DE336870C - Device with which the correctness of the commands for marked shooting at one's own aircraft is checked - Google Patents

Description

Device with which the correctness of the commands for marked shooting is checked on its own aircraft. The anti-aircraft guns are located The earth and sea artillery is in an unfavorable position as one Realistic target representation for practical target practice extremely difficult and, on the other hand, the officer's ability to shoot is particularly important. high demands are made. For this reason it is necessary to have a device to create, on which command exercises counter-realistic goals, .d. H. in this case can be done against your own aircraft without these aircraft through a real bombardment are endangered. This task is supposed to be the present Meet exercise device.

The examination of the command given in real shooting is justified to determine the location of the detonation point at the goal. The exercise device must therefore also the location of the aircraft at the end of the projectile flight time and the location the detonation point; how he complied with the command in its actual execution would have to determine and both in such a lifelike position to each other bring that the shooter the result of his command spatially, vividly and sees it numerically.

This training device must, of course, depend on the type of boring shooting process take different forms.

The shape of the device for direct straightening (Fig. I).

The device consists of three separate parts, a lower part for Determination of the location of the flight, an upper part to determine the location of the explosive cloud, and a third part to bring these points together more realistically Shape.

The lower part consists of the bent telescope a, the double ruler b parallel to the line of sight of a , the vertically displaceable horizontal height bar c and the slide d, all of which are carried by the tube f, which can be rotated about the fixed axis e. If a is directed towards the aircraft by rotating the entire pipe around the vertical axis e and by rotating it around the horizontal axis g, c is cranked to the height determined by a range finder and marked at f, and finally d becomes the intersection of b and c pushed up; the point h of the slider represents the true position of the kies plane in the lower system, e.g. B. on a scale of i: io ooo.

The upper part, which can be independently rotated about e, consists of a telescope i, a ruler k and a slide 1. i can be adjusted to the plane by rotating about the fixed vertical axis e and by rotating about the horizontal axis in. The line of sight of i and the direction of k are parallel to each other in the zero position of i, but can be shifted against each other by any lead angle according to the height (division n.) And to the side (division o). If the individual values, the commands are now set, namely the distance by shifting 1 on the division k, the lead angle according to the height at the division n and the lead angle according to the. Side at the division o, and if i is reported to the aircraft up to the command "fire", but then left in its position, the position of l reflects the explosive cloud location p corresponding to the commando in the upper system.

To p with h. To compare, p must be projected down into the lower system. This is done through the rod q. q is of the same length as the distance between the two horizontal axes g, in and can be set vertically, ie parallel to the main axis e. Its lower sharpener projects the explosive cloud location p into the lower system.

If you let the lower system stand still at the moment in which the projectile flight time belonging to the command, calculated from the moment of fire has expired, in this way you can determine the position of the command corresponding to the command Explosive cloud location and the location of the flight at the moment of the projectile explosion Compare on a scaled-down, realistic scale, by finding of the distance 11., r: determine the success of the command and. determine at the same time like the shot from: the battery, and how it looked to lateral observers would have.

The numerical errors of the individual command pieces can be determined on the device in the following way: The distance error can be read off immediately as a difference in distance at b and k, the errors - the lead angle are obtained if, after the moment "fire", the aircraft continues with i, however, by means of the drives belonging to the divisions n and o, and after the projectile flight time has elapsed, reads off the remaining numbers at the divisions of n and o. The shape of the device for indirect straightening (Fig.a) That part of the device which is used to determine the location of the fire is the same here as in the first form, only that it is moved upwards for external reasons. The part which is used to determine the explosion point is adapted to the command form of indirect straightening. s represents the explosion point determined by the command according to focal length, overall elevation and lateral direction in a spatially correct manner. The projection of this explosion point into the upper system is carried out in a similar way to the first form by t. The location of the aircraft and the location of the explosive cloud can now be compared according to their spatial position, and the numerical errors of the individual command parts can also be determined by bringing the two points to coincide by setting the location of the explosive cloud and on the diagram and the horizontal division the associated sizes of the focal length, the total increase and the direction of the page. Shape of the device for other types of shooting. The device can be adapted to any other shooting method in that the part for determining the location of the flight always remains the same, and the part for determining the location of the explosive cloud is adapted to the command form. The latter is always possible, since a command for an anti-aircraft gun is nothing more than the definition of the intended meeting point by three spatial coordinates of any kind.

Claims (1)

PATRNT CLAIM: Device with which the correctness of the commands is checked during marked shooting at one's own aircraft, characterized in that there is a target device which allows the true location of the aircraft to be spatially determined at the end of the projectile flight time, and a second device on which or the detonation point of the projectile belonging to the command is to be set in accordance with the command pieces corresponding to the firing method used, are connected to each other in such a way that by shutting down the entire device after the calculated projectile flight time has elapsed, the mutual position of the place of flight and the detonation point by means of a projection element (q or t) spatially determined, and that the errors in the commands, according to the shooting method used, can be numerically determined at divisions.