EE 742 Chap. 7: Wind Power Generation. Y. Baghzouz

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Transcription:

EE 742 Chap. 7: Wind Power Generation Y. Baghzouz

Wind Energy 101: See Video Link Below http://energy.gov/eere/videos/energy-101- wind-turbines-2014-update

Wind Power Inland and Offshore

Growth in Wind Energy Production

Installed Wind Capacity by Country (MW)

US Wind Resource Map

Wind Turbines Horizontal axis wind turbines (HAWT) are the most popular - compared to vertical axis wind turbines (VAWT). 3 blades used to minimize power pulsations (if < 3) and aerodynamic interference (if > 3). The aerodynamic blades produce a lift force along the blade which produces a mechanical torque on the turbine shaft.

Wind and Turbine Power Power of the wind: P w = (1/2)ρAv w 3 Where ρ is the air density, A is turbine sweep area, and v w is the wind speed. Power extracted by the turbine: P t = c p P w where c p is the turbine performance coefficient. The theoretical maximum value of c p (derived from the conservation of mass and energy) is 16/27 60%. In practice c p is less than the above value and its varies with the tip speed ratio: λ = ωr/v w where ω is the rotor speed r is the rotor radius and v w is the wind speed.

Turbine Power A typical c p - λ curve is shown below and is unique to a particular turbine design. Modern wind turbine design can reach 70-80% of the theoretical limit. To extract maximum power, the turbine must be operated at the peak of the curve (peak power tracking). For a given wind speed v w and the c p - λ characteristics, the turbine power can be calculated as a function of shaft speed.

Turbine Power For a given turbine c p, the turbine power can be graphed as a function of the wind speed as shown below. The figure shows the cut-in speed (around 3-4 m/s), rated speed (around 12.5 m/s), and shut down speed (around 25 m/s). Turbines are typically designed to withstand wind speeds of up to 50 m/s (180 km/hr)

Power control Some form of power control at high wind speeds is needed so that the turbine does not exceed its rated speed. Two methods are available: Passive stall control normally used on fixed speed machines. In here the turbine blades are designed so that the lift force on the blades reduces and the blade progressively goes into stall with increased wind speed. Active pitch control - in here, the pitch of the blade is changed to reduce the output power (requires feedback control signal such as rotational speed) See typical output power for fixed speed turbines (with passive stall control) and variable speed turbines (with active pitch control) below: Pitch control vary angle of attack

Average Power in the Wind The average power in the wind is proportional to the average of the cube of the wind velocity, not the cube of the average wind speed. P avg 1 2 1 2 3 3 ( Av ) avg A( v ) avg A( vavg Example: Calculate the cube of the average value and the average of the cube of the wind if v( t) V sin t M 1 2 ) 3 Ans: 8 4 3 3 3 3 3 3 3 ( vavg ) V 0.26, ( ) 0.42 3 M VM v avg VM VM

Diameter and operating speeds of various wind turbine sizes (assuming rated speed of 12.5 m/s)

Wind annual distribution (with MAWS = 7 m/s) and annual energy yield by a 60 m diameter turbine (with rated speed of 12.5 m/s)

Hourly wind speed variation over 1 year is Las Vegas (average wind speed: 4.9 m/s)

Capacitor Factor Capacity factor of a wind power generator is defined as for a site with a MAWS of 7 m/s, c f is around 30%. for a site with a MAWS of 5 m/s, c f is about 12%.

Wind intermittency: most important issue Source: NREL

Generator configurations Synchronous generator (not practical fixed speed) Fig. 7.5 squirrel cage induction generator (energy capture cannot be maximized due to nearly fixed speed range) Fig. 7.6

Generator configurations Wound rotor induction generator (limited speed range) Fig. 7.7 Squirrel cage induction generator with fully rated converter (wide range) Fig. 7.8

Generator configurations Doubly-fed induction generator (partially rated converted) speed limit (30%) Fig. 7.9 Permanent magnet generator with fully rated converter (wide range) Fig. 7.10

Generator configurations Wound field generator with fully rated converter (wide range) Generator Options: Fig. 7.11

Induction motor equivalent circuit

Torque-speed curve Mechanical power delivered to the shaft: Mechanical torque:

Power flow in an induction machine If the losses in the stator winding resistance and iron cores are neglected, then the power supplied by the grid is the same as that supplied to the rotor. In the figure below, the directions are shown as positive for motor action (slip s is positive). for generator action (slip s is negative), P m and P s reverse direction, while the rotor loss remains unchanged

Induction generator coupled to the grid A synchronous generator is stiffly coupled to the network wind turbulence can cause large stress on the drive shaft. An induction generator, on the other hand, is softly coupled to the network as a it allows relative movement of the shaft speed. For small slip values, the machine torque is proportional to speed deviation (this is analogous to a mechanical damper):

Induction generator coupled to the grid Refer to the equivalent circuit of an induction generator connected to a distribution line through a transformer (incorporate X s and X T into X 1, and R s into R 1 ) The induction machine torque-slip curve determines the steady-state stability limit. The maximum (pull-out) torque determines the steady-state stability limit.

Induction generator coupled to the grid The maximum torque depends on X 1 (including the system reactance) and supply voltage V s : A stiff system (i.e., small X s ) results in larger max. torque A weak system (i.e., large X s ) results in a smaller max. torque A drop in supply voltage results in a sharp drop in max. torque A larger rotor resistance does not affect the max. torque, but increases the slip at which the max. torque occurs.

Induction generator with external rotor resistance This method allows and increase in speed variation. The rated torque and current are the same, but this occurs at a different slip values. The gain in energy capture obtained by allowing more speed variation should be balanced against reduced efficiency.

Doubly-fed induction machine (DFIM) The 4-quadrant converter can feed power to or form the rotor at any frequency or voltage. The grid-side inverter is controlled to maintain constant DC link voltage The rotor-side inverter inject a voltage into the rotor winding (at slip frequency) that is controlled in both magnitude and phase.

DFIM Equivalent Circuit If the injected voltage is in phase with the rotor current, this is equivalent to adding a resistance R ext to the rotor (= V s /I 2 ). The rotor current and mechanical torque can be derived as before. The slip can be written in terms of the injected voltage as

DFIM Equivalent Circuit If the stator winding losses are neglected, the power supplied to the machine is approximated by The second term depends on the polarity of the injected voltage (extracted from or delivered to the rotor ) Further, if the rotor winding resistance is neglected, the P g = P m. (i.e., 100% efficiency)

DFIM as a synchronous generator In a SG, the DC current is fed in the rotor circuit to produce the synchronously rotating field. In the DFIM current is fed in the rotor circuit at slip frequency in order to produce the synchronously rotating field. The voltage across the magnetizing reactance can be written as where Note that the equivalent circuit of a DFIM now resembles that of a SG. Both the magnitude and phase of I 2 (hence of E) by controlled by the injected voltage V s in the rotor winding.

Phasor diagram of a DFIG as a SG I 2 fully controls the magnitude and phase of E (while the field current in a SG controls only the magnitude of E). Machine complex power: I 2a controls P I 2b controls Q

Rotor current components in terms of P and Q: Control strategy of DFIG

Fully rated converter systems The machine-side converter is generally operated to control the generator torque loading at a particular speed (for max power) while the grid-side inverter is operated to control reactive power and maintain constant DC bus voltage.

Peak power tracking sudden change in wind speed

Fault behavior of induction generators Fixed speed induction generators consume reactive power (detrimental to voltage recovery). They are disconnected from the grid as soon as a voltage drop is detected. If they remain connected, then they become unstable if the fault duration is greater than t 2 (see figure to right). Variable speed induction generators can generate reactive power (beneficial to voltage recovery) are required to ride through the fault so that they can contribute to system stability (but with complex control of the power converters).

Wind intermittency: Important Issue Source: NREL

Largest wind turbine generators to date: Manufacturer: Enercon Rated power: 6 MW, Rotor diameter: 126 m, Total height; 198 m. Manufacturer: Mitsubishi Rated power: 7 MW, Rotor diameter:? Total height; 220 m.

Wind Power in Nevada: Spring Valley Wind (Pine County): 152 MW

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