DE2009847B2 - Device for rotating a hanging load around its vertical axis - Google Patents

Description

The invention relates to a device for rotating a - in particular on the load hook of a hoist - hanging load around its vertical axis, consisting of a gyroscopic system, its precession moment according to the principle of a tilting axis running at right angles to a horizontal gyro axis takes effect.

In the case of cranes and loading harnesses, loads are usually only suspended from a rope or tackle. Between Loads and rope or tackle, a vortex is arranged, which serves the purpose of the necessary turning the load around the vertical axis without twisting the tackle (rope).

The loads were usually rotated by hand or with an electric motor via a gear, it being necessary that external moments ⁶ S act on the load. In the first case, ropes are attached to the load in the simplest way and the load is thus rotated into the desired position. In the second case, a motor is switched between the load and the suspension. However, a torque can only be exerted on the load when the counter-torque can be absorbed by an auxiliary rope spread apart from the loading platform. In many cases, however, the auxiliary rope can rub against hatch coamings and the cargo, which limits the usability of the method.

A device is already known in which there is no need to absorb the counter torque, because here the housing of a motor suspended vertically with its axis is designed as a freely rotating mass and the rotor axis on the one hand via a vortex with the tackle, on the other hand via a hook connected to the load. So here the housing mass (moment of inertia) and its velocity outweigh the mass of the load and its velocity. A disadvantage of this known device the control of the rotational movement and the change in the direction of the rotational movement. Because the housing mass cannot exceed a certain mass for reasons of the profitability of the hoist used. Your circulation speed will therefore have to be very high. However, this high rotational speed must always be slowed down and brought to the value zero when the rotation of the load about its vertical axis is complete. The speed of rotation of the housing mass must, however, increase again in the opposite direction if the load is to be rotated backwards. This is particularly disadvantageous when, as a result of the oscillating movement of the load hanging in the hoist, small corrections of the rotational position of the load about its vertical axis that follow one another often have to be made. Considerable power is required for this in order to be able to generate the deceleration torques and the acceleration torques in the shortest possible time.

Furthermore, a device has been proposed in an earlier application, which consists of a gyro system exists whose precession moment according to the principle of a right-angled to a horizontal gyro axis running tilt axis becomes effective. There are two versions of this:

a) The gyro system is fixedly coupled to the load with respect beidsinniger rotations about the vertical axis, and its movement around the tilt axis "■" it means of a drive controllable With a -nc. 'η forced tilting movement of the Kt i :;. ^"; the load (+ gyro system) as specified s', - ..; a rotation around the vertical axis «. ,,.

b) The gyro system is freely movable around the tilt axis, and between the gyro system and the A torque around a vertical axis can be applied to the load with the aid of a drive. The circle reacts to the torque with a simple tilting movement, and so it can handle the counter-torque to raise.

These types of arrangement are generally sufficient in all cases in which the freely suspended load is around her The suspension point does not perform pendulum-like vibrations or these vibrations only in one plane take place, which is perpendicular to the gyro axis. If these conditions are not met, as is the case with cranes and ship loading gear is the case, the gyro axis changes its angular position, ζ. B. to the horizontal, and such a change in angular position would be similar or equal to a rotation about the tilt axis.

That means, oscillations of the Lasl around their point of suspension would in this case lead to an unintentional triggering of a precession movement and the Load to convey a rotation around its vertical axis, which is due to pendulous vibrations of the Load around its suspension point is undesirable.

Any construction with only one gyro also has the following disadvantage: In the rest position, the axis of the gyro lies in the horizontal, i. h “its angular momentum has only a horizontal component. When the top is tilted, its axis is turned out of the horizontal, ie the horizontal component of the angular momentum is reduced. It is thus destroyed the angular momentum of what is always a torque other words necessary: When tilting the Sch "jngrades unwanted torque occurs about a horizontal axis, resulting in rocking movements of the load this-s is important because, when loading light Loads or with an idle stroke only with the sling, the load or the sling very quickly gets into uncontrollable pendulum movements.

The problem underlying the invention is to eliminate these deficiencies.

The invention consists in that the gyro system consists of two in different directions of rotation, but with equal angular momentum rotating machine-driven gyroscopes and that both rotary axes arranged in the rest position in the horizontal plane and around them at right angles and to each other parallel horizontal tilt axes are pivotable in opposite directions.

In such a construction with two gyroscopes, the two are horizontal components of angular momentum always the same opposite. So there is no horizontal component of the angular momentum on the outside. the So there are no difficulties with the single gyro system just described.

When the load oscillates around its suspension points in a plane parallel to the axes of the gyroscope two oppositely directed precession moments occur, which cancel each other out, so that too any unwanted rotation of the load around a vertical axis is avoided. When tilting the top it becomes like already described, the horizontal component of the angular momentum is reduced. Because the tops rotate in opposite directions rotate, the torques resulting from the reduction of the angular momentum are raised by a horizontal one Axis on each other so that no rocking movement can occur.

Another advantage of the two-circuit system for the single-circuit design is that the gyroscopes can be smaller for the same performance of the device, since two are available. This in turn means that you can work with higher speeds than with a gyroscope, since the bearing forces are correspondingly smaller due to the small masses. Higher speeds mean smaller masses, which means that the two-gyro system can be made more compact and lighter than the single-gyro system. ίο

A rotation of the load can be achieved with two different versions:

a) The rotary movement is achieved in that the gyro system about a vertical axis with the Load is firmly coupled and the swiveling movements of the gyroscope around the tilting axes as a function are controllable from each other. They lead to a precession movement in the same direction, whose size is proportional to the sum of the angular momentum of the individual gyroscopes.

b) The rotary movement is achieved in that between the gyro system and the load a torque about a vertical axis with the help of a Drive can be applied, and the gyroscopes are freely pivotable about the tilting axes.

If a torque is exerted on this gyro system around a vertical axis, the gyroscopes react with opposing tilting movements and thereby absorb the counter torque.

A possible asymmetry of the swivel movements impossible to make, they are carried out by means of a swiveling device that is common to both gyroscopes. are the tilting axes with each other (e.g. by means of a gearbox) coupled that only pivoting movements by equal angles in the opposite direction possible are.

The gyro system forms a non-rotatable platform that generates the counter torque of an underneath, z. B. on the rotor side with the platform and on the stator side with the load connected rotary drive.

The above-described embodiments of the invention Devices are to be placed below the vertebra in the suspension between the load and the suspension point is provided. Within this range, the device according to the invention above or below the load hook or also directly or indirectly in connection with the load or the hot utensil and / or the spreading devices of the hot utensils.

In the designs of the device according to the invention, it is advantageous to use the gyro axes and the Set up axes of the gyro suspension fixable to avoid damage when the device out of order and exposed to rough handling.

The invention is illustrated schematically and by way of example in the drawing. It shows

F i g. 1 a schematic representation of what is described under a),

F i g. 2 is a schematic representation of what is described under b).

Fig.1 shows schematically the device in connection with a load 8. The gyro system causing the rotation consists of the gyro drives 1, 1 ', the gyro axes 2.2 'and the gyro masses 3.3'.

F i g. 1 also shows the load 8 hanging in a hoist on the hook 6, which with the help of a swivel 5 around a vertical axis is rotatable. For this purpose the z. B. a container representing load with the Vortex 5 connected by spread load ropes 9. The expansion means 10 consist essentially of rods or pipes and form a frame which is approximately in the horizontal plane and delimits the accommodates device according to the invention, which consists of two counter-rotating gyroscopic systems 1, 2, 3, Γ, 2 ', 3', which are pivotable about tilt axes 15, 15 '. This pivoting movement is also in opposite directions and will shared by one of the two tilting axes 15 and 15 'and with them by mechanical transmission means 12,12 'connected swivel drive 13 accomplished.

Any other type of pivoting device can also be used for the worm drive shown come.

2 illustrates, so to speak, the reverse the training according to F i g. 1.

F i g. 2 again shows two gyro systems 1, 2, 3

and Γ, 2 ', 3', carried by the load ropes 9, expansion means 10 below the vortex 5. The tilting axes 15, 15 ' the two gyroscopes are connected to one another by means of a gear 19, the two tilting axes one mutually opposite movement of the same size and the same speed allows to disruptive Avoid asymmetry between the tilting movements of the two gyroscopes. With the one carrying the tops rotatable platform, which consists essentially of the expansion means 10, is below the same Rotary drive 16 connected, its rotor 17 with the platform and its stator 18 with the load 8 in connection stands.

The application of the invention is not limited to handling heavy loads, but rather them is also of particular importance for all those cases in which the load can also be rotated from the outside attacking means by hand or with the help of mechanical aids is not possible but who are particularly concerned with the very precise handling of the load.

For this purpose 2 sheets of drawings

Claims (7)

Patent claims: 1. Device for rotating a - especially on the load hook of a hoist - hanging Load around its vertical axis, consisting of a gyroscopic system, whose precession moment according to the principle of a tilt axis running at right angles to a horizontal gyro axis is characterized in that the gyro system consists of two in different directions of rotation, but machine-driven gyroscopes (1,2,3, Γ, 2 ', 3') and that both gyro axes (2, 2 ') are arranged in the horizontal plane in the rest position and about horizontal tilt axes (15, 15 ') running in opposite directions at right angles to them and parallel to one another are pivotable. 2. Device for a load that is tightly coupled to the gyro system about a vertical axis Claim 1, characterized in that the pivoting movements of the gyroscopes (1, 2, 3. Γ, 2 ', 3') about the tilting axes (15, 15 ') can be controlled as a function of one another. 3. Device in which between the gyro system and the load, a torque of a vertical Axis can be applied with the aid of a drive, according to claim 1, characterized in that the Gyroscope (1, 2, 3, 1 ', 2', 2 ') are freely pivotable about the tilt axes (15, 15'). 4. Device according to claims 1 and 2, characterized in that the pivoting movement by means of a swivel drive (13) common to both gyroscopes. 5. Device according to claims 1 and 3, characterized in that the tilting axes (15, 15 ') coupled to one another we ^r the that only pivoting movements by equal angles in the opposite direction are possible. 6. Device according to claims 1 to 5, characterized in that it is above or below of the crane hook (6) is arranged. 7. Device according to claims 1 to 6, characterized in that the gyro axes and the tilt axes fe ^ 'are settable.