The present invention relates to a machine for launching targets and a method for adjusting this machine.
It can be used in the field of projecting targets for ball trap shooting for which targets in the shape of plates in the shape of a saucer, often called clay pigeons, are used.
Machines allowing targets to be launched have been known for several decades. These machines generally use a rotatably mounted launching arm loaded, for example by a spring tension system, in such a way that the triggering of the rotation of the arm, on command, generates a quick movement of the arm. The latter intercepts a target placed on a projection surface and the target is projected at a fast speed.
In the most highly developed machines, it is possible to launch a large number of targets without reloading the machine. For this purpose, the machine comprises a magazine for storing targets, the targets being delivered one by one to the projection surface. One magazine design comprises a barrel having a movement of rotation. The barrel incorporates a plurality of columns allowing each to store a plurality of superimposed targets. The rotational movement of the barrel ensures the sequential positioning of one of the columns opposite a hole allowing the delivery of the target placed the lowest in the column to the projection surface.
Generally, the sequential rotation of the barrel (the angular pitch of which is dependent on the number of columns) is coupled to the rotational cycle of the arm, one cycle of the arm generating a movement of the barrel in such a way as to place a following column opposite the hole and thus, by this circular movement, progressively empty the columns of the barrel.
On the basis of this technology, the offer of a variety of shooting possibilities was sought, so as to multiply the exercise configurations of the ball trap. One of the possibilities involves varying the direction of rotation of the launching arm in order to produce a projection by the right side or by the left side of the machine. Machines were thus proposed for which the arm, and thus also the barrel, rotate in the counterclockwise direction and, in addition to the machines for which the arm and the barrel rotate in the clockwise direction. As a result, there needs to be a plurality of specific machines—at least two—in order to provide this variety of shots.
There is a need to allow target-launching alternatives, in particular with different rotations of the arm, without leading to a multiplication of the costs. Also, in general, there is a need to adjust the direction of projection of the machines.
The present invention relates, according to one aspect, to a machine for launching targets, comprising a chassis on which a support is mounted, relative to which a barrel is mounted rotatably about an axis of rotation, the barrel comprising a plurality of columns for storing stacked targets, the columns each having a longitudinal axis parallel to the axis of rotation, the chassis comprising a surface for receiving targets for a launch, the support comprising a hole configured to allow the passage of a target from a column of the barrel to the receiving surface.
According to an advantageous aspect, the support comprises a first locking position with respect to the chassis and at least a second locking position with respect to the chassis, the first position and the second position having an angular offset in a direction parallel to the axis of rotation.
The direction of projection of the target can thus be adjusted. This is useful in particular for compensating for the effects of the inertia of the target passing through the hole. More specifically, the target in question passes through the hole after having first been subjected to a force, substantially tangential to the trajectory of the barrel, due to the rotation of the latter. The target does not therefore fall onto the receiving surface with only its weight being applied, but also with a component related to its inertia in this movement caused by the rotation of the barrel. In practice, the target does not reach the receiving surface exactly vertically in line with the hole, but in a slightly offset manner.
The presence of two angular positions for the support allows the position of the hole to be moved in order to take into account the natural offsetting of the target. One use for this adjustment is to allow operation of the machine either in a first direction of rotation of the arm or in an opposite direction while keeping the same direction of rotation of the barrel (and thus avoiding the need to design and produce barrels dedicated to a single direction of rotation of the arm). In practice, because of the invention, the user can use the machine in a direction of rotation of the arm corresponding to that of the barrel, then simply mount the arm (and optionally the receiving surface) in order for the arm to rotate in the opposite direction and produce a target launch on another side of the machine. As for the barrel, it remains in place and its direction of rotation is not modified. The position of the target falling onto the receiving surface is simply corrected by modifying the angular position of the support, in order to take into account the fact that the barrel and the arm rotate in opposite directions this time. A fixed starting position of the target, on the receiving surface, with respect to the arm is thus always ensured. Only the direction of rotation of the arm is modified.
Thus, a modifiable machine with two directions of rotation of the arm is provided by simply adding one or more supports for locking the receiving surface and especially by using 100% of the parts of the original machine; the manufacturing is standardized.
The adjustment of a trajectory is obtained by an angular adjustment of the base of the machine with respect to its support. This is a very simple and very quick operation. Modifying the position of the barrel in order to obtain a similar effect would take much longer to carry out especially if the machine is full.
The invention also relates to a method.
The invention will be better understood with the drawings appended to the present description, which present non-limiting embodiments of the invention in the following drawings:
Before describing embodiments of the invention, in particular in reference to the drawings, options that the invention can optionally have in any possible combination are presented below.
In reference to
The system for actuating the launching arm 9 functions in a cyclical manner in such a way that, after the release of the spring, the launching arm 9 is brought back from a rest position to a reloaded position via the action of the motor 7.
Such a machine allows the launch of at least one target 13 during such a movement. In order to make the machine autonomous in the launching of a large number of targets 13, the machine advantageously comprises a barrel 3 in which a plurality of targets 13 can be stored. More specifically, the barrel 3 comprises a plurality of columns 4, these columns extending in parallel to each other and being organized in an angular sector, at the edge of the barrel 3, around an axis 10. The number of columns 4 is not limited. Each column 4 is for example defined by rods 5 extending along the axis 10 and acting as lateral stop surface for the targets 13 that are stacked in each of the columns 4. Thus, sets of targets 13 superimposed on each other are formed. In the upper portion of the barrel 4, an upper frame 6b is advantageously positioned in order to connect together all the distal ends of the rods 5. In the lower portion, the barrel 3 advantageously comprises a lower frame having the same function as the upper frame but in order to connect together the proximal ends of the rods 5. The terms “lower” and “upper” are, unless another arrangement is made in the present description, to mean a relative position of parts with respect to the action of gravity in the movement of the targets 13.
As shown, the lower frame 6a defines openings for each column 4 in such a way that a target 13 placed in the lowest position in a column 4 is capable of being extracted from the barrel 3 by its lower end. At this location, on the wall of the lower frame 6a opposite the rest of the barrel 3, there is a support 2 allowing the targets 13 to be retained in the columns 4 by opposing gravity. Preferably, in order to limit friction, the support 2 comprises a retaining surface 8, for example in the form of two annular portions extending along the trajectory of the columns 4 around the axis 10 in such a way as to produce local bearing of the lower wall of the targets 13 placed in the lowest position of each column 4. The retaining surface 8 advantageously does not extend over the entire angular displacement of the support 2 in such a way as to leave a portion having a lower level than that of the retaining surfaces 8 at the support 2. This portion is illustrated in the form of a transfer zone 19 in
The support 2 comprises, as shown in particular in
In reference to
In reference to
The example of
In order to limit the influence of this lateral offsetting of the target 13, an aspect of to the invention is preferably implemented in which the offset between the support 2 and the receiving surface 12 is very small in the direction of the axis of rotation 10 in order to produce a significant reduction in the lateral offset between the hole 14 and the upstream side of the target 13. The effect of this reduction of distance between the support 2 and the receiving surface 12 is illustrated in
For example, the height of the target 13 can be approximately 20 to 30 mm and for example approximately 25 mm. An offset of 27 mm between the lower wall of the support 2 in the zone of the hole 14 and the upper wall of the receiving surface 12 provides a residual clearance “e” of 2 mm.
Since the targets have a standardized height in most cases, the offset can be set during manufacturing. Optionally, a system for adjusting the offset can be incorporated.
According to another aspect of the invention, again with the goal of limiting the offsetting of the target 13 during its loading onto the receiving surface 12, the present invention can have, at the hole 14, a deflector 16 configured to limit the component, oriented in the plane of the support 2, of movements of the target 13 passing through the hole 14. For this purpose, the deflector 16 has a configuration allowing bearing on an area of the outer contour of the target 13 in order to force the movement of the target 13 downwards, that is to say, along the axis of rotation 10. Thus, the component of movements along the axis of rotation 10 is promoted for the target 13 by limiting the component that is perpendicular to it via the bearing on the deflector 16. Preferably, the deflector 16 comprises an inclined flat surface, this incline going towards the outside of the hole 14 when going from the support 2 to the receiving surface 12. An example of a deflector 16 is shown in
In a non-limiting manner, this capacity for adjustment can be used to indifferently produce, via the invention, a machine capable of launching targets from the right or from the left.
Nevertheless, the present invention does not involve a modification of the system for storage and loading of the targets onto the receiving surface 12 and in particular the barrel 3 is not modified. Thus, it is noted that in the two operating modes of the machine, the barrel 3 continues to rotate in the same direction.
Preferably, at least one of the aspects described above with regard to the height offset between the support 2 and the receiving surface 12 and the presence of a deflector 16 is implemented in such a way that, regardless of the direction of rotation of the launching arm 9, the target 13 is brought onto the receiving surface 12 almost of the hole 14 in such a way that the reversal of the direction of rotation of the arm 9 does not fundamentally influence the launching of the target 13.
In addition or alternatively with these previous aspects, the present invention can comprise the ability to adjust the machine in such a way as to modify the relative angular position between the support 2 and the chassis 1 and compensate for the effect of the change in rotation of the arm 9. For this purpose, the support 2 can be mounted on the chassis 1 between a first position and at least a second position, these two positions having an angular offset along the axis of rotation 10 of the barrel or an axis that is parallel to it. It is therefore possible, for example, to compensate for the residual offset L2 or L3 or L1 of the target 13 in both directions of rotation (indeed, it should be recalled that by reversing the direction of rotation of the launching arm 9 without reversing the direction of rotation of the barrel 3, the effect of the offset L1, L2, L3 is reversed for the relative position of the target 13 in position on the receiving surface 12 relative to the launching arm 9).
To carry out the angular position adjustment of the support 2, the latter preferably comprises a first anchoring zone 17 and at least a second anchoring zone 18 at which the support 2 can alternatively be attached to the chassis 1. For example, the first and second anchoring zones 17, 18 can be holes passing through the support 2 and allowing the formation of a point for attachment of the support 2 with respect to the chassis 1. Nevertheless, an oblong hole or other mode of continuous adjustment of the angle of the support can be suitable. Preferably, the holes 17, 18 are also used to carry out the mounting of the axis of rotation 11 of the arm 9 therein. Thus, two alternative positions that adjust the angular offset between the support 2 and the chassis 1 are produced while mounting the rotatable launching arm 9.
It should be noted that the axis of rotation 10 of the barrel is advantageously parallel to the axis of rotation 11 of the arm. Likewise, the angular displacement between the support 2 and the chassis 1 occurs about an axis parallel to the two previous axes.
The pivoting of the support 2 between two angular positions preferably happens along an axis parallel to the axis of rotation of the barrel 3.
The result of the invention is particularly surprising because although a barrel 3 always rotating in the same direction of rotation is used, two machine configurations can be achieved (with rotation of the launching arm 9 in the counterclockwise or clockwise direction) without disturbing the direction of the shot. For example, in the illustration of
Number | Date | Country | Kind |
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14 62607 | Dec 2014 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/079056 | 12/9/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/096552 | 6/23/2016 | WO | A |
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9618864 | Jun 1996 | WO |
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Entry |
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International Search Report for corresponding International PCT Application No. PCT/EP2015/079056. |
Number | Date | Country | |
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20180010893 A1 | Jan 2018 | US |