1000 resultados para Solar houses.
Resumo:
At the beginning of 2003 the four year long research project REBUS on education, research, development and demonstration of competitive solar combisystems was launched. Research groups in Norway, Denmark, Sweden and Latvia are working together with partners from industry on innovative solutions for solar heating in the Nordic countries. Existing system concepts have been analyzed and based on the results new system designs have been developed. The proposed solutions have to fulfill country specific technical, sociological and cost requirements. Due to the similar demands on the systems in Denmark and Sweden it has been decided to develop a common system concept for both countries, which increases the market potential for the manufacturer. The focus of the development is on systems for the large number of rather well insulated existing single family houses. In close collaboration with the industrial partners a system concept has been developed that is characterized by its high compactness and flexibility. It allows the use of different types of boilers, heating distribution systems and a variable store and collector size. Two prototypes have been built, one for the Danish market with a gas boiler, and one for the Swedish market with a pellet boiler as auxiliary heater. After intensive testing and eventual further improvements at least two systems will be installed and monitored in demonstration houses. The systems have been modeled in TRNSYS and the simulation results will be used to further improve the system and evaluate the system performance.
Resumo:
Within the framework of the REBUS project the German building industry has been investigated regarding their energy concepts. The intention was to evaluatethe establishment of renewable energy sources on the German market for new built houses and prefab houses in particular. For this purpose the products of 85manufacturers of prefab houses have been analyzed. Of special interest was the applicationof heating and hot water systems driven by solar energy and biomass. The results show that both techniques are well accepted and established. Almost 90% of themanufacturers offer solar systems on request and almost 70% heating systems based on Pellets. 24% offered solar and 7% as standard options in their range. From theachieved figures the potential of the Swedish market can be worked out. Strategies to introduce renewable energy to a greater extent to Swedish house manufacturers and builders might also be found.
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Pilot versions of a solar heating/natural gas burner system, of a solar heating/pellet burner system and of a façade/roof integrated polymeric collector have been installed in the summer of 2006 in a number of demonstration houses in Denmark, Sweden and Norway.These three new products have been evaluated by means of measurements of the thermal performance and energy savings of the pilot systems in practice and by means of a commercial evaluation.The conclusion of the evaluations is that the products are attractive for the industry partners METRO THERM A/S, Solentek and SOLARNOR. It is expected that the companies will bring the products into the market in 2007.Further, the results of the project have been presented atinternational and national congresses and seminars for the solar heating branch. The congresses and seminars attracted a lot of interested participants.Furthermore, the project results have been published in international congress papers as well as in national journals in the energy field.Consequently, the Nordic solar heating industry will benefit from the project.
Resumo:
Reduction of household energy consumption is one of the top issues in contemporary discussions on sustainable consumption. This chapter concerns one way through which consumption of purchased energy for house heating can be reduced; by having a solar thermal system added to one's house. However, the fact that one of the components - the solar collector - usually is situated on the roof or the facade of a building, is a recurrent impediment to such installations. In certain contexts, these attributes may melt into the building, while in others, they may be perceived as problematic. The latter may particularly be the case when the appearance of the building is of major imiportance, as with houses deemed worthy of preservation for coming generations. This chapter draws upon a study carried out in Visby Town, a walled Hanseatic town and a World Heritage site on the island of Gotland, Sweden.
Resumo:
This paper focuses on the study of cascade heat pump systems in combination with solar thermal for the production of hot water and space heating in single family houses with relatively high heating demand. The system concept was developed by Ratiotherm GmbH and simulated with TRNSYS 17. The basic cascade system uses the heat pump and solar collectors in parallel operation while a further development is the inclusion of an intermediate store that enables the possibility of serial/parallel operation and the use of low temperature solar heat. Parametric studies in terms of compressor size, refrigerant pair and size of intermediate heat exchanger were carried out for the optimization of the basic system. The system configurations were simulated for the complete year and compared to a reference of a solar thermal system combined with an air source heat pump. The results show ~13% savings in electricity use for all three cascade systems compared to the reference. However, the complexity of the systems is different and thus higher capital costs are expected.
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Dynamic system test methods for heating systems were developed and applied by the institutes SERC and SP from Sweden, INES from France and SPF from Switzerland already before the MacSheep project started. These test methods followed the same principle: a complete heating system – including heat generators, storage, control etc., is installed on the test rig; the test rig software and hardware simulates and emulates the heat load for space heating and domestic hot water of a single family house, while the unit under test has to act autonomously to cover the heat demand during a representative test cycle. Within the work package 2 of the MacSheep project these similar – but different – test methods were harmonized and improved. The work undertaken includes: • Harmonization of the physical boundaries of the unit under test. • Harmonization of the boundary conditions of climate and load. • Definition of an approach to reach identical space heat load in combination with an autonomous control of the space heat distribution by the unit under test. • Derivation and validation of new six day and a twelve day test profiles for direct extrapolation of test results. The new harmonized test method combines the advantages of the different methods that existed before the MacSheep project. The new method is a benchmark test, which means that the load for space heating and domestic hot water preparation will be identical for all tested systems, and that the result is representative for the performance of the system over a whole year. Thus, no modelling and simulation of the tested system is needed in order to obtain the benchmark results for a yearly cycle. The method is thus also applicable to products for which simulation models are not available yet. Some of the advantages of the new whole system test method and performance rating compared to the testing and energy rating of single components are: • Interaction between the different components of a heating system, e.g. storage, solar collector circuit, heat pump, control, etc. are included and evaluated in this test. • Dynamic effects are included and influence the result just as they influence the annual performance in the field. • Heat losses are influencing the results in a more realistic way, since they are evaluated under "real installed" and representative part-load conditions rather than under single component steady state conditions. The described method is also suited for the development process of new systems, where it replaces time-consuming and costly field testing with the advantage of a higher accuracy of the measured data (compared to the typically used measurement equipment in field tests) and identical, thus comparable boundary conditions. Thus, the method can be used for system optimization in the test bench under realistic operative conditions, i.e. under relevant operating environment in the lab. This report describes the physical boundaries of the tested systems, as well as the test procedures and the requirements for both the unit under test and the test facility. The new six day and twelve day test profiles are also described as are the validation results.
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The first step in order to comply with the European Union goals of Near to Zero Energy Buildings is to reduce the energy consumption in buildings. Most of the building consumption is related to the use of active systems to maintain the interior comfort. Passive design strategies contribute to improve the interior comfort conditions, increasing the energy efficiency in buildings and reducing their energy consumption. In this work, an analysis of the passive strategies used in Net Energy Plus Houses has been made. The participating houses of the Solar Decathlon Europe 2012 competition were used as case studies. The passive design strategies of these houses were compared with the annual simulations, and the competition monitored data, especially during the Passive Monitored Period. The analysis included the thermal properties of the building envelope, geometric parameters, ratios and others passive solutions such as Thermal Energy Storage systems, evaporative cooling, night ventilation, solar gains and night sky radiation cooling. The results reflect the impact of passive design strategies on the houses' comfort and efficiency, as well as their influence in helping to achieve the Zero Energy Buildings category.
Resumo:
Solar Decathlon Europe (SDE) is an international multidisciplinary competition in which 20 universityteams build and operate energy-efficient solar-powered houses. The aim of SDE is not only scientificbut also educational and divulgative, making visitors to understand the problems presented by realengineering applications and architecture. From a research perspective, the energy data gathered dur-ing the competition constitutes a very promising information for the analysis and understanding of thephotovoltaic systems, grid structures, energy balances and energy efficiency of the set of houses. Thisarticle focuses on the electrical energy components of SDE competition, the energy performance of thehouses and the strategies and behaviors followed by the teams. The rules evaluate the houses? electricalenergy self-sufficiency by looking at the electricity autonomy in terms of aggregated electrical energybalance; the temporary generation-consumption profile pattern correlation; and the use of electricityper measurable area. Although the houses are evaluated under the same climatological and consump-tion conditions, production results are very different due to the specific engineering solutions (differentelectrical topologies, presence or absence of batteries, diverse photovoltaic module solutions, etc.)
Resumo:
Given the global energy and environmental situation, the European Union has been issuing directives with increasingly demanding requirements in term of the energy efficiency in buildings. The international competition of sustainable houses, Solar Decathlon Europe (SDE), is aligned with these European objectives. SDE houses are low energy solar buildings that must reach the near to zero energy houses goal. In the 2012 edition, in order to emphasize its significance, the Energy Efficiency Contest was added. SDE houses interior comfort, functioning and energy performance is monitored. The monitoring data can give an idea about the efficiency of the houses. However, a jury comprised by international experts is responsible for carrying out the houses energy efficiency evaluation. Passive strategies and houses services are analyzed. Additionally, the jury's assessment has been compared with the behavior of the houses during the monitoring period. Comparative studies make emphasis on the energy aspects, houses functioning and their interior comfort. Conclusions include thoughts related with the evaluation process, the results of the comparative studies and suggestions for the next competitions.
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Este trabajo se ocupa de la construcción modular ligera de viviendas unifamiliares, más concretamente aborda el problema de la definición constructiva de las mismas, habida cuenta de lo poco conocido y publicado de este aspecto en particular. Dado que la construcción es fruto de la evolución, resulta de gran importancia el estudio de los antecedentes para comprender la situación actual, por ello para documentar como corresponde el estado de la técnica y de la investigación se estudiaron los antecedentes desde sus primeras manifestaciones a finales del siglo XIX hasta nuestros días. Contrariamente a las profecías de Le Corbusier y otros, la industrialización no ha llegado a la construcción ni en la forma ni en la medida que era de esperar a principios del siglo XX. Sin embargo y a pesar del relativo “fracaso” de la industrialización en convertirse en la forma mayoritaria de producir edificios, lo cierto es que algunos sistemas altamente industrializados, como lo es la construcción modular ligera, han logrado un lugar en el mercado, que en algunos países resulta cuanto menos significativo. Delimitar el estado de la técnica y la situación actual es crucial en este trabajo, toda vez que la construcción industrializada la realizan empresas, y situarse al margen de las mismas y de su producción, nos guste o no, resulta contrario al sentido común. De este modo se han identificado y documentado ejemplos como el de EE.UU. y Japón, entre otros, que resultan muy ilustrativos tanto desde la evolución como del estado actual. Del estado de la técnica y la investigación también resulta la escasez de publicación de detalles constructivos específicos de la construcción modular ligera. Es obvio que los fabricantes intentan blindarse mediante el secreto industrial, logrando que las soluciones constructivas más interesantes queden fuertemente protegidas dentro del conocimiento reservado de la empresa. De este modo un sistema que alcanza grados de prefabricación del 95%, tan atractivo e interesante para el arquitecto queda reservado al conocimiento de unos pocos dentro de las empresas. La búsqueda de mayor información sobre estos sistemas encuentra un filón indiscutible en los proyectos de las casas del concurso Solar Decathlon. En efecto, debido a las condiciones particulares de este concurso, las casas que compiten deben ser instaladas en un plazo corto, por lo que en su mayoría recurren al método de construcción modular ligera, para lograr correctamente este objetivo. Adicionalmente todos los planos de proyecto incluidos los de detalle, así como memorias de especificaciones técnicas, quedan colgadas en la Web, a libre disposición del público. De este modo se ha considerado interesante, conveniente y útil, aprovechar como fuente documental de este trabajo, aparte de lo obtenido en el estado de la técnica y la investigación, los proyectos de las casas de los concursos 2005 y 2007, que fueron las dos últimas ediciones celebradas cuando se inició esta tesis. De modo similar a esta carencia de detalles publicados se observa igualmente una falta de investigación y de metodologías adecuadas a la misma sobre soluciones y detalles constructivos propios de la construcción modular ligera. Por eso y ante la dificultad de manejar adecuadamente una información disponible pero farragosa, este trabajo ha dedicado una parte importante de su esfuerzo a la creación de una metodología adecuada a este tipo de situación. Hay que destacar que cada proyecto puede constar fácilmente de 60 a casi 200 planos, sin contar las memorias técnicas y otros documentos, tales como galerías de imágenes, etc. Por otra parte resulta útil establecer esta metodología, no solo para esta tesis, sino para futuros trabajos de investigación sobre el tema, toda vez que con posterioridad a 2007 se han celebrado nuevas ediciones del concurso con su correspondiente volumen de información disponible. La metodología del análisis de los proyectos se basa en el diseño y creación de siete fichas tipo que resumen los aspectos fundamentales del proyecto desde el punto de vista constructivo, permitiendo de este modo su rápida visualización y comprensión sin pretender exhaustividad, ya que en caso de querer profundizar en el detalle de la información siempre está el proyecto original para ello. Tras estudiar la información obtenida de los proyectos de las casas de concurso, se contrastan y discuten los resultados para obtener conocimientos de interés para el objetivo propuesto en la tesis. Se comparan los resultados procedentes del estado de la técnica y de la investigación y se obtienen las conclusiones correspondientes. De este modo ha sido posible identificar una serie de criterios técnicos de proyecto de viviendas unifamiliares realizadas mediante construcción modular ligera, que además se organizan en varios niveles, por lo que el resultado es un conjunto de criterios como germen de una futura guía o manual. Como conclusiones fundamentales de la tesis hay que destacar las metodológicas, que habilitan la extensión de este estudio a otros trabajos y la aportación original al conocimiento con la definición de una serie de criterios técnicos de proyecto de viviendas realizadas mediante construcción modular ligera, que además de mejorar esta parte del saber constructivo serán de gran ayuda a los arquitectos de cara a la reducción de errores, que a menudo derivan en mayores costes y plazos, cuando no directamente al abandono del sistema constructivo. El trabajo de la tesis se estructura en siete capítulos a saber: Capítulo 1: Introducción, donde se explica el tema de la tesis, el objetivo principal, las limitaciones y se aportan algunas definiciones. Capítulo 2: Estado de la técnica y la investigación, dentro del cual se presentan los antecedentes desde sus inicios pasando por la primera y segunda mitad del siglo XX y finalizando con el estado actual que recorre los sistemas de EE.UU, Japón, Europa, Escandinavia, centro Europa, Francia, España y algunos ejemplos de Latinoamérica. En el estado de la investigación se presentan las publicaciones tanto en revistas científicas indexadas en el JCR, como publicaciones no indexadas en las que se muestran artículos científicos, comunicaciones a congresos, documentación sobre el concurso Solar Decathlon, libros específicos y libros genéricos sobre construcción modular ligera, tesis doctorales tanto generales como específicas sobre el concurso Solar Decathlon, documentos de idoneidad técnica, páginas Web del concurso Solar Decathlon y finalmente páginas Web de empresas de construcción modular ligera y patentes. También se expresan las conclusiones parciales del capítulo así también como la justificación y los objetivos particulares. Capítulo 3: Metodología, se expone en primer lugar el planteamiento del problema, para luego desarrollar los métodos utilizados para el estudio y clasificación del transporte y de la organización modular, la relación entre la organización modular y distribución espacial, el diseño y contenido de las fichas resumen de los 38 proyectos presentados al SD2005 y SD2007, así también como la información consultada para su realización. Se explica asimismo como se realizaron las tablas comparativas partiendo de la información de las fichas. Finalmente se expresa la manera en que se trató el estudio particular de la junta entre módulos. Capítulo 4: Discusión de resultados, dónde en primer lugar se presenta la clasificación y las estrategias del transporte así también como una clasificación de la organización modular, en segundo lugar se estudian las relaciones que existen entre el sistema modular y la organización espacial. A partir de aquí se muestra el estudio de la estructura de todas las casas del SD2005 y SD2007, según el tipo y material de las zapatas, mostrando tanto tablas cuantitativas como tablas gráficas con fotos. De la misma manera se tratan los forjados, los pilares y las vigas y las cubiertas. Se estudia además el cerramiento opaco y acristalado, la cubierta y el forjado según las capas que lo componen. En el caso de las instalaciones se estudian las que son especiales, descartando las normales en este tipo de casas, como son los paneles fotovoltaicos, placas térmicas o tubos de vacío y los sistemas de almacenamiento de energía, como las baterías, presentando tablas numéricas y gráficas con fotos. El transporte se analiza según corresponda al traslado de la vivienda o al transporte de apoyo, según el tipo y la cantidad utilizado. Con respecto al montaje se diferencia en si se usó grúa o no, y en el caso de no utilizarse se muestran los métodos alternativos. Con respecto a la exploración de la organización modular se presentan la cantidad de módulos que utilizó cada casa, así como también la cuantificación de los sistemas híbridos como son elementos lineales 1D, paneles 2D. Por último se muestra el estudio detallado de la junta entre módulos 3D. Finalmente se realiza la propuesta de un conjunto de criterios técnicos de proyecto organizado en cuatro niveles: 1º nivel de criterios generales, 2º nivel sobre sistemas constructivos, 3º nivel de detalles constructivos y el 4º nivel llamado logística obras previas, transporte y montaje. Capítulo 5: Conclusiones y líneas futuras de investigación, se exponen las conclusiones generales, metodológicas, documentales y por último las de construcción modular. Finalmente se realiza una propuesta de líneas futuras de investigación. Capítulo 6: Bibliografía. Capítulo 7: Anexos, en el que se presentan todas las fichas resumen de las casas realizadas por el autor de esta tesis. Además se incluyen los casos concretos de Voisin en Francia y la TVA (Tennessee Valley Authority) en EE.UU., así como referencias de manuales genéricos de construcción ligera, medidas de transporte en España e información sobre estadísticas de viviendas en la Unión Europea. ABSTRACT This paper deals with Light Modular Construction of houses, and specifically addresses the problem of the constructive definition of the same, given how little known and published this subject has been. Since building construction is the result of evolution, it is of great importance to study its background for understanding the current situation, therefore to document the state of the art and research, its history was studied from its origins dating to the end nineteenth century to our days. Contrary to the prophecies of Le Corbusier and others, industrialization has not reached the construction neither in the form nor to the extent that it was expected in the early twentieth century. However, despite the relative "failure" of industrialization to become the major form of production for buildings, the fact is that some highly industrialized systems, such as the so called Lightweight Modular Construction, have achieved a place in the market, which in some countries is at least significant. To outline the state of the art and the current situation is crucial in this work, since industrialized construction is carried out by companies, and to step away from them and their production, whether we like it or not, it is contrary to common sense. So that, several cases have been identified and documented, such as the US and Japan examples, among others, which are very illustrative both from evolution and the current status. The state of the art and research shows also a shortage of publication of specific construction details of light modular construction. Obviously, manufacturers try to shield themselves by trade secret, making the most interesting constructive solutions remain heavily protected within the reserved knowledge of the company, so a system that reaches levels of 95% prefabrication, so attractive and interesting for the architect It is reserved to the knowledge of a few people inside the companies. The search for more information on these systems finds an invaluable reef in the projects of the Solar Decathlon houses. Indeed, due to the particular conditions of this contest, houses competing must be installed in a short time, so mostly turn to modular construction methods for this purpose to achieve properly this goal. Additionally all levels of project, including detailed and technical specifications reports are published on the Web, freely available to the general public. Thus it was considered interesting, convenient and useful to take advantage as a documentary source of this work, apart from what it were obtained in the state of the art and research, the projects of the houses of the 2005 and 2007 contests, which were the last two editions already held before this thesis was started. Similar to this lack of published details it is also observed a lack of research and methodologies adapted to the solutions and construction details of lightweight modular construction. So that, and facing the difficulty of adequately manage the available but bulky information, this work has devoted a significant part of its effort to create an appropriate methodology for this type of situation. It is noteworthy that each project can easily consist of 60 to almost 200 blueprints, not including technical reports and other documents, such as photo galleries, etc. The methodology of the analysis of the projects is based on the design and creation of seven record sheets that summarize key aspects of the project from a construction point of view, thus allowing quick watching and understanding of the project, without claiming completeness, always keeping for further information the blueprints themselves. After studying the information obtained from the projects of the competition houses, the results are compared and discussed to obtain relevant knowledge according to the objective proposed in the thesis. The results from the state of the art and research are also compared and the conclusions so obtained make possible to identify a number of technical design criteria for single family homes made using lightweight modular construction, which also have been organized at various levels, so the result is a set of criteria as a seed for a future guide or manual. Among the main conclusions of the thesis must be noted the methodological ones, that enable the extension of this study to other works and are an original contribution to knowledge with the definition of a number of technical criteria for housing projects made by light modular construction, what in addition to improving this part of the constructive knowledge will be of great help for the architects to reduce errors that often result in higher costs and delays, if not in abandonment of the construction system itself. The work of the thesis is divided into seven chapters as follows: Chapter 1: Introduction, where the topic of the thesis, the main objective, limitations and the provided definitions is explained. Chapter 2: State of the art and research, within which history is presented from the beginning through the first and second half of the twentieth century and ending with the current systems, that spans from the USA to Japan, Europe, Scandinavia, Central Europe, France, Spain and some Latin American examples. In the state of research publications are presented both on scientific journals indexed in the JCR, and non-indexed publications in which scientific articles, conference papers, information about the Solar Decathlon competition, generic and specific books on light modular construction, articles both general and specific on the Solar Decathlon competition, technical approval documents, dissertations, the Solar Decathlon Web pages and finally lightweight modular construction companies Web pages and patents. The partial conclusions of the chapter as well as the rationale and specific objectives are also expressed. Chapter 3: Methodology first of all exposes the problem statement and then develops the methods used for the study and classification of transportation and modular organization, the relationship between the modular organization and spatial distribution, design and content summary records of the 38 projects submitted to the SD2005 and SD2007, as well as information consulted for its realization. It explains equally how the comparative tables based on information from the chips were made. Finally, the way the particular study of the joint between modules is carried out is also treated. Chapter 4: Discussion, first sorting a classification of transport strategies as well as of modular organization, secondly the relationship between the modular system and the spatial organization studied is presented. From then on, the study of the structure of every house Moreover, to establish this methodology is useful not only for this thesis, but for future research on the subject, since after 2007 there have been held new editions of the contest with a corresponding volume of information available. shown in the SD2005 and SD2007 contests, depending on the type and material of the shoe, showing both quantitative tables as graphic boards with pictures is carried out. Similarly slabs, columns and beams and roofs are treated. Furthermore, the opaque and transparent façades, as well as roof and floor enclosure, according to the layers that compose them are studied. In the case of facilities there have been only addressed that which are of a special type, discarding that considered usual in this type of houses such as photovoltaic panels, thermal panels or vacuum tubes and energy storage systems such as batteries, presenting numerical and graphical tables with photos .The transportation is analyzed depending on it is used to move the house or for additional support, depending on the type and quantity of items used. Regarding assembly it has been made a difference if crane is or not used and if not, what the alternative methods are. With respect to the exploration of the modular organization, the amount of modules used in each house is presented, as well as the quantification of hybrid systems such as linear members as well as 1D, 2D panels. Finally, it has been carried out the detailed study of the joint between 3D modules. Finally it is proposed a set of technical criteria organized into four levels, 1st level of general criteria, 2nd level on building systems, 3rd level construction details and 4th level called previous works and logistics, transportation and assembly. Chapter 5: Conclusions and future research, where general, methodological, documentary and finally modular construction findings are presented. A proposal for further research is done. Chapter 6: Bibliography. Chapter 7: Annexes, in which all the record sheets of houses made by the author of this thesis are presented. Besides the specific cases of Voisin in France and TVA (Tennessee Valley Authority) in the USA, as well as general reference manuals on lightweight construction, transportation dimensions in Spain, and information on housing statistics in the European Union are included.
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Face aos padrões atuais de vida, em que despendemos a maior parte do nosso tempo no interior de edifícios, com um nível de conforto que ninguém quer abdicar, urge o desenvolvimento de tecnologias de climatização sustentáveis. Devido a uma combinação única de fatores, casas de baixo consumo de energia (e também casas passivas) em Portugal, são particularmente adequadas de explorar as vantagens da energia solar térmica, especialmente quando combinado com armazenamento sazonal de energia. No entanto nenhum exemplo documentado existe de como esta sinergia pode ser explorada com sucesso em Portugal, ilustrando assim o modo em que a necessidade de aquecimento pode ser colmatada de uma forma sustentável sem o uso de combustíveis fósseis. A energia solar é uma excelente alternativa de fonte de energia para aquecimento de edifícios. Um principal fator que limita a sua aplicação é que é uma fonte de energia com uma disponibilidade média de variação cíclica. O uso de armazenamento sazonal de energia pode reduzir substancialmente o custo do sistema solar que é capaz de fornecer até 100% das necessidades energéticas dos edifícios. Estes sistemas são projetados para armazenar a energia solar durante o verão e reter o calor armazenado para posterior utilização durante o inverno; Abstract: SEASONAL SOLAR THERMAL ENERGY STORAGE FOR LOW TEMPERATURE HEATING BUILDINGS. Given the current standards of living, where we spent most of our time inside buildings, with a level of Comfort that no one wants to give up, urges the development of sustainable climate control technologies. Due to a unique combination of factors, low energy (and also passive) houses in Portugal are particularly well suited to exploiting the advantages of solar thermal energy especially when combined with seasonal energy storage. However no documented example there of how this synergy can be exploited successfully in Portugal, illustrating the way in which the need for heating can be addressed in a sustainable manner without the use of fossil fuels. Solar energy is an important alternative energy source for heating applications. One main factor that limits its application is that it is an energy source with an average availability of cyclical variation. The use of seasonal thermal energy storage can substantially reduce the cost of solar energy systems that can supply up to 100% of buildings energy needs. Such systems are designed to collect solar energy during the summer and retain the stored heat for use during the winter.
