Long shaft propeller controller and bearing seal protector
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B63H-001/18
B63H-001/28
출원번호
US-0398864
(2012-02-17)
등록번호
US-8911272
(2014-12-16)
발명자
/ 주소
Gilk, Arlon J.
Hoeschen, Lawrence L.
출원인 / 주소
Gilk, Arlon J.
대리인 / 주소
Watkins, Albert W.
인용정보
피인용 횟수 :
2인용 특허 :
62
초록▼
A marine propulsion system for shallow waters, swamps, savannahs and the like includes a rotating propeller shaft supporting a propeller. An anti-cavitation body defines a partial cylinder having a longitudinal axis adjacent to the propeller. The propeller generates a vacuum between the anti-cavitat
A marine propulsion system for shallow waters, swamps, savannahs and the like includes a rotating propeller shaft supporting a propeller. An anti-cavitation body defines a partial cylinder having a longitudinal axis adjacent to the propeller. The propeller generates a vacuum between the anti-cavitation body and a surface of a water body. First and second wings adjacent to edges of the anti-cavitation body are generally planar and operatively angled towards the bottom of a water body. The first and second wings are adjusted to run below the water body surface and seal the anti-cavitation body to maintain generated vacuum. A first thread is cut in a first helical direction at an end of the rotating propeller shaft adjacent the propeller, and slightly more distal therefrom a second thread is cut in a second helical direction opposed to the first thread helical direction. The second thread drives matter away from the bearing.
대표청구항▼
1. A marine propulsion linkage for connecting a propeller to a motive power source, comprising: a shaft adapted for rotation about a first axis having a first end and elongated along said first axis from said first end to a second end, said first and second ends terminating said shaft;a means for co
1. A marine propulsion linkage for connecting a propeller to a motive power source, comprising: a shaft adapted for rotation about a first axis having a first end and elongated along said first axis from said first end to a second end, said first and second ends terminating said shaft;a means for coupling said shaft to said propeller adjacent said second end;an anti-cavitation body defining a partial cylinder having a longitudinal axis, a radius of curvature defined by a displacement of said body with respect to said longitudinal axis and larger in diameter than said propeller, a degree of rotation defined by the angular extent of said body about said longitudinal axis and terminating at first and second edges of angular extent, said longitudinal axis angled with respect to said first axis and forming an anti-cavitation chamber adjacent to said propeller and operatively enclosing a vacuum between said anti-cavitation body and a surface of a water body;first and second wings adjacent to said first and second edges of angular extent, respectively, angularly offset from said partial cylinder to extend radially outward therefrom and operatively angled into said water body, wherein said first and second wings are adapted to operatively run below said water body surface and thereby improve a seal between said anti-cavitation body and said water body surface to better maintain said generated vacuum therein; andwherein said first and second wings each have a separate center of radius that is both substantially offset sideways from said anti-cavitation body center of radius, and also have a radius that is larger than said anti-cavitation body radius of curvature. 2. The marine propulsion linkage of claim 1, wherein said first and second wings are generally planar. 3. The marine propulsion linkage of claim 1, further comprising: a casing generally co-axial with and circumscribing at least a portion of said shaft; anda mounting support rigidly coupled to said casing;wherein said anti-cavitation body is removably rigidly coupled to said mounting support. 4. The marine propulsion linkage of claim 3, further comprising a means for making small angular adjustments between said anti-cavitation body and said casing, whereby an angle between said anti-cavitation body and said casing is adjustable to constrain said propeller immediately adjacent to and partially above a normal level for said surface of said water body. 5. The marine propulsion linkage of claim 4, wherein said means for making small angular adjustments between said anti-cavitation body and said casing further comprises an adjusting shim. 6. The marine propulsion linkage of claim 3, wherein said first and second wings extend longitudinally with said anti-cavitation body adjacent to said propeller and terminate spaced and distal from said anti-cavitation body mounting support. 7. A marine propulsion linkage for connecting a propeller to a motive power source and operative within a body of water having an average surface level and surface waves therein, comprising: a shaft adapted for rotation about a first axis having a first end and elongated along said first axis from said first end to a second end, said first and second ends terminating said shaft;a means for coupling said shaft to said motive power source adjacent said first end;a means for coupling said shaft to said propeller adjacent said second end;a casing enclosing said shaft between said first and second ends;a generally planar skeg coupled with and descending in a generally vertical plane from said casing;a framework adding structural integrity to said casing;a pivotal transom mount permitting said shaft, casing and framework to pivot about two orthogonal axes;a handle coupled to said framework and adapted to operatively allow said propeller to be pivoted about a generally horizontal axis to thereby raise and lower said propeller within a body of water, and adapted to operatively allow said propeller to be pivoted about a generally vertical axis to thereby shift said propeller between port and starboard of said transom mount;an anti-cavitation body having a generally tear-drop geometry from a top plan view and including an oval cut-out defining a leading edge adjacent to and engaging said casing and gentle tapering edges extending from said casing and adapted to operatively guide said propeller around obstacles while also preventing foreign matter from becoming affixed adjacent to said oval cut-out, said anti-cavitation body further defining a partial cylinder from a rear elevational view and having a longitudinal axis and a radius of curvature about said longitudinal axis larger in diameter than propeller and extending from said leading edge to a trailing edge partially encompassing and extending beyond said propeller;first and second wings adjacent to said first and second edges of angular extent, respectively, and angularly offset from said partial cylinder to extend radially outward therefrom, and angled into said water body deeper than said anti-cavitation body, wherein said first and second wings are adapted to operatively run below said water body surface and improve a seal between said anti-cavitation body and said water body adjacent to said propeller and adapted to operatively develop a vacuum with said water body to contain water between said anti-cavitation body and propeller and thereby tend to keep propeller at a level partially above said water body average surface level; andwherein said first and second wings each further comprise a longitudinal axis that is both laterally displaced from said anti-cavitation body longitudinal axis, and wherein said wings have a larger radius of curvature than said anti-cavitation body radius of curvature. 8. The marine propulsion linkage of claim 7, wherein said first and second wings further comprise generally planar surfaces. 9. The marine propulsion linkage of claim 7, wherein said first and second wings further extend in a direction parallel to said anti-cavitation body longitudinal axis adjacent to said anti-cavitation body trailing edge and terminate longitudinally distally from said anti-cavitation body leading edge. 10. The marine propulsion linkage of claim 7, further comprising: a mounting support rigidly affixed to said casing;a plurality of holes through said cavitation plate; anda plurality of fasteners passing through said plurality of holes and removed ably attached to said mounting support. 11. The marine propulsion linkage of claim 7, further comprising an adjusting shim between said anti-cavitation body adjacent to said leading edge and said casing and adapted to operatively permit small angular adjustments to be made and fixed between said anti-cavitation body and said casing. 12. The marine propulsion linkage of claim 7, wherein said first and second wings and an angular adjustment of said anti-cavitation body relative to said casing are each adapted to operatively provide sufficient drag in said body of water when said anti-cavitation body becomes fully submerged in said body of water to operatively force water down and thereby in turn lift said propeller, and if said propeller lifts above said body of water, said first and second wings operatively catch water and pull said propeller downward into said body of water and said anti-cavitation body reacts with said propeller and said body of water to generate a vacuum to operatively tend to constrain said propeller immediately adjacent to and partially above said average surface level of said body of water. 13. A marine propulsion linkage for connecting a propeller to a motive power source and operative within a body of water having an average surface level and surface waves therein, comprising: a shaft adapted for rotation about a first axis having a first end and elongated along said first axis from said first end to a second end, said first and second ends terminating said shaft;a means for coupling said shaft to said motive power source adjacent said first end;a means for coupling said shaft to said propeller adjacent said second end;a casing enclosing said shaft between said first and second ends;a pivotal transom mount permitting said shaft and casing framework to pivot about two orthogonal axes;an anti-cavitation body having a generally tear-drop geometry from a top plan view and including an oval cut-out defining a leading edge adjacent to and engaging said casing and gentle tapering edges extending from said casing and adapted to operatively guide said propeller around obstacles while also preventing foreign matter from becoming affixed adjacent to said oval cut-out, said anti-cavitation body further defining a partial cylinder from a rear elevational view and having a longitudinal axis and a radius of curvature about said longitudinal axis larger in diameter than propeller and extending from said leading edge to a trailing edge partially encompassing and extending beyond said propeller;first and second wings adjacent to said first and second edges of angular extent, respectively, and angularly offset from said partial cylinder to extend radially outward therefrom, and angled into said water body deeper than said anti-cavitation body, wherein said first and second wings are adapted to operatively run below said water body surface and improve a seal between said anti-cavitation body and said water body adjacent to said propeller and adapted to operatively develop a vacuum with said water body to contain water between said anti-cavitation body and propeller and thereby tend to keep propeller at a level partially above said water body average surface level; andwherein said first and second wings each further comprise a longitudinal axis that is both laterally displaced from said anti-cavitation body longitudinal axis, and wherein said wings have a larger radius of curvature than said anti-cavitation body radius of curvature. 14. The marine propulsion linkage of claim 13, wherein said first and second wings further extend in a direction parallel to said anti-cavitation body longitudinal axis adjacent to said anti-cavitation body trailing edge and terminate longitudinally distally from said anti-cavitation body leading edge. 15. The marine propulsion linkage of claim 13, further comprising: a mounting support rigidly affixed to said casing;a plurality of holes through said cavitation plate;a plurality of fasteners passing through said plurality of holes and removed ably attached to said mounting support; andan adjusting shim between said anti-cavitation body adjacent to said leading edge and said casing and adapted to operatively permit small angular adjustments to be made and fixed between said anti-cavitation body and said casing. 16. The marine propulsion linkage of claim 13, wherein said first and second wings and an angular adjustment of said anti-cavitation body relative to said casing are each adapted to operatively provide sufficient drag in said body of water when said anti-cavitation body becomes fully submerged in said body of water to operatively force water down and thereby in turn lift said propeller, and if said propeller lifts above said body of water, said first and second wings operatively catch water and pull said propeller downward into said body of water and said anti-cavitation body reacts with said propeller and said body of water to generate a vacuum to operatively tend to constrain said propeller immediately adjacent to and partially above said average surface level of said body of water.
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이 특허에 인용된 특허 (62)
Litjens John J. (Oshkosh WI) Frazzell Michael E. (Neenah WI) Karls Michael A. (Hilbert WI) Steiner Ronald M. (Oshkosh WI) Lang William P. (Oshkosh WI), Anti-ventilation plate.
Rodrigue Roland (2233 N. Von Braun Harvey LA 70058) Rodrigue Ronnie (2233 N. Von Braun Harvey LA 70058), Boat and propulsion system including a transom platform.
Rivette ; Jr. W. John (12103 Cline Dr. Baker LA 70714) Bourgeois Thomas G. (Rte. 8 ; Box 444 Gonzalas LA 70737) Calamia ; Jr. Samuel P. (13830 Spreading Oaks Dr. Baton Rouge LA 70818), Driving and steering mechanism for boats.
McElroy Kennedy K. (Lindenhurst IL) Higby Jeffrey P. (Waukegan IL) Zorc Philip A. (St. Joseph MI), Marine propulsion device bearing lubrication system.
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