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Specialization in Ocean Energy MODELLING OF WAVE ENERGY CONVERSION

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1 Specialization in Ocean Energy MODELLING OF WAVE ENERGY CONVERSION
António F.O. Falcão Instituto Superior Técnico, Universidade de Lisboa 2018

2 MODELLING OF OWC WAVE ENERGY CONVERTERS
PART 4 MODELLING OF OWC WAVE ENERGY CONVERTERS

3 Basic approaches to OWC modelling
will be analized here

4 Basic equations Volume flow rate of air displaced by OWC motion
Decompose into excitation flow rate radiation flow rate

5 air compressibility effect
Basic equations air compressibility effect

6 Thermodynamics of air chamber
Assume compression/decompression process in air chamber to be isentropic (adiabatic + reversible). This implies perfectly efficient air turbine.

7 X Aerodynamics of air turbine
Dependence on Mach number Ma in general neglected, because of scarce information from model testing. X

8 Frequency domain analysis
Linear turbine Linear relationship air density versus pressure Linearize: Wells turbine

9 Frequency domain analysis
The system is linear Decompose Note: radiation conductance G cannot be negative

10 PICO OWC PLANT, AZORES, PORTUGAL

11 Frequency domain analysis
(deep water) Axisymmetric body (deep water)

12

13 If the inner free surface is approximately flat, then there is a relationship between A, B, G, H, Fe and Qe

14 Frequency domain analysis
Power Power available to turbine = pressure head x volume flow rate Regular waves Time average

15 Can be rewritten as: For given OWC and given incident regular waves, Qe and G are fixed.

16 Frequency domain analysis
Power Turbine power output Wells turbine

17 Exercise Consider the Pico OWC plant. Air chamber volume V0 = 1050 m3 . Compute the average power absorbed from regular waves of period 10 s and amplitude 1.0 m. Compute approximately D and W for the Wells turbine Pico plant

18 Pico plant

19 Wells turbine with guide vanes

20 Turbine efficiency

21 Turbine power

22 Turbine flow rate versus pressure head

23 Time-domain analysis of OWCs
The Wells turbine is approximately linear. So frequency-domain analysis is a good approximation. Other turbines (e.g. impulse turbines) are far from linear. So, time-domain analysis must be used, even in regular waves. This affects specially the radiation flow rate, with memory effects. The theoretical approach is similar to time-domain analysis of oscillating bodies.

24 radiation flow rate memory function

25 MODELLING OF OWC WAVE ENERGY CONVERTERS
END OF PART 4 MODELLING OF OWC WAVE ENERGY CONVERTERS

26 Additional Exercise 5

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