Basic performance, heavy metal leaching mechanism and risk assessment analysis of waste concrete

Wang, Chao-qiang; Cheng, Lin-xiao; Huang, Qi-cong; Shui, Zhong-he; Liu, Yan-yan; Zhao, Hui; Zhang, Zhao-ji

doi:10.1007/s43452-023-00666-y

Artykuł - szczegóły

Tytuł artykułu

Basic performance, heavy metal leaching mechanism and risk assessment analysis of waste concrete

Autorzy

Wang Chao-qiang , Cheng Lin-xiao , Huang Qi-cong , Shui Zhong-he , Liu Yan-yan , Zhao Hui , Zhang Zhao-ji

Wybrane pełne teksty z tego czasopisma

http://www.springer.com/journal/43452

Identyfikatory

DOI

10.1007/s43452-023-00666-y

Warianty tytułu

Języki publikacji

Abstrakty

With the acceleration of urbanization, the production of waste concrete is getting higher and higher. A large amount of outdoor accumulations of waste concrete will leach heavy metals, not only causing harm to the soil, but also posing a risk to human health. Based on this, this paper systematically studies the basic physical properties and microstructure (XRF, XRD, and SEM-EDS) of outdoor natural accumulation waste concrete, and analyzes the heavy metals in waste concrete from the aspects of existing state, leaching mechanism, human health risk analysis, and summarized the direction of resource utilization of waste concrete, calculated the carbon emission reduction during recycling. The study found that heavy metals in waste concrete mainly exist in hydration products in the form of precipitation, adsorption, and replacement, summarized the leaching mechanism from the micro- and macro-aspects. The leaching mechanism of heavy metals can be assigned to chemical (mineral dissolution and effective amount of components) and physical (advection, surface erosion, and diffusion) processes from the macro-perspective. From the micro-analysis, it can be assigned to the following five processes: acid migrates from solution to liquid-solid surface, acid migration through leaching layer, rapid dissolution reaction controlled by diffusion at leaching boundary, heavy metal through leaching layer, and heavy metals through the solid/liquid surface to the solution. In addition, the concentration and the leaching rate of heavy metals in waste concrete were analyzed. It was found that the concentration of Cr was the highest reached to 4.7 mg/kg and the leaching rate of Cd was the highest, its leaching coefficient was calculated as a result of 1.713 × 10^–6. However, there was no obvious regularity in the leaching of heavy metals in different accumulate particle sizes. Through the establishment of risk assessment system was found the concentration of heavy metals in waste concrete will not cause significant harm to human health. The effective limit of heavy metals after 3 months of accumulation of waste concrete was calculated as: Cr < 0.09 mg/kg, Cd < 0.00715 mg/kg, As < 0.392 mg/kg, and Pb < 0.732 mg/kg. And the carbon emission reduction of waste concrete recycling was calculated to be 28.764kgCO₂/t. All the results of this study can promote the safe and environmentally friendly utilization of waste concrete.

Słowa kluczowe

waste concrete heavy metal leaching mechanism ecological risk assessment

odpady betonowe metal ciężki mechanizm ługowania ocena ryzyka ekologicznego

Wydawca

Springer
Wrocław University of Science and Technology

Czasopismo

Archives of Civil and Mechanical Engineering

Rocznik

2023

Tom

Vol. 23, no. 2

Strony

art. no. e122, 2023

Opis fizyczny

Bibliogr. 80 poz., rys., tab., wykr.

Twórcy

autor

Wang Chao-qiang

wcq598676239@126.com

School of Materials Science and Engineering, Chongqing Jiaotong University, Chongqing 400074, China

autor

Cheng Lin-xiao

School of Materials Science and Engineering, Chongqing Jiaotong University, Chongqing 400074, China

autor

Huang Qi-cong

Chongqing Institute of Modern Construction Industry Development, Chongqing 400066, China

autor

Shui Zhong-he

438516618@qq.com

State Key Laboratory of Silicate Materials for Architectures, Wuhan University of Technology), Wuhan 430070, China

autor

Liu Yan-yan

School of Materials Science and Engineering, Chongqing Jiaotong University, Chongqing 400074, China
Guangxi Key Laboratory of Road Structure and Materials, Nanning 530007, Guangxi, China
Guangxi Transportation Science and Technology Group Co. Ltd, Nanning 530007, Guangxi, China

autor

Zhao Hui

Chongqing Institute of Modern Construction Industry Development, Chongqing 400066, China

autor

Zhang Zhao-ji

zjzhang@iue.ac.cn

Key Laboratory of Urban Pollutant Conversion, Chinese Academy of Sciences, Xiamen 361021, Fujian, China

Bibliografia

1. Alex J, Dhanalakshmi J, Ambedkar B. Experimental investigation on rice husk ash as cement replacement on concrete production. Constr Build Mater. 2016;127:353-62.
2. He XY, Li WL, Su Y, Zheng ZQ, Fu JJ, Zeng JY, Tan HB, Wu Y, Yang J. Recycling of plastic waste concrete to prepare an effective additive for early strength and late permeability improvement of cement paste. Constr Build Mater. 2022;347: 128581.
3. Hao JL, Yu SW, Tang XN, Wu WW. Determinants of workers’ pro-environmental behaviour towards enhancing construction waste management: contributing to China’s circular economy. JClean Prod. 2022;369: 133265.
4. Huang BJ, Wang XY, Kua H, Geng Y, Bleischwitz R, Ren JZ. Construction and demolition waste management in China through the 3R principle. Resour Conserv Recy. 2018;129:36-44.
5. Jin RY, Li B, Zhou TY, Wanatowski D, Piroozfar P. An empirical study of perceptions towards construction and demolition waste recycling and reuse in China. Resour Conserv Recy. 2017;126:86-98.
6. Aslam MS, Huang BJ, Cui LF. Review of construction and demolition waste management in China and USA. J Environ Manage. 2020;264: 110445.
7. Lu W, Lee WM, Bao Z, Chi B, Webster C. Cross-jurisdictional construction waste material trading: learning from the smart grid. J Clean Prod. 2020;277: 123352.
8. Al-Waked Q, Bai JP, Kinuthia J, Davies P. Durability and microstructural analyses of concrete produced with treated demolition waste aggregates. Constr Build Mater. 2022;347: 128597.
9. Jin RY, Li B, Elamin A, Wang SQ, Tsioulou O, Wanatowski D. Experimental investigation of properties of concrete containing recycled construction wastes. Int J Civ Eng. 2018;16(11):1621-33.
10. Xuan XD, Zhan BJ, Poon CS. Durability of recycled aggregate concrete prepared with carbonated recycled concrete aggregates. Cemen Concrete Comp. 2017;84:214-21.
11. Ozbakkaloglu T, Gholampour A, Xie TY. Mechanical and durability properties of recycled aggregate concrete: effect of recycled aggregate properties and content. J Mater Civil Eng. 2018;30(2):04017275.
12. Wang JG, Zhang JX, Cao DD, Dang HX, Ding B. Comparison of recycled aggregate treatment methods on the performance for recycled concrete. Constr Build Mater. 2020;234: 117366.
13. Liu X, Wu J, Yan PP, Ji WY. Grading method of mixed recycled coarse aggregate. J Mater Civil Eng. 2021;33(5):04021085.
14. Ren P, Li B, Yu JG, Ling TC. Utilization of recycled concrete fines and powders to produce alkali-activated slag concrete blocks. J Clean Prod. 2020;267: 122115.
15. Oksri-Nelfia L, Mahiex PY, Amiri O, Turcry Ph, Lux J. Reuse of recycled crushed concrete fines as mineral addition in cementitious materials. Mater Struct. 2016;49(8):3239-51.
16. Liu XY, Liu L, Lyu K, Li TY, Zhao PZ, Liu RD, Zuo JQ, Fu F, Shah SP. Enhanced early hydration and mechanical properties of cement-based materials with recycled concrete powder modified by nano-silica. J Build Eng. 2022;50: 104175.
17. Duan ZH, Singh A, Xiao JZ. Combined use of recycled powder and recycled coarse aggregate derived from construction and demolition waste in self-compacting concrete. Constr Build Mater. 2020;254: 119323.
18. Xiao JZ, Ma ZM, Sui TB, Akbarnezhad A, Duan ZH. Mechanical properties of concrete mixed with recycled powder produced from construction and demolition waste. J Clean Prod. 2018;188:720-31.
19. Pavlů T, Koči V, Šefflova M. Study replacement of cement with recycled cement Powder and the Environmental Assessment. Solid State Phenom. 2016;249:136-41.
20. Duan Z, Hou S, Xiao J, Singh A. Rheological properties of mortar containing recycled powders from construction and demolition wastes. Constr Build Mater. 2020;237: 117622.
21. Yu KQ, Zhu WJ, Ding Y, Lu ZD, Yu JT, Xiao JZ. Micro-structural and mechanical properties of ultra-high performance engineered cementitious composites (UHP-ECC) incorporation of recycled fine powder (RFP). Cement Concr Res. 2019;124: 105813.
22. Katz A, Kulisch D. Performance of mortars containing recycled fine aggregate from construction and demolition waste. Mater Struct. 2017;50(4):1-16.
23. Zhang ZQ, Zhang YF, Yan CG, Liu YX. Influence of crushing index on properties of recycled aggregates pervious concrete. Constr Build Mater. 2017;135:112-8.
24. Kim HS, Lee SH, Kim B. Properties of extrusion concrete panel using waste concrete powder. Appl Sci. 2017;7(9):910.
25. Meng T, Hong YP, Ying KJ, Wang ZJ. Comparison of technical properties of cement pastes with different activated recycled powder from construction and demolition waste. Cemen Concrete Comp. 2021;120: 104065.
26. Huang MR, Feng HJ, Shen DS, Li N, Chen YQ, ShenTu JL. Leaching behavior of heavy metals from cement pastes using a modified toxicity characteristic leaching procedure (TCLP). B Environ Contam Tox. 2016;96(3):354-60.
27. Pang FJ, Wei CB, Zhang ZY, Wang WL, Wang ZM. The migration and immobilization for heavy metal chromium ions in the hydration products of calcium sulfoaluminate cement and their leaching behavior. J Clean Prod. 2022;365: 132778.
28. El-Nemr A, EI-Said GF, Khaled A, Ragab S. Distribution and ecological risk assessment of some heavy metals in coastal surface sediments along the Red Sea, Egypt. Int J Sediment Res 2016; 31(2):164-172
29. Cui L, Li J, Gao XY, Tian B, Zhang JW, Wang XN, Liu ZT. Human health ambient water quality criteria for 13 heavy metals and health risk assessment in Taihu Lake. Front Env Sci Eng. 2022;16(4):1-11.
30. Wang ZX, Guo QW, Yang ZJ, Sun GQ, Ye WS, Hu XB. A land use-based spatial analysis method for human health risk assessment of heavy metals in soil and its application in Zhuzhou City, Hunan Province. China J Cent South Univ. 2016;23(8):1915-23.
31. Liu XT, Zhai YB, Zhu Y, Liu YN, Chen HM, Li P, Peng C, Xu BB, Li CT, Zeng GM. Mass concentration and health risk assessment of heavy metals in size-segregated airborne particulate matter in Changsha. Sci Total Environ. 2015;517:215-21.
32. Jayasuriya A, Adams MP, Bandelt MJ. Understanding variability in recycled aggregate concrete mechanical properties through numerical simulation and statistical evaluation. Constr Build Mater. 2018;178:301-12.
33. Saravanakumar P, Abhiram K, Manoj B. Properties of treated recycled aggregates and its influence on concrete strength characteristics. Constr Build Mater. 2016;111:611-7.
34. Lee DJ. Formation of leadhillite and calcium lead silicate hydrate (C-Pb-S-H) in the solidification/stabilization of lead contaminants. Chemosphere. 2007;66(9):1727-33.
35. Mahmood AH, Afroz S, Kashani A, Kim T, Foster SJ. The efficiency of recycled glass powder in mitigating the alkali-silica reaction induced by recycled glass aggregate in cementitious mortars. Mater Struct. 2022;55(6):1-20.
36. Guo XL, Yuan ST, Xu YF, Qian GR. Effects of phosphorus and iron on the composition and property of Portland cement clinker utilized incinerated sewage sludge ash. Constr Build Mater. 2022;341: 127754.
37. Liu LH, Liu SY, Peng HL, Yang ZC, Zhao L, Tang AP. Surface charge of mesoporous calcium silicate and its adsorption characteristics for heavy metal ions. Solid State Sci. 2020;99: 106072.
38. Liu SJ, Cui SP, Guo HX, Wang YL, Zheng Y. Adsorption of lead ion from wastewater using non-crystal hydrated calcium silicate gel. Materials. 2021;14(4):842.
39. Huang ZX, Liu KS, Duan JS, Wang Q. A review of waste-containing building materials: characterization of the heavy metal. Constr Build Mater. 2021;309: 125107.
40. Ma W, Chen D, Pan M, Gu T, Zhong L, Chen G, Cheng Z. Performance of chemical chelating agent stabilization and cement solidification on heavy metals in MSWI fly ash: a comparative study. J Environ Manage. 2019;247:169-77.
41. Wang DQ, Wang Q. Clarifying and quantifying the immobilization capacity of cement pastes on heavy metals. Cement Concrete Res. 2022;161: 106945.
42. Lu H, Wei F, Tang J, Giesy JP. Leaching of metals from cement under simulated environmental conditions. J Environ Manage. 2016;169:319-27.
43. Xu GR, Zou JL, Li GB. Stabilization of heavy metals in ceramsite made with sewage sludge. J Hazard Mater. 2008;152(1):56-61.
44. Jian S, Wang D, Deng P, Li B, Gao X, Huang J. Preparation of lightweight aggregates using waste soil contaminated with heavy metals: physical properties, microstructure and verification of heavy metal solidification through different leaching tests. J Build Eng. 2022;61: 105243.
45. Qiao P, Yang S, Lei M, Chen T, Dong N. Quantitative analysis of the factors influencing spatial distribution of soil heavy metals based on geographical detector. Sci Total Environ. 2019;664:392-413.
46. Liu G, Wang J, Liu X, Liu X, Li X, Ren Y, Wang J, Dong L. Partitioning and geochemical fractions of heavy metals from geogenic and anthropogenic sources in various soil particle size fractions. Geoderma. 2018;312:104-13.
47. Ma J, Zhong B, Khan MA. Transport of mobile particles in heavy metal contaminated soil with simulated acid rain leaching. B Environ Contam Tox. 2021;106:965-9.
48. Van der Sloot. European activities on harmonisation of leaching/extraction tests and standardisation in relation to the use of alternative materials in construction. 2001.
49. Liu Q, Wang X, Gao M, Guan Y, Wu C, Wang Q, Liu S. Heavy metal leaching behaviour and long-term environmental risk assessment of cement-solidified municipal solid waste incineration fly ash in sanitary landfill. Chemosphere. 2022;300: 134571.
50. Yu Q, Nagataki S, Lin J, Saeki T, Hisada M. The leachability of heavy metals in hardened fly ash cement and cement-solidified fly ash. Cement Concrete Res. 2005;35(6):1056-63.
51. Cheng KY. Controlling mechanisms of metals release from cement-based waste form in acetic acid solution, University of Cincinnati. 1991.
52. Wang JH, Zhang X, Yang Q, Zhang K, Zheng Y, Zhou GH. Pollution characteristics of atmospheric dustfall and heavy metals in a typical inland heavy industry city in China. J Environ Sci. 2018;71:283-91.
53. Li WX, Zhang XX, Wu B, Sun SL, Chen YS, Pan WY, Zhao DY, Cheng SP. A comparative analysis of environmental quality assessment methods for heavy metal-contaminated soils. Pedosphere. 2008;18(3):344-52.
54. Ferreira SL, da Silva Junior JB, dos Sandos IF, de Oliveira OM, Cerda V, Queiroz AF. Use of pollution indices and ecological risk in the assessment of contamination from chemical elements in soils and sediments-practical aspects. Trends Environ Anal. 2022;35: e00169.
55. Zhou WW, Dan Z, Dan DA. Distribution characteristics and potential ecological risk assessment of heavy metals in soils around Shannan landfill site, Tibet. Environ Geochem Hlth. 2022: 1-15.
56. Soultanidis V, Papaspyros I, Voudrias EA, Moutsopoulos KN. Release of heavy metals from conventional and reflective cool cement pavements. J Clean Prod. 2022;336: 130434.
57. Wang B, Yan LB, Fu QN, Kasal B. A comprehensive review on recycled aggregate and recycled aggregate concrete. Resour Conserv Recy. 2021;171: 105565.
58. Koga H, Katahira H, Shimata A. The introduction of recycled-aggregate concrete specifications in Japan and the research into the freezing-thawing resistance of recycled-aggregate concrete. J Mate Cycles Waste. 2022;24:1207-15.
59. Kim J. Influence of quality of recycled aggregates on the mechanical properties of recycled aggregate concretes: an overview. Constr Build Mater. 2022;328: 127071.
60. Kurda R, de Brito J, Silvestre JD. Influence of recycled aggregates and high contents of fly ash on concrete fresh properties. Cement Concrete Comp. 2017;84:198-213.
61. Wang RX, Zhang YX. Recycling fresh concrete waste: a review. Struct Concrete. 2018;19(6):1939-55.
62. Al Ajmani H, Sulleiman F, Abuzayed I, Tamimi A. Evaluation of concrete strength made with recycled aggregate. Buildings. 2019;9(3):56.
63. Grabiec AM, Zawal D, Rasaq WA. The effect of curing conditions on selected properties of recycled aggregate concrete. Appl Sci. 2020;10(13):4441.
64. Zheng LN, Wu.HY, Zhang H, Duan HB, Wang JY, Jiang WP, Dong BQ, Liu G, Zuo J, Song QB. Characterizing the generation and flows of construction and demolition waste in China. Constr Build Mater. 2017;136: 405-413.
65. Vishnu TB, Singh KL. A study on the suitability of solid waste materials in pavement construction: a review. Inter J Pavement Res Technol. 2021;14(5):625-37.
66. Sha F, Lin C, Li Z, Liu R. Reinforcement simulation of water-rich and broken rock with portland cement-based grout. Constr Build Mater. 2019;221:292-300.
67. Dun ZL, Wang MQ, Ren LW, Dun ZY. Tests Research on Grouting Materials of Waste-Concrete-Powder Cement for Goaf Ground Improvement. Adv Mater Sci Eng. 2021.
68. Wu.M, Fridh.K, Johannesso B, Geiker M. Impact of sample crushing on porosity characterization of hardened cement pastes by low temperature calorimetry: comparison of powder and cylinder samples. Thermochimica Acta. 2018;665:11-19.
69. Peng LH, Dai HL, Wu YF, Peng YH, Lu XW. A comprehensive review of phosphorus recovery from wastewater by crystallization processes. Chemosphere. 2018;197:768-81.
70. Jennings HM, Thomas JJ, Gevrenov JS, Constantinides G. A multi-technique investigation of the nanoporosity of cement paste. Cement Concrete Res. 2007;37(3):329-36.
71. Zhang N, Xi B, Li JB, Liu L, Song GG. Utilization of CO2 into recycled construction materials: a systematic literature review. J Mater Cycles Waste. 2022;24:2108-2105.
72. Vashistha P, Park S, Pyo S. A Review on sustainable fabrication of futuristic cementitious binders based on application of waste concrete powder, steel slags, and coal bottom ash. Int J Concr Struct M. 2022;16(1):1-28.
73. Krour H, Trauchessec R, Lecomte A, Diliberto C, Barnes-Davin L, Bolze B, Delhay A. Incorporation rate of recycled aggregates in cement raw meals. Constr Build Mater. 2020;248: 118217.
74. Kwon E, Ahn J, Cho B, Park D. A study on development of recycled cement made from waste cementitious powder. Constr Build Mater. 2015;83:174-80.
75. Revilla-Cuesta V, Skaf M, Espinosa AB, Ortega-Lopez V. Multicriteria feasibility of real use of self-compacting concrete with sustainable aggregate, binder and powder. J Clean Prod. 2021;325: 129327.
76. Bouarroudj ME, Remond S, Bulteel D, Potier G, Michel F, Zhao Z, Courard L. Use of grinded hardened cement pastes as mineral addition for mortars. J Build Eng. 2021;34: 101863.
77. Liu JK, Huang ZJ, Wang XT. Economic and environmental assessment of carbon emissions from demolition waste based on LCA and LCC. Sustainability. 2020;12(16):6683.
78. Zhang ZY, Wang B. Research on the life-cycle CO2 emission of China’s construction sector. Energ Buildings. 2016;112:244-55.
79. Shan YL, Liu Z, Guan DB. CO2 emissions from China’s lime industry. Appl Energ. 2016;166:245-52.
80. Wang JY, Wu HY, Duan HB, Zillante G, Zuo J, Yuan HP. Combining life cycle assessment and Building Information Modelling to account for carbon emission of building demolition waste: a case study. J Clean Prod. 2018;172:3154-66.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-b2ce4d45-eb07-4d1c-9681-e5f7a9cad63c