Patent Application
20120161497
1. Field of the Invention
This invention pertains to a system and method for a combination of a flywheel and motor/generator(s) contained within a wheel hub used for hybrid vehicle propulsion. The system may be used in conjunction with electric vehicles for an electric-kinetic hybrid vehicle, or used in conjunction with vehicles powered by internal combustion for a fuel-kinetic hybrid vehicle.
2. Description of the Related Art
Traditional electric vehicles and electric hybrid vehicles face the same set of challenges and/or limitations. First, because energy is stored in a chemical form in batteries, which differs from the mechanical, kinetic form of energy the vehicle ultimately uses, the energy stored and reused must undergo several stages of conversion. From mechanical to electric, from electric to chemical, from chemical to electric, and from electric to mechanical again, a typical path for reusing energy recovered from regenerative braking, the energy undergoes four conversions, resulting in significant energy losses due to conversion. Only a small portion of regenerated energy can be reused, which limits the efficiency of electric vehicles and hybrids. Second, the power density of both motor/generators and batteries are not high enough, which restricts vehicle performance and acceleration. Moreover, with current battery technologies, battery life is a significant consideration; since the number of charge/recharge cycles the battery can undergo is limited, this results in a need to replace the battery pack after some time, adding to the cost of owning the hybrid vehicle. Additionally, for electric vehicles, the distance the vehicle can travel per charge is relatively short.
Flywheel hybrids, as known as kinetic hybrids, are an alternative to electric hybrids. There exist mechanical continuously variable transmissions to control the storage and release of energy in a flywheel hybrid vehicle, but these mechanical CVTs suffer low efficiency at a high transmission ratio. There are also electromagnetic means to transfer energy in and out of the flywheel; however, these methods emphasize using the flywheel solely as energy storage. Demanding high energy capacities in the flywheel necessitates high flywheel speeds, which adds safety issues, not to mention that the energy in the flywheel is not used during cruise. More importantly, using electromagnetic means to control the transfer of energy to and from the flywheel makes it so that 100 percent of the energy stored into the flywheel must undergo conversion, limiting efficiency. The prior art has not sufficiently used the advantages of the flywheel while avoiding its disadvantages for flywheel hybrids to be industrially competitive.
The system and method of the present invention improve the vehicle's efficiency and performance by making full use of the flywheel's advantages such as high power density and the fact that the energy stored is in the same form it is to be used in, while at the same time avoiding such disadvantages as having low energy density without resorting to special materials. The flywheel may be designed to contain only the amount of energy necessary to accelerate the vehicle to a certain speed, so it may be designed to be lightweight and safe. The invention uses a three port planetary gear system and motor/generator(s) to form an electrically controlled continuously variable transmission to store and release energy to and from the flywheel. By planetary gear system, the present invention refers to both traditional mechanical planetary gear sets and magnetic planetary gears. The flywheel, motor/generator, and planetary gear system with three ports may all be contained within a wheel hub. The three ports of the planetary gear system are respectively connected to the flywheel, the variator for the flywheel, and the wheel containing the planetary gear system. Another motor/generator may be connected to either the flywheel or the vehicle's wheel to form a power split system. Changing the speed of one port on the planetary gear system with the variator for the flywheel changes the speeds of the other two ports, enabling a change in the speed ratio between the other two ports to allow the flywheel and the vehicle to directly exchange kinetic energy. Functionally, then, the flywheel is not only used for energy storage (like a battery pack) but also as a power source (like a traction motor). The system of the present invention therefore includes a kinetic power source, an electric power source, and a kinetic energy storage. Additionally, if the system is used within a vehicle with an internal combustion engine, the vehicle can become a fuel-kinetic-electric hybrid vehicle. There are three embodiments for the system of the present invention.
In the first embodiment, the flywheel, a three port planetary gear system, and two motor/generators are in the same wheel hub. A first port of the planetary gear system is connected to the flywheel, a second port is connected to the variator motor/generator, and a third port is connected to the wheel. The second motor/generator, which can use the energy generated by the variator motor/generator back into accelerating the wheel, shares the first port with the flywheel.
In the second embodiment, the flywheel, a three port planetary gear system, and two motor/generators are in the same wheel hub; in the planetary gear system, a first port is connected to the flywheel, a second port is connected to the variator motor/generator, and a third port is connected to the wheel and to the second motor/generator.
In the third embodiment, a flywheel, a three port planetary gear system, and one motor/generator are contained in the same wheel hub; the first port of the planetary gear system is connected to the flywheel, a second port is connected to the variator motor/generator, and a third port is connected to the wheel. A second motor/generator is contained inside a second wheel hub, which is used with the first wheel hub. Although structurally different, the third embodiment is functionally equivalent to the second.
The present invention offers the following advantages over conventional electric vehicles and electric hybrids. The primary improvement over the prior art is in energy efficiency and the reduction of emissions by virtue of improved fuel efficiency. Because the flywheel stores energy in kinetic form, which is the same form of energy the vehicle uses, many energy conversion stages are avoided compared to electric vehicles and electric hybrids, reducing energy losses due to conversion quite significantly. Furthermore, many transmission line losses can be avoided or minimized by installing the flywheel and its variator motor/generator into the wheel hub to directly accelerate the wheel and/or recover energy from the wheel. A second area of improvement is in the vehicle's performance, as the flywheel provides power at a higher power density than either motor/generators or batteries can provide. The power transmitted with the system is greater than the power of the motor/generator, so the vehicle's accelerative performance is improved. Another advantage is that the present invention can reduce the cost of the hybrid vehicle. Because the flywheel is responsible for the majority of the energy stored and released, the vehicle is less dependent on the battery pack, and the rate of charge/discharge as well as the number of charge/discharge cycles can be reduced, extending the battery life, which also reduces the cost of ownership over the life of the vehicle. With the extra power provided by the flywheel, the power requirements on motor/generators and inverter/controllers can be reduced, which also reduces the cost of manufacture. Integrating the flywheel into the wheel hubs of a vehicle makes for more flexibility, which can reduce design costs, so the present invention is also an improvement over flywheel hybrids of the prior art. If the present invention is used in an electric vehicle, it can also increase the vehicle's range per charge because of better efficiency.
a) shows a schematic for the first embodiment of the invention, and
a) through 2(j) illustrate the method to be used to control the first embodiment;
a) shows a schematic for the second embodiment of the invention, and
a) shows a schematic for the third embodiment of the invention, and
a) through 5(j) illustrate the method to be used with the second and third embodiments of the invention;
a) demonstrates how the first and second embodiments may be used within a vehicle for an electric-kinetic hybrid mode and/or a fuel-kinetic hybrid mode, and
a) and 8(b) compare the first embodiment realized respectively via traditional planetary gearing and magnetic planetary gearing;
a) and 9(b) compare the second embodiment realized respectively via traditional planetary gearing and magnetic planetary gearing;
a) and 10(b) compare part of the third embodiment realized respectively via traditional planetary gearing and magnetic planetary gearing.
Embodiment(s) of the present invention are described herein with reference to the drawings. In the drawings, like reference numerals represent like elements.
a) is a schematic for the mechanical components of the first embodiment. The planetary gear set 12 connects the flywheel 10, the motor/generators 01 and 02, as well as the wheel rim 37, into a three port kinetic-electric hybrid power-split system. The first port of the planetary gear set 12 (for instance, the sun gear S) connects to the flywheel 10; the second port (for instance, the ring gear R) connects to the variator motor/generator 01; the third port (for instance, the planet carrier C) connects to the wheel rim 37 inside the tire 39. The other motor/generator 02 shares the first port S with the flywheel 10 and a one-way clutch 24, which prevents the flywheel 10 from rotating in the reverse direction. The primary power source is provided by the motor/generators 01 and 02 powered by the battery pack 05 through the controller/inverters 03 and 04, respectively supplying 01 and 02 with energy. The secondary power source and the secondary energy storage are provided by the flywheel 10.
b) provides a structural mechanical representation of the first embodiment. The vehicle wheel 39 encloses motor/generators 01 and 02, the flywheel 10, and the planetary gear set 12 (the components inside box 30 in
A suitable control method is also desirable to draw out the benefits that the configuration can offer. In a three port planetary gear set of the mechanical type, the speed relationship between the gears can be expressed by the following equation:
(k+1)ωc=kωr+ωs (1)
Here, ωc, ωr and ωs are respectively the rotational speeds of the planet carrier gear C, ring gear R and sun gear S, with the constant k being the ratio between the number of teeth in the ring gear R and the number of teeth in the sun gear S. Changing the speed of one port affects the speed of the other ports. The speed of the third port can be determined when the speeds of any two ports are known. The motor/generator 01 and the planetary gear set 12 comprise an electrically controlled continuously variable transmission (CVT) for the flywheel 10. By adjusting the rotational speed and/or rotational direction of the ring gear R, the speed ratio between the sun gear S and the planet carrier gear C can be manipulated. In other words, the variator motor/generator 01 can control the transmission ratio between the flywheel 10 and the vehicle's wheel 39 by changing its own rotational speed and direction.
a) through 2(j) depict various operation states the kinetic hybrid vehicle using the first embodiment may encounter along a typical journey from starting up the vehicle to parking. In these diagrams, G signifies that the motor/generator depicted is in the generator state, and M indicates the motoring state for the motor/generator. F represents the flywheel 10, W represents the wheel 39, and B represents the battery pack 05. The concentric circles at the top of these diagrams represent the planetary gear set 12 and its constituent ports. These constituent ports are also represented in the boxes below showing connections with other components, with C representing the planet carrier gear, R representing the ring gear, and S representing the sun gear. Thin arrows indicate the direction of energy flow, with thin solid lines indicating that no energy is transferred and dotted lines indicating that the component is decoupled and not in use. For the concentric circles representing the various gears in the planetary gear set 12, thick solid arrows indicate the direction of motion, and thick unfilled arrows indicate the direction of torque.
a) illustrates the flywheel pre-charge state. In this state, either one motor/generator may be used, or both motor/generators may be simultaneously used to store energy in the flywheel F; M1 should rotate in the counterclockwise (CCW) direction and/or M2 should rotate in the clockwise (CW) direction to rotate the flywheel F in the clockwise direction while the planet carrier gear C is locked in place. What is specifically shown in
b) shows the first acceleration state, in which the variator G1 produces torque in the reverse direction of the motion of the ring gear R, and the resulting reaction torque can be transmitted from the flywheel F to the vehicle's wheel W. A portion of the kinetic energy from the flywheel F is directly passed to the wheel W through a direct mechanical path with no conversion loss, and another portion passes through the variator G1, converting to electricity. Because of motor M2, the electricity generated by the variator G1 is not stored to the battery pack B, but is passed to the motor M2 to produce torque in the same direction as the motion of the flywheel F and the sun gear S, so that M2 also contributes to accelerating the wheel W, avoiding two stages of energy conversion (electric to chemical in the batteries, chemical to electric in the motor/generators). Thus with motor M2 efficiency can be increased, battery life can be extended, and accelerative performance can be improved.
c) illustrates a second acceleration state, in which the direction of torque in the ring gear R is the same as the direction of the ring gear R's motion, at which point the variator M1 is in the motoring state. The combined torques of M1, M2, and the flywheel F contribute an even greater force to accelerate the vehicle.
d) represents the neutral/coasting state, in which the variator M/G1 is inactive, its rotor rotating freely with the ring gear R. The motor M2 may be inactive like M/G1, or M2 may charge the flywheel F to increase the amount of energy stored, which has no effect on the vehicle speed, since without a torque on the ring gear R there is no energy transfer between the flywheel F and the vehicle.
e) shows a first cruise state, when only the motor M1 is at work. The motor M2 is inactive. The variator M1 drives the ring gear R in the CW direction, and once the energy in the flywheel F is released to zero, the sun gear S is locked in place by the one-way clutch 24 mentioned earlier, preventing the flywheel F from turning in the reverse direction. Then, the motor M1 can drive the vehicle forward at a transmission ratio of (k+1)/k. There is no more energy stored in the flywheel F, but the motor M2 is available if acceleration is suddenly desired.
f) depicts a second cruise state. When the cruise speed is set very high, both motors M1 and M2 work to maintain the vehicle speed desired, providing a more suitable CVT ratio. The flywheel F will reach an equilibrium and then stop exchanging energy with the vehicle, serving to steady the vehicle speed desired.
g) shows a first deceleration and energy recovery state, in which the rotational direction of the ring gear R is the same as the direction of motion for the planet carrier gear C, and the variator G1 produces torque in the reverse direction so as to brake the ring gear R, decelerating the carrier gear C, and accelerating the sun gear S and the flywheel F. A portion of the vehicle's kinetic energy passes through a direct mechanical path to be stored into the flywheel F without conversion. Another portion of the vehicle's kinetic energy passes through the variator G1, and is used immediately by the motor M2 to increase the speed of the flywheel F, hence avoiding charging the battery pack B, and extending the battery life.
h) illustrates a second deceleration and energy recovery state, in which the rotational direction of the ring gear R is now in the reverse direction of the direction of motion for the planet carrier gear C. The variator M1 is in the motoring state, and accelerates the motion of the ring gear R in the reverse direction, resulting in continued transfer of the vehicle's kinetic energy to the flywheel F until the vehicle speed reaches zero. The motor/generator M2 may be inactive in this state of deceleration.
i) shows an operation state for driving the vehicle in reverse. The motor M1 drives the ring gear R to rotate CCW, and the generator G2 produces torque against the CW motion of the sun gear S. The result is that the planet carrier gear C rotates in reverse, and thus the wheel W is driven in reverse.
j) represents an operation state where the energy in the flywheel F is recovered to the battery pack B. Anytime the variator G1 is made inactive by stopping electricity to G1, the ring gear R rotates freely without a torque acting on it, and the vehicle is in a neutral state no matter whether the vehicle is stopped or gliding. Meanwhile, the generator G2 can convert the flywheel F′s kinetic energy to electricity, charging the battery pack B.
a) is a mechanical schematic for the second embodiment of the present invention; compared to the first embodiment described above, the motor/generator 02 is now connected to a different port, sharing the planet carrier port C of the planetary gear set 12 with the wheel rim 37. The flywheel 10 is connected to the sun gear S.
A structural mechanical drawing is shown in
In
a) illustrates an operation state for pre-charging the flywheel F. When the vehicle is stopped, either prior to starting the vehicle or when the vehicle is stopped for traffic, the wheel is braked, and the planet carrier gear C remains stationary. The motor M1 rotates CCW, and according to Equation (1) the flywheel F spins in the CW direction and stores up the energy from M1.
b) represents a first acceleration state; the variator G1 produces a torque opposite to the rotational direction of the ring gear R, and the reaction torque enables the transfer of energy from the flywheel F to the wheel W. The kinetic energy from the flywheel F travels via two paths to the wheel(s) W. A portion is passed along a direct mechanical path to the vehicle's wheel(s) W, avoiding any conversion losses, while an other portion of the energy passes through the variator G1, and is then used by the motor M2 to drive the vehicle's wheel(s) W, undergoing two energy conversions from mechanical to electric and then from electric to mechanical. Additionally, the motor M2 may draw more power from the battery pack B as well to drive the wheel(s) W, depending on how much acceleration is desired.
c) shows a second acceleration state. When the direction of rotational motion of the ring gear R becomes the same and the direction of torque produced by the variator M1, M1 operates as a motor. The motor/generators M1, M2 combine their torque with that of the flywheel F to accelerate the vehicle.
In
e) illustrates a first cruise state. The variator G1 is off, and the ring gear R rotates freely; the status of the flywheel F is unchanged because there is no torque on the ring gear R; the motor M2 alone drives the vehicle to maintain the desired vehicle speed.
f) illustrates a second cruise state. When there is significant resistance encountered (such as driving up a hill), both the motor/generators M1 and M2 work to drive the vehicle, and the energy in the flywheel F can be completely released to zero.
g) presents a first deceleration and energy recovery operation state. When the ring gear R rotates in the same direction as the planet carrier gear C, the variator G1 produces torque opposite to the direction of motion of the ring gear R, reducing its speed, which results in the deceleration of the planet carrier gear C and the acceleration of the flywheel F. The vehicle's kinetic energy travels a mechanical path to the flywheel F without energy conversion. The generator G2 can convert the vehicle's kinetic energy to electricity and charge the battery pack B.
h) illustrates a second deceleration and energy recovery operation state. By the time the motion of the ring gear R is reduced to zero and the ring gear R starts rotating in the direction opposite to the motion of the planet carrier gear C, the generator G2 provides electricity to the motor M1 to further drive the ring gear R to rotate in the reverse direction, thus inducing the vehicle's kinetic energy to be continued to be charged into the flywheel F, until the vehicle speed reaches zero.
i) shows an operation state for reversing the vehicle; the motor M2 drives the planet carrier gear C in the reverse direction. The motor M1 is inactive.
In
a) and 6(b) demonstrate how the present invention may be integrated into an existing vehicle for vehicle propulsion. Used with an ECU, inverter, and battery pack in the vehicle's powertrain, the system of the present invention transforms the vehicle into a kinetic-electric hybrid. Used with an internal combustion engine and transmission in the vehicle's powertrain, the system of the present invention transforms the vehicle into a fuel-kinetic-electric hybrid. In particular, the arrangement depicted in
a) is exactly the same as
b) illustrates the structure of the second embodiment of the present invention if a magnetic planetary gear system is used. In this case, the connections among the flywheel 10b, the rotor 103b and stator 101b of the motor/generator 01, and the magnetic gears MS, MR and MC are the same as what was shown in
b) depicts a magnetic planetary gear system implementation of the third embodiment. The connections among the flywheel 10b, the rotor 103b and stator 101b of the motor/generator 01, and the magnetic gears MS, MR and MC are the same as in
c) shows an implementation of the second wheel hub of the third embodiment containing the group of components 34c, which includes the motor/generator 02, using a mechanical planetary gear system.
The system of the present invention can be integrated easily into new or existing vehicles for improved fuel economy. Mechanical planetary gears provide a purely mechanical path for the exchange of kinetic energy between the flywheel and the vehicle, improving accelerative performance and regenerative braking capabilities. Magnetic planetary gears can be even more efficient at transmitting power than mechanical planetary gears due to the fact that they are contactless and frictionless.
