Optimization for Preparation of Phase Change and Humidity Control Composite Materials of Hexadecanol-Palmitic Acid-lauric Acid/SiO2

doi:10.11901/1005.3093.2015.134

Chinese Journal of Materials Research

2015, Vol. 29

Issue (9): 671-678 DOI: 10.11901/1005.3093.2015.134

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Optimization for Preparation of Phase Change and Humidity Control Composite Materials of Hexadecanol-Palmitic Acid-lauric Acid/SiO₂

Hao ZHANG(

),Xinjie HUANG,Xiuyu LIU,Gang TANG

School of Civil Engineering and Architecture, Anhui University of Technology, Ma’anshan 243032, China

Cite this article:

Hao ZHANG,Xinjie HUANG,Xiuyu LIU,Gang TANG. Optimization for Preparation of Phase Change and Humidity Control Composite Materials of Hexadecanol-Palmitic Acid-lauric Acid/SiO₂. Chinese Journal of Materials Research, 2015, 29(9): 671-678.

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Abstract

Phase change and humidity control composite materials of hexadecanol-palmitic acid-lauric acid/SiO₂ were prepared with SiO₂ as carrier material and hexadecanol-palmitic acid-lauric acid as phase change material. The effect of processing parameters on performance of humidity- and temperature-control of the composite materials was investigated by uniform design and multivariate nonlinear regression. The results show that their effect may be ranked as a sequence as follows: mole ratio of absolute alcohol to tetraethyl orthosilicate > solution pH value > mole ratio of hexadecanol-palmitic acid-lauric acid to tetraethyl orthosilicate > ultrasonic wave power > mole ratio of deionized water to tetraethyl orthosilicate. The optimal processing parameters are as follows: solution pH value 2.68, ultrasonic wave power 113 W, mole ratio of deionized water to tetraethyl orthosilicate 9.03, mole ratio of absolute alcohol to tetraethyl orthosilicate 5.22, mole ratio of decanoic-palmitic acid to tetraethyl orthosilicate 0.51.

Key words: inorganic non-metallic materials hexadecanol-palmitic acid-lauric acid SiO₂ humidity controlling performance temperature controlling performance optimized preparation

Received: 17 March 2015

Fund: *Supported by National Natural Science Foundation of China No. 51206002.

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https://www.cjmr.org/EN/10.11901/1005.3093.2015.134 OR https://www.cjmr.org/EN/Y2015/V29/I9/671

Table 1 Relative humidity of saturated salt in water (25℃)

Table 2 Uniform design of hexadecanol-palmitic acid-lauric acid/SiO₂ composite phase change and humidity controlling materials U₁₀*(10¹⁰)

Table 3 Equilibrium moisture content of hexadecanol- palmitic acid- lauric acid/SiO₂ composite phasechange and humidity controlling materials U₁₀*(10¹⁰)

Fig.1 Cooling curves of hexadecanol-palmitic acid-lauric acid/SiO₂ composite phase change and humidity controlling materials

Table 4 Target values Y

Table 5 Correlation coefficient for Y

Fig.2 Equilibrium moisture content of optimal hexadecanol-palmitic acid-lauric acid/SiO₂ composite phase change and humidity controlling materials

Fig.3 Cooling curves of optimal hexadecanol-palmitic acid-lauric acid/SiO₂ composite phase change and humidity controlling materials

Fig.4 FI-IR spectra of SiO₂(a), hexadecanol-palmitic acid-lauric acid (b) and hexadecanol-palmitic acid-lauric acid/SiO₂ composite phase change and humidity controlling materials (c)

Fig.5 SEM images of SiO₂(a) and hexadecanol-palmitic acid-lauric acid/SiO₂ composite phase change and humidity controlling materials (b)

Fig.6 DSC curves of hexadecanol-palmitic acid-lauric acid (a) and hexadecanol-palmitic acid-lauric acid/SiO₂ composite phase change and humidity controlling materials (b)

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