Pore structure and surface properties of diatomite with mechanical grinding and its influence on humidity control

Hu, Zhibo; Zheng, Shuilin; Li, Jinyu; Zhang, Shuaiqian; Liu, Min; Wang, Zhicheng; Li, Jiaxin; Sun, Hongjuan

doi:10.37190/ppmp/153509

Artykuł - szczegóły

Tytuł artykułu

Pore structure and surface properties of diatomite with mechanical grinding and its influence on humidity control

Autorzy

Hu Zhibo , Zheng Shuilin , Li Jinyu , Zhang Shuaiqian , Liu Min , Wang Zhicheng , Li Jiaxin , Sun Hongjuan

Treść / Zawartość

Pełne teksty:

Pobierz

Identyfikatory

DOI

10.37190/ppmp/153509

Warianty tytułu

Języki publikacji

Abstrakty

Mechanical grinding (MG) is an effective method to regulate the pore structure and surface properties of mineral material. Grinding diatomite samples were prepared by horizontal sander under different grinding time. The pore structure and surface properties of grinding samples were characterized systematically by the particle size analysis, low temperature nitrogen adsorption, MIP, fractal theory, XRD, SEM, TEM, FTIR and surface hydroxyl density analysis. The humidity control performance (HCP) of grinding diatomite was tested under different temperature and relative humidity. The relationship among pore structure, surface properties and HCP was analyzed. The results show that macroporous is more easily damaged by mechanical force than mesoporous, and the internal blind holes structure can be opened. The HCP of diatomite is positively correlated with the specific surface area, mesoporous volume, the inhomogeneity of macroporous structure and the number of hydroxyl groups, while negatively correlated with the proportion of macroporous volume.

Słowa kluczowe

diatomite mechanical grinding pore structure surface properties humidity control performance

Wydawca

Oficyna Wydawnicza Politechniki Wrocławskiej

Czasopismo

Physicochemical Problems of Mineral Processing

Rocznik

2022

Tom

Vol. 58, iss. 6

Strony

art. no. 153509

Opis fizyczny

Bibliogr. 49 poz., rys., wykr.

Twórcy

autor

Hu Zhibo

zhibohu@swust.edu.cn

School of Environment and Resource, Southwest University of Science and Technology, Mianyang, 621010, China
Key Laboratory of Solid Waste Treatment and Resource Recycle, Ministry of Education, Southwest University of Science and Technology, Mianyang, 621010, China
Sichuan Provincial Engineering Lab of Non-Metallic Mineral Powder Modification and High-Value Utilization, Southwest University of Science and Technology, Mianyang, 621010,

autor

Zheng Shuilin

School of Chemical and Environmental Engineering, China University of Mining & Technology(Beijing), Beijing, 100083, China

autor

Li Jinyu

School of Environment and Resource, Southwest University of Science and Technology, Mianyang, 621010, China

autor

Zhang Shuaiqian

School of Environment and Resource, Southwest University of Science and Technology, Mianyang, 621010, China

autor

Liu Min

School of Environment and Resource, Southwest University of Science and Technology, Mianyang, 621010, China

autor

Wang Zhicheng

School of Environment and Resource, Southwest University of Science and Technology, Mianyang, 621010, China

autor

Li Jiaxin

School of Environment and Resource, Southwest University of Science and Technology, Mianyang, 621010, China

autor

Sun Hongjuan

School of Environment and Resource, Southwest University of Science and Technology, Mianyang, 621010, China
Key Laboratory of Solid Waste Treatment and Resource Recycle, Ministry of Education, Southwest University of Science and Technology, Mianyang, 621010, China

Bibliografia

AI Z., LIU C., ZHANG Q., QU J., LI Z., HE X., 2018. Adding ZnO and SiO2 to scatter the agglomeration of mechanochemically prepared Zn-Al LDH precursor and promote its adsorption toward methyl orange. Journal of Alloys and Compounds 763, 342-8.
AL-DEGS Y., KHRAISHEH M., TUTUNJI M.F., 2001. Sorption of lead ions on diatomite and manganese oxides modified diatomite. Water Research 35, 3724-8.
BERGER J., LEGROS C., ABDYKARIM M., 2021. Dimensionless formulation and similarity to assess the main phenomena of heat and mass transfer in building porous material. Journal of Building Engineering 35, 101849.
DU Y., SHI S., DAI H., 2011. Water-bathing synthesis of high-surface-area zeolite P from diatomite. Particuology 9(2), 174-178.
FIGARSKA-WARCHOŁ B., STAŃCZAK G., REMBIŚ M., TOBOŁA T., 2015. Diatomaceous rocks of the Jawornik deposit, the Polish Outer Carpathians. - petrophysical and petrographical evaluation. Geology, Geophysics, Environment 41, 311-31.
FU H., BALTAZAR J.-C., CLARIDGE D.E., 2021. Review of developments in whole-building statistical energy consumption models for commercial buildings. Renewable and Sustainable Energy Reviews 147, 111248.
HA J-H, BAE B, SONG I-H,2015. Effect of pore characteristics on permeability of sintered diatomite filter for microfiltration. Advances in Applied Ceramics 114(3), 156-163
HU Z.-P., REN J.-T., YANG D., WANG Z., YUAN Z.-Y., 2019. Mesoporous carbons as metal-free catalysts for propane dehydrogenation: Effect of the pore structure and surface property. Chinese Journal of Catalysis 40, 1385-94.
HU Z., ZHENG S., JIA M., DONG X., SUN Z., 2017a. Preparation and characterization of novel diatomite/ground calcium carbonate composite humidity control material. Advanced Powder Technology 28, 1372-81.
HU Z., ZHENG S., SUN Z., CHEN Y., YAN Y., 2017b. Influence of pore structure on humidity control performance of diatomite. Science and Technology for the Built Environment 23, 1305-13.
HU Z., ZHENG S., TAN Y., JIA M., 2017c. Preparation and characterization of diatomite/silica composite humidity control material by partial alkali dissolution. Materials Letters 196, 234-7.
HUO Y., YIN M., RAO Z., 2022. Heat transfer enhanced by angle-optimized fan-shaped porous medium in phase change thermal energy storage system at pore scale. International Journal of Thermal Sciences 172, 107363.
IMAMURA H., TABATA S., SHIGETOMI N., TAKESUE Y., SAKATA Y., 2002. Composites for hydrogen storage by mechanical grinding of graphite carbon and magnesium. Journal of Alloys, Compounds 330, 579-83.
JIANG D., YUAN Y., WU J., DU Y., WANG J., ZHANG Y., 2019. Advances in Application of Diatomite-based Composites in the Field of Energy and Environment. Materials Reports 33(5), 1483-1489.
KHRAISHEH M.A., AL-DEGS Y.S., MCMINN W., 2004. Remediation of wastewater containing heavy metals using Raw and modified diatomite. Chemical Engineering Journal 99(2),177-184.
KORUNIC Z., 1998. Review Diatomaceous earths, a group of natural insecticides. Journal of Stored Products Research 34, 87-97.
LEHMANN A.G., BIONDUCCI M., BUFFA F., 1998. Effect of mechanical grinding on the hexagonal structure of CdSe. Physical Review B 58, 5275-81.
LI J., HUANG Q., WANG G., WANG E., 2022. Influence of active water on gas sorption and pore structure of coal. Fuel 310, 122400.
LI J., WANG X., WANG J., LI Y., XIA S., ZHAO J., 2019. Simultaneous recovery of microalgae, ammonium and phosphate from simulated wastewater by MgO modified diatomite. Chemical Engineering Journal 362, 802-11.
LIU C., ZHANG Y., SUN L., GAO W., JING X., YE W., 2021. Influence of indoor air temperature and relative humidity on learning performance of undergraduates. Case Studies in Thermal Engineering 28, 101458.
MANNION A.M., 2012. The diatoms: applications for the environmental and earth sciences. Journal of Biological Education 46, 200-1.
MINGMING M.A., ZHANG W., 2017. Preparation and characterization of diatomite humidity-controlling building material. New Building Materials.
MU Y., CUI M., ZHANG S., ZHAO J., MENG C., SUN Q., 2018. Comparison study between a series of new type functional diatomite on methane adsorption performance. Microporous and Mesoporous Materials 267, 203-11.
OKAMURA C., UEDA T., HASEZAKI K., 2010. Preparation of Single-Phase ZnSb Thermoelectric Materials Using a Mechanical Grinding Process. Journal of the Japan Institute of Metals 51, 860-2.
PEDDARASI S., SARKAR D., 2021. Mechanochemical effect on synthesis and sintering behavior of MgAl2O4 spinel. Materials Chemistry and Physics 262, 124275.
PYUN S.I., NA K.H., GO J.Y., PARK J.J., 2003. Characterization of Surface Roughness and Inhomogeneity of Hot-Rolled Carbon Steels by Using Image Analysis Method and Electrochemical Impedance Spectroscopy. Journal of the Korean Electrochemical Society 6(3), 217-223
QUANG-TUNG, TRAN, TRUNG-DUNG, DANG, ROY, SUDIPTA, BANERJEE, ARGHYA, NARAYAN, 2016. Fast degradation of dyes in water using manganese-oxide-coated diatomite for environmental remediation. The journal of physics and chemistry of solids 98, 50-8.
SEOK-HO Y., JONG-BOK N., WON-SEON J., 1989. Effects of Domestic Diatomite Filter Aid on the Characteristics of Cake Filtration. Korean Chemical Engineering Research 27(4), 482.
SERTSUNGNERN P., CHAIWIWATWORAKUL P., 2011. Development of a Performance Rating Scheme of Air-Conditioning Systems for Buildings: A Case of Thailand. Energy Procedia 9, 84-94.
SHENG G., WANG S., HU J., YI L., LI J., DONG Y., WANG X., 2009. Adsorption of Pb(II. on diatomite as affected via aqueous solution chemistry and temperature. Colloids, Surfaces A Physicochemical, Engineering Aspects 339, 159-66.
SHIH Y.F., WEI C.H., KOTHARANGANNAGARI V.K., 2020. Study on Reuse of Wasted Diatomite from Brewing Industry for Building Materials. Key Engineering Materials 845, 73-8.
SONG M.Y., BOBET J.L., DARRIET B., 2002. Improvement in hydrogen sorption properties of Mg by reactive mechanical grinding with Cr2O3, Al2O3 and CeO2. Journal of Alloys, Compounds 340, 256-62.
SONWANE C.G., BHATIA S.K., CALOS N.J., 1999. Characterization of Surface Roughness of MCM-41 Using Methods of Fractal Analysis. Langmuir 15, 4603-12.
STAMATAKIS M.G., KOUKOUZAS N.K., 2001. The occurrence of phosphate minerals in lacustrine Clayem diatomite deposits, Thessaly, Central Greece. Sedimentary Geology 139, 33-47.
THIANGCHANTA S., DO T.A., SUTTAKUL P., MONA Y., 2021. Energy reduction of split-type air conditioners using a pre-cooling system for the condenser. Energy Reports 7, 1-6.
THIANGCHANTA S., DO T.A., TACHAJAPONG W., MONA Y., 2020. Experimental investigation of the thermoelectric cooling with vacuum wall system. Energy Reports 6, 1244-8.
VERDUGO R.N., 2008. Singularities of Geotechnical Properties of Complex Soils in Seismic Regions. Journal of Geotechnical and Geoenvironmental Engineering 134, 982-91.
VILCHIS-GRANADOS J., GRANADOS-CORREA F., BARRERA-DÍAZ C.E., 2013. Surface fractal dimensions and textural properties of mesoporous alkaline-earth hydroxyapatites. Applied Surface Science 279, 97-102.
VU D.H., WANG K.S., BAC B.H., NAM B.X., 2013. Humidity control materials prepared from diatomite and volcanic ash. Construction and Building Materials 38, 1066-72.
WANG Y., JIANG Q., JING W., ZHONG Z., XING W., 2022. Pore structure and surface property design of silicon carbide membrane for water-in-oil emulsification. Journal of Membrane Science 648, 120347.
WU S., WANG C., JIN Y., ZHOU G., ZHANG L., YU P., SUN L., 2021. Green synthesis of reusable super-paramagnetic diatomite for aqueous nickel, II. removal. Journal of Colloid and Interface Science 582, 1179-90.
XIA B.Q., PAN Z.H., YAN J., ZHAO C.Y., 2019. Mesoscopic exploration on mass transfer in porous thermochemical heat storage materials. International Journal of Heat and Mass Transfer 135, 52-61.
XIAO Y., LU H.-Q., SHI C.-R., LEI F.-H., RACKEMANN D., LI K., LI W., DOHERTY W.O.S., 2022. High-performance quaternary ammonium-functionalized chitosan/graphene oxide composite aerogel for remelt syrup decolorization in su gar refining. Chemical Engineering Journal 428, 132575.
YANG X., LI S., ZHAO J., WANG X., HUANG H., WANG Y., DENG L., 2021. Development of lithium hydroxide-metal organic framework-derived porous carbon composite materials for efficient low temperature thermal energy storage. Microporous and Mesoporous Materials 328, 111455.
YUAN P., LIU D., TAN D.-Y., LIU K.-K., YU H.-G., ZHONG Y.-H., YUAN A.-H., YU W.-B., HE H.-P., 2013. Surface silylation of mesoporous/macroporous diatomite, diatomaceous earth. and its function in Cu(II. adsorption: The effects of heating pretreatment. Microporous and Mesoporous Materials 170, 9-19.
ZHANG S., ZHAO H., GAO X., ZHAO D., WEI G., LI Z., 2022. Enhanced surface capacitive sodium storage by pores regulation in carbon/carbon composite nanofibers. Microporous and Mesoporous Materials 332, 111706.
ZHANG X., LI C., CHEN T., TAN Y., LIU X., YUAN F., ZHENG S., SUN Z., 2021. Enhanced visible-light-assisted peroxymonosulfate activation over MnFe2O4 modified g-C3N4/diatomite composite for bisphenol A degradation. International Journal of Mining Science and Technology 31(6), 1169-1179.
ZHENG J., SHI J., MA Q., DAI X., CHEN Z., 2017. Experimental study on humidity control performance of diatomite-based building materials. Applied Thermal Engineering 114, 450-6.
ZHONG H., WANG J., JIA H., MU Y., LV S., 2019. Vector field-based support vector regression for building energy consumption prediction. Applied Energy 242, 403-14

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-aaa22ca9-cbc4-4920-981a-84511f5b0157