In clay target shooting sports, “Trap” is a well-known event, where people shoot at a series of clay targets exiting from a box launcher. The shooter knows the height and direction of the targets, which are always launched from the box launcher in the same way. The shooter's interception of each target is the objective. The targets can have different shapes according to the type of trajectory they trace in the shooting area. The trajectory of the axially symmetrical clays targets is usually quite predictable by the most experienced shooters. Because of this, the axially symmetrical clays have been replaced by flying targets shaped to trace more unpredictable trajectories in order to make hitting the target more challenging. To this end, in the '60s, a target, commonly called “helice,” was designed and constructed. It comprises a central body made of flexible plastic and a helical body, provided with two opposite blades and made of rigid plastic. These kinds of targets are used in the discipline called “electrocibles.”
The central body of the target, usually named as “witness cap,” is shaped similar to the convex surface of a clay target. As such, the witness cap is connected in a snap-like manner to the helical body (which it may be detachable from), which acts as a support for the same witness cap. In some cases, the helical (or firmed) body has mushroom shaped pins, which couple with housings provided in the peripheral part of the witness cap. The material of which the witness cap is made is flexible, meaning that, when hit by projectiles, it does not break, and if it falls into a designated area, a point is scored, such as in the discipline called electrocibles.
A device for launching of flying targets is the subject of this application.
The disclosed embodiments of the present disclosure described herein provide a new, automated way of loading and launching flying targets made of various material, such as helice targets, clay targets, plastic targets, skeet, and the like. The embodiments save time loading targets and maintain the integrity of the targets. The disclosed embodiments reduce target jams and breakage, and allow for the use of any manufacture of helice target.
As such, the disclosed embodiments provide for a device for launching a target having an arm motor a gear motor shaft coupled to the arm motor configured to rotate right and left rotating arms, and right and left target loading arms each having (1) a cam assembly coupled to a corresponding rotating aim and (2) and arm extension. The device includes a horizontal linear loader configured to hold a plurality of targets and a backstop, where one of the plurality of targets sits against the backstop, where the right and left loading arms via the corresponding arm extensions lift a target up from the backstop. The device includes an oscillation motor coupled to a throwing motor, the throwing motor being connected to a beak assembly configured to hold the lifted target, the oscillation motor turns the throwing motor, and the turning of the throwing motor spins the lifted target held on the beak assembly.
In some embodiments, a single rotation of a gear motor shaft is all that is needed to load the target on the arm, load the target onto the throwing motor, and then back to pick up the next target. This is unique to this equipment and reduces the complexity of the automatic loading of helice to a single rotation, eliminating the need for complex computer electronics, mechanical complexity, and the labor that is required of both automated and non-automated equipment.
In some embodiments, unlike conventional automated equipment where the motor is brought to the target, the equipment of the present disclosure brings the target to the motor, and this, in and of itself, eliminates major mechanical, computer, and electronic issues associated with conventional automated loaders.
In some embodiments, the equipment of the present disclosure is used to launch two-piece targets for Helice competitions and the practice. The machine works by placing targets in the horizontal linear loader. The targets fit together and line up against a backstop, the target against the backstop being ready to load. When the arm motor is activated, the shaft turns a set of rotating arms that fits into cams on the target loading arms, forcing the arms up in tandem and the hooks on the arm extensions under the first target. The arms then move up, lifting the target along an axis that intersects the center line axis of the throwing motor at the apex of the arm; at this point the rotation of the arm motor pushes the stop in the cam and glides the arm and target back in a linear direction, allowing the target to seat on the beak assembly attached to the throwing motor, which holds and spins the target at up to 10,000 RPMs, until it is released by the shooter upon his call, either by voice activation or a manual switch that activates the linear actuator, which releases the target.
In some embodiments, once a target is set at the throwing motor and before it starts to spin, the arms start back to pick up the next target to reload after the currently-set target is thrown. The target starts to spin once the arms and arm extensions clear, activating the oscillating motor to start turning the throwing motor. The linear loader is activated when the arms return to their beginning point, and it sets the next target against the backstop, ready to be lifted after a target is released. The entire process is repeated.
In some embodiments, the helice equipment of the present disclosure automatically loads targets by bringing the target to the throwing motor, instead of the motor to the target, more closely mimicking manually-loaded equipment, where the target is placed at the motor by hand.
In some embodiments, the embodiments of the present disclosure may be used by individuals participating in the shooting sport of Helice. The linear loader would be filled with helice targets, and the shooter would activate the equipment by pressing a button—upon the shooter's calling “pull,” a target would be released from a random one of five machines set in front of the shooter. The shooter would then attempt to shoot the target and score a hit. Some unique features of the disclosed embodiments may include:
Conventional equipment has several shortcomings:
In some embodiments, the disclosure, due to its design, makes it possible to shoot any manufacturer's helice target, reduces time and labor, makes for a less expensive, quicker-paced sport, and affords a better experience for everyone involved. The equipment is lightweight and, unlike other equipment, can be lifted and placed with little effort; it also requires less maintenance, and repairs and maintenance are simple, with the vast majority of parts being readily available from auto parts supply stores and online mail-order stores. The decentralized design of the invention at hand allows for no connection between throwers nor any physical connections to a central control, thus overcoming problems with lightning strikes. Due to the novel design of the invention, it has little vibration, reducing or eliminating fastener failure, improving electrical and mechanical stability, and resulting in equipment that is extremely reliable.
The embodiments of the present disclosure can be utilized in shotgun shooting sports other than Helice; for example, the equipment can also be set to throw a non-random target for Sporting Clays disciplines, which do not utilize random targets.
This present disclosure describes embodiments of a flying target (helice targets, clay targets, plastic targets, skeet, and the like) launching machine that permits users to shoot targets without having to frequently reload the equipment. The disclosed embodiments make it possible for entities (e.g., shooting clubs) to reduce labor and allow users (e.g., shooters) to shoot more practice.
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The arm motor 16 may be disposed at the front section 19 of the base 18. For example, the motor 16 may be located between two beams 15a and 15b of the base 18. In some embodiments, the motor 16 may be supported by a platform 17 that may be supported (e.g., via columns/beams 13) by the base 18. The arm motor 16 may be located in a housing 77, such as a rectangular housing or a mounting housing. A feeder stop 75 may be coupled below the motor 16 (
A gear motor shaft 4 may be a cylindrical shaft and may be coupled to the arm motor 16 (e.g., a worm gear motor). For example, the shaft 4 may extend horizontally through the housing 77 of the arm motor 16, such that a right side of the gear motor shaft 4 may extend out of the right side of the housing of the motor 16 and the left side of the gear motor shaft 4 may extend out of the left side of the housing of the motor 16. The right side of the shaft 4 may be connected to a right rotating arm 20 extending vertically down from the gear motor shaft 4. A left side of the gear motor shaft 4 may be connected to a left rotating arm 20 extending vertically down from the gear motor shaft 4. The gear motor 16 may rotate the gear motor shaft 4, and the gear motor shaft 4 may rotate the right and left rotating arms 20.
Right and left target loading arms 8 may extend on the right and left sides of the arm motor 16. Each loading arm 8 may extend above the front section 19 of the base 18 to above the mid-section 21 of the base 18. Each loading aim 8 may include a cam assembly 22, which may couple (e.g., via a pin 34) to a corresponding right or left rotating arm 20. The end of each loading arm 8 closer to the mid-section 21 of the base 18 may include a corresponding arm extension 26, which may include a hook 24 disposed near backstop 14. The front ends of the loading arms 8 may be connected by a horizontally-positioned spring rod 9. According to some aspects, the loading arms 8 may each include a slot 28 disclosed in the front portion of the loading arm 8. The loading arms 8 may act to pivot about a pivot point at the slot 28 via a corresponding pivot extension 30 extending up from platform 17, such as when the loading arms 8 are lifting targets 6 and then lowering back down to a lower starting position. The pivot extension 30 may be tubular or any other shape. In some cases, the pivot extension 30 may include a horizontal shaft 29 that may interact and/or lock the arm 8 via the slot 28 with the pivot extension 30, and the arm 8 may pivot about the shaft 29.
The horizontal linear loader 12 may extend above the mid-section 21 of the base 18 to the rear section 23 of the base 18. The linear loader 12 may hold one or a plurality of targets 6. The linear loader may include one or more guiding poles 33 that may guide the targets 6 along the length of the loader 12. The rear of the linear loader 12 may include an end plate 50, which may be connected to the poles 33. Attached to an inner side of the end plate 50 may be a feeder stop 51. The linear loader 12 may include a round spring plunger 29 that may be coupled to a spring 31, where the plunger 29 and spring 31 may act to push or force the targets 6 loaded in the linear loader 12 toward the backstop 14 near the mid-section 21. For example, the linear loader 12 may include a pushing plate (plunger 29) and a spring mechanism (spring 31) that act to push the targets 6 against the backstop 14 via a drive plate 52. In some cases, the linear loader 12 may use an all thread to move targets 6 to set targets 6 against the backstop 14. A cover 32 may extend over the backstop 14 and/or a portion of the plurality of targets. The ends of the cover 32 may be connected to the base 18 (e.g., to beams 15a and 15b) at the mid-section 21.
The backstop 14 may be disposed near a first end of the linear loader near the mid-section 21 of the base 18. A first target 6 of a plurality of targets 6 may sit against the backstop 14, such that the right and left loading arms 8 via the corresponding arm extensions 26 and/or hooks 24 may lift the first target 6 up from the backstop 14. In some embodiments, the hooks 24 may lift a target 6 by hooking blades or extensions extending out from a central cap of the target 6. According to some aspects, responsive to or after a target 6 is lifted from the backstop 14, the pushing plate (plunger 29) and spring mechanism (spring 31) may push the next target against the backstop 14.
The oscillation motor 40 may be vertically positioned in front of the backstop 14 and may be coupled to a bracket 44 extending above the oscillation motor 40. The oscillation motor 40 may be partially or fully enclosed in a housing 41. The oscillation motor 40 may include or be coupled to a solenoid 43 and a stop 45 (
The oscillation motor 40 may operate to turn the throwing motor 10, where the turning of the throwing motor 10 spins the lifted target 6 held by the beak assembly 36. For example, the throwing motor 10 may spin the lifted target 6 on the beak assembly 36 via a linear actuator 38, and the linear actuator 38 may release the spinning target 6 from the beak assembly 36 (e.g., responsive to a voice activation or responsive to a manual switch by a user). In some embodiments, the linear actuator 38 may release the lifted target 6 by using plunger 47. In some embodiments, a Bluetooth device may be utilized to program and/or act as a control for the device 2 or for any part of device 2. In some embodiments, the throwing motor 10 may spin the lifted target 6 up to about 10,000 rotations per minute (e.g., before releasing the spinning target 6). In some embodiments, the throwing motor 10 may spin the lifted target 6 on the beak assembly 36 after the loading arms 8 are lowered from the lifted position. In some embodiments, the loading arms 8 lower back to a lower starting point after the lifted target 6 is disposed on the beak assembly 36.
In some cases, the beak assembly 36 may include one or more stops 46 that may contact the lifted target 6, and these stops 46 may include elastomeric material. For example, gravity may pull a metal male stop down into a notch and stops a carrier head in the same position on the notch. When carrier head is reversed, the male stop might have no effect and may allow the carrier head to spin freely. The stop action may orient the carrier head to allow for target insertion.
According to some aspects, any and/or all components described herein may be coupled and/or connected by any coupling means, including (but not limited to), screws, bolts, ties, welding, epoxy, and the like.
The term “about” as used herein will typically mean a numerical value which is approximate and whose small variation would not significantly affect the practice of the disclosed embodiments. Where a numerical limitation is used, unless indicated otherwise by the context, “about” means the numerical value can vary by +/−5%, +/−10%, or in certain embodiments +/−15%, or possibly as much as +/−20%. Similarly, the term “substantially” will typically mean at least 85% to 99% of the characteristic modified by the term. For example, “substantially all” will mean at least 85%, at least 90%, or at least 95%, etc.
While preferred embodiments of the disclosure have been described, it is to be understood that the embodiments described are illustrative only and that the scope of the disclosure is to be defined solely by the appended claims when accorded a full range of equivalence, many variations and modifications naturally occurring to those skilled in the art from a perusal hereof.
This application claims the benefit of and priority to U.S. Provisional Patent Application No. 62/685,109 filed on Jun. 14, 2018, and the benefit of and priority to U.S. Provisional Patent Application No. 62/807,450 filed on Feb. 19, 2019, which are both incorporated herein by reference in their entirety for any and all purposes.
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Number | Date | Country | |
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