for PV: until now there is a good pool of existing analyses of the life cycle of PV systems. But from an ELCC perspective the examination of common hot spots and trade offs between economic and environmental aspects should be expanded. The theoretical framework of ELCC for PV, the encoded studies and the inventory of life cycle analyses for PV are now the starting point for further analyses, especially of the individual outcome within studies, which will then pose a benchmark for new life cycle studies of PV technology.

Life Cycle Assessment

Life Cycle Costing

Environmental Life Cycle Costing

Photovoltaik

Solarzelle

Solarmodul

Solar Panel

Life Cycle Assessment

Life Cycle Costing

Environmental Life Cycle Costing

Photovoltaic

Solar Cell

Solar Module

Solar Panel

ddc:330

rvk:QT 800

Environmental Life Cycle Costing (ELCC) für Produkte der Solarenergie: Die Verbindung von Life Cycle Assessment (LCA) und Life Cycle Costing (LCC) - from Cradle to Grave - angewandt auf die Photovoltaik. Anforderungen bei der Durchführung und aktueller Stand in der Praxis

Krause, Marcus

January 2011

Vor dem Hintergrund der zukünftigen Notwendigkeit einer nachhaltigen Energieversorgung beschäftigt sich die vorliegende Arbeit mit Technologien der regenerativen Energiequelle Solarenergie, insbesondere Photovoltaik (PV). Systeme zur Nutzung der unerschöpflich verfügbaren, sauberen und im Prinzip “frei Haus” gelieferten Energie der Sonne können eine bedeutsame Rolle in einer umweltverträglicheren Zukunft spielen. Allerdings ist die Herstellung der erforderlichen Komponenten heute i.d.R. noch energie- und kostenintensiv, weshalb für eine korrekte Bewertung dieser Technologien der gesamte Lebenszyklus betrachtet werden muss. Zur tieferen Analyse der PV wird die Methodik des Environmental Life Cycle Costing (ELCC) auf der Grundlage von drei Grundideen eingeführt. Konkret sind dies die Ausgangspunkte: Nachhaltigkeit, Lebenszyklusdenken und die Drei-Dimensionalität dieses Instrumentes durch die gemeinsame Betrachtung ökologischer, ökonomischer und technischer Aspekte in ihrem Zusammenspiel. Ausgehend von theoretischen Elementen der Ökobilanzierung (Life Cycle Assessment) und des Life Cycle Costings, verbunden mit den technischen Eigenschaften der Photovoltaik werden wichtigste Anforderungen und Schritte für die Durchführung eines ELCC für PV beschrieben. Mittels einer softwaregestützten Inhaltsanalyse wird im Anschluss der definierte Rahmen für ein ELCC für PV getestet (und modifiziert) gegen eine Auswahl von 135 bereits existierender Studien, die sich mit dem Lebenszyklus von PV-Technologien aus ökologischer und ökonomischer Sicht beschäftigen. Im Ergebnis hieraus können die wichtigsten Elemente eines ELCC für PV, wie beispielsweise ökologische Wirkungskategorien oder ökonomische Indikatoren, identifiziert werden (methodisches Feedback). In einem nächsten Schritt werden die Studien hinsichtlich ihrer “Qualität” bezogen auf ökologische, ökonomische und übergreifende Inhalte eines ELCC für PV bewertet. Auf diese Weise kann ein Inventar von Lebenszyklusanalysen für PV erstellt werden, das nach den Technologien und der inhaltlichen Qualität bezüglich eines ELCC strukturiert ist und für weitere Analysen als Grundlage dienen kann. Aus den bisherigen Ergebissen kann eine erste Einschätzung zum aktuellen Stand des ELCC für PV in der Literatur vorgenommen werden: Es existiert bereits ein großer Pool von Studien, die sich mit dem Lebenszyklus der PV beschäftigen. Mit Blick auf die Anforderungen eines ELCC für PV besteht jedoch Nachholbedarf in der Verbindung und gemeinsamen Betrachtung von hot spots und trade offs aus ökologischer und ökonomischer Perspektive. Der definierte theoretische Rahmen für ein ELCC für PV, die kodierten Studien sowie das erstellte Inventar von Lebenszyklusanalysen der PV können nun als Grundlage für weitere Analysen dienen. Insbesondere eine inhaltliche Auswertung der konkreten Ergebnisse von Studien kann so einen Benchmark und Orientierung für neue Lebenszyklusanalysen für PV-Technologien liefern. / The special need of a sustainable energy supply in mind the technologies of the renewable source solar energy, especially photovoltaics (PV) is main subject of the present thesis. Using the inexhaustible, clean and “freely delievered” power from the sun solar devices may play a major role in a cleaner future, but, on the other hand, they are still energy consuming and expensive in their production which consequently demands a whole life cycle perspective when assessing this technology. For a closer look at PV the methodology of Environmental Life Cycle Costing (ELCC) is introduced by following three theoretical points of view. Namely these are sustainability, life cycle thinking and the three dimensional nature of this tool by regarding environmental, economic and technical aspects in their interaction. Based on theoretical elements of Life Cycle Assessment and Life Cycle Costing in combination with the technical background of photovoltaics main requirements and steps for performing an ELCC for PV are described. By executing software based content analysis the defined framework is checked (and modified) against a choice of 135 existing studies analyzing the life cycle of PV technologies from an environmental or economic perspective. As a result the main elements of an ELCC for PV, e.g. environmental impact categories and economic indicators, are identified (methodological feedback). Within the next step the existing studies are rated by their “quality” regarding the environmental, economic and more general parts of an ELCC for PV in order to create an inventory of life cycle studies for PV. This inventory is structured by technologies as well as quality of content respecting ELCC and might be used for further analyses. At this stage the results propose the possibility of a first estimate of the present status of ELCC for PV: until now there is a good pool of existing analyses of the life cycle of PV systems. But from an ELCC perspective the examination of common hot spots and trade offs between economic and environmental aspects should be expanded. The theoretical framework of ELCC for PV, the encoded studies and the inventory of life cycle analyses for PV are now the starting point for further analyses, especially of the individual outcome within studies, which will then pose a benchmark for new life cycle studies of PV technology.

info:eu-repo/classification/ddc/330

ddc:330

Charging electric cars from solar energy

Liang, Xusheng, Tanyi, Elvis, Zou, Xin

January 2016

Before vehicles were heavily relied on coal, fossil fuels and wind for power.  Now, they are rapidly being replaced by electric vehicles and or plug-in hybrid electric cars. But these electric cars are still faced with the problem of energy availability because they rely on energy from biomass, hydro power and wind turbines for power generation. The abundance of solar radiation and its use as solar energy as a power source in driving these rapidly increasing electric cars is not only an important decision but also a necessary condition for eradication of environmental pollution. This study presents a model for charging electric cars from solar energy. Little focus on detailed technologies involved from solar energy capture to battery charging but our main focus is how to provide a modified charging parking lot in Karlskrona city-Sweden. With a surface area of 2850m2, we were able to choose 1STH-350-WH as the right PV modules. Based on the latitude of our design area, a computed 71 degrees angle positioning between solar panel and roof so as to maximise the surface area and optimise the solar irradiance gathering. Based on the power output of approximately116kW these PV modules generated, we further analysed and selected SDP 30KW inverter and Monocrystalline Silicon (1SolTech 1STH-350-WH (350W) solar modules. Also we provide different car charging method by choosing the SAE J1772 standard as one of specifications for dedicated vehicle charging and Clipper Creek HSC-40 as our option of charger. With the data of the generating solar energy every day, charging time, consuming power, we can estimate how many cars the system can handle to charge. Moreover, our system provides AC power from AC power network by general socket type F. We finally concluded that, our model for charging of electric car batteries was not only supportive but efficient in terms of extracting solar energy from sunlight to charge electric cars, thus making the region an eco-friendly place.

AC Net

Converter

Controller

Electric Car Charging

Photovoltaic

Solar Energy

Solar Panel

Storage Battery

Solar Irradiance

System design

Optically transparent UWB antenna for wireless application & energy harvesting

Peter, Thomas

January 2012

Transparent UWB antennas have been the focus of this PhD research. The use of transparent UWB antennas for stealth and energy harvesting has been the underlying applications that have given impetus to this research. Such transparent antennas being built on materials that are discreet, flexible, conformal, conductive and having the ability to provide good antenna performance on glass to serve as the ‘last mile’ link in subsequent generation communications after 4G have been the basis for this contention. UWB in this regard is able to provide the transmission and reception of high data rates and fast video transmission that is an elementary demand of even a 4G wireless communications system. The integration of UWB antennas with photovoltaic to provide integral energy harvesting solutions that will further enhance the value of the UWB system in terms of cost effectiveness and performance are thus the basis of this work. This work hence starts with the study of a transparent conductive oxide polymer, AgHT and its properties, and culminates in the development of a transparent UWB antenna, which can be integrated with photovoltaic for window glass applications on homes and buildings. Other applications such transparent antennas can find use for like on-body wireless communications in healthcare monitoring was also analysed and presented. The radar absorbing material (RAM) property of the AgHT was investigated and highlighted using CST simulation software, as no measurement facilities were available. The transparent UWB antenna in lieu of the inherent absorbent property of the AgHT material is thus able to exhibit stealth characteristics, a feature that would be much desired in military communications. Introduction of a novel method of connecting the co-axial connector to the feed of the antenna to improve gain and efficiency of transparent polymer based antennas and the development of a UWB antenna that maintains its Omni-directional characteristic instead of becoming directional on an amorphous silicon solar cell are presented as some of the contributions for this research work. Some preliminary analysis on the impact of glass on UWB antennas for video transmission and how to improve transmission is presented. The ability of the conductive part of the antenna radiator to be used as a RF and microwave harvester and how it can further add value to a transparent UWB antenna is presented by way of experimental data. Finally yet importantly, this thesis presents some insight into how transparent antennas may be used in Green Technology Buildings to provide an integrated solution for both wireless communications and energy harvesting as part of the future work. Improvement to the aesthetics of the external appearance of residential buildings through the integration of transparent satellite dish onto solar panels on rooftops is also discussed and illustrated as part of this future work.

384.5

SOLENERGI FÖR MILLENNIUM AVSALTNINGSANLÄGGNING : Undersökning av potentialen hos solceller i en off-grid lösning som energikälla inom projektet ''Water in a box''

Wu, Ming

January 2018

This thesis aims first to investigate whether solar panels on the container can provide the process of desalination with energy at the desired location, as well as to dimension a photovoltaic system and battery storage that can run the facility off-grid. Then investigate whether solar cells can be an effective energy solution for Millennium Desalination Device (MDD). The results of this study show that the most annual solar production from containers is 11 510 kWh in Gobabeb, Namibia with a modular efficiency of 22,8 %, which corresponds to 8,2 % operating time per year and is the longest operating time that can be obtained from the all three scenarios. This means that with existing technology and only solar panels on the container, desalination plant is impossible to drive all year round off-grid. The installed power for driving 100 % operating time for one year is 141 kW in Gobabeb and 270 kW in Visby, the corresponding module surface will be lowest 618 m2 and 1184 m2 with modular efficiency of 22,8 %, but there are no additional spaces for all equipment like MDD, solar cells and battery in the container. If the operating time drops to 50 %, the installed power will be 71 kW in Gobabeb, the corresponding module surface will be lowest 415 m2 and battery storage capacity will be at least 160 kWh. Net volume with all equipment will be less than the volume of the container. The cost will be at least 0.2 Swedish kronor per liter of pure water produced with a life of 25 year for solar modules. Usage fee per liter of pure water is 0.03 Swedish kronor based on Gotland’s water and wastewater agency and it means MDD is not a cost-effective solution for Gotland at nowadays. But costs may fall in the future with the price reduction of solar cells and batteries. For water shortage areas, this can be a valuable way to solve the water crisis, but it also depends mostly on the area’s water price.

photovoltaic

solar panel

desalination

water scarcity

battery storage

renewable energy

off-grid

PVGIS

Engineering and Technology

Teknik och teknologier

Egenproducerad solel i ett småhusområde

Englund, Anders, Sundholm, Sara

January 2010

<p>Sverige ska år 2020 ha en energiförsörjning bestående av 50 % förnybara energikällor. Den viktigaste källan till förnybar energi är solen. Solel är dock en dyr investering idag och gällande regelverk försvårar möjligheterna till att tillgodoräkna sig egenproducerad el.</p><p>Byggföretaget JM bygger redan hus med låg energianvändning. Ett sätt att bidra till ett förnybart energianvändande är att installera system som producerar egen el till husen. Detta arbete har genomförts för att undersöka om solel kan komma att bli en konkurrenskraftig produkt att erbjuda JM:s husköpare. I arbetet har ett specifikt område och en av företagets typhusmodeller studerats.</p><p>Dagens solcellsteknik har studerats och ett system för huset har komponerats. Det finns ett flertal typer av solceller men i detta arbete har polykristallina solceller valts utifrån det offertförslag som legat till grund för arbetet. För att kunna dimensionera anläggningen har placering, orientering och solvinklar undersökts. Genom att välja en anläggning har investeringskalkyler och simuleringar kunnat utföras för ett par olika scenarier. Samtliga scenarier bygger på nätanslutna system men skiljer sig mellan dagens regelverk och ett framtida scenario med nettodebitering, dvs. kvittning av egenproducerad el och köpt el.</p><p>Från JM:s sida har det funnits önskemål om att studera hur ett bostadsområde skulle kunna dela på en solcellsanläggning genom ett samfällt system. Den samfällda anläggningen har dimensionerats utifrån fullgott solläge. I aktuellt område innebar det att 16 av 35 hus är lämpligt placerade mot solen, detta kan dock skilja mellan olika områden.</p><p>Resultatet visar att en investering i solel är svår att försvara idag. Med ett statligt stöd på 60 % är återbetalningstiden likväl 20 år. Med ett förändrat regelverk och ett långsiktigt stöd skulle det kunna bli ekonomiskt lönsamt. Genom att solcellstekniken blir billigare och elpriset stiger förbättras läget för solelen. Investeringskostnaden blir lägre per person och öppnar därmed upp för fler investerare.</p>

photovoltaic energy

solar panel

net debit

renewable energy

solel

solcell

nettodebitering

egenproducerad el

samfälld solcellsanläggning

förnybar energi

Building engineering

Byggnadsteknik

Floatovoltaics: Quantifying the Benefits of a Hydro-Solar Power Fusion

McKay, Abe

01 May 2013

To slow climate change, humans should take immediate and widespread action. One way to slow climate change is by switching to switch to renewable power plants such as solar fields. Recently, pioneering companies have built solar fields on water bodies. This study found that such a pairing of water and solar could increase production efficiency by 8-10% through panel cooling, save millions of liters of water from evaporation, and produce energy with under-utilized space.

floatovoltaic

solar panel

floating photovoltaic

Silver Lake

Folsom Lake

Lake Mead

Environmental Engineering

Oil, Gas, and Energy

Sustainability

Water Resource Management

Energy –Efficient Solar Model Improvement Using Motor Calibration Preference

Sahni, Abhishek

09 November 2015

The amount of force or power when applied can move one object from one position to another or the capacity of a system to do work is called energy. It exists in everybody whether they are human beings or animals or non-living things. There are many forms of energy such as: kinetic, potential, light, sound, gravitational, elastic, electromagnetic or nuclear. According to the law of conservation of energy, any form of energy can be converted into another form and the total energy will remain the same. Energy can be broadly classified into two main groups’ i.e. renewable and nonrenewable resources. Many of the renewable energy a technology have been around for years, and as the time go by, are increasing in efficiency. Keywords: solar panel improvement, motor control, energy –efficient Solarplatten, Motosteuerung, Energieeffizenz

Solarpanel

Energieeffizienz

Android

Smartphone

Solar Model

Energy

Motor Calibration Preference

tracking

solar panel

Android smartphone

ddc:004

Sonnenenergie

Energieeffizienz

Smartphone

Egenproducerad solel i ett småhusområde

Englund, Anders, Sundholm, Sara

January 2010

Sverige ska år 2020 ha en energiförsörjning bestående av 50 % förnybara energikällor. Den viktigaste källan till förnybar energi är solen. Solel är dock en dyr investering idag och gällande regelverk försvårar möjligheterna till att tillgodoräkna sig egenproducerad el. Byggföretaget JM bygger redan hus med låg energianvändning. Ett sätt att bidra till ett förnybart energianvändande är att installera system som producerar egen el till husen. Detta arbete har genomförts för att undersöka om solel kan komma att bli en konkurrenskraftig produkt att erbjuda JM:s husköpare. I arbetet har ett specifikt område och en av företagets typhusmodeller studerats. Dagens solcellsteknik har studerats och ett system för huset har komponerats. Det finns ett flertal typer av solceller men i detta arbete har polykristallina solceller valts utifrån det offertförslag som legat till grund för arbetet. För att kunna dimensionera anläggningen har placering, orientering och solvinklar undersökts. Genom att välja en anläggning har investeringskalkyler och simuleringar kunnat utföras för ett par olika scenarier. Samtliga scenarier bygger på nätanslutna system men skiljer sig mellan dagens regelverk och ett framtida scenario med nettodebitering, dvs. kvittning av egenproducerad el och köpt el. Från JM:s sida har det funnits önskemål om att studera hur ett bostadsområde skulle kunna dela på en solcellsanläggning genom ett samfällt system. Den samfällda anläggningen har dimensionerats utifrån fullgott solläge. I aktuellt område innebar det att 16 av 35 hus är lämpligt placerade mot solen, detta kan dock skilja mellan olika områden. Resultatet visar att en investering i solel är svår att försvara idag. Med ett statligt stöd på 60 % är återbetalningstiden likväl 20 år. Med ett förändrat regelverk och ett långsiktigt stöd skulle det kunna bli ekonomiskt lönsamt. Genom att solcellstekniken blir billigare och elpriset stiger förbättras läget för solelen. Investeringskostnaden blir lägre per person och öppnar därmed upp för fler investerare.

photovoltaic energy

solar panel

net debit

renewable energy

solel

solcell

nettodebitering

egenproducerad el

samfälld solcellsanläggning

förnybar energi

Building engineering

Byggnadsteknik

Determinação da eficiência de um coletor solar plano com aletas de vidro

Bentivenha, Luiz Carlos [UNESP]

25 January 2005

Made available in DSpace on 2014-06-11T19:24:42Z (GMT). No. of bitstreams: 0 Previous issue date: 2005-01-25Bitstream added on 2014-06-13T19:11:16Z : No. of bitstreams: 1 bentivenha_lc_me_botfca.pdf: 1314612 bytes, checksum: 253e63a1300e0c3946bf45baca1a4fba (MD5) / Universidade Estadual Paulista (UNESP) / Os coletores solares comumente utilizados no aquecimento de água, para o consumo doméstico, possuem a placa de aquecimento solar plana do tipo chapa - tubo. Devido à crescente utilização desses equipamentos, buscou-se, através deste trabalho, modificar um equipamento convencional, o qual recebeu, na placa solar, aletas de vidro, instaladas no plano vertical em relação à tampa de vidro, dividindo a mesma em diversas áreas, propiciando um aumento, tanto da reflexão dos raios infravermelhos em seu interior, quanto do efeito estufa. O objetivo do ensaio foi estudar o comportamento térmico desse equipamento, trabalhando a determinada vazão e obtendo as temperaturas com o emprego de termopares instalados em vários pontos do sistema, buscando a determinação da eficiência térmica da placa solar modificada. Para a determinação da eficiência, foram considerados o calor útil, o calor absorvido e as perdas de calor. As equações empregadas na determinação da eficiência térmica foram trabalhadas no programa Excel.Verificou-se que o equipamento apresentou um bom rendimento, atendendo as especificações definidas pelo INMETRO. A temperatura média de saída da água do equipamento apresentou valor superior a de equipamento similar, o mesmo não ocorreu com seu rendimento, embora as diferenças registradas tenham sido pequenas. A eficiência do equipamento não depende apenas dos parâmetros do projeto, mas também de outros fatores que levam a perda de energia. / The solar collectors commonly used in the water heating for domestic consumption possess the flat plate solar heating of plate type - tube. Due to increasing applications of those equipments the purpose was to modify the conventional, which received glass fins in the solar plate, installed in the vertical plan in relation to the glass cover, dividing the same in several areas, enabling reflection increase of the infrared rays in its interior as well as greenhouse effect. The thermal performance of the equipment has been studied analyzing the certain flow and obtaining the temperatures with the thermopairs installed in several points of the system and determining the thermal efficiency of the modified solar plate. The useful heat, the absorbed heat and the losses of heat were considered. The equations of the thermal efficiency were obtained in the Excel program. The equipment presented a good performance according to INMETRO specifications. The medium temperature of the water exit presented superior value when compared to a similar equipment. The same didn't occur with its performance, although the registered differences have been small. The efficiency of the equipment doesn't depend only on the parameters of the project, but also on other factors which lead to energy loss.

Aquecimento solar

Energia solar

Aquecedores solares de água

Coletores solares

Solar panel of water

Solar energy

Solar heating

Solar collectors