Your search keyword '"Ayaka Matsumoto"' showing total 2 results

1. EFD and CFD Study of Forces, Ship Motions, and Flow Field for KRISO Container Ship Model in Waves

Author

Md. Alfaz Hossain, Naoki Kawakami, Kento Tamaki, Yasuyuki Toda, Ayaka Matsumoto, Ping-Chen Wu, and Htike Aung Kyaw

Subjects

Numerical Analysis, business.industry, Applied Mathematics, Mechanical Engineering, Ocean Engineering, Regular wave, Computational fluid dynamics, Ship motions, Flow field, Container (abstract data type), business, Geology, Civil and Structural Engineering, Marine engineering

Abstract

Ship motion responses and added resistance in waves have been predicted by a wide variety of computational tools. However, validation of the computational flow field still remains a challenge. In the previous study, the flow field around the Korea Research Institute for Ships and Ocean Engineering (KRISO) Very Large Crude-oil Carrier 2 tanker model with and without propeller condition and without rudder condition was measured by the authors, as well as the resistance and self-propulsion tests in waves. In this study, the KRISO container ship model appended with a rudder was used for the higher Froude number .26 and smaller block coefficient .65. The experiments were conducted in the Osaka University towing tank using a 3.2-m-long ship model for resistance and self-propulsion tests in waves. Viscous flow simulation was performed by using CFDShip-Iowa. The wave conditions proposed in Computational Fluid Dynamics (CFD) Workshop 2015 were considered, i.e., the wave-ship length ratio λ/L = .65, .85, 1.15, 1.37, 1.95, and calm water. The objective of this study was to validate CFD results by Experimental Fluid Dynamics (EFD) data for ship vertical motions, added resistance, and wake flow field. The detailed flow field for nominal wake and self-propulsion condition will be analyzed for λ/L = .65, 1.15, 1.37, and calm water. Furthermore, bilge vortex movement and boundary layer development on propeller plane, propeller thrust, and wake factor oscillation in waves will be studied.

Published

2020

2. EFD and CFD Study of Forces, Ship Motions, and Flow Field for KRISO Container Ship Model in Waves.

Author

Ping-Chen Wu, Hossain, Md. Alfaz, Naoki Kawakami, Kento Tamaki, Htike Aung Kyaw, Ayaka Matsumoto, and Yasuyuki Toda

Subjects

CONTAINER ships, SHIP models, COMPUTATIONAL fluid dynamics, FLUID dynamics, VISCOUS flow, FLOW simulations, BOUNDARY layer (Aerodynamics)

Abstract

Ship motion responses and added resistance in waves have been predicted by a wide variety of computational tools. However, validation of the computational flow field still remains a challenge. In the previous study, the flow field around the Korea Research Institute for Ships and Ocean Engineering (KRISO) Very Large Crude-oil Carrier 2 tanker model with and without propeller condition and without rudder condition was measured by the authors, as well as the resistance and self-propulsion tests in waves. In this study, the KRISO container shipmodel appended with a rudder was used for the higher Froude number .26 and smaller block coefficient .65. The experiments were conducted in the Osaka University towing tank using a 3.2-m-long ship model for resistance and self-propulsion tests in waves. Viscous flow simulation was performed by using CFDShip-Iowa. The wave conditions proposed in Computational Fluid Dynamics (CFD) Workshop 2015 were considered, i.e., the wave-ship length ratio λ/L = .65, .85, 1.15, 1.37, 1.95, and calm water. The objective of this study was to validate CFD results by Experimental Fluid Dynamics (EFD) data for ship vertical motions, added resistance, andwake flowfield. The detailed flowfield for nominalwake and self-propulsion condition will be analyzed for λ/L = .65, 1.15, 1.37, and calm water. Furthermore, bilge vortex movement and boundary layer development on propeller plane, propeller thrust, and wake factor oscillation in waves will be studied. [ABSTRACT FROM AUTHOR]

Published

2020