基于栅条式微涡絮凝的隧道废水处理技术数值模拟

兰州理工大学学报 ›› 2024, Vol. 50 ›› Issue (1): 68-75.

基于栅条式微涡絮凝的隧道废水处理技术数值模拟

张东海^*

中铁第一勘察设计院集团有限公司, 陕西西安 710043

收稿日期:2022-08-22 出版日期:2024-02-28 发布日期:2024-03-04
通讯作者: 张东海(1983-),男,甘肃榆中人,高级工程师. Email:275592838@qq.com

Numerical simulation study of tunnel wastewater treatment technology based on grating-type micro-vortex flocculation

ZHANG Dong-hai

China Railway First Survey and Design Institute Group Co. Ltd., Xi'an 710043, China

Received:2022-08-22 Online:2024-02-28 Published:2024-03-04

摘要/Abstract

摘要： 为探究微涡混凝技术在隧道废水处理工艺上的可行性,通过数值模拟手段对不同特征的栅条式微涡发生器所产生的混凝流场特性进行了研究,并采用最优组合形式对浊度为1 300 NTU模拟隧道废水进行了水力絮凝验证实验.结果表明:栅条的粗细主要影响流场内流体湍动能及湍耗散的在初始混凝阶段的消耗程度,边长为5 mm的方形栅条更容易维持整个流场内混凝过程中所需的动能;栅条布置间距会改变栅条对流体的阻滞作用,布置间距为11 mm时,流体能在反应中后段提供更高的湍动能及湍耗散用于絮凝反应;栅条的长度主要影响流场在轴向方向的能量演变情况,400、600、800 mm的栅条会延长流体在流场内的能量分配距离,使反应器中后段的絮体也能够有足够用于聚集的能量.采用最优组合形式的栅条对浊度为1 300 NTU模拟隧道废水进行了水力絮凝验证实验,废水最终出水浊度可稳定在50 NTU以下.

关键词: 涡旋絮凝技术, 数值计算, 栅条式微涡发生器, 湍动能, 湍耗散

Abstract: To explore the feasibility of micro-vortex coagulation technology in tunnel wastewater treatment process, a numerical simulation is conducted to investigate the the characteristics of the coagulation flow field produced by the grid micro vortex generator with different characteristics.Furthermore, a hydraulic flocculation validation experiment is conducted using the optimal combination of grating-types for simulated tunnel wastewater with turbidity of 1 300 NUT. The results show that the thickness of the grid bars primarily affects the turbulent kinetic energy of the fluid in the flow field and the consumption degree of turbulent dissipation in the initial coagulation stage. The square grid bars with a side length of 5 mm are better suited to maintain the kinetic energy required in the whole coagulation process in the flow field. The spacing of the grid bars alter their blocking effect of the grid bars on the fluid. When the spacing is 11 mm, the fluid can provide higher turbulent kinetic energy and turbulent dissipation for flocculation reaction. The length of grid bars mainly affects the energy evolution of the flow field in the axial direction. The grid bars of 400 mm, 600 mm and 800 mm extend the energy distribution distance of the fluid in the flow field, providing sufficient energy for aggregation of the flocs in the rear section of the reactor. The hydraulic flocculation verification experiment of simulated tunnel wastewater with turbidity of 1 300 NTU was carried out using the optimal combination of grid bars, resulting in a stable effluent turbidity of the wastewater of less than 50 NTU.

Key words: vortex flocculation technology, numerical calculations, gridded micro-vortex generators, turbulent kinetic energy, turbulent energy dissipation rate

中图分类号:

X703

张东海. 基于栅条式微涡絮凝的隧道废水处理技术数值模拟[J]. 兰州理工大学学报, 2024, 50(1): 68-75.

ZHANG Dong-hai. Numerical simulation study of tunnel wastewater treatment technology based on grating-type micro-vortex flocculation[J]. Journal of Lanzhou University of Technology, 2024, 50(1): 68-75.

参考文献

[1] 周文哲.隧道施工废水处理研究 [J].铁道建筑,2019,59(9):77-80.
[2] 祝捷.引汉济渭工程输水隧洞施工废水处理工艺研究 [J].铁道工程学报,2014,31(6):109-113.
[3] 薛正.铁路隧道施工废水处理存在的问题 [J].铁道建筑,2021,61(4):57-61.
[4] 吴楠,王三反,黑见星,等.高海拔低温地区强化混凝沉淀过滤处理隧道施工废水 [J].中国给水排水,2017,33(22):85-88.
[5] 中华人民共和国国家质量监督检验检疫总局,中国国家标准化管理委员会.污水综合排放标准:GB 8978—1996 [S].北京:中国环境科学出版社,1996.
[6] 中华人民共和国国家质量监督检验检疫总局,中国国家标准化管理委员会.地表水质量标准:GB 3838—2002 [S].北京: 中国环境科学出版社,2002.
[7] 常青.水处理絮凝学 [M].北京:化学工业出版社,2011.
[8] 常青.絮凝动力学的现状与研究方法进展 [J].环境科学学报,2015,35(10):3042-3049.
[9] 王绍文.惯性效应在絮凝中的动力学作用 [J].中国给水排水,1998,14(2):13-15.
[10] 童祯恭,胡锋平.一体化涡旋网格澄清工艺的研制与应用 [J].中国给水排水,2010(6):63-68.
[11] DAI H L,QIU Z M,HU F P,et al.Floc Performance parameters during water treatment in a micro-vortex flocculation process determined by machine vision [J].Environmental Technology,2019,40(23):3062-3071.
[12] WANG X,CUI B,WEI D,et al.CFD-PBM modelling of tailings flocculation in a lab-scale gravity thickener [J].Powder Technology,2022,396:139-151.
[13] 何亚其,白健华,孙超,等.新型微涡流混凝器絮凝效果评价及数值模拟分析 [J].工业水处理,2021,41(6):206-210.
[14] LIANO C E,CORAL J A,FONTALVO J,et al.CFD assisted analysis and design of hydraulic flocculators [J].Revista Mexicana de Ingenieria Quimica,2019,18(3):995-1015.
[15] ZHAN M,YOU M,LIU L,et al.Numerical simulation of mechanical flocculation in water treatment [J].Journal Of Environmental Chemical Engineering,2021,9(4):105536.
[16] 柴宝红,方布雷,王岩,等.隧道废水小粒径悬浮物微絮凝法快速处理技术 [J].隧道与地下工程灾害防治,2021,3(4):61-67.
[17] 史志皓,朱海涛,欧阳卓明,等.武汉市汉江原水悬浮物浓度与浊度对应关系的研究 [J].中国给水排水,2022,38(21):51-56.