Radiant heating and cooling systems based on capillary micro tubes

Автор: Khrestianovskaia M.V., Rodionova M.A., Gabitova G.A.

Журнал: Строительство уникальных зданий и сооружений @unistroy

Статья в выпуске: 9 (60), 2017 года.

Бесплатный доступ

Radiant heating and cooling systems based on capillary micro tubes have been gaining much popularity due to large operational area, space saving, small difference between temperatures of flowing water and air inside the room and consequently improved energy efficiency. The objective of this review is to find out fields of applying capillary micro tubes, to discover advantages and limitations and analysis of future development. Based on research results it can be concluded that heating system based on capillary mats is an effective and promising solution for residential and public buildings.

Radiant heating and cooling systems, energy efficiency, capillary tubes mat, capillary micro tubes, hydronic heating systems, low temperature heating

Короткий адрес: https://sciup.org/143163540

IDR: 143163540

Список литературы Radiant heating and cooling systems based on capillary micro tubes

  • EPDB, Energy Performance of Building Directive, European Union. http://europa.eu/legislation_summaries/other/l27042_eu.htm.
  • Mikeska T., Svendsen S. Study of thermal performance of capillary micro tubes integrated into building sandwich element made of high performance concrete. Applied Thermal Engineering. 2013. Vol. 52. Issue 2. Pp. 576-584.
  • Pérez-Lombard L, Ortiz J, Pout C. A review on buildings energy consumption information. Energy Build. 2008. Vol. 40. Pp. 394-398.
  • Mikeska T., Svendsen S. Dynamic behavior of radiant cooling system based on capillary tubes in walls made of high performance concrete. Energy and Buidings. 2015. Vol. 108. Pp. 92-100.
  • Weibin K., Zhao M., Xing L., XiangZhao M., Lianying Z., Wangyyang H. Experimental investigation on a ceiling capillary radiant heating system. Energy Procedia. 2015. Vol. 75. Pp. 1380-1386.
  • Feng J., Schiavon S., Bauman F. New method for the design of radiant floor cooling systems with solar radiation. Energy and buildings. 2016. Vol. 125. Pp. 9-18
  • ASHRAE, ASHRAE handbook -HVAC systems and equipment. Atlanta, GA: American Society of Heating, Refrigerating, and Air Conditioning Engineers, 2012.
  • Wang, Shan K. Handbook of air conditioning and refrigeration. 2001. 326 p.
  • Çengel Yunus A., Heat Transfer: A Practical Approach, second ed., McGraw-Hill. 2003. p. 562.
  • Pereverzeva I.S., Pavlov S.A. Sovremennii podhodi k kondizionirovaniyu zhilih obschestvennih zdanii . The new Ideas of New Century -2015: The Fifteenth International Scentific Conference Proceedings. 2015. No. 3. Pp. 280-286. (rus)
  • Olesen BW. Radiant floor heating in theory and practice. ASHRAE Journal, 2002. Vol. 44. Pp. 19-26.
  • Simmonds, P. Using radiant cooled floors to condition large spaces and maintain comfort conditions. ASHRAE Transactions. 2000. Vol. 1060. Pp. 695-701.
  • Olesen B.W. Radiant floor cooling systems. ASHRAE J. 2008. Vol. 2. Pp. 28-37.
  • Pisarev E. Teplii pol, vodyanoii ili elektricheskii . Moscow: Robur, 2012. 47 p. (rus)
  • Olesen, B.W. Thermo active building systems using building mass to heat and cool. ASHRAE Journal. 2012. Vol. 54. Pp. 44-52.
  • Helmut E. Feustel, Corina Stetiu. Hydronic radiant cooling -preliminary assessment. Energy and Buidings. 1995. Vol.22. Pp. 193-205.
  • Bearzi V. Tjeplii poli. Teoriya I praktika. . АВОК. 2005. Vol. 7. Pp. 70-82. (rus)
  • Kosir M., Krainer A., Dovjak M., Perdan R., Kristl Z. Alternative to the conventional heating and cooling systems in public buildings. Strojniski vestnik -Journal of Mechanical Engineering. 2010. Vol. 56. Pp. 575-583.
  • Hesaraki A., Bourdakis E., Ploskic A., Holmberg S. Experimental study of energy performance in low-temperature hydronic heating systems. Energy and Buildings. 2015. Vol. 109. Pp. 108-114.
  • Maivel M., Kurnitski J. Low temperature radiator heating distribution and emission efficiency in residential buildings. Energy Build. 2014. Vol. 69. Pp. 224-236.
  • Koca A. 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. Springer. 2014. p. 435-445.
  • Hu R, Niu J. A review of the application of radiant cooling & heating systems in Mainland China. Energy and Buildings. 2012. Vol. 52. Pp. 11-19.
  • Bojic M. Performances of low temperature radiant heating systems. Energy and Buildings. 2013. Vol. 61. Рp. 233-238
  • Hasan A, Kurnitski J, Jokiranta K. A combined low temperature water heating system consisting of radiators and floor heating. Energy Build. 2009. Vol. 41. Pp. 470-479.
  • Guidebook No 7: Low Temperature Heating and High Temperature Cooling. REHVA. 2007.
  • Boersta A., Veld P.O., Eijdems H. The health, safety and comfort advantages of low-temperature heating system: a literature review. Proceedings of the 6th International Conference on Healthy Buildings, Espoo, Finland, August, 2000.
  • Bean R, Olesen B.W., Kim K.W. History of radiant heating and cooling systems: part 1. ASHRAE Journal. 2010. Vol. 52. Pp. 40-41.
  • Bean R., Olesen B.W., Kim K.W. History of Radiant Heating & Cooling Systems, Part 2. ASHRAE Journal. 2010. Vol. 2. Pp. 50-55.
  • Rhee K-N, Kim KW. A 50 year review of basic and applied research in radiant heating and cooling systems for the built environment. Building and Environment. 2015. Vol. 91. Pp. 166-190.
  • Bansal N. Characteristic parameters of a hypocaust construction. Build Environ. 1998. Vol. 34. Pp. 305-318.
  • Kim D-K. The natural environment control system of Korean traditional architecture: comparison with Korean contemporary architecture. Built Environ. 2009. Vol. 41. Pp. 1905-1912.
  • Bae C, Chun C. Research on seasonal indoor thermal environment and residents' control behaviour of cooling and heating systems in Korea. Build Environ. 2009. Vol. 44. Pp. 2300-2307.
  • Hesaraki A., Holmberg S. Energy performance of low-temperature heating systems in five new-built Swedish dwellings: a case study using simulations and on-site measurements. Build. Environ. 2013. Vol. 64. Pp. 85-93.
  • Olesen B.W. Possibilities and limitations of radiant floor cooling. ASHRAE Transactions. 1997. Vol. 103. Pp. 42-48.
  • Fonseca N, Cuevas C, Lemort V. Radiant ceiling systems coupled to its environment part 1: Experimental analysis. Applied Thermal Engineering. 2010. Vol. 30(14-15). Pp. 2187-2195.
  • Ochs F., Dermentzis G., Feist W. Investigation of new concepts of ground heat exchangers and building integrated heat exchangers for passive houses by means of dynamic building and system simulation. Proceedings of BS2013: 13th Conference of International Building Performance Simulation Association, Chambéry, France, August 26-28
  • Banjac M., Vasiljevic B., Gojak M. Low-temperature hydronic heating system with radiators and geothermal ground source heat pump. FME Transactions. 2007. Vol. 35. Pp. 129-134.
  • Meierhans R.A. Room air conditioning by means of overnight cooling of the concrete ceiling. ASHRAE Transactions. 1996. Vol. 102. Pp. 693-697.
  • Yost A., Barbour E., Watson R. An evaluation of thermal comfort and energy consumption for a surface mounted ceiling radiant panel heating system. ASHRAE Transactions. 1995. Vol. 101. Pp. 1221-1235.
  • Bojic M., Cvetkovic D., Miletic M., Malesevic J., Boyer H. Energy, cost, and CO2 emission comparison between radiant wall panel systems and radiator systems. Energy and Buildings. 2012. Vol. 54. Pp. 496-502.
  • Atmaca I, Kaynakli O, Yigit A. Effects of radiant temperature on thermal comfort. Build Environ. 2007. Vol. 42. Pp. 3210-3220.
  • Myhren J.A., Holmberg S. Flow patterns and thermal comfort in a room with panel, floor and wall heating. Energy Build. 2008. Vol. 40. Pp. 524-36.
  • Simmonds P., Holst S., Reuss S., Gaw W. Using radiant cooled floors to condition large spaces and maintain comfort conditions. ASHRAE Trans. 2000. Vol. 106 (1). Pp. 695-701.
  • Imanari T., Omori T., Bogaki K. Thermal comfort and energy consumption of the radiant ceiling panel system. Comparison with the conventional all air system. Energy and Building. 1999. Vol. 30. Pp. 167-175.
  • Aste N., Della Torre S., Adhikari R.S., Buzzetti M., Del Pero C., Leonforte F., Manfren M. Sustainable church heating: The Basilica di Collemaggio case-study. Energy and Buildings. 2016. Vol. 116. Pp. 218-231
  • Liu Y, Wang D, Liu J. Study on heat transfer process for in-slab heating floor. Build Environ. 2012. Vol. 54. Pp. 77-85.
  • Khorasanizadeh H et al. Numerical study of air flow and heat transfer in a two dimensional enclosure with floor heating. Energy Build. 2014. Vol. 78. Pp. 98-104.
  • Zhang D, Cai N, Wang Z. Experimental and numerical analysis of lightweight radiant floor heating system. Energy Build. 2013. Vol. 61. Pp. 260-266.
  • Zhang L, Liu X, Jiang Y. Experimental evaluation of a suspended metal ceiling radiant panel with inclined fins. Energy and Buildings. 2013. Vol. 62. Pp. 522-529.
  • Causone F., Corgnati S.P., Filippi M., Olesen B.W. Experimental evaluation of heat transfer coefficients between radiant ceiling and room. Energy and Buildings. 2009. Vol. 41 Pp. 622-628.
  • Olesen, B.W., Michel, E., Bonnefoi, F., De Carli, M. Heat exchange coefficient between floor surface and space by floor cooling: theory or a question of definition. ASHRAE Transactions. Part I. 2000.
  • Zhang Z., Pate B. A semi-analytical formulation of heat transfer from structures with embedded tubes. Heat Transfer in Buildings and Structures. 1987. Vol. 78. Pp. 17-25.
  • Strand K., Pederson O. Modeling radiant systems in an integrated heat balance based energy simulation program. ASHRAE Transactions. 2002. Vol. 108. Pp. 1-9.
  • Miriel J., Serres L., Trombe A. Radiant ceiling panel heating-cooling systems: experimental and simulated study of the performances, thermal comfort and energy consumptions. Applied Thermal Engineering. 2002. Vol. 22. Pp. 1861-1873.
  • Laouadi A. Development of a radiant heating and cooling model for building energy simulation software. Building and Environment. 2004. Vol. 39. Pp. 421-431.
  • Dovjak M., Shukuya M., Krainer A. Exergy analysis of conventional and low exergy systems for heating and cooling of near zero energy buildings. Strojniski vestnik -Journal of Mechanical Engineering. 2012. Vol. 58. Pp. 453-461.
  • Kilkis B. Exergy metrication of radiant panel heating and cooling with heat pumps. Energy Conversion and Management. 2012. Vol. 63. Pp. 218-224.
  • Odyjas A., Gorka A. Simulations of floor cooling system capacity. Applied Thermal Engineering. 2013. Vol. 51. Pp. 84-90.
  • Andrés-Chicote M., Tejero-Gonzalez A., Velasco-Gomez E., Rey-Martinez F.J. Experimental study on the cooling capacity of a radiant cooled ceiling system. Energy Build. 2012. Vol. 54. Pp. 207-214.
  • Zhang L., Liu X.-H., Jiang Y. Simplified calculation for cooling/heating capacity, surface temperature distribution of radiant floor. Energy Build. 2012. Vol. 55. Pp. 397-404.
  • Cholewa T., M. Rosinski, Z. Spik, M.R. Dudziiska, A. Siuta-Olcha. On the heat transfer coefficients between heated/cooled radiant floor and room. Energy Build. 2013. Vol. 66. Pp. 599-606.
  • Feng J., Bauman F., Schiavon S. Experimental comparison of zone cooling load between radiant and air systems. Energy Build. 2014. Vol. 84. Pp. 152-159.
  • Ghatti V. Experimental validation of the EnergyPlus low-temperature radiant simulation. ASHRAE Trans. 2013. Vol. 109 (2). Pp. 614-623.
  • Strand R.K., Baumgartner K.T. Modeling radiant heating and cooling systems: integration with a whole-building simulation program. Energy and Buildings. 2005. Vol. 37. Pp. 389-397.
  • Nizovcev M.I., Sakharov I.A. Raschet vzaimnogo vliyania teplovih I konstruktivnih parametrov vodyanogo teplogo pola . Polzunovskii vestnik. 2013. No. 4-3. Pp. 33-37. (rus)
  • Catalina T, Virgone J, Kuznik F. Evaluation of thermal comfort using combined CFD and experimentation study in a test room equipped with a cooling ceiling. Build Environ. 2009. Vol. 44. Pp. 1740-1750.
  • Jin X, Zhang X, Luo Y, Cao R. Numerical simulation of radiant floor cooling system: the effects of thermal resistance of pipe and water velocity on the performance. Build Environ. 2010. Vol. 45. Pp. 2545-52.
  • Olesen, B.W. "Hydronic Radiant Heating and Cooling of Buildings Using Pipes Embedded in the Building Structure". 2000. 41 AICARR Conference.
  • Barzin R. Application of PCM under floor heating in combination with PCM wallboards for space heating using price based control system. Applied Energy. 2015. Vol. 148. Pp. 39-48.
  • Hesaraki A, Holmberg S. Demand-controlled ventilation in new residential buildings: consequences on indoor air quality and energy savings. Indoor Built Environ. 2013. Vol. 24. Pp. 162-173.
  • Bojić M, Cvetković D, Marjanović V, et al. Performances of low temperature radiant heating systems. Energy and Buildings. 2013. Vol. 61. Pp. 233-238.
  • Maloney M., Pederson O., Witte J. Development of a radiant heating system model for BLAST. ASHRAE Transactions. 1988. Vol. 94. Pp. 1795-1808
  • Kilkis S. A net-zero building application and its role in exergy-aware local energy strategies for sustainability. Energy Conversion and Management. 2012. Vol. 63. Pp. 208-217.
  • Nall D. Thermally active floors. ASHRAE J. 2013. Vol. 36. Pp. 36-46.
  • Doebber I., Moore M., Deru M. Radiant slab cooling for retail. ASHRAE J. 2010. Vol. 52(12). Pp. 28-38.
  • Dieckmann, J., K. Roth, and J. Broderick. Dedicated outdoor air systems. ASHRAE Journal. 2003. Vol. 45(3) Pp. 58 -59.
  • Hasan A., Kurnitski J., Jokiranta K. A combined low-temperature water heating system consisting of radiators and floor heating. Energy Build. 2009. Vol. 41. Pp. 470-479.
  • Zhou G., He J. Thermal performance of a radiant floor heating system with different heat storage materials and heating pipes. Applied Energy. 2015. Vol. 138. Pp. 648-660.
  • Lim J-H, Jo J-H, Kim Y-Y, Yeo M-S, Kim K-W. Application of the control methods for radiant floor cooling system in residential buildings. Build Environ. 2006. Vol. 41. Pp. 60-73.
  • Kilkis, I.B. Radiant ceiling cooling with solar energy: Fundamentals, modelling, and a case design. ASHRAE Transactions. 1993. Vol. 99. Pp. 521-533.
  • Shan M, Yu T, Yang X. Assessment of an integrated active solar and air-source heat pump water heating system operated within a passive house in a cold climate zone. Renew Energy. 2016. Vol. 87. Pp.1059-66.
  • Chen X et al. Experimental studies on a ground coupled heat pump with solar thermal collectors for space heating. Energy. 2011. Vol. 36. Pp. 5292-5300.
  • Carbonell D, Haller MY, Philippen D, et al. Simulations of Combined Solar Thermal and Heat Pump Systems for Domestic Hot Water and Space Heating. Energy Procedia. 2014. Vol. 48. Pp. 524-534.
  • Zhao K., Liu X.-H., Jiang Y. Application of radiant floor cooling in a large open space building with high-intensity solar radiation. Energy and buildings. 2013. Vol. 66. Pp. 246-257.
  • Causone F., Corgnati S.P., Filippi M., Olesen B.W. Solar radiation and cooling load calculation for radiant systems: definition and evaluation of the direct solar load. Energy Build. 2010. Vol. 42 (3). Pp. 305-314.
  • Li Q., Wu J., Liu H., Pan T., Li Y. Experimental research on office building solar capillary heating system. Procedia Engineering. 2015. Vol. 121. Pp. 2021-2028.
  • Simmonds P., Mehlomakulu B., Ebert T. Radiant cooled floors: operation and control dependant upon solar radiation. ASHRAE Trans. 2006. Vol. 112 (1). Pp. 358-367.
  • Dieckmann, J., K. Roth, and J. Brodrick. Radiant ceiling cooling. ASHRAE Journal. 2003. Vol. 46(6). Pp. 42-43.
  • Kilkis, I.B., Sager S.S., Uludag M. A simplified model for radiant heating and cooling panels. Simulation Practice and Theory Journal. 1994. Vol. 2. Pp. 61-76.
  • Weitzmann P., Modelling Building Integrated Heating and Cooling Systems. PhD thesis. Technical University of Denmark. 2004.
  • Stetiu C. Energy and peak power potential of radiant cooling systems in US commercial buildings. Energy and Buildings. 1999. Vol. 30. Pp. 127-138.
  • Shuravina D.M., Kharkov N.S., Nemova D.V., Tseytin D.N. Temperaturnoye pole uchastka tekhnologicheskoi pliti sanno-bobsleynoi trassi i ego raschet . Construction of Unique Buildings and Structures. 2013. No. 9 (14). Pp. 57-68. (rus)
Еще
Статья обзорная