DE102020110427A1 - Brake device for control systems of aircraft - Google Patents

Abstract

The invention relates to a braking device for a control system of aircraft, the braking device comprising a housing and a multi-stage braking mechanism for deriving a torque of a shaft of the control system into the housing, a first stage of the braking mechanism being an electromechanical brake with at least one rotor and acts with at least one stator fixed on the housing, on which the rotor is braked in the active state of the electromechanical brake. According to the invention, a second stage of the braking mechanism has a mechanism that allows the brake disc to rotate against the shaft and, as a result of such rotation, boosts the brake force of the first stage or additionally fixes the shaft to a stator fixed to the housing within the second stage.

Description

The invention relates to a braking device for control systems and in particular high-lift systems of aircraft, comprising a housing and a multi-stage braking mechanism for diverting a torque of a shaft into the housing.

In aircraft, the movement of control surfaces such as slats or landing flaps is controlled by high-lift systems that have a central drive arranged in the aircraft fuselage and transmission shafts extending into the wings on both sides. Modern high-lift systems typically include braking devices in the wings, which in the active state derive a torque from the shaft into the wing structure and can fix the shaft to the wing structure, for example in order to fix the shaft in the event of an anomaly in the central drive and thus an asymmetry between the shafts of the two Avoiding wings.

In the prior art, such braking devices are usually designed as electromechanical brakes, with a brake disc being compressed by an armature to close the brake. The armature is mostly biased against the closed position by means of a spring and is held back by an electromagnet as long as it is energized, which corresponds to a de-energized closed version of the brake.

Due to physical limits in the performance of electromagnets with regard to the lifting force and, due to the degressive characteristic curve, the working stroke, there is an inherent limitation of the braking and holding torque that can be achieved with such brakes in relation to the size and weight of the brake. Therefore, such brakes often have little power reserve and even small changes, for example in the coefficient of friction, lead to unacceptable power losses. Ensuring the required braking and holding force under vibration conditions is also a major challenge, because here the mass acceleration of components with backlash acts on the brake. To optimize the efficiency of electromechanical brakes, brake disk packs with several staggered brake disks are used in the prior art in order to enlarge the friction surface. The improvement that can be achieved with this measure is limited due to the increase in the mass of the parts to be moved, the friction and the required working stroke.

Sufficient braking and holding forces for an at least statically safe brake are achieved in the prior art using a multi-stage design, the electromechanical brake being a first stage of the brake, the activation of which subsequently triggers a second stage. As a rule, ball ramps are used to activate a second brake disk package. As an example is the WO 2005/015044 A1 to call. However, these constructions are usually relatively large, heavy and expensive.

The object of the invention is to provide a braking device which, due to its multi-stage design, can provide sufficient braking and holding forces, but which, compared to known solutions, manages with a smaller number of parts and can be made more compact, lighter and more cost-effective.

Against this background, the invention relates to a braking device for a control system of aircraft, the braking device comprising a housing and a multi-stage braking mechanism for deriving a torque of a shaft of the control system into the housing, a first stage of the braking mechanism being an electromechanical brake at least one rotor, preferably at least one brake disk and with at least one stator fixed on the housing, on which the rotor is braked in the active state of the electromechanical brake.

According to the invention, it is provided that a second stage of the brake mechanism has a mechanism that allows the brake disc to rotate against the shaft and, as a result of such rotation, a brake force boost of the first stage or an additional fixation of the shaft on a stator fixed on the housing within the second stage causes.

The mechanism is used to activate the second stage as a result of a counter-torque acting on the shaft from the rotor, which occurs after the electromechanical brake of the first stage has been activated. The first stage serves as a trigger.

The braking mechanism is preferably a braking and holding mechanism which is intended not only to brake a moving shaft, but also to fix an unmoving shaft on the housing. The braking device is also preferably a braking and holding device. For the sake of simplicity, however, the terms of a brake mechanism and a brake device are used here, which in one embodiment are also intended to cover holding mechanisms or devices. The control system is preferably a high-lift system for controlling, for example, slats or landing flaps.

The multi-stage braking mechanism preferably comprises two stages. The mechanism of the second stage is preferably such that a rotation of the brake disc relative to the shaft by a certain angular amount is permitted.

The electromechanical brake of the first stage preferably comprises one or more brake disks, a variable position armature for optionally clamping and relieving the brake disks, a spring for preloading the armature against the brake disks (normally closed) or from the brake disks (normally open) and with an electromagnet for Movement of the armature against the mechanical prestress.

The electromechanical brake of the first stage is preferably a normally closed brake.

The brake disk can be a single brake disk. In one embodiment, however, a brake disk package is preferred.

In particular, it can be provided within the scope of the present invention that the first and the second stage of the braking device share one or more common components. The second stage is therefore at least partially integrated into the first stage. For example, both stages can share the same rotor and / or the same stator.

If the same stator is used together, the two stages can act at different points on the stator and use different contours or friction surfaces of the stator.

A special case of using the same rotor is the use of the same brake disc or the same brake disc package. In particular, it can be provided that the brake disc has two separate parts, an inner part extending radially inward from an annular dividing line and an outer part extending radially outward from the dividing line, the parts being connected to one another in a rotationally fixed manner , but can be moved in the axial direction relative to each other, the outer part of the brake disc is braked in the active state of the electromechanical brake of the first stage on the stator, the mechanics of the second stage of the braking mechanism being formed as a result of a rotation of the brake disc against the Shaft to cause an axial movement of the inner part of the brake disc relative to the outer part, and wherein a contour is provided on the inner part of the brake disc which, as a result of the axial movement of the inner part of the brake disc relative to the outer part, the brake force boosting of the first stage or the additional fix ation of the wave within the second stage causes. In the case of a brake disk pack, the inner part can be in contact with several or all of the individual brake disks and form their common inner part.

The mechanics of the second stage of the brake mechanism is preferably a ball ramp which has a plurality of balls enclosed between two driver disks, one of the driver disks being rotationally fixed to the shaft and the other of the driver disks being rotationally fixed to the brake disk of the electromechanical brake first stage is coupled. The other driver disk is preferably formed by the inner part of the brake disk.

Alternatively, the mechanics of the second stage of the braking mechanism can comprise other elements for activating the second stage, such as, for example, trapezoidal threads, helical grooves or eccentrically mounted bevel gears.

The additional fixation of the shaft within the second stage can take place in a variant of the invention by means of a frictional connection. As an example of a frictional or force-locking connection in the second stage, contacting of corresponding friction surfaces on a common stator of the first and second stage on the one hand and on the inner part of the brake disc on the other hand can be mentioned. The corresponding friction surfaces can be designed, for example, conical. As a further example, a pinch roller mechanism between a common stator of the first and second stages on the one hand and a body fixed in a rotationally fixed manner on the shaft on the other hand can be mentioned.

In another variant of the invention, the shaft can be additionally fixed within the second stage by means of a form fit. As an example of a frictional or force-locking connection in the second stage, the insertion of pins on the inner part of the brake disc or on the common stator of the first and second stage in grooves on the other part can be mentioned when the inner part of the brake disc is axially on moves the stator closed. As a further example, interlocking teeth on a common stator of the first and second stages on the one hand and on the inner part of the brake disc on the other hand can be mentioned.

In the context of the invention, the first stage is used to fix a mechanism that is activated when the shaft is rotated further. The mechanism works equally in both directions of rotation. An axial movement is preferably caused by rotation, which for Brake booster of the first stage or for frictional or positive locking of the shaft is used in the second stage.

One advantage of the braking device according to the invention is that, by integrating the second stage into the first stage, the number of parts, the required installation space and the weight can be kept low compared to known two-stage brakes. The mechanical reinforcement enables very high braking torques to be achieved regardless of the available magnetic force of the electromechanical brake. The holding torque generated is always greater than the applied torque. Due to the compact design, the braking device according to the invention can be integrated into gears or actuators without any problems. The electrical power requirement is low.

The invention also relates to a control system for an aircraft which comprises at least one braking device according to the invention.

The control system is preferably a high lift system for moving lift aids in the wings of an aircraft. Such a system typically comprises a central drive and transmission shafts extending therefrom on both sides, with one or more actuators for transferring loads into the buoyancy aids being arranged on each of the transmission shafts. The buoyancy aids can be slats or landing flaps, for example. Braking devices are preferably arranged on both transmission shafts in the area of the wings. In particular, these can be arranged in the distal end area of the transmission shafts behind the last actuator or between two of the outermost two, three or four actuators. The transmission shaft is the shaft whose torque is to be diverted into the housing of the braking device and consequently into the wing structure or which is to be fixed on the housing and consequently on the wing structure.

The invention also relates to an aircraft with at least one such control system.

The central drive of the control system or preferably high-lift system is preferably arranged in the aircraft fuselage and the transmission waves extend into the wings of the aircraft, with lift aids such as slats or landing flaps being connected to the actuators.

• 1: eine schematische Darstellung eines ersten Ausführungsbeispiels einer erfindungsgemäßen Bremsvorrichtung;
• 2: eine schematische Darstellung eines zweiten Ausführungsbeispiels einer erfindungsgemäßen Bremsvorrichtung;
• 3a-3b: schematische Darstellungen eines dritten Ausführungsbeispiels einer erfindungsgemäßen Bremsvorrichtung;
• 4a-4c: schematische Darstellungen eines vierten Ausführungsbeispiels einer erfindungsgemäßen Bremsvorrichtung; und
• 5: eine schematische Darstellung eines fünften Ausführungsbeispiels einer erfindungsgemäßen Bremsvorrichtung.

Further details and advantages of the invention emerge from the exemplary embodiments described below with reference to the figures. In the figures show:

• 1 : a schematic representation of a first embodiment of a braking device according to the invention;
• 2 : a schematic representation of a second embodiment of a braking device according to the invention;
• 3a-3b : schematic representations of a third embodiment of a braking device according to the invention;
• 4a-4c : schematic representations of a fourth embodiment of a braking device according to the invention; and
• 5 : a schematic representation of a fifth embodiment of a braking device according to the invention.

In 1 is an embodiment of a braking device according to the invention 100 shown schematically. The braking device shown 100 comprises a two-stage brake mechanism as an essential component, the first stage in the form of an electromechanical brake 110 and one with this electromechanical brake 110 includes coupled second stage. The two stages are in a common housing 101 the braking device 100 are arranged. A wave 102 runs in the axial direction through this housing 101 . With the aid of the two-stage brake mechanism, a torque of the moving shaft should be generated when the brake is active 102 in the housing 101 derived or the motionless wave 102 fixed to the housing in a torsion-proof manner.

The electromechanical brake 110 is designed as a normally closed brake (Power-Off-Brake, POB). It comprises a stop which is arranged in a stationary manner on the housing and serves as a stator 111 and an armature plate which can be displaced in the axial direction but is non-rotatably arranged on the housing 112 framed brake disc 130 . Instead of a single brake disc 130 A brake disk package can also be used, but for the sake of simplicity, only a single brake disk is shown in the figure. The anchor plate 112 is based on a metallic compression spring 114 against the brake disc 130 preloaded so that the brake disc 130 when the brake is de-energized 110 based on the spring force between the anchor plate and the stop 111 is clamped. From the perspective of the brake disc 130 behind the anchor plate 112 arranged electromagnet 115 works when the brake is energized 110 on the anchor plate 112 and pulls it against the bias of the spring 114 from the brake disc 130 which releases the brake.

In the exemplary embodiment, the second stage comprises 1 not an actual brake, but rather a brake booster for the electromechanical brake 110 the first stage.

The brake booster includes a ball ramp 120 , taking a number of balls 121 in a known manner between two drive plates 122 and 132 are edged, with the drive plates 122 and 132 on the surfaces facing each other are structured so that ramp-shaped tracks for the balls 121 are formed. One drive plate on the shaft side 122 is a radially protruding web on the shaft 102 formed and stands firmly with the shaft 102 in connection, i.e. non-rotatable and also without the possibility of axial displacement relative to the shaft 102 . The other driver plate on the brake side 132 is through the radially innermost section of the brake disc 130 the electromechanical brake 110 formed relative to the remaining outer part 131 the brake disc 130 is rotationally fixed, but can be moved in the axial direction, which will be discussed in more detail below. In any case, the brake-side drive plate is 132 using a disc spring 124 against the drive plate on the shaft side 122 biased. The disc spring or other compression spring 124 is supported against a radially protruding web 125 the wave 102 off, being between the web 125 and the disc spring 124 a thrust bearing 126 is arranged to allow relative movement between shaft 102 and brake-side drive plate 132 to enable.

The coupling between the drive plate on the brake side 132 and the remaining outer part 131 the brake disc 130 takes place on corresponding guide elements 133 on the outer jacket of the brake-side drive plate 132 and on the inner jacket of the outer part 131 the brake disc 130 (or the multiple brake disks in the case of a brake disk package). The guiding elements 133 allow a relative movement of the brake-side drive plate 132 compared to the remaining part 131 the brake disc 130 in the axial direction, but bind these parts to one another in a rotationally fixed manner. One radially from the outer jacket of the brake-side drive plate 132 protruding stop contour 134 serves as a stop with regard to an axial displacement of the outer part 131 the brake disc 130 relative to the inner part 132 in the direction of the drive plate on the shaft side 122 (to the right in the figure).

In the in 1 shown open state of the braking device 100 the brake disc rotates 130 together with the wave 102 , with the torque via the ball ramp 120 is transmitted.

Will the electromechanical brake 110 activated by the electromagnet 115 is switched off, the spring pushes 114 the anchor plate 112 against the brake disc 130 so that it is between the stators, namely the stop 111 and the anchor plate 112 is clamped and thereby braked. In response to that on the brake disc 130 The counter-torque generated is the brake-side drive plate 132 the ball ramp against the bias of the disc spring or other compression spring 124 from the drive plate on the shaft side 122 splayed and slightly in the direction of the stop 111 the brake 110 (to the left in the figure) axially displaced. The stop contour 134 ensures that in the course of this also the outer part 131 the brake disc 130 in the direction of the stop 111 the brake 110 (in the figure to the left) is pressed, so that there is a reinforcement of the originally only by the compression spring 114 clamping force exerted on the brake 110 comes.

In 2 is a further embodiment of a braking device according to the invention 100 shown schematically. Corresponding components are marked with corresponding reference symbols.

In this exemplary embodiment, the second stage comprises an additional friction brake with conical friction surfaces.

In this embodiment, there is no stop contour that extends radially from the outer surface of the brake-side driver disk 132 stand out and as a stop for the outer part 131 the brake disc 130 would serve. Instead, the inner and outer parts of the brake disc 130 are freely moved axially in both directions relative to each other. The brake-side drive plate 132 has a conical shape instead of the stop contour 135 on their drive plate on the shaft side 122 facing away. The conical surface of this formation 135 serves as the friction surface of an additional friction brake, which is located between the brake-side drive plate 132 and the attack 111 the brake 110 is trained. For this purpose, compared to the embodiment example 1 also the attack 111 extends inward in the radial direction and forms a conical friction surface on its inner lateral surface as a counterpart to the friction surface of the brake-side drive plate 132 the end. The angles of attack of the two friction surfaces correspond to one another.

Furthermore, in this embodiment, the 2 compared to the above-described embodiment of the 1 the one on the brake-side drive plate 132 acting disc spring and the associated axial bearing by a coaxially around the shaft 102 coiled coil spring 127 replaced, acting as a compression spring between the radial protruding web 125 the wave 102 and the drive plate on the brake side 132 extends.

In the in 2 shown open state of the braking device 100 the brake disc rotates in turn 130 together with the wave 102 , with the torque via the ball ramp 120 is transmitted.

Will the electromechanical brake 110 activated, the brake-side drive plate spreads apart 132 from the drive plate on the shaft side 122 , whereby the brake-side drive plate 132 in the direction of the stop 111 is axially displaced and the conical friction surfaces on the brake-side drive plate 132 and the attack 111 get in touch with each other. The conical friction surfaces that come into contact form a second braking stage. The attack 111 also serves as a stator for the second stage.

Due to the conical design of the friction surfaces, a large braking effect can be achieved in relation to the contact force. Based on variations in the angle of attack of the friction surfaces, in the radial distance between the friction surfaces and the shaft 102 , in the surface properties of the friction surfaces and in general in the design of the ball ramp 120 the braking characteristics can be adjusted to the exact requirements. The coil spring 127 can serve as an adjusting spring to compensate for a change in braking force when the friction surfaces are worn.

In 3a-3b is yet another embodiment of a braking device according to the invention 100 shown schematically. 3a shows the already 1 and 2 known schematic side view. 3b shows a schematic sectional view along the line BB. Corresponding components are also identified in this figure with corresponding reference symbols.

In this exemplary embodiment, the second stage comprises the 3a-3b a pinch roller mechanism.

In this embodiment too, the inner and outer parts of the brake disc 130 can be moved freely relative to each other axially in both directions and also in this embodiment is the brake-side drive plate 132 using a coaxially around the shaft 102 coiled compression spring 127 against the drive plate on the shaft side 131 biased. Instead of the conical shape, the driver plate on the brake side has 132 however, a roller cage on the relevant side in this exemplary embodiment 136 with several webs distributed over the circumference, axially from the brake-side drive plate 132 stand out and define individual roller pockets.

There is a polygonal body on the inside of the roller pocket facing the shaft 128 , which rotatably on the shaft 102 is attached and arranged coaxially to this. It has a sleeve-shaped basic shape and surrounds the compression spring 127 on the outside. The attachment of the polygonal body 128 on the shaft 102 takes place on a web which protrudes radially inward from the sleeve-shaped area and is located between the compression spring 127 and the jetty 125 inserts and up to the shaft 102 enough. The outer surface of the polygon body 128 is flattened on several sides in the area of the roller pockets so that its outer surface is not round in cross-section, but rather has the shape of a regular polygon with several edges, in the example shown the shape of a hexagon. This particular is off 3b evident. However, other polygonal shapes such as, for example, that of an octagon can also be provided. The flattened areas between the edges of the polygon body 128 form the bottoms of the roller bags. The number of roller pockets and the number of edges of the polygonal body 128 correspond to each other, so that in the case of the hexagon shown, the roller cage 136 forms six roller pockets.

The cover of the roller pockets running on the outside of the roller pockets facing away from the shaft is defined by the annular inner lateral surface of the stop 111 the electromechanical brake 110 educated. The attack 111 lies in the same axial position as the reel pockets and extends inward to a suitable extent.

There are cylindrical rollers in each of the roller pockets 129 arranged, the axis of which is parallel to the axis of the shaft 102 runs and whose diameter D is less than the maximum radial distance dmax between the polygonal body 128 and stop 111 , but larger than the minimum radial distance dmin between polygon bodies 128 and stop 111 is. The maximum radial distance dmax is measured starting from the center between two edges of the polygonal body 128 , the minimum radial distance dmin starting from the edges.

The tangential width of the roller pockets roughly corresponds to the diameter of the cylindrical rollers 129 and is less than the tangential width of the flattened areas on the outer surface of the polygonal body 128 . The relative angular position between the brake-side drive plate 132 on the one hand and the polygon body 128 on the other hand, the roller pockets are in the middle of the flattened areas on the outer surface of the polygonal body 128 lie.

In the in 3a-3b shown open state of the braking device 100 the brake disc rotates 130 together with the wave 102 , with the torque via the ball ramp 120 is transmitted. The relative angular position between the brake-side drive plate 132 on the one hand and the polygon body 128 on the other hand, it remains constant, so that the roller pockets are in the middle of the flattened areas on the outer surface of the polygonal body 128 stay and the rollers can rotate freely around their axis.

Will the electromechanical brake 110 activated, the driver plate on the brake side is activated 132 not only from the drive plate on the shaft side 122 splayed and in the direction of the stop 111 axially shifted, but also by a certain angular amount relative to the shaft 102 twisted. As a result, the roller pockets migrate from the center to the edges of the respective flattened areas on the outer surface of the polygonal body 128 , whereby the radial distance between the floor and the ceiling of the roller pockets until the diameter of the rollers is reached 129 decreases. If the radial distance reaches the diameter of the rollers 129 , the roles will jam 129 between the polygon body 128 and the attack 111 , whereby a second braking stage is formed. The form-fit clamping causes further movement of the shaft 102 blocked. The attack 111 in turn also serves as a stator for the second stage.

By varying the size of the roles 129 , the number of edges of the polygon 128 , the radial distance between polygon bodies 128 and stop 111 and compression force of the coil spring 127 response and clamping behavior can be set.

In 4a-4c is a further embodiment of a braking device according to the invention 100 shown. Corresponding components are again marked with corresponding reference symbols. 4a-4b show them already 1 , 2 and 3a well-known schematic side view of the open brake ( 4a) and the closed brake ( 4b) . 4c shows a schematic sectional view along the line CC.

In this exemplary embodiment, the second stage comprises a positive locking mechanism.

As in the exemplary embodiments according to 2 and according to 3a-3b can also in this embodiment, the inner and outer parts of the brake disc 130 are freely moved axially in both directions relative to each other. As in the embodiment according to 1 is the brake-side drive plate 132 using a disc spring 124 against the drive plate on the shaft side 122 preloaded, with the disc spring 124 against a radially protruding web 125 the wave 102 supported and being between the web 125 and the disc spring 124 a thrust bearing 126 is arranged to allow relative movement between shaft 102 and brake-side drive plate 132 to enable.

The brake-side drive plate 132 has in this exemplary embodiment on its the drive plate on the shaft side 122 facing away from axially protruding pins 141 on. The attack 111 the electromechanical brake 110 includes on its the brake-side drive plate 132 facing side partially annular grooves 116 at corresponding radial positions. The shape of the grooves 116 is particularly in 4c clearly visible.

In the in 4a shown open state of the braking device 100 the brake disc rotates in turn 130 together with the wave 102 , with the torque via the ball ramp 120 is transmitted.

Will the electromechanical brake 110 activated, there is again a spreading of the brake-side drive plate 132 from the drive plate on the shaft side 122 , whereby the brake-side drive plate 132 in the direction of the stop 111 is shifted axially and the pins 141 in the partially annular grooves 116 of the attack 111 be pushed as it is in 4b is shown. Will be the ridge between the grooves 116 hit, the shaft turns 102 a little further until the pins 141 engage in the grooves. This leads to a form-fitting blocking of further movement of the shaft 102 . The attack 111 also serves as a stator for the second stage.

The closed braking device 100 is therefore completely insensitive to vibrations, which are always a problem with frictional brakes. Due to the partially annular expansion of the grooves 116 dynamic braking is possible despite a form fit.

In 5 is a further embodiment of a braking device according to the invention 100 shown, the second stage comprises another variant of a positive locking mechanism.

In contrast to the embodiment according to 4a-4c there is a lack of pins on the brake-side drive plate 132 and on grooves at the stop 111 . Instead, according to the inner radius of the stop 111 and the outer radius of the brake-side drive plate 132 each other and on the outer surface of the brake-side drive plate 132 and the inner surface of the stop 111 Corresponding holding contours are formed. The holding contours on Outer jacket of the brake-side drive plate 132 can be used in a double function by the guide elements 133 for connection to the outer part 121 the brake disc 130 are formed. The retaining contours on the inner surface of the stop 111 can through tooth contours 117 are formed on that of the drive plate 132 facing area of the inner jacket.

Will the electromechanical brake 110 activated, the retaining contours on the outer surface of the brake-side drive plate are activated 132 on the corresponding holding contours on the inner surface of the stop 111 pushed, resulting in a positive blocking of further movement of the shaft 102 leads. If the end faces of the corresponding holding contours meet, the shaft rotates 102 a little further until the retaining contours can interlock. As in the embodiment according to 4a-4c a form fit can be achieved with three pairs of corresponding holding contours and dynamic braking can be enabled at the same time.

All braking devices 100 the 1-5 work equally in both directions of rotation.

Advantages of the braking devices according to the invention include a high braking force that is independent of the available electrical power with a low weight, compact dimensions, a small number of components and consequently low unit production costs. The invention can be set variably depending on the needs of the customer, are easy to assemble and integrate into existing systems and are very reliable. All the variants described can be used dry or in an environment filled with oil or grease.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was 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.

Patent literature cited

• WO 2005/015044 A1 [0005]

Claims (10)

Braking device for a control system of aircraft, the braking device comprising a housing and a multi-stage braking mechanism for deriving a torque of a shaft of the control system into the housing, wherein a first stage of the braking mechanism is an electromechanical brake with at least one rotor, preferably at least one Brake disk and acts with at least one stator fixed on the housing, on which the rotor is braked in the active state of the electromechanical brake, characterized in that a second stage of the brake mechanism has a mechanism that allows a relative rotation of the brake disk against the shaft and as a result Such a rotation causes a brake force boost of the first stage or an additional fixation of the shaft on a stator fixed to the housing within the second stage. Braking device according to Claim 1 , characterized in that the electromechanical brake of the first stage is a normally closed brake. Braking device according to one of the preceding claims, characterized in that the first and the second stage of the braking device share one or more common components. Braking device according to Claim 3 , characterized in that the first and the second stage of the braking device share the stator. Braking device according to one of the preceding claims, characterized in that the brake disc has two separate parts, an inner part extending radially inward from an annular dividing line and an outer part extending radially outward from the dividing line, the parts being non-rotatable are coupled together, but can be moved in the axial direction relative to each other, the outer part of the brake disc is braked in the active state of the electromechanical brake of the first stage on the stator, the mechanics of the second stage of the braking mechanism being formed as a result of a rotation of the brake disc against the shaft to cause an axial movement of the inner part of the brake disc relative to the outer part, and wherein a contour is provided on the inner part of the brake disc, which as a result of the axial movement of the inner part of the brake disc relative to the outer part, the brake booster the first stage or the additional fixation of the shaft within the second stage. Braking device according to one of the preceding claims, characterized in that the mechanics of the second stage of the braking mechanism is a ball ramp which has a plurality of balls enclosed between two driver disks, one of the driver disks being rotatably coupled to the shaft and the other the drive disks are rotatably coupled to the brake disk of the electromechanical brake of the first stage. Braking device according to one of the preceding claims, characterized in that the additional fixing of the shaft within the second stage takes place by means of a force fit. Braking device according to one of the preceding claims, characterized in that the additional fixing of the shaft takes place within the second stage by means of a form fit. Control system for an aircraft, characterized in that the control system comprises at least one braking device according to one of the preceding claims. Aircraft with at least one control system Claim 9 .

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