IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0713204
(2012-12-13)
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등록번호 |
US-9284946
(2016-03-15)
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발명자
/ 주소 |
|
출원인 / 주소 |
|
대리인 / 주소 |
Merek, Blackmon & Voorhees, LLC
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인용정보 |
피인용 횟수 :
0 인용 특허 :
16 |
초록
▼
A windmill is disclosed having over speed protection. In a preferred embodiment, the vanes are symmetric, curved metal sheets, with each vane's shape having a circular arc corresponding to its portion of the cylindrical support structure. Each vane is mounted with a large leading portion exposed to
A windmill is disclosed having over speed protection. In a preferred embodiment, the vanes are symmetric, curved metal sheets, with each vane's shape having a circular arc corresponding to its portion of the cylindrical support structure. Each vane is mounted with a large leading portion exposed to the wind. The imbalance of surface area causes the wind to push the vane open when moving downwind and push the vane closed when moving upwind. During periods of high rotational speed, the off-axis centers of mass cause each vane to rotate towards a closed position under centrifugal force. Once the critical speed is reached, the vanes fully close as they pass through the upwind side.
대표청구항
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1. A windmill rotating in a first direction about a vertical axis comprising: a windmill support having a circular upper support plate and a lower support plate and connected by a central drive shaft;a base for retaining said windmill support, said central drive shaft received in said base for allow
1. A windmill rotating in a first direction about a vertical axis comprising: a windmill support having a circular upper support plate and a lower support plate and connected by a central drive shaft;a base for retaining said windmill support, said central drive shaft received in said base for allowing rotation of said windmill support about said base;a plurality of vane supports, each vane support being connected from an outer perimeter of said upper support plate to an outer perimeter of said lower support plate;a windmill vane asymmetrically mounted of each of said vane supports, each said vane having a first front portion defined from said vane support to a first outer edge of said vane parallel to said vane support, and having a second rear portion defined from said vane support to a second outer edge of said vane opposite from said first outer edge, wherein during rotation of said windmill in said first direction about said base, said first outer edge of each windmill vane proceeds the second outer edge;wherein said windmill vanes are normally biased so that said front vane portion lies inward from said rear vane portion such that wind pressure against said windmill vanes causes said windmill to rotate in said first direction;wherein each windmill vane on said vane supports can open and close independently of any other windmill vane mounted on said vane supports. 2. The windmill of claim 1, wherein said upper support plate and said lower support plate having the same radius; and said upper support plate, said lower support plates and said plurality of vane supports form a cylindrical shape. 3. The windmill of claim 1, wherein said upper support plate has a radius larger than said lower support plate; and said upper support plate, said lower support plates and said plurality of vane supports form a frustoconical shape. 4. The windmill of claim 1, wherein said front vane portion weighs more than said rear vane portion. 5. The windmill of claim 1, further having a cam mounted between said windmill vane and said lower support plate for biasing said windmill vane in said in said open position. 6. A method of protecting a windmill rotating in a first direction about a vertical axis comprising: providing a windmill support having a circular upper support plate and a circular lower support plate and connected by a central drive shaft;providing a base for retaining said windmill support, said central drive shaft received in said base for allowing rotation of said windmill support about said base;providing a plurality of vane supports, each vane support being connected from an outer perimeter of said upper support plate to an outer perimeter of said lower support plate;providing a windmill vane asymmetrically mounted of each of said vane supports, each said vane having a first front portion defined from said vane support to a first outer edge of said vane parallel to said vane support, and having a second rear portion defined from said vane support to a second outer edge of said vane opposite from said first outer edge, wherein during rotation of said windmill in said first direction about said base, said first outer edge of each windmill vane proceeds the second outer edge;exposing said windmill to wind pressure, said wind pressure causes said windmill to rotate said windmill in said first direction;each of said windmill vanes having a concave surface for receiving said wind pressure and causing said vanes to act against said vane support to move said windmill in said first direction;each of said windmill vanes having a convex portion opposite said concave portion to reduce the counterproductive force of wind on the vane supports from said concave portion;mounting each said windmill vanes to rotate relative to said upper and lower support plates, such that wind pressure on said concave portion biases said vanes towards a first deployed position independent of the position of any other windmill vane on said windmill and such that wind pressure on said convex portion biases said vanes towards a second, non-deployed position; andhaving a cam mounted between each of said windmill vanes and said lower support plate for biasing each of said windmill vanes in said first deployed position. 7. The method of protecting a windmill of claim 6 further comprising: weighting said front portion of each said windmill vane with more weight than said rear portion of each respective windmill vane such that when the wind is at a first, low speed, the vanes, the forces on a first windmill vane bias the first windmill vane towards the deployed position, and when said wind is at a second, high speed, a centrifugal force acting on said front portion of said first windmill vane cause said first windmill vane to retract to the non-deployed position for a portion of one rotation of the windmill in the first direction. 8. The method of protecting a windmill of claim 7, further comprising: when said wind is at a third, highest speed, a centrifugal force acting on said front portion of said first windmill vane cause said first windmill vane to retract to the non-deployed position for a complete one rotation of the windmill in the first direction. 9. The method of protecting a windmill of claim 7, wherein weighting of each said windmill vane comprises adding a first weight along the outer portion of each said windmill vane, said weight having a higher density than said windmill vane. 10. The method of protecting a windmill of claim 6, wherein said upper support plate and said lower support plate form a cylindrical shape. 11. The method of protecting a windmill of claim 6, wherein said upper support plate has a radius larger than said lower support plate; and said upper support plate, said lower support plates and said plurality of vane supports form a frustoconical shape. 12. The method of protecting a windmill of claim 6, wherein said upper support plate and said lower support plate form a cylindrical shape; and when each of said vanes is in the non-deployed position, the upper support plate, lower support plate and windmill vanes all lie along a cylindrical shape. 13. The method of protecting a windmill of claim 6, wherein said upper support plate has a radius larger than said lower support plate; said upper support plate, said lower support plates and said plurality of vane supports form a frustoconical shape; andwhen each of said vanes is in the non-deployed position, the upper support plate, lower support plate and windmill vanes all lie along a frustoconical pattern. 14. A method of protecting a windmill rotating in a first direction about a vertical axis comprising: providing a cylindrical windmill support formed by a circular upper support plate and a circular lower support plate and a plurality of vane supports being connected between an outer perimeter of said upper support plate and an outer perimeter of said lower support plate;providing said windmill support with a central drive shaft;providing a base for retaining said windmill support, said central drive shaft received in said base for allowing rotation of said windmill support about said base;providing a windmill vane asymmetrically mounted of each of said vane supports, each said vane having a first front portion defined from said vane support to a first outer edge of said vane parallel to said vane support, and having a second rear portion defined from said vane support to a second outer edge of said vane opposite from said first outer edge, wherein during rotation of said windmill in said first direction about said base, said first outer edge of each windmill vane proceeds the second outer edge;exposing said windmill to wind pressure, said wind pressure causes said windmill to rotate said windmill in said first direction;each of said windmill vanes having a concave surface for receiving said wind pressure and causing said vanes to act against said vane support to move said windmill in said first direction;each of said windmill vanes having a convex portion opposite said concave portion to reduce the counterproductive force of wind on the vane supports from said concave portion;mounting each said windmill vanes to rotate relative to said upper and lower support plates, such that wind pressure on said concave portion biases said vanes towards a first deployed position and such that wind pressure on said convex portion biases said vanes towards a second, non-deployed position;providing a cam between said windmill vane and said lower support such that rotation of said windmill vane to said second, non-deployed position raises said windmill vane along said cam, whereby when said wind pressure on said concave portion is reduced, gravity causes said windmill vane to move vertically downward along said cam toward said first deployed position. 15. The method of protecting a windmill of claim 14 further comprising: weighting said front portion of each said windmill vane with more weight than said rear portion of each respective windmill vane such that when the wind is at a first, low speed, the vanes, the forces on a first windmill vane bias the first windmill vane towards the deployed position, and when said wind is at a second, high speed, a centrifugal force acting on said front portion of said first windmill vane cause said first windmill vane to retract to the non-deployed position for a portion of one rotation of the windmill in the first direction. 16. The method of protecting a windmill of claim 14, further comprising: when said wind is at a third, highest speed, a centrifugal force acting on said front portion of said first windmill vane cause said first windmill vane to retract to the non-deployed position for a complete one rotation of the windmill in the first direction. 17. The method of protecting a windmill of claim 14, wherein when each of said vanes is in the non-deployed position, the upper support plate, lower support plate and windmill vanes form the perimeter of a cylinder. 18. The method of protecting a windmill of claim 14, wherein when each of said vanes is in the non-deployed position, the rear portion of a first vane over lies part of the front portion of an adjacent vane. 19. The method of protecting a windmill of claim 14, wherein each windmill vane can move from said first, deployed position to said second, non-deployed position and back to said first, deployed position independent of any other windmill vane.
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