Motion of a capsule in a curved tube

Numerical and experimental techniques were used to study the physics of flow separation for steady internal flow in a 45° junction geometry, such as that observed between two pipes or between the downstream end of a bypass graft and an artery. The three-dimensional Navier–Stokes equations were solved using a validated finite element code, and complementary experiments were performed using the photochromic dye tracer technique. Inlet Reynolds numbers in the range 250 to 1650 were considered. An adaptive mesh refinement approach was adopted to ensure grid-independent solutions. Good agreement was observed between the numerical results and the experimentally measured velocity fields; however, the wall shear stress agreement was less satisfactory. Just distal to the ‘toe’ of the junction, axial flow separation was observed for all Reynolds numbers greater than 250. Further downstream (approximately 1.3 diameters from the toe), the axial flow again separated for Re [ges ] 450. The location and structure of axial flow separation in this geometry is controlled by secondary flows, which at sufficiently high Re create free stagnation points on the model symmetry plane. In fact, separation in this flow is best explained by a secondary flow boundary layer collision model, analogous to that proposed for flow in the entry region of a curved tube. Novel features of this flow include axial flow separation at modest Re (as compared to flow in a curved tube, where separation occurs only at much higher Re), and the existence and interaction of two distinct three-dimensional separation zones.

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Construction of a computational non-planar curved tube model from MRI data

IEEE International Workshop on Imaging Systems and Techniques, 2005 ◽

10.1109/ist.2005.1594533 ◽

2006 ◽

Cited By ~ 2

Author(s):

T.A. Spirka ◽

J.G. Myers ◽

R.M. Setser ◽

S.S. Halliburton ◽

R.D. White ◽

...

Keyword(s):

Tube Model ◽

Curved Tube

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A Study of a Sharp 90 Degree Curved Flow

ASME 1992 International Computers in Engineering Conference: Volume 1 — Artificial Intelligence; Expert Systems; CAD/CAM/CAE; Computers in Fluid Mechanics/Thermal Systems ◽

10.1115/cie1992-0069 ◽

1992 ◽

Author(s):

R. H. Kim

Keyword(s):

Turbulence Model ◽

Ideal Gas ◽

Radius Of Curvature ◽

Dimensional Theory ◽

One Dimensional ◽

Algebraic Stress Model ◽

Finite Difference Technique ◽

Curved Tube ◽

Kinetic Energy Loss ◽

The Ideal

Abstract An investigation of air flow along a 90 degree elbow-like tube is conducted to determine the velocity and temperature distributions of the flow. The tube has a sharp 90 degree turn with a radius of curvature of almost zero. The flow is assumed to be a steady two-dimensional turbulent flow satisfying the ideal gas relation. The flow will be analyzed using a finite difference technique with the K-ε turbulence model, and the algebraic stress model (ASM). The FLUENT code was used to determine the parameter distributions in the passage. There are certain conditions for which the K-ε model does not describe the fluid phenomenon properly. For these conditions, an alternative turbulence model, the ASM with or without QUICK was employed. FLUENT has these models among its features. The results are compared with the result computed by using elementary one-dimensional theory including the kinetic energy loss along the passage of the sharp 90 degree curved tube.

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Heat Transfer in Reciprocating Planar Curved Tube With Piston Cooling Application

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.1995768 ◽

2005 ◽

Vol 128 (1) ◽

pp. 219-229 ◽

Cited By ~ 4

Author(s):

Shyy Woei Chang ◽

Yao Zheng

Keyword(s):

Heat Transfer ◽

Local Heat Transfer ◽

Local Heat ◽

Interactive Effects ◽

Experimental Conditions ◽

Nusselt Numbers ◽

Curved Tube ◽

The Individual ◽

Cooling Passage ◽

Piston Cooling

This paper describes an experimental study of heat transfer in a reciprocating planar curved tube that simulates a cooling passage in piston. The coupled inertial, centrifugal, and reciprocating forces in the reciprocating curved tube interact with buoyancy to exhibit a synergistic effect on heat transfer. For the present experimental conditions, the local Nusselt numbers in the reciprocating curved tube are in the range of 0.6–1.15 times of static tube levels. Without buoyancy interaction, the coupled reciprocating and centrifugal force effect causes the heat transfer to be initially reduced from the static level but recovered when the reciprocating force is further increased. Heat transfer improvement and impediment could be superimposed by the location-dependent buoyancy effect. The empirical heat transfer correlation has been developed to permit the evaluation of the individual and interactive effects of inertial, centrifugal, and reciprocating forces with and without buoyancy interaction on local heat transfer in a reciprocating planar curved tube.

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An experimental study of pulsatile flow in a curved tube

Journal of Biomechanics ◽

10.1016/0021-9290(79)90095-2 ◽

1979 ◽

Vol 12 (8) ◽

pp. 626 ◽

Cited By ~ 1

Author(s):

K.B. Chandran ◽

T.L. Yearwood

Keyword(s):

Experimental Study ◽

Pulsatile Flow ◽

Curved Tube

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Unbending of Curved Tube by Internal Pressure

Shell-like Structures - Advanced Structured Materials ◽

10.1007/978-3-642-21855-2_31 ◽

2011 ◽

pp. 491-498 ◽

Cited By ~ 2

Author(s):

Alexei M. Kolesnikov

Keyword(s):

Internal Pressure ◽

Curved Tube

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Experimental study of micromixing in curved tube reactors by the reactive tracer method

Chemical Engineering Research and Design ◽

10.1016/j.cherd.2020.04.042 ◽

2020 ◽

Vol 160 ◽

pp. 335-350

Author(s):

Antoni Rożeń ◽

Janusz Kopytowski

Keyword(s):

Experimental Study ◽

Tracer Method ◽

Curved Tube ◽

Reactive Tracer

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A SIMPLE MECHANICAL MEASUREMENT FOR PRESSURE DISTRIBUTIONS AND FLOW RATES OF THORACIC AORTA

Biomedical Engineering Applications Basis and Communications ◽

10.4015/s1016237205000378 ◽

2005 ◽

Vol 17 (05) ◽

pp. 252-257

Author(s):

YANG-YAO NIU ◽

NANG-PING KAN

Keyword(s):

Flow Rate ◽

Three Dimensional ◽

Blood Flow Rate ◽

Aortic Pressure ◽

Test Cases ◽

Water Pump ◽

Mechanical Measurement ◽

Current Image ◽

Pressure Distributions ◽

Curved Tube

The aim of this research is to design a simple three-dimensional aortic model to measure the relation of aortic pressure distributions and blood flow rate at the outlets of the aorta. The current experiment considers an area-varying curved tube with one branch to mimic an aortic arch. The measurement utilizes a water pump to substitute for the heart pumping task and collects data for the distributions of the pressure and flow rate relied on a PC-controlled pressure sensor. Various pressures as 160, 140, 110 and 90 mm Hg are chosen as aortic entrance blood pressure conditions for the test cases. The pressure distributions from the current measurement will be used for the numerical boundary condition which can not be obtained from the current image technology.

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Architecture of the Bacterial Flagellar Distal Rod and Hook of Salmonella

Biomolecules ◽

10.3390/biom9070260 ◽

2019 ◽

Vol 9 (7) ◽

pp. 260 ◽

Cited By ~ 6

Author(s):

Yumiko Saijo-Hamano ◽

Hideyuki Matsunami ◽

Keiichi Namba ◽

Katsumi Imada

Keyword(s):

Mechanical Properties ◽

Structural Model ◽

Sequence Similarity ◽

Significant Sequence Similarity ◽

Protein Subunits ◽

Bacterial Flagellum ◽

Curved Tube ◽

Single Protein ◽

Associated Proteins ◽

Density Map

The bacterial flagellum is a large molecular complex composed of thousands of protein subunits for motility. The filamentous part of the flagellum, which is called the axial structure, consists of the filament, the hook, and the rods, with other minor components—the cap protein and the hook associated proteins. They share a common basic architecture of subunit arrangement, but each part shows quite distinct mechanical properties to achieve its specific function. The distal rod and the hook are helical assemblies of a single protein, FlgG and FlgE, respectively. They show a significant sequence similarity but have distinct mechanical characteristics. The rod is a rigid, straight cylinder, whereas the hook is a curved tube with high bending flexibility. Here, we report a structural model of the rod constructed by using the crystal structure of a core fragment of FlgG with a density map obtained previously by electron cryomicroscopy. Our structural model suggests that a segment called L-stretch plays a key role in achieving the distinct mechanical properties of the rod using a structurally similar component protein to that of the hook.

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