Готові списки джерел за темами / Solar thermal power generation

Добірка наукової літератури з теми "Solar thermal power generation"

Автор: Grafiati
Опубліковано: 6 вересня 2023

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Статті в журналах з теми "Solar thermal power generation"

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Verma, Rahul, and Dr Deepika Chauhan. "Solar and Thermal Power Generation." International Journal of Trend in Scientific Research and Development Volume-2, Issue-3 (April 30, 2018): 1071–74. http://dx.doi.org/10.31142/ijtsrd11190.

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2

Karni, Jacob. "SOLAR-THERMAL POWER GENERATION." Annual Review of Heat Transfer 15, no. 15 (2012): 37–92. http://dx.doi.org/10.1615/annualrevheattransfer.2012004925.

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3

Sukhatme, S. P. "Solar thermal power generation." Journal of Chemical Sciences 109, no. 6 (December 1997): 521–31. http://dx.doi.org/10.1007/bf02869211.

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4

Hu, Eric, YongPing Yang, Akira Nishimura, Ferdi Yilmaz, and Abbas Kouzani. "Solar thermal aided power generation." Applied Energy 87, no. 9 (September 2010): 2881–85. http://dx.doi.org/10.1016/j.apenergy.2009.10.025.

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5

Wang, Xi Bo, Ya Lin Lei, and Min Yao. "China's Thermal Power Generation Forecasting Based on Generalized Weng Model." Advanced Materials Research 960-961 (June 2014): 503–9. http://dx.doi.org/10.4028/www.scientific.net/amr.960-961.503.

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Since the 21st century, China's power industry has been developing very quickly, and the generated electrical energy has been growing rapidly. Although nuclear power, wind power, solar power generations have been increased, thermal power generation still accounts for more than 80% of the total generating capacity. Thermal power provides an important material basis for the development of the national economy. Therefore, the prediction research on China's thermal power generation trend is becoming a topic of great interest. The fuel of thermal power generation-coal, is an exhaustible resource. Due to the exhaustible constraints the fuel, thermal power generation trend is bound to show a similar trend bell curve as the coal production trend, similar to a bell-shaped curve—a gradual increase to maximum output and then a short peak and a gradual decline. To get more accurate results of future thermal power generation, this paper applies the generalized Weng model to forecast China's thermal power generation peak and trend. The result indicted that the peak of China's thermal power generation appears in 2022 with generating capacity of 51,702 TWh. The generating capacity of thermal power will decrease gradually after 2022. Based on the results, the paper proposes some policy recommendations for the sustainable development of China's electrical energy. China should decrease the percentage of the capacity which comes from thermal generation and reduce the dependence on thermal power generation. Moreover, nuclear, hydraulic, wind and solar power should be developed before the thermal power generation peak.
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6

Liu, Yudong, Fangqin Li, Jianxing Ren, Guizhou Ren, Honghong Shen, and Gang Liu. "Solar thermal power generation technology research." E3S Web of Conferences 136 (2019): 02016. http://dx.doi.org/10.1051/e3sconf/201913602016.

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China is a big consumer of energy resources. With the gradual decrease of non-renewable resources such as oil and coal, it is very important to adopt renewable energy for economic development. As a kind of abundant renewable energy, solar power has been widely used. This paper introduces the development status of solar power generation technology, mainly introduces solar photovoltaic power generation technology, briefly describes the principle of solar photovoltaic power generation, and compares and analyzes four kinds of solar photovoltaic power generation technology, among which photovoltaic power generation technology is the most mature solar photovoltaic power utilization technology at present.
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7

Daryabi, Shaik, and Pentakota Sai Sampth. "250KW Solar Power with MPPT Hybrid Power Generation Station." International Journal for Research in Applied Science and Engineering Technology 10, no. 12 (December 31, 2022): 346–53. http://dx.doi.org/10.22214/ijraset.2022.47864.

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Abstract: Energy comes in different forms. Light is a form of energy. So is heat. So is electricity. Often, one form of energy can be turned into another. This fact is very important because it explains how we get electricity, which we use in so many ways. Electricity is used to light streets and buildings, to run computers and TVs, and to run many other machines and appliances at home, at school, and at work. One way to get electricity is to This method for making electricity is popular. But it has some problems. Our planet has only a limited supply of oil and coal .In this method details about Endless Energy, Solar Cells Galore, Energy from Sun shine , Understanding Electricity. Solar Thermal power plant use the Sun as a heat source. In order to generate a high enough temperature for a power plant, solar energy must be concentrated. In a solar thermal power plant this in normally achieved with mirrors. Estimation for global solar thermal potential indicates that it could more than provide for total global electricity needs. There are three primary solar thermal technologies based on three ways no of concentrating solar energy: solar parabolic through plants, solar tower power plants, and solar dish power plants. The mirrors used in these plants are normally constructed from glass, a although, other techniques are being explored. Power plant of these types use solar heat to heat a thermodynamics fluid such as water in order to drive a thermodynamic engine; for water this will be a stream turbine. Solar thermal power plants can have heat storage systems that allow them to generate electricity beyond daylight hours.
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Wang, Zhihang, Zhenhua Wu, Zhiyu Hu, Jessica Orrego-Hernández, Erzhen Mu, Zhao-Yang Zhang, Martyn Jevric, et al. "Chip-scale solar thermal electrical power generation." Cell Reports Physical Science 3, no. 3 (March 2022): 100789. http://dx.doi.org/10.1016/j.xcrp.2022.100789.

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Hou, Hong Juan, Jian Mao, Chuan Wen Zhou, and Min Xing Zhang. "Solar-Coal Hybrid Thermal Power Generation in China." Advanced Materials Research 347-353 (October 2011): 1117–26. http://dx.doi.org/10.4028/www.scientific.net/amr.347-353.1117.

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Анотація:
Coal is presently the largest source of electricity in China, with the increasing demand for electricity, the problems of environment pollution become more and more severe. In order to solve the problems, all options for power generation by new and renewable energies are enjoying growing attention in recent years. China has abundant solar energy resources and large wasteland areas, which makes China an ideal country for solar thermal power generation development. However, its present higher costs for China made it difficult to promote large-scale. Under this condition solar hybrid with coal thermal power generation becomes the best solution of the problem. In this paper, the feasibility of solar hybrid with coal thermal power generation in China was analyzed from the aspects of environment, policy, investment risk and economics.
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Fu, Qiang, Chengxi Fu, Peng Fu, and Yuke Deng. "Application of Green Power Generation Technology for Distributed Energy." E3S Web of Conferences 329 (2021): 01021. http://dx.doi.org/10.1051/e3sconf/202132901021.

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This article discusses and analyzes the technical strengths and weaknesses of the green power generation that can be used for distributed system (power generation) power generation, for instance, solar power generation, wind power, hydrogen fuel cells, biomass power generation, and small gas turbines. The key to the discussion is to apply the technical distributed power generation of solar power stations. In addition, it also discussed the use of "focusing solar power generation high-temperature solar thermal power conversion system software" technical completion of distributed system power distribution. Low-cost, high-temperature solar thermal power generation is selected as the power generation solution medium, the power generation is technically low consumption and high-efficiency, the volume and power generation methods are conveniently equipped, the stability is high, and the economic development is environmentally friendly.
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Дисертації з теми "Solar thermal power generation"

1

Omer, Siddig Adam. "Solar thermoelectric system for small scale power generation." Thesis, Loughborough University, 1997. https://dspace.lboro.ac.uk/2134/7440.

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This thesis is concerned with the design and evaluation of a small scale solarthermoelectric power generation system. The system is intended for electricity generation and thermal energy supply to small scale applications in developing countries of the sunny equatorial regions. Detailed design methodologies and evaluations of both the thermoelectric device and the solar energy collector, which are parts of the combined system, are presented. In addition to experimental evaluations, three theoretical models are presented which allow the design and evaluation of both the thermoelectric module and the solar energy collector. One of the models (a unified thermoelectric device model) concerns the geometrical optimization and performance prediction of a thermoelectric module in power generation mode. The model is unified in the sense that it accounts for the effect of all the parameters that contribute to the performance of the thermoelectric module, a number of which are ignored by the available design models. The unified model is used for a comparative evaluation of five thermoelectric modules. One of these is commercially available and the others are assumed to have optimum geometry but with different design parameters (thermal and electrical contact layer properties). The model has been validated using data from an experimental investigation undertaken to evaluate the commercial thermoelectric module in power generation mode. Results showed that though the commercially available thermoelectric cooling devices can be used for electricity generation, it is appropriate to have modules optimized specifically for power generation, and to improve the contact layers of thermoelement accordingly. Attempts have also been made to produce and evaluate thermoelectric materials using a simple melt-qucnching technique which produces materials with properties similar to those of the more expensive crystalline materials.
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2

Sharma, Chandan. "Techno-economics of solar thermal power generation in india." Thesis, IIT Delhi, 2016. http://localhost:8080/xmlui/handle/12345678/6985.

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3

Kamanzi, Janvier. "Thermal electric solar power conversion panel development." Thesis, Cape Peninsula University of Technology, 2017. http://hdl.handle.net/20.500.11838/2527.

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Thesis (DTech (Engineering))--Cape Peninsula University of Technology, 2017.
The world has been experiencing energy-related problems following pressuring energy demands which go along with the global economy growth. These problems can be phrased in three paradoxical statements: Firstly, in spite of a massive and costless solar energy, global unprecedented energy crisis has prevailed, resulting in skyrocketing costs. Secondly, though the sun releases a clean energy, yet conventional plants are mainly being run on unclean energy sources despite their part in the climate changes and global warming. Thirdly, while a negligible percentage of the solar energy is used for power generation purposes, it is not optimally exploited since more than its half is wasted in the form of heat which contributes to lowering efficiency of solar cells and causes their premature degradation and anticipated ageing. The research is geared at addressing the issue related to unsatisfactory efficiencies and anticipated ageing of solar modules. The methodology adopted to achieve the research aim consisted of a literature survey which in turn inspired the devising of a high-efficiency novel thermal electric solar power panel. Through an in-depth overview, the literature survey outlined the rationale of the research interest, factors affecting the performance of PVs as well as existing strategies towards addressing spotted shortcomings. While photovoltaic (PV) panels could be identified as the most reliable platform for sunlight-to-electricity conversion, they exhibit a shortcoming in terms of following the sun so as to maximize exposure to sunlight which negatively affects PVs’ efficiencies in one hand. On the other hand, the inability of solar cells to reflect the unusable heat energy present in the sunlight poses as a lifespan threat. Strategies and techniques in place to track the sun and keep PVs in nominal operational temperatures were therefore reviewed.
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4

Pierce, Warrick Tait. "Solar assisted power generation (SAPG) : investigation of solar preheating of feedwater." Thesis, Stellenbosch : Stellenbosch University, 2013. http://hdl.handle.net/10019.1/80139.

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Thesis (MEng)--Stellenbosch University, 2013.
ENGLISH ABSTRACT: Solar Assisted Power Generation (SAPG) can be seen as a synergy of solar and fossil plants – combining the environmental benefits of the former and the scale, efficiency and reliability of the latter. SAPG offers great potential for cost effective utilization of solar energy on utility scale and could accelerate the adoption of solar thermal energy technologies in the short and medium term, especially in countries with a significant coal base and a good solar resource such as Australia, China, United States, India and South Africa. SAPG is the replacement of bled-off steam in a Regenerative Rankine power cycle. Power plant simulations were performed using weather data for Lephalale, South Africa (Matimba power station). With an increase in the solar field outlet temperature, an increase in overall solar to electric efficiency was observed, superior to a stand-alone Solar Thermal Power Plant(s) (STPP) at similar temperatures. The performance of four solar collector technologies was compared: flat plate, evacuated tube, Linear Fresnel (LF) and Parabolic Trough (PT). This comparison was limited to the normal incidence angles of irradiation. For this application, nonconcentrating technologies are not competitive. For non-normal incidence angles, annual simulations were limited to PT and LF at final feedwater heater temperatures. The actual aperture area of around 80 000 m2 was used (50 MW thermal based on LF). On an equal aperture area basis, PT outperforms LF significantly. For the conventional North-South arrangement, LF needs to be around 53% of the specific installation cost (in $/m2 aperture area) of PT to be cost competitive. A SAPG plant at Lephalale was compared to a stand-alone Solar Thermal Power Plant STPP in a good solar resource area, namely Upington, South Africa – Parabolic Trough solar collector fields of equal size were considered for both configurations. It was found that the annual electricity generated with a SAPG plant is more than 25% greater than a stand-alone STPP. If the cost of SAPG is taken as 72% of the cost of a stand-alone STPP, this translates into SAPG being 1.8 times more cost effective than stand-alone STPP. Furthermore, SAPG performs better in high electricity demand months (South African winter – May to August). Stand-alone STPP have been adopted in South Africa and are currently being built. This was achieved by the government creating an attractive environment for Independent Power Producers (IPP). Eskom, the national power supplier, is currently investigating solar boosting at existing Eskom sites. This report argues that on a national level, SAPG, specifically solar preheating of feedwater, is a more viable solution for South Africa, with both its significant coal base and good solar resource.
AFRIKAANSE OPSOMMING: Son ondersteunde krag generasie (SOKG) kan gesien word as sinergie van sonkrag en fossiele brandstof aanlegte – dit voeg die omgewings voordele van die eersgenoemde en die grote, effektiwiteit en betroubaarheid van die laasgenoemde by mekaar. SOKG opper groot potensiaal vir koste effektiewe gebruik van son energie op nutsmaatskappyskaal en kan die aanvaarding van sontermiese energietegnologieë in die kort en medium termyn versnel, veral in lande met beduidende kool reserwes en goeie sonkrag voorkoms soos Australië, China, Verenigde State van Amerika, Indië en Suid-Afrika. SOKG impliseer die vervanging van aftap stoom in die regeneratiewe Rankine krag kringloop. Kragstasie simulasies was gedoen met die gebruik van weer data van Lephalale, Suid-Afrika (Matimba kragstasie). Met die toename van die sonveld uitlaat temperatuur kon oorhoofse son-na-elektrisiteit effektiwiteit vasgestel word, wat hoër is as die van alleenstaande sontermiese krag stasie (STKS) by soortgelyke temperature. Die effektiwiteit van vier son kollekteerder tegnologieë was vergelyk: plat plaat, vakuum buis, lineêre Fresnel (LF) en paraboliese trog (PT). Die vergelyking was beperk tot normale inval van bestraling. Vir hierdie toepassing is nie-konsentreerende tegnologie nie mededingend nie. Vir nie-normale inval hoeke was jaarlange simulasies beperk tot PT en LF by finale voedingswater temperatuur. Die werklike opening area van omtrent 80 000 m2 was gebruik (50 MW termies gebaseer op LF). By gelyke opening area, uitpresteer PT LF beduidend. Vir die gebruiklike Noord-Suid rankskikking benodig LF omtrent 53% van die spesifieke installasie kostes (in $/m2 opening area) van PT om kostes mededingend te kan wees. ‘n SOKG aanleg by Lephalale was vergelyk met alleenstaande STKS in die goeie son voorkoms gebied van Upington, Suid-Afrika – Paraboliese trog kollekteerder velde van gelyke grote was oorweeg vir al twee konfigurasies. Dit was gevind dat die jaarlikse elektrisiteit gegenereer vanaf SOKG meer as 25% is as die van alleenstaande STKS. Indien SOKG oorweeg word met 72% van die kostes van alleenstaande STKS, dan beteken dit dat SOKG 1.8 keer meer koste effektief is as alleenstade STKS. Verder, SOKG presteer beter in die hoer elektrisiteitsnavraag maande (Suid- Afrikaanse winter – May tot Augustus). Alleenstaande STKS is gekies vir Suid-Afrika en word tans gebou. Dit is bereik deur dat die regering ‘n aantreklike omgewing geskep het vir onafhanglike krag produsente. Eskom ondersoek tans SOKG by bestaande Eskom persele. Hierdie verslag beweer dat op nasionale/Eskom vlak, SOKG, besonders son voorverhitting van voedingswater, meer haalbare oplossing is vir Suid-Afrika met sy beduidende koolreserwes en goeie son voorkoms.
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5

Desai, Ranjit. "Thermo-Economic Analysis of a Solar Thermal Power Plant with a Central Tower Receiver for Direct Steam Generation." Thesis, KTH, Kraft- och värmeteknologi, 2013. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-131764.

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6

Sun, Amy (Amy Teh-Yu). "Field fabrication of solar-thermal powered stream turbines for generation of mechanical power." Thesis, Massachusetts Institute of Technology, 2006. http://hdl.handle.net/1721.1/37400.

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Анотація:
Thesis (S.M.)--Massachusetts Institute of Technology, School of Architecture and Planning, Program in Media Arts and Sciences, 2006.
Includes bibliographical references (p. 65).
Providing adequate energy to developing countries is one of the greatest global technical challenges today. Fabrication is undergoing a revolution that parallels the digitization of computation and communications. Emerging affordable, "desktop" fabrication tools are providing the precision and repeatability necessary for regular people to design, manufacture, and install a system to convert solar thermal energy to useful work. In the spectrum of devices that use solar energy, this field-fabricated system exists in a space between crude solar cookers for heating food and complex, expensive photovoltaic cells. Computer control and high precision allows regular people to experimentally converge on a locally-appropriate design and implementation to solve the challenge of providing energy. This thesis describes a field producible, small-scale turbine that uses solar thermal energy to provide mechanical energy. I investigate a solar thermal steam-driven turbine system and build and evaluate several versions in field fabrication lab locations around the world. I consider the efficacy of deployment in rural developing areas.
by Amy Sun.
S.M.
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7

Assembe, Cedric Obiang. "Integrated solar photovoltaic and thermal system for enhanced energy efficiency." Thesis, Cape Peninsula University of Technology, 2016. http://hdl.handle.net/20.500.11838/2387.

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Thesis (MTech (Mechanical Engineering))--Cape Peninsula University of Technology, 2016.
South Africa has raised concerns regarding the development of renewable energy sources such as wind, hydro and solar energy. Integration of a combined photovoltaic and thermal system was considered to transform simultaneous energy into electricity and heat. This was done to challenge the low energy efficiency observed when the two solar energy conversion technologies are employed separately, in order to gain higher overall energy efficiency and ensure better utilization of the solar energy. Therefore, the notion of using a combined photovoltaic and thermal system was to optimize and to improve the overall PV panel efficiency by adding conversion to thermal energy for residential and commercial needs of hot water or space heating or space cooling using appropriate technology. The PV/T model constructed using water as fluid like the one used for the experimental work, presented a marginal increase in electrical efficiency but a considerable yield on the overall PV/T efficiency, because of the simultaneous operation by coupling a PV module with a thermal collectors.
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8

Muhammad, Mubarak Danladi. "Development of a cascaded latent heat storage system for parabolic trough solar thermal power generation." Thesis, Cranfield University, 2014. http://dspace.lib.cranfield.ac.uk/handle/1826/9303.

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Concentrated solar power (CSP) has the potential of fulfilling the world’s electricity needs. Parabolic-trough system using synthetic oil as the HTF with operating temperature between 300 and 400o C, is the most matured CSP technology. A thermal storage system is required for the stable and cost effective operation of CSP plants. The current storage technology is the indirect two-tank system which is expensive and has high energy consumption due to the need to prevent the storage material from freezing. Latent heat storage (LHS) systems offer higher storage density translating into smaller storage size and higher performance but suitable phase change materials (PCMs) have low thermal conductivity, thus hindering the realization of their potential. The low thermal conductivity can be solved by heat transfer enhancement in the PCM. There is also lack of suitable commercially-available PCMs to cover the operating temperature range. In this study, a hybrid cascaded storage system (HCSS) consisting of a cascaded finned LHS and a high temperature sensible or concrete tube register (CTR) stages was proposed and analysed via modelling and simulation. Fluent CFD code and the Dymola simulation environment were employed. A validated CFD phase change model was used in determining the heat transfer characteristics during charging and discharging of a finned and unfinned LHS shell-and-tube storage element. The effects of various fin configurations were investigated and heat transfer coefficients that can be used for predicting the performance of the system were obtained. A model of the HCSS was then developed in the Dymola simulation environment. Simulations were conducted considering the required boundary conditions of the system to develop the best design of a system having a capacity of 875 MWhth, equivalent to 6 hours of full load operation of a 50 MWe power plant. The cascaded finned LHS section provided ~46% of the entire HCSS capacity. The HCSS and cascaded finned LHS section have volumetric specific capacities 9.3% and 54% greater than that of the two-tank system, respectively. It has been estimated that the capital cost of the system is ~12% greater than that of the two-tank system. Considering that the passive HCSS has lower operational and maintenance costs it will be more cost effective than the twotank system considering the life cycle of the system. There is no requirement of keeping the storage material above its melting temperature always. The HCSS has also the potential of even lower capital cost at higher capacities (>6 hours of full load operation).
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9

Kumbasar, Serdar. "Techno-Economic Assessment of Solar PV/Thermal System for Power and Cooling Generation in Antalya, Turkey." Thesis, KTH, Tillämpad termodynamik och kylteknik, 2013. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-119608.

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In this study a roof-top PVT/absorption chiller system is modeled for a hotel building in Antalya, Turkey to cover the cooling demand of the hotel, to produce electricity and domestic hot water. PVT modules, an absorption chiller, a hot storage tank and a natural gas fired auxiliary heater are the main components of the system. Elecetrical power produced by the system is 94.2 MWh, the cooling power is 185.5 MWh and the amount of domestic hot water produced in the system is 65135 m3 at 45 0C annually.  Even though the systems is capable of meeting the demands of the hotel building, because of the high investment costs of PVT modules and high interest rates in Turkey, it is not economically favorable. Using cheaper solar collectors, integrating a cold storage unit in the system or having an improved conrol strategy are the options to increase the system efficiency and to make the system economically competitive.
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10

Howard, Dustin F. "Modeling, simulation, and analysis of grid connected dish-stirling solar power plants." Thesis, Georgia Institute of Technology, 2010. http://hdl.handle.net/1853/34832.

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The percentage of renewable energy within the global electric power generation portfolio is expected to increase rapidly over the next few decades due to increasing concerns about climate change, fossil fuel costs, and energy security. Solar thermal energy, also known as concentrating solar power (CSP), is emerging as an important solution to new demands for clean, renewable electricity generation. Dish-Stirling (DS) technology, a form of CSP, is a relatively new player in the renewable energy market, although research in the technology has been ongoing now for nearly thirty years. The first large plant utilizing DS technology, rated at 1.5 MW, came online in January 2010 in Peoria, AZ, and plants rated for several hundred MW are in the planning stages. Increasing capacity of this technology within the utility grid requires extensive dynamic simulation studies to ensure that the power system maintains its safety and reliability in spite of the technological challenges that DS technology presents, particularly related to the intermittency of the energy source and its use of a non-conventional asynchronous generator. The research presented in this thesis attempts to fill in the gaps between the well established research on Stirling engines in the world of thermodynamics and the use of DS systems in electric power system applications, a topic which has received scant attention in publications since the emergence of this technology. DS technology uses a paraboloidal shaped dish of mirrors to concentrate sunlight to a single point. The high temperatures achieved at the focal point of the mirrors is used as a heat source for the Stirling engine, which is a closed-cycle, external heat engine. Invented by the Scottish clergyman Robert Stirling in 1816, the Stirling engine is capable of high efficiency and releases no emissions, making it highly compatible with concentrated solar energy. The Stirling engine turns a squirrel-cage induction generator, where electricity is delivered through underground cables from thousands of independent, autonomous 10-25 kW rated DS units in a large solar farm. A dynamic model of the DS system is presented in this thesis, including models of the Stirling engine working gas and mechanical dynamics. Custom FORTRAN code is written to model the Stirling engine dynamics within PSCAD/EMTDC. The Stirling engine and various other components of the DS system are incorporated into an electrical network, including first a single-machine, infinite bus network, and then a larger 12-bus network including conventional generators, loads, and transmission lines. An analysis of the DS control systems is presented, and simulation results are provided to demonstrate the system's steady state and dynamic behavior within these electric power networks. Potential grid interconnection requirements are discussed, including issues with power factor correction and low voltage ride-through, and simulation results are provided to illustrate the dish-Stirling system's capability for meeting such requirements.
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Книги з теми "Solar thermal power generation"

1

M, Becker, Klimas Paul C, Chavez James M, Kolb Gregory J, Meinecke W, Deutsche Forschungsanstalt für Luft- und Raumfahrt., and Sandia National Laboratories, eds. Second generation central receiver technologies: A status report. Karlsruhe: C.F. Müller, 1993.

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2

Co, Business Communications, ed. Solar thermal and photovoltaics: World growth markets. Norwalk, CT: Business Communications Co., 1991.

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3

Robert, Moran. Solar thermal and photovoltaics: World growth markets. Norwalk, CT: Business Communications Co., 1996.

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4

S, Mehos Mark, and National Renewable Energy Laboratory (U.S.), eds. Enabling greater penetration of solar power via the use of CSP with thermal energy storage. Golden, CO: National Renewable Energy Laboratory, 2011.

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5

Li, Jing. Structural Optimization and Experimental Investigation of the Organic Rankine Cycle for Solar Thermal Power Generation. Berlin, Heidelberg: Springer Berlin Heidelberg, 2015. http://dx.doi.org/10.1007/978-3-662-45623-1.

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6

Perez-Davis, Marla E. Sensible heat receiver for solar dynamic space power system. [Washington, DC]: National Aeronautics and Space Administration, 1991.

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7

Feuermann, D. Analysis and evaluation of the Paz solar thermal system at the Ben-Gurion Sede Boqer Test Center for Solar Electricity Generating Technologies. [Jerusalem?]: State of Israel, Ministry of Energy & Infrastructure, Division of Research & Development, 1990.

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8

Krauter, Stefan C. W. Solar electric power generation - photovoltaic energy systems: Modeling of optical and thermal performance, electrical yield, energy balance, effect on reduction of greenhouse gas emissions. Berlin: Springer, 2006.

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9

Functional materials for sustainable energy applications. Oxford: Woodhead Pub., 2012.

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10

Forum on New Materials (5th 2010 Montecatini Terme, Italy). New materials II: Thermal-to-electrical energy conversion, photovoltaic solar energy conversion and concentrating solar technologies : proceedings of the 5th Forum on New Materials, part of CIMTEC 2010, 12th International Ceramics Congress and 5th Forum on New Materials, Montecatini Terme, Italy, June 13-18, 2010. Stafa-Zurich, Switzerland: Trans Tech Publications, 2011.

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Частини книг з теми "Solar thermal power generation"

1

Awasthi, Rajeev, Shubham Jain, Ram Kumar Pal, and K. Ravi Kumar. "Solar Thermal Power Generation." In Energy Systems in Electrical Engineering, 35–77. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-33-6456-1_3.

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2

Shah, Yatish T. "Advanced Solar Thermal Power Systems." In Advanced Power Generation Systems, 169–244. Boca Raton: CRC Press, 2022. http://dx.doi.org/10.1201/9781003328087-5.

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3

Blazev, Anco S. "Solar Thermal Technologies." In Photovoltaics for Commercial and Utilities Power Generation, 15–26. New York: River Publishers, 2020. http://dx.doi.org/10.1201/9781003151630-2.

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4

Pfund, Philip A., and John F. Hoosic. "Electric Power Generation Study for the Dominican Republic." In Solar Thermal Central Receiver Systems, 199–208. Berlin, Heidelberg: Springer Berlin Heidelberg, 1986. http://dx.doi.org/10.1007/978-3-642-82910-9_13.

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Norton, Brian. "Solar Thermal Power Generation and Industrial Process Heat." In Lecture Notes in Energy, 123–43. Dordrecht: Springer Netherlands, 2013. http://dx.doi.org/10.1007/978-94-007-7275-5_7.

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6

Hafner, Manfred, and Giacomo Luciani. "Economics of Power Generation." In The Palgrave Handbook of International Energy Economics, 103–9. Cham: Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-030-86884-0_5.

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AbstractThis chapter provides an introduction to the economics of electricity generation, presenting the major economic differences between the multiple power generation solutions and highlighting the comparative advantages and disadvantages of each. In order to provide a satisfactory treatment of power generation technology and economics, a single chapter would have expanded beyond a practical dimension: accordingly the discussion has been divided into a general introduction and a sequence of specific chapters each devoted to a different generation solution: thermal power based on fossil fuels (coal, oil, and gas), thermal power based on nuclear fission, hydroelectricity chapter, solar power, wind power, geothermal power, and power from tides and waves. The present introductory chapter explains where on the load curve the different power generation options should be placed depending on costs, the issue of dispatchability, as well as the difference in the economic cost approach between dispatching and future capacity planning. Also flexibility mechanisms to integrate a large share of non-dispatchable renewable energy sources are discussed. Finally, issues related to space occupation and locational constraints are addressed.
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7

Dirks, J. A. "Central Receiver Costs for Electric Power Generation." In Thermo-Mechanical Solar Power Plants, 307–11. Dordrecht: Springer Netherlands, 1985. http://dx.doi.org/10.1007/978-94-009-5402-1_45.

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8

McColl, Stuart J., Peter Rodgers, and Valerie Eveloy. "Thermal Management of Solar Photovoltaics Modules for Enhanced Power Generation." In ICREGA’14 - Renewable Energy: Generation and Applications, 479–90. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-05708-8_38.

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9

Toggweiler, P., and R. Minder. "Comparison of Solar Thermal and Photovoltaic Electricity Generation Using Experimental Data from the Iea SSPS Project." In Thermo-Mechanical Solar Power Plants, 275–80. Dordrecht: Springer Netherlands, 1985. http://dx.doi.org/10.1007/978-94-009-5402-1_41.

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Gupta, Neeraj, Vivek Kumar, Hrishikesh Dhasmana, Abhishek Verma, Avshish Kumar, Prashant Shukla, Amit Kumar, S. K. Dhawan, and Vinod Kumar Jain. "Improving Thermal Comfort in Helmet Using Phase Change Nanocomposite Material." In Advances in Solar Power Generation and Energy Harvesting, 45–52. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-3635-9_6.

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Тези доповідей конференцій з теми "Solar thermal power generation"

1

Lokurlu, Ahmet, Karim Saidi, and Christian Gunkel. "Solar Thermal Power Generation." In ISES Solar World Congress 2011. Freiburg, Germany: International Solar Energy Society, 2011. http://dx.doi.org/10.18086/swc.2011.25.19.

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2

Islam, M. K., M. Hosenuzzaman, M. M. Rahman, M. Hasanuzzaman, and N. A. Rahim. "Thermal performance improvement of solar thermal power generation." In 2013 IEEE Conference on Clean Energy and Technology (CEAT). IEEE, 2013. http://dx.doi.org/10.1109/ceat.2013.6775618.

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3

Utamura, Motoaki, Yutaka Tamaura, and Hiroshi Hasuike. "Some Alternative Technologies for Solar Thermal Power Generation." In ASME 2006 International Solar Energy Conference. ASMEDC, 2006. http://dx.doi.org/10.1115/isec2006-99123.

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Two advanced optical systems and a highly efficient thermal cycle suitable for beam-down power tower with thermal storage are presented. (1) To increase field efficiency, the “cross beam” heliostat array concept is proposed. Using continuum optical model, the characteristics of the cross beam concept and its economy were investigated. (2) To protect the central reflector (CR) against wind force, a “multi-ring CR” concept is proposed. The concentration performance of multi-ring CRs is calculated using the ray-tracing method. It shows no worse results than the case with a single hyperboloid mirror. (3) The potential of a closed gas turbine cycle with supercritical carbon dioxide as a working fluid was investigated. An optimal cycle configuration involves a regenerative cycle with pre-cooling and inter-cooling cycles, in which theoretically achievable cycle thermal efficiency is 47% at the turbine inlet temperature of 800 K and turbine inlet pressure of 20 MPa. Detailed thermal design of a critical component, regenerative heat exchanger (RHX) is carried out using a newly developed printed heat exchanger (PCHE). It proved to be a feasible design.
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4

Weng, Guozhu. "Solar Thermal Power Generation and Its Application." In Advances in Materials, Machinery, Electrical Engineering (AMMEE 2017). Paris, France: Atlantis Press, 2017. http://dx.doi.org/10.2991/ammee-17.2017.97.

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5

Cheng, Xiang. "Review of Solar Thermal Power Generation Technology." In 2017 2nd International Conference on Materials Science, Machinery and Energy Engineering (MSMEE 2017). Paris, France: Atlantis Press, 2017. http://dx.doi.org/10.2991/msmee-17.2017.326.

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6

Baskar, S., T. Maridurai, R. Arivazhagan, S. SivaChandran, and R. Venkatesh. "Thermal management of solar thermoelectric power generation." In THIRD VIRTUAL INTERNATIONAL CONFERENCE ON MATERIALS, MANUFACTURING AND NANOTECHNOLOGY. AIP Publishing, 2022. http://dx.doi.org/10.1063/5.0096456.

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7

Der Minassians, Artin, Konrad H. Aschenbach, and Seth R. Sanders. "Low-cost distributed solar-thermal-electric power generation." In Optical Science and Technology, SPIE's 48th Annual Meeting, edited by Roland Winston. SPIE, 2004. http://dx.doi.org/10.1117/12.509785.

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8

Howard, Dustin, and Ronald G. Harley. "Modeling of dish-Stirling solar thermal power generation." In Energy Society General Meeting. IEEE, 2010. http://dx.doi.org/10.1109/pes.2010.5590188.

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9

Lowrie, David, Peter Rodgers, Valerie Eveloy, and Abdul Roof Baba. "Enhancement of flat-type solar photovoltaics power generation in harsh environmental conditions." In 2014 30th Semiconductor Thermal Measurement & Management Symposium (SEMI-THERM). IEEE, 2014. http://dx.doi.org/10.1109/semi-therm.2014.6892230.

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10

Price, Suzanne E., and J. Rhett Mayor. "Analysis of Solar-Thermal Power Cycles for Distributed Power Generation." 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/es2009-90404.

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In this study, the thermoeconometric feasibility of a 12.5 kW solar thermal power system is discussed. A previous study by these authors examined five potential 12.5kW solar thermal cycles and preliminary thermoeconometric analyses based on the collector area. The current study expands to six potential power cycles, including the five from the previous study, the Rankine, R123 Organic Rankine, toluene Organic Rankine, ethylbenzene organic Rankine, and the Kalina cycle, with the addition of the Maloney-Robertson cycle as well as detailed cost analysis for the components associated with each cycle. A detailed first law thermodynamic analysis for the Maloney-Robertson and Kalina cycles is presented. Likewise, the pinch point analysis is used for the inclusion of the sink and source stream as well as a developed heat exchanger model. The thermoeconometric study includes cost-per-component estimates for all of the components in the cycles; thus, increased component cost is taken into account for the ammonia-water cycles. The findings from this study show that R123 is the only cycle that operates with a source temperature below 225°C within the cycle applied operating constraints for meso-scale distributed power generation.. When higher temperatures are achieved, the Kalina cycle has the highest thermal efficiency but also the highest cost-to-efficiency ratio. Therefore, the thermoeconometrics study shows that the toluene and ethylbenzene ORCs have the lowest cost-to-efficiency ratio when source temperatures reach 225°C to 350°C even though they do not have the highest cycle efficiencies.
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Звіти організацій з теми "Solar thermal power generation"

1

Neti, Sudhakar, Alparslan Oztekin, John Chen, Kemal Tuzla, and Wojciech Misiolek. Novel Thermal Storage Technologies for Concentrating Solar Power Generation. Office of Scientific and Technical Information (OSTI), June 2013. http://dx.doi.org/10.2172/1159108.

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2

Reddy, Ramana G. Novel Molten Salts Thermal Energy Storage for Concentrating Solar Power Generation. Office of Scientific and Technical Information (OSTI), October 2013. http://dx.doi.org/10.2172/1111584.

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3

Hosemann, Peter, Mark Asta, Jan Schroers, and Y. Sungtaek Ju. HIGH-OPERATING TEMPERATURE HEAT TRANSFER FLUIDS FOR SOLAR THERMAL POWER GENERATION. Office of Scientific and Technical Information (OSTI), March 2020. http://dx.doi.org/10.2172/1670850.

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4

McTigue, Joshua Dominic P., Guangdong Zhu, Craig S. Turchi, Greg Mungas, Nick Kramer, John King, and Jose Castro. Hybridizing a Geothermal Plant with Solar and Thermal Energy Storage to Enhance Power Generation. Office of Scientific and Technical Information (OSTI), June 2018. http://dx.doi.org/10.2172/1452695.

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5

Qui, Songgang, and Ross Galbraith. Innovative Application of Maintenance-Free Phase-Change Thermal Energy Storage for Dish-Engine Solar Power Generation. Office of Scientific and Technical Information (OSTI), January 2013. http://dx.doi.org/10.2172/1096171.

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6

R. Panneer Selvam, Micah Hale, and Matt Strasser. Development and Performance Evaluation of High Temperature Concrete for Thermal Energy Storage for Solar Power Generation. Office of Scientific and Technical Information (OSTI), March 2013. http://dx.doi.org/10.2172/1072014.

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7

Robert L. Johnson Jr. and Gary E. Carver. Solar Power Generation Development. Office of Scientific and Technical Information (OSTI), October 2011. http://dx.doi.org/10.2172/1047740.

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8

Skone, Timothy J. Solar Thermal Power Plant, Assembly. Office of Scientific and Technical Information (OSTI), October 2011. http://dx.doi.org/10.2172/1509033.

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Drost, M. K., Z. I. Antoniak, D. R. Brown, and K. Sathyanarayana. Thermal energy storage for power generation. Office of Scientific and Technical Information (OSTI), October 1989. http://dx.doi.org/10.2172/5055651.

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Williams, T. A., J. A. Dirks, D. R. Brown, Z. I. Antoniak, R. T. Allemann, E. P. Coomes, S. N. Craig, M. K. Drost, K. K. Humphreys, and K. K. Nomura. Solar thermal bowl concepts and economic comparisons for electricity generation. Office of Scientific and Technical Information (OSTI), April 1988. http://dx.doi.org/10.2172/5045636.

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