EP0003085A1 - Fire control equipment - Google Patents

Abstract

The fire control device is associated with a telescopic sight (11-12) and it comprises on the one hand a collimator integrated in a laser rangefinder and composed of a lens (54) and a reticle (61) of aiming the range finder whose image is seen in the telescope to serve for locating the direction of measurement of the distance, on the other hand a collimator for shifting the collimation line composed of a lens (21) and a shooting reticle (23) placed at the focal point of this objective and associated with a reflective optical element (3) serving to return the image of the shooting reticle (23) in the telescope, the two collimators being arranged so that the image of the telemetry pointing reticle (61) passes through the reflecting optical element (3) to be returned by the shooting reticle (23) towards said reflecting optical element (3), the shooting reticle (23) being provided with 'a reflecting face capable of returning the image of the reticle (61) for pointing telemetry. The device is used to equip an artillery vehicle.

Description

The present invention relates to a fire control device intended to obtain the aiming of a cannon by introducing, between the axis of this cannon and the direction of the target, an angular offset based on the trajectory of the munition.

The device according to the invention is used to equip an artillery vehicle.

An artillery vehicle cannon can pivot about two perpendicular axes relative to the vehicle. The barrel is mounted on a turret so as to be able to pivot around a substantially vertical axis. Furthermore, the barrel generally pivots relative to the turret, about an axis substantially perpendicular to the axis of rotation of this turret.

The direction of aiming of the gun relative to the direction of the target takes account of certain parameters which will be mentioned below. Because the cannon is far from the target to be hit and the ammunition describes a curve in space, it is necessary to give a so-called angle of increase between the direction of the cannon and the direction of the target. The relationship between the rise and the distance is not linear. When the vehicle carrying the barrel is tilted so that the barrel journal axis is not horizontal, account must be taken of the cant of this journal axis to correct the angle of increase accordingly. Other parameters are also important. A site correction must be made to take account in particular of the angle of increase, this correction depending on the distance. A bearing correction must also be made to take certain parameters into account, and this correction is very roughly proportional to the angle of increase.

We know different fire control systems. We will refer, for example, to the US patent 2,887,774, to the French patent 2,016. 096, in French patent 2,140,699.

A fire control device includes a firing scope. This scope can be a periscopic scope or a shield scope. A reticle appears in the telescope so as to define a line of collimation. At the start of the operation, the collimation line is pointed at the target, the gun being parallel to this line. An angular shift of the collimation line is carried out and this line is again pointed at the target. The angular offset takes into account the different firing parameters.

The collimation line is offset by at least one optical element incorporated in the telescope and subjected to a motor mechanism. The offset can be ensured either by displacement of the reticle as in American patent 2,887,774, or by operation of a diasporameter as in French patent 2,140,699, or by displacement of a mirror as in French patent 2,016,096 .

Determining the magnitude of the offset requires a rangefinder. This instrument measures the distance from the target and it then makes it possible to determine the appropriate values of the corrections to be made to control the motor or motors which operate the optical element or elements shifting the collimation line.

The measurement of the rangefinder is transformed into one or two signals suitable for the corrections to be made, these signals acting on the motors for operating the optical elements deflecting the collimation line. This transformation is carried out either by an electronic computer receiving the signal from the rangefinder and possibly the signals from other sensors, or by a cam mechanism.

The rangefinders that we currently use are laser rangefinders.

In certain fire control lines using a laser rangefinder, it is sought to maintain the telemetry direction parallel to the direction of the collimation line. The telemetry direction is pointed at the target even when the aiming correction has been made and it is then offset from the axis of the gun. In other fire lines, the telemetry direction remains fixed relative to the gun regardless of the position of the collimating line. When a shift in the collimation line has been made, it is difficult to accurately determine the telemetry direction.

The present invention relates to a fire control device such that the telemetry direction remains constantly parallel to the barrel while being located in the field of vision of the telescope. The location of the telemetry line is carried out by the projection, in the telescopic sight, of a reticle independent of the movable reticle materializing the direction of sight. The design of the device is simple and uses minimal optical elements.

The fire control device according to the invention is intended to obtain the aiming of a cannon by introducing, between the axis of this cannon and the direction of the target, an angular offset based on the trajectory of the ammunition and it is composed on the one hand of a telescopic sight in which is visible the image of a shooting reticle defining a collimation line, on the other hand of the means of displacement of the shooting reticle which are subjected to the signal of a rangefinder, this rangefinder being of the laser type and provided with a set for transmitting a laser beam and a set for receiving this beam after diffusion, and it is characterized by the fact that it comprises a part a collimator integrated into the rangefinder and composed of a lens and a rangefinder pointing reticle whose image is seen in the telescope to serve for the location of the direction of measurement of the distance, on the other hand a collimator collimating line offset composed of a lens and the reticle of shooting placed at the focus of this objective and associated with a reflective optical element serving to return the image of the shooting reticle in the telescope, the two collimators being arranged so that the image of the telemetry pointing reticle crosses the reflective optical element to be returned by the shooting reticle to said reflecting optical element, the shooting reticle being provided with a reflecting face capable of returning the image of the telemetry pointing reticle.

According to a characteristic of the invention, the shooting reticle is constituted by a plate provided with crossed and transparent lines standing out against an opaque background and with a reflecting face.

According to another characteristic of the invention, the optical reflection element comprises a semi-reflecting face positioned so that the shooting reticle on the one hand and the eyepiece of the scope on the other hand are located in the same side of said surface.

According to another characteristic of the invention, the rangefinder pointing collimator and the collimating line shift collimator are arranged on either side of the optical reflection element.

The invention will now be described in more detail with reference to an embodiment given by way of example and represented by the accompanying drawing.

The single figure is a perspective representation, with sections, of a fire control device according to the invention.

The device which is the subject of the invention is placed in front of a rifle scope which is constituted by a system of lenses comprising an objective 11 and an eyepiece 12. These lenses are aligned along the optical axis 13 which is parallel to the axis of the barrel, which is not shown. The eyepiece 12 is associated with an eyepiece 14.

The image of a shooting reticle defining the collimation line is visible in the telescope. This image comes from a collimator composed of a lens 21 and a reticle 23. The reticle 23 is placed as usual at the focus of the lens 21 so as to give an image at infinity. The reticle is illuminated by a light source 24 associated with an optic 25. The collimator formed by the objective 21 and the reticle 23 is arranged, relative to the telescope, so that its optical axis 22 intersects the optical axis 13 of the glasses. The two axes are preferably 90 ° from each other.

The image of the shooting reticle is returned to the scope of the telescope by a reflective optical element 3. The collimation line passes through the image of the intersection of the lines of the shooting reticle 23. The reflective optical element comprises a semi-reflective flat face which can return the image of the shooting reticle 23, while letting the image of the landscape pass. The reflective optical element 3 is placed in front of the objective of the telescope so as to reflect the image to infinity of the shooting reticle. The semi-reflecting face is positioned so that the shooting reticle on the one hand and the eyepiece of the telescope on the other hand are located on the same side of this face. It is also positioned at the intersection of axes 13 and 22 and it is perpendicular to the bisector of the angle formed by these axes. Because the angle formed between the optical axes 13 and 22 is straight, the semi-reflecting face is 45 ° from these axes. The reflecting optical element provided with the semi-reflecting face is constituted either by a plane mirror or by a separating cube.

A control mechanism 4 exploits the signal provided by the laser rangefinder of the shooting line to move the shooting reticle 23 so as to introduce an offset in elevation of the collimation line which makes it possible to take account of certain parameters such as the rise. The reticle control mechanism may include a computer established to calculate the correction to be made to the collimation line from the signals from the sensors and the laser rangefinder. In the realization mode which is shown in the figure, the reticle is moved by a cam 41 whose profile is determined by the rise values of the shooting table. The cam pivots around an axis 42 and it is driven by a motor 43. The position of the cam is identified by an encoder 44. The signal supplied by the laser rangefinder is transmitted to the servo which controls the motor. Thus the signal from the rangefinder is transmitted at 45 to an adder amplifier 46 which controls the motor and which receives the signal from the encoder.

The laser rangefinder comprises an emission assembly which comprises a laser 51 associated with an optic 52 whose optical axis is marked 53. The emission assembly not being parallel to the telescope, the beam is reflected on the reflective optical element 3. The range finder also comprises a reception assembly formed by an optic 54, a diaphragm 55 and a photoelectric cell 56. The range finder usually comprises a counter which is not shown on the face. This counter produces a signal as a function of the time elapsing between the emission and the reception of the light beam.

The laser rangefinder comprises a pointing collimator composed of the objective 54 used to focus the backscattered laser beam and of a reticle 61 for pointing and locating the telemetry. This reticle is illuminated by a light source 63 associated with an optic 62. Because the backscattered laser beam and the beam coming from the reticle 61 are refracted by the objective 54, an optical separating element 64 is used to separate the beam going from the reticle 61 towards the objective 54 and the laser beam focused by the objective 54. This optical element 64 is constituted for example by a dichroic blade. In the embodiment which is represented in the figure, it is the beam coming from the reticle 61 which is reflected by the blade 64.

The aiming collimator of the rangefinder composed of the objective 54 and the reticle 61 and the aiming offset collimator composed of the objective 21 and the reticle 23 are arranged on either side of the semi-reflecting face of the plate 3. The optical axis 57 of the objective 54 and the optical axis 22 of the objective 21 are aligned. The semi-reflecting flat face of the strip 3 is positioned at the intersection of the optical axis 57 and the optical axis 13 of the telescope and along the bisector of the angle formed by these axes. Preferably the axis 57 is perpendicular to the optical axis 13.

The line of sight offset collimator comprising the firing reticle 23 is mechanically secured to the laser rangefinder and in particular to the rangefinder pointing collimator. The assembly is mounted in front of the bezel. A porthole 15, placed in front of the telescope and in front of the reflective optical element 3, protects this assembly.

The light beam coming from the shooting reticle 23, after emerging from the objective 21, is reflected on the blade 3. The image of the reticle firing is thus projected into the scope of the telescope.

The plate 3 also serves to reflect the incident laser beam directed towards the target, and the backscattered laser beam coming from the target.

The light beam coming from the reticle 61 is reflected by the blade 64 and is then refracted to give an image at infinity. The light beam passes through the reflective optical element 3 and it is focused by the objective 21 on the shooting reticle 23. The light beam is reflected on the shooting reticle 23 and it is refracted again by the objective 21. The beam emerges from this objective giving an infinite image of the telemetry pointing reticle. The beam is reflected on the reflecting optical element 3 so that the image of the reticle 61 is seen in the telescope.

To ensure the reflection of the beam coming from the telemetry reticle 61, the firing reticle 23 consists of a plate provided with crossed and transparent lines standing out against an opaque background. A reflecting face is arranged on this reticle, on the side of the objective 21, so as to produce a mirror. The layer constituting the reflecting face can constitute the opaque background. The telemetry pointing reticle 61 may be constituted by transparent lines on an opaque background or by dark lines on a light background.

The beam given by the reticle 61, in the path between the blade 3 and the lens 21, and the corresponding reflected beam, in the path between the lens 21 and said blade, are parallel. Furthermore, they are parallel to the optical axis 57. This characteristic is due to the fact that the retro-reflecting system formed by the objective 21 and by the mirror of the reticle 23, placed at the focal point of the objective, constitutes an invariant optical system. . The reflected beam arriving on the blade 3 has a constant position relative to the optical axis of the telescope and the image of the rangefinder reticle is therefore fixed in the field of the telescope.

The shooting reticle 23 can be moved by the associated mechanism 4. The image of the shooting reticle is thus mobile in the scope of the telescope. The movement of the shooting reticle does not affect the course of the rays coming from the telemetry reticle. Even if the reticle is not exactly perpendicular to the optical axis of the objective 21, the path of the rays is not modified.

Of course, it is without departing from the scope of the invention to imagine variants and improvements of details as well as to envisage the use of equivalent means.

Claims (6)

1 ° / Fire control device intended to obtain the aiming of a cannon by introducing, between the axis of this cannon and the direction of the target, an angular offset based on the trajectory of the ammunition and composed on the one hand of a telescopic sight 11-12 in which is visible the image of a firing reticle 23 defining a collimation line, on the other hand of displacement means 41 of the firing reticle 23 which are subjected to the signal of a rangefinder, this rangefinder being of the laser type and provided with a set of emission 51, 52, 53 of a laser beam and of a set of reception 54, 55, 56 of this beam after diffusion, characterized by the fact that it comprises on the one hand a collimator integrated into the rangefinder and composed of a lens 54 and a reticle 61 for pointing the rangefinder, the image of which is seen in the telescope 11-12 to serve for locating the direction of measurement of the distance and on the other hand a collimator: of offset of the lig: ie of collimation composed of an objective 21 and the firing reticle 23 and associated with a reflective optical element 3 serving to return the image of the firing reticle 23 in the telescope 11-12, the two collimators being arranged so that the image of the pointing reticle 61 of the telemetry crosses the reflecting optical element 3 to be returned by the firing reticle 23 towards said reflecting optical element 3, the firing reticle 23 being provided with a reflecting face suitable for returning the image of the reticle 61 pointing the telemetry. 2 ° / shooting control device according to claim 1, characterized in that the shooting reticle 23 is constituted by a plate provided with crossed and transparent lines standing out against an opaque background and a reflecting face. 3 ° / fire control device according to any one of the preceding claims, characterized in that the reflective optical element 3 has a semi-reflecting face positioned so that the shooting reticle 23 on the one hand and the eyepiece 12 of the bezel else share are located on the same side of said face. 4 ° / fire control device according to claim 3, characterized in that the collimator 61-54 pointing the rangefinder and the collimator 23-21 of offset of the collimation line are arranged on either side of the semi-reflecting face of the reflecting optical element 3. 5 ° / fire control device according to claim 4, characterized in that the collimator 61-54 pointing the rangefinder and the collimator 23-21 of offset of the collimation line are arranged so that their optical axes are aligned . 6 ° / fire control device according to any one of the preceding claims, characterized in that it comprises an optical separator element 64 separating the beam going from the reticle 61 pointing towards the optic 54 of the collimator and the laser beam which is also focused by said lens 54.

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