Separation of fine particle dispersions using periodic flows in a spining coiled tube

Papanu, J. S.; Adler, Robert J.; Gorensek, Maximilian B.; Menon, Murali M.

doi:10.1002/aic.690320510

Cited by 11 publications

(3 citation statements)

References 22 publications

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“…Flows in rotating curved channels arise in a variety of practical processes. Examples are flows in centrifuges (Hochrainer 1971 ]), cooling channels of rotating machinery (Ito and Motai [1974], Miyazaki [1971Miyazaki [ , 1973 and Morris [1981]), particle separation devices (Lennartz et al [1987], Papanu et al [1986], Hoover et al [1984, St6ber and Flachsbart [1969] and Kotrappa and Light [1972]) and rotating heat exchangers (Qiu et al [1990]). Studies on the hydrodynamics in the rotating curved channels are, therefore, not only of considerable theoretical interest, but also of practical importance.…”

Section: Introductionmentioning

confidence: 99%

Visualization of Flows in Curved Channels with aModerate or High Rotation Speed

Wang

Cheng

1996

International Journal of Rotating Machinery

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Flows in channels with streamwise curvature and spanwise rotation are visualized in terms of end-view near the exit of the test sections through injecting smoke into the flows. Two test sections are used, i.e. the rectangular channels with the aspect ratio of and 10, respectively. The work focuses on visualization of Dean and Coriolis vortices under the effects of secondary instabilities and flows in the region with a relatively high rotation speed. The results show that the secondary instabilities cause the Dean and Coriolis vortices oscillating in various forms and the flows at high rotation speeds are controlled by the secondary instabilities rather than the primary instability. In particular, the secondary instabilities lead the flows to be unsteady and turbulent somewhat like the bursting flow in the turbulent boundary layers.

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Section: Introductionmentioning

confidence: 99%

Visualization of Flows in Curved Channels with aModerate or High Rotation Speed

Wang

Cheng

1996

International Journal of Rotating Machinery

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“…particles, such as with a hydraulic cyclone, spinning coils (Papanu et al, 1986), and coil planet centrifuge (Ito et al, 1966), but they do not give fractions with narrow size distributions.…”

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Separation of fine particles by laminar flow in a tilted slender tube slowly rotating around the longitudinal axis

Kimura¹,

Shirane²,

Yamaguchi³

et al. 1990

Ind. Eng. Chem. Res.

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Fractionation of fine particle slurries using periodic flows in a spinning helix

1989

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An unusual method of separating or fractionating fine-particle slurries has been proposed and partially explored by Landin (1980), Papanu (1983Papanu ( , 1986, Menon (1983), Lennartz (1984), and Lennartz et al (1987). A helically coiled tube spinning steadily on its major axis is connected to two agitated reservoir pumps which cycle a slurry bidirectionally through the helix as shown in Figure 1. With appropriate pumping steps, slurries can be concentrated or fractionated. The operation can be made continuous by adding feed at F and withdrawing products at I and 11.Research is motivated by the prospect of achieving sharp separations with fine particles smaller than about 10 pm. The technique is inherently multistage; the number of theoretical stages is approximately equal to the helix tube volume divided by the fluid volume pumped per cycle. The number of theoretical stages increases with reduced pumping volume.In this work, the method is further explored for fractionation.Early investigators found that separation was hindered by material accumulation in the helix, caused by ineffective particle resuspension, an essential step of each cycle. A new equipment design provides more effective particle resuspension by reorienting sedimented particles in the centrifugal field. A mathematical model is developed to describe and simulate the process. Data from a batch fractionation experiment using a sand/kaoh-clay slurry is reported. Fractionation-Six-Step SequenceA slurry containing two types of particles, A and B, with different settling rates, is fractionated by convecting particle-free fluid, slurry containing B, and slurry containing both A and B, a t By the end of this step, secondary flows are generated, due to an imbalance of centrifugal forces in the helix cross-section. These secondary flows resuspend sedimented solids in step 5. If these secondary flows are inadequate for particle resuspension (the particles collect at a stagnation point), the helix cross-section may be reoriented in the centrifugal field to move sedimented solids back into the fluid stream during step 5. Figure 2 shows these secondary flows, axial flows, and centrifugal forces, for cases where the fluid flow opposes or complements the spinning direction. In step 6, resuspended A and B particles are convected leftward with fluid, toward the A-rich reservoir. The sum of volumes pumped left in steps 4 and 6 equals the volume pumped right in step 2; no net fluid movement occurs. At the end of the sequence, there has been a net movement of B particles toward the right reservoir and A particles toward the left reservoir. Repeating the sequence indefinitely, increases the degree of fractionation until steady state is achieved with balance axial dispersion and axial separation effects. ModelThe six-step fractionation cycle is modeled by material balances for the suspended and the sedimented particles. Since the helix fluid velocity profiles are not known precisely, the model detail is limited to a one (space) dimensional axial dispersionconvection ap...

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Separation of fine particle dispersions using periodic flows in a spining coiled tube

Abstract: A centrifugal method for fractionating fine ( Show more

Cited by 11 publications

References 22 publications

Visualization of Flows in Curved Channels with aModerate or High Rotation Speed

Visualization of Flows in Curved Channels with aModerate or High Rotation Speed

Separation of fine particles by laminar flow in a tilted slender tube slowly rotating around the longitudinal axis

Fractionation of fine particle slurries using periodic flows in a spinning helix

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