WO2008112513A1 - Apparatus and method to optimize sailing efficiency - Google Patents
Apparatus and method to optimize sailing efficiency Download PDFInfo
- Publication number
- WO2008112513A1 WO2008112513A1 PCT/US2008/056131 US2008056131W WO2008112513A1 WO 2008112513 A1 WO2008112513 A1 WO 2008112513A1 US 2008056131 W US2008056131 W US 2008056131W WO 2008112513 A1 WO2008112513 A1 WO 2008112513A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- appendage
- vessel
- hydrofoil
- hull
- sailing vessel
- Prior art date
Links
- 238000000034 method Methods 0.000 title claims description 5
- 238000013461 design Methods 0.000 claims abstract description 101
- 230000002441 reversible effect Effects 0.000 claims description 9
- 238000005457 optimization Methods 0.000 claims description 2
- 230000006872 improvement Effects 0.000 abstract description 15
- 230000008901 benefit Effects 0.000 abstract description 13
- 239000011888 foil Substances 0.000 description 36
- 230000001965 increasing effect Effects 0.000 description 29
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 23
- 230000006870 function Effects 0.000 description 22
- 230000007423 decrease Effects 0.000 description 20
- 230000008859 change Effects 0.000 description 19
- 230000009467 reduction Effects 0.000 description 18
- 241000380131 Ammophila arenaria Species 0.000 description 12
- 239000012530 fluid Substances 0.000 description 10
- 230000000694 effects Effects 0.000 description 9
- 230000003247 decreasing effect Effects 0.000 description 6
- 238000006073 displacement reaction Methods 0.000 description 6
- 230000007246 mechanism Effects 0.000 description 6
- 238000010586 diagram Methods 0.000 description 5
- 230000005484 gravity Effects 0.000 description 5
- 230000009471 action Effects 0.000 description 4
- 238000005096 rolling process Methods 0.000 description 4
- 239000003570 air Substances 0.000 description 3
- 230000000295 complement effect Effects 0.000 description 3
- 230000001276 controlling effect Effects 0.000 description 3
- 230000004048 modification Effects 0.000 description 3
- 238000012986 modification Methods 0.000 description 3
- 238000012937 correction Methods 0.000 description 2
- 238000007654 immersion Methods 0.000 description 2
- 238000004519 manufacturing process Methods 0.000 description 2
- 230000004044 response Effects 0.000 description 2
- 208000031481 Pathologic Constriction Diseases 0.000 description 1
- 241001333990 Rugopharynx theta Species 0.000 description 1
- 230000001154 acute effect Effects 0.000 description 1
- 239000000654 additive Substances 0.000 description 1
- 230000000996 additive effect Effects 0.000 description 1
- 230000003466 anti-cipated effect Effects 0.000 description 1
- 239000002131 composite material Substances 0.000 description 1
- 238000010276 construction Methods 0.000 description 1
- 230000008878 coupling Effects 0.000 description 1
- 238000010168 coupling process Methods 0.000 description 1
- 238000005859 coupling reaction Methods 0.000 description 1
- 238000010001 crabbing Methods 0.000 description 1
- 108700041286 delta Proteins 0.000 description 1
- 230000001419 dependent effect Effects 0.000 description 1
- 238000011161 development Methods 0.000 description 1
- 230000003292 diminished effect Effects 0.000 description 1
- 230000008030 elimination Effects 0.000 description 1
- 238000003379 elimination reaction Methods 0.000 description 1
- 239000011521 glass Substances 0.000 description 1
- 230000001939 inductive effect Effects 0.000 description 1
- 239000004615 ingredient Substances 0.000 description 1
- 210000003141 lower extremity Anatomy 0.000 description 1
- 239000000463 material Substances 0.000 description 1
- 238000005259 measurement Methods 0.000 description 1
- 230000003278 mimic effect Effects 0.000 description 1
- 238000003825 pressing Methods 0.000 description 1
- 230000001105 regulatory effect Effects 0.000 description 1
- 239000013535 sea water Substances 0.000 description 1
- 238000007493 shaping process Methods 0.000 description 1
- 239000013598 vector Substances 0.000 description 1
- 238000005303 weighing Methods 0.000 description 1
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63B—SHIPS OR OTHER WATERBORNE VESSELS; EQUIPMENT FOR SHIPPING
- B63B41/00—Drop keels, e.g. centre boards or side boards ; Collapsible keels, or the like, e.g. telescopically; Longitudinally split hinged keels
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63B—SHIPS OR OTHER WATERBORNE VESSELS; EQUIPMENT FOR SHIPPING
- B63B1/00—Hydrodynamic or hydrostatic features of hulls or of hydrofoils
- B63B1/16—Hydrodynamic or hydrostatic features of hulls or of hydrofoils deriving additional lift from hydrodynamic forces
- B63B1/24—Hydrodynamic or hydrostatic features of hulls or of hydrofoils deriving additional lift from hydrodynamic forces of hydrofoil type
- B63B1/28—Hydrodynamic or hydrostatic features of hulls or of hydrofoils deriving additional lift from hydrodynamic forces of hydrofoil type with movable hydrofoils
- B63B1/285—Hydrodynamic or hydrostatic features of hulls or of hydrofoils deriving additional lift from hydrodynamic forces of hydrofoil type with movable hydrofoils changing the angle of attack or the lift of the foil
- B63B1/286—Hydrodynamic or hydrostatic features of hulls or of hydrofoils deriving additional lift from hydrodynamic forces of hydrofoil type with movable hydrofoils changing the angle of attack or the lift of the foil using flaps
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63B—SHIPS OR OTHER WATERBORNE VESSELS; EQUIPMENT FOR SHIPPING
- B63B39/00—Equipment to decrease pitch, roll, or like unwanted vessel movements; Apparatus for indicating vessel attitude
- B63B39/06—Equipment to decrease pitch, roll, or like unwanted vessel movements; Apparatus for indicating vessel attitude to decrease vessel movements by using foils acting on ambient water
-
- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05D—SYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
- G05D1/00—Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
- G05D1/08—Control of attitude, i.e. control of roll, pitch, or yaw
- G05D1/0875—Control of attitude, i.e. control of roll, pitch, or yaw specially adapted to water vehicles
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B63—SHIPS OR OTHER WATERBORNE VESSELS; RELATED EQUIPMENT
- B63B—SHIPS OR OTHER WATERBORNE VESSELS; EQUIPMENT FOR SHIPPING
- B63B3/00—Hulls characterised by their structure or component parts
- B63B3/14—Hull parts
- B63B3/38—Keels
- B63B2003/385—Keels with means for controlling heeling or rolling motions, or lift, e.g. flaps, by changing geometry, or by ballast displacement
Definitions
- This invention relates to sailing vessels.
- this invention relates to appendages extending from a sailing vessel hull — keels, centerboards, dagger boards, and the like. More particularly, this invention relates to sailing vessel appendages that simultaneously control leeward drift forces, heeling forces, effective weight, and drag.
- the invention is particularly suited for high performance sailing yachts.
- VMG Velocity Made Good
- VMG Velocity Made Good
- the aerodynamic and hydrodynamic fluid forces that act on a sailing vessel as it moves toward its windward mark or destination can be resolved into components that are parallel and perpendicular to the direction of undisturbed fluid flow.
- the component parallel to the direction of undisturbed fluid flow is called a driving force when acting in a forward direction or drag when opposing forward motion.
- the component perpendicular to the direction of undisturbed fluid flow is called lift.
- the lift force of the sails is perpendicular to the direction of the apparent wind and lift force of the hull is in a plane perpendicular to the course sailed (PPCS).
- the leeward drift of a conventional keeled sailing vessel is a result of the lateral component of the wind force on the exposed surface area above the waterline (including sails, rigging, and hull) and the lateral component of the water forces acting on the surfaces below the waterline, including the hull, keel, and rudder.
- the keel and rudder In order for a vessel to sail toward its windward mark, the keel and rudder must provide resistance to the leeward drift forces. Since a conventional keel is symmetrical, this can only be accomplished by establishing a leeward angle of attack which makes the vessel angle, or crab, toward its objective.
- the leeward angle ⁇ is defined as the angle between the course steered and the course, or track, sailed.
- the minimum resistance offered by the water to forward motion of the canoe body and keel of a sailing vessel occurs when the vessel is pointed directly opposite to the incident fluid flow, that is, in the direction of the course sailed. Therefore, directing a vessel at a leeward angle to its track through the water increases the drag on its hull and keel. The increased drag reduces the forward velocity of the vessel. The decrease in the forward velocity, in turn, reduces the velocity made good, VMG.
- the heeling angle of a sailing vessel is proportional to the lateral forces of the wind pressing upon its sails, rigging and hull as well as lateral water forces on its hull, keel and rudder.
- a vessel When a vessel is sailing upright, or perpendicular to the plane of the surface of the water, it captures the maximum available wind and therefore has the maximum amount of wind energy to convert into forward propelling energy.
- the horizontal projection of the sail area is reduced in proportion to the increase in heeling angle. Thus, forward propelling energy is lost because less wind energy is captured by the sails.
- the heeling angle also creates a vertical component of the wind force that, like gravitational weight such as ballast, acts in a downward direction. This downward component of the force is lost to forward propelling energy and without compensation would also contribute to the effective weight of the vessel and thereby increase the displacement, wetted surface, and associated drag.
- the lift force generated by the symmetrical keel of a conventional sailing vessel is in a plane perpendicular to the course sailed, PPCS, and is a function of the angle of attack of the keel to the incident water. Therefore when the helm compensates for an increased leeward drift force by increasing the leeward angle, the angle of attack of the keel is increased.
- the increased lift force so produced comprises a horizontal component that counters the leeward drift force of the sails and an upward vertical force component that counters the downward force exerted by the sails, thus returning the vessel to equilibrium and maintaining its original track.
- This is not without cost, however, because the higher angle of attack increases the induced drag on the vessel.
- Other losses are introduced by heeling because the shape of the hull is usually optimized for minimum drag and/or wetted surface when the vessel is sailing upright or perpendicular to the plane of the water. For this reason, the drag is also increased by heeling, at an additional expense to the forward velocity of the vessel.
- the horizontal force that the keel provides to resist leeward drift is a function of the heeling angle of a vessel and, all other things being equal, is diminished as the cosine of the heeling angle diminishes with an increase in the heeling angle.
- the weight, or more properly, the effective weight of a sailing vessel determines the displacement and therefore the wetted surface and related drag on a sailing vessel.
- a decrease in the effective weight results in a decrease in the wetted surface and associated drag with an attendant increase in forward velocity.
- Less effective weight also improves the vessel's ability to reach a planing condition-
- a decrease in weight or effective weight is accompanied by a decrease in drag on a sailing vessel.
- a decrease in the effective weight can be achieved by a reduction in the heeling angle which will redirect the force exerted by the sails into a more horizontal direction. Accordingly, cascading benefits will accrue: a proportional component of the sail force will be converted from a vertically downward or effective weight force into forward driving force which increases the velocity of the vessel; a higher velocity permits a reduction in the leeward angle that must be sailed in order to reach a given mark; the reduced leeward angle decreases the drag associated with the angle of attack of the keel and the crabbing of the canoe body of the sailing vessel.
- the overall efficiency of a sailing vessel can be substantially improved by a decrease in leeward drift, heeling angle, effective weight, or drag; provided, of course, that the improvement in any one of these characteristics is not obtained at an equivalent or greater expense of one or more of the other characteristics.
- U.S. Patent No. 6,032,603 discloses such a prior art, asymmetric hydrofoil, keel design.
- Figure 3 of that patent is reproduced as Figure 1 here.
- the sailing vessel is shown on a starboard tack heeling at an angle of 20 degrees.
- the hydrofoil is mounted on the keel, with its cambered surface facing toward the windward side, to create a generally windward directed, counter- leeward drift force. This does give relief to the leeward drift forces acting on the vessel; that is, the counter leeward-drift force equals the lateral force, Q, generated by the hydrofoil, times the cosine of the heeling angle of the vessel.
- the hydrofoil also generates, however, a heeling moment which is equal to the force, Q, times its perpendicular distance from the line of that force to the (instant) axis of rotation of the sailing vessel.
- Symmetric keels of traditional sailing vessels oppose leeward drift by sailing at a leeward angle to the track of a vessel but leeward drift can also be opposed by an asymmetric hydrofoil designed and located to provide counter- leeward drift forces. The latter is more efficient in two ways.
- an asymmetric hydrofoil can move at a lower angle of attack thereby inducing less drag; and second, since the counter- leeward drift force generated by an asymmetric hydrofoil reduces the required leeward angle, it permits the vessel to point closer to its desired track. It is noteworthy that although an asymmetric hydrofoil does not require sailing at a leeward angle to produce a counter leeward drift force as does a symmetric keel shape, if necessary it can do so, which would increase its angle of attack and thus its lifting force and, like its symmetric cousin, but to a lesser extent, its drag will also increase.
- Figure 1 provides an example of an asymmetric hydrofoil mounted on the keel of a sailing vessel.
- the hydrofoil has a cambered surface facing generally toward the windward side of the vessel and a non-cambered surface facing generally toward the leeward side of the vessel.
- the velocity over the cambered surface is higher than the velocity over the non-cambered surface and according to Bernoulli's principal, an increase in velocity will be accompanied by a proportional decrease in pressure.
- differential between the lower pressure on the cambered side and the higher pressure on the non- cambered side of the hydrofoil produces a force Q toward the windward side of the vessel.
- its horizontal component serves to oppose leeward drift forces acting on the vessel.
- force Q also acts at a perpendicular distance from the instant axis of rotation of the vessel and force Q multiplied by this distance exerts a heeling moment that adds to the existing heeling moments acting on the vessel.
- a canting keel has been introduced to provide a counter- heeling moment by suspending a ballast bulb beneath the hull on a laterally swinging or canting member that increases the anti-heeling lever arm of the ballast when rotated toward the windward side of a tacking sailing vessel.
- Such mechanisms do resist heeling moments but, like conventional ballast, because they function gravitationally, considerable weight must be incorporated in their design.
- a keel canted to a severe angle can do little to resist leeward drift forces. Therefore, supplementary fore and aft appendages must be added to provide the necessary counter-leeward drift forces.
- a subsequent development in the canting keel is the addition of a hinged hydrofoil or flap mounted on a canting keel or strut that connects the hull to the ballast.
- This hydrofoil, or flap is intended to provide additional heeling resistance when it is necessary to increase the anti-heeling force because the ballast has been canted to its limit and operating conditions require additional anti-heeling force.
- U.S. Patent No. 5,622,130 discloses such a flap.
- Figure 1 of that patent is reproduced as Figure 2 here.
- the counter-heeling flap or hydrofoil 20 is mounted on the trailing edge of the keel or strut 14 on an axis along, or parallel to, the longitudinal dimension of the strut 14.
- the force generated by the hydrofoil 20 will be at an angle to the horizontal. Since the flap would only be activated when the vessel was heeling, its hydrodynamic force would be at an angle to the horizontal.
- FIG. 3 is a stern view schematic of the prior art shown in Figure 2 with the appendages 16 and 18 omitted for clarity.
- the flap 20, mounted on a canting keel 14 of a sailing vessel is at an angle of 42 degrees to the vertical because the vessel is heeling at an angle (Phi) of 20 degrees, with its keel canted at an angle (Kappa) of 22 degrees from the midplane of the vessel,.
- flap 20 is actuated to exert an additional counter-heeling force (Feu)
- the horizontal, or drift component of this force (FD) would equal FCH X cosine 42 degrees, or 0.743 F C H acting in a leeward direction, thus increasing the drift of the vessel.
- the vertical or weight component of force F C H called Fw, would equal F CH X sine 42 degrees, or 0.669 F CH acting in a downward direction, increasing the effective weight of the vessel.
- FIG. 3 of that patent is shown here as prior art Figure 4.
- the vessel is shown heeled 20 degrees on a starboard tack.
- Two fins, 5a and 5b which are shaped and positioned to produce hydrodynamic forces in a generally downward direction, are shown.
- the fins are fixed to the tip of the keel and the surfaces on their undersides are angled at 20 degrees down from the horizontal when the keel is in the vertical position.
- the force Q' on the windward side is equal to the force Q' on the leeward side, named herein Q'L- If SO, the windward fin 5b produces no counter-leeward drift lift while the leeward fin 5a produces a counter-leeward drift equal to Q'L Sin 40° for a net decrease in the leeward drift forces acting on the vessel.
- Formula (a) shows that the factors L and/or S can be increased when DSP, which is equivalent to weight, increases.
- formula (d) shows that for any vessel exceeding 24,000 kilograms a weight penalty (WP) is imposed and according to formula (b) the weight penalty WP will dictate either a reduction in the measured length LM or an increase in the value of the rated length L.
- WP weight penalty
- the Measured Length LM would have to be decreased sufficient to reduce the value of rated length L by 3.54 meters in order to compensate for the Weight Penalty WP in this example. It can be seen that, all other things being the same, for a vessel of a given rated length L and weighing more than 24,000 kg, a decrease in the weight, and therefore a decrease in the weight penalty, (WP), will allow an increase in the measured length (LM) and thus an increase the maximum attainable velocity of such a high performance racing yacht. An alternative would be to not change LM, which would then reduce the value of the rated Length L. This would then permit an increase in the sail area.
- the present invention is directed toward overcoming the aforementioned problems associated with keel arrangements and designs, thus creating a more efficient sailing vessel in any class or category.
- the present invention is further directed toward improved designs, embodiments, and systems that enable the improvement of any one, or any combination, of the above cited performance characteristics.
- the present invention is still further directed to overcoming the aforementioned problems associated with keel arrangements and designs while adhering to the design rules required for boats to participate in the America's Cup Race. Summary of the Invention It is therefore an object of the present invention to provide a drift control and a heel control system that can simultaneously improve leeward drift, heeling, effective weight and associated drag, or any combination thereof, to enable an overall improvement in the efficiency of sailing vessels.
- CLD counter-leeward drift
- CH counter-heeling
- a still further object of the present invention is to provide a keel that acts hydrodynamically rather than gravitationally in reducing the heeling angle of a sailing vessel thus enabling a reduction or even the elimination of gravitational ballast of a vessel.
- a single appendage e.g. keel
- heel control and drift control systems that can act independently or interactively, including, but not limited to any of the following: Systems that can be coupled to yield optimum or predetermined sailing characteristics. Systems that can be controlled by related mechanical, electro-mechanical or like assemblage and/or governed by the helm or in combination with an interrelated, or predetermined program. Systems that can also incorporate servo controls to make sensitive, self regulated, automatic performance corrections and systems that can be controlled in response to positioning, apparent wind velocity and direction, vessel velocity, heading and track data received from on board instrumentation, GPS or the like and attitude data obtained from gyroscopic, gravitational, magnetic or like instrumentation.
- the objects of the present invention will be generally achieved by providing a sailing yacht with an adjustable hydrodynamic heel control system that acts independent of, or in conjunction with, an adjustable hydrodynamic drift control system to simultaneously counter both heel and drift forces.
- a sailing yacht with a keel-mounted, variable, controllable, counter- leeward drift hydrofoil and a keel-mounted, variable, controllable, counter- heeling hydrofoil.
- Still further objects of the present invention will generally be achieved by providing a sailing yacht with a keel-mounted, variable, controllable, counter-leeward drift hydrofoil and a keel-mounted, variable, controllable, counter-heeling hydrofoil that are independent but can act in conjunction with prior-art drift or heel control systems such as fixed ballast or canting keel designs.
- Still further objects of the present invention will generally be achieved by providing a sailing yacht with a keel-mounted, single rotating member that provides primarily counter-leeward drift forces by a hydrofoil-shaped section of the member positioned at an upper and forward facing position on the keel, while simultaneously providing primarily counter-heeling forces by a second hydrofoil-shaped section of the member positioned at a lower and rearward- facing position on the keel, the entire member acting as one unit but performing two functions.
- a sailing vessel having a hull, an appendage extending from the hull and having a midplane, a first flap attached to the appendage and rotatable about a first axis that is disposed within or substantially parallel to the midplane and is also disposed at an angle of less than 90 degrees from a vertical plane perpendicular to the midplane, and a second flap attached to the appendage and rotatable about a second axis that is disposed within or substantially parallel to the midplane and is also disposed at an angle of less than 90 degrees from a vertical plane perpendicular to the midplane.
- first axis or the second axis is substantially parallel to a vertical plane perpendicular to the midplane. Further objects will be achieved where the first axis and the second axis are substantially parallel to a vertical plane perpendicular to the midplane. and substantially vertically aligned.
- At least one of the first axis or the second axis is adjustable to an angle of less than 90 degrees from a vertical plane perpendicular to the midplane.
- At least one of the first flap or the second flap is attached to the appendage by a hinge.
- one of the first flap or the second flap is attached to the appendage at a minimum distance from a design longitudinal axis of the hull and the other is attached to the appendage at a maximum distance from the design longitudinal axis of the hull.
- first flap is disposed proximate to the root end of the appendage and extends substantially toward the trailing edge of the appendage; and wherein the second flap is disposed at the tip end of the appendage and extends substantially toward the trailing edge of the appendage.
- first flap is disposed proximate to the root end of the appendage and extends substantially toward the leading edge of the appendage; and where the second flap is disposed at the tip end of the appendage and extends substantially toward the leading edge of the appendage.
- first flap is disposed proximate to a root end of the appendage and extends substantially toward the leading edge of the appendage; and wherein the second flap is disposed at a tip end of the appendage and extends substantially toward the trailing edge of the appendage.
- first flap is disposed proximate to a root end of the appendage and extends substantially toward the trailing edge of the appendage; and where the second flap is disposed at a tip end of the appendage and extends substantially toward the leading edge of the appendage.
- a sailing vessel having: a hull; an appendage extending from the hull and having a leading edge, a trailing edge, two surfaces, and a midplane; a first hydrofoil member; and a second hydrofoil member; and a single, rotatable member having an axis disposed substantially parallel to the midplane; where the first hydrofoil member and the second hydrofoil member are incorporated in and integral with, the single, rotatable member.
- first hydrofoil member is disposed proximate to the root end of the appendage and extends from the rotatable member substantially toward the leading edge of the appendage; and where the second hydrofoil member is disposed at the tip end of the appendage and extends from the rotatable member substantially toward the trailing edge of the appendage.
- first hydrofoil member is disposed proximate to the root end of the appendage and extends from the rotatable member substantially toward the trailing edge of the appendage; and where the second hydrofoil member is disposed at the tip end of the appendage and extends from the rotatable member substantially toward the leading edge of the appendage.
- first hydrofoil member and the second hydrofoil member are configured to move toward opposite surfaces of the appendage when the rotatable member is rotated.
- a sailing vessel having: a hull; an appendage extending from the hull and having a leading edge, a trailing edge, two surfaces, and a midplane; a first hydrofoil, with at least one cambered side, slidably attached to the appendage; and a second hydrofoil, with at least one cambered side, slidably attached to the appendage.
- cambered surface of at least one of the first hydrofoil and the second hydrofoil is disposed at an angle to the midplane of the appendage.
- first hydrofoil or the second hydrofoil slide in a track that is substantially parallel to the leading edge or the trailing edge of the appendage.
- each hydrofoil may be parked on the flared section when moved to root end of the appendage.
- a sailing vessel having: a hull; an appendage extending from the hull and having a leading edge, a trailing edge, two sides, and a midplane; and a plurality of deformable members; where at least one deformable member is deposed on each of the two sides.
- first deformable member proximate to the root end of the appendage; and a second deformable member proximate to the tip end of the appendage.
- first deformable member disposed on a first side of the appendage and comprising a flexible surface
- second deformable member disposed on a second side of the appendage and comprising a flexible surface
- an upper cam configured to deform a portion of the first deformable member at a first rotational position and deform a portion of the second deformable member at a second rotational position
- a lower cam configured to deform a portion of the first deformable member at a first rotational position and deform a portion of the second deformable member at a second rotational position.
- a sailing vessel having: a hull having a midplane that includes a design longitudinal axis of the hull; an appendage extending from the hull and having a root end, a tip end, and first and second surfaces; a first fixed member mounted on the appendage proximate to the root end and extending from the first surface; and a second fixed member mounted on the appendage proximate to the tip end and extending from the second surface.
- a plurality of the appendages and a slot, through which at least one of the appendages can be inserted, where the slot is disposed in a plane at an angle of less than 90 degrees from the midplane of the hull.
- a plurality of the appendages including a plurality of the appendages; a slot, adapted to hold at least two appendages; and an axis around which each appendage pivots; where the axis is disposed within a vertical plane and/or a horizontal plane at an angle of 90 degrees or less from the midplane of the hull.
- a sailing vessel having: a hull having a midplane and a design longitudinal axis; an appendage having a root end and a tip end; a first reversible member (1) having a cambered side and a substantially flat side, (2) mounted on the appendage, and (3) having an axis substantially parallel to the design longitudinal axis of the hull; and a second reversible member (1) having a cambered side and a substantially flat side, (2) mounted on the appendage, and (3) having an axis substantially parallel to the design longitudinal axis of the hull; where the first reversible member is disposed proximate to the root end of the appendage and the second reversible member is disposed proximate to the tip end of the appendage.
- Objects of the present invention will be achieved by a sailing vessel having a hull; an appendage extending from the hull; means for generating counter-heeling forces; means for generating counter-leeward drift forces.
- Objects of the present invention will be achieved by a sailing vessel having: a hull; an appendage extending from the hull; means for hydrodynamically generating counter-heeling forces; means for hydrodynamically generating counter-leeward drift forces.
- control system capable of (1) determining apparent wind direction and velocity; (2) determining the sailing vessel's position, velocity, heading, track, pitch, yaw, and roll; (3) calculating any adjustments necessary to optimize time to a desired mark; (4) adjusting the flaps, hydrofoils, or members to substantially achieve the optimization.
- Objects of the present invention will be achieved by steps for maximizing the efficiency of a sailing vessel, having a hull, an appendage extending from the hull, a first flap or member attached to the appendage and a second flap or member attached to the appendage, including: (1) dete ⁇ r ⁇ ning a mark; (2) pointing the vessel to a heading necessary to reach the mark; (3) adjusting a first flap, hydrofoil, or member attached to the appendage to account for leeward drift forces; and (4) adjusting a second flap, hydrofoil, or member attached to the appendage to account for heeling forces; and (5) readjusting controls for optimized sailing efficiency to reach the mark.
- flaps or members are adjusted by rotating a single unit that is integrally connected to two oppositely acting flaps or members in order to simultaneously account for leeward drift and heeling forces.
- Objects of the present invention will be achieved by steps for maximizing the efficiency of a sailing vessel, having a hull, an appendage extending from the hull, a first adjustable hydrodynamic member attached to the appendage, and a second adjustable hydrodynamic member attached to the appendage, including: (1) determining a mark; (2) deterrr ⁇ ig apparent wind direction and velocity, (3) determining the sailing vessel's position, velocity, heading, track, pitch, yaw, and roll; (4) pointing the hull at a heading necessary to reach the mark; (5) adjusting a first hydrodynamic member attached to the appendage to account for leeward drift forces; (6) adjusting a second hydrodynamic member attached to the appendage to account for heeling forces; and (7) readjusting heading for optimized sailing efficiency to reach the mark.
- Figure 1 is a cross sectional view of a sailing yacht on a starboard tack and heeling at an angle of 20 degrees showing a prior art, counter-leeward drift design, which corresponds to figure 3 of U.S. Patent 6,032,603.
- Figure 2 is an isometric view of a sailing yacht showing a prior art canting keel design, which corresponds to Figure 1 of U.S. Patent 5,622,130.
- Figure 3 is a cross sectional view of the sailing yacht of Figure 2 above, depicting a prior-art canting-keel design on a starboard tack and with vessel heeling at an angle of 20 degrees and with the keel canted 22 degrees from the midplane of the vessel.
- Figure 4 is a cross sectional view of a sailing yacht on a starboard tack and heeling at an angle of 20 degrees, showing a prior-art winged keel design, which corresponds to figure 3 in Australian Patent Application AU-A- 85 668/82.
- Figure 5 is an isometric view of a fixed keel sailing vessel with a counter-leeward drift (CLD) flap and a counter-heeling (CH) flap constructed in accordance with an embodiment of the present invention.
- CLD counter-leeward drift
- CH counter-heeling
- Figure 6a is a profile view of an embodiment of the present invention depicted in Figure 5 showing the counter-leeward drift flap 11 above the counter-heeling flap 12.
- Figure 6b is a detailed profile view of Figure 6a depicting the keel with two vertically hinged flaps.
- Figure 6c is an isometric view of the embodiment shown in Figures 6a and 6b providing additional detail of the hinged flaps depicted in Figures 5 through 6b.
- Figure 6d is an isometric view of the embodiment shown in Figures 5-6c depicting the design longitudinal axis of rotation 10 of the hull and a plane 15 perpendicular to said design longitudinal axis of rotation.
- Figure 6e is a cross-sectional stern view of the vessel shown in Figure 6d showing the midplane 6 of the hull, the midplane 16 of the keel appendage, and the design longitudinal axis of rotation 10 of the hull.
- Figure 7a is a cross-sectional, stern view, perpendicular to the course sailed, PPCS, of a sailing vessel equipped with an upper, counter-leeward drift flap 11 and a lower, counter-heeling flap 12 of an embodiment of the present invention shown in Figures 5 through 6e.
- Figure 7b is a simplified diagram showing the angles and relative dimensions of Figure 7a.
- Figure 7c is a graphic representation of the angles and dimensions of vessel of Figure 7a including sail area.
- Figure 7d is a simplified drawing of the vessel shown in Figure 7a, also showing cross-section designations, A-A and B-B, for Figures 7e and 7f.
- Figure 7e is a top view of the cross-section A-A of Figure 7d, showing the counter-leeward drift (CLD) hydrofoil with its flap 11 rotated toward leeward.
- CLD counter-leeward drift
- Figure 7f is a top view of the cross-section B-B of Figure 7d, showing the counter-heeling (CH) hydrofoil with its flap 12 rotated toward windward-
- Figure 8a is an isometric view of another embodiment of the present invention showing counter-leeward drift and counter-heeling flaps on a canting keel sailing vessel.
- Figure 8b is a cross-sectional, stern view of the embodiment of the present invention depicted in Figure 8a, with counter-leeward drift flap 21 and counter-heeling flap 22 affixed to the keel which is shown in both the canted and uncanted positions.
- Figure 9a is an isometric view of another embodiment of the counter- leeward drift and counter-heeling members for of the present invention.
- Figure 9b illustrates the detail of the embodiment of the present invention shown in Figure 9a showing both an upper, leading hydrofoil member 101 and a lower, trailing hydrofoil member 102 hydrofoil projecting from a common axis mounted within a keel.
- Figure 9c shows an isometric view of the embodiment of the combined heel and drift control assembly shown in Figure 9b, detailing the construction of the leading 101 and trailing 102 hydrofoil members incorporated on a common axis.
- Figure 9d is a cross-sectional, stern view of the embodiment depicted in Figure 9a shown on a 20 degree starboard tack.
- Figure 10 is a profile view illustrating yet another embodiment of the counter-leeward drift 41 and counter-heeling 42 flaps of the present invention with non-vertical hinges.
- Figure 1 Ia is a cross-sectional stern view, perpendicular to the course sailed, PPCS, of still another embodiment of the present invention, depicting two vertically slidable hydrofoils 51 and 52.
- Figure 1 Ib is a profile view illustrating one of the slidable hydrofoils from the embodiment of Figure 11a and an embodiment of the hydrofoil slide track or slot 58.
- Figure 1 Ic is a cross-sectional stern view, perpendicular to the course sailed, PPCS, of still another embodiment of the present invention, depicting two vertically slidable hydrofoils mounted on angled tracks.
- the tracks are in a plane essentially parallel to the midplane of the keel through most of the lower portion of the keel, 57, but angle out from the midplane of the keel when they reach their uppermost positions.
- Figure 12a is a cross-sectional stern view, perpendicular to the course sailed, PPCS, of another embodiment of the present invention, including two vertically slidable, angled cross-section hydrofoils 61 and 62.
- Figure 12b is a cross-sectional stern view of an angled, open cross- section, sliding hydrofoil 71 embodiment, showing the detail near the hull of the sailing vessel.
- Figure 12c is a cross-sectional stern view of an angled sliding hydrofoil 72 embodiment, showing the detail near the tip of the keel.
- Figure 13 is a chart comparing angle Beta ⁇ of Figure 12 vs. EWf, CHf and CDf of the vessel depicted in Figure 12a.
- Figure 14a is a cross-sectional stern view of still another embodiment of the present invention, depicting a sailing vessel on a starboard tack having a port tack centerboard 87 retracted and a starboard tack centerboard 97 shown rotated down into active position with an upper CLD hydrofoil 91 on the windward side and a lower CH hydrofoil 92 on the leeward side.
- Figure 14b is a cross-sectional stem view of still another embodiment of the present invention, depicting a sailing vessel on a starboard tack having a retracted port tack centerboard 126, angled counter-clockwise by an amount p from the midplane 125c of the hull, and a complimentary starboard tack centerboard 127, angled clockwise by an amount p from the midplane 125c of the hull and shown rotated down into active position with an upper CLD hydrofoil 128 on the windward side and a lower CH hydrofoil 129 on the leeward side.
- Figure 14c is a plan view of still another embodiment of the present invention, depicting a sailing vessel on starboard tack, having a retracted port tack centerboard 146, with the slot of its trunk 142 rotated counter-clockwise to an angle ⁇ from the design longitudinal axis of the hull of the vessel and a complimentary starboard tack centerboard 147 with the slot of its trunk 143 rotated clockwise to an angle ⁇ from the design longitudinal axis of the hull of the vessel, said centerboard 147 shown rotated down into active position with an upper CLD hydrofoil 148 on the windward side and a lower CH hydrofoil 149 on the leeward side.
- Figure 15a is a cross-sectional stem view of still another embodiment of the present invention, depicting a sailing vessel on a starboard tack having a port tack daggerboard 107 retracted and a starboard tack daggerboard 117 shown inserted into active position with an upper CLD hydrofoil 111 on the windward side and a lower CH hydrofoil 112 on the leeward side.
- Figure 15b is a cross-sectional stem view of still another embodiment of the present invention, depicting a sailing vessel on a starboard tack having a retracted port tack daggerboard 136, with the slot of its trunk 134 angled counter-clockwise by an amount tau ⁇ from the midplane 135c of the vessel, and a complimentary starboard tack daggerboard 137, with the slot of its trunk 133 angled clockwise by an amount tau ⁇ from the midplane 135c of the vessel, said starboard daggerboard shown inserted into active position with an upper CLD hydrofoil 138 on the windward side and a lower CH hydrofoil 139 on the leeward side.
- Figure 15c is a plan view of still another embodiment of the present invention, depicting a sailing vessel on starboard tack, having a retracted port tack daggerboard 156, with the slot of its trunk 152 disposed at an angle psi ⁇ counter-clockwise from the design longitudinal axis of the hull of the vessel and a complimentary starboard tack daggerboard 157, with the slot of its trunk 153 disposed at an angle psi ⁇ clockwise from the design longitudinal axis of the hull of he vessel; said starboard daggerboard 157 inserted down into the active position with an upper CLD hydrofoil 158 on the windward side and a lower CH hydrofoil 159 on the leeward side
- Figure 16a is a cross-sectional stern view of still another embodiment of the present invention, depicting a keel having a frame 164 with sides 167 and 168 that can be deformed in the upper section, near the root, by a CLD cam 161 and in the lower section, near the tip, by a CH cam 162 when the camshaft 163, which is controlled from above, is rotated.
- Figure 16b shows a top view, taken as section B-B designated in Figure 16a.
- Figure 16c shows a side or profile view, taken as section C-C designated in Figure 16b.
- Figure 17 depicts a sailing vessel on a starboard tack having two CLD hydrofoils, active hydrofoil 171 and inactive hydrofoil 173, disposed at the root end of keel 177 and two CH hydrofoils, active hydrofoil 174 and inactive hydrofoil 172, disposed at the tip end of keel 177.
- Figure 18 is a stern view of a sailing vessel on a starboard tack showing two rotatable hydrofoil members 185 and 186 mounted on axes one above the other in parallel disposition to each other and to the longitudinal axis of the vessel. The upper member is shown with a cambered surface directed toward windward and the lower member is shown with a cambered surface directed toward leeward.
- appendage means a keel, a centerboard, a dagger board, or a similar protrusion extending from the hull of a sailing vessel and into the water.
- hull means a vessel's shell or body, exclusive of appendages, which provides buoyancy and structure upon which to mount deck, cabin, sails, rigging, and the like. This term is meant to include a monohull of conventional sailing vessels and a single hull of the so- called multihull boats such as catamarans and trimarans, where the multiple hulls are often singularly referred to as pontoons.
- center of gravity CG means the geometric center of weight of the boat and every item in it.
- VCG vertical center of gravity
- center of buoyancy means the center of gravity of the water displaced by the boat.
- vertical center of buoyancy means the height at which the center of buoyancy is located.
- waterline plane of the hull means the two dimensional area within a line defined by the intersection of the hull and the surface of the water within which a vessel floats.
- design waterline plane of the hull means the plane within which the designer intended the vessel to float at zero degrees heel.
- load waterline plane of the hull means the plane within which the completed vessel actually floats at zero degrees heel. For purposes herein this will be considered to be the same as the "design waterline plane of the hull”.
- the "heeled or instant waterline plane” means the two dimensional area within a line defined by the intersection of the hull and the surface of the water when the vessel is heeling at any given angle.
- the term "design longitudinal axis of rotation, or rolling” (DLAR) means a line extending fore and aft of the hull or pontoon of a sailing vessel upon which the vessel initiates rotation (or rolling) from an initial position of zero degrees heeling. For purposes herein, this will be assumed to be close to the waterline plane and bisect or be about halfway between equal areas of the design waterline plane of the hull.
- ILAR instant longitudinal axis of rotation
- this axis will be assumed to bisect or be about halfway between equal areas, to port and starboard, of the heeled waterline plane of the hull.
- the ILAR is equal to the DLAR and as the heeled waterline plane moves, relative to the hull with increased heeling, the ILAR will move accordingly.
- the term "midplane” means a bisecting, fore and aft, centered plane of symmetry.
- the midplane of the hull, or hull midplane bisects the hull of a sailing vessel in the longitudinal direction and is in a vertical attitude at a heeling angle of zero degrees.
- the midplane of an appendage, or appendage midplane bisects an appendage of a sailing vessel in the longitudinal direction from the leading edge to the trailing edge of the appendage.
- the plane of a conventional keel is typically in the same plane as is the midplane of the hull.
- FIG. 6e An example of a midplane of a hull appears in Figure 6e as reference number 6. Also shown in this figure is an example of a midplane of an appendage or keel, which appears as reference number 16. It can be seen that in this case the two planes are in alignment. Similarly, examples of appendage (e.g., keel, centerboard, or dagger board) midplanes appear in Figures 6e, 14a and 15a as reference numbers 16, 95 a and 115a respectfully.
- appendage e.g., keel, centerboard, or dagger board
- FIGS 5 through 7f depict a sailing vessel shown with hull or body 5, rudder 8, keel 17, and ballast bulb 19. Specific attention is directed to two control flaps mounted on the keel, i.e,, an upper, counter-leeward drift flap 11 and a lower, counter-heeling flap 12.
- an upper, counter-leeward drift flap 11 and a lower, counter-heeling flap 12.
- Figure 5 shows the hull 5 of a typical, but modified, according to the present invention, sailing yacht.
- Its keel 17 is rigidly attached at its root or base to the bottom of the hull 5, its midplane being in vertical alignment with the midplane of the hull.
- the counter-leeward drift flap 11 is attached to the upper or root portion and trailing edge of the keel 17, close to the hull 5.
- the counter-heeling flap 12 is attached at the trailing edge and at the lower end, or tip, of the keel 17, just above the ballast bulb 19.
- either or both of these hydrofoils or flaps, 11 and 12 can be attached to the leading edge of the keel 17 where, similar to leading-edge flaps on aircraft, they can perform the same function.
- the two aforementioned flaps, 11 and 12, are designed and located such that the center of effort of the counter-heeling flap 12 is at a considerably greater distance from the design longitudinal axis of rotation, or rolling, taken to be located at point R in Figure 7a, of the vessel than is the center of effort of the counter leeward-drift flap 11. This distance is intended to provide a much longer moment arm for the counter heeling flap 12 than the moment arm of the counter leeward-drift flap 11. This allows the counter-heeling flap 12 to be much more effective in its intended function.
- the differential of these moment arms can be increased or decreased as can be the size, shape or locations of these foils to achieve the desired results.
- FIGS 6a, 6b, 6c, 6d and 6e more clearly show the elements of Figure 5. Specifically, these figures show detailed views of the counter-leeward drift flap 11 and the counter-heeling flap 12 shown in Figure 5.
- the size and shape of the counter-leeward drift flap 11 and the counter-heeling flap 12 can be adapted to meet the objectives of any particular keel design.
- the angle of deflection can be independently varied during sailing, to increase or decrease the hydrodynamic force exerted by the associated hydrofoil on the vessel as required in order to maximize sailing efficiency.
- the flaps may be coupled to act in accordance with a relationship designed into the coupling mechanism.
- Hinges 13 and 14 allow for flap movement.
- Control systems for various hydrofoil movements are known in. the art. The present invention envisages any such control system. Such systems could include mechanical and/or electromechanical linkages powered by a crank, lever, hydraulic system, servomotor or the like.
- the CLD flap or hydrofoil will be located high on the keel appendage, as close to the root as efficiency will allow. This will position its center of effective effort close to the design longitudinal axis of rotation ( Figures 6d and 6e, reference 10) which will ⁇ miirnize its contribution to the heeling moments on the vessel.
- the CH flap or hydrofoil will be located as close to the lower or tip end of the keel or appendage as efficiency will allow. This will position its center of effort at the maximum effective distance from the design longitudinal axis of rotation which will maximize its contribution to the counter-heeling moments on the vessel.
- Figure 6e wherein the hinge 13 of CLD flap 11 and the hinge 14 of CH flap 12 are shown to be located essentially within the midplane 16 of the keel or appendage.
- the CLD flap is referenced as 41 mounted on hinge 43 and the CH flap is referenced as 42 mounted on hinge 44.
- hinges 43 and 44 are shown at respective angles ⁇ and ⁇ 2 which are oriented at less than ninety (90) degrees, fore or aft, to a lateral plane (Figure 6d, reference 15) perpendicular to the design longitudinal axis of rotation of the vessel.
- Lateral plane 15 in Figure 6d may also be defined as the vertical plane that is perpendicular to the midplane 16 of appendage or keel 17.
- FIG 7a shows a stern view, in a plane perpendicular to the course sailed (PPCS), of the sailing vessel, depicted in Figures 5 through 6e, on a starboard tack, heeling at 20 degrees.
- PPCS course sailed
- the counter-leeward drift flap 11 is shown rotated toward the leeward side in order to generate a hydrodynamic force FQL F generally toward the windward side of the vessel
- FQL F acts at the center of effort A of the CLD hydrofoil which is the combination of flap 11 and its complementary section of keel 17.
- FLD is the component of the hydrodynamic force FCLF of the CLD hydrofoil, resolved into a plane perpendicular to the course sailed (PPCS).
- F LD has a horizontal component F C D which is equal to F LD COS ⁇ . (Refer to Figure 7a), where ⁇ is the heeling angle of the vessel. This is the counter-leeward drift force contributed by the CLD hydrofoil.
- FH Another component of force F LD contributes to the heeling moments acting on the vessel.
- This component, FH also acts at the center of effort A of the CLD hydrofoil within a plane perpendicular to the course sailed (PPCS).
- FH is equal to F LD COS ⁇ , where ⁇ is the angle between RA and the midplane of the keel.
- RA is the perpendicular distance between the line of the force FH and the instant longitudinal axis of rotation, which is taken to be at point R in the figure.
- the perfect symmetry of its circular cross-section would cause the axis of rotation, or rolling, to reside at the intersection of the midplane and a projected line of the buoyancy force, regardless of the angle of heel. This would allow the vessel to immerse a volume on one side of the vessel equal to the volume being emerged on the opposite side of the vessel as the vessel rotates on this axis at any heeling angle.
- the symmetry of the submerged cross-section is lost upon heeling and, as the area of the instant waterline plane moves away from the midplane with rotation of the hull, the instant axis of rotation will move as well.
- the movement of the axis will closely follow a position that continues to allow the area of the instant waterline plane to be longitudinally bisected by this axis, thus assuring that the volume of water displaced by immersion on one side of the axis is replaced by an equal volume of water due to emergence on the opposite side of the axis.
- the buoyant force necessary to support the weight of the vessel thus remains constant. It may also be noted that the variation of cross-section along the length of the hull will also have an effect on the longitudinal trim of the vessel.
- F L H is the component of the hydrodynam ⁇ c force, FcH F of the CH hydrofoil, resolved into a plane perpendicular to the course sailed (PPCS).
- FLH in turn, has a horizontal component FD, which is equal to FLH COS ⁇ , where ⁇ is the heeling angle of the vessel.
- F D also acts at the center of effort C of the hydrofoil 12 in the plane perpendicular to the course sailed (PPCS). This is the leeward drift force contributed by the CH hydrofoil.
- the force F LH also has a component, in the plane perpendicular to the course sailed that acts at the center of effort C of hydrofoil 12 in a direction perpendicular to the instant longitudinal axis of rotation R of the vessel.
- This component, F C H is equal to F L H COS ⁇ , where ⁇ is the angle between RC and the midplane of the keel.
- RC is the perpendicular distance between the line of force FCH , and the instant longitudinal axis of rotation R of the vessel.
- the force FCH multiplied by its perpendicular distance RC to the instant longitudinal axis of rotation R of the vessel represents the counter-heeling moment, F C H X RC, provided to the vessel by the CH hydrofoil.
- ⁇ LDF 11/12 F LD cosine ⁇ - F LH cosine ⁇
- a positive value of ⁇ LDF 11/12 indicates an increase in counter-drift forces.
- FL D is a component of the hydrodynamic force of the CLD foil, of which flap 11 is an element, resolved into a plane perpendicular to the course sailed, PPCS.
- FLH ⁇ S a component of the hydrodynamic force of the CH foil, of which flap 12 is an element, resolved into a plane perpendicular to the course sailed, PPCS.
- Fc D is the horizontal counter-leeward drift force component of F LD, also acting in the plane perpendicular to the course sailed, PPCS.
- FD is the horizontal leeward drift force component of Fm also acting in the plane perpendicular to the course sailed (PPCS).
- Phi ( ⁇ ) is the heeling angle of the vessel.
- R is the instant longitudinal axis of rotation of the vessel.
- A is the center of effort of the upper hydrofoil 11.
- RA is the lever arm distance between points R and A.
- Theta ( ⁇ ) is the angle between RA and the midplane of the keel 17.
- F LD is a component of the hydrodynamic force of the CLD foil, of which flap 11 is an element, resolved into a plane perpendicular to the course sailed, PPCS.
- F H is that component of force FL D directed at right angles to lever arm RA also acting in the plane perpendicular to the course sailed (PPCS).
- R is the instant longitudinal axis of rotation of the vessel
- C is the center of effort of the CH hydrofoil RC is the lever arm distance between points R and C Mu ( ⁇ ) is the angle between RC and the midplane of the keel 17.
- F L H is a component of the hydrodynamic force of the CH foil, of which flap 12 is an element, resolved into a plane perpendicular to the course sailed (PPCS).
- Fen is that component of force FL H directed at right angles to lever arm RC, also acting in the plane perpendicular to the course sailed (PPCS).
- ⁇ CHM 11/12 F LH cosine ⁇ x RC - F L D cosine ⁇ x RA
- a Counter-heeling to Heeling Improvement Ratio (CHIR) contributed by the hydrofoils can be stated as:
- Equation 1H-3 also shows that, if desired, in operation this deviation would be readily trimmed out with corrections to FLH and/or FLD made by the helm or by an associated control system. Therefore, for simplification and explanatory purposes herein, this ratio will be assumed to remain constant.
- drift forces contributed by the two hydrofoils in this example can be obtained by a summarization of the horizontal forces.
- ⁇ CHM 11/12 F LH x DC - 2 x F LH xDC / 3
- a positive value of ⁇ CHM 11/12 indicates a net reduction in heeling moments acting on a sailing vessel, equal to 1/3 FLH X DC.
- the resultant counter-heeling moments generated by embodiments of the present invention are able to work independently or in conjunction with counter-heeling moments produced by conventional, new, prior art and other designs including, but not limited to, such that utilize ballast and/or moments produced by the weight of the vessel when the axis of rotation shifts due to heeling.
- Figure 7c shows a typical configuration wherein this embodiment of the present invention joins the ballast on a conventional sailing vessel
- F H RA, F C H and RC have been previously defined.
- Fsp is a component of the aerodynamic force generated by the wind on the sails resolved into a plane perpendicular to the course sailed, PPCS.
- ds is the perpendicular distance from the line of action of Fsp and the instant longitudinal axis of rotation R of the vessel.
- FK comprises the residual forces acting on the keel, including rudder, hull and like forces but excluding the forces associated with the CLD and CH hydrofoils which are shown separately.
- die is the perpendicular distance from the line of action of FK and the instant longitudinal axis of rotation R of the vessel.
- Fw is the weight, including ballast 19, of the vessel assumed to be concentrated at the center of gravity (G) of the vessel.
- d ⁇ w is the perpendicular distance between the lines of action of the weight force Fw and the buoyancy force FB-
- Fg is the buoyancy force acting on the vessel, equal and opposite to Fw .
- this embodiment of the present invention will assist the counter-heeling capabilities of the vessel, such that the vessel will heel less and/or ballast weight can be reduced with a significant improvement in the sailing efficiency of the vessel.
- the design criteria for this invention including moment arms, hydrofoils, flaps, or members, shapes and sizes, mounting arrangements, control systems and the like can be varied in many combinations at the discretion of designers to simultaneously and significantly improve the heeling and the drift characteristics of sailing vessels. Also, controls for these embodiments, provided for the helmsman, will permit immediate adjustments as demand requires during their operation. By increasing or decreasing the angle of rotation of either the CLD or CH flap, the helmsman can vary the lift force generated by either or both hydrofoils to suit the immediate conditions.
- each of the flaps can be rotated independently to provide more or less lift.
- the flaps can be coupled by design to rotate according to a prescribed algorithm.
- the algorithm can include inputs from the helm, apparent wind speed and wind direction, heeling angle, position (GPS), heading, drift, track, weather, destination and other relative factors, as desired.
- twin hydrofoil, keel of the present invention can be used by sailing vessels of virtually every design category.
- Figures 8a and 8b show a sailing vessel as described above but with a canting keel 27, rather than a fixed keel.
- counter-leeward drift flap 21 and counter- heeling flap 22, similar to previously described flaps 11 and 12 are mounted on the canting keel 27.
- both of these flaps are mounted on the keel, reducing or precluding a requirement for additional separate appendages or devices to counter leeward drift forces or heeling moments.
- a CLD flap can be mounted on the upper portion of the keel 2 and a CH flap can be mounted on the lower portion of the keel 2, either above or below the fins 5a and 5b.
- the forces generated by the CLD and CH flaps would function to complement the action of fins 5a and 5b.
- Figures 9a through 9d simultaneously provides both counter-leeward drift forces and counter-heeling moments. As depicted in Figures 9a through 9d, only two rotating appendages are utilized on the vessel, a rudder 8 and the assembly 100. Like the winged keel of Figure 4, with two wings or hydrofoils, configured together as a single unit, assembly 100 is also a single unit configured with two hydrofoils that enable both counter-leeward drift forces and counter heeling moments to be generated.
- Figure 9a shows a sailing vessel similar in design to the sailing vessel of Figures 5 through 7, previously described; however, the counter-leeward drift hydrofoil member 101 and the counter-heeling hydrofoil member 102 are each an integral part of a composite assembly 100 and, in operation, are designed to rotate as a single unit
- the counter-leeward drift foil 101 is shown projecting from axel 103 toward the leading edge of the keel 37 rather than toward the trailing edge of the keel.
- the counter heeling foil 102 is shown extending from axel 103 toward the trailing edge of the keel 37.
- Figure 9b shows a detailed view of the assembly 100 installed in the keel 37 and rotated in a counter-clockwise direction when viewed from above.
- the upper and forward section, 101, of assembly 100 is shaped like and is intended to function, in concert with its neighboring section of keel 37, like a hydrofoil. Since it is located near the top of the assembly, its primary function is intended to provide counter-leeward drift forces.
- the lower and trailing section 102 of assembly 100 is also shaped like and is intended to function, in concert with its neighboring section of the keel 37, as a hydrofoil.
- the keel Since it is located near the lower extremity of the keel, its primary function is intended to provide counter heeling moments; If a designer wishes, he can project the upper foil toward the trailing edge and the lower hydrofoil toward the leading edge; they will still move toward opposite sides of the keel when assembly 100 is rotated and this will not change their function. Again, the upper foil is always the Counter-leeward Drift foil and the lower foil is always the Counter-heeling hydrofoil.
- the components of assembly 100 comprise its axel 103 and two hydrofoil members 101 and 102.
- the assembly 100 is mounted in an upper bearing 104, affixed to the canoe body 5, or proximate to the upper end of the keel 37 and a lower bearing 105 mounted proximate to the lower end of the keel 37 or on the upper surface of the ballast bulb 39.
- a counter-leeward drift hydrofoil member 101 Positioned near the upper end of the axel is a counter-leeward drift hydrofoil member 101, which extends toward the leading edge of the keel 37.
- a counter-heeling hydrofoil member 102 Positioned near the lower end of the axel is a counter-heeling hydrofoil member 102, which extends to ward the trailing edge of the keel 37.
- the configuration is such that, as the assembly 100 rotates, the hydrofoil members 101 and 102 move to opposite sides of the keel.
- Figure 9d shows a partial schematic, aft view of the vessel heeling at 20 degrees on a starboard tack. In this case, when Assembly 100 rotates counterclockwise, as viewed from above, the upper and forward, counter-leeward drift flap 101 rotates toward the leeward side of keel 37, generating a lift toward the windward side of the keel 37.
- the lower and trailing, counter-heeling flap 102 which also extends from axel (shaft) 103 but to the trailing edge of the keel 37, rotates to the windward side of the keel 37, generating lift toward the leeward side of the keel 37.
- These two flaps, 101 and 102 are intended to function similarly to the flaps 11, 12, 21 and 22 of Figures 5 through 8b, such that their locations on a keel, or similar appendage, positions the lower CH flap at a significantly greater distance from the design longitudinal axis of rotation of the vessel than the upper CLD flap is positioned from the design longitudinal axis of rotation, thus enabling a sailing vessel to counter both leeward drift forces and heeling moments simultaneously.
- the two hydrofoils, 101 and 102 do not have to be sized and shaped such that they each provide the same amount of lift. Rather, the lift characteristics can be varied or modified according to the objectives of the sailing vessel designer.
- FIG 10 shows a keel appendage 47, which has two flap-type hydrofoils, 41 and 42, mounted on hinges 43 and 44 respectively. This is similar to keel appendage 17 of Figures 6a -6b with hydrofoils 11 and 12 mounted on hinges 13 and 14. The significant difference between these two appendages is in the angles of the hinges on each keel 17 or 47 that connect the flaps to the keel.
- a foil when it is rotated out of the plane of the keel, to either side, as opposed to a foil with a vertical hinge, which generates lift essentially normal to the plane of the keel, it will direct its hydrodynamic force not just out from the plane of the keel, but out and up, such that an upward force component will be generated. Therefore, the utilization of this concept enables the vessel designer to build in an increased amount of upward force for reduced effective weight when the hydrofoils are rotated. The more that the angles ⁇ t and ⁇ are raked back from the vertical the greater that upward component will be.
- This component will be at the expense of the net counter-leeward drift and counter- heeling forces, but it enables the vessel designer to modify or balance these forces to achieve his desired sailing characteristics. It follows that the opposite effect can be achieved in either or both flaps by angling the hinge(s) on either or both flaps in the opposite direction, that is, a forward rake from the vertical. In this case, the force of the hydrofoil will be directed in a more downward direction. This will increase the effective weight force and benefit both the counter-leeward drift characteristics and the counter-heeling moments.
- the present invention envisages designs that may utilize either the same, different or variable values for the angles ⁇ and ⁇ 2 and either may be in a forward or aft raked direction.
- the CLD flap or hydrofoil will be located high on the keel appendage, as close to the root as efficiency will allow. This will position its center of effective effort close to the design longitudinal axis of rotation ( Figure 6d and 6e, reference 10) which will rninimize its contribution to the heeling moments on the vessel. Complimenting this concept, the CH flap or hydrofoil will be located as close to the lower or tip end of the keel or appendage as efficiency will allow. This will position its center of effort at the maximum effective distance from the design longitudinal axis of rotation which will maximize its contribution to the counter-heeling moments on the vessel.
- FIG. 6d wherein the hinge 13 of CLD flap 11 and the hinge 14 of CH flap 12 are shown to be located essentially within the midplane (Figure 6e, reference 16) of the keel or appendage.
- the CLD flap is referenced as 41 mounted on hinge 43
- the CH flap is referenced as 42 mounted on hinge 44.
- hinges 43 and 44 While still located essentially within the midplane of the keel, hinges 43 and 44 are shown at respective angles ⁇ j and 6 2 which are oriented at less than ninety (90) degrees, fore or aft, to a lateral plane (Figure 6d, reference 15) perpendicular to the design longitudinal axis of rotation of the vessel.
- Lateral plane 15 in Figure 6d may also be defined as the vertical plane that is perpendicular to the midplane 16 of appendage or keel 17.
- the present invention also envisages embodiments where (1 ) the flaps have hinges with fixed alignments and (2) the flaps have hinges where the alignment of the hinges is adjustable.
- Figure 11a shows a stern view, in a plane perpendicular to the course sailed, of a sailing vessel heeling at 20 degrees on a starboard tack; that is the starboard side of the vessel is to windward.
- Attached to the keel 57 are two hydrofoils that are made as mirror images of each other, a starboard-side hydrofoil 51 and a port- side hydrofoil 52.
- the keel includes tracks 58, one on each side of the keel.
- These tracks may run (i) parallel to the keel leading edge, as shown (ii) parallel to the keel trailing edge or (iii) along any other substantially vertical line.
- the tracks permit the hydrofoils to be slid, by suitable means, to the top position on the keel 57 or to the bottom position on the keel 57, as desired by the helm.
- hydrofoil on the leeward side be positioned at the lowest point on the keel with its cambered surface and thus its hydrodynamic force being directed generally in a leeward direction and the hydrofoil on the windward side be positioned at the highest point on the keel with its cambered surface and thus its hydrodynamic force being directed generally in a windward direction.
- the positions of the hydrofoils will also be reversed. When running before the wind they can. be positioned opposite to each other at any convenient position on the keel.
- the hydrofoil 52 on the leeward side of the keel 57 is moved to the bottom position near the tip of the keel, as shown in Figure 1 Ia, where it will generate a hydrodynamic force generally toward the leeward side of the sailing vessel.
- a component of that leeward force, resolved into a vertical plane, perpendicular to the course sailed (PPCS), is shown, as lift force F LH.
- F L H has a component F C H, also acting in the plane perpendicular to the course sailed, that is equal to FL H COS ⁇ that contributes to the counter-heeling moments acting on the vessel.
- F CH acts at the point of effective effort C in a direction perpendicular to the lever arm RC.
- Lever arm RC is the distance between the point of effective effort, C, and the instant longitudinal axis of rotation, taken to be at point R of the vessel.
- Angle ⁇ is the angle included within RC and the midplane of the keel 57. Since FCH acts at right angles to RC, it exerts a counter- heeling moment of F C H ⁇ RC or FL H Cos ⁇ x RC.
- FQ the horizontal component of FLH 5 adds to the leeward drift forces acting on the sailing vessel.
- F D is equal to FL H Cos ⁇ , where ⁇ is the heeling angle.
- the hydrofoil 51 Concurrently, on the windward side of the keel 57, the hydrofoil 51 is moved to the top position near the root of the keel, as shovm in Figure lla, where it will generate a hydrodynamic force, generally toward the windward side of the sailing vessel.
- FL D has a horizontal component FCD which acts at the center of effort A and is equal to FLD COS ⁇ , also acting in a plane perpendicular to the course sailed (PPCS), and is the resulting counter-leeward drift force F C D exerted by CLD hydrofoil 51.
- This horizontal component, F C D will counter leeward drift forces acting on the vessel.
- FLD Another component of force FLD contributes to the heeling moments acting on the vessel.
- This force component, FH also acting in a plane perpendicular to the course sailed (PPCS), is equal to FLD COS ⁇ and acts at the center of effort A in a direction perpendicular to the lever arm RA.
- Lever arm RA is the distance from the center of effort A to the instant longitudinal axis of rotation R of the vessel.
- Angle ⁇ is the angle included between RA and the midplane of the keel 57. Since F H acts at right angles to RA, it exerts a heeling moment of FH X RA or FLD COS ⁇ X RA.
- a positive value of ⁇ LDF 51/52 indicates a net increase in counter-leeward drift forces.
- FLD is a lift component of the hydrodynamic force of foil 51 , resolved into a plane perpendicular to the course sailed, PPCS.
- FLH ⁇ S a lift component of the hydrodynamic force of foil 52, resolved into a plane perpendicular to the course sailed, PPCS.
- FcD is the horizontal counter-leeward drift force component of FLD, also acting in the plane perpendicular to the course sailed, PPCS.
- F D is the horizontal leeward drift force component of F L H also acting in the plane perpendicular to the course sailed
- a summation of the heeling moments contributed by hydrofoils, 51 and 52, is as follows:
- R is the instant longitudinal axis of rotation of the vessel.
- A is the center of effort of the upper hydrofoil 51.
- RA is the lever arm distance between points A and R.
- Theta ( ⁇ ) is the angle between RA and the midplane of the keel 57.
- F LD is a lift component of the hydrodynamic force of foil 51, resolved into a plane perpendicular to the course sailed (PPSC).
- F H is that component of force F LD directed at right angles to lever arm RA also acting in the plane perpendicular to the course sailed (PPSC).
- the counter-heeling moment generated by hydrofoil 52 is: Counter-heeling Moment of Hydrofoil 52 (CHM 52):
- R is the instant longitudinal axis of rotation of the vessel
- C is the center of effort of the lower hydrofoil 52 RC is the lever arm distance between points R and C
- Mu ( ⁇ ) is the angle between BC and the midplane of the keel 57.
- F L H is a lift component of the hydrodynamic force of foil 52, resolved into a plane perpendicular to the course sailed (PPSC).
- FcH is that component of force FLH directed at right angles to lever arm RC also acting in the plane perpendicular to the course sailed
- ⁇ CHM 51/52 F LH ( DC - DA )
- a Counter-heeling to Heeling Improvement Ratio (CHIR 52/51) contributed by foils 52 and 51 can be stated as:
- Figure lie which is a stern view, in a plane perpendicular to the course sailed (PPCS), depicts a variation in the lateral direction of the tracks of hydrofoils 51 and 52 which are shown here as 51' and 52' respectively.
- the two tracks of hydrofoils 51' and 52' are in planes essentially vertical and parallel to the midplane of the keel 57' for most of their travel in the lower portion of the keel, 57' , but angle away from the midplane of the keel 57' when they reach their uppermost positions where they function as CLD hydrofoils.
- This variation is intended to park each hydrofoil, when it is in the uppermost position, with its cambered surface facing somewhat down from parallel to the plane of the keel.
- FIG. 12a An analysis treated hereinafter relating to Figure 12a depicts sliding hydrofoils which are fashioned with their cambered surfaces positioned at an angle ⁇ to the midplane of the keel. It will be shown, for example in Figure 13, that the counter-heeling, counter-leeward drift and effective weight characteristics can be modified to significantly improve the efficiency of a sailing vessel by changing the angle ⁇ . It is also apparent that designs of the embodiment depicted in Figure 10 may utilize different values for each of angles ⁇ i and ⁇ 2 depending upon the objectives. However, if both of these angles were made comparable to the angle ⁇ of Figure 12a, the results would be analogous.
- Figure 12a shows a stern view perpendicular to the course sailed of a sailing vessel heeling at 20 degrees on a starboard tack Attached to the keel 61 are two hydrofoils that are made as mirror images of each other, a starboard-side hydrofoil 61 and a port-side hydrofoil 62. Essentially, these hydrofoils are designed, mounted and function similar to the hydrofoils shown in Figure lla but with one significant distinction.
- each hydrofoil, 51 and 52 is parallel to the midplane of the keel
- Figure 12a shows that the plane of the cambered surface of the starboard side hydrofoil 61 is fixed at an angle ⁇ rotated clockwise from the midplane of the keel and the cambered surface of the port side hydrofoil 62 is fixed at an equal angle ⁇ rotated counter-clockwise from the midplane of the keel.
- This positioning, or angling changes the direction of the forces generated by the hydrofoils relative to the degree that they are angled.
- ⁇ EWF 61/62 F LD sine ( ⁇ - ⁇ ) - F LH sine ( ⁇ + ⁇ )
- a negative value of ⁇ EWF 61/62 indicates an increase in effective weight
- FL D is a lift component of the force of the windward hydrofoil 61 resolved into a plane that is perpendicular to the course sailed (PPCS).
- FLH is a lift component of the force of the leeward hydrofoil 62 resolved into a vertical plane that is perpendicular to the course sailed (PPCS).
- Phi ( ⁇ ) is the heeling angle of the vessel.
- Beta ( ⁇ ) is the angle that the cambered surface of either hydrofoil is rotated away from the midplane of the keel.
- ⁇ LDF 61/62 F CD - F D
- ⁇ LDF 61/62 F LD cosine ( ⁇ - ⁇ ) - F LH cosine ( ⁇ + ⁇ )
- a positive value of ⁇ LDF 61/62 indicates a net increase in counter-drift forces.
- FL D is a lift component of the force of the windward hydrofoil 61 resolved into a plane that is perpendicular to the course sailed (PPCS).
- FLH is a lift component of the force of the leeward hydrofoil 62 resolved into a plane that is perpendicular to the course sailed (PPCS).
- Fc D is the horizontal counter-leeward drift force component of FLD, also acting in the plane perpendicular to the course sailed.
- FD is the horizontal leeward drift force component of FLH , also acting in the plane perpendicular to the course sailed.
- Phi ( ⁇ ) is the heeling angle of the vessel.
- ⁇ LDF 61/62 F LH ⁇ cosine ( ⁇ - ⁇ ) - cosine ( ⁇ + ⁇ ) ]
- CDf Counter Leeward-drift factor
- R is the location of the instant longitudinal axis of rotation of the vessel.
- A is the center of effort of the upper hydrofoil 61.
- RA is the distance between points R and A.
- Theta ( ⁇ ) is the angle between RA and the midplane of the keel 67.
- Beta ( ⁇ ) is the angle that the cambered surface of hydrofoil 61 is rotated clockwise away from the midplane of the keel.
- FLD is the lift component of the force of the windward hydrofoil 61 resolved into a plane that is perpendicular to the course sailed (PPCS).
- FH is that component of lift force FL D that acts at right angles to lever arm RA also acting in the plane perpendicular to the course sailed (PPCS).
- the counter-heeling moment generated by hydrofoil 62 is: Counter-heeling Moment of Hydrofoil 62 (CHM 62):
- R is the location of the instant longitudinal axis of rotation of the vessel.
- C is the center of effort of the lower hydrofoil 62.
- RC is the distance between points R and C.
- Beta ( ⁇ ) is the angle that the cambered surface of hydrofoil 62 is rotated counter-clockwise away from the midplane of the keel 67.
- Mu ( ⁇ ) is the angle between RC and the midplane of the keel 57.
- F L H is the lift component of the force of the leeward hydrofoil 62 resolved into a plane that is perpendicular to the course sailed (PPCS).
- Fc H is that component of lift force Fm that acts at right angles to lever arm RC also acting in the plane perpendicular to the course sailed (PPCS).
- CHM 62 -HM 61 Fc H x RC - FH x RA
- FIG. 12b shows a sliding, open-hydrofoil design. This open-hydrofoil design presents a slimmer profile to the incident fluid flow to reduce drag.
- the figure shows the upper portion of keel 77 on a starboard tack, the starboard hydrofoil 71 positioned at the upper position on keel 77, the cambered surface 73 of starboard hydrofoil 71, the keyed, slidable foot 75 of starboard hydrofoil 71 and the lift force F LD of starboard foil 71.
- Figure 12c shows the lower portion of keel 77 on a starboard tack, the port side hydrofoil 72 positioned at the lower position on keel 77, the cambered surface 74 of port side hydrofoil 72, the keyed, slidable foot 76 of port side hydrofoil 72 and the lift foTce F LH of port side foil 72.
- FIG 13 the effect of redirecting the hydrodynamic forces generated by hydrofoils 61 and 62 or 71 and 72 of Figures 12a to 12c is shown.
- the graph shows EWf, CDf and CHf plotted against values of the angle beta, ⁇ .
- a wide range of values is offered to allow designers to make comparisons and weigh alternatives.
- specific values of beta ( ⁇ ) will be chosen to obtain performance characteristics in tune with design objectives.
- Figure 13 shows the relationship between the Effective Weight factor, EWf, the Counter Drift factor, CDf and the Counter Heeling factor, CHf and how they vary with a change in the angle beta ( ⁇ ).
- embodiments of the present invention can be applied to various appendages that extend from a sailing vessel hull, including fixed appendages such as conventional keels and winged keels and appendages affixed movably such as canting keels and rudders and the like. Also, specifically included are removable appendages such as centerboards and daggerboards
- FIG. 14a is a stern view of a sailing vessel on a starboard tack.
- This figure depicts two centerboards 87 and 97 mounted side-by-side, within a trunk 83, on an axel 84 such mat each centerboard can be pivoted downward into the active position when desired.
- Centerboard 97 is shown in the active position for a starboard tack.
- it has a CLD hydrofoil 91 mounted on its uppermost portion which will generate a force generally in the windward direction of the vessel.
- CH hydrofoil 92 mounted on its lowermost portion which will generate a force generally in the leeward direction of the vessel.
- centerboard 87 In this starboard tack mode, centerboard 87, with CLD hydrofoil 81 and CH hydrofoil 82 attached, is shown retracted to the inactive position. Although centerboard 87 is shown mounted on the port side of the vessel and centerboard 97 on the starboard side, these positions could be reversed depending upon the objectives of the designer.
- FIG 15a which is a schematic diagram of a stern view of a sailing vessel on a starboard tack, depicts two daggerboards 107 and 117 mounted side- by-side, within a trunk 113, having two slide slots 106, such that each daggerboard can be inserted and slid downward into the active position when desired.
- Daggerboard 117 is shown in the active position for a starboard tack. As configured, it has a CLD hydrofoil 111 mounted on its uppermost portion which will generate a force generally in the windward direction of the vessel. It also has a CH hydrofoil 112 mounted on its lowermost portion which will generate a foTce generally in the leeward direction of the vessel.
- daggerboard 107 In this starboard tack mode, daggerboard 107, with CLD hydrofoil 109 and CH hydrofoil 110 attached, is shown retracted to the inactive position. Although daggerboard 107 is shown mounted on the port side of the vessel and daggerboard 117 on the starboard side, these positions could be reversed depending upon the objectives of the designer.
- FIG. 14b is a stem view of a sailing vessel on a starboard tack, wherein the single axel 84 of Figure 14a described above is replaced by two axels, a starboard axel 120 and a port axel 121.
- each axel would be disposed at an angle rho (p) from the horizontal or design waterline plane of the hull, such that, when the appropriate centerboard is rotated down to its active position when the vessel is heeling during a tack, it would be directed in a more vertical direction and penetrate more deeply into the water.
- the starboard centerboard 127 would be rotated on its axel 120 downwardly into the active position and, as shown, would be positioned in a more vertical attitude by an amount equal to the angle p.
- the port centerboard 126 mounted on its port axel 121, which is rotated by an amount p in the opposite direction from the horizontal or design waterline plane of the hull, would also be positioned in a more vertical attitude by an amount equal to the angle p. This would direct the forces generated by the hydrofoils in a more horizontal direction and sink the centerboards deeper into the water.
- axels with axes that are adjustable, permitting an increase or decrease in the value of angle p.
- FIG. 15b is a stern view of a sailing vessel on a starboard tack, wherein the parallel slots 106 of Figure 15a described above are replaced by two slots, a starboard slot within trunk 133 and a port slot within trunk 134.
- each slot would be disposed at an angle tau ( ⁇ ) from the vertical axis of the vessel, such that, when the appropriate daggerboard is inserted downwardly into its active position when the vessel is heeling during a tack, it would be directed at a more vertical angle and would penetrate more deeply into the water.
- ⁇ angle tau
- the starboard daggerboard 137 would be inserted downwardly into the slot of trunk 133, which is angled clockwise from the vertical midplane of the vessel. It would then reside in its active station and, as shown, would be positioned in a more vertical attitude by an amount equal to the angle ⁇ .
- the port daggerboard 136 On a port tack, the port daggerboard 136, would be inserted downwardly into the slot of trunk 134, which is angled counter-clockwise from the vertical midplane of the vessel. It would then reside in its active station and be positioned in a more vertical attitude by an amount equal to the angle t. This would direct the forces generated by the hydrofoils in a more horizontal direction and sink the daggerboards deeper into the water. Also envisaged are such trunks with slots that are adjustable, permitting an increase or decrease in the value of angle ⁇ at the discretion of the helm.
- FIG 14c is a plan view showing a sailing vessel with starboard centerboard 147 rotated down to the active position for a starboard tack and port centerboard 146 shown retracted to the inactive position.
- Centerboards 147 and 146 are mounted on axels 140 and 141 respectively that are affixed perpendicular to the sides of trunks 143 and 142, each side of which is configured, as shown, at an angle omega ( ⁇ ) from the design longitudinal axis of the vessel.
- FIG. 15c is a plan view of a sailing vessel having two slots, each of which provide for a daggerboard to be inserted and slid downward into its active position on the appropriate tack.
- Daggerboards 157 and 156 are configured to slide within slots that are defined by parallel inner surfaces of the trunks 153 and 152 respectively, said surfaces being directed, as shown, at an angle psi ( ⁇ ) to the longitudinal axis of the vessel.
- the orientation of the centerboard at the angle ⁇ to the longitudinal axis of the vessel will increase the angle of attack of the appropriate centerboard enabling it to generate additional counter-leeward drift forces while permitting the hull of the vessel to point more directly toward the incident fluid flow or course sailed.
- trunks or slots that are adjustable, permitting the value of angle ⁇ to be increased or decreased at the discretion of the helm.
- the hydrofoils could be fixed and symmetrical front to back when viewed from the top and the daggerboard or centerboard and its holding mechanism designed such that, when the tack of the vessel is reversed, the daggerboard or centerboard can be easily be withdrawn from its active position, reversed and reinserted for the new tack. Combinations of these fixed and adjustable hydrofoil embodiments are also envisaged.
- hydrofoils utilized in the present invention could be adjustable or modifiable in any manner such as through inflation or deformation of entire surfaces or portions of each hydrofoil, through the use of materials capable of being deformed by air or hydraulic pressure, levers, cams, servomotors, or the like or by adjustable, interconnected rigid sections capable of changing the surface of the hydrofoil.
- FIG. 16a Such an embodiment is depicted in schematic diagram Figure 16a showing a sailing vessel on a starboard tack.
- Figure 16b shows a top view, taken as section B-B designated in Figure 16a.
- Figure 16c shows a side view, taken as section C-C designated in Figure 16b.
- the figures show a keel assembly comprising a frame 164 affixed to hull 5, bearings 165 and 166 affixed to the hull 5 and the tip end of frame 164 respectively, a rotatable shaft 163 mounted in said bearings 165 and 166, a deformable first surface 167 affixed to frame 164 on the starboard side of the keel assembly, a deformable second surface 168 affixed to frame 164 on the port side of the keel assembly, an upper CLD cam 161 locked to shaft 163 and a lower CH cam 162 locked to shaft 163.
- the shaft has been rotated to activate the keel assembly for a starboard tack.
- the upper CLD cam pushes against the upper portion of first surface 167 giving the upper section of surface 167 a camber.
- the lower CH cam pushes against the lower portion of second surface 168 giving the lowe ⁇ section of second surface 168 a camber.
- the upper portion of surface 167, acting as a CLD hydrofoil generates a force generally in the windward direction of the vessel while the lower section of surface 168 acts as CH hydrofoil generating a force generally in the leeward direction of the vessel.
- the shaft When the tack is reversed to a port tack, the shaft will be rotated 180 degrees to generally reverse the CLD and CH forces.
- the shapes of the cams could be such and the degree of rotation controllable to permit adjustable shaping of the deformable surfaces in order to vary their lift characteristics as desired.
- Other adjustable hydrofoil embodiments would be particularly useful in applications where hydrofoils are disposed on opposite sides of the keel, but are not slidable. In such embodiments, two or more adjustable hydrofoils would be attached to each side of the keel. By way of the mechanisms described above, these hydrofoils could lay flat against the keel until operated. When operated, the appropriate hydrofoils would expand or deform to create the counter heeling or counter-leeward drift forces as needed.
- FIG. 17 is a stem view, in a plane perpendicular to the course sailed, of a sailing vessel on a starboard tack.
- This figure depicts a keel 177 attached to the hull 5 of the vessel at its root end and having a ballast bulb 179 attached to its tip end.
- Also attached proximate to the root end of keel 177 are two inflatable CLD hydrofoils. Since the vessel is shown on a starboard tack, the starboard side CLD hydrofoil 171 is shown inflated to generate a hydrodynamic force F LD generally in the windward direction and the port side CLD hydrofoil 173 is shown deflated, as shown.
- starboard side CLD hydrofoil 171 On a port tack, starboard side CLD hydrofoil 171 would be deflated and port side CLD hydrofoil 173 would be inflated to generate a hydrodynamic force generally toward the new windward direction.
- Proximate to the tip end of keel 177 are two inflatable CH hydrofoils.
- the port side CH hydrofoil 174 When the vessel is on a starboard tack as shown, the port side CH hydrofoil 174 would be inflated to generate a hydrodynam ⁇ c force FLH generally in the leeward direction and the starboard side CH hydrofoil 172 would be deflated, as shown.
- the port side CH hydrofoil 174 would be deflated and the starboard side CH hydrofoil 172 would be inflated to generate a hydrodynamic force generally toward the new leeward direction.
- CLD counter-leeward drift
- CH counter-heeling
- FIG. 18 Another embodiment of the present invention is shown in Figure 18 wherein two rotatable hydrofoils 185 and 186 are mounted on an appendage, such as a keel 187 of a sailing vessel, one above the other on axes 181 and 182, each parallel to the chord of the appendage and each having cambered surfaces 188 and 189, respectively, on one side and lesser cambered surfaces 183 and 184, respectively, on the opposite side.
- an appendage such as a keel 187 of a sailing vessel, one above the other on axes 181 and 182, each parallel to the chord of the appendage and each having cambered surfaces 188 and 189, respectively, on one side and lesser cambered surfaces 183 and 184, respectively, on the opposite side.
- the upper member disposed toward the root of the appendage and acting as a CLD hydrofoil 185, would be rotated such that its more cambered surface 188 would be facing toward the windward side of the vessel to generate a hydrodynamic force toward windward
- the lower member disposed toward the tip end of the appendage and acting as a CH hydrofoil 186, would be rotated such that its more cambered surface 189 would be facing toward leeward to generate a hydrodynamic force toward leeward.
- the amount of inflation of these hydrofoils could be adjustable to allow control of their individual hydrodynamic shapes.
Landscapes
- Engineering & Computer Science (AREA)
- Physics & Mathematics (AREA)
- Combustion & Propulsion (AREA)
- Mechanical Engineering (AREA)
- Ocean & Marine Engineering (AREA)
- Chemical & Material Sciences (AREA)
- Fluid Mechanics (AREA)
- Radar, Positioning & Navigation (AREA)
- Remote Sensing (AREA)
- General Physics & Mathematics (AREA)
- Automation & Control Theory (AREA)
- Aviation & Aerospace Engineering (AREA)
- Wind Motors (AREA)
- Toys (AREA)
- Filling Or Discharging Of Gas Storage Vessels (AREA)
Abstract
Description
Claims
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
AU2008226586A AU2008226586A1 (en) | 2007-03-09 | 2008-03-07 | Apparatus and method to optimize sailing efficiency |
EP08731604A EP2125502A4 (en) | 2007-03-09 | 2008-03-07 | Apparatus and method to optimize sailing efficiency |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US11/716,349 US7509917B2 (en) | 2007-03-09 | 2007-03-09 | Apparatus and method to optimize sailing efficiency |
US11/716,349 | 2007-03-09 |
Publications (1)
Publication Number | Publication Date |
---|---|
WO2008112513A1 true WO2008112513A1 (en) | 2008-09-18 |
Family
ID=39740363
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
PCT/US2008/056131 WO2008112513A1 (en) | 2007-03-09 | 2008-03-07 | Apparatus and method to optimize sailing efficiency |
Country Status (4)
Country | Link |
---|---|
US (4) | US7509917B2 (en) |
EP (1) | EP2125502A4 (en) |
AU (1) | AU2008226586A1 (en) |
WO (1) | WO2008112513A1 (en) |
Families Citing this family (15)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
PL2184224T3 (en) * | 2008-11-11 | 2012-03-30 | Harken Italy Spa | Apparatus and method for automatically adjusting the sail surface exposed to the wind |
US8347802B2 (en) * | 2008-12-03 | 2013-01-08 | Fred Pereira | Watercraft with reactive suspension and an integrated braking and steering system |
US8718842B2 (en) * | 2008-12-03 | 2014-05-06 | Fred Pereira | Hydroplaning vessel with reactive suspension and integrated braking, steering system |
GB2468839A (en) * | 2009-03-13 | 2010-09-29 | Michael Dickinson | Keel with deployable hydrofoil surfaces |
US20120048165A1 (en) * | 2010-08-31 | 2012-03-01 | Terry Alan Westerman | Hydrodynamic Wings For Roll Control of Marine Vessels |
DE102011052616A1 (en) * | 2011-03-28 | 2012-10-04 | Peter Huber | Apparatus and method for defending a target object against at least one attacking missile |
US9302757B2 (en) * | 2011-09-28 | 2016-04-05 | Fred Pereira | Split outer hull hydroplaning vessel with a reactive suspension and integrated braking and steering system |
EP2960146A1 (en) * | 2014-06-27 | 2015-12-30 | Kowalewski Sp. z o. o. | Centreboard of unique design |
US10005526B2 (en) * | 2016-04-21 | 2018-06-26 | Chris White Designs LLC | Apparatus and method for powering a vessel with wind |
GB201702625D0 (en) * | 2017-02-17 | 2017-04-05 | Ben Ainslie Racing (Holdings) Ltd | Powerboat |
FR3065705B1 (en) * | 2017-04-27 | 2021-03-12 | Ixblue | MECHANICAL MOTORIZED MECHANICAL PROPULSION SURFACE SHIP WITH FUSIFORM HULL AND WEAKED Keel |
US11827312B2 (en) | 2020-11-14 | 2023-11-28 | Subseasail LLC | Method and apparatus for reducing a heeling moment of a sailing vessel |
WO2022140637A1 (en) | 2020-12-22 | 2022-06-30 | Subseasail LLC | Method, apparatus and system for recovering a sailing vessel |
US11751551B2 (en) * | 2021-04-15 | 2023-09-12 | Bradley David Cahoon | Hydrofoil fishing lure apparatus |
IT202200001541A1 (en) | 2022-01-31 | 2023-07-31 | Stefano Costantini | MODULAR SYSTEM FOR REGULATING THE WATERLINE OF BOATS |
Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO1989009159A1 (en) * | 1988-03-30 | 1989-10-05 | Angelo Scarpa | Sailing yacht |
JPH11105794A (en) * | 1997-10-03 | 1999-04-20 | Sanoyasu Hishino Meisho:Kk | Deformation reaction rudder |
KR100632970B1 (en) * | 2005-05-30 | 2006-10-11 | 한국해양연구원 | A yacht keel having foldaway wings |
Family Cites Families (42)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE376152C (en) * | 1920-06-22 | 1923-05-24 | Emil Palmblad | Sword for sailing ships |
US2858788A (en) * | 1955-05-23 | 1958-11-04 | Aero Nautical Boat Shop Inc | Water craft |
US3156209A (en) * | 1962-07-06 | 1964-11-10 | United Aircraft Corp | Autopilot for hydrofoil craft |
GB1005758A (en) * | 1963-09-26 | 1965-09-29 | Frederick Joseph Theaker | Improvements in and relating to keels or centre-boards for boats |
US3606852A (en) * | 1970-01-27 | 1971-09-21 | Thomas Cafiero | Rudder |
US3690284A (en) * | 1971-04-15 | 1972-09-12 | Stadt E G Scheepwert Nv Van De | Rudder or keel for a wind and/or power propelled vessel |
US3886884A (en) * | 1972-10-31 | 1975-06-03 | Boeing Co | Control system for hydrofoil |
US3990384A (en) * | 1975-08-08 | 1976-11-09 | Reynolds Iii Collins J | Hull with righting moment producing fins |
US4074646A (en) * | 1976-05-21 | 1978-02-21 | Jan William Dorfman | Variable foil keel and sail boat |
DE3001279A1 (en) * | 1980-01-15 | 1981-07-23 | Paul Dr. 1000 Berlin Mader | ARRANGEMENT OF A BODY WHICH SERVES AS A FIN BOARD OR SWORD ON A SAILING BOAT |
DE3031133A1 (en) * | 1980-08-18 | 1982-04-08 | Horst von 2900 Oldenburg Elm | Pivot wheel for sailing yacht - with hydraulic damping and detachable mounting for trailer mounting |
JPS5861086A (en) * | 1981-10-03 | 1983-04-11 | Hidehiko Okuma | Horizontal stabilizer to stabilize hull |
NL8200457A (en) | 1982-02-05 | 1983-09-01 | Norport Pty Ltd | SAILING YACHT. |
DE3461266D1 (en) * | 1983-08-23 | 1987-01-02 | Warwick Ian Collins | Keel structures for sailing vessels |
WO1985003237A1 (en) | 1984-01-26 | 1985-08-01 | Star Fin Pty. Limited | Surfboard and fin |
DE3713176A1 (en) | 1987-02-07 | 1988-08-18 | Erich Victora | Sailing boat with winged keel |
US4860680A (en) * | 1987-10-19 | 1989-08-29 | Faulconer H A | Sailboat with leeway reducing keel |
FR2639018A1 (en) * | 1988-11-15 | 1990-05-18 | Jardilliet Roland | Boat with a keel |
US5313905A (en) * | 1991-05-09 | 1994-05-24 | Calderon Albert A | Twin wing sailing yacht |
DE4119430A1 (en) * | 1991-06-13 | 1992-12-17 | Kunststoffspezialteile Gmbh | Heeling compensation control for watercraft high sails - consists of underwater, flow profile with proportional damping surface and steerable rudder |
DE4334496A1 (en) * | 1993-10-09 | 1995-04-13 | Triebel Georg | Laminar flow body for controlling watercraft |
US5622130A (en) * | 1995-05-22 | 1997-04-22 | Dyna-Yacht, Inc. | Heel control system for sailing yachts and sailing yacht hull |
US5533462A (en) * | 1995-09-11 | 1996-07-09 | National Research Council Of Canada | Keel arrangement for sailboat hull |
DE19613673C2 (en) | 1996-04-04 | 1998-02-26 | Norbert Zellner | Profile body for the stabilization of wind-driven water vehicles, in particular fin or keel |
DE29614257U1 (en) * | 1996-08-17 | 1996-10-10 | Stoll, Fritz, 90768 Fürth | Lateral element |
US6032603A (en) * | 1997-01-23 | 2000-03-07 | Olcott; Bernard | Method and apparatus to increase the velocity of sailing vessels |
FR2765549B1 (en) | 1997-07-01 | 1999-08-20 | Jacques Fiocca | STABILIZATION DEVICE FOR SAILING BOAT |
US6453836B1 (en) * | 1999-11-29 | 2002-09-24 | Stephen Hampton Ditmore | Sailboat keel with a rotatable secondary foil |
US6499419B1 (en) * | 2000-01-27 | 2002-12-31 | Robert W. Bussard | Hydrofoil wing system for monohull keel boat |
FR2821053A1 (en) * | 2001-02-21 | 2002-08-23 | Marc Jean Edouard Delaunay | Sailing ship pivoting keel has automatic control in one to three axes by sensors and computers set electrically driven valves to drive hydraulic actuators |
DE20109888U1 (en) * | 2001-06-15 | 2002-02-07 | Wewers, Ulrich, 58730 Fröndenberg | rotation sword |
US6796259B2 (en) * | 2001-09-07 | 2004-09-28 | Frederick E. Hood | Sailboat rotatable keel appendage |
ITSP20020003U1 (en) * | 2002-01-11 | 2002-04-11 | Roberto Sgorbini | SECTOR OF ROTATING BED BULB FOR SAILBOATS WITH DINGHY WITH FUNCTION OF CONTROL OF THE HULL STRUCTURE |
US6719079B2 (en) * | 2002-09-17 | 2004-04-13 | William Larry Jones | Ground effect vehicle using a frontal ram air stream and aerodynamic lift |
EP1464572A1 (en) * | 2003-04-04 | 2004-10-06 | Gianfranco Bianchi | Finkeel for boats, with movable lee-boards |
US6789489B1 (en) * | 2003-06-11 | 2004-09-14 | Jeffrey S. Phipps | Sailboat with gimbaled mast and keel |
US6805068B1 (en) * | 2003-08-05 | 2004-10-19 | Raimer Tossavainen | Hydrofoil system for lifting a boat partially out of water an amount sufficient to reduce drag |
WO2005061319A1 (en) * | 2003-12-23 | 2005-07-07 | Macnaghten, James | Waterborne vessel with loop keel |
US6886481B1 (en) * | 2004-03-03 | 2005-05-03 | Douglas W. Lord | Pivotable bulb mounted foil for sailboats |
FR2883254B1 (en) * | 2005-03-18 | 2007-04-27 | Yann Lafosse | SEPARABLE PENDULAR SHAFT HYDRACTIVE FOR VESSEL COMPRISING ORIENTABLE SIDE FINS. |
FR2886918B1 (en) * | 2005-06-10 | 2008-09-05 | Agence Spatiale Europeenne | MODULE AND SYSTEM FOR AUTOMATICALLY DRIVING A SAILBOAT FOR NAVIGATION IN THE PRESENCE OF WAVES. |
US10005526B2 (en) * | 2016-04-21 | 2018-06-26 | Chris White Designs LLC | Apparatus and method for powering a vessel with wind |
-
2007
- 2007-03-09 US US11/716,349 patent/US7509917B2/en not_active Expired - Fee Related
-
2008
- 2008-03-07 EP EP08731604A patent/EP2125502A4/en not_active Withdrawn
- 2008-03-07 WO PCT/US2008/056131 patent/WO2008112513A1/en active Application Filing
- 2008-03-07 AU AU2008226586A patent/AU2008226586A1/en not_active Abandoned
-
2009
- 2009-03-03 US US12/397,056 patent/US9731799B2/en not_active Expired - Fee Related
-
2017
- 2017-07-07 US US15/644,001 patent/US10597124B2/en not_active Expired - Fee Related
-
2020
- 2020-03-23 US US16/826,797 patent/US11117642B2/en active Active
Patent Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO1989009159A1 (en) * | 1988-03-30 | 1989-10-05 | Angelo Scarpa | Sailing yacht |
JPH11105794A (en) * | 1997-10-03 | 1999-04-20 | Sanoyasu Hishino Meisho:Kk | Deformation reaction rudder |
KR100632970B1 (en) * | 2005-05-30 | 2006-10-11 | 한국해양연구원 | A yacht keel having foldaway wings |
Non-Patent Citations (1)
Title |
---|
See also references of EP2125502A4 * |
Also Published As
Publication number | Publication date |
---|---|
US7509917B2 (en) | 2009-03-31 |
US9731799B2 (en) | 2017-08-15 |
US10597124B2 (en) | 2020-03-24 |
US20080216728A1 (en) | 2008-09-11 |
AU2008226586A1 (en) | 2008-09-18 |
US20200283106A1 (en) | 2020-09-10 |
US20090165692A1 (en) | 2009-07-02 |
EP2125502A4 (en) | 2013-02-20 |
US11117642B2 (en) | 2021-09-14 |
US20180178888A1 (en) | 2018-06-28 |
EP2125502A1 (en) | 2009-12-02 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
US11117642B2 (en) | Apparatus and method to optimize sailing efficiency | |
US5163377A (en) | Sailing yacht | |
US4027614A (en) | Sailboat construction | |
EP2004479B1 (en) | Hydrofoil system for mono-hull sailboats | |
US6499419B1 (en) | Hydrofoil wing system for monohull keel boat | |
US3972300A (en) | Sailing craft | |
US5309859A (en) | Hydrofoil device | |
US9032897B2 (en) | Planing hull extensions for watercraft | |
US3762353A (en) | High speed sailboat | |
US3968765A (en) | Rotatable-mounting apparatus for sails | |
US6578506B2 (en) | Aft hung hydrofoil for reduction of water resistance of partially immersed sailing vessels | |
US3789789A (en) | Hydrofoil sailing craft | |
US4615291A (en) | Hydrofoil boat | |
NO175199B (en) | ||
US4579076A (en) | Hydrofoil device stabilized by a tail unit, and marine craft equipped with this device | |
US4280428A (en) | Non-heeling sailboat | |
US5313905A (en) | Twin wing sailing yacht | |
US20050011427A1 (en) | Two degree of freedom rudder/stabilizer for waterborne vessels | |
US4945845A (en) | High-speed sailing craft | |
US6349659B1 (en) | Sailboat rotatable keel appendage | |
US20070137541A1 (en) | Twister wings sailboat | |
EP3939876B1 (en) | Wind-powered watercraft | |
GB2164296A (en) | Improved hydrofoil keel | |
US20110048306A1 (en) | Hydrofoil stabilizer of list, pitch and roll for sail vessels | |
AU2007100124A4 (en) | A Monohull Sailing Vessel Having a Lifting Hydrofoil |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
121 | Ep: the epo has been informed by wipo that ep was designated in this application |
Ref document number: 08731604 Country of ref document: EP Kind code of ref document: A1 |
|
NENP | Non-entry into the national phase |
Ref country code: DE |
|
WWE | Wipo information: entry into national phase |
Ref document number: 2008226586 Country of ref document: AU Ref document number: 579582 Country of ref document: NZ |
|
ENP | Entry into the national phase |
Ref document number: 2008226586 Country of ref document: AU Date of ref document: 20080307 Kind code of ref document: A |
|
WWE | Wipo information: entry into national phase |
Ref document number: 2008731604 Country of ref document: EP |