• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to an equipment support (1) comprising: - at least one accessory (3) comprising an output shaft (30), - an input wheel (12), said input wheel (12) being on the one hand rotated by the motor shaft (2) at a main speed and secondly connected to the output shaft (30) of the accessory to drive it in rotation at an output speed determined, - an input shaft (14), rotated by the input wheel (12) at a determined input speed, and - a magnetic gear reducer (20) interposed between the drive shaft input (14) and the output shaft (30), so that the input speed is different from the output speed.
    公开号:FR3027367A1
    申请号:FR1460046
    申请日:2014-10-17
    公开日:2016-04-22
    发明作者:Maxence Guillemont;Stephane Prunera-Usach;Julien Viel;Antoine Barbe
    申请人:Hispano Suiza SA;
    IPC主号:
    专利说明:

    [0001] FIELD OF THE INVENTION The present invention relates to the field of turbomachines. It aims in particular the mounting of auxiliary equipment and the mechanical transmission between a motor shaft of a turbojet engine or a turboprop engine and these equipment using an accessory drive box, or AGB (for Accessory Gearbox, or between the engine and the propeller of a turboprop with a propeller gearbox type PGB (for Propeller Gearbox, in English).
    [0002] BACKGROUND ART The accessory gearbox, well known to those skilled in the art under its English name "Accessory Gear Box" (AGB), supports various auxiliary equipment, or accessories, mounted on the motor and necessary for its operation. or that of the aircraft. These various accessories may include a generator, a starter, an alternator, hydraulic pumps for fuel or oil, and are mechanically driven by the motor shaft via shafts. The power required to drive the accessories is usually taken mechanically at the compressor of the turbomachine. Usually, the AGB includes parallel axis gears to mechanically drive the accessories. The spacing of the accessories is therefore determined by the spacings of the gears, and not by their respective dimensions. To increase this spacing, it is therefore necessary to add one or more intermediate gears, which has the disadvantage of increasing both the size of the AGB and its mass. Furthermore, the axes of all the gears of the AGB being parallel, the accessories necessarily have the same orientation with respect to the AGB and the engine.
    [0003] Moreover, in the case of a turbojet (or "turbofan" in English), the gas generator is connected to a fan which is housed in a fan casing. The nacelle then has a generally circular section. The space available for housing the AGB is therefore defined in an annular portion housed in the nacelle, around the turbomachine, and therefore has a generally curved shape (see Figure 1).
    [0004] To gain engine performance, one solution is to reduce the size of the nacelle at the fan to increase the size of the fan without increasing the outer diameter of the turbomachine. The space available in the nacelle under the blower is greatly reduced: it is therefore necessary either to reduce the size of the AGB in order to still be able to integrate it under the blower in the nacelle, or to move the AGB downstream of the blower in the central compartment of the turbomachine (that is to say in the "core" zone), in which the available space is even smaller. Conventional AGB turbojet engines are therefore not adapted from a structural point of view, dimensional and functional, new configurations of fan and core zone of the turbomachine. It has therefore been proposed in document FR 1355241 in the name of the Applicant an AGB comprising: - a primary angle transmission formed of a drive meshing member driven by the drive shaft of the turboprop and a drive member primary meshing, at least one mechanical drive assembly of the transmission shaft of the accessory, which is driven by the primary gearing means via a secondary angle gear comprising two meshing in engagement with non-parallel axes. Such an AGB gear with non-parallel axes has the advantage of being easily adjustable and also allow to ease the installation of the various accessories overcoming their size, without changing the speed of training.
    [0005] However, upgrading specifications on an AGB can lead to changes in accessories or rotational speeds on some existing lines, which means redefining the AGB kinematic chain and the consequent risk lifts. SUMMARY OF THE INVENTION An object of the invention is therefore to propose an equipment support, such as an accessory drive case or a PGB type drive case that can be used in a turbomachine which can be modulated and allows to ease the installation of the various accessories by overcoming their size without changing their drive speed, which also has a moderate weight and which allows to distribute the accessories on a larger periphery of the turbomachine. For this purpose, the invention proposes an equipment support for an engine comprising a motor shaft, said equipment support comprising: at least one accessory comprising an output shaft, an input wheel, said wheel, input being firstly rotated by the motor shaft of the motor at a main speed and secondly connected to the output shaft of the accessory to drive it in rotation zo at a determined output speed an input shaft, rotated by the input wheel at a determined input speed, and a magnetic gear reducer, interposed between the input shaft and the output shaft, so that that the input speed is different from the output speed. Some preferred but non-limiting features of the equipment carrier described above are the following: the input wheel comprises a spiro-conical gear, the equipment carrier further comprises a second accessory comprising an output shaft rotated by the input wheel at a speed equal to the input speed; - the equipment carrier further comprises an equipment support casing, the magnetic gear reducer comprising an internal rotor fixed to the input gear; input shaft, an outer rotor, fixed on the output shaft, and a stator, fixed relative to the housing of the equipment support and housed between the inner rotor and the outer rotor, the inner rotor, the outer rotor and the stator being coaxial with the input shaft and the output shaft, - the magnetic gear reducer further comprises a cooling system, - the equipment support further comprises a fixed gear housing relative to the equipment support housing, and wherein the gear housing includes an inner revolution housing and an outer revolution housing coaxial with the input shaft and the output shaft, said inner housing extending inside the outer casing, and the cooling system comprises a cooling space for receiving a cooling fluid, said cooling space being provided between the inner casing and the outer casing, - the accessory is housed in a casing fixed relative to the equipment support casing, one of the inner casing and the outer casing being secured to the equipment support casing via an internal flange while the other of the outer casing and the inner casing is attached to an accessory casing via an external flange, - the equipment support further comprises substantially annular dynamic seals in fitted between the inner rotor and the gearbox housing on the one hand and between the outer rotor and the gearbox housing on the other hand, - the equipment carrier further comprises a substantially annular-shaped static sealing gasket from and other of the cooling space between the inner casing and the outer casing configured to ensure a sealing of said cooling space, - the cooling space comprises at least one annular groove, substantially coaxial with the inner casing and the casing external, and a series of annular grooves, formed in the inner housing and extending radially from the annular groove, - the equipment carrier comprises an accessory drive housing for a turbojet or turboprop or a drive housing a turboprop. According to a second aspect, the invention also proposes a turbomachine engine, comprising an equipment support as described above. According to a third aspect, the invention also includes an aircraft comprising such an engine. BRIEF DESCRIPTION OF THE DRAWINGS Other characteristics, objects and advantages of the present invention will appear better on reading the detailed description which follows, and with reference to the appended drawings given by way of non-limiting examples and in which: FIG. 1 is a perspective view of an exemplary equipment carrier of the type of drive gearbox with parallel axes according to the prior art, on which the accessories have been omitted. FIG. 2 is a diagrammatic view of An example of an equipment carrier of the non-parallel axis accessory drive gear type is shown in FIG. 3 is a partial diagrammatic view of an exemplary architecture of a carrier of the invention. 4a is an axial sectional view of an exemplary embodiment of a gearbox with magnetic gears, FIG. 4b is a front view of the gear reducer, FIG. Fig. 5 is a partial sectional view of a magnetic gearbox housing on which the cooling space is visible.
    [0006] DETAILED DESCRIPTION OF AN EMBODIMENT The invention will be described particularly with reference to an aircraft comprising a turbojet engine and an accessory drive unit 1 adapted to mechanically drive auxiliary equipment, or accessories 3, necessary for the operation of the engine. or that of an aircraft. This is however not limiting, insofar as the invention is also applicable to any other type of equipment support, such as in particular a PGB type drive housing, that the accessory drive box 1 could be used in any other turbomachine to support and drive accessories 3, and the number of accessories 3 described in the following may be different according to the needs of the turbomachine.
    [0007] A turbojet typically comprises a nacelle which forms an opening for the admission of a given flow of air to the engine itself. Generally, the turbojet engine comprises one or more air compression sections admitted into the engine. The air thus compressed is admitted into a combustion chamber and mixed with fuel before being burned. The hot exhaust gases from this combustion are then expanded in different turbine stages. The turbine then provides the rotational power to the blower. The gearbox of the accessories 1, or AGB 1, can be fixed on a motor housing, for example at the level under the blower or in the central compartment, and mechanically drives a series of accessories 3 by taking the power of drive required on a motor shaft 2, usually the compressor shaft. For this purpose, the motor shaft 2 is housed in the motor housing and defines an axis of rotation. Furthermore, the accessories 3 each comprise an output shaft 30 for mechanically driving the corresponding accessory 3.
    [0008] The AGB 1 in turn is connected to the drive shaft 2 via a radial transmission shaft 4, which is itself driven by the drive shaft 2.
    [0009] The AGB 1 further comprises an input wheel 12 which is rotated by the driving shaft 2 at a main speed and which is connected to the output shaft 30 of the accessory 3 in order to drive it into position. rotation according to a determined output speed. The output speed is determined in particular by the type of accessory 3 to which the output shaft 30 is connected. Since the determination of the output speeds according to the accessories 3 is conventional, it will not be further described here. The AGB 1 further comprises an input shaft 14, rotated by the input wheel 12 at a determined input speed, and a magnetic gear reducer 20, interposed between the input shaft 14 and the output shaft 30, so that the input speed is different from the output speed. The magnetic gear reducer 20, or magnetic reducer 20, thus makes it possible to modify the driving speed of the output shaft 30 in a simple, inexpensive and reliable manner for an axial space requirement (along the output axis of the accessory 3) reduced and a limited weight. In the following, the invention will be more particularly described in the case of an AGB 1 of the gear type with non-parallel axes. This is however not limiting, the invention also being applied without substantial modification to an AGB 1 comprising gears with parallel axes (as illustrated in FIG. 1), insofar as it suffices to interpose the magnetic reducer 20 between the output shaft 30 of the accessory 3 and the input wheel 12 of the AGB 1.
    [0010] An AGB 1 with non-parallel axes comprises: - a primary shaft 10, driven via a primary gear 9 by the radial transmission shaft 4, - a series of mechanical drive assemblies output shafts 30 of the accessories 3, each comprising a bevel gear 16 thus distributing the accessories 3 over a larger angular sector of the periphery of the turbojet 8, taking into account its dimensions and its geometry. Each bevel gear 16 may comprise a driving ring 16a, driven by the primary shaft 10 of the AGB 1, and an output gear 16b, meshing with the pinion gear and adapted to drive the drive shaft. output 30 to which it is connected. The driving ring 16a and the output gear 16b may be of intersecting axes (of the 10-bevel type) or of non-intersecting axes (of the worm type). In particular, reference may be made to the document FR 1355241 cited above for more information. Information on this type of AGB 1. The primary shaft 10 and the mechanical drive assemblies of the accessories 3 are housed in a housing 18 of AGB. Here, the input wheel 12 is thus fixed on the primary shaft 10 of the AGB 1 and driven in rotation by the drive shaft 2 via the primary angle gear 11 and the radial shaft. 4. The speed of rotation of the input wheel 12 is therefore imposed by the speed of rotation 20 of the drive shaft 2, the reduction ratio between the drive shaft 2 and the radial transmission shaft 4 and the reduction ratio between the radial transmission shaft 4 and the primary shaft 10 of the AGB 1. The input wheel 12 rotates an associated input pinion 13, fixedly secured to the input shaft 14 to rotate it. In order to allow meshing of the input gear 13 and the input wheel 12, the input gear 13 is chosen so as to have teeth of the same type and the same module as the input wheel 12. For example, the input wheel 12 may be of the spiro-conical type. The input gear 13 is then also of the spiro-conical type and the same module. The reduction ratio between the input gear 13 and the input wheel 12 determines the rotational speed of the input shaft 14.
    [0011] Preferably, the input wheel 12 can drive a second gear 16b, same module and the same type as the input wheel 12. The second gear 16b is then fixed on the output shaft 30 of an accessory 3 to drive it in rotation. Conventionally, the rotational speed of the second gear 16b depends on the gear ratio between the second gear 16b and the input wheel 12: here, the speed is substantially equal to the rotation speed of the input shaft 14. The magnetic reducer 20 comprises: - an inner rotor 22, fixed on the input shaft 14, for example by means of a crenelated connection, and comprising a first number of magnetic poles, - an outer rotor 23 , fixed on the output shaft 30 and comprising a second number of magnetic poles, and - a stator 26, fixed relative to the housing 18 of the AGB 1, said stator 26 being housed between the inner rotor 22 and the outer rotor 23 and comprising a third number of magnetic poles. The inner rotor 22 and the outer rotor 23 are coaxial with the input shaft 14 and the output shaft 30, and thus define an axis X, visible in Figures 4a and 4b. In a manner known per se, the number of magnetic poles of the inner rotor 22 and of the outer rotor 23 determines the reduction ratio of the magnetic reducer 20. Furthermore, the type of magnetic poles (constituent material) and the geometry of the magnetic poles make it possible to adjusting the coupling between the inner rotor 22 and the outer rotor 23, and thus the coupling between the input shaft 14 and the output shaft 30. In an exemplary embodiment, the inner rotor 22 comprises fewer magnetic poles the outer rotor 23 to obtain a reduction ratio greater than 1. Furthermore, the magnetic poles of the inner rotor 22 and the stator 26 may comprise samarium-cobalt magnets 30 whereas the magnetic poles of the outer rotor 23 may include ferromagnetic bars.
    [0012] Note that the implementation of a magnetic reducer 20 allows, if necessary, to avoid the addition of fusible means in the case where the rotational speed too high for the accessory 3. Indeed, the choice different magnetic poles is used to define a maximum coupling speed from which the output shaft 30 picks up. Indeed, when the coupling becomes too great between the input shaft 14 and the output shaft 30, the electromagnetic interaction between the magnetic poles of the inner rotor 22 and the magnetic poles of the outer rotor 23 is no longer sufficient. to drive the output shaft 30 in rotation: it then occurs a decoupling, which acts as a fuse for mechanically isolating the input shaft 14 and the output shaft 30. The implementation of a magnetic reducer 20 further allows to ensure a transmission of the torque without contact, and therefore without wear of the various meshing members 22, 23.
    [0013] The magnetic reducer 20 is housed in a casing 26, configured to isolate the magnetic reducer 20 from its environment. In particular, the casing 26 makes it possible to prevent the introduction of oil from the engagement members of the AGB 1 (in order to lubricate the various members), which would be likely to damage the magnetic reducer 20 and to alter its performance by introducing a shear due to the presence of fluid between the rotors 22, 23. It will be noted that, in operation, the casing 18 of the AGB contains a relatively continuous oil mist resulting from the movement of different meshing organs that compose it. The accessories 3 can also be housed in housings 32 of accessories. The casing 28 of the magnetic reducer 20 and the casings 32 of accessories are fixed relative to the housing 18 of the AGB.
    [0014] The magnetic reducer 20 is likely to rise in temperature during the different phases of flight of the engine, it may include a cooling system. The cooling system must however be able to effectively cool the active parts of the magnetic reducer 20, namely the inner rotor 22, the outer rotor 23 and the stator 24, without drowning in the cooling fluid F.
    [0015] The housing 26 of the magnetic reducer 20 may for example comprise a housing of internal revolution 27 and a housing of external revolution 28 coaxial with the input shaft 14 and the output shaft 30, the inner housing 27 extending to the In this case, a clearance can be provided between the inner casing 27 and the outer casing 28, in order to define a confined cooling space 40 in which a cooling fluid F can circulate. cooling 40 can be formed by machining the facing faces of the inner casing 27 and the outer casing 28.
    [0016] In the exemplary embodiment illustrated in the figures, the inner casing 27 is fixed to the casing of the AGB 1 by means of an internal flange 27a, while the outer casing 28 is fixed to the casing of the accessory 3 via an external flange 28a. Alternatively, the inner housing 27 could be attached to the housing 30 of the accessory through the outer flange 28a, while the inner housing 27 is attached to the housing of the AGB 1 through the inner flange. 27a. The inner casing 27 and the outer casing 28 are therefore fixed relative to the casing of the AGB 1 and to the casing of the accessory 3.
    [0017] The cooling space 40 can in particular be in the form of an annular groove 42 machined in walls facing the inner casing 27 and the outer casing 28, the section of which can be defined as a function of the cooling fluid F chosen and the exchanges The magnetic reducer 20 may then comprise, on either side of the cooling space 40 (in the axial direction of the magnetic reducer 20), a static sealing gasket 41a. type O-ring to ensure the sealing of the cooling space 40 and prevent the passage of the cooling fluid F to the inner rotor 22, the outer rotor 23 or the stator 24. Also optionally, the magnetic reducer 20 can comprise, in addition to or in place of the static seals 41a, dynamic seals 41b of the labyrinth seal type, arranged in the gearbox housing 26 and the inner rotor 22 on the one hand and the outer rotor 23 on the other hand. In the example illustrated in the figures, a first labyrinth seal 41b is formed between a radial wall of the inner housing 27 and the inner rotor 22, at the inner flange 27a, and a second labyrinth seal 41b is formed between a radial wall of the outer casing 28 and the outer rotor 23, at the outer flange 28a. Alternatively, the dynamic seals 41b may include air seals (air injection in the middle of the labyrinths to seal the gap).
    [0018] For example, the cooling space 40 may have an annular shape coaxial with the output shaft 30 and the input shaft 14 with a substantially circular or parallelepipedal section, and include a series of annular grooves 44 formed in the inner housing 27 and extending radially from the annular groove 42. The grooves 44 thus make it possible to maximize the convective exchanges with the internal casing 27, for a reduced radial and axial space requirement. The cooling space 40 may in particular be supplied with cooling fluid F from a separate reservoir. The cooling space 40 may also be in fluid communication with the internal zone of the casing of the AGB 1: the cooling fluid F then comprises the oil intended to circulate in the casing 18 of the AGB 1 in the form of fog in order to lubricate the meshing members. For example, a line 46 may be formed between the source of lubricating oil and the housing 26 of the magnetic reducer 20, in order to bring the oil into the cooling space 40. The oil then circulates in space annular 40 cooling, where it cools by forced convection the magnetic reducer 20, then leaves the cooling space 40 at a higher temperature by an outlet 48 and between, with the aid of a dedicated pipe 48, in the AGB casing 1.
    [0019] Thus, in the example illustrated in FIG. 4b, the cooling fluid F enters the annular cooling space 40 via the pipe 46, passes through the casing of the AGB 1 and cools the magnetic reducer 20, and then returns to the opposite end thereof through the pipe 48. The cooling fluid F can then be sent into the housing 18 of the AGB.10
    权利要求:
    Claims (11)
    [0001]
    REVENDICATIONS1. An equipment carrier (1) for an engine comprising a motor shaft (2), said equipment carrier (1) comprising: - at least one accessory (3) comprising an output shaft (30), and - a wheel input (12), said input wheel (12) being rotatably driven by the motor shaft (2) of the motor at a main speed and secondly connected to the output shaft (30). ) of the accessory in order to drive it in rotation according to a determined output speed, the equipment support (1) being characterized in that it further comprises an input shaft (14), driven in rotation by the input wheel (12) at a determined input speed, and a magnetic gear reducer (20) interposed between the input shaft (14) and the output shaft (30), so that the input speed is different from the output speed.
    [0002]
    2. Equipment carrier (1) according to claim 1, wherein the input wheel (12) comprises a spiro-conical gear.
    [0003]
    3. Equipment carrier (1) according to one of claims 1 or 2, further comprising a second accessory (3) comprising an output shaft (30) driven in rotation by the input wheel (12) following a speed equal to the speed of entry.
    [0004]
    The equipment carrier (1) according to one of claims 1 to 3, further comprising an equipment support housing (18), the magnetic gear reducer (20) comprising: - an internal rotor (22) ), fixed on the input shaft (14), - an outer rotor (23), fixed on the output shaft (30), and - a stator (24) fixed with respect to the housing (28) of the equipment support 30 and housed between the inner rotor (22) and the outer rotor (23), the inner rotor (22), the outer rotor (23) and the stator (24) being coaxial with the input shaft (14) and the output shaft (30).
    [0005]
    The equipment carrier (1) according to one of claims 1 to 4, wherein the magnetic gear reducer (20) further comprises a cooling system (40).
    [0006]
    6. Equipment carrier (1) according to claim 5, further comprising a gear housing (26), fixed relative to the housing (18) of the equipment carrier, and wherein: - the gear housing (26 ) comprises an inner revolution housing (27) and an outer revolution housing (28) coaxial with the input shaft (14) and the output shaft (30), said inner housing (27) extending to the inside of the outer casing (28), and - the cooling system comprises a cooling space (40) for receiving a cooling fluid (F), said cooling space (40) being provided between the inner casing (27). ) and the outer casing (28).
    [0007]
    7. Equipment carrier (1) according to claim 6, wherein the accessory (3) is housed in an accessory housing (30) fixed relative to the housing (18) of the equipment support, one among the inner housing (27) and the outer housing (28) being fixed to the housing (18) of the equipment support via an inner flange (27a) while the other of the outer housing (28). and the inner housing (27) is attached to an accessory housing (30) via an outer flange (28a).
    [0008]
    8. Equipment carrier (1) according to one of claims 5 to 7, taken in combination with claim 4, further comprising substantially annular dynamic seals (41b) positioned between the inner rotor (22) and the gearbox housing (26) on the one hand and between the outer rotor (23) and the gearbox housing (26) on the other hand.
    [0009]
    9. Equipment carrier (1) according to one of claims 6 to 8, further comprising a static seal (41a) of substantially annular shape on either side of the cooling space (40) between the inner housing (27) and the outer housing (28) configured to ensure sealing of said cooling space (40).
    [0010]
    10. Equipment carrier (1) according to one of claims 6 to 9, wherein the cooling space (40) comprises at least one annular groove (42), substantially coaxial with the inner housing (27) and the outer housing (28), and a series of annular grooves (44) formed in the inner housing (27) and extending radially from the annular groove (42).
    [0011]
    11. Equipment carrier (1) according to one of claims 1 to 10, characterized in that it comprises an accessory drive housing 15 (AGB) for a turbojet engine or a turboprop or a drive housing ( BMP) of a turboprop.
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    同族专利:
    公开号 | 公开日
    EP3207235B1|2019-04-03|
    US20170306854A1|2017-10-26|
    CN107076030A|2017-08-18|
    EP3207235A1|2017-08-23|
    WO2016059346A1|2016-04-21|
    RU2017116922A3|2019-04-10|
    CA2964332A1|2016-04-21|
    JP6682524B2|2020-04-15|
    CN107076030B|2018-09-18|
    FR3027367B1|2018-02-09|
    RU2017116922A|2018-11-20|
    RU2700837C2|2019-09-23|
    US10352250B2|2019-07-16|
    JP2017538897A|2017-12-28|
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    法律状态:
    2015-10-19| PLFP| Fee payment|Year of fee payment: 2 |
    2016-04-22| PLSC| Publication of the preliminary search report|Effective date: 20160422 |
    2016-10-06| PLFP| Fee payment|Year of fee payment: 3 |
    2017-08-25| CD| Change of name or company name|Owner name: HISPANO - SUIZA, FR Effective date: 20170725 |
    2017-09-21| PLFP| Fee payment|Year of fee payment: 4 |
    2018-09-19| PLFP| Fee payment|Year of fee payment: 5 |
    2019-09-19| PLFP| Fee payment|Year of fee payment: 6 |
    2020-09-17| PLFP| Fee payment|Year of fee payment: 7 |
    2021-09-22| PLFP| Fee payment|Year of fee payment: 8 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1460046|2014-10-17|
    FR1460046A|FR3027367B1|2014-10-17|2014-10-17|EQUIPMENT SUPPORT FOR A TURBOMACHINE COMPRISING A MAGNETIC REDUCER|FR1460046A| FR3027367B1|2014-10-17|2014-10-17|EQUIPMENT SUPPORT FOR A TURBOMACHINE COMPRISING A MAGNETIC REDUCER|
    US15/518,281| US10352250B2|2014-10-17|2015-10-15|Equipment support of a turbo machine comprising a reducer with magnetic gears|
    JP2017520375A| JP6682524B2|2014-10-17|2015-10-15|Equipment support for turbomachines with magnetic geared reducer|
    RU2017116922A| RU2700837C2|2014-10-17|2015-10-15|Box for installation of auxiliary equipment on gas turbine engine containing magnetic reduction gear|
    CN201580055997.3A| CN107076030B|2014-10-17|2015-10-15|It include the equipment support of the turbine of the retarder with magnetic gear|
    EP15793871.3A| EP3207235B1|2014-10-17|2015-10-15|Means for supporting auxiliary equipment in turbomachines comprising a magnetic gearbox|
    PCT/FR2015/052772| WO2016059346A1|2014-10-17|2015-10-15|Equipment support of a turbo machine comprising a magnetic reducer|
    CA2964332A| CA2964332A1|2014-10-17|2015-10-15|Equipment support of a turbo machine comprising a magnetic reducer|
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