Synthesis and Properties of a Novel Environmentally Friendly Phase Change Energy Storage Coating Additive

Peng Fu; Peng Xi; Fu Lai Zhao; Bo Wen Cheng

doi:10.4028/www.scientific.net/AMR.805-806.1538

Paper Titles

Unscrambling the Building Envelope Insulation Technique in "Tianjin Energy Efficiency Design Standard for Rural Residential Buildings"
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Research on Foundation Settlement of Oil Tank Project Based on Red Soil Foundation
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Applicability Research of Germany “Passive Housing” Technology in Hot Summer and Cold Winter Area in China
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Numerical Simulation on the Influence of Double-Jet Air Curtain of Smoke-Preventing in Tunnel Fires
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Synthesis and Properties of a Novel Environmentally Friendly Phase Change Energy Storage Coating Additive
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The Thermal Insulation Design for Refuge Chamber
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Comparison of Air Distribution of Induced Ventilation System's Different Exhaust Way in Underground Garage
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Environmental Impact Evaluation and Economy Analysis of Air-Conditioning Cold and Heat Source Based on TEWI Index
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Research on Demand Controlled Ventilation Strategy for Laboratory Ventilation System
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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 805-806Synthesis and Properties of a Novel...

Synthesis and Properties of a Novel Environmentally Friendly Phase Change Energy Storage Coating Additive

Abstract:

Waterborne polyurethane (PU) coatings are diluted with water as the medium, without volatile organic solvents and harmful to human body and environment. Adding insulation materials in building individually is a waste of resource. We found a kind of waterborne PU phase change energy storage material easily dissolved and formed film after solvent evaporating having the potential of coating. In this article, we synthesized a new kind of waterborne PU phase change energy storage coating additive via two-step synthesis method, of which a new type of aromatic tetrahydroxycompound (ATTC) is used as branch unit, 4, 4'-diphenylmethanediisocyanate (MDI) and polyethylene glycol (PEG) respectively as hard and soft segments. POM photographs show that the sphaerocrystals of this new coating additive can reach 200-500μm. The crystal structure is characterized by XRD, and the phase change unit is PEG. DSC tests show that the phase change enthalpy value of this coating additive is very high reached more than 90 J/g. The preservation of this water-soluble PU coating is relatively simple, using water as solvent, which can be easy to dissolve in water and form film after water evaporated.