|
|
改良红黏土持水性及植物性试验研究
|
Abstract:
本文采用保水剂对红黏土进行改良,通过掺入不同含量的保水剂材料,对改良红黏土的持水特性、蒸发特性、植物适用性展开研究。试验结果表明:在持水蒸发特性方面,当按0.5%、1%、3%、5%的质量分数掺入改良材料时,红黏土最大持水量显著提升,保水剂对持水性改善效果明显;同时随保水剂含量增加红黏土保水能力提高,但改良材料超3%后,其比表面积特征会使土体与空气接触面增大,导致抗蒸发能力降低,抵抗蒸发的最佳改良材料配比为3%。在植物适应性研究中,随保水剂掺量增加植物发芽率逐步上涨,且保水剂掺量较高组植物株长势良好,未改良红黏土组及低掺量组存在倒苗现象,添加保水剂对植物生长的积极作用主要源于其良好的持水保水特性。
In this paper, red clay was improved with water retaining agent. By adding different contents of water retaining agent, the water retaining property, evaporation property and plant applicability of the improved red clay were studied. The test results show that the maximum water holding capacity of red clay is significantly increased when the modified material is added with the mass fraction of 0.5%, 1%, 3% and 5%, and the water holding capacity is obviously improved by the water retaining agent. At the same time, with the increase of water retaining agent content, the water retaining ability of red clay is improved, but when the modified material exceeds 3%, its specific surface area characteristics will increase the contact surface between soil and air, resulting in a decrease in evaporation resistance. The optimal ratio of modified material to resist evaporation is 3%. In the study of plant adaptability, the germination rate of plants increased gradually with the increase of water retaining agent content, and the plant growth was good in the higher water retaining agent content group, while the seedling was reversed in the unimproved red clay group and the low water retaining agent group. The positive effect of adding water retaining agent on plant growth was mainly due to its good water retaining characteristics.
| [1] | Venkatesh, C., Chand, M. and Nerella, R. (2019) A State of the Art on Red Mud as a Substitutional Cementitious Material. Annales de Chimie-Science des Matériaux, 43, 99-103. https://doi.org/10.18280/acsm.430206 |
| [2] | Zhu, F., Chen, L., Yao, Y., Zhao, Q. and Li, J. (2020) Experimental Study on Direct Shear Mechanical Characteristics of Warm Frozen Silty Clay. Annales de Chimie—Science des Matériaux, 44, 53-58. https://doi.org/10.18280/acsm.440107 |
| [3] | Ghobadi, M.H., Abdilor, Y. and Babazadeh, R. (2013) Stabilization of Clay Soils Using Lime and Effect of Ph Variations on Shear Strength Parameters. Bulletin of Engineering Geology and the Environment, 73, 611-619. https://doi.org/10.1007/s10064-013-0563-7 |
| [4] | 中国人民共和国交通运输部. 2020年交通运输行业发展统计公报[R]. 2021. |
| [5] | 赵亚文. 不同含水率下红黏土抗剪强度特性的方法探讨[J]. 南方农机, 2018, 49(5): 174-179. |
| [6] | Yang, L., Yang, Y., Chen, Z., Guo, C. and Li, S. (2014) Influence of Super Absorbent Polymer on Soil Water Retention, Seed Germination and Plant Survivals for Rocky Slopes Eco-Engineering. Ecological Engineering, 62, 27-32. https://doi.org/10.1016/j.ecoleng.2013.10.019 |
| [7] | 胡甫嵩, 王琮棋, 夏德强, 等. 保水剂的发展现状及应用研究[J]. 云南化工, 2024, 51(9): 20-23. |
| [8] | 张阁艳, 哈斯毕力格, 于海龙. 荒漠草原天然草地施加保水剂对植被生长的影响研究[J]. 农村牧区机械化, 2015(1): 42-43. |
| [9] | 袁惠燕, 梅晓东, 胡磊, 等. 干旱胁迫下保水剂对高羊茅种子萌发及幼苗生长的影响[J]. 北方园艺, 2014(1): 72-74. |
| [10] | 安彦勇, 张洪江, 辛志杰. HEC土体固结剂在闵行铁路货场工程中的应用[J]. 施工技术, 2009, 38(9): 103-104. |
| [11] | 王小彬, 蔡典雄, 张锐. 几种高分子材料固土性能比较与评价研究[J]. 中国农业科学, 2005, 38(8): 1608-1615. |
| [12] | 佟长福, 侯洪飞, 李瑞平, 等. 保水剂和蒸腾抑制剂对玉米生长和水肥耦合的影响[J]. 节水灌溉, 2024(6): 63-68, 76. |
