SPRING DISC ENERGY HARVESTER APPARATUS AND METHOD

US 20100237748A1
Filed: 06/02/2010
Published: 09/23/2010
Est. Priority Date: 02/08/2007
Status: Active Grant

First Claim

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1. An energy harvesting apparatus, comprising:

a first disc spring having an axial center and an outer peripheral area;

a second disc spring having an axial center and an outer peripheral area;

an electrically responsive material secured to a surface of said first disc spring, said electrically responsive material operating to generate an electrical output signal in response to changing levels of strain experienced by said electrically responsive material, in response to flexing motion of said first disc spring;

a support member for supporting said outer peripheral areas of said first and second disc springs and holding said disc springs in facing relationship to one another; and

a fastening assembly for applying a preload force to said disc springs to soften said disc springs, said fastening assembly adapted to be secured to a vibrating structure such that vibration energy from said structure is transmitted to said disc springs, causing flexing of said disc springs.

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Abstract

An energy harvesting apparatus and method that is especially well suited for harvesting low frequency broadband vibration energy from a vibrating structure is presented. The apparatus includes a pair of disc springs that are arranged in an opposing relationship. A threaded fastening member and a threaded nut extend through apertures in each of the disc springs and enable a predetermined preload force to be applied to the disc springs. The preload effectively “softens” the disc springs, thus heightening the sensitivity of the disc springs to low frequency, low amplitude vibration energy. A piezoelectric material ring is secured to each of the disc springs. Each piezoelectric material ring experiences changes in strain as its associated disc spring deflects in response to vibration energy experienced from a vibrating structure. The electrical output from each piezoelectric material ring can be used to power or activate various forms of electronic sensors and devices, or it can be conditioned and stored in a circuit for later use.

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20 Claims

1. An energy harvesting apparatus, comprising:
- a first disc spring having an axial center and an outer peripheral area;
  
  a second disc spring having an axial center and an outer peripheral area;
  
  an electrically responsive material secured to a surface of said first disc spring, said electrically responsive material operating to generate an electrical output signal in response to changing levels of strain experienced by said electrically responsive material, in response to flexing motion of said first disc spring;
  
  a support member for supporting said outer peripheral areas of said first and second disc springs and holding said disc springs in facing relationship to one another; and
  
  a fastening assembly for applying a preload force to said disc springs to soften said disc springs, said fastening assembly adapted to be secured to a vibrating structure such that vibration energy from said structure is transmitted to said disc springs, causing flexing of said disc springs.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
- - 2. The apparatus of claim 1, further comprising an electrically responsive material secured to said second disc spring.
  - 3. The apparatus of claim 1, wherein said electrically responsive material comprises a ring of piezoelectric material adhered to said first disc spring coaxially with said axial center of said first spring disc.
  - 4. The apparatus of claim 1, wherein said disc springs each include an aperture at said axial center thereof.
  - 5. The apparatus of claim 4, wherein said fastening assembly includes a threaded bolt extending through said apertures in said disc springs, and a threaded nut secured to said threaded bolt.
  - 6. The apparatus of claim 1, wherein at least one of said disc springs is comprised of spring steel.
  - 7. The apparatus of claim 1, wherein said preload force is sufficient to place said disc springs in a condition of low stiffness.
  - 8. The apparatus of claim 7, wherein said preload force deflects said disc springs to positions where said disc springs are at an approximate midpoint of a range of low stiffness.

9. An energy harvesting apparatus, comprising:
- a disc spring having an axial center and an outer peripheral area;
  
  an electrically responsive material secured to a surface of the disc spring, said electrically responsive material operating to generate an electrical output signal in response to changing levels of strain experienced by said electrically responsive material, in response to flexing motion of said disc spring;
  
  a support member for supporting said outer peripheral area of said disc spring, said support member further being supported, relative to a structure, to receive vibration energy experienced by said structure, so that said vibration energy causes flexing of said disc spring; and
  
  a fastening assembly for securing said disc spring to said support member with a predetermined preload force directed along said axial center of said disc spring sufficient to soften said disc spring to promote flexing thereof in response to said vibration.
- View Dependent Claims (10, 11, 12, 13, 14)
- - 10. The energy harvesting apparatus of claim 9, wherein:
    - said disc spring includes an aperture formed at an axial center thereof;
      
      said support member includes an aperture at an axial center thereof; and
      
      said fastening assembly includes a threaded bolt that extends through said apertures, and a threaded nut that enables said preload force to be applied to said disc spring.
  - 11. The energy harvesting apparatus of claim 10, wherein said electrically responsive material comprises a piezoelectric ring having an aperture formed at an axial center thereof.
  - 12. The energy harvesting apparatus of claim 11, wherein said piezoelectric ring is adhered to said surface of said disc spring.
  - 13. The energy harvesting apparatus of claim 9, wherein said support member comprises another disc spring having a peripheral area, and wherein said peripheral areas of said disc springs are arranged in opposing relationship to one another.
  - 14. The energy harvesting apparatus of claim 9, wherein said disc spring is comprised of spring steel.

15. A method for forming an energy harvesting device, comprising:
- a) providing a disc spring;
  
  b) supporting an outer peripheral edge of said disc spring;
  
  c) applying a pre-load force to an inner peripheral edge of said disc spring directed along an axial center of said disc spring;
  
  d) while said pre-load force is being applied, using an adhesive compound to adhere a piezoelectric material to said disc spring;
  
  e) waiting a predetermined time until said adhesive compound has cured;
  
  f) securing said disc spring to a support element using a fastening assembly; and
  
  g) using said fastening assembly and said support element to apply a predetermined preload force to said disc spring that causes a degree of deflection of said disc spring, said deflection being sufficient to place said disc spring in a condition of reduced stiffness.
- View Dependent Claims (17, 18)
- - 17. The method of claim 15, further comprising repeating operations b) through g) for a second disc spring and arranging said disc spring and said second disc spring in opposing relationship.
  - 18. The method of claim 15, wherein using an adhesive compound includes using a first electrically conductive, adhesive compound and a second, non-conductive adhesive compound.

16. The method of clam 15, wherein using said fastening assembly comprises using a threaded bolt having a threaded nut.

19. A method for harvesting vibration energy from a vibrating source, comprising:
- securing a pair of disc springs to the vibrating source, where the disc springs are held in opposing relationship and pre-loaded with a force sufficient to substantially soften the disc springs and to make the disc springs sensitive to low frequency, low amplitude vibration energy;
  
  securing a material to a first one of the disc springs, where the material generates an electrical output signal in response to changes in strain that is experienced as said first disc spring flexes in response to vibration transmitted from said vibrating structure; and
  
  receiving electrical output signals from said material as said one disc spring flexes during vibration of said structure.
- View Dependent Claims (20)
- - 20. The method of claim 19, further comprising:
    - securing a material to a second one of said disc springs to generate electrical signals in response to changes in strain experienced by said second one of said disc springs.

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Current Assignee
The Boeing Co.
Original Assignee
The Boeing Co.
Inventors
Peña, Gerardo, Malkin, Matthew C.

Granted Patent

US 8,415,860 B2
Time in Patent Office

Days
Field of Search
US Class Current

310/339
CPC Class Codes

H02N 2/021   using intermittent driving,...

H02N 2/186   Vibration harvesters

H02N 2/22   Methods relating to manufac...

H10N 30/03   Assembling devices that inc...

H10N 30/88   Mounts; Supports; Enclosure...

H10N 30/886   Mechanical prestressing mea...

Y10T 29/42   Piezoelectric device making

SPRING DISC ENERGY HARVESTER APPARATUS AND METHOD

First Claim

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Abstract

38 Citations

20 Claims

Specification

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SPRING DISC ENERGY HARVESTER APPARATUS AND METHOD

First Claim

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0 Petitions

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Accused Products

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Abstract

38 Citations

20 Claims

Specification

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Solutions

Use Cases

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