Relevant bibliographies by topics / 170103 Residential energy efficiency

Academic literature on the topic '170103 Residential energy efficiency'

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Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "170103 Residential energy efficiency"

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Korucan, Aysun, Serap Aşık, and Elif Akbostancı. "Residential Energy Efficiency: Turkish Case." Ekonomik Yaklasim 32, no. 121 (2021): 381. http://dx.doi.org/10.5455/ey.21002.

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Kabalan, A. "Consumers Energy Efficiency Practices." Advanced Materials Research 433-440 (January 2012): 3870–72. http://dx.doi.org/10.4028/www.scientific.net/amr.433-440.3870.

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This paper aims to give the consumer a list of energy saving practices in order to reduce the usage of energy in residential and commercial buildings. Such practices are crucial to any residential or commercial setting before embarking on installing renewable energy systems such as solar power systems. Those methods are relatively cheap to implement and has the potential to provide energy savings up to 30 %.
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Haid, Achim Andreas, and Ali Öztüren. "Energy Efficiency Perceptions in Residential Buildings." Open House International 40, no. 3 (September 1, 2015): 61–67. http://dx.doi.org/10.1108/ohi-03-2015-b0010.

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This study aims to understand the house owners' energy concerns. An exploratory inductive research design has been chosen to explore the perceptions of households towards the modernization of energy use in residential buildings. Face-to-face interviews with experts and households were conducted in Baden-Württemberg, Germany to collect the data. This study found that most of the house owners do not know about the benefits of increasing the energy performance in residential buildings and which energy efficiency potentials they can acquire. Additionally, house owners’ superficial knowledge creates fears and doubts concerning the modernization of energy use in residential buildings. Moreover, this study found that the local public administration, such as the municipalities, has a good reputation among households. Hence, public marketing activities should be run locally. It is suggested that the public administration should not conduct any public marketing activities without the support, for example, of the mayor. Further, it is necessary to supply the house owners with clear and understandable information on the topic and to demonstrate the functionality of the technologies to increase energy efficiency in residential buildings. Moreover, interpersonal communication such as a hotline and personal advisory service concerning energy-efficient refurbishment of residential buildings can be very beneficial to support the households. Local public administration should aim to introduce public marketing activities to enhance the modernization of energy use in residential buildings.
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Zacharioudakis, Emmanouil, Helen C. Leligou, and Aikaterini Papadopoulou. "Energy efficiency tools for residential users." MATEC Web of Conferences 125 (2017): 02066. http://dx.doi.org/10.1051/matecconf/201712502066.

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Fuinhas, José Alberto, Matheus Koengkan, Nuno Silva, Emad Kazemzadeh, Anna Auza, Renato Santiago, Mônica Teixeira, and Fariba Osmani. "The Impact of Energy Policies on the Energy Efficiency Performance of Residential Properties in Portugal." Energies 15, no. 3 (January 22, 2022): 802. http://dx.doi.org/10.3390/en15030802.

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The effect of energy policies on the energy performance of residential properties/houses in nineteen Portuguese districts from 2014 to 2021 was investigated. A linear random-effects model regression was used as the method in this empirical investigation. The empirical results indicated that the income per capita has a negative effect on residential properties with high energy efficiency certificates (e.g., A+, A, and B) and a positive impact on residential properties with low energy efficiency certificates (e.g., C, D, E, and F); the codes and standards energy policies for energy efficiency have a positive effect on residential properties with high energy efficiency certificates (e.g., A, B, and B−) and residential properties with low energy efficiency certificates (e.g., C, D, E, and F); the fiscal and financial incentive policies for energy efficiency have a positive effect on residential properties with high energy efficiency certificates (e.g., A+, A, and B) and a negative effect on residential properties with B− energy certificate, and also a negative effect on residential properties with low energy efficiency certificates (e.g., C and D) and a positive effect on residential properties with an F energy certificate; the information and education policies of energy efficiency have a positive effect on residential properties with high energy efficiency certificates (e.g., A+, A, and B) and residential properties with low energy efficiency certificates (e.g., C, D, and E); and, finally, the consumer credit per capita has a positive effect on residential properties with high energy efficiency certificates (e.g., A+, A, and B) and a negative effect on residential properties with low energy efficiency certificates (e.g., C, D, and F), as well as a positive effect on residential properties with an F energy certificate.
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GRIGORYEVA, N. "ESTIMATION OF ECONOMIC EFFICIENCY CONCEPT OF ENERGY EFFICIENCY MEASURES FOR RESIDENTIAL BUILDINGS." Экономическая наука сегодня, no. 6 (December 21, 2017): 199–208. http://dx.doi.org/10.21122/2309-6667-2017-6-199-208.

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The residential sector is a significant reserve for improving the energy efficiency of the Belarussian economy. Increasing the energy efficiency of residential buildings approaches are explored through a comprehensive concept for assessing the economic efficiency of energy efficiency measures. Four types of evaluation of the effectiveness of measures to improve the energy efficiency of residential buildings are defined: the economic cost estimation, the evaluation of economic results, the evaluation of social results, the evaluation of environmental results. Depending on the objectives and constraints set by stakeholders, inherent in each project, four models are identified for the formation of a project to improve the energy efficiency of residential buildings.
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Sumarac, Dragoslav, Maja Todorovic, Maja Djurovic-Petrovic, and Natasa Trisovic. "Energy efficiency of residential buildings in Serbia." Thermal Science 14, suppl. (2010): 97–113. http://dx.doi.org/10.2298/tsci100430017s.

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In this paper, presented is the state of the art of Energy Efficiency (EE) of residential buildings in Serbia. Special attention is paid to energy efficiency in already existing buildings. The average energy consumption in residential buildings in Serbia is over 150 kWh/m2 per year, while in developed European countries it is about 50 kWh/m2 per year. In this paper examined is the contribution of ventilation losses, through the windows of low quality, regardless whether they are poorly made, or made from bad materials, or with no adequate glass. Besides ventilation losses, which are of major importance in our buildings, special attention is paid to transmission losses, which are consequence of the quality and energy efficiency of the facade. All of the above statements are proved by measurements obtained on a representative building of the Block 34 in New Belgrade, built in the eighties of the last century. In addition to measurements performed the calculation of energy consumption for heating during winter has been made. The results of two different methods of calculation of energy consumption for heating are compared with the values obtained by measuring.
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Baquero L, María T., and Felipe Quesada M. "Energy efficiency in Cuenca’s residential sector, Ecuador." MASKANA 7, no. 2 (December 1, 2016): 147–65. http://dx.doi.org/10.18537/mskn.007.002.11.

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Glushkov, Sergey, Nikolay Kachalov, Elena Senkiv, and Victoriya Glushkova. "Estimation of energy efficiency of residential buildings." MATEC Web of Conferences 92 (December 21, 2016): 01072. http://dx.doi.org/10.1051/matecconf/20179201072.

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Collins, Matthew, and Seraphim Dempsey. "Residential energy efficiency retrofits: potential unintended consequences." Journal of Environmental Planning and Management 62, no. 12 (December 21, 2018): 2010–25. http://dx.doi.org/10.1080/09640568.2018.1509788.

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Dissertations / Theses on the topic "170103 Residential energy efficiency"

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Jeter, Teresa M. "A model residential energy efficiency program." Virtual Press, 1995. http://liblink.bsu.edu/uhtbin/catkey/941726.

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The opportunity for reducing energy expenditures in homes has never been greater nor has the need been more pressing. Based on the current analysis of weatherization programs, millions of houses do not receive energy efficiency measures and houses that are being weatherized are not receiving the kinds of measures that generate the greatest energy savings. Many of these problems are attributed to program policies, regulations and funding limitations. Given these critical issues. The creative project is a model residential energy efficiency program. Its purpose is to serve as a guide for planning, designing, developing and implementing the kinds of residential energy efficiency programs that will maximize services and benefits. More specifically, the model will assist in the design and implementation of programs that are effective, efficient and can deliver the “right” energy measures to “any” house that needs them. A community in a small Midwestern city was selected to help demonstrate the various components of the model program.
Department of Urban Planning
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Roswell, David. "Activating Community to Enable Residential Energy Efficiency." Oberlin College Honors Theses / OhioLINK, 2013. http://rave.ohiolink.edu/etdc/view?acc_num=oberlin1387102781.

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Shell, Kara. "Analysis of Energy Efficiency Strategies in Residential Buildings." The Ohio State University, 2010. http://rave.ohiolink.edu/etdc/view?acc_num=osu1276830510.

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Pavlenko, V., and O. Volianyk. "Efficiency of window recuperator in residential premises." Thesis, Київський національний університет технологій та дизайну, 2019. https://er.knutd.edu.ua/handle/123456789/14631.

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Tramel, Nathan, Jacob Dill, and Hussam Almuqallad. "Remote Monitoring of Residential Energy Usage." International Foundation for Telemetering, 2013. http://hdl.handle.net/10150/579583.

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ITC/USA 2013 Conference Proceedings / The Forty-Ninth Annual International Telemetering Conference and Technical Exhibition / October 21-24, 2013 / Bally's Hotel & Convention Center, Las Vegas, NV
A substantial amount of the energy usage in developed countries is consumed by climate control of residential and commercial structures. Collecting information on the usage patterns of heating, ventilation and air conditioning (HVAC) systems can allow a consumer to better understand the cost and effectiveness of these systems, and allow landlords and others to monitor their use. This paper describes a system which can easily be retrofitted onto legacy HVAC systems to monitor their activity, and then transmit the information over a wireless radio network for archiving and analysis
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Carlson, Derrick R. "Analyzing Residential End-Use Energy Consumption Data to Inform Residential Consumer Decisions and Enable Energy Efficiency Improvements." Research Showcase @ CMU, 2013. http://repository.cmu.edu/dissertations/298.

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While renewable energy is in the process of maturing, energy efficiency improvements may provide an opportunity to reduce energy consumption and consequent greenhouse gas emissions to bridge the gap between current emissions and the reductions necessary to prevent serious effects of climate change and will continue to be an integral part of greenhouse gas emissions policy moving forward. Residential energy is a largely untapped source of energy reductions as consumers, who wish to reduce energy consumption for monetary, environmental, and other reasons, face barriers. One such barrier is a lack of knowledge or understanding of how energy is consumed in a home and how to reduce this consumption effectively through behavioral and technological changes. One way to improve understanding of residential energy consumption is through the creation of a model to predict which appliances and electronics will be present and significantly contribute to the electricity consumption of a home on the basis of various characteristics of that home. The basis of this model is publicly available survey data from the Residential Energy Consumption Survey (RECS). By predicting how households are likely to consume energy, homeowners, policy makers, and other stakeholders have access to valuable data that enables reductions in energy consumption in the residential sector. This model can be used to select homes that may be ripe for energy reductions and to predict the appliances that are the basis of these potential reductions. This work suggests that most homes in the U.S. have about eight appliances that are responsible for about 80% of the electricity consumption in that home. Characteristics such as census region, floor space,income, and total electricity consumption affect which appliances are likely to be ina home, however the number of appliances is generally around 8. Generally it takesaround 4 appliances to reach the 50% threshold and 12 appliances to reach 90% ofelectricity consumption, which suggests significant diminishing returns for partiesinterested in monitoring appliance level electricity consumption. Another way to improve understanding of residential energy consumption isthrough the development of residential use phase energy vectors for use in theEconomic Input-Output Life Cycle Assessment (EIO-LCA) model. The EIO-LCAmodel is a valuable scoping tool to predict the environmental impacts of economicactivity. This tool has a gap in its capabilities as residential use phase energy isoutside the scope of the model. Adding use phase energy vectors to the EIO-LCAmodel will improve the modeling, provide a more complete estimation of energyimpacts and allow for embedded energy to be compared to use phase energy for thepurchase of goods and services in the residential sector. This work adds 21 quads ofenergy to the residential energy sector for the model and 15 quads of energy forpersonal transportation. These additions represent one third of the total energyconsumption of the United States and a third of the total energy in the EIO-LCAmodel. This work also demonstrates that for many products such as electronics andhousehold appliances use phase energy demands are much greater thanmanufacturing energy demands and dominate the life cycles for these products. A final way in which this thesis improves upon the understanding of how usephase energy is consumed in a home is through the exploration of potential energy reductions in a home. This analysis selects products that are used or consumed in ahome, and explores the potential for reductions in the embedded manufacturing anduse phase energy of that product using EIO-LCA and the energy vectors created inChapter 3. The results give consumers an understanding of where energy isconsumed in the lifecycle of products that they purchase and provide policy makerswith valuable information on how to focus or refocus policies that are aimed andreducing energy in the residential sector. This work finds that a majority of theenergy consumed by retail products is consumed in the use phase of electronics andappliances. Consequently the largest potential reductions in residential energy usecan be found in the same area. The work also shows that targeting reductions in themanufacturing energy for many products is likely to be an ineffective strategy forenergy reductions with the exception of a select few products. Supply chain energyreductions may be more promising than manufacturing energy reductions, thoughneither is likely to be as effective as strategies that target use phase energyreductions.
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Joelsson, Anna. "Primary energy efficiency and CO2 mitigation in residential buildings." Doctoral thesis, Mittuniversitetet, Institutionen för teknik och hållbar utveckling, 2008. http://urn.kb.se/resolve?urn=urn:nbn:se:miun:diva-7865.

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In order to control climate change it is important to limit the atmosphericconcentration of carbon dioxide (CO2). Increased energy efficiency, as well as ashift from fossil fuels to renewable resources can reduce net CO2 emission. Theenergy required for constructing and operating buildings is significant in manycountries, and it is thus important to design energy efficient buildings and energysupply systems.Improvements in existing buildings are needed in order to achieve short-termemission reductions. The Swedish building stock expanded greatly during the1960s and 1970s. The energy efficiency of these houses was often quite low, andmany of them were built with resistance heating. In this thesis increased energyefficiency in such buildings is studied, as well as conversions from resistanceheating to other heating systems, and various technologies and fuels for theproduction of electricity and heat. The effects of these measures are analysed withrespect to primary energy use, CO2 emission and societal cost. The studies wereperformed using process-based systems analysis in a life-cycle perspective. Thesystem boundaries include energy chains from the natural resources to the usefulelectricity and heat in the houses. The results show that the choice of heatingsystem in the house has a greater effect on the primary energy use than measureson both the house envelope and the energy supply chains. District heating basedon cogeneration of heat and electricity and bedrock heat pumps were found to beenergy-efficient systems. The net emission of CO2 is dependent on the fuel and theCO2 emissions from these systems are comparable to those from a wood pelletboiler, if biomass-based supply chains are used. Conversion from resistanceheating to any of the other heating systems studied is also profitable from a societaleconomic perspective.The decision to implement energy-efficiency measures or install a new heatingsystem in a detached house is taken by the house owner. In order for successfulimplementation the alternatives must either be sufficiently attractive or incentivesor policy instruments that affects this large, inhomogeneous group must beimplemented. In this thesis, the house owners’ economic situation when changingthe heating system and implementing energy-efficiency measures on the buildingenvelope is analysed. The economic analysis includes current Swedish policyinstruments, such as an investment subsidy for heating system conversion, anincome tax deduction for replacing windows, levying a consumer electricity tax and increasing real estate tax. House owners’ perceptions of different heatingsystems are analysed through the results of comprehensive questionnaires. Societaleconomy, private economy and individuals’ perceptions are compared. Theconversion subsidy provides some incentive to house owners to act according tothe national energy policy, as does the electricity tax, which has a significantinfluence on consumer costs. The use of economic instruments seems efficient inpromoting systems in line with environmental goals since environmental factorsare ranked much lower by the home owners. However, the effect on the annualcost of most of the policy instruments studied is smaller than the price variationsbetween different energy suppliers. Energy suppliers thus have considerableopportunity to influence house owners.To achieve long-term changes in the building sector new houses should beconstructed with as low primary energy use and emission as possible, seen overtheir entire life cycle. The primary energy use is analysed for both the productionand operational phase of several types of residential buildings. When the demandfor operational primary energy decreases, due to a high energy standard orenergy-efficient supply, the relative importance of the energy required forproduction will increase. The amount of primary energy required for theproduction of a new low-energy building is significant compared with the primaryenergy required for space heating. One way of reducing both primary energy useand CO2 emission in the production phase is to use constructions with woodframes instead of concrete.The energy supply system is nevertheless still important also for low energybuildings. A new house built to passive standard, heated with fossil-fuel-basedresistance heating gives rise to higher primary energy use and CO2 emission than aconventional detached house from the 1970s that is heated with an energy-efficientbiomass-based heating system. The results thus indicate that wood-framed houseswith a high energy standard, together with efficient energy supply systems, couldbe an option for sustainable residential construction.
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Busic-Sontic, Ante. "Energy efficiency investments in residential buildings : does personality matter?" Thesis, University of Cambridge, 2019. https://www.repository.cam.ac.uk/handle/1810/284556.

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In recent years, energy efficiency in the built environment has been attracting considerable interest to mitigate energy consumption. A number of scientific studies indicate that rising air pollution, decreasing biodiversity, ocean acidification and other adverse effects on humans and the environment in recent decades are due to greenhouse gas emissions, and a substantial share of the emissions can be attributed to energy usage in residential buildings. Investments in energy-efficient technologies have been made to alleviate such human induced causes contributing to the emissions, but they are still far from widespread, calling for a thorough understanding of individuals' decision-making processes to promote further adoption of energy efficiency investments. Although personality has been widely recognised as an explanatory factor of behaviour, a rigorous discussion of it in the context of energy efficiency investments is missing. As such, to understand the role of personality traits in making high-cost energy efficiency investments in residential buildings, this research applies a multidisciplinary approach to derive theoretical models that are evaluated in subsequent empirical investigations using quantitative methods and data from the UK and Germany. The findings suggest three ways through which personality can influence energy efficiency investments. The first is an indirect impact of personality traits through risk preferences, in which the significance of the personality effects depends on the financial subsidy context. The second is an indirect effect of personality traits through environmental concern. The third way suggests an impact of personality traits through their importance for individuals' capability and willingness to consider peer behaviour.
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Unéus, Viktor. "Energy efficiency trends in large clusters of residential buildings." Thesis, Högskolan Dalarna, Energiteknik, 2020. http://urn.kb.se/resolve?urn=urn:nbn:se:du-34559.

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The aim of this thesis work is to analyse the trends in heat use among Borlänge Energis district heating customer over the last 20 years. Several reports show that in general the buildings stock get more and more efficient, both in Sweden and other European countries, but will the same trend be seen among Borlänge Energis customer? Data of delivered heat to 324 customers, both single-family houses and multifamily houses, for the period of 1998-2018 is used in this study. The heating that is assumed for domestic hot water is calculated and the heat used for heating is temperature corrected so the heat needed for a normal year could be calculated. The investigated customers are divided into different groups representing various types of buildings with different building years. From this data it’s possible to see trends in heat usage in kWh/building, and year for various types of buildings over the period. Other studies on how trends for heating usage in buildings have report heating usage in kWh/(m2,year). It wasn’t possible in this work to get data of the size of each building, which means that it’s not possible to compare the result from this study with other studies. However, assuming that the building area have been the same and that no extensions of the buildings have been done during the period, the trend in changed heat use should be the same, unless the result is presented in kWh/m2, year and kWh/building, year. The overall results show that there is a reduction in energy use in the buildings in Borlänge during the period 1998-2018. The decrease in heat use are in the order of 0.3 – 0.4 %/year, with larger decrease in multi-family houses. This is considerably less than the decrease of heat use in the buildings stock of 0.9 – 1.2 %/year reported for the entire building stock in Sweden during approximately the same period.
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Kumirai, Tichaona. "Energy efficiency interventions for residential buildings in Bloemfontein using passive energy techniques." Thesis, Bloemfontein : Central University of Technology, Free State, 2010. http://hdl.handle.net/11462/124.

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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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Books on the topic "170103 Residential energy efficiency"

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Pont, Peter Du. Residential indoor air quality and energy efficiency. Washington, D.C: American Council for an Energy-Efficient Economy, 1989.

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Alberta. Scientific and Engineering Services and Research Division. Performance characteristics of energy-efficient residential furnaces. Edmonton]: Alberta Energy, Scientific and Engineering Services and Research Division, 1987.

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E, King Joseph. Building for the future: A guide to residential energy efficiency. Topeka, Kan. (Suite 314, 400 W. 8th, Topeka 66603): Kansas Electric Utilities Research Program, 1993.

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Residential manual for compliance with the 1998 energy efficiency standards (for low-rise residential buildings). [Sacramento]: The Commission, n.d.

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Development, Market and Business. The UK residential energy efficiency market development: Quarter Two 2000. Manchester: Market and Business Development, 2000.

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Andreou, Eleni. Aspects of improving the energy efficiency of existing residential buildings. Dublin: University College Dublin, 2000.

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Koomey, Jon. The Potential for electricity efficiency improvements in the U.S. residential sector. Berkeley, Ca: Energy Analysis Program, Applied Science Division, Lawrence Berkeley Laboratory, Univ. of Calif., 1991.

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United States. Dept. of Energy. Residential and Conservation Program. Directory of energy efficiency information services for the residential and commercial sectors. Alexandria, VA 4300 King St., Suite 400, Alexandria: The Corporation, 1988.

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Program, United States Dept of Energy Residential and Commercial Conservation. Directory of energy efficiency information services for the residential and commercial sectors. Alexandria, VA 4300 King St., Suite 400, Alexandria: The Corporation, 1988.

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California Energy Commission. Building & Appliance Efficiency Office. Initial study/proposed negative declaration for the 2008 building energy efficiency standards for residential and nonresidential buildings. Sacramento, Calif.]: California Energy Commission, 2008.

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Book chapters on the topic "170103 Residential energy efficiency"

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Wei, Yi-Ming, and Hua Liao. "Residential Energy Consumption." In Energy Economics: Energy Efficiency in China, 119–66. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-44631-8_4.

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Otsuka, Akihiro. "Residential Energy Demand and Energy Efficiency." In Regional Energy Demand and Energy Efficiency in Japan, 83–98. Cham: Springer International Publishing, 2016. http://dx.doi.org/10.1007/978-3-319-47566-0_5.

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De Martino Jannuzzi, Gilberto, Vanice Ferreira dos Santos, Mara F. L. Bittencourt, and Paulo Augusto Leonelli. "Implementation and Evaluation of Residential Lighting Projects in Brazil." In Energy Efficiency in Household Appliances, 412–18. Berlin, Heidelberg: Springer Berlin Heidelberg, 1999. http://dx.doi.org/10.1007/978-3-642-60020-3_49.

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Gálvez, Pablo, Petr Mariel, and David Hoyos. "Estimating the Direct Rebound Effect in the Residential Energy Sector: An Application in Spain." In Green Energy and Efficiency, 165–82. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-03632-8_7.

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Costantini, Valeria, Francesco Crespi, Gianluca Orsatti, and Alessandro Palma. "Policy Inducement Effects in Energy Efficiency Technologies. An Empirical Analysis of the Residential Sector." In Green Energy and Efficiency, 201–32. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-03632-8_9.

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Jabari, Farkhondeh, Behnam Mohammadi-Ivatloo, and Mohammad Rasouli. "Optimal Planning of a Micro-combined Cooling, Heating and Power System Using Air-Source Heat Pumps for Residential Buildings." In Energy Harvesting and Energy Efficiency, 423–55. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-49875-1_15.

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Turiel, Isaac. "Present Status of Residential Appliance Energy Efficiency Standards — An International Review." In Energy Efficiency in Household Appliances, 43–54. Berlin, Heidelberg: Springer Berlin Heidelberg, 1999. http://dx.doi.org/10.1007/978-3-642-60020-3_7.

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Smeureanu, Ion, Francesco Moresino, Marian Dardala, Adriana Reveiu, and Felix Furtuna. "Optimizing Residential Energy Consumption in Romania." In 2nd International Congress on Energy Efficiency and Energy Related Materials (ENEFM2014), 313–18. Cham: Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-16901-9_38.

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Sidler, Olivier. "End Use Measurement Campaigns of Electricity Specific Uses in the Residential Sector." In Energy Efficiency in Household Appliances, 158–70. Berlin, Heidelberg: Springer Berlin Heidelberg, 1999. http://dx.doi.org/10.1007/978-3-642-60020-3_20.

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Rosenquist, Gregory J. "Residential Air Conditioners: U.S. Experience and Possible Extensions to the Global Market." In Energy Efficiency in Household Appliances, 296–308. Berlin, Heidelberg: Springer Berlin Heidelberg, 1999. http://dx.doi.org/10.1007/978-3-642-60020-3_35.

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Conference papers on the topic "170103 Residential energy efficiency"

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Aydin, Erdal, Nils Kok, and Dirk Brounen. "Capitalization of Residential Energy Efficiency." In 22nd Annual European Real Estate Society Conference. European Real Estate Society, 2015. http://dx.doi.org/10.15396/eres2015_1.

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Jantschi, Lorentz, Mugur Balan, Margareata Emilia Podar, and Sorana Daniela Bolboaca. "Thermal Energy Efficiency Analysis for Residential Buildings." In EUROCON 2007 - The International Conference on "Computer as a Tool". IEEE, 2007. http://dx.doi.org/10.1109/eurcon.2007.4400261.

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Jewell, Ward. "Residential Energy Efficiency and Electric Demand Response." In 2016 49th Hawaii International Conference on System Sciences (HICSS). IEEE, 2016. http://dx.doi.org/10.1109/hicss.2016.304.

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Larionov, A., and E. Smirnova. "Energy efficiency in residential construction: Risk assessment." In IV INTERNATIONAL SCIENTIFIC AND PRACTICAL CONFERENCE “NEW INFORMATION TECHNOLOGIES IN THE ARCHITECTURE AND CONSTRUCTION” (NITAC 2021). AIP Publishing, 2022. http://dx.doi.org/10.1063/5.0106716.

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Qian, Queena, Henk Visscher, Kun Song, and Jiefang Ma. "Applying behavioural economics to residential energy efficiency policy." In 24th Annual European Real Estate Society Conference. European Real Estate Society, 2017. http://dx.doi.org/10.15396/eres2017_256.

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Tiedemann, K. "Performance standards and residential energy efficiency in Egypt." In WASTE MANAGEMENT 2006. Southampton, UK: WIT Press, 2006. http://dx.doi.org/10.2495/wm060481.

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Almajali, Ziyad. "Residential Electrical Water Heater Energy Efficiency Monitoring system." In 2021 IEEE Jordan International Joint Conference on Electrical Engineering and Information Technology (JEEIT). IEEE, 2021. http://dx.doi.org/10.1109/jeeit53412.2021.9634093.

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Fuerst, Franz. "Do Mandatory Energy Efficiency Upgrades Drive up Residential Rents?" In 28th Annual European Real Estate Society Conference. European Real Estate Society, 2022. http://dx.doi.org/10.15396/eres2022_216.

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Rosenfeld, Arthur H. "Residential energy efficiency: Progress since 1973 and future potential." In AIP Conference Proceedings Vol. 135. AIP, 1985. http://dx.doi.org/10.1063/1.35484.

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Burlacu, C. "Energy efficiency in Romanian residential sector: facts, opportunities, perspectives." In 18th International Conference and Exhibition on Electricity Distribution (CIRED 2005). IEE, 2005. http://dx.doi.org/10.1049/cp:20051210.

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Reports on the topic "170103 Residential energy efficiency"

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Hauber, Jerry. Developing Residential Energy Usage Baselines and Energy Efficiency Options. Office of Scientific and Technical Information (OSTI), April 2022. http://dx.doi.org/10.2172/1864584.

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none,. Overview of Residential Energy Feedback and Behavior-based Energy Efficiency. Office of Scientific and Technical Information (OSTI), February 2011. http://dx.doi.org/10.2172/1219691.

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none,. Residential Energy Efficiency Research Planning Meeting Summary Report. Office of Scientific and Technical Information (OSTI), February 2012. http://dx.doi.org/10.2172/1219524.

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Speake, Andrew, Jes Brossman, and Jeff Maguire. Residential Energy Efficiency Design Guide for Tribal Lands. Office of Scientific and Technical Information (OSTI), December 2022. http://dx.doi.org/10.2172/1905286.

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Aldubyan, Mohammad, Moncef Krarti, and Eric Williams. Evaluating Energy Demand and Energy Efficiency Programs in Saudi Residential Buildings. King Abdullah Petroleum Studies and Research Center, February 2021. http://dx.doi.org/10.30573/ks--2020-mp05.

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Abstract:
This paper describes the development of the Residential Energy Model (REEM) for Saudi Arabia using an engineering bottom-up approach. The model can assess energy demand for the current residential building stock and the impact of energy efficiency and demand-side management programs. It accounts for the makeup and features of the Kingdom’s existing housing stock using 54 prototypes of residential buildings defined by three building types, three vintages, and six locations representing different climatic zones.
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Allcott, Hunt, and Michael Greenstone. Measuring the Welfare Effects of Residential Energy Efficiency Programs. Cambridge, MA: National Bureau of Economic Research, May 2017. http://dx.doi.org/10.3386/w23386.

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Polly, B., M. Gestwick, M. Bianchi, R. Anderson, S. Horowitz, C. Christensen, and R. Judkoff. A Method for Determining Optimal Residential Energy Efficiency Packages. Office of Scientific and Technical Information (OSTI), April 2011. http://dx.doi.org/10.2172/1219163.

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none,. 2011 Residential Energy Efficiency Technical Update Meeting Summary Report. Office of Scientific and Technical Information (OSTI), November 2011. http://dx.doi.org/10.2172/1219356.

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Polly, B., M. Gestwick, M. Bianchi, R. Anderson, S. Horowitz, C. Christensen, and R. Judkoff. Method for Determining Optimal Residential Energy Efficiency Retrofit Packages. Office of Scientific and Technical Information (OSTI), April 2011. http://dx.doi.org/10.2172/1015501.

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Davis, Robert, Adria Banks, Ben Larson, Hyunwoo Lim, Scott Spielman, Helen Townsend, Saranya Gunasingh, et al. Residential Building Energy Efficiency Field Studies: Low-Rise Multifamily. Office of Scientific and Technical Information (OSTI), June 2020. http://dx.doi.org/10.2172/1656655.

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