Effects of hydrodynamic turbulent conditions on aggregate fractal structures

LI Dong-mei; JIN Tong-gui; WANG He-ping; MEI Sheng; TAN Wan-chun

Based on adding the cation high molecular weight polymer into the turbid suspended liquor containing 85 kg/m³ of sediments,this paper discusses the changing hydrodynamic turbulent conditions in the process of flocculation,such as shearing rate r (or velocity gradient G) and shearing time t,and the use of the settlement and the image analysis technology,the factor "fractal dimension D" which can characterize the fractal properties in quantity and the evolution regularities of the fractal structures of the bridging-flocculated aggregates.The results show that there are two critical values about hydrodynamic turbulent strength Gt (G₁t₁= 2350±100 at rapid flocculation stage and G₂t₂= 12400±100 at slow flocculation stage) when fractal structures reach the optimum state.It is found in experiment that the optimum Gt value is nearly the same when the compactness of the fractal structures of the bridging flocculated aggregates reaches the highest point of the different raw silt content.When raw silt content is low,r or G value should be reduced and t value increased However,the value of the fractal dimen sion D decreases Furthermore,when the fractal structures of flocs formed by the addition inorganic coagulant and the bridging-flocculation aggregates formed by the additional high molecular flocculant reach the optimum state with the same raw silt content,the former needs the higher Gt value,corresponding to the lower G value and the longer t value and the average mass fractal dimension D₃ value of floc is higher,but the fractal structure of floc appears frangible.

Effects of hydrodynamic turbulent conditions on aggregate fractal structures

1. School of Construction, Guangdong University of Technology, Guangzhou 510500, China;

2. School of Environmental & Municipal Engineering, Xi'an University of Architecture & Technology, Xi'an 710055, China;

3. School of Chemical and Environmental Engineering, Changsha University of Science & Technology, Changsha 410076, China

Funds: The study is financially supported by the National Natural Science Foundation of China (No.50078043).

Received Date: 2005-02-17

Rev Recd Date: 2005-05-10

Publish Date: 2006-05-25

Key words:

Abstract: Based on adding the cation high molecular weight polymer into the turbid suspended liquor containing 85 kg/m³ of sediments,this paper discusses the changing hydrodynamic turbulent conditions in the process of flocculation,such as shearing rate r (or velocity gradient G) and shearing time t,and the use of the settlement and the image analysis technology,the factor "fractal dimension D" which can characterize the fractal properties in quantity and the evolution regularities of the fractal structures of the bridging-flocculated aggregates.The results show that there are two critical values about hydrodynamic turbulent strength Gt (G₁t₁= 2350±100 at rapid flocculation stage and G₂t₂= 12400±100 at slow flocculation stage) when fractal structures reach the optimum state.It is found in experiment that the optimum Gt value is nearly the same when the compactness of the fractal structures of the bridging flocculated aggregates reaches the highest point of the different raw silt content.When raw silt content is low,r or G value should be reduced and t value increased However,the value of the fractal dimen sion D decreases Furthermore,when the fractal structures of flocs formed by the addition inorganic coagulant and the bridging-flocculation aggregates formed by the additional high molecular flocculant reach the optimum state with the same raw silt content,the former needs the higher Gt value,corresponding to the lower G value and the longer t value and the average mass fractal dimension D₃ value of floc is higher,but the fractal structure of floc appears frangible.

HTML

Reference (10)

[1]	E.I.巴宾科夫著.郭连起译.论水的混凝[M].北京:中国建筑工业出版社,1982.125-148.
[2]	李冬梅,金同轨,梅胜,等.含沙高浊水架桥絮体的质量分形[J].中国给水排水,2004,20(11):52-54.
[3]	李冬梅,梅胜,金同轨,等.黄河泥沙架桥絮体分形结构的动态演变研究[J].给水排水,2004,30(11):1-5.
[4]	Tang S,Preece J M,McFarlane C M,et al.Fractal Morphology and Breakage of DLCA and RLCA Aggregates[J].Joural of Colloid and Interface Science,2000,221:114-123.
[5]	John Gregory.The Density of Particle Aggregates[J].Wat Sci Technolo,1997,36(4):1-13.
[6]	Gmachowski L.mechanism of shear aggregation[J].Wat Res,1995,29(8):1 815-1 820.
[7]	许保玖.给水处理理论[M].北京:中国建筑工业出版社,2000.201-203.
[8]	Serge Stoll,Jacques Buffle.Computer Computer Simulation of Flocculation Progresses:The Roles of Chain Conformation and Chain/Colloid Concentration Ratio in the Aggregate Structures[J].Journal of Colloid and Interface Science,1998,205,290-304.
[9]	Elimelich M,Gregory J,Jia X,et al.Particle Deposition and Aggregation:Measurement,Modelling and Simulation[M].Butterworth-Heinemann,Oxford,1995.
[10]	La Mer,V K.Rheological Phenomena of Clay Sols in Connection with the Charge Distribution on the Micelles[J].Discuss.Faraday Soc,1966,(42):248-257.

Effects of hydrodynamic turbulent conditions on aggregate fractal structures

Abstract

References

Proportional views

通讯作者: 陈斌, bchen63@163.com

Article Metrics

Proportional views

Related