Ship Resistance and Propulsion: Practical Estimation of Propulsive PowerCambridge University Press, 8 thg 8, 2011 - 537 trang Ship Resistance and Propulsion provides a comprehensive approach to evaluating ship resistance and propulsion. Informed by applied research, including experimental and CFD techniques, this book provides guidance for the practical estimation of ship propulsive power for a range of ship types. Published standard series data for hull resistance and propeller performance enables practitioners to make ship power predictions based on material and data contained within the book. Fully worked examples illustrate applications of the data and powering methodologies; these include cargo and container ships, tankers and bulk carriers, ferries, warships, patrol craft, work boats, planing craft and yachts. The book is aimed at a broad readership including practising naval architects and marine engineers, seagoing officers, small craft designers, undergraduate and postgraduate students. Also useful for those involved in transportation, transport efficiency and ecologistics who need to carry out reliable estimates of ship power requirements. |
Nội dung
1 | |
7 | |
12 | |
4 ModelShip Extrapolation | 69 |
5 ModelShip Correlation | 85 |
6 Restricted Water Depth and Breadth | 97 |
7 Measurement of Resistance Components | 108 |
8 Wake and Thrust Deduction | 144 |
12 Propeller Characteristics | 261 |
13 Powering Process | 296 |
14 Hull Form Design | 313 |
15 Numerical Methods for Propeller Analysis | 337 |
16 Propulsor Design Data | 369 |
17 Applications | 418 |
Appendix A1 Background Physics | 473 |
Appendix A2 Derivation of Eggers Formula for Wave Resistance | 484 |
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Ship Resistance and Propulsion: Practical Estimation of Ship Propulsive Power Anthony F. Molland Không có bản xem trước - 2011 |
Thuật ngữ và cụm từ thông dụng
analysis angle appendages application approximate Architects and Marine blade block coefficient boundary layer BSRA bulbous bow catamaran cavitation Chapter coefficient coefficients components computational fluid dynamics correction derived diameter displacement drag drag coefficient draught efficiency Equation estimate example flow fluid follows form factor Froude number hence high-speed craft hull form hydrodynamic increase Institution of Naval Institution ofNaval Architects ITTC knots load Marine Engineers measurements methods Molland monohull Naval Architects parameters pitch prediction pressure propulsor ratio regression residuary resistance resistance data Royal Institution ofNaval rudder self-propulsion Series 62 shaft ship resistance Shipbuilding shown in Figure skin friction Society of Naval tests thrust deduction torque total resistance Towing Tank Transactions transverse wave Typical University of Southampton values velocity vessels viscous wake fraction wave pattern wave resistance wetted area wetted surface area wind yacht