Patent Grant
11274899
The present disclosure generally relates to archery bows and limbs for archery bows.
Bows and crossbows have flexible portions called limbs that resiliently store the energy or work done by the archer when the bowstring is drawn. When the bowstring is released, the energy stored in the resilient limbs is released to the bowstring, which launches the projectile with the force generated.
The limb may be referred to as a beam member which generally stores strain energy through controlled displacement of the beam across its length. Many bows, especially compound bows, use limbs that are detachable or otherwise made separate from the bow's handle and riser. The ends of the riser usually have a limb pocket in which the limb is inserted and attached to the riser. Thus, the bow's limbs may be removable or replaceable, such as when a limb is damaged or when the archer wishes to change the stiffness and weight of the bow.
Traditionally, a limb has often been secured to the pocket by a pin or bolt that extends through the limb. This pin or bolt prevents sliding between the limb and pocket. For example, a bolt or pin may extend through an aperture that is positioned transversely through the limb. Other designs include a limb that has lateral notches that are configured to mate with protrusions on an inner surface of the pocket, thereby preventing axial withdrawal of the limb from the pocket due to forces pulling the limb distally as the bow is drawn.
As the bowstring is drawn and the limbs flex, several issues may arise with these traditional securement methods. For example, the bolt, pin, or notches hinder or disable flex in the region of the limb between the proximal end (i.e., the butt end of limb within the end pocket) and the intermediate rocker support (which is positioned between the proximal and distal ends). The limbs are therefore more stiff in that region and effectively have diminished ability to store energy there. Thus, the working length of limb is reduced and stress levels in the rest of the limb may be increased.
A pin or bolt may also mechanically limit translation of the end of the limb and thereby increase loads in the beam that are not efficient for energy storage and recovery. The aperture for a bolt or pin may undesirably concentrate stresses around that area of the limb.
In most cases, the limb is also prevented from rotating about its neutral axis. The principles of beam theory show that internal beam reactions are generally increased when beam rotation is limited by the beam's support methods. The result is a generally higher internal shear force or a higher internal bending moment in a limb, so limb designs are limited due to having to account for increased stress and strain caused by the center of rotation being spaced from the neutral axis. Limbs also tend to “walk” out of a pocket over repeated cycles absent some type of a frictional engagement between the limb and the pocket. This frictional engagement often causes a loss of energy and performance.
There is therefore a need for improvements in limbs and limb securement systems for archery bows.
One aspect of the present disclosure relates to an archery bow with abutting limb support. The bow may comprise a riser that has a handle portion and first and second riser portions. The first riser portion extends from the handle portion and has a plurality of limb contact surfaces that are spaced apart. The second riser portion extends from the handle portion as well. The bow also comprises a first limb having a proximal end portion that has a plurality of external surfaces. The plurality of external surfaces abut and are articulable relative to the plurality of limb contact surfaces, and the first limb is free-floating against the first riser portion. A second limb is connected to the second riser portion, and a bowstring is connected to the archery bow, wherein tension in the bowstring is transferred to the first and second limbs.
In this bow, the plurality of limb contact surfaces may comprise a proximal limb pocket, with the proximal limb pocket having a proximally-facing surface configured to contact a distally-facing surface of the proximal end portion of the limb. The plurality of external surfaces of the first limb may include at least one bulbous end surface positioned at the proximal end portion of the first limb. The first limb may have a thickness, and the plurality of external surfaces of the first limb may include a proximal end surface having a radius of curvature greater than half of the thickness. The first limb may be seated in the limb pocket by a limb reaction force resulting from the tension in the bowstring. The tension may be transferred to a distal end of the first limb.
In some embodiments, the plurality of external surfaces that abut the plurality of limb contact surfaces may protrude from the first limb. The plurality of limb contact surfaces may be recessed. The plurality of external surfaces may be slidable against the plurality of limb contact surfaces. The plurality of limb contact surfaces may comprise a proximal limb pocket and an intermediate limb pocket, wherein the proximal limb pocket may be positioned to contact a tension surface of the first limb at a proximal end of the first limb, and the intermediate limb pocket may be positioned to contact a compression surface of the first limb at an intermediate portion of the first limb.
The intermediate portion of the first limb that contacts a portion of the plurality of limb contact surfaces may translate proximally upon applying tension to the bowstring, and the proximal end of the first limb may not translate upon applying tension to the bowstring. A surface area of contact between the plurality of external surfaces of the first limb and the plurality of limb contact surfaces of the first riser portion may remain constant throughout a draw cycle of the bowstring. Tension applied by the bowstring may increase engagement forces between the plurality of external surfaces of the first limb and the plurality of limb contact surfaces of the first riser portion.
In another aspect of the disclosure, an archery bow is disclosed that may comprise a handle portion and a first riser portion extending from the handle portion, with the first riser portion having a limb pocket. The bow may also have a first limb comprising a neutral axis positioned within the first limb and a proximal end portion that is rotatable about an axis of rotation. The axis of rotation may intersect the neutral axis, and the first limb may be free-floating against the first riser portion. The bow may also have a second riser portion extending from the handle portion and a second limb connected to the second riser portion. A bowstring may be connected to the archery bow, wherein tension in the bowstring is transferred to the first and second limbs.
This bow may have a limb pocket that has a rounded limb contact surface and the proximal end portion of the first limb may have a rounded pocket contact surface. The rounded limb contact surface may be slidable against the rounded pocket contact surface. A portion of the limb contact surface may contact a distal side of the rounded pocket contact surface of the first limb. In some arrangements, the first limb further comprises an intermediate portion, the first riser portion further comprises an intermediate limb pocket, and the intermediate portion of the first limb abuts the intermediate limb pocket. A distance between the proximal end portion and the intermediate portion of the first limb may decrease as the first limb bends.
A dampening member may be positioned between the proximal end portion and the intermediate portion of the first limb. The tension in the bowstring transferred to the first limb may apply a force proximally driving the proximal end portion along the neutral axis.
Another aspect of the disclosure relates to an archery bow with abutting limb support. The bow may comprise a handle portion and a riser extending from the handle portion, with the riser having a proximal limb pocket and an intermediate limb pocket. A first limb may abut and may be slidable against the proximal and intermediate limb pockets. The first limb may have a limb length, wherein a distance between the proximal limb pocket and the intermediate limb pocket is less than or equal to one third of the limb length. The bow may further include a second limb connected to the riser and may further include a bowstring, wherein tension in the bowstring is transferred to the first and second limbs.
In some configurations, the first limb is free-floating against the proximal and intermediate limb pockets. The first limb may be arranged to bend along the distance between the proximal limb pocket and the intermediate limb pocket. Additionally, a portion of the first limb abutting the intermediate limb pocket may slide proximally when tension in the bowstring is transferred to the first limb.
Yet another aspect of the disclosure relates to an archery bow with abutting limb support that comprises a riser with a handle portion, a first riser portion extending from the handle portion which has a proximal limb pocket, and a second riser portion extending from the handle portion. A first limb that has a proximal end portion may also be included, wherein the proximal end portion has an external surface that abuts and is articulable relative to the proximal limb pocket such that the first limb is free-floating against the proximal limb pocket. A second limb connected to the second riser portion may also be included, and a bowstring may be connected to the archery bow, wherein tension in the bowstring is transferred to the first and second limbs.
In some embodiments, the first riser portion comprises an intermediate limb pocket and the first limb comprises an intermediate portion, with the intermediate portion of the first limb abutting the intermediate limb pocket. The intermediate portion may be free-floating against the intermediate limb pocket. The external surface of the proximal end portion of the first limb may be bulbous.
Still another aspect of the disclosure is a dampened limb support system for an archery bow. The support system may include a riser having a proximal limb support and an intermediate limb support. A limb may be supported by the proximal and intermediate limb supports and may have a span extending between the proximal and intermediate limb supports. A dampening member may contact the span of the limb between the proximal and intermediate limb supports, and the dampening member may be configured to dampen movement of the span of the limb.
The dampening member may be attached to the riser. Tension applied to the limb by a bowstring may decrease engagement between the dampening member and the limb. In some arrangements, a plurality of dampening members are axially spaced along the limb. The dampening member may be positioned on a compression side of the limb and/or may be cantilevered. The dampening members may extend laterally away from the riser.
Yet another aspect of the disclosure is an archery bow having angled limb support. The bow may comprise a riser that has a handle portion, a first riser portion extending from the handle portion, with the first riser portion having a limb contact surface that is tilted at an angle away from the handle portion and laterally away from a centerline of the first riser portion, and a second riser portion extending from the handle portion. A first limb may have an abutting surface contacting the limb contact surface and tilting at the angle of the limb contact surface. A second limb may be connected to the second riser portion, and a bowstring may be connected to the archery bow, wherein tension in the bowstring is transferred to the first and second limbs.
The abutting surface of the first limb may be on an intermediate portion of the first limb, and the limb contact surface of the first riser portion may be on an intermediate support of the first riser portion. The abutting surface and the limb contact surface may be free-floating against each other. The first limb may further comprise a tension surface, wherein the abutting surface of the first limb is positioned non-parallel to the tension surface.
The above summary of the present invention is not intended to describe each embodiment or every implementation of the present invention. The Figures and the detailed description that follow more particularly exemplify one or more preferred embodiments.
The accompanying drawings and figures illustrate a number of exemplary embodiments and are part of the specification. Together with the present description, these drawings demonstrate and explain various principles of this disclosure. A further understanding of the nature and advantages of the present invention may be realized by reference to the following drawings. In the appended figures, similar components or features may have the same reference label.
While the embodiments described herein are susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and will be described in detail herein. However, the exemplary embodiments described herein are not intended to be limited to the particular forms disclosed. Rather, the instant disclosure covers all modifications, equivalents, and alternatives falling within the scope of the appended claims.
Aspects of the present disclosure relate to a limb and limb pocket system for an archery bow that may reduce internal stresses in the limb, may improve energy storage ability of portions of the limb that are conventionally underutilized, and may help to keep the limb engaged with the pocket by reducing frictional losses. In one embodiment, an archery bow is provided with a limb pocket in its riser that receives the proximal end portion of at least one limb. The limb may be seated in and also articulable or rotatable relative to the limb pocket. The proximal end portion may have a plurality of external surfaces that contact a plurality of limb contact surfaces on the riser (e.g., within the proximal limb pocket and at an intermediate rocker support/pocket). The limb may be free-floating within the limb pocket and against the first riser.
As used herein, a “free-floating” limb is defined as a limb held to the riser only through tension applied to the limb and resultant forces generated by contact between the external surfaces of the limb and outer surfaces of the riser. In some exemplary embodiments, that tension may be applied to the limb via a wheel, cam, and/or bowstring. The tension may cause the limb to abut surfaces of the riser in such a manner that the abutting surfaces keep the limb secured to the riser without any fasteners, pins, bolts, clamps, or other friction-applying devices that extend through or clamp down the limb. Accordingly, in some cases, when tension is completely released on a free-floating limb, the limb may fall out of limb pockets and may thereby be loosed from the riser without having to remove a separate securing mechanism and without having to remove a pin from a receiving hole. Additionally, a free-floating limb may be able to bend throughout its length and its ends may be able to rotate or slide relative to the riser since there is no fastener or clamping device preventing its movement, just contact between the outer surfaces of the riser and limb. In this way, the limb “floats” and slides while abutting the surfaces of the riser.
The limb and pocket system may, however, comprise surfaces configured to help prevent the limb from slipping out of its seating in the pocket, such as, for example, an at least partially proximally-facing surface that is positioned distal to an at least partially distally-facing surface of the limb. Thus, the surfaces on the riser that contact the limb may provide some mechanical interference to distal withdrawal of the limb from the limb pocket by contact with a portion of the plurality of external surfaces of the proximal end portion. The mechanical interference, however, may still allow the limb to rotate and bend while only sliding in or abutting the pocket. The holding surfaces may also be configured to allow the limb to slip out of contact with them once tension is released on the limb. Thus, they may not lock the limb in place relative to the riser when there is no tension in the limb, or only a light amount of pressure may be needed to remove the limb after tension is released.
Another aspect of limb and pocket systems of the present disclosure relates to the contact surface area between the limb and the surfaces of the riser that are contacted by the limb. The sliding contact between the limb and the riser may permit the contact surface area to remain at least constant throughout a draw cycle of the bowstring. In conventional limb systems, the limb may not slide relative to the riser or, in some cases, the sliding surfaces in contact with the riser may change as the limb bends, even if the limb is held in place by a pin or bolt. A constant, or potentially increasing, contact surface area throughout the loading of the limb may reduce shear and stress concentration in the limb and may help keep retention surfaces in contact throughout the draw cycle.
Another feature of a limb retention system may include a center of rotation at the proximal end of the limb that is on or near a neutral axis of the limb. The neutral axis may longitudinally extend through the thickness of the limb (e.g., between the tension side and compression side of the limb). Some conventional limbs use a pivot center that is outside the limb's thickness, such as on a protrusion extending from the tension surface of the limb. The amount of rotation possible in those limbs is limited by the stiffness or moment of inertia of the limb due to the pivot being away from the neutral axis of the limb. This property has been established, for example, using the well-known parallel axis theorem, which shows that stiffness increases as a function of the square of distance away from the neutral bending axis. When the pivot center is significantly offset from the neutral axis, the limb may axially translate away from the pivot center as it bends. This increases stress at the pivot center and at the limb's supports (e.g., at an intermediate limb support). Accordingly, the present disclosure shows limbs having proximal pivot centers that lie between tension and compression sides of the limbs and/or near the limbs' neutral axes to minimize these effects and to allow the limbs to have more evenly distributed stresses, more consistent stiffness, and less axial translation. Thus, these limbs may have improved reliability and reduced materials specifications.
The present description provides examples, and is not limiting of the scope, applicability, or configuration set forth in the claims. Thus, it will be understood that changes may be made in the function and arrangement of elements discussed without departing from the spirit and scope of the disclosure, and various embodiments may omit, substitute, or add other procedures or components as appropriate. For instance, methods described may be performed in an order different from that described, and various steps may be added, omitted, or combined. Also, features described with respect to certain embodiments may be combined in other embodiments.
Referring now to the figures in detail,
The limbs 104, 106 each have a proximal end 212 (i.e., a butt end) positioned adjacent to the proximal limb pocket 118 and a distal end 215 (i.e., an outer end) extending away from the proximal limb pocket 118 and connected to an axle 126 on which wheels 128 or cams turn. A bowstring 130 extends between the wheels 128 and provides tension to the wheels 128, and that tension is in turn applied to the limbs 104, 106. In other embodiments, such as in embodiments where the bow is a traditional bow, recurve bow, or crossbow, the bowstring may be directly connected to the distal ends of the limbs 104, 106 and therefore may transfer tension directly to the limbs.
Drawing the bowstring 130 therefore flexes and bends the distal ends 215 of the limbs 104, 106 inward (i.e., toward each other). The energy thereby stored by the limbs 104, 106 is released when the bowstring 130 is released, and the spring of the limbs 104, 106 forcefully straightens them and drives a projectile connected to the bowstring 130 forward at high acceleration and velocity away from the archer and toward a target.
While in this example embodiment a compound archery bow is shown and described, it will be understood that the principles and teachings of the present disclosure are adaptable to many other areas, including, without limitation, crossbows, traditional bows, recurve bows, and other related products. Additionally, while the bow 100 in this example has upper and lower limbs 104, 106 that both have features of the present disclosure, it will be appreciated that in some embodiments only some of the limbs 104, 106 may have the features disclosed herein, with the remaining limbs having conventional features. Thus, the present disclosure is presented to provide examples of ways that principles and features of the limbs of the present disclosure may be implemented without limiting the disclosure to the exact configuration shown.
In some embodiments, the riser 102 may be a single piece having a handle portion 107 and upper and lower riser portions 114, 116, as shown in
The pocket guide 121 may also comprise a plurality of apertures 206 that may be used to hold dampening members 208. See
The proximal limb pockets 118 are positioned forward of the intermediate limb pockets 120 on the riser 102 along proximal direction P. See
As shown in
When the proximal radius of curvature RP is greater than one-half of the thickness T of the limb 104, there is broad surface area at the outer pivoting surface 213 for load support. Additionally, pressure may be applied on both sides of the quadrant around the center of rotation (i.e., center of curvature CP) during draw and letdown. This may encourage proper rotation of the limb 104. Compression between the curved inner surface 210 of the proximal limb pocket 118 and the outer pivoting surface 213 of the proximal end portion 212 of the limb 104 may help keep the limb 104 from slipping or withdrawing from the proximal limb pocket 118.
The center of curvature of the curved surface 214 of intermediate limb pocket 120 and the outer pivoting surface 218 may lie outside the thickness of the limb 104. The outer pivoting surface 218 may extend and protrude from a compression surface 211 of the limb 104.
In an example embodiment, as the limb 104 bends, the proximal end portion 212 contacts the proximal limb pocket 118, the intermediate portion 216 contacts the intermediate limb pocket 120, and the proximal end portion 212 and intermediate portion 216 both start to rotate around their respective centers of rotation CP, CI. See
By contrast, bending conventional limbs generates forces that translate their proximal ends distally. One reason that a stress-concentrating pin or axle must be positioned through the limbs is to prevent them from slipping distally and disconnecting from the riser surface. The present limb 104, however, increases engagement with the proximal limb pocket 118 as bending increases, further securing the limb 104 to the riser 102 rather than urging the limb 104 to disconnect from the riser 102 by moving in a distal direction D. This allows the limb 104 to bend more freely with less risk of the limb 104 coming loose, despite the lack of a pinned mechanical device holding the limb 104 to the riser 102.
Sliding engagement at the limb pockets 118, 120 may also accommodate free bending of the limb 104, particularly in the span of the limb (i.e., the portion of the limb 104 extending between the limb pockets 118, 120; see length L2 in
In many conventional limbs, the intermediate portion of the limb is pinned to the riser or the proximal end is pinned to the riser through an axis offset from the thickness of the limb. In these cases, the proximal end must withdraw distally to accommodate the shortening of the span as the limb bends. This may reduce engagement between the proximal end and the limb pocket and may make the limb come out of its proximal pocket. Bending in the span is therefore undesirable in those limbs, and they are engineered with a thick span and are rigidly attached to the riser to avoid these issues. This, however, reduces the amount of energy the limb can store since the span is much more rigid than the rest of the limb.
By comparison, embodiments of the present disclosure may allow more bending in the span, and more of the limb can store energy. Limbs 104 of the present disclosure may bend in the span with the intermediate portion 216 translating slightly toward the proximal limb pocket 118 while the proximal end portion 212 does not translate. Thus, the bend is accommodated rather than avoided, and no stress-concentrating pins or axles are required to keep the limb 104 secured to the riser 102 since the external surfaces of the limb 104 and contact surfaces of the riser 102 are pressed toward each other as bending occurs rather than being drawn apart.
A free-floating proximal end portion 212 and sliding intermediate portion 216 may also allow the load of the limb to be more evenly distributed throughout the limb's supports. Also, because the proximal end portion 212 slides and remains in constant contact with the curved inner surface 210 of the proximal limb pocket 118, contact surface area is maintained and stresses are more consistently supported by the proximal end portion 212 during bending of the limb. In conventional limbs, the support surface contact area at their proximal ends can change as the limb bends, so pressure on different parts of their proximal ends can fluctuate significantly in comparison to the consistent (or, in some cases, increasing) surface area provided by limbs of the present disclosure.
In some embodiments, the outer pivoting surfaces 213, 218 may be positioned on components that are separate from the main body of the limb 104. For example, a proximal cap 220 may extend around the proximal end portion 212 of the limb 104 and may have outer pivoting surface 213, and an intermediate cap 222 or slide may have outer pivoting surface 218 and may be positioned around the intermediate portion 216 of the limb 104. In such configurations, the caps 220, 222 may comprise a different material from the main body of the limb 104, such as by comprising a durable, low-friction material (e.g., nylon) instead of a metal or composite (e.g., carbon fiber) that could be used for the main body. In other arrangements, the proximal cap 220 and intermediate cap 222 may be integrated as a single piece with the rest of the body of the limb 104. In other words, the outer surface of the limb 104 may be formed with the outer pivoting surfaces 213, 218 being continuous with the rest of the outer surfaces of the limb 104 or formed as part of the limb 104 itself rather than on caps 220, 222 attached to the limb 104.
The outer pivoting surfaces 213, 218 of the caps 220, 222 may comprise a plurality of transverse grooves 224 (see
The curved inner surface 210 and outer pivoting surface 213 may also be designed to interact in a manner that resists inadvertent removal of the limb 104 from the proximal limb pocket 118 while the limb 104 is mounted to the bow 100 and tension is applied to its distal end 215. The curved inner surface 210 comprises a proximally-facing surface 226 (see
Some conventional limbs have an intermediate support portion that is slidable relative to a riser. When a force is applied to the distal end of those limbs, the limb pivots approximately at the intermediate support portion and a resultant force is generated at the proximal end of the limb. The intermediate support portion is located at about half the length of the limb to make the resultant force about equal to the applied force at the distal end. This is important to those limbs because the distal and proximal ends each have axles extending therethrough. If the resultant force is multiplied due to a leverage effect because the intermediate support portion is positioned at less than half the length from the proximal end to the distal end, the resultant force can cause failure of the proximal end of the limb, especially where the stress-concentrating axle or pin extends through the limb. Otherwise, the limb must be designed to be much bulkier and stiffer at the proximal end in order to withstand the amplified load.
Embodiments of the present disclosure, however, may have limbs 104 with an intermediate support that is closer to the proximal end portion 212 than to the distal end 215 since there are no stress-concentrating pins in the proximal end portion 212. Compared to the overall length L1 of the limb 104 (see
In this embodiment, when the limbs 704 are loaded, tension in the limbs 704 drives the caps 722 downward (toward the curved surfaces 714) and inward (toward each other). Thus, the tension increases engagement between the abutting curved surfaces 214 and outer pivoting surfaces 718 and prevents the limbs 704 from sliding laterally away from the riser 702. Instead, the limbs 704 are urged to move toward the centerline of the riser 702. As a result, the limbs 704 may be more predictably loaded and may be less prone to lateral sliding away from the riser 702, even if the caps 722 or intermediate limb pockets 720 begin to wear over time.
Various inventions have been described herein with reference to certain specific embodiments and examples. However, they will be recognized by those skilled in the art that many variations are possible without departing from the scope and spirit of the inventions disclosed herein, in that those inventions set forth in the claims below are intended to cover all variations and modifications of the inventions disclosed without departing from the spirit of the inventions. The terms “including:” and “having” come as used in the specification and claims shall have the same meaning as the term “comprising.”
| Number | Name | Date | Kind |
|---|---|---|---|
| 5339790 | Smith | Aug 1994 | A |
| 5408982 | Doornenbal | Apr 1995 | A |
| 5429106 | Martin et al. | Jul 1995 | A |
| 5720267 | Walk | Feb 1998 | A |
| 5901692 | Allshouse | May 1999 | A |
| 5921227 | Allshouse | Jul 1999 | A |
| 6244259 | Adkins | Jun 2001 | B1 |
| 6758204 | Goff | Jul 2004 | B1 |
| 8047189 | McPherson | Nov 2011 | B2 |
| 8347869 | Sims | Jan 2013 | B2 |
| 8448630 | McPherson | May 2013 | B1 |
| 8453635 | McPherson | Jun 2013 | B1 |
| 8459244 | Yehle | Jun 2013 | B2 |
| 8776770 | Batdorf | Jul 2014 | B2 |
| 20060011181 | Andrews | Jan 2006 | A1 |
| 20080127961 | McPherson | Jun 2008 | A1 |
| 20090314271 | Ribi | Dec 2009 | A1 |
| 20110120436 | Eee | May 2011 | A1 |
| 20140041645 | Wasilewski | Feb 2014 | A1 |
| 20140116408 | McPherson | May 2014 | A1 |
| 20140283804 | Badgerow | Sep 2014 | A1 |
| 20160091273 | Denton | Mar 2016 | A1 |
| Entry |
|---|
| Bowtech Guardian, Bowtech Product Guide. 2007. |
| Bowtech Admiral, Bowtech Product Guide. 2009. |
| PSE DNA, PSE Archery Product Guide, 2013. |
| Strothers Vital, Strother Archery Product Guide, 2014. |
| Number | Date | Country | |
|---|---|---|---|
| 20170030674 A1 | Feb 2017 | US |
