Victor M. Lyatkher - Wave, Wind, and Current Power Generation

6 Chapter 6Fig. 6.1 Six tier balanced turbine with one blade in each tier.Fig. 6.2 Turbine common views.Fig. 6.3 Completely balanced turbine concerning the central point of contact.Fig. 6.4 One blade on a disk with the balance weight.Fig. 6.5 Profile and general view of the blade of the turbine.Fig. 6.6 Fragment of an aluminum shaft.Fig. 6.7 Turbine power P opposite speed relation.Fig. 6.8 The generator with the constant magnets ГВ-2/650-110-12Г ( «Erga», Kalu...Fig. 6.9 From left - a comparison of passport (1) and experimental (2) data. Rig...Fig. 6.10 Rotational speed of the turbine (1) and the voltage on the generator (...Fig. 6.11 Rotational speed of the turbine (1) and power at the generator termina...Fig. 6.12 Rotational speed of the turbine (1) and power at the generator termina...Fig. 6.13Fig. 6.14 Scheme of micro-hydroelectric power station 1) turbine (2.7 × 0.64 m2)...Fig. 6.15 Completely balanced turbine with 2 blades on each tier.Fig. 6.16 Efficiency of two blades machine. Solidity 0.2.Fig. 6.17 Efficiency curve. Solidity 0.3.Fig. 6.18 Short hydro-turbine diameter of 1.6 m and a height of 0.9 m with 3 bla...

7 Chapter 7Fig. 7.1 The tidal parameters in the basin of TPP.Fig. 7.2 General view of the orthogonal multi blade power unit. The top of the c...Fig. 7.3 Cross section of the rings.Fig. 7.4 The model of multi-blade rotor in the hydraulic channel.Fig. 7.5 The efficiency factor of the rotor of a multiblade hydropower unit acco...Fig. 7.6 The power factor of the multi blade turbine CN in the function of the r...Fig. 7.7 The tidal power station in the eastern part of Bay of Fundy (Minas Basi...Fig. 7.8 TPP without the dam near Auckland. 1- TPP general, capacity up to 1.3GW...Fig. 7.9 The tidal power station in the narrowness of Tugursky Bay. The width of...Fig. 7.10 The water levels and flow speeds in Tugur and Lindholm (solid lines) s...Fig. 7.11 The tidal power station in the northern part of Penzhenskaya Bay. The ...Fig. 7.12 The conditional cross section (a) and the unit of the turbines (b), lo...Fig. 7.13 Total power from two TPP. In the inside straight α = 0.2.Fig. 7.14 The bays of Iceland to build TPP with basis power.

8 Chapter 8Fig. 8.1 Isolines of mean streams of wind power (kW/sq.m) over Moscow.Fig. 8.2 Wind power density (kW/m2) that was exceeded 5%, 32%, 50%, 68%, and 95%...Fig. 8.3 The blocks of High-Altitude Wind Power Plant.Fig. 8.4 High-Altitude Wind Power Plant (HAWPP) with 3 blocks included Orthogona...Fig. 8.5 Maximum efficiency of a frame two-bladed rotor with a solidity 0.3 reac...Fig. 8.6 The relative loads acting on one tier of two-bladed turbine. ReV= 8.5×1...Fig. 8.7 Left-. Longitudinal section of plant blades (one layer). The Max. lifti...Fig. 8.8 Coefficient of a lifting force of a wing on tests in water as an angle ...Fig. 8.9 Options of an arrangement of a crack for giving of a jet, b = 200 mm, a...Fig. 8.10 Option 1. Jet on shady side at the end of a wing.Fig. 8.11 At negative corners a jet on the shaded party. Jet influence at small ...Fig. 8.12 Jet influence at large numbers Strukhal . Fig. 8.13 Option 2 – a jet at the beginning of a wing. Small numbers Strukhalya....Fig. 8.14 Option 2. Large numbers Strukhal. The jet on shady side of a profile c...Fig. 8.15 General view of model and Scheme of giving of a stream. On the opposit...Fig. 8.16 The turbine model with hollow blades and shaft.Fig. 8.17 1) sock of the blade, 2) an alignment of the greatest thickness o the ...Fig. 8.18 Example of the blade’s profile (top)1,2 - nozzles, forming a wall jets...Fig. 8.19 Sections of channels supplying air to blade surface for circulation co...

9 Chapter 9Fig. 9.1 General view of the car with spirals (up) and a section along the spira...Fig. 9.2 Fragment of a spiral turbine in a single-blade rotor variant. The blade...Fig. 9.3 High maneuverability vehicle that does not require expensive equipment.Fig. 9.4 Geometric parameters and flow diagram of the wing profile.Fig. 9.5 Components of the blade load in the absence of a jet.Fig. 9.6 Components of the load on the blade under the action of the jet on the ...Fig. 9.7 Two rotors with parallel axes above the roof of the vehicle.Fig. 9.8 Turbines with straight blades approximating the spiral.Fig. 9.9 Arrangement of turbine blades with compensation of centrifugal forces.

10 Chapter 10Fig. 10.1 Jet stream.Fig. 10.2 Average wind power density [1].Fig. 10.3 Different types of kites.Fig. 10.4 Buoyant Airborne Turbine.Fig. 10.5 Vertical axis high altitude wind turbine.Fig. 10.6 Tether designed for high altitude wind power generation with two power...Fig. 10.7 Relative flow conditions at the origin O, an arbitrary point T along t...Fig. 10.8 Ground-based power generation.Fig. 10.9 Pumping cycle with reel-out stage (top) and reel-in stage (bottom) [29...Fig. 10.10 Converter topology in the airborne unit for ABM supported on board po...Fig. 10.11 HAT in low intermittent wind.Fig. 10.12 Production cost [33].Fig. 10.13 Global distribution of the wind power density on 1 December 2014 9:00...Fig. 10.14 Overview of major companies [34].Fig. 10.15 GIS map of wind power in period I, 30 m.Fig. 10.16 GIS map of wind power in period II, 30 m.Fig. 10.17 The overall GIS map of wind power for the center of Iran, 30 m.Fig. 10.18 Wind power density averaged over a 20-year time span across various p...Fig. 10.19 Absolute wind velocities averaged over a 20-year time span across var...Fig. 10.20 Wind power density averaged by month from 2010 to 2013 to a height of...

11 Application 1Fig. Ap1.1 Rotor IAT21 L3.Fig. Ap1.2 Parameters of rotor.Fig. Ap1.3 Flow around the blade.Fig. Ap1.4 2D rotor grid IAT21 L3.Fig. Ap1.5 Instant speed distribution near rotor (Ω=500 rpm).Fig. Ap1.6 Instant speed distribution (Ω=500 rpm).Fig. Ap1.7 Instant pressure distribution (Ω=500 rpm).Fig. Ap1.8 Dependence of rotor thrust on rotation speed.Fig. Ap1.9 Dependence of rotor power on speed of rotation.Fig. Ap1.10 Geometric parameters and airfoil motion pattern.Fig. Ap1.11 Computational grid.Fig. Ap1.12 Average speed (m/s).Fig. Ap1.13 Instantaneous speed (m/s).Fig. Ap1.14 Horizontal force (N).Fig. Ap1.15 Vertical force (N).Fig. Ap1.16 Moment (N m).Fig. Ap1.17 Typical pressure field at the moment of jet outflow, Pа.Fig. Ap1.18 The typical velocity field at the moment of the jet outflow, m/s.Fig. Ap1.19 Horizontal force.Fig. Ap1.20 Vertical force.Fig. Ap1.21 Мoment.Fig1. Ap1.22 Moment [4].Fig. Ap1.23 Typical pressure field at the moment of jet outflow, Pa.Fig. Ap1.24 Typical velocity field at the moment of jet outflow, m/s.Fig. Ap1.25 Horizontal force (only aerodynamic component - on the left, with the...Fig. Ap1.26 Vertical force (only aerodynamic component - left, with the addition...Fig. Ap1.27 Moment (only aerodynamic component) - on the left, with the addition...Fig. Ap1.28 Typical pressure field at the moment of jet outflow, Pa.Fig. Ap1.29 Typical velocity field at the moment of jet outflow, m/s.Fig. Ap1.30 Horizontal force (aerodynamic component only) - on the left, with th...Fig. Ap1.31 Vertical force (aerodynamic component only) - on the left, with the ...Fig. Ap1.32 Moment (aerodynamic component only) - on the left, with the addition...Fig. Ap1.33 Typical pressure field at the moment of jet outflow, Pa.Fig. Ap1.34 Typical velocity field at the moment of jet outflow, m/s.Fig. Ap1.35 Horizontal force (aerodynamic component only) - on the left, with th...Fig. Ap1.36 Vertical force (aerodynamic component only) - on the left, with the ...Fig. Ap1.37 Moment (aerodynamic component only) - on the left, with the addition...

1 Cover

2 Table of Contents

3 Title Page

4 Copyright

5 Preface

6 Begin Reading

7 Application 1

8 Index

9 Also of Interest

10 End User License Agreement

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