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“Phase Changing Materials(PCMs) used as
Building Material”
By,
Rojan P.V
4sf10cv034
8th Semester Civil
GuideAsst. Prof Ashraf
2
1.Introduction
2.Principle
3.Working
4.PCM incorporation
5.Building application
6.Bio PCM
7.GlassX
8.Thermal core
9.Selection criteria
10.Case study
11.conclusion
contents
3
• Modern architecture is Attractive, flexible and light weight
• Leads to less thermal storage capacity and more solar
heat gains
• PCM - Interior finishing alternatives
• Stores much larger amount of thermal energy per unit
mass than conventional building materials
• Requires less amount of energy for production
• This presentation involves microencapsulated PCM use,
its applications, etc.
Introduction
4
• When heat is applied to any substance, heat transfers in
two ways
Sensible heat
Latent heat
• PCMs works on the principle of latent heat
• Latent heat enables PCMs to control room temperature
PRINCIPLE
5
• PCMs used in construction change from solid to liquid at
23ºC - 26ºC
• They melt, absorb heat from room and room temperature is
kept constant until the change of state is complete
• PCM then returned to solid state by night time ventilation /
mechanical means
• The phase change cycle repeats
WORKING
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• There are many types of PCM but not all are suitable for use in buildings
• The two main types of PCM used in construction are inorganic salt hydrates and organic paraffin or fatty acids
• both materials have a set of advantages and disadvantages that must be taken into consideration.
Types of PCM
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Inorganic salt hydrates
• Salt hydrates are a low-cost, readily available PCM.
• They have a high latent heat storage capacity and high thermal conductivity
• They are also non-flammable.
continued
9
• Paraffin’s and fatty acids do not expand as they melt, and freeze without much super cooling,
• They are chemically stable, compatible with conventional construction materials and recyclable.
• Paraffin’s are hydrophobic, which means they are water-repellant.
Organics: paraffin’s and fatty acids
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• Paraffin’s are hydrophobic, which means they are water-repellant.
• As a result, their phase-change points are reliable.
• Pure paraffin’s are also highly durable, and do not degrade in contact with oxygen.
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• Impregnated into building materials by 2 ways :
Either directly or as pellets(Paraffin wax – most promising material used)
Microencapsulation
• Microencapsulation most preferred always.
• Night cooling considered as the main difficulty
• Mechanical ventilation provided
PCM Incorporation :
13
MICRO-ENCAPSULATION• A process by which individual particles of solid/ liquid material are coated with a continuous film of polymeric material to produce capsules called microcapsules.
• Microcapsules – small sphere with uniform wall round it
• Micrometer to millimeter range
• Appearance of beads, powder
• Polymer sphere shaped
Structure of a microcapsule :
• Material inside is called core.
• Wall is called shell or coating.
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Morphology :
• Depends on core material and the deposition process of the shell
• Basically 3 types :
Mononuclear
Poly nuclear
Matrix encapsulation
• Also mononuclear with multiple shells, or clusters of microcapsules.
20
•BioPCM:
A rolled mat that contains PCM
Integrated into new construction or retrofitted into existing
Mat is installed between insulation and drywall layers and
located in walls and ceiling.
23
GlassX• An insulated glazing unit that can be used as full glass walls
and windows.
• It has an outer pane of glass that reflects high-angle sun
and allows low-angle sunlight to pass.
• Sunlight transmitted through this outer pane of glass passes
through inner polycarbonate channels that are embedded
with salt-hydrate PCMs.
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• These PCMs store the heat from the sunlight, release the
heat to the interior of the building as the temperature cools.
26
ThermalCORE • Made by National Gypsum/BASF Corporation.
• A drywall panel embedded with paraffin PCM.
• The microscopic paraffin capsules absorb and distribute heat
as the wax melts and solidifies with temperature fluctuations.
• ThermalCORE is not currently commercially available for
purchase and is still undergoing testing.
27
• A melting temperature range in construction is 23°C or
26°C.
• A high latent heat of fusion per unit volume minimizes the
area of PCM tiles that are needed.
• High thermal conductivity.
Selection criteria
• Minimal changes in volume
• Congruent melting
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• A completely reversible freezing/melting cycle.
• Durability over a large number of cycles.
• Non-corrosiveness to construction materials.
• Non-flammability.
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• Three semi transparent domes of 18.5,20,24m diameter
• Building has been built in one of the city harbor of Rotterdam
• Climate is managed in different way in different room
• Exhibition hall temperature is kept about 15 ˚C
• Conference hall temp is maintained about 21˚C
• Temperature is varied with the help of PCM
continued
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CONCLUSION• Improves thermal comfort levels and obviate or reduce the need for air-conditioning.
• Reduction in peak temperatures is possible.
• Used in Residential buildings too.
• Significant advantages for both commercial and residential buildings.
• Night ventilation- an integral part.
• Likely to become a valuable tool for improving thermal comfort in domestic buildings.
32
REFFERENCES
• http://www.basf.com sighted on 10/2/2014
• http://www.apartmenttherapy.com sighted on 10/2/2014
• Zubillaga (2007), “Use of microencapsulated PCM inconcrete
walls for energy savings. Energy and Buildings “, Vol. 39 pp.113-
119.
• I.O. Salyer, A.K. Sircar, R.P. Chartoff, D.E. Miller.
1995.Advanced phase-change materials for passive solar storage
applications. In: Proceedings of the 20th Intersociety Energy
Conversion Engineering Conference. Warrendale, Pennsylvania,
USA: 699-709.