Synthesis and analysis of new humidity-controlling composite materials

Jian-li Shang; Zhi-fang Zong; Hao Zhang

doi:10.1007/s12613-017-1441-2

International Journal of Minerals, Metallurgy, and Materials ›› 2017, Vol. 24 ›› Issue (5) : 594 -602. DOI: 10.1007/s12613-017-1441-2

Article

Synthesis and analysis of new humidity-controlling composite materials

Author information +

History +

PDF

Abstract

Gypsum is a traditional building material. To improve the humidity-controlling properties of gypsum, we prepared a new type of humidity-controlling composite using the sol–gel method. Methods to determine the maximum equilibrium moisture content and speed of adsorption/desorption were subsequently applied to analyze the performance of the samples. The appearance and structural properties of the samples were characterized by scanning electronic microscopy (SEM). The experimental results show that the humidity-controlling gel with added LiCl exhibits high moisture storage and that the equilibrium maximum moisture content is 5.652 g/g at a 75.29% relative humidity (RH). A mass ratio of LiCl/sol = 0.15 is demonstrated to be appropriate for the preparation of the new humidity-controlling composites. A coarse network with tiny pores is observed on the surface of the new humidity-controlling composites, and this pore network provides sufficient space for moisture adsorption.

Keywords

composite materials / gypsum / humidity control / sol-gel processing / adsorption / desorption

Cite this article

Download citation ▾

Jian-li Shang, Zhi-fang Zong, Hao Zhang. Synthesis and analysis of new humidity-controlling composite materials. International Journal of Minerals, Metallurgy, and Materials, 2017, 24(5): 594-602 DOI:10.1007/s12613-017-1441-2

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Shi X., Memon S.A., Tang W., Cui H.Z., Xing F. Experimental assessment of position of macro encapsulated phase change material in concrete walls on indoor temperatures and humidity levels. Energy Build., 2014, 71(3): 80.

[2]	Toftum J., Jorgensen A.S., Fanger P.O. Upper limits of air humidity for preventing warm respiratory discomfort. Energy Build., 1998, 28(1): 15.

[3]	Toftum J., Jørgensen A.S., Fanger P.O. Upper limits for indoor air humidity to avoid uncomfortably humid skin. Energy Build., 1998, 28(1): 1.

[4]	Fang L., Clausen G., Fanger P.O. Impact of temperature and humidity on the perception of indoor air quality. Indoor Air, 1998, 8(2): 80.

[5]	Wu Y.B., Bi J., Lou T., Song T.B., Yu H.Q. Preparation of a novel PAN/cellulose acetate-Ag based activated carbon nanofiber and its adsorption performance for low-concentration SO2. Int. J. Miner. Metall. Mater., 2015, 22(4): 437.

[6]	Yang H.L., Peng Z.Q., Zhao F., Zhang J., Cao X.Y., Hu Z.W. Preparation and performances of a novel intelligent humidity control composite material. Energy Build., 2011, 43(2–3): 386.

[7]	Zheng J., Chen Z. Application analogue simulation of diatomite- based humidity control building material. J. Southeast Univ. Nat. Sci. Ed., 2013, 43(4): 840.

[8]	Chaparro M.C., Saaltink M.W. Water, vapour and heat transport in concrete cells for storing radioactive waste. Adv. Water Resour., 2016, 94, 120.

[9]	Chen J.S., Zhao B., Wang X.M., Zhang Q.L., Wang L. Cemented backfilling performance of yellow phosphorus slag. Int. J. Miner. Metall. Mater., 2010, 17(1): 121.

[10]	Ohmae Y., Saito Y., Inoue M., Nakano T. Water adsorption process of bamboo heated at low temperature. J. Wood Sci., 2009, 55(1): 13.

[11]	Mcgregor F., Heath A., Shea A., Lawrence M. The moisture buffering capacity of unfired clay masonry. Build. Environ., 2014, 82, 599.

[12]	Hameury S. Moisture buffering capacity of heavy timber structures directly exposed to an indoor climate: a numerical study. Build. Environ., 2005, 40(10): 1400.

[13]	Han D.S., Gong M.S. Zwitterionic sulfobetaine- containing polyelectrolyte for controlling humidity- sensitivity. Sens. Actuators B, 2010, 145(1): 254.

[14]	Lim D.I., Cha J.R., Gong M.S. Preparation of flexible resistive micro-humidity sensors and their humidity-sensing properties. Sens. Actuators B, 2013, 183(13): 574.

[15]	Foucquier A., Robert S., Suard F., Stéphan L., Jay A. State of the art in building modelling and energy performances prediction: a review. Renewable Sustainable Energy Rev., 2013, 23(4): 272.

[16]	GB/T 20312—2006. Measurement of Hygrothermal Performance and Hygroscopic Properties of Building Materials and Products.

[17]	Arfvidsson J., Claesson J. Isothermal moisture flow in building materials: modeling measurements and calculations based on Kirchhoff’s potential. Build. Environ., 2000, 35(6): 519.

[18]	Jin Z.F., Asako Y., Yamaguchi Y., Yoshida H. Thermal and water storage characteristics of super- absorbent polymer gel which absorbed aqueous solution of calcium chloride. Int. J. Heat Mass Transfer, 2000, 43(18): 3407.

[19]	Tong M.W., Wu Z.Z., Wu P., Liu B. Theoretical analysis and experimental study on the effect of the different components of porous medium gypsum on porosity. J. Chongqing Univ., 2011, 34(10): 97.

[20]	Assadi M.G., Mahkam M., Tajrezaiy Z. Synthesis and characterization of some organosilicon derivatives of poly 2-hydroxyethyl methacrylate with cubane as a cross-linking agent. J. Organomet. Chem., 2005, 690(21–22): 4755.

[21]	Feng D.Y., Lin Z., Liu M.M., Xie J., Wan J.M., Wang B., Zhou Y., Yang H.L., Zheng H.L., Peng Z.Q., Hu Z.W. Silica- alumina gel humidity control beads with bimodal pore structure produced by phase separation during the sol-gel process. Microporous Mesoporous Mater., 2016, 222, 138.