DE1481594B - Blade bearing for a helicopter rotor - Google Patents

Description

The invention relates to a blade bearing for a helicopter rotor with two blades on the longitudinal axis arranged, each having at least one layer of an elastomer having bearings, wherein the elastomeric layer of one of the two bearings extends essentially transversely to the longitudinal axis of the blade and arranged between two surfaces of bearing supports running essentially transversely to the longitudinal axis of the blade and is attached to these, of which the bearing bracket, which is closer to the blade, has the hub and the bearing bracket closer to the hub is connected to the blade.

Such a blade storage is known (US Pat. No. 3,111,172). Only one thing serves here Bearing to absorb the centrifugal forces of the rotating blade. This camp offers a certain Resistance to adjustment of the blade pitch angle (rotation of the blade around the blade's longitudinal axis). Furthermore, this bearing serves to provide resistance to the pivoting movement due to its rigidity and against the flapping motion of the blade. The second, with the known blade storage The bearing used, on the other hand, is designed quite differently and only serves to accommodate transverse to the blade axis acting forces. This second bearing does not take up the centrifugal forces during rotation of the leaf at, and it does not affect the torsion spring action of the first bearing, which at this serves to absorb the forces from the blade adjustment movement. Overall, this results in the known blade storage that the first, extending essentially transversely to the longitudinal axis of the blade Bearing can absorb high loads as a result of centrifugal forces, but it has a relatively high resistance to pitch movements. The invention is on the other hand, the task based on creating a blade bearing using elastomeric bearings, which when recorded large centrifugal forces has a low resistance to pitch movements. In the case of a blade bearing of the type mentioned at the outset, this is achieved according to the invention in that the second, spaced from the first bearing of the same design and attached to the hub and the sheet is attached.

This has the following advantages:

- Since the centrifugal forces are evenly divided between two bearings, the size of each bearing can can be significantly reduced, which also results in a reduction in flow resistance the camp results.

- Although the same or even greater centrifugal forces can be absorbed than with a bearing, there is a significant reduction in the rigidity of the bearing Blade adjustment movements, namely because the torsion spring stiffness of the bearings Function of the square of the bearing radius is so that when using two accordingly Smaller bearings instead of a large one, the torsional stiffness is roughly halved.

- The damping and / or the spring stiffness in the flapping and pivoting direction of the blade can easily be mastered or controlled by choosing the distance between the two bearings without affecting the torsional stiffness of the bearings with respect to blade setting movements.
55

A blade bearing is known (USA.-Patent 2 830 669), which has two identically constructed bearings lying one behind the other. Included However, these are rigid spherical shell bearings and not elastomeric bearings, where the Problem of reduction in resistance to pitch movements occurs.

In a further development of the invention, the two bearings can be symmetrical to one transverse to the longitudinal axis of the blade extending axis be arranged. This results in both simplified and simplified manufacture Storage particularly favorable storage properties.

3 4

In the above first-mentioned known sheet pressure to be increased under compressive load, there are several

storage, the hub-side bearing connection consists of insert plates 12 made of metal or another

two material of low elasticity running approximately parallel to the longitudinal axis of the blade at intervals of-

Struts with two extending roughly transversely to these - each other in the whole body transversely to the direction

the, arranged on the blade longitudinal axis at a distance from each other 5 of the centrifugal load and with the

arranged bearing support ^ for receiving the elasto-body connected. The deposits 12 prevent one

several layers of bearings. In the invention, the body 10 can bulge under pressure

now the blade-side bearing connection similarly increase and thereby increase the stiffness of the body. On the other hand

built and offset around the longitudinal axis of the blade, the inlays do not affect the shear stiffness of the

be arranged on the hub bearing connection. So that io body 10 and therefore not the elasticity of the

the result is a particularly simple structure of the joint for the torsional movement for change

Storage in which the distances between those of the blade pitch angle. On the other hand, the increase

both bearings and the formation of the two deposits considerably the stiffness of the joint against ^

Bearings themselves can be varied widely to accommodate the centrifugal load.

an optimal combination of the bearing properties 15 The joint 7 has a bearing element 13 a, which is to achieve. Further features in the context of which the earth arm 2 is attached, with a spherical surface 13, are identified in the remaining subclaims which face the rotor shaft, furthermore a bearing, element 14 α, which is attached to the blade 3

Embodiments of the invention are in a spherical surface 14 facing this, and

Drawing shown and are in the following 20 a body 15 made of an elastomer between

wrote. It shows the surfaces 13 and 14 arranged and with them

F i g. 1 a rotor head is connected in a plan view. The body 15 is provided with inlays 12

Helicopter, provided which the stiffness of the joint opposite

F i g. 2 in a plan view of a modified form to increase the centrifugal force load, the shear stiffness of the

However, this does not affect the shape of the rotor head for a lifting joint. The surfaces 13 and

screwdrivers, 14 are spherical surfaces with the center 16. The

F i g. 3 shows a section along line 3-3 in FIG. 1 joint 6 is designed similarly to joint 7.

and the joints 6 and 7 are parallel to each other

4 shows a section along the line X-X in FIG. 1. switches, so that the centrifugal force load on the blade

In the drawing, 1, the rotor shaft hub 30 is divided between the two joints and denotes a given one of a helicopter. This hub has compressive stress on the elastomer of the outer several radially protruding arms 2, each of which is reduced with the diameter of the joints. Bear the blade 3 coaxial with the arm. The rotor shaft webs 8 α and 13 a are miteinwird driven by struts 8 b by the usual gear. The other connected, the leaves radially outward from the axis is each assigned an adjustment linkage, which is 35 of the sheet arranged with this axis of symmetry and driven at the same speed as the are. The webs 9 α and 14 α are similarly rotor and an arm 3 α, which is connected to each other by struts 9 b , the radial set of the blade pitch angle rotates the blade around its outward from the axis of the blade with this as the longitudinal axis . In addition to the rotation about the leaf axis of symmetry and offset to the struts 8 b , each leaf can have a flapping movement around a 40 ordered. As a result of the smaller diameter of the horizontal axis 4 and a pivoting movement around the joints, the air resistance load must also have a vertical axis 5. The impact movement is smaller and the torsional stiffness for the movement of the movement about the axis 4 is indicated by the arrow 4 α- sheet of the arrow 2 α to change the sheet, the pivoting movement about the axis 5 by angle at a given centrifugal force absorption arrow 5 α and the movement to change the 45 capacity is approximately halved, because the torsion spring leaf setting angle around the axis of the arm 2 by a function of the square of the joint radius the arrow 2 a hard. is. As a result of the division of the centrifugal force load on

To enable the required movements, the two joints is also used to change the is the blade 3 with the arm 2 by two swing blade pitch required force to half metal joints 6 and 7 connected, which are reduced in the direction of 5 ° of the force that in comparable Konder Longitudinal axis of the sheet at a distance from each other is required in which the whole provided and arranged transversely to this axis centrifugal force load from a single joint. The oscillating metal joint 6 has a bearing.

element 8 α with a spherical surface 8, which is attached to the The stiffness in the direction of the arrow 4 a

Arm 2 is attached and facing the rotor shaft, 55 indicated flapping movement and in the direction of the

a bearing element 9 α with a spherical surface 9, the pivoting movement indicated by the arrow 5 α

attached to the sheet 3 and facing it, and is due to the distance between the joints 6

a body 10 made of an elastomer which is between and 7 and the distance between the centers

the surfaces 8 and 9 arranged and determined with them 11 and 16. These two distances can

is bound. The surfaces 8 and 9 are spherical surfaces 60 can be changed without the torsional

with the center point 11. It is not necessary, however, to change rigid in the direction of the arrow 2 α ,

that the surfaces 8 and 9 represent spherical surfaces, If the centers 11 and 16 coincide,

but they must have the same center. have the joints in the direction of the through the

It is essential that the surfaces 8 and 9 approximately arrow 4 α indicated stroke movement and in the

are arranged transversely to the longitudinal axis of the sheet, 65 direction of the indicated by the arrow 5 α

so that the centrifugal force load by a pressure swivel movement the least stiffness, because through

stress on the body 10 made of the elastomer, these movements of the elastomer only on shear

is recorded. To the stiffness of the elastomer is stressed. If, on the other hand, the midpoints

5 6

11 and 16 at a small distance from each other 23 made of an elastomer between one of the

lie, as shown in FIG. 1, a ball surface 24 of the arm 2 that faces the rotor shaft guides

movement in the direction of arrows 4 α and 5 a to and one connected to the sheet 3 and him

a certain compression of the elastomer, facing spherical surface 25 arranged and with

so that its rigidity is increased. The stiffener around which 5 of these surfaces is connected. Surfaces 24 and 25

Axes 4 and 5 can also thereby have changed the common center point 26. As in FIG

that the radius of curvature and the size of the embodiment according to FIG. 1 are in the elastomer

of the areas 8,9 and 13,14 can be changed. If spherical inserts made of a material of low

the curvature and the size of the surfaces are embedded and connected to the chosen elasticity,

are that they introduce a large component of pressure, i.e. to bulge out under pressure

will suppress the joints in the direction of the impact and thereby the stiffness of the joints in

movement and the direction of pivoting movement to increase the axial direction of the blade. Since the

rather stiff, so that approximately the same conditional surfaces 19, 20 and 24, 25 are convex to one another,

are obtained as with a rigid rotor. a considerable pressure component is initiated,

Another possibility is to make one of the 15, which opposes a rotation about the axes 4 and 5, one of the two joints 6, 7 more rigidly than the other, to resist. This means that the stiffness in that the joints are either of different sizes in the direction of the pivoting movement and the or made of materials with different spring rates of impact movement is very large, consist of at least ten times. The joints are connected in parallel and are as large as in the embodiment according to FIG. 1 therefore share the centrifugal and leaf forces proportionally and about a hundred times as large as in the construction to their spring stiffness. In the case of unequal springs according to US Pat. This is advantageous in the direction of the pivoting movement and the impact, because many designers of the helicopter movement prefer, when changing the blade setting, to lower the effective pivot point of the 25 pitch angle effective torsion spring constant as far as possible outwards from the rotor, because this movement to arrange the elastomer on a straight shaft. This can be achieved by using shear stress.

that the joint 7 is made stiffer than the joint

steer 6th rotor head according to F i g. 1 at the intersection of the axis

In the in F i g. 2 embodiment shown are 30 sen 4 and 5 is the spring stiffness for the Verdie Oscillating metal joints essentially the same. change of the blade pitch angle, the pivoting movement is formed as in Fig. 1, but not as in Fig. 1 and the flapping movement is the smallest. the with their spherical surfaces concave, but rather convex to- spring hardening for the pivoting movement and the each other. That is, the midpoints of the stroke movement are raised by moving the articular surfaces not between the joints, but 35 steered apart along the blade axis, the on the sides of the joints facing away from one another, the radius of curvature of the articular surfaces is changed and lie. Corresponding parts are arranged convexly to one another with the same function as numbered digits. this in FIG. 2 is shown. The spring stiffness for the

In this embodiment, the vibration is absorbed by shear stress

metal joint 17, which corresponds to joint 6, a change in the blade pitch angle is changed,

Body 18 made of an elastomer which is between one by the size of the elastomer body between the

the spherical surface 19 of the joint surfaces facing the rotor shaft is changed. The spring stiffness against

Arm 2 and one connected to the sheet 3 and absorbed by a compressive load

facing him spherical surface 20 arranged and with menen centrifugal load is changed by the

connected to these surfaces. The surfaces 19 and 20 45 elements can be changed, causing a bulging

have the common center point 21. The joint of the elastomer has a contact under pressure

22 corresponds to the joint 7 and has a body to oppose it.

1 sheet of drawings:

Claims (5)

Patent claims: 1. Blade storage for a helicopter rotor with two arranged on the longitudinal axis of the blade, in each case at least one layer of an elastomer having bearings, the elastomeric Layer of one of the two bearings extends essentially transversely to the longitudinal axis of the blade and between two surfaces of bearing supports running essentially transversely to the longitudinal axis of the blade is arranged and attached to these, of which the bearing bracket located closer to the sheet is connected to the hub and the bearing bracket closer to the hub is connected to the blade, characterized in that the second (6), spaced from the first (7) The bearing is of the same design and is connected to the hub (1) and the blade (3). 2. Blade mounting according to claim 1, characterized in that the two bearings (6,7) are symmetrical are arranged to an axis running transversely to the longitudinal axis of the blade. 3. Blade bearing according to claim 1, in which the hub-side bearing connection consists of two struts running approximately parallel to the longitudinal axis of the blade with two bearing supports which extend approximately transversely to the longitudinal axis and are spaced from one another on the longitudinal axis of the blade for receiving the elastomeric layers of the two bearings, characterized in that, that the blade-side bearing connection (9 a, 9 b, 14 ä) is constructed in the same way and is arranged offset about the longitudinal axis of the blade with respect to the hub-side bearing connection (2, Sa, Sb, 13 d) . 4. Blade storage according to claim 3, in which each of the bearing supports of one of the two bearings have spherical surface sections that are essentially concentric to one another, characterized in that that the spherical surface sections of the two bearings (6,7) are concave to one another. 5. blade storage according to claim 3, in which each of the bearing supports of one of the two bearings have spherical surface sections that are essentially concentric to one another, characterized in that that the spherical surface sections of the two bearings (17, 22) are convex to one another.