粒径和渗流速度对多孔介质中悬浮颗粒迁移和沉积特性的耦合影响

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (259 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要关于粒径和渗流速度的研究对更好地描述悬浮颗粒的迁移和沉积过程有着重要的意义。在不同的粒径和渗流速度条件下进行悬浮颗粒的室内土柱试验，对比分析不同条件下穿透曲线的变化规律。试验很好地克服了悬浮颗粒形状和化学因素等对试验结果的影响。试验结果表明，对于粒径相同的悬浮颗粒来说，流出液中悬浮颗粒的浓度峰值随渗流速度增大而增大，相应的沉积颗粒却随之减小；并且，渗流速度存在一个临界值(0.173 cm/s)，大于该临界值，渗流速度的变化对悬浮颗粒的迁移特性的影响很小。其次，渗流速度相同时，流出液中悬浮颗粒的浓度峰值随粒径增大而减小，相应的沉积颗粒却随之增大；渗流速度越小，粒径对筛滤作用的影响越明显。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章

关键词 ：土力学, 悬浮颗粒, 多孔介质, 筛滤, 水动力, 颗粒粒径

Abstract：Particle size and flow rate play an important role in particle transportation and deposition in porous media. Different suspended particles were studied under different flow rates in soil columns tests，and the corresponding breakthrough curves were analyzed. The effects of particle shape and chemical factors on test results were excluded from the tests. Test results show that the peak concentration of effluent increases and the quantity of deposition particle decreases with the increasing flow rate for the same particle size. However，the deposition particle decreases with the increasing flow rate. There exists a critical flow rate of 0.173 cm/s，and the effect of flow rate on particle transportation can be negligible when the flow rate is larger than the critical value. On the other hand，the peak concentration of effluent decreases and deposition increases with the increasing particle size for the same flow rate. Furthermore，the effect of particle size on particle straining is obvious at low flow rate.

Key words： soil mechanics suspended particle porous media straining hydrodynamic force particle size

收稿日期: 2011-12-27

引用本文:

陈星欣，白冰，于涛，郭兰杰. 粒径和渗流速度对多孔介质中悬浮颗粒迁移和沉积特性的耦合影响[J]. 岩石力学与工程学报, 2013, 32(s1): 2840-2845.
CHEN Xingxin，BAI Bing，YU Tao，GUO Lanjie. COUPLED EFFECTS OF PARTICLE SIZE AND FLOW RATE ON CHARACTERISTICS OF PARTICLE TRANSPORTATION AND DEPOSITION IN POROUS MEDIA. , 2013, 32(s1): 2840-2845.

链接本文:

http://www.rockmech.org/CN/Y2013/V32/Is1/2840

[1]	SAIERS J E，HORNBERGER G M. The role of colloidal kaolinite in the transport of cesium through laboratory sand columns[J]. Water Resources Research，1996，32(1)：33-41. " target="_blank">
[2]	GROLIMUND D，ELIMELECH M，BORKOVEC M，et al. Transport of in situ mobilized colloidal particles in packed soil columns[J]. Environmental Science and Technology，1998，32(22)：3 562-3 569. " target="_blank">
[3]	UTSUNOMIYA S，KERSTING A B，EWING R C. Groundwater nanoparticles in the far-field at the Nevada test site：mechanism for radionuclide transport[J]. Environmental Science and Technology，2009，43(5)：1 293-1 298. " target="_blank">
[5]	NATARAJAN N，KUMAR G S. Spatial moment analysis of colloid facilitated radionuclide transport in a coupled fracture-matrix system[J]. International Journal of Energy and Environment，2011，2(3)：491-504. " target="_blank">
[7]	AHFIR N D，WANG H Q，BENAMAR A，et al. Transport and deposition of suspended particles in saturated porous media：hydrodynamic effect[J]. Hydrogeology Journal，2007，15(4)：659-668.
[10]	AHFIR N D，BENAMAR A，ALEM A，et al. Influence of internal structure and medium length on transport and deposition of suspended particles：a laboratory study[J]. Transport in Porous Media，2009，76(2)：289-307.
[12]	KELLER A A，AUSET M. A review of visualization techniques of biocolloid transport processes at the pore scale under saturated and unsaturated conditions[J]. Advances in Water Resources，2007，30(6/7)：1 392-1 407. " target="_blank">
[13]	BRADFORD S A，YATES S R，BETTAHAR M，et al. Physical factors affecting the transport and fate of colloids in saturated porous media[J]. Water Resources Research，2002，38(12)：1 327-1 338. " target="_blank">
[14]	XU S P，GAO B，SAIERS J E. Straining of colloidal particles in saturated porous media[J]. Water Resources Research，2006，42：W12S16. doi：1029/2006WR004948. " target="_blank">
[16]	BRADFORD S A，TORKZABAN S，WALKER S L. Coupling of physical and chemical mechanisms of colloid straining in saturated porous media[J]. Water Research，2007，41(13)：3 012-3 024. " target="_blank">
[17]	TORKZABAN S，BRADFORD S A，WALKER S L. Colloid transport in unsaturated porous media：The role of water content and ionic strength on particle straining[J]. Journal of Contaminant Hydrology，96(1/2/3/4)：113-127. " target="_blank">
[19]	薛元忠，何青，王元叶. OBS浊度计测量泥沙浓度的方法与实践研究[J]. 泥沙研究，2004，(4)：56-60.(XUE Yuanzhong，HE Qing，WANG Yuanye. The method and application OBS in the measurement of sediment concentration[J]. Journal of Sediment Research，2004，(4)：56-60.(in Chinese)) " target="_blank">
[20]	JASTRAM J D，ZIPPER C E，ZELAZNY L W，et al. Increasing precision of turbidity-based suspended sediment concentration and load estimates[J]. Journal of Environmental Quality，2010，39(4)：1 306-1 316. " target="_blank">
[8]	OCHIAI N，DRAGILA M I，PARKER J L. Three-Dimensional tracking of colloids at the pore scale using epifluorescence microscopy[J]. Vadose Zone Journal，2010，9(3)：576-587. " target="_blank">
[18]	PFANNKUCHE J，SCHMIDT A. Determination of suspended particulate matter concentration from turbidity measurements：particle size effects and calibration procedures[J]. Hydrological Processes，2003，17(10)：1 951-1 963. " target="_blank">
[21]	MURILLO J M. Turbidity and suspended solids in the runoff susceptible of use for the artificial recharge of the deep granular aquifer subjacent to the town of San Luis de Potosí(Mexico)[J]. Boletín Geológicoy Minero，2009，120(2)：169-184. " target="_blank">
[6]	MASSEI N，LACROIX M，WANG H Q，et al. Transport of particulate material and dissolved tracer in a highly permeable porous medium：comparison of the transfer parameters[J]. Journal of Contaminant Hydrology，2002，57(1/2)：21-39. " target="_blank">
[11]	LI X Q，LIN C L，MILLER J D，et al. Role of grain-to grain contacts on profiles of retained colloids in porous media in the presence of an energy barrier to deposition[J]. Environmental Science and Technology，2006，40(12)：3 769-3 774. " target="_blank">
[4]	MÖRI A，ALEXANDER W R，GECKEIS H，et al. The colloid and radionuclide retardation experiment at the Grimsel test site：influence of bentonite colloids on radionuclide migration in a fractured rock[J]. Colloids and Surfaces A：Physicochemical and Engineering Aspects，2003，217(1/2/3)：33-47. " target="_blank">
[9]	FREY J M，SCHMITZ P，DUFRECHE J，et al. Particle deposition in porous media：analysis of hydrodynamic and weak inertial effect[J]. Transport in porous media，1999，37(1)：25-54. " target="_blank">
[15]	PORUBCAN A A，XU S P. Colloid straining within saturated heterogeneous porous media[J]. Water Resources Research，2011，45(4)：1 796-1 806. " target="_blank">