Analysis of Mechanical Properties and Microscopic Discrete Element Study of Foam Concrete under Dry-Wet Cycles

Authors

• XU Ke, Central South Construction Group Co., Ltd., Changsha, Hunan 410007, China; School of Civil Engineering, Hunan University of Science and Technology, Xiangtan, Hunan 411201, ChinaFollow
• ZHANG Jun, Central South Construction Group Co., Ltd., Changsha, Hunan 410007, China
• KUANG Yuyang, Hangzhou Nengzhixin Intelligent Software Co., Ltd., Hangzhou, Zhejiang 311256, ChinaFollow

Corresponding Author

匡渝阳, 男, 助理工程师. E-mail: 1024558983@qq.com

Abstract

To reveal the effects of the number of dry-wet cycles and the material density gradient on the deterioration laws of macroscopic mechanical properties, microscopic damage mechanisms, and failure modes of foam concrete, foam concrete test blocks with densities of 800 kg/m3, 1 000 kg/m3, and 1 200 kg/m3 were investigated in this paper. Macro-micro joint tests and three-dimensional discrete element simulation methods were combined. Specifically, 25 dry-wet cycle tests, nuclear magnetic resonance pore analyses, and uniaxial compression tests were conducted, and a discrete element model considering particle expansion and contraction, as well as crystalline salt deterioration effects was constructed. The results indicate that the interface is deteriorated by dry-wet cycles through periodic particle expansion and contraction and crystalline salt precipitation, and the pore connectivity rate is significantly increased;after 25 cycles, the strength loss rates of the FC- 800, FC- 1 000, and FC- 1 200 test blocks are 23. 37%, 17. 59%, and 13. 97%, respectively. The damage mode is regulated by the density gradient;diffused cracks are induced by the low-density zone to weaken the overall bearing capacity, while localized concentrated expansion of cracks is promoted by the high-density zone. The material instability is caused by force chain fractures and displacement field mutations. Based on the differences in damage modes caused by the density effect, a subgrade layered optimization strategy is proposed in this paper:High-density materials are adopted in the surface layer to resist deterioration, and low-density materials are selected in the deep layer to reduce load. A microscopic theoretical basis and operable engineering recommendations are provided by this paper for the long-term service performance of road and bridge transition sections under the dry-wet cycle environment.

Publication Date

4-24-2026

DOI

10.14048/j.issn.1671-2579.2026.02.012

First Page

106

Last Page

116

Submission Date

April 2026

Recommended Citation

Ke, XU; Jun, ZHANG; and Yuyang, KUANG (2026) "Analysis of Mechanical Properties and Microscopic Discrete Element Study of Foam Concrete under Dry-Wet Cycles," Journal of China & Foreign Highway: Vol. 46: Iss. 2, Article 12.
DOI: 10.14048/j.issn.1671-2579.2026.02.012
Available at: https://zwgl1980.csust.edu.cn/journal/vol46/iss2/12

Reference

[1] LIU Y J, ZHAO Z L, AMIN M N, et al. Foam concrete for lightweight construction applications: A comprehensive review of the research development and material characteristics [J]. Reviews on Advanced Materials Science, 2024, 63: 20240022.
[2] 刘本立, 张朋, 单景松, 等. 纳米硅 +聚丙烯纤维复合改性透水混凝土性能研究 [J]. 中外公路, 2024, 44(4): 97-103. LIU Benli, ZHANG Peng, SHAN Jingsong, et al. Performance of composite modified permeable concrete with nano-silicon and polypropylene fiber [J]. Journal of China & Foreign Highway, 2024, 44(4): 97-103.
[3] AHıSKALı A, AHıSKALı M, BAYRAKTAR O Y, et al. Mechanical and durability properties of polymer fiber reinforced one-part foam geopolymer concrete: A sustainable strategy for the recycling of waste steel slag aggregate and fly ash [J]. Construction and Building Materials, 2024, 440: 137492.
[4] 宋承哲, 李家全, 孔靖勋, 等. 含混凝土再生骨料水泥稳定基层性能综述 [J]. 中外公路, 2025, 45(1): 88-99. SONG Chengzhe, LI Jiaquan, KONG Jingxun, et al. A review of performance of cement-stabilized base materials containing recycled concrete aggregate [J]. Journal of China & Foreign Highway, 2025, 45(1): 88-99.
[5] 李辉, 陈锋, 匡渝阳, 等. 外掺剂对泡沫混凝土影响及冻融‒循环破坏研究 [J]. 混凝土, 2023 (5): 115-120, 123. LI Hui, CHEN Feng, KUANG Yuyang, et al. Study on the effect of admixture on foam concrete and its freeze-thaw-cycle failure [J]. Concrete, 2023 (5): 115-120, 123.
[6] MUGAHED AMRAN Y H, FARZADNIA N, ABANG ALI A A. Properties and applications of foamed concrete: A review [J]. Construction and Building Materials, 2015, 101: 990-1005.
[7] 马凯凯, 赵峰, 孙荣晓, 等. 矿物掺合料对喷射混凝土性能的影响 [J]. 中外公路, 2025, 45(3): 83-88. MA Kaikai, ZHAO Feng, SUN Rongxiao, et al. Effect of mineral admixtures on properties of shotcrete [J]. Journal of China & Foreign Highway, 2025, 45(3): 83-88.
[8] HUANG Z C, SU Q, HUANG J J, et al. Field assessment of a subgrade-culvert transition zone constructed with foamed concrete in the ballasted railway [J]. International Journal of Rail Transportation, 2024, 12(3): 391-413.
[9] DU X L, ZHU L P, LI Y Y, et al. Research on the damage evolution law of iron tailing sand based foam concrete under cyclic loading [J]. Case Studies in Construction Materials, 2024, 21: e04117.
[10] CHATTERJEE A, POKHAREL S, BREAULT M. Rehabilitation of rail track facing cross-level issues using polymeric geocell [J]. E3S Web of Conferences, 2024, 569: 05001.
[11] 沈水龙, 石名磊, 杜守继, 等. 软土地基上道路桥头跳车缓解工法的设计与工程实践 [J]. 岩石力学与工程学报, 2005, 24(7): 1173-1177. SHEN Shuilong, SHI Minglei, DU Shouji, et al. Mitigaton of differential settlement between earth structure and road on soft clays [J]. Chinese Journal of Rock Mechanics and Engineering, 2005, 24(7): 1173-1177.
[12] 刘建敏. 横向加筋注浆技术防治高速公路桥头跳车技术研究 [J]. 石家庄铁道大学学报 (自然科学版), 2015, 28(4): 39-47. LIU Jianmin. Research on transverse reinforcement grouting technique for preventing highway bump at the ends of bridges [J]. Journal of Shijiazhuang Tiedao University (Natural Science Edition), 2015, 28(4): 39-47.
[13] 廖师贤, 黄蕾. 基于浆体取代法再生砖粉泡沫混凝土试验研究 [J]. 中外公路, 2023, 43(4): 256-260. LIAO Shixian, HUANG Lei. Experimental study on recycled brick powder foam concrete based on slurry substitution method [J]. Journal of China & Foreign Highway, 2023, 43(4): 256-260.
[14] 蔡军, 匡渝阳. 路用泡沫混凝土微观孔隙结构特性影响研究 [J]. 中外公路, 2021, 41(5): 222-226. CAI Jun, KUANG Yuyang. Study on microscopic pore structure characteristics of pavement cellular concrete [J]. Journal of China & Foreign Highway, 2021, 41(5): 222-226.
[15] 郭炎军. 泡沫混凝土在路桥过渡段中的应用 [J]. 工程技术研究, 2019, 4(4): 119-120. GUO Yanjun. Application of foamed concrete in road-bridge transition se ction [J]. Engineering and Technological Research, 2019, 4(4): 119-120.
[16] BAGHERI A, SAMEA S A. Role of non-reactive powder in strength enhancement of foamed concrete [J]. Construction and Building Materials, 2019, 203: 134-145.
[17] JIN Z Q, LI M Y, PANG B, et al. Internal superhydrophobic marine concrete: Interface modification based on slag microstructure regulation [J]. Journal of Building Engineering, 2024, 86: 108769.
[18] 杜素云, 刘启顺, 操龙玉, 等. 泡沫混凝土在绍兴软基地段路基工程中的应用 [J]. 混凝土, 2013 (4): 147-149. DU Suyun, LIU Qishun, CAO Longyu, et al. Application of bubble concrete in Shaoxing soft subgrade engineering[J]. Concrete, 2013 (4): 147-149.
[19] HAN B, LIU N, TANG X L, et al. Cracking behaviour and mechanical properties of rock-filled concrete: Influence of contact interfaces on the rock skeleton [J]. Construction and Building Materials, 2025, 472: 140943.
[20] ZHANG S, LIU M P, WANG C, et al. Compression, unloading-reloading, and tension mechanical behaviors of silt-based foamed concrete under uniaxial loading [J]. Construction and Building Materials, 2022, 347: 128558.
[21] 中国建筑材料科学研究总院. 通用硅酸盐水泥: GB 175—2007 [S]. 北京: 中国标准出版社, 2008. China Building Materials Academy. Common portland cement: GB 175—2007 [S]. Beijing: China Standards Press, 2008.
[22] 中国建筑科学研究院. 泡沫混凝土: JG/T 266—2011 [S]. 北京: 中国标准出版社, 2011. China Academy of Building Research. Foamed concrete: JG/T 266—2011 [S]. Beijing: China Standards Press, 2011.
[23] 中国加气混凝土协会. 蒸压加气混凝土性能试验方法: GB/T 11969—2020 [S]. 北京: 中国标准出版社, 2020. China Autoclaved Aerated Concrete Association. Test methods for autoclav ed aerated concrete: GB/T 11969—2020 [S]. Beijing: China Standards Press, 2020.
[24] 谢洪阳, 戴宜文, 任宇航, 等. 多因素及干湿循环对泡沫混 凝 土 性 能 的 影 响 [J]. 中 国 粉 体 技 术, 2023, 29(5): 125-134. XIE Hongyang, DAI Yiwen, REN Yuhang, et al. Effects of multiple factors and wetting and drying cycles on properties of brick powder foamed concrete [J]. China Powder Science and Technology, 2023, 29(5): 125-134.
[25] WANG Z C, LIU S Y, WU K, et al. Durability against dry-wet and freeze-thaw cycles of alkali residue-based foamed concrete [J]. Materials and Structures, 2024, 57(3): 51.
[26] TAHMASEBI P. A state-of-the-art review of experimental and computational studies of granular materials: Properties, advances, challenges, and future directions [J]. Progress in Materials Science, 2023, 138: 101157.
[27] 莫品强, 赵子露, 胡裕琛, 等. 颗粒堆积体各向异性及宏细观力学特性的三维离散元模拟研究 [J]. 太原理工大学学报, 2022, 53(1): 129-139. MO Pinqiang, ZHAO Zilu, HU Yuchen, et al. Anisotropy and mechanical behaviour of sand pile using 3D DEM simulation [J]. Journal of Taiyuan University of Technology, 2022, 53(1): 129-139.
[28] HU Y Y, LU Y. A novel framework for calibrating DEM parameters: A case study of sand and soil-rock mixture [J]. Computers and Geotechnics, 2024, 174: 106619.
[29] ZHU X Y, LEI P. A novel prediction model for failure mechanism of foamed concrete [J]. Construction and Building Materials, 2023, 370: 130625.
[30] CHEN J L, CHEN B, QIANG S, et al. Study on strength deterioration mechanism of foamed concrete under freeze-thaw cycles: Experiment and numerical simulation [J]. Construction and Building Materials, 2024, 438: 137083.
[31] GAO Y, CHENG Y, CHEN J Z. Experimental study and 3-D meso-scale discrete element modeling on the compressive behavior of foamed concrete [J]. Buildings, 2023, 13(3): 674.