Download - Phase Control Techniques and their implementation on Wave Energy Converters Torkel Bjarte-Larsson
Phase Control Techniques and their implementation on Wave
Energy Converters
Torkel Bjarte-Larsson
CeSOSNorwegian University of Science and Technology NTNU
Trondheim, Norway
Outline• Practical implementation
– Resonance turning– Continuous control: Reactive
– Discrete control: Latching
• Phase control: Physical explanation• Electric analogy (reactive)• Mathematical condition (reactive)• Numerical results for wave-power absorption by
heaving semisubmerged sphere.• Power conversion by laboratory model.
Two conditions for absorbing maximum power
• The oscillation velocity must be in phase with the excitation force.
• The amplitude of the oscillation must be adjusted to the optimum value. (The absorbed power is equal to the power reradiated into the sea).
Resonance turning• The natural period of
the device should at all times be turned to the period of the wave.
• Changing the mass of the oscillating body by pumping water in and out of ballast tanks.
• The buoy reacting against an internal mass by stiffness modulation.
Smm
T r 20
Continuous control• During the mid 1970s it was purposed independendently by Salter
and by Budal to apply control engineering for optimising the oscillatory motion of a wave-energy converter in order to maximise the energy output.
• For the practical implementation it was proposed to use a controllable power take-off device, for instance a combined generator-and-motor or turbine-and-pump.
• Reference: • Budal, K. And Falnes, J., 1977. Optimum operation of improved wave-power converter.
Marine Science Communications, Vol 3, pp 133-150.• Salter, S.H., Jeffery, D.C., and Taylor, J.R.M., 1976. The architecture of nodding duck
wave power generators. The Naval Architect, pp 21-24
Continuous control
• The energy used by the motor should not be considered as lost, since it has been used so that the converter is able to produce more energy in the future (later in the wave period).
Continuous control of double acting piston
This system allows continuous control of the velocity of the piston.
But requires that the motor/pump is able to handle a very large flow.
Hydraulic power take-off for latching control
Electromagnet for latching and hydraulic power take-off
• Hydraulisk pumpe benyttes for energiuttak
• Låsemekanismen for fasestyring består av jern skinner som går gjennom luftgapet til en elektrisk magnet.
PICT0015.JPG
t
Optimal phase at resonance
Phase control by latching
or by reactive control
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Wave and heave motion of power buoy
Phase control and amplitude control
• Instead of the terms phase control and amplitude control the terms reactive control and load control are used.
• Amplitude control is also termed resistive control.
• When both phase and amplitude of the oscillation are controlled, the term complexconjugate control is also used.
• Optimum control include both phase control and amplitude control.
Nilsson & Riedel Electric Circuits:
• The apparent power, or volt-amp,requirement of a device designed to convert electric energy to a nonelectric form is more important than the average power requirement. Although the average power represents the useful output of the energy converting device, the apparent power represent the volt-amp capacity required to supply the average power.
Accumulation of energy by oscillating body.
reactive controllatching controlno control (passive)
By reactive control, energy flow through the conversion machinery has to be reversed during part of the wave cycle.
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Theoretical (numerical) study of heaving semi-submerged sphere
Diameter 2a = 10 m smax = 0.6 a = 3 m
Natural heave period = 4.3 s6EWTEC 2005-08-31 TB-L&JF/NTNU
Absorbed power (MW) from wave of period T = 9 s
Amplitude (m) of incident wave
latching
Example: A = 0.5 m:
Preact = 172 kWPlatch = 137 kWPpassiv = 24 kW
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Average slope:
Preact = 172 kW
Platch = 137 kW
Ppassiv = 24 kW
A = 0.5 m, T = 9 s
Absorbed energy Curve slope = instantaneous power
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Heaving buoy.
Cylinder with hemispherical bottom.
Arranged to slide along a vertical strut.
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Heaving buoy of diameter 0.14 mand natural heave frequency 1.1 Hz,tested in a wave channel 0.33 m wide.
Power take-off by piston pump lifting water to an elevated reservoir.Two vertical rails may be latched by twoelectromagnets on the lower fixed platform.
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Relative absorbed power and useful power without and with phase-control
versus heave/wave amplitude ratio
absorbed
useful
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Amplitude ratio |s/A| decreases by increasing the load (increasing the pump head). Curves are fits to a mathematical model.
Concluding remarks.
• Compared to reactive control, latching control is slightly sub-optimum, but avoids the necessity for reversing the power flow.
• The relative benefit of applying control (reactive or latching) is strongly dependent upon the width of the resonance curve, that is, upon the size of the oscillating body compared to the wavelength.
• The model experiment demonstrates the need for developing a guiding system with less friction.
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THE END
6EWTEC 2005-08-31 TB-L&JF/NTNU
Outline:• Phase control and amplitude control
• Reactive control (optimum) and latching control (sub-optimum).
• Numerical results for wave-power absorption by heaving semisubmerged sphere.
•
• Heaving vertical cylinder:
• Hydrodynamical parameters approximated.
• Power conversion by laboratory model.
• Concluding remarks.6EWTEC 2005-08-31 TB-L&JF/NTNU
10.15m
3.65m
3.3m
0.3m
4m
Sketch of the floating wave-energy converterrounded edge geometry
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Water depthh = 25 m
Radiation resistance versus frequency in normalised units.
numerical (AQUADYN)
limit for = 0
Upper curve: approximate empirical elementary-function deep-water formula.
Lower curve: same formula, but with k = k() for water depth h = 25 m.