DE10257675A1 - Barrel stabilization method following shooting of a gun, whereby an acceleration signal derived from the opposing movements of two elements of a compensating electro-mechanical drive is used in a control loop - Google Patents

Abstract

Method for stabilizing the barrel axis of a gun in which at least one acceleration signal is used in the control loop for stability control. The acceleration signal is determined from direct measurement of the relative acceleration of two separate parts that are moving towards each other with an electro-mechanical drive.

Description

Gun stabilization systems are part of defense technology standard equipment for main battle tanks for many years; also Schützenpanzer have been equipped with it as standard for a number of years, and recently, even the smaller caliber weapons are getting on armored ones Team and transport vehicles such a facility. In connection with an observation link directly or indirectly linked to the weapon and target device becomes the possibility created a goal even during the Driving in uneven terrain to recognize and fight. The gun barrel must be regarding its orientation towards the target can be stabilized inertially in space, and this is always possible with a 2-axis drive design. you speaks of an altitude and a side axis (very common, The terms Elevation are also used in German and azimuth instead of altitude and side).

The basic structure of a stabilization control loop for the height axis is based on the example of 1 shown:
One on a pad ( 1 ) supported weapon ( 2 ) is about the elevation axis ( 3 ) rotatably mounted. Your relative angular position in relation to the base ( 1 ) can be done by means of the drive motor ( 4 ) via the gearbox ( 5 ) change. If the inertial angular position of the weapon barrel is deflected from its target position by an interference movement triggered by the base, the interference movement is offset by a gyroscope attached to the weapon ( 6 ) sensed and via a target / actual value comparison ( 7 ) control electronics ( 8th ) supplied, which forms a correction signal and this to a power electronics ( 9 ) from which the drive motor of the actuator is supplied with the current required for the dynamic position correction. The control loop described is the main control loop in all known weapon stabilization systems and is usually called the stabilization control loop. The associated controller is often referred to as a speed controller because the state variable controlled thereby is an angular velocity.

Accordingly, for the stabilization control loop often the term speed control loop is used.

If the weapon is tracked by a self-stabilized observation and aiming device, the basic structure of the stabilization control loop described here is retained; only a so-called tracking control loop is superimposed, with the output signal of the tracking controller ( 10 ) serves as the input signal of the speed control loop.

With this state of the art satisfactory stabilization results only achieved as long as the weapon is not a distinctive one Unbalance around their storage. With one completely around their weapon has to be balanced such filing errors are corrected, which depend on the document, i.e. thus due to rotational disturbances due to pitching movements of the vehicle due to friction in the transmission and be transferred to the weapon in the trunnion bearing. Such favorable external conditions are often not given. For example, the demand of a higher one Armor protection especially for the turret front in battle tanks caused the weapon shield to thicken heavily was what a noticeable increase the unbalance moment of the weapon with it about its shield pin axis brings. In addition, weapon constructions have recently been brought forward extended Pipes introduced, so that also through such measures the unbalance additionally considerably elevated. This problem occurs not only with main battle tanks, but also in armored vehicles with weapons of smaller caliber. With these the imbalance lies in the fact that to achieve of a big one Elevation angle during the straightening process usually no different at all possible is. As a result, it turns out that there are also translational vertical interfering movements, which the vehicle is always exposed when driving in uneven terrain, strong in the form of stabilization errors on the weapon.

In practice, it has been shown that the rotational interference movements triggered by the pitching movements of the vehicle change in accordance with 1 Have the built-up control loop compensated sufficiently well if an additional turning gyro ( 11 ) is introduced into the system, which is generally referred to as an auxiliary gyro or disturbance variable gyro. It measures the angular velocity of the cause of the fault, for example the pitching movement of the turret around the elevation axis of the weapon in a battle tank, and leads this signal as a "feedforward control" (referred to in international parlance as a "feed-forward" signal) to the target / actual value comparison ( 7 ) of the stabilization control loop. With this measure, however, the stabilization errors caused by the translational disturbances cannot be dealt with in terms of control technology.

Weapon stabilization can not only be negatively influenced by imbalance disturbance moments around the elevation axis, but also by those around the azimuth axis. This is the case, for example, if the weapon is stored in a turret or attached to a turret. that the line of action of the recoil force does not run through that of the turret axis of rotation (see 2 ). The disturbance torque that occurs during shooting increases with increasing asymmetry in relation to the turret axis of rotation and can lead to undesirably large deposits from the target, especially when firing volleys from a rapid-fire weapon; if necessary, further shots can no longer be fired be resolved because the prescribed coincidence condition between target device and weapon is no longer met.

The object of this invention is to find a control arrangement that drives the drive motor the electro-mechanical actuating device is activated faster than it so far with the as introduced applicable control devices possible is.

This object is achieved according to the invention solved, that in Stabilization control loop using at least one acceleration signal finds which is from direct measurement of the relative acceleration of two mutually moving parts in the electromechanical drive system is determined.

This signal ( 12 ) according to one 3 built-up stabilization control loop fed into the target-actual value comparison ( 15 ) of an underlying acceleration control loop with an acceleration controller ( 16 ), whose output signal ( 17 ) directly to the input of the power electronics ( 9 ) leads as setpoint for the current of the drive motor in the respective drive axis elevation or azimuth. Since the amplitude of the motor current is representative and proportional to the system acceleration and since the acceleration is measured here directly without delay, e.g. with a sensor working according to the Ferraris principle, the acceleration circuit has a wide bandwidth with a high cut-off frequency and is therefore characterized by a much shorter response time for an at least partial disturbance variable regulation compared to a sole regulation via the gyro-supported speed control loop according to 1 with its higher time constants.

If there are rotational disturbances around the elevation axis of the weapon, the stabilization behavior can be improved even further by introducing another sensor ( 13 ), the acceleration on the pad ( 1 ) of the control device and this signal also compares the setpoint and actual value ( 15 ) of the acceleration control loop.

This procedure leaves you interpret as a transformation of the aforementioned method the feed-forward from the speed range in the faster acceleration comparison.

If, on the other hand, translational disturbances have an effect on the weapon system because it has a high unbalance moment around its elevation axis, the stabilization can be considerably improved by the signal from a sensor ( 14 ), which measures the translational acceleration, e.g. on the weapon cradle perpendicular to the weapon in the vertical direction, also in the target / actual value comparison ( 15 ) is fed.

The measure described last can also be used for the azimuth axis and is of particular importance there if the barrel axis of the weapon does not intersect the turret axis of rotation because, as already mentioned above, high recoil forces develop around the turret axis of rotation during firing and severely impair the azimuth stabilization. Here, too, it is advisable to feed a signal into the setpoint / actual value comparison ( 15 ) of the subordinate acceleration circuit, which is representative of the interference acceleration of the turret when firing. The associated measuring location in this case is the tower itself or an area lying in the tower plane or parallel to the tower plane.

Claims (9)

Method for stabilizing the barrel core of a weapon, which is mounted on a moving assembly base, in relation to disturbing movements which occur during movement of the assembly base or as a result of reaction forces when firing, the inertial rotary movement of the weapon being measured and fed to a stabilization controller using of an electromechanical directional drive which is in operative connection with the weapon and the assembly base, characterized in that at least one acceleration signal is used for the control in the control loop, which is determined from direct measurement of the relative acceleration of two parts moving against one another in the electromechanical drive. Process for stabilizing the tube core axis a weapon according to claim 1, characterized in that the acceleration is measured with a sensor constructed according to the Ferrari principle. Process for stabilizing the tube core axis a weapon according to claim 1, characterized in that the acceleration at least between the rotor of the motor and the stator of the drive motor is measured. Process for stabilizing the tube core axis a weapon according to claims 1 to 3, characterized in that the direct measured acceleration with a movement signal measured on the base compared and the result of the comparison in the stabilization control loop is regulated. Process for stabilizing the tube core axis a weapon according to claims 1 to 4, characterized in that on the Underlying a rotational acceleration is measured A method for stabilizing the barrel core of a weapon according to claim 1 to 5 thereby ge indicates that a linear acceleration is measured on the base and is taken into account in the control loop. Process for stabilizing the tube core axis a weapon according to claims 1 to 6, characterized in that the drive motor a brushless Motor is, with the Ferraris sensor integrated in the motor housing. Process for stabilizing the tube core axis a weapon according to claims 1 to 7, characterized in that two acceleration sensors acceleration on different moving parts of the drive measure up. Process for stabilizing the tube core axis a weapon according to claims 1 to 8, characterized in that the two Acceleration values are compared with each other and from the determined Difference signal controller parameters in the control loop can be influenced online.