FLUID FLOW ENERGY HARVESTER

US 20100187829A1
Filed: 01/22/2010
Published: 07/29/2010
Est. Priority Date: 01/26/2009
Status: Abandoned Application

First Claim

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1. An energy harvester, comprising:

a fluid flow path defined by an inflow fluid channel, an outflow fluid channel, and a chamber disposed between said inflow fluid channel and said outflow channel;

a main shaft located in said chamber and axially positioned in said fluid flow path;

a first Magnus cylinder mounted transversely in said fluid flow path on said main shaft located in said chamber, said first Magnus cylinder being mounted on said main shaft by a first central axis and rotationally driven about said first central axis by a motor;

a second Magnus cylinder cooperatively associated with said first Magnus cylinder and mounted on said main shaft by a second central axis, said second Magnus cylinder being separated by a distance in a downstream direction of said fluid flow path and rotationally driven on said second central axis by said motor;

a means for producing an electrical current from a movement of said main shaft caused at least in part by a movement of said first Magnus cylinder and said second Magnus cylinder, said movement of said main shaft being in a direction perpendicular to said fluid flow path and providing a torque value that is greater than a theoretical torque value due to an acceleration of a fluid moving in said downstream direction of said fluid flow path, said acceleration being caused by a rotation of at least one of said first Magnus cylinder and said second Magnus cylinder;

a battery for charging by said electrical current produced from said means for producing said electrical current; and

means for connecting said battery to an electrical grid.

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Abstract

An energy harvester capable of providing motion from fluid flow includes a Magnus cylinder defined by a cylinder driven by a motor causing the cylinder to rotate so that lift is created by the fluid flowing past the cylinder. A channel or system may be provided to direct the fluid flow to the cylinder. The rotating cylinder configuration is integrated into a mechanical device that is designed to transfer the lift into a rotary mechanical motion to drive a generator. The device can be utilized in either air or hydraulic environments. A modification of the energy harvester can be configured to utilize the electricity generate to produce hydrogen for use in fuel cells or for combustion.

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42 Claims

1. An energy harvester, comprising:
- a fluid flow path defined by an inflow fluid channel, an outflow fluid channel, and a chamber disposed between said inflow fluid channel and said outflow channel;
  
  a main shaft located in said chamber and axially positioned in said fluid flow path;
  
  a first Magnus cylinder mounted transversely in said fluid flow path on said main shaft located in said chamber, said first Magnus cylinder being mounted on said main shaft by a first central axis and rotationally driven about said first central axis by a motor;
  
  a second Magnus cylinder cooperatively associated with said first Magnus cylinder and mounted on said main shaft by a second central axis, said second Magnus cylinder being separated by a distance in a downstream direction of said fluid flow path and rotationally driven on said second central axis by said motor;
  
  a means for producing an electrical current from a movement of said main shaft caused at least in part by a movement of said first Magnus cylinder and said second Magnus cylinder, said movement of said main shaft being in a direction perpendicular to said fluid flow path and providing a torque value that is greater than a theoretical torque value due to an acceleration of a fluid moving in said downstream direction of said fluid flow path, said acceleration being caused by a rotation of at least one of said first Magnus cylinder and said second Magnus cylinder;
  
  a battery for charging by said electrical current produced from said means for producing said electrical current; and
  
  means for connecting said battery to an electrical grid.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 19, 20, 21, 27)
- - 2. The energy harvester of claim 1, wherein said distance separating said second Magnus cylinder from said first Magnus cylinder is about 2 to about 20 diameters of said first Magnus cylinder in the downstream direction.
  - 3. The energy harvester of claim 1, wherein said motor is operable under electric power.
  - 4. The energy harvester of claim 1, wherein said motor is operable under pneumatic power.
  - 5. The energy harvester of claim 1, wherein said motor is operable under hydraulic power.
  - 6. The energy harvester of claim 1, wherein said energy harvester is attached to a floating platform.
  - 7. The energy harvester of claim 1, wherein said energy harvester is attached to a non floating platform.
  - 8. The energy harvester of claim 1 wherein a fluid in said fluid flow path is air.
  - 9. The energy harvester of claim 1 wherein a fluid in said fluid flow path is water.
  - 10. The energy harvester of claim 1 where said motor rotationally driving the Magnus cylinder rotates said Magnus cylinder in one direction for a positive flow and in an opposite direction for a negative flow.
  - 11. The energy harvester of claim 1, wherein said means for producing said electrical current comprises:
    - a belt rotatably movable in response to movement of at least one of said first Magnus cylinder and said second Magnus cylinder, andat least one pinion gear drivable by the movement of said belt, said pinion gear being operable connected to an electrical generator,wherein driving of said pinion gear operable connected to an electrical generator produces said electrical current.
  - 12. The energy harvester of claim 11, wherein said belt is selected from the group consisting of v-belts, ribbed belts, cogged belts, roller chain, and cables.
  - 13. The energy harvester of claim 1, wherein at least two Magnus cylinders are positioned in said fluid flow path, said at least two Magnus cylinders being separated from each other by a minimum distance of 1 diameter of the largest Magnus cylinder.
  - 14. The energy harvester of claim 1, wherein at least two Magnus cylinders are positioned in said fluid flow path, said at least two Magnus cylinders being separated by a maximum distance of 20 diameters of the largest Magnus cylinder.
  - 19. The energy harvester of claim 1, wherein a fluid in said fluid flow path is received from an effluent system.
  - 20. The energy harvester of claim 1, wherein a fluid in said fluid flow path is a gas.
  - 21. The energy harvester of claim 1 where the inflow fluid channel is connected to one or more of a sewer, a water treatment facility, a water drain, a holding pond, a roof drain, an air conditioning line, and a holding tank.
  - 27. The energy harvester of claim 1, wherein said means for producing said electrical current comprises:
    - a drive shaft rotate ably movable in response to movement of at least said first Magnus cylinder, andat least one gear drivable by the movement of at least said first Magnus cylinder, said gear being operably connected to an electrical generator,wherein driving of said gear operably connected to an electrical generator produces said electrical current.

15. An energy harvesting system for use in a fluid flow path, said energy harvesting system comprising:
- a source of fluid;
  
  a fluid flow path from said source of fluid and defined by an inflow fluid channel, an outflow fluid channel, and an energy harvester chamber disposed between said inflow fluid channel and said outflow fluid channel;
  
  a first Magnus cylinder mounted in said energy harvester chamber transversely to said fluid flow path;
  
  a second Magus cylinder cooperatively associated with said first Magnus cylinder located in a downstream direction from the first Magnus cylinder;
  
  means for producing an electrical current from a movement of said first Magnus cylinder and said second Magnus cylinder, said movement of said first Magnus cylinder and said second Magnus cylinder being perpendicular to said fluid flow path and providing a torque value that is greater than a theoretical torque value due to an acceleration of a fluid flow in said downstream direction, said acceleration being caused by a rotation of at least one of said first Magnus cylinder and said second Magnus cylinder; and
  
  means for connecting said means for producing said electrical current to an electrical power grid.
- View Dependent Claims (16, 17, 18)
- - 16. The energy harvesting system of claim 15, wherein said source of fluid is an effluent system.
  - 17. The energy harvesting system of claim 15, wherein said source of fluid is a gas.
  - 18. The energy harvesting system of claim 15 where the inflow fluid channel is connected to one or more of a sewer, a water treatment facility, a water drain, a holding pond, an aqueduct, a roof drain, an outflow from a dam, an air conditioning line, and a holding tank.

22. An energy harvesting system for use in a fluid flow application, said energy harvesting system comprising:
- a source of fluid;
  
  an outflow line extending from said source of fluid;
  
  a fluid flow path in said outflow line and defined by an inflow fluid channel, an outflow fluid channel, and an energy harvester chamber disposed between said inflow fluid channel and said outflow fluid channel;
  
  a first Magnus cylinder mounted in said energy harvester chamber transverse to a flow of fluid in said fluid flow path;
  
  at least a second Magus cylinder downstream from said first Magnus cylinder and cooperatively associated with said first Magnus cylinder;
  
  means for producing an electrical current from a movement of said first Magnus cylinder and said second Magnus cylinder in a direction perpendicular to said fluid flow path and providing a torque value that is greater than a theoretical torque value due to an acceleration of said flow of fluid in a downstream direction of said fluid flow path, said acceleration being caused by a rotation of at least one of said first Magnus cylinder and said second Magnus cylinder;
  
  a reaction chamber for separating water into oxygen and hydrogen using said electrical current;
  
  an outflow means for the oxygen; and
  
  an outflow means for the hydrogen.

23. An energy harvesting system for use in a fluid flow application, said energy harvesting system comprising:
- a source of fluid;
  
  a floating platform located in fluid communication with said source of fluid;
  
  an outflow line extending from said source of fluid;
  
  a fluid flow path in said outflow line and defined by an inflow fluid channel, an outflow fluid channel, and an energy harvester chamber disposed between said inflow fluid channel and said outflow fluid channel;
  
  a first Magnus cylinder transversely mounted in said energy harvester chamber and retractably movable parallel to a flow of fluid in said fluid flow path;
  
  at least a second Magus cylinder cooperatively associated with said first Magnus cylinder and retractably movable parallel to said flow of fluid in said fluid flow path;
  
  means for producing an electrical current from a movement of said first Magnus cylinder and said second Magnus cylinder perpendicular to said flow of fluid in said fluid flow path and providing a torque value that is greater than a theoretical torque value due to an acceleration of said flow of fluid in a downstream direction of said fluid flow path, said acceleration being caused by a rotation of at least one of said first Magnus cylinder and said second Magnus cylinder; and
  
  means for connecting the means for producing the electrical current to an electrical grid.
- View Dependent Claims (25)
- - 25. The energy harvester of claim 23, wherein the electrical generator produces said electrical current and is connected directly to the power grid.

24. An energy harvesting system for use in a fluid flow, said energy harvesting system comprising:
- a bridge platform;
  
  a source of fluid;
  
  an outflow line extending from said source of fluid;
  
  a fluid flow path in said outflow line and defined by an inflow fluid channel, an outflow fluid channel, and an energy harvester chamber disposed between said inflow fluid channel and said outflow fluid channel;
  
  a first Magnus cylinder transversely mounted in said energy harvester chamber and retractably movable parallel to a flow of fluid in said fluid flow path;
  
  at least a second Magus cylinder cooperatively associated with said first Magnus cylinder;
  
  means for producing an electrical current from a movement of at least said first Magnus cylinder in said fluid flow path perpendicular to said flow of fluid in said fluid flow path, said movement providing a torque value that is greater than a theoretical torque value due to an acceleration of said flow of fluid moving in a downstream direction of said fluid flow path, said acceleration being caused by a rotation of at least one of said first Magnus cylinder and said second Magnus cylinder; and
  
  means for connecting the means for producing the electrical current to an electrical grid.

26. An energy harvesting system for use in a fluid flow application, said energy harvesting system comprising:
- a bridge platform;
  
  a source of fluid;
  
  an outflow line extending from said source of fluid;
  
  a fluid flow path in said outflow line and defined by an inflow fluid channel, an outflow fluid channel, and an energy harvester chamber disposed between said inflow fluid channel and said outflow fluid channel;
  
  a first Magnus cylinder transversely mounted in said energy harvester chamber and retractably movable parallel to the flow of fluid;
  
  at least a second Magus cylinder located in a downstream direction at least 2 diameters of the first Magnus cylinder from said first Magnus cylinder and cooperatively associated with said first Magnus cylinder; and
  
  means for producing an electrical current from a movement of at least said first Magnus cylinder in said fluid flow path in a direction perpendicular to said fluid flow path, said movement providing a torque value that is greater than a theoretical torque value due to an acceleration of a fluid moving in said downstream direction of said fluid flow path, said acceleration being caused by a rotation of at least one of said first Magnus cylinder and said second Magnus cylinder.
- View Dependent Claims (40)
- - 40. The energy harvesting system of claim 26, wherein a distance separating the first Magnus cylinder and the second Magnus cylinder is from 2 to 20 diameters of the first Magnus cylinder.

28. An energy harvester, comprising:
- a first drive shaft;
  
  means to rotate said first drive shaft;
  
  a first Magnus cylinder connected to said first drive shaft for driving said first Magnus cylinder;
  
  a second Magnus cylinder located downstream from the first Magnus cylinder and connected to said first drive shaft for associated operability with the first Magnus cylinder;
  
  a fluid in communication with said first and second Magnus cylinders;
  
  a second drive shaft rotatably movable in response to movement of said first Magnus cylinder and said second Magnus cylinder, andat least one gear drivable by the movement of at least said second drive shaft, said gear being operable connected to an electrical generator,wherein driving of said gear operable connected to an electrical generator produces said electrical current.
- View Dependent Claims (29, 30, 31, 32, 33, 34, 35, 36, 37)
- - 29. The energy harvester of claim 28, wherein second Magnus cylinder is separated by 2 to 20 diameters of the diameter of said first Magnus cylinder in the downstream direction.
  - 30. The energy harvester of claim 28, wherein said means to rotate the first drive shaft is an electric motor.
  - 31. The energy harvester of claim 28, wherein said means to rotate the first drive shaft is a pneumatic motor.
  - 32. The energy harvester of claim 28, wherein said means to rotate the first drive shaft is a hydraulic motor.
  - 33. The energy harvester of claim 28, wherein said energy harvester is attached to a floating platform.
  - 34. The energy harvester of claim 28, wherein said energy harvester is attached to a non floating platform.
  - 35. The energy harvester of claim 28 wherein said fluid is air.
  - 36. The energy harvester of claim 28 wherein said fluid is water.
  - 37. The energy harvester of claim 28 wherein said means to rotate said first drive shaft rotates said first Magnus cylinder in one direction for a flow of said fluid in one direction and in a reverse direction for a flow of said fluid in an opposite direction.

38. A device for energy harvesting, comprising:
- a first drive shaft;
  
  means to rotate said first drive shaft;
  
  a first Magnus cylinder connected to said first drive shaft and rotatable by said first drive shaft;
  
  a second Magnus cylinder located downstream from the first Magnus cylinder at least 2 diameters of the first Magnus cylinder from the first Magnus cylinder and connected to said first drive shaft for associated operability with the first Magnus cylinder;
  
  a fluid in communication with said first and second Magnus cylinders;
  
  a second drive shaft rotatably movable in response to movement of said first Magnus cylinder and said second Magnus cylinder, andat least one gear drivable by the movement of at least said second drive shaft, said gear being operably connected to an electrical generator,wherein a torque produced by the driving of said gear operably connected to said electrical generator produces said electrical current; and
  
  wherein said torque is greater than a theoretical torque value due to an acceleration of said fluid moving in a downstream direction, said acceleration being caused by a rotation of at least one of said first Magnus cylinder and said second Magnus cylinder.
- View Dependent Claims (41)
- - 41. The device of claim 38, wherein a distance separating the first Magnus cylinder and the second Magnus cylinder is from 2 to 20 diameters of the first Magnus cylinder.

39. A device for energy harvesting, comprising:
- a first drive shaft;
  
  means to rotate said first drive shaft;
  
  a first Magnus cylinder connected to said first drive shaft and rotatable by said first drive shaft;
  
  a second Magnus cylinder located downstream from the first Magnus cylinder at least 2 diameters of the first Magnus cylinder from the first Magnus cylinder and connected to said first drive shaft for associated operability with the first Magnus cylinder;
  
  a first fluid in communication with said first and second Magnus cylinders;
  
  a second drive shaft rotatably movable in response to movement of said first Magnus cylinder and said second Magnus cylinder in said first fluid, andat least one gear drivable by the movement of at least said second drive shaft, said gear being operably connected to a pump,wherein a torque produced by the driving of said gear operably connected to the pump pumps a second fluid; and
  
  wherein said torque is greater than a theoretical torque value due to an acceleration of said first fluid moving in a downstream direction, said acceleration being caused by a rotation of at least one of said first Magnus cylinder and said second Magnus cylinder.
- View Dependent Claims (42)
- - 42. The device of claim 39, wherein a distance separating the first Magnus cylinder and the second Magnus cylinder is from 2 to 20 diameters of the first Magnus cylinder.

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Current Assignee
E. Gen LLC
Original Assignee
E. Gen LLC
Inventors
Douglas, Joel S.

Application Number

US12/691,951
Publication Number

US 20100187829A1
Time in Patent Office

Days
Field of Search
US Class Current

290/55
CPC Class Codes

F03B 17/062   with rotation axis substant...

F03B 5/00   Machines or engines charact...

F03D 1/0601   using the Magnus effect

F03D 3/007   using the Magnus effect

F05B 2240/201   using the Magnus-effect

Y02E 10/20   Hydro energy

Y02E 10/30   Energy from the sea, e.g. u...

Y02E 10/72   Wind turbines with rotation...

Y02E 10/74   Wind turbines with rotation...

FLUID FLOW ENERGY HARVESTER

First Claim

1 Assignment

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Abstract

26 Citations

42 Claims

Specification

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FLUID FLOW ENERGY HARVESTER

First Claim

1 Assignment

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

26 Citations

42 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links