Relevant bibliographies by topics / Radiant Heating and Cooling

Academic literature on the topic 'Radiant Heating and Cooling'

Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "Radiant Heating and Cooling"

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Yoo, Seung-Ho. "Thermal Behavior of Passive Intelligent Radiant Cooling Systems." Processes 10, no. 12 (December 12, 2022): 2666. http://dx.doi.org/10.3390/pr10122666.

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Efficient cooling and heating solutions for nearly zero-energy solar dwellings are required to mitigate climate change and to make dwellings sustainable. The installed pipeline for a radiant heating system, which is only used for space heating when heating is necessary, can also be used to cool the room with only the enthalpic use of natural city water by releasing the natural city water through the embedded pipeline already installed for radiant heating. Natural city water used for radiant cooling can be used in necessary locations such as for toilets, washing cars, laundry facilities, and garden water, which corresponds to approximately 56% of the water we use at home. As a result, the embedded pipes that make up a radiant heating system can be converted to a passive intelligent radiant cooling system with minimal added installation and control systems. Thermal comfort and behavior analyses in an enclosure with a radiant cooling system are fulfilled through experimentation, mean radiant temperature simulation, and asymmetric radiation calculation. No uncomfortable asymmetric radiation is encountered during the cooling period, so the cooling spaces are well controlled within the comfortable cooling range. A passive intelligent radiant cooling system that uses just the enthalpy of natural city water can be an appropriate ecological solution to better develop zero-energy dwellings. No extra cooling energy and power are required to cool a space that uses just enthalpy and pressure from natural city water.
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Kulkarni, Shubham S. "A Glance on Radiant Cooling Technology for Heating and Cooling for Residential and Commercial Building Application." Journal of Advanced Research in Applied Mechanics and Computational Fluid Dynamics 07, no. 3&4 (November 6, 2020): 13–19. http://dx.doi.org/10.24321/2349.7661.202005.

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As we know that nowadays due to the hot and humid weather and the increasing temperature the high amount of energy consumption is used for the heating & cooling purpose in residential as well as in commercial building for air conditioning systems. To overcome this problem and to reduce the energy consumption as well as good thermal comfort to people in the indoor environment, use the radiant heating & cooling system is a better way. This concept is used to cool or heat the room and absorbs the indoor sensible heat by thermal radiation. The system removes heat by using less energy and more energy-efficient. This system uses water as a medium to cool or heat the room space. There are three types discussed in these papers for cooling & heating. In this paper, we did an overall study regarding radiant heating and cooling systems. It reduces the energy lost due to the duct leakage. It also has a lower life cycle cost compared to conventional. In this paper, we have reviewed how to reduce energy consumption and give thermal comfortable air-condition through radiant cooling and chilled ceiling panel system.
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Du, Yan. "Feasibility Analysis of Radiant Floor Cooling and Heating System Applications." Applied Mechanics and Materials 716-717 (December 2014): 428–30. http://dx.doi.org/10.4028/www.scientific.net/amm.716-717.428.

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Radiant floor cooling and heating system is the new system which can shares the same tube to cooling in summer and heating in winter. It meet the requirements for human comfort , save energy, and reduce cost, so it is popular the field of building energy efficiency in recent years. This paper briefly describes the radiant floor cooling and heating field research at home and abroad and its advantages, and briefly analyses the factors of heat exchange efficiency in radiant floor cooling and heating system.
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Gendelis, Staņislavs, Jevgēnijs Teličko, Andris Jakovičs, and Indulis Bukans. "Radiant capillary heat exchangers – power calculation for optimal heating and cooling." Journal of Physics: Conference Series 2423, no. 1 (January 1, 2023): 012011. http://dx.doi.org/10.1088/1742-6596/2423/1/012011.

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Abstract The issue of switching to renewable energy sources becomes very actual and it is important not only to change the energy source, but also the reduce the final energy needs by improving the energy efficiency of buildings and usage of efficient heating systems. Heat pumps as the most popular renewable energy source are widely used, but their energy efficiency is depending on temperature of the supplied energy carrier. The most efficient are radiant capillary heat exchangers with a large surface area and a low temperature, which typically does not exceed 30°C. Another advantage of radiant capillary heat exchangers is the possibility to operate them in both - heating and cooling modes. Unlike the underfloor heating solution, where the role of thermal convection is very important, the built-in radiant capillary heat exchanger systems provide the energy mainly due to thermal radiation. This study explores two modelling approaches for determination of required power and corresponding area of radiant capillary heat exchangers to be installed in a room to provide heating and cooling: simplified approach, which allows to create the heat balance with a minimum amount of input data and a precise standard-based approach. Calculations were made for three different rooms with variable glazing area and spatial orientation using both approaches. Analysis of the calculation results shows the limits of the simplified method, which overestimates heating need and underestimates cooling need, and the main reason for such differences is simplification of room orientation and subsequent solar heat gains. As the calculated cooling power is less than heating power, therefore the heating estimation is sufficient to estimate the amount of radiant capillary heat exchangers in small/medium rooms for providing both heating and cooling in the climatic conditions of Riga. The use of complex, comprehensive modelling approaches is necessary for rooms with large glazed areas, where the simplified method gives incorrect estimations.
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Budiaková, Mária. "Effective Ventilation and Heating Systems in Office Buildings." Advanced Materials Research 649 (January 2013): 189–92. http://dx.doi.org/10.4028/www.scientific.net/amr.649.189.

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The paper is oriented on the effective ventilation, heating and cooling systems in office buildings by utilization of renewable energy sources. All these systems must be in mutual harmony and ensure thermal comfort. Ventilation system must use the power of wind, the heated air from the double skin facade, heat recovery system, preheating or cooling in the ground channel. In the summer, there must be used the night natural cooling of building. For the heating is the most suitable to use radiant floor heating (30%) in combination with radiant ceiling heating (70%). The next progressive way is the combination of new concrete core conditioning and floor convector heaters.
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Qin, S. Y., Y. A. Wang, S. Gao, D. G. Xu, X. Cui, M. Zhao, and L. W. Jin. "Heat transfer characteristics of a composite radiant wall under cooling/heating conditions." Indoor and Built Environment 29, no. 8 (September 24, 2019): 1155–68. http://dx.doi.org/10.1177/1420326x19876673.

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The radiant wall composited with capillary tubes has been widely applied in heating or cooling systems due to its large heat transfer area, low-temperature heating and high-temperature cooling. In this study, a ratio model of heat transfer in steady-state condition was established, which explores heat transfer capacity from the capillary layer (active layer) towards the indoor and outdoor sides. The experimental data including the radiant surface temperature, the capillary layer temperature and the heat flux distribution were collected in cooling and heating conditions. The proposed ratio model was validated. The results show that the fluctuation of indoor air temperature is relatively small, suggesting that the radiant system possesses higher stability. Results showed that thermal resistances of the composite radiant wall in summer and winter conditions vary greatly due to different moisture contents. With the continuation of the system operation, the calculated values from the ratio model under the steady-state condition were more consistent with average values obtained from experiments under unsteady-state conditions, indicating that the overall heat transfer performance of the composite radiant wall could be properly evaluated by the proposed model in engineering applications.
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Qin, Wenqi, Yingning Hu, Jinwen Su, and Yubang Hu. "A New Type of Air Conditioning System Based on Finned Ceiling Radiant Coupled with Independent Fresh Air and Its Thermal Comfort Experimental Study." Computational Intelligence and Neuroscience 2022 (September 17, 2022): 1–15. http://dx.doi.org/10.1155/2022/4144569.

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The traditional radiation air conditioning system has some problems, such as easy condensation, insufficient refrigeration capacity, complex structure, and control system. Therefore, this study proposes a new type of finned metal radiant plate with large heat flow per unit area, sufficient cooling capacity, and simplified heat exchange system, in order to realize large temperature difference between cooling and heating. The temperature field uniformity and thermal comfort test of a novel type of finned ceiling radiant panel and independent fresh air linked air conditioning system under summer cooling and winter heating circumstances are accomplished through artificially generated climate environments. The study’s findings demonstrate that in the radiation and fresh air modes, the maximum interior temperature differential under cooling conditions does not rise over 2.1°C. The maximum temperature differential in the space at any one moment in the radiation and fresh air modes cannot be greater than 3°C when heating conditions are present. The fresh air’s cooling and dehumidifying effects are clear. The dehumidification efficiency may reach 50%, and the moisture content ranges from 5.48 to 9.63 g/kg. With PMV ranging from −0.34 to 0.54, the enhanced air conditioning system in this research provides exceptionally good thermal comfort. Additionally, the finned radiant panel’s installation area occupies just 14% of the ceiling, which is sufficient to fulfill the room’s cooling and heating load needs as well as provide high thermal comfort and consistent indoor temperature. The theoretical investigation and practical implementation of the direct expansion radiant air conditioning system are both strongly supported by this research.
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Cai, Wei, Wen Lv, Le Xian Zhu, and Peng Feng Yang. "Numerical Simulation on Indoor Thermal Environment of Radiant Flooring Cooling System with Displacement Ventilation." Advanced Materials Research 743 (August 2013): 90–93. http://dx.doi.org/10.4028/www.scientific.net/amr.743.90.

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The purpose of this study is to investigate the thermal environment of a radiant floor cooling system using the existing radiant floor heating system. The thermal environment of the model office space was analyzed using Computational Fluid Dynamics (CFD) method. Two typical air distributions (hybrid air cooling system composed of radiant floor cooling and displacement ventilation and all-air system) were simulated. Installing two human models in the office, the characteristics of heat transportation from the human model were also analyzed. The results show that two air distribution forms can meet the demand of thermal comfort. The operative temperature in the radiant floor cooling system was lower than in the all-air cooling system when each of the sensible cooling loads of the two types of HVAC system was the same.
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Kim, Kwang Woo. "Virtual special issue – Radiant heating and cooling systems." Building and Environment 96 (February 2016): 301–2. http://dx.doi.org/10.1016/j.buildenv.2015.05.031.

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Rhee, Kyu-Nam, Bjarne W. Olesen, and Kwang Woo Kim. "Ten questions about radiant heating and cooling systems." Building and Environment 112 (February 2017): 367–81. http://dx.doi.org/10.1016/j.buildenv.2016.11.030.

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Dissertations / Theses on the topic "Radiant Heating and Cooling"

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Poulis, P. D. A. "Radiant wall and floor heating and cooling." Thesis, Open University, 1988. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.384588.

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Gong, Xiangyang. "Investigation of a radiantly heated and cooled office with an integrated desiccant ventilation unit." [College Station, Tex. : Texas A&M University, 2007. http://hdl.handle.net/1969.1/ETD-TAMU-1559.

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Jarumongkonsak, Pornput. "Development and performance investigation on solar-powered thermoelectric radiant cooling in building-integrated system for a bedroom under hot and humid climate." Thesis, University of Nottingham, 2016. http://eprints.nottingham.ac.uk/33629/.

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In order to replace a conventional air-conditioner (AC) based on vapour compression technology that directly has high global warming potential and also currently consumes the most fossil fuel primary energy in building sector of tropical countries for generating thermal comfort on sleeping purpose, other alternative green space cooling technologies, as thermoelectric cooling (TEC), has to be improved to have same performance with AC. This research aims to develop and investigate a performance of Solar-powered Thermoelectric Radiant Cooling (STRC) system, as the combination of TEC and radiant cooling (RC) that is well known in its low energy consumption advantage. The studies were conducted through calculations, CFD simulations, system performance simulations and experiments. The results of optimum STRC system design was proved to provide better thermal and air quality performances, while the result in energy performance was depended on the TEC’s COP and vapour condensation prevention. After novel developing of TEC’s cooling channel with combined helical and an oblique fin to induce effective secondary flows that highly reduced the TEC’s hot side temperature in this research, the COP was able to increase up to 175%. Meanwhile, a novel bio-inspired combined superhydrophobic and hydrophobic coating on RC panel were able to competently repel most condensed water droplets, leaving just tiny droplets that was hard to be seen by naked eye. Finally, the COP of STRC system from house model experiment in 1:100 scales under hot and high humid climate was as high as 2.1 that helped STRC to consume electricity 34% less than AC system. Along with other benefits, as no working fluid, noise-free and low maintenance needs, the return of investment (ROI) was studied to be only 5-6 years when being operated with grid electricity and 17-18 years with PV panel generated electricity.
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Romaní, Picas Joaquim. "Improvement of building energy efficiency with radiant walls." Doctoral thesis, Universitat de Lleida, 2017. http://hdl.handle.net/10803/461942.

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Els edificis suposen una part molt significant del consum energètic i de les emissions de CO2 a nivell global. Resoldre aquest problema requereix de la implementació de tecnologies d'eficiència energètica i de la integració d'energies renovables. En aquest context, els mur radiants són una tecnologia capaç d'afrontar aquests reptes. La avaluació del potencial d'aquest sistema s'ha dut a terme amb la experimentació d'una caseta amb murs radiant connectada a un sistema geotèrmic. Els resultats mostren la capacitat del sistema per reduir el consum energètic i desplaçar el pics de demanda, destacant també la sensibilitat als paràmetres de control. Les dades experimentals han servit per desenvolupar un model numèric del mur radiant, el qual s'ha fet servir per un estudi paramètric dels paràmetres de disseny. Finalment, aquest s'ha integrat a un model d'una habitació per estudiar diferents conceptes de control que maximitzin l'aprofitament de la producció d'uns panells fotovoltaics.
Los edificios suponen una fracción significativa del consumo energético y de emisiones de CO2 globales. Resolver este problema requiere implementar tecnologías de eficiencia energética e integrar energías renovables. En este contexto, los muros radiantes son una tecnología capaz de lidiar con estos retos. La evaluación del potencial del sistema se ha llevado a cabo con la experimentación de un cubículo con muros radiantes conectados a un sistema geotérmico. Los resultados muestran la capacidad del sistema para reducir el consumo energético y desplazar los picos de demanda, destacando también la sensibilidad a los parámetros de control. Los datos experimentales sirvieron para desarrollar un modelo numérico del muro radiante, el cual se ha usado para un estudio paramétrico de los parámetros de diseño. Finalmente, este se ha integrado a un modelo de cubículo para estudiar diferentes conceptos de control que maximicen el aprovechamiento de la producción de unos paneles fotovoltaicos.
Buildings represent a significant fraction of the global energy use and CO2 emissions. Solving this issue require the implementation of energy efficiency technologies and the integration of renewable energies. In this context, radiant walls are a technology capable of dealing with these challenges. The evaluation of this system was carried out with the experimentation of a radiant wall cubicle coupled to a geothermal system. The results showed the capability of the system for reducing the energy and shifting the peak loads, highlighting the sensitivity to control parameters. The experimental data was used for the development of a numerical model of the radiant wall, which was used in a parametric study of the design parameters. Finally, the numeric model was integrated in a cubicle model in order to study different control concepts that maximized the use of the energy produced by photovoltaic panels.
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Benzarti, Ghedas Habiba. "Modeling and thermal optimization of residential buildings using BIM and based on RTS method : application to traditional and standard house in Sousse city." Doctoral thesis, Universitat Politècnica de Catalunya, 2017. http://hdl.handle.net/10803/406007.

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The thermal quality of the contemporary building tends to be deteriorated due to aesthetic and economic considerations. Cheap materials which are thermally inappropriate are still rising in new buildings. Actually, the architectural design has been changed. Hence, the orientation is poorly investigated. The interior height of the new buildings is defectively compared to those of traditional houses. In addition, the patio is replaced by a corridor and different parts have already become communicating. Accordingly, the heating and cooling space becomes more and more important. The traditional dwelling, in fact, has a bioclimatic architecture which provides naturally minimal comfort. In our work, we tend to exploit the REVIT software in the residential building simulation in Tunisia and to optimize the modern housing model. Following the REVIT validation of the obtained results and comparing them to TRNSYS and SPREADSHEET ASHRAE, we have already relied on them to assess both housing models (contemporary and traditional). Using REVIT, the evaluation results show that traditional housing are more efficient than contemporary ones particularly during summer period. Then, we optimize the modern models making use of the passive strategies of traditional bioclimatic architecture and the improvement measures in the previous investigations. Numerous tests have been generated applying REVIT software in order to determine various models of contemporary housing which are able to be integrated into the Mediterranean climate. In fact, these tests indicate that REVIT efficiency is based on RTS method in thermal simulation of residential buildings.
La qualité thermique des bâtiments modernes a une tendance à se détériorer en raison de considérations esthétiques et économiques. L'utilisation de matériaux de construction de bon marché et thermiquement inappropriées ne cesse d'augmenter dans les nouvelles constructions. À l'heure actuelle, la conception architecturale a changé. L'orientation est peu étudiée, la hauteur intérieure des nouveaux locaux est faible comparée à celle de la maison traditionnelle et le patio est remplacé par un couloir. Les différentes parties sont devenues communicantes. Ainsi, l'espace de chauffage et de refroidissement devient plus important. L'habitation traditionnelle tunisienne présente une architecture bioclimatique qui permet de fournir un confort minimal naturellement. Notre travail vise à exploiter le REVIT dans la simulation des bâtiments résidentiels en Tunisie et d'optimiser le modèle d'habitat moderne. Après validation des résultats obtenus par REVIT, comparés à ceux de TRNSYS et SPREADSHEET ASHRAE, nous l'avons, tout d'abord, exploité pour évaluer les deux modèles d'habitats (traditionnels et contemporains). Les résultats d'évaluation, en utilisant REVIT, montrent que l'habitat traditionnel sont plus efficaces que celui moderne particulièrement en période estivale. Par la suite, nous avons optimisé le modèle de maisons contemporaines, en utilisant en premier lieu, les stratégies passives de l'architecture bioclimatique traditionnelle, et en second lieu, en utilisant les mesures d'amélioration utilisées dans des études antérieures. Afin, de déterminer une variante de modèle d'habitat contemporain thermiquement optimal et qui s'intègre dans le climat méditerranéen, plusieurs tests sont générés en utilisant REVIT. Ces tests montrent l'efficacité de ce dernier qui se base sur la méthode RTS dans la simulation thermique des bâtiments résidentiels.
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Khanna, Amit. "Development and Demonstration of a Performance Test Protocol For Radiant Floor Heating Systems." Thesis, Virginia Tech, 2006. http://hdl.handle.net/10919/30987.

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The Radiant Heating markets - especially, the hydronic segment - are growing rapidly in North America due to homeownersâ increasing demand for comfort and the steady rise in residential construction. Radiant systems are promising technologies for energy saving in commercial and residential building sectors together with improving occupant thermal comfort. Such a technology is different from the more standard all-air systems and thus can be termed Space Conditioning. However, the thermal performance of radiant systems in buildings has not been fully understood and accounted for. This is primarily due to lack of any standard testing mechanism. The central thrust of this paper is to experimentally investigate questions relating to thermal performance of radiant systems, thus also contribute towards evolving a new standard for testing mechanisms. Products from 12 different radiant floor systems were chosen from the market. Having defined each with similar control parameters such as flow rate, supply water temperature and similar design parameters like size, insulation etc., they are separately tested in a well insulated test setup. Experiments on the time variations for each test floor were performed at supply water temperatures ranging between 100F â 140F with a 10F increment at each stage. Having gathered data through the Data Acquisition System (DAS), the data is analyzed and compared between all systems. The paper concludes by providing recommendations for experimentally testing thermal energy performance, thermal uniformity and thermal stability of radiant floor heating technology.
Master of Science
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Zhang, Zhi Long. "Temperature control strategies for radiant floor heating systems." Thesis, National Library of Canada = Bibliothèque nationale du Canada, 2001. http://www.collectionscanada.ca/obj/s4/f2/dsk3/ftp04/MQ59301.pdf.

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Kegel, Martin. "Experimental and Analytical Analysis of Perimeter Radiant Heating Panels." Thesis, University of Waterloo, 2006. http://hdl.handle.net/10012/2867.

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In recent years the U. S. and Canada have seen a steady increase in energy consumption. The U. S. in particular uses 25% more energy than it did 20 years ago. With declining natural resources and an increase in fuel costs, it has become important to find methods of reducing energy consumption, in which energy conservation in space heating and cooling has become a widely researched area. One method that has been identified to reduce the energy required for space heating is the use of radiant panels. Radiant panels are beneficial because the temperature set points in a room can be lowered without sacrificing occupant comfort. They have therefore become very popular in the market. Further research, however, is required to optimize the performance of these panels so energy savings can be realized.

An analytical model has been developed to predict the panel temperature and heat output for perimeter radiant panel systems with a known inlet temperature and flow rate, based on a flat plate solar collector (RSC) model. As radiative and convective heat transfer coefficients were required to run the model, an analytical analysis of the radiative heat transfer was performed, and a numerical model was developed to predict the convective heat transfer coefficient. Using the conventional radiative heat exchange method assuming a three-surface enclosure, the radiative heat transfer could be determined. Numerically, a correlation was developed to predict the natural convective heat transfer.

To validate the analytical model, an experimental analysis was performed on radiant panels. A 4m by 4m by 3m test chamber was constructed in which the surrounding walls and floor were maintained at a constant temperature and the heat output from an installed radiant panel was measured. Two radiant panels were tested; a 0. 61m wide panel with 4 passes and a 0. 61m wide panel with 8 passes. The panels were tested at 5 different inlet water temperatures ranging from 50°C to 100°C.

The RSC model panel temperature and heat output predictions were in good agreement with the experimental results. The RSC model followed the same trends as that in the experimental results, and the panel temperature and panel heat output were within experimental uncertainty, concluding that the RSC model is a viable, simple algorithm which could be used to predict panel performance.
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Gayeski, Nicholas (Nicholas Thomas). "Predictive pre-cooling control for low lift radiant cooling using building thermal mass." Thesis, Massachusetts Institute of Technology, 2010. http://hdl.handle.net/1721.1/61508.

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Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Architecture, 2010.
This electronic version was submitted by the student author. The certified thesis is available in the Institute Archives and Special Collections.
Cataloged from student-submitted PDF version of thesis.
Includes bibliographical references (p. 143-159).
Low lift cooling systems (LLCS) hold the potential for significant energy savings relative to conventional cooling systems. An LLCS is a cooling system which leverages existing HVAC technologies to provide low energy cooling by operating a chiller at low pressure ratios more of the time. An LLCS combines variable capacity chillers, hydronic distribution, radiant cooling, thermal energy storage and predictive control to achieve lower condensing temperatures, higher evaporating temperatures, and reductions in instantaneous cooling loads by spreading the daily cooling load over time. The LLCS studied in this research is composed of a variable speed chiller and a concrete-core radiant floor, which acts as thermal energy storage. The operation of the chiller is optimized to minimize daily energy consumption while meeting thermal comfort requirements. This is achieved through predictive pre-cooling of the thermally massive concrete floor. The predictive pre-cooling control optimization uses measured data from a test chamber, forecasts of controlled climate conditions and internal loads, empirical models of chiller performance, and data-driven models of the temperature response of the zone being controlled. These data and models are used to determine a near-optimal operational strategy for the chiller over a 24-hour horizon. At each hour, this optimization is updated with measured data from the previous hour and new forecasts for the next 24 hours. The novel contributions of this research include the following: experimental validation of the sensible cooling energy savings of the LLCS relative to a high efficiency split system air conditioner - savings measured in a full size test chamber were 25 percent for a typical summer week in Atlanta subject to standard efficiency internal loads; development of a methodology for incorporating real building thermal mass, chiller performance models, and room temperature response models into a predictive pre-cooling control optimization for LLCS; and detailed experimental data on the performance of a rolling-piston compressor chiller to support this and future research.
by Nicholas Thomas Gayeski.
Ph.D.
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Soderlund, Matthew Roger. "Congeneration dedicated to heating and cooling." Thesis, Georgia Institute of Technology, 2001. http://hdl.handle.net/1853/17672.

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Books on the topic "Radiant Heating and Cooling"

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Brand, Larry. Radiant heating and cooling and measured home performance for California homes. Davis, CA]: [Gas Technology Institute, Western Cooling Efficiency Center], 2013.

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Woodson, R. Dodge. Radiant floor heating. 2nd ed. New York: McGraw-Hill, 2010.

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Woodson, R. Dodge. Radiant floor heating. 2nd ed. New York: McGraw-Hill, 2010.

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Ballard, Carol. Heating and cooling. Chicago, Ill: Heinemann Library, 2008.

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Books, Time-Life, ed. Home heating & cooling. Alexandria, Va: Time-Life Books, 1988.

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Kelk, Gregory Hall. Selective radiant floor heating. Ottawa: National Library of Canada, 2002.

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Healey, Joseph F., Mary F. Babington, Lori L. Mort, and Tonia Ferrell. Comfort heating & cooling equipment. Cleveland: Freedonia Group, 2000.

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Killinger, Jerry. Heating and cooling essentials. Tinley Park, Ill: Goodheart-Willcox, 2003.

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Killinger, Jerry. Heating and cooling essentials. Tinley Park, Ill: Goodheart-Willcox, 2003.

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Killinger, Jerry. Heating and cooling essentials. Tinley Park, Ill: Goodheart-Willcox, 1999.

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Book chapters on the topic "Radiant Heating and Cooling"

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Yiping, Wang, Cui Yong, Zhu Li, and Kong Jianguo. "Thermal Performance Analysis of a Solar Heating and Nocturnal Radiant Cooling System." In Proceedings of ISES World Congress 2007 (Vol. I – Vol. V), 546–50. Berlin, Heidelberg: Springer Berlin Heidelberg, 2008. http://dx.doi.org/10.1007/978-3-540-75997-3_99.

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Zhou, Xiang, Yunliang Liu, Shaochen Tian, Maohui Luo, Lili Zhang, and Yongli Yuan. "Evaluation of Radiant Heating and Cooling Terminals Based on Structural Thermal Resistance." In Environmental Science and Engineering, 1367–77. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-13-9528-4_138.

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Koca, Aliihsan, Zafer Gemici, Koray Bedir, Erhan Böke, Barış Burak Kanbur, and Yalçın Topaçoğlu. "Thermal Comfort Analysis of Novel Low Exergy Radiant Heating Cooling System and Energy Saving Potential Comparing to Conventional Systems." In Progress in Exergy, Energy, and the Environment, 435–45. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-04681-5_38.

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Gooch, Jan W. "Radiant Heating." In Encyclopedic Dictionary of Polymers, 606. New York, NY: Springer New York, 2011. http://dx.doi.org/10.1007/978-1-4419-6247-8_9724.

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Leff, Harvey S. "Working, Heating, Cooling." In Energy and Entropy, 213–50. Boca Raton : CRC Press, 2020.: CRC Press, 2020. http://dx.doi.org/10.1201/9780429330018-8.

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Kazmer, David O. "Heating and Cooling." In Plastics Manufacturing Systems Engineering, 47–83. München: Carl Hanser Verlag GmbH & Co. KG, 2009. http://dx.doi.org/10.3139/9783446430143.003.

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Zainal, A. Z., and A. S. Binghooth. "Desiccant Dehumidification Integrated with Hydronic Radiant Cooling System." In Desiccant-Assisted Cooling, 217–47. London: Springer London, 2013. http://dx.doi.org/10.1007/978-1-4471-5565-2_8.

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Boulton, Roger B., Vernon L. Singleton, Linda F. Bisson, and Ralph E. Kunkee. "Heating and Cooling Applications." In Principles and Practices of Winemaking, 492–520. Boston, MA: Springer US, 1996. http://dx.doi.org/10.1007/978-1-4615-1781-8_14.

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Kranzl, Lukas, Marcus Hummel, Wolfgang Loibl, Andreas Müller, Irene Schicker, Agne Toleikyte, Gabriel Bachner, and Birgit Bednar-Friedl. "Buildings: Heating and Cooling." In Economic Evaluation of Climate Change Impacts, 235–55. Cham: Springer International Publishing, 2014. http://dx.doi.org/10.1007/978-3-319-12457-5_13.

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Guerrero-Lemus, Ricardo, and José Manuel Martínez-Duart. "Solar Heating and Cooling." In Lecture Notes in Energy, 263–87. London: Springer London, 2012. http://dx.doi.org/10.1007/978-1-4471-4385-7_13.

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Conference papers on the topic "Radiant Heating and Cooling"

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Beghi, Alessandro, Luca Cecchinato, and Mirco Rampazzo. "Thermal and comfort control for radiant heating/cooling systems." In Control (MSC). IEEE, 2011. http://dx.doi.org/10.1109/cca.2011.6044398.

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Ren Yanli and Li Deying. "The theory study on radiant floor heating and cooling system." In 2011 International Conference on Computer Science and Service System (CSSS). IEEE, 2011. http://dx.doi.org/10.1109/csss.2011.5974753.

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Carbonell, Dani, Jordi Cadafalch, and Ricard Consul. "A Transient Model for Radiant Heating and Cooling Terminal Heat Exchangers Applied to Radiant Floors and Ceiling Panels." In ISES Solar World Congress 2011. Freiburg, Germany: International Solar Energy Society, 2011. http://dx.doi.org/10.18086/swc.2011.26.03.

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Smith, Stephen M. "Implementation of Solar Thermal Driven Absorption Cooling in the Southeast." In ASME 2010 4th International Conference on Energy Sustainability. ASMEDC, 2010. http://dx.doi.org/10.1115/es2010-90403.

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A 35,000 ft2 [3,251 m2] Creative Arts instruction building is being constructed on the campus of Haywood Community College in Clyde, NC (∼25 miles [40 km] west of Asheville). The building’s HVAC system consists of a solar absorption chiller, two parallel back-up electric chillers, and radiant floor heating with condensing boiler back-up. Hot water is to be heated by 117 solar thermal panels with thermal energy storage in a 12,000 gallon [45,000 liters] insulated tank and service to both the absorption chiller and the radiant under-floor heating system. Peak cooling loads and unfavorable solar conditions are to be handled by parallel electric chillers, operated in sequence to achieve maximum performance. Emergency radiant under-floor heating hot water back-up is to be handled by gas-fired condensing boilers in the event of unavailable solar heated hot water. This paper will examine the extensive modeling process required of the system as performed in EnergyPlus, how preliminary modeling results influenced the control and design strategy, the annual behavior of the system and the importance of controllability.
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Jochum, Michael, Gokulakrishnan Murugesan, Kelly Kissock, and Kevin Hallinan. "Low Exergy Heating and Cooling in Residential Buildings." In ASME 2011 5th International Conference on Energy Sustainability. ASMEDC, 2011. http://dx.doi.org/10.1115/es2011-54671.

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Exergy is destroyed when work is degraded by friction and turbulence and when heat is transferred through finite temperature differences. Typical HVAC systems use a combination of high quality energy from combustion and electricity to overcome relatively small temperature differences between the building and the environment. It is possible to achieve the heating/cooling necessary to maintain comfort in a building without these high quality energy sources and their high potential-energy destruction. A low-exergy heating and cooling system seeks to better match the quality of energy to the loads of the building and thus to minimize exergy destruction and increase the exergetic efficiency of the building’s heating and cooling system. The method described here for low exergy building system design begins by minimizing overall heating and cooling loads using a tight, highly-insulated envelope and passive solar design strategies. Next a low-exergy heating and cooling system is designed that uses hydronic radiant heating and cooling in floors, along with high thermal mass. The large surface area of the floors enable low fluid flow rates and relatively small temperature differences to achieve heat transfer rates that would traditionally be driven by high temperature differentials and flows. The building uses a solar wall to passively drive ventilation requirements and earth tubes to condition the ventilation air. High thermal mass in the floor reduces peak loads and eliminates the need for solar thermal storage tanks. Thus, this paper begins to explore the practical limits of low-exergy design.
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Gallardo, Andres, and Umberto Berardi. "Dynamic simulation of a radiant ceiling panel incorporating PCMs for building cooling and heating applications." In 2021 Building Simulation Conference. KU Leuven, 2021. http://dx.doi.org/10.26868/25222708.2021.30724.

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Ratnanandan, Rajeevan, and Jorge E. González. "A System Modeling Approach for Active Solar Heating and Cooling System With Phase Change Material (PCM) for Small Buildings." In ASME 2012 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2012. http://dx.doi.org/10.1115/imece2012-93038.

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The paper presents a study of the performance of an active solar thermal heating and cooling system for small buildings. The work is motivated by the need for finding sustainable alternatives for building applications that are climate adaptable. The energy demand for heating and cooling needs in residential and light commercial buildings in mid-latitudes represent more than 50% of the energy consumed annually by these buildings. Solar thermal energy represents an untapped opportunity to address this challenge with sustainable solutions. Direct heating could be a source for space heating and hot water, and for heat operated cooling systems to provide space cooling. However, a key limitation in mainstreaming solar thermal for heating and cooling has been the size of thermal storage to implement related technologies. We address this issue by coupling a Phase Change Material (PCM) with an adsorption chiller and a radiant flooring system for year round solar thermal energy utilization in Northern climates. The adsorption chiller allows for chill water production driven by low temperature solar thermal energy for summer cooling, and low temperature radiant heating provides for space heating in winter conditions, while hot water demand is supplied year round. These active systems are operated by high performance solar thermal collectors. The PCM has been selected to match temperatures requirements of the adsorption chiller, and the tank was designed to provide three levels of temperatures for all applications; cooling, heating, and hot water. The material selection is paraffin sandwiched with a graphite matrix to increase the conductivity. The specific objective of the preset work is to provide a system optimization of this active system. The system is represented by a series of mathematical models for each component; PCM tank with heat exchangers, the adsorption machine, the radiant floor, and the solar thermal collectors (Evacuated tubular collectors). The PCM modeling allows for sensible heating, phase change process, and superheating. Parametric simulations are conducted for a defined small building in different locations in US with the objective of defining design parameters for; optimal solar collector array, sizing of the PCM tank, and performance of the adsorption machine and radiant heating system. The monthly and annual solar fractions of the system are also reported.
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Asadi, Somayeh, and Marwa Hassan. "Evaluation of the Thermal Performance of Radiant Barrier in Heating and Cooling Load Reduction of Residential Buildings." In International Conference on Sustainable Design and Construction (ICSDC) 2011. Reston, VA: American Society of Civil Engineers, 2012. http://dx.doi.org/10.1061/41204(426)29.

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Seyednezhad, Mohadeseh, and Hamidreza Najafi. "An Assessment of Thermal Comfort for Thermoelectric-Based Radiant Cooling Systems: A Numerical Investigation." In ASME 2021 15th International Conference on Energy Sustainability collocated with the ASME 2021 Heat Transfer Summer Conference. American Society of Mechanical Engineers, 2021. http://dx.doi.org/10.1115/es2021-63980.

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Abstract Studying various innovative cooling/heating technologies as alternatives to vapor-compression refrigeration cycles has received growing attention over the last few years. Thermoelectric (TE) systems are among the promising emerging technologies in this category. In the present paper, numerical modeling and analysis is performed using COMSOL Multiphysics to assess the performance of a thermoelectric (TE)-based radiant cooling ceiling panel on the thermal comfort in a test chamber. The system consists of a rectangular test chamber (∼ 1.2 m × 1.2 m × 1.5 m) with a ceiling panel fabricated on the center of the ceiling (0.6 m × 0.6 m × 0.002 m). Four TE modules are installed on the backside of the ceiling panel producing a cooling effect to maintain the ceiling temperature at the desired level. The lowered temperature of the ceiling panel allows heat exchange through radiation and convection. A spherical object is used to model a globe thermometer (GT) and capture the mean radiant temperature inside of the chamber. The variation of mean radiant temperature and operative temperature versus time are assessed under natural convection, and the comfort level is evaluated using the PMV method based on ASHRAE Standard 55. Design challenges, such as temperature limitation to the dew point temperature, among others, will be discussed. The result of this study provides insights regarding the expected thermal comfort from TE-based radiant cooling systems under various conditions.
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Sterman, Michael, and Melody Baglione. "Simulating the Use of CO2 Concentration Inputs for Controlling Temperature in a Hydronic Radiant System." In ASME 2017 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2017. http://dx.doi.org/10.1115/imece2017-71095.

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Incorporating predictive control into heating, ventilation and air conditioning (HVAC) systems has the potential to improve occupancy comfort and reduce energy use. This paper simulates the novel use of carbon dioxide (CO2) concentration inputs to augment temperature prediction and control. An artificial neural network (ANN) model and a least mean squares (LMS) filtering algorithm are used to simulate the temperature and control of a classroom in a high performance academic building with hydronic radiant heating and cooling panels. Numerical models are populated with variables that affect the heat energy entering, leaving, and being generated in a classroom. These variables include indoor and outdoor air temperature, radiant water and supply air temperatures, and classroom CO2 concentrations. The models are compared and then used to simulate the effect of a new control system that inputs CO2 measurements to account for the heat being generated by occupants of the controlled space. Simulation results suggest that augmenting HVAC control systems with CO2 measurements has the potential to improve temperature regulation by anticipating heating and cooling demand fluctuations in spaces with abrupt changes in occupancy.
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Reports on the topic "Radiant Heating and Cooling"

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Feustel, H. E. Hydronic radiant cooling: Overview and preliminary performance assessment. Office of Scientific and Technical Information (OSTI), May 1993. http://dx.doi.org/10.2172/6214501.

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Feustel, H. E. Hydronic radiant cooling: Overview and preliminary performance assessment. Office of Scientific and Technical Information (OSTI), May 1993. http://dx.doi.org/10.2172/10169585.

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Sitarski, M. Radiant heating of one- and two-phase aerosols. Office of Scientific and Technical Information (OSTI), July 1989. http://dx.doi.org/10.2172/5240976.

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Damman, Dennis. Cab Heating and Cooling. Office of Scientific and Technical Information (OSTI), October 2005. http://dx.doi.org/10.2172/903061.

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Cooper, Marcia A., William Wilding Erikson, Michael S. Oliver, Michael Jiro Kaneshige, and Daniel Sandoval. Radiant heating cookoff experiments and predictive simulations for fast cookoff. Office of Scientific and Technical Information (OSTI), October 2012. http://dx.doi.org/10.2172/1055867.

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Hunt, A., J. Ayer, P. Hull, R. McLaughlin, F. Miller, J. Noring, R. Russo, and W. Yuen. Solar radiant heating of gas-particle mixtures. FY 1984 summary report. Office of Scientific and Technical Information (OSTI), June 1986. http://dx.doi.org/10.2172/5188817.

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Teotia, A. P. S., D. E. Karvelas, E. J. Daniels, and J. L. Anderson. District heating and cooling market assessment. Office of Scientific and Technical Information (OSTI), June 1993. http://dx.doi.org/10.2172/10157992.

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Holtz, M. IEA solar heating and cooling program. Office of Scientific and Technical Information (OSTI), April 1989. http://dx.doi.org/10.2172/6925318.

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Levins, W., M. Karnitz, and J. Hall. Cooling season energy measurements of dust and ventilation effects on radiant barriers. Office of Scientific and Technical Information (OSTI), March 1990. http://dx.doi.org/10.2172/7064651.

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Garton, Byron. Heating and Cooling Cost Model user’s guide. Information Technology Laboratory (U.S.), July 2019. http://dx.doi.org/10.21079/11681/33591.

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