Thermodynamic Analysis And Simulation Of A Solar Thermal Power System

Harith, Akila

01 1900

Solar energy is a virtually inexhaustible energy resource, and thus, has great potential in helping meet many of our future energy requirements. Current technology used for solar energy conversion, however, is not cost effective. In addition, solar thermal power systems are also generally less efficient as compared to fossil fuel based thermal power plants. There is a large variety of systems for solar thermal power generation, each with certain advantages and disadvantages. A distinct advantage of solar thermal power generation systems is that they can be easily integrated with a storage system and/or with an auxiliary heating system (as in hybrid power systems) to provide stable and reliable power. Also, as the power block of a solar thermal plant resembles that of a conventional thermal power plant, most of the equipment and technology used is already well defined, and hence does not require major break through research for effective utilisation. Manufacturing of components, too, can be easily indigenized. A solar collector field is generally used for solar thermal energy conversion. The field converts high grade radiation energy to low grade heat energy, which will inevitably involve energy losses as per the laws of thermodynamics. The 2nd law of thermodynamics requires that a certain amount of heat energy cannot be utilised and has to be rejected as waste heat. This limits the efficiency of solar thermal energy technology. However, in many situations, the waste heat can be effectively utilized to perform refrigeration and desalination using absorption or solid sorption systems, with technologies popularly known as “polygeneration”. There is extensive research done in the area of solar collectors, including but not limiting to thermal analysis, testing of solar collectors, and economic analysis of solar collectors. Exergy and optimization analyses have also been done for certain solar collector configurations. Research on solar thermal power plants includes energy analysis at system level with certain configurations. Research containing analysis with insolation varying throughout the day is limited. Hence, there is scope for analysis incorporating diurnal variation of insolation for a solar thermal power system. This thesis centres on the thermodynamic analysis at system level of a solar thermal power system using a concentrating solar collector field and a simple Rankine cycle power generation (with steam as the working fluid) for Indian conditions. The aim is to develop a tool for thermodynamic analysis of solar thermal power systems, with a generalised approach that can also be used with different solar collector types, different heat transfer fluids in the primary loop, and also different working fluids in the secondary loop. This analysis emphasises the solar collector field and a basic sensible heat storage system, and investigates the various energy and exergy losses present. Comparisons have been made with and without a storage unit and resulting performance issues of solar thermal power plants have been studied. Differences between the system under consideration and commercially used thermal power plants have also been discussed, which brought out certain limitations of the technology currently in use. A solution from an optimization analysis has been utilized and modified for maximization of exergy generated at collector field. The analysis has been done with models incorporating equations using the laws of thermodynamics. MATLAB has been used to program and simulate the models. Solar radiation data used is from NREL’s Indian Solar Resource Data, which is obtained using their SUNY model by interpreting satellite imagery. The performance of the system has been analysed for Bangalore for four different days with different daylight durations, each day having certain differences in the incident solar radiation or insolation received. A particular solution of an optimization analysis has been modified using the simulation model developed and analysed with the objective of maximization of exergy generated at collector field. It has been found that the performance of the solar thermal power system was largely dependent on the variation of incident solar radiation. The storage system provided a stableperformance for short duration interruptions of solar radiation occurred on Autumn Equinox (23-09-2002).The duration of the interruption was within the limits of storage unit capacity. The major disruption in insolation transpired on Summer Solstice (21-06-2002) caused a significantly large drop in the solar thermal system performance; practically the system ceased to function due to lack of energy resource. Hence, the use of an auxiliary heating system hasbeen considered desirable. The absence of a storage unit has been shown to cause a significant loss in gross performance of the power system. The Rankine cycle turbine had many issues coping with a highly fluctuating energy input, and thus caused efficiency losses and even ceased power generation. A storage unit has been found to be ideal for steady power generation purposes. Some commercial configurations may lack a storage system, but they have been compensated by the auxiliary heating system to ensure stable power generation. The optimization of the solar collector determines that optimal collector temperatures vary in accordance to the incident solar radiation. Hence, the collector fluid outlet temperature must not be fixed so as to handle varying insolation for optimal exergy extraction. The optimal temperatures determined for Bangalore are around 576 K which is close to the values obtained by the simulation of the solar thermal power system. The tools for analysis and simulation of solar thermal power plants developed in this thesis is fairly generalised, as it can be adapted for various types of solar collectors and for different working fluids (other than steam), such as for Organic Rankine Cycle (ORC). The model can also be easily extended to other types of power cycles such as Brayton and Stirling cycles.

Solar Thermal Power System

Solar Collectors

Solar Thermal Energy Conversion

Rankine Cycle Power Generation

Solar Energy

Solar Thermal Power

Solar Thermal Power Plant

Rankine Cycle System

Organic Rankine Cycle (ORC)

Heat Engineering

A solar concentrating photovoltaic/thermal collector

Coventry, Joseph Sydney, Joe.Coventry@anu.edu.au

January 2004

This thesis discusses aspects of a novel solar concentrating photovoltaic / thermal (PV/T) collector that has been designed to produce both electricity and hot water. The motivation for the development of the Combined Heat and Power Solar (CHAPS) collector is twofold: in the short term, to produce photovoltaic power and solar hot water at a cost which is competitive with other renewable energy technologies, and in the longer term, at a cost which is lower than possible with current technologies. To the author’s knowledge, the CHAPS collector is the first PV/T system using a reflective linear concentrator with a concentration ratio in the range 20-40x. The work contained in this thesis is a thorough study of all facets of the CHAPS collector, through a combination of theoretical and experimental investigation. A theoretical discussion of the concept of ‘energy value’ is presented, with the aim of developing methodologies that could be used in optimisation studies to compare the value of electrical and thermal energy. Three approaches are discussed; thermodynamic methods, using second law concepts of energy usefulness; economic valuation of the hot water and electricity through levelised energy costs; and environmental valuation, based on the greenhouse gas emissions associated with the generation of hot water and electricity. It is proposed that the value of electrical energy and thermal energy is best compared using a simple ratio. Experimental measurement of the thermal and electrical efficiency of a CHAPS receiver was carried out for a range of operating temperatures and fluid flow rates. The effectiveness of internal fins incorporated to augment heat transfer was examined. The glass surface temperature was measured using an infrared camera, to assist in the calculation of thermal losses, and to help determine the extent of radiation absorbed in the cover materials. FEA analysis, using the software package Strand7, examines the conductive heat transfer within the receiver body to obtain a temperature profile under operating conditions. Electrical efficiency is not only affected by temperature, but by non-uniformities in the radiation flux profile. Highly non-uniform illumination across the cells was found to reduce the efficiency by about 10% relative. The radiation flux profile longitudinal to the receivers was measured by a custom-built flux scanning device. The results show significant fluctuations in the flux profile and, at worst, the minimum flux intensity is as much as 27% lower than the median. A single cell with low flux intensity limits the current and performance of all cells in series, causing a significant drop in overall output. Therefore, a detailed understanding of the causes of flux non-uniformities is essential for the design of a single-axis tracking PV trough concentrator. Simulation of the flux profile was carried out using the ray tracing software Opticad, and good agreement was achieved between the simulated and measured results. The ray tracing allows the effect of the receiver supports, the gap between mirrors and the mirror shape imperfections to be examined individually. A detailed analytical model simulating the CHAPS collector was developed in the TRNSYS simulation environment. The accuracy of the new component was tested against measured data, with acceptable results. A system model was created to demonstrate how sub components of the collector, such as the insulation thickness and the conductivity of the tape bonding the cells to the receiver, can be examined as part of a long term simulation.

solar thermal concentrator

pv concentrator

pvt

CHAPS

PV/thermal

Second Law Performance Analysis of a Large Thermal Energy Storage Vessel using CFD

Rysanek, Adam M.

22 September 2009

This work is an example of a CFD-assisted design and characterization process for thermal energy storage vessels. A general modeling technique for future works is also proposed. The Short-Term Thermal Storage (STTS) tanks at the Drake Landing Solar Community (DLSC) were used as the principal case study. The performance characterization of the STTS tanks and the evaluation of other tank designs were made under solar charging conditions and for the STTS “Hot Tank” only. Three sets of simulations were undertaken for each tank design, each representing a different state of inlet conditions reflected in the DLSC’s operational manual. Characterization of the STTS tanks was done mainly by applying a set of 2nd Law characterization indices, both existing and new, using exergy as the primary Figure of Merit. It was evident that significant mixing occurs in the current STTS tanks due to the ineffective placement of the inlet ports and the lack of an appropriate flow diffuser to prevent mixing. For example, at the end of the simulations exhibiting constant inlet temperature and flow rate, the total exergy in the original STTS tank was only 68% of a perfectly-stratified vessel. A modified design of the STTS tanks, which only shifted the position of the inlet port and center baffle, significantly improved this value to over 90%. Additional analysis also indicated that the STTS tanks would benefit from a simple flow distributor or inlet manifold that would address stratification issues inherent to variable temperature inlet conditions. However, further analysis on this particular design configuration is needed. The characterization methods employed in this work represent an effective means to differentiate between the stratification effectiveness of various thermal storage vessel designs. This work would further benefit from a future study that compares changes to the STTS tanks’ stratification efficiency with changes to the DLSC’s overall performance, including a cost-benefit analysis. / Thesis (Master, Mechanical and Materials Engineering) -- Queen's University, 2009-09-18 05:50:58.362

thermal storage

solar thermal

district heating

stratification

exergy

The Solar Energy Tracker

Maples, David William

January 2008

Reference is increasingly being made towards the need for the world to find new and renewable forms of energy, especially for electric power generation, but also for space heating and the heating of water. Solar energy is one of the cheapest forms of renewable energy available and is so far one of the most underutilised resources. One contribution makes reference to the way forward as being ‘using concentrating solar power which uses parabolic mirrors to focus the solar heat (energy) and generate steam to drive electric generators’ as is currently happening in the utility power marketplace in the USA. This thesis deals with the issues surrounding the original development of a two axis solar energy tracking system (SET) in 1997. The subsequent redesign, development and upgrade, undertaken from 2002 to 2006, with its performance and efficiency being measured in 2006 and 2007 using a specially configured measurement and recording system. A Solar Energy Tracker (SET) is designed to track the sun moving in two axes, reflecting the solar radiation received on its mirrors to a target mounted at the end of a boom, at the focal point of the mirrors. In late 2005 and early 2006, a solar thermal hot water manufacturer and installer heard about the developments and requested some form of involvement, especially if Christchurch Polytechnic Institute of Technology (CPIT) provided research input and assisted in the further development and testing of solar thermal hot water systems. This sponsor offered two projects in 2006 and again in 2007. Other solar thermal hot water suppliers also requested involvement in the research and development being performed at CPIT, which led in August 2006, December 2006, June 2007 and December 2007, to a number of other solar thermal hot water and air wall systems being installed. Progressively, the roof of C block at CPIT has become full of solar thermal hot water systems and solar air wall systems, both of the conventional type and those with newer technologies at the core of their development. This thesis outlines the stages in the redesign and development of the SET, and the various stages in its testing, development and refinement up to its present form. The thesis chapters are written based around the mechanical and electrical design, the auto-tracking and daylight controls, the PLC (programmable logic controller) controller, the mirror and substrate testing, the SCADA (Supervisory Control And Data Acquisition) system, the testing and comparison with other domestic solar thermal hot water systems and finally the testing of the SET itself. It also details the future developments and outlines possible uses for the SET in its redefined form. With clean and polished mirrors the SET has proven itself capable of achieving a temperature rise across the target of 15 °C at a flow rate of 4 l/m. On some occasions this temperature rise can be in excess of 20 °C, but testing thus far, has shown this cannot be sustained for any worthwhile period of time (15-30 minutes). This translates to an efficiency of 5-10 % when related to an energy produced per twenty four hour time period. However, if the efficiency is calculated for the actual period of generation, ‘generation efficiency,’ then this figure rises to 24 %. An overview is given of associated solar thermal hot water and solar air wall system research and development (that is ongoing at CPIT) as well as the performance and efficiency graphs for the solar thermal hot water systems on test. No manufacturer’s, industry or brand trade names are mentioned, as this research is still confidential and commercially sensitive. However, the technology involved and characterised by each solar thermal system is recorded in a generic sense. The SET was originally developed with the purpose of heating hot water and today this is still the intent. The possible applications for this hot water are many and varied from electricity generation, space heating and further into developing or new industrial processes. The performances of the other domestic solar thermal hot water systems currently under test, are compared with the figures from the SET, with the maximum efficiency, presently available, being from an evacuated tube heat pipe system at up to 65 %, whereas traditional finned flat plate technologies have efficiencies after twelve months of up to 48 %.

solar energy tracking

solar thermal hot water systems

Thermo-economic Analysis of Retrofitting an Existing Coal-Fired Power Plant with Solar Heat

Shimeles, Surafel

January 2014

At a time when global environmental change is posing a growing challenge to the world’s economy and creating uncertainties to livelihood of its inhabitants, Coal thermal power plants are under pressure to meet stringent environmental regulations into achieving worldwide set millennial goals for mitigating the effect of emission gases on the atmosphere. Owing to its abundance, it is unlikely to see the use of coal completely missing from the global energy mix within the next hundred years to come. While innovative emission reduction technologies are evolving for the better, trendy technological solutions which require reintegration of these coal plants with alternative greener fuels are growing at the moment. Among these solutions, the following paper investigates possible means for repowering a coal steam power plant with indirect solar heating solutions to boost its annual outputs. Two widely deployable solar thermal technologies, parabolic trough and Central tower receiver systems, are introduced at different locations in the steam plant to heat working fluid thereby enhancing the thermodynamic quality of steam being generated. Potential annual energy output was estimated using commercially available TRNSYS software upon mass and heat balance to every component of solar and steam plant. The annual energy outputs are weighed against their plant erecting and running costs to evaluate the economic vitality of the proposed repowering options. The results show that parabolic trough heating method could serve as the most cost effective method generating electricity at competitive prices than solar only powered SEGS plants. While cost may be acceptable in the unit of energy sense, the scale of implementation has been proven to be technically limited. / Kriel Power Plant

Hybrid

coal power plant

solar thermal system

Thermo-economic analysis

Numerical Investigation of One-Dimensional Storage Tank Models and the Development of Analytical Modelling Techniques

Unrau, Cody

06 1900

To assess the long-term performance of a solar thermal system, mathematical models that accurately capture the effects of heat transfer within and interactions between individual components are required. For solar domestic hot water systems, the components can include the solar collectors, storage tanks, heat exchangers, pumps, and associated piping. In addition, weather data and demand profiles are also required. Simplified models for each component are needed to reduce the computational time required to run long-term simulations. The simplified models, however, must also be sufficiently accurate in order to provide meaningful system-level results. Accurate prediction of the temperature profiles in the storage tanks of these systems is important since the temperature within the tank has a large impact on the efficiency of the entire system. TRNSYS, which is a commercial code commonly used for such simulations, contains a variety of different one-dimensional storage tank models. Previous research has indicated that these models have deficiencies in predicting experimental data. Therefore, this thesis is focussed on the analysis of the tank modelling used in TRNSYS. Results of this thesis show that the poor predictions are a result of numerical diffusion due to insufficient grid resolution. The correct theoretical profiles could be obtained by using a large number of nodes. However, this would lead to a significant increase in computational time. Alternative modelling strategies were also developed using analytical techniques to more accurately predict the temperature profiles within a storage tank while keeping a relatively low computational cost. Different models were created which considered the different mixing mechanisms present in a storage tank, such as increasing inlet temperatures with time, heat losses to the surroundings, tank wall heat conduction, and inlet jet mixing. / Thesis / Master of Applied Science (MASc)

Thermal Storage

One-Dimensional Model

Solar Thermal

TRNSYS

Solar cooling systems : A comparative analysis for solar thermal and solar PV cooling systems for Industries using a techno-economic approach

Larsson, Christoffer

January 2022

With the need to reduce CO2 emissions in the energy sector, ensure electric grid stability and reduce future cost uncertainties for process cooling, solar cooling can be an interesting solution. This report describes the comparison of solar cooling with either a photovoltaics system or a solar thermal system using a thermally driven chiller. The application investigated was industrial process cooling, for three load profiles and three locations in Europe. The method of comparing was by simulations in TRNSYS and calculation of the global levelized cost of cooling, taking into account the total cost of covering the whole cooling demand. The results for the global levelized cost of cooling showed that solar thermal cooling was not economically competitive compared to the reference system or the photovoltaic cooling system for any of the investigated boundary conditions. The general trend was that the global LCOC for the solar thermal cooling increased with the solar cooling fraction. The photovoltaic solar cooling system global LCOC was in parity with the reference system for low SCF of 20 % to 30 %, and even up to 60 % for some boundary conditions.

Photovoltaic cooling

solar thermal cooling

global LCOC

Energy Systems

Energisystem

Simulação de um sistema de refrigeração por absorção com energia solar térmica para locais isolados

Souza, Ronaldo Bueno de

07 April 2015

Submitted by Maicon Juliano Schmidt (maicons) on 2015-07-20T14:17:58Z No. of bitstreams: 1 Ronaldo Bueno de Souza.pdf: 1999281 bytes, checksum: 5dd2b3645a9e4750a12f291e30ba6d41 (MD5) / Made available in DSpace on 2015-07-20T14:17:58Z (GMT). No. of bitstreams: 1 Ronaldo Bueno de Souza.pdf: 1999281 bytes, checksum: 5dd2b3645a9e4750a12f291e30ba6d41 (MD5) Previous issue date: 2015-04-07 / CYTED - Programa Iberoamericano de Ciencia y Tecnología para el Desarrollo / Este trabalho apresenta o estudo de um sistema de refrigeração por absorção assistido por energia solar térmica com intuito de ser empregado no arrefecimento de uma pousada de ecoturismo localizada em um local remoto, desprovida de conexão à rede elétrica. Para o estudo do sistema proposto foi utilizado o software de simulações TRNSYS, onde em uma etapa inicial do trabalho foi realizada a comparação dos resultados do software com os resultados dos modelos matemáticos dos componentes do sistema de refrigeração. Foi desenvolvido um modelo computacional, para realização de simulações horárias que permitiu a simulação de três configurações de sistemas de refrigeração por absorção, podendo assim determinar a influência dos componentes e parâmetros utilizados no sistema no uso da energia auxiliar e no atendimento da carga térmica. O primeiro modelo é constituído por um sistema onde a água aquecida pelo coletor solar térmico e é armazenada em um reservatório térmico, sendo a mesma utilizada para a alimentação do chiller de absorção. A água gelada produzida pelo chiller é armazenada em outro reservatório térmico onde fica disponível para o consumo. Neste modelo observa-se que com o uso de 120 m² de coletores de tubo evacuado chega-se a índices de atendimento dos consumos superiores a 87 %. O segundo modelo é similar ao primeiro, com a inclusão de um aquecedor auxiliar para a água de alimentação do chiller de absorção. Neste modelo observou-se que com o uso de 120 m² de coletores de placas planas chega-se a um consumo de energia auxiliar inferior a 195 GJ, e com o uso de 120 m² de coletores de tubo evacuado chega-se a um consumo de energia auxiliar inferior a 150 GJ. O terceiro modelo é similar ao segundo, onde foi acrescentado um sistema para utilização da água de arrefecimento do chiller de absorção, para uso no consumo de água quente para banho, nos chuveiros. Neste modelo observa-se que o aproveitamento da água de arrefecimento não afeta o consumo de energia auxiliar, se comparado com o consumo do segundo modelo. / This paper presents the study of a cooling system for absorption assisted by solar energy with a view to be used in the cooling of an ecotourism lodge located in a remote location, devoid of connection to the grid. To study the proposed system was used TRNSYS simulation software, where in an initial work step of comparing software results with the results of mathematical models of the components of the refrigeration system is performed. A computer model was developed to perform simulations slot which simulated three configurations absorption refrigeration systems and can therefore determine the influence of the components and system parameters used in the auxiliary power usage and meet the thermal load. The first model is made up of a system where the water heated by the solar thermal collector and is stored in a thermal storage tank, being the same used for feeding the absorption chiller. The chilled water produced by the chiller is stored in another thermal reservoir where it is available for consumption. In this model it is observed that with the use of 120 m² evacuated tube collectors comes to fuel consumption attendance rates of over 87 %. The second model is similar to the first, with the inclusion of an auxiliary heater to supply water from the absorption chiller. In this model we found that with the use of 120 m² of flat plate collectors comes to an auxiliary power consumption of less than 195 GJ, and with the use of 120 m² evacuated tube collectors we arrive at a consumption of auxiliary power less than 150 GJ. The third model is similar to the second, which was added to a system using the cooling water from absorption chiller for use in the consumption of hot water for baths, showers on. In this model, it is observed that the use of the cooling water does not affect the auxiliary power consumption compared with the consumption of the second model.

Absorção

Coletor solar térmico

Energia térmica solar

Chiller

Absorption

Solar thermal collector

Solar thermal energy

Optimization of a SEGS solar field for cost effective power output

Bialobrzeski, Robert Wetherill

10 July 2007

This thesis presents and demonstrates procedures to model and optimize the collector field of a parabolic trough solar thermal power plant. The collector field of such a plant is universally organized into parallel loops of solar collectors. Heat transfer fluid returning from the energy conversion plant is heated to a moderately high temperature in the field. Typically fluid enters a collector loop around 270 °C and leaves at 380 °C. The fluid is then returned to the plant to generate steam. In the first part of this thesis, the collector field and the energy conversion system of a typical parabolic trough solar thermal power plant are modeled. The model is compared with actual performance data and is enhanced and verified as necessary. Originally, the collectors in the plants under consideration were provided with evacuated tube receivers of the highest feasible efficiency without much regard for cost effectiveness. In practice, these receivers have failed at an unexpected rate and need replacement. It is unlikely that a very expensive evacuated tube receiver is now the most cost effective for every location in a collector loop. In particular, a receiver optimized for 270 °C operation may not be optimal at 380 °C. For example, a relatively inexpensive receiver with a flat black absorber and no vacuum may be more cost effective in the lower temperature segments of a loop. In the second part of this thesis, a procedure for the optimum deployment of collectors is developed and demonstrated. The results of this research should be directly applicable to the refurbishment and upgrading of several of the largest solar energy plants in the world.

Solar field

SEGS

Parabolic trough

Solar thermal

Solar energy

Renewable energy sources

Solar concentrators

Parabolic troughs

Solar collectors

Solar thermal energy

Optimisation, design, development, and trial of a low-cost solar oven with novel concentrator geometry

Berryman, Ian

January 2016

A promising and novel solar concentrator design has been thoroughly investigated and optimised. A prototype concentrator based on this novel geometry was validated using ray tracing techniques. This ray tracing demonstrated the comparative performance of this novel concentrator in regards to equivalent parabolic dishes. The effect of mirror surface normal errors on performance was established using Monte-Carlo based ray tracing code, which agreed well with the optical performance of this prototype which was determined experimentally. A need for low-cost solar cookers to replace bio-mass worldwide was identified, and the concentrator design was then developed as a low-cost solar oven. Despite existing in some number, no current design is able to achieve high performance at low-cost. An industrial partner, Dytecna, was initially involved in the process of this development of the system as a solar cooker. In support of a field trial for the solar cooker developed with Dytecna, a detailed thermal model of the oven was developed. A low-cost lightmeter was constructed and calibrated in order to measure the direct normal irradiance during the field trial in Italy. Laboratory work provided baseline results for the heating of various thermal masses in the oven. The Italian field trials provided a wealth of feedback into the design of the system and many valuable results. The solar cooker was able to bring 0.75L of water to the boil in 33 minutes with an average heat throughput of 203W. Important benchmark results and practical experience of several competing receiver materials was obtained; further lab testing provided more accurate measurements of the receivers' performances. The experiences of the Italian field trial were fed back into the design of a subsequent prototype, intended for a much larger field trial in Tanzania. Improvements in the hotplate, receiver material, and the oven were all incorporated into the design. Additionally, the structure of the solar cooker was redesigned to incorporate a low-cost wooden construction. Supporting work was conducted for the month long trial in which 8 solar cookers would be distributed to families in Tanzania. The field trial in Tanzania provided a wealth of user feedback into the design. At the same time the new solar cooker exceeded previously established performances in Italy. The new design was able to provide an average of 246W of heat to 1kg of water, which was brought to boiling point in 25 minutes. This represents a heating efficiency of 66% compared to the incident solar flux on the hotplate. In response to findings during the Tanzanian trials, further laboratory work was conducted into establishing the reflectivities of low-cost candidate mirror materials. Throughout all phases of the project the design of the solar cooker was refined and improved with the goal of a solar cooker design that could reach price-point, performance, and usability standards which would ensure market success.