Global ETD Search

1	The simulation and design of building attached sunspaces Parsons, Brian Keith. January 1900 (has links) Thesis (M.S.)--University of Wisconsin--Madison, 1983. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 181-184). Solar space heating.
2	Design of air heaters using waste oil as fuel Zolghadr, M. January 1987 (has links) No description available. 697 Space heating using waste oils
3	Computer Modeling of Solar Thermal System with Underground Storage Tank for Space Heating Naser, Mohammad Yousef Mousa 13 May 2021 (has links) No description available. Mechanical Engineering Solar Energy Space Heating CFD
4	Measuring and modelling the energy demand reduction potential of using zonal space heating control in a UK home Beizaee, Arash January 2016 (has links) Most existing houses in the UK have a single thermostat, a timer and conventional thermostatic radiator valves to control the low pressure, hot water space heating system. A number of companies are now offering a solution for room-by-room temperature and time control in such older houses. These systems comprise of motorised radiator valves with inbuilt thermostats and time control. There is currently no evidence of any rigorous scientific study to support the energy saving claims of these zonal control systems. This thesis quantifies the potential savings of zonal control for a typical UK home. There were three components to the research. Firstly, full-scale experiments were undertaken in a matched pair of instrumented, three bedroom, un-furbished, 1930s, test houses that included equipment to replicate the impacts of an occupant family. Secondly, a dynamic thermal model of the same houses, with the same occupancy pattern, that was calibrated against the measured results. Thirdly, the experimental and model results were assessed to explore how the energy savings might vary in different UK climates or in houses with different levels of insulation. The results of the experiments indicated that over an 8-week winter period, the house with zonal control used 12% less gas for space heating compared with a conventionally controlled system. This was despite the zonal control system resulting in a 2 percentage point lower boiler efficiency. A calibrated dynamic thermal model was able to predict the energy use, indoor air temperatures and energy savings to a reasonable level of accuracy. Wider scale evaluation showed that the annual gas savings for similar houses in different regions of the UK would be between 10 and 14% but the energy savings in better insulated homes would be lower. 697
5	Evaluating building energy performance : a lifecycle risk management methodology Doylend, Nicholas January 2015 (has links) There is widespread acceptance of the need to reduce energy consumption within the built environment. Despite this, there are often large discrepancies between the energy performance aspiration and operational reality of modern buildings. The application of existing mitigation measures appears to be piecemeal and lacks a whole-system approach to the problem. This Engineering Doctorate aims to identify common reasons for performance discrepancies and develop a methodology for risk mitigation. Existing literature was reviewed in detail to identify individual factors contributing to the risk of a building failing to meet performance aspirations. Risk factors thus identified were assembled into a taxonomy that forms the basis of a methodology for identifying and evaluating performance risk. A detailed case study was used to investigate performance at whole-building and sub-system levels. A probabilistic approach to estimating system energy consumption was also developed to provide a simple and workable improvement to industry best practice. Analysis of monitoring data revealed that, even after accounting for the absence of unregulated loads in the design estimates, annual operational energy consumption was over twice the design figure. A significant part of this discrepancy was due to the space heating sub-system, which used more than four times its estimated energy consumption, and the domestic hot water sub-system, which used more than twice. These discrepancies were the result of whole-system lifecycle risk factors ranging from design decisions and construction project management to occupant behaviour and staff training. Application of the probabilistic technique to the estimate of domestic hot water consumption revealed that the discrepancies observed could be predicted given the uncertainties in the design assumptions. The risk taxonomy was used to identify factors present in the results of the qualitative case study evaluation. This work has built on practical building evaluation techniques to develop a new way of evaluating both the uncertainty in energy performance estimates and the presence of lifecycle performance risks. These techniques form a risk management methodology that can be applied usefully throughout the project lifecycle. 696
6	Wind Allocation Methods for Improving Energy Security in Residential Space and Hot Water Heating Lakshminarayanan, Harisubramanian 22 August 2012 (has links) Worldwide, wind energy added to the energy mix of electricity suppliers may be seen as way of improving energy security and reducing greenhouse gas emissions. However, due to wind's variability wind electricity cannot be used to meet demands which require a continuous supply of electricity. One solution to the variability problem is to adopt services that are capable of storing energy for use at a later time. Five new wind-allocation methods are considered to maximize its use of wind-electricity while at the same time reducing emissions. Simulations results, show that households benefit from an annual savings of about 30% to 36% with an estimated payback period ranging between 3.5 and 5.5 years. Emissions reduction in the off-peak scenarios is between 32% and 35% and about 86% in the anytime scenario. Heating demands satisfied ranges between 75% and 96% and total wind used for heating is between 3%-4%. Energy Security Wind Electricity Allocation Allocation Methods Space Heating Electric Thermal Storage Energy Storage
7	Vytápění a větrání v rodinném domě typu bungalov / Space heating and ventilation in a bungalow family house Menšík, Marek January 2018 (has links) This diploma thesis deals with design of ventilation and heating of bungalow single-storey house. The work is divided into three parts. In the first part is presented the design of the house with calculation of heat losses. The second part deals with the design, calculations and regulation of the heating of the house. In the third part there is designed a system of forced ventilation for the house.
8	Exploring the technological potential for improving energy efficiency of residential space heating in the UK by 2050 Demdoum, Sofian January 2017 (has links) The UK has pledged to reduce its greenhouse gas emissions by 80% by 2050, compared to 1990 levels. With the residential sector accounting for roughly a quarter of the UK's total carbon emissions, and with space heating accounting for roughly two thirds of residential energy consumption, addressing heating demand will prove instrumental for the UK to reach its targets. The large-scale deployment of low-carbon heating technologies, combined with signicant improvements in energy efficiency, is seen as the primary way of reducing both energy demandand carbon emissions. In this thesis, the technical potential for energy efficiency improvements in the UK's residential space heating sector is explored. Three areas of improvement are identied: the thermal performance of the building envelope, the efficiency of heating equipment, and the use of smartheating devices. In all three areas, signicant potential exists to further reduce energy demand for space heating, and the associated carbon emissions. To understand the effects of different technology adoption patterns on energy demand for spaceheating by 2050, a selectively disaggregated bottom-up model of the UK's building stock is developed. The model projects energy demand for space heating for four different technologyadoption scenarios, based on projections of future total heated oor area. In the `Minimal effort' scenario, which assumes that the least possible amount of effort is made to improve the effciency of the space heating sector, energy demand by 2050 increases slightly, by 4.3 %. In this scenario, the achieved minor effciency improvements are not able to offset the increase in the total heated oor area, leading to this small increase in space heating energydemand. In the `Efficiency focus' scenario, which assumes that signicant effort is made to improve the efficiency of the space heating sector, energy demand by 2050 decreases by 34.5 %. Despite these signicant efficiency improvements, fossil fuels still make up roughly three quarters of the fuel mix, as no major shift to cleaner energy sources has been achieved. In contrast, in the `Renewables focus' scenario, which focuses on shifting towards renewable heating options, energy demand decreases slightly less, by only 32 %, but fossil fuels make up only around 46% of the fuel mix, due to the uptake of low-carbon options such as heat pumps, district heat, and biomass. The analysis carried out in this thesis shows that the UK's residential sector consists of manyold and inefficient buildings, still heavily relies on fossil fuel-fired heating equipment, and makes nearly no use of smart heating devices to further reduce energy demand for space heating. Clearly, the technical potential for achieving energy eficiency improvements is signicant, in all three of the identified improvement areas. However, achieving the targets set forth by policymakers will require strong efforts, given the relatively bad current condition of the residential space heating sector. Existing barriers to achieving these improvements should be identifiedand addressed immediately, to ensure timely efforts are possible. Energy Efficiency Residential Space heating United Kingdom Bottom-up 2050 Energy Engineering Energiteknik
9	Contribution au pilotage de la charge pour accroître la flexibilité du système électrique. Saker, Nathalie 30 January 2013 (has links) (PDF) Les défis environnementaux et l'augmentation de la population viennent en preuve de l'importance de réfléchir à d'autres moyens de production tout en maintenant la sécurité et la fiabilité du système électrique. La sûreté du système électrique exige à tout moment que la production soit égale à la demande des consommateurs, pour ça, différentes solutions sont déjà mises en place, ces solutions consistent à mettre en marche des moyens de pointes couteux et polluants pendant les périodes de pointes, mais comme les moyens de production son insuffisants et vue la difficulté d'exploitation de nouveaux moyens de production, une nouvelle réflexion sur la gestion de la demande est apparue; celle-ci se base sur la possibilité à gérer la demande du consommateur final au lieu de la satisfaire.L'objectif de la thèse est d'étudier la possibilité à rendre des services au système électrique en appliquant des actions de contrôle dites de DR (Demand Response), sur différents types de charges électriques. Ces actions de DR représentent des interruptions partielles appliquées sur les charges électriques de type thermique. Notre choix s'est basé sur ces types de charges parce que celles-ci emmagasinent de la chaleur respectivement dans l'air et dans l'eau; qui peut être restituée pendant la période de contrôle ou d'interruption. Néanmoins, il existe un effet négatif qui suit le contrôle de ces charges car l'énergie effacée de ces charges est reportée à l'instant de reconnexion de celles-ci; ce report prend la forme d'un pic de consommation nommé CLPU (Cold Load Pick-Up) et qui apparait au moment de la reconnexion. Le CLPU représente un problème qui doit être géré, et sa magnitude dépend des types d'actions de contrôle qu'on veut implanter et aussi des conditions du système électrique (contingence, défaillance d'une unité de production ou besoin de réserve de puissance). Pendant la thèse, le CLPU est contrôlé et optimisé ainsi que la puissance effacée. Un cas d'étude est présenté sur la contribution des actions de gestion de la demande à l'ajustement entre la demande et la production et l'effet généré sur le réglage secondaire de fréquence. [SPI:OTHER] Engineering Sciences/Other CLPU(Cold Load Pick - up) DR (Demand Response) Electric Space Heating Load Electric Water Heaters
10	Effects of Energy Performance Improving Measures on a 1990's Brick House in Southern Czech Republic : Computer Simulations using IDA-ICE Panek, Vaclav January 2023 (has links) The residential sector was responsible for 25% of the Final Energy Demand (FED) in the European Union in 2015. Countries in Central and Eastern Europe such as the Czech Republic are particularly concerned with ensuring security of supply at the lowest possible cost in recent years. FED for space heating still corresponds to the largest fraction of the total FED in the residential sector in the Czech Republic. The vast majority of buildings constructed in 1990- 2000 do not comply with current standards for thermal protection and owners often rely on their own financial means when attempting to improve the overall Energy Performance (EP) of buildings. The goal(s) associated with renovation- or refurbishment measures must be defined to clarify the extent of work and consequently minimize investments. The aim of this thesis, a case study, was to use a whole building energy simulation program (IDA-ICE) to get insight into the potential of different retrofitting measures (represented by scenarios) to improve EP of a single-family summer house located in the South Bohemian Region of the Czech Republic. One of the simulated scenarios was the owner ́s suggestion to replace windows and entrance doors. The goal was to reduce FED for space heating to ≤50 kWh.m-2 floor area and year and by doing so attaining the status of a low-energy building. Simultaneously, reduced FED for space heating was supposed to be achieved without compromising air quality and should involve only the most efficient refurbishment measures to minimize the overall work. The scope was strictly limited to EP improving measures without consideration of mechanical ventilation or modification of the currently used space heating system. It was concluded that the owner's suggestion to merely replace windows and entrance doors would be an insufficient solution. SC-4 (i.e. the combined effect of windows and entrance doors replacement and the ground-floor insulation) and SC-5 (i.e. the combined effect of ground-floor insulation and the insulation of external walls and the roof) were deemed to represent the most optimal solutions from the simulated EP improving measures. The goal was achieved in both, i.e. 46.8 kWh.m-2 floor area and year in SC-4 and 44.3 kWh.m- 2 floor area and year in SC-5. Averages of zone air temperatures in selected zones were found to be more stable in SC-4, however, SC-5 performed better when comparing averages of CO2 concentration-values in selected zones on the first floor. Nevertheless, averages of relative humidity and CO2 concentration-values in all simulated scenarios were within the acceptable range of 35-60% and about 520 to 1000 ppm respectively (except for Bedroom 2 zone). Final energy demand Primary energy demand Energy performance Refurbishment Single-family house Space heating Engineering and Technology Teknik och teknologier

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