Underfloor heating

Underfloor heating and cooling is a form of central heating and cooling which achieves indoor climate control for thermal comfort using conduction, radiation and convection. The terms radiant heating and radiant cooling are commonly used to describe this approach because radiation is responsible for a significant portion of the resulting thermal comfort but this usage is technically correct only when radiation composes more than 50% of the heat exchange between the floor and the rest of the space.[1]

History

Underfloor heating has a long history back into the Neoglacial and Neolithic periods. Archeological digs in Asia and the Aleutian islands of Alaska reveal how the inhabitants drafted smoke from fires through stone covered trenches which were excavated in the floors of their subterranean dwellings. The hot smoke heated the floor stones which then radiated into the living spaces. These early forms have evolved into modern systems using fluid filled pipes or electrical cables and mats. Below is a chronological overview of under floor heating from around the world.

Time period, c. BC[2] Description[2]
5,000 Evidence of "baked floors" are found foreshadowing early forms of kang and dikang "heated floor" later ondol meaning "warm stone" in Manchuria and Korea respectively.[3]
3,000 Korean fire hearth, was used both as kitchen range and heating stove.
1,000Ondol type system used in the Aleutian Islands, Alaska[4] and in Unggi, Hamgyeongbuk-do (present-day North Korea).
1,000 More than two hearths were used in one dwelling; one hearth located at the center was used for heating, the others at the perimeter was used for cooking throughout the year. This perimeter hearth is the initial form of the budumak (meaning kitchen range), which composes combustion section of the traditional ondol in Korea.
500 Greeks and later Romans scale up the use of conditioned surfaces (floors and walls) with the hypocausts.
200 Central hearth developed into gudeul (meaning heat releasing section of ondol) and perimeter hearth for cooking became more developed and budumak was almost established in Korea.
50 China, Korea and Roman Empire use kang, dikang/ondol and hypocaust respectively.
Time period, c. AD[5] Description[5]
500 Asia continues to use conditioned surfaces but the application is lost in Europe where it is replaced by the open fire or rudimentary forms of the modern fireplace. Anecdotal literary reference to radiant cooling system in the Middle East using snow packed wall cavities.
700More sophisticated and developed gudeul was found in some palaces and living quarters of upper-class people in Korea. Countries in the Mediterranean Basin (Iran, Algeria, Turkey et al.) use various forms of hypocaust type heating in public baths and homes (ref.: tabakhana, atishkhana, sandali) but also use heat from cooking (see:tandoor, also tanur) to heat the floors.[6][7][8]
1000 Ondol continues to evolve in Asia. The most advanced true ondol system was established. The fire furnace was moved outside and the room was entirely floored with ondol in Korea. Europe uses various forms of the fireplace with the evolution of drafting combustion products with chimneys.
1300 Hypocaust type systems used to heat monasteries in Poland and teutonic Malbork Castle.[9]
1400 Hypocaust type systems used to heat Turkish Baths of the Ottoman Empire.
1500 Attention to comfort and architecture in Europe evolves; China and Korea continue to apply floor heating with wide scale adoption.
1600 In France, heated flues in floors and walls are used in greenhouses.
1700 Benjamin Franklin studies the French and Asian cultures and makes note of their respective heating system leading to the development of the Franklin stove. Steam based radiant pipes are used in France. Hypocaust type system used to heat public bath (Hammam) in the citadel town of Erbil located in modern-day Iraq.[10]
1800 Beginnings of the European evolution of the modern water heater/boiler and water based piping systems including studies in thermal conductivities and specific heat of materials and emissivity/reflectivity of surfaces (Watt/Leslie/Rumford).[11] Reference to the use of small bore pipes used in the John Soane house and museum.[12]
1864 Ondol type system used at Civil War hospital sites in America.[13] Reichstag building in Germany uses the thermal mass of the building for cooling and heating.
1899 The earliest beginnings of polyethylene-based pipes occur when German scientist, Hans von Pechmann, discovered a waxy residue at the bottom of a test tube, colleagues Eugen Bamberger and Friedrich Tschirner called it polymethylene but it was discarded as having no commercial use at the time.[14]
1904 Liverpool Cathedral in England is heated with system based on the hypocaust principles.
1905 Frank Lloyd Wright makes his first trip to Japan, later incorporates various early forms of radiant heating in his projects.
1907 England, Prof. Barker granted Patent No. 28477 for panel warming using small pipes. Patents later sold to the Crittal Company who appointed representatives across Europe. A.M. Byers of America promotes radiant heating using small bore water pipes. Asia continues to use traditional ondol and kang—wood is used as the fuel, combustion gases sent under floor.
1930 Oscar Faber in England uses water pipes used to radiant heat and cool several large buildings.[15]
1933 Explosion at England’s Imperial Chemical Industries (ICI) laboratory during a high pressure experiment with ethylene gas results in a wax like substance—later to become polyethylene and the re-beginnings of PEX pipe.[16]
1937 Frank Lloyd Wright designs the radiant heated Herbert Jacobs house, the first Usonian home.
1939 First small scale polyethylene plant built in America.
1945 American developer William Levitt builds large scale developments for returning GI’s. Water based (copper pipe) radiant heating used throughout thousands of homes. Poor building envelopes on all continents require excessive surface temperatures leading in some cases to health problems. Thermal comfort and health science research (using hot plates, thermal manikins and comfort laboratories) in Europe and America later establishes lower surface temperature limits and development of comfort standards.
1950 Korean War wipes out wood supplies for ondol, population forced to use coal. Developer Joseph Eichler in California begins the construction of thousands of radiant heated homes.
1951 Dr. J. Bjorksten of Bjorksten Research Laboratories in Madison, WI, announces first results of what is believed to be the first instance of testing three types of plastic tubing for radiant floor heating in America. Polyethylene, vinyl chloride copolymer, and vinylidene chloride were tested over three winters.[17]
1953The first Canadian polyethylene plant is built near Edmonton, Alberta.[18]
1960NRC researcher from Canada installs underfloor heating in his home and later remarks, "Decades later it would be identified as a passive solar house. It incorporated innovative features such as the radiant heating system supplied with hot water from an automatically stoked anthracite furnace."[19]
1965 Thomas Engel patents method for stabilizing polyethylene by cross linking molecules using peroxide (PEx-A) and in 1967 sells license options to a number of pipe producers.[20]
1970 Evolution of Korean architecture leads to multistory housings, flue gases from coal based ondol results in many deaths leading to the removal of the home based flue gas system to a central water based heating plants. Oxygen permeation becomes corrosion issue in Europe leading to the development of barriered pipe and oxygen permeation standards.
1980 The first standards for floor heating are developed in Europe. Water-based ondol system is applied to almost all of residential buildings in Korea.
1985 Floor heating becomes a traditional heating systems in residential buildings in Middle Europe and Nordic countries and increasing applications in non-residential buildings.
1995 The application of floor cooling and thermal active building systems (TABS) in residential and commercial buildings are widely introduced into the market.[21]
2000 The use of embedded radiant cooling systems in middle of Europe becomes a standard system with many parts of the world applying radiant based HVAC systems as means of using low temperatures for heating and high temperatures for cooling.
2010 Radiant conditioned Pearl River Tower in Guangzhou, China, topped out at 71-stories.

Description

Modern underfloor heating systems use either electrical resistance elements ("electric systems") or fluid flowing in pipes ("hydronic systems") to heat the floor. Either type can be installed as the primary, whole-building heating system or as localized floor heating for thermal comfort. Electrical resistance can only be used for heating; when space cooling is also required, hydronic systems must be used. Other applications for which either electric or hydronic systems are suited include snow/ice melting for walks, driveways and landing pads, turf conditioning of football and soccer fields and frost prevention in freezers and skating rinks. A range of underfloor heating systems and designs are available to suit different types of flooring.[22]

Electric heating elements or hydronic piping can be cast in a concrete floor slab ("poured floor system" or "wet system"). They can also be placed under the floor covering ("dry system") or attached directly to a wood sub floor ("sub floor system" or "dry system").

Some commercial buildings are designed to take advantage of thermal mass which is heated or cooled during off peak hours when utility rates are lower. With the heating/cooling system turned off during the day, the concrete mass and room temperature drift up or down within the desired comfort range. Such systems are known as thermally activated building systems or TABS.[23][24]

Hydronic systems

Hydronic systems use water or a mix of water and anti-freeze such as propylene glycol[25] as the heat transfer fluid in a "closed loop" that is recirculated between the floor and the boiler.

Various types of pipes are available specifically for hydronic underfloor heating and cooling systems and are generally made from polyethylene including PEX, PEX-Al-PEX and PERT. Older materials such as Polybutylene (PB) and copper or steel pipe are still used in some locales or for specialized applications.

Hydronic systems require skilled designers and tradespeople familiar with boilers, circulators, controls, fluid pressures and temperature. The use of modern factory assembled sub-stations, used primarily in district heating and cooling, can greatly simplify design requirements and reduce the installation and commissioning time of hydronic systems.

Hydronic systems can use a single source or combination of energy sources to help manage energy costs. Hydronic system energy source options are:

Electric systems

Electric floor heating installation, cement being applied

Electric systems are used only for heating and employ non-corrosive, flexible heating elements including cables, pre-formed cable mats, bronze mesh, and carbon films. Due to their low profile they can be installed in a thermal mass or directly under floor finishes. Electric systems can also take advantage of time-of-use electricity metering and are frequently used as carpet heaters, portable under area rug heaters, under laminate floor heaters, under tile heating, under wood floor heating, and floor warming systems, including under shower floor and seat heating. Large electric systems also require skilled designers and tradespeople but this is less so for small floor warming systems. Electric systems use fewer components and are simpler to install and commission than hydronic systems. Some electric systems use line voltage technology while others use low voltage technology. Power consumption of an electric system is not based on voltage but rather wattage output produced by the heating element.

Features

Thermal comfort quality

As defined by ANSI/ASHRAE Standard 55 – Thermal Environmental Conditions for Human Occupancy, thermal comfort is, "that condition of mind which expresses satisfaction with the thermal environment and is assessed by subjective evaluation." Relating specifically to underfloor heating, thermal comfort is influenced by floor surface temperature and associated elements such as radiant asymmetry, mean radiant temperature and operative temperature. Research by Nevins, Rohles, Gagge, P. Ole Fanger et al. show that humans at rest with clothing typical of light office and home wear, exchange over 50% of their sensible heat via radiation.

Underfloor heating influences the radiant exchange by thermally conditioning the interior surfaces with low temperature long wave radiation. The heating of the surfaces suppresses body heat loss resulting in a perception of heating comfort. This general sensation of comfort is further enhanced through conduction (feet on floor) and through convection by the surface's influence on air density. Underfloor cooling works by absorbing both short wave and long wave radiation resulting in cool interior surfaces. These cool surfaces encourage the loss of body heat resulting in a perception of cooling comfort. Localized discomfort due to cold and warm floors wearing normal foot wear and stocking feet is addressed in the ISO 7730 and ASHRAE 55 standards and ASHRAE Fundamentals Handbooks and can be corrected or regulated with floor heating and cooling systems.

Indoor air quality

Underfloor heating can have a positive effect on the quality of indoor air by facilitating the choice of otherwise perceived cold flooring materials such as tile, slate, terrazzo and concrete. These masonry surfaces typically have very low VOC emissions (volatile organic compounds) in comparison to other flooring options. In conjunction with moisture control, floor heating also establishes temperature conditions that are less favorable in supporting mold, bacteria, viruses and dust mites.[26][27] By removing the sensible heating load from the total HVAC (Heating, Ventilating, and Air Conditioning) load, ventilation, filtration and dehumidification of incoming air can be accomplished with dedicated outdoor air systems having less volumetric turnover to mitigate distribution of airborne contaminates. There is recognition from the medical community relating to the benefits of floor heating especially as it relates to allergens.[28][29]

Energy

Under floor radiant systems are evaluated for sustainability through the principles of efficiency, entropy, exergy[30] and efficacy. When combined with high performance buildings, under floor systems operate with low temperatures in heating and high temperatures in cooling[31] in the ranges found typically in geothermal[32] and solar thermal systems. When coupled with these non combustible, renewable energy sources the sustainability benefits include reduction or elimination of combustion and greenhouse gases produced by boilers and power generation for heat pumps[33] and chillers, as well as reduced demands for non renewables and greater inventories for future generations. This has been supported through simulation evaluations[34][35][36][37] and through research funded by the U.S. Department of Energy,[38][39] Canada Mortgage and Housing Corporation,[40] Fraunhofer Institute[41] as well as ASHRAE.[42]

Safety and health

Low temperature underfloor heating is embedded in the floor or placed under the floor covering. As such it occupies no wall space and creates no burn hazards, nor is it a hazard for physical injuries due to accidental contact leading to tripping and falling. This has been referenced as a positive feature in healthcare facilities including those serving elderly clients and those with dementia.[43][44][45] Anecdotally, under similar environmental conditions, heated floors will speed evaporation of wetted floors (showering, cleaning, and spills). Additionally, underfloor heating with fluid filled pipes is useful in heating and cooling explosion proof environments where combustion and electrical equipment can be located remotely from the explosive environment.

There is a likelihood that underfloor heating may add to offgassing and sick building syndrome in an environment, particularly when carpet is used as a flooring.

Electric underfloor heating systems cause low frequency magnetic fields (in the 50–60 Hz range), old 1-wire systems much more so than modern 2-wire systems.[46][47] The International Agency for Research on Cancer (IARC) has classified static and low-frequency magnetic fields as possibly carcinogenic (Group 2B).[48]

Longevity, maintenance and repair

Equipment maintenance and repair is the same as for other water or electrical based HVAC systems except when pipes, cables or mats are embedded in the floor. Early trials (for example homes built by Levitt and Eichler, c. 1940-70’s) experienced failures in embedded copper and steel piping systems as well as failures assigned by the courts to Shell, Goodyear and others for polybutylene and EPDM materials.[49][50] There also have been a few publicized claims of failed electric heated gypsum panels from the mid 90’s.[51]

Failures associated with most installations are attributable to job site neglect, installation errors and product mishandling such as exposure to ultraviolet radiation. Pre-pour pressure tests required by concrete installation standards[52] and good practice guidelines[53] for the design, construction, operation and repair of radiant heating and cooling systems mitigate problems resulting from improper installation and operation.

Fluid based systems using Cross-linked polyethylene (PE-x) a product developed in the 1930s and its various derivatives such as PE-rt, have demonstrated reliable long term performance in harsh cold-climate applications such as bridge decks, aircraft hangar aprons and landing pads. PEX has become a popular and reliable option in home use for new concrete slab construction, and new underfloor joist construction as well as (joist) retrofit. Since the materials are produced from polyethylene and its bonds are cross-linked, it is highly resistant to corrosion or the temperature and pressure stresses associated with typical fluid based HVAC systems.[54] For PEX reliability, installation procedures must be precise (especially at joints) and manufacturers specifications for maximum temperature of water or fluid, etc. must be carefully followed.

Design and installation

General considerations for placing radiant heating and cooling pipes in flooring assemblies where other HVAC and plumbing components may be present
Typical under floor heating and cooling assemblies. Local practices, codes, standards, best practices and fire regulations will determine actual materials and methods

The engineering of underfloor cooling and heating systems is governed by industry standards and guidelines.[55][56][notes 2]

Technical design

The amount of heat exchanged from or to an underfloor system is based on the combined radiant and convective heat transfer coefficients.

Convective heat transfer with underfloor systems is much greater when the system is operating in a heating rather than cooling mode.[57] Typically with underfloor heating the convective component is almost 50% of the total heat transfer and in underfloor cooling the convective component is less than 10%.[58]

Heat and moisture considerations

When heated and cooled pipes or heating cables share the same spaces as other building components, parasitic heat transfer can occur between refrigeration appliances, cold storage areas, domestic cold water lines, air conditioning and ventilation ducts. To control this, the pipes, cables and other building components must all be well insulated.

With underfloor cooling, condensation may collect on the surface of the floor. To prevent this, air humidity is kept low, below 50%, and floor temperatures are maintained above the dew point, 19 °C (66F).[59]

Building systems and materials

Control system

Underfloor heating and cooling systems can have several control points including the management of:

Mechanical schematic

Example of a radiant based HVAC schematic

Illustrated is a simplified mechanical schematic of an underfloor heating and cooling system for thermal comfort quality[64] with a separate air handling system for indoor air quality.[65][66] In high performance residential homes of moderate size (e.g. under 3000 ft2 (278 m2) total conditioned floor area), this system using manufactured hydronic control appliances would take up about the same space as a three or four piece bathroom.

Modeling piping patterns with finite element analysis

Modeling radiant piping (also tube or loop) patterns with finite element analysis (FEA) predicts the thermal diffusions and surface temperature quality or efficacy of various loop layouts. The performance of the model (left image above) and image to the right are useful to gain an understanding in relationships between flooring resistances, conductivities of surrounding mass, tube spacings, depths and fluid temperatures. As with all FEA simulations, they depict a snap shot in time for a specific assembly and may not be representative of all floor assemblies nor for system that have been operative for considerable time in a steady state condition. The practical application of FEA for the engineer is being able to assess each design for fluid temperature, back losses and surface temperature quality. Through several iterations it is possible to optimize the design for the lowest fluid temperature in heating and the highest fluid temperature in cooling which enables combustion and compression equipment to achieve its maximum rated efficiency performance.

Economics

There is a wide range of pricing for underfloor systems based on regional differences, materials, application and project complexity. It is widely adopted in the Nordic, Asian and European communities. Consequently, the market is more mature and systems relatively more affordable than North America where market share for fluid based systems remains between 3% to 7% of HVAC systems (ref. Statistics Canada and United States Census Bureau).

In energy efficiency buildings such as Passive House, R-2000 or Net Zero Energy, simple thermostatic radiator valves can be installed along with a single compact circulator and small condensing heater controlled without or with basic hot water reset[67] control. Economical electric resistance based systems also are useful in small zones such as bathrooms and kitchens, but also for entire buildings where heating loads are very low. Larger structures will need more sophisticated systems to deal with cooling and heating needs, and often require building management control systems to regulate the energy use and control the overall indoor environment.

Low temperature radiant heating and high temperature radiant cooling systems lend themselves well to district energy systems (community based systems) due to the temperature differentials between the plant and the buildings which allow small diameter insulated distribution networks and low pumping power requirements. The low return temperatures in heating and high return temperatures in cooling enable the district energy plant to achieve maximum efficiency. The principles behind district energy with underfloor systems can also be applied to stand alone multi story buildings with the same benefits.[68] Additionally, underfloor radiant systems are ideally suited to renewable energy sources including geothermal and solar thermal systems or any system where waste heat is recoverable.

In the global drive for sustainability, long term economics supports the need to eliminate where possible, compression for cooling and combustion for heating. It will then be necessary to use low quality heat sources for which radiant underfloor heating and cooling is well suited.

System efficiency

System efficiency and energy use analysis takes into account building enclosure performance, efficiency of the heating and cooling plant, system controls and the conductivities, surface characteristics, tube/element spacing and depth of the radiant panel, operating fluid temperatures and wire to water efficiency of the circulators.[69] The efficiency in electric systems is analyzed by similar processes and includes the efficiency of electricity generation.

Though the efficiency of radiant systems is under constant debate with no shortage of anecdotal claims and scientific papers presenting both sides, the low return fluid temperatures in heating and high return fluid temperatures in cooling enable condensing boilers,[70] chillers[71] and heat pumps[72] to operate at or near their maximum engineered performance.[73][74] The greater efficiency of 'wire to water' versus 'wire to air' flow due to water's significantly greater heat capacity favors fluid based systems over air based systems.[75] Both field application and simulation research have demonstrated significant electrical energy savings with radiant cooling and dedicated outdoor air systems based in part on the previous noted principles.[76][77]

In Passive Houses, R-2000 homes or Net Zero Energy buildings the low temperatures of radiant heating and cooling systems present significant opportunities to exploit exergy.[78]

Efficiency considerations for flooring surface materials

System efficiency is also affected by the floor covering serving as the radiational boundary layer between the floor mass and occupants and other contents of the conditioned space. For example, carpeting has a greater resistance or lower conductance than tile. Thus carpeted floors need to operate at higher internal temperatures than tile which can create lower efficiencies for boilers and heat pumps. However, when the floor covering is known at the time the system is installed, then the internal floor temperature required for a given covering can be achieved through proper tube spacing without sacrificing plant efficiency (though the higher internal floor temperatures may result in increased heat loss from the non-room surfaces of the floor).[79]

The emissivity, reflectivity and absorptivity of a floor surface are critical determinants of its heat exchange with the occupants and room. Unpolished flooring surface materials and treatments have very high emissivity’s (0.85 to 0.95) and therefore make good heat radiators.[80]

With underfloor heating and cooling ("reversible floors") flooring surfaces with high absorbance and emissivity and low reflectivity are most desirable.

Thermographic evaluation

Thermographic images of a room heated with low temperature radiant heating shortly after starting up the system

Thermography is a useful tool to see the actual thermal efficacy of an underfloor system from its start up (as shown) to its operating conditions. In a startup it is easy to identify the tube location but less so as the system moves into a steady state condition. It is important to interpret thermographic images correctly. As is the case with finite element analysis (FEA), what is seen, reflects the conditions at the time of the image and may not represent the steady conditions. For example, the surfaces viewed in the images shown, may appear ‘hot’, but in reality are actually below the nominal temperature of the skin and core temperatures of the human body and the ability to ‘see’ the pipes does not equate to ‘feel’ the pipes. Thermography can also point out flaws in the building enclosures (left image, corner intersection detail), thermal bridging (right image, studs) and the heat losses associated with exterior doors (center image).

Global examples of large modern buildings using radiant heating and cooling

See also

References

  1. 1 2 Chapter 6, Panel Heating and Cooling, 2000 ASHRAE Systems and Equipment Handbook
  2. 1 2 Bean, R., Olesen, B., Kim, K.W., History of Radiant Heating and Cooling Systems, ASHRAE Journal, Part 1, January, 2010
  3. Guo, Q., (2005), Chinese Architecture and Planning: Ideas, Methods, Techniques. Sttutgart: Edition Axel Menges, Part 1, Chpt 2, pg 20-27
  4. Pringle, H., (2007), The Battle Over Amaknak Bridge. Archeology. 60(3)
  5. 1 2 Bean, R., Olesen, B., Kim, K.W., History of Radiant Heating and Cooling Systems, ASHRAE Journal, Part 2, January, 2010
  6. Papers on Traditional Public Baths-Hammam-in the Mediterranean, Archnet-IJAR, International Journal of Architectural Research, Vol. 3, Issue 1:157-170, March, 2009
  7. Kennedy, H., From Polis To Madina: Urban Change in Late Antique and Early Islamic Syria, Past and Present (1985) 106 (1): 3-27. doi:10.1093/past/106.1.3
  8. Rashti, C. (Intro), Urban Conservation and Area Development in Afghanistan, Aga Khan Historic Cities Programme, Aga Khan Trust for Culture, May, 2007
  9. "Muzeum Zamkowe w Malborku". www.zamek.malbork.pl.
  10. "High Commission for Erbil Citadel Revitalization, The Hammam". erbilcitadel.org. Archived from the original on 2009-07-05.
  11. Gallo, E., Jean Simon Bonnemain (1743-1830) and the Origins of Hot Water Central Heating, 2nd International Congress on Construction History, Queens' College, Cambridge, UK, edited by the Construction History Society, 2006
  12. Bruegmann, R., Central Heating and Forced Ventilation: Origins and Effects on Architectural Design, JSAH, Vol. 37, No.3, October 1978.
  13. The Medical and Surgical History of The War Of The Rebellion Part III., Volume II., Surgical History, 1883.
  14. "Science at a Distance". www.brooklyn.cuny.edu.
  15. Panel Heating, Structural Paper No.19, Oscar Faber, O.B.E, D.C.L (Hon), D.Sc. (Eng.), The Institution of Civil Engineers, May, 1947, pp.16
  16. PEX Association,The History and Influence of PEX Pipe on Indoor Environmental Quality,
  17. Bjorksten Test New Plastic Heating Tubes, (June 7, 1951), Consolidated Press Clipping Bureau U.S., Chicago
  18. The Canadian Encyclopedia, Industry - Petrochemical Industry , <"Archived copy". Archived from the original on October 20, 2008. Retrieved September 15, 2010.>
  19. Rush, K., (1997) Odyssey of an Engineering Researcher, The Engineering Institute of Canada, Eic History & Archives
  20. Engle, T. (1990) Polyethylene, A Modern Plastic From Its Discovery Until Today
  21. Moe, K., 2010, Thermally Active Surfaces in Architecture, Princeton Architectural Press , ISBN 978-1-56898-880-1
  22. "Archived copy" (PDF). Archived from the original (PDF) on September 4, 2014. Retrieved September 17, 2015.
  23. Kolarik, J., Yang, L., Thermal mass activation (Chpt.5) with Expert Guide Part 2, IEA ECBSC Annex 44, Integrating environmentally responsive elements in buildings, 2009
  24. Lehmann, B., Dorer, V., Koschenz, M., Application range of thermally activated building systems tabs, Energy and Buildings, 39:593–598, 2007
  25. "Low Temperature Heating Systems, Increased Energy Efficiency and Improved Comfort, Annex 37, International Energy Association" (PDF). lowex.org.
  26. Boerstra A., Op ´t Veld P., Eijdems H. (2000), The health, safety and comfort advantages of low temperature heating systems: a literature review. Proceedings of the Healthy Buildings conference 2000, Espoo, Finland, 6–10 August 2000.
  27. Eijdems, H.H., Boerrsta, A.C., Op ‘t Veld, P.J., Low temperature heating systems: Impact on IAQ, thermal comfort and energy consumption, the Netherlands Agency for Energy and the Environment (NOVEM) (c.1996)
  28. Rea, M.D., William J, "Optimum Environments for Optimum Health & Creativity", Environmental Health Center-Dallas, Texas.
  29. "Buying An Allergy-Friendly House: Q and A with Dr. Stephen Lockey". Allergy & Asthma Center. Archived from the original on October 25, 2010. Retrieved September 11, 2010.
  30. Asada, H., Boelman, E.C., Exergy analysis of a low temperature radiant heating system, Building Service Engineering , 25:197-209, 2004
  31. Babiak J., Olesen, B.W., Petráš, D., Low temperature heating and high temperature cooling – Embedded water based surface systems, REHVA Guidebook no. 7, Forssan Kirjapaino Oy- Forssan, Finland, 2007
  32. Meierhans, R.A., Slab cooling and earth coupling, ASHRAE Transactions, vol. 99(2):511-518, 1993
  33. Kilkis, B.I., Advantages of combining heat pumps with radiant panel and cooling systems, IEA Heat Pump Centre Newsletter 11 (4): 28-31, 1993
  34. Chantrasrisalai, C., Ghatti, V. , Fisher, D.E., Scheatzle, D.G., Experimental validation of the EnergyPlus low-temperature radiant simulation, ASHRAE Transactions, vol. 109(2):614-623, 2003
  35. Chapman, K.S., DeGreef, J.M., Watson, R.D., Thermal comfort analysis using BCAP for retrofitting a radiantly heated residence (RP-907), ASHRAE Transactions, vol. 103(1):959-965, 1997
  36. De Carli, M., Zarrella, A., Zecchin, R., Comparison between a radiant floor and two radiant walls on heating and cooling energy demand, ASHRAE Transactions, vol. 115(2), Louisville 2009
  37. Ghatti, V. S., Scheatzle, D. G., Bryan, H., Addison, M., Passive performance of a high-mass residence: actual data vs. simulation, ASHRAE Transactions, vol. 109(2):598-605, 2003
  38. Cort, K.A., Dirks, J.A., Hostick, D.J., Elliott, D.B., Analyzing the life cycle energy savings of DOE-supported buildings technologies(PNNL-18658), Pacific Northwest National Laboratory (for U.S. Department of Energy), August 2009
  39. Roth, K.W., Westphalen, D. , Dieckmann, J. , Hamilton, S.D. , Goetzler, W., Energy consumption characteristics of commercial building HVAC systems volume III: energy savings potential, TIAX, 2002
  40. Analysis of renewable energy potential in the residential sector through high-resolution building-energy simulation, Canada Mortgage and Housing Corporation, Technical Series 08-106, November 2008
  41. Herkel,S., Miara, M., Kagerer, F. (2010), Systemintegration Solar + Wärmepumpe, Fraunhofer-Institut für Solare Energiesysteme ISE
  42. Baskin, E., Evaluation of hydronic forced-air and radiant slab heating and cooling systems, ASHRAE Transactions, vol. 111(1):525-534, 2005
  43. Hoof, J.V., Kort, S.M., Supportive living environments: A first concept of a dwelling designed for older adults with dementia, Dementia, Vol. 8, No. 2, 293-316 (2009) doi:10.1177/1471301209103276
  44. Hashiguchi, N., Tochihara, Y., Ohnaka, T., Tsuchida, C., Otsuki, T., Physiological and subjective responses in the elderly when using floor heating and air conditioning systems, Journal of Physiological Anthropology and Applied Human Science, 23: 205–213, 2004
  45. Springer, W. E., Nevins, R.G., Feyerherm, A.M., Michaels, K.B., Effect of floor surface temperature on comfort: Part III, the elderly, ASHRAE Transactions 72: 292-300, 1966
  46. Underfloor heating EMFs.info
  47. Electric floor heating systems [Swiss] Federal Office of Public Health
  48. Non-Ionizing Radiation, Part 1: Static and Extremely Low-Frequency (ELF) Electric and Magnetic Fields International Agency for Research on Cancer, 2002
  49. Settlement Announced in Class Action with Shell, http://www.classaction.ca/pdf/Shell_PBP_PR_Release.pdf
  50. "Galanti v. The Goodyear Tire & Rubber Company and Kelman v. The Goodyear Tire & Rubber Company et al.". entraniisettlement.com.
  51. "Radiant ceiling panels, Ministry of Municipal Affairs, Electric Safety Branch, Province of British Columbia, 1994" (PDF). eiabc.org.
  52. "ACI 318-05 Building Code Requirements for Structural Concrete and Commentary". concrete.org.
  53. E.g. Radiant Panel Association, Canadian Institute of Plumbing and Heating, Thermal Environmental Comfort Association of British Columbia, and ISO Standards.
  54. "Plastic Pipe Institute, The Facts On Cross-Linked Polyethylene (Pex) Pipe Systems" (PDF). plasticpipe.org.
  55. ANSI/ASHRAE 55- Thermal Environmental Conditions for Human Occupancy
  56. ISO 7730:2005, Ergonomics of the thermal environment -- Analytical determination and interpretation of thermal comfort using calculation of the PMV and PPD indices and local thermal comfort criteria
  57. Bean, R., Kilkis, B., 2010, Short Course on the Fundamentals of Panel Heating and Cooling, American Society of Heating, Refrigerating and Air-Conditioning Engineers, Inc., <"Archived copy". Archived from the original on July 6, 2010. Retrieved August 25, 2010.>
  58. "ASHRAE Singapore Chapter" (PDF). www.ashrae.org.sg.
  59. Mumma, S., 2001, Designing Dedicated Outdoor Air Systems, ASHRAE Journal, 29-31
  60. Table 3 Soil Thermal Conductivities, 2008 ASHRAE Handbook—HVAC Systems and Equipment
  61. Natural Resources Canada's (NRCan's) validation of new building designs policies and procedures and interpretation of the Model National Energy Code for Commercial Buildings (MNECB), 2009
  62. Beausoleil-Morrison, I., Paige Kemery, B., Analysis of basement insulation alternatives, Carleton University, April 2009
  63. Wood Handbook, Wood as an Engineering Material, U.S. Department of Agriculture, Forest Service, Forest Products Laboratory, 2010
  64. 1 2 ANSI/ASHRAE Standard 55 - Thermal Environmental Conditions for Human Occupancy
  65. ASHRAE 62.1 Ventilation for Acceptable Indoor Air Quality
  66. ASHRAE 62.2 Ventilation and Acceptable Indoor Air Quality in Low Rise Residential Buildings
  67. Butcher, T., Hydronic baseboard thermal distribution system with outdoor reset control to enable the use of a condensing boiler, Brookhaven National Laboratory, (for) Office of Buildings Technology U.S. Department of Energy, October, 2004
  68. "Olesen, B., Simmonds, P., Doran, T., Bean, R., Vertically Integrated Systems in Standalone Multi Story Buildings, ASHRAE Journal Vol. 47, 6, June 2005," (PDF). psu.edu.
  69. "Rishel, J.B., Wire-to-Water Efficiency of Pumping Systems, ASHRAE Journal, April, 2001" (PDF). ashrae.org.
  70. Fig. 5 Effect of Inlet Water Temperature on Efficiency of Condensing Boilers, Chapter 27, Boilers, 2000 ASHRAE Systems and Equipment Handbook
  71. Thornton, B.A., Wang, W., Lane, M.D., Rosenberg, M.I., Liu, B., (September 2009), Technical Support Document: 50% Energy Savings Design Technology Packages for Medium Office Buildings, Pacific Northwest National Laboratory for the U.S. Department of Energy, DE-AC05-76RL01830
  72. Jiang, W., Winiarski, D.W., Katipamula, S., Armstrong, P.R., Cost-effective integration of efficient low-lift base-load cooling equipment (Final Report), Pacific Northwest National Laboratory, Prepared for the U.S. Department of Energy Office of Energy Efficiency and Renewable Energy Federal Energy Management Program, December, 2007
  73. Fitzgerald, D. Does warm air heating use less energy than radiant heating? A clear answer, Building Serv Eng Res Technol 1983; 4; 26, doi:10.1177/014362448300400106
  74. Olesen, B.W., deCarli, M., Embedded Radiant Heating and Cooling Systems: Impact of New European Directive for Energy Performance of Buildings and Related CEN Standardization, Part 3 Calculated Energy Performance of Buildings with Embedded Systems (Draft), 2005, < "Archived copy". Archived from the original on October 3, 2011. Retrieved September 14, 2010.>
  75. "Heat, Work and Energy". www.engineeringtoolbox.com.
  76. "Leigh, S.B., Song, D.S., Hwang , S.H., Lee, S.Y., A Study for Evaluating Performance of Radiant Floor Cooling Integrated with Controlled Ventilation, ASHRAE Transactions: Research, 2005" (PDF). nrel.gov.
  77. Leach, M., Lobato, C., Hirsch, A., Pless, S., Torcellini, P., Technical Support Document: Strategies for 50% Energy Savings in Large Office Buildings, National Renewable Energy Laboratory, Technical Report, NREL/TP-550-49213 , September 2010
  78. International Energy Agency, Annex 37 Low Exergy Systems for Heating and Cooling in Buildings
  79. Fig. 9 Design Graph for Heating and Cooling with Floor and Ceiling Panels, Panel Heating and Cooling, 2000 ASHRAE Systems and Equipment Handbook
  80. Pedersen, C.O., Fisher, D.E., Lindstrom, P.C. (March, 1997), Impact of Surface Characteristics on Radiant Panel Output, ASHRAE 876 TRP
  81. Simmonds, P., Gaw, W., Holst, S., Reuss, S., Using radiant cooled floors to condition large spaces and maintain comfort conditions, ASHRAE Transactions, vol. 106(1):695-701, 2000

Notes

  1. (CHP) (see also micro CHP and fuel cell
  2. A sample of design and installation standards:
    Part 1: Determination of the design heating and cooling capacity
    Part 2: Design, dimensioning and installation
    Part 3: Optimizing for use of renewable energy sources, Brussels, Belgium.
    Part 1: Definitions and symbols
    Part 2: Floor heating: Prove methods for the determination of the thermal output using calculation and test methods
    Part 3: Dimensioning
    Part 4: Installation
    Part 5: Heating and cooling surfaces embedded in floors, ceilings and walls - Determination of the thermal output
    ISO TC 205/ WG 5, Indoor thermal environment
    ISO TC 205/ WG 8, Radiant heating and cooling systems
    ISO TC 205/ WG 8, Heating and cooling systems
  3. A sample of standards for pipes used in underfloor heating:
    • ASTM F2623 - Standard Specification for Polyethylene of Raised Temperature (PE-RT) SDR 9 Tubing
    • ASTM F2788 - Standard Specification for Crosslinked Polyethylene (PEX) Pipe
    • ASTM F876 - Standard Specification for Crosslinked Polyethylene (PEX) Tubing
    • ASTM F2657 - Standard Test Method for Outdoor Weathering Exposure of Crosslinked Polyethylene (PEX) Tubing
    • CSA B137.5 - Crosslinked Polyethylene (PEX) Tubing Systems for Pressure Applications
    • CSA C22.2 NO. 130, Requirements for Electrical Resistance Heating Cables and Heating Device Sets
    • UL Standard 1673 – Electric Radiant Heating Cables
    • UL Standard 1693 – Electric Radiant Heating Panels and Heating Panel Sets
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