1. Field of the Invention
The present invention relates generally to sighting mechanisms for use in conjunction with archery bows and other subsonic weapons (such as paintball guns and the like). The present invention relates more specifically to bow sights that use illuminated spots to facilitate the aiming of an archery bow at targets over a variety of distances.
2. Background of the Invention
A number of devices have been developed to facilitate the aiming of an archery bow at a target positioned over a range of distances from the archer. The nature of archery is such that relatively small variations in distance to a target require relatively significant variations in the angle at which the archer holds the bow and aims towards the target. Whereas a distance difference of one hundred yards may merit little change in the aiming angle for a rifle, such distance variations in archery required a much more significant change in the aiming angle. Sighting devices designed for rifles do not translate well into sights suitable for bows.
Many sighting devices for archery have been developed in recent years that utilize light image aiming spots that are positioned within the archer's field of view. In general, such sights either provide a direct view of one end of a fiber optic light guide or provide a reflected image of an LED or other light source. The view produced in either case is typically positioned within a ring that forms the bow sight through which the archer aims. Fiber optic light wave guides are typically positioned within the field of view and extend to one side where they are arranged so as to either gather light from ambient sources or to connect to a small electrically powered light source such as an LED. Such designs provide the ability to individually adjust the position of each of the spots thus created within the bow sight.
Other efforts in the past have focused on providing electrical light sources either directly in the bow sight (in place of the fiber optic light wave guides) or positioning electrical light sources in such a manner that a reflection of the light source is directed towards the archer through the bow sight. What has not been achieved in the prior art is a bow sight that combines the advantages of a fiber optic based system utilizing ambient light with the advantages of a reflective bow sight system that eliminates the need to directly position light sources or light guides within the field of view. The present invention provides such a solution to the problem of an efficient, adjustable, and inexpensive bow sight.
Other efforts in the past have included the following patents and patent applications:
U.S. Pat. No. 5,090,805 issued to Stawarz on Feb. 25, 1992 entitled Bow Sight with Projected Reticule Aiming Spot.
U.S. Pat. No. 5,383,278 issued to Kay on Jan. 24, 1995 entitled Wide Field of View Reflex Sight for a Bow.
U.S. Pat. No. 5,653,034 issued to Bindon on Aug. 5, 1997 entitled Reflex Sighting Device for Day and Night Sighting.
U.S. Pat. No. 5,231,765 issued to Sherman on Aug. 3, 1993 entitled Illuminated Sight Having a Light Collector Serving a Fiber Optic.
U.S. Pat. No. 5,394,615 issued to Hoppe et al. on Mar. 7, 1995 entitled Light Archery Sight.
U.S. Pat. No. 5,634,278 issued to London on Jun. 3, 1997 entitled Bow Sight.
U.S. Pat. No. 5,813,159 issued to Kay et al. on Sep. 29, 1998 entitled Wide Field of View Reflex Gunsight.
U.S. Pat. No. 5,914,775 issued to Hargrove et al. on Jun. 22, 1999 entitled Triangulation Rangefinder and Sight Positioning System.
U.S. Pat. No. 6,725,854 issued to Afshari on Apr. 27, 2004 entitled Illuminated Sight Pin.
U.S. Patent Application Publication No. US 2006/0254065 A1 (Grace) published on Nov. 16, 2006 entitled Archery Bow Sight.
U.S. Pat. No. 5,619,801 issued to Slates on Apr. 15, 1997 entitled Fiber Optic Pin Sight for a Bow.
U.S. Patent Application Publication No. US 2006/0150429 A1 (Khoshnood) published on Jul. 13, 2006 entitled Ambient Light Collecting Sight Pin for a Bow Sight.
The full disclosures of each of the issued U.S. patents and the Published Applications listed above are incorporated in their entirety herein by reference.
The present invention provides a bow sight that utilizes fiber optic wave guides as a basis for collecting ambient light and projecting multiple aiming spots within the archer's field of view. Rather than positioning the terminal end of the fiber optic wave guides directly in the field of view (as well as the required support structures), the wave guide terminal ends are positioned so as to have images thereof reflected on a moveable reflective objective optic within the archer's field of view. The multiple aiming spots thus reflected in the bow sight provide the archer with sighting spots for targets over a range of distances.
Each of the individual fiber optic wave guides collects ambient light and terminates in a terminal block that may be varied in its position so as to individually adjust the reflected image of the aiming spot. Various mechanisms for adjusting the position of the ambient light wave guides are also described.
The various figures include referenced elements and components that are common and which include the following referenced component:
10 bow stock cross section (dashed outline)
12 bow mounting plate
14 clamp screw (horizontal adjustment)
16 clamp (vertical)
18 clamp screw (vertical adjustment)
20 sight stock
22 projection stock
24 fiber optic channel
26 channel cover plate
28
a-28d fiber optic terminal blocks (four spot version)
30
a-30d fiber optic adjustment set screws (four spot version)
32
a-32d fiber optic wave guides (four spot version)
34 light receptor coil assembly
36 coil bracket
38 sight base assembly
40 sight tube (sight ring)
42 reflective objective optic
44 optic retainer ring
46 sight pivot screw
48 sight adjustment screw
50
a-50d aiming spot images
52 bow stock mounting apertures
54 fixed angular reference point
60 alternate embodiment bow sight system
62 bow mounting plate
64 vertical adjustment clamp
66 lens bracket
68 sight tube with optic
70 main beam
72 fiber optic holder rack
74 right fiber optic holder shell
76 left fiber optic holder shell
80 fiber optic holder (typical)
82 mounting holes
84 fiber light gathering slots
86 fiber optic adjustment view window
88 mounting plate clamp tightening screw
90 sight tube mounting screw
92 horizontal fiber optic image adjustment screw
94 vertical adjustment clamp tightening screw
96 sight tube mounting screws
98 fiber optic passage
100 fiber optic holder adjustment screw
102 fiber optic channel aperture
The present invention is generally described by the referenced Drawing figures attached.
The side to side placement of the aiming spots in the field of view is achieved by way of a pivoting sight tube bracket. The elevation (vertical adjustment) of the individual aiming spots may be varied according to one of a number of different mechanisms within the fiber optic terminal block assembly as disclosed in the attached Drawing figures. Four (4) spot and five (5) spot versions of the preferred embodiments are shown although those skilled in the art will recognize that the present invention lends itself to use in conjunction with systems that incorporate from three (3) to as many as seven (7) or more aiming spots. It is preferable to use different colored fiber optic wave guides for the different aiming spots to facilitate the choice of an appropriate spot for a particular range.
Sight stock 20 supports projection stock 22 and integrates fiber optic channel 24 with channel cover plate 26. Fiber optic terminal blocks (four spot version) 28a-28d incorporate fiber optic adjustment set screws (four spot version) 30a-30d projection stock 22. Fiber optic terminal blocks consist of end blocks that are curved inward in order to allow the fiber terminations to be close enough to generate distinct individual images that represent a practical variation in ranges. Images spaced too far apart would not accommodate enough variation that would allow the archer to accurately select the best distance. Images spaced too close together could be difficult to resolve distinctly. The number and spacing shown provides a balanced manner of addressing these concerns. Fiber optic wave guides (four spot version) 32a-32d carry light from the light receptor coil assembly 34 mounted on the coil bracket 36 which is positioned on the sight base assembly 38.
Sight tube (sight ring) 40 integrates and holds reflective objective optic 42 with optic retainer ring 44. The angle of sight tube 40 can be adjusted using sight pivot screw 46 and sight adjustment screw 48.
The changing the configuration from side mounted fibers in the first preferred embodiment to mounting them vertically provides certain additional advantages. When the orientation is vertical with a side configuration, the virtual image generated by the concave lens can sometimes be skewed and as a result may not accurately track the arrow point of impact due to the extreme side angle of reflection. If this is the case, the second preferred embodiment provides an orientation where the fiber holders are located vertically and back in an adjustable housing.
The entire adjustable housing can move side to side with an adjustment screw as described above. This arrangement allows the archer to sight the bow with the overall sight adjustments and then center the dots in the lens with the housing adjustments. Each fiber holder is still individually adjustable vertically, to sight in at the varying distances.
The fiber optic fibers are run out of the housing and through the grove in the main support beam. They are run along the top, side and front of this beam to gather ambient light from all directions. In the preferred embodiment, these fibers are held in clear plastic tubing which may be adhered to the main beam.
The lens in the second preferred embodiment is a concave semi-reflective lens. Depending on availability, a concave circular lens of specific (optically defined) radius of curvature with a semi-reflective coating may be used (the type often used on sunglasses). The fibers must be placed at a specific distance in order to generate the proper virtual image in the lens. This distance is critical to track the point of impact. The light source must be at a precise proportion to the focal length of the lens. The resulting virtual image is greatly magnified and perfectly in line with the point of impact.
Depending on the diameter of the fiber optic fiber the above mentioned magnification can cause some problems. With a fiber of 0.020″ the lens magnifies about 3 times and the resulting dot is too big in the view of the archer. The large image is not accurate enough at the longer ranges. One solution is to countersink a 0.023″ hole into the holder and then drill out a 0.010″ hole for the light to shine through. This cuts the fiber image in half so that it is usable to the archer. This may be a practical approach to reducing the size of the light spot image when necessary. Alternately, a 0.010″ or smaller fiber may be used as such finer gauge fibers are now becoming available.
Although a specific advantage of the present invention is its ability to gather ambient light, it is adaptable for use in conjunction with artificial light sources. The basic system of the present invention may be used in conjunction with standard bow sight mounts that provide horizontal and vertical support adjustments. In addition, the system allows for use on either right or left handed bows by simply inverting the assembly. The system does not interfere with the arrow or the arrow rest in any configuration and generally adds little to the weight of the bow. The various components of the system of the present invention are easily assembled and disassembled as needed for adjustment, maintenance, and/or replacement. The same basic frame, sight tube, and light gathering assembly, may be used with any of the various described fiber optic terminal block assemblies.
The system of the present invention combines the advantages of an ambient light fiber optic bow sight with the advantages of a reflex bow sight. Specifically, the bow sight of the present invention requires no electrical power and collect sufficient ambient light to provide easily visible aiming spots. The system utilizes multiple fiber optic wave guides in order to provide multiple, independently adjustable, aiming spots. The system uses a reflective objective optic to reflect an image of the bright ends of the fiber optics within the field of view. Unlike most systems that utilize fiber optic wave guides, the present invention does not clutter or obstruct the field of view with support structures or other components required by non-reflex systems.
The present invention solves the above described problem by providing a fixed angular reference point 54 to help vertically and rotationally align the floating holographic dot images. Essentially, the stationary point places a representation of the vertical and rotational orientation of the bow stock within close proximity to the view that the archer is focused on, namely the elevation aligning dot images. This allows the archer to hold this focus and align the vertical and side to side angles of the bow at the same time the proper elevation angle is established.
The fixed angular reference shown in the figures (
Various alternate fixed angular reference indicators 54 are envisioned. The reference may be an etched triangle or line in one or more of the lens assembly elements, or a wire or metal tab that extends from the lens assembly holder (sight tube) 68 towards the center of the lens. As can be seen from the balance of the drawing figures, the vertical and side to side angular orientations of sight tube 68 are fixed with respect to the bow stock (roughly centered at the grip as the point of rotation and/or twisting). Tilting adjustments that allow for calibration of the imaged dots on the optics are possible without altering the fixed axis of rotation alignment between the sight tube and the bow stock. In other words, while elevation can be calibrated, the rotational and torque alignments are fixed to the bow, with adjustments occurring only through the motion of the archer's wrist. This makes the alignment and sighting process fully within the control of the archer during target sighting. Once again, the objective is to provide all of the necessary sighting tools within the very narrow, focused field of view of the archer, such that the archer can very quickly and accurately align the target. The feature described uniquely allows this to occur.
Although the present invention has been described in terms of the foregoing preferred embodiments, this description has been provided by way of explanation only, and is not intended to be construed as limiting of the invention. Those skilled in the art will recognize modifications of the present invention that might accommodate specific types of subsonic weapons or targeting environments. Such modifications, as to size, shape, construction material, and component arrangements, where such modifications are coincidental to the types of weapon being utilized or the environment within which it is being targeted, do not necessarily depart from the spirit and scope of the invention.
This application claims the benefit under 35 USC §120 of co-pending U.S. patent application Ser. No. 12/214,556 filed Jun. 18, 2008, which further claims the benefit under 35 USC §119(e) of U.S. Provisional Patent Application No. 60/936,121; Filed: Jun. 18, 2007, the full disclosures of which are incorporated herein by reference.
Number | Date | Country | |
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60936121 | Jun 2007 | US |
Number | Date | Country | |
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Parent | 12214556 | Jun 2008 | US |
Child | 12551005 | US |