DE102015201935A1 - Arrangement for controlling flaps on wings of an aircraft - Google Patents

Abstract

It is proposed an arrangement for driving flaps (F_A, F_I) on wings of an aircraft, wherein at least one central drive (PCU) and at least one switchable planetary gear (GBX_0, GBX_L, GBX_R) is provided, the central drive (PCU) with a central coupled between the left wing and the right wing Umlaufrädergetriebe (GBX_0) is coupled, and wherein the central planetary gear (GBX_0) at least one clutch (K_0) for locking and releasing the epicyclic gear (GBX_0) is associated.

Description

The present invention relates to an arrangement for controlling flaps on wings of an aircraft according to the closer defined in the preamble of claim 1. Art.

For example, from the document EP 1 547 917 A1 is a device for controlling and adjusting flaps on aircraft wings known. Each wing side are associated with two adjacent flaps. Each of the flaps has associated drive units which are actuated via a central drive via associated drive shafts. In order to allow independent adjustment of adjacent flaps of a wing side, the drive shafts of adjacent flaps are coupled via a differential gear, wherein another drive train of the differential gear is coupled to a secondary drive, so that the movements of the drive train for the flaps on the central drive and the secondary drive for the flaps can be superimposed.

In such aircraft high lift systems, simple mechanical systems are used to position the flaps. These systems consist of a central transmission shaft, which is guided through the wing and connects stations for flap operation. At the stations, mechanical torque and gearbox provide the torque required to move or position the flaps. Each door requires two stations to operate the door. The central transmission shaft is driven by the central drive unit, wherein between the central drive and the transmission shaft gear and waves for angular and / or axial offset are used. Consequently, the flaps of each wing are connected to the central drive unit, so that a differential movement of the flaps relative to each other relative to the wings is not possible.

The present invention is based on the object to propose an arrangement of the type described above, which allows for the smallest possible design effort a differential flap adjustment of the flaps of the two wings.

This object is achieved by the features of claim 1. Advantageous embodiments will become apparent from the dependent claims and the description and the drawings.

Thus, an arrangement for driving flaps on wings of an aircraft is proposed, wherein at least one central drive and at least one switchable epicyclic gear are provided. According to the central drive is coupled to a centrally arranged between the left wing and the right wing Umlaufrädergetriebe, wherein the central planetary gear at least one clutch is assigned to lock and unlock the epicyclic gear.

Accordingly, a lockable planetary gear is integrated in the known arrangement. If the epicyclic gear is locked, so a block circulation is realized, the flaps of the right and left wing are adjusted simultaneously with the arrangement, while in the unlocked state, the differential gear or Umlaufrädergetriebe allows only a portion of the flaps is adjusted, although a other part remains in the position. This differential control of the flaps takes place without additional drive units or the like. It is readily possible that different types of planetary gear transmissions are used. For example, so-called bevel gear differentials but also spur gear differentials or planetary gear differentials can be used with at least three waves.

The switchable planetary gear can be locked and thus rotate in the block to provide no torque or speed conversion. It is also possible that the planetary gear is used as a transmission gear by the setting of a shaft. Finally, it is also possible that the planetary gear is used as a superposition gear when all waves have a speed.

In the context of advantageous embodiments, the central planetary gear can be combined with decentralized epicyclic gearboxes with or without additional activatable drives. For example, for this purpose, a decentralized planetary gear between the inner flaps and the outer flaps are connected to the corresponding drive shaft.

The proposed arrangement will be further explained with reference to the drawings. Show it:

1 a schematic view of an inventive arrangement for driving flaps of an aircraft by way of example with reference to the right wing;

2 a table with possible functions of the arrangement as a function of operating states of the arrangement;

3 a schematic view of the inventive arrangement with decentralized epicyclic gearbox on the wings exemplified on the right wing;

4 a table with corresponding functions depending on the operation of the arrangement;

5 a schematic view of the arrangement with a further variant of a decentralized planetary gear example by way of the right wing;

6 a schematic view of the arrangement with a next embodiment of a decentralized Umlaufrädergetriebes based on the right wing;

7 a further schematic view of the arrangement with a coupled with a brake decentralized epicyclic gearbox example using the right wing;

8th a table with possible functions depending on operating conditions of the arrangement;

9 a schematic view of the arrangement with central epicyclic gearbox and with decentralized epicyclic gearbox with activatable drive motor by way of example with reference to the right wing;

10 a schematic view of the arrangement with decentralized drive motors based on both wings;

11 a schematic view of the arrangement of both wings with decentralized drive motors at the ends of the wings and central brake;

12 a schematic view of the arrangement of an alternative arrangement of the drive motors on both wings;

13 a schematic view of the arrangement with a next alternative arrangement of the drive motors on both wings;

14 a schematic view of the arrangement with two centrally arranged drive motors for the wings;

15 a schematic view of the arrangement with central clutch and decentralized drive motors at the ends of the wings;

16 a schematic view of the arrangement with centrally located brake and decentralized clutches and brakes on the wings;

17 a schematic view of the arrangement with connected via a brake central drive motor and decentralized via the clutch and brake connected drive motors;

18 a schematic view of the arrangement with two decentralized drive motors and planetary gears on the left wing and a decentralized drive motor on the right wing;

19 a schematic view of the arrangement with a decentralized drive motor on the right wing and decentralized drive motor and epicyclic gearbox on the left wing with centrally arranged brake;

20 a schematic view of the arrangement according to 19 without a decentralized coupling on the right-hand wing between the decentralized drive motor and the decentralized brake;

21 a schematic view of the arrangement with two connected via a brake drive motors and two decentralized Umlaufrädergetrieben; and

22 a schematic view of the arrangement with two connected via brakes central drive motors and associated with both wing ends wing tip brakes.

In the figures, an arrangement according to the invention for driving inner flaps F_I and outer flaps F_A is shown by way of example on wings of an aircraft, wherein at least one central drive PCU and at least one switchable epicyclic gear GBX_0, GBX_L, GBX_R is provided.

According to the invention, the central drive PCU is coupled to a planetary gearbox GBX_0 arranged centrally between the left-hand support surface and the right-hand supporting surface, wherein at least one clutch K_0 for locking and releasing the epicyclic gearbox GBX_0 is associated with the central epicyclic gearbox GBX_0, thus allowing a differential valve adjustment becomes.

Like, for example 1 it can be seen, each wing is associated with a shaft W_R, W_L, which then drives the respective stations 1 to 4 for actuating the inner flaps F_I and the outer flaps F_A. Every wing or each wing may be associated with a so-called wing tip brake or safety brake WTB_R and WTB_L, with which a certain system state or operating state of the arrangement by closing the WTB_R, WTB_L can be maintained. It is also conceivable that the central drive PCU is driven accordingly in order to achieve a holding effect.

The centrally arranged epicyclic gearing GBX_0 comprises a compensation carrier AT supporting a compensating wheel AR which is coupled to the central drive PCU, the compensating wheel AR having both the flaps F_A, F_I of the right-hand supporting surface activating the shaft W_R as the first central wheel ZR 1 and one of the flaps F_A, F_I of the left wing driving left shaft W_L as the second central gear ZR 2 is engaged and wherein via the central clutch K_0 of the balance carrier AT with one of the central wheels ZR 1, ZR 2 is connectable.

1 shows by way of example the right wing or the right wing of the aircraft with the arrangement according to the invention, in which the epicyclic gearing GBX_0 is designed, for example, as a bevel gear differential. In this possible embodiment, the central drive PCU is connected, for example via a spur gear with the balance carrier AT, which stores the designed as a bevel gear differential gear AR. The compensating wheel AR is engaged both with the first central gear ZR 1 as a bevel gear and with the second central gear ZR 2 also as a bevel gear. The first central wheel ZR 1 is connected to the left-hand shaft WR_L of the left-hand wing, while the second central gear ZR 2 is connected to the right-hand shaft W_R of the right-hand wing. Via the central clutch K_0, the left shaft W_L is connected to the compensation carrier AT when it is closed.

The design with the central epicyclic gearbox as a conical differential results in the advantage that the same ratio between the central drive PCU and the left or right wing adjusts when the function "flap right or left wing procedure" is activated. As already mentioned, however, other types of epicyclic gearboxes are possible in principle. Under certain circumstances, these lead to an asymmetrical transmission between the central drive PCU and the left and right shaft W_R, W_L. In the illustrated variant with bevel gear differential results in a translation of i = n_S / n_L = n_S / n_R = 0, 5. The speed of the central drive n_PCU corresponds to the speed of the web shaft or the differential cage or the balance carrier AT, while the speed at the right wave W_R with n_R and the speed of the left wave W_L is denoted by n_L. The translation is independent of the choice of the number of teeth.

In the arrangement with centrally arranged planetary gear according to 1 results in the locked state (central clutch K_0 activated or closed) all the functions that are possible even with known arrangement. However, in the unlocked state, it is possible, for. B. including the wingtip brakes WTB_R, WTB_L the inner flaps F_I and the outer flaps F_A, for example, the left wing to adjust simultaneously and in the same direction, while the inner flaps F_I and the outer flaps F_A the right wing are held in position. The same function is also possible for the other wing.

The table according to 2 gives an overview of possible functions depending on the activation of the arrangement to activate or deactivate. In this case, drive_PCU means that the central drive PCU applies a drive torque and Bremse_PCU means that the central drive PCU applies a braking torque and a movement is prevented. This is done in the system either by the haltendwirkenden central drive PCU or by a closed wing tip brake WTB_R, WTB_L.

The table indicates which actuation of the arrangement is necessary to perform the various functions of "holding both wings", "adjusting both wings equally", "moving right wing flaps through air loads", "moving left wing flaps through air loads", "flaps right wing procedure "and flaps move left wing", to activate or not to activate. Here an X in the corresponding fields means that "Drive_PCU", "Brake_PCU", "K_0", "WTB_R" or "WTB_L" is active, while an X in brackets means that the drive could be active. An empty field means that the corresponding control is not active in order to perform the corresponding function.

In 3 is a further embodiment with decentralized epicyclic gearing GBX_R shown with an active drive motor M_R example on the right wing, the left wing can be configured according to identical.

This means that the right-hand shaft W_A is assigned a right-hand peripheral planetary gearbox GBX_R between the inner flaps F_I and the outer flaps F_A of the right-hand wing and that the left-hand shaft W_L has at least one left-hand peripheral planetary gearbox GBX_L between the inner flaps F_I and the outer flaps F_A assigned to the left wing is, wherein the right decentralized Umlaufrädergetriebe GBX_R and the left decentralized Umlaufrädergetriebe GBX_L can be configured, for example, as a bevel gear or as a spur gear differential.

In 3 the embodiment is shown as bevel gear differential, in which the outer flaps F_A are connected to the balance carrier AT, wherein a first central gear ZR 1 is connected as a bevel gear with the inner flaps F_I. The second central gear ZR 2 as a bevel gear is connected to the decentralized drive motor M_R or M_L of the support surface, wherein the compensation carrier AT via a decentralized coupling K_R or K_L with the first central gear ZR 1 is connectable and wherein the drive motor M_R or M_L with a decentralized brake B_R or B_L of the respective wing is connected.

In normal operation, both decentralized differential gears or epicyclic gearboxes GBX_R and GBX_L are blocked by activated or closed decentralized clutches K_R and K_L. Thus, the arrangement behaves like known arrangements, so that all the flaps can be adjusted simultaneously and in the same direction with the central drive PCU. When opening the decentralized clutch K_R or K_L in the decentralized epicyclic gearbox GBX_R or GBX_L and by engagement of the other existing brake elements B_R or B_L arise in this embodiment of the arrangement various functions, which in the in 4 shown again with an X for activation, an X for possible activation, and an empty non-activation field.

The hold functions are shown in the first three columns. The flaps F_I, F_A can be held in their current position. There are several ways to do this, depending on which brake elements can or should be used. The fourth column represents the adjustment function of all flaps F_I, F_A of the wings. All flaps F_I, F_A can be adjusted in the same direction and at the same time. The functions described above represent the functions of known arrangements.

In the arrangement according to the invention further adjustment functions according to columns 7 and 9 are possible. For example, adjusting only the outer flaps F_A. By opening the decentralized right-hand epicyclic gearbox GBX_R, ie when the decentralized clutch K_R is not active, the additional drive unit or the additional decentralized drive motor M_R can move the outer flap F_A independently of all other flaps. The other flaps are held in their current position. The fact that in the left wing also a decentralized drive unit or a decentralized drive motor M_L is provided, the outer flaps F_A of the left wing can also be simultaneously adjusted independently of each other and independently of the inner flaps F_I, which in column 11 in 4 is shown.

The adjustment function according to column 5 corresponds to the adjustment of only the inner flaps F_I. By opening the decentralized clutch K_R and the decentralized clutch K_L and by activating the wing tip brakes WTB_L and WTB_R, the inner flaps F_I can be adjusted with the central drive PCU and the outer flaps are held in their position.

The adjustment functions according to columns 8 and 10 correspond to the adjustment of all the flaps except one of the outer flaps. For this purpose, the holding of, for example, the right outer flap F_A of the right wing is described. The right outer flap F_A of the right wing is held by the wing tip brake WTB_R and separated from the rest of the shaft by opening the remote clutch K_R. The central drive PCU can now move all other flaps simultaneously and in the same direction.

There are also other combinations conceivable. For example, an outer flap F_A of the right or left wing can be held, while the inner flaps F_I both wings are moved to the central drive PCU and the other outer flap F_A by the decentralized Umlaufrädergetriebe GBX_R and GBX_L as a superposition gear independently of the inner flaps F_I can be adjusted.

5 shows another variant of decentralized differentials and drives on the wings. According to 5 is exemplified the right wing, wherein the balance carrier AT of the decentralized epicyclic gearbox GBX_R and GBX_L is connected to the inner flaps F_I, wherein the first central gear ZR 1 is connected as a spur gear with the decentralized drive motor M_R or M_L. Furthermore, the second central gear ZR 2 is connected as a spur gear to the outer flaps F_A, wherein the first central gear ZR 1 and the second central gear ZR 2 are coupled via a 2-stage spur gear as a compensating wheel AR. The compensation carrier AT can be connected to the second central gear ZR 2 via the decentralized clutch K_R or K_L, wherein the decentralized drive motor M_R or M_L is connected to the decentralized brake B_R or B_L.

In this variant, it is provided that the ratio between the decentralized drive motor M_R or M_L and the outer flaps F_A is maximum, which offers the advantage that the Torque of the additional decentralized drive motors M_R and M_L is translated correspondingly high and they require a corresponding lower drive torque. Other requirements can lead to other connections of the waves W_R or W_L and are also possible in principle.

In 6 is a further embodiment of a decentralized Umlaufrädergetriebes GBX_R or GBX_L shown with decentralized drive motor M_R or M_L. In this case, the compensation carrier AT of the decentralized epicyclic gearbox GBX_R or GBX_L is connected to the outer valves F_A, the first central gear ZR 1 being connected as a sun gear to the drive motor M_R or M_L. The second central gear ZR 2 as a ring gear is connected to the inner flaps F_I, wherein the sun gear and the ring gear are coupled via a planetary gear as a balancing gear AR. The drive motor M_R or M_L is connected to the decentralized brake B_R or B_L, wherein the first central gear ZR 1 can be connected to the second central gear ZR 2 via the decentralized clutch K_R or K_L.

Another embodiment with decentralized differential with decentralized braking device is in 7 shown. In this embodiment, an additional to the respective shaft W_R or W_L wave for connecting a decentralized brake B_R to the waves W_R or B_L is provided. A decentralized drive motor M_R or M_L is not provided. It is conceivable that the flaps F_I or F_A are moved by air loads. For this purpose, different areas of the arrangement can be decoupled and selectively released, so that the external loads can move certain flaps F_I, F_A. A later synchronization is also possible, in which all flaps F_I, F_A are actively brought into the same position.

At the in 7 The compensation carrier AT of the decentralized epicyclic gearbox GBX_R or GBX_L is connected to the decentralized brake B_R or B_L, wherein the first central gear ZR 1 is connected as bevel gear to the inner flaps F_I, while the second central gear ZR 2 is connected to the outer gear as bevel gear Flaps F_A is connected. The first central gear ZR 1 and the second central gear ZR 2 are coupled via the formed as a bevel gear balance wheel AR. The compensation carrier AT can be connected to the first central gear ZR 1 via the decentralized clutch K_R or K_L.

In 8th a table is shown for the possible functions. Here again the functions in the columns and the components of the arrangement to be activated or not activated are shown in the lines. Also in this table, an X in the corresponding field means the activation of the component of the assembly, an X in parentheses the possible activation of the component of the assembly, a Y a controlled engagement, and an empty field the non-activation of the component of the assembly.

After the flaps F_I and F_A have been moved by the air load, they can be held in their position. The other flaps F_I and F_A are brought into the same position by the central drive PCU. If all the flaps F_I and F_A are synchronized again, the central drive PCU can initially move all the flaps F_I and F_A back the same.

According to 9 is a combination of central epicyclic gearing GBX_0 and two decentralized epicyclic gearing GBX_L and GBX_R shown.

In the aforementioned embodiments, a direction of rotation reversal compensation can also take place in that in the corresponding figures, a spur gear with intermediate gear is provided for this purpose, for example with angular gear, which is necessary due to the Flügelpfeilung. Other types of planetary gear transmissions are also conceivable. In this case, it is also possible to provide other shaft connections of the epicyclic gearing GBX_0, GBX_R, GBX_L. The blocking of the epicyclic gearboxes GBX_0, GBX_R, GBX_L by the central clutch K_0 or by the decentralized clutches K_L and K_R can also be achieved in other ways. For example, between other waves. It is also conceivable to provide a so-called fail-safe system or a redundant system, for example by pressure outlet brakes and clutches.

The provided decentralized drive motors M_R and M_L can be driven hydraulically or the like. It is also conceivable that the drive motors M_R and M_L act as a generator, so that a return of energy into the electrical system of the aircraft is possible.

The decentralized brakes B_R and B_L may be mechanical, hydraulic, electric or the like. It also diagnostic functions are possible, which can also be performed before the start to rule out errors in the arrangement. For this purpose, the individual elements or components can be controlled accordingly and errors are excluded in this way. For this purpose, no additional sensor is required, but today's sensors, such as speed, rotation angle sensors on the central drive PCU and the wingtip brakes WTB_R, WTB_L are sufficient for this purpose to enable these functions. The envisaged central or decentralized clutches K_0, K_R, K_L or brakes B_0, B_R, B_L are usually referred to as normally closed units executed. However, normally open versions can also be used.

10 to 22 show further embodiments of the arrangement according to the invention to adjust the flaps of the right wing independently of the left wing and also to allow independent adjustment between the outer flaps F_A and the inner flaps F_I. In particular, the embodiments are characterized by the fact that, in addition to the previously possible functions, they can realize further functions with fewer or more simply constructed components. The used drive motors M_0, M_R, M_L and the used brakes B_0, B_R, B_L as well as the used clutches K_0, K_R, K_L can be actuated hydraulically with a corresponding safety concept. It can be provided that the decentralized right drive motor M_R is fed by a hydraulic system other than the decentralized drive motor M_L. An advantage of decentralized drive motors M_R, M_L results from the fact that the engines are not arranged in the fuselage of the aircraft. Thus, the noise pollution is lower.

10 shows a variant of the arrangement in which the outer end of each shaft W_R, W_L a decentralized drive motor M_R, M_L is assigned, which is connectable via a decentralized coupling K_R, K_L respectively with the shaft W_R, W_L, wherein the ends of the left and Right wave W_R, W_L is assigned in each case a decentralized brake B_R, B_L.

11 shows an embodiment supplemented by a central brake B_0 for safety reasons, in which the central brake B_0 is connected to the left and right shaft W_R, W_L between the right and the left wing.

12 shows an embodiment of the arrangement in which the outer end of each shaft W_R, W_L of the wings each have a decentralized brake B_R, B_L is assigned. Between the right and left wing also the central brake B_0 is assigned to the waves. Furthermore, in each case between the inner flaps F_I and the outer flaps F_A on each shaft W_R, W_L of the wings a decentralized drive motor M_R, M_L via an associated decentralized coupling K_R, K_L connected. With the two decentralized drive motors M_L, M_R a fail-operational behavior is achieved in which after a break, the arrangement can continue to operate with the same performance.

13 shows a next embodiment of the arrangement in which the outer end of each shaft W_R, W_L of the wings each have a decentralized brake B_R, B_L is assigned. Furthermore, a central brake B_0 is assigned to the shafts W_R, W_L between the right-hand and left-hand wings and, moreover, a decentralized drive motor M_R, M_L is connected between the inner flaps F_I and the outer flaps F_A on each shaft W_R, W_L of the wings.

Another version with central drive motor M_0, which is connected decentrally, is in 14 shown. It is envisaged that two central drive motors M_0 are provided, wherein a first drive motor M_0 between the wings and the second drive motor M_0 is assigned to the respective end of the shafts W_R, W_L of the wings, the ends each having a decentralized brake B_R, B_L and a assigned to the wings associated central brake B_0.

If the in 10 a central coupling K_0 is added, a differential flap adjustment between the flaps of the left and right wing is made possible, which in 15 is shown. Here, the central coupling K_0 is provided between the wings for connecting right shaft W_R and left shaft W_L. The central coupling K_0 can be designed as a so-called normally closed coupling, so that it can only be opened in the intact system. Again, it is possible to additionally provide a central brake B_0.

In 16 is an execution as per 11 illustrated, it being additionally provided that between the inner flaps F_I and the outer flaps F_A on the right shaft W_A and on the left shaft W_L each have a decentralized coupling K_R, K_L is provided. This allows a differential flap adjustment between the inner flaps F_I and the outer flaps F_A on each wing. Thus, in this arrangement, the inner flaps F_I can be moved into positions, with all the flaps moved simultaneously and in the same direction. In this position, the flaps can be locked by the central brake B_0 and by opening the decentralized clutches K_R and K_L, the outer flaps can be moved independently of the inner flaps F_I and independently. In addition, an independent actuation of the outer flaps F_A is possible. As a result, a substantial multi-function is made possible with little extra effort, with the provided decentralized drive motors M_R, M_L being far away from the passengers.

In addition to the in 16 illustrated embodiment is in the in 17 a central drive motor M_0 connected via the central brake B_0 with the right shaft W_R and the left shaft W_L. In this way The inner flaps F_I can be moved even when the outer flaps F_A stationary. Thus, the inner flaps F_I can be adjusted independently of the outer flaps F_A.

In 18 is the in 10 shown arrangement is supplemented by the fact that between the inner flaps F_I and the outer flaps F_A the left wing a decentralized drive motor M_L and a decentralized epicyclic gears GBX_L are arranged, between the epicyclic gearing GBX_L and the drive motor M_L a decentralized brake B_L is provided. Furthermore, a decentralized clutch K_R is provided between the inner flaps F_I and the outer flaps F_A of the right-hand wing.

Due to the displacement of the central motor M_0 and the use of a differential gear with two degrees of freedom (normal non-lockable planetary gear) as decentralized epicyclic gearing GBX_L an asymmetric structure can be generated, which has similar properties. By different control of the motors M_L M_R (these are operated according to the kinematics with different speeds to produce a uniform movement of all valves F_I and F_A), the same properties as described above can be achieved. The third motor M_L is also arranged here at a large distance from the passengers.

19 shows another asymmetrical concept in which a central brake B_0 is provided between the wings, which is connected to the left shaft W_L and the right shaft W_R. Furthermore, a decentralized clutch K_R is provided between the inner flaps F_I and the outer flaps F_A of the right-hand wing. The outer end of the right shaft W_R is assigned a decentralized drive motor M_R, which can be connected to the right shaft W_R via a clutch K_R, wherein a decentralized brake B_R is assigned to the end of the right shaft W_R. Between the inner flaps F_I and the outer flaps F_A of the left wing a decentralized drive motor M_L and a decentralized planetary gear GBX_L as a planetary gear with 2 degrees of freedom, which is not blocked, assigned between the epicyclic gearing GBX_L and the planetary gear and the drive motor M_L a decentralized brake B_L is provided.

20 shows another asymmetric concept in which it is provided that a central brake B_0 is provided between the wings, which is connected to the left shaft W_L and the right shaft W_R. Furthermore, both ends of the wings are assigned a decentralized brake B_R and B_L. In addition, a decentralized clutch K_R is connected to the right shaft W_R between the inner flaps F_I and the outer flaps F_A of the right-hand wing. Between the inner flaps F_I and the outer flaps F_A of the left-hand wing, a decentralized drive motor M_L and a decentralized epicyclic gearbox GBX_L are connected to the left-hand shaft W_L, with a non-lockable planetary gear being used as epicyclic gearing. Between the planetary gearbox GBX_L and the decentralized drive motor M_L a decentralized brake B_L is provided.

21 shows an embodiment of the arrangement in which each end of the wings is assigned a decentralized brake B_R, B_L. Furthermore, between the inner flaps F_I and the outer flaps F_A on the right shaft W_R and the left shaft W_L are each assigned a decentralized planetary gearbox GBX_R, GBX_L as a normal non-lockable planetary gear, each with a first central drive motor M_0 and a first central brake B_0 are connected. Between the wings, a central second drive motor M_0 and a second central brake B_0 are further connected to the right shaft W_R and the left shaft W_L.

Finally shows 22 a further embodiment of the arrangement in which it is provided that each end of the left shaft W_L and the right shaft W_A a wing tip brake WTB_R, WTB_L are assigned. Furthermore, a decentralized clutch K_R, K_L is connected to the right shaft W_R and the left shaft W_L between the inner flaps F_I and the outer flaps F_A. Between the wings, a first central drive motor M_0 and a second central drive motor M_0 are each connected via a central brake B_0 to the left shaft W_L and the right shaft W_R.

In the in the 10 to 20 The illustrated embodiments is in the 1 to 9 illustrated central drive PCU and the central epicyclic gearing GBX_0 preferably not further shown. It is also conceivable that the statements according to 10 to 22 without central drive PCU and / or planetary gearbox GBX_0 can be used.

In summary, it can be stated that the engine, clutch and brake units do not necessarily have to be hydraulically actuated. The aforementioned concepts are predominantly aligned with the central waves of the wings.

The executions on aircraft or aircraft are also transferable with more than four flaps. The versions are also transferable to so-called Slats. Whichever Requirements are made to the drives, also further simplifications are possible. For example, it is necessary for a defective engine to be disconnected from the system. For example, this can be done via coupling unit or the like.

reference numeral

• FA

  outer flaps

  f_i

  inner flaps

  PCU

  Central drive

  GBX_0

  central epicyclic gearbox

  GBX_L

  left decentralized epicyclic gearbox

  GBX_R

  right decentralized epicyclic gearbox

  K_0

  central coupling

  B_0

  central brake

  K_R

  right decentralized clutch

  K_L

  left decentralized clutch

  B_r

  right decentralized brake

  B_L

  left decentralized brake

  AT

  balance beam

  AR

  pinion

  ZR 1

  first central wheel

  ZR 2

  second central wheel

  W_R

  right wave

  W_L

  left shaft

  M_0

  central drive motor

  M_r

  right decentralized drive motor

  M_L

  left decentralized drive motor

  WTB_R

  right wing tip brake

  WTB_L

  left wing tip brake

  Station 1 to 4

  Actuation of the flaps

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1547917 A1 [0002]

Claims (22)

Arrangement for controlling flaps (F_A, F_I) on wings of an aircraft, wherein at least one central drive (PCU) and at least one switchable planetary gear (GBX_0, GBX_L, GBX_R) is provided, characterized in that the central drive (PCU) with a centrally between the left wing and the right wing arranged Umlaufrädergetriebe (GBX_0) is coupled, wherein the central epicyclic gearbox (GBX_0) at least one clutch (K_0) for locking and releasing the epicyclic gearbox (GBX_0) is assigned. Arrangement according to claim 1, characterized in that the centrally arranged epicyclic gearbox (GBX_0) comprises a balance wheel (AR) bearing compensating carrier (AT) coupled to the central drive (PCU), wherein the differential gear (AR) with both the flaps (F_A, F_I) of the right wing driving wave (W_R) as a first central wheel and with a the flaps (F_A, F_I) of the left wing driving left shaft (W_L) is engaged as a second central gear and that via the clutch (K_0) of the Compensation carrier is connectable to one of the central wheels. Arrangement according to one of the preceding claims, characterized in that the central epicyclic gear (GBX_0) for setting a same ratio on the right shaft (W_R) and the left shaft (W_L) is designed as a bevel gear differential. Arrangement according to one of the preceding claims, characterized in that in the central bevel gear differential of the balance carrier (AT) with the central drive (PCU) is connected, that the differential gear (AR) is designed as a bevel gear and with the first central wheel (ZR 1) as a bevel gear and engaged with the second central gear (ZR 2) as bevel gear, that the first central gear (ZR 1) is connected to the left shaft (W_L) and the second central gear (ZR 2) to the right shaft (W_R), and that by the central coupling (K_0), the left shaft (W_L) with the balance carrier (AT) is connectable. Arrangement according to one of the preceding claims, characterized in that the right-hand shaft (W_R) is assigned at least one right-hand peripheral planetary gearbox (GBX_R) between the inner flaps (F_I) and the outer flaps (F_A) of the right-hand wing and / or the left-hand one Shaft (W_L) is assigned at least one left peripheral planetary gear (GBX_L) between the inner flaps (F_I) and the outer flaps (F_A) of the left wing, wherein the right decentralized Umlaufrädergetriebe (GBX_R) and the left decentralized Umlaufrädergetriebe (GBX_L) as a bevel gear differential or designed as a spur gear differential. Arrangement according to claim 5, characterized in that the balance carrier (AT) of the decentralized planetary gear (GBX_R, GBX_L) is connected to the outer flaps (F_A) that a first central wheel (ZR 1) connected as a bevel gear with the inner flaps (F_I) is that a second central gear (ZR 2) is connected as a bevel gear with a decentralized drive motor (M_R, M_L) of the support surface, that the balance carrier (AT) via a coupling (K_R, K_L) is connectable to the first central wheel and that the drive motor (M_R, M_L) is connected to a brake (B_R, B_L) of the respective wing. Arrangement according to one of claims 5 or 6, characterized in that a balance carrier (AT) of the decentralized epicyclic gearbox (GBX_R, GBX_L) is connected to the inner flaps (F_I) that a first central wheel (ZR1) as a spur gear with the decentralized drive motor ( M_R, M_L), that a second central gear (ZR2) is connected as a spur gear with the outer flaps (F_A), wherein the first central gear (ZR1) and the second central gear (ZR 2) via a 2-stage spur gear as a balance wheel (AR) are coupled, that the balance carrier (AT) via the decentralized coupling (K_R, K_L) with the second central gear (ZR2) is connectable and that the drive motor (M_R, M_L) with the decentralized brake (B_R, B_L) is connected. Arrangement according to one of claims 5 to 7, characterized in that the balance carrier (AT) of the decentralized epicyclic gearbox (GBX_R, GBX_L) is connected to the outer flaps (F_A) that the first central gear (ZR 1) as a sun gear with the decentralized drive motor (M_R, M_L) is connected, that the second central gear (ZR 2) are connected as a ring gear with the inner flaps (F_I), wherein the sun gear and the ring gear via a planetary gear as a differential gear (AR) are coupled, that the drive motor (M_R , M_L) is connected to the decentralized brake (B_R, B_L) and that the first central gear (ZR 1) can be connected to the second central gear (ZR 2) via the decentralized clutch (K_R, K_L). Arrangement according to one of claims 5 to 8, characterized in that the balance carrier (AT) of the decentralized epicyclic gearbox (GBX_R, GBX_L) is connected to the decentralized brake (B_R, B_L) that the first central gear (ZR 1) as bevel gear with the inner flaps (F_I) is connected, that the second central gear (ZR 2) is connected as bevel gear with the outer flaps (F_A), wherein the first central wheel (ZR 1) and the second central wheel (ZR 2) via the as bevel gear trained compensating wheel (AR) are coupled, and that the balance carrier (AT) via the decentralized coupling (K_R, K_L) with the first central wheel (ZR 1) is connectable. Arrangement according to one of the preceding claims, characterized in that the outer end of each shaft (W_R, W_L) is associated with a decentralized drive motor (M_R, M_L), which via a decentralized coupling (K_R, K_L) with the shaft (W_R, W_L). can be connected, wherein the ends of the shafts (W_R, W_L) is assigned a decentralized brake (B_R, B_L). Arrangement according to claim 10, characterized in that between the right and the left wing a central brake (B_0) with the shafts (W_R, W_L) is connected. Arrangement according to one of the preceding claims, characterized in that the outer end of each shaft (W_R, W_L) of the wings is assigned in each case a brake (B_R, B_L) that between the right and the left wing a central brake (B_0) the waves (W_R, W_L) is assigned and that in each case between the inner flaps (F_I) and the outer flaps (F_A) to each shaft (W_R, W_L) of the wings a drive motor (M_R, M_L) via an associated decentralized clutch (K_R, K_L ) is attached. Arrangement according to one of the preceding claims, characterized in that the outer end of each shaft (W_R, W_L) of the wings in each case a decentralized brake (B_R, B_L) is assigned, that between the right and the left wing a central brake (B_0) the Waves (W_A, W_L) is assigned and that in each case between the inner flaps (F_I) and the outer flaps (F_A) to each shaft (W_R, W_L) of the wings a decentralized drive motor (M_R, M_L) is connected. Arrangement according to one of the preceding claims, characterized in that two central drive motors (M_0) are provided, wherein a first drive motor (M_0) between the wings and the second drive motor (M_0) associated with the respective end of the shafts (W_R, W_L) of the wings is and that the ends each have a decentralized brake (B_R, B_L) and the wings a central brake (B_0) are assigned. Arrangement according to claim 10, characterized in that a central coupling (K_0) is provided between the wings for connecting right shaft (W_R) and left shaft (W_L). Arrangement according to claim 11, characterized in that between the inner flaps (F_I) and the outer flaps (F_A) on the right shaft (W_R) and on the left shaft (W_L) each have a decentralized coupling (K_R, K_L) is provided , Arrangement according to claim 16, characterized in that a central drive motor (M_0) via the central brake (B_0) with the right shaft (W_R) and the left shaft (W_L) is connected. Arrangement according to claim 10, characterized in that between the inner flaps (F_I) and the outer flaps (F_A) of the left wing a decentralized drive motor (M_L) and a decentralized epicyclic gearbox (GBX_L) are arranged, wherein between the planetary gear (GBX_L) and the drive motor (M_L) is a decentralized brake (B_L) is provided and that between the inner flaps (F_I) and the outer flaps (F_A) of the right wing a decentralized coupling (K_R) are provided. Arrangement according to one of the preceding claims, characterized in that a central brake (B_0) is provided between the wings, which is connected to the left shaft (W_L) and the right shaft (W_R), that between the inner flaps (F_I) and the outer flaps (F_A) of the right wing a decentralized coupling (K_R) are provided, that the outer end right shaft (W_R) is associated with a decentralized drive motor (M_R), which via a decentralized coupling (K_R) with the right shaft (W_R ) is connectable, wherein the end of the right shaft (W_R) is associated with a decentralized brake (B_R), and that between the inner flaps (F_I) and the outer flaps (F_A) of the left wing a decentralized drive motor (M_L) and a decentralized Planetary gear (GBX_L) are arranged, wherein between the planetary gear (GBX_L) and the drive motor (M_L) a decentralized brake (B_L) is provided. Arrangement according to one of the preceding claims, characterized in that a central brake (B_0) is provided between the wings, which is connected to the left shaft (W_L) and the right shaft (W_R), that a decentralized brake (B_0) at both ends of the wings ( B_R, B_L), that between the inner flaps (F_I) and the outer flaps (F_A) of the right-hand wing a decentralized coupling (K_R) is connected to the right-hand wave (W_R), and that between the inner flaps (F_I) and the outer flaps (F_A) of the left wing a decentralized drive motor (M_L) and a decentralized epicyclic gearbox (GBX_L) with the left shaft (W_L) is connected, between the planetary gear (GBX_L) and the decentralized drive motor (M_L) a decentralized brake (B_L) is provided. Arrangement according to one of the preceding claims, characterized in that a decentralized brake (B_R, B_L) is assigned to each end of the wings, that between the inner flaps (F_I) and the outer flaps (F_A) on the right shaft (W_R) and the are each assigned a decentralized planetary gear (GBX_R, GBX_L), which are each connected to a first central drive motor (M_0) and a first central brake (B_0) and that between the wings a second central drive motor (M_0) and a second central brake (B_0) is connected to the right shaft (W_R) and the left shaft (W_L). Arrangement according to one of the preceding claims, characterized in that each end of the left shaft (W_L) and the right shaft (W_R) are associated with a wing tip brake (WTB_R, WTB_L) connected to the right shaft (W_R) and the left shaft (W_L ) between the inner flaps (F_I) and the outer flaps (F_A) each have a decentralized coupling (K_R, K_L) is connected and that between the wings a first central drive motor (M_0) and a second central drive motor (M_0) each via a central Brake (B_0) to the left shaft (W_L) and the right shaft (W_R) are connected.

Images