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6 results on '"Khar San Teh"'

1. Reflective insulation assemblies for above-ceiling applications

Author

Patrick Loi, Khar San Teh, David W. Yarbrough, and Kah Wei Yam

Subjects
Radiant barrier, Materials science, Thermal resistance, Acoustics, General Materials Science, Building and Construction, Ceiling (cloud)
Abstract

Previously published hot-box data have been used to construct equations for the thermal resistance of enclosed reflective air spaces (reflective insulation assemblies) for a wide range of temperatures, air gap dimensions, thermal emittances, and heat flow directions. The thermal resistances or R-values (RSI) calculated with the equations compare favorably with previously published thermal resistances. Significant differences from RSI values (m2 K/W) calculated using ISO 6946 were observed. Equations for calculating heat transfer coefficients for conduction–convection with constants for the heat flow directions up, 45° up, horizontal, 45° down, and down are contained in this article. The conduction–convection coefficient for planar air spaces oriented at any angle and heated above can be obtained by interpolation between heat flow down and heat flow at a downward angle of 45° or heat flow down at an angle of 45° and horizontal heat flow. The overall heat transfer coefficient is obtained by adding the thermal radiation contribution to the conduction–convection contribution. The RSI of enclosed reflective air spaces is the reciprocal of the overall heat transfer coefficient for the air space. This air space RSI is especially useful as input for the calculation of U-values for ceiling–roof assemblies located in hot climates.

Published
2020
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2. Field evaluation of reflective insulation in south east Asia

Author

Khar San Teh, David W. Yarbrough, Elias Salleh, and Chin Haw Lim

Subjects
Radiant barrier, reflective insulation, Environmental Engineering, Field (physics), 020209 energy, reflective air space, 0211 other engineering and technologies, Aerospace Engineering, 02 engineering and technology, 021105 building & construction, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Thermal emittance, South east asia, Electrical and Electronic Engineering, Civil and Structural Engineering, Materials processing, emittance, Mechanical Engineering, thermal resistance, Industrial chemistry, Engineering (General). Civil engineering (General), Engineering physics, Environmental science, TA1-2040, test hut, reflective technology
Abstract

The objective of this research was to obtain thermal performance data for reflective insulations in a South East Asia environment. Thermal resistance data (RSI, m2 ⋅ K/W) for reflective insulations are well established from 1-D steady-state tests, but thermal data for reflective insulation in structures like those found in South East Asia are scarce. Data for reflective insulations in South East Asia will add to the worldwide database for this type of energy-conserving material. RSI were obtained from heat flux and temperature data of three identical structures in the same location. One unit did not have insulation above the ceiling, while the second and third units were insulated with reflective insulation with emittance less than 0.05. RSI for the uninsulated test unit varied from 0.37 to 0.40 m2 ⋅ K/W. RSI for a single-sheet reflective insulation (woven foil) varied from 2.15 to 2.26 m2 ⋅ K/W, while bubble-foil insulation varied from 2.69 to 3.09 m2 ⋅ K/W. The range of RSI values resulted from differences in the spacing between the reflective insulation and the roof. In addition, the reflective insulation below the roof lowered attic temperatures by as much as 9.7° C. Reductions in ceiling heat flux of 80 to 90% relative to the uninsulated structure, due to the reflective insulation, were observed.

Published
2017

3. Hybrid and Reflective Insulation Assemblies for Buildings

Author

Malaysia, USA╃Khar San Teh$San Miguel Yamamura Woven Products, Cookeville, Air Keroh, David W. Yarbrough$R D Services, and Bangi

Subjects
Radiant barrier, Vacuum insulated panel, Architectural engineering, 020209 energy, Thermal resistance, 0211 other engineering and technologies, Enclosure, Mechanical engineering, 02 engineering and technology, Attic, Dynamic insulation, 021105 building & construction, Heat transfer, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Thermal emittance
Abstract

Materials with a low thermal emittance surface have been used for many years to create reflective insulations that reduce the rate of heat flow across building envelopes. Reflective insulation technology is now being combined with other energy conserving technologies to optimize overall thermal performance. The basis for the performance of reflective insulations and radiant barriers will be discussed along with the combination of these materials with cellular plastic or mineral fiber insulations to form hybrid insulation assemblies. Calculations of thermal resistance for enclosed reflective air spaces and current field data from Southeast Asia will be presented. These data show that reductions in heat transfer across the building enclosure can be effectively reduced by the use of enclosed reflective air spaces and attic radiant barriers. Reflective technology increases the overall thermal resistance of the building enclosure when used to insulate poured concrete structures.

Published
2016
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