Biotechnology

생명 공학 분야에 전산 유체 역학을 적용하는 것은 비교적 새로운 방법으로, 다양한 의료 기기를 효과적으로 사용하거나, 분석 구현하는 방법을 개선하는데 큰 도움이 될 수 있습니다.
FLOW-3D는 하나의 패키지로 구성되어 있으며, 광범위한 범위를 갖는 강력한 시뮬레이션 해석 프로그램 입니다.
FLOW-3D가 가지고 있는 기능으로 자유 표면과 제한된 갇혀 있는 유체의 흐름, 가변 밀도, 상 변화, 움직이는 물체, 기계 및 열 응력 해석이 가능합니다.
 
자세한 내용은 FLOW-3D의 모델링 기능의 전체 목록을 살펴보십시오.
Von Mises stress 분포.
FLOW-3D‘s fluid-structure interaction model 을 이용한 안압 분석 결과.
Courtesy University at Buffalo.

바이오 분야의 다양한 해석 사례

관련 기술자료

Fig. 8. Pressure distribution during the infiltration of preform with the 50 ¯m particles and 20 % starches: (a) 25 % filled, (b) 57 % filled, and (c) 99 % filled.

Experimental study and numerical simulation of infiltration of AlSi12 alloys into Si porous preforms with micro-computed tomography inspection characteristics

마이크로 컴퓨터 단층 촬영 검사 특성을 가진 Si 다공성 프리폼에 AlSi12 합금의 침투에 대한 실험적 연구 및 수치 시뮬레이션 Ruizhe ...
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Liquid-solid co-printing of multi-material 3D fluidic devices via material jetting

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Fig. 2: Scheme of the LED photo-crosslinking and 3D-printing section of the microfluidic/3D-printing device. The droplet train is transferred from the chip microchannel into a microtubing in a straight section with nearly identical inner channel and inner microtubing diameter. Further downstream, the microtubing passes an LED-section for fast photo cross-linking to generate the microgels. This section is contained in an aluminum encasing to avoid premature crosslinking of polymer precursor in upstream channel sections by stray light. Subsequently, the microtubing is integrated into a 3D-printhead, where the microgels are jammed into a filament that is directly 3D-printed into the scaffold.

On-Chip Fabrication and In-Flow 3D-Printing of Cell-Laden Microgel Constructs: From Chip to Scaffold Materials in One Integral Process

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Figure 3 Simulation PTC pipes enhanced with copper foam and nanoparticles in FLOW-3D software.

다공성 미디어 및 나노유체에 의해 강화된 수집기로 태양광 CCHP 시스템의 최적화

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Energy and exergy analysis of an enhanced solar CCHP system with a collector embedded by porous media and nano fluid

Energy and exergy analysis of an enhanced solar CCHP system with a collector embedded by porous media and nano fluid

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Fig.1 Schematic diagram of the novel cytometric device

Fabrication and Experimental Investigation of a Novel 3D Hydrodynamic Focusing Micro Cytometric Device

Yongquan Wang*a , Jingyuan Wangb, Hualing Chenc School of Mechanical Engineering, Xi’an Jiaotong University, Xi’an, Shaanxi, 710049, P. R. Chinaa ...
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Figure 1. (a) Top view of the microfluidic-magnetophoretic device, (b) Schematic representation of the channel cross-sections studied in this work, and (c) the magnet position relative to the channel location (Sepy and Sepz are the magnet separation distances in y and z, respectively).

Continuous-Flow Separation of Magnetic Particles from Biofluids: How Does the Microdevice Geometry Determine the Separation Performance?

by  Cristina González Fernández1, Jenifer Gómez Pastora2, Arantza Basauri1, Marcos Fallanza1, Eugenio Bringas1, Jeffrey J. Chalmers2 and Inmaculada Ortiz1,* 1Department of Chemical and Biomolecular Engineering, ETSIIT, ...
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Fluid velocity magnitude including velocity vectors and blood volumetric fraction contours for scenario 3: (a,b) Magnet distance d = 0; (c,d) Magnet distance d = 1 mm.

Numerical Analysis of Bead Magnetophoresis from Flowing Blood in a Continuous-Flow Microchannel: Implications to the Bead-Fluid Interactions

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Fig. 12. Comparison of simulation results with experimental data for a flow rate of water = Ql=15 ml/hr and a flow rate of air = Qg =3 ml/hr.

Simulation of Droplet Dynamics and Mixing in Microfluidic Devices using a VOF-Based Method

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Figure 1. Cross-sectional dimensions of a V-groove channel

Modeling Open Surface Microfluidics

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