Claims
- 1. A bimodal fan having a variable flow rate and thrust and power requirement without changing its pressure ratio, said bimodal fan comprising:
a fan, driven by an engine; a duct, enclosing the fan, for directing flow of air from the fan; and two concentric but separate flow paths within said duct, said flow paths including:
a first, inner flow path fully open all the time and sized to provide best take off performance with available horsepower, and; a second, outer flow path, concentric to the first, inner flow path, said second, outer flow path including a radial array of movable vanes for varying the flow through the second, outer flow path.
- 2. The bimodal fan of claim 1 wherein the movable vanes are closed at takeoff and opened at altitude to provide additional thrust.
- 3. The bimodal fan of claim 1, further comprising:
a low loss heat exchanger provided in at least one of the first and second flow paths, for transferring waste heat of the internal combustion engine from at least one of exhaust and cooling water, directly to fan discharge air down stream of the fan so as to remove the engine waste heat, and boost the fan system effective thermal efficiency by increasing the enthalpy of fan discharge air, the heat exchanger comprising a cluster of thin walled tubes which vary in cross sectional shape.
- 4. The bimodal fan of claim 3, further comprising a supercharger using the fan to supercharge the engine to provide an additional altitude capability, increasing cruising speed and lowering fuel consumption for a given speed and reducing engine wear by diverting pressurized air from the inner fan flow path through hollow struts which inject the pressurized air into a collector plenum which is attached to the outside of the duct in the outer flow path.
- 5. The bimodal fan of claim 1, further comprising:
a water injection system, coupled to said engine, for injecting water into an intake of said engine to reduce detonation an increase horsepower output of said engine, said water injection system comprising:
a nozzle body, coupled to the intake of said engine, said nozzle body receiving pressurized air from the duct through the rear of the nozzle body and passing through an array of holes into a plenum chamber; a center bullet, provided within the nozzle, for providing a contour for a narrow nozzle annulus, said bullet being concentric to the nozzle body; a narrow annular gap, formed between the center bullet and nozzle body; an annular water chamber, formed in the nozzle body, for receiving pressurized water from a pressurized water source; and a circumferential gap leading from an annular water chamber to the nozzle annulus.
- 6. The bimodal fan of claim 5, wherein water enters the nozzle body and fills the annular water chamber which feeds water to the circumferential gap introducing water into the airflow such that as water emerges from the circumferential gap, the shearing action of high velocity air through the nozzle body forms small droplets of water injected into the engine.
- 7. A method of generating variable thrust from a ducted fan without changing its pressure ratio, the method of generating variable thrust from a ducted fan comprising:
generating, using a fan driven by an engine, a flow of air through a duct, enclosing the fan and directing flow of air from the fan, diverting the flow of air through two concentric but separate flow paths within the duct, the flow paths including a first, inner flow path fully open all the time and sized to provide best take off performance with available horsepower, and a second, outer flow path, concentric to the first, inner flow path, the second, outer flow path including a radial array of movable vanes for varying the flow through the second, outer flow path.
- 8. The method of generating variable thrust from a ducted fan of claim 7 wherein the movable vanes are closed at takeoff and opened at altitude to provide additional thrust.
- 9. The method of generating variable thrust from a ducted fan of claim 7, further comprising the steps of:
directing the flow of air through a low loss heat exchanger provided in at least one of the first and second flow paths, transferring waste heat of the internal combustion engine from at least one of exhaust and cooling water directly to fan discharge air down stream of the fan so as to remove the engine waste heat, and boost the fan system effective thermal efficiency by increasing the enthalpy of fan discharge air.
- 10. The method of generating variable thrust from a ducted fan of claim 9, further comprising the steps of:
using the fan to supercharge the engine to provide an additional altitude capability, increasing cruising speed and lowering fuel consumption for a given speed and reducing engine wear by diverting pressurized air from the inner fan flow path through hollow struts which inject the pressurized air into a collector plenum which is attached to the outside of the duct in the outer flow path.
- 11. The method of generating variable thrust from a ducted fan of claim 7, further comprising the steps of:
injecting water into an intake of the engine to reduce detonation an increase horsepower output of the engine, said step of injecting water into the engine comprising the steps of providing a nozzle body, coupled to the intake of the engine, the nozzle body receiving pressurized air from the duct through the rear of the nozzle body and passing through an array of holes into a plenum chamber, providing a center bullet within the nozzle, for providing a contour for a narrow nozzle annulus, the bullet being concentric to the nozzle body, providing a narrow annular gap between the center bullet and nozzle body, providing an annular water chamber, formed in the nozzle body, for receiving pressurized water from a pressurized water source, and providing a circumferential gap leading from an annular water chamber to the nozzle annulus.
- 12. The method of generating variable thrust from a ducted fan of claim 11, wherein water enters the nozzle body and fills the annular water chamber which feeds water to the circumferential gap introducing water into the airflow such that as water emerges from the circumferential gap, the shearing action of high velocity air through the nozzle body forms small droplets of water injected into the engine.
- 13. A water injection system for injecting water into an intake of an engine to reduce detonation an increase horsepower output of said engine, said water injection system comprising:
a nozzle body, coupled to the intake of said engine, said nozzle body receiving pressurized air from the duct through the rear of the nozzle body and passing through an array of holes into a plenum chamber; a center bullet, provided within the nozzle, for providing a contour for a narrow nozzle annulus, said bullet being concentric to the nozzle body; a narrow annular gap, formed between the center bullet and nozzle body; an annular water chamber, formed in the nozzle body, for receiving pressurized water from a pressurized water source; and a circumferential gap leading from an annular water chamber to the nozzle annulus.
- 14. The bimodal fan of claim 13, wherein water enters the nozzle body and fills the annular water chamber which feeds water to the circumferential gap introducing water into the airflow such that as water emerges from the circumferential gap, the shearing action of high velocity air through the nozzle body forms small droplets of water injected into the engine.
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] The present application claims priority from Provisional U.S. Patent Application No. 60/286,51760 filed on Apr. 27, 2001, and incorporated herein by reference.
Provisional Applications (1)
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Number |
Date |
Country |
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60286517 |
Apr 2001 |
US |