Solar thermal heating of a glasshouse using phase change material (PCM) thermal storage techniques

Boampong, James Kwadwo

January 2015

The Royal Botanic Gardens (RGB) is used as an umbrella name for the institution that runs Kew and Wakehurst Place gardens in Sussex The RBG has a large number of glasshouses at Kew and Wakehurst sites that consume lots of heating energy which is a major concern and the group is looking for an alternative heating system that will be more efficient and sustainable to save energy, cost and reduce CO2 emissions. Glasshouse due to greenhouse effect trap solar energy in the space with the slightest solar gains but the energy trapped in the space most often is vented through the roof wasted to keep the space temperature to the required level. An environmental measurement was carried out in twenty one zones of the glasshouse to establish the temperature and humidity profiles in the zones for at least three weeks. The investigation established that large amount of heat energy is vented to the atmosphere wasted and therefore need a heating system that could absorb and store the waste thermal energy. Phase change material (PCM) thermal energy storage technique was selected to be the best options compared to the others. It has been established that active and passive solar systems could provide enough thermal energy to meet the glasshouse heating requirements. PCM filled heating pipes will be installed to absorb the heat energy trapped in the glasshouse and use it when needed. The research analysis established that 204 MWh of the trapped energy wasted could be saved. The space temperature of the glasshouse could be maintained through melting and freezing of the PCM filled in the heating pipes. The site CHP waste heat could be useful. The research results have shown that nearly zero CO2 emission heating system could be achieved and the project is technically, economically and environmentally viable.

697

Návrh malého jaderného reaktoru pro účely dodávek tepla / Concept of a small nuclear reactor for the heat supply purposes

Bobčík, Marek

January 2013

The objective of this diploma thesis is to assess the suitability of a small nuclear reactor for the purpose of heat supply in small towns and cities. First, all the heat demands of these towns and cities are analysed. Then, a small nuclear reactor to serve these needs is designed and a computational model for burn-up fuel is created. The thesis aims to propose a design of a new heat exchanger. Economic and environmental criteria are taken into account as well and including safety measures. The outcome of this thesis is an evaluation of the whole concept with respect to potential future implementation.

For Improved Energy Economy – How Can Extended Smart Metering Be Displayed? / For Improved Energy Economy – How Can Extended Smart Metering Be Displayed?

Ahmed, Nisar, Yousaf, Shahid

January 2011

Context: A District Heating System (DHS) uses a central heating plant to produce and distribute hot water in a community. Such a plant is connected with consumers’ premises to provide them with hot water and space heating facilities. Variations in the consumption of heat energy depend upon different factors like difference in energy prices, living standards, environmental effects and economical conditions etc. These factors can manage intelligently by advanced tools of Information and Communication Technology (ICT) such as smart metering. That is a new and emerging technology; used normally for metering of District Heating (DH), district cooling, electricity and gas. Traditional meters measures overall consumption of energy, in contrast smart meters have the ability to frequently record and transmit energy consumption statistics to both energy providers and consumers by using their communication networks and network management systems. Objectives: First objective of conducted study was providing energy consumption/saving suggestions on smart metering display for accepted consumer behavior, proposed by the energy providers. Our second objective was analysis of financial benefits for the energy provides, which could be expected through better consumer behavior. Third objective was analysis of energy consumption behavior of the residential consumes that how we can support it. Moreover, forth objective of the study was to use extracted suggestions of consumer behaviors to propose Extended Smart Metering Display for improving energy economy. Methods: In this study a background study was conducted to develop basic understanding about District Heat Energy (DHE), smart meters and their existing display, consumer behaviors and its effects on energy consumption. Moreover, interviews were conducted with representatives of smart heat meters’ manufacturer, energy providers and residential consumers. Interviews’ findings enabled us to propose an Extended Smart Metering Display, that satisfies recommendations received from all the interviewees and background study. Further in this study, a workshop was conducted for the evaluation of the proposed Extended Smart Metering Display which involved representatives of smart heat meters’ manufacture and residential energy consumers. DHE providers also contributed in this workshop through their comments in online conversation, for which an evaluation request was sent to member companies of Swedish District Heating Association. Results: Informants in this research have different levels of experiences. Through a systematic procedure we have obtained and analyzed findings from all the informants. To fulfill the energy demands during peak hours, the informants emphasized on providing efficient energy consumption behavior to be displayed on smart heat meters. According to the informants, efficient energy consumption behavior can be presented through energy consumption/saving suggestions on display of smart meters. These suggestions are related to daily life activities like taking bath and shower, cleaning, washing and heating usage. We analyzed that efficient energy consumption behavior recommended by the energy providers can provide financial improvements both for the energy providers and the residential consumers. On the basis of these findings, we proposed Extended Smart Metering Display to present information in simple and interactive way. Furthermore, the proposed Extended Smart Metering Display can also be helpful in measuring consumers’ energy consumption behavior effectively. Conclusions: After obtaining answers of the research questions, we concluded that extension of existing smart heat meters’ display can effectively help the energy providers and the residential consumers to utilize the resources efficiently. That is, it will not only reduce energy bills for the residential consumers, but it will also help the energy provider to save scarce energy and enable them to serve the consumers better in peak hours. After deployment of the proposed Extended Smart Metering Display the energy providers will able to support the consumers’ behavior in a reliable way and the consumers will find/follow the energy consumption/saving guidelines easily. / mcs294@yahoo.com, shahid_yousaf27@yahoo.com

Smart meter/metering/display/feedbacks

Consumer behavior

Computer Sciences

Datavetenskap (datalogi)

Human Computer Interaction

Modelagem e integração energética do processo de produção de etanol a partir da biomassa de cana-de-açúcar / Modeling and energy integration of the ethanol production process from sugarcane biomass

Palacios Bereche, Reynaldo

18 August 2018

Orientador: Silvia Azucena Nebra de Pérez / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica / Made available in DSpace on 2018-08-18T14:25:37Z (GMT). No. of bitstreams: 1 PalaciosBereche_Reynaldo_D.pdf: 4111250 bytes, checksum: 43defaf6dca45a15dd8d50bbb286f989 (MD5) Previous issue date: 2011 / Resumo: A produção de etanol a partir da hidrolise enzimática do bagaço e eventualmente da palha se apresenta como uma alternativa de grande interesse, uma vez que permite ampliar significativamente a produção sem necessidade de aumentar a área plantada de cana. Não obstante, a introdução da hidrolise se apresenta como um verdadeiro desafio uma vez que o bagaço e o combustível do processo atual e ao mesmo tempo e matéria prima para o novo. Assim, o presente estudo tem como objetivo elaborar propostas de integração energética, e realizar avaliações do potencial de incremento da produção de etanol do processo integrado. Para este fim foi utilizado o simulador Aspen Plus® como ferramenta de analise e o método Pinch-Point para realizar a integração energética. Um estudo foi realizado com a finalidade de verificar se as propriedades das substancias envolvidas no processo são calculadas apropriadamente pelo simulador. O sistema de cogeração também foi modelado no simulador e depois inserido na modelagem do processo de produção. Em uma primeira analise foi modelado o processo de produção de etanol por hidrolise enzimática inserido no processo convencional considerando o arranjo (layout) usual das usinas sucroalcooleiras hoje. Os resultados desta analise foram modestos apresentando um incremento na produção de etanol de 9,7%, o que indicou que mudanças que visem a otimização do sistema em termos de uso de energia devem ser realizadas no processo tradicional. Em um segundo estudo foi avaliado o potencial de produção de etanol considerando a integração térmica das correntes do processo, utilizando o método Pinch-Point, e visando a minimização do consumo de utilidades quentes e frias. Este segundo estudo apresentou melhores resultados, atingindo um incremento na produção de etanol de 22,4% quando são consideradas membranas para a concentração do licor de glicose obtido no processo de hidrolise / Abstract: Ethanol production process by enzymatic hydrolysis of sugarcane bagasse and eventually from sugarcane trash presents itself as an interesting alternative since to it allows a significant ethanol production increase without needing to increase the planted area. The introduction of the hydrolysis process is a true challenge, since bagasse is the fuel of the current process while it is raw material for the hydrolysis process. Thus, the aim of this study is to accomplish proposals for energy integration of processes and to assess the ethanol production potential from the hydrolysis process integrated to the conventional process. Simulator Aspen Plus was used as analysis tool and Pinch-Point method was applied in order to perform the thermal integration of the system. A study of properties was carried out to verify the simulator accuracy in property calculations. The cogeneration system was modeled in the simulator and after, it was inserted into the modeling of the ethanol production process. In a first analysis the enzymatic hydrolysis process inserted in the conventional process, considering the current configuration of sugarcane mills today, was modeled. The results of this preliminary study were modest obtaining an ethanol production increase of 9,7%, which indicates that changes in conventional production process should be done. These changes should improve and optimize the system in terms of energy use. In a second analysis the potential of ethanol production was evaluated, considering the heat integration of process streams using the Pinch Point method. This method aims to minimize the consumption of hot and cold utilities in the integrated system. This second analysis presented better results, obtaining an ethanol production increase of 22,4% when the concentration of glucose liquor is accomplished by a membrane system / Doutorado / Termica e Fluidos / Doutor em Engenharia Mecânica

Álcool

Cana-de-açúcar

Hidrólise enzimática

Energia elétrica e calor - Cogeração

Energia - Consumo

Ethanol

Sugarcane

Enzymatic hydrolysis

Energy - Consumption

Vyhodnocení provozních dat tepelného čerpadla / Evaluation of heat pump operation data

Charvátová, Marie

January 2019

This diploma thesis deals with the issue of heat pumps as devices using low-potential heat of the surrounding environment for heating of buildings. In the theoretical part of the thesis there are described various types of these devices, the sources of low-potential heat and the possibilities of heat energy accumulation. The practical part of the thesis is focused on processing and evaluation of operational data of air/water heat pump used for heating of family house and assessment of importance of accumulation tank in heating system. Part of the thesis is also a proposal of optimization of heat pump control.

Electricity, Heat, and Gas Sector Data for Modeling the German System

Kunz, Friedrich, Kendziorski, Mario, Schill, Wolf-Peter, Weibezahn, Jens, Zepter, Jan, von Hirschhausen, Christian, Hauser, Philipp, Zech, Matthias, Möst, Dominik, Heidari, Sina, Felten, Björn, Weber, Christoph

January 2018

Diese Dokumentation beschreibt Daten zum deutschen Strom- Wärme- und Gassektor und ermöglicht eine modellgestützte Abbildung dieser Energiesysteme. Die Aufbereitung der Daten erfolgte im Rahmen des vom BMWi geförderten Forschungsprojekts LKD-EU (Langfristige Planung und kurzfristige Optimierung des Elektrizitätssystems in Deutschland im europäischen Kontext, FKZ 03ET4028C). In Zusammenarbeit mit dem Deutschen Institut für Wirtschaftsforschung (DIW), der Arbeitsgruppe Wirtschafts- und Infrastrukturpolitik (WIP) der Technischen Universität Berlin (TUB), dem Lehrstuhl für Energiewirtschaft (EE2), der Technischen Universität Dresden (TUD) und dem House of Energy Markets & Finance der Universität Duisburg-Essen (UDE). Ziel des Dokumentes ist es, Referenzdaten zur Verfügung zu stellen, die den aktuellen Zustand des deutschen Energiesystems repräsentieren. Das Bezugsjahr ist 2015. Diese Dokumentation trägt dazu bei, die Transparenz in der Verfügbarkeit von Daten zum deutschen Energiesystem zu erhöhen. / This data documentation describes a data set of the German electricity, heat, and natural gas sectors compiled within the research project ‘LKD-EU’ (Long-term planning and short-term optimization of the German electricity system within the European framework: Further development of methods and models to analyze the electricity system including the heat and gas sector). The project is a joined effort by the German Institute for Economic Research (DIW Berlin), the Workgroup for Infrastructure Policy (WIP) at Technische Universität Berlin (TUB), the Chair of Energy Economics (EE2) at Technische Universität Dresden (TUD), and the House of Energy Markets & Finance at University of Duisburg-Essen. The project was funded by the German Federal Ministry for Economic Affairs and Energy through the grant ‘LKD-EU’, FKZ 03ET4028A. The objective of this paper is to document a reference data set representing the status quo of the German energy sector. We also update and extend parts of the previous DIW Data Documentation 75 (Egerer et al. 2014). While the focus is on the electricity sector, the heat and natural gas sectors are covered as well. With this reference data set, we aim to increase the transparency of energy infrastructure data in Germany. On the one hand, this documentation presents sources of original data and information used for the data set. On the other hand, it elaborates on the methodologies which have been applied to derive the data from respective sources in order to make it useful for modeling purposes and to promote a discussion about the underlying assumptions. Furthermore, we briefly discuss the underlying regulations with regard to data transparency in the energy sector. Where not otherwise stated, the data included in this report is given with reference to the year 2015 for Germany.

info:eu-repo/classification/ddc/330

ddc:330

Identifikace tepelné vodivosti a tepelné kapacity stavebních látek metodou „Hot Wire Method“ / Identification of Thermal Conductivity and Thermal Capacity of Building Materials by the "Hot Wire Method"

Průša, David

January 2019

This aim of task deals with study of heat dissipation mechanisms and the description of physical phenomena, which is accompanied by non-stationary measurement of thermal characteristics by the method "hot-wire method". In particular, we observe the coefficient of thermal conductivity and its dependence on various variables such as the temperature of the measured sample, its moisture state, the volume of the sample and its porosity. The above mentioned findings are used for the invention of the measuring device of a nonstationary gauge, which is based on regular heating and is dedicated to measuring the thermal conductivity coefficient and the heat capacity by the "hot-wire method" method. In the last part of the thesis is verified functionality of the proposed measuring device, the suitability of the created algorithm for the processing of the measured data and the evaluation of the results was verified. The reproducibility of the measurements was verified and the measured results were compared with the measurement methods, which are commonly used. the influence of humidity on the coefficient of thermal conductivity.

Energieeffizienzpolitik in Deutschland und Südkorea : Kraft-Wärme-Kopplung im Spannungsfeld zwischen Klimaschutz und Energiewirtschaft /

Jung, Yeon-Mi.

January 2009

Thesis (doctoral)--Freie Universität, Berlin, 2007. / Includes bibliographical references.

Études de systèmes thermo-fluidiques auto-oscillants pour des applications de récupération d'énergie thermique

Monin, Thomas

January 2017

Les progrès technologiques considérables menés depuis ces dernières décennies nous permettent aujourd’hui de disséminer dans notre environnement une nuée de noeuds de capteurs communicants combinant la taille micrométrique et la consommation dérisoire caractéristiques des MEMS avec la puissance des protocoles de communications Internet. L’Internet des Objets, formé par ce réseau de capteurs, possède le potentiel d‘optimiser un grand panel d’applications industrielles et domotiques. Le nouveau défi, que la communauté du Energy Harvesting tente de relever depuis une décennie maintenant, est de rendre ces noeuds de capteurs autonomes en les alimentant grâce à l’énergie perdue dans leur environnement. Dans ces travaux de recherche, nous explorons le potentiel d’un principe thermo-fluidique auto-oscillant pour la génération d’énergie utile à partir d’une source thermique de faible qualité. L’implémentation de cette technologie en tant que machine thermique est étudiée et mène à la caractérisation d’un nouveau cycle thermodynamique caractéristique du SOFHE (Self Oscillating Fluidic Heat Engine). Nous montrons, par une approche phénoménologique, que notre machine thermique se comporte comme un oscillateur mécanique, excité par les évaporations et condensations successives du fluide de travail. Ces changements de phase alternatifs mettent en mouvement une colonne d’eau, jouant le rôle de masse, couplée à une zone de vapeur, jouant le rôle d’un ressort. Une étude de l’influence du couplage du SOFHE avec un transducteur électromécanique, représenté par un oscillateur, mène à la conception et la fabrication d’une spirale piézoélectrique. L’intégration de cette spirale à notre machine thermique forme un générateur thermo-électrique dont les capacités de conversion sont démontrées par la charge d’une capacité. Finalement, la miniaturisation du principe thermo-fluidique SOFHE est rendue possible par la réalisation d’un procédé de fabrication utilisant les techniques MEMS. Des dispositifs miniatures parviennent à exhiber un comportement oscillatoire montrant le potentiel d’intégration de cette technologie. / Abstract : The tremendous technological progresses realized in the last decades allow us to swarm our environment with Wireless Sensors Networks. These WSNs combine the MEMS’ miniature size and low energy consumption, and the powerful Internet communication protocols. This Internet of Things shows great potential in many applications such as industry or housing. For a decade now, the Energy Harvesting community wants to build autonomous WSNs by enabling them to feed off energy wastes. In this work, we study the electricity generation capabilities of a Self-Oscillating Fluidic Heat Engine (SOFHE) and present its characteristic thermodynamic cycle. Our model shows that the SOFHE acts as a mechanical resonator excited by the successive evaporation and condensation processes underwent by the working fluid. These phase changes put a liquid mass in motion, coupled with a vapor spring. The coupling of our heat engine with an electromechanical transducer is studied and leads to a piezoelectric spiral conception and fabrication. Their association forms a thermo-electrical generator able to power and charge an electrical capacitor. Eventually, we demonstrate the miniaturization prospects and integration potential of this SOFHE technology. A micro-fabrication process enables a SOFHE MEMS implementation. Our process includes a deep glass wet etching step as well as a Au-Si eutectic wafer bonding.

Récupération d'énergie thermique

Auto-oscillations

Oscillateur thermofluidique

SOFHE

Spirale piézoélectrique

Procédés MEMS

Collage eutectique

Heat energy harvesting

Thermodynamic cycle

Piezoelectric spiral

MEMS fabrication processes

Eutectic bonding

Analytical and Numerical Modeling for Heat Transport in a Geothermal Reservoir due to Cold Water Injection

Ganguly, Sayantan

January 2014

Geothermal energy is the energy naturally present inside the earth crust. When a large volume of hot water and steam is trapped in subsurface porous and permeable rock structure and a convective circulating current is set up, it forms a geothermal reservoir. A geothermal system can be defined as - convective water in the upper crust of earth, which transfers heat from a heat source (in the reservoir) to a heat sink, usually the free surface. A geothermal system is made up of three main elements: a heat source, a reservoir and a fluid, which is the carrier that transfers the heat. As an alternative source of energy geothermal energy has been under attention of the researchers for quite some time. The reason behind this is the existence of several benefits like clean and renewable source of energy which has considerable environmental advantage, with no chemical pollutants or wastes are generated due to geothermal emissions, and the reliability of the power resource. Hence research has been directed in several directions like exploration of geothermal resources, modeling the characteristics of different types of geothermal reservoirs and technologies to extract energy from them. The target of these models has been the prediction of the production of the hot water and steam and thus the estimation of the electricity generating potential of a geothermal reservoir in future years. In a geothermal power plant reinjection of the heat depleted water extracted from the geothermal reservoir has been a common practice for quite some time. This started for safe wastewater disposal and later on the technology was employed to obtain higher efficiency of heat and energy extraction. In most of the cases a very small fraction of the thermal energy present in the reservoir can be recovered without the reinjection of geothermal fluid. Also maintaining the reservoir pressure is essential which gradually reduces due to continuous extraction of reservoir fluid without reinjection, especially for reservoirs with low permeabilities. Although reinjection of cold-water has several benefits, the possibility of premature breakthrough of the cold-water front, from injection well zone to production well zone, reduces the efficiency of the reservoir operation drastically. Hence for maintaining the reservoir efficiency and longer life of the reservoir, the injectionproduction well scheme is to be properly designed and injection and extraction rates are to be properly fixed. Modeling of flow and heat transport in a geothermal reservoir due to reinjection of coldwater has been attempted by several researchers analytically, numerically and experimentally. The analytical models which exist in this field deal mostly with a single injection well model injecting cold-water into a confined homogeneous porous-fractured geothermal reservoir. Often the thermal conductivity is neglected in the analytical study considering it to be negligible which is not always so, as proved in this study. Moreover heterogeneity in the reservoir is also a major factor which has not been considered in any such analytical study. In the field of numerical modeling there also exists a need of a general coupled three-dimensional thermo-hydrogeological model including all the modes of heat transport (advection and conduction), the heat loss to the confining rocks, the regional groundwater flow and the geothermal gradient. No study existing so far reported such a numerical model including those mentioned above. The present study is concerned about modeling the non-isothermal flow and heat transport in a geothermal reservoir due to reinjection of heat depleted water into a geothermal reservoir. Analytical and numerical models are developed here for the transient temperature distributions and advancement of the thermal front in a geothermal reservoir which is generated due to the cold-water injection. First homogeneous geothermal aquifers are considered and later heterogeneities of different kinds are brought into picture. Threedimensional numerical models are developed using a software code DuMux which solves flow and heat transport problems in porous media and can handle both single and multiphase flows. The results derived by the numerical models have been validated using the results from the analytical models derived in this study. Chapter 1 of the thesis gives a brief introduction about different types of geothermal reservoirs, followed by discussion on the governing differential equations, the conceptual model of a geothermal reservoir system, the efficiency of geothermal reservoirs, the modeling and simulation concepts (models construction, boundary conditions, model calibration etc.). Some problems related with geothermal reservoirs and geothermal power is also discussed. The scenario of India in the context having a huge geothermal power potential is described and different potential geothermal sites have been pointed out. In Chapter 2, the concept of reinjection of the heat depleted (cold) water into the geothermal reservoir is introduced. Starting with a brief history of the geothermal reinjection, the chapter describes the purpose and the need of reinjection of geothermal fluid giving examples of different geothermal fields over the world where reinjection has been in practice and benefitted by that. The chapter further discusses on the problems and obstacles faced by the geothermal projects resulting from the geothermal reinjection, most important of which is the thermal-breakthrough and cooling of production wells. Lastly the problem of this thesis is discussed which is to model the transient temperature distribution and the movement of the cold-water thermal front generated due to the reinjection. The need of this modeling is elaborated which represents the motivation of taking up the problem of the thesis. Chapter 3 describes an analytical model developed for the transient temperature in a porous geothermal reservoir due to injection of cold-water. The reservoir is composed of a confined aquifer, sandwiched between rocks of different thermo-geological properties. The heat transport processes considered are advection, longitudinal conduction in the geothermal aquifer, and the conductive heat transfer to the underlying and overlying rocks of different geological properties. The one-dimensional heat transfer equation has been solved using the Laplace transform with the assumption of constant density and thermal properties of both rock and fluid. Two simple solutions are derived afterwards, first neglecting the longitudinal conductive heat transport and then heat transport to confining rocks. The analytical solutions represent the transient temperature distribution in the geothermal aquifer and the confining rocks and model the movement of the cold-water thermal front in them. The results show that the heat transport to the confining rocks plays an influential role in the transient heat transport here. The influence of some parameters, e.g. the volumetric injection rate, the longitudinal thermal conductivity and the porosity of the porous media, on the transient heat transport phenomenon is judged by observing the variation of the transient temperature distribution with different values of the parameters. The effects of injection rate and thermal conductivity have been found to be high on the results. Chapter 4 represents another analytical model for transient temperature distribution in a heterogeneous geothermal reservoir underlain and overlain by impermeable rocks due to injection of cold-water. The heterogeneity of the porous medium is expressed by the spatial variation of the flow velocity and the longitudinal effective thermal conductivity of the medium. Simpler solutions are also derived afterwards first neglecting the longitudinal conduction, then the heat loss to the confining rocks depending on the situation where the contribution of them to the transient heat transport phenomenon in the porous media is negligible. Solution for a homogeneous aquifer with constant values of the rock and fluid parameters is also derived with an aim to compare the results with that of the heterogeneous one. The effect of heat loss to the confining rocks in this case is also determined and the influence of some of the parameters involved, on the transient heat transport phenomenon is assessed by observing the variation of the results with different magnitudes of those parameters. Results show that the heterogeneity plays a major role in controlling the cold-water thermal front movement. The transient temperature distribution in the geothermal reservoir depends on the type of heterogeneity. The heat loss to the confining rocks of the geothermal aquifer also has influence on the heat transport phenomenon. In Chapter 5 another analytical model is derived for a heterogeneous reservoir where the heterogeneous geothermal aquifer considered is a confined aquifer consisted of homogeneous layers of finite length and overlain and underlain by impermeable rock media. All the different layers in the aquifer and the overlying and underlying rocks are of different thermo-hydrogeological properties. Results show that the advancement of the cold-water thermal front is highly influenced by the layered heterogeneity of the aquifer. As the cold-water thermal front encounters layers of different thermo-hydrogeological properties the movement of it changes accordingly. The analytical solution derived here has been compared with a numerical model developed by the multiphysics software code COMSOL which shows excellent agreement with each other. Lastly it is shown that approximation of the properties of a geothermal aquifer by taking mean of the properties of all the layers present will lead to erroneous estimation of the temperature distribution. Chapter 6 represents a coupled three-dimensional thermo-hydrogeological numerical model for transient temperature distribution in a confined porous geothermal aquifer due to cold-water injection. This 3D numerical model is developed for solving more practical problems which eliminate the assumptions taken into account in analytical models. The numerical modeling is performed using a software code DuMux as mentioned before. Besides modeling the three-dimensional transient temperature distribution in the model domain, the chapter investigates the regional groundwater flow has been found to be a very important parameter to consider. The movement of the thermal front accelerates or decelerates depending on the direction of the flow. Influence of a few parameters involved in the study on the transient heat transport phenomenon in the geothermal reservoir domain, namely the injection rate, the permeability of the confining rocks and the thermal conductivity of the geothermal aquifer is also evaluated in this chapter. The models have been validated using analytical solutions derived in this thesis. The results are in very good agreement with each other. In Chapter 7 the main conclusions drawn from the study have been enlisted and the scope of further research is also pointed out.

Geothermal Energy

Heat Transport

Geothermal Reservoirs

Cold Water Injection

Geothermal Reinjection

Geothermal Reservoirs System Model

Thermo-Hydrogeological Numerical Model

Geothermal Systems

Geothermal Reservoir System

Heat Energy

Geothermal Reservoir

Thermal Energy Storage System

Geothermal Energy

Civil Engineering