The present disclosure pertains to a target stand, and more particularly to a target stand configured to move a target object under test.
Destructive testing may be used to measure or characterize the performance of an object under test. Typically, destructive testing is conducted in accordance with a test specification which defines time-consuming and sometimes difficult-to-execute test procedures. An example of destructive testing is when the object under test is subjected to projectile penetration. One example is a battery having a 6T form factor, as described in MIL-PRF-32565 (17 Nov. 2016), the entirety of which is incorporated herein by reference. Here, the battery is expected to not exceed SAE J2464 Hazard Severity Level 4 when the battery case is penetrated by three 7.62 mm armor piercing incendiary projectiles.
According to one non-limiting embodiment of the disclosure, a target stand is described. The target stand may comprise a frame; a first rail; a second rail; and a trolley. The frame may support the first and second rails, wherein the first and second rails are inclined and each have an upper end and a lower end, wherein the first and second rails each extend relative to a y-axis and a z-axis, wherein the second rail is spaced from the first rail relative to an x-axis. The trolley may comprise a base, a first wheel assembly coupled to the base and in contact with the first rail, and a second wheel assembly coupled to the base and in contact with the second rail, wherein the trolley is movable between the respective lower ends of the first and second rails and the respective upper ends of the first and second rails via the first and second wheel assemblies contacting the first and second rails. The base of the trolley may comprise a proximal portion and a cantilevered portion extending away from the proximal portion to a free end, wherein the first and second wheel assemblies are coupled to the proximal portion and the cantilevered portion extends over the first and second rails.
Figure (
Turning now to
By firing multiple projectiles P relative to axis x and by moving trolley 24, a front face F of target B may be impacted at several different points without moving the projectile source 14. As shown in
Test system 10, and more particularly target stand 20, may facilitate testing in accordance with stringent projectile penetration requirements for objects such as target B. As described more below, target stand 20 may be used to fulfill requirements that define a relatively small impact region and/or projectile grouping such as those set forth in MIL-PRF-32565. For purposes of aiding a non-limiting explanation herein, test system 10 will be explained below with respect to testing a STANAG 4015 battery having a 6T form factor using 7.62 mm armor piercing incendiary (API) projectiles (fired from a 7.62 mm compatible weapon) wherein the 7.62 API projectiles impact front face F at an angle normal to the face F, as defined in MIL-PRF-32565. However, it will be appreciated that test system 10 may be used with different test objects under test, using different projectiles/projectile sources, at different angular orientations, etc. Thus, while a test system is described that facilitates military performance testing, test system 10 may be used for commercial and industrial testing as well (e.g., and in some circumstances, test system 10 may be applicable testing targets for police, private security, and/or other suitable entities).
The range 12 of test system 10 may be any suitable firing range. Range 12 is defined as a longitudinal region between the firing line 16 and an optional backstop 30 (or a sufficient longitudinal distance so that persons, objects, etc. are not disrupted by projectiles P). Thus, range 12 may include target line 28. Optional backstop 30 may include a hill of soil, a man-made structure for slowing projectiles, etc. Range 12 may be equipped with known safety systems (not shown) to promote safety of the users of the range. Additionally, range 12 may operate with predetermined protocols—e.g., regarding when operators are free to resume fire following a technician being down-range (e.g., anywhere between the firing line 16 and backstop 30). As explained below, execution of range protocols may be time-consuming during testing as delays may occur each time a technician enters the range 12, makes an adjustment to the target stand 20, and then exits the range. Range 12 may be suitable for large-caliber weapons, firing rifles, shotguns, handguns, other small arms, cross- and other bows, etc.
Projectile source 14 refers to any machine which propels projectiles P. Non-limiting examples include large-caliber weapons, rifles, shotguns, handguns, other small arms, cross- and other bows, and the like. Projectile source 14 may be supported by a stand or other suitable structure 34. Stand or other suitable structure 34 may permit a human user to fire the projectile source 14 without moving or disturbing the aim of source 14; alternatively, projectile source 14 may be fired by stand itself or by some other suitable mechanism (e.g., as in a weapon station). Some non-limiting examples of stand or other suitable structure 34 include a tripod stand, a pedestal stand, any suitable rest, recoil-reducing devices, or a combination thereof. In at least one example, projectile source 14 is 7.62 mm compatible weapon, projectiles P are 7.61 mm API, and the stand or other suitable structure 34 is a pedestal stand that positions the 7.62 mm compatible weapon so that its projectiles P strike front face F of target B normal to the front face F.
Turning to
Frame 22 may be any structure suitable for supporting trolley 24 and facilitating movement thereof. In at least one example, frame 22 comprise a front side portion 42, a rear side portion 42′, an end bracket 46, and an end bracket 48. In at least one embodiment—but not required, front and rear side portions 42, 42′ may be identical and may be oriented as mirror images of one another; therefore, only one will be explained in detail.
Front side portion 42 may comprise a first upright member 50, a second upright member 52, a lower strut 54 extending between and coupling corresponding lower portions of first upright member 50 and second upright member 52, and an inclined member 56 (extending between and coupling corresponding upper portions of first and second upright members 50, 52). In some embodiments (although not required), inclined member 56 may have a hockey stick shape comprising a body 58 and a flange 60 coupled to and extending from body 58, wherein an end portion 62 of body 58 may be coupled to an upper portion 64 of first upright member 50, wherein an end portion 66 of flange 60 may be coupled to an upper portion 68 of second upright member 52. In at least one example, front side portion 42 may be formed in a single, unitary piece; however, this is not required.
Inclined member 56 (more particularly, body 58) is shown oriented at angle α (
Inclined member 56 may comprise a plurality of holes 70 (e.g., through-holes) which may be spaced linearly along at least a portion of the length of inclined member 56. According to an example, these holes 70 may be extend from an outboard face 72 to an inboard face 74 along a lower region 76 of the inclined member 56. And in at least one embodiment, these holes 70 are aligned in a straight line. As will be discussed more below, these holes 70 may be used to move the trolley 24 a predetermined (and incremental) distance along the target stand 20. The spacing between any two holes 70 may vary; accordingly, the incremental distances may vary as well.
Target stand 20 further may comprise a pair of rails 80, 80′ (e.g., a first rail and a second rail, respectively); rails 80, 80′ may be spaced from one another relative to the x-axis. In at least one example, these rails 80, 80′ may be identical and may be oriented as the mirror images of one another (e.g., rail 80 may be coupled to inclined member 56 and rail 80′ may be coupled to inclined member 56′). Thus, only one will be described in detail.
Rail 80 may extend along inboard face 74 at an upper region 82 (of inclined member 56); it may be coupled to inclined member 56 via any suitable technique (e.g., fasteners, welding, etc.). Rail 80 may comprise an upper end 84 and a lower end 86 having an inclined orientation (extending relative to the y- and z-axes)—e.g., in at least one embodiment, rail 80 extends parallel to body 58. Other examples also exist; e.g., rail 80 may have an orientation according to any of the orientations of inclined member 56, as described above. Further, in at least one example, the orientation of rail 80 may differ from that of inclined member 56.
As best shown in
Locating the rails 80, 80′ on inboard faces 74, 74′ of the rails 80, 80′, respectively, offers some ballistic protection during live-fire testing; however, other embodiments of rails 80, 80′ also may be used. E.g., rails 80, 80′ could be mounted on an upper surface of each of the respective inclined members 56, 56′ so that channels 87, 87′ face upwardly instead of inwardly.
As discussed above, rear side portion 42′ may comprise similar features. Each feature is designated using an apostrophe (′), and for sake of brevity, will not be re-described here.
End bracket 46 may comprise a rectangular border 94 which comprises, among other things, a side 96 and a side 98 (which is opposite side 96). Sides 96, 98 may be coupled to (and between) front and rear side portions 42, 42′, respectively. In the illustrated embodiment, end bracket 46 also comprises a criss-cross brace 100 extending within and coupled to border 94; in other embodiments, a different brace may be used or no brace may be present.
End bracket 48 may be similar to end bracket 46, except it may be taller to accommodate the height of the target stand 20 on an opposite end; thus, frame 22 has a high end 48H (corresponding to end bracket 48) and a low end 46L (corresponding to end bracket 46), wherein the frame 22 slopes downwardly from high end 48H to low end 46L with respect to the y- and z-axes. For example, end bracket 48 may comprise a rectangular border 104 which comprises, among other things, a side 106 and a side 108 (which is opposite side 106). Sides 106, 108 may be coupled to (and between) front and rear side portions 42, 42′, respectively. In the illustrated embodiment, end bracket 48 also comprises a criss-cross brace 110 extending within and coupled to border 104; in other embodiments, a different brace may be used or no brace may be present.
Frame 22 may comprise other features as well. E.g., in the illustrations, frame 22 includes a first stanchion 112 and a second stanchion 114. First stanchion 112 may extend between inclined members 56, 56′ (and more particularly, between flanges 60, 60′). Second stanchion 114 may extend between lower strut 54 (of front side portion 42) and lower strut 54′ (of rear side portion 42′). In the illustrated embodiment, first stanchion 112 is positioned directly above second stanchion 114; however, this is not required in all embodiments. In at least one embodiment, frame 22 further comprises adjustable feet 116. E.g., feet 116 may facilitate leveling frame 22 when the ground is uneven (see
It should be appreciated that the figures illustrate an embodiment of frame 22 and that other embodiments could be employed that suitably support trolley 24 and movement of trolley 24, as described more below. Further, frame 22 may be comprise of any suitable material. E.g., frame 22 may be composed of metal or composite; non-limiting examples include aluminum, steel, high hard steel, or the like. Further, couplings of the elements of frame 22 may include any suitable fasteners (screws, bolts, etc.), weldments, etc.
According to an embodiment, trolley 24 may comprise a base 120, an actuator bracket 122 coupled to the base 120, a first wheel assembly 124, and a second wheel assembly 124′, wherein the first and second wheel assemblies 124, 124′ each may be coupled to base 120 and actuating bracket 122. Each will be discussed in turn.
Base 120 may be any suitable platform for carrying target B. In the illustrations, it is illustrated as rectangular plate (oriented with respect to (e.g., parallel to) the x- and y-axes) having a proximal portion 130 and a cantilevered portion 132, wherein the proximal portion 130 is nearer the first and second wheel assemblies 124, 124′, wherein the cantilevered portion extends over the rails 80, 80′. As used herein, the base 120 comprising cantilevered portion 132 may refer to the base 120 being a rigid structural element and being supported at only one end (in this case supported only at the proximal portion 130 and not at the cantilevered portion 132). In at least one embodiment, an edge 134 of the proximal portion 130 is coupled to the actuator bracket 122, and a free end 136 in the cantilevered portion 132 is not coupled to anything. As will be clarified more in the description below, cantilevered portion 132 may be suitable for live fire testing as target B is positioned away from the remainder of the target stand 20 so as to minimize damage of the target stand 20 due to stray projectiles P. Base 120 may be sized to fit and move between the front and rear side portions 42, 42′ of frame 22. In at least some examples, base 120 may be configured to be slightly larger than the intended target; however, this is not required. Other embodiments of base 120 are also contemplated. While not shown, base 120 may comprise additional straps, brackets, etc. to retain target B thereto during testing.
Actuator bracket 122 may comprise any suitable plate that extends away from base 120 and is used to move the trolley 24 on frame 22. In the illustrated embodiment, actuator bracket 122 extends upwardly and is oriented with respect to (e.g., parallel to) the x- and z-axes such that an edge 138 is coupled to edge 134. This is merely an example, and actuator bracket 122 may have different shapes or sizes in other embodiments.
In at least one example, actuator bracket 122 may comprise a T-bracket or other suitable bracket 140 on a side 142 (side 142 facing away from base 120). In the illustrations, bracket 140 comprises a feature 144 (e.g., holes) for coupling to actuator 26. In this manner, actuator 26 may pull the trolley 24, as explained more below.
First wheel assembly 124 and second wheel assembly 124′ may be mirror images of one another; therefore, only one will be described in detail. That said, first and second wheel assemblies could differ from one another; an example of a wheel assembly follows. First wheel assembly 124 may comprise a wheel portion 150 and a stopper portion 152.
Wheel portion 150 may comprise a carrier 154 which may comprise an elongated plate having axle holes (not shown) with a plurality of (or set of) wheels 158 carried via the axle holes (see
Stopper portion 152 may comprise a flange portion 162 extending from one side 164 (downwardly) of carrier 154, a spacer 166, and a clip 170. In some examples, carrier 154 and flange portion 162 may be formed in one unitary piece; however, this is not required. The carrier 154, the flange portion 162, or both may be coupled to outer edges 172, 174 of the base 120 and actuator bracket 122, respectively—giving the trolley 24 rigidity and a robustness for live-fire testing.
Spacer 166 may be any suitable protrusion that extends radially outwardly from outboard side 160 of flange portion 162. In the illustrated example, spacer 166 is a rectangular block having a first side 178 that abuts and is coupled to outboard side 160 and an opposite side 180 that abuts clip 170; however, other shapes may be used instead. The span between sides 178, 180 of spacer 166 may be sufficiently large so as to permit clip 170 to engage the holes 70 along inclined member 56 as the trolley 24 moves via actuator 26 and rails 80, 80′. In some embodiments of stopper portion 152, the spacer 166 and clip 170 are integrated into a single element; in other embodiments, the spacer 166 is not required.
According to an embodiment shown in the illustrations, clip 170 comprises a spring 186 and a unidirectional lock 188. In this example, spring 186 comprises a first leg 190 that is coupled to side 180 of spacer 166, a second leg 192 (shown in a nominal position) having a free end 194, and a U-shaped bend 196 coupled to first and second legs 190, 192 (one leg extending from each end of bend 196). When the free end 194 of the second leg 192 is displaced toward the first leg 190 (i.e., radially inwardly) (to a displaced position), U-shaped bend 196 is biased to cause the second leg 194 to return to the nominal position (biased radially outwardly). The free end 194 of second leg 192 may be oriented toward (and positioned closer to) actuator bracket 122 (and end bracket 48 of frame 22), whereas the U-shaped bend 196 may be oriented toward (and positioned closer to) free end 136 of trolley 24 (and accordingly, closer to end bracket 46 of frame 22). While not required in all embodiments, spring 186 may be oriented parallel to rail 80.
Lock 188 may comprise a ramped projection 200 coupled near free end 194 and extending radially outwardly from second leg 192. In at least one embodiment, ramped projection 200 has a circular periphery 202; however, this is not required. Ramped projection 200 may be sized to fit without interference into any of holes 70 of inclined member 56 (of frame 22)—e.g., as trolley 24 moves between inclined members 56, 56′. More particularly, lock 188 may comprise a low edge 204 and a high edge 206 and a radially-outwardly facing surface 208 that gradually slopes from low edge 204 to high edge 206. Low edge 204 may be nearer free end 194, and high edge 206 may be nearer the U-shaped bend 196. Based on this orientation (and as described more below), trolley 24 may be moved (by actuator 26) toward upper ends 84, 84′ of rails 80, 80′—and as the trolley 24 is moved in this direction, free end 194 of second leg 192 of spring 186 may bend radially inwardly as lock 188 contacts the inboard face 74 of inclined member 56 (i.e., between the holes 70) and lock 188 may enter holes 70 as the trolley 24 moves into a corresponding position, wherein a radially extending side 210 of periphery 202 may inhibit trolley 24 from moving toward lower ends 86, 86′ of rails 80, 80′, respectively—e.g., when actuator is OFF or inactive.
The illustrated arrangement is merely an example. Other suitable springs and locks may be used instead. Spring 186 may be any suitable mechanism including but not limited to a compression springs, torsion springs, clock springs, various flat-form springs, various wire-form springs, and the like, just to name a few examples. Similarly, lock 188 may be any device that engages the inclined member 56 to cause the trolley 24 to brake and/or be retained in a desired position. Hence, non-limiting examples of lock 188 may comprise other protrusions, calipers, etc. Lock 188 and spring 186 may be integrated in a single piece or may be two elements that are coupled to one another.
According to at least one embodiment, only one of the first or second wheel assemblies 124, 124′ comprise stopper portion 152. According to another embodiment, both of the first and second wheel assemblies 124, 124′ comprise stopper portion 152.
Turning now to the actuator of target stand 20, according to one embodiment of actuator 26, actuator 26 may comprise a cable 220 and a cable feed system 222 (see
Cable feed system 222 may comprise any suitable elements to physically route the cable 220—while also permitting cable translation (in either direction) and cable turns (e.g., at a corner or bend). In the illustrated example (see
Trolley 24 may be comprised of any suitable metal or composite material. Actuator bracket 122 may be fastened or welded to base 120. Similarly, wheel assemblies 124, 124′ may be fastened or welded to actuator bracket 122 and/or base 120. Wheels 158 of trolley 24 may be located within rails 80, 80′; thereafter, rails 80, 80′ may be assembled to frame 22. Once frame 22 and trolley 24 are assembled, cable feed system 222 may be coupled to frame and trolley, and thereafter, cable 220 may be routed as previously described.
As disclosed above, when the actuator 26 is actuated, the trolley 24 may be moved incrementally in at least one direction. According to the embodiment previously described, trolley 24 may move upwardly (e.g., toward upper pulley 228). Lock 188 (and a corresponding unidirectional lock on wheel assembly 124′ (not shown)) may detent through a number of holes 70 of inclined members 56, 56′. In this manner, if the target (located on base 120) is aligned with a firing path of projection source 14, trolley 24 may be inhibited from moving downwardly. Further, a predetermined sequence of trolley positions may be achieved by moving trolley 24 until the locks 188 are positioned in the desired holes 70.
Other target stand examples also exist. According to an example, inclined members 56, 56′ may have at least some curvature. E.g., the previously described inclined members (and rails) were illustrated as straight; however, this is not required in all examples.
In at least one embodiment, target stand 20 is equipped with an electrical harness that is secured to the frame 22 at a first point and to trolley 24 at a second point in such a manner that the electrical harness dangles sufficiently between the first and second points to permit movement of trolley 24 from an upper end of inclined members 56, 56′ to a lower end thereof—and it such a manner that the electrical harness does not create interference of such movement. In this manner, when target B is a battery, the battery may be connected to a resistive load (not on the trolley 24) during live fire testing. In other embodiments, the resistive load is carried by the trolley 24 as well (and no harness-routing on frame 22 is required).
Still other embodiments exist. For example,
In another embodiment, the wireless communication could be replaced with a wired link. E.g., an electrical cable could extend from the interface 246 to the motor 240.
Still other examples exist as well. For example, channels 87, 87′ of rails 80, 80′ may include a rack gear, and wheels 158 of trolley 24 may comprise corresponding pinion gears. In such an embodiment, the trolley could move upwardly or downwardly incrementally or otherwise. This arrangement may be used in conjunction with actuator 26, actuator 26A, or another actuator configuration. Further, other implementations could be employed that permit the trolley to move upwardly toward the upper ends 84 of rails 80, 80′ or to move downwardly toward the lower ends 86 of rails 80, 80′.
Each of
According to an example, front face F of target B may be positioned co-planar with respect to plane-YZ (e.g., shown in
Each face F, R, LS, RS of the target B may have an impact region, wherein the impact region may be an area within which projectiles P are to strike the target B; a front impact region 300 is shown in
MIL-PRF-32565 requires (a) three projectiles P to impact within impact region 300; (b) that each of the impacts are to be at least 50 mm on center from one another; (c) that each projectile strike the impact region 300 at a 90° angle; and (d) that the first projectile strike the target B within 90 seconds of the third projectile. It will be appreciated that projectiles P are fired at target B from a distance—and while some degree of accuracy is attainable—perfection is typically not possible. For instance, in some examples it is desirable to perform live fire testing of 7.62 mm projectiles at a distance between 8 and 100 meters. Accordingly, the target stand 20 facilitates striking the impact region 300 (or 302). Using the target stand 20 which raises the trolley 24 and target B diagonally, a span S of the impact region 300 can be utilized without moving the projectile source 14 (i.e., without moving the weapon). Since span S is longer than the width (w) or height (h) of impact region 300, the space between projectiles can be increased thereby increasing the likelihood that three projectiles P can be fired at the target B and that all requirements of MIL-PRF-32565 can be met. Further, since the trolley 24 can be remotely moved (e.g., by a user of the projectile source 14 up-range), the 90 second requirement may be more easily achievable.
It will be appreciated that though MIL-PRF-32565 identifies an electric battery as the targeted object under test. Other examples of target B also could be used instead—e.g., such as bulletproof glass, bulletproof vests, armor or armor plating, etc. Target stand 20 may be adapted to meet other military requirements regarding timing of projectile firing and projectile spacing. Further, it should be appreciated that while a few example targets have been listed; this list is not intended to be exhaustive, nor is the target stand 20 intended to be limited to military testing. E.g., commercial security, police, and other industries similarly may design and implement target stand 20 for testing of any suitable projectile testing.
Thus, there has been described a target stand for a range. The target stand includes a frame and trolley that is adapted to carry a target. The trolley comprises a base; the base comprises a proximal portion that is coupled to a pair of wheel assemblies and a cantilevered portion that protrudes away from the proximal portion. According to an example described above (and not intending to be limiting), the trolley may be actuated to move diagonally upwardly with respect to the frame so that multiple projectiles may be fired at the target from an up-range position and so that a relatively-small impact region may be struck in accordance with a predetermined spacing.
Embodiments of the present disclosure have been described above. It is to be understood, however, that the disclosed embodiments are merely examples and other embodiments can take various and alternative forms. Further, it is contemplated that one or more embodiments may be combined with one another—regardless of whether such various combinations of embodiments are explicitly illustrated in the figures or described in the written description.
The figures are not necessarily to scale; some features could be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the embodiments.
In addition, relative terms in the detailed description or in the claims such as “upper,” “lower,” “middle,” “above,” “over,” “b el ow,” “under,” “front,” “back,” “forward,” “rearward”, “right,” “left,” and the like are not intended to be limiting; instead, such terms are used to illustrate, to enhance explanation, to explain relative positions of the elements, etc. Terms in the detailed description or in the claims such as “first,” “second,” “third,” etc. are not intended to be limiting either; instead, such terms are used merely to differentiate elements from one another or the like.
Herein, the term “coupled” refers to either “coupled directly” or “coupled indirectly”. For example, where a structure comprises X coupled to Y and Y is further coupled to Z, then X may be referred to as “coupled” to Z. Additionally, X may be referred to as “indirectly coupled” to Z and “directly coupled” to Y. Thus, where the detailed description or claims recite “coupled”, this term means either “coupled directly” or “coupled indirectly”. Alternatively, if the detailed description or claims mean coupled directly or coupled indirectly, it explicitly uses the terms “directly” or “indirectly”.
The invention(s) described herein may be manufactured, used, and/or licensed by or for the Government of the United States of America without payment by the Government of any royalties thereon.