DE1181931B - Gyroscope with a drive charge arranged in the rotor - Google Patents

Description

Gyroscope with a propulsion charge arranged in the rotor the invention is a gyro with a drive charge arranged in the rotor for Generation of gases, which through nozzles arranged tangentially in the rotor wall exit and thus set the rotor rotating by recoil, as well as with a electric igniter to ignite the drive charge in the rotor.

The invention is concerned with the arrangement of the electrical power line to ignite the drive charge in the rotor of such a gyro, such that the After the rotor has ignited and started, it does not lead to its movement hindered, the arrangement at the same time a movement of the rotor before ignition prevent for example as a result of any vibrations during transport target. Either a single conductor is provided if the rotor and support frame bearings can be used as a return line, or otherwise two current conductors.

The gyro according to the invention is characterized in that the for ignition serving electrical current conductors from the inner wall of the gyro housing through one of the tangential nozzles to the electric igniter and that one resilient 'holder is provided for the conductor, which the conductor to the Inner wall of the centrifugal housing leads away from the rotor when it is after ignition of the drive charge has been disconnected from the detonator.

In one embodiment of the invention, there is the resilient holder from a hollow spring that encloses the conductor and is in the relaxed state rests flat on the inner wall of the gyro housing.

The hollow spring can be a resilient tube that protrudes into the nozzle and also exerts a spring force in the direction of the rotor axis to rotate the rotor to prevent that stimulated by external disturbances such as when transporting the gyro could become.

As an exemplary embodiment, a gimbal-mounted one is shown in the drawings Gyro shown. However, the invention is also applicable to gyroscopes in the same way applicable with fewer degrees of freedom.

F i g. 1 is a perspective view of the gyro; F i g. Figure 2 is a similar view of the rotor on its own, with the walls of the rotor partially omitted to show its internal structure; F i g. 3 and 4 are sections through the top in two mutually perpendicular planes, namely along the axes of rotation of the rotor, and FIG. 5 is a section along the line VV in FIG. 4.

The gimbal-mounted gyro shown has an approximately spherical rotor 10 , which is held in the usual way in two support rings, namely a rotor arm 11 and a gimbal ring 12, which are rotatably arranged about axes AA and BB that intersect at right angles. The gimbal ring 12 is rotatably attached at 121, 121 to a housing 5 13 which encloses the entire instrument.

A combustion chamber 101 is arranged in the rotor 10 , in which a drive charge 14 and an electric igniter or starter 15 are provided. The walls of the rotor are pierced by two diametrically opposed channels 102, 103 which are tangential to the rotor axis; These channels 102, 103 represent nozzle outlet openings, so that the recoil of the gases generated by the combustion 5 of the charge 14 - gives the rotor 10 a rotary motion.

The charge 14 consists of a plurality of solid fuel cartridges 141, which can be ignited by the igniter 15 , in which an electrical fuse which is responsive to low voltages is installed. This fuse is connected to an external voltage source via power line wires 16 , the power conductors 16 through one of the above-mentioned nozzles, e.g. B. the nozzle 102, are directed into the interior of the rotor 10 ; the arrangement is such that the aforementioned current conductors 16 are severed during ignition, so that the rotor 10 can rotate freely. On the one hand to prevent the aforementioned current conductors 16 from interfering with the operating gyro, and on the other hand to protect the conductors 16 from breakage which could occur as a result of rotor inertia forces occurring during handling or transport. the conductors 16 are guided through a hollow spring tube 17 into the rotor; the spring tube 17 is fastened at 171 to the housing 13 in such a way that it also exerts a small force in the rotor nozzle 1021 in the direction of the rotor axis and thus exerts a small locking torque against small adjustment forces which could act on the rotor.

Upon ignition of the drive charge 14, the heat and thrust of the gases flowing through the nozzle 102 will sever the conductors 16 and the free end of the spring 17 will be ejected before any appreciable rotation of the rotor 10 occurs. The spring 17 is thrown out of the nozzle 102 together with approximately unburned parts of the conductors 16 and, due to the spring tension within the housing 13 , assumes a position such that the movement of the support rings and the rotor are not hindered.

The F i g. 3 and 4 show a mechanical locking device for the gyro. It consists of a bolt 18 which engages in a sleeve 111 on the rotor arm 11. The bolt 18 is held in this position by a fuse wire 19. When the fuse wire 19 melts by supplying electrical energy via the terminals 20, the bolt 18 is released and moved away from the locking position by the force of a spring 181.

Claims (3)

Claims: 1. Gyroscope with a drive charge arranged in the rotor for generating gases which exit through nozzles arranged tangentially in the rotor wall and thus set the rotor rotating by recoil, as well as with an electric igniter for igniting the drive charge in the rotor, characterized in that, that the electrical current conductor (16) used for ignition runs from the inner wall of the gyro housing (13) through one of the tangential nozzles (102, 103) to the electrical igniter (15) and that a resilient holder (17) for the current conductor (16) is provided, which leads the current conductor to the inner wall of the gyro housing (13) away from the rotor (10) when it has been separated from the igniter (15) after ignition of the drive charge (14). 2. Gyro according to claim 1, characterized in that the resilient holder consists of a hollow spring (17) which surrounds the current conductor (16) and rests flat on the inner wall of the gyro housing (13) in the relaxed state. 3. Gyro according to claim 2, characterized in that the hollow spring (17) is a resilient tube which projects into the nozzle (102 or 103) and also exerts a spring force in the direction of the rotor axis. Documents considered: German Patent No. 109 218; British Patent No. 581737; U.S. Patent Nos. 2,743,576, 2,390,635.