DE1232830B - Towing device for towing objects for helicopters - Google Patents

Description

Towing device for towing objects for helicopters The invention relates to a towing device for a helicopter, which for this purpose is used to drag objects by means of a rope.

When dragging objects on the water or along the surface of the earth by means of a helicopter, the force generated by the rotor must be in the forward direction be inclined so that a horizontal component of the force is obtained that is equal to the resistance of the object to be towed or greater than this. This usually creates a horizontal component of lift in helicopters generated that the blade tip plane of the rotor by means of the device for cyclic Angle of attack change of the rotor blades is inclined. There are also other institutions for this purpose known. However, such institutions only master a range of a few degrees and therefore only result in relatively small horizontal force components. To horizontal To obtain force components that are of a sufficient size for towing processes, it is, as was found, necessary, the rotor axis or the helicopter itself to tilt.

When the attachment point of the tow hook on the helicopter is in the center of gravity of the helicopter is the only moment that causes the Helicopter is available, the one that results from the inclination of the lift force of the rotor results. Because this moment is due to the distance between the rotor hub and the center of gravity of the helicopter and by means of the cyclic blade adjustment mentioned above achievable angle of inclination is limited, this moment is insufficient uni to provide adequate control for satisfactory towing.

When the attachment point of the tow hook on the helicopter is not in the center of gravity of the helicopter and the helicopter for towing is tilted, then there is only a single angle of inclination at which the Line of action of the drag force passes through the center of gravity, so that no moment is generated, which seeks to raise the helicopter. At any other angle of inclination the line of action of the towing force is shifted relative to the center of gravity and creates a moment that tries to change the helicopter's attitude. Because the only one available moment that can counteract such a moment, that is, which results from the inclination of the lift force of the rotor and, as above mentioned, is limited, adequate safe control is not achievable. Furthermore, such a control torque does not have a sufficient magnitude for that due to the towing force Generated moment to overcompensate when the towing process is finished and the helicopter should be returned to a horizontal position.

The purpose of the invention is therefore to provide means which the helicopter in an inclined towing position for the towing process and in a horizontal position Move into position when the towing process is to be ended.

The invention, accordingly, relates to a towing device for towing of items for helicopters with at least one rotor, with one from the pilot operable control stick for cyclic adjustment of the angle of attack of the rotor blades, where the line of action of the towing force normally passes through the center of gravity of the Helicopter goes, refers, is that the pulling device by one movement of the control stick can be pivoted relative to the helicopter via an actuating device is, so that by the drag force acting on the pulling device a to the The center of gravity of the helicopter is created, which is caused by the movement of the stick introduced control torque reinforced.

Further features within the scope of the invention are characterized in the subclaims. Embodiments of the invention are explained below with reference to the drawing. F i g. 1 shows a side view of a helicopter in its position when towing an object; F i g. 2 shows the details of the pulling device and the actuating device in a side view of the helicopter; F i g. 3 is a plan view showing the controls for the rotor of the helicopter; - F igl. Figure 4 is a cross-section of the helicopter in a plane behind the rope hook attachment; F i g. Fig. 5 is an exploded view of the pulling device; F i g. 6 is a side view of a helicopter according to another embodiment.

According to FIG. 1 , the helicopter 10 is provided with a tow bar 11 which is attached to the fuselage of the helicopter in its center of gravity Cg. is attached and which extends downwards and backwards from its attachment point during a towing process. A tow rope 12 connects the free end of the rod 11 with the object 13 to be towed, which is shown here as a truck. It can be seen that the line of action of the towing force runs in the direction of the towing rod, so that it passes through the center of gravity of the helicopter and does not generate a moment that tries to straighten the helicopter during the towing process.

The tow bar 11 is, as shown in FIG. 5 , it is provided at its upper end with a fork-shaped connecting piece 14 by means of which the rod is pivotably mounted on an axle 15 which in turn is carried by a pivot block 16 . The block 16 is provided at both ends with pivot pins 17 by which it is pivotably connected to a support arm 18 which is attached to the cell of the helicopter. One end of the axle 15 is connected to a servomotor 19 which is pivotably attached to the cell with the aid of a support arm 20 and which can pivot the tow rod 11 about the axis of the pivot pin 17 . As shown in FIG. 2, the lower end part of the rod 11 is connected to a servomotor 21 which is attached to the fixed frame of the helicopter in an articulated manner on the support arm 22 and which can pivot the rod 11 about the axis 15 . The servomotors 19 and 21 are provided with control valves 23 and 24, respectively, which can be fed with pressure medium from a source not shown.

As shown in FIGS. 2 and 3 , the controls of the pilot comprise - as usual - the control stick 25 for cyclical change of the angle of attack of the rotor blades, the pitch lever 26 for collective change of the blade angle and flow pedals 27 for the rudder control.

The inclination of the buoyancy force of the rotor to the front or back occurs analogously by moving the control stick 25 to the front or back via a horn 29, a tube 28, a link 31 and an angle lever 30 and further links and angle levers up to the swash plate 32.

The inclination of the buoyancy force to the left or right occurs analogously by moving the stick 25 to the left or right via a link 34 which extends through the tube 28 , an angle lever 135 and others, link and angle lever and an angle lever36 up to the swash plate31. As a result of the inclination of the swash plate, the angles of attack of the rotor blades 33 are changed correspondingly cyclically.

This design of the control of the cyclical change in the angle of attack of the rotor blades is known. A link 37 is pivotably connected at one end to the angle lever 30 and at its other end to a lever 38 which is articulated on the housing of the control valve 24. The other end of the lever 38 is connected to the valve member of the control valve 24, via which pressurized working medium can be supplied to one or the other side of the servomotor 21. Similarly, a link 39 is pivotably connected at one end to the angle lever 36 and at its other end to a lever 40 which is articulated on the housing of the control valve 23. The other end of the lever 40 is pivotably connected to the valve member of the control valve 23 , via which pressurized working medium can be supplied to one or the other side of the servomotor 19.

In operation, a movement of the stick 25 forwards via the Rome 29 and the link 31 causes the angle lever 30 to rotate counterclockwise (according to FIG. 2). The rotation of the angle lever 30 causes a displacement of the valve member of the control valve 24 via the handlebar 37 and the lever 38 , so that pressurized working fluid is fed to the rear end of the servomotor 21, whereby the piston rod of the servomotor 21 is drawn in and the tow rod 11 is relatively closed the helicopter is rotated about the axis 15 clockwise (according to FIG. 2). The line of action b of the towing force then runs below the center of gravity Cg., Whereby a tilting moment directed down the nose is generated, which causes an increase in the forward tilt of the helicopter into a position in which the line of action c of the towing force passes through the center of gravity again.

This process takes place when the stick 25 moves backwards vice versa.

A movement of the stick 25 to the left causes the angle lever 36 to rotate counterclockwise (according to FIG. 2) via the link 34, the angle lever 35 and the associated link system. The rotation of the angle lever 36 causes a displacement of the valve member of the control valve 23 via the handlebar 39 and the lever 40, whereby pressurized working fluid is fed to the rear end of the servomotor 19 , whereby the piston rod of the servomotor 19 is drawn in and the tow rod 11 around the Pivot pin 17 is rotated clockwise (seen from above). The line of action of the towing force then runs to the left of the center of gravity and at an angle to the longitudinal axis of the helicopter so that a combination of a roll movement of the helicopter and a yaw movement to the left is caused.

When the stick 25 is moved to the right, this process is reversed.

In Fig. 6 shows another embodiment in which the fastening point 41 of the tow rope is not in the center of gravity of the helicopter, but below and backwards from the center of gravity. The helicopter is shown in the towing position, and it can be seen that the line of action a 'of the towing force, which extends along the rod 11 , passes through the center of gravity.

The tow bar 11 is in the above with reference to F ig. 5 and connected to a servomotor 42, which can pivot the tow rod 11 about the axis 15 by retracting or extending the piston rod. A valve 43 controls the admission of pressurized working medium to one or the other end of the servomotor 42, and the valve is actuated by a linkage which is connected to the angle lever 30 .

Movement of the lever 25 forward causes Accordingly, in addition to the cyclic angle of attack of the rotor blades a displacement of the valve member of the control valve 43 so that the upper end of the servo motor 42 is supplied with pressurized working fluid whereby the tow bar 11 in the in F i g. 6 position shown by dotted lines is pivoted. As a result, the line of action b 'of the towing force, which runs in the direction of the tow rope 12, is opposite the center of gravity Cg. shifted so that a tilting moment pressing the nose downward is generated. This moment causes the helicopter to increase its forward inclination to a position in which the tow rope 12 is again aligned with the rod 11 and the line of action c 'of the towing force again passes through the center of gravity.

When the stick 25 is moved backwards, this process is reversed.

From Fig. 6 it can also be seen that the servomotor 44 is attached to the cell of the helicopter and connected to the axis 15 in a manner similar to that described in relation to FIG. 5 is connected. A valve 45 controls the admission of pressurized working medium to one or the other end of the servomotor 44. This valve is actuated by a linkage which is connected to the angle lever 36 .

A movement of the stick 25 to the left accordingly causes, in addition to the cyclical change in the angle of attack of the rotor blades, a displacement of the valve member of the control valve 45, so that pressurized working medium is fed to the lower end of the servomotor 44, whereby the piston rod of the servomotor 44 retracts and the towing rod 11 is pivoted about the pivot pin 17. The line of action of the towing force, which runs in the direction of the tow rope 12, is thereby shifted relative to the center of gravity, so that a yaw and roll moment is generated to the left, whereby the tow rope 12 is then aligned again with the rod 11 and the line of action c 'of Towing force passes through the center of gravity again.

When the stick 25 is moved to the right, this process is reversed.

Claims (2)

Patent claims: 1. Towing device for towing objects for helicopters with at least one rotor, with a control stick that can be operated by the pilot for cyclical adjustment of the angle of attack of the rotor blades, the line of action of the towing force normally going through the center of gravity of the helicopter, which is indicated by gck that the pulling device (rod 11) can be pivoted relative to the helicopter by a movement of the control stick (25) via an actuating device (servomotors (19, 21 or 44, 42)) so that the towing force acting on the pulling device causes a center of gravity ( Cg.) Of the helicopter is created, which amplifies the control torque introduced by the stick movement. 2. Pulling device according to claim 1, characterized in that the actuating device has a first servomotor (21 or 42) for pivoting the pulling device about an axis parallel to the transverse axis of the helicopter (15) and a second servomotor (19 or 44) for pivoting the Has pulling device about an axis perpendicular to the axis (15). 3. Pulling device according to claim 2, characterized in that the pivoting by the first servomotor (21 or 42) in the back and forth movement of the control stick (25) and the pivoting by the second servomotor (19 or 44) with lateral movement of the Joystick takes place. 4. Pulling device according to claim 1, 2 or 3, characterized in that the joint around which the pulling device pivots is arranged in the center of gravity (Cg.) Of the helicopter. References considered: U.S. Patent No. 2,663,523; British Patent No. 748 059.