Flow-Field-Assisted Dielectrophoretic Microchips for High-Efficiency Sheathless Particle/Cell Separation with Dual Mode

The present deficiency about numerical simulation research on blade outlet width of centrifugal pumps is pointed out. In the case of different outlet widths, the flow field in six centrifugal pumps whose specific speed vary from 45 to 260 are simulated by using commercial code FLUENT and the characteristics are predicted. The standard k-ε turbulence model and SIMPLEC algorithm are chosen in FLUENT. The simulation is steady and moving reference frame is used to consider rotor-stator interaction. The research results show that the change of impeller outlet width has obvious impacts on characteristics at design point, flow field and the shape of performance curves. At nominal condition, the change of outlet width has more important effects on moderate specific speed centrifugal pumps. The flow field analysis indicates that blade outlet width change has an important effect on the location and area of low pressure region behind the blade inlet, jet-wake structure in impellers, the secondary flow in volute cross section and the back flow in impellers. The head-flow curve becomes more flat with the increase of outlet width. For moderate and low specific speed centrifugal pumps, the high efficiency area of efficiency-flow curve get bigger with the increase of outlet width and the area will be constant within certain outlet width change scope for high specific speed centrifugal pump. The research results agree well with experiment results.

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Design of dual‐mode high efficiency tri‐band power amplifier using input and output harmonic control technology

International Journal of RF and Microwave Computer-Aided Engineering ◽

10.1002/mmce.22790 ◽

2021 ◽

Author(s):

Ce Shen ◽

Songbai He ◽

Jun Peng ◽

Tingting Yao ◽

Fei You

Keyword(s):

Power Amplifier ◽

High Efficiency ◽

Control Technology ◽

Dual Mode ◽

Harmonic Control ◽

Input And Output ◽

Band Power

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The new concept of flux enhancement during cell separation with MF/UF processes

Water Science & Technology Water Supply ◽

10.2166/ws.2001.0137 ◽

2001 ◽

Vol 1 (5-6) ◽

pp. 381-386

Author(s):

A. Kołtuniewicz

Keyword(s):

Cell Separation ◽

High Efficiency ◽

Membrane Surface ◽

Cross Flow ◽

Dry Mass ◽

High Energy ◽

Process Conditions ◽

Permeate Flux ◽

Flux Enhancement ◽

Flow Systems

The microfiltration and ultrafiltration processes are considered as matured membrane processes that are well established in industrial practice. Nevertheless, the main obstacles of their further development in the new competitive implementations are the economical problems. The key economic factors are permeate flux and energy consumption. However, although the cross-flow systems enable us to attain higher flux, it is usually very expensive. The high energy is consumed to maintain circulation velocity of the retentate that is sufficient for sweeping out the retained component from the membrane surface. Moreover in the case of cells separation the high intensity of the fouling and low cake permeability makes it necessary to apply additional efforts, such as backflushing, backpulsing, promoters of turbulence, vibrations, ultrasounds and many other. Therefore, dead-end systems are still quite competitive with cross-flow, especially for diluted (less than 0.5% of dry mass) suspensions or solutions. Cell separation with membranes is one of the most vivid problems for modern biotechnology, wastewater and water treatment. Membranes offer mild process conditions and high selectivity of separation. This enables us to solve a variety of problems such as cell culturing, fractionation, concentration, purification and sterilisation. The selected cells may be precisely separated from other components of broth and subsequently directed into the reaction space again in good conditions to ensure a quasi-continuous mode of operation. Moreover, membranes enable us to attain high efficiency of the bioconversion by removal of all product and inhibitors directly from the bioreactor. This is the reason for the huge interest in cell separation with membranes. The idea of the paper was to present the new concept of flux enhancement for cell separation on membranes. This concept lies in taking advantage of the specific rheological nature of biopolymers, which are the main foulants. The biopolymers retained on the membrane surface (i.e. on the top layer) can be applied as a lubricant for the cells that can settle on such a ‘movable layer’. As is shown, further in the paper, the thickness of the moving layer is lower and the flux is greater. The common movement of the cells and gel layer is very convenient from the cells integrity point of view. However the hydrodynamic conditions always play an important role in cross-flow systems; the resistance of ultrafiltration membranes may be reduced much more when compared with more open microfiltration membranes.

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A high-efficiency, dual-mode, dynamic, buck-boost power supply IC for portable applications

18th International Conference on VLSI Design held jointly with 4th International Conference on Embedded Systems Design ◽

10.1109/icvd.2005.15 ◽

2005 ◽

Cited By ~ 33

Author(s):

B. Sahu ◽

G.A. Rincon-Mora

Keyword(s):

Power Supply ◽

High Efficiency ◽

Dual Mode

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Effect of NS-DBD Actuator Parameters on the Aerodynamic Performance of a Flap Lifting Device

Applied Sciences ◽

10.3390/app9235213 ◽

2019 ◽

Vol 9 (23) ◽

pp. 5213 ◽

Cited By ~ 1

Author(s):

Kun Chen ◽

Chen-Yao Wei ◽

Zhi-Wei Shi

Keyword(s):

Energy Density ◽

Flow Field ◽

Drag Reduction ◽

Pulse Width ◽

High Efficiency ◽

Aerodynamic Drag ◽

Pulse Discharge ◽

Excitation Frequency ◽

Aerodynamic Performance ◽

Discharge Pulse

The flap lift device is an important part of the conventional configuration of aircrafts and has an important impact on the aerodynamic performance. In this paper, a high-efficiency, simple, and energy-saving nanosecond dielectric barrier discharge (DBD) plasma actuator is placed in the vicinity of the flap lift device to improve the aerodynamic performance of the flap by controlling the flow field. The two-dimensional airfoil GAW-1 and its 29% flap were selected as the research objects, and the nanosecond (NS) DBD actuators were fixed at different locations near the deflection angle of the 10°flap. The excitation frequency, pulse width, and energy density parameters of the pulse discharge were adjusted, and then, the effects of parameter changes on aerodynamic characteristics of the airfoil were studied by numerical simulation. The simulation results show that adjusting the excitation frequency on the aerodynamic drag is weak and that the effect on the aerodynamic lift is obvious. The increase of the discharge pulse width will have a more significant effect on the flow field, i.e., a proper increase of the discharge pulse width can achieve better drag reduction, and increase lift after a stall at a high angle of attack. Although the increase of discharge energy density can strengthen the pulse perturbation effect on the flow field, it also contributes to some adverse effects and has no obvious optimization effect on the control efficiency of lift increase and drag reduction.

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Design and Simulation of an Integrated Centrifugal Microfluidic Device for CTCs Separation and Cell Lysis

Micromachines ◽

10.3390/mi11070699 ◽

2020 ◽

Vol 11 (7) ◽

pp. 699

Author(s):

Rohollah Nasiri ◽

Amir Shamloo ◽

Javad Akbari ◽

Peyton Tebon ◽

Mehmet R. Dokmeci ◽

...

Keyword(s):

Numerical Simulation ◽

Angular Velocity ◽

Microfluidic Device ◽

Cell Separation ◽

High Efficiency ◽

Separation Efficiency ◽

White Blood Cells ◽

Cell Lysis ◽

Target Cells ◽

Separation Unit

Separation of circulating tumor cells (CTCs) from blood samples and subsequent DNA extraction from these cells play a crucial role in cancer research and drug discovery. Microfluidics is a versatile technology that has been applied to create niche solutions to biomedical applications, such as cell separation and mixing, droplet generation, bioprinting, and organs on a chip. Centrifugal microfluidic biochips created on compact disks show great potential in processing biological samples for point of care diagnostics. This study investigates the design and numerical simulation of an integrated microfluidic device, including a cell separation unit for isolating CTCs from a blood sample and a micromixer unit for cell lysis on a rotating disk platform. For this purpose, an inertial microfluidic device was designed for the separation of target cells by using contraction–expansion microchannel arrays. Additionally, a micromixer was incorporated to mix separated target cells with the cell lysis chemical reagent to dissolve their membranes to facilitate further assays. Our numerical simulation approach was validated for both cell separation and micromixer units and corroborates existing experimental results. In the first compartment of the proposed device (cell separation unit), several simulations were performed at different angular velocities from 500 rpm to 3000 rpm to find the optimum angular velocity for maximum separation efficiency. By using the proposed inertial separation approach, CTCs, were successfully separated from white blood cells (WBCs) with high efficiency (~90%) at an angular velocity of 2000 rpm. Furthermore, a serpentine channel with rectangular obstacles was designed to achieve a highly efficient micromixer unit with high mixing quality (~98%) for isolated CTCs lysis at 2000 rpm.

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