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| United States Patent Application |
20110109096
|
| Kind Code
|
A1
|
|
Earley; Matthew
|
May 12, 2011
|
Fixed pitch wind (or water) turbine with centrifugal weight control (CWC)
Abstract
The Fixed Pitch Wind (Water) turbine is a more productive system than
current technology in that it extracts increasing amounts of energy from
wind (or water) flows throughout typical operating ranges (25 m/s for
wind and 3.4 m/s for tidal). Further, an inherently stronger fixed pitch
solution can have greater blade solidity that will, in turn increase
torque across the entire operating range.
Extending the low speed shaft brings major and heavy system components to
the tower base (for wind) or above water line (tidal) for reduced cost,
both initially and on an ongoing basis.
The weight control system acts as a buffer for energy storage that will
accommodate gusty or turbulent conditions and also facilitate gear
changes as the speed of the rotor changes.
| Inventors: |
Earley; Matthew; (Allenwood, NJ)
|
| Family ID:
|
43973596
|
| Appl. No.:
|
12/925235
|
| Filed:
|
October 18, 2010 |
Related U.S. Patent Documents
| | | | |
|---|
|
| Application Number | Filing Date | Patent Number |
|---|
| | 61280606 | Nov 6, 2009 | |
|
|
| Current U.S. Class: |
290/55 |
| Current CPC Class: |
Y02E 10/20 20130101; F03B 17/061 20130101; Y02E 10/30 20130101; Y02E 10/72 20130101; F03D 7/0276 20130101; F03D 9/25 20160501 |
| Class at Publication: |
290/55 |
| International Class: |
F03D 9/02 20060101 F03D009/02 |
Claims
1. A wind (water) turbine power generating assembly comprising: a fixed
pitch blade/rotor assembly; an extended low speed shaft with 1:1 gearbox
for 90.degree. turn; a centrifugal weight control assembly; a clutch and
transmission assembly in lieu of traditional gearbox; an assembly at the
tower base including CWC, transmission, and generator(s);
2. Apparatus as set forth in claim 1; wherein increasing amounts of power
will be generated in the 15 to 25 m/s range for wind and the 2.4 to 3.4
m/s range for tidal (bi-directional flow); wherein optimized tip speed
ratio can be maintained for the entire operating range of the flow (wind
or water).
3. Apparatus as set forth in claim 2; wherein initial build and ongoing
operational and maintenance costs will be significantly less than current
technology.
Description
[0001] This non-provisional application does reference and claim benefit
of an earlier provisional application having an Nov. 6, 2009 filing date
and application No. 61/280,606.
BACKGROUND OF INVENTION
[0002] The invention incorporates a unique and patented means of
controlling rotor speed and is in lieu of traditional aerodynamic
solutions (pitch or stall). In current systems pitch or stall in
conjunction with generator torque is the typical solution for speed
control. In the proposed system the weight scheme in conjunction with
generator torque will control rotor speed.
BRIEF SUMMARY OF INVENTION
[0003] The fixed pitch rotor and centrifugal weight control will permit
the generation of increasing amounts of energy for the full distribution
of operating speeds in both wind and water scenarios. Current technology
captures and transforms less than half of the energy content available in
the discussed distribution. In wind, operating speed is typically up to
25 m/s though rated power is typically reached at 14 or 15 m/s. In water,
highest flow rate is typically 3.4 m/s though rated power is usually at
2.4 m/s. The table in FIG. 6 shows a 20-year projection for a 36-meter
system with power totals at 15 m/s for current solution and 25 m/s for
the discussed solution.
[0004] Further, this same weight control scheme permits use of a
transmission (in lieu of gearbox). In so doing the rotor can continue to
increase speed (rpm's) in an increasing flow (wind or water) while
generator speed can be held constant via gear ratio reductions offered by
the transmission.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS AND TABLES
[0005] FIG. 1 Fixed Pitch Wind Turbine w/CWC
[0006] FIG. 2 Fixed Pitch Water Turbine w/CWC
[0007] FIG. 3 CWC System/Wind Implementation
[0008] FIG. 4 CWC Storage Calculations
[0009] FIG. 5 Nacelle top down view
[0010] FIG. 6 Power/Energy Tables
DETAILED DESCRIPTION OF THE INVENTION
[0011] This fixed pitch wind (or water) turbine makes use of a patented
(U.S. Pat. No. 6,949,842) control solution know as "Centrifugal Weight
Control"--or CWC. Such an implementation presents an opportunity to
extend the low speed shaft down the length of the tower (wind turbine) or
up above the water line (water turbine). See FIGS. 1 & 2 respectively.
[0012] In the wind implementation, extending the low speed shaft down the
length of the tower also means you can move other major components down,
including generator and gearbox. Doing so results in several compelling
advantages as outlined below: [0013] Significant reductions in top head
mass (weight at top of tower) can be realized. [0014] Moving the
generator(s) to the base of the tower permits the use of a larger,
heavier and less costly generator product. [0015] At the base of the
tower available space will accommodate a generator(s) having a greater
number of pole pairs. [0016] The need for lightweight technology
employing rare earth elements will no longer be necessary. [0017] More
pole pairs in the generator will permit lower gear ratios in the gearbox
(or transmission). [0018] Economies in the built phase and ongoing
operation and maintenance of the system will be realized. [0019] An
inherently stronger fixed pitch solution will accommodate increases in
blade solidity. Solidity increases equate to increases in torque that, in
turn equate to increases in power.
[0020] Employing CWC (in lieu of pitch or stall solutions) in conjunction
with induction generator torque, enables on demand control of necessary
amounts of opposing torque to manage rotor speed in gusty and increasing
wind speeds through cut-out . . . typically 25 meters per second. The sum
of opposing torques found in full extension of weights and generator(s)
at rated power must be greater than rotor torque at 25 m/s.
[0021] CWC will dampen and temporally store energy. FIG. 4 demonstrates
storage capability of CWC with eight weights (each at 1000 lbs). Such
temporary storage will relieve stresses currently known to damage
gearboxes. Downtime and costly repairs or replacement can be avoided.
[0022] Under program control CWC will be used in response to two recurring
operating conditions: [0023] In response to wind gusts or turbulent
flows (water), the plurality of weights on jackscrews in conjunction with
generator torque will be employed to control rotor speed through 25 m/s
(3.4 m/s water). Generator torque will increase only at a rate that the
gearboxes can easily tolerate. This parallel extension of weights and use
of generator torque will assure control of rotor speed and its rate of
increase. When adequate control is achieved generator torque will be
further increased to take additional energy from what is stored in the
extended weights and accordingly the weights will retract. [0024] CWC
will control rotor speed while gear changes occur. CWC will temporarily
displace generator torque (during disengagement) while the clutch
operates for gear change.
[0025] In both wind and water implementations the CWC configuration is
horizontal (perpendicular to vertical low speed shaft). A rotating and
circular guide/sled on roller bearings will be necessary to carry the CWC
weights as they extend or retract for routine operation. See FIG. 3.
[0026] In the wind implementation stopping/parking the rotor at cutout
will employ both yaw and conventional brakes.. In the water
implementation yaw may be used to reduce load, but braking to overcome
rotor forces will not be employed. When flows in excess of 3.4 m/s are
encountered the rotor and low speed shaft will disengage from generator
(via clutch) and weights will fully retract. Rotor will turn freely until
normal operating conditions return.
[0027] In both wind and water implementations a vertical chassis integral
to tower or monopile, will be necessary to carry vertical and lateral
loads of the low speed shaft.
[0028] Clutch operation for gear changes will be under program control.
This control will extend or retract weights to control rotor speed and
manage generator speed while disengaged to accommodate a gear change.
Gear changes will routinely occur to maintain desired generator rpm's
across the distribution of operating wind speeds. Same control will be
applied to the water turbine.
[0029] Centrifugal weight control, fixed pitch, an extended low speed
shaft and transmission distinguish the discussed solution from present
day wind and water turbines.
* * * * *
