DE3228027A1 - Method for settling the vector axis of a ship's gyroscope - Google Patents

Abstract

The invention relates to a method for settling the vector axis of a ship's gyroscope, comprising a gyroscope sphere (1) floating in a liquid (2) and containing the gyroscope or gyroscopes (7, 8), an enveloping shell (3) containing the liquid, which is supported freely rotatably with respect to a ship's deck (6), a first device for generating a first difference signal corresponding to a misalignment between gyroscope sphere and enveloping shell, a tracking control loop (4) with a motor (5) which rotates the enveloping shell in order to align it with the gyroscope sphere or, respectively, the vector axis of the gyroscope or gyroscopes in dependence on the first difference signal, and a synchro device for generating a synchro signal which corresponds to the alignment of the enveloping shell or respectively, gyroscope sphere with respect to the ship's position. In order to considerably shorten the settling time, the following steps are provided: a) after manufacture and maintaining the floating state of the gyroscope sphere but without switching on the gyroscope drive, the enveloping shell (3) is aligned with the gyroscope sphere (1) by switching on the tracking control loop (4), b) the synchro signal corresponding to the alignment of the enveloping shell (3) or respectively of the gyroscope sphere (1) aligned with the enveloping shell with respect to the ship's position is supplied to a computer (9) and compared with a predetermined nominal position signal which corresponds to the ship's position with respect to North, c) on the basis of the value and of the change in the (second) difference signal which may result from the comparison, the computer imparts such rotations to the enveloping shell (3) and the gyroscope sphere (1) connected to the enveloping shell via the liquid friction that an alignment between ship's position and enveloping shell/gyroscope sphere unit, and thus an alignment of the gyroscope vector axis in the north direction is effected, d) the gyroscope drive is switched on, retaining (also) the electrodynamic clamping described in item b) and c) until the nominal vector value is reached and the settling process has ended. <IMAGE>

Description

Method for settling the spin axis of a ship's gyro

The invention relates to a method for settling the Spin axis of a ship's gyro according to the preamble of claim 1.

When commissioning a ship's gyro, for example before each one When leaving a port for a longer stay, it is necessary to to put the gyro into operation again. The commissioning of a ship's gyro has previously required a settling process that took many hours, usually 5 - 6 hours. The gyro is so far put into operation that at the same time Heater for the liquid container, gyro drive and bubble device for maintenance the gyro sphere in the floating state within the shell, are set in motion. The top running up to the swirl setpoint or the swirl resultant of several, usually two, gyroscopes, causes severe misorientation, the due to the sewing management that is switched on and constantly in operation at the same time can only be compensated in the specified time.

The resulting twist axis is only after the specified time The ship's gyro along with the tracked shell is oriented to the north.

The invention is based on the object of providing a method according to the Form the preamble of claim 1 so that the Einwingteit of the twist axis a ship's gyro is significantly reduced.

According to the invention, the object is achieved by the features of the label of claim 1 solved. Further: Refinements of the invention are set out in the subclaims shown.

The essence of the invention will be briefly explained below.

While in the known method initially the resulting gyroscopic spin axis or more inaccurately the gyro sphere due to a long-lasting one Settling process while the driven gyroscope is running up and then set to north and at the same time or thereafter via the tracking control circuit the Shell is readjusted until no more difference signal occurs, that is, until the shell and the gyro ball are aligned with one another, one goes with the subject matter of the invention the opposite way. This is where the gyro sphere and the aligned with it Shell is first preset to north, then only starts with switching on of the gyro drive the actual transient process of the twist axis until it is reached the set twist and the setting of the resulting twist axis respectively the gyro sphere and the correspondingly tracked shell on north. It showed that this procedure can shorten the total settling time considerably.

The generally known position of the ship is used for implementation advance law. Since the direction of the quay of a port and thus also of the parallel ship arranged to the quay is usually known, this does not represent a larger one Problem. Furthermore, a computer is required in the subject matter of the invention, softer the synchro signals generated in a known manner with a predetermined one Compares the setpoint for the actual position of the ship and provides corresponding signals, to align the circular sphere shell unit with the ship's position to the north. Once this has been achieved, the orientation of the spin axis of the ship's gyro is at the same time made on north.

One embodiment of the invention is the only schematic Figure shown.

The core of the gyro system shown in the figure forms the Gyro ball 1 with two schematically indicated gyros 7 and 8. At a distance of the top sphere 1 is the likewise essentially spherical shell 3 indicated; in between there is an electrically conductive liquid 2.

This liquid 2 is via an inlet opening 13 and an outlet opening 14 connected to a compass housing 11 which is filled with identical liquid 12 which is located in the space between the top sphere and the shell, preferably from below upwards, is circulated in order to maintain the levitation state. Will this Liquid is not heated, so it is relatively viscous, so that the top ball 1 rests against the inner wall of the shell 3 at the top. With the help of a schematic indicated heater 10, the circulated liquid 2 and 12 respectively heated a temperature that the viscosity is lowered so much. that the top ball 1 goes down. So that they are not nowmellr on the lower P, nrt <'of the shell 3 rests, on the one hand the flow through the liquid 12 or 2. In addition, a so-called (not shown) bubble device is often in the Inside the gyro ball 1 is provided. This facility generates in the wall the shell 3, especially in the lower area, eddy currents.

In this way there is an electromagnetic repulsion between the shell 3 and gyro ball 1 causes.

The (not shown) supply of the power lines from the outside through the shell and the liquid 2 through into the interior of the gyroscope ball, in particular for propulsion the centrifugal motors and the blowing device are preferably carried out via electrolytic Conduction pathways. The outer surface of the top ball has semicircular guide bands, which cooperate with reversing contacts on the inside of the shell 3 (not shown). Likewise, a center tap is brought out in the equatorial plane of the enveloping sphere, which generates a first differential signal via a differential transformer, which the Misorientation represents between gyro sphere 1 and shell 3. This first difference signal is fed to a control circuit 4, which in corresponding Way, a motor 5 actuated, which via a gear mechanism 15, the suspension axis 1.6., The shell 3 rotates so long until the first difference signal to zero will.

It goes without saying that the sign of the difference signal is used during the tracking taken into account in order to achieve tracking in the right direction.

It should be noted that the compass housing 11 including. Ceiling '17 is rigidly connected to the ship deck 9 and that. the one connected to the shell 3 Axis of rotation 16 is arranged freely rotatable in cover 17. At the top of the axis of rotation 16 of the shell 3 is the compass rose 18 shown i @ the figure the computer 9 is shown schematically as the control loop control signals to the The same motor 5 is around the shell 3 via the @ atrieb @ welle @@ @@ zureibe @. The latter Signa @ e @@ enen, however, not like the tracking control loop, shell and centrifugal sphere to align with each other, but shell or at the same time to align the gyro ball aligned with the ship's position. This position of the ship is available to the computer in the form of a default value.

A transient process takes place as follows.

First the heating is switched on around the liquid in the compass housing to be heated accordingly via a pump (not shown) is then the.

Liquid over, the insertion opening 13 in the space between Spinning ball 1 and shell 3 introduced and occurs at the top of the discharge opening 14th

back into the compass housing 1.2. Is the. Warming up after about 10 minutes to about 50 degrees Celsius, the top ball 1 sinks down.

To this with security in a floating position within the shell 3, the blower described above is turned on.

Now it is determined after switching on the tracking control loop 4, whether gyro ball 1 and shell 3 are exactly aligned with one another. Should this be not be the case, then automatically via the motor 5 and the axis of rotation 16 the liüllschale adjusted. Since when the shell 3 rotates due to the liquid friction the top ball 1 also rotates to a certain extent. this is not a one-off. but a longer adjustment process that often changes the sign.

Is the alignment between shell 3 and gyro ball 1 established, so there is no longer any difference signal supplied by the center tap at the control circuit 4 on, a further alignment process is carried out, namely the alignment process between the gyro ball shell unit and the ship's position. Eit0e possible Any deviation between these two positions is indicated by a synchro signal. This synchro signal is fed to the computer 9 and compared with a nominal position signal given by d @ rt. If this comparison results in a @@ deviation, corresponding control signals are sent d @ n motor 5 of the rule @g @@@@@ @@@@@@ corresponding way the Drenachse 1 @ and then the shell 3 together with the centrifugal ball connected to it via the fluid friction 1 rotates until there is a match between the position of the ship and the position of the gyro ball shell unit and thus the position of the resulting gyro-twist axis.

This condition represents the correct alignment of the twist axis of a Ship's gyro to the north, but without gyro drive. This gyro drive now sets in. Due to interfering influences known in theory, the Nordaus - @@ attention to the gyro axis when the gyro drive is now switched on despite (always) switched on tracking control loop 4 partially canceled, as far as the orientation of the twist axis - ship's position is concerned. While the or the gyro up to the target twist and possibly a little longer therefore the additional tracking via the computer 9 is also maintained. It should be mentioned that the computer in the speed and duration of the control of the motor 5 to Drive of the axis of rotation 16 can vary.

For example, if there is a greater deviation between the ship's position, it can and position of the twist axis allow the shell 3 to be rotated several times, the speed can also be varied accordingly. The same can be taken into account that a higher speed of the twist axis also stronger balancing forces needed. In all tracking processes, the transmission of the frictional forces is between Shell 3 and gyro ball 1 via the liquid 2 to be taken into account, the same the braking of the shell 3 after switching off the tracking motor. It deals this is not a one-time, continuous process, as already mentioned above-, but a gradual approach until the exact alignment is achieved.

Is correspondingly greatly shortened in this way after the completion of the A swinging process shows a north alignment of the twist axis or a correspondence the alignment with the ship's position is achieved, the computer is switched off, the additional computer-controlled tracking known as electrodynamic clamping to achieve a correspondence between the ship's position and the position of the twist axis is finished.

L e r s e i t e

Claims (7)

Method for oscillating the twist axis of a ship's scraper. PATENT CLAIMS Method for settling the spin axis of a ship's gyro, with one in one Liquid (2) floating, the top or top (7, 8) containing the top ball (1), a filling bowl (3) containing the liquid, facing the ship deck (6) is freely rotatably mounted, a first device for generating a first Difference signal corresponding to a misalignment between the gyro sphere and the shell, a tracking control circuit (4) with a motor (5) that rotates the Hüflschale depending on the first difference sign on the gyro sphere or to align the spin axis of the gyroscope or gyroscopes, as well as a synchro device to generate a synchro signal that the alignment of the shell or The gyro ball corresponds to the ship's position, characterized by the following steps: a) after production and while maintaining the floating state of the top ball, but without switching on the gyro drive, the tracking control loop is switched on (4) the shell (3) aligned with the top ball (1), b) that the alignment of the shell (3) or that aligned to the shell Gyro ball (1) for the corresponding synchro signal is sent to a computer (9) supplied and with a predetermined position target signal, which the SchiffsXåget against North corresponds, compared, c) due to the value as well as the change in itself possibly offset from the comparison resulting (second) difference signal the computer the shell (3) and the fluid friction with the shell connected gyroscopic ball (I) in such rotations that an alignment between Ship's position and shell-gyro-ball unit and thus an alignment of the gyro-spin axis to north takes place d) the gyro drive is switched on whereby (also) the in feature b) and c) described. electro-axial clamping until the swirl setpoint is reached and is maintained until the transient process has ended. 2. The method according to claim 1, characterized in that for production the state of suspension of the top ball (1) in the liquid (2) within the shell (3) a rapid heater (10) for the liquid in the compass housing (11) (12) is provided, which this liquid within 10 minutes on the target temperature heated by about 50 degrees Celsius to a lower inlet opening (13) and an upper outlet opening (14) in the casing shell (3) reduces the toughness to reach until the top of the shell lying on the top of the gyro ball down sinks into limbo. 3. The method according to claim 1 or 2, characterized by an electrical driven bladder device within the gyroscope ball (1), which in the from suitable material existing shell (a) eddy currents generated, which, due to magnetic repulsion, push the top ball (1) upwards and so maintain the state of suspension in the liquid (2). 4. The method according to any one of claims 1 - 3, characterized in, that the position setpoint signal for the ship's position given in the computer (9). before the polling procedure is entered according to the known actual ship position. 5. The method according to any one of claims 1 - 4, characterized in that that the rotation signals triggered by the computer (9) on the motor (5) of the Follow-up control device (4) act to rotate the shell (3). 6. The method according to any one of claims 1 - ã, characterized in, that the computer (9) determines the speed and duration of the rotation of the shell (3) depending on the degree of positional deviation between the shell and the ship's position as well as preferably controls from the existing gyroscopic swirl. 7. The method according to any one of claims 1-6, characterized by Facilities within the computer (9) to get out of the magnification respectively the extension of the second, differential signal the correct direction of rotation to determine for the tracking of the shell-gyro-ball unit and accordingly to control.