Global ETD Search

1	Heat transfer in mixing vessels using induction heated impellers Linn, Linsey Margaret January 1989 (has links) No description available. 536.7 Batch vessel heating/cooling
2	Establishing design criteria for the incorporation of highly glazed spaces into the domestic building envelope Swann, Barbara January 1996 (has links) This thesis investigates the design of domestic glazed spaces in the United Kingdom, by studying the effect of a range of variables on the thermal properties of glazed spaces, in order to achieve a thermally comfortable environment while minimising the use of energy for heating and cooling. Earlier research work on domestic glazed spaces has concentrated on optimising the design of the space as a mechanism for reducing the space heating load of the parent house. Computer based dynamic thermal simulation is used in this study as the method of assessment and the variables tested are; glazing type, orientation and the degree of integration of the glazed space with the parent building. Unshaded, unventilated, and unheated, glazed spaces were found to be thermally comfortable for only a quarter to a third of the hours of possible use whatever the form, orientation or glazing type. Generally the higher the insulating value of the glazing the fewer the number of comfortable hours for all orientations and arrangements, due to discomfort being caused by high temperatures, even though the weather data used for the simulations only rose above 27'C for 25 hours during the course of the year. Further studies showed that significant reductions in the number of hours experiencing high temperatures could be achieved by the use of buoyancy driven ventilation. The studies indicated that glazed spaces integrated into the house plan tended to experience high temperatures for long periods but that the peak temperatures were much lower than those experienced for shorter periods in the exposed spaces. The effect of ventilation on overheating was therefore more marked in the integral than in the exposed glazed spaces. A study of the effects of roof shading blinds indicated that internal blinds had minimal effect in reducing high temperatures. External blinds had a greater effect than ventilation and a combination of external roof blinds and ventilation appears to provide the best strategy for the control of high temperatures. Studies on space heating loads for the houses and glazed spaces indicated wide variations in the heating loads of the glazed spaces depending predominantly on the insulating properties of the glazing. In terms of the reduction in the space heating load for the parent house, the thermal simulation results predict very little change due to the presence of the glazed space. A study on the effect of increasing the thermal storage properties of the floor construction of the glazed spaces, by substituting a clay tile finish for the original thin carpet layer, in order to reduce high temperatures proved inconclusive with minimal changes in the number of comfortable hours experienced. An investigation of thermal comfort during the Winter indicated that low surface temperatures did not reduce resultant temperatures below the lower limit of the comfortable range in the glazed spaces, during the heated period. 697 Heating; Cooling; Thermal comfort
3	Soft Heating and Cooling in Humid Climates Karlström, Petra January 2004 (has links) No description available. heating cooling Civil Engineering Samhällsbyggnadsteknik
4	Investigation and improvement of ejector-driven heating and refrigeration systems Al-Ansary, Hany A. M., January 2004 (has links) (PDF) Thesis (Ph. D.)--School of Mechanical Engineering, Georgia Institute of Technology, 2004. Directed by Sheldon M. Jeter. / Vita. Includes bibliographical references (leaves 195-201).
5	Optimization of Thermal Energy Storage Sizing Using Thermodynamic Analysis Villanueva, Andrew 27 August 2020 (has links) The aim of this thesis is to examine the effect that Thermal Energy Storage (TES) sizing has on a building’s ability to meet heating and cooling demands in an energy and cost efficient manner. The focus of the research is the quantification the effects of TES for system sizing and boiler cycling. Research is accomplished by modelling TES systems with various storage capacities using thermodynamic analysis. Energy costs are subject to increase during peak usage periods due to a limited supply of energy. Peak heating and cooling periods also force thermal systems to be sized for loads that are only experienced for a small fraction of the year leading to poor efficiencies and frequent cycling during off peak times of year. TES introduces the capability to mitigate this issue by shifting peak thermal loads from one period to another, theoretically reducing the minimum necessary boiler or chiller capacity for a given system and potentially improving the efficiency of 4 thermal systems. The scope of this research is to model the operation of thermal systems with varying storage capacities in order to quantify these capabilities with respect to capacity and cycling. This is accomplished with modelling in Transient Systems Simulation Program (TRNSYS). In this software, a simple heating loop and cooling loop are independently considered and subjected to hourly load data extrapolated from heating and cooling load data originating from a retirement community in Massachusetts. The model built is intended to be robust enough to be easily applied and adapted to assess similar problems with energy storage capacity sizing. Construction Engineering Energy Systems
6	Living with nature the Farnsworth House and the environmental successes and failures of Modernist architecture Williams, James J., M.B.A. January 2015 (has links) No description available. Architectural Engineering Environmental Comforts Mechanical Systems Passive Heating Cooling
7	Control and energy optimization of ground source heat pump systems for heating and cooling in buildings Cervera Vázquez, Javier 30 June 2016 (has links) [EN] In a context of global warming concern and global energy policies, in which heating and cooling systems in buildings account for a significant amount of the global energy consumption, ground source heat pump (GSHP) systems are widely considered as being among the most efficient and comfortable heating and cooling renewable technologies currently available. Nevertheless, both an optimal design of components and an optimal operation of the system as a whole become crucial so that these systems can have a significant contribution to the attenuation of the global energy problem. The overall objective of this PhD dissertation is to perform the control and energy optimization of an experimental GSHP system installed at the Universitat Politècnica de València, making the control system adaptive to the thermal demand of the building and to the climate conditions. For that purpose, different control strategies are proposed, described, developed, implemented and tested in the system. The optimization of any system requires a comprehensive study of its behaviour, by means of a thorough analysis of all the variables and parameters implied on its performance. Therefore, the first step is to analyse the short-term performance of the system, but also the long-term performance based on the experimental data collected at the installation. Second and prior to developing any optimization strategies, it is important to analyse the optimal configuration of the system according to the objectives targeted. This objective includes the study of the best location for the temperature control sensor and the buffer tank, as well as an adequate size for this buffer tank. Finally, once the behaviour of the system has been fully understood, the components of the system are the most efficient according to the possibilities of the research work and they have been connected adequately, the final objective is to develop control and optimization strategies which optimize the operation of the experimental GSHP system. These strategies target the control of the heat pump compressor, but also and more importantly, the energy optimization of the complete system. The focus is not in optimizing the performance of each individual component, but in optimizing the energy performance of the system working as a whole. In this direction, a first approach which combined a temperature compensation strategy and the variation of the frequency of the water circulation pumps, and hence the flow rate, as a function of the thermal load of the building, was first attempted. The application of this first approach resulted in significant energy savings, but also in a lack of user comfort in some of the offices under extreme weather conditions during summer. Consequently, the control and optimization methodology has been upgraded in a global algorithm (which is the final result of this PhD thesis) which couples both strategies in order to ensure the user comfort while keeping significant energy savings. In brief, this PhD work provides a comprehensive experimental study for the energy optimization of a GSHP system for both cooling and heating operation. Experimental results for a one-year operation period demonstrate important energy savings when compared to the standard control operation, up to 35% in the summer season and 53% in the winter season, while keeping the user comfort. / [ES] En un contexto de creciente preocupación por el calentamiento global y de políticas energéticas internacionales, en el cual los sistemas de climatización en edificios representan una parte importante del consumo energético global, los sistemas de bomba de calor geotérmica están ampliamente considerados como una de las tecnologias de climatización de espacios más eficientes disponibles en la actualidad. Sin embargo, tanto un buen diseño de los componentes como una óptima operación del sistema son de vital importancia para que estos sistemas puedan contribuir de manera significativa a atenuar el problema energético global. El objetivo general de esta tesis doctoral es el control y la optimización energética de una instalación experimental de bomba de calor geotérmica construida en la Universitat Politècnica de València, haciendo que el sistema de control se adapte a la demanda térmica del edificio y a las condiciones climatológicas. Para ello, se proponen diferentes estrategias de control, las cuáles son descritas, desarrolladas, implementadas y evaluadas a lo largo de este trabajo de investigación. La optimización de cualquier sistema requiere un amplio estudio de su comportamiento, analizando concienzudamente todas las variables y parámetros implicados en su funcionamiento. Por tanto, el primer paso llevado a cabo es el análisis de los días típicos de funcionamiento de la instalación, pero también su comportamiento a más largo plazo, a partir de los datos experimentales recogidos. En segundo lugar, y como paso previo al desarrollo de las estrategias de optimización, es importante analizar la configuración óptima del sistema de acuerdo con los objetivos perseguidos. Este objetivo incluye el estudio de la posición del sensor de temperatura empleado para el control y del depósito de inercia, así como el dimensionamiento adecuado de este depósito. Finalmente, una vez se ha analizado en profundidad el funcionamiento del sistema, los componentes del mismo son lo más eficientes posible, y éstos han sido conectados de manera adecuada, el objetivo final es el desarrollo de estrategias de control y optimización energética que optimicen la operación de la instalación experimental de bomba de calor geotérmica. Estas estrategias se dirigen principalmente a la optimización del sistema completo. El objetivo no es optimizar el funcionamiento de cada componente de manera individual, sino optimizar el comportamiento energético del sistema trabajando como un todo. En este sentido, se desarrolló una primera metodología que combinaba la compensación de la temperatura de consigna de la bomba de calor en función de la temperatura ambiente exterior, y la variación de la frecuencia de las bombas de circulación (y por tanto el caudal de agua) en función de la carga térmica del edificio. La aplicación de esta primera estrategia resultó en una importante mejora del rendimiento energético, pero también en la pérdida de confort en algunas de las oficinas climatizadas cuando las condiciones climatológicas eran extremas durante el verano. En consecuencia, la metodología de control y optimización desarrollada fue mejorada dando como resultado un algoritmo global de optimización energética (que es el resultado final de esta tesis), el cual acopla ambas estrategias anteriores de manera que se cumpla el confort del usuario y se mantenga un ahorro de energía significativo. En resumen, esta tesis doctoral proporciona un estudio experimental exhaustivo de la optimización energética de un sistema de bomba de calor geotérmica para la climatización de un edificio de oficinas. Los resultados experimentales para un año completo de funcionamiento del sistema muestran un ahorro de energía significativo en comparación con el modo de control de referencia, hasta un 35% en modo refrigeración y un 53% en modo calefacción, a la vez que se mantiene el confort de los usuarios. / [CAT] En un context de creixent preocupació per l'escalfament global i de polítiques energètiques internacionals, en el qual els sistemes de climatització en edificis representen una part important del consum energètic global, els sistemes de bomba de calor geotèrmica estan amplament considerats com una de les tecnologies de climatització més eficients disponibles en la actualitat pel que fa a la climatització d'espais. No obstant això, tant un bon disseny dels components com una operació òptima del sistema són de vital importància per tal que aquests sistemes puguen contribuir de manera significativa a atenuar el problema energètic global. L'objectiu general d'aquesta tesi doctoral és el control i l'optimització energètica d'una instal·lació experimental de bomba de calor geotèrmica construïda a la Universitat Politècnica de València, fent que el sistema de control s'adapte a la demanda tèrmica de l'edifici i a les condicions climatològiques. Amb aquest objectiu, es proposen diferents estratègies de control, les quals són descrites, desenvolupades, implementades i avaluades al llarg d'aquest treball d'investigació. L'optimització de qualsevol sistema requereix un ampli estudi del seu comportament, analitzant conscienciosament totes les variables i paràmetres implicats en el seu funcionament. Per tant, el primer pas duit a terme és l'anàlisi dels dies típics de funcionament de la instal·lació, però també el seu comportament a més llarg termini, a partir de les dades experimentals recollides. En segon lloc, i com pas previ al desenvolupament de les estratègies d'optimització, és important analitzar la configuració òptima del sistema d'acord als objectius perseguits. Aquest objectiu inclou l'estudi de la posició del sensor de temperatura emprat pel control i del dipòsit d'inèrcia, així com el correcte dimensionament d'aquest dipòsit. Finalment, una vegada s'ha analitzat en profunditat el funcionament del sistema, els components d'aquest són el més eficients possible, i han sigut connectats de manera adequada, l'objectiu final és el desenvolupament d'estratègies de control i optimització energètica les quals optimitzen l'operació de la instal·lació experimental de bomba de calor geotèrmica. Aquestes estratègies es dirigeixen principalment a l'optimització del sistema complet. L'objectiu no és optimitzar el funcionament de cada component de manera aïllada, sinó més bé optimitzar el comportament energètic del sistema treballant com un tot. En aquest sentit, es va desenvolupar una primera metodologia que combinava la compensació de la temperatura de consigna de la bomba de calor en funció de la temperatura ambient exterior, i la variació de la freqüència de les bombes de circulació (i per tant del cabdal d'aigua) en funció de la càrrega tèrmica de l'edifici. L'aplicació d'aquest primer apropament va resultar en una important millora del rendiment energètic, però també en la pèrdua de confort en algunes de les oficines climatitzades quan les condicions climatològiques eren extremes durant l'estiu. En conseqüència, la metodologia de control i optimització desenvolupada va ser millorada resultant en un algoritme global d'optimització energètica (resultat principal d'aquesta tesi), el qual acobla ambdues estratègies anteriors de manera que es complisca el confort de l'usuari i es mantinga un important estalvi d'energia. En resum, aquesta tesi doctoral proporciona un estudi experimental exhaustiu de l'optimit\-zació energètica d'un sistema de bomba de calor geotèrmica per la climatització d'un edifici d'oficines. Els resultats experimentals per un any complet de funcionament del sistema mostren un estalvi d'energia significatiu en comparació amb el mode de control de referencia, fins un 35% en mode refrigeració i un 53% en mode calefacció, a la vegada que es manté el confort dels usuaris. / Cervera Vázquez, J. (2016). Control and energy optimization of ground source heat pump systems for heating and cooling in buildings [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/66748 / TESIS Heating/cooling systems Ground source heat pump Energy efficiency Optimization MAQUINAS Y MOTORES TERMICOS
8	Behavior Of Cfrp Confined Concrete Specimens Under Temperature Cycles And Sustained Loads Erdil, Baris 01 February 2012 (has links) (PDF) The application of carbon fiber reinforced polymers (CFRP) is one of the effective retrofitting and strengthening methods that is used worldwide and is starting to be used in Turkey as well because they have high strength and high modulus in the fiber direction, have very low coefficient of thermal expansion when compared to concrete and steel and are known not to corrode. Since FRPs are lightweight, their mass can be neglected when compared to concrete and steel. However, before proposing this material as an alternative for strengthening and retrofitting applications their long-term behavior should be understood because they are applied on to concrete by several layers of epoxy-based adhesives, which can be affected by change in humidity, temperature and load. Therefore, behavior of CFRP-strengthened structures in varying temperature and humidity conditions must be investigated. In this dissertation, behavior of CFRP confined cylindrical and prismatic concrete specimens having square cross-section were investigated under sustained compressive loads, dry and wet heating-cooling cycles, and outdoor exposures under direct sunlight, to determine the possible changes in their mechanical properties. Sustained loads were applied as the 40% and 50% of their confined axial load capacity. In addition to the sustained loads, specimens were subjected to 200 heating-cooling cycles between -10&deg / C to 50&deg / C. In order to understand the change in behavior of CFRP confined concrete specimens better, they were divided in six groups. A single effect was investigated in each group. After aging tests mechanical properties of the specimens were recorded via monotonic uniaxial loading. It was observed that temperature cycles had little effect on behavior but sustained loads changed the shape of the axial stress-strain diagram and resulted in a dramatic decrease in ultimate strain. Based on the test results and also using the data of similar studies available in the literature, strength and strain models considering the exposures as independent parameters were established and finally axial stress-strain curve was tried to be predicted.
9	Gyvenamojo namo šildymo ir vėdinimo sistemos kompiuterinio valdymo modelio sudarymas ir tyrimas naudojant miglotąją logiką / Modeling and analysis of house heating and cooling computer control system using fuzzy logic Jasaitis, Vytautas 22 May 2005 (has links) Presently information systems are increasingly penetrating to our daily life. Recently it is relevant to integrate the newest technologies. In that way traditional system becomes “smart” who are more economical, optimal, and self-sufficient. The biggest problem is to make a model of “smart” system. There were analyzed modeling methods, heating and cooling control systems in this job. Mathematical model for heating and cooling controller using fuzzy logic was presented. According to analyzed problems it was made verification with Matlab during experimental phase. There was made comparison evaluation of mathematical model made with fuzzy logic and timed Petri nets. Informatics Fuzzy logic Realiojo laiko sistema Real time system Miglotoji logika Heating cooling system Šildymo vėdinimo sistema
10	From Archaic To contemporary : Energy Efficient Adaptive Reuse of Historic Building Borgohain, Nisha 29 October 2019 (has links) Over recent decades, the global focus on climate change and on conservation of resources has brought about a paradigm shift in the adaptive reuse of old and historic buildings. Adaptive reuse is now seen as a key factor in the conservation of land and environment, preservation of cultural identity, and reduction of urban sprawl. Increasingly, engineers, architects, and urban planners are making concerted efforts to realize the reuse potential of existing and outdated structures. Therefore, those involved in building design have studied the viability of adaptive reuse and generally favor the repurposing of old/historic buildings to suit new patterns of occupancy and use without disturbing the environment or increasing carbon footprints. Redesign and reconstruction through refurbishment, remodeling, renewal, repair and retrofitting is carried out to meet new requirements and provide performance that was not in the original design. Buildings are one of the largest energy users in the United States.[1] In total, buildings used around 40 percent of energy in 2015, which accounts for the largest share among forms of energy consumption. Many of the buildings are not energy efficient but do have historic value; while giving them a new purpose, their historic legacy can also be preserved. There are many challenges like program modification feasibility, structural issues and energy efficiency which need to be addressed during pre-construction and can be addressed by careful planning and innovative techniques. To understand the various challenges involving adaptive reuse, this study employs the Clark Hall at the University of Massachusetts to test the efficacy of design and performance interventions. Clark Hall was originally used for science classes and botany research and later was converted into painting studios. Presently the building structure is still intact, provides enough room for program modification, and has significant reuse potential. Therefore, Clark Hall is a suitable candidate for adaptive reuse as an academic office building that satisfies contemporary building standards and meets the growing demand for office space. Through this project, an attempt has been made to explore and understand the complexities and challenges as well as the various possible ways to change the function of Clark Hall from a defunct structure to a modern energy efficient and environmentally sustainable academic office building with measures for energy conservation through contemporary innovative design approaches. The research work begins with a background study of the building’s history and its different purposes, along with three precedent studies of contemporary and innovative design examples. It also identifies relevant local, federal, and state building and zoning regulations and incorporates existing energy-saving technologies and materials appropriate to Clark Hall. Keeping in mind the financial viability of project, an attempt has been made to control and bring down the operating and the maintenance costs by carrying out extensive energy modelling and simulations to support these recommendations. In conclusion, the final outcome of my project is a design plan for the adaptive reuse of Clark Hall as a new energy efficient and environmentally sustainable office building for the benefit and the use of University of Massachusetts Amherst that mitigates costs and improves design utility and aesthetics, while preserving its historic value. [1] According to the U.S. Energy Information Administration, “in 2017, about 39% of total U.S. energy consumption was consumed by the residential and commercial sectors.” https://www.eia.gov/tools/faqs/faq.php?id=86&t=1. October 2018. Adaptive Reuse Energy Efficiency Historic Preservation Building Simulation Renewable Strategies Heating/Cooling Lighting Architectural Technology Historic Preservation and Conservation

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