Dry-fire prevention mechanism for crossbows

Abstract

A dry fire prevention safety mechanism for crossbows having a trigger mechanism which releases a bowstring to discharge an arrow. A spring-loaded catch arm is pivotally connected to the crossbow and has a hook at one end and a ramp portion at the opposite end which extends into an arrow seating well. When an arrow is positioned to be discharged, the ramp portion is abutted by the arrow which disengages the hook from the trigger and enables operation of the crossbow.

Description

BACKGROUND OF THE INVENTION

The field of the invention pertains to crossbows and crossbow trigger mechanisms. The invention relates more particularly to an anti-dry fire mechanism for crossbows, wherein an arrow contacting surface operates a hook-type catch to engage and prevent operation of a trigger mechanism.

Various types of trigger mechanisms have been specifically developed for use in crossbows. Many, if not most, of these crossbow trigger mechanisms are designed with built-in safety mechanisms which prevent accidental discharge of an arrow. However, these conventional safety mechanisms are typically not designed for preventing the release of a cocked but unloaded bowstring, i.e. when an arrow is not positioned for discharge. This situation, commonly known as “dry fire”, can cause damage to the crossbow or be potentially hazardous to the user. In an effort to prevent the occurrence of dry fire situations, various dry fire prevention devices have been developed for crossbows which disable operation of the crossbow trigger mechanism while an arrow is not positioned to be discharged.

For example, in U.S. Pat. No. 5,085,200 a self-actuating, dry-fire prevention safety device for a crossbow is shown having a stop block 30 which pivotally operates to block forward movement of a safety assembly block plate 22 when an arrow is not positioned to be discharged. It does so by abutting a blocking portion 34 of the stop block 30 against a rounded operating pin 24 of the safety assembly block plate 22 . The disadvantage of this arrangement is the limited efficacy and unreliability of a blocking impedance as opposed to impedance by catch-engagement. While exact alignment of the blocking component 34 with the operating pin 24 would effectively prevent dry fire (FIG. 5 ), the slightest variation in pivot angle of the stop block 30 may cause the blocking engagement to slip and thereby enable dry fire.

And in U.S. Pat. No. 5,598,829 a crossbow dry fire prevention device is shown having a string catch member with an arrow contacting surface which cause the string catch member to be moved out of the string catching position when an arrow is placed in the firing position. When the bowstring is cocked but an arrow is not in place, the string catch member is urged into the release path of the bowstring. In this manner, the string catch member functions to catch the inadvertently released bowstring to prevent dry fire. However, this arrangement does not operate to inhibit operation of the trigger mechanism. Notwithstanding the absence of an arrow, actuation of the trigger mechanism will release the cocked bowstring from the sear, only to be caught by the string catching member.

Similar to the 839 patent, a crossbow is shown in U.S. Pat. No. 5,884,614 also having a dry fire prevention mechanism which operates to block the release passage of a bowstring when an arrow is not in place. In particular, a safety latch positioned above the release passage is urged downward into the release passage by means of a safety latch spring. This arrangement, however, also does not inhibit operation of the trigger mechanism. While inadvertent release of the unloaded bowstring will not dry fire, the bowstring must be cocked again and reset onto the sear before successful operation may take place.

In summary, it is therefore desirable to provide a dry fire prevention safety mechanism for use on crossbows which not only blocks movement of the trigger mechanism, but directly catches a part of the trigger mechanism to prevent operation of the crossbow trigger mechanism when no arrow is positioned for discharge. Moreover, a dry fire prevention mechanism having a minimal number of moving parts, e.g. a single moving arm, would provide simplified operation, as well as reduce manufacturing costs compared to complex, multi-link dry fire prevention safety systems.

BRIEF SUMMARY OF THE INVENTION

It is an object of the present invention to provide a reliable dry fire prevention mechanism for crossbows wherein the crossbow trigger mechanism is made inoperable while an arrow is not positioned for discharge.

It is a further object of the present invention to provide a simple and efficient dry fire mechanism for crossbows having a one-piece catch arm which directly catch-engages the trigger without any wasted movement or the need for additional links or intermediate components.

It is a still further object of the present invention to provide a dry fire mechanism for crossbows which may be manufactured in a cost-effective manner by conventional manufacturing methods.

The present invention is for a safety mechanism for preventing dry fire of a crossbow. The crossbow is of the type having a bow mounted on a crossbow stock and a trigger mechanism which releases a bowstring to discharge an arrow. The safety mechanism comprises a catch arm which is pivotally connected to the crossbow stock. The catch arm has a first catch element, such as a hook, at one end for releasably engaging a second catch element, such as a catch pin, of the trigger mechanism. Additionally, the catch arm has an arrow contacting surface which pivots the first catch element out of engagement with the second catch element when an arrow is positioned to be discharged. And finally the safety mechanism comprises resiliently biasing means for urging the first catch element to releasably engage the second catch element of the trigger mechanism when no arrow is positioned to be discharged, thereby preventing dry fire while an arrow is not in place.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a crossbow of the present invention.

FIG. 2 is a top view of the crossbow in FIG. 1 , illustrating deflection of the bow and bowstring when in a cocked position.

FIG. 3A is a schematic view of the crossbow stock upon cocking and releasably locking the nocking member and bowstring, but prior to loading of an arrow.

FIG. 3B is an enlarged view of Circle 3 B in FIG. 3A showing in detail the engagement of the primary safety mechanism.

FIG. 4A is a schematic view of the crossbow stock following FIG. 3A wherein an arrow is now loaded, and the safety device is disengaged.

FIG. 4B is an enlarged view of Circle 4 B in FIG. 4A showing in detail the disengagement of the primary safety mechanism, and closure of the electrical circuit.

FIG. 5 is a schematic view of the crossbow stock following FIG. 4A , wherein the trigger mechanism is actuated, the bowstring and nocking member released, and the arrow discharged.

FIG. 6A is a cross-sectional view of the bowstring release mechanism taken along line 6 A of FIG. 3A , and shown in the closed position.

FIG. 6B is a cross-sectional view of the bowstring release mechanism following FIG. 6A , and shown in the open position to release the nocking member and bowstring.

FIG. 7 is an enlarged perspective view of the slider component of the safety mechanism.

FIG. 8 is a partially cut-away schematic view of the crossbow stock illustrating the electric circuit for the laser.

FIG. 9 is a skeletal schematic view of a second preferred embodiment of the crossbow, having a rifle configuration.

FIG. 10 is a detailed view of the rifle type crossbow of FIG. 9 , shown in a closed position with a cocked nocking member positioned to be discharged.

FIG. 11 is a detailed view of the rifle type crossbow following FIG. 10 , shown in the open position after discharging an arrow.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring now to the drawings, FIGS. 1-8 show a first preferred embodiment of a crossbow having a hand-held pistol type configuration, generally indicated at reference character 10 . The crossbow 10 is designed to receive, engage, and discharge an arrow, generally indicated at reference character 24 , having a leading end 25 and a tail end 26 with a nock portion 27 . As can be seen in FIGS. 1 and 2 , the crossbow 10 includes a bow, generally indicated at reference character 11 , which is mounted on a crossbow stock, generally indicated at reference character 17 . In particular, a riser portion 12 of the bow 11 is mounted at a forward portion 19 of a barrel 18 of the crossbow stock 17 . A rearward portion 20 of the barrel 18 is connected to a handle portion 21 of the crossbow stock 17 which is used for grasping and handling of the crossbow 10 . The bow 11 has a pair of bow limbs 13 connected at their distal ends by a bowstring 14 . A nocking member 15 is centrally mounted on the bowstring 14 for engaging the nock portion 27 of an arrow 24 . In this regard, the nock portion 27 has a recess 28 ( FIGS. 3A , 4 A, and 5 ) suitably adapted to releasably engage the nocking member 15 , as will be discussed in detail below.

One important feature of the crossbow 10 is a bowstring release mechanism and system, shown in FIGS. 3-6B , which operates to hold and release the bowstring 14 by way of the nocking member 15 . The bowstring release mechanism and system is generally comprised of upper and lower catch surfaces, 64 and 64 ′ respectively (see FIGS. 6 A and 6 B), positioned at the rearward portion 20 of the crossbow stock 17 in vertical relation to each other. A release passage 82 is formed between the catch surfaces 64 , 64 ′. The release passage 82 leads into a retaining area 82 ′ where a cocked nocking member 15 (along with the bowstring 14 ) is held prior to being discharged through the release passage 82 . Preferably, the upper and lower catch surfaces 64 , 64 ′ are the curvilinear contact surfaces of upper and lower rollers 60 , 62 which are adapted to spin freely about rotational axes 61 , 63 respectively. The upper end lower catch surfaces 64 , 64 ′ are thus preferably continuous rolling surfaces having circular cross-sections as shown in FIGS. 3A , 4 A, and 5 . Alternatively, however, it is appreciated that the upper and lower catch surfaces 64 , 64 ′ may be rigidly fixed to prevent any movement, rotational or otherwise.

Furthermore, as can be seen in FIGS. 6A and 6B showing a cross-sectional view taken along line 6 A of FIG. 3A , each of the upper and lower rollers 60 , 62 has a substantially hourglass configuration with a hyperbolic cross-section, i.e. the center portion has a narrower width than the opposing ends. Thus the upper catch surface 64 of the upper roller 60 and the adjacent lower catch surface 64 ′ of the lower roller 62 are concave relative to each other when viewed along a longitudinal axis (not shown) of the barrel 18 . Moreover, the concave configuration of each of the catch surfaces 64 , 64 ′ is adapted to contour to the particular shape of the nocking member 15 . As shown in the figures, the nocking member 15 preferably has a substantially ball-shaped configuration with a bore 16 through which the bowstring 14 extends. Thus the recess 28 of the nock portion 27 of an arrow 24 has a semi-spherically concave configuration which seats the ball-shaped nocking member 15 . Alternatively, however, it is appreciated that the nocking member 15 may also have various non-spherical, curvilinear shapes, with correspondingly contoured upper catch surface, lower catch surface, and nocking portion recess 28 .

Additionally, the bowstring release mechanism and system comprises actuating means for vertically moving the upper and lower catch surfaces 64 , 64 ′ relative to each other between a closed position (FIGS. 3 A and 4 A), and an open position (FIG. 5 ), thereby narrowing or widening the release passage 82 , respectively. Preferably, as can be seen in the figures, the upper catch surface 64 (of the upper roller 60 ) is mounted on a front limb 42 of a sear arm 41 which is pivotally connected to the crossbow stock 17 at a sear arm pivot joint 44 . As can be seen in the figures, the upper catch surface 64 is preferably positioned away from the tip of the front limb 42 , to enable a abutment surface 45 to clamp down an inserted arrow 24 by pressing it against an opposite brace surface connected to the crossbow stock 17 . The sear arm pivot joint 44 is positioned between the front limb 42 and a rear limb 43 extending opposite the front limb 42 of the sear arm 41 . The sear arm 41 is thus configured to rock about the sear arm pivot joint 44 by applying an upward locking force or an opposite downward unlocking force on the rear limb 43 .

To produce the upward locking and downward unlocking forces which actuate the sear arm 31 , the rear limb 43 is pivotally connected to a coupler link 36 at a rear pivot joint 37 . The coupler link 36 is in turn pivotally connected to a trigger link 33 at an upper trigger link joint 35 , and the trigger link 33 is pivotally connected to the crossbow stock 17 at a lower trigger link pivot joint 34 . Furthermore, a resiliently biasing means, such as a coil spring 46 , is positioned above the rear limb 43 which exerts the downward unlocking force against the rear limb 43 . It is notable that due to the downward unlocking force exerted by the coil spring 46 on the rear limb 43 of the sear arm 41 , alignment of the upper trigger link pivot joint 35 along the alignment axis 47 is inherently unstable, with the upper trigger link pivot joint 35 having a tendency to push away from the axis 47 . It is further notable that because the rear pivot joint 37 and upper trigger link pivot joint 35 are not pivotally connected to the crossbow stock 17 , these joints are capable of being translationally displaced relative to the crossbow stock 17 .

In this manner, the relative position of the upper trigger link pivot joint 35 with respect to the alignment axis 47 will ultimately determine the open or closed positioning of the sear arm 31 . The rear limb 43 of the sear arm 41 will reach its highest point when the upper trigger link pivot joint 35 is collinear with the rear pivot joint 37 and the lower trigger link pivot joint 34 along an alignment axis 47 . And consequently, the front limb 42 of the sear arm 41 , together with the upper catch surface 64 , will be simultaneously lowered to the closed position, as shown in FIG. 4 A. In providing the upward locking force necessary to pivot the sear arm 31 to the closed position, a pressure plate 38 is connected to the coupler link 36 for actuating the coupler link 36 . By pushing against the pressure plate 38 , the trigger link 33 pivots about the lower trigger link pivot joint 34 such that the upper trigger link pivot joint 35 crosses the alignment axis 47 . This consequently raises pivot point 37 of the coupler link 33 . As can be seen in FIG. 4A when in the ready position, the upper trigger link pivot joint 35 is positioned slightly forward of the alignment axis 47 and is stabilized and prevented from further movement by means of a trigger 29 which abuts the trigger link 33 along an abutting end 32 .

Once in the releasably locked position, actuation of the trigger 29 causes the abutting end 32 to urge the trigger link 33 rearward past the alignment axis 47 . As the upper trigger link pivot joint 35 moves rearward past the alignment axis 47 , the compressed sear arm spring 46 provides the necessary momentum to accelerate the upper trigger link far past the alignment axis 47 . This movement lowers the rear limb 43 of the sear arm 41 and consequently raises the front limb 42 .

Generally, when the upper and lower rollers 60 , 62 are in the closed position, as shown in FIG. 6A , the upper and lower catch surfaces 64 , 64 ′ block passage of a cocked nocking member 15 through the release passage 82 . They do so by abutting a frontal portion of the cocked nocking member 15 to keep it contained within the retaining area 82 ′. It is notable that because only the forward section of the ball-shaped nocking member 15 abuts against the catch surfaces, the nocking member 15 is not seized by the upper and lower catch surfaces 64 , 64 ′. It is appreciated that the term “blocking” is defined and used herein to mean preventing movement in one or more predetermined directions, whereas the term “seizing” is defined and used herein as preventing movement in all directions by a pair of equal and opposite forces, i.e. complete relative immobility with respect to the seizing instrument or object.

When in the open position, as shown in FIG. 6B , the upper and lower catch surfaces 64 , 64 ′ are sufficiently separated to enable the cock nocking member 15 to pass through the release passage 82 . As can be seen in the figures, the use of upper and lower rollers 60 , 62 minimizes or altogether eliminates slip between the nocking member 15 and the rolling catch surfaces 64 , 64 ′. Alternatively, however, where the catch surfaces 64 , 64 ′ are rigidly fixed to the crossbow stock 17 , the nocking member 15 must pass through the release passage 82 by sliding against the catch surfaces 64 , 64 ′. It is appreciated that wear caused by slip friction between the surfaces is effectively reduced for repeated use cycles due to the curved and contoured catch surfaces 64 , 64 ′ which provide relatively even pressure distribution along the contact and separation points between the nocking member 15 and the catch surfaces 64 , 64 ′. In this manner, the ball-shaped nocking member 15 may separate smoothly and evenly from the catch surfaces 64 , 64 ′ to propel the arrow 24 much more accurately.

Another important feature of the crossbow 10 is a dry fire prevention mechanism which operates to disable operation of the trigger 29 while an arrow 24 is not positioned to be discharged. As can be seen in the figures, the dry fire prevention mechanism is preferably a catch arm 65 which is pivotally connected to the crossbow stock 17 at a catch arm pivot joint 66 . The catch arm 65 has a top end 67 adjacent the lower roller 62 and a bottom end 68 having a first catch element 69 which is preferably a hook 69 . The catch arm pivot joint 66 is preferably intermediately positioned between the top and bottom ends 67 , 68 . Resiliently biasing means 71 , such as a coil spring 71 , is provided to urge the hook 69 of the catch arm 65 into releasable engagement with a second catch element 31 of the trigger mechanism 29 when no arrow 24 is positioned to be discharged. As shown in the figures, the second catch element is preferably a catch pin 31 . Furthermore, an arrow contacting surface 70 is located at the top end 67 of the catch arm 65 , which is preferably positively inclined towards the rear of the crossbow 10 .

Operation of the dry fire prevention mechanism can be best seen in FIGS. 3A , 4 A, and 5 which illustrate the progression of loading and firing an arrow 24 . Prior to insertion of the arrow 24 , the catch arm 65 preferably abuts against a stopper block 72 and the hook 69 is releasably engaged to catch pin 31 such that the trigger mechanism 29 may not be actuated and the crossbow 10 is non-operational. As can be seen in FIG. 4A upon the insertion of an arrow 24 adjacent the abutment surface 45 , the tail end 26 of arrow 24 presses against the arrow contacting surface 70 to thereby pivot the catch arm 65 about catch arm pivot pin 66 . Consequently, the resulting pivoting action of the catch arm 65 is sufficient to disengage and clear the hook 69 from the pin 31 . As can be seen in FIG. 5 , upon release of the nocking member 15 , the arrow contacting surface 70 returns to its unpivoted position and the catch arm 65 once again abuts the stopper block 72 . Furthermore, as can be seen in FIGS. 3A , 4 A, 5 , the catch arm 65 has means for manually overriding engagement of the first and second catch elements. This is preferably an override actuator arm 68 ′ transversely extending from the catch arm 65 and accessible by the user.

A third important feature of the crossbow 10 is a laser circuit activation system which utilizes a safety component of the trigger mechanism 29 to activate a laser generating means, generally indicated by reference character 73 . FIG. 8 generally shows a schematic view of an electrical circuit of the laser generating means 73 , generally indicated by reference character 74 . The electrical circuit 74 comprises an energy source, such as a battery 75 , connected by electrical wiring 76 to a primary switch 77 positioned adjacent a trigger safety device. The trigger safety device comprises a slider component 48 best shown in FIG. 7 . The slider component 48 has a reset shoe 53 connected to a reset extension arm 54 . And the reset extension arm 54 is connected to a cam 51 having a reversed incline surface 52 . The cam 51 connects to a thumb switch 49 by means of a neck 50 . As shown in FIG. 7 , the slider component 48 is seated along a planer slide surface 22 of a top end of the handle portion 21 . Furthermore, the trigger safety device has a leaf spring 55 having a fixed end 56 and a movable end 57 . A latch portion is connected to the movable end 57 which engages a safety aperture 39 located on the pressure plate 38 to releasably lock the trigger mechanism 29 .

As shown in FIGS. 3B and 4B , the trigger safety device may be disengaged when the thumb switch 49 is urged forward such that the reverse inclined surface 52 contacts and steps over step surface 59 of the leaf spring 55 . This causes the leaf spring 55 to bias sufficiently downward such that the latch portion 58 is disengaged from the safety aperture 39 . Consequently, and simultaneously, the movable end 57 of the leaf spring 55 depresses a switch actuator arm 80 of the primary switch 77 . This action bridges the positive terminal 78 with a negative terminal 79 to complete the electrical circuit 74 of the laser generating means 73 .

In this manner, when the safety device is disengaged to enable discharge of an arrow 24 , the laser means 73 is simultaneously activated to produce a laser beam (not shown). And upon discharging the arrow 24 from the crossbow 10 , the pivoting movement of the trigger link 33 causes the trigger link 33 to abuttingly urge the reset shoe 53 rearward. This in turn moves the slider component 48 back to the safety position which releases the leaf spring 55 and automatically resets the safety device to prevent accidental discharge. Consequently, the leaf spring 55 also releases the switch actuator arm 80 to thereby open the electrical circuit 74 and turn off the laser 73 . This helps conserve energy needed to power the laser means 73 by supplying power only immediately prior to discharging the crossbow 10 , i.e. when the safety is disengaged. Furthermore, a secondary switch 81 may be provided as a manual override for turning the laser 73 on and off.

A second preferred embodiment of the cross bow is shown in FIGS. 9-11 , having a crossbow stock with a rifle-type configuration, generally indicated by reference character 100 . Similar to the pistol-type crossbow 10 of the first preferred embodiment, the rifle crossbow stock 100 has an elongated barrel 101 with a front portion 102 and a rear portion 103 . Additionally, a shoulder rest 105 extends to the rear of the handle portion 104 .

As can be best seen in FIG. 10 , the rifle crossbow stock 100 also preferably incorporates a bowstring release mechanism and system having an upper roller 127 and a lower roller 129 . Upper roller 127 is also rotatably connected to a sear arm 120 having a front portion 121 and an oppositely directed rear portion 122 , with a sear arm 120 pivoting about a sear arm pivot axis 123 . While the trigger mechanism shown in FIG. 10 differs from that of the pistol-type crossbow 10 in FIGS. 1-8 , the bowstring release mechanism and system operate in essentially the same manner. Likewise, the rifle-type crossbow 100 also has a safety mechanism for preventing dry fire which utilizes a catch arm 131 pivotally connected at a catch arm pivot joint 132 to the crossbow stock 100 . An arrow contacting surface 137 similarly extends from a top end of the catch arm 131 into the path of an arrow for pivoting the catch arm 131 about the catch arm pivot joint 132 . And the catch arm 131 has a hook 136 which engages a catch pin 108 of the trigger mechanism 106 . In this embodiment, however, the engagement pin 108 is a pivoting joint between a cocking lever 115 , having an upper end 116 and a pivot axis 117 , and a connecting safety arm 119 . In this second embodiment, the safety arm 119 has an analogous function to the pressure plate 38 of the first preferred embodiment. Thus, the safety arm 119 connects to a pivot joint 112 connecting to a coupler link 113 and a trigger link 110 . The trigger link 113 is pivotally connected to the rear limb 122 of the sear arm 120 at a rear pivot joint 114 . Similar to the alignment axis 47 of the first preferred embodiment, the alignment axis 126 of the second preferred embodiment is the equilibrium threshold which must be overcome to cross between the open and closed positions.

The present embodiments of this invention are thus to be considered in all respects as illustrative and restrictive; the scope of the invention being indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are intended to be embraced therein.

Claims

1. A safety mechanism for preventing dry fire of a crossbow having a bow mounted on a crossbow stock and a trigger mechanism for releasing a bowstring to discharge an arrow, said safety mechanism comprising:a catch arm pivotally connected to said crossbow stock, said catch arm having a first catch element for releasably engaging a second catch element of said trigger mechanism to prevent operation thereof, and an arrow contacting surface which pivots said first catch element out of engagement with said second catch element when an arrow is positioned to be discharged; and resiliently biasing means for urging said first catch element to releasably engage said second catch element of said trigger mechanism when no arrow is positioned to be discharged.

2. The safety mechanism of claim 1,wherein said first catch element is a hook and said second catch element is a pin.

3. The safety mechanism of claim 1,wherein said resiliently biasing means is a coil spring element.

4. The safety mechanism of claim 1,wherein said arrow contacting surface and said first catch element are located at opposite ends of said catch arm with a pivot axis therebetween.

5. The safety mechanism of claim 1,wherein said arrow contacting surface is a pivot ramp.

6. The safety mechanism of claim 5,wherein said pivot ramp is contoured to laterally receive a tail end of an arrow.

7. The safety mechanism of claim 1,wherein said safety mechanism further comprises means for manually overriding engagement of said first and second catch elements.

8. The safety mechanism of claim 7,wherein said means for manually overriding is an override actuator arm transversely extending from said catch arm.