Influence of Waste Circuit Board Non-Metallic Powder on Properties of Alkali-Activated Slag/Fly Ash Cementitious Material

Abstract

Abstract: A novel alkali-activated slag/fly ash cementitious material was prepared by incorporating 0%~25% (mass fraction) waste circuit board non-metallic powder (NMP). The properties of this new material were evaluated, including its mechanical strength, hydration heat release, phase composition, and pore size distribution. The microstructural features were also analyzed. The results indicate that the addition of NMP not only reduces the workability and cumulative heat release of cementitious material, but also slightly reduces its 7 and 28 d compressive strength. When the NMP content is less than 15% (mass fraction), the 28 d flexural strength of cementitious material is positively correlated with the NMP content due to the presence of glass fibers, resulting in a maximum increase of 55.5%. Incorporating NMP reduces the proportion of pores with diameter between 100 nm and 1 000 nm, while improving the proportion of micropores with diameter below 100 nm, leading to an overall increase in total porosity. The resin particles in NMP are tightly bound to the cementitious material matrix, filling the voids between the fibers and the matrix. The addition of NMP does not affect the types of hydration products in the original cementitious material.

Key words: cementitious material, waste circuit board, non-metallic powder, alkali-activated slag, property, glass fiber, resource regeneration

CLC Number:

TQ172

LIU Yonghua, HU Xinlang, SHI Limin, GAO Yingli. Influence of Waste Circuit Board Non-Metallic Powder on Properties of Alkali-Activated Slag/Fly Ash Cementitious Material[J]. BULLETIN OF THE CHINESE CERAMIC SOCIETY, 2023, 42(12): 4456-4464.

References

[1] LUHAR S, LUHAR I. Potential application of E-wastes in construction industry: a review[J]. Construction and Building Materials, 2019, 203: 222-240.
[2] HAMSAVATHI K, PRAKASH K S, KAVIMANI V. Green high strength concrete containing recycled cathode ray tube panel plastics (E-waste) as coarse aggregate in concrete beams for structural applications[J]. Journal of Building Engineering, 2020, 30: 101192.
[3] MOU P, XIANG D, DUAN G H. Products made from nonmetallic materials reclaimed from waste printed circuit boards[J]. Tsinghua Science & Technology, 2007, 12(3): 276-283.
[4] 刘旸, 刘静欣, 秦红, 等. NaOH-NaNO₃-Air体系低温碱性熔炼处理废弃电路板多金属粉末[J]. 中南大学学报(自然科学版), 2015, 46(8): 2804-2811.
LIU Y, LIU J X, QIN H, et al. Treatment of crushed metal enrichment of waste printed circuit board by low-temperature alkaline smelting in NaOH-NaNO₃-air system[J]. Journal of Central South University (Science and Technology), 2015, 46(8): 2804-2811 (in Chinese).
[5] 杨建广, 陈冰, 雷杰, 等. 废弃电路板铜锡多金属粉隔膜电积回收锡实验研究[J]. 东北大学学报(自然科学版), 2017, 38(11): 1648-1653.
YANG J G, CHEN B, LEI J, et al. Experimental study on tin recovery based on membrane electrodeposition from metal fractions of waste printed circuit boards[J]. Journal of Northeastern University (Natural Science), 2017, 38(11): 1648-1653 (in Chinese).
[6] QIU R J, LIN M, RUAN J J, et al. Recovering full metallic resources from waste printed circuit boards: a refined review[J]. Journal of Cleaner Production, 2020, 244: 118690.
[7] LEDWABA P, SOSIBO N. Cathode ray tube recycling in South Africa[J]. Recycling, 2017, 2(1): 4.
[8] MUNDADA M N, KUMAR S, SHEKDAR A V. E-waste: a new challenge for waste management in India[J]. International Journal of Environmental Studies, 2004, 61(3): 265-279.
[9] 郝娟娟, 王乙舒, 吴玉峰, 等. 废线路板非金属材料回收利用技术现状与展望[J]. 材料导报, 2021, 35(7): 7001-7012.
HAO J J, WANG Y S, WU Y F, et al. Current situation and prospect of recovery and utilization of non-metal materials of waste printed circuit board[J]. Materials Reports, 2021, 35(7): 7001-7012 (in Chinese).
[10] ARYA C, CLARKE J L, KAY E A, et al. TR 55: design guidance for stengthening concrete structures using fibre composite materials: a review[J]. Engineering Structures, 2002, 24(7): 889-900.
[11] LI J A, LU H Z, GUO J E, et al. Recycle technology for recovering resources and products from waste printed circuit boards[J]. Environmental Science & Technology, 2007, 41(6): 1995-2000.
[12] MOU P, LAYIDING W, XIANG D, et al. A physical process for recycling and reusing waste printed circuit boards[C]. IEEE International Symposium on Electronics ＆ the Environment. Scottsdale, AZ, USA, 2004: 237-242.
[13] GAVHANE M A, SUTAR M D, SONI M S, et al. Utilisation of E-plastic waste in concrete[J]. International Journal of Engineering Research and, 2016, V5(2): 594-601.
[14] KANCHANAPIYA P, PINYO W, JAREEMIT S, et al. Recycling of non-metallic powder from printed circuit board waste as a filler material in a fiber reinforced polymer[J]. Environment Protection Engineering, 2015, 41(4): 151-166.
[15] WANG R, ZHANG T F, WANG P M. Waste printed circuit boards nonmetallic powder as admixture in cement mortar[J]. Materials and Structures, 2012, 45(10): 1439-1445.
[16] 徐丽军, 关杰, 袁昊, 等. 掺杂废弃线路板非金属粉末的粉刷石膏复合材料的力学性能[J]. 环境工程学报, 2017, 11(4): 2439-2446.
XU L J, GUAN J, YUAN H, et al. Mechanical performance of gypsum plaster composite materials reinforced by non-metallic powder recycled from waste printed circuit board[J]. Chinese Journal of Environmental Engineering, 2017, 11(4): 2439-2446 (in Chinese).
[17] 谢恒来, 吴曼, 赵军, 等. 导向管喷动流化床中废弃印刷线路板的非金属颗粒包覆改性[J]. 化工学报, 2015, 66(3): 1185-1193.
XIE H L, WU M, ZHAO J, et al. Coating modification of non-metal particles of waste printed circuit boards in spout-fluid bed with draft tube[J]. CIESC Journal, 2015, 66(3): 1185-1193 (in Chinese).
[18] WANG Q, ZHANG B G, YU S Q, et al. Waste-printed circuit board recycling: focusing on preparing polymer composites and geopolymers[J]. ACS Omega, 2020, 5(29): 17850-17856.
[19] JANARDHANAN T, RAMASAMY V. Improvements in the microstructural and mechanical properties of geopolymer concrete containing NMF’s of E-wastes as partial replacement of aggregates[J]. European Journal of Environmental and Civil Engineering, 2017: 1-12.
[20] YANG K H, SONG J K, SONG K I. Assessment of CO₂ reduction of alkali-activated concrete[J]. Journal of Cleaner Production, 2013, 39: 265-272.
[21] KAKRIA K, THIRUMALINI S, SECCO M, et al. A novel approach for the development of sustainable hybridized geopolymer mortar from waste printed circuit boards[J]. Resources, Conservation and Recycling, 2020, 163: 105066.
[22] 国家市场监督管理总局. 水泥胶砂强度检验方法(ISO方法): GB/T 17671—2021[S]. 北京: 中国标准出版社, 2021.
State Administration for Market Regulation. Test method for strength of cement mortar (ISO method): GB/T 17671—2021[S]. Beijing: China Standard Press, 2021 (in Chinese).
[23] MARQUES A C, CABRERA MARRERO J M, DE FRAGA MALFATTI C. A review of the recycling of non-metallic fractions of printed circuit boards[J]. Springer Plus, 2013, 2(1): 1-11.
[24] ISMAIL Z Z, AL-HASHMI E A. Use of waste plastic in concrete mixture as aggregate replacement[J]. Waste Management, 2008, 28(11): 2041-2047.
[25] NING C, LIN C S K, HUI D C W, et al. Waste printed circuit board (PCB) recycling techniques[J]. Topics in Current Chemistry, 2017, 375(2): 43.
[26] NEKOUEI K R, TUDELA I, PAHLEVANI F, et al. Current trends in direct transformation of waste printed circuit boards (WPCBs) into value-added materials and products[J]. Current Opinion in Green and Sustainable Chemistry, 2020, 24: 14-20.
[27] SUA-IAM G, CHATVEERA B. A study on workability and mechanical properties of eco-sustainable self-compacting concrete incorporating PCB waste and fly ash[J]. Journal of Cleaner Production, 2021, 329: 129523.
[28] GESOGLU M, GÜNEYISI E, HANSU O, et al. Mechanical and fracture characteristics of self-compacting concretes containing different percentage of plastic waste powder[J]. Construction and Building Materials, 2017, 140: 562-569.
[29] ALMESHAL I, TAYEH B A, ALYOUSEF R, et al. Eco-friendly concrete containing recycled plastic as partial replacement for sand[J]. Journal of Materials Research and Technology, 2020, 9(3): 4631-4643.
[30] HAMA S M, HILAL N N. Fresh properties of self-compacting concrete with plastic waste as partial replacement of sand[J]. International Journal of Sustainable Built Environment, 2017, 6(2): 299-308.
[31] FARAJ R H, SHERWANI A F H, DARAEI A. Mechanical, fracture and durability properties of self-compacting high strength concrete containing recycled polypropylene plastic particles[J]. Journal of Building Engineering, 2019, 25: 100808.
[32] FARAJ R H, HAMA ALI H F, SHERWANI A F H, et al. Use of recycled plastic in self-compacting concrete: a comprehensive review on fresh and mechanical properties[J]. Journal of Building Engineering, 2020, 30: 101283.
[33] GU L, OZBAKKALOGLU T. Use of recycled plastics in concrete: a critical review[J]. Waste Management, 2016, 51: 19-42.