WO2022115132A1 - Architecture de système d'alimentation électrique et aéronef à décollage et atterrissage verticaux, tolérant aux pannes, la mettant en oeuvre - Google Patents

Architecture de système d'alimentation électrique et aéronef à décollage et atterrissage verticaux, tolérant aux pannes, la mettant en oeuvre Download PDF

Info

Publication number
WO2022115132A1
WO2022115132A1 PCT/US2021/042205 US2021042205W WO2022115132A1 WO 2022115132 A1 WO2022115132 A1 WO 2022115132A1 US 2021042205 W US2021042205 W US 2021042205W WO 2022115132 A1 WO2022115132 A1 WO 2022115132A1
Authority
WO
WIPO (PCT)
Prior art keywords
battery
motor
aircraft
flight
power
Prior art date
Application number
PCT/US2021/042205
Other languages
English (en)
Inventor
Joeben Bevirt
Alex STOLL
Martin VAN DER GEEST
Scott MACAFEE
Jason Ryan
Original Assignee
Joby Aero, Inc.
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Joby Aero, Inc. filed Critical Joby Aero, Inc.
Publication of WO2022115132A1 publication Critical patent/WO2022115132A1/fr

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L58/00Methods or circuit arrangements for monitoring or controlling batteries or fuel cells, specially adapted for electric vehicles
    • B60L58/10Methods or circuit arrangements for monitoring or controlling batteries or fuel cells, specially adapted for electric vehicles for monitoring or controlling batteries
    • B60L58/12Methods or circuit arrangements for monitoring or controlling batteries or fuel cells, specially adapted for electric vehicles for monitoring or controlling batteries responding to state of charge [SoC]
    • B60L58/14Preventing excessive discharging
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L3/00Electric devices on electrically-propelled vehicles for safety purposes; Monitoring operating variables, e.g. speed, deceleration or energy consumption
    • B60L3/0023Detecting, eliminating, remedying or compensating for drive train abnormalities, e.g. failures within the drive train
    • B60L3/0061Detecting, eliminating, remedying or compensating for drive train abnormalities, e.g. failures within the drive train relating to electrical machines
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L3/00Electric devices on electrically-propelled vehicles for safety purposes; Monitoring operating variables, e.g. speed, deceleration or energy consumption
    • B60L3/0092Electric devices on electrically-propelled vehicles for safety purposes; Monitoring operating variables, e.g. speed, deceleration or energy consumption with use of redundant elements for safety purposes
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L58/00Methods or circuit arrangements for monitoring or controlling batteries or fuel cells, specially adapted for electric vehicles
    • B60L58/10Methods or circuit arrangements for monitoring or controlling batteries or fuel cells, specially adapted for electric vehicles for monitoring or controlling batteries
    • B60L58/18Methods or circuit arrangements for monitoring or controlling batteries or fuel cells, specially adapted for electric vehicles for monitoring or controlling batteries of two or more battery modules
    • B60L58/21Methods or circuit arrangements for monitoring or controlling batteries or fuel cells, specially adapted for electric vehicles for monitoring or controlling batteries of two or more battery modules having the same nominal voltage
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B64AIRCRAFT; AVIATION; COSMONAUTICS
    • B64CAEROPLANES; HELICOPTERS
    • B64C29/00Aircraft capable of landing or taking-off vertically, e.g. vertical take-off and landing [VTOL] aircraft
    • B64C29/0008Aircraft capable of landing or taking-off vertically, e.g. vertical take-off and landing [VTOL] aircraft having its flight directional axis horizontal when grounded
    • B64C29/0016Aircraft capable of landing or taking-off vertically, e.g. vertical take-off and landing [VTOL] aircraft having its flight directional axis horizontal when grounded the lift during taking-off being created by free or ducted propellers or by blowers
    • B64C29/0033Aircraft capable of landing or taking-off vertically, e.g. vertical take-off and landing [VTOL] aircraft having its flight directional axis horizontal when grounded the lift during taking-off being created by free or ducted propellers or by blowers the propellers being tiltable relative to the fuselage
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B64AIRCRAFT; AVIATION; COSMONAUTICS
    • B64CAEROPLANES; HELICOPTERS
    • B64C5/00Stabilising surfaces
    • B64C5/02Tailplanes
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B64AIRCRAFT; AVIATION; COSMONAUTICS
    • B64DEQUIPMENT FOR FITTING IN OR TO AIRCRAFT; FLIGHT SUITS; PARACHUTES; ARRANGEMENT OR MOUNTING OF POWER PLANTS OR PROPULSION TRANSMISSIONS IN AIRCRAFT
    • B64D27/00Arrangement or mounting of power plants in aircraft; Aircraft characterised by the type or position of power plants
    • B64D27/02Aircraft characterised by the type or position of power plants
    • B64D27/24Aircraft characterised by the type or position of power plants using steam or spring force
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L2200/00Type of vehicles
    • B60L2200/10Air crafts
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L2220/00Electrical machine types; Structures or applications thereof
    • B60L2220/40Electrical machine applications
    • B60L2220/42Electrical machine applications with use of more than one motor

Definitions

  • This invention relates to electric powered flight, namely a power system for electric motors used on aircrafts.
  • Figures 1A-1D are of a VTOL aircraft in a hover configuration according to some embodiments of the present invention.
  • Figures 1E-1H are of a VTOL aircraft in a forward flight configuration according to some embodiments of the present invention.
  • Figures 1I-1K are of a VTOL aircraft transitioning from a forward flight configuration to a vertical take-off and landing configuration according to some embodiments of the present invention.
  • Figure 2A is a layout of a flight system with a ring architecture according to some embodiments of the present invention.
  • Figure 2B is a layout identifying motor locations for the ring architecture according to some embodiments of the present invention.
  • Figure 2C is a layout of battery locations according to some embodiments of the present invention.
  • Figure 3 is a motor power chart according to some embodiments of the present invention.
  • Figure 4 is a failure scenario layout according to some embodiments of the present invention.
  • Figure 5 is a failure compensation layout according to some embodiments of the present invention.
  • Figure 6 is a failure compensation layout according to some embodiments of the present invention.
  • Figure 7 is a power architecture layout according to some embodiments of the present invention.
  • Figure 8 is a battery discharge chart according to some embodiments of the present invention.
  • Figure 9 is a flight control system architecture layout according to some embodiments of the present invention.
  • Figure 10 illustrates flight control software architecture according to some embodiments of the present invention.
  • Figure 11A is a layout of a flight power system with a doublet architecture according to some embodiments of the present invention.
  • Figure 11B is a layout of a flight power system with a doublet architecture according to some embodiments of the present invention.
  • Figure 11C is a layout of a flight power system with a doublet architecture with a motor failure according to some embodiments of the present invention.
  • Figure 11D is a layout of a flight power system with a doublet architecture with a battery failure according to some embodiments of the present invention.
  • Figure 12 is a layout of a flight power system with a hexagram architecture according to some embodiments of the present invention.
  • Figure 13 is a layout of a flight power system with a star architecture according to some embodiments of the present invention.
  • Figure 14 is a layout of a flight power system with a mesh architecture according to some embodiments of the present invention.
  • FIGURE 16 is a schematic representation of a variant of a power system architecture.
  • FIGURE 17 is a diagrammatic representation of a variant of a power distribution in a multiple failure scenario.
  • FIGURE 18 is a schematic representation of a variant of a power system architecture.
  • FIGURE 19 is a diagrammatic representation of battery balancing for a variant of the power system.
  • FIGURE 20 is a schematic representation of a variant of a power system architecture.
  • FIGURE 21 is a schematic representation of a variant of a power system architecture.
  • FIGURE 22 is a schematic representation of a variant of a power system architecture.
  • FIGURE 23A-B schematic representations of a first and second variant of a power system architecture, respectively, illustrating powered relationships between batteries, electric propulsion units, and control surfaces.
  • FIGURE 24A-D are diagrammatic representations of a first, second, third, and fourth example of operating conditions of a variant of the power system architecture, respectively.
  • the power system can include: a plurality of batteries, a plurality of electric propulsion units, flight computers, and power connections.
  • the propulsion assemblies can include a motor, a propeller, and one or more inverters.
  • the power system can optionally include a plurality of flight actuators. However, the power system can include any other suitable set of components.
  • the power system functions to provide aircraft propulsion and/or aircraft control authority during flight.
  • the power system can be implemented in conjunction with the redundant power architecture and/or tiltrotor aircraft power configuration described in US Application Number 16/428,794, filed 3i- May-20i9, which is incorporated in its entirety by this reference.
  • the power system can be implemented in conjunction with the electric aircraft configuration described in US Application Number 16/409,653, filed 10- May-2019, which is incorporated in its entirety by this reference.
  • Motors of the power system can be integrated into a propeller and/or include an integrated inverter, or can be otherwise suitably connected to an inverter and/or propeller.
  • the term “electric propulsion unit” (EPU) as referenced herein can refer to any suitable motor, propeller, and/ or inverter system.
  • rotor in relation to portions of the power system 100 or otherwise, can refer to a rotor, a propeller, and/or any other suitable rotary aerodynamic actuator. While a rotor can refer to a rotary aerodynamic actuator that makes use of an articulated or semi-rigid hub (e.g., wherein the connection of the blades to the hub can be articulated, flexible, rigid, and/ or otherwise connected), and a propeller can refer to a rotary aerodynamic actuator that makes use of a rigid hub (e.g., wherein the connection of the blades to the hub can be articulated, flexible, rigid, and/or otherwise connected), no such distinction is explicit or implied when used herein, and the usage of “rotor” can refer to either configuration, and any other suitable configuration of articulated or rigid blades, and/or any other suitable configuration of blade connections to a central member or hub.
  • the usage of “propeller” can refer to either configuration, and any other suitable configuration of articulated or rigid blades, and/or any other suitable configuration of blade connections to a central member or hub. Accordingly, the tiltrotor aircraft can be referred to as a tilt-propeller aircraft, a tilt-prop aircraft, and/ or otherwise suitably referred to or described.
  • battery in relation to portions of the power architecture or otherwise, can refer to any suitable set or combination of battery cells, battery bricks, battery modules, battery packs, and/ or other suitable portions of an energy system.
  • Battery “cell” preferably refers to a unitary battery element, but can be otherwise defined.
  • Abattery “brick” can refer to a plurality of battery cells connected in parallel (e.g., with a common bus), but can be otherwise defined.
  • a battery module can refer to a plurality of battery cells and/or bricks arranged in series, but can be otherwise defined.
  • a battery pack can refer to any suitable combination or permutation of battery cells, bricks, and/or modules arranged in series and/or parallel; a set of battery cells, bricks, and/or modules enclosed within a common housing; and/or otherwise defined.
  • One or more battery packs can collectively form an energy system, which can supply power to various aircraft endpoints.
  • variations of the power system can prevent marginal power and/ or actuator failures from escalating into a serious failure (e.g., loss of aircraft command and control ability, etc.) by utilizing multiple layers of power and/or actuator redundancy.
  • the power system can retain control authority with a loss of any two batteries, motors (and propellers mounted thereto), flight control surfaces (or flight actuators driving said flight control surfaces), power connections, and/or any other suitable components.
  • the power system can rely upon dual-wound motors to provide an additional degree of power redundancy (e.g., for control surface actuators) and/or electrical redundancy.
  • the power system can reliably enhance power system architecture for electric motors adapted for use in an aircraft.
  • Individual batteries maybe used to power a subset of two or more motors in power systems with six or more motors, for example.
  • Each motor may be powered by two or more subsets of batteries, allowing accommodation for motor failure.
  • Each motor may have two or more sets of windings, with each winding powered by a different battery. With a failed winding, failed battery, or failed motor in a forward flight or a vertical take-off and landing mode, power routing may be automatically altered to continue proper attitude control, and to provide sufficient thrust. With a failed motor a second motor offset from the failed motor may be powered down to facilitate attitude control.
  • the power system can include any other suitable redundancies.
  • variations of the power system can make the aircraft robust to unplanned external damage sources (e.g., electrical or mechanical inputs).
  • components of the power system can be arranged such that flight-critical hardware (e.g., flight computers, batteries, PoE switches, etc.) are physically separated from one another (while connected via the power architecture and/ or data transfer network) outside of a predetermined radius (e.g., predetermined based on a predicted, estimated, and/or historical damage radius resulting from explosive component failure, decompression, fire damage, etc.).
  • flight-critical hardware e.g., flight computers, batteries, PoE switches, etc.
  • a predetermined radius e.g., predetermined based on a predicted, estimated, and/or historical damage radius resulting from explosive component failure, decompression, fire damage, etc.
  • variations of the power system can provide continuous power availability by load balancing various batteries of the aircraft.
  • the flight computers can command different proportions of power to various motors, motor windings, and/or flight actuators within the power architecture to shift power/current draw to batteries with the greatest remaining charger (e.g., highest SOC).
  • the power architecture can otherwise ensure continuous power availability on the aircraft.
  • variations of the technology can additionally or alternatively provide any other suitable benefits and/or advantages.
  • the power system 100 can include: a plurality of batteries, a plurality of electric propulsion units, flight computers, and power connections (e.g., forming a power distribution architecture).
  • the electric propulsion units (EPUs) can include a motor, a propeller, and one or more inverters.
  • the power system can optionally include a plurality of flight actuators. However, the power system can include any other suitable set of components.
  • the power system functions to provide aircraft propulsion and/or aircraft control authority during flight.
  • the power system 100 can include a plurality of batteries which function to store electrochemical energy in a rechargeable manner.
  • the system can include any suitable number of batteries (e.g., battery packs), such as 1, 2, 3, 4, 5, 6, more than 6, a range bounded by the aforementioned values, and/or any other suitable number of battery packs as a part of a complete energy system.
  • Battery packs can be arranged and/ or distributed about the aircraft in any suitable manner. Preferably, battery packs are arranged proximal to a vertical lateral plane of the aircraft, but can be otherwise suitably arranged. Battery packs can be arranged within wings (e.g., inside of an airfoil cavity), inside nacelles, and/ or in any other suitable location on the aircraft.
  • the system includes a first battery pack within an inboard portion of a left wing and a second battery pack within an inboard portion of a right wing.
  • the system includes a first battery pack within an inboard nacelle of a left wing and a second battery pack within an inboard nacelle of a right wing.
  • one or more battery packs include a plurality of battery modules.
  • the battery pack can include or exclude the battery pack housing/enclosures (e.g., closeouts), can be assembled into the aircraft separately from the battery pack housing/enclosures, and/or can be otherwise suitably configured.
  • the battery pack can include any suitable cells of any suitable type, chemistry, voltage, maximum C-rate, capacity, and/or other characteristics.
  • Battery cells can be the same or different across various battery modules/ packs, or within the same battery module/pack.
  • Battery cell types e.g., geometries
  • the electric propulsion units function to rotate an airfoil to generate thrust and/or aerodynamic lift, propelling the aircraft.
  • the EPUs (hereinafter interchangeably referenced as “propulsion assemblies”) can include a motor, a propeller, and one or more inverters. However, the EPUs can include any other suitably components.
  • the aircraft preferably includes 6 EPUs, but can additionally or alternatively include 3 EPUs, 8 EPUs, and/or any other suitable number of EPUs.
  • the EPUs are preferably distributed symmetrically about a sagittal midplane of the aircraft, and most preferably substantially equidistant from a center of gravity of the aircraft, but can be otherwise suitably implemented.
  • the motor functions to generate a torque about and/ or rotate about a motor axis.
  • the motor can be connected to a propeller of an aircraft and/or integrated into the hub of a propeller.
  • the motor can be an in-runner motor, outrunner motor, and/or any other suitable type of motor.
  • the motor is a large diameter motor and/or a motor designed for high-torque, low-speed operation.
  • the motor can include a diameter of: 100 mm, 200 mm, 250 mm, 300 mm, 320 mm, 350 mm, 380 mm, 400 mm, 420 mm, 450 mm, 500 mm, greater than 500 mm, any range bounded by the aforementioned values, and/or any other suitable diameter.
  • the motor can have any other suitable dimensions.
  • the motor can have any suitable power capabilities and/ or requirements.
  • the motor is a 3-phase motor, and more preferably is a dual wound 3-phase motor (e.g., two sets of redundant 3-phase windings).
  • the motor can include any other suitable number of phases or be otherwise constructed.
  • the motor can have a power threshold (e.g., peak power, maximum continuous power, nominal power, max power of individual set of windings of dual-wound motor, etc.) of: less than 8okW, 80 kW, 120 kW, 150 kW, 200 kW, 220 kW, 230 kW, 240 kW, 250 kW, 300 kW, 450 kW, 460 kW, 480 kW, 500 kW, greater than 500 kW, any range bounded by the aforementioned values, and/or any other suitable power characteristics.
  • the torque/speed characteristics of the motor can be designed/selected to correspond to the aerodynamic properties of the propeller (and/ or aircraft).
  • the motor can be operate the rotor at a top speed of: less than 100 RPM, 100 RPM, 300 RPM, 500 RPM, 800 RPM, 1000 RPM, 1200 RPM, 1300 RPM, 1500 RPM, 1800 RPM, 2000 RPM, 2200 RPM, 2500 RPM, 3000 RPM, 5000 RPM, greater than 5000 RPM, any range bounded by the aforementioned values, and/ or any appropriate speed, and can operate with a maximum torque of: less than 10 N-m, 50 N-m, 100 N-m, 500 N-m, 800 N-m, 1000 N-m, 1200 N-m, 1500 N-m, 1800 N-m, 2000 N-m, 2200 N-m, 2500 N-m, 3000 N- m, 5000 N-m, greater than 5000 N-m, any range bounded by the aforementioned values, and/or any appropriate maximum torque.
  • the motor can have any suitable torque/speed characteristics, and the propeller can likewise be operated in
  • first and second set of windings e.g., 2 sets of 3 phase windings
  • adjacent field coils are in opposing sets of windings, however the field coils can be otherwise suitably distributed to enable independent and/or separate actuation via each set of windings.
  • each set of windings can be powered by a separate inverter and/or can be powered by the same inverter.
  • the dual wound variant can provide an additional layer of redundancy, since a single point of electrical failure (either within the motor and/ or at the inverter) can compromise only a single set of windings.
  • each set of windings and/or each inverter can be powered by a separate set of power sources (e.g., separate sets of battery packs), which can similarly allow the motor to continue operating even with the loss of one or more power sources.
  • the bussing divides the full electromagnetic motor circuit into equal partial motors dividing stator and windings (e.g., like ‘pie slices’) which are controlled by two independent phase control schemes.
  • the electrical bussing is preferably arranged on a rear portion of the motor and/or inboard portion of the motor, but can additionally or alternately be formed on the front side, radially inward of the stator body, and/ or otherwise suitably configured.
  • the electrical bussing can include a set of motor terminals (e.g., one terminal associated with each pole of the motor for each set of windings) which connect the motor to the inverter and a set of power connections connecting the field coil terminals.
  • the motor can alternatively include only a single set of windings (e.g., one set of three phase windings), include more than two sets of windings, and/ or be otherwise suitably configured.
  • the EPUs can include any other suitable motor.
  • the inverters function to supply conditioned power to the motor and/or control the rotation of the motor based on the commands from the flight computer(s).
  • each EPU can include a first and second inverter respectively associated with the first and second sets of windings of a dual-wound motor.
  • the EPU can include additional inverters, which can power a motor cooling pump, cooling fan, blade pitch mechanism, and/or tilt linkage of the propulsion assembly.
  • the inverter can be integrated into the motor, mounted to an inboard portion of the motor, separate from the motor (e.g., arranged within a nacelle, remote, etc.) and connected to the motor within the power system.
  • the EPUs can include any other suitable inverters.
  • the propellers function to generate aerodynamic lift when driven by the rotation of the motor about the motor axis, thereby propelling the aircraft.
  • the propellers can be mounted to the motor in a fixed and/or pivotable manner (e.g., by a blade pitch mechanism), and are configured to rotate about the motor axis.
  • the propulsion assemblies can include any suitable propellers.
  • the propulsion assemblies can optionally include a tilt mechanism which functions to pivot and/or translate the motor (and the propeller mounted thereto).
  • the tilt mechanism can be configured to transform the motor and propeller between a forward configuration, wherein the motor/propeller axis is substantially parallel with the longitudinal/roll axis of the aircraft, and a hover configuration, wherein the motor/propeller axis is substantially parallel to the vertical/yaw axis of the aircraft (e.g., and/or a gravity vector).
  • the tilt mechanism can connect to the rear/inboard portion of the motor (and/ or an inverter mounted thereto) and mount the motor to the airframe of the aircraft.
  • the tilt mechanism can include the linkage and/or nacelle/boom pivot described in U.S. Application Number 16/409,653, filed 10-MAY-2019, which is incorporated herein in its entirety by this reference.
  • the tilt mechanism can include the linkage described in U.S. Application Number US14/ 660,838, filed 17-Mar-2015, which is incorporated herein in its entirety by this reference.
  • the propulsion assembly can include any other suitable tilt mechanism, and/ or exclude a tilt mechanism.
  • the propulsion assemblies can optionally include a blade pitching mechanism which functions to change an angle of attack of the blades of an aircraft propeller (e.g., relative to a disc plane).
  • the blade pitching mechanism can allow independent articulation of each blade, collective articulation of the blade pitch (e.g., simultaneous), cyclic articulation of the blade pitch, and/or otherwise suitably allow articulation.
  • the blade pitching mechanism can include a rotary plate mechanism (e.g., swashplate) and/or linkage which extends through an interior of the motor. In a specific example, the blade pitching mechanism extends through an interior of a motor bearing and/or is mounted at a radial position inward of the bearing.
  • the blade pitching mechanism can extend through the motor (e.g., along the motor’s rotational axis, through the motor center), extend around the motor, or be otherwise arranged.
  • the blade pitching mechanism can connect to the tilt mechanism directly and/ or indirectly (e.g., mounted to the inverter housing and/or stator of the motor).
  • the set of actuators can include any other suitable blade pitching mechanism, and/ or exclude a blade pitching mechanism.
  • the flight computer functions to generate commands that can be transmitted to and interpreted by EPU inverters and/or flight actuators to control aircraft flight.
  • each of the plurality of flight computers can be a substantially identical instance of the same computer architecture and components, but can additionally or alternatively be instances of distinct computer architectures and components (e.g., generalized processors manufactured by different manufacturers).
  • the flight computers can include: CPUs, GPUs, TPUs, ASICs, microprocessors, and/or any other suitable set of processing systems.
  • each of the flight computers performs substantially identical operations (e.g., processing of data, issuing of commands, etc.) in parallel, and is connected (e.g., via the distribution network) to the same set of flight components.
  • each flight computer is provided to the EPUs and/or flight actuators by way of a data distribution network (e.g., as described in U.S. Application Number 16/573,837, filed 17-SEP-2019, which is incorporated herein in its entirety by this reference).
  • a data distribution network e.g., as described in U.S. Application Number 16/573,837, filed 17-SEP-2019, which is incorporated herein in its entirety by this reference.
  • the power system can be used with any suitable propulsion assemblies.
  • the power connections function to distribute power between the batteries and the EPUs, and can additionally or alternatively function to provide power to a (e.g., low voltage) data transfer network and/or flight actuators.
  • Power connections can be configured in any suitable architectures. Examples of power connection architectures are shown in FIGURES 11A, 12, 13, and 14. However, the power system can include any suitable distribution of power connections between any suitable power sources (e.g., batteries) and power sinks (EPUs, flight actuators, flight computers, switches, etc.).
  • the power connections can group the batteries into battery sets, where batteries within a battery set are connected to each component within a component set (e.g., wherein components of the same type can be divided into component sets).
  • component sets include: battery sets, flight actuator sets, EPU sets, and/or sets of other components.
  • Component sets preferably do not overlap with other sets of the same component type, but can alternatively overlap with other sets of the same component type.
  • Component sets connected to a given battery set are preferably connected to each other and/or are not connected to other component sets that are connected to other battery sets, but the component sets powered by a different battery sets can alternatively overlap.
  • the power connections between the battery set and each component set can be: a shared wire, a shared bus, different connections (e.g., wires, busses, etc.) for each battery-component connection, and/or be otherwise configured.
  • the power connections can group the batteries into various ‘pairs’, where paired batteries are connected to the respective windings of one or more dual wound motors and/ or are connected to two different inverters of an EPU (associated in a pairwise manner with the dual windings of the motor within the EPU).
  • each battery can be paired with exactly one other battery and/ or can form a portion of exactly one battery pair (e.g., doublet variant, an example is shown in FIGURE 16), can be paired with two batteries, can be paired with each battery, can be un-paired with one or more batteries, and/ or can be otherwise suitable interconnected within the power system by the power connections.
  • Paired batteries can be distributed on the same side (e.g., left pair, right pair, etc.; an example is shown in FIGURE 23A) and/ or different sides of the sagittal plane of the aircraft. Paired batteries can be respectively connected to both windings of single dual-wound motor (an example is shown in FIGURE 12) and/ or both windings of multiple dual-wound motors (an example is shown in FIGURE 13, an example is shown in FIGURE 14, with one or more motors connected to only one battery of the battery pair). In a specific example, for each dual wound motor having a first set of windings connected to the first battery of a battery pair, the second (remaining) windings are connected to the second (remaining) battery of the battery pair. Accordingly, batteries can be considered “unpaired” in the power architecture if the intersection of their respective sets of associated motors is null (e.g., no motors are connected to both batteries.).
  • Paired and/ or unpaired batteries can be distributed about the aircraft based on: a threshold spatial offset (e.g., for impact survivability), fire vent paths, distance from passenger seats, electrically isolation (e.g., between switch sets and/ or actuator sets, as described in US Application Number 16/428,794, filed 3i- May-20i9, which is incorporated in its entirety by this reference), and/or otherwise suitably distributed.
  • a threshold spatial offset e.g., for impact survivability
  • fire vent paths e.g., distance from passenger seats
  • electrically isolation e.g., between switch sets and/ or actuator sets, as described in US Application Number 16/428,794, filed 3i- May-20i9, which is incorporated in its entirety by this reference
  • power connections can interconnect batteries with the EPUs and/or other components of the power system in any suitably manner.
  • the power system can include any other suitable components.
  • an aircraft may use bladed propellers powered by electric motors to provide thrust during take-off.
  • the propeller/motor units maybe referred to as propulsion assemblies.
  • the wings of the aircraft may rotate, with the leading edges facing upwards, such that the propellers provide vertical thrust for takeoff and landing.
  • the motor driven propeller units on the wings may themselves rotate relative to a fixed wing, such that the propellers provide vertical thrust for take-off and landing. The rotation of the motor driven propeller units may allow for directional change of thrust by rotating both the propeller and the electric motor, thus not requiring any gimbaling, or other method, of torque drive around or through a rotating joint.
  • aircrafts according to embodiments of the present invention take off from the ground with vertical thrust from rotor assemblies that have deployed into a vertical configuration.
  • the rotor assemblies may begin to be tilted forward in order to begin forward acceleration.
  • airflow over the wings results in lift, such that the rotors become less important and then unnecessary for maintaining altitude using vertical thrust.
  • some or all of the blades used for providing vertical thrust during take-off may be stowed along their nacelles.
  • all propulsion assemblies used for vertical take-off and landing are also used during forward flight.
  • the nacelle supporting the propulsion assemblies may have recesses such that the blades may nest into the recesses, greatly reducing the drag of the disengaged rotor assemblies.
  • an aircraft 200 uses fixed wings 202, 203, which may be forward swept wings, with propulsion assemblies of the same or different types adapted for both vertical take-off and landing and for forward flight.
  • the propulsion assemblies are positioned for vertical thrusting.
  • the aircraft body 201 supports a left wing 202 and a right wing 203.
  • Motor driven rotor assemblies 206 along the wings may include electric motors and propellers which are adapted to articulate from a forward flight configuration to a vertical configuration using deployment mechanisms which may reside in the nacelle body, and which deploy the motor and propeller while all or most of the nacelle remains in place attached to the wing.
  • the propeller blades may stow and nest into the nacelle body.
  • the motor driven rotor assemblies 207 at the wing tips may deploy from a forward flight configuration to a vertical take-off and landing configuration along a pivot axis wherein the nacelle and the electric motor and propeller deploy in unison.
  • more mid-span propulsion assemblies may be present.
  • the aircraft body 201 extends rearward is also attached to raised rear stabilizers 204.
  • the rear stabilizers have rear propulsion assemblies 205 attached thereto.
  • the motor driven rotor assemblies 207 at the tips of the rear stabilizers may deploy from a forward flight configuration to a vertical take-off and landing configuration along a pivot axis wherein the nacelle and the electric motor and propeller deploy in unison.
  • the propulsion assemblies are positioned at different distances from the aircraft center of mass, in two axes. Attitude control during vertical take-off and landing may be manipulated by varying the thrust at each of the propulsion assembly locations. In the circumstance of a motor failure during vertical take off or landing, and especially a motor failure at the wing outboard propulsion assembly, the attitude of the aircraft may be maintained by implementing fault tolerance strategies described herein.
  • the aircraft 200 is seen with two passenger seats side by side, as well as landing gear under the body 201. Although two passenger seats are illustrated, other numbers of passengers may be accommodated in differing embodiments of the present invention.
  • FIGs lE through lH illustrates the aircraft 200 in a forward flight configuration.
  • the propulsion assemblies are positioned to provide forward thrust during horizontal flight.
  • the centers of mass of the motors and of the propellers may be forward of the leading edge of the wings in the forward flight configuration.
  • the propulsion assemblies 205 on the rear stabilizers 204 may be at a different elevation than the propulsion assemblies 206, 2070h the wings.
  • the attitude of the aircraft may be maintained by implementing fault tolerance strategies described herein.
  • all or a portion of the wing mounted propulsion assemblies may be adapted to be used in a forward flight configuration, while other wing mounted propellers may be adapted to be fully stowed during regular, forward, flight.
  • the aircraft 200 may have two propulsion assemblies on the right wing 203 and two propulsion assemblies on the left wing 202.
  • the inboard propulsion assemblies on each wing may have wing mounted rotors 206 that are adapted to flip up into a deployed position for vertical take-off and landing, to be moved back towards a stowed position during transition to forward flight, and then to have their blades stowed, and nested, during forward flight.
  • the outboard propulsion assembly 207 may pivot in unison from a horizontal to a vertical thrust configuration.
  • each rear stabilizer 204 may have propulsion assemblies mounted to it, both of which are adapted to be used during vertical take-off and landing, and transition, modes.
  • all of the propulsion assemblies designs are the same, with a subset used with their main blades for forward flight.
  • all of the propulsion assemblies designs are the same, with all propellers used for forward flight.
  • Flight actuators can include control surface actuators (configured to drive control surfaces), tilt linkages (e.g., which function to transform the aircraft and/or propulsion assemblies thereon between a forward and a hover configuration), variable blade pitch actuators (e.g., for variable blade pitch rotors), and/ or any other suitable actuators.
  • Control surfaces can include flaps, elevators, ailerons, rudders, ruddervators, spoilers, slats, air brakes, and/or any other suitable control surfaces.
  • control surfaces can include the high-lift mechanism as described in US Application Number 17/033,178, filed 25-SEP- 2020, which is incorporated in its entirety by this reference.
  • the aircraft can additionally or alternatively include landing gear (e.g., retractable landing gear, fixed landing gear), which functions to structurally support the aircraft when it is in contact with the ground and/ or maneuver the aircraft during taxi.
  • landing gear e.g., retractable landing gear, fixed landing gear
  • the power architecture can be integrated into and/or implemented in conjunction with any suitable aircraft.
  • the motors driving the wing mounted propulsion assemblies 206, 207 and/or the motors driving the rear stabilizer mounted propulsion assemblies may each have two sets of windings. In some aspects, both winding sets are powered during flight. In some aspects, each winding of the motor is powered by a different battery circuit. In some aspects, each motor may have more than two sets of windings. In variants, each motor can be configured to be separately and/ or cooperatively powered via a plurality of inverters.
  • each electric propulsion unit can include two inverters (e.g., quad inverters), each powered by a separate battery (e.g., of a doublet pair, etc.), an example of which is shown in Figure 20, [0081]
  • the electric motors of the aircraft are powered by rechargeable batteries.
  • the use of multiple batteries driving one or more power busses enhances reliability, in the case of a single battery failure.
  • the batteries reside within the vehicle body on a rack with adjustable position such that the vehicle balance may be adjusted depending upon the weight of the pilot.
  • Figure 10 illustrates a battery location layout for a six battery system according to some embodiments of the present invention.
  • a high reliability power system io for an electrically powered vertical take-off and landing aircraft has six motors and six batteries in a ring architecture.
  • Each of the batteries provides power to two motors, and each motor receives power from two batteries.
  • Figure 2B illustrates a layout of six motors on a VTOL aircraft in an exemplary embodiment using six propulsion assemblies and six batteries.
  • Figure 2C illustrates a layout of six batteries in a VTOL aircraft in an exemplary embodiment using six propulsion assemblies and six batteries.
  • each battery is powering two separate motors.
  • each of the motors is wound with two sets of windings, and each set of windings receives power from a different battery.
  • each of the six batteries supplies two power inverters 31, for a total of 12 power inverters.
  • the nominal voltage of the batteries is 600V.
  • Each of the six propulsion motors has two sets of windings, with each motor powered by two inverters, one for each set of windings.
  • the two inverters powering a single motor each are supplied power by different batteries.
  • the first motor 11 is coupled to the sixth battery 26 and the first battery 21.
  • the second motor 12 is coupled to the first battery 21 and the second battery 22.
  • the third motor 13 is coupled to the second battery 22 and the third battery 23.
  • the fourth motor 14 is coupled to the third battery 23 and the fourth battery 24.
  • the fifth motor 15 is coupled to the fourth battery 24 and the fifth battery 25.
  • the sixth motor 16 is coupled to the fifth battery 25 and the sixth battery 26.
  • each battery splits its power distribution evenly between the two motors to which it is coupled, and each motor receives an equal amount of power from each battery to which it is coupled.
  • the fault tolerant aspect of the power system architecture is adapted to withstand, and respond to, at least the following failures: the failure of a battery; the failure of a motor; or the failure of a motor inverter.
  • Figure 3 is a bar graph (with bar pairs for each operating mode) of the power required for a single motor 40 in the six motor embodiment.
  • the blue vertical bars (on the left side of the bar pair for each mode) illustrate nominal (normal) operating power, per motor, for the five different flight phases: hover 41, vertical ascent 42, vertical descent 43, cruise climb 44, and cruise 45.
  • the hover, vertical ascent, and vertical descent modes are VTOL modes wherein the motors are rotated to a vertical thrust position as seen in Figures 1A-1D.
  • the cruise climb and cruise phases are with the motors in a forward flight position, as seen in Figure 1E-1H.
  • the red vertical bars (on the right side of the bar pair for each mode) represent emergency phase operation, as discussed below.
  • the illustrative embodiment of a six motor six battery ring architecture system runs about 60 kW per motor in a VTOL mode during nominal conditions. This 60 kW compares to approximately the 150 kW maximum available power. In the case of a motor failure, however, more power may be diverted to remaining motors to maintain attitude and altitude control, as discussed further below.
  • Figure 4 illustrates a potential failure mode 60 wherein the first motor fails.
  • the loss of the first motor 11 represents loss of thrust at the far port motor, which will have a significant impact on the attitude of the aircraft.
  • the flight computer may immediately sense at least two things: first, that the motor has quit drawing current; second, that there is a disruption to the attitude of the aircraft.
  • the flight control computer will reduce power to the opposing motor(s) as needed.
  • the power to the fourth motor 14 will be reduced.
  • the loss of lift due to the shutdown of two motors requires that the remaining four motors take more power and deliver more lift.
  • Figure 6 illustrates how the increased load demands in the second, third, fifth, and sixth motors are met by distributing more power from the batteries.
  • the red vertical bars illustrate the power delivery required with the motor failure and then the motor shutdown of the opposing motor.
  • the power down of the fourth motor and the increase in power to the second, third, fifth, and sixth motors may take place simultaneously in some aspects. In some aspects, the power down of the fourth motor and the increase in power to the second, third, fifth, and sixth motors may take place sequentially.
  • the first battery 21 now only delivers power to the second motor 12.
  • the third battery only delivers power to the third motor
  • the fourth battery only delivers power to the fifth motor
  • the sixth battery only delivers power to the sixth motor.
  • the second battery delivers power to both the second and third motors
  • the fifth battery delivers power to the fifth and sixth motors.
  • the cross motor may be run at a low level, in the range of 0-20% of nominal power, for example.
  • each battery may be putting out the same amount of power, but two batteries are splitting their power delivery, and four motors are providing (or substantially providing) power to only a single motor.
  • the increased load demand of the motors in this emergency mode is shared through the battery architecture to utilize the available energy onboard the aircraft. Although one motor has been disabled and a second motor has been powered down to accommodate attitude control concerns, each battery is still being used and delivering power.
  • the vertical take-off and landing aircraft has an autonomous attitude control system adapted to withstand a power link failure, or complete motor failure, in a multi -battery system by load sharing to better equate battery discharge levels.
  • each motor is driven on multiple complementary winding sets, with each winding set using a different load link and being driven by a different battery.
  • Figure 7 is an illustrative embodiment of the electrical system power architecture for a six motor six battery aircraft.
  • Each of the six batteries 201 supplies two power inverters, for a total of 12 power inverters 202.
  • the nominal voltage of the batteries is 600V.
  • Each of the six propulsion motors 203 has two sets of windings, with each motor powered by two inverters, one for each set of windings.
  • the two inverters powering a single motor each are supplied power by different batteries.
  • the battery also supplies power to the rotor deployment mechanisms 204 (nacelle tilt actuators) which are used to deploy and stow the rotors during various flight modes (vertical take-off and landing configuration, forward flight configuration, and transition between).
  • a flight computer 205 monitors the current from each of the twelve motor inverters 202 which are supplying power to the twelve winding sets in the six motors 203.
  • the flight computer 205 may also control the motor current supplied to each of the 12 sets of windings of the six motors.
  • the batteries 201 also supply power to the blade pitch motors and position encoders of the variable pitch propellers 206.
  • the batteries also supply power to control surface actuators 207 used to position various control surfaces on the airplane.
  • the blade pitch motors and the control surface actuators 207 may receive power run through a DC-DC converter 208, stepping the voltage down from 600V to 160V, for example.
  • a suite of avionics 209 may also be coupled to the flight computer.
  • a battery charger 210 maybe used to recharge the batteries 201, and the battery charger maybe external to the aircraft and ground based.
  • the flight computer can be implemented and communicatively connected within the power architecture as described in US Application Number 16/573,837, filed 17-SEP-2019, which is incorporated in its entirety by this reference.
  • a first set of batteries e.g., doublet pair
  • a second set of batteries e.g., separate and distinct from the first set, remainder of the batteries, second doublet pair, etc.
  • the switch sets communicatively connecting the flight computers to the flight actuators (e.g., an example is shown in FIGURE 18).
  • the compensations to power distribution to the various motors from the various batteries, as described above, may be done autonomously and onboard the aircraft.
  • the compensations may be done without needing input from the pilot, for example.
  • a single winding on a motor may fail.
  • the opposing motor may be powered down somewhat while the motor with a sole remaining winding may be powered up somewhat.
  • the power supplied by the batteries may be moderated to even out the discharge of the various batteries.
  • a battery may fail.
  • the cross motor may be reduced 10-20%, with the sole battery remaining on the motor with the failed battery/inverter providing extra power, and differential power along the ring used to spread the battery discharge.
  • Figure 8 illustrates four flight modes and a bar chart 235 of the battery discharge rates for each flight mode.
  • the vertical axis in the bar chart is the battery discharge rate C.
  • the battery discharge rate is a normalized coefficient wherein a 1 C discharge rate would discharge the battery in one hour.
  • a 2 C discharge rate would discharge the battery in 30 minutes, a 3 C discharge rate would discharge the battery in 20 minutes, and so on.
  • a maximum peak discharge rate 236, which is about 5 C in this exemplary embodiment, may be set by the limitations of the battery chemistry.
  • the nominal flight modes are hover 232, transition 233, and cruise 234.
  • the cruise discharge rate 240 may be approximately 1 C.
  • the aircraft will change to a transition mode 233, which may have a transition discharge rate 239 of approximately 2 C.
  • the aircraft will then go into hover mode 232 as it lands, which may have a discharge rate of approximately 2.5 C.
  • the aircraft may go into an emergency hover mode 231, wherein a cross motor may be powered down to achieve attitude stability.
  • the hover mode discharge rate 237 maybe over 3 C.
  • the maximum gross take-off weight maybe 4200 pounds.
  • the discharge rates are out of ground effect (OGE), with a total energy storage of all batteries of 150 kWh.
  • OGE ground effect
  • the anticipated time using the high discharge rate at the emergency hover discharge rate 237 is approximately 1 minute.
  • Figure 9 illustrates a flight control system architecture for a high reliability electric powered aircraft according to some embodiments of the present invention.
  • the flight computer 111 of the control system receives flight commands 114 from the mission computer 112 and from the pilot 113.
  • the flight computer may also receive inputs from a flight critical sensor suite 110.
  • the flight critical sensors may be triply redundant.
  • the flight computer may be triply redundant.
  • the system may include a voting bridge 116 on each actuator 115.
  • Figure 10 illustrates the flight control software architecture according to some embodiments of the present invention.
  • a doublet architecture 120 which uses four batteries to the electric motors of six propulsion assemblies; a left wing tip propulsion assembly 121, a left wing propulsion assembly 122, a right wing propulsion assembly 123, a right wing tip propulsion assembly 124, a left rear propulsion assembly 125, and a right rear propulsion assembly 126.
  • each battery provides power to one or motors on each side of the aircraft longitudinal centerline.
  • a battery failure By linking a battery that powers the furthest outboard to a motor on the other side of the centerline of the aircraft, a battery failure then has its effect more spread out across the aircraft, reducing the amount of attitude offset due to the battery failure.
  • a motor failure at the first motor 121 for example, there may still be an instantaneous reduction in power to the fourth motor to compensate for the failure.
  • the compensation regime for power sharing in a doublet architecture using the remaining motors will allow for lower inverter loads in an inverter optimized system as compared to the ring architecture that was disclosed above.
  • the compensation regime for power sharing in a doublet architecture using the remaining motors will allow for lower battery loads in a battery optimized system as compared to the ring architecture.
  • Figure nB illustrates a nominal operating condition for the doublet architecture 120 wherein each of the four batteries 111, 112, 113, 114 provides 35 KW to one winding of three different motors, for a total of loskW delivered per battery, and a total of 70 kW received per motor, for a total delivery of 420 kW. Each motor is receiving power from three batteries.
  • FIG 11C illustrates a motor failure condition, in this exemplary case the motor 121 of the left wing tip propulsion assembly.
  • the motor 124 on the right wing tip has been unpowered and is no longer drawing any power, in order to offset the loss of the left wing tip motor.
  • Each of the batteries is now powering two motors instead of the prior three, and each motor is receiving power from two batteries, instead of the prior three.
  • Each of the batteries is able to run at the same power output level, and each of the motor windings, and their associated inverters, are also able to run at the same power level.
  • Figure 11D illustrates a battery failure condition, in this exemplary case the first battery 111.
  • each remaining battery provides the same power output level, although the different motors run at different power levels in order to balance the thrust generated on each side of the aircraft longitudinal centerline.
  • FIG. 12 illustrates a six battery six motor hexagram architecture 200 according to some embodiments of the present invention.
  • each of the six batteries powers two motors, as with the ring architecture. And each motor is powered by two batteries. However, the first battery provides power to the first and third motor, the second battery provides power to the second and fourth motor, and so on.
  • the hexagram architecture creates two separate rings encompassing the first, third, and sixth motors, and the second, fourth, and fifth motors.
  • FIG. 16 illustrates the maximum loads in the inverters, batteries, and motors for inverter-optimized, battery-optimized, and motor- optimized solutions for the various motor-battery architectures described herein during a battery failure.
  • the hexagram architecture is indicated with a symbol, as opposed to a name like the other architectures, in Figure 16.
  • Figures 13 and 14 illustrate six motor four battery systems according to some embodiments of the present invention.
  • Figure 13 illustrates a star architecture using four batteries to power six motors. Each battery is coupled to three motors.
  • Figure 14 illustrates a mesh architecture with four batteries and six motors.
  • the power architecture can be integrated into and/or implemented in conjunction with an aircraft including any suitable number and/or arrangement of EPUs, motors, propulsion assemblies.
  • the aircraft can include any suitable number and/or arrangement of batteries (packs, cells, modules, etc.).
  • Figures 15A, 15B, and 15C illustrate the maximum loads in the inverters, batteries, and motors, respectively, for inverter-optimized, battery-optimized, and motor- optimized solutions for the various motor-battery architectures described herein during a motor failure.
  • the hexagram architecture is indicated with a symbol, as opposed to a name like the other architectures.
  • Figure 17 illustrates an example thrust distribution in a two-motor inoperable scenario.
  • Flight actuators and/or landing gear can include redundancies which functions to preserve control authority in the event of a failure (e.g., mechanical, electrical, thermal, communication, etc.).
  • Flight actuator and/ or landing gear redundancy can include: duplicative redundancy (e.g., multiple instances of a control surface and/or actuator on the same side of a sagittal midplane of the aircraft), multiplicative communication channels (e.g., to distinct switch sets, an example is shown in FIGURE 18), redundant power inputs (e.g., where the flight actuator includes multiple sets of windings configured to separately and/or cooperatively drive actuation), redundant positional feedback/sensing, and/or any other suitable redundancies.
  • duplicative redundancy e.g., multiple instances of a control surface and/or actuator on the same side of a sagittal midplane of the aircraft
  • multiplicative communication channels e.g., to distinct switch sets, an example is shown in FIGURE 18
  • redundant power inputs e
  • Redundant pairs/sets flight actuators are preferably distributed symmetrically about the aircraft, but can alternatively be distributed asymmetrically and/ or otherwise suitably distributed.
  • redundant sets of flight actuators can be otherwise suitably distributed.
  • each flight actuator can be supplied with power from a single battery (e.g., by a single power connection; an example is shown in FIGURE 21; etc.), but can additionally or alternatively be powered by a plurality of batteries (e.g., via a single power connection; indirectly; by multiple connections; by individual connections; etc.) and/or otherwise suitably powered.
  • duplicative/redundant flight actuators can separately and/or cooperatively drive actuation of their respective control surfaces in order to affect a commanded aircraft control.
  • a specific aircraft maneuver can be achieved by fully deploying a first control surface, but can alternatively be achieved by fully deploying a second (redundant) control surface and/ or by partially deploying the first and the second control surfaces (e.g., cooperatively influencing aircraft forces/moments).
  • flight actuators associated with duplicative control surfaces are powered by a pair of batteries connected to respective sets of windings of one or more dual-wound motors of the aircraft, an example of which is shown in Figure 24A.
  • battery pack failure and/ or full charge depletion of one battery of a pair can be accommodated by electrically regenerating power using one set of windings of a dual wound motor (electrically connected to both batteries of the doublet pair), which can be used to power the flight actuators coupled to the failed battery (an example is shown in FIGURE 24B) and/ or charge the depleted battery (an example is shown in Figure 24D).
  • paired batteries connected to the respective sets of windings of one or more dual wound motors
  • SOC state of charge
  • flight computers can determine a weighted thrust distribution (e.g., across all the motors, an example of which is shown in FIGURE 17) and/or a weighted power distribution (e.g., for each winding of a dual wound motor) which achieves a desired power output, and communicate this power to the inverters, which draw the appropriate proportion of power from the respective batteries (e.g., different current through each set of windings of a dual-wound motor, an example is shown in FIGURE 24C).
  • a weighted thrust distribution e.g., across all the motors, an example of which is shown in FIGURE 17
  • a weighted power distribution e.g., for each winding of a dual wound motor
  • the flight actuators can additionally or alternatively preferentially draw power from the paired battery with a higher state of charge and/ or the flight actuators connected to the higher power battery can be considered the “default” actuators, with the remaining actuators reserved for infrequent and/or emergency use, such as in the case of mechanical failure of a default flight actuator or when approaching the bounds of a flight control envelope (e.g., aggressive banking approaching a minimum turning radius, etc.).
  • Load balancing between “unpaired” motors can be achieved by commanding a thrust distribution which de-weights the motors (and/or motor windings therein) associated with batteries having a lower net state of charge (SOC), thereby resulting in different depletion rates among the batteries.
  • SOC state of charge
  • Flight actuators can be subdivided into sets/pairs if they are redundant (e.g., can interchangeably/ cooperatively affect the same generic aircraft control authority) and are separately powered by paired batteries. Flight actuator pairs are preferably located on the same side of the sagittal midplane of the aircraft and/ or adjacent to one another (e.g., along a rear portion of the main wing, along a rear portion of the rear stabilizer, etc.), but can be otherwise suitably arranged/distributed. However, flight actuators can alternatively be construed to define any other suitable redundant and/ or non-redundant sets/groups.
  • flight actuators can be otherwise suitably powered and/or operated in conjunction with various load balancing schemes. 5. Examples
  • Redundant flight actuators (and/ or control surfaces driven thereby) and/ or landing gear can be associated with (e.g., powered by) paired batteries and/or unpaired batteries.
  • the aircraft can include two wing flaps on each side of the sagittal midplane of the aircraft (e.g., 4 wing flaps: 2 left and 2 right).
  • the two left wing flaps (mounted to the main wing) are preferably associated with (e.g., driven by actuators powered by) the first and second batteries of a first battery pair, respectively.
  • the two right wing flaps are preferably associated with (e.g., powered by) the first and second batteries of a second battery pair (e.g., where the intersection of the first and second battery pairs is null), respectively.
  • the first example can likewise hold for ailerons in place of flaps, and/ or any other suitable control surfaces on the main wing or rear stabilizer.
  • the aircraft can include a three ruddervators (e.g., mounted to the rear stabilizer 204) on each side of the sagittal midplane of the aircraft (e.g., 6 ruddervators: 3 left and 3 right).
  • the three left ruddervators are preferably associated with the first battery of a first battery pair, the second battery of a first battery pair, and the first battery of a second battery pair (e.g., unpaired with either the first or second batteries of the first battery pair), respectively.
  • the second example can likewise hold for elevators, rudders, ailerons, and/or any other suitable control surfaces in place of ruddervators (e.g., on either the main wing or rear stabilizer).
  • landing gear actuators can be dual would and powered by paired batteries.
  • landing gear actuators can be dual wound and redundantly powered by unpaired batteries.
  • each of a plurality of dual wound landing gear actuators is powered by a different combination of batteries (an example is shown in FIGURE 22).
  • the landing gear on the aircraft is fixed (e.g., in a deployed configuration).
  • any flight actuators (and/or control surfaces driven thereby) and/ or landing gear on the aircraft can be powered as in any combination and/or permutation of a set of the aforementioned examples.
  • flight actuators and/ or landing gear can include any other suitable redundancies.
  • an electric aircraft comprising: a battery pair comprising a first and second battery; a first propulsion assembly comprising: a dual- wound electric motor comprising a first and second set of windings connected to the first and second batteries, respectively; and a propeller coupled to the dual-wound electric motor; a pair of control surfaces arranged on a first side of the mid-sagittal plane of the aircraft, the pair comprising a first and a second control surface; and a first and a second flight actuator electrically connected to the first and second batteries, respectively, wherein the first and second flight actuators are mechanically connected to the first and second control surfaces, respectively.
  • first flight actuator is not redundantly powered by the second battery.
  • the aircraft is configured to equilibrate a state of charge (SoC) of the first and second batteries based on a weighted power distribution of the first and second sets of windings.
  • SoC state of charge
  • the aircraft further comprising a second and third propulsion assembly, each comprising a respective dual-wound electric motor and a respective propeller, the first and second batteries connected to a respective set of windings of the dual-wound electric motor of each of the second and third propulsion assemblies.
  • the electric aircraft further comprising: a first motor inverter electrically coupled to the first set of windings and the first control surface; and a second motor inverter electrically coupled to the second set of windings, wherein the second battery is selectively connected to the first flight actuator in a propulsive mode of the second motor inverter and a regenerative mode of the first motor inverter.
  • each battery of the battery pair is sized to be capable of independently powering the first propulsion assembly above a power threshold of the motor.
  • the first battery is arranged on the first side of the midsagittal plane and the second battery is arranged on a second side of the midsagittal plane, opposite the first side.
  • the first battery is arranged within an inboard portion of a wing of the aircraft, wherein the second battery is arranged within an outboard portion of the wing relative to the inboard portion.
  • the electric aircraft further comprising: a second battery pair comprising a third and fourth battery; a second propulsion assembly comprising: a second dual-wound electric motor comprising a third and fourth set of windings connected to the third and fourth batteries, respectively; and a propeller coupled to the dual-wound electric motor; a second pair of control surfaces comprising a third and a fourth control surface symmetrically opposing the first and second control surfaces across the midsagittal plane, respectively; and a third and a fourth flight actuator electrically connected to the third and fourth batteries and mechanically connected to the third and fourth control surfaces, respectively.
  • the third control surface is in a deployed position
  • the first actuator is configured to actuate the first control surface to mirror the deployed position of the third control surface
  • the electric aircraft comprising a plurality of propulsion assemblies comprising the first and second propulsion assemblies, wherein the electric aircraft is further configured to accommodate a failure state of the first propulsion assembly by: reducing a first power provision to the second propulsion assembly; and increasing a respective power provision to each of a remainder of the plurality of propulsion assemblies.
  • the electric aircraft further comprising: a fifth control surface adjacent to the first and second control surfaces and arranged on a first side of the mid-sagittal plane; and a fifth flight actuator electrically connected to the third battery and mechanically connected to the fifth control surface.
  • the first, second, and third control surfaces are ruddervators.
  • the third battery is larger than the fourth battery and the third battery symmetrically opposes the first battery across the midsagittal plane.
  • the first and second control surfaces are duplicative.
  • a method comprising: determining a flight command for an electric aircraft, the electric aircraft comprising: a battery pair comprising a first and a second battery; and a propulsion assembly comprising a propeller coupled to a dual-wound motor, the dual wound motor having a first and a second set of windings connected to the first and second batteries of the battery pair, respectively; determining a battery state for each battery of the battery pair; determining a weighted power distribution relative to the battery states of the first and second batteries, the weighted power distribution comprising a first weight associated with the first battery and a second weight associated with the second battery; based on the flight command and the first weight, supplying power from the first battery to the first set of windings of a propulsion assembly of the plurality; while supplying power to the first set of windings, regeneratively harvesting power from the propeller at the second set of windings based on the second weight; and supplying the regeneratively harvested power to a
  • the first and second batteries are arranged on opposing sides of a midsagittal plane of the electric aircraft and are asymmetric about the midsagittal plane.
  • the electric aircraft further comprises: a second flight actuator, wherein the second and first flight actuators are electrically connected to the first and second batteries, respectively; and a duplicative pair of control surfaces arranged on a first side of the mid-sagittal plane of the aircraft, the pair comprising a first and a second control surface, wherein the first and second flight actuators are mechanically connected to the first and second control surfaces, respectively.
  • the method further comprising cooperatively actuating the duplicative pair of actuators based on a flight command.
  • a method comprising: determining a flight command for an electric aircraft, the electric aircraft comprising: a battery pair comprising a first and a second battery; and a plurality of propulsion assemblies, each comprising a propeller coupled to a dual-wound motor, the dual wound motor having a first and a second set of windings connected to the first and second batteries of the battery pair, respectively; a pair of control surfaces arranged on a first side of the mid-sagittal plane of the aircraft, the pair comprising a first and a second control surface; and a first and a second flight actuator electrically connected to the first and second batteries, respectively, the first and second flight actuators mechanically connected to the first and second control surfaces, respectively; determining a battery state for each battery of the battery pair; based on the battery state, load balancing the battery pair, comprising: determining a weighted power distribution relative to the battery states of the first and second batteries, the weighted power distribution comprising a first weight associated
  • supplying power to the propulsion assembly comprises: based on the first weight, supplying power from the first battery to the first set of windings of a propulsion assembly of the plurality; while supplying power to the first set of windings, regeneratively harvesting power from the propeller at the second set of windings based on the second weight; and supplying the regeneratively harvested power to the second battery.
  • FIG. 1 Alternative embodiments implement the above methods and/ or processing modules in non-transitory computer-readable media, storing computer-readable instructions.
  • the instructions can be executed by computer-executable components integrated with the computer-readable medium and/or processing system.
  • the computer-readable medium may include any suitable computer readable media such as RAMs, ROMs, flash memory, EEPROMs, optical devices (CD or DVD), hard drives, floppy drives, non-transitory computer readable media, or any suitable device.
  • the computer- executable component can include a computing system and/or processing system (e.g., including one or more collocated or distributed, remote or local processors) connected to the non-transitory computer-readable medium, such as CPUs, GPUs, TPUS, microprocessors, or ASICs, but the instructions can alternatively or additionally be executed by any suitable dedicated hardware device.
  • a computing system and/or processing system e.g., including one or more collocated or distributed, remote or local processors
  • the instructions can alternatively or additionally be executed by any suitable dedicated hardware device.
  • Embodiments of the system and/ or method can include every combination and permutation of the various system components and the various method processes, wherein one or more instances of the method and/or processes described herein can be performed asynchronously (e.g., sequentially), concurrently (e.g., in parallel), or in any other suitable order by and/ or using one or more instances of the systems, elements, and/or entities described herein.

Landscapes

  • Engineering & Computer Science (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Sustainable Development (AREA)
  • Sustainable Energy (AREA)
  • Power Engineering (AREA)
  • Transportation (AREA)
  • Mechanical Engineering (AREA)
  • Aviation & Aerospace Engineering (AREA)
  • Electric Propulsion And Braking For Vehicles (AREA)

Abstract

L'invention concerne un système d'alimentation pouvant comprendre : une pluralité de batteries, une pluralité d'unités de propulsion électrique, des ordinateurs de vol et des connexions électriques. Les ensembles de propulsion peuvent comprendre un moteur, une hélice et au moins un onduleur. Le système d'alimentation selon l'invention peut éventuellement comprendre une pluralité d'actionneurs de vol. Cependant, le système d'alimentation peut comprendre tout autre ensemble de composants approprié. Le système d'alimentation fonctionne pour fournir une propulsion d'aéronef et/ou une autorité de contrôle d'aéronef pendant le vol.
PCT/US2021/042205 2020-11-25 2021-07-19 Architecture de système d'alimentation électrique et aéronef à décollage et atterrissage verticaux, tolérant aux pannes, la mettant en oeuvre WO2022115132A1 (fr)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
US202063118504P 2020-11-25 2020-11-25
US63/118,504 2020-11-25
US202163135387P 2021-01-08 2021-01-08
US63/135,387 2021-01-08

Publications (1)

Publication Number Publication Date
WO2022115132A1 true WO2022115132A1 (fr) 2022-06-02

Family

ID=81756017

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/US2021/042205 WO2022115132A1 (fr) 2020-11-25 2021-07-19 Architecture de système d'alimentation électrique et aéronef à décollage et atterrissage verticaux, tolérant aux pannes, la mettant en oeuvre

Country Status (1)

Country Link
WO (1) WO2022115132A1 (fr)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US11827347B2 (en) 2018-05-31 2023-11-28 Joby Aero, Inc. Electric power system architecture and fault tolerant VTOL aircraft using same

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1634167A (en) * 1926-05-06 1927-06-28 George A Wilson Electrical generating apparatus for airplanes
US7193391B2 (en) * 2004-08-12 2007-03-20 Enerdel, Inc. Method for cell balancing for lithium battery systems
US20170057650A1 (en) * 2014-06-20 2017-03-02 Dale Martin Walter-Robinson Energy Cell Regenerative System For Electrically Powered Aircraft
US20180141428A1 (en) * 2015-06-08 2018-05-24 Nissan Motor Co., Ltd. Power generation control system for hybrid vehicle
US20200010187A1 (en) * 2018-05-31 2020-01-09 Joby Aero, Inc. Electric power system architecture and fault tolerant vtol aircraft using same

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US1634167A (en) * 1926-05-06 1927-06-28 George A Wilson Electrical generating apparatus for airplanes
US7193391B2 (en) * 2004-08-12 2007-03-20 Enerdel, Inc. Method for cell balancing for lithium battery systems
US20170057650A1 (en) * 2014-06-20 2017-03-02 Dale Martin Walter-Robinson Energy Cell Regenerative System For Electrically Powered Aircraft
US20180141428A1 (en) * 2015-06-08 2018-05-24 Nissan Motor Co., Ltd. Power generation control system for hybrid vehicle
US20200010187A1 (en) * 2018-05-31 2020-01-09 Joby Aero, Inc. Electric power system architecture and fault tolerant vtol aircraft using same

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US11827347B2 (en) 2018-05-31 2023-11-28 Joby Aero, Inc. Electric power system architecture and fault tolerant VTOL aircraft using same

Similar Documents

Publication Publication Date Title
US20240025543A1 (en) Electric power system architecture and fault tolerant vtol aircraft using same
US11198515B2 (en) Method and system for distributed electrical loads connected to shared power sources
US11724801B2 (en) VTOL aircraft having fixed-wing and rotorcraft configurations
US11661180B2 (en) Systems and methods for power distribution in electric aircraft
US11945594B2 (en) Systems and methods for power distribution in electric aircraft
CN112262075A (zh) 电动倾转旋翼飞行器
US11465532B2 (en) Systems and methods for power distribution in electric aircraft
WO2022115132A1 (fr) Architecture de système d'alimentation électrique et aéronef à décollage et atterrissage verticaux, tolérant aux pannes, la mettant en oeuvre
JP2022157287A (ja) 電力供給システム
US11990647B2 (en) Modular battery systems for aircraft
US12006048B2 (en) Electric power system architecture and fault tolerant VTOL aircraft using same
US20210339881A1 (en) Electric power system architecture and fault tolerant vtol aircraft using same
US12006035B1 (en) Systems and methods for flight control of EVTOL aircraft
WO2024107760A1 (fr) Architecture de batterie haute tension

Legal Events

Date Code Title Description
121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 21898864

Country of ref document: EP

Kind code of ref document: A1

NENP Non-entry into the national phase

Ref country code: DE

122 Ep: pct application non-entry in european phase

Ref document number: 21898864

Country of ref document: EP

Kind code of ref document: A1