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Effect of control parameters on energy consumption of a room heating systemDesai, Nainan Vijay January 2011 (has links)
Photocopy of typescript. / Digitized by Kansas Correctional Industries
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Energy conservation in multi-family housing in a hot and humid climateWiltz, Simon Rogers January 1976 (has links)
Thesis. 1976. M.Arch.--Massachusetts Institute of Technology. Dept. of Architecture. / Microfiche copy available in Archives and Rotch. / Bibliography: leaves 66-67. / by Simon Wiltz. / M.Arch.
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Strategies for development of energy-efficient housing.Michaels, Harvey Gilbert January 1975 (has links)
Thesis. 1975. M.C.P.--Massachusetts Institute of Technology. Dept. of Urban Studies and Planning. / Bibliography: leaves 135-136. / M.C.P.
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Energy conservation : its potential impact on future R.A.P. housing strategies.Nottingham, Dana January 1977 (has links)
Thesis. 1977. M.C.P.--Massachusetts Institute of Technology. Dept. of Urban Studies and Planning. / MICROFICHE COPY AVAILABLE IN ARCHIES AND ROTCH. / Includes bibliographical references. / M.C.P.
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Natural ventilation and solar control : design analysis of suburban Bangkok housing estatesChirattikalwong, Anawat January 2007 (has links)
The housing estates boom was and is a result of the Southeast Asia economic growth after the economic crisis between 1997 and 1998. Housing estates, especially in the suburbs of Bangkok, are designed by considering only aesthetics and costs without considering the negative effects that might occur to the occupants and nature. These negative effects lead to the insufficiency energy crisis.Determining how to reduce the energy used and increase the living quality in the building type is the critical question for architects to answer. Redesigning the housing estate using sustainable design concepts, especially with a focus on the natural ventilation and shading device strategies, can lift up the occupants' living quality because such design can provide cross ventilation through the house and solar shading to reduce the heat gain in the house. Not only would such design improvements make houses more comfortable for inhabitants, they also would reduce the energy use.The methodologies of research start with spatial analyses to define the general character of this type of house, then the redesigning of a selected existing house is used to focus on natural ventilation and shading devices design in order to improve the occupants living quality and to reduce the energy used in the house. It is hoped that this project can be the first step for other architects to understand the logic of natural ventilation and shading control design strategies within the realm of sustainability. / Department of Architecture
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Urban space heating with a heat pump-condenser temperature water systemYee, Wee Tong. January 1976 (has links)
Thesis: M.S., Massachusetts Institute of Technology, Department of Mechanical Engineering, 1976 / Includes bibliographical references. / by Wee T. Yee. / M.S. / M.S. Massachusetts Institute of Technology, Department of Mechanical Engineering
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Energy efficiency interventions for residential buildings in Bloemfontein using passive energy techniquesKumirai, Tichaona January 2010 (has links)
Thesis (M. Tech. (Mech. Eng.)) -- Central University of Technology, Free state, 2010 / The purpose of this research is to minimize the use of active systems in providing thermal comfort in single-family detached, middle to high income residential buildings in Bloemfontein. The typical case study house was selected according to the criteria as reviewed by Mathews et al., (1999).
Measurements were taken for seven days (18 – 24 May 2009). The measurements were carried out in the winter period for Bloemfontein, South Africa. Ecolog TH1, humidity and temperature data logger was used in doing the measurements. These measurements included indoor temperatures and indoor relative humidity.
Temperature swings of 8.43 ºC and thermal lag of 1 hour were observed. For the period of seven days (168 hours), the house was thermally comfortable for 84 hours.
Thermal analysis for the base case house was done using Ecotect™ (building analysis software) and the simulated results were compared with the measured results. A mean bias error (MBE) of between 10.3% ≤≤11.5% was obtained on the initial calibration. The final calibration of the model yielded error between0.364% ≤≤0.365%. The final calibration model which presented a small error was adopted as the base case.
Passive strategies were incorporated to the Ecotect™ model (final calibrated model) singly and in combination; then both thermal and space load simulations were obtained and compared to simulations from the original situation (base case) for assessing improvements in terms of thermal comfort and heating, ventilation and air conditioning (HVAC) energy consumption. Annual HVAC electricity savings of up to 55.2 % were obtained from incorporating passive strategies in combination. Incorporating passive strategies resulted in small improvements in thermal comfort.
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Evaluation of Phase Change Materials for Cooling in a Super-Insulated Passive HouseLauck, Jeffrey Stephen 03 October 2013 (has links)
Due to factors such as rising energy costs, diminishing resources, and climate change, the demand for high performance buildings is on the rise. As a result, several new building standards have emerged including the Passive House Standard, a rigorous energy-use standard based on a super-insulated and very tightly sealed building envelope. The standard requires that that air infiltration is less than or equal to 0.6 air changes per hour at a 50 Pascal pressure difference, annual heating energy is less than or equal to 15kWh/m2, and total annual source energy is less than or equal to 120 kWh/m2. A common complaint about passive houses is that they tend to overheat. Prior research using simulation suggests that the use of Phase Change Materials (PCMs), which store heat as they melt and release heat as the freeze, can reduce the number of overheated hours and improve thermal comfort.
In this study, an actual passive house duplex in Southeast Portland was thoroughly instrumented to monitor various air and surface temperatures. One unit contains 130kg of PCM while the other unit contains no PCM to serve as an experimental control. The performance of the PCM was evaluated through analysis of observed data and through additional simulation using an EnergyPlus model validated with observed data. The study found that installation of the PCM had a positive effect on thermal comfort, reducing the estimated overheated hours from about 400 to 200.
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A Feasibility Study of Model-Based Natural Ventilation Control in a Midrise Student Dormitory BuildingGross, Steven James 01 January 2011 (has links)
Past research has shown that natural ventilation can be used to satisfy upwards of 98% of the yearly cooling demand when utilized in the appropriate climate zone. Yet widespread implementation of natural ventilation has been limited in practice. This delay in market adoption is mainly due to lack of effective and reliable control. Historically, control of natural ventilation was left to the occupant (i.e. they are responsible for opening and closing their windows) because occupants are more readily satisfied when given control of the indoor environment. This strategy has been shown to be effective during summer months, but can lead to both over and under ventilation, as well as the associated unnecessary energy waste during the winter months. This research presents the development and evaluation of a model-based control algorithm for natural ventilation. The proposed controller is designed to modulate the operable windows based on ambient temperature, wind speed, wind direction, solar radiation, indoor temperature and other building characteristics to ensure adequate ventilation and thermal comfort throughout the year without the use of mechanical ventilation and cooling systems. A midrise student dormitory building, located in Portland OR, has been used to demonstrate the performance of the proposed controller. Simulation results show that the model-based controller is able to reduce under-ventilated hours to 6.2% of the summer season (June - September) and 2.5% of the winter (October - May) while preventing over-heating during 99% of the year. In addition, the model-based-controller reduces the yearly energy cost by 33% when compared to a conventional heat pump system. As a proactive control, model-based control has been used in a wide range of building control applications. This research serves as proof-of-concept that it can be used to control operable windows to provide adequate ventilation year-round without significantly affecting thermal comfort. The resulting control algorithm significantly improves the reliability of natural ventilation design and could lead to a wider adoption of natural ventilation in appropriate climate zones.
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