Wave rotor apparatus
A wave rotor apparatus is provided. In another aspect of the present invention, a radial wave rotor includes fluid passageways oriented in a direction offset from its rotational axis. A further aspect of the present invention employs stacked layers of generally radial channels in a wave rotor. Moreover, turbomachinery is located internal to a wave rotor in yet another aspect of the present invention. In yet another aspect of the present invention, a radial wave rotor has an igniter and fuel injector. Correctional passages are employed in still another aspect of the present invention wave rotor.
Latest Board of Trustees of Michigan State University Patents:
- Transparent Solar Cells For Agrivoltaics
- Control circuit for transistor with floating source node
- Wirelessly powered resistive sensor
- Solar power system for induction motor soft-starting and power compensation, and related methods
- Reusable energy absorbing apparatus including gas-liquid interactions in nanopores
This application claims priority to U.S. Provisional patent application Ser. No. 60/627,742, filed on Nov. 12, 2004, which is incorporated by reference herein.
BACKGROUND OF THE INVENTIONThe present invention relates generally to fluid power devices and more particularly to a wave rotor apparatus.
It is known to use an axial wave rotor as a supercharger in internal combustion engines for automotive vehicles. This conventional device is described in P. Akbari and N. Müller, “Gas Dynamic Design Analyses of Charging Zone for Reverse-Flow Pressure Wave Superchargers,” ICES 2003-690, ASME (May 11-14, 2003). Wave rotors have also been proposed for use in propulsive jet engines and power turbines as disclosed in U.S. Pat. No. 6,584,764 entitled “Propulsion Module” which issued to Baker on Jul. 1, 2003; and U.S. Pat. No. 5,894,719 entitled “Method and Apparatus for Cold Gas Reinjection in Through-Flow and Reverse-Flow Wave Rotors” which issued to Nalim et al. on Apr. 20, 1999; both of which are incorporated by reference herein. Various attempts have also been made to cancel an expansion wave generated by a wave rotor. Such a configuration is taught in U.S. Pat. No. 5,267,432 entitled “System and Method for Cancelling Expansion Waves in a Wave Rotor” which issued to Paxson on Dec. 7, 1993, and is incorporated by reference herein. Traditional attempts to use depressions or pockets to control wave reflections of off-design operation undesirably, reduce the sensitivity of axial wave rotors to engine speed changes. Nevertheless, there still exists a need to improve the performance and reduce the size of traditional wave rotors to enhance their commercial viability or adapt a different geometry for more convenient implementation.
SUMMARY OF THE INVENTIONIn accordance with the present invention, a wave rotor apparatus is provided. In another aspect of the present invention, a radial wave rotor includes fluid passageways oriented in a direction offset from its rotational axis. A further aspect of the present invention employs stacked layers of generally radial channels in a wave rotor. Moreover, turbomachinery is located internal and/or external to a wave rotor in yet another aspect of the present invention. In another aspect of the present invention, a radial wave rotor has an igniter and fuel injector. Correctional passages are employed in still another aspect of the present invention wave rotor.
The radial wave rotor of the present invention is advantageous over conventional devices since the present invention should produce higher power densities, an improved efficiency, a smaller frontal area, and a smaller size compared to known axial wave rotors. The centrifugal forces of the fluid, created by the present invention, advantageously improve flow scavenging and compression. The offset or generally radial passageways of the wave rotor of the present invention are also easier and less expensive to manufacture as compared to many traditional, axial wave rotors, especially if incorporated into a layered arrangement. The stacked configuration and/or shapes of channels employed in the present invention further provide advantageous variations in cycle timing.
Moreover, performance of the radial wave rotor of the present invention is simpler to model, predict and analyze in the design stage than traditional wave rotors. Placing turbomachinery in the presently disclosed locations also reduces undesirable pressure losses caused by conventional collectors and/or diffusers. Additionally, the correctional passageways of the present invention advantageously achieve directed and self-actuated aerodynamic control of the internal flow and shock wave pattern. Scavenging processes are also improved by the present invention's use of centrifugal forces. Additional advantages and features of the present invention will become apparent from the following description and appended claims, taken in conjunction with the accompanying drawings.
A wave rotor is a machine in which a fluid is pressurized by generally unsteady shock or compression waves and expanded by expansion waves. As a general principle for wave rotors used in a gas turbine engines, a wave rotor provides a pressure gain additional to that provided by a compressor. It also enables higher combustion end temperatures without raising a turbine inlet temperature since a portion of the energy of the burning gas exiting a combustion chamber is used in the shock compression to increase the pressure and temperature of the fresh air before it enters the combustion chamber. Accordingly, the pre-expanded burned gas is scavenged toward a turbine and channels of the wave rotor are reconnected to the compressor outlet, allowing fresh, pre-compressed air to flow into the wave rotor channels. Thus, wave rotors utilize a high-pressure fluid to transfer its energy directly to a low-pressure fluid when two fluids with different thermodynamic properties are brought into direct contact for a very short time, wherein pressure exchange occurs faster than mixing.
A first preferred embodiment of a wave rotor apparatus 21 is shown in
Referring to
It should alternately be appreciated that multiple layers of channels can be created within a single piece, radial wave rotor which does not require subsequent layer assembly; such an arrangement is shown in
With reference now to
Compressor 25 is a rotating turbomachinery component that can be positioned inside of internal end plate 27 and cavity 111 of radial wave rotor 31. Compressor 25 includes a base (disc) 121, a plurality of curved, fluid-impinging vanes 123 and a central hub 125. A rotational compressor axis 127 coaxially extends through hub 125 and vanes 123. Compressor axis 127 is angularly offset from axis 53 of radial wave rotor 31 by an angle α of between about 10-80 degrees, and more preferably by about 25 degrees. The majority of compressor inlet port 23 is also stationarily disposed within internal end plate 27 and wave rotor cavity 111. Compressor 25 is allowed to rotate independently of radial wave rotor 31 at least when no fluid is flowing and in certain potential operating conditions. When fluid is flowing, compressor 25 rotates in generally the same direction as radial wave rotor 31, however, the angles and curves of vanes 123 of compressor 25 can be varied and/or inlet and channel angles of radial wave rotor 31 can be varied to cause opposite and/or the same rotational direction between the compressor and radial wave rotor. It should be appreciated that alternate turbomachinery members, such as turbines or the like, may be rotationally provided within an internal cavity, whether central or not, of wave rotor 31. The angularly offset axes 53 and 127 between compressor 25 and wave rotor 31 create a continuous interface flow at the inner and outer periphery of external turbomachinery shown in
As best observed in
Wave rotor apparatus 21, as disclosed with the first preferred embodiment, shows the use of a radial wave rotor as a topping component for a gas turbine and is intended for use within an aircraft, jet engine, a stationary, electricity-producing power plant or for propelling other vehicles like land or water vehicles. With slight modification, the radial wave rotor apparatus of the present invention can also be used as a supercharger within an internal combustion engine, such as that employed in an automotive land vehicle, as a pressure exchanger in air or other gas refrigeration cycles, or as a condensing wave rotor, for example, in a water based refrigeration system. One such exemplary water refrigeration system is disclosed in U.S. Pat. No. 6,427,453 entitled “Vapor-Compression Evaporative Air Conditioning Systems and Components” which issued to Holtzapple et al. on Aug. 6, 2002, and is incorporated by reference herein. Another is disclosed in Akbari, P., Kharazi, A., Müller, N., “Utilizing Wave Rotor Technology to Enhance the Turbo Compression in Power and Refrigeration Cycles,” 2003 International Mechanical Engineering Conference, ASME Paper IMECE 2003-44222 (2003). Radial wave rotor 31 offers great potential and advantages for a condensing wave rotor in a vapor (phase change) refrigeration system, since it exploits the enormous density differences of gaseous and liquid fluid by the action of centrifugal forces. This greatly supports the separation of vapor and condensed fluid in the scavenging process and channel drying before refilling, which addresses a concern in handling of phase changes occurring in both directions in conventional, axial wave rotors.
Further, a fourth preferred radial wave rotor embodiment is shown in
The first preferred embodiment wave rotor apparatus 31 operates as follows. Fresh air enters air intake 43 and flows to compressor inlet port 23. Rotation of turbine 35 mechanically causes compressor 25 to also rotate, which, in turn, forces the intake air into the radial wave rotor channels 53 when they are aligned with port 113 of internal end plate 27. Expanded and burned gases exiting outlet duct 45 may go through supplemental conduits or ducts, or a jet nozzle (not shown). The air inserted from compressor 25 to wave rotor channels 53 is preferably of a non-supersonic flow and will generate unsteady shock waves inside channels 53 due to pressure differences between the compressor outlet and the temporarily lower pressure in channels 53. The centrifugal force additionally supports the flow in channel 53. The radial action of wave rotor 31 improves scavenging and acceleration of fluid within each channel. The fluid flowing action from compressor 25 and through wave rotor channels 53 can also serve to rotate radial wave rotor 31, after which, the burned gases exit the channels aligned with port 115 of external end plate 29. The radial wave rotor alternately may be driven by a gear and/or electrical motor. In the case of a fluid driven wave rotor, the wave rotor may extract even more energy from the fluid and drive an additional generator connected to it or integrated in it and the housing. The periodical exposure of the channels to the port openings in the end plates initiates compression and expansion waves that move through the wave rotor channels and internally generate an unsteady flow in the wave rotor. Thus, pressure is exchanged dynamically between high pressure and low pressure fluid utilizing unsteady pressure waves such that both compression and expansion are accomplished in the single component, being the wave rotor. In the preferred embodiment, combustion takes place (as shown in
Another alternate embodiment wave rotor apparatus 251 is illustrated in
An igniter or spark plug 313 is affixed to platform 311 and is selectively aligned with fire channel apertures 315 in each layer 305 having access to each channel 307. A fuel line 317, having a fuel injector 319 aligned with each layer 305, is stationarily mounted within a central, internal cavity 321 of radial wave rotor 303. An internal end plate 323 has one or more ports aligned with fuel injectors 319. Air inlets 325 allow fresh air from ambient or pre-compressed air from a compressor (such as that of
It is alternately envisioned that fire channel apertures 315 can be either circular holes or elongated slots. Additionally, it is alternately envisioned that fuel injectors can be selectively turned off and on so that only a limited number of the multiple layers of channel sets have fuel injected therein, thereby improving fuel efficiency within the wave rotor portion of the internal combustion engine in certain vehicle operational modes, such as in an idle condition. In another alternate arrangement, rotating electrical igniters, activated only in a certain angular position of the mixture-filled channel or a fixed laser beam igniter, can be substituted for fixed igniter 313 and apertures 315.
Correctional passages 401 and 403 can be provided in any of the previously disclosed embodiment wave rotor apparatuses or even in any axial wave rotor although some of the advantages of the present invention may not be achieved. This modification is shown in
The correctional passages correct the rotational speed of disk or rotor to obtain or maintain the proper position of the compression waves. In contrast to the traditional correctional pockets or open, depressions in conventional, axial wave rotors, the correctional passages of the present invention advantageously only have a noticeable effect on fluid flow if the primary and secondary compression waves hitting the end plate are not in their properly desired positions. The arrival location of the primary wave depends on the rotational speed of the wave rotor. In the tuned case, it should be at the leading edge of the compressed air port. A passage having an inlet just before the leading edge of the compressed fluid outlet port, and with an exit or outlet opening in the rotational direction, should have the primary shock wave reach the inlet opening if the rotational speed is too low. The pressure ratio across the shock wave will then induce a jet of redirected fluid to exit the outlet opening of correctional passage 401 and the rotational direction and to thereby accelerate the wave rotor with the momentum of the jet. This is shown in the operational condition of
More specifically,
A fourth alternate embodiment wave rotor apparatus 501 is of a first variation shown in
A fifth alternate embodiment wave rotor apparatus 531/561 is illustrated as a wave disc micro-engine in
The engine disc rotates with speeds much lower than a conventional turbo-unit, thereby simplifying bearing problems and construction of the electric generator. The present wave disc geometrical configuration and porting system causes one and two stage compression-decompression processes to increase the total efficiency. Middle pressure by-pass generates the torque and consequently, net power. Wave disc 533 is a radial wave rotor having curved channels. It overcomes the traditional poor scavenging problem by adding, in a controllable way, additional force (being the component of centrifugal forces) which improves the scavenging process. Further, the motor-generator can be directly integrated within the engine.
The exemplary construction of
As can be observed in
Various embodiments have been disclosed, however, variations can be made which fall within the scope of the present invention. For example, the wave rotor can be stationary with the end plates rotating, although centrifugal flow advantages may not be fully realized. Further, it is envisioned that an electric motor actuator or the like may drive the wave rotor. Reverse-flow or through-flow wave rotor channels can be employed. Various aspects of the ultra-micro devices and methods disclosed in PCT Serial No. PCT/US05/24290, filed on Jul. 7, 2005, entitled “Ultra Micro Gas Turbine” and invented by Muller et al., which is incorporated by reference herein, can be used with the radial wave rotor of the present invention. Additionally, it is envisioned that the present invention pertains to the internal location of compressors or other rotatable members within an internal cavity of otherwise conventional axial wave rotors, although many of the advantages of the radial wave rotor may not be achieved. It is further envisioned that two or more radial wave rotors can be coaxially aligned and used together, preferably rotating at the same speed, or alternately, at different speeds. While various materials, quantities and shapes have been disclosed, it should be appreciated that various other materials, quantities and shapes can be employed. It is intended by the following claims to cover these and any other departures from the disclosed embodiments which fall within the true spirit of this invention.
Claims
1. An apparatus comprising: a wave rotor operably rotating about a rotor axis; the wave rotor including a first set of channels located substantially on a first plane, a second set of channels located substantially on a second plane and at least a third set of channels located substantially on at least a third plane, the first, second, and third sets of channels each being in a stacked relationship offset along the rotor axis; and at least the majority of the channels having elongated flow directions outwardly radiating relative to the rotor axis, and certain sets of the channels operate in a different timing scheme.
2. The apparatus of claim 1 further comprising multiple channels located substantially on a fourth plane, the planes being substantially parallel to each other, openings of the channels on the first plane being circumferentially offset from those on the second plane.
3. The apparatus of claim 1 wherein at least a majority of the channels are radially offset from the rotor axis, and the first, second and third planes are substantially parallel.
4. The apparatus of claim 1 wherein all of the channels are substantially perpendicular to the rotor axis.
5. The apparatus of claim 1 wherein at least a majority of the channels have a straight elongated orientation.
6. The apparatus of claim 1 wherein at least a majority of the channels have a curved elongated orientation.
7. The apparatus of claim 1 wherein the channels on the first plane are made as a separate layer from the channels on the second plane, the layers being stacked upon each other and joined together in a coaxial manner.
8. The apparatus of claim 1 further comprising a fuel injector and igniter aligned with at least one of the channels in at least one operating position, wherein the wave rotor utilizes shock waves to exchange energy from a high energy fluid to a low energy fluid, increasing both temperature and pressure of the low energy fluid, in an internal combustion engine.
9. An apparatus comprising:
- a wave rotor having a plurality of fluid passageways, the wave rotor being rotatable about a rotor axis, the wave rotor having an internal surface defining an internal cavity; and
- a rotatable member located inside the internal cavity of the wave rotor, the member further comprising a plurality of fluid-impinging vanes rotatable about a member axis independent of the fluid passageways.
10. The apparatus of claim 9 wherein the member is a fluid compressor.
11. The apparatus of claim 9 wherein the member axis is angularly offset from the rotor axis.
12. The apparatus of claim 9 wherein the member axis is offset from the rotor axis by about 20-50 degrees, the vanes of the member being oriented in an outwardly radiating manner relative to the member axis.
13. The apparatus of claim 9 wherein the wave rotor is a radial wave rotor with its passageways being elongated in an orientation substantially radially offset relative to the rotor axis.
14. The apparatus of claim 9 further comprising:
- an internal end plate having at least one port, the internal end plate being located between the internal surface of the wave rotor and the member; and
- an external end plate having at least one port, the external end plate being located around an exterior surface of the wave rotor substantially coaxial with the rotor axis;
- the ports of the internal and external end plates selectively aligning with the wave rotor passageways depending upon the positioning of the wave rotor; and
- other portions of the internal and external end plates selectively blocking fluid entry and exit of the wave rotor passageways depending upon the positions of the wave rotor.
15. The apparatus of claim 9 further comprising:
- a rotatable turbine mechanically coupled to the member; and
- a turbine volute surrounding at least a portion of the turbine;
- wherein fluid first flows to the member, radially outward through the wave rotor passages, through the turbine volute and subsequently to the turbine.
16. The apparatus of claim 9 further comprising a fuel injector and igniter aligned with at least one of the passageways in at least one operating position, wherein the wave rotor utilizes shock waves to exchange energy from a high energy fluid to a low energy fluid, increasing both temperature and pressure of the low energy fluid, in an internal combustion engine.
17. An apparatus comprising:
- a radial wave rotor including a rotational axis and multiple fluid carrying channels angularly offset from the axis in a substantially radial manner;
- a radial compressor selectively in fluid communication with and being located inside the radial wave rotor; and
- a turbine;
- the compressor and radial wave rotor operably utilizing fluid to exchange energy from a high energy fluid state to a low energy fluid state, increasing both temperature and pressure of the low energy fluid state during fluid flow from the compressor to the radial wave rotor and then to the turbine, free of a collector and free of a diffuser.
18. The apparatus of claim 17 further comprising a mechanical coupling attaching the turbine to the radial compressor.
19. The apparatus of claim 18 further comprising a turbine volute surrounding at least a majority of the turbine.
20. The apparatus of claim 17 wherein the radial wave rotor includes some of the channels being located on a first plane which are a separate layer from some of the channels being located on a second plane, the layers being stacked upon each other in a coaxial manner.
21. An apparatus comprising a radial wave rotor including a rotational rotor axis and fluid carrying channels having fluid flow directions oriented substantially radial to the rotor axis, the radial wave rotor operably creating a compressed fluid-pressure wave, and a plurality of groups of channels adjacent each other being in a stacked relationship, the groups of channels being offset from each other along the rotor axis, and a fuel injector and igniter aligned with at least one of the channels in at least one operating position, wherein the wave rotor utilizes shock waves to exchange energy from a high energy fluid to a low energy fluid, increasing both temperature and pressure of the low energy fluid, in an internal combustion engine.
22. The apparatus of claim 21 further comprising a compressor located internal to the radial wave rotor, the compressor operably rotating around a compressor axis.
23. The apparatus of claim 22 wherein the compressor axis is angularly offset from the rotor axis.
24. The apparatus of claim 21 wherein at least a majority of the channels have a straight elongated orientation.
25. The apparatus of claim 21 wherein at least a majority of the channels have a curved elongated orientation.
26. The apparatus of claim 21 wherein an opening of each of the channels has a substantially square shape relative to the rotor axis.
27. The apparatus of claim 21 wherein An apparatus comprising a radial wave rotor including a rotational rotor axis and fluid carrying channels having fluid flow directions oriented substantially radial to the rotor axis, the radial wave rotor operably creating a compressed fluid-pressure wave, and a plurality of groups of channels adjacent each other being in a stacked relationship, the groups of channels being offset from each other along the rotor axis, and an opening of each of the channels has having a substantially diamond shape relative to the rotor axis.
28. The apparatus of claim 21 further comprising a fuel injector and igniter aligned with at least one of the channels in at least one operating position, wherein the wave rotor utilizes shock waves to exchange energy from a high energy fluid to a low energy fluid, increasing both temperature and pressure of the low energy fluid, in an internal combustion engine.
29. The apparatus of claim 21 further comprising:
- a compressor;
- an internal end plate having at least one port, the internal end plate being located between an internal surface of the wave rotor and the compressor; and
- an external end plate having at least one port, the external end plate being located around an exterior surface of the wave rotor substantially coaxial with the rotor axis;
- the ports of the internal and external end plates selectively aligning with the wave rotor channels depending upon the positioning of the wave rotor.
30. The apparatus of claim 21 wherein fluid flows into the wave rotor at a subsonic speed.
31. The apparatus of claim 21 wherein the wave rotor acts as a refrigeration condenser.
32. The apparatus of claim 21 wherein the wave rotor is part of an aircraft jet engine.
33. The apparatus of claim 21 further comprising wherein the wave rotor acts as an active compression-decompression wave engine using centrifugal forces acting on fluid in the wave rotor to improve scavenging therein, the wave rotor generating torque during operation.
34. An apparatus comprising:
- a wave rotor having fluid flow paths, the wave rotor being rotatable about a rotor axis; and
- a compressor including fluid-contacting structures rotatable about a compressor axis;
- the compressor axis being angularly offset from the rotor axis, and the compressor operably supplying fluid to the wave rotor; and
- the wave rotor being a radial wave rotor with its paths being elongated in an orientation substantially radially offset relative to the rotor axis.
35. The apparatus of claim 34 wherein the wave rotor is a radial wave rotor with its paths being elongated in an orientation substantially radially offset relative to the rotor axis.
36. The apparatus of claim 34 wherein the compressor axis is offset from the rotor axis by about 20-50 degrees.
37. The apparatus of claim 34 further comprising:
- an internal end plate having at least one port, the internal end plate being located between an internal surface of the wave rotor, defining an internal cavity, and the compressor; and
- an external end plate having at least one port, the external end plate being located around an exterior surface of the wave rotor substantially coaxial with the rotor axis;
- the ports of the internal and external end plates selectively aligning with the wave rotor paths depending upon the positioning of the wave rotor.
38. The apparatus of claim 34 wherein the compressor is rotatably located inside an internal cavity of the wave rotor.
39. A wave rotor apparatus comprising a surface defining an elongated channel being rotated around an axis, a shock wave of a flowing fluid moving through the channel, and a correctional passage located in the surface, the correctional passage being elongated and enclosed between an inlet and an outlet of the passage channel, the correctional passage operably receiving a portion of the flowing fluid and changing flow characteristics of the shock wave in at least one operating condition;
- wherein the channel is part of a radial wave rotor, the channel being radially elongated in a direction offset from the axis.
40. The apparatus of claim 39 wherein the inlet and outlet of the correctional passage substantially face the same direction, and the correctional passage operably varies a rotational speed of the wave rotor to obtain a proper position of the shock wave.
41. An apparatus comprising:
- a wave rotor including multiple fluid-carrying passageways, each of the passageways having an inlet opening and an outlet opening; and
- at least one end plate including a fluid blocking section, and the end plate further including an elongated and diagonally angled port being in periodic alignment with at least one of the passageways to allow fluid flow between the port and aligned passageway, the port being elongated and diagonally angled across a peripheral surface of the end plate, the elongation direction of the port being angularly offset from a rotational axis of the wave rotor;
- a fluid compressor;
- a rotatable turbine mechanically coupled to the compressor; and
- a turbine volute surrounding at least a portion of the turbine;
- wherein fluid first flows to the compressor, radially outward through the wave rotor passages, through the turbine volute and subsequently to the turbine.
42. An apparatus comprising:
- a wave rotor including multiple fluid-carrying passageways, each of the passageways having an inlet opening and an outlet opening; and
- at least one end plate including a fluid blocking section, and the end plate further including a port defined by an edge at an internal face of the end plate, the edge of the port being elongated and diagonally angled port, the port being in periodic alignment with at least one of the passageways to allow fluid flow between the port and aligned passageway;
- wherein the passageways of the wave rotor are elongated in an outwardly radiating direction relative to a rotational axis of the wave rotor; and
- wherein the diagonally angled port is elongated larger than the corresponding opening of the wave rotor passageways and a section of the diagonally angled port is offset from the corresponding opening in all operating conditions.
43. The apparatus of claim 41 wherein fluid flows into the wave rotor at a subsonic speed and the passageways have a curve in their elongated directions.
44. An apparatus comprising:
- a radial wave rotor having a plurality of fluid passageways, the wave rotor being rotatable about a rotor axis with the passageways being elongated in an orientation substantially radially offset relative to the rotor axis, the wave rotor having an internal surface defining an internal cavity; and
- an electromagnetic generator located inside the cavity of the wave rotor.
45. The apparatus of claim 44 wherein the device is an electric motor.
46. An apparatus comprising:
- a wave rotor having a plurality of fluid passageways, the wave rotor being rotatable about a rotor axis, the wave rotor having an internal surface defining an internal cavity; and
- an electromagnetic device located inside the cavity of the wave rotor;
- wherein a central axis of the device is angularly offset from the rotor axis.
47. The apparatus of claim 46 wherein the wave rotor is a radial wave rotor with its passageways being elongated in an orientation substantially radially offset relative to the rotor axis.
48. The apparatus of claim 44 46 wherein the device is an electric generator.
49. The apparatus of claim 1 wherein certain sets of the channels operate in a different timing scheme.
50. The apparatus of claim 21 further comprising wherein the radial wave rotor acts as an active compression-decompression wave engine using centrifugal forces acting on fluid in the wave rotor to improve compression therein, the wave rotor generating torque during operation.
51. The apparatus of claim 21 further comprising wherein the radial wave rotor acts as an active compression-decompression wave engine using the radial channel orientation in the wave rotor to improve scavenging therein, the wave rotor generating torque during operation.
52. A method of manufacturing a power generation assembly comprising:
- (a) creating a first member to include outwardly radiating fluid passageways and an internal cavity;
- (b) creating a second member to include fluid-contacting vanes;
- (c) orienting the second member substantially inside the cavity of the first member;
- (d) providing selective fluid communication between the first and second members;
- (e) allowing the first and second members to rotate independently of each other in at least one condition; and
- (f) utilizing shock waves inside the passageways of the first member to transfer energy from a high energy fluid to a low energy fluid, increasing both temperature and pressure of the low energy fluid.
53. The method of claim 52 wherein the first member is a radial wave rotor and the second member is a compressor.
54. The method of claim 52 wherein the first member is a radial wave rotor with internal combustion.
55. The method of claim 52 further comprising aligning an internal combustion engine fuel injector and an igniter with at least one of the passageways.
56. The method of claim 52 further comprising connecting a rotatable turbine to the second member and flowing fluid to the members and thereafter to the turbine.
57. The method of claim 52 further comprising making the first member with stacked layers, with at least some of the layers each including an outwardly radiating set of the passageways, such that the outwardly radiating passageways are located on different parallel planes substantially perpendicular to a rotational axis of the first member.
58. The apparatus of claim 41 further comprising An apparatus comprising:
- a wave rotor including multiple fluid-carrying passageways, each of the passageways having an inlet opening and an outlet opening;
- at least one end plate including a fluid blocking section, and the end plate further including an elongated and diagonally angled port being in periodic alignment with at least one of the passageways to allow fluid flow between the port and aligned passageway, the port being elongated and diagonally angled across a peripheral surface of the end plate, the elongation direction of the port being angularly offset from a rotational axis of the wave rotor; and
- a fuel injector and igniter aligned with at least one of the passageways in at least one operating position, wherein the wave rotor utilizes shock waves to exchange energy from a high energy fluid to a low energy fluid, increasing both temperature and pressure of the low energy fluid, in an internal combustion engine.
59. The apparatus of claim 41 wherein at least a majority of the passageways have a straight elongated orientation.
60. The apparatus of claim 41 further comprising wherein the at least one end plate comprises an external end plate having a port which is elongated and diagonally angled across an internal surface of the external end plate, the wave rotor operably rotating between the external end plates plate and an internal end plate.
61. The apparatus of claim 41 further comprising:
- a fluid compressor;
- a rotatable turbine mechanically coupled to the compressor; and
- a turbine volute surrounding at least a portion of the turbine;
- wherein fluid first flows to the compressor, radially outward through the wave rotor passages, through the turbine volute and subsequently to the turbine.
62. The apparatus of claim 42 further comprising a fuel injector and igniter aligned with at least one of the passageways in at least one operating position, wherein the wave rotor utilizes shock waves to exchange energy from a high energy fluid to a low energy fluid, increasing both temperature and pressure of the low energy fluid, in an internal combustion engine.
63. The apparatus of claim 42 wherein at least a majority of the passageways have a straight elongated orientation.
64. The apparatus of claim 42 further comprising wherein the at least one end plate comprises an external end plate having a port which is elongated and diagonally angled across an internal surface of the external end plate, the wave rotor operably rotating between the external end plates plate and an internal end plate.
65. The apparatus of claim 42 further comprising:
- a fluid compressor;
- a rotatable turbine mechanically coupled to the compressor; and
- a turbine volute surrounding at least a portion of the turbine;
- wherein fluid first flows to the compressor, radially outward through the wave rotor passages, through the turbine volute and subsequently to the turbine.
66. An apparatus comprising:
- a wave rotor including a rotational axis and fluid passageways each being elongated in a substantially radial manner away from the axis;
- a fuel injector operably supplying fuel into the passageways;
- an igniter operably having access to the passageways to ignite the fuel therein; and
- at least one air inlet port located in an internal end plate operably allowing air to enter the passageways when aligned, an inlet port quantity being less than a quantity of the passageways.
67. The apparatus of claim 66 wherein the igniter is a spark plug elongated substantially parallel to the rotational axis.
68. The apparatus of claim 66 further comprising an electrical generator, each of the passageways having a curved segment to create torque to the wave rotor during flow scavenging which drives the generator.
69. The apparatus of claim 66 further comprising an external end plate including at least one port through which burned gases exit when the port is aligned with at least one of the passageways within which a fuel and air mixture is combusted, the internal and external end plates having annular walls between which the passageways rotate, the annular walls being concentric with each other and coaxial with the rotational axis, and the inlet and exit ports being located through the respective annular walls.
70. The apparatus of claim 66 further comprising at least a second wave rotor including a plurality of fluid passageways each being elongated in a substantially radial manner away from the rotational axis, one of the wave rotors being coaxially and longitudinally stacked on top of the other and both of the wave rotors rotating when there is combustion of the fuel therein.
71. The apparatus of claim 66, further comprising an automotive land vehicle at least partially powered by the wave rotor.
72. The apparatus of claim 66 wherein rotation of the wave rotor about the axis causes centrifugal force to act upon a combusted fuel and air mixture therein to improve scavenging and acceleration of fluid with each passageway.
73. An apparatus comprising:
- a radial wave rotor including substantially radially elongated channels each having a non-linear elongated configuration;
- an automotive land vehicle at least partially powered by the radial wave rotor;
- combusted fluid exiting an outer end of at least one of the channels while the radial wave rotor rotates; and
- an ignitor operably having access to at least one of the channels, a quantity of the channels being greater than an ignitor quantity.
74. The apparatus of claim 73 wherein the ignitor is a laser beam ignitor.
75. The apparatus of claim 73 wherein rotation of the wave rotor about an axis causes centrifugal force to act upon a combusted fuel and air mixture therein to improve scavenging and acceleration of fluid with each channel.
76. An apparatus comprising:
- a radial wave rotor including substantially radially elongated channels each having a non-linear elongated configuration;
- an automotive land vehicle at least partially powered by the radial wave rotor;
- combusted fluid exiting an outer end of at least one of the channels while the radial wave rotor rotates; and
- an external end plate including at least one port through which the combusted fluid exits when the port is aligned with at least one of the channels within which a fuel and air mixture is combusted, and an internal end plate having at least one entry port therethrough, the internal and external end plates having annular walls between which the channels rotate, the annular walls being coaxial with a rotational axis and the entry and exit ports being located through the respective annular walls.
77. The apparatus of claim 73 further comprising at least a second wave rotor including a plurality of fluid channels each being elongated in a substantially radial manner away from a rotational axis, one of the wave rotors being coaxially and longitudinally stacked on top of the other, and the wave rotors rotating during combustion of fuel therein.
78. The apparatus of claim 73 wherein the non-linear configuration is a curved shape in the elongated direction.
79. The apparatus of claim 73 further comprising an electric generator rotated by the radial wave rotor.
80. The apparatus of claim 73 wherein the wave rotor is a ceramic material.
81. The apparatus of claim 73 further comprising an internal end plate and an external end plate, each of the end plates including ports which are periodically aligned with the channels rotating therebetween, the port-to-channel alignment controlling fluid flow through the channels.
82. The apparatus of claim 73 further comprising a fresh air inlet centrally located adjacent a rotational axis of the radial wave rotor, upstanding stationary walls adjacent the inlet and internal to the wave rotor assisting in guiding the fresh air from the inlet to at least one entry port periodically aligned with inner ends of the channels.
83. The apparatus of claim 73 wherein the radial wave rotor acts as a supercharger for an internal combustion engine.
84. The apparatus of claim 73 further comprising a compressor, fluidicly connected to the wave rotor, being rotated by a shaft.
85. An apparatus comprising:
- a radial wave rotor including a rotational axis and fluid passageways radially extending on a plane located perpendicular to the rotational axis, the passageways having a curved shape when viewed in a true view to the plane;
- an internal end plate and an external end plate, each of the end plates including ports which are periodically aligned with the passageways operably rotating therebetween, port-to-passageway alignment controlling fluid flow through the passageways; and
- a fuel injector operably injecting fuel directly into the passageways.
86. The apparatus of claim 85 wherein the injector is adjacent the rotational axis.
87. The apparatus of claim 86 further comprising a spark plug emitting a spark into a hole in communication with at least one of the passageways, the spark plug being spaced away from the fuel injector.
88. The apparatus of claim 85 wherein the wave rotor is an automotive vehicle supercharger.
89. The apparatus of claim 85 further comprising an electrical generator rotated by the wave rotor.
90. The apparatus of claim 85 further comprising an automotive land vehicle at least partially powered by the wave rotor.
91. The apparatus of claim 85 further comprising at least a second wave rotor including a plurality of fluid passageways each being elongated in a substantially radial manner away from the axis, one of the wave rotors being coaxially and longitudinally stacked on top of the other of the wave rotors, and the wave rotors operably rotating during combustion of fuel therein.
92. The apparatus of claim 85 wherein burned gases exit the port in the external end plate when it is aligned with at least one of the passageways within which fuel and air mixture is combusted, the internal and external end plates having annular walls between which the passageways rotate, the annular walls being coaxial with the rotational axis, and the inlet and exit ports being located through the respective annular walls.
93. The apparatus of claim 85 wherein rotation of the wave rotor about the axis causes centrifugal force to act upon a combusted fuel and air mixture therein to improve scavenging and acceleration of fluid with each passageway.
94. The apparatus of claim 85 further comprising an external combustor in communication with at least one of the passageways of the radial wave rotor.
95. The apparatus of claim 85 further comprising a compressor in fluid communication with the passageways of the radial wave rotor.
96. The apparatus of claim 85 further comprising a fresh air inlet centrally located adjacent the rotational axis, and upstanding stationary walls located within the internal end plate assisting in guiding the fresh air from the inlet to at least one of the ports adjacent inner ends of the passageways.
97. An apparatus comprising:
- a wave rotor having an axis, the wave rotor further comprising at least two stacked layers of channels rotating about the axis;
- at least one inlet port located adjacent an end of each of the channels of at least one of the layers;
- at least one outlet port located adjacent an opposite end of each of the channels of at least one of the layers;
- pressure waves of combusted fluid moving toward ends of the channels containing the fluid adjacent the outlet port in at least one operating condition; and
- a wall between a channel in one of the layers and a channel in another of the layers including an aperture to allow access between the channels associated therewith.
98. The apparatus of claim 97 further comprising an ignitor accessible to at least some of the channels and causing combustion of the fluid in the channels, the aperture being a fire channel to assist with combustion between the associated channels connected by the aperture.
99. The apparatus of claim 97 wherein the wave rotor is a radial wave rotor with the channels each having a direction of elongation substantially radially extending away from the axis.
100. The apparatus of claim 97 further comprising an automotive vehicle powered by the wave rotor.
101. The apparatus of claim 97 wherein the aperture is an elongated slot and the wall is on a plane perpendicular to the axis.
102. An apparatus comprising a wave rotor including an axis and fluid carrying channels rotating about the axis, at least one of the channels comprising an elongated curved configuration between an inlet end and an outlet end, and the at least one of the channels further comprising an offset angled wall configuration adjacent the outlet end, a flat wall having a circular periphery, a plurality of the channels each having an internal surface defined by the flat wall, side walls each separating adjacent pairs of the channels and including the curved and offset configurations, the side walls upstanding from the flat wall and the walls rotating about the axis.
103. The apparatus of claim 102 wherein rotation of the wave rotor about the axis causes centrifugal force to act upon a combusted fuel and air mixture therein to improve scavenging and acceleration of fluid with each channel, and the wave rotor is a radial wave rotor that is part of an automotive vehicular engine.
104. An apparatus comprising:
- a first radial wave rotor including multiple fluid carrying channels; and
- at least a second radial wave rotor including multiple fluid carrying channels;
- the radial wave rotors being coaxially aligned and rotating at different speeds in at least one operating condition.
105. The apparatus of claim 104 wherein the channels of at least one of the radial wave rotors each have a curved elongated configuration.
106. The apparatus of claim 104 further comprising an electrical generator rotated by at least one of the wave rotors.
107. The apparatus of claim 104 further comprising an automotive land vehicle at least partially powered by at least one of the wave rotors.
108. The apparatus of claim 104 further comprising an internal end plate including at least one inlet port intermittently aligned with the channels of the first radial wave rotor, and an external end plate including at least one outlet port intermittently aligned with the channels of the first radial wave rotor, and centrifugal force acting on a combusted fuel and air mixture in the channels of the first radial wave rotor improving scavenging and acceleration of the mixture therein.
109. A method of using a radial wave rotor, the method comprising:
- (a) rotating the radial wave rotor around an axis;
- (b) flowing air to at least one inlet port;
- (c) outwardly flowing the air into elongated channels outwardly extending in a substantially radial direction relative to the axis, only when the channels are aligned with the at least one inlet port;
- (d) supplying fuel directly into the channels;
- (e) igniting the fuel inside the channels;
- (f) generating waves inside the channels due to pressure differences therein;
- (g) using centrifugal force to improve scavenging of the combusted air/fuel mixture within each channel; and
- (h) rotating an electric generator with rotation of the radial wave rotor.
110. The method of claim 109 further comprising rotating the electric generator by rotating the radial wave rotor connected to it, and the radial wave rotor is part of an automotive vehicular engine.
111. The method of claim 109 further comprising periodically exposing the channels to outlet and the at least one inlet ports to initiate compression and expansion waves that move through the channels, and dynamically exchanging pressure between high pressure and low pressure fluid utilizing unsteady pressure waves such that both compression and expansion are accomplished in the radial wave rotor.
112. The method of claim 109 further comprising rotating the channels along a plane perpendicular to the axis.
113. The method of claim 109 further comprising self-rotating the radial wave rotor by flowing the fluid therein against curved side walls defining each of the channels.
114. The method of claim 109 further comprising using metal material for the wave rotor and ducting burned gas from the wave rotor through an elongated duct.
115. A method of using a radial wave rotor, the method comprising:
- (a) rotating the radial wave rotor around an axis;
- (b) causing elongated channels of the radial wave rotor to rotate along a plane perpendicular to the axis;
- (c) using centrifugal force to improve outward scavenging of fluid within each channel;
- (d) periodically exposing the channels to outlet and inlet ports to initiate compression and expansion waves that move through the channels, and dynamically exchanging pressure between high pressure and low pressure fluid utilizing unsteady pressure waves such that both compression and expansion are accomplished in the radial wave rotor; and
- (e) using internal combustion of the fluid inside the channels of the radial wave rotor.
116. The method of claim 115 further comprising rotating a second radial wave rotor around the axis, the radial wave rotors being coaxially stacked against each other.
117. The method of claim 115 further comprising at least partially powering an automotive land vehicle by rotation of the radial wave rotor.
118. The method of claim 115 further comprising rotating an electric generator by rotating the radial wave rotor.
119. The method of claim 115 further comprising using the radial wave rotor as a vehicular supercharger.
120. The method of claim 115 further comprising injecting fuel directly into the channels.
121. The method of claim 115 further comprising compressing the fluid before it enters the radial wave rotor.
122. A method of using a wave rotor, the method comprising:
- (a) rotating the wave rotor about an axis so as to outwardly move combusting fluid between an inlet port and an outlet port within a rotating channel which is elongated perpendicular to the axis;
- (b) using centrifugal force to scavenge the combusting fluid within the rotating channel;
- (c) periodically exposing the rotating channel to the inlet and outlet ports to cause compression and expansion waves that move through the channel; and
- (d) supplying power to a land vehicle with the wave rotor.
123. The method of claim 122 further comprising providing electrical power with the wave rotor.
124. The method of claim 122 further comprising providing supercharger power with the wave rotor.
125. The method of claim 122 wherein the wave rotor comprises multiples of the channel which are each radially elongated perpendicular to the rotational axis of the wave rotor and on a common plane, and at least one of the channels having a curved elongated shape, and aligning an ignitor with at least one of the rotating channels.
126. The method of claim 122 wherein the channel is part of a first set of wave rotor channels, further comprising rotating a second set of wave rotor channels coaxially mounted in a stacked manner relative to the first set of channels, and injecting fuel directly into at least one of the rotating channels.
2045152 | June 1936 | Lebre |
2399394 | April 1946 | Seippel |
2852915 | September 1958 | Boszormenyi et al. |
2864237 | December 1958 | Coleman, Jr. |
2904245 | September 1959 | Pearson |
2904246 | September 1959 | Pearson |
2970745 | February 1961 | Berchtold |
3106073 | October 1963 | Kentfield |
3190542 | June 1965 | Vickery |
3232520 | February 1966 | Spalding |
3726619 | April 1973 | Adams |
3756310 | September 1973 | Becker |
3797559 | March 1974 | Paul et al. |
3811796 | May 1974 | Coleman et al. |
3828573 | August 1974 | Eskeli |
3869808 | March 1975 | Sawyer |
3879937 | April 1975 | Jenny |
3952798 | April 27, 1976 | Jacobson et al. |
3958899 | May 25, 1976 | Coleman, Jr. et al. |
4002414 | January 11, 1977 | Coleman, Jr. et al. |
4005587 | February 1, 1977 | Eskeli |
4044824 | August 30, 1977 | Eskeli |
4171623 | October 23, 1979 | Lavigne, Jr. et al. |
4182402 | January 8, 1980 | Adrian |
4397613 | August 9, 1983 | Keller |
4582128 | April 15, 1986 | Jarreby |
4597835 | July 1, 1986 | Moss |
4627890 | December 9, 1986 | Porter et al. |
4662342 | May 5, 1987 | Altmann et al. |
4719746 | January 19, 1988 | Keller |
4744213 | May 17, 1988 | El-Nashar |
5052898 | October 1, 1991 | Cook |
5116205 | May 26, 1992 | Kirchhofer |
5119886 | June 9, 1992 | Fletcher et al. |
5154580 | October 13, 1992 | Hora |
5267432 | December 7, 1993 | Paxson |
5274994 | January 4, 1994 | Chyou et al. |
5297384 | March 29, 1994 | Paxson |
5445216 | August 29, 1995 | Cannata |
5464325 | November 7, 1995 | Albring et al. |
5490760 | February 13, 1996 | Kotzur |
5503222 | April 2, 1996 | Dunne |
5520008 | May 28, 1996 | Ophir et al. |
5522217 | June 4, 1996 | Zauner |
5639208 | June 17, 1997 | Theis |
5647221 | July 15, 1997 | Garris, Jr. |
5894719 | April 20, 1999 | Nalim et al. |
5904470 | May 18, 1999 | Kerrebrock et al. |
5916125 | June 29, 1999 | Snyder |
5931640 | August 3, 1999 | Van Houten et al. |
5932940 | August 3, 1999 | Epstein et al. |
6065297 | May 23, 2000 | Tischer et al. |
6082341 | July 4, 2000 | Arai et al. |
6134109 | October 17, 2000 | Muller et al. |
6138456 | October 31, 2000 | Garris |
6185956 | February 13, 2001 | Brasz |
6196809 | March 6, 2001 | Takahashi et al. |
RE37134 | April 17, 2001 | Wilson |
6238524 | May 29, 2001 | Zebuhr |
6253833 | July 3, 2001 | Köster et al. |
6261419 | July 17, 2001 | Zebuhr |
6328094 | December 11, 2001 | Mori et al. |
6351934 | March 5, 2002 | Snyder |
6381948 | May 7, 2002 | Klingels |
6388346 | May 14, 2002 | Lopatinsky et al. |
6392313 | May 21, 2002 | Epstein et al. |
6393208 | May 21, 2002 | Nosenchuck |
6427464 | August 6, 2002 | Beaverson et al. |
6439209 | August 27, 2002 | Wenger et al. |
6449939 | September 17, 2002 | Snyder |
6460342 | October 8, 2002 | Nalim |
6505462 | January 14, 2003 | Meholic |
6526936 | March 4, 2003 | Nalim |
6584764 | July 1, 2003 | Baker |
6606854 | August 19, 2003 | Siefker et al. |
6928804 | August 16, 2005 | Venkataramani et al. |
6988493 | January 24, 2006 | Wenger |
7044718 | May 16, 2006 | Platts |
7137243 | November 21, 2006 | Snyder et al. |
7487641 | February 10, 2009 | Frechette et al. |
7621118 | November 24, 2009 | Snyder et al. |
8132399 | March 13, 2012 | VanHolstyn |
20010015058 | August 23, 2001 | Snyder |
20010052228 | December 20, 2001 | Rakhmailov |
20020038555 | April 4, 2002 | Zebuhr |
20020071979 | June 13, 2002 | DuBose et al. |
20030079713 | May 1, 2003 | Nalim |
20050193713 | September 8, 2005 | Kovasity et al. |
20080000238 | January 3, 2008 | Ribaud et al. |
443643 | January 1942 | BE |
225426 | January 1943 | CH |
229280 | October 1943 | CH |
485386 | November 1929 | DE |
0582809 | June 1993 | EP |
0592817 | April 1994 | EP |
1455065 | May 2006 | EP |
2891310 | March 2007 | FR |
2373 | 1913 | GB |
959721 | June 1964 | GB |
1126705 | September 1968 | GB |
56101003 | August 1981 | JP |
60150427 | August 1985 | JP |
62020630 | January 1987 | JP |
4081510 | March 1992 | JP |
4094419 | March 1992 | JP |
6159101 | June 1994 | JP |
WO-2008/057826 | July 2008 | WO |
WO-2012/005619 | January 2012 | WO |
- A. Kharazi et al., “Preliminary Study of a Novel R718 Turbo-Compressoin Cycle Using a 3-Port Condensing Wave Rotor”, GT2004-53622, Proceedings of ASME Turbo Expo Power for Land, Sea, and Air, Jun. 2004 pp. 1-7.
- N. Müller, “Design of Compressor Impellers for Water as a Refrigerant”, ASHRAE Transaction, vol. 107 at 214-222 (2001).
- N. Müller, “Ein schneller Algorithmus für Entwurf and Berechnung von Laufrädern mit Radialfaserschaufeln”, Klingenberg J., Heller W.: Beiträge Zur Strömungs-Mechanik, TU Dresden at 235-244 (2001).
- P. Akbari et al., “Performance Improvement of Recuperated and Unrecuperated Microturbines Using Wave Rotor Machines”, Paper No. 218, CIMAC Congress 2004, Kyoto, pp. 1-13.
- P. Akbari et al., “Performance Improvement of Small Gas Turbines through Use of Wave Rotor Topping Cycles”, GT2003-38772, Proceedings of ASME Turbo Expo Power for Land, Sea, and Air, Jun. 2003, (ASME 2002), 2002, pp. 1-11.
- F. Iancu et al., “Feasibility Study of Integrating Four-Port Wave Rotors into Ultra-Micro Gas Turbines (UμGT)”, XP-002391768, 40th AIAA/ASME/SAE/ASEE Joint Propulsoin Conference and Exhibit, Jul. 2004, pp. 1-12.
- M. Nalim, “Longitudinally Stratified Combustion in Wave Rotors”, Journal of Propulsion and Power, vol. 15, No. 6, Nov.-Dec. 2000, pp. 1060-1068.
- R. Nalim et al., “Two-Dimensional Flow and NOx Emissions in Deflagrative Internal Combustion Wave Rotor Configurations”, GT-2002-30085, Proceedings of ASME International Turbine Institute ASME Turbo Expo, Jun. 2002, pp. 1-11.
- Photograph of Comprex Axial Wave Rotor in Mazda Diesel Engine (publicly used in or before 1987); 1 page.
- Capstone C60 Natural Gas (MicroTurbine)—Product Datasheet, Capstone Turbine Corp. (2003); 2 pages.
- Gerard E. Welch et al., Wave-Rotor-Enhanced Gas Turbine Engine Demonstrator, Gas Turbine Operation and Technology for Land, Sea and Air Propulsion and Power Systems Symposium, NATA/TM-1999-209459, Oct. 18-21, 1999.
- A. Kharazi et al., “Preliminary Study of a Novel R718 Turbo-Compression Cycle Using a 3-Port Condensing Wave Rotor”, GT2004-53622, Proceedings of ASME Turbo Expo Power for Land, Sea, and Air, Jun. 2004 pp. 1-7.
- G. Welch, “Overview of Wave-Rotor Technology for Gas Turbine Engne Topping Cycles”, U.S. Army Research Laboratory (Lewis field), (believed to have been published before Nov. 12, 2004), pp. 1-17.
- J. Kentfield, “Wave-Rotors and Highlights of their Development”, AIAA98-3248, 34th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit, Jul. 1998, pp. 1-9.
- J. Piechna et al., “Radial-Flow Wave Rotor Concepts, Unconventional Designs and Applications”, DRAFT IMECE2004-59022, Proceedings of IMECE04 2004 ASME International Mechanical Engineering Congress, Nov. 2004, pp. 1-10.
- M. Frackowiak et al., “Numerical Simulation of Unsteady-Flow Processes in Wave Rotors”, DRAFT IMECE2003-60973, Proceedings of IMECE04 2004 ASME International Mechanical Engineering Congress, Nov. 2004, pp. 1-16.
- P. Akbari et al., “Performance Investigation of Small Gas Turbine Engines Topped with Wave Rotors”, AIAA 2003-4414, 39th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit, Jul. 2003, pp. 1-11.
- P. Akbari et al., “A Review of Wave Rotor Technology and Its Applications”, IMECE2004-60082, Proceedings of IMECE04 2004 ASME International Mechanical Engineering Congress, Nov. 2004, pp. 1-23.
- P. Akbari et al., “Gas Dynamic Design Analyses of Charging Zone for Reverse-Flow Pressure Wave Superchargers”, Proceedings of ICES03 2003 Spring Technical Conference of the ASME Internal Combustion Engine Division, May 2003, (ASME 2002), ICES2003-690, pp. 1-11.
- P. Akbari et al., “Performance Improvement of Recuperated and Unrecuperated Microturbines Using Wave Rotor Machines”, Paper No. 218, CIMAC Contress 2004, Kyoto, pp. 1-13.
- P. Akbari et al., “Performance Improvement of Small Gas Turbines through Use of Wave Rotor Topping Cycles”, GT2003-38772, Proceedings of ASME Turbo Expo Power for Land, Sea, and Air, Jun. 2003, (ASME 2002), pp. 1-7 2002, pp. 1-11.
- P. Akbari et al., “Preliminary Design Procedure for Gas Turbine Topping Reverse-Flow Wave Rotors”, GTSJ, IGTC2003Tokyo FR-301, Proceedings of the International Gas Turbine Congress, Nov. 2003, pp. 1-8.
- P. Akbari et al., “Utilizing Wave Rotor Technology to Enhance the Turbo Compression in Power and Refrigeration Cycles”, IMECE2003-44222, Proceedings of IMECE'03 2003 ASME International Mechanical Engineering Congress and Exposition, Nov. 2003, pp. 1-9.
- A. Mehra et al., “A Six-Wafer Combustion System for a Silicon Micro Gas Turbine Engine”, Journal of Microelectromechanical Systems, vol. 9, No. 4, Dec. 2000, pp. 517-527.
- M. Schmidt, “Portable MEMS Power Sources”, 2003 IEEE International Solid-State Circuits Conference, Session 22, TD: Embedded Technologies, Paper 22.5, 8 pages.
- S. Ashley, “Turbines on a Dime”, XP-000727170, Mechanical Engineering ASME, vol. 119, No. 10, Oct. 1997, pp. 78-81.
- F. Iancu et al., “Feasibility Study of Integrating Four-Port Wave Rotors into Ultra-Mirco Gas Turbines (UμGT)”, XP-002391768, 40th AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit, Jul. 2004, pp. 1-12.
- J. Wilson et al., “Wave Rotor Optimization for Gas Turbine Engine Topping Cycles”, Journal of Propulsion and Power, vol. 12, No. 4, Jul.-Aug. 1996, pp. 778-785.
- Y. Oguri et al., “Research on Adaptation of Pressure Wave Supercharger (PWS) to Gasoline Engine”, 2001-01-0368, SAE Technical Paper Series, SAE 2001 World Congress, Mar. 5-8, 2001, pp. 1-7.
- H. Heisler, “Advanced Engine Technology”, SAE International, 1997, pp. 356-363.
- B. Berlinger, “New Pressure Wave Supercharger Improves Engine Performance, Reduces Emissions”, Caterpillar, Tech of the Week (believed to have been published or publically used prior to Nov. 12, 2004), 2 pages.
- M. Nalim, “Longitudinally Stratifield Combustion in Wave Rotors”, Journal of Propulsion and Power, vol. 15, No. 6, Nov.-Dec. 2000, pp. 1060-1068.
- R. Nalim et al., “Two-Dimensional Flow and NOx Emissions in Deflagrative Internal Combustion Wave Rotor Configurations”, GT-2002-20085, Proceedings of ASME International Turbine Institute ASME Turbo Expo, Jun. 2002, pp. 1-11.
- J. Wilson, “Design of the NASA Lewis 4-Port Wave Rotor Experiment”, Nasa Contractor Report 202351, Contract No. NAS3-27186, AIAA-97-3139, Jun. 1997, pp. 1-6.
- P. Azoury, “Engineering Applications of Unsteady Fluid Flow”, John Wiley & Sons, 1992, pp. 1-31, 109-144 (including contents, pp. vii-ix; foreward, pp. xi-xii; preface, pp. xiii-xvii).
- Photograph of Comprex Axial Wave Rotor in Mazda Diesel Engine (publicly used in or befor 1987); 1 page.
- Capstone C60 Natural Gas (Micro Turbine)—Product Datasheet, Capstone Turbine Corp. (2003); 2 pages.
- Livermore, Carol; “Here Come The Microengines;” The Industrial Physicist, (Dec. 2001/Jan. 2002); 4 pages.
- “Mini Generator Has Enough Power To Run Electronics;” Georgia Institute of Technology (Nov. 24, 2004); 2 pages.
Type: Grant
Filed: Mar 1, 2011
Date of Patent: Mar 3, 2015
Assignee: Board of Trustees of Michigan State University (East Lansing, MI)
Inventors: Norbert Müller (Haslett, MI), Pejman Akbari (New York, NY), Janusz Piechna (Warsaw), Florin Iancu (Silver Spring, MD)
Primary Examiner: Andrew Nguyen
Application Number: 13/023,568
International Classification: F02C 3/02 (20060101);