Back in the ancient times of 10
or 15 years ago, it wasn’t unusual
for wind turbines to generate
power in the range of tens
or hundreds of kilowatts.
Compared to the power
levels found on the utility
grid, this puny generating
capacity almost
made individual turbines
an afterthought. Utilities
didn’t have to worry
much about grid operations
being interrupted
by problems at a wind
farm.
But wind farms are
getting bigger. The next
generation of multi-megawatt-
scale turbines
start to look less like
quaint curiosities and
more like regular power
plants. That also means
the wind turbines now coming
off the drawing boards must have
the same kind of reliability and
safeguards as conventional power
plants. Their economics must be in
the same ballpark as well.
The latter point is important because
since about 2002, the cost of
wind-powered electricity has not
declined. To that end, wind-turbine
designers are striving to come
up with designs that are both more
economical and reliable.
Enter Clipper Windpower and
its Liberty turbine. The Liberty
sports innovations that include a
distributed generation drivetrain
design (dubbed the Quantum
Drive) and high-efficiency, permanent-
magnet generators. These pair up with a sophisticated control
system that adjusts both rotor
blades and generator operation
to squeeze power even out of light
breezes.
The Liberty design also incorporates
ideas aimed at simplifying the
maintenance of wind farms. For
example, many of its components
are light enough to be winched up
its tower rather than be manhandled
by a mobile crane.
Checking out the Drivetrain
The meat and potatoes of a wind
turbine are its rotor, gearbox, and
generator. Liberty’s major drivetrain
components illustrate some
of the directions in which windturbine
development is progressing today.
The gearbox cranks up the rotational
speed that the wind rotor
provides. The traditional way
of doing this has been through a
planetary gearbox with three or
four stages of rpm step-up. The
gearbox output shaft turns the
shaft of a generator. The generator
connects to the utility grid through
conversion circuits that change the
ac it generates to dc, and finally to
ac synchronized with the grid frequency.
A transformer then boosts
the output to about 30 kV for insertion
onto the grid.
Traditional wind turbines configured
this way have drawbacks
that become apparent in machines
big enough to generate more than about
a megawatt. Generators and
gearboxes on this scale are large
and heavy. Problems in either of
these two mechanisms can take the
wind turbine off-line, potentially
for a long time. Moreover, windfarm
operators often must bring
in a crane to take heavy generators
and gearboxes out of the wind-turbine
nacelle for maintenance.
One way the Liberty wind turbine
addresses these problems is
by using its gearbox to drive four
smaller generators rather than one
big one. The generators are light
enough to be raised and lowered
with a hoist built into the turbine
structure. And a problem with a
single generator doesn’t take the
whole wind turbine off the grid.
The gearbox driving the generators
has a special patented design
with features aimed at minimizing
the need for maintenance. Unlike
those in most wind turbines, it is
not in a planetary configuration.
Instead, the input shaft from the
turbine blades couples to a pair of
65-in.-diameter bull gears. Four
double-helical pinions engage the
bull gears. On the other end of
each pinion shaft is an intermediate
gear.
The intermediate gears are configured
so they engage four singlehelix
pinions. Each pinion engages
two adjacent intermediate gears.
Thus the gearbox has two
stages. The pair of bull gears and
double-helix pinions make up the
first stage. The intermediate gears
engaging the output pinions on the
output shafts comprise the second.
Helical gears promote smooth meshing. Clipper uses the double-helix
pinions in the first stage for
their ability to cancel out internally
generated thrust loads. But the helices
on the pinions are set at two
different angles. The exact rationale
for using two different helix angles
is proprietary. All Clipper will say
is that due to the double helix,
the net thrust on the intermediate
shaft assembly is zero. Thus, there
is no need for a thrust bearing on
the intermediate shaft. The highspeed
shaft has a net thrust so it is
equipped with a thrust bearing.
Besides providing quiet meshing, use of double-helical teeth
let the gear have a wide face while
loosening up the manufacturing
tolerances. They also have about
half the deflection sensitivity of
spur gearing thanks to the fact
that each face of the doublehelical
system distributes loads
independently.
Also, the two-tooth engagement
of the intermediate gears with output
pinions lets the intermediate
gear transmit twice the torque of
a spur gear’s single-tooth engagement.
The load sharing lets the
gears be smaller than they would
be otherwise. And tooth pressure is
in one direction rather than reversing
so the gears can handle higher
loads than would be the case in
planetary systems.
It is also interesting to note there
are eight load paths in the first
stage and the load is split twice in
the second stage. This contrasts
with planetary systems where
torque typically gets transmitted
in three stages to three planetary
gears, each with two teeth simultaneously
engaged, one with the sun gear, the other with the ring gear.
Thus the load divides into onesixth
the total at each gear mesh.
But in planetary systems, loads
alternate on opposite sides of the
teeth. This effect, plus the need for
a fudge factor to meet life targets,
means the effective load division is
about a factor of four.
Finally, the gearbox includes
features designed to mitigate the vibrational energy that arises from
the transmission error in gear
meshes. Developers specified the
number of teeth so the meshing on
different power paths would be out
of phase, to keep their vibrational
energy from building up. Gear
teeth were optimized for low noise
rather than cost. All in all, these
measures eliminated the need for
rubber isolation mounts on the gearbox that eventually wear out.
New Generators
The generators connected to the
gearbox are different than usual
designs. First consider the typical
wind turbine that is able to produce
power at variable wind speeds.
The generator operates in what’s
called doubly fed mode. According
to Clipper Senior Vice President
of Engineering Amir Mikhail,
the idea was created to get around
limitations of IGBT technology as
it was in the 1990s. “The IGBTs of
the time couldn’t handle as much
power as generators could produce,”
he says. Mikhail is one of the
patent holders on the technique
which is now owned by GE.
The doubly fed generator bleeds
a small bit of ac power off the utility
grid and converts it to a signal that
creates the wound rotor’s magnetic
field at low wind speeds, when the
generator is spinning at below its
synchronous speed. Fast
electronics control the
spinning rotor’s magnetic
field such that the generator
puts out a 60-Hz signal
even when it is turning
slowly. (Above synchronous
speed, the rotor of
doubly fed generators produce
power to the grid.)
Over time, IGBT capacity
has grown, and doubly
fed generation schemes are
no longer necessary. Present-
day IGBT switching
devices can handle the full
output power of the four
670-kW generators in the
Clipper Liberty. Though
many of the generator’s
construction details are
proprietary, Clipper says it uses
a permanent-magnet rotor with
neodymium-iron-boron magnets
for compactness. It is a three-phase
synchronous design and is only
about 3 ft in diameter.
Besides being compact, PM
generators have the advantage of
working at a power factor that is
higher than that of induction generators,
about 98% down to low values of rated power, says Clipper’s
Mikhail. The frequency of the
generator output varies with wind
speed. So rather than being connected
directly to the grid, the generator
output gets rectified to dc.
The dc then is converted to ac synchronized
to the grid frequency.
The converter circuitry does
more than just generate synchronized
ac. It also implements any
necessary power factor correction
and handles what’s called fault ride
through. This capability is mandatory
for large generators on the
grid. It essentially ensures that if
there are faults on the utility grid
that momentarily drop the grid
voltage to zero, the wind turbine
will still try to put out current at
the right phase and frequency.
The technique uses the fact that
grid frequency and phase information
are both still detectable even
when grid voltage is essentially
zero. So the converter watches the
frequency on one phase of the grid
connection, then uses this information
to try driving converter
current onto the grid regardless of
the grid voltage.
A control unit manages the generators
and coordinates the servomechanism
that controls the pitch
of the turbine blades. Its overarching
goal is to optimize the generator
torque and blade pitch to capture
the most amount of energy while
minimizing the mechanical loads.
To do so, it starts with a digitized
map of the power the wind turbine
should put out for a given wind
speed. It then adjusts the actual
power out of the converter to compensate
for mechanical resonances
arising because of compliance in
the gearshafts, blade inertia, and
other factors. Resonances manifest
themselves as repetitive signals in
the rectified dc from the generator.
One factor that comes in handy
for damping out resonances is that
the synchronous generators can
double as tachometers. Generator
speed is one of the inputs factored
into a control scheme for minimizing
resonance effects. Here
the rectified dc from the generator gets passed through a filter
tuned to the resonant frequency
of the main shaft. The resulting
signal is scaled and used as one of
the inputs for controlling power
switches in the inverter producing
the ac for the grid.
Basically the controller looks at
what the power output should be
for the wind conditions, then adjusts
it by controlling the on and
off times of power switches in the
inverter. The amount of power extracted
from the generator affects
the torque on the drivetrain components.
Thus judiciously controlling
the inverter this way can
actively damp out the mechanical
resonances.
Look for Liberty wind turbines
going up in your area soon. The
first prototype went live in 2005.
Clipper says it has gotten orders for
1,530 MW of capacity (612 units)
and joint development/contingent
sale agreements for up to 4,000 MW.
Current customers include BP Alternative
Energy, Edison Mission
Energy, Florida Power and Light,
and UPC Wind.
Make Contact
Clipper Windpower, clipperwind.com
Danish Windpower tutorial on
wind-turbine generators, tinyurl.com/2c87m4
The bull gear
for the Liberty
gear box has a
diameter of 65 in.