A database of full-scale three-dimensional sail shapes is presented with the aerodynamic coefficients for the upwind condition
of International Measurement System (IMS) type sails. Three-dimensional shape data are used for the input of numerical calculations
and the results are compared with the measured sail performance. The sail shapes and performance were measured using sail
dynamometer boat Fujin. This is a boat of 10.3-m length overall in which load cells and CCD cameras were installed to simultaneously measure the
sail forces and shapes. At the same time, the sailing conditions of the boat, e.g., boat speed, heel angle, wind speed, and
wind angle, were measured. The sail configurations tested were: mainsail with 130% jib, mainsail with 75% jib, and mainsail
alone. Sail shapes were measured at several vertical positions for the shape parameters defined by: chord length, maximum
draft, maximum draft position, entry angle at the luff, and exit angle at the leech, all of which finally yield three-dimensional
coordinates of the sail geometry. The tabulated shape data, along with aerodynamic coefficients, are presented in this article.
In addition, numerical flow simulations were performed for the measured sail shapes and the sailing conditions to investigate
the capability and limitations of the methods through detailed comparison with the measurements. Two numerical methods were
used: a vortex lattice method (VLM) and a Reynolds-averaged Navier–Stokes (RANS)-based computational fluid dynamics method.
The sail shape database, in association with the numerical results, provides a good benchmark for the sail performance analysis
of the upwind condition of IMS type sails. 相似文献
The main objective of this article is to describe the development of two advanced multiobjective optimization methods based
on derivative-free techniques and complex computational fluid dynamics (CFD) analysis. Alternatives for the geometry and mesh
manipulation techniques are also described. Emphasis is on advanced strategies for the use of computer resource-intensive
CFD solvers in the optimization process: indeed, two up-to-date free surface-fitting Reynolds-averaged Navier-Stokes equation
solvers are used as analysis tools for the evaluation of the objective function and functional constraints. The two optimization
methods are realized and demonstrated on a real design problem: the optimization of the entire hull form of a surface combatant,
the David Taylor Model Basin—Model 5415. Realistic functional and geometrical constraints for preventing unfeasible results
and to get a final meaningful design are enforced and discussed. Finally, a recently proposed verification and validation
methodology is applied to assess uncertainties and errors in simulation-based optimization, based on the differences between
the numerically predicted improvement of the objective function and the actual improvement measured in a dedicated experimental
campaign. The optimized model demonstrates improved characteristics beyond the numerical and experimental uncertainty, confirming
the validity of the simulation-based design frameworks. 相似文献
For clarifying the usefulness and practical issues of a tradable permit system empirically, we implemented a tradable permit system for a bicycle-sharing service in Yokohama city, Japan. We analyzed both travel and transaction behavior within this system. Many activity factors, such as the amount of free time in each day, home location and travel mode to the bicycle port, were shown to affect the transaction of tradable permits. The results of the pilot program indicated that inefficient allocation of tradable permits occurred when participants postponed their decision-making because of uncertainty. To determine the reason for this effect and the contributing factors, we created a dynamic discrete choice model to describe the choice results and timing. The estimation result indicated that the option value of postponing decision-making caused the transactions to be performed at the last minute, and that this effect blocked the liquidity of the permits trade. In addition, because the result reveals that there was heterogeneity in the time discount factor, the initial allocation of permits was found to be important for efficient allocation.
Steady flow simulations for the Korean Research Institute for Ships and Ocean Engineering (KRISO) container ship (KCS) were
performed for towing and self-propulsion. The main focus in the present article is on the evaluation of computational fluid
dynamics (CFD) as a tool for hull form design along with application of state-of-the-art technology in the flow simulations.
Two Reynolds-averaged Navier-Stokes (RANS) equation solvers were employed, namely CFDShip-Iowa version 4 and Flowpack version
2004e, for the towing and self-propulsion cases, respectively. The new features of CFDShip-Iowa version 4 include a single-phase
level-set method to model the free surface and an overset gridding capability to increase resolution in the flow and wave
fields. The new features of Flowpack version 2004e are related to a self-propulsion scheme in which the RANS solver is coupled
with a propeller performance program based on the infinitely bladed propeller theory. The present work is based on a close
interaction between IIHR-Hydroscience and Engineering of the University of Iowa and Osaka Prefecture University. In the following
article, overviews are given of the present numerical methods and results are presented and discussed for the KCS in towing
and self-propulsion modes, including comparison with available experimental fluid dynamics (EFD) data. Additional evaluation
is provided through discussion of the recent CFD Workshop Tokyo 2005, where both methods appeared to yield very promising
results. 相似文献
This paper assesses travellers’ responses to the use of existing Park-and-Ride (P&R) services based on an economical welfare maximisation approach. Specifically, the paper presents a modelling framework to estimate consumer surplus and producer surplus (business profits) on the basis of modal choice probabilities. The paper draws on evidence from Stated Preference surveys conducted around two P&R sites in Sapporo, Japan, where P&R services occupy a modest market space. Overall, the results suggest that business profit increases when economical welfare is maximised, as a consequence of increased demand. It is also shown that P&R choice is not only influenced by parking fees, but also by the fares and other attributes of alternative transportation modes. Accordingly, the interactions of P&R with alternative transportation modes should be taken into consideration in any strategic transportation policies oriented towards motivating sustainable transport mode choices. 相似文献
Numerical optimization of the initial design of a fast catamaran (high-speed sealift research model B, HSSL-B) has been carried
out through a simulation-based design (SBD) framework, based on an advanced free-surface unsteady Reynolds-averaged Navier–Stokes
(URANS) solver and a potential flow solver, and global optimization (GO) algorithms. The potential flow computational fluid
dynamics (CFD) SBD was used to guide the more expensive URANS CFD SBD. The fluid-dynamic analysis of the flow past the catamaran
proved that the use of the URANS solver was fundamental in dealing with the multihull interference problem. In the case investigated,
the separation distance was small and the viscous flow quite distorted by the proximity of the hulls, so that only viscous
solvers could correctly capture the flow details. Sinkage and trim effects, due to the high speed range and again to the small
separation distance investigated, are also relevant. The initial HSSL-B geometry and three optimization problems, including
single- and multiobjective optimization problems, proposed by designers from Bath Iron Works, were successfully optimized/solved,
and finally an experimental campaign was carried out to validate the optimal design. A new verification and validation methodology
for assessing uncertainties and errors in simulation-based optimization was used based on the trends, i.e., the differences
between the numerically predicted improvement of the objective function and the actual improvement measured in a dedicated
experimental campaign, including consideration of numerical and experimental uncertainties. Finally, the success of the optimization
processes was confirmed by the experimental measurements, and trends for total resistance, sinkage, and trim between the original
and optimal designs were numerically and experimentally verified and validated. 相似文献
This paper presents comparisons of computational and experimental fluid dynamics results for boundary layers, wakes, and
wave fields for the Series 60 CB= 0.6 ship model in steady drift motion. The numerical method solves the unsteady Reynolds-averaged Navier–Stokes and continuity
equations with the Baldwin–Lomax turbulence model, exact nonlinear kinematic and approximate dynamic free-surface boundary
conditions, and a body/free-surface conforming grid. The experimental and computational conditions, i.e., Froude numbers of
0.16 and 0.316 for the experiments, and Froude numbers of 0 and 0.316 for the computations, allow comparisons of low and high
Froude number results, respectively, which allows an evaluation of Froude number effects and validation of the computational
fluid dynamics at both low and high Froude numbers. This article gives an overview of this numerical approach, and the computational
conditions and uncertainty analysis are described. Results are presented for the wave and flow fields, with emphasis on the
important flow features of drift- and wave-induced effects in comparison with the experiments. Finally, conclusions from the
present study are given, together with recommendations for future work.
Received: August 31, 2001 / Accepted: March 25, 2002 相似文献
The Japan Marine Science and Technology Center (JAMSTEC) has been, and is now promoting the “OD21” program (i.e., “Ocean
drilling in the 21st century”). This is the first plan in the world to utilize deep-water riser-drilling technologies for
scientific drilling. One of the important factors for the success of this program is the development of a high-performance
drilling vessel. Since 1990, JAMSTEC has been continuing a technological study of a riser-drilling vessel for scientific studies
with an operational capability in waters up to 4000 m deep. It was decided to start the construction with a two-phase plan:
a vessel with a riser operation for waters up to 2500 m deep will be constructed in the initial stage, and then the vessel
will be modified to a 4000-m depth capability. In the development process of the vessel, named Chikyu, many new technical developments have taken place, such as drilling/coring equipment, a dynamic positioning system, etc.
Thus, the Chikyu is expected to contribute to ocean engineering and other work, in addition to scientific advances.
Received: June 15, 2002 / Accepted: November 11, 2002
Address correspondence to: Y. Yano (e-mail: yanoy@jamstec.go.jp) 相似文献