User:Reuqr/R-value (insulation)
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In building and construction,[4] the R-value is a measure of how well an object, per unit of its exposed area, resists conductive[5] flow of heat:[6] the greater the R-value, the greater the resistance, and so the better the thermal insulating properties of the object. R-values are used in describing effectiveness of insulation and in analysis of heat flow across assemblies (such as walls, roofs, and windows) under steady-state conditions.[6] Heat flow through an object is driven by temperature difference (e.g. ) between two sides of the object, and the R-value quantifies how effectively the object resists this drive:[7][8] divided by the R-value and then multiplied by the surface area of the object's side gives the total rate of heat flow through the object (as measured in
An R-value can be given for a material (e.g. for polyethylene foam), or for an assembly of materials (e.g. a wall or a window). In the case of materials, it is often expressed in terms of R-value per unit length (e.g. per inch of thickness). The latter can be misleading in the case of low-density building thermal insulations, for which R-values are not additive: their R-value per inch is not constant as the material gets thicker, but rather usually decreases.[9]
The units of an R-value (see below) are usually not explicitly stated, and so it is important to decide from context which units are being used: an R-value expressed in I-P (inch-pound) units[14] is about 5.68 times larger than when expressed in SI units,[15] so that, for example, a window that is R-2 in I-P units has an RSI of 0.35 (since 2/5.68=0.35). For R-values there is no difference between US customary units and imperial units. As far as how R-values are reported, all of the following mean the same thing: ″this is an R-2 window″;[16] ″this is an R2 window″;[17][12] ″this window has an R-value of 2″;[16] ″this is a window with R=2″[18] (and similarly with RSI-values, which also include the possibility ″this window provides RSI 0.35 of resistance to heat flow″[19][12]).
The more a material is intrinsically able to conduct heat, as given by its
The R-value is the reciprocal of the thermal transmittance (U-factor) of a material or assembly. The U.S. construction industry preferes to use R-values, however, because they are additive and because bigger values mean better insulation, neither of which is true for U-factors.[4]
U-factor/U-value
The U-factor or U-value is the overall heat transfer coefficient that describes how well a building element conducts heat or the rate of transfer of heat (in watts) through one square metre of a structure divided by the difference in temperature across the structure.[23] The elements are commonly assemblies of many layers of components such as those that make up walls/floors/roofs etc. It measures the rate of heat transfer through a building element over a given area under standardised conditions. The usual standard is at a temperature gradient of 24 °C (75.2 °F), at 50% humidity with no wind[24] (a smaller U-factor is better at reducing heat transfer). It is expressed in watts per meter squared kelvin (W/m²K). This means that the higher the U-value the worse the thermal performance of the building envelope. A low U-value usually indicates high levels of insulation. They are useful as it is a way of predicting the composite behavior of an entire building element rather than relying on the properties of individual materials.
In most countries the properties of specific materials (such as insulation) are indicated by the
U is the inverse of R[27] with SI units of W/(m2K) and U.S. units of BTU/(hr °F ft2);
where is the heat flux, is the tempreture difference across the material, k is the material's coefficient of thermal conductivity and L is its thickness. In some contexts, U is referred to as unit surface conductance.[28]
See also: tog (unit) or Thermal Overall Grade (where 1 tog = 0.1 m2·K/W), used for duvet rating.
Note that the term "U-factor" (which redirects here) is usually used in the U.S. and Canada to express the heat flow through entire assemblies (such as roofs, walls, and windows[29]). For example, energy codes such as ASHRAE 90.1 and the IECC prescribe U-values. However, R-value is widely used in practice to describe the thermal resistance of insulation products, layers, and most other parts of the building enclosure (walls, floors, roofs). Other areas of the world more commonly use U-value/U-factor for elements of the entire building enclosure including windows, doors, walls, roof, and ground slabs.[30]
Units: metric (SI) vs. inch-pound (I-P)
The SI (metric) unit of R-value is
- square-metre kelvin per watt (m2·K/W or, equally, m2·°C/W),
whereas the I-P (inch-pound) unit is
For R-values there is no difference between US customary units and imperial units, so the same I-P unit is used in both.
Some sources use ″RSI″ when referring to R-values in SI units.[12][13]
R-values expressed in I-P units are approximately 5.68 times as large as R-values expressed in SI units.[15] For example, a window that is R-2 in the I-P system is about RSI 0.35, since 2/5.68 ≈ 0.35.
In countries where the SI system is generally in use, the R-values will also normally be given in SI units. This includes the U.K., Australia, and New Zealand.
I-P values are commonly given in the U.S. and Canada, though in Canada normally both I-P and RSI values are listed.[31]
Because the units are usually not explicitly stated, one must decide from context which units are being used. In this regard, it helps to keep in mind that I-P R-values are 5.68 times larger than the corresponding SI R-values.
- R-value (in I-P) = RSI-value (in SI) × 5.678263337
- RSI-value (in SI) = R-value (in I-P) × 0.1761101838
References
- ^ Kahn, Jeffery (1991), Aerogel Research at LBL: From the Lab to the Marketplace, Lawrence Berkeley National Laboratory, retrieved 5 February 2018
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- ^ U.S. Department of Energy, Faced fiberglass batt insulation can be stapled to the stud faces or slightly inset, but avoid compressing the batts, U.S. Department of Energy, retrieved 5 February 2018
- ^ ISBN 0-8031-1183-5.
- ISBN 0-8493-0866-6.
- ^ ISBN 978-1498715270.
- ISBN 978-1-4398-8250-4.
- ISBN 978-0-470-64780-6.
- ^ a b c Krause, Carolyn (Summer 1980). "The Promise of Energy-Efficient Buildings". Oak Ridge National Laboratory Review. 13 (3): 6.
- ISBN 978-1-936504-46-6.
- ^ ISBN 978-0-7637-7752-4.
- ^ ISBN 019-860522-6.
- ^ ISBN 978-184407-243-9.
- ^ ISBN 978-1-118-58242-8.
- ^ ISBN 978-184407-243-9.
- ^ ISBN 978-1-118-58242-8.
- ISBN 978-184407-243-9.
- ISBN 978-1609830014.
- ISBN 978-184407-243-9.
- ^ The Polyisocyanurate Insulation Manufacturers Association (PIMA), LTTR/QualityMark, The Polyisocyanurate Insulation Manufacturers Association (PIMA), retrieved 5 February 2018
- ^ Bailes, Allison (24 April 2013), Big News: The R-Value of Insulation Is Not a Constant, Energy Vanguard, retrieved 5 February 2018
- ^ Building Science Corporation (23 January 2013), RR-0002: The Thermal Metric Project, Building Science Corporation, retrieved 5 February 2018
- ^ "U-Value Measurement Case Study". Retrieved 2014-10-29.
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(help) - ^ P2000 Insulation System, R-value Testing
- ^ Polystyrene insulation
- ^ European phenolic foam association: Properties of phenolic foam
- ^ "Indicators of Insulation Quality: U-value and R-value" (PDF). U-value and building physics. greenTEG. 2016-03-17. Retrieved 2016-03-17.
- ISBN 978-0-471-47015-1.
- ^ "Efficient Windows Collaborative".
- ^ "Public Codes Cyberregs".
- ^ Canada Mortgage and Housing Corporation (CMHC) (2018), Insulating Your House, Canada Mortgage and Housing Corporation (CMHC), retrieved 5 February 2018
- ISBN 978-1-936504-46-6.
- ISBN 978-1-4471-0805-4.
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