Double helix anti-phased archery limb

Abstract

A limb for an archery bow includes a first member in the form of a helix and a second member in the form of a helix. The bow includes a riser and spaced cams, wheels or limb tips carrying a bow string. The first and second members extend between the riser and a cam, wheel or limb tip.

Claims

1. A limb assembly for an archery bow, the limb assembly comprising a riser, an axle, a cam, a first limb member in the form of a helix, and a second limb member in the form of a helix wherein a first end of the first limb member and a first end of the second limb member are connected to one end of the riser and a second end of the first limb member and a second end of the second limb member are fixed to the axle, wherein said cam is positioned on said axle so that said cam is rotatably journaled on said axle, wherein an entirety of said first limb member and said second limb member maintains a helical rotation of 180 or more between said first ends and said second ends of said first and second limb members and wherein said first limb member and said second limb member do not contact one another.

2. The limb assembly of claim 1, wherein the first limb member is out of phase with the second limb member.

3. The limb assembly of claim 2, wherein the first limb member is out of polarity with the second limb member.

4. The limb assembly of claim 2, wherein the first limb member is in polarity with the second limb member.

5. The limb assembly of claim 1, wherein the one end of the riser has a fulcrum point.

6. The limb assembly of claim 1, wherein both the first limb member and the second limb member are made from high strength composite material.

7. A limb assembly for an archery bow, the limb assembly comprising a rigid riser, spaced axles, spaced cams, one of said spaced cams being positioned on and rotatably journaled on one of said spaced axles and the other of said spaced cams being positioned on and rotatably journaled on the other of said spaced axles, a first limb member in the form of a helix connected to one end of said riser and fixed to one of said spaced axles, a second limb member in the form of a helix connected to said one end of said riser and fixed to said one of said spaced axles, another first limb member in the form of a helix connected to another end of said riser and fixed to the other of said spaced axles, and another second limb member in the form of a helix connected to said other end of said riser and fixed to said other of said spaced axles, wherein the entirety of said first limb member is out of polarity with the entirety of said second limb member and the entirety of said another first limb member is out of polarity with the entirety of said another second limb member, and wherein the entirety of said first limb member, said second limb member, said another first limb member, and said another second limb member maintains a helical rotation of 180 or more.

8. The limb assembly of claim 7, wherein said first limb member is out of phase with said second limb member, and wherein said another first limb member is out of phase with said another second limb member.

9. The limb assembly of claim 7, wherein both said first limb member and said second limb member are made from high strength composite material, and wherein both said another first limb member and said another second limb member are also made from high strength composite material.

10. A limb assembly for an archery bow, the limb assembly having a riser, an axle, a first member in the form of a helix and a second member in the form of a helix wherein a first end of the first member and a first end of the second member are connected to one end of the riser and a second end of the first member and a second end of the second member are fixed to the axle, wherein an entirety of said first member and said second member maintains a helical rotation of 180 between said first ends and second ends of said first and second members, wherein said first member and said second member do not contact one another, and wherein said first member is connected to a left side of said one end of said riser and fixed to a right side of said axle and said second member is connected to a right side of said one end of said riser and fixed to a left side of said axle.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a rear elevational view of a bow using the double helix limb design of the present invention;

(2) FIG. 2 is a side elevational view of a bow using the double helix limb design of the present invention;

(3) FIG. 3 is a top plan view of a limb of a bow using the double helix limb design of the present invention;

(4) FIG. 4 is a side elevational view of a limb of a bow using the double helix limb design of the present invention;

(5) FIG. 5 is an example of a destructive interference pattern;

(6) FIG. 6 is a front elevational view of an alternative embodiment of a limb of a bow using the double helix limb design of the present invention;

(7) FIG. 7 is a top plan view of an alternative embodiment of a limb of a bow using the double helix limb design of the present invention; and

(8) FIG. 8 is an isometric elevational view of a bow using an alternative embodiment of the double helix limb design of the present invention.

PREFERRED EMBODIMENTS FOR CARRYING OUT THE INVENTION

(9) An archery bow made in accordance with the present invention is indicated generally by the numeral 10 and is shown in FIGS. 1-4. Bow 10 includes a first limb 12 and a second limb 14, each of which are formed of a first member 16a in the configuration of a helix and a second member 16b in the configuration of a helix. With respect to the first limb 12, the paired first member 16a and second member 16b are in-polarity with one another, but are out of phase with each other. With respect to the second limb 14, not only are the paired first member 16a and second member 16b out of phase and in-polarity with each other, but also they are considered to be out of polarity with respect to the first limb 12. In the present invention, the term in-polarity is defined as configuring the helix of the first member 16a and the helix of the second member 16b to rotate in the same direction as each other, either clockwise or counter-clockwise. The term out of polarity is defined as configuring the helix of the first member 16a in one direction, either clockwise or counterclockwise, and the helix of the second member 16b being configured in the opposite direction, either counterclockwise or clockwise. The term out of phase is defined as configuring the helix of the first member 16a and the helix of the second member 16b such that the helix of the second member starts its rotation phased by 180 degrees from the helix of the first member. Even while out of phase with each other, the helix of the first member 16a and the helix of the second member 16b continue to maintain identical directional rotation.

(10) The tip of each limb 12, 14 may carry a cam 18 or a wheel 20 (both a cam and a wheel are shown in FIG. 2 as they are virtually interchangeable with one another), which are rotatable on an axle 22. Limbs 12 and 14 are connected to a riser 26 at a fulcrum pivot point 24 and a limb anchor point (not shown). Thus, the riser 26 is located between the first limb 12 and the second limb 14. A bowstring 28 extends between the tips of each limb 12 and 14, and if the tips have a cam 18 or wheel 20, then the bowstring 28 would extend around the cam 18 or wheel 20. Although both are not shown in the drawings, each bow 10 employs both a limb anchor point, which connects the limb to the riser to prevent the rear portion of the limb from moving, and a pair of cables, which are used to compress the limbs 12 and 14 as the cam 18 and/or wheel 20, rotates. The limb anchor point is located on the limb at the end of the portion of the limb not connected by the axle 22. In one embodiment, one end of one of the cables attaches to the cam 18 and/or wheel 20 of the first limb 12, and the other end of the cable attaches to the second limb 14 and vice versa with the other cable. When the bow string 28 is drawn back, the cables are taken up on the cam 18 and/or wheel 20 as it rotates and this action pulls on the opposite limb to provide compression of the limb.

(11) In an alternative embodiment shown in FIGS. 6 through 8, a first limb 112 and a second limb 114 are configured as double helical limbs, each of which includes a pair of anti-phased helixes 116a and 116b. With respect to the first limb 112, the paired first member 116a and second member 116b are out of polarity with one another, as well as being out of phase with each other. In a traditional bow 100, the first limb 112 is used with a second limb 114 which also has a pair of anti-phased helixes, 116a and 116b. Each limb 112, 114 may carry a cam or wheel 120, which are rotatable on an axle 122. Limbs 112 and 114 are connected to a riser 126 at a fulcrum pivot point 124 and a limb anchor point (not shown). Thus, the riser 126 is located between the first limb 112 and the second limb 114. A bow string 128 extends between the tips of the limbs 112 and 114 having cams or wheels 120 of the first limb 113 and the second limb 114. Although both are not shown in the drawings, each bow 100 employs both a limb anchor point, which connects the limb to the riser to prevent the rear portion of the limb from moving, and a pair of cables, which are used to compress the limbs 112 and 114 as the wheel 120, rotates.

(12) The specified polarizations and phase shifts of the first member 16a and the second member 16b of both the first limb 12 and the second limb 14, or of the first helix 116a and the second helix 116b of both the first limb 112 and the second limb 114 is requisite for the proper function of the efficiency improvements offered by the present invention. Each individual member, 16a or 16b and 116a or 116b, is constructed from a geometric tube or rod and they may be either solid or hollow. In one embodiment, the material used to make each individual member, 16a or 16b and 116a or 116b, is selected from the group consisting of chopped or continuous strands of high strength composite material. Potentially, rather than be constructed from more basic circular tubes, each individual member, 16a or 16b and 116a or 116b, can be formed from specific geometric polygons in order to further control the propagation of mechanical resonance. In a further embodiment, this is accomplished by utilizing a round or polygonal rod or tube, which is linearly twisted, shaped or spiraled in an arc pattern so that it has the property of a curve on a plane that winds around or in and out of a fixed center point at a continuously increasing or decreasing distance from the point; that is, a spiral, or a three-dimensional curve that turns around an axis at a constant or continuously varying distance while moving parallel to the axis; that is, a helix.

(13) The helical construction of the first limb 12 or 112 and the second limb 14 or 114 is intended to create a coherent anti phased relationship between each limb and each pair of limbs so that the first and second limb, create destructive interference patterns when they vibrate as a whole. As the bow 10 or 100 is drawn, the elastic energy in the first limb 12 or 112 and the second limb 14 or 114 stacks until the archer reaches full draw. At this point the arrow is released and the stored elastic potential in the first limb 12 or 112 and the second limb 14 or 114 transfers energy to the bow string 28 or 128. As the arrow is released at the end of the power stroke, the system is seeking equilibrium. This is the moment where the audible transient occurs along with the mechanical shockwave of bows found in the prior art. Vibration and sound are physical and audible representations of potential energy being lost, bows not using the spiraled or helical construction of the present invention will be less efficient due to the linear way in which they store and release elastic potential energy and the way in which they vibrate constructively when they reach equilibrium.

(14) The spiraled or helical construction of the present invention, on the other hand, mitigates such inefficiencies by providing phase shifted or pole shifted spirals or helixes. Since each member 16a or 116a is shifted from its paired member 16b and 116b, meaning that the second helix is 180 degrees out of phase or out of polarity from the first helix, the resonant interference patterns of each helix in a limb as it propagates waves will be destructive in nature. This causes the vibration of the first limb 12 or 112 to cancel the vibrations of the second limb 14 or 114 on a mechanical level. This destructive interference pattern is visualized in FIG. 5. Destructive interference occurs when the interference of two waves of equal frequency and opposite phase or polarity, result in their cancellation where the negative displacement of one always coincides with the positive displacement of the other. The principle of superposition of waves states that when two or more propagating waves of same type are incident on the same point, the total displacement at that point is equal to the sum of the displacements of the individual waves. If a crest of a wave meets a crest of another wave of the same frequency at the same point, then the magnitude of the displacement is the sum of the individual magnitudesthis is constructive interference. If a crest of one wave meets a trough of another wave then the magnitude of the displacements is equal to the difference in the individual magnitudesthis is known as destructive interference.

(15) Effectively, by being out of phase or out of polarity the acoustical energy from one helix phase cancels out the acoustical energy from the other helix, greatly reducing resonance and allowing for the increase in stored potential energy being transferred to the arrow. Essentially, the design of the present invention capitalizes upon the properties of wave mechanics to greatly reduce fluctuations in the limbs of a bow during the power stroke, resulting in an increase of potential energy and subsequently a higher efficiency. This can be applied to various bow and crossbow designs to offer an improvement over current bow and crossbow limb designs. As the first limb 12 or 112 and second limb 14 or 114 resonate, they propagate waves that create destructive interference patterns. These interference patterns naturally cancel mechanical vibration and sound.

(16) In light of the foregoing, it should be appreciated that the present invention significantly advances the art by providing a double helix limb design for bows and crossbows that is structurally and functionally improved in a number of ways. While particular embodiments of the invention have been disclosed in detail herein, it should be appreciated that the invention is not limited thereto or thereby inasmuch as variations on the invention herein will be readily appreciated by those of ordinary skill in the art. The scope of the invention shall be appreciated from the claims that follow.