JP2676161B2 - Vertical Toluca for Gyro Compass - Google Patents

Description

TECHNICAL FIELD The present invention relates to a gyro compass torquer used in a ship or the like, and more particularly to a vertical torquer thereof.

[Conventional technology]

As a conventional gyro compass to which the present invention is applied, there is, for example, the one shown in FIG. In the figure, reference numeral (A) represents the entire gyro compass,
(1) is a gyro case, this gyro case (1)
Has a built-in gyro rotor that is rotated by an induction motor at high speed and at a constant rotation speed, and its rotation vector is southward (clockwise when viewed from the north side). The gyro case (1) has a pair of vertical shafts (2) and (2 ') projecting vertically, and these vertical shafts (2) and (2') are arranged outside the gyro case (1). Ball bearings (4), (4 ') mounted at corresponding positions on the vertical ring (3)
The inner ring of each is fitted. The lower end of the suspension line (5) is fixed to the vertical shaft (2), and the upper end of the suspension line (5) is attached to the vertical ring (3) via a suspension line mount (5 ').

With the above structure, the weight of the gyro case (1) is reduced by the ball bearings (4) of the vertical axes (2) and (2 '),
(4 ') Thrust load does not result, all suspension lines (5)
Is responsible for the ball bearing (4),
The friction torque of (4 ') can be greatly reduced. To the east and west of the vertical ring (3) is mounted a pair of liquid ballasts (6) for applying finger torque to the gyro.

As shown in FIG. 5, each liquid stabilizer (6) is a kind of connecting pipe, and is a pot (6-
1), (6-1 '), a liquid (6-2) having a high specific gravity that satisfies these spaces, and an air pipe (6) for communicating upward and downward between the north and south urns (6-1), (6-1'). -3), and a liquid pipe (6-4) connecting them downward.

As shown in FIG. 6, a damping weight (7) for damping the finger north movement is attached to the west side of the gyro case (1).

As shown in FIG. 4, on the east side of the gyro case (1), a differential transformer for detecting a deviation angle around the vertical axes (2) and (2 ') of the gyro case (1) and the vertical ring (3). The primary coil (8-1) and the secondary coil (8-2) of the differential transformer are respectively attached to the positions of the vertical ring (3) facing the primary coil (8-1) to form a follow-up pickup (8). To do.

7A, B and C show an example of a follow-up pickup (8). As shown in the figure, the primary coil (8-1) includes an E-shaped iron core (8-1a) made of a high magnetic permeability material and an AC power source (8-1).
c) connected to the central tooth (8-1a) of the E-shaped iron core (8-1a).
It is composed of a primary coil section (8-1b) wound around aa). On the other hand, as shown in FIG. 7C, the secondary coil (8-2) includes two secondary coil portions (8-2a) and (8-2b) which are differentially connected to each other. , And a substrate (8-2c) to which these are fixed. In addition, (8-1d)
Is a fitting for attaching the primary coil (8-1b) to the gyro case (1).

FIG. 8 is a schematic diagram for explaining the operation principle of the follow-up pickup (8). In the figure, the AC power source (8
-1c) excites the primary coil portion (8-1b), the central tooth (8-1aa) of the E-shaped iron core (8-1a) to the tooth (8-1ab), (8-1ac) on both sides. ) Symmetrically alternating magnetic flux B
Is created in space. Here, in the case where the secondary coil (8-2), that is, the two coil portions (8-2a) (8-2b) are located symmetrically with respect to the primary coil (8-1), 2
An equal voltage is induced in each of the secondary coil portions (8-2a) and (8-2b). However, since both are differentially connected, no output voltage appears at the output terminal (8-2d) of the secondary coil (8-2). On the other hand, the primary coil (8-1)
On the other hand, when the secondary coil (8-2) moves in the direction of the arrow (D) in FIG. 8, the two secondary coil parts (8-2a), (8) of the secondary coil (8-2) are moved. A difference occurs in the voltage induced in −2b), and a voltage corresponding to the relative movement amount in the direction of the arrow (D) is induced at these output ends (8-2d), and the pickup becomes a follow-up pickup.

In FIG. 4, the vertical ring (3) further includes a pair of horizontal axes (9), which are outward from the east-west position orthogonal to both the vertical axes (2), (2 ') and the gyro spin axis.
(9 ') has a protruding, these horizontal axes (9),
(9 ') is a horizontal ring (1
Ball bearing (1
Fit into the inner rings of 1) and (11 ') respectively. Horizontal ring (10)
Is further in the horizontal plane and above the horizontal axis (9),
A pair of gimbal shafts (12) at a position orthogonal to (9 '),
It has (12 '). These gimbal axes (12), (12 ')
Is a pair of gimbal shaft ball bearings (14) mounted on the follower ring (13) located outside the horizontal ring (10),
Fit in (14 ') respectively.

As shown in FIG. 4, the follower ring (13) has follower shafts (15) and (15 ') on the upper and lower sides, and these follower shafts (15) and (1
5 ') are fitted with the follower shaft ball bearings (17), (17') at corresponding positions of the board device (16), respectively.

Compass card (18) on the shaft end of the upper follower shaft (15)
Is attached, and the azimuth angle of the bow is read by this and the base line (18B) fixed to the corresponding position of the bow side of the board (16). An azimuth servomotor (19) is attached to the lower part of the panel unit (16), and its rotation axis (19A) is driven through an azimuth pinion (20). Combine with An azimuth oscillator (22) is attached to the lower part of the board device (16), and its rotation shaft (22A) is meshed with the azimuth gear (21) via a gear system (not shown).
The azimuth signal is converted into an electric signal and transmitted to the outside.

Here, the part within the horizontal ring (10), that is, the part including the horizontal ring (10), the vertical ring (3), the gyro case (1), etc., is usually called a sharp area. The sharp part is the gimbal axis (12),
A lower heavy physical pendulum is constructed around (12 '), so that the horizontal axes (9), (9') are always kept in the horizontal plane regardless of the hull inclination.

If there is a difference between the azimuth of the gyro case (1) and the azimuth of the vertical ring (3), the following pickup (8) provided between them detects the difference and converts it into an electric signal. This electric signal is amplified by an external servo amplifier (23) and applied to an azimuth servomotor (19) (azimuth servo system).
The rotation of the azimuth servo motor (19) is controlled by the follower ring (1) through the rotation axis (19A), the azimuth pinion (20) and the azimuth gear (21).
3), then the horizontal ring (10), horizontal axis (9),
The azimuth deviation between the vertical ring (3) and the gyro case (1) is transmitted to the vertical ring (3) via (9 ') and the like, and is always kept at zero.

Horizontal axis (9), (9 ')
And the gyro spin axis always maintain an orthogonal relationship, and the torsional torque of the suspension line (5) is not applied to the gyro at all. That is, a vertical axis (2) having a servo system,
The gyro case (1) is completely insulated from the angular motion of the hull by the action of three axes (2 '), horizontal axes (9), (9') and gimbal axes (12, 12 '). This constitutes a gyroscope.

The above-mentioned liquid ballast (6) gives the above-mentioned gyroscope the function of finger power, that is, the function as a compass.
It is.

Next, the principle of the liquid stabilizer (6) will be described with reference to FIG. Note that FIG. 5 is a diagram when the north end of the finger of the gyro is raised by an angle θ with respect to the horizontal plane. Considering the case where the ship is stopped, the liquid (6-
The liquid level in 2) is orthogonal to the direction of the gravity g. Therefore, compared with the case of zero inclination, the liquid in the shaded area in the figure decreases in the northern jar (6-1 ') and decreases in the southern jar (6-
In 1), it increases. Now, the horizontal axis (9), (9 ') from both pot (6-1), (6-1') r ₁ the distance to the center of both fountain (6-1), (6-1 ') Is S, the liquid (6-
Assuming that the specific gravity of 2) is ρ, the weight of the liquid in the inclined portion is S × r ₁ sin θ × ρ × g.

The above weight imbalance is based on both north and south urns (6-1),
(6-1 ') and the horizontal axis (9),
(9 ') moment arm from the so r _1, after all, the horizontal axis to make the liquid ballast (6) when the inclined angle theta (9), (9' torque T _H around), the approximation to a T _H = 2Sr ₁ ² gρθ.

Here, at the 2Sr ₁ ² gρ = K, it is called a ballast constant K. That is, the liquid ballast (6) applies a torque proportional to the inclination of the gyro spin axis with respect to the horizontal plane, to the gyro horizontal axis (9),
The gyro has a finger north force, thereby acting as a gyro compass.

On the other hand, as shown in FIG. 6, the damping weight (7) includes vertical axes (2) and (2 ′), and in the plane orthogonal to the gyro spin axis, the damping weight (7) is Mounted on the gyro case (1) with a distance of r ₂ (perpendicular to the paper surface). FIG. 6 is a view of the gyro case (1) in which the north side of the finger rises and is inclined by an angle θ with respect to the horizontal plane as viewed from the west side. The gravitational acceleration g acts on the damping weight (7) having the mass m, and a force of m × g acts on the damping weight (7) in the vertical direction. This force is applied to vertical axis (2),
It is considered that the component is divided into a component mg cos θ parallel to (2 ′) and a component mg sin θ parallel to the spin axis. Among them, the component parallel to the vertical axes (2) and (2 ') only acts as a load on the vertical axis ball bearings (4) and (4'), while the component parallel to the spin axis is Vertical axis (2), (2 ')
Vertical axis by multiplying the distance r ₂ from (2), it acts on the gyro as a torque around (2 '). If this torque is expressed as Tφ, Tφ is approximately expressed by the following equation.

Tφ = μ · θ where μ = mgr ₂ That is, the damping weight (7) is a device that applies a torque proportional to the inclination of the gyro spin axis with respect to the horizontal plane around the gyro vertical axes (2) and (2 ′). Yes, this can attenuate the compass fingering movement.

The vertical ring (3) has an accelerometer or inclinometer (50) having an input axis parallel to the spin axis of the gyro rotor, and the vertical ring (3) and the gyro case (1) have an input current. A vertical torque (51) is attached which applies a proportional torque about the vertical axis (2), (2 ') of the gyro case (1).

Furthermore, the output signal (8A) of the tracking pickup (8) and the output signal (50A) of the accelerometer (50) (proportional to the inclination angle of the gyro spin axis with respect to the horizontal plane) are input and output to the vertical torquer (51). A control device (52) that outputs a signal (51A) is provided.

FIG. 9 shows the conventional gyro compass described above,
The azimuth error φ and the inclination angle θ from the true north of the north end of the finger of the gyro spin axis are used as variables, and the northern movement of the initial errors φ ₀ and θ _{0 is} represented by a Laplace operator and a transfer function. It is shown in. In the figure,
g is gravitational acceleration, R is earth radius, Ω is earth rotation angular velocity,
H is the angular motion of the gyro, λ is the latitude at that point, K is the finger north constant (ballast constant), μ is the damping constant, and S is the Laplace operator.

Now, if there is an azimuth error φ, this error φ multiplied by the horizontal component Ω cosλ (100) of the earth's rotation angular velocity Ω acts as an angular velocity input on the element (101) around the horizontal axis of the gyro, and the initial tilt A gyro inclination angle θ is generated together with the angle θ ₀ . The vertical ring (3) also has the same inclination according to the inclination angle θ of the gyro spin axis, the liquid ballast (6) attached to the vertical ring (3) also inclines, and the liquid (6-2) in the lower part is lower. By moving to the urn, a torque of Kθ is generated around the horizontal axis of the gyro. This torque Kθ
Is divided by the angular momentum H of the gyro, and the vertical component Ω sin λ of the Earth's rotation angular velocity is added to act on the element (102) around the vertical axis of the gyro as an angular velocity input,
The addition of the initial azimuth error φ ₀ to this gives the azimuth error φ, and the loop closes. This loop is the finger north loop of the gyrocompass. This loop is an oscillation solution because there are two poles represented by 1 / S in the loop. On the other hand, the torque μ obtained by multiplying the gyro tilt angle θ by the damping constant μ
A value obtained by dividing θ by the angular momentum H is negatively fed back to the horizontal axis element (101) of the gyro as an angular velocity input so as to reduce the inclination angle θ, and the finger north movement of the finger north loop is attenuated. This loop is a damping loop.

In FIG. 4, the control device (52) outputs the output signals (8A), (50) of the tracking pickup (8) and the accelerometer (50).
A) is input, and after performing a short-term settling calculation to settle the spin axis of the gyro to true north within a short time, the output (51A) is supplied to the vertical torquer (51). However, since these details are not directly related to the present invention, further description will be omitted.

[Problems to be solved by the invention]

However, in such a conventional gyro compass, a follow-up pickup (8) and a vertical torquer (51)
Since these are completely separate elements as shown in FIG. 4, 1) the manufacturing cost as an element, that is, the parts manufacturing cost and the assembly cost are added, resulting in a high cost.
2) By providing the vertical torquer (51) separately from the pickup (8), the vertical torquer (51) can be moved from the control device (51) to the vertical torquer (51).
It takes time and labor for parts such as slip rings, flexible electric circuits, etc. and wiring, leading to cost increase.

[Means for solving the problem]

According to the present invention, a gyro case (1) containing at least a gyro rotor and having vertical axes (2, 2 ′) vertically, a vertical ring (3) arranged on the outer periphery of the gyro case, and the gyro case described above. The vertical axis of the gyro case and the vertical ring, which comprises a primary coil (8-1) fixed and excited by an AC power source (8-1c) and a secondary coil (8-2) fixed to the vertical ring. In a vertical torquer for a gyrocompass having a follow-up pickup (8) for detecting a relative angular deviation around, a coil portion (8-
1b) and the AC power source, a diode (60-1) and a resistor (60-2) are connected in parallel to form a partial rectifier circuit (6
By inserting 0), the follow-up pickup can be operated also as a vertical torquer, and a vertical torquer for a gyro compass is obtained.

[Action]

The primary coil (8-1) is AC-excited through the partial rectifier circuit (60) to generate an AC magnetic field and a DC magnetic field at the position of the secondary coil (8-2).

By connecting a function separation circuit (62) consisting of a capacitor (63) and a constant current circuit (64) to the output of the secondary coil, and applying a Toruca current i _T to the secondary coil via the constant current circuit, By interacting with the DC field described above, a torque proportional to the torquer current i _T can be applied around the vertical axis of the gyro.

〔Example〕

 Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a circuit diagram of one embodiment of the present invention. In the figure, the same elements as those in FIGS. 4 to 8 are designated by the same reference numerals, and detailed description thereof will be omitted.

In FIG. 1, an AC power supply (8-1c) is connected in parallel to the coil part (8-1b) of the primary coil (8-1), which is composed of a diode (60-1) and a resistor (60-2). Connection is made via the partial rectifier circuit (60). On the other hand, the output ends (8-2d) of the coil parts (8-2a) and (8-2b) of the secondary coil (8-2) are connected to the capacitor (63) of the function separation circuit (62).
And the input side of the constant current circuit (64), respectively. Further, the output side of the condenser (63) and the output end of the coil portion (8-2b) of the secondary coil (8-2) are connected to the follow-up pickup (8).
Terminal (65) of the servo amplifier (23) (4th
Connect to the input side (Fig.). Further, the output end (8-2d) of the secondary coil (8-2) is connected to the output end of the constant current circuit (64), and the input end of the constant current circuit (64) is connected to the torquer terminal (66). The output end (51A) of the control device (52) for short-term static determination shown in FIG. 4 is connected to this, or the latitude error (latitude It is used to correct the azimuth error which is proportional to the tangent.

2 and 3 are diagrams for explaining the principle of the present invention.

Figure 2 shows the coil section (8-1b) of the primary coil (8-1).
It is a wave form diagram which shows the electric current which flows into. One current i ₁ is the same as the forward direction of the diode (60-1), so the resistor (60
-2) does not flow, but only the diode (60-1) flows, so that the amplitude is large as shown in FIG. On the other hand, the other current i ₂ is in the opposite direction to the diode (60-1), so that its passage is blocked by the diode (60-1) and flows through the resistor (60-2). Become. Therefore, the amplitude of the current i ₂ is smaller than that of the current i ₁ .

That is, in this example, by exciting the primary coil (8-1) with the AC power supply (8-1c) through the diode (60-1) and the resistor (63-2), the AC amplitude i _ac = ( i ₁ + i ₂ ) / 2 It is equivalent to flowing two kinds of currents in the primary coil (8-1) (component rectification circuit). The alternating current produces an alternating magnetic field at the position of the secondary coil (8-2) as in the conventional example, and the secondary coil (8-2) produces an alternating signal corresponding to the relative displacement in the vertical direction in FIG. And becomes the pickup signal.

On the other hand, due to the direct current, the secondary coil (8-2)
Since a DC magnetic field φ (see Fig. 3) is created at the position of, the predetermined toruca current i _T is passed through the secondary coil (8-2) through the constant current circuit (64), so that Fleming's left hand According to the law of, the primary coil (8-1) and the secondary coil (8-
As shown in FIG. 3, a force F proportional to the torquer current i _T is generated between 2) and the torqueer current i _T , and a function as a torquer that applies a torque around the vertical axis of the gyro case (1) is generated. . The capacitor (63) is provided to cut the direct current so that the Toruca current i _T does not flow to the servo amplifier (23).

〔The invention's effect〕

As described above, according to the present invention, the following effects can be obtained.

A simple method of exciting the primary coil of a conventional tracking pickup from an AC power source via a partial rectifier circuit consisting of a diode and a resistor and adding a function separation circuit consisting of a capacitor and a constant current circuit to the output end of the secondary coil. With the structure, it is possible to add the function as a vertical ToruCa,
The function of the Toruca can be obtained at low cost compared to the conventional example in which a separate Toruca is prepared.

Since the coil portion of the secondary coil of the pickup is also used as a torquer, it is not necessary to add an electric circuit or slip ring, and a highly reliable torquer can be obtained.

[Brief description of the drawings]

FIG. 1 is a circuit diagram for explaining the function of the vertical torquer of the present invention, FIGS. 2 and 3 are waveform diagrams and schematic diagrams showing the operation as a torquer, and FIG. 4 is a conventional diagram to which the present invention is applied. FIG. 5 is a perspective view of the gyro compass, FIG. 5 is a schematic diagram of the liquid stabilizer of the gyro compass, FIG. 6 is a schematic diagram for explaining the principle of the damping weight, and FIG. 7 is a structural diagram of its follow-up pickup. FIG. 8 is a schematic diagram for explaining the principle thereof, and FIG. 9 is a block diagram for explaining the principle of the gyrocompass of FIG. In the figure, (1) is a gyro case, (3) is a vertical ring, (8) is a follow-up pickup, (8-1) is a primary coil, (8-2) is a secondary coil, and (60) is a partial rectifier circuit. ,
(62) shows the function separation circuits respectively.

Continuation of the front page (56) Reference JP-A-1-113610 (JP, A) JP-A-61-167811 (JP, A) JP-B-51-12787 (JP, B1)

Claims (1)

(57) [Claims] 1. A gyro case containing at least a gyro rotor and having a vertical axis in the vertical direction, a vertical ring arranged on the outer periphery of the gyro case, a primary coil fixed to the gyro case and excited by an AC power source, and the vertical. A vertical torquer for a gyrocompass, comprising a secondary coil fixed to a ring and having a follow-up pickup for detecting a relative angular deviation between the vertical ring and the vertical ring, and a coil of the primary coil. A vertical torquer for a gyrocompass, characterized in that the tracking pickup is made to operate also as a vertical torquer by inserting a partial rectifier circuit formed by connecting a diode and a resistor in parallel between this section and the AC power supply. .