The present invention relates generally to a wind turbine system for generating electricity and more specifically to a wind turbine system for generating electricity that includes two up-wind rotors and one down-wind rotor structure.
Existing large scale wind turbine systems for utilizing wind energy to generate electricity have certain disadvantages.
For example, when the diameter of a wind turbine rotor exceeds twelve (12) meters, the wind input at its center has no effect on the rotation of the rotor thereby creating “an aerodynamic dead zone.” Accordingly, a large scale wind turbine system has its corresponding large aerodynamic dead zone.
Another disadvantage involves the coupling the rotational forces of two or more rotors with different RPMs, where the force generated is limited by the gear ratio of each rotor's RPM and the total rotational force is decreased by the drag force created between the rotors of different tip speed rotor.
Furthermore, when the input wind speed is above the rated wind speed, a mechanical stress can be created that exceeds the point where the wind turbine system can operate safely without breaking.
Another challenge to a developer of a wind turbine system is avoiding aerodynamic interference between the counter-rotating rotors.
Accordingly, it is an object of the present invention to provide an improved wind turbine system for generating electricity.
Another object of the present invention is to provide a high speed small control rotor placed in front of auxiliary rotor in an up-wind position to create an aerodynamic dead zone-less system.
The control rotor increases the rotational speed of both auxiliary rotor in the up-wind position and main rotor in the down-wind position during low wind speed as well as during rated wind speed.
Another object of the present invention is to provide a flexible electromagnetic torque coupling where the rotational force of two or more rotors of different RPM is not limited by the gear ration of the RPMs of each rotors.
When the tip speed ratio of each rotors are different, rotation of one rotor acts as a drag force on each other thereby decreasing the total rotational force. Coupling of electromagnetic torque of the current invention is flexible and is not dependent on the gear ratio of the rotors and the drag force created by the different tip speed is avoided.
Further, the present invention is can operate under variable system capacity (i.e. variable load) corresponding to different input wind energy.
The variable system capacity improves the generators efficiency through the load share ratio of a large-sized generator in accordance with the magnitudes of the energy caused by the variation of input wind speed.
Other objects and the scope of applicability of the present invention will become apparent from the detailed description given hereinafter. It should be understood, however, that the detailed description and the specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art from this detailed description.
The present invention will become more fully understood from the detailed description given herein below and the accompanying drawings which are given by way of illustration only, and thus are not (imitative of the present invention, and wherein:
Part 4 comprises of twin generators 4, 4-1. Part 5 comprises of the auxiliary generator 5 which combines rotational forces of CR 81 and AR 71. Part 6 comprises of dual axis input gear box 6 which combines the rotational forces of CR 81 and AR 71. Part 7 comprises of CR hub 7 and AR hub 8 in a up wind position.
A wind turbine obtains its power input by converting the force of the wind into a torque on the rotor blades. The amount of energy which the wind transfers to the rotor depends on the density of the air, the rotor area, and the wind speed.
The kinetic energy of a moving body is proportional to its mass or weight. The kinetic energy in the wind thus depends on the density of the air. In other words, the “heavier” the air, the more energy is received by the turbine.
At normal atmospheric pressure and at 15 Celsius air weighs some 1.255 kg per cubic meter. The greater the diameter of a wind turbine rotor, the greater the effect of tip speed to limit and reduce revolutions per minute (“RPM”). This creates an “aerodynamic dead zone” in part of the hub where no lift force is generated due to its low RPM.
More specifically, the aerodynamic dead zone is about 30% of the blade from the center axis, which no wind energy can be converted into mechanical energy.
Fast spinning CR 81 is placed directly in front of AR 71 blade extender hubs so that the wind inputs into this aerodynamic zone of the AR blades extenders is diverted outside of the dead zone thereby increasing the air density and directing this increased air density to the tips of the AR blade where the sweeping speed is the greatest.
This phenomenon depends on the diameter of CR 81, the distance between CR 81 and AR 71, the diameter of AR 71, and the distance between AR 71 and MR 11. This phenomenon has been tested and proved numerous times with smaller model in a experimental field tests as well as actual sized scaled model field tests.
When there is wind speed 1.8-2.2 m/s, CR 81 rotates in the direction as shown in
Then in FIG 7, this rotational force of CR 81 further extends and rotates rotational shaft 76 and spline coupling 76-1. This rotational force is transferred then to the CR-AR dual axis input gear box 6 where it rotates the input rotation shaft 66 and the Input member planet gear carrier 67.
As shown in
As CR 81 starts to rotate the second sun gear 62-2 attached to the input member planet gear carrier 67 also rotates. This sun gear 62-2 rotation will cause to counter rotate the second ring gear 62-4 which is attached to the second ring gear cylinder 62-5. Since the second ring gear cylinder 62-5 is coupled to AR 71, CR 81 rotation will eventually make AR 71 rotating in the opposite direction of CR 81.
Hence, the rotational force of CR 81 transfers to AR 71 adds to the direct natural wind input and assist AR 71 rotate more easily. The inverse rotational forces of these two rotors CR 81 and AR 71 creates the air stream tube 105 as shown in
As shown in
CR 81 Input RPM: N1 X {1+(ZR1/ZS1)} (1)
AR 71 Input RPM: N2 X (ZR2/ZS2) (2)
Total RPM of Sun Gear output shaft 61-1:
Tn1n2=[N1 X {1+(ZR1/ZS1)}]+N2 X (ZR2/ZS2) (3)
ZS1: number of first sun gear teeth
ZS2: number of second sun gear teeth
ZR1: number of first ring gear teeth
ZR2: number of second ring gear teeth
Above equation (1) only applies when the RPMs of the sun gear 61 and the ring gear 63, and the input torque are same. Based on the characteristic of dual axis gearbox 6, the larger torque AR 71 s rotational speed and CR 81 s rotational speed are determined by the the gear ratio of the second sun gear 62-2 and the second ring gear 62-4.
In order to make CR 81 and AR 71 s tip speed ratio the same, the size of the CR 81, and the gear ratio of the second sun gear 62-2 and the second ring gear 62-4 are adjusted so that the speed of AR 71 rotation is optimized to increase the efficiency of the system at the dual axis inputs gearbox 6.
However, since CR 81 performs the pitch control at the wind speed greater than the rated wind speed, rotational speed of CR 81 acts as a drag force on the rotational speed of AR 71 through the second planetary gear assembly shown in
This slows down the rotational speed of the rotor 53 of auxiliary generator 5, and weakens the electromagnetic torque of the rotating stator 51 thereby decreasing the rotational speed of the MR 11 allowing the overall system to operate more safely.
The rotational force of CR 81 and AR 71 combined at the dual axis inputs gearbox 6 is transferred via the high speed output shaft 61-1, the connection plate 62-6, and the connection plate 59-1 of the auxiliary generator 5 to the rotor 52 attached to the rotor shaft 53 thereby rotating the rotor 52 clockwise as shown in
Then the electromagnetic coupling torque of the load is created. This causes the slow rotating stator 51 that is rotating in the same direction as the high speed rotating rotor 52 to rotate in the same direction, thereby increasing the rotational speed of the MR 11.
This mechanism is summarized as follows:
Torque of CR 81+Rotational Torque of AR 71=generation power of the auxiliary generator 5
Electromagnetic torque from the load between the rotor 52 of the auxiliary generator 5 and the rotation stator 51+rotational torque of MR 11=generation power of the twins generators 4, 4-1
The general principle behind the generators is based on the rotational force created between the stator and the rotor. Energy is generated when one or other rotates or when they rotate in opposite direction to one another.
However, the generator of the present invention generates energy even though both the rotor and the stator are rotating in the same direction. The number of poles of auxiliary generator has a prescribed RPM's.
It is the difference of this prescribed RPM's in effect acts as though either the stator 51 or the rotor 52 is in a fixed position thereby generating energy. If the RPM of the rotor 52 is defined as V1, RPM of the stator 51 rotating in same direction is defined as V2, and the prescribed RPM of the number of poles of the auxiliary generator 5 is defined as V0:
V0=V1−V2 (4)
RPM of V2 is accelerated by predetermined number of rotation of MR 11's gearbox 2. This RPM V2 inputs to a horizontal input shaft 39 of CR-AR rotational force combining gearbox 3 which is coupled to the rotation stator 51. The energy generated from the auxiliary generator 5 is drawn out by the slip ring 54. And this energy also rotates the bearings 58, 55 which are mounted on the drive train pad 17 of the auxiliary generator 5.
Rotational force generated by MR 11 and rotational force generated by the electromagnetic coupling torque created between rotor 52 and stator 51 of the auxiliary generator 5 by the load combined at the gearbox 3. As shown in
In
Such sun gear and planetary gear assembly is known from the Applicant's U.S. Pat. No. 5,876,181, the contents of which are hereby incorporated in their entirety.
In
Further, the bevel gear 38 is attached to the planet gear input shaft 36 on each twin planetary gear system. In each twin planetary gear system, the planet gear carrier 36-1, the ring gear cylinder input shaft 35 and the ring gear cylinder 35-1 are attached to the ring gear 33.
The ring gear 33 rotates in the opposite direction to the planet gears 32 as indicated by the arrows as shown in
Z0={(1+ZR/ZS)+(ZR/ZS)}X n (5).
Z0 is the total output RPM
ZS is the number of sun gear teeth
ZR is the number of ring gear teeth
n is the input RPM
The sun gear 31 accelerated to the rated output RPM rotates the output shaft 34, thereby rotating the twin generators 4, 4-1. The gearbox 3 is a twin planetary gearbox system with symmetrical gearbox on either side of horizontal input shaft 39.
The rotational forces of MR 11, AR 71 and CR 81 are combined at this horizontal input shaft 39. Depending on the variable forces of the input wind energy, one or both generators can be operated.
When the input wind energy from cut-in wind speed is up to 10 m/s, about 60% of the full system is operated where the auxiliary generator 5 and the twin generator 4 operates. When the wind speed ranges from 10.1 m/s to rated wind speed of 12 m/s, the twins generator 4-1 is added to the auxiliary generator 5 and the twin generator 4.
Accordingly, the present invention includes the auxiliary generator's electromagnetic coupling torque, the triple rotor-irtegrating force, and aerodynamic dead zone-less wind power generating system, thereby increasing the system's potential capacity to a maximum degree and providing high efficiency aerodynamic operation.
No doubt many other effective alternatives will occur to the skilled person. It will be understood that the invention is not limited to the described embodiments and encompasses modifications apparent to those skilled in the art lying within the sprit and scope of the claims appended hereto.
This application claims the benefit of U.S. Provisional Application No. 61/353,679 filed Jun. 11, 2010, which is incorporated herein in its entirety.
Number | Date | Country | |
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61353679 | Jun 2010 | US |