Journal of the Chinese Ceramic Society, Volume. 50, Issue 9, 2510(2022)
Research Progress on Solid Waste-Based Foamed Ceramics Based on In-Situ Foaming Process
[1] [1] MOHAJERANI A, VAJNA J, CHEUNG T H H, et al. Practical recycling applications of crushed waste glass in construction materials: A review[J]. Constr Building Mater, 2017, 156: 443-467.
[2] [2] RAWLINGS R D, WU J P, BOCCACCINI A R. Glass-ceramics: Their production from wastes: A review[J]. J Mater Sci, 2006, 41(3): 733-761.
[3] [3] BERNARDO E, CEDRO R, FLOREAN M, et al. Reutilization and stabilization of wastes by the production of glass foams[J]. Ceram Inter, 2007, 33(6): 963-968.
[4] [4] LIU T, TANG Y, HAN L, et al. Recycling of harmful waste lead-zinc mine tailings and fly ash for preparation of inorganic porous ceramics[J]. Ceram Inter, 2017, 43(6): 4910-4918.
[5] [5] BERNARDO E, SCARINCI G, MADDALENA A, et al. Development and mechanical properties of metal-particulate glass matrix composites from recycled glasses[J]. Composites Part A: Appl Sci Manuf, 2004, 35(1): 17-22.
[6] [6] TANG B, LIN J, QIAN S, et al. Preparation of glass-ceramic foams from the municipal solid waste slag produced by plasma gasification process[J]. Mater Lett, 2014, 128: 68-70.
[7] [7] YANG Y, WEI Z, CHEN Y L, et al. Utilizing phosphate mine tailings to produce ceramisite[J]. Constr Building Mater, 2017, 155: 1081-1090.
[8] [8] APKAR’YAN A S, GUBAIDULINA T A, KAMINSKAYA O V. Foam-glass ceramic based filtering material for removing iron and manganese from drinking water[J]. Glass Ceram, 2015, 71(11/12): 413-417.
[9] [9] PENG H X, FAN Z, EVANS J R G, et al. Microstructure of ceramic foams[J]. J Eur Ceram Soc, 2000, 20: 807-813.
[10] [10] LAKSHMI V, RESMI V G, RAJU A, et al. Concentration dependent pore morphological tuning of kaolin clay foams using sodium dodecyl sulfate as foaming agent[J]. Ceram Inter, 2015, 41(10): 14263-14269.
[11] [11] SILVA R V, DE BRITO J, LYE C Q, et al. The role of glass waste in the production of ceramic-based products and other applications: A review[J]. J Cleaner Prod, 2017, 167: 346-364.
[12] [12] ZHU M, JI R, LI Z, et al. Preparation of glass ceramic foams for thermal insulation applications from coal fly ash and waste glass[J]. Constr Building Mater, 2016, 112: 398-405.
[13] [13] FANG X, LI Q, YANG T, et al. Preparation and characterization of glass foams for artificial floating island from waste glass and Li2CO3[J]. Constr Building Mater, 2017, 134: 358-363.
[14] [14] LIMBACHIYA M, MEDDAH M S, FOTIADOU S. Performance of granulated foam glass concrete[J]. Constr Building Mater, 2012, 28(1): 759-768.
[15] [15] ONITSUKA K. Construction utilization of foamed waste glass[J]. J Environ Sci, 2004, 16(2): 302-307.
[16] [16] YAO Z, LING T C, SARKER P K, et al. Recycling difficult-to-treat e-waste cathode-ray-tube glass as construction and building materials: A critical review[J]. Renewable Sustainable Energy Rev, 2018, 81: 595-604.
[17] [17] INIAGHE P O, ADIE G U. Management practices for end-of-life cathode ray tube glass: Review of advances in recycling and best available technologies[J]. Waste Manag Res, 2015, 33(11): 947-961.
[18] [18] CIFTCI M, CICEK B. E-waste: A review of CRT (cathode ray tube) recycling[J]. Res Rev: J Mater Sci, 2017, 5(2): 170.
[19] [19] LLAUDIS A S, TARI M J O, TEN F J G, et al. Foaming of flat glass cullet using Si3N4 and MnO2 powders[J]. Ceram Inter, 2009, 35(5): 1953-1959.
[20] [20] FERNANDES H R, TULYAGANOV D U, FERREIRA J M F. Production and characterisation of glass ceramic foams from recycled raw materials[J]. Adv Appl Ceram, 2009, 108(1): 9-13.
[21] [21] WU J P, BOCCACCINI A R, LEE P D, et al. Glass ceramic foams from coal ash and waste glass: production and characterisation[J]. Adv Appl Ceram, 2006, 105(1): 32-39.
[22] [22] FERNANDES H R, TULYAGANOV D U, FERREIRA J M F. Preparation and characterization of foams from sheet glass and fly ash using carbonates as foaming agents[J]. Ceram Inter, 2009, 35(1): 229-235.
[23] [23] WEI Y L, CHENG S, HOU K T, et al. Effect of calcium compounds on lightweight aggregates prepared by firing a mixture of coal fly ash and waste glass[J]. Ceram Inter, 2017, 43(17): 15573-15579.
[24] [24] TUAN B L A, HWANG C L, LIN K L, et al. Development of lightweight aggregate from sewage sludge and waste glass powder for concrete[J]. Constr Building Mater, 2013, 47: 334-339.
[25] [25] WANG H, SUN Y, LIU L, et al. Integrated utilization of fly ash and waste glass for synthesis of foam/dense bi-layered insulation ceramic tile[J]. Energy Buildings, 2018, 168: 67-75.
[26] [26] TAURINO R L I, BARBIERI L, ET AL. Glass-ceramic foams from borosilicate glass waste[J]. Inter J Appl Glass Sci, 2014, 5(2): 136-145.
[27] [27] EWAIS E M M, ATTIA M A A, ELAMIR A A M, et al. Optimal conditions and significant factors for fabrication of soda lime glass foam from industrial waste using nano AlN[J]. J Alloys Comp, 2018, 747: 408-415.
[28] [28] ARULRAJAH A, DISFANI M M, MAGHOOLPILEHROOD F, et al. Engineering and environmental properties of foamed recycled glass as a lightweight engineering material[J]. J Cleaner Prod, 2015, 94: 369-375.
[29] [29] PONSOT I, BERNARDO E. Self glazed glass ceramic foams from metallurgical slag and recycled glass[J]. J Cleaner Prod, 2013, 59: 245-250.
[30] [30] LEBULLENGER R, CHENU S, ROCHERULLé J, et al. Glass foams for environmental applications[J]. Ceram Inter, 2010, 356(44-49): 2562-2568.
[31] [31] MARANGONI M, SECCO M, PARISATTO M, et al. Cellular glass ceramics from a self foaming mixture of glass and basalt scoria[J]. Ceram Inter, 2014, 403: 38-46.
[32] [32] PETERSEN R R, KNIG J, YUE Y. The viscosity window of the silicate glass foam production[J]. Ceram Inter, 2017, 456: 49-54.
[33] [33] BAI J, YANG X, XU S, et al. Preparation of foam glass from waste glass and fly ash[J]. Mater Lett, 2014, 136: 52-54.
[34] [34] DING L, NING W, WANG Q, et al. Preparation and characterization of glass ceramic foams from blast furnace slag and waste glass[J]. Mater Lett, 2015, 141: 327-329.
[35] [35] WANG H, FENG K, ZHOU Y, et al. Effects of Na2B4O7·5H2O on the properties of foam glass from waste glass and titania-bearing blast furnace slag[J]. Mater Lett, 2014, 132: 176-178.
[36] [36] WANG X, FENG D, ZHANG B, et al. Effect of KNO3 on the microstruture and physical properties of glass foam from solid waste glass and SiC powder[J]. Mater Lett, 2016, 169: 21-23.
[37] [37] YIN H, MA M, BAI J, et al. Fabrication of foam glass from iron tailings[J]. Mater Lett, 2016, 185: 511-513.
[38] [38] PETRELLA A, PETRUZZELLI V, BASILE T, et al. Recycled porous glass from municipal/industrial solid wastes sorting operations as a lead ion sorbent from waste waters[J]. React Funct Polym, 2010, 70(4): 203-209.
[39] [39] AYADI A, STITI N, BOUMCHEDDA K, et al. Elaboration and characterization of porous granules based on waste glass[J]. Powder Technol, 2011, 208(2): 423-426.
[40] [40] BENTO A C, KUBASKI E T, SEQUINEL T, et al. Glass foam of macroporosity using glass waste and sodium hydroxide as the foaming agent[J]. Ceram Inter, 2013, 39(3): 2423-2430.
[41] [41] CAO J, LU J, JIANG L, et al. Sinterability, microstructure and compressive strength of porous glass ceramics from metallurgical silicon slag and waste glass[J]. Ceram Inter, 2016, 42(8): 10079-10084.
[42] [42] CHAKARTNARODOM P, INEURE P. Foam glass development using glass cullet and fly ash or rice husk ash as the raw materials[J]. Key Eng Mater, 2014, 608: 73-78.
[43] [43] KNIG J, PETERSEN R R, YUE Y. Influence of the glass particle size on the foaming process and physical characteristics of foam glasses[J]. J Non-Crys Solids, 2016, 447: 190-197.
[44] [44] BERNARDO E, ALBERTINI F. Glass foams from dismantled cathode ray tubes[J]. Ceram Inter, 2006, 32(6): 603-608.
[45] [45] FERNANDES H R, FERREIRA D D, ANDREOLA F, et al. Environmental friendly management of CRT glass by foaming with waste egg shells, calcite or dolomite[J]. Ceram Inter, 2014, 40(8): 13371-13379.
[46] [46] KNIG J, PETERSEN R R, YUE Y. Fabrication of highly insulating foam glass made from CRT panel glass[J]. Ceram Inter, 2015, 41(8): 9793-9800.
[47] [47] KNIG J, PETERSEN R R, YUE Y, et al. Gas-releasing reactions in foam glass formation using carbon and MnxOy as the foaming agents[J]. Ceram Inter, 2017, 43(5): 4638-4646.
[48] [48] MéAR F, YOT P, VIENNOIS R, et al. Mechanical behaviour and thermal and electrical properties of foam glass[J]. Ceram Inter, 2007, 33(4): 543-550.
[49] [49] ZHANG Q, HE F, SHU H, et al. Preparation of high strength glass ceramic foams from waste cathode ray tube and germanium tailings[J]. Constr Building Mater, 2016, 111: 105-110.
[50] [50] PETERSEN R R K J, SMEDSKJAER M M. Foaming of CRT panel glass powder using Na2CO3[J]. Glass Technol, 2014, 55(1): 1-6.
[52] [52] PETERSEN R R, KNIG J, SMEDSKJAER M M, et al. Effect of Na2CO3 as foaming agent on dynamics and structure of foam glass melts[J]. J Non-Cryst Solids, 2014, 400: 1-5.
[53] [53] KNIG J, PETERSEN R R, YUE Y. Influence of the glass calcium carbonate mixture's characteristics on the foaming process and the properties of the foam glass[J]. J Eur Ceram Soc, 2014, 34(6): 1591-1598.
[54] [54] GUO H W, GONG Y X, GAO S Y. Preparation of high strength foam glass ceramics from waste cathode ray tube[J]. Mater Lett, 2010, 64(8): 997-999.
[55] [55] MéAR F, YOT P, RIBES M. Effects of temperature, reaction time and reducing agent content on the synthesis of macroporous foam glasses from waste funnel glasses[J]. Mater Lett, 2006, 60(7): 929-934.
[56] [56] MEAR F, YOT P, CAMBON M, et al. Characterisation of porous glasses prepared from cathode ray tube (CRT)[J]. Powder Technol, 2006, 162(1): 59-63.
[57] [57] CHEN B, LUO Z, LU A. Preparation of sintered foam glass with high fly ash content[J]. Mater Lett, 2011, 65(23/24): 3555-3558.
[58] [58] CHEN B, WANG K, CHEN X, et al. Study of foam glass with high content of fly ash using calcium carbonate as foaming agent[J]. Mater Lett, 2012, 79: 263-265.
[59] [59] LI J, ZHUANG X, MONFORT E, et al. Utilization of coal fly ash from a Chinese power plant for manufacturing highly insulating foam glass: Implications of physical, mechanical properties and environmental features[J]. Constr Building Mater, 2018, 175: 64-76.
[60] [60] GUO Y, ZHANG Y, HUANG H, et al. Novel glass ceramic foams materials based on red mud[J]. Ceram Inter, 2014, 40(5): 6677-6683.
[61] [61] KORAT L, DUCMAN V, LEGAT A, et al. Characterisation of the pore-forming process in lightweight aggregate based on silica sludge by means of X-ray micro-tomography (micro-CT) and mercury intrusion porosimetry (MIP)[J]. Ceram Inter, 2013, 39(6): 6997-7005.
[62] [62] ZHOU M, GE X, WANG H, et al. Effect of the CaO content and decomposition of calcium-containing minerals on properties and microstructure of ceramic foams from fly ash[J]. Ceram Inter, 2017, 43(12): 9451-9457.
[63] [63] CHEN H J, WANG S Y, TANG C W. Reuse of incineration fly ashes and reaction ashes for manufacturing lightweight aggregate[J]. Constr Building Mater, 2010, 24(1): 46-55.
[64] [64] GONZLEZ-CORROCHANO B, ALONSO-AZCRATE J, RODAS M. Characterization of lightweight aggregates manufactured from washing aggregate sludge and fly ash[J]. Resour, Conserv Recycl, 2009, 53(10): 571-581.
[65] [65] HOU L J, LIU T Y, LU A X. Red mud and fly ash-based ceramic foams using starch and manganese dioxide as foaming agent[J]. Transact Nonferrous Met Soc China, 2017, 27(3): 591-598.
[66] [66] LUO Y, ZHENG S, MA S, et al. Preparation of sintered foamed ceramics derived entirely from coal fly ash[J]. Constr Building Mater, 2018, 163: 529-538.
[67] [67] CHEN X, LU A, QU G. Preparation and characterization of foam ceramics from red mud and fly ash using sodium silicate as foaming agent[J]. Ceram Inter, 2013, 39(2): 1923-1929.
[68] [68] LIU T, TANG Y, LI Z, et al. Red mud and fly ash incorporation for lightweight foamed ceramics using lead-zinc mine tailings as foaming agent[J]. Mater Lett, 2016, 183: 362-364.
[69] [69] LIAO Y C, HUANG C Y. Glass foam from the mixture of reservoir sediment and Na2CO3[J]. Ceram Inter, 2012, 38(5): 4415-4520.
[70] [70] LIU M, LIU X, WANG W, et al. Effect of SiO2 and Al2O3 on characteristics of lightweight aggregate made from sewage sludge and river sediment[J]. Ceram Inter, 2018, 44(4): 4313-4319.
[71] [71] GONZáLEZ-CORROCHANO B, ALONSO-AZCáRATE J, RODRíGUEZ L, et al. Valorization of washing aggregate sludge and sewage sludge for lightweight aggregates production[J]. Constr Building Mater, 2016, 116: 252-262.
[72] [72] FRANUS M, BARNAT-HUNEK D, WDOWIN M. Utilization of sewage sludge in the manufacture of lightweight aggregate[J]. Environ Monit Assess, 2016, 188: 10.
[73] [73] GONZALEZ-CORROCHANO B, ALONSO-AZCARATE J, RODAS M. Production of lightweight aggregates from mining and industrial wastes[J]. J Environ Manage, 2009, 90(8): 2801-2812.
[74] [74] LIU M, WANG C, BAI Y, et al. Effects of sintering temperature on the characteristics of lightweight aggregate made from sewage sludge and river sediment[J]. J Alloys Comp, 2018, 748: 522-527.
[75] [75] LIU M, XU G, LI G. Effect of the ratio of components on the characteristics of lightweight aggregate made from sewage sludge and river sediment[J]. Process Saf Environ Prot, 2017, 105: 109-116.
[76] [76] LAU P C, TEO D C L, MANNAN M A. Mechanical, durability and microstructure properties of lightweight concrete using aggregate made from lime-treated sewage sludge and palm oil fuel ash[J]. Constr Building Mater, 2018, 176: 24-34.
[77] [77] LIU T, LI X, GUAN L, et al. Low-cost and environment-friendly ceramic foams made from leadzinc mine tailings and red mud: Foaming mechanism, physical, mechanical and chemical properties[J]. Ceram Inter, 2016, 42(1): 1733-1739.
[78] [78] XI X, XIONG H, SHUI A, et al. Foaming inhibition of SiC-containing porcelain ceramics by using Si powders during sintering[J]. J Eur Ceram Soc, 2017, 37(15): 5044-5050.
[79] [79] GUO Y, ZHANG Y, HUANG H, et al. Novel glass ceramic foams materials based on polishing porcelain waste using the carbon ash waste as foaming agent[J]. Constr Building Mater, 2016, 125: 1093-1100.
[80] [80] XI X, SHUI A, LI Y, et al. Effects of magnesium oxychloride and silicon carbide additives on the foaming property during firing for porcelain ceramics and their microstructure[J]. J Eur Ceram Soc, 2012, 32(12): 3035-3041.
[81] [81] WANG H, CHEN Z, LIU L, et al. Synthesis of a foam ceramic based on ceramic tile polishing waste using SiC as foaming agent[J]. Ceram Inter, 2018, 44(9): 10078-10086.
[82] [82] VOLLAND S, BRTZ J. Lightweight aggregates produced from sand sludge and zeolitic rocks[J]. Constr Building Mater, 2015, 85: 22-29.
[83] [83] VOLLAND S, KAZMINA O, VERESHCHAGIN V, et al. Recycling of sand sludge as a resource for lightweight aggregates[J]. Constr Building Mater, 2014, 52: 361-365.
[84] [84] VOLLAND S. Influence of the mechanical activation of raw mixes on the properties of foam glass from sand sludge[J]. Constr Building Mater, 2016, 125: 119-126.
[85] [85] MARTíNEZ J D, BETANCOURT-PARRA S, CARVAJAL-MARíN I, et al. Ceramic light-weight aggregates production from petrochemical wastes and carbonates (NaHCO3 and CaCO3) as expansion agents[J]. Constr Building Mater, 2018, 180: 124-133.
[86] [86] MORENO-MAROTO J M, GONZALEZ-CORROCHANO B, ALONSO-AZCARATE J, et al. Development of lightweight aggregates from stone cutting sludge, plastic wastes and sepiolite rejections for agricultural and environmental purposes[J]. J Environ Manage, 2017, 200: 229-242.
[87] [87] MORENO-MAROTO J M, GONZLEZ-CORROCHANO B, ALONSO-AZCáRATE J, et al. Manufacturing of lightweight aggregates with carbon fiber and mineral wastes[J]. Cem Concr Compos, 2017, 83: 335-348.
[88] [88] JIANG C, HUANG S, LI G, et al. Formation of closed-pore foam ceramic from granite scraps[J]. Ceram Inter, 2018, 44(3): 3469-3471.
[89] [89] SOLTAN A M M, KAHL W A, ABD ELRAOOF F, et al. Lightweight aggregates from mixtures of granite wastes with clay[J]. J Cleaner Product, 2016, 117: 139-149.
[90] [90] GONZLEZ-CORROCHANO B, ALONSO-AZCRATE J, RODAS M. Effect of prefiring and firing dwell times on the properties of artificial lightweight aggregates[J]. Constr Building Mater, 2014, 53: 91-101.
[91] [91] MUELLER A, SCHNELL A, RUEBNER K. The manufacture of lightweight aggregates from recycled masonry rubble[J]. Constr Building Mater, 2015, 98: 376-387.
[92] [92] GE X, ZHOU M, WANG H, et al. Preparation and characterization of ceramic foams from chromium slag and coal bottom ash[J]. Ceram Inter, 2018, 44(10): 11888-11891.
[93] [93] WEI Y L, KO G W. Recycling steel wastewater sludges as raw materials for preparing lightweight aggregates[J]. J Cleaner Product, 2017, 165: 905-916.
[94] [94] CHRISTOGEROU A, KAVAS T, ANGELOPOULOS G N. Synergy of boron containing solid wastes and fructose for the production of lightweight aggregates: microstructure and properties[J]. WasteBiomass Valorizat, 2013, 5(4): 733-741.
[95] [95] KAVAS T, CHRISTOGEROU A, PONTIKES Y, et al. Valorisation of different types of boron containing wastes for the production of lightweight aggregates[J]. J Hazard Mater, 2011, 185(2/3): 1381- 1389.
[96] [96] HAN M C, HAN D, SHIN J K. Use of bottom ash and stone dust to make lightweight aggregate[J]. Constr Building Mater, 2015, 99: 192-199.
[97] [97] BAINO F, FERRARIS M. Production and characterization of ceramic foams derivevitrified bottom ashes[J]. Mater Lett, 2019, 236: 281-284.
[98] [98] ASSEFI M, MAROUFI S, MANSURI I, et al. High strength glass foams recycled from LCD waste screens for insulation application[J]. J Cleaner Product, 2021, 280: 124311.
[99] [99] ZHU X, SUN N, HUANG Y, et al. Preparation of full tailings-based foam ceramics and auxiliary foaming effect of vanadium-titanium magnetite tailings[J]. J Non-Cryst Solids, 2021, 571: 121063.
[100] [100] CHEN Z, WANG H, JI R, et al. Reuse of mineral wool waste and recycled glass in ceramic foams[J]. Ceram Inter, 2019, 45(12): 15057-15064.
[101] [101] BAI J, YANG X, SHI Y, et al. Fabrication of directional SiC porous ceramics using Fe2O3 as pore-forming agent[J]. Mater Lett, 2012, 78: 192-194.
[102] [102] XI X, XU L, SHUI A, et al. Effect of silicon carbide particle size and CaO content on foaming properties during firing and microstructure of porcelain ceramics[J]. Ceram Inter, 2014, 40(8): 12931-12938.
[103] [103] JI R, ZHANG Z, HE Y, et al. Synthesis, characterization and modeling of new building insulation material using ceramic polishing waste residue[J]. Constr Building Mater, 2015, 85: 119-126.
[104] [104] GARCíA-TEN J, SABURIT A, BERNARDO E, et al. Development of lightweight porcelain stoneware tiles using foaming agents[J]. J Eur Ceram Soc, 2012, 32(4): 745-752.
[105] [105] ZHAI C, LI Z, ZHU Y, et al. Effects of Sb2O3 on the mechanical properties of the borosilicate foam glasses sintered at low temperature[J]. Adv Mater Sci Eng, 2014, 2014: 1-6.
[106] [106] HWANG J Y, YU J H, KANG K. A study of the gasification of carbon black with molten salt of Li2CO3 and K2CO3 for application in the external anode media of a direct carbon fuel cell[J]. Currt Appl Phys, 2015, 15(12): 1580-1586.
[107] [107] STERGAARD M B, PETERSEN R R, KNIG J, et al. Effect of alkali phosphate content on foaming of CRT panel glass using Mn3O4 and carbon as foaming agents[J]. J Non-Cryst Solids, 2018, 482: 217-222.
[108] [108] SHI H, FENG K Q, WANG H B, et al. Influence of aluminium nitride as a foaming agent on the preparation of foam glass ceramics from high-titanium blast furnace slag[J]. Inter J Miner, Metall Mater, 2016, 23(5): 595-600.
[109] [109] KNIG J P R R, YUE Y. Influence of the glass calcium carbonate mixture's characteristics on the foaming process and the properties of the foam glass[J]. J Eur Ceram Soc, 2014, 34(6): 1591-1598.
[110] [110] DONDI M, CAPPELLETTI P, D’AMORE M, et al. Lightweight aggregates from waste materials: Reappraisal of expansion behavior and prediction schemes for bloating[J]. Constr Building Mater, 2016, 127: 394-409.
[111] [111] CHINNAM R K, FRANCIS A A, WILL J, et al. Functional glasses and glass ceramics derived from iron rich waste and combination of industrial residues[J]. J Non-Cryst Solids, 2013, 365: 63-74.
[112] [112] DUCMAN V, KORAT L, LEGAT A, et al. X-ray micro-tomography investigation of the foaming process in the system of waste glass silica mud-MnO2[J]. Mater Charact, 2013, 86: 316-321.
[113] [113] PETERSEN R R, KNIG J, YUE Y. The mechanism of foaming and thermal conductivity of glasses foamed with MnO2[J]. J Non-Cryst Solids, 2015, 425: 74-82.
[115] [115] WANG H, FENG K, SUN Q. Effect of calcium carbonate on the preparation of glass ceramic foams from water-quenched titanium-bearing blast furnace slag and waste glass[J]. Advances in Appl Ceram, 2018, 117(5): 312-318.
[116] [116] KIM H, LEE S, HAN Y, et al. Control of pore size in ceramic foams: Influence of surfactant concentration[J]. Mater Chem and Phys, 2009, 113(1): 441-444.
[118] [118] ZHANG J Y, FU Y M, ZENG X M. Compressive properties of open-cell ceramic foams[J]. Transact Nonferr Met Soc China, 2006, 16: s453-s456.
[119] [119] LIANG B, ZHANG M, LI H, et al. Preparation of ceramic foams from ceramic tile polishing waste and fly ash without added foaming agent[J]. Ceram Inter, 2021, 47(16): 23338-23349.
[120] [120] KUANG F H, WANG S M, GAO C, et al. Unique microstructure and thermal insulation property of a novel waste-utilized foam ceramic[J]. J Mater Sci Technol, 2020, 48: 175-179.
[121] [121] FANG W, HOU L, LI Y. Foaming mechanism of SiC in steel slag foamed ceramics[J]. ISIJ Internat, 2021, 61(3): 1043-1052.
[122] [122] BENZERGA R, LAUR V, LEBULLENGER R, et al. Waste glass recycling: A step toward microwave applications[J]. Mater Res Bull, 2015, 67: 261-265.
[123] [123] ABBASI S, MIRKAZEMI S M, ZIAEE A, et al. The effects of Fe2O3 and Co3O4 on microstructure and properties of foam glass from soda lime waste glasses[J]. Glass Phys Chem, 2014, 40(2): 173-179.
[124] [124] GALLO L S A, DE MARCHI MOSCA T, TEIDER B H, et al. Effects of lithium oxide on the crystallization kinetics of Na2O·2CaO·3SiO2 glass[J]. J Non-Cryst Solids, 2015, 408: 102-114.
[125] [125] LI J, CAO J, XU B, et al. Effect of gas-solid interface on pore wall microstructure evolution during thermal melting of foamed ceramics[J]. J Therm Anal Calorimetry, 2021, 147(3): 2035-2046.
[127] [127] YAN Z, WANG Z, LIU H, et al. Decomposition and solid reactions of calcium sulfate doped with SiO2, Fe2O3 and Al2O3[J]. J Anal Appl Pyrolysis, 2015, 113: 491-498.
[129] [129] HASHEMINIA S, NEMATI A, EFTEKHARI YEKTA B, et al. Preparation and characterisation of diopside-based glass ceramic foams[J]. Ceram Inter, 2012, 38(3): 2005-2010.
[130] [130] VERNEROV M, CINCIBUSOV P, KLOUEK J, et al. Method of examination of bubble nucleation in glass melts[J]. J Non-Cryst Solids, 2015, 411: 59-67.
[131] [131] AVINASH G, HARIKA V, SANDEEPIKA C, et al. Pore size control in aluminium foam by standardizing bubble rise velocity and melt viscosity[J]. IOP Conf Ser: Mater Sci Eng, 2018, 338: 012010.
[132] [132] ZHANG J, LIU B, ZHANG S. A review of glass ceramic foams prepared from solid wastes: processing, heavy-metal solidification and volatilization, applications[J]. Sci Tot Environ, 2021, 781: 146727.
[135] [135] CHUANG K H, LU C H, CHEN J C, et al. Reuse of bottom ash and fly ash from mechanical-bed and fluidized-bed municipal incinerators in manufacturing lightweight aggregates[J]. Ceram Inter, 2018, 44(11): 12691-12696.
[136] [136] LAUR V, BENZERGA R, LEBULLENGER R, et al. Green foams for microwave absorbing applications: synthesis and characterization[J]. Mater Res Bull, 2017, 96: 100-106.
[137] [137] BENHAOUA F, AYADI A, STITI N, et al. Elaboration and characterization of a cellular glass based cullet loaded with carbon fibers[J]. Mater Lett, 2015, 160: 278-281.
[139] [139] RANGEL E M, MELO C C N D, MACHADO F M. Ceramic foam decorated with ZnO for photodegradation of Rhodamine B dye[J]. BOL SOC ESP CERAM V, 2019, 58(3): 134-140.
[140] [140] RAN H T, TU S C, LI C, et al. Preparation and oil removal efficiency of foamed ceramics from red mud and fly ash[J]. Transact Mater Heat Treat, 2016, 37: 31-35.
[141] [141] JIANG C C, ZHANG X Z, WANG D, et al. Recycling fly ash and red mud to manufacture self-foaming ceramic foams[J]. Ceram Silikaty, 2020, 64(4): 371-378.
Get Citation
Copy Citation Text
JIANG Congcong, DONG Yiran, HUANG Shifeng, CHENG Xin. Research Progress on Solid Waste-Based Foamed Ceramics Based on In-Situ Foaming Process[J]. Journal of the Chinese Ceramic Society, 2022, 50(9): 2510
Category:
Received: May. 10, 2022
Accepted: --
Published Online: Jan. 3, 2023
The Author Email: Congcong JIANG (mse_jiangcc@163.com)