DE4234026C1 - Inertial measurement unit for missile or projectile - aligns optical rotation sensor axis with drift axis of two=axis mechanical gyroscope and with axis of high acceleration of launch - Google Patents

Abstract

Within the launching tube (10), a cylindrical missile (12) contains an inertial measurement unit (16) which senses the angular velocity of rotation about the longitudinal axis (14) and two other input axes (18,20) at right angles to each other. A dynamically-adjusted two-axis gyroscope (22) has its drift axis (24) aligned with the longitudinal axis of the missile. The rate of rotation about this axis is measured by an optical sensor (26) whose optical path follows the internal surface of the fuselage (30), ahead of an electronic control unit (32) and interface (34). ADVANTAGE - Very compact device exhibits little drift even under high acceleration along particular axis.

Description

The invention relates to an inertial measuring unit for three mutually orthogonal axes for use in missiles with an optical rotational speed sensor ( 26 ) and mechanical, inertial sensor means for measuring the missile movement about two axes perpendicular to the input axis of the optical rotational speed sensor.

Inertial measuring units are used for navigation and flight control known that changes in position relative to the inertial space speak to. Such measuring units measure rotational speeds or the position around three mutually orthogonal input axes. Measuring units of this type are known which are mechanical Gyros are built. Such mechanical gyroscopes can dynamically tuned gyros. Using of mechanical gyros, e.g. B. two dynamically tuned Gyroscopes with two input axes each is at least one of the Gyro with its swirl axis perpendicular to the longitudinal axis of the Missile or projectile arranged. Towards this Long accelerations occur along the longitudinal axis. This can due to unbalanced mass of the gyro rotor an undesirably high Drift of this gyro will occur.

There are optical rotational speed sensors, for example known in the form of fiber or laser gyros. Such optical rotation speed sensors are based on the Sagnac effect. They contain one in one level  closed light path and speak on rotational speeds about an input axis perpendicular to said plane. One with three such optical rotation speed sensors built measuring unit requires a quite large Installation volume. Those obtained through the Sagnac effect optical path differences are proportional to that of the Light path enclosed area.

The structure of the inertial measuring unit in a uniform Technology than either only with mechanical gyros or just with optical rotation speed sensors, has the other Disadvantage that the alignment of the different sensors to each other is quite expensive.

US Pat. No. 4,901,565 is an inertial measuring unit for Missile known from an optical Rotational speed sensor for measuring the Rolling speed and two mechanical, inertial Sensors, namely two micromechanical rotational acceleration Sensors. These sensors are said to be one of a kind Integrated circuit built measuring unit created become.

The invention has for its object an inertial Measuring unit to create the high accelerations along one endures given axis, is as compact as possible and even at high accelerations along the axis in question Exhibits drift.

According to the invention, this object is achieved in that Use in highly accelerated missiles or  Shot the mechanical, inertial sensor means from a biaxial mechanical gyroscope is formed, whose swirl axis is parallel to the input axis of the optical rotational speed sensor is arranged.

The measuring device can be in the missile or Projectile with the swirl axis parallel to the longitudinal axis of the Missile or projectile be installed.

In this way the mechanical gyro is against the in Direction of the longitudinal axis of the missile or projectile acting high acceleration largely insensitive. It there is no drift of the gyro due to mass imbalance which acts the acceleration. The mechanical gyroscope detects the rotational speeds around two to the swirl axis of the Gyroscope and thus the longitudinal axis of the missile perpendicular Axes. The optical rotational speed sensor extends essentially in one to the missile longitudinal axis vertical plane and forms an annular or disc-shaped Component. The one optical rotation speed sensor therefore requires only a small installation volume. The optical one Rotation speed sensor can, if necessary total internal cross section of the missile or projectile fill in or enclose so that there is a large enclosed area and thus the best possible accuracy. The optical rotation speed sensor is in the direction of Acceleration very stable. The optical rotational speed Sensor detects the speed of rotation around the swirl axis of the mechanical gyroscope and thus around the longitudinal axis of the Missile or projectile.

An embodiment of the invention is in the figure shown and described below.

The figure shows schematically a longitudinal section of a Missile or projectile in a launch tube.  

In the figure , 10 is a launch tube. An essentially cylindrical missile or projectile 12 sits in the launch tube 10 . The longitudinal axis of the missile or projectile is designated by 14 . An inertial measuring unit 16 sits in the missile or projectile 12 . The inertial measuring unit 16 measures, among other things, the rotational speeds of the missile 12 about the missile longitudinal axis 14 and about two input axes 18 and 20 perpendicular to the missile longitudinal axis 14 and to one another. The input axis 18 is shown in the paper plane of the figure. The input axis 20 is then perpendicular to the paper plane in the figure.

The missile 12 is subjected to strong accelerations in the direction of its longitudinal axis 14 .

The measuring unit 16 contains a dynamically tuned, two-axis gyroscope 22 . The swirl axis 24 of the gyroscope 22 coincides with the longitudinal axis 14 of the missile 12 . The two input axes of the gyroscope 22 are perpendicular to the swirl axis 24 and are perpendicular to one another. These input axes form the two input axes 18 and 20 of the measuring unit.

An optical rotational speed sensor 26 is provided for measuring the rotational speed of the missile 12 about the longitudinal axis 14 . The optical rotational speed sensor 26 is ring-shaped or disk-shaped. The optical rotational speed sensor extends perpendicular to the longitudinal axis 14 of the missile. The input axis 28 of the optical rotational speed sensor 26 also coincides with the longitudinal axis 14 of the missile 12 . The optical path of the optical rotational speed sensor 26 runs along the inner surface of the missile cell 30 . This optical path therefore encloses an optimally large area. The measuring unit 16 with the dynamically tuned gyroscope 22 and the optical rotational speed sensor 26 is very compact and space-saving. The gyroscope 22 is very stable in the direction of acceleration. The acceleration in the direction of the longitudinal axis 14 does not lead to a drift even when there is an unbalance of the gyroscope 22 . The optical rotation speed sensor is also very stable in the direction of acceleration.

The operating electronics 32 of the measuring unit 16 are located behind the optical rotational speed sensor 26 . An interface 34 is arranged behind it.

Claims (1)

Inertial measuring unit for three mutually orthogonal axes for use in missiles with an optical rotational speed sensor ( 26 ) and mechanical, inertial sensor means for measuring the missile movement around two axes perpendicular to the input axis of the optical rotational speed sensor, characterized in that for use in highly accelerated missiles or projectiles, the mechanical, inertial sensor means are formed by a biaxial, mechanical gyroscope, the swirl axis of which is arranged parallel to the input axis of the optical rotational speed sensor.