Your search keyword '"Ken Fujimoto"' showing total 3 results

1. Numerical Solution and Experimental Validation of the Drawing Process of Six-Hole Optical Fibers Including the Effects of Inner Pressure and Surface Tension

Author

Philipp Epple, Antonio Delgado, Ken Fujimoto, Giovanni Luzi, Cornelia Rauh, and Michael Scharrer

Subjects

Optical fiber, Materials science, business.industry, Capillary action, Physics::Optics, Internal pressure, Mechanics, Atomic and Molecular Physics, and Optics, law.invention, Surface tension, Optics, law, Fiber, business, Refractive index, Photonic crystal, Photonic-crystal fiber

Abstract

Microstructured optical fibers (MOFs) achieve their desired performance via a pattern of holes that run trough the whole length of the fiber. The variation of the hole pattern allows the production of a variety of optical effects. However, the cross-sectional hole structure can be different from that designed in the preform, due to the combined effects of surface tension and internal pressure. The present paper focuses on the comparison between experiments and numerical calculation of a six hole-optical fiber taking into account the effects of surface tension and internal hole-pressure, since those are of essential importance during drawing. It is shown that the numerical computations deliver reliable results for practical applications and can be used as a predictive tool for fiber development, as long as the inner pressure or the temperature do not exceed too high values.

Published

2012

2. Comparison Between an Analytical Asymptotic Fiber Drawing Model With Full Navier-Stokes Solution Taking Into Account the Effects of Inner Pressure and Surface Tension

Author

Philipp Epple, Antonio Delgado, Ken Fujimoto, Cornelia Rauh, Michael Scharrer, and Giovanni Luzi

Subjects

Physics, Surface tension, Asymptotic analysis, Classical mechanics, Capillary action, Numerical analysis, Mechanics, Solver, Navier–Stokes equations, Aspect ratio (image), Atomic and Molecular Physics, and Optics, Finite element method

Abstract

A fluid-mechanics model that make use of asymptotic analysis based on small aspect ratio of capillaries has been compared with the full 3-D set of the N.-St. equations, for modelling the fabrication of capillary tubes. The final asymptotic equations are solved numerically and then compared with the N.-St. solutions, obtained with a commercial finite elements solver. The present paper focuses on the comparison of the solution of the two methods taking into account the effects of surface tension and internal hole pressure, since those are of essential importance during drawing. It is shown that the analytical asymptotic method delivers reliable results for practical applications, as long as the inner pressure or the temperature does not exceed too high values.

Published

2011

3. Influence of Surface Tension and Inner Pressure on the Process of Fibre Drawing

Author

Michael Scharrer, Giovanni Luzi, Cornelia Rauh, Philipp Epple, Ken Fujimoto, and Antonio Delgado

Subjects

Surface tension, Asymptotic analysis, Materials science, Capillary action, Flow (psychology), Equations of motion, Internal pressure, Process variable, Mechanics, Aspect ratio (image), Atomic and Molecular Physics, and Optics

Abstract

The present contribution deals with thermofluidynamical features occurring during the drawing of capillaries for microstructured optical fibres. Here, the process stability depends strongly on flow and thermal processes taking place as a preform is heated and drawn in the furnace. This is the case particularly for hollow fibres for which the existence of the inner hole directly depends on material parameters such as the surface tension and the rheological properties and on process parameter such as hole internal pressure and the process temperature. A fluid-mechanics model suggested in the literature that makes use of asymptotic analysis based on small aspect ratio of the micro capillaries, has been revisited and improved recently and the leading-order equations have been then examined in some asymptotic limits by Luzi et al. Starting from the novel class of solutions of the simplified equations of motion the present paper focuses on the effect of both surface tension and internal hole pressure since those are of essential importance during drawing. Thus, comparisons with experimental data are performed, in order to validate the analytical model developed in, which will be briefly presented here. The theoretical model gives very accurate predictions both when the internal hole is pressurized or when no pressure is applied, as long as the temperature does not reach too high values.

Published

2010