RU2583535C1 - Multimotor drive for wheel landing gear and operation method thereof - Google Patents

Abstract

FIELD: aviation.

SUBSTANCE: multimotor electromechanical drive (MEMP) of gear wheel consists of several motors with gearboxes, brake disc package, and multiple servo linear actuators, control units servo actuators, main control unit MEMP connected interface bus with motor control units and sensors. Each motor of brushless servo actuator, DC, with permanent magnet excitation. Reducer of each servo electric wave with rotation bodies. Installed on output shaft gear engagement means are cylindrical cams having symmetry line, with fixed on them rolling bearings cooperating with teeth of spur gear formed cycloidal surface, forming eccentrically cycloidal engagement. Output shaft of each servo actuator has angular position sensor connected to an interface bus with corresponding servo electric control unit and main control unit.

EFFECT: higher functional capabilities and reliability due to MEMP backup.

9 cl, 15 dwg

Description

The invention relates to aircraft manufacturing, and in particular to electric wheels of the chassis of aircraft, allowing their independent movement on the territory of the aerodrome.

A known electric drive for a pair of wheels of an airplane’s landing gear (application WO No. 2011/134503 dated 04/28/2010, RU No. 2529558 dated April 28, 2010) includes two electric motors arranged in tandem in series, the output shaft of which, perpendicular to the axis of the wheels, is connected by gears of the wheels through two-stage gearbox, one of the stages of which includes a bevel gear. This arrangement of electric motors increases the height of the aircraft chassis.

The known design of the electric drive wheels of the chassis of the aircraft (US patent No. 4659039 from 07.29.1985, PM RU No. 116719 U1 from 08.02.2012, US No. 2015/0034761 from 07.28.2014). The electric drive contains a controlled electric motor, the rotor of which is connected to the chassis wheel through a linear mechanical transmission and an overrunning clutch. The disadvantage is the inability to reverse the wheel and the unreliability of the freewheel due to its possible jamming.

The invention is known of devices for braking and driving the wheel of an airplane landing gear (US patents No. 8633665 dated 01/08/2011, US No. 8579229 dated 12/06/2011, application US No. 2013/0327884 dated 01/19/2012), including an electromechanical disk brake drive; an electromechanical wheel drive, consisting of at least one electric motor and a multi-stage gearbox, the output shaft of which is connected by a clutch to the ring gear of the wheel.

The disadvantage of these devices is that they have reduced reliability due to the presence of controlled connecting devices located between the electric drive with a gear reducer and the gear transmission of rotational motion to the wheel rim.

Known electric wheel gear of the landing gear of the aircraft (US patent No. 8136761 from 08/06/2009), in which the gear reducer connecting the electric motor to the wheel is wave.

The disadvantage of this device is that gear wave reducers do not have high reliability when transmitting large torque.

The invention is known for the electromechanical drive of a disk brake of an aircraft landing gear wheel (patent RU No. 2522643 dated July 25, 2012) having several electromechanical linear motors placed uniformly on the supporting disk on the circumference.

Eccentric-cycloidal internal or external engagement of composite gear profiles is known (patent RU No. 2385435 dated December 22, 2008), consisting of several disks displaced in phase with respect to each other, each with a cycloidal ring interacting with an eccentric shaft with the number of eccentrics equal to the number of wheels. Each eccentric is cylindrical and has a bearing mounted on an eccentrically displaced portion of the common shaft. The shaft can be driven in rotation from any engine, including an electric motor.

The disadvantage of a mechanical electric motor with a gearbox having the described gearing is the complexity of the gearing design and reduced reliability due to the presence of a single shaft electric drive with several eccentrics.

The invention of the electric drive of rotation of the wheel and the wheel brake of an airplane is known (US Pat. Nos. 8,579,229 dated December 6, 2011, US No. 8633605 dated January 8, 2011, US No. 8444086 dated December 22, 2010), consisting of electric motors with gearboxes mounted on a support disk on the wheel axis so that the axes of the electric drives are parallel to the axis of the wheel, the output shafts of the gearboxes have gearing means with a gear rim mounted on the wheel rim, as well as brake disc packages with an electromechanical drive mounted on the support disk located in the wheel rim.

The disadvantage of this electric drive is its reduced reliability due to the presence of a gear clutch controlled by an electromagnet connecting the gear rim of the wheel drive to the wheel rim.

Known electric wheel gear of an aircraft landing gear, consisting of an electric motor mounted on a landing gear with a gear on the output shaft and a chain transmission (US patent No. 8684300 B2 dated 08/04/2010), installed with the possibility of its input for interaction with the ring gear for spinning the wheel before landing and its rotation while driving on the taxiway. The chain drive is removed from the interaction with the ring gear before accelerating the aircraft for takeoff. Such a transmission of movement from the electric motor to the wheel may include a timing belt (patent EP No. 2749494 from 12.31.2012) or gears (patent EP No. 2527249 from 05.27.2011). To enter any of the gears into gearing or to disengage from the gears of the wheel, the design has an additional electric linear or hydraulic drive, which complicates the design of the wheel drive and reduces its reliability. With such drives, the use of small-sized servo-driven electric drives with an electric motor rotor speed of up to 100,000 min ^{-1 is} excluded.

The device and system of a multi-motor servo gearless direct drive (application US No. 2014/0097859 from 12/12/2013), including:

- a lot of electric motors, each with a shaft angle sensor and a determinant of its rotation speed;

- braking devices on each of the shafts;

- a lot of electric motor control units, each of which provides an electric current supply to each electric motor;

- microprocessor controls, forming the main unit (controller), connected to many electric motor control units and with position sensors of the motor shafts, issuing commands to the motor control units in accordance with the specified parameters and the position of the shafts.

In this system, the connection of control units with electric motors that does not match the specified main control unit is excluded.

In the description of the present invention there is no data on the operating modes of many electric motors on a common shaft.

A multi-motor electric drive is known, including several electric drives with the same power (patent RU No. 2323288 from 10.24.2006). Each electric drive includes an electric motor, a transmission mechanism (torque multiplier), a rotational speed and rotation angle sensor of an electric motor rotor mounted on an electric motor or in a transmission mechanism, a current angular speed adjuster, and an electric motor rotor speed regulator connected to microprocessor control devices in the form of a vector control unit moment of the electric motor and power converter connected to the motor windings and connected to the vector th torque control of the electric motor. In this multi-motor electromechanical drive, the design of the main gear mechanism from the output shafts of the electric drives to the main shaft connected to the load object is not disclosed; there are no means for disconnecting the plurality of electric drives from the main shaft for its free rotation.

It is known microprocessor control of electric drives with valve motors equipped with rotor position sensors connected to a drive control controller [http: //filearchive/reports-magazine/2012-26-1/199.pdf].

Each electric motor has a transistor module connected to an electric drive control controller, a current sensor and a transistor switch. The drive control controller provides the reception and transmission of commands from the central microprocessor, controls the direction of rotation of the electric motors and adjusts their rotation speed.

In the description of this microprocessor control there is no description of the operating modes of many electric motors on a common shaft.

There is a known description of a control system for a valve induction electric motor (VID) [http://elmech.mpei.ac.ru/books/edu/SRM_design/index.html], including a microprocessor (MP). The signals from the VID rotor position sensor are transmitted to the MP through the conversion and matching device, which brings the signals to the type and level necessary for the normal operation of the MP. MP generates an optimal algorithm for switching VID windings according to the program embedded in the MP.

A known method of operation of a multi-motor electric drive (US patent No. 7038421 dated 06/17/2003), having at least two actuating electric drives, means for determining the angular position and angular velocity of the rotor, voltage and current sensors supplied to the inverters, microprocessor means for controlling the multi-motor electric drive.

The method of operation of this multi-motor drive includes receiving microprocessor-based control means of signals from sensors about the parameters of each of the electric drives, comparing the received signals with the given ones and determining the difference of their values, sending commands to control the inverters to change the parameters of each of the electric drives based on the difference of the values received from the sensors and given parameters.

A known method of operation of a multi-motor electromechanical drive with valve motors with rotor position sensors (http://wvvw.kaskod.ru/product/motorsrm/srm_article01/) with a microprocessor control unit, an electronic switch and an electromechanical converter, including:

- MEMP start-up according to the signals supplied by the GBU to the control units of the tracking electric drives in accordance with the algorithms laid down in the control programs;

- acceleration and braking of the driven object with the necessary acceleration according to the program specified by the GBU and the generated signals, which are converted in the control units of the tracking electric drives;

- tracking the angular position of the main output shaft and the driven object according to the signals received from the GBU and converted in the control units of the tracking electric drives;

- stopping all electric motors and the driven object in the specified GBU angular position of the shafts according to the signals received from the GBU and converted in the control units of the tracking electric drives;

- a change in the direction of rotation of the main shaft with the driven object according to the signals received from the GBU and converted in the control units of the tracking electric drives.

In this method of operation of a multi-motor electromechanical drive, the possibility of free rotation of the main shaft with the driven object is not provided.

An analysis of the technical level of multi-motor electromechanical drives (MEMPs) showed that in the design of the transmission mechanism "output shafts of servo-driven electric drives - chassis wheel", in which the moments from the electric drives are summed up and the total moment is applied to the chassis wheel, the mode of free rotation of the wheel is impossible without introduction to the design electric drives of additional devices - controlled or freewheel couplings, disconnecting, if necessary, the shafts of electric drives from the ring gear sa or a drive disconnecting a drive wheel mechanism (gear, chain, with a timing belt, etc.) from the ring gear of a wheel or a drive disconnecting a drive mechanism (gear, chain, with a timing belt, etc.) from a drive link, which leads to reduce the functionality and increase the overall dimensions of the multi-motor electromechanical drive, eliminates redundancy of electric drives and reduces their reliability.

The technical task of the invention is to increase the functionality and reliability by redundant multi-engine electromechanical drive wheels of the landing gear of the aircraft.

The technical problem is solved in the design of the MEMP wheels of the landing gear of the aircraft, consisting of:

- several electric motors of the same power with gears mounted on a support disk mounted on the wheel axis so that the axes of the servo-electric drives are parallel to the wheel axis, the output shafts of the gearboxes have gearing means with a gear ring mounted on the wheel rim; means for determining the angular position of each rotor of the electric motor;

- a package of brake discs located in the rim of the chassis wheel, and installed on the supporting disc of several servo linear actuators;

- position sensors of pressure plungers of linear servo electric disc brake drives;

- wheel angle sensor;

- control units for tracking electric drives;

- the main control unit of a multi-engine electromechanical drive connected by an interface bus to the motor control units and sensors, while

- each electric motor of the tracking electric drive is brushless, direct current, with excitation from permanent magnets;

- the number of follow-up electric drives is not less than three;

- the gearbox of each servo drive is wave with bodies of revolution;

- the gears mounted on the output shafts of the gearboxes are cylindrical eccentrics with a line of symmetry, with rolling bearings mounted on them, interacting with the teeth of the spur gear, formed by a cycloidal surface, forming an eccentric-cycloidal gearing, while the axes of the output shafts are placed on a circle, radius which is determined by the dependence:

R _e = R _max -e ± r _p ,

where R _e is the radius of the circle on which the axis of the shafts of the servo-electric drives are located, described relative to the axis of the main output shaft;

R _max is the radius of the circle on which the tops of the teeth or the hollows of the wheel of the external or internal eccentric-cycloidal engagement are located;

e is the eccentricity of the cylindrical eccentric;

r _p - the outer radius of the rolling bearing mounted on a cylindrical eccentric;

+ r _p - for external eccentric-cycloidal engagement;

-r _p - for internal eccentric-cycloidal engagement;

the output shaft of each servo-electric drive has an angular position sensor connected by an interface bus to the control unit of the corresponding servo-electric drive and to the main control unit.

Since when taxiing along the runway the speed of the aircraft is in the range of 40-20 km / h, and the wheel speed at this speed of the aircraft is 300-150 min ^-1 , then when the rotational speed of the rotor of the electric motor is in the range of 7000 ... 100000 min ^-1 , to reduce the frequency of rotation of the output shaft of the electric drive, the wave reducer with rotation bodies has from one to three stages.

To increase the power of the electric drive with a reduced size, it has four servo-wheel electric drives mounted on a fixed support disk in pairs on axial lines located at an angle of ± 45 ° to the vertical on opposite sides of the disk axis, and four servo-linear disk brake electric drives, two of which located on the vertical axis, and two on the horizontal axis on opposite sides of the axis of the disk.

Depending on the dimensions and weight of the aircraft, the MEMP can be mounted on one or two wheels of the main or nose landing gear of the aircraft or on each of the wheels of the landing gear of the aircraft.

For light aircraft, MEMP can be mounted on at least one wheel of the left and right main landing gear supports.

For heavy aircraft, MEMP is installed on each wheel of the main and nose landing gears of the aircraft.

The advantages of MEMP are manifested in the method of operation of the MEMP of the aircraft landing gear wheel described below, including:

- the input of servo-driven electric drives into gearing with a gear wheel according to the signals received from GBU and converted in the control units of servo-driven electric drives;

- start-up of follow-up electric drives for spinning the wheel before landing according to the signals received in GBU from the aircraft control system (SUS) and from GBU - into control units of the follow-up electric drives in accordance with the algorithms laid down in the control program;

- withdrawal of servo-driven electric drives from gearing with the wheel, carried out according to the signals received from the GBU and converted in the control units of servo-driven electric drives;

- rotation of the wheel after touching the runway and to reduce the speed of the aircraft to 40-20 km / h;

- start-up of follow-up electric drives after landing of the aircraft according to the signals received in the control unit from the aircraft control system and from the control unit — into control units of the follow-up electric drives in accordance with the algorithms laid down in the control program;

- acceleration, steady movement and braking of the wheels during taxiing according to the program specified by the control unit and the generated signals converted in the control units of servo drives, while tracking the angular position of the wheel and output shafts of the servo drives according to the signals received from the drive and converted in the control units of servo drives;

- disengaging the gears from the ring gear and stopping all servo-controlled electric drives according to the signals received from GBU and converted in the control units of servo-controlled electric drives;

- braking the aircraft wheel to a complete stop;

- changing the direction of rotation of the aircraft wheel according to the signals received from the GBU and converted in the control units of the tracking electric drives, while

- the withdrawal of servo drives from gearing with the wheel until the centers of all the eccentrics occupy the position on the radial lines connecting the axle of the gear wheel with the axis of each shaft of the servo drives, and the stop of all servo drives for towing the aircraft is carried out according to signals from the control unit in accordance with the control program specified by the algorithm embedded in the GBU program;

- start-up of follow-up electric drives after landing and reaching a speed of 40-20 km / h is carried out by a signal supplied to the GBU to determine the angular position of the output shafts of the electric drives and the subsequent formation and supply of control signals from the control units for installing each of the output shafts by turning into a predetermined mutual the angular position of the lines of symmetry of the cylindrical eccentrics during engagement with the teeth formed by the cycloidal surface of the gear;

- acceleration, steady motion and braking of the aircraft wheel are carried out while maintaining a predetermined mutual angular position of the lines of symmetry of the eccentrics of all servo-driven electric drives in accordance with the algorithm laid down in the GBU program;

- the aircraft wheel is braked to a complete stop by turning on all linear electric drives of the disk brake according to the signals received from the control gear and converted into control units of the linear electric drives after the follow-up control gears are disengaged from the gear by the signal from the control gear in accordance with the control program defined by the algorithm laid down in the GBU program by subsequently turning the output shafts to occupy the centers of all the eccentrics of the position on the radial lines connecting the gear axis to oles with the axis of each output shaft and stops all servo drives;

- entering into engagement with the wheel of all tracking electric drives and their stop at a given mutual angular position of the lines of symmetry of the cylindrical eccentrics is carried out by a signal from the GBU in accordance with the control program specified by the algorithm laid down in the GBU program.

To reduce tire wear before landing, the wheels (wheels) are unwound by launching follow-up electric drives according to a signal supplied to the GBU to determine the angular position of the output shafts of the electric drives, by generating and supplying control sequences from the control units to turn each of the output shafts to a predetermined mutual angular position symmetry lines of cylindrical eccentrics and their engagement with the teeth formed by the cycloidal surface of the gear.

The achievement of the technical effect - improving the reliability of the MEMP wheels of the aircraft landing gear - is provided by the following combination of distinctive features:

for MEMP:

- each electric motor of the tracking electric drive is brushless, direct current, with excitation from permanent magnets;

- the number of follow-up electric drives is not less than three;

- the gearbox of each servo drive is wave with bodies of revolution;

- the gears mounted on the output shafts of the gearboxes are cylindrical eccentrics with a line of symmetry, with rolling bearings mounted on them, interacting with the teeth of the spur gear, formed by a cycloidal surface, forming an eccentric-cycloidal gearing, while the axes of the output shafts are placed on a circle, radius which is determined by the dependence:

R _e = R _max -e ± r _p ;

- the output shaft of each servo drive has an angular position sensor connected by an interface bus to the control unit of the corresponding servo drive and to the main control unit.

Since when taxiing along the runway the speed of the aircraft is in the range of 40-20 km / h, and the wheel speed at this speed of the aircraft is 300-150 min ^-1 , then when the rotational speed of the rotor of the electric motor is in the range of 7000 ... 100000 min ^-1 , to reduce the frequency of rotation of the output shaft of the electric drive, the wave reducer with rotation bodies has from one to three stages.

To increase the power of the electric drive with a reduced size, it has four servo-wheel electric drives mounted on a fixed support disk in pairs on axial lines located at an angle of ± 45 ° to the vertical on opposite sides of the disk axis, and four servo-linear disk brake electric drives, two of which located on the vertical axis, and two on the horizontal axis on opposite sides of the axis of the disk.

Depending on the dimensions and weight of the aircraft, the MEMP can be mounted on one or two wheels of the main or nose landing gear of the aircraft or on each of the wheels of the landing gear of the aircraft.

For light aircraft, MEMP can be mounted on at least one wheel of the left and right main landing gear supports.

For heavy aircraft, MEMP is installed on each wheel of the main and nose landing gears of the aircraft.

For the mode of operation of the MEMP:

- the withdrawal of servo drives from gearing with the wheel until the centers of all the eccentrics occupy the position on the radial lines connecting the axle of the gear wheel with the axis of each shaft of the servo drives, and the stop of all servo drives for towing the aircraft is carried out according to signals from the control unit in accordance with the control program specified by the algorithm embedded in the GBU program;

- start-up of follow-up electric drives after landing and reaching a speed of 40-20 km / h is carried out by a signal supplied to the GBU to determine the angular position of the output shafts of the electric drives and the subsequent formation and supply of control signals from the control units for installing each of the output shafts by turning into a predetermined mutual the angular position of the lines of symmetry of the cylindrical eccentrics during engagement with the teeth formed by the cycloidal surface of the gear;

- acceleration, steady motion and braking of the aircraft wheel are carried out while maintaining a predetermined mutual angular position of the lines of symmetry of the eccentrics of all servo-driven electric drives in accordance with the algorithm laid down in the GBU program;

- the aircraft wheel is braked to a complete stop by turning on all linear electric drives of the disk brake according to the signals received from the control gear and converted into control units of the linear electric drives after the follow-up control gears are disengaged from the gear by the signal from the control gear in accordance with the control program defined by the algorithm laid down in the GBU program by subsequently turning the output shafts to occupy the centers of all the eccentrics of the position on the radial lines connecting the gear axis to oles with the axis of each output shaft and stops all servo drives;

- entering into engagement with the wheel of all tracking electric drives and their stop at a given mutual angular position of the lines of symmetry of the cylindrical eccentrics is carried out by a signal from the GBU in accordance with the control program specified by the algorithm laid down in the GBU program.

To reduce tire wear before landing, the wheels (wheels) are unwound by launching follow-up electric drives according to a signal supplied to the GBU to determine the angular position of the output shafts of the electric drives, by generating and supplying control sequences from the control units to turn each of the output shafts to a predetermined mutual angular position symmetry lines of cylindrical eccentrics and their engagement with the teeth formed by the cycloidal surface of the gear.

This set of distinctive features was not found during the patent information search, therefore, the invention meets the criterion of "novelty."

This set of distinctive features does not follow explicitly from the prior art, therefore, the invention meets the criterion of "inventive step".

In FIG. 1 shows the MEMP of an airplane landing gear wheel.

In FIG. 2 - fragment I in FIG. 1 for internal eccentric cycloidal engagement.

In FIG. 3 is a section AA in FIG. 1 with three electromechanical wheel drives and three electromechanical brake disc drives.

In FIG. 4 is a section AA in FIG. 1 with four electromechanical drives of a wheel and four electromechanical drives of brake disks.

In FIG. 5 is a cross-section BB in FIG. 1 with three electromechanical drives in the state of engagement of eccentrics with gears.

In FIG. 6 is a section BB in FIG. 1 with three electromechanical drives in the state of eccentrics disengaged from the gear.

In FIG. 7 is a section BB in FIG. 1 with four electromechanical drives in the state of engagement of eccentrics with gears.

In FIG. 8 is a section BB in FIG. 1 with four electromechanical drives in the state of eccentrics disengaged from the gear.

In FIG. 9 is a fragment I in FIG. 1 for external eccentric cycloidal engagement.

In FIG. 10 is a section BB in FIG. 1 for external eccentric-cycloidal gearing with four electromechanical drives in the state of gearing of eccentrics with gears.

In FIG. 11 is a cross-section BB in FIG. 1 for external eccentric-cycloidal engagement with four electromechanical drives in the state of eccentrics disengaged from the gear.

In FIG. 12 is an example of the design of an electromechanical drive wheel with a wave gear with bodies of revolution.

In FIG. 13 is an example of a design of an electromechanical drive with a two-stage gearbox with rotation bodies for brake discs of a wheel.

In FIG. 14 is an example of the design of an electromechanical drive of two wheels located on one chassis support.

In FIG. 15 is a block diagram of a MEMP control system including electric motor control units and a main control unit.

A multi-engine electromechanical drive of the wheel 1 of the aircraft chassis (Fig. 1-15), having the axis 2 of the wheel 1 (Fig. 1, 2, 12, 14), a gear ring 3, mounted on the rim 4 of the wheel; a sensor 5 (Fig. 15) of the angular position of the wheel 1; mounted on the axis 2 of the wheel 1, the support disk 6 and the disc brake 7 mounted on it, the brake discs 8 of which are located in the rim 4 of the wheel 1 with the possibility of movement in the axial direction; several linear servo-driven electric drives 9 (Fig. 13) mounted on the support disk 6 with pressure plungers 10 interacting with the brake discs 8 and with sensors 11 (Fig. 15) of the position of the pressure plungers 10; includes

- at least three follow-up electric drives 12 (Fig. 3, 5, 6), mounted on the support disk 6 parallel to the axis 2 of the wheel 1, each of which consists of the same brushless, direct current power, with excitation from permanent magnets of the electric motors 13 (Fig .12) having sensors 14 of the angular position of the rotor; blocks 15 (Fig. 15) control servo-electric drives 12; wave reducers 16 connected to the shafts of the electric motors 13 with rotation bodies 17, the balanced output shaft 18 of each of which has a cylindrical eccentric 19 (Figs. 5, 6, 10-12) with a rolling bearing 20 having a line of symmetry 21 and interacting with the formed cycloidal surface 22 teeth 23 of the ring gear 3, forming, when interacting with the eccentrics 19, an eccentric-cycloidal gear 24 (Fig. 2), while the axes of the output shafts 18 are located on a circle 25, the radius of which is determined by the dependence:

R _e = R _max -e ± r _p ,

where R _e is the radius of the circle 25, on which are located the axis 26 of the output shafts 18 of the follow-up electric drives 12, described relative to the axis 2 of the wheel 1;

R _max is the radius of the circle 27 on which the vertices 28 of the teeth 23 of the external eccentric-cycloidal gear (Fig. 10) or the cavity 29 of the internal eccentric-cycloidal gear (Fig. 5) are located;

e - the eccentricity of the cylindrical eccentric 19;

r _p - the outer radius of the rolling bearing 20 mounted on a cylindrical eccentric 19;

+ r _p - for external eccentric-cycloidal engagement (Fig. 10, 11);

- r _p - for internal eccentric-cycloidal engagement (Fig. 5, 6, 7, 8);

- placed on the chassis or in the immediate vicinity of it, the main control unit 30 (Fig. 15) of the MEMP control, connected by an interface bus 31 to the electric motor control units 15 of the servo-electric drives 12 and the linear electric drives 9 of the disk brake 7, with a sensor 32 (Fig. 13) the angular position of the output shaft 18 of each servo drive 12 and the interface bus 33 (Fig. 15) with the sensor 5 of the angular position of the wheel 1. The main control unit 30 can be included in an external control system or receive commands from an external control system I am.

Provided that the cylindrical eccentric 19 performs the function of a single-tooth gear (Figs. 5, 6, 10, 11), the gear ratio of the eccentric-cycloidal gear 24 is equal to the number of teeth 23 of the gear ring 3, therefore, the more teeth 23 have a gear ring 3 of the wheel 1, the higher the gear ratio of the eccentric-cycloidal transmission 24.

When the rotational speed of the rotor of the electric motor 13 is in the range of 7000 ... 100000 min ^-1 , the wave gear 16 with the bodies of revolution 17 has from one to three steps (Fig. 12), which allows for a gear ratio of an eccentric-cycloidal gear 24 equal to the number of teeth 23 on the ring gear 3, get a wheel speed of 150-300 min ^-1 , sufficient for movement when taxiing the aircraft at a speed of 20-40 km / h.

To set a given power, the MEMP with a reduced size of the tracking electric drives 12 with a high rotational speed of the rotors of the electric motors 13 has

- four servo-electric drive 12 of the wheel 1 (Fig. 4, 10, 11), mounted on the supporting disk 6 in pairs on an axial line located at an angle of ± 45 ° to the vertical on opposite sides of the supporting disk 6, and

- four linear servo electric drive 9 (Fig. 4) of the disk brake 7, two of which are located on the vertical axis, and two on the horizontal axis on opposite sides of the axis of the supporting disk 6.

Depending on the dimensions and mass of the aircraft, the MEMP can be installed on one or two wheels 1 (Fig. 14) of the main or nose landing gear of the aircraft or on each of the wheels of the landing gear of the aircraft. On light aircraft, MEMP can be mounted on at least one wheel 1 of each main landing gear of the aircraft, and possibly on wheel 1 of the front landing gear of the aircraft. On heavy aircraft, MEMP is installed on each wheel of 1 aircraft chassis.

The advantages of the MEMP wheel 1 of the aircraft landing gear are manifested in the following method of operation, including:

- the input of the eccentrics 19 of the servo-driven electric drives 12 into engagement with the ring gear 3 of the wheel 1, carried out to spin the wheels 1 before landing, before taxiing after boarding or before take-off, by a signal received in GBU 30 to determine the angular position of the output shafts of 18 servo-electric drives 12 and the subsequent formation and supply of control signals from blocks 15 for installing each of the output shafts 18 by turning to a predetermined mutual angular position of the symmetry lines 21 of the cylindrical eccentrics 19 (Figs. 5, 7, 10) in the process gearing with the teeth 23 formed by the cycloidal surface 22 of the ring gear 3;

- the withdrawal of cylindrical eccentrics 19 servo-driven electric drives 12 from meshing with the ring gear 3 of the wheel 1 until the centers of all the eccentrics 19 occupy the position on the radial lines connecting the axis of the ring gear 3 with the axis 26 of each output shaft 18 (Fig. 6, 8, 11) of the servo-electric 12, and the stopping of all servo-driven electric drives 12 for towing the aircraft is carried out according to the signals from GBU 30, converted in blocks 15 in accordance with the control program specified by the algorithm laid down in the GBU 30 program, carried out before take-off and dkoy aircraft on the runway;

- free rotation of the wheel 1 after touching the runway and until the aircraft speed drops to 40-20 km / h (to taxiing speed), the subsequent start of the tracking electric drives 12 after reaching the taxiing speed and putting the eccentrics 19 of the tracking electric drives 12 into engagement with the ring gear 3 wheels 1 (Fig. 5, 7, 10) according to the signals received in GBU 30 (Fig. 15) from the sensor 5 of the angular position of the wheel 1, the sensors 14 of the angular position of the output shafts 18 and from the aircraft control system, and from the GBU 30 - into the control units 15 of the tracking electric drives 12 in accordance with algorithms embedded in the control program;

- acceleration, steady movement and braking of the wheels 1 when taxiing while maintaining a given mutual angular position of the lines of symmetry 21 of the eccentrics 19 (Fig. 5, 7, 10) of all servo electric drives 12 in accordance with the algorithm laid down in the program GBU 30 and the generated signals converted in blocks 15 of the control servo-electric drives 12;

- the output of the eccentrics 19 from engagement with the ring gear 3 (Fig. 6, 8, 11) of the wheel 1 and the stop of all servo-controlled electric drives 12; according to the signals received from the GBU 30 and converted in the control units 15 of the tracking electric drives 12; subsequent braking of the aircraft wheel 1 with a disk brake 7 to reduce the speed of movement or to a complete stop by the signals coming from the aircraft control system through GBU 30 and linear electric drive control units 15a 9;

- changing the direction of rotation of the wheel 1 when taxiing according to signals from GBU 30 and converted in the control units 15 of the tracking electric drives 12,

- braking of the wheel 1 of the aircraft to a complete stop, carried out by turning on all linear electric drives 9 of the disk brake 7 according to the signals received from GBU 30 and converted in the control units 15a of the linear electric drives 9 after the eccentrics 19 of the tracking electric drives 12 are disengaged from the ring gear 3 by subsequent rotation output shafts 18 for the centers of all eccentrics 19 (Fig. 6, 8, 11) to occupy positions on radial lines connecting the axis of the gear ring 3 with the axis of each output shaft 18 and stopping all servo electrics roprivodov 12 by a signal from SBD 30 in accordance with a control program given by the algorithm embedded within the SBD 30.

Claims (9)

1. The multi-motor electromechanical drive of the airplane landing gear wheel, consisting of several electric motors with the same power with gears, mounted on a support disk mounted on the wheel axis so that the axes of the servo-electric drives are parallel to the wheel axis, the output shafts of the gearboxes have gearing means with a gear mounted on the wheel rim crown, means for determining the angular position of each rotor of the electric motor, a package of brake discs located in the rim of the chassis wheel, and installed on the supporting disk how many follow-up linear electric drives, position sensors of pressure plungers of linear follow-up electric drives of a brake brake, wheel angle sensor, control units of follow-up electric drives, the main control unit of a multi-motor electromechanical drive, connected by an interface bus to control units of electric motors and sensors, characterized in that each follow-up electric drive electric motor is brushless, direct current, with excitation from permanent magnets, to the number of servo-driven electric drives is at least three, the gearbox of each servo-driven electric drive is wave with rotation bodies, the gears mounted on the output shafts of the gearboxes are cylindrical eccentrics with a line of symmetry, with rolling bearings mounted on them, interacting with the teeth of the cylindrical gear formed by a cycloidal surface, forming an eccentric-cycloidal engagement, while the axes of the output shafts are placed on a circle whose radius is determined divided by:
R _e = R _max -e ± r _p ,
where R _e is the radius of the circle on which the axis of the shafts of the servo-electric drives are located, described relative to the axis of the main output shaft,
R _max is the radius of the circle on which the tops of the teeth or the hollows of the wheel of the external or internal eccentric-cycloidal engagement are located,
e is the eccentricity of the cylindrical eccentric,
r _p - the outer radius of the rolling bearing mounted on a cylindrical eccentric,
+ r _p - for external eccentric-cycloidal engagement,
-r _p - for internal eccentric-cycloidal engagement,
the output shaft of each servo drive has an angular position sensor connected by an interface bus to the control unit of the corresponding servo drive and to the main control unit (GBU). 2. The multi-motor electromechanical drive according to claim 1, characterized in that the rotational speed of the rotor of the electric motor is in the range of 7000 ... 100000 min ^-1 , and the wave gear with bodies of revolution has from one to three stages. 3. The multi-motor electromechanical drive according to claim 1, characterized in that it has four servo-electric wheel drives mounted on a fixed support disk in pairs on axial lines located at an angle of ± 45 ° to the vertical on opposite sides of the disk axis, and four servo linear electric disk brake, two of which are located on the vertical axis, and two on the horizontal axis on opposite sides of the axis of the disk. 4. A multi-engine electromechanical drive according to any one of claims 1 to 3, characterized in that it is mounted on at least one wheel of the left and right main supports of the aircraft landing gear. 5. A multi-engine electromechanical drive according to any one of claims 1 to 3, characterized in that it is mounted on each wheel of the main landing gear of the aircraft. 6. A multi-engine electromechanical drive according to any one of claims 1 to 3, characterized in that it is mounted on one or all of the wheels of the nose landing gear of the aircraft. 7. A multi-engine electromechanical drive according to any one of claims 1 to 3, characterized in that it is mounted on all wheels of the nose and main supports of the aircraft landing gear. 8. The method of operation of a multi-engine electromechanical drive wheel of an aircraft landing gear according to claim 1, including:
- input tracking servo drives meshing with a gear wheel according to signals from GBU and converted in the control units of servo drives,
- start-up of follow-up electric drives for spinning the wheel before landing according to the signals received in GBU from the aircraft control system (SUS) and from GBU - into control units of the follow-up electric drives in accordance with the algorithms laid down in the control program,
- the withdrawal of servo drives from gearing with the wheel, carried out according to the signals received from the GBU and converted in the control units of servo drives,
- rotation of the wheel after touching the runway and to reduce the speed of the aircraft to 20-40 km / h,
- start-up of follow-up electric drives after landing the plane according to the signals received in GBU from CMS and from GBU - to control units of follow-up electric drives in accordance with the algorithms laid down in the control program,
- acceleration, steady movement and braking of the wheels during taxiing according to the program specified by the GBU and the generated signals converted in the control units of the servo drives, while tracking the angular position of the wheel and the output shafts of the servo drives according to the signals received from the GBU and converted in the control units of the servo drives
- disengaging the gears from the ring gear and stopping all servo-driven electric drives according to the signals received from the GBU and converted in the control units of servo-driven electric drives,
- braking the aircraft wheel to a complete stop,
- a change in the direction of rotation of the aircraft wheel according to the signals received from the GBU and converted in the control units of the tracking electric drives,
characterized in that
- the withdrawal of servo drives from gearing with the wheel until the centers of all the eccentrics occupy the position on the radial lines connecting the axle of the gear wheel with the axis of each shaft of the servo drives, and the stop of all servo drives for towing the aircraft is carried out according to signals from the control unit in accordance with the control program specified by the algorithm included in the GBU program,
- start-up of follow-up electric drives after landing and reaching a speed of 20-40 km / h is carried out by a signal supplied to the GBU to determine the angular position of the output shafts of the electric drives and the subsequent formation and supply of control signals from the control units for installing each of the output shafts by turning into a predetermined mutual the angular position of the lines of symmetry of the cylindrical eccentrics during engagement with the teeth formed by the cycloidal surface of the gear,
- acceleration, steady motion and braking of the aircraft wheel are carried out while maintaining a predetermined mutual angular position of the lines of symmetry of the eccentrics of all servo-driven electric drives in accordance with the algorithm laid down in the GBU program,
- the aircraft wheel is braked to a complete stop by turning on all linear electric drives of the disk brake according to the signals received from the control gear and converted into control units of the linear electric drives after the follow-up control gears are disengaged from the gear by the signal from the control gear in accordance with the control program defined by the algorithm laid down in the GBU program by subsequently turning the output shafts to occupy the centers of all the eccentrics of the position on the radial lines connecting the gear axis to oles with the axis of each output shaft and stopping all servo drives,
- entering into engagement with the wheel of all tracking electric drives and their stop at a given mutual angular position of the lines of symmetry of the cylindrical eccentrics is carried out by a signal from the GBU in accordance with the control program specified by the algorithm laid down in the GBU program. 9. The method according to p. 8, characterized in that the spin of the wheel before landing the plane is carried out by starting the tracking electric drives according to the signal supplied to the GBU to determine the angular position of the output shafts of the electric drives, forming and supplying from the control units a sequence of control signals for turning each of the output shafts into a given mutual angular position of the lines of symmetry of the cylindrical eccentrics and their engagement with the teeth formed by the cycloidal surface of the gear.

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