Relevant bibliographies by topics / SOLAR WATER HEATING SYSTEM

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'SOLAR WATER HEATING SYSTEM'

Author: Grafiati
Published: 11 September 2023

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Journal articles on the topic "SOLAR WATER HEATING SYSTEM"

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Pant, Gunjan, Chandan Swaroop Meena, and Veena Choudhary. "Review on Solar Assisted Heat Pump Water Heating System." International Journal of Energy Resources Applications 1, no. 2 (December 30, 2022): 58–84. http://dx.doi.org/10.56896/ijera.2022.1.2.011.

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Fanney, A. H., and B. P. Dougherty. "A Photovoltaic Solar Water Heating System." Journal of Solar Energy Engineering 119, no. 2 (May 1, 1997): 126–33. http://dx.doi.org/10.1115/1.2887891.

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A novel solar water heating system was patented in 1994. This system uses photovoltaic cells to generate electrical energy that is subsequently dissipated in multiple electric resistive heating elements. A microprocessor controller continually selects the appropriate heating elements such that the resistive load causes the photovoltaic array to operate at or near maximum power. Unlike other residential photovoltaic systems, the photovoltaic solar water heating system does not require an inverter to convert the direct current supplied by the photovoltaic array to an alternating current or a battery system for storage. It uses the direct current supplied by the photovoltaic array and the inherent storage capabilities of a residential water heater. A photovoltaic solar hot water system eliminates the components most often associated with the failures of solar thermal hot water systems. Although currently more expensive than a solar thermal hot water system, the continued decline of photovoltaic cell prices is likely to make this system competitive with solar thermal hot water systems within the next decade. This paper describes the system, discusses the advantages and disadvantages relative to solar thermal water heating systems, reviews the various control strategies which have been considered, and presents experimental results for two full-scale prototype systems.
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Ait Ahmed, Wassima, Mohammed Aggour, and Fayçal Bennani. "Automating a solar water heating system." Journal of Energy Systems 1, no. 2 (November 5, 2017): 56–64. http://dx.doi.org/10.30521/jes.330414.

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Gojak, Milan, Filip Ljubinac, and Miloš Banjac. "Simulation of solar water heating system." FME Transactions 47, no. 1 (2019): 1–6. http://dx.doi.org/10.5937/fmet1901001g.

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Mohsen, Mousa S., and Bilal A. Akash. "On integrated solar water heating system." International Communications in Heat and Mass Transfer 29, no. 1 (January 2002): 135–40. http://dx.doi.org/10.1016/s0735-1933(01)00332-3.

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Khambalkar, Vivek P., Sharashchandra R. Gadge, and Dhiraj S. Karale. "Solar water cost and feasibility of solar water heating system." International Journal of Global Energy Issues 31, no. 2 (2009): 208. http://dx.doi.org/10.1504/ijgei.2009.023896.

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Matuska, Tomas, and Borivoj Sourek. "Performance Analysis of Photovoltaic Water Heating System." International Journal of Photoenergy 2017 (2017): 1–10. http://dx.doi.org/10.1155/2017/7540250.

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Performance of solar photovoltaic water heating systems with direct coupling of PV array to DC resistive heating elements has been studied and compared with solar photothermal systems. An analysis of optimum fixed load resistance for different climate conditions has been performed for simple PV heating systems. The optimum value of the fixed load resistance depends on the climate, especially on annual solar irradiation level. Use of maximum power point tracking compared to fixed optimized load resistance increases the annual yield by 20 to 35%. While total annual efficiency of the PV water heating systems in Europe ranges from 10% for PV systems without MPP tracking up to 15% for system with advanced MPP trackers, the efficiency of solar photothermal system for identical hot water load and climate conditions is more than 3 times higher.
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Syaifurrahman, A. Gani Usman, and Rakasiwi Rinjani. "Solar Water Heating System for Biodiesel Production." E3S Web of Conferences 31 (2018): 02012. http://dx.doi.org/10.1051/e3sconf/20183102012.

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Nowadays, electricity become very expensive thing in some remote areas. Energy from solar panels give the solution as renewable energy that is environment friendly. West Borneo is located on the equator where the sun shines for almost 10-15 hours/day. Solar water heating system which is includes storage tank and solar collections becomes a cost-effective way to generate the energy. Solar panel heat water is delivered to water in storage tank. Hot water is used as hot fluid in biodiesel jacked reactor. The purposes of this research are to design Solar Water Heating System for Biodiesel Production and measure the rate of heat-transfer water in storage tank. This test has done for 6 days, every day from 8.30 am until 2.30 pm. Storage tank and collection are made from stainless steel and polystyrene a well-insulated. The results show that the heater can be reach at 50ºC for ±2.5 hours and the maximum temperature is 62ºC where the average of light intensity is 1280 lux.
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Sun, Liangliang, Nan Xiang, Yanping Yuan, and Xiaoling Cao. "Experimental Investigation on Performance Comparison of Solar Water Heating-Phase Change Material System and Solar Water Heating System." Energies 12, no. 12 (June 19, 2019): 2347. http://dx.doi.org/10.3390/en12122347.

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Phase change material can be used as heat transfer fluid in the solar water heating system, which is the latest way to improve thermal efficiency. In this paper, graphene composite paraffin emulsion is used as heat transfer fluid in a solar water heating-phase change material (SWH-PCM) system. By comparing with the traditional solar water heating (SWH) system, the thermal performance characteristics of SWH-PCM system have been investigated experimentally. The SWH-PCM system has higher heat storage than the SWH system. The heat storage of SWH-PCM system and SWH system all increase with the increase of solar irradiance, while the thermal efficiency has the opposite trend. The flow rate has a greater influence on the thermal efficiency of SWH-PCM system than that of the SWH system. With the flow rate of 200 L/h, the thermal efficiency of SWH-PCM system is 14.21% higher than that of the SWH system. In summary, the SWH-PCM system is a promising solar water heating system with high heat storage and thermal efficiency.
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Wang, Hai Ying, Song Tao Hu, and Jia Ping Liu. "Joint Application of Solar Water Heating System and Air-Conditioning System in a Dormitory Building." Advanced Materials Research 171-172 (December 2010): 215–18. http://dx.doi.org/10.4028/www.scientific.net/amr.171-172.215.

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Solar water heating system is used to supply hot water all-year-round for a new dormitory building. Flat solar energy collectors are mounted on the roof. The hot water tank and pumps are installed together with the air conditioning equipments in the plant room. Air cooled heat pump is used to provide cooling in summer, and high temperature water from boiler room (in old building) is used as heat source in winter. Usually auxiliary heating is necessary to improve the stability and reliability of solar water heating system. In this case, we take full use of the equipment of air conditioning system instead of electricity as auxiliary heating resources. In this paper, we introduced the design of the solar water heating system and the auxiliary heating method by air conditioning systems. The control strategies to fulfill all the functions and switch between different conditions are also introduced.
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Dissertations / Theses on the topic "SOLAR WATER HEATING SYSTEM"

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Magnusson, Erik, and Johan Schedwin. "Development of solar water heating system." Thesis, Högskolan i Skövde, Institutionen för teknik och samhälle, 2010. http://urn.kb.se/resolve?urn=urn:nbn:se:his:diva-4428.

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This report includes development of an already designed solar water heater. The product shall be constructed in a way that it will suit a manufacturing line in Kampala, Uganda. To find the most suitable design for each area a research was carried out which included study visits, interviews and background reading. It provided the following results: Regarding the attachment of in- and outgoing pipes from the water tank many methods were taken into consideration and it was found that the best and most suitable way for this case is to weld the fittings using a weld robot. Regarding the fitting of the acrylic, a suitable solution is to make a flange when vacuum forming the plastic casing to further support the design. This could also be used to waterproof the case by using a sealing material. A suggestion of using pre-molded PU-foam is also presented. Regarding the ability to open the case for maintenance, two solutions were recommended. Either the use of spire clips or having the clips integrated into the casing. Regarding the calculation of material usage when deep drawing the tank and collector, it is possible to do a reasonably accurate assumption. The complicated design in this product makes the estimation less accurate. It is recommended that test draws are done and often the machine producer has more precise numbers. Regarding the coloring of the collector; chemical coloration is not possible on a galvanized surface. The method used is painting, either with powder coating or with wet paint.
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Lo, S. N. G. "Passive solar space and water heating systems." Thesis, Cranfield University, 1990. http://hdl.handle.net/1826/3935.

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The performance of three types of passive solar feature has been studied; fifteen Roof-Space Collectors on an estate of low energy houses at the Milton Keynes Energy Park, 101m2 of Thermosyphoning Air Panels at a county primary school in Nazeing, Essex, and three Thermosyphon Solar Water Heaters installed on a group of three terraced cottages at Cranfield, Bedfordshire. Each of these passive solar features was monitored intensively for at least one heating season using dedicated data-acquisition systems. The maximum specific annual solar contributions to the auxiliary space/water heating systems were 128 kWh/M2 , 78 kWh/M2' and 104 kWh/M2 respectively. The corresponding payback periods were 25,37 & 21 years respectively, on replication.
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Sánchez, Herranz Daniel. "DESIGN OF A SOLAR WATER HEATING SYSTEM IN A RESIDENTIAL BUILDING." Thesis, University of Gävle, University of Gävle, Department of Technology and Built Environment, 2009. http://urn.kb.se/resolve?urn=urn:nbn:se:hig:diva-4957.

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Elhabishi, Ali Mohamed. "Optimising collector plate geometry for a specific solar syphon system design." Thesis, Cape Peninsula University of Technology, 2016. http://hdl.handle.net/20.500.11838/2385.

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Thesis (MTech (Mechanical Engineering))--Cape Peninsula University of Technology, 2016.
Solar energy is still not being used effectively in countries in the developing world, though it's a partial solution to the problem of shortage and expensive energy. Normally harvested through flat plate collectors, converting solar radiation into heat is the most direct application that can be effected in water heating systems. Many researchers have attempted to develop means of improving the efficiency of the flat plate solar energy collector; however there appears to be no evidence of any work regarding the effect of geometric configuration on the performance of flat plate solar collector. This study presents results obtained when comparing the performance of a solar water heating system equipped with three manufactured flat plate solar collector panels of numerically identical surface area but of different geometric configuration as they were individually attached to a typical geyser. Data was obtained inside a laboratory. The amount of heat acquired from flat plate collectors of solar energy depends primarily on their surface area that is exposed to the solar irradiance, however, the geometry of the collectors was thought that it might affect to some extent the amount of heat harvested. The circulation of the water from the panel to the geyser was due to the self-induced thermo-syphon effect. The results obtained during the test period (7 hours per day for two consecutive days) indicated that the system’s thermal efficiency was best when the square geometrical configuration collector was used. A dimensional analysis using the Π Buckingham method that was performed on the parameters affecting a flat plate solar collector yielded three dimensionless numbers that lead to a power law relationship which might be useful in enhancing solar water heating systems’ design.
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Skytt, Johanna, and Elina Järkil. "Solar heating in Colombia." Thesis, Högskolan i Halmstad, Sektionen för ekonomi och teknik (SET), 2012. http://urn.kb.se/resolve?urn=urn:nbn:se:hh:diva-18094.

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This report describes the process of a thesis implemented in Colombia concerning solar energy. The project was to install a self-circulating solar heating system, as well as creating exchange of knowledge regarding renewable energy. One of the two major goals of the project was to achieve a functioning solar heating system in Timbio, a village outside the city of Popayán in south west Colombia. The purpose was to use the free power from the sun and show people how to use it in a way that is not complicated or too expensive. The second major goal was to hold workshops about renewable energy in general, and solar energy in particular. The preparatory work started in October 2010 by concretizing the project, applying for scholarships and establishing necessary contacts; both in Colombia and Sweden. Research and correspondence continued throughout 2011, along with the search for finance from companies and funds to cover the project costs. The implementation took approximately three months and was finished in April 2012. However, the project was limited due to time scale and financial resources. The project was successful; a functioning solar heater and workshops. The aim to arise interest for renewable energy is fulfilled plus the aim to show how to use solar energy in a practical and useful way.
Denna rapport beskriver processen av ett examensarbete som behandlar solenergi, implementerat i Colombia. Projektet innebar en installation av en självcirkulerande solvärmeanläggning, och även kunskapsutbyte om förnybar energi. Ett av de två huvudmålen var att installera en fungerande solvärmeanläggning i byn Timbio utanför staden Popayán i sydvästra Colombia. Syftet var att använda gratis energi från solen och visa människor hur man kan använda energin på ett inte alltför komplicerat eller dyrt sätt. Det andra huvudmålet var att hålla workshops om förnybar energi i allmänhet och solenergi i synnerhet. Förberedelserna började i oktober 2010 genom konkretisering av projektet, stipendieansökningar och skapandet av nödvändiga kontakter; i Colombia och Sverige. Efterforskningar och korrespondens fortsatte under 2011 samtidigt som finansiering till projektet söktes från företag och fonder. Installationen tog ungefär tre månader och färdigställdes i april 2012. Projektet begränsades av tillgänglig tid och ekonomiska resurser. Projektet blev framgångsrikt; en fungerande solvärmeanläggning och lyckade workshops. Målet att väcka intresse för förnybar energi uppfylldes, även målet att visa hur solenergi kan användas på ett praktiskt och användbart sätt.
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Wang, Zhangyuan. "Investigation of a novel façade-based solar loop heat pipe water heating system." Thesis, University of Nottingham, 2012. http://eprints.nottingham.ac.uk/12343/.

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Solar thermal is one of the most cost-effective renewable energy technologies, and solar water heating is one of the most popular solar thermal systems. Based on the considerations on the existing barriers of the solar water heating, this research will propose a novel façade-based solar water heating system employing a unique loop heat pipe (LHP) structure with top-level liquid feeder, which will lead to a façade-integrated, low cost, aesthetically appealing and highly efficient solar system and has considerable potential to provide energy savings and reduce carbon emissions to the environment. The research initially involved the conceptual design of the proposed system. The prefabricated external module could convert the solar energy to heat in the form of low-temperature vapour. The vapour will be transported to indoors through the transport line and condensed within the heat exchanger by releasing the heat to the service water. The heated water will then be stored in the tank for use. An analytical model was developed to investigate six limits to the loop heat pipe’s operation, i.e., capillary, entrainment, viscous, boiling, sonic and filled liquid mass. It was found that mesh-screen wick was able to obtain a higher capillary (governing) limit than sintered-powder. Higher fluid temperature, larger pipe diameter and larger exchanger-to-pipes height difference would lead to a higher capillary limit. Adequate system configuration and operating conditions were suggested as: pipe inner diameter of 16 mm, mesh-screen wick, heat transfer fluid temperature of 60oC and height difference of 1.5 m. This research further developed a computer model to investigate the dynamic performance of the system, taking into account heat balances occurring in different parts of the system, e.g., solar absorber, heat pipes loop, heat exchanger, and tank. Data extracted from two previously published papers were used to compare with the established model of the same setups, and an agreement could be achieved under a reasonable error limit. This research further constructed a prototype system and its associated testing rig at the SRB (Sustainable Research Building) Laboratory, University of Nottingham and conducted testing through measurement of various operational parameters, i.e., heat transfer fluid temperature, tank water temperature, solar efficiency and system COP (Coefficient of Performance). Two types of glass covers, i.e., evacuated tubes and single glazing, were applied to the prototype, and each type was tested on two different days of 8 hours from 09:00:00 to 17:00:00. By comparison of the measurement data with the modelling results, reasonable model accuracy could be achieved in predicting the LHP system performance. The water temperature remained a steady growth trend throughout the day with an increase of 13.5oC for the evacuated tube system and 10.0oC for the single glazing system. The average testing efficiencies of the evacuated tube system were 48.8% and 46.7% for the two cases with the testing COPs of 14.0 and 13.4, respectively. For the single glazing system, the average testing efficiencies were 36.0% and 30.9% for the two cases with the COPs of 10.5 and 8.9, respectively. Experimental results also indicated that the evacuated tube based system was the preferred system compared to the single glazing system. This research finally analysed the annual operational performance, economic and environmental impacts of the optimised evacuated tube system under real weather conditions in Beijing, China by running an approved computer model. It was concluded that the novel system had the potential to be highly-efficient, cost-effective and environmentally-friendly through comparison with a conventional flat-plate solar water heating system.
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Yeung, King-ho, and 楊景豪. "An optimization model for a solar hybrid water heating and adsorption ice-making system." Thesis, The University of Hong Kong (Pokfulam, Hong Kong), 2003. http://hub.hku.hk/bib/B29632432.

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Ibrahim, Idowu David. "Development of Smart Parabolic Trough Solar Collector for Water Heating and Hybrid Polymeric Composite Water Storage Tank." Electronic Thesis or Diss., université Paris-Saclay, 2020. http://www.theses.fr/2020UPASG049.

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Les sources d’énergies utilisées pour le chauffage de l’eau dans les bâtiments commerciaux et résidentielles sont multiples. Ces ressources sont essentiellement électriques dans les milieux urbains et utilisent le bois dans les milieux ruraux. Le pourcentage de l’énergie solaire utilisé reste assez faible. Les méthodes les utilisées pour produire l’eau chaude sont pour basés pour l’essentielle sur l’utilisation des résistances électrique ou des capteurs solaire plat. Le travail présenté dans cette thèse est basé sur l’utilisation des concentrateurs solaires pour chauffer des collecteurs d’énergie. Le rendement est augmenté par le développement de nouveau matériaux pour le stockage.La structure pour le support du collecteur a été conçue et analysée utilisant le logiciel Solidworks®. Les forces agissant sur les éléments de la structure sont simulées pour assurer la fiabilité du support lors des différentes conditions de fonctionnement. L’analyse par la méthode des éléments finis a permis la vérification de la structure utilisée pour le réflecteur et son support.Les performances énergétiques ont été simulées pour cinq ans d’opération utilisant le logiciel Matlab Simulink®. Cette simulation a été basée sur l’utilisation de trois données différentes. La première est une base de données météorologique de cinq ans en Afrique du Sud dans la Ville de Tshwane. La deuxième est un profil d’utilisation pour un foyer type. La troisième est le coût de complément de chauffage en électricité dépendant de l’heure de l’utilisation. Cette simulation a permis la validation des choix de dimensions de différents éléments du système de chauffage.Cette étude a permis le développement d’une approche pour la conception d’un système de chauffage solaire en optimisant les dimensions des différents éléments pour un foyer type et une région spécifique.De plus, nous avons conçu un autre réservoir d’eau chaude. Nous avons démontré que l'utilisation de matériaux polymères et d'autres matériaux comme le polyuréthane, le sel et l'aluminium est possible pour le développement d'un réservoir de stockage d'eau chaude en fonction de leurs propriétés inhérentes.L'extension des résultats de cette thèse améliorera encore les conceptions des technologies de concentrateurs solaires et des systèmes de chauffage solaire de l'eau. Par conséquent, certaines recommandations et suggestions sont mises en évidence afin d'améliorer la conception, l'analyse et les performances globales du système
In recent years, various energy sources and methods have been used to heat water in domestic and commercial buildings. The known sources for water heating include electrical energy and solar radiation energy in the urban regions or burning of firewood in the rural areas. Several water heating methods may be used such as electrical heating elements, solar concentrators, flat plate collectors and evacuated tube collectors. This thesis focuses on ways to further improve the system’s performance for water heating through the combined use of solar energy and solar concentrator technique. Furthermore, the study proposed an alternative design method for the hot water storage tank.The solar collector-supporting frame was designed and analysed using Solidworks®. The forces acting on the structural members were simulated to determine the capacity of the frame to sustain the load, and the possible regions on the supporting frame, which could potentially fail while in operation.Energy performance was simulated for five years of operation using Matlab Simulink® software. This simulation was based on the use of three different data. The first is a five-year weather database of the City of Tshwane in South Africa. The second is a hot water consumption profile for a typical household. The third is the cost of additional heating with electricity depending on the time of use. This simulation allowed the validation of the choices of the different elements of the heating system.This study allowed the development of an approach for the design of a solar heating system by optimising the dimensions of the different elements for a typical household and a specific region.In addition, the use of polymeric materials and other materials like polyurethane, salt and aluminium is possible for the development of a hot water storage tank based on their inherent properties.Extending the findings in this thesis will further improve the designs for solar concentrator technologies and solar water heating systems. Therefore, some recommendations and suggestions are highlighted in order to improve the overall system design, analysis and performance
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Alwaer, Ayad Almakhzum Mohamed. "A prototype desalination system using solar energy and heat pipe technology." Thesis, Cape Peninsula University of Technology, 2016. http://hdl.handle.net/20.500.11838/2455.

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Thesis (DTech (Mechanical Engineering))--Cape Peninsula University of Technology, 2016.
The water desalination process needs large quantities of energy, either directly from fossil fuel or electricity from the national grid. However, these sources of energy significantly contribute to problems such as global warming in addition to creating a drain on the economy, due to their high cost. This dissertation is a description of the research undertaken with the aim of producing a water desalination prototype; a novel approach that was designed using state-of-the-art solar water heating equipment, incorporating the technologies of evacuated tubes and heat pipes. During the execution of the project, various modifications to the original commercially-available solar water heating system were attempted, each aimed at increasing the production of pure water. Finally, the system proved capable of producing a reasonable amount of pure water after twelve lengthy indoor experiments conducted in a laboratory in the department of Mechanical Engineering at the Cape Peninsula University of Technology, Bellville Campus, Cape Town, South Africa. Each experiment lasted five days on the basis of seven hours of exposure to an average amount of simulated solar radiation, followed by seventeen hours daily of inactivity and partial cooling down of the system.
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Sawsan, Issa. "Barriers to widespread adoption of solar water heating systems in Jordan /." [Beersheba, Israel] : Ben-Gurion University of the Negev, 2009. http://aranne5.lib.ad.bgu.ac.il/yaatz/SawsanIssa.pdf.

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Books on the topic "SOLAR WATER HEATING SYSTEM"

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Garg, H. P., ed. Solar Water Heating Systems. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-5480-9.

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Benjamin, Nusz, ed. Solar water heating: A comprehensive guide to solar water and space heating systems. Gabriola, B.C: New Society Publishers, 2010.

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Ramlow, Bob. Solar Water Heating--Revised & Expanded Edition: A Comprehensive Guide to Solar Water and Space Heating Systems. Gabriola Island: New Society Publishers, 2010.

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Canada, Canada Natural Resources, ed. Chanterelle Inn, Nova Scotia, benefits from a commercial solar water heating system. [Ottawa]: Natural Resources Canada, 2002.

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Michael, Noble, and Canada Natural Resources Canada, eds. Solar water heating systems: A buyer's guide. [Ottawa]: Natural Resources Canada, 2000.

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Solar Rating & Certification Corporation (Washington, D.C.), ed. Summary of SRCC certified solar collector and water heating system ratings. Cocoa, FL: Solar Rating & Certification Corp., 2005.

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P, Garg H., ed. Solar water heating systems: Proceedings of the Workshop on Solar Water Heating Systems, New Delhi, India, 6-10 May 1985. Dordrecht: D. Reidel Pub. Co., 1986.

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McGrath, E. Solar space heating and domestic hot water systems. Luxembourg: Commission of the European Communities, 1985.

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Dutre, W. L. Solar space heating systems and domestic hot water. Luxembourg: Commission of the European Communities, 1985.

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Sibbitt, B. E. Scald protection in solar domestic hot water systems. Ottawa: Energy, Mines and Resources Canada, 1987.

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Book chapters on the topic "SOLAR WATER HEATING SYSTEM"

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Luo, X., X. Ma, Y. F. Xu, Z. K. Feng, W. P. Du, R. Z. Wang, and M. Li. "Solar Water Heating System." In Handbook of Energy Systems in Green Buildings, 1–51. Berlin, Heidelberg: Springer Berlin Heidelberg, 2017. http://dx.doi.org/10.1007/978-3-662-49088-4_32-1.

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Luo, X., Xiaoli Ma, Y. F. Xu, Z. K. Feng, W. P. Du, Ruzhu Wang, and Ming Li. "Solar Water Heating System." In Handbook of Energy Systems in Green Buildings, 145–94. Berlin, Heidelberg: Springer Berlin Heidelberg, 2018. http://dx.doi.org/10.1007/978-3-662-49120-1_32.

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Rao, M. Ramakrishna. "Instrumentation and Controls for Solar Water Heating System." In Solar Water Heating Systems, 179–98. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-5480-9_15.

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Bansal, N. K., and Jugal Kishor. "Heat Exchanger Optimization for Hot Water Heating System." In Solar Water Heating Systems, 257–77. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-5480-9_19.

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Mani, Anna. "Solar Radiation." In Solar Water Heating Systems, 15–35. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-5480-9_3.

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Rao, K. S. "Solar Water Heating System in a Textile Industry — a Case Study." In Solar Water Heating Systems, 347–60. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-5480-9_25.

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Tiwari, G. N., Arvind Tiwari, and Shyam. "Solar Water-Heating Systems." In Energy Systems in Electrical Engineering, 327–68. Singapore: Springer Singapore, 2016. http://dx.doi.org/10.1007/978-981-10-0807-8_8.

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Sukhatme, S. P. "Hot Water Storage Systems." In Solar Water Heating Systems, 113–23. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-5480-9_8.

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Sharma, A. K., and M. S. Sodha. "Testing of Solar Collectors." In Solar Water Heating Systems, 383–97. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-5480-9_28.

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Mathur, S. S., and N. K. Bansal. "Domestic Thermosyphon Water Heating Systems." In Solar Water Heating Systems, 299–326. Dordrecht: Springer Netherlands, 1986. http://dx.doi.org/10.1007/978-94-009-5480-9_22.

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Conference papers on the topic "SOLAR WATER HEATING SYSTEM"

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Raveendran, S. K., and C. Q. Shen. "Implementing slab solar water heating system." In ADVANCED MATERIALS AND RADIATION PHYSICS (AMRP-2015): 4th National Conference on Advanced Materials and Radiation Physics. AIP Publishing LLC, 2015. http://dx.doi.org/10.1063/1.4928830.

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Murthy, M. S., Y. S. Patil, D. Ambekar, T. Patil, G. Sonawane, R. Chaudhari, G. Patil, et al. "Concrete slab solar water heating system." In 2011 IEEE Conference on Clean Energy and Technology (CET). IEEE, 2011. http://dx.doi.org/10.1109/cet.2011.6041486.

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Pereira, Elizabeth, Emerson Salvador, Rafael David, Alexandre Andrade, Jane Fantinelli, M. Guimaraes, Luciana Carvalho, et al. "Brazilian Solar Water Heating Systems Evaluation." In ISES Solar World Congress 2011. Freiburg, Germany: International Solar Energy Society, 2011. http://dx.doi.org/10.18086/swc.2011.22.17.

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Wilson, Eric J. H., and John J. Burkhardt. "Cost-Effectiveness of a Photovoltaic-Powered Heat Pump Water Heating System vs. Solar Thermal Water Heating." In ASME 2009 3rd International Conference on Energy Sustainability collocated with the Heat Transfer and InterPACK09 Conferences. ASMEDC, 2009. http://dx.doi.org/10.1115/es2009-90238.

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Abstract:
The cost-effectiveness of a photovoltaic (PV) powered heat pump water heater (HPWH) system is compared to that of a traditional solar thermal water heating system. HPWH evaporators are most often located inside the conditioned building space, resulting in a year-round cooling effect in the building. This effect is beneficial during the cooling season but detrimental during the heating season. The significance of this cooling effect was evaluated as part of the life cycle cost (LCC) analysis of the PV-powered HPWH system. Four different locations were considered: Boulder, CO; Miami, FL; Chicago, IL; and Seattle, WA. For the solar thermal analysis, both electric resistance and gas-fired auxiliary water heating scenarios were considered. Life cycle costs for the PV-HPWH system were calculated for the case of a PV system dedicated to providing electricity for the HPWH, and for the case of a previously planned residential PV system being increased in size to accommodate the HPWH. This latter case uses a lower, incremental cost of increasing the size of the PV system. The most notable results of the analysis are summarized below: • In general, the solar thermal system is more cost effective than the PV-HPWH system, even using the incremental cost of increasing the size of a planned PV system. • In locations where there are incentives that apply to PV but not solar thermal systems, as in much of Colorado, the PV-HPWH system will be more cost-effective than solar thermal. • The cooling effect of the HPWH evaporator is a net benefit in Miami, FL, but a net penalty in the other three locations. • The PV-HPWH system becomes more cost-effective than solar thermal with gas auxiliary in Miami when the price of natural gas is increased from $1 to $1.50 per therm. • Increasing the price of gas in the other locations does not make the PV-HPWH system compete against solar thermal because the cooling effect penalty also increases with the price of natural gas.
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Slesarenko, I. "Complex Modeling of Solar Water Heating Systems." In ISES Solar World Congress 2015. Freiburg, Germany: International Solar Energy Society, 2016. http://dx.doi.org/10.18086/swc.2015.10.26.

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Lipnitski, L., A. Khamitsevich, and A. Butko. "HEATING WATER IN A HOT WATER SYSTEM USING SOLAR COLLECTORS." In SAKHAROV READINGS 2020:ENVIRONMENTAL PROBLEMS OF THE XXI CENTURY. Minsk, ICC of Minfin, 2020. http://dx.doi.org/10.46646/sakh-2020-2-406-409.

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Denis Alexandre de Rubim Costa Negócio, Luiz Guilherme Meira de Souza, Arthur Kleyton Azevedo de Araújo, Pedro Henrique Xavier de Mesquita, Luiz Paulo de Oliveira Queiroz, Israel Loiola Rêgo, Francisca Moreira da Silva, and Luiz Guilherme Vieira Meira de Souza. "SOLAR WATER HEATING SYSTEM USING MIXED ABSORBING GRID." In 23rd ABCM International Congress of Mechanical Engineering. Rio de Janeiro, Brazil: ABCM Brazilian Society of Mechanical Sciences and Engineering, 2015. http://dx.doi.org/10.20906/cps/cob-2015-1486.

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Bani-Hani, Ehab Hussein, Mamdouh El Haj Assad, Maryam Nooman AlMallahi, and Mohammed AlShabi. "Experimental Study On Solar Hot Water Heating System." In 2022 Advances in Science and Engineering Technology International Conferences (ASET). IEEE, 2022. http://dx.doi.org/10.1109/aset53988.2022.9735075.

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Sarbu, Ioan. "SOLAR WATER AND SPACE-HEATING SYSTEMS." In 18th International Multidisciplinary Scientific GeoConference SGEM2018. Stef92 Technology, 2018. http://dx.doi.org/10.5593/sgem2018/4.1/s17.082.

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Slesarenko, Viacheslav, Galina Bogdanovich, and Ilya Slesarenko. "Solar Water Heating Systems: The Analysis of Schemes." In ISES Solar World Congress 2011. Freiburg, Germany: International Solar Energy Society, 2011. http://dx.doi.org/10.18086/swc.2011.26.16.

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Reports on the topic "SOLAR WATER HEATING SYSTEM"

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Davidson, J., and W. Liu. Comparison of natural convection heat exchangers for solar water heating systems. Office of Scientific and Technical Information (OSTI), September 1998. http://dx.doi.org/10.2172/676960.

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Amorim, Ricardo. IEA-SHC Task 39 INFO Sheet B17 - UNISOL – universal solar system for pre-heating water. IEA Solar Heating and Cooling Programme, May 2015. http://dx.doi.org/10.18777/ieashc-task39-2015-0034.

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Zinian, HE. Test methods for close-coupled solar water heating systems - Reliability and safety. IEA SHC Task 57, September 2018. http://dx.doi.org/10.18777/ieashc-task57-2018-0004.

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Bin, Shen. Test methods for mechanical load on support of close-coupled solar water heating systems. IEA SHC Task 57, September 2018. http://dx.doi.org/10.18777/ieashc-task57-2018-0007.

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Hansen, Tim, Eric Ringler, and William Chatterton. Demonstration of a Solar Thermal Combined Heating, Cooling and Hot Water System Utilizing an Adsorption Chiller for DoD Installations. Fort Belvoir, VA: Defense Technical Information Center, December 2013. http://dx.doi.org/10.21236/ada608953.

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Smith, T. R. In-situ parameter estimation for solar domestic hot water heating systems components. Final report, June 1995--May 1996. Office of Scientific and Technical Information (OSTI), March 1997. http://dx.doi.org/10.2172/631225.

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Davidson, J. H. Natural convection heat exchangers for solar water heating systems. Techniacl progress report, June 1, 1995--July 31, 1995. Office of Scientific and Technical Information (OSTI), June 1998. http://dx.doi.org/10.2172/621845.

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Davidson, J. H. Natural convection heat exchangers for solar water heating systems. Technical progress report, August 1, 1995--September 30, 1995. Office of Scientific and Technical Information (OSTI), June 1998. http://dx.doi.org/10.2172/621846.

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Davidson, J. H. Natural convection heat exchangers for solar water heating systems. Technical progress report, December 31, 1995--January 31, 1996. Office of Scientific and Technical Information (OSTI), June 1998. http://dx.doi.org/10.2172/621847.

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Davidson, J. H. Natural convection heat exchangers for solar water heating systems. Technical progress report, September 15, 1996--November 14, 1996. Office of Scientific and Technical Information (OSTI), June 1998. http://dx.doi.org/10.2172/621848.

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