Serrated keel

Abstract

A boat hull includes a serrated keel which is utilized to dissipate local energy and increase efficiency by reducing drag. In one embodiment, the boat hull preferably includes serrations which are teardrop shaped with a ratio of 3 to 1 in that the length of the teardrop cutout is 3 times the depth.

Claims

1. A boat hull including a serrated keel, wherein the serrated keel comprises at least two serrations, said serrations having a depth which is less than a length of the serration, said serrations being generally V-shaped when viewed from below the hull, wherein each serration has a starboard portion and a port portion, a fore end and an aft end, said starboard and port portions meeting at a centerline of the hull and each extending from the centerline of the hull rearwardly and away from the centerline of the hull.

2. The hull of claim 1, wherein the serrations are limited to the aft parts of the keel.

3. The hull of claim 1, wherein the serrations are limited to the forward parts of the keel.

4. The hull of claim 1 wherein the hull further comprises lifting strakes.

5. The hull of claim 4 wherein the serrations comprise aft serrations and the aft serrations do not cross the lifting strakes.

6. The hull of claim 4 wherein the serrations comprise forward serrations and the forward serrations cross the lifting strakes.

7. The hull of claim 4, wherein the serrations have a depth which is one third their length.

8. The hull of claim 1 wherein the serrations are made using plugs.

9. The hull of claim 1 wherein the serrations are teardrop shaped and wherein the hull has a bottom which is V shaped, wherein the serration has an angle which decreases to match the V shaped bottom of the hull and a teardrop shape which has a diameter which is extended to match said decrease of the angle.

10. The hull of claim 1, wherein the depth is one third of the length.

11. A boat hull comprising a serrated keel, at least two lifting strakes, a starboard chine, a port chine, and at least one hull step, wherein the serrated keel comprises at least two serrations, said serrations having a depth which is less than a length of the serration, each serration comprising two teardrop shaped cutouts which meet at a centerline of the hull, each teardrop cutout departing from the centerline of the hull at an oblique angle towards an aft portion of the hull; wherein the serrations comprise aft hull serrations; wherein said aft hull serrations do not cross the at least two lifting strakes; and wherein the at least one hull step crosses the at least two lifting strakes and extends from the starboard chine to the port chine.

12. The boat hull of claim 11 wherein the serrations comprise forward hull serrations and wherein the forward hull serrations cross the lifting strakes.

13. The boat hull of claim 12 wherein the forward hull serrations decrease in size from aft to forward as the bow gets narrower.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

(1) For a further understanding of the nature, objects, and advantages of the present invention, reference should be had to the following detailed description, read in conjunction with the following drawings, wherein like reference numerals denote like elements and wherein:

(2) FIG. 1 is a bottom view of a preferred embodiment of the apparatus of the present invention;

(3) FIG. 2 is front perspective view of a preferred embodiment of the apparatus of the present invention;

(4) FIG. 3 is a side perspective view of a preferred embodiment of the apparatus of the present invention;

(5) FIG. 4 is a side view of a preferred embodiment of the apparatus of the present invention displaying the low-pressure area, direction of fluid flow, and direction of travel;

(6) FIG. 5 is a bottom view of a preferred embodiment of the apparatus of the present invention;

(7) FIG. 6 is partial side view of a preferred embodiment of the apparatus of the present invention displaying oblique angle departures on rear half of hull;

(8) FIG. 7 is a close-up detail of the tear drop cutout of a preferred embodiment of the apparatus of the present invention;

(9) FIG. 8 is a partial side view diagram of a preferred embodiment of the apparatus of the present invention displaying the low-pressure area, direction of fluid flow, and direction of travel;

(10) FIG. 9 is a partial view of the hull bottom of a preferred embodiment of the apparatus of the present invention;

(11) FIG. 10 is partial side view of a preferred embodiment of the apparatus of the present invention displaying a close-up of a serrated hull located in rear of hull;

(12) FIGS. 11-20 show plugs to be used in molds to produce hulls with serrations;

(13) FIGS. 21-22 show partial views of the plugs to be used in molds to produce hulls with serrations;

(14) FIGS. 23-25 show a boat hull with the serrations produced by the plugs of FIGS. 11-22; and

(15) FIGS. 26 and 27 are views of a plug showing relationships of sizes of different parts of the plug.

DETAILED DESCRIPTION OF THE INVENTION

(16) Description of the Invention: A serrated keel offers cushioning or dampening from impacts and includes channels to disperse energy outwards and rearwards along the hull

(17) FIGS. 1-4 of my provisional patent application show overall hull bottom with proposed changes to the normally flat or linear surface of the keel.

(18) The present invention can include teardrop hull cutouts. The semi-teardrop shapes induce a low-pressure area behind the initial cutouts when the hull is at speed. This low-pressure area causes interruption to the buildup of parasitic drag along the originally flat surface of the hull bottom. The teardrop hull cutouts also allow increased surface area for the impact force of the hull on the surface of the water to be better dissipated and directed or channeled towards the rear and side of the hull. In this manner the cutouts act as accumulator pockets or dampeners to the hull when the hull impacts the surface of the water while at speed. This function will cushion and smooth the ride and also act to increase efficiency.

(19) In various embodiments, some or all of the teardrop cutouts depart from the centerline in oblique angles. The departure angles and extensions of the teardrop cutouts function as fluid channels to direct water under compression forces away from the impact. The oblique angles towards the rear of the hull direct fluids away from the centerline and allow the compressive forces to dissipate outwards and rearwards. These extensions of the teardrop shapes allow a “follow through” or conduit for the energy concentrated at the center of the hull during impacts to be neatly and evenly distributed outwards and away from the hull. The extensions also serve to break up the surface area which further lends to reduced parasitic drag.

(20) As shown in FIG. 1, aft hull serrations 20-26 may be of similar size as the width of the hull panels are similar through the length. As shown in FIG. 1, the forward hull serrations may get smaller from aft to forward as the bow gets narrower.

(21) As shown in FIG. 1, for example, the serrated keel comprises at least two serrations 20, 21, said serrations being generally V-shaped when viewed from below the hull, wherein each serration has a starboard portion and a port portion, a fore end and an aft end, said starboard and port portions meeting at the centerline of the hull and each extending from the centerline of the hull rearwardly and away from the centerline of the hull.

(22) Additional support and further expansion or definition in detail of the concepts related to the present invention is set forth below:

(23) 1. Pad Area

(24) The area in which the hull maintains lift and stability while cruising may have serrations. Furthermore, the bow area which takes the brunt of the impact may have more aggressive serrations including the panel area pockets in which to provide shock absorption when impacting waves.

(25) 2. Interface Between Air and Water

(26) When discussing movement of a vehicle through air, many forces and parameters are applied. Examples are thrust, drag, lift, weight, speed and pressure to name a few. When discussing high speed or supersonic flight, compressibility, angles of shockwaves and the Area Rule may be added.

(27) When discussing movement of a vehicle through water there are similar parameters that are applied, static pressure at depth, dynamic pressure before and after an object passes, cavitation, buoyancy, etc.

(28) When a conversation occurs that must take these two mediums into account at the same time such as a planing boat hull, the interface of this vehicle between the air and the water must include aspects of both mediums.

(29) A very similar concept to this conversation would be how a car tire interacts with the road. Tires are designed to be minimally interfacing with the road to reduce friction, but also provide traction at the same time. This interface is a balance between how much area is allowed to be in contact with the road surface (the less the better for friction) and how much traction can be gained by this area (the more the better). This can be further discussed when the tire is subjected to a wet road surface as the compressibility of the tire must be taken into account as the water will not compress and thus needs to be absorbed (tire will take a small amount of deflection), must be displaced (tread patterns and channels in the tire will allow and direct the water away from the impact area), or lastly the water impact area will be too great for either of the above and the result will be hydroplaning, which is almost exactly what happens to a boat hull at speed.

(30) Therefor the concept of the serrated keel takes into account the intent to redefine or minimize the friction of the boat hull in relation to the water surface while at speed (by allowing air to be introduced at the interface between the hull and the water), while also providing channels for either the water to escape or be dampened (accumulator effect) during impacts using the same structures.

(31) The Rule of 3 is preferably to be applied to the teardrop cutouts. This rule would be applied to the frequency of cutouts from a depth and a length perspective—the teardrop should be one third the depth as the length. This would allow a symmetry to be kept along the hull even if the size of the serrations is altered.

(32) The acute angles of the wing shape when viewed from below are preferably to be defined based on shockwave angles of supersonic aircraft. This would seem logical as this would be a natural effect of an object moving at speed with compressibility of a fluid applied to the interface of vehicle and fluid.

(33) 3. Building the Design or Implementing the Design into an Existing Hull Mold.

(34) One of the benefits of the design of the apparatus of the present invention is that the serration shape could be a “plug” or a male part applied to the female hull mold as this shape could be molded into the final part. The reverse aspect of this would be that the design which adds the shape to the hull would actually be removing material from the flat hull surface rather than adding a protruding shape to the hull surface. This would be of huge importance to any hull manufacturer as the semi-teardrop shape parts can be simply laid out onto any existing hull mold (and be similarly removed if required). This would preferably require that the shapes be formed out of hard plastic or other easily worked or molded material and simply positioned on the female hull mold. When utilizing the traditional method of hand laying out the fiberglass material, the serrated shapes will preferably be included in the hull design. In other words, any existing hull mold could be modified by adding the serrated shapes in the proper areas to generate the intended design.

(35) In the present invention, a male plug would preferably only be used when molding a hull using a female mold. When building a hull out of wood or metal, the wing shape would preferably be installed as part of the hull.

(36) This design will also serve to strengthen the area between bulkheads and stringers. The “panel” areas would be the flat areas of the hull that are formed when the longitudinal stringers and transverse bulkheads are installed during the building process. The rectangular flat areas are subject to flexural stresses as the hull impacts the water surface during operation. These rectangular areas would be strengthened by adding the serrated shapes to the hull bottom which includes the oblique angles. The added structural length and thickness of each serration half would be advantageous to the overall hull design similar to the way convoluted surfaces are typically stronger than flat surfaces when flexing.

(37) In one embodiment, the height of the teardrop cutout is preferably 1 radius.

(38) In one embodiment, as shown in FIG. 26, the center length of the teardrop cutout will preferably be 3 diameters, the longest angle will preferably be 12 diameters. However, the center length can be for example 2-5 diameters and the longest angle can be for example 9-15 diameters.

(39) In one embodiment, as shown in FIG. 27, there is preferably a 20 degree rise from horizontal (though it could be for example a 5-75 degree rise). In this position the height of the wing plug will be distended from the original or flat rendering. When viewed from a flat position with no horizontal rise, the shape will preferably be a proper 3:1 ratio with a hemispherical starting point (first diameter) (though it could be for example a 2-5:1 ratio).

(40) As the angle of the wing increases away from horizontal, the height of the shape will preferably also increase as the two halves merge together along the center length. The center length or the wing lengths will preferably not change, only the height of the original radius and the corresponding curve along the entire part will change.

(41) In various embodiments, the “plugs” would be used with conventional fiber reinforced plastic (FRP) construction, such as typical “fiberglass” layup methods. If the hull were made of metal, each half of the wing shape would need to be shaped using metal forming techniques such as rolling or hydraulic die stamping.

(42) In certain embodiments of the present invention, the aft serrations will not cross the lifting strakes.

(43) In certain embodiments of the present invention, the forward serrations may cross the lifting strakes.

(44) In preferred embodiments of the present invention, as the wing plug shape angle decreases to match the V shaped bottom of the hull, the diameter of the teardrop shape will be extended to match. In these embodiments, the wing plug will have a higher angle of attack near the bow where the hull gets sharper.

(45) A bottom view of a preferred embodiment of the apparatus of the present invention is shown in FIG. 5. As seen in FIG. 5, the boat hull comprises a centerline 134, stepped hull 133, and oblique angle departures on rear half of hull 101. The direction of travel is shown by arrow 102.

(46) FIG. 6 is partial side view of a preferred embodiment of the apparatus of the present invention displaying oblique angle departures 101 on rear half of hull. The direction of travel is shown by arrow 102.

(47) FIG. 7 is a close-up detail of the tear drop cutout 103 of a preferred embodiment of the apparatus of the present invention.

(48) FIG. 8 is a partial side view diagram of a preferred embodiment of the apparatus of the present invention displaying the low-pressure area 106, direction of fluid flow 104, and direction of travel 102. The oblique angle departure 101 from centerline cutout extends from the centerline of the hull 105.

(49) FIG. 9 is a partial view of the hull 105 bottom of a preferred embodiment of the apparatus of the present invention. As seen in FIG. 9, the departures 107 can be at a shallower angle than hull 105 bottom so that they only extend half the distance to outside of the hull.

(50) FIG. 10 is partial side view of a preferred embodiment of the apparatus of the present invention displaying a close-up of a serrated hull 105 located in rear of hull. As seen in FIG. 10, each serration provides a low pressure area 106. Fluid flow is designated by arrow 104 and direction of travel by arrow 102 in FIG. 10.

(51) FIGS. 11-20 show plugs to be used in molds to produce hulls with serrations. Each plug 12 comprises a base point 14 and two apexes 13.

(52) FIGS. 21-22 show partial views of the plugs to be used in molds to produce hulls with serrations. FIG. 21 shows the flat surface 16 of wing plug 12 (attaches to boat hull mold) and FIG. 22 shows curved portion 17 of wing plug 12.

(53) FIGS. 23-25 show a boat hull 10 with the serrations produced by the plugs of FIGS. 11-22. As seen in FIGS. 23 and 24, there can be smaller wing plugs 15 used on the aft portion of the hull and larger wing plugs 12 used on the forward portion of the hull.

(54) FIGS. 26 and 27 are views of a plug showing relationships of sizes of different parts of the plug. As seen in FIG. 26, in an embodiment the center length of the teardrop cutout 109 will preferably be 3 diameters and the longest angle of teardrop cutout 108 will preferably be 12 diameters. As seen in FIG. 27, in one embodiment, there is preferably a 20 degree rise from horizontal. In this position the height of the wing plug will be distended from the original or flat rendering. When viewed from a flat position with no horizontal rise, the shape will preferably be a proper 3:1 ratio with a hemispherical starting point (first diameter).

PARTS LIST

(55) The following is a list of parts and materials suitable for use in the present invention:

(56) Parts Number Description

(57) 10 boat hull apparatus 11 boat hull mold 12 larger wing plug 13 apex of wing plug 12 14 base point of wing plug 12 15 smaller wing plug (preferably same proportions as wing plug 12, just smaller) 16 flat surface of wing plug 12 (attaches to boat hull mold) 17 curved portion of wing plug 12 20 serration produced by smaller wing plug on aft hull section 21 serration produced by smaller wing plug on aft hull section 22 serration produced by smaller wing plug on aft hull section 23 serration produced by smaller wing plug on aft hull section 24 serration produced by smaller wing plug on aft hull section 25 serration produced by smaller wing plug on aft hull section 26 serration produced by smaller wing plug on aft hull section 27 serration produced by larger wing plug on forward hull section 28 serration produced by larger wing plug on forward hull section 29 serration produced by larger wing plug on forward hull section 30 serration produced by larger wing plug on forward hull section 31 serration produced by larger wing plug on forward hull section 32 aft hull step 33 forward hull step 34 centerline or keel of boat hull 40 transom 41 starboard stern section of hull 42 starboard bow section of hull 43 port stern section of hull 44 port bow section of hull 50 stern section of hull flat panel area between lifting strakes 60 starboard chine 61 starboard outer lifting strake 62 starboard inner lifting strake 101 oblique angle departure 102 direction of travel 103 tear drop cutout 104 fluid flow direction 105 hull 106 low pressure area 107 departures 108 longest angle of teardrop cutout 109 center length of teardrop cutout 133 forward hull step 134 centerline or keel of boat hull

(58) All measurements disclosed herein are at standard temperature and pressure, at sea level on Earth, unless indicated otherwise. All materials used or intended to be used in a human being are biocompatible, unless indicated otherwise.

(59) The foregoing embodiments are presented by way of example only; the scope of the present invention is to be limited only by the following claims.