Target practice is an important aspect of firearm training for law enforcement and other individuals. At indoor target ranges, paper targets are typically hung by a hanger on a wire that can be moved out any desired distance from the shooter. Unfortunately, indoor target ranges can be expensive, crowded, noisy, and are not available in all areas.
Often, those desiring target practice head outdoors. Target shooting is permitted on a lot of federal land and on private property. In addition to overcoming the shortfalls of indoor target ranges, outdoor ranges allow shooters to be outdoors, often with more space around them, at little or no cost.
At outdoor target ranges, targets are often tacked to cardboard boxes, fallen trees, strung between trees or other objects in the field, etc. These targets are often unstable and may fall over during target practice and need to be set up again several times during the course of target practice.
Professional targets are available, but often have to be manually reset. The primary drawback is having to walk down the firing range to reset the target after it has been hit. Not only is this time consuming, but can also be dangerous if other shooters are present.
An axial reset target structure is disclosed for supporting targets during target practice. An example axial reset target structure includes a base member with a base ramp. The example axial reset target structure also includes a target mounting member for mounting a target thereto. The example axial reset target structure also includes a mounting ramp in the target mounting member. The example axial reset target structure has at least one firing position for firing at the target mounted to the target mounting member. The example axial reset target structure also has a hit position when the target is struck. The mounting ramp rotates in a first direction relative to the base ramp to move the target mounting member away from the base member in the hit position. The target automatically resets to the firing position. The example axial reset target structure is readily assembled for use in a variety of different operational configurations with a variety of different types of targets.
The axial reset target is a target system designed to allow for dynamic multi-target systems and automatically resetting targets without the need for the shooter to manually reset targets. The system uses a single helical ramp, or a group of integrated helical ramps, which causes horizontal movement of the target into vertical motion. This vertical motion is resisted axially. Examples include, but are not limited to resistance by gravity or a device such as a magnet, tension spring, or compression spring, air bags, pistons, compressible and resilient foam and/or rubber, or a weighted configuration. This force is applied axially through the axis of rotation and does not need to be angled in order to function.
When in motion, the motion of the target is resisted by the force through the helical ramp, and upon its first impact with a stopping point, the remaining kinetic energy is insufficient to climb the ramp again against this resistance. The force then pulls the target into a final resting position at the bottom of the ramp, resetting the target without the need for intervention from the shooter.
This mechanism and the target itself can be separated, allowing for the replacement of targets due to wear or in order to change function. Additionally, different slotting allows targets to be placed in the mechanism at angles from 0 to 30 degrees, in order to allow for safe operation by deflecting projectiles down towards the ground.
The example axial reset target structure can be implemented for use with horizontal shooting targets and vertical shooting targets. The example axial reset target structure enables a user to change various types and sizes of targets quickly and easily in the field.
Before continuing, it is noted that as used herein, the terms “includes” and “including” mean, but is not limited to, “includes” or “including” and “includes at least” or “including at least.” The term “based on” means “based on” and “based at least in part on.”
It is also noted that the examples described herein are provided for purposes of illustration, and are not intended to be limiting. Other devices and/or device configurations may be utilized to carry out the operations described herein.
The operations shown and described herein are provided to illustrate example implementations. It is noted that the operations are not limited to the ordering shown. Still other operations may also be implemented.
In an example, the target 12 may be removably inserted into the axial reset target structure 10 to be interchangeable with other targets or target mounts. For example, the target 12 is illustrated in
The example axial reset target structure 10 includes a base member 18 having an upper portion 20a and a lower portion 20b. A base ramp 22 is provided in the upper portion 20a of the base member 18. The base ramp 22 has a first mating surface (e.g., the top or outside surface). The example axial reset target structure 10 also includes a target mounting member 24 having an upper portion 26a and a lower portion 26b. The target mounting member 24 is for mounting a target 12 thereto, as discussed above with reference to
A hit position 30c, 30d is provided for when the target 12 is struck by a projectile (e.g., in the direction illustrated by arrow 31). The hit position 30c may be defined as any position behind the firing position(s) 30a, 30b (e.g., just less than 180 degrees between 30a and 30b). The hit position may be referred to herein as a full hit position 30d, when the target 12 is perpendicular to the firing position(s) 30a, 30b. In the hit position 30c, 30d, the mounting ramp 28 rotates in a first direction (e.g., illustrated by arrow 32a or 32b) relative to the base ramp 22 to move the target mounting member 24 away from the base member 18 (e.g., in an upward or vertical direction) as the target mounting member 24 “climbs” the base ramp 22. It is noted that if the target 12 is in firing position 30b, that the first direction is opposite that illustrated by arrow 32a.
The target 12 may be reset to either firing position 30a, 30b. For example, the target 12 may be manually reset by the user. In an example, the target automatically resets to at least one of the firing positions 30a, 30b. Automatic reset is discussed in more detail below with reference to
The terms “first” and “second” as these are used herein to refer to direction are not intended to be limiting, and are only used to distinguish between different directions. In an example, the first direction is opposite the second direction. For example, the first direction may be clockwise and the second direction is then counterclockwise. Or for example, the first direction is counterclockwise and the second direction is clockwise.
In an example, the first mating surface 40 of the base ramp 22 on base member 18, and the second mating surface 42 on the mounting ramp 28 of the target mounting member 24 are helical in shape. Other shapes may also be implemented, as will be understood by those having ordinary skill in the art after becoming familiar with the teachings herein.
In an example, the first mating surface 40 of the base ramp 22, and the second mating surface 42 of the mounting ramp 28 are at least partly congruent with one another. That is, the shapes of the ramps are identical when superimposed over one another, but when one is turned upside down relative to the other, the two surfaces mate with one another. Rotation between the base member 18 and the target mounting member 24 causes the base member 18 and the target mounting member 24 to move away from each other.
In an example, when the target 12 is struck, the force of the projectile on the target 12 causes the target 12 to rotate (e.g., from one of the firing positions shown in
The target mounting member 24 moves axially back toward the base member 19, returning the target 12 to one of the firing positions. In an example, when the target 12 is struck, the target mounting member 24 moves vertically or axially upward from the base member 18, and then returns or resets by moving vertically or axially downward toward the base member 18.
In an example, the reset member 52 may be attached to the bottom of cylinder or post member 48 of the target mounting member 24, and extends through receiving chamber 46 of the base member 18 and is attached thereto (e.g., by a plate 44 under the opening at the bottom of reset chamber 43 under the receiving chamber 46). It is noted that receiving chamber 46 may house other return mechanisms and reset member 52 is not limited to being a “spring”. The reset member 52 (e.g., a spring mounted to both the target mounting member 24 and the base member 18), biases the target mounting member 24 and the base member 18 toward each other (e.g., in one of the firing positions shown in
In an example, the reset member 52 applies a force on the target mounting member 24 and pulls the target mounting member 24 back toward the base member 18. This downward motion rotates the mounting ramp 28, and hence the target 12, in the second direction relative to the base ramp 22 to automatically reset the target 12 in the firing position.
It is noted that any suitable reset member 52 may be provided. For example, the reset member 52 may be at least one magnet, at least one compression spring, at least one tension spring, at least one of a piston, a piston spring, an air spring, an airbag, a vacuum chamber, and compressed gas. In an example, the reset member 52 is at least one of a compressible and resilient material (e.g., rubber) that tends or biases the target mounting member 24 toward the base member 18, while the ramps 22 and 28 rotate the target 12 back to the firing position, as illustrated by
The first mating surface 40 of the base ramp 22 mates with the second mating surface 42 of the mounting ramp 28 in a first firing position (see, e.g., firing position 30a in
The mounting ramp 28 rotates in a first direction (e.g., illustrated by arrows 32a, 32b in
In an example, the mounting ramp 28 rotates in a second direction (e.g., illustrated by arrows 32c and 32d, or 32e) relative to the base ramp 22 to return the target mounting member 24 back to the first firing position thereby resetting the target 12 for firing.
In another example, the mounting ramp 28 rotates again in the first direction after being fired on (e.g., continuing in the direction illustrated by arrows 32a, 32b) to continue to move or rotate the target mounting member 24 into a second firing position (e.g., illustrated at 30b in
It is noted that, depending on the force of the projectile, the target 12 may rotate fully between firing positions 30a and 30b, keep returning to position 30a, keep returning to position 30b, and so forth. For example, moving between firing positions 30a and 30b may indicate a more direct hit (better shot), versus a glancing blow by the projectile on the target 12. Other factors that may affect rotation of the target 12 may include the type of projectile, distance to the target, etc.
While the axial reset target structure 10 has been described herein with reference to a target 12 mounted to a single structure 10, it is noted that multiple axial reset target structures 10 may be implemented to support a larger target.
It is noted that the examples shown and described are provided for purposes of illustration and are not intended to be limiting. Still other examples are also contemplated.
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Number | Date | Country |
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467755 | Sep 1992 | SE |
Entry |
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Robert Zalar, “Sophia Target Shooting,” https://www.youtube.com/watch?v=hBOQ2KMtsFU, uploaded Nov. 4, 2015 (Year: 2015). |
English machine translation of Pilskaer (SE-467755-B) (Year: 1992). |
Number | Date | Country | |
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20230324151 A1 | Oct 2023 | US |