Patent Application
20240337213
There are varying types of aircraft that are propelled using different types of propulsion mechanisms, such as propellers, turbine or jet engines, rockets, or ramjets. Different types of propulsion mechanisms may be powered in different ways. For example, some propulsion mechanisms like a propeller may be powered by an internal combustion engine or an electric motor. Aircraft that use combustion engines may additionally include a turbocharger to increase total maximum output power of the engine.
In an embodiment, a turbocharger includes a compressor configured to compress intake air for an engine. The turbocharger further includes an electric motor configured to power the compressor. The turbocharger further includes a turbine configured to receive exhaust air from the engine. The turbocharger further includes an electric generator configured to be driven by the turbine to generate electric power.
Described herein are various embodiments for a split turbocharger having independent electric turbine and electric compressor components. The electric turbine and the electric compressor may both be connected to an electric bus, such as a direct current (DC) bus of an aircraft used to power propulsion mechanisms of the aircraft.
Many types of vehicles, such as cars, use turbochargers to enhance performance of an engine. However, turbochargers for use in aircraft may face certain challenges. For example, a compressor of a turbocharger that may deliver proper manifold air pressure (MAP) at a high altitude may perform poorly at sea level (and vice versa). As another example, variable inlet compressors may be inefficient and wastegates of turbines of turbochargers may dump valuable exhaust heat and pressure overboard in an attempt to regulate performance of a typical turbocharger.
Accordingly, described herein are turbochargers where the turbocharger is split into two separate parts (e.g., a compressor and a turbine), and each of these separate parts (e.g., a compressor and a turbine) is connected to independent and highly efficient high-voltage electric motors/generators. With this arrangement, the turbine components may be designed to extract maximum torque and power from an exhaust stream of an engine at all times, as there may be no reason to limit output power by the use of a wastegate. At the same time, the compressor may be designed for optimum performance at high altitude (e.g., high pressure ratio and nominal shaft speed) and near-optimum performance on the ground (e.g., same component at a lower shaft speed). As just one example, for a given hybrid-electric engine/generator that produces 185 kilowatts (kW) of power, a split turbocharger as described herein may add an additional net of 23 kW of power. The turbocharger with electric machines may also weigh relatively little, such as approximately 50 pounds, thereby offering an advantageous power to weight ratio. By splitting the turbocharger, the compressor and turbine sides of the turbocharger may operate at different rotations per minute (RPMs) than one another, as they operate independently from one another as opposed to turbochargers where the compressor and turbine share a common shaft for the turbine to power the compressor directly.
Also described herein is a high voltage electrical bus (e.g., a DC bus) to efficiently receive power from the turbine and deliver power to the compressor. This bus may also contain storage such as from a battery pack with many benefits to the system, including for example attenuation of any power fluctuations on the DC bus.
That turbine blade 1810 of the turbine 1805 is connected to a shaft 1815, and torque and power are fed through a central bearing housing 1820 and turn a compressor blade 1825 (e.g., fan, wheel, etc.) of a compressor 1830 on the other side of the turbocharger, which is connected to the same shaft 1815 as the turbine blade 1810. This compressor 1830 uses the torque and power fed through the shaft 1815 to compress the air entering the engine. By pushing more air into the engine, power output and overall thermal efficiency of the engine are increased.
At point 3, air exhausted from the engine 1905 to a turbine 1920 of the turbocharger 1910 has what may be referred to as an exhaust gas temperature (EGT) or turbine inlet temperature (TIT), and an exhaust backpressure. At point 4, exhaust air from the turbine 1920 may have what is referred to as a tailpipe temperature and pressure.
Important performance parameters of a turbocharger may include a pressure ratio of the compressor (ratio of MAP [at point 2]/ambient pressure [at point 1]) and turbo shaft 1925 speed in rotations per minute (RPM). Turbochargers for street cars may be designed to operate over a fairly limited range of pressure altitude (e.g., from sea level up to approximately 10,000 feet above sea level). Over this range, a turbocharger may deliver enhanced engine performance by raising MAP above ambient pressure, and turbo shaft 1925 speed may vary with altitude.
In aviation, it is common for flight to take place at various altitudes, including, e.g., 15,000 feet, 20,000 feet, 25,000 feet, 30,000 feet, and/or up to 35,000 feet or more. At these high altitudes, the atmospheric pressure is much less than at or near sea level, and therefore the air is less dense. A typical prior turbocharger may be a fixed unit—it may be comprised of a single aluminum or iron housing, a single blade or wheel in each side (e.g., each of the turbine and compressor sides), and the only variable may be the turbo shaft speed which may affect both sides of the turbocharger equally. At higher altitudes there is less ambient air pressure. That means the compressor pressure ratio may need to be very high to deliver a desired MAP. That same compressor at lower altitude may therefore be poorly matched to conditions at those lower altitudes. Either it may deliver MAP too high for safe operation of the engine, or the turbo may need to spin slowly to limit MAP (and thus may have a negative effect on the turbine efficiency).
There are many solutions which seek to address this problem for various engines under various conditions. Some engines employ two turbochargers, one before the other—in a twin-sequential arrangement. Some engines use inlet guide vanes to control the air entering the compressor with the intent of maintaining efficient compressor performance over a broader range of ambient conditions. However, none of these solutions offer the advantages of the embodiments described herein.
On the turbine side, an important parameter is backpressure, e.g., at point 3 in
The ideal turbocharger may have a compressor pressure ratio and rotations per minute (RPM) matched perfectly to the needs of an engine under all ambient conditions. It may seek to deliver the target MAP (e.g., at point 2 of
This ideal turbocharger may also feature a turbine that is able to extract all of the available power from the exhaust stream under all conditions. Such a turbocharger may not use a wastegate since it may accept the maximum torque and power with no consideration of limitations from the compressor side. However, such an ideal turbocharger may not be possible when the two sides are connected by a common shaft. Instead, a split turbocharger as described herein may advantageously be used to achieve a more ideal or more efficient turbocharger.
Second, a high-voltage (HV) or other type of electrical bus may advantageously be used, for example, in an environment characterized by hybrid-electric power and distributed electric propulsion. Such a high-voltage bus in this environment may also be connected to a battery pack which may help to set and maintain the system voltage and accept or give power as required by varying conditions. The HV bus may be, for example direct current (DC) or alternating current (AC).
The turbine assembly 2125 may be a similarly optimized housing and wheel driving a high-voltage and highly efficient electric generator 2115 via a shaft 2140. This generator 2115 may be designed to operate across the expected RPM range of that turbine 2125 with suitable torque and power characteristics to absorb all available thermal energy from the exhaust stream at all altitudes and all engine running conditions. These two devices may be attached to the same HV bus 2105, and the turbine may advantageously deliver power equal to or greater than that required by the compressor, resulting in a net increase in available power and energy on the HV bus 2105. There may be an inverter or other AC/DC conversion device at the electric generator 2115 or otherwise electrically between the electric generator 2115 and the HV bus 2105 so that AC power, for example, output from the electric generator 2115 may be converted to DC power for the HV bus 2105. A controller 2120 may optionally control various elements of the turbocharger 2100, and/or may receive measurements of various aspects of the turbocharger to monitor functioning of the turbocharger 2100.
The controller 2120 may further be used to operate the turbocharger in different ways. For example, the controller 2120 may use the separate sides of the turbocharger alone (e.g., shut off one side) and/or may use the different sides to different degrees as opposed to their full capacity. As an example, the cold (compressor) side of the turbocharger may be used similar to an electric supercharger. The controller 2120 may also use the two sides of the turbocharger based on different circumstances, such as a flight stage, altitude, or any other input that may be used to adjust how the turbocharger functions. Similarly, in various embodiments, an aircraft may be built with only one side of the turbocharger as desired.
The embodiments herein may advantageously be valuable in an environment characterized by large altitude variation (e.g., 10,000 feet or more) and with a high voltage bus present (e.g., the DC bus 2105).
Various arrangements and strategies for using the turbocharger 2100 may be implemented in various embodiments. For example, using battery boost from a DC bus to accelerate the compressor may be advantageous for electrical dynamic reasons (e.g., transient power needs). As another example, certain operational offsets (between point 2 on the compressor side and point 3 on the turbine side) may offer benefits to engine performance, efficiency, and/or durability. In other words, various advantages to using the split turbochargers described herein may be realized based on control of the components of the turbocharger and/or optimization of the components in designing the turbocharger for a particular aircraft or other implementation.
Also described herein are hybrid electric architectures with engines in which the turbochargers disclosed herein may be used (see section titled Hybrid Electric Architecture below). In addition, various components and functioning of an aircraft with a DC bus is described herein, and the various turbochargers described herein may be used in such aircraft (see DC Bus Components section below).
In various embodiments, the split turbocharger described herein may be used in different ways at different stages of flight of an aircraft that uses a split turbocharger. For example, at takeoff, landing, and/or at generally low altitude, a compressor of the turbocharger may be run based on varying an RPM of the compressor to optimize MAP to a target threshold or value. The RPM may be relatively low due to denser air being present at lower altitudes. For example, an RPM may be varied across a range of RPMs, including, for example a range of 85,000 to 150,000 RPM.
In another example, at cruising altitudes and/or flight modes, a compressor MAP target value, threshold, or range may be set be based on a particular goal for an aircraft powerplant described herein, such as a goal to optimize engine shaft power output, fuel economy, or system HV power management. A desired MAP may be a pressure of anywhere from 50 to 70 inches of water (inWC), such as about 50 inWC, 52.5 inWC, 55 inWC, 57.5 inWC, 60 inWC, 62.5 inWC, 65 inWC, 67.5 inWC, 70 inWC, etc. The MAP may be maintained to meet those objectives or may also be reduced to achieve maximum cruise efficiency for the aircraft. A desired MAP may be set based on, and may be dependent on, various factors such as the engine, parameters related to the engine design and tuning including a fuel type being used. In various embodiments, a turbine of a split turbocharger may also be dialed not only to maximum power extraction but may also be tuned to optimize backpressure for maximum engine efficiency for cruising. Any tradeoff in power output made for optimizing backpressure may be considered in the design or operation of an aircraft based on the following: whether it is desirable to raise turbine inlet pressure (e.g., at point 3) to extract more HV power or to reduce turbine inlet pressure (e.g., at point 3) to improve engine thermal efficiency.
At higher altitude flight beyond, for example, a normal cruising altitude, a compressor RPM and power may be chosen to maximize MAP (e.g., allow MAP to be as high as possible given the inherent constraints of a turbocharger and surrounding air pressure/density) even if the net HV power flow is negative. Higher altitude may be anywhere from 25,000 feet to 35,000 feet, such as about 25,000 feet, about 26,000 feet, about 27,000 feet, about 28,000 feet, about 29,000 feet, about 30,000 feet, about 31,000 feet, about 32,000 feet, about 33,000 feet, about 34,000 feet, about 35,000 feet, etc. In other words, more HV power may be used to drive the compressor motor than the turbine power that is extracted from the turbine. In this way, an aircraft powerplant may be controlled to have a net consumption of stored electrical power (e.g., power consumed from a battery via a HV bus) to generate higher engine power output based on various factors (e.g., flight mission, time, and/or other flight/aircraft requirements/constraints).
As such, over a total flight profile from warmup to takeoff, cruise, descent, and landing (and optionally including hover in the case of VTOL), it is contemplated that the net power available on a HV bus or a net change in state of charge (SOC) of any onboard battery pack may be improved (increased) by the careful application of control of the various components of a split turbocharger as described by the various embodiments herein.
Aircraft typically have custom designed propulsion mechanisms and methods for powering those propulsion mechanisms. In this way, the propulsion mechanisms and power supplied to those propulsion mechanisms can be optimized to provide the amount of propulsion needed for a particular type and size of aircraft, while minimizing weight of the components in the aircraft. In other words, the propulsion mechanisms and power for those propulsion mechanisms are often optimized for a particular type and size of aircrafts such that components of one aircraft could not be easily used in a different types of aircraft drive architectures, such as direct drive aircraft, parallel drive aircraft, and serial drive aircraft.
Described herein are various embodiments for a flexible architecture for an aerospace hybrid system and optimized components thereof. A hybrid system may be or may include a system where fuel is burned in a piston, rotary, turbine, or other engine, and an output of the piston engine may be operatively connected to an electric generator for outputting electric power. The embodiments described herein may include flexible systems that can provide power for many different types of aircraft and propulsion mechanisms. Such systems may advantageously reduce the complexity of designing different types of aircraft, may reduce the costs of manufacturing such systems as less customization allows for economies of scale in mass producing the systems, and ultimately may reduce the complexity of aircraft that use the systems described herein.
The flexible architectures described herein may further be used to provide power to propulsion mechanisms in different ways, either in a same aircraft or in different aircraft. For example, a flexible architecture for providing power to propulsion mechanisms may be able to operate in multiple different modes to provide power to different types of propulsion mechanisms. A first aircraft may utilize one, some, or all of the multiple different modes in which the flexible architecture may operate. A second aircraft may utilize one, some, or all of the multiple different modes, and the modes utilized by the second aircraft may be different than those utilized by the first aircraft.
Therefore, different aircraft may take advantage of different modes of providing power to propulsion mechanisms provided by the flexible architectures described herein. While use of the flexible architectures may be customized in this way, the physical hardware of the flexible architectures may be adapted to use by different aircraft with minimal or no changes to the physical components of the flexible architectures described herein. Instead, the use of different modes in different aircraft may be accomplished largely based on how the components of the flexible architectures are controlled using a processor or controller. As such, computer readable instructions may therefore also be stored on a memory operably coupled to a processor or controller, such that when the instructions are executed by the processor or controller, a computing device that includes the processor or controller may control the various components of the flexible architectures described herein to utilize any possible mode of use desired for a particular implementation, aircraft, flight phase, etc.
Power generation and propulsion systems for aircraft may also utilize various cooling systems to ensure that the various components of an aircraft remain at safe temperatures for operation, as well as maintaining components within temperature ranges where they may operate more efficiently. Further described herein are advantageous cooling systems that leverage various aspects of the hybrid architecture described herein to efficiently cool components of a flexible architecture for providing power to propulsion mechanisms of an aircraft.
Aircraft that have hardware for providing different modes of power to its propulsion mechanisms, may have a variety of components for which it may be desirable to provide cooling. Thus, a single cooling system that efficiently moves air to the different components that enable different modes of power may cut down on weight of the aircraft, as well as power consumption of the cooling systems.
In various embodiments, the split turbochargers described herein may be used with the example flexible architectures described herein. For example, a flexible architecture with an engine as described herein (e.g., engine 105 of
The flexible architecture 101 of
As described above, the engine 105 may be a piston combustion engine. A piston combustion engine may advantageously spin an output rotor or shaft at rotations per minute (RPMs) that may be more desirable for direct output to power a generator and/or a propulsion mechanisms (e.g., a propeller) than other engines. For example, a piston combustion engine may have an output on the order of thousands of RPMs. For example, a piston combustion engine may have an output anywhere from 2200 to 2500 RPM, which may be a desirable RPM for a propeller. In particular, a propeller may be designed to have a size that yields a desired tip speed of the propeller based on the RPM output of the piston combustion engine (e.g., of 2200 to 2500 RPM). Other types of engines, such as a turbine engine, may output rotational power on the order of tens of thousands of RPMs, much higher than a piston combustion engine. Another embodiment may drive the motor/generator at the higher RPM of a turbine engine to benefit the efficiency, power output, or other important factors. In some embodiments, a gear box could be added between the output of a high RPM engine and the other components of
The engine 105 may output rotational power to the clutch 115, which may be controlled to engage or disengage the power shaft 111. In other words, the power shaft 111 may be engaged with the rotational output of the engine 105 by the clutch 115, so that rotational force may be transferred between the engine 105 output and the power shaft 111. When the clutch 115 disengages the output of the engine 105 and the power shaft 111, the power shaft 111 may rotate independently of the output of the engine 105. The clutch 115 may be physically located between the engine 105 and the generator/motor 121, and may even contact the engine 105 and the generator/motor 121 on opposing sides in order to reduce the overall footprint of the flexible architecture.
The generator/motor 121 may also be engaged or disengaged with the power shaft 111. In other words, the generator/motor 121 may be controlled to switch off such that rotation of the power shaft 111 does not cause the generator/motor 121 to generate electrical power. Similarly, the generator/motor 121 may also be controlled to switch on such that the rotation of the power shaft causes the generator/motor 121 to generate electrical power. The generator/motor 121 is referred to as a generator/motor because it may function as either a generator or a motor. In various embodiments, the generator/motor 121 may be referred to as an electric machine, where an electric machine may be an electric generator, an electric motor, or both.
The flexible architecture further includes an electrical power input and output (I/O) 125 connected to the generator/motor 121. As described further herein, the generator/motor 121 may generate electrical power based on rotation of the power shaft 111 that is output via the electrical power I/O 125 or may receive electrical power via the electrical power I/O 125 that may be used to drive the power shaft 111.
The generator/motor 121 may also act as a driver for the power shaft 111. Upon receiving electrical power via the electrical power I/O 125 from batteries or some other form of electrical energy storage elsewhere in the system, the generator/motor 121 may impart a rotational force on the power shaft 111 to drive the power shaft 111. This may occur as long as the generator/motor 121 is controlled to be switched on to engage with the power shaft 111. If the generator/motor 121 is controlled to be switched off such that it does not engage with the power shaft 111, the power shaft 111 may not be rotated by the generator/motor 121.
Electrical power output from the electrical power I/O 125 may be used to drive an electric motor for an electric propulsion mechanism (e.g., a propeller). Electrical power output from the electrical power I/O 125 may also be used to power and/or charge other devices on an aircraft or aerospace vehicle. For example, electrical power output from the electrical power I/O 125 may be used to charge one or more batteries. The electrical power output from the electrical power I/O 125 may also be used to power other devices or accessories on an aircraft or aerospace vehicle. Because the electrical power I/O 125 also has an input, the power shaft 111 may be driven by any electrical power received via the electrical power I/O 125, such as power from one or more batteries. The power generated by the generator/motor 121 may be an alternating current (AC) power. That AC power may be converted by power electronics (e.g., a rectifier or inverter) into direct current (DC) power and output to a DC bus. That DC bus may be connected to batteries and/or an electric propulsion mechanism. In this way, the electric propulsion mechanism may be supplied with power via a DC bus. In various embodiments, a motor of the electric propulsion mechanism may use AC power, and the DC power from the DC bus may therefore be converted from DC power to AC power before it is used by the electric propulsion mechanism (e.g., by an inverter).
Any rotation of the power shaft 111 itself, whether driven by the engine 105 or the generator/motor 121, may also be used to drive one or more propulsion mechanisms. For example, rotation of the power shaft 111 may be used to direct drive a propeller or may be used to power an electric motor that drives a propulsion mechanism. The rotation of the power shaft 111 may also drive a gearbox operably connected to another component, such as one or more propellers, one or more rotors, or other rotating devices for various uses on an aircraft.
An accessory pad 131 may also be coupled to the engine 105, and may include a lower voltage direct current (DC) generator for electrical power that is separate from the generator/motor 121 and the electrical power I/O 125, which may be configured for high voltage and high power I/O. In some embodiments, the generator/motor 121 may also have two different windings and the electrical power I/O 125 may have two different outputs (e.g., high voltage and low voltage). Accessory power may be associated with one of the electrical power I/O 125 outputs in addition to or instead of the accessory pad 131 output. The accessory pad 131 may be used to provide power to devices or accessories on an aircraft or aerospace vehicle that does not require high voltage or current outputs that may be output by the generator/motor 121 at the electrical power I/O 125. A high voltage (HV) of an aircraft may be, for example, 400 volts (V) or 800 V, but may also be anywhere between 50 V to 1200 V. A low voltage (LV) of an aircraft may be 12 V, 14 V, 28 V, or any other voltage below 50 V.
The clutch 175 may be configured to engage the power shaft 180 to translate rotational motion from the crankshaft 160 and the output flange 165 to the power shaft 180. The clutch 175 may be further configured to disengage the power shaft 180 such that the power shaft 180 may rotate independently with respect the crankshaft 160 and the output flange 165. In addition,
Advantageously, the generator/motor 121 of
The memory 210 may be a computer readable media configured for instructions to be stored thereon. Such instructions may be computer executable code that is executed by the controller 205 to implement the various methods and systems described herein, including the various modes of using the flexible architectures herein and combinations of those modes. The computer code may be written such that the various methods of implementing different modes of the flexible architectures herein are automatically implemented based on various inputs that indicate, for example, a particular flight phase (e.g., landing, takeoff, cruising, etc.). In various embodiments the computer code may be written to implement the various modes herein based on input from a user or pilot of the aircraft or aerospace vehicle, or may be implemented based on a combination of user input and automatic implementation based on non-human inputs (e.g., from sensors on or off the aircraft, based on planned flight plans, etc.) The controller 205 may be powered by a power source on the aircraft or aerospace vehicle, such as the accessory pad 131, one or more batteries, an output of the electrical power I/O 125, a power bus of the aircraft powered by any power source, and/or any other power source available.
The controller 205 may also be in communication with each of the engine 230, the generator/motor 235, the clutch 240, the electrical power I/O 245, the accessory pad 250, and/or the sensor(s) 260. In this way, the components of flexible architectures may be controlled to implement various modes as described herein. In various embodiments, engine 230, the generator/motor 235, the clutch 240, the electrical power I/O 245, and the accessory pad 250 may be similar to or may be the similarly named components shown in and described above with respect to
The sensor(s) 260 may include various sensors for monitoring the different components of the flexible architecture 201. Such sensors may include temperature sensors, tachometers, fluid pressure sensors, voltage sensors, current sensors, state sensors to determine, for example, a current state of the clutch 250, or any other type of sensor. For example, voltage and/or current sensors may be used to inform function and settings of a motor/generator, a state chosen for the clutch, or for adjusting any other component of a system. A state sensor could also indicate a specific mode the flexible architecture is being used in, and the system may receive inputs (e.g., from a pilot, from an automated flight controller), to change the system to a different state or mode for a certain phase of flight that may be upcoming. Other sensors may include a pitot tube for measuring aircraft airspeed, an altimeter for measuring aircraft altitude, and/or a global positioning system (GPS) or similar geographic location sensor for determining a location relative to the ground and/or known/mapped structures.
The components of
In various embodiments, the main aircraft controller 220 may also transmit control signals related to future desired power outputs, future flight phase or flight plan information, etc. In this way, the controller 205 may receive and use information about the expected power demands of the aircraft to determine how to control the aspects of the flexible architecture 201 at both a present moment and in the future. For example, flight plan information may be used to determine when battery power should be used, when batteries should be charged, etc. In another example, if a big demand for power is expected, the controller 205 may ensure that the engine 230 is running at a desired RPM to begin delivering a desired level of power.
In various embodiments, the controller 205 may also be in communication with one or more batteries to monitor their charge levels, control when the batteries are charged or discharged, control when the batteries are used to power the generator/motor 235, control when the batteries are used to directly power another aspect of the aircraft. However, in other embodiments, the main aircraft controller 220 may be in communication with batteries of the aircraft, and/or may relay information related to the batteries and control thereof to the controller 205. Similarly, if the batteries of the aircraft are controlled with the main aircraft controller 220 rather than the controller 205, the controller 205 may transmit control signals related to the batteries to the main aircraft controller so that the batteries may be controlled as needed or desired with respect to the functioning of the flexible architecture 201.
In various embodiments, the electrical power I/O 245 may include two different outputs (e.g., a high voltage (HV) output and low voltage (LV) output) that are associated with two different windings of the generator/motor 235. As such, two different voltages (e.g., HV and LV) may be output and controlled by the controller 205 and/or the main aircraft controller 220. The electrical power I/O 245 may additionally or alternatively have voltage conversion components (e.g., a DC to DC converter) such that two or more different voltages may be output. In such an embodiment, two different outputs may be achieved without the use of two separate windings. The two different outputs may, for example, be output to different power busses on the aircraft, such as a HV bus and a LV bus. The two outputs of the electrical power I/O 245 may also be separately controlled by the controller 205. As such, the outputs may be turned off (e.g., by letting the power shaft and rotor of the generator spin or freewheel with respect to the rest of the motor/generator by turning off field current of the motor/generator).
In some embodiments, the accessory pad may not be controlled by the controller 205 and/or the main aircraft controller 220. The accessory pad may simply always be on when the engine 230 is operating, or may be controlled separately (e.g., by a manual switch flipped by a user) to control when and how power is supplied to accessories on the aircraft.
In some embodiments, the controller 205 may be in communication with a wireless transceiver that may be on-board an aircraft or aerospace vehicle, so that the controller 205 may communicate with other computing devices not hard-wire connected to the system 200. In this way, instructions or inputs for implementing the various modes for the flexible architectures described herein may also be received from a remote device computing device wirelessly. In other embodiments, the system 200 may only communicate with components on-board the aircraft.
The controller 285 may be in communication with one or more of the propulsion mechanism(s) 255 on the aircraft to control them. The controller 285 may also be in communication with one or more sensor(s) 270 on an aircraft or aerospace vehicle, which may be sensors of the aircraft and sensors of the flexible architecture. In particular, the sensor(s) 260 may also be embedded in any of the components of
In either of
In various embodiments, any of the controllers 205, 220, or 280 may also be or may be in communication with the controller 2120, so that the components of a split turbocharger as shown in
Described below are five specific modes that may be implemented using various embodiments of the flexible architecture described herein (including, e.g., the flexible architectures shown in and described with respect to
In a first mode, which may be referred to herein as a hybrid generator mode, a clutch (e.g., the clutch 115 of
In a second mode, which may be referred to herein as a direct drive engine mode, a clutch (e.g., the clutch 115 of
In a third mode, which may be referred to herein as an augmented thrust mode, a clutch (e.g., the clutch 115 of
In a fourth mode, which may be referred to herein as a direct drive generator/motor mode, a clutch (e.g., the clutch 115 of
In a fifth mode, which may be referred to herein as a split engine power mode, a clutch (e.g., the clutch 115 of
As described herein, any of these five modes (or variations thereof) may be used with the single flexible architecture described herein. In addition, certain modes and or combinations of modes may be beneficial for certain aircraft or aerospace vehicle types, certain propulsion mechanism types, certain flight phases of an aircraft or aerospace vehicle, etc.
For example, in a hybrid electric vertical takeoff and landing (VTOL) aircraft with electric motor driven propellers, the flexible architecture herein may be used solely as a source of electrical power. As such, the flexible architecture may drive the aircraft in the first mode (e.g., the hybrid generator mode) during any portion of a phase of flight in which power must be provided to a power bus of the aircraft or one or more motors of the aircraft.
In another example, in an aircraft with a single, large main pusher propeller (e.g., at the rear of a fuselage of an aircraft) and array of electric motors/propellers (e.g., on a wing of an aircraft) the flexible architecture may be used in the fifth mode (e.g., split engine power mode) during takeoff to supply power mechanically to the main pusher propeller and electrically to the wing-mounted motors.
Alternatively, the flexible architecture described herein may be used to power configurations like those shown in
In another example, an aircraft may be a VTOL aircraft with a gyrocopter style main rotor that may be operated powered or unpowered, and may have forward propulsion motors and propellers mounted on wings. In an embodiment, the flexible architecture may be used entirely in the first mode (e.g., the hybrid generator mode) with electrical power supplied from the electrical power input/output (and the generator/motor) driving a motor coupled to the gyrocopter style main rotor and driving the wing-mounted motors using electrical power. In an embodiment, the aircraft may also be configured with a clutch between the power shaft and the gyrocopter style main rotor such that the flexible architecture may use the second mode (e.g., the direct drive engine mode) or the third mode (e.g., augmented thrust mode) to spin the gyrocopter style main rotor (e.g., to get the gyrocopter style rotor up to speed for takeoff). In such an example, the controller may then cause the flexible architecture to switch to the first mode (e.g., the hybrid generator mode) after the gyrocopter style rotor is up to speed (e.g., switch to the first mode for cruising flight). The fourth mode (e.g., the direct drive generator/motor mode) may again be used in the event of an engine failure to use electrical power to drive the power shaft (and therefore the gyrocopter style rotor) from a power source such as one or more batteries.
Accordingly, described herein are advantageous flexible architectures for aircraft through which a variety of modes for supplying power to propulsion mechanisms may be achieved. While particular aircraft and propulsion mechanism configurations may not utilize each mode described herein that a flexible architecture is capable of, the flexible architectures may still be implemented in different aircraft to achieve different modes. Similarly, while an example of a flexible architecture with five different modes for powering propulsion mechanisms is described in detail herein, other flexible architectures with fewer, more, or different modes for powering propulsion mechanisms are also contemplated herein.
For example, a flexible architecture may not have a clutch as described herein and may still be able to implement various modes described herein where it is desirably to have the engine output coupled to the motor/generator and/or an output power shaft of the system. For example, in the first mode, the engine may rotate a power shaft to cause the generator to generate electricity. In the second mode, the engine may direct drive a mechanical propulsion component, for example, but the engine need not be disengaged from the motor/generator or power shaft because the motor/generator can be turned off or allow the power shaft and rotor of the motor/generator to freewheel within the motor/generator. In the third mode, the engine and motor/generator are used to drive the power shaft, so it would not be desirable to disengage the engine and the motor/generator using a clutch. In the fifth mode, the engine may rotate a power shaft to cause the generator to generate electricity and to cause the power shaft to mechanically power a propulsion mechanism. As such, the power shaft need not be disengaged from the engine output in an aircraft that utilizes any of the first, second, third and/or fifth modes as described above. As such, for an implementation that uses any combination of the first, second, third, and/or fifth modes (and not the fourth mode), a clutch may not be used as the system may have the output of the engine constantly connected to the power shaft in the motor/generator. Such an embodiment may be valuable because clutches may be heavy and/or unreliable.
Referring back to
In other various embodiments, a flywheel may not be used. For example, further embodiments of dampening systems and apparatuses are described herein that can dampen torque on a power shaft (e.g., the power shaft 111) but do not include a flywheel. Further, in various embodiments, a flywheel and other damping systems or components may be used in combination to dampen or smooth out torque applied to a power shaft.
For example, the power shaft or rotor within the generator/motor itself may be rigidly coupled to a crankshaft of the generator/motor. In this way, the crankshaft and rotor together can dampen the torque pulses on the power shaft or rotor, and may reduce tangential acceleration due to the torque pulses from an engine. In such embodiments, a clutch may be omitted. As such, a dampening system would be internal to the generator/motor, and the footprint and weight of the dampening systems may be less than a flywheel or other dampening system that may be external to a generator/motor. In particular, the rigid coupling of the power shaft or rotor with the crankshaft may increase the inertia of the power shaft or rotor, such that the additional inertia helps prevent the power shaft from slowing down or otherwise rotating in a manner that would make it more susceptible to acceleration from torque pulses of an engine. In such embodiments, the power shaft or rotor and the crankshaft may function similarly to a flywheel.
In various embodiments, a generator/motor having a static inner portion and a spinning outer portion may be used. This may increase an inertia of the spinning portion and may allow the magnets in the generator/motor to spin and avoid being dislodged by torque spikes. In other words, the magnets may be already spinning in the outer portion and therefore may have a constant stabilizing radial force applied in addition to any tangential inertial force due to torque spike acceleration.
A torque damping system may also be configured as part of the power shaft or rotor that connects the output of the engine to the generator/motor. For example, a hub between the power shaft or rotor of the generator/motor may include a coupling that has torsional spring and/or damping properties. Torsional dampening couplings may include an elastomeric component or spring (e.g., made from steel or another metal) that reduces potentially harmful torque impulses from being passed from an engine output to a power shaft or rotor of a generator. Torsional dampening couplings may be similar to or may also be referred to as a resonance damping coupling. For example, such torsional dampening couplings may reduce an overall system weight and size as opposed to systems that use a flywheel or other large dampening system. One or more torsional dampening couplings may be installed at any one or more of, within an engine, between an engine and clutch, in the clutch, between the clutch and the generator, and/or within the generator to achieve dampening before the power shaft or rotor damages components of the generator itself.
Other ways of dampening torque on a power shaft or rotor of a generator may also be used. For example, a magnetic field on a generator may be controlled to pulse it such that it acts upon the power shaft or rotor of the generator to cancel some or all of the torque pulses imparted on the power shaft or rotor by an engine. Such pulses on the field of the generator may be controlled based on a measurement of the torque pulses applied by the engine, and may result in the generator components not being damaged by the diesel engine. For example, the third mode described above where both an engine and a generator/motor apply power to a power shaft, pulses to the power shaft from the generator may both apply power to the power shaft and protect the components of the generator from being damaged. In the other modes described herein, pulses to the power shaft using the generator may be applied whenever the power shaft is being driven in whole in part by the engine. Thus, in order to properly protect the components of the generator in such a method, the pulses applied by the magnetic field of the generator to the power shaft or rotor may be configured to correlate to the torque pulses of the engine to properly counteract those torque pulses.
Further described below are examples of how the flexible architectures described herein may be packaged and/or used in an actual aircraft. For example, certain aircraft may use electric motors to drive propulsion systems, and therefore must have sufficient on-board electrical energy or ways to generate such on-board electrical energy to drive those propulsion systems. In addition, regulations in a given jurisdiction may also require sufficient reserve energy to comply with operational regulations of an aircraft. The flexible architectures described herein may provide such electrical energy for propulsion systems and/or reserve energy such that they systems described herein may work with a variety of electric aircraft. For example, the embodiments herein provide for efficient conversion of jet fuel (or other liquid or gas fuel) to electricity, such that electric aircraft may be powered using widely available fuel sources.
In addition, the hybrid unit may include an integrated cooling system 905 that cools various aspects of the hybrid unit, heat exchangers related to the hybrid unit, or heat sinks such as finned attachments for any aspects of the hybrid unit. A power output 910 may be a power shaft (e.g., the power shaft 110 of
By virtue of the power output 910 and the electrical connectors 915, the hybrid unit of
The hybrid unit of
Accordingly, the hybrid units described herein may be used to power an electric or hybrid electric aircraft, and may offer better power than a battery pack alone would. For example, a hybrid unit as shown in
The flexible architectures described herein may also be scalable. For example, in a larger aircraft, two or more of the flexible architectures described herein may be used. The flexible architectures may also be used in different aircrafts designed for different functions and purposes. For example, the flexible architectures described herein may be useful in urban air mobility (UAM) systems, such as electric vertical takeoff and landing (eVTOL) aircraft, electric short takeoff and landing (eSTOL) aircraft, electric conventional takeoff and landing (eCTOL) aircraft, etc. One example flexible architecture, such as the one shown in
As shown above, a 185 kW hybrid unit may be provided. Accordingly, two hybrid units may be provided in a given aircraft to provide 370 kW of power.
As such, the various embodiments herein provide for a hybrid electric powerplants that may be incorporated into various different types of aircraft in the aerospace market. In doing so, aircraft manufacturers may not have to build their own systems that are made up of an engine, a generator, power electronics, cooling systems, and/or control systems to provide power to those aircraft. This may be advantageous, as a development process to create a powerplant system and certify it to aerospace standards may last 4+ years and may cost more than $10 M.
As such, the hybrid powerplants or flexible architectures described herein may be design, manufactured, etc. separably from the design of the aircraft. A few aspects of the flexible architectures may be customized as desired by an aircraft manufacturer, but in a way that does not cause the total system to be redesigned or reconfigured. The embodiments herein therefore provide for an integrated unit that includes the engine, generator, power electronics, cooling systems, and/or control systems in one package to be installed on an aircraft. Combining these elements into a single standalone unit further advantageously allows for that unit to go through the Federal Aviation Administration (FAA) certification process as a system. Then, multiple aircraft manufacturers may use the certified system, removing that certification burden and development burden from the aircraft developer as well as adding efficiencies where multiple aircraft manufacturers will not have to seek certification of many different powerplant systems specifically designed for their aircraft.
By providing a combined unit having an engine, generator, power electronics, cooling systems, and/or control systems, the hybrid flexible architectures described herein may be optimized as a whole system rather than as individual components. entire system rather than optimization of the pieces. Additionally, such a hybrid unit may be used in multiple aircraft designs, whereas systems designed as part of an aircraft design process are configured such that it is difficult to reapply them elsewhere. Having a hybrid unit that may be applied in multiple market segments and aircraft designs with common power requirements leads to faster development of aircraft where a major component (e.g., the hybrid units or flexible architectures) of an aircraft is already certified and in production.
Hybrid electric systems for aviation have historically been designed from scratch for each application/aircraft. Such a process is inefficient and addressed by the embodiments herein. For example, some aircraft have unique powerplants designed specifically for the aircraft. Such a solution may include custom engine, generator, power electronics, control systems, cooling systems, battery pack, propulsion motors, and/or propellers. The embodiment herein provides for a compact hybrid system for an aircraft that may make up one half of two distinct halves within an aircraft power and propulsion system: upstream and downstream ends of a powertrain (such as a hybrid powertrain as described herein).
Specifically, the upstream end of the powertrain may include hybrid powertrain elements responsible for producing electrical power. Such upstream components 1305 may include the engine, generator, power electronics, control systems (for the upstream power generation components), cooling systems (for the upstream components), battery pack, and/or fuel. The downstream end of the powertrain may include hybrid powertrain elements responsible for turning the electrical power into thrust, attitude control, and/or active control of aerodynamics. These downstream components 1310 may further include electric motors, propellers, motor controllers, and/or control systems for the propulsion system.
As such, there may be common upstream powertrain needs across very different electric aircraft designs that are of similar sizes and total power requirements. However, the downstream powertrains may have little consistency from one aircraft to the next and therefore these components may not be standardized to work on many aircraft designs the way the upstream components can. Furthermore, the upstream elements that lend themselves to standardization may include the components that are linked to the power requirements but not the total energy requirements. In the case of the engine, generator, power electronics, cooling systems, and/or control systems, these elements of the upstream powertrain may be sized to fit a specific power requirement (kW or hp) of an aircraft. However, the quantity of fuel and the size of the battery pack may be driven by total energy requirements (kWh or hp hr) and these may vary from aircraft to aircraft. In such embodiments, the volume of fuel may be scaled by changing the size of the fuel tank to match the requirements of the aircraft design, and the capacity of the battery pack in kWh may be scaled by adjusting the number of parallel stacks of cells within a battery pack or by adding additional battery packs.
Therefore, provided herein are embodiments for supplying a hybrid powerplant that tightly integrates the engine, generator, power electronics, control systems (for the power generation system), and/or cooling systems in a weight-efficient and space efficient manner that can be certified as a standalone unit designed to provide propulsive power that is separable from the aircraft.
In addition, as described herein, a rotor inside the generator may be optimized to serve multiple purposes in the context of a hybrid powerplant. Conventional combustion engines may have a flywheel mass attached to the rotational shaft to enhance smoothness of operation. However, in the context of an aerospace system it may be unattractive to add extra mass. When an engine is coupled to a generator in a hybrid powerplant as described herein, the rotor in the generator may be designed to withstand any torque impulses from the engine and it may be designed to be the rotating mass that the engine utilizes for smoothness of operation.
Further, while auxiliary power units are known in the prior art, these systems may be designed for different purposes than as a primary source of propulsion power for an aircraft, and therefore may not have control systems capable of being certified to the standards required for use in propulsion. Additionally, such systems may be designed without the cooling systems, leaving that aspect to the airframe designer. As such, these systems are not certified to Part 33 (FAA regulations for aircraft powerplants). Also, these auxiliary power unit systems are designed to be lightweight auxiliary systems that are used intermittently rather than for highly efficient propulsion systems that are used in all phases of flight. Additionally, auxiliary power units may be designed to produce alternating current (AC) power, whereas hybrid electric powerplants as described herein may produce direct current (DC) power so that the hybrid electric powerplants may be coupled to a large propulsive battery pack, as battery packs provide and are charged using DC power.
Turbogenerators are a type of adapted auxiliary power units that have been proposed for hybrid power. Such systems lack cooling system integration that provides an airframe developer with a cooling system that is part of the hybrid powerplant. As such, airframe developers may be left to design their own cooling systems to accompany use of a turbogenerator. Using the embodiments herein, separate cooling systems for cooling the hybrid powerplants described herein may advantageously not need to be designed or developed for particular airframes, as such cooling systems are already included in the flexible architectures described herein.
As such, the flexible architectures and hybrid electric powerplants described herein advantageously provide an engine that converts liquid fuel (or gaseous fuel) into rotational mechanical power, a generator coupled to the engine that is configured to convert the rotational mechanical power to electricity, and/or power electronics coupled to the generator that are configured to convert the direct AC output of the generator to high voltage DC power. The flexible architectures and hybrid electric powerplants described herein further advantageously provide control systems that are configured to vary the power output of the engine to match the power demand on a main propulsive electrical bus of an aircraft to meet the demands of an aircraft for electric power.
Hybrid powerplant control systems, power electronics, generator, and/or engine designs described herein may further comply with regulatory requirements for the reliability of propulsive aerospace systems (e.g., failure should have a probability of less than 106 or ten to the power of negative six). Flexible architectures and hybrid electric powerplants may further include a control interface that enables the flexible architecture or hybrid powerplant to communicate with a vehicle-level flight control systems to enable propulsive power commands to be provided from the vehicle-level flight control systems to the hybrid-powerplant control systems, and also advantageously provide for the hybrid-powerplant control systems to send status messages back to the vehicle-level flight control systems (e.g., feedback for use in controlling the flexible architecture or hybrid powerplant). Flexible architectures and hybrid electric powerplants may further include cooling systems that maintain the temperature range of the generator, power electronics, and/or engine over a full range of operating power output of the flexible architectures and hybrid electric powerplants described herein.
Various embodiments of flexible architectures or hybrid electric powerplants described herein may further include control systems that vary power output by varying engine torque and/or maintain rotations per minute (RPM) substantially constant over a significant range of power output. Such embodiments may provide for faster response of the flexible architectures or hybrid electric powerplants by eliminating throttle lag and a longer response time relating to system rotational inertia.
Various embodiments of flexible architectures or hybrid electric powerplants described herein may further include the option to provide a portion of the engine's power output as mechanical shaft power and a portion provided as DC electrical power. Various embodiments of flexible architectures or hybrid electric powerplants described herein may further include that the engine may be a piston engine, diesel piston engine, turbine engine, rotary engine, or other forms of combustion engine. Various embodiments of flexible architectures or hybrid electric powerplants described herein may further include examples where the rotor of the generator is designed to be a flywheel for the engine. Various embodiments of flexible architectures or hybrid electric powerplants described herein may further include a clutch between the engine and generator to enable operation of the generator as a motor that can be operated while the engine is shut down in some types of parallel hybrid installations as described herein.
Described herein are various embodiments for implementing a hybrid-electric aircraft. Such an aircraft may utilize a high voltage electrical bus to distribute power to various components of the aircraft, such as motors for propulsion mechanisms of the aircraft. In such a hybrid-electric aircraft, it may be desirable to stabilize the high voltage electrical bus within a specific, predetermined voltage range (e.g., around a nominal voltage level) so that the propulsion motors may perform adequately. Various embodiments described herein may specifically use a direct current (DC) bus, so maintaining a desired DC voltage range may be desirable. Advantageously, the various embodiments herein provide for efficiently maintaining a desired DC voltage range on a DC bus by connecting at least one battery or supercapacitor directly to the DC bus, and further maintaining a sufficient charge on the at least one battery or supercapacitor to maintain the desired DC voltage range on the DC bus. Such embodiments may prevent voltage spikes that may be damaging to components of a hybrid-electric or electric aircraft (e.g., electric motors and inverters for propulsion) and avoid voltage spikes or sags that may negatively impact the reliability and/or performance and safety of the aircraft or systems of the aircraft.
In electrified aviation, various embodiments of an overall architecture may include one or more electric power creation devices (e.g., an electric generator) connected via a low-impedance connection to a high voltage DC bus and feeding electrical power and energy onto that bus. In the same vehicle and attached to that same DC bus may be one or more power consuming devices (e.g., electric motors) that receive electrical power and energy from that DC bus. Various embodiments of electrified aircraft may also include energy storage devices such as battery packs or capacitors (e.g., supercapacitors), which may receive or deliver power as desired depending on bus voltage and battery pack voltage.
If a high-voltage electric generator is directly generating DC power or is operating through a passive rectifier, for example, the DC voltage created by the motor may be a function primarily of motor rotations per minute (RPM) of the shaft rotating the electric generator. A permanent magnet electric motor, for example, may create a voltage based on rotational speed (RPM). For many uses, the coupling of voltage with RPM may create an issue for motor control that limits the value of that electric motor in a system. To gain additional usefulness from a brushless motor without permanent magnets, an external voltage reference may be used to maintain a desired voltage level. A unique problem in aviation is that flight safety requires precise control of power consumers over a wide range of flight conditions (electric motors driving fans, propellers, or other devices) that may not match the characteristics of contributors (such as an electric brushless generator). If a high-voltage generator used is turning slower than expected for any reason, the bus voltage may be lower than desired and any motors on that bus may perform below expectations, which may lead to an unsafe or undesirable condition. If such a high-voltage generator is turning faster than expected, bus voltage may be high and motor performance may again be outside expected or desired values. As such, it may be desirable for applications of generators and motors sharing a common bus to design the generators and motors used accordingly. For electrified aviation, precise control of any motor(s) is desirable to provide lift, thrust, aircraft attitude, etc. for an aircraft. As such, as compared to other, non-aviation related implementations, it is desirable to have better control over a power supplied to any motor(s) (e.g., over the DC bus) by maintaining power supplied to the motor(s) at a voltage that keeps the motor(s) operating at a desired performance level. In addition, the power supplied to the motor(s) may be quickly adjustable so that a pilot or control system of an aircraft may control the motor(s) over a wide range of use as needed (e.g., provide a pilot or control system with a flexible, wide range over which they may control the motor(s)). In various embodiments, inverters may be used to regulate an output voltage of an upstream electric generator(s), which may be used to feed a high voltage bus. Inverters may also be used to precisely control downstream motors under varying load conditions.
Inverters may allow a system designer to expand an operating envelope of any motors and/or generators by controlling current. In order for these inverters to function properly, a bus voltage feeding power to the inverters may advantageously be set and maintained by other methods besides motor RPM (as voltage on a bus may be difficult to control precisely where only motor RPM is used). The maintenance of the bus voltage relates to capacitance and the expected variations in load present under all system operating conditions. If that bus has loads that are varying too rapidly or capacitance (which acts like inertia in an analogous mechanical system) that is too low, for example, then the high voltage bus and power electronic system may become unstable.
In various embodiments, bus voltage may be established and maintained using battery pack(s), capacitor(s), or any combination thereof. Such devices may add capacitance and/or electrical inertia to the bus and are passive, meaning their intended function is ruled completely by physics and may not require control or intervention (e.g., by a controller or control system). Supercapacitors (or ultracapacitors) additionally have a desirable feature of high capacitance, though they typically lack significant energy storage. Supercapacitors may respond to very rapid fluctuations with enormous power (e.g., energy over time). In short, they may provide stability to a bus for fluctuations that are relatively short in duration, low in amplitude, or where the product of those two values is relatively low. Batteries may also be desirable because they have significant capacitance for bus stability and may also store high energy. Batteries may not be able to respond to a change in voltage as quickly as a supercapacitor, as batteries often have more limited rate of power applications, particularly in charging (where discharging power capacity is often 10× or more higher than charging capacity). For example, if it is necessary to pull current off a bus to maintain a desired voltage level (e.g., charge a battery), a battery may not absorb that current as quickly as would be desired in certain embodiments (depending on the specific characteristics of a selected battery). In some embodiments, however, one or more battery packs alone may be sufficient to maintain a desired voltage level on a bus.
Accordingly, various embodiments are described herein that enable independent control of one or multiple upstream electric generators and downstream motors by adding a battery pack and/or supercapacitor bank with an appropriate design to maintain a desired voltage on a DC bus. With an architecture where the voltage and capacitance of those storage elements are directly electrically connected to the main motor control elements on the bus (and not shielded by other switches, chargers, or like devices), the battery pack and/or supercapacitor bank provide a lightweight and effective anchor or setpoint for a high voltage DC bus.
A battery pack in an aircraft may be deployed along with a hybrid-electric generation system to support system safety standards applied to flight articles. If these battery packs and/or supercapacitors are chosen not only to provide required power or energy but are also set at a correct or desired voltage and are connected to high voltage motor controllers, the battery pack and/or supercapacitor bank may provide a second and valuable benefit of bus stabilization by connecting the battery pack and/or supercapacitor bank directly to a DC bus. The battery pack and/or supercapacitor bank may also be advantageously chosen for a given aircraft such that it has a target voltage, though actual voltage on the bus may naturally fluctuate some with state-of-charge (SOC) and varying electric loads. The battery pack and/or supercapacitor bank may also be advantageously chosen so that the actual voltage is unlikely to go outside of a desired range. In instances where the actual voltage does go out of the desired range or is expected to go out of the desired range, a controller of the aircraft or a hybrid-electric genset in the aircraft may adjust the power (e.g., torque) supplied to the generator to add or reduce electric power supplied to the DC bus to maintain the voltage within a proper, desired range. RPM may further be maintained at a constant or relatively constant level or within a predetermined range. Therefore, power supplied to the generator or otherwise output to a power shaft may be adjusted by adjusting the torque output by the engine rather than through adjustment of the RPM of the output of the engine. It may further be desirable to maintain an actual voltage set point that may fluctuate at a range that remains within desired tolerances for operating electric motors or other components of an aircraft. In addition, a battery pack may advantageously serve as an auxiliary source of power to drive motors or other components of an aircraft in the event of a fault in the generator(s) or other component of a hybrid-electric genset. This may therefore add a level of system safety and fault tolerance.
The system 1460 further includes aircraft components such as inverters 1472 and 1476 connected to the DC bus 1467, electric motors 1474 and 1478 connected to the inverters 1472 and 1476, a controller 1480, and battery packs 1482 and 1484. In various embodiments, the aircraft components may have supercapacitors instead of or in addition to the battery packs 1482 and 1484. In various embodiments one or more battery packs and/or supercapacitors may be included as part of the hybrid-electric genset 1461 and connected directly to the DC bus within the hybrid-electric genset 1461, whether or not the aircraft components have separate batteries and/or supercapacitors. While
In various embodiments, the DC bus 1467 may be or may be connected to the HV bus 2105 of
In various embodiments, fewer, additional, or different elements to those shown in
At an operation 1504, a controller may therefore be able to determine how a power output of a hybrid-electric genset should be adjusted to maintain a desired voltage range on a DC bus. For example, if a battery's charge level is too low such that it is in danger of not being able to maintain a desired voltage, the controller may transmit instructions at an operation 1506 to increase the power output of the hybrid-electric genset so that there is sufficient power to charge the battery. In another example, if a motor of the aircraft is currently using or is expected to require significantly more power than is currently being used, the controller may transmit instructions at an operation 1506 to increase power output of the hybrid-electric genset. The power output may also similarly be decreased. In either instance, the controller may adjust this overall power output to the DC bus by varying the RPM supplied to an electric generator by an engine. As such, while the battery packs and supercapacitors may reduce a need to provide real time adjustments to power output of a hybrid-electric genset, as the battery packs and/or supercapacitors may maintain the DC bus at a desired voltage level, some control or adjustment of the RPM and therefore output power to the DC bus may still be desirable in various embodiments.
At an operation 1602, aspects of power available at or flowing through a DC bus is measured by the controller. If the DC bus is measurable by a system-wide aircraft controller, the operation 1602 may be carried out by the system-wide aircraft controller as well. Similarly, if batteries and/or supercapacitors are packaged as part of a hybrid-electric genset rather than being positioned as part of an overall aircraft system, the controller may at operation 1602 also measure a state of the batteries/supercapacitors (e.g., charge state, current, voltage, etc.). At an operation 304, the controller determines how power output of the hybrid-electric genset should be adjusted based on the measurements. For example, if a DC bus voltage is getting close to going outside of a desired range, it may be desirable to transmit instructions at an operation 306 to the components of the hybrid-electric genset to adjust power output of the hybrid-electric genset based on the determination at the operation 304 to ensure the DC bus voltage stays within a desired voltage range.
In its most basic configuration, computing system environment 100 typically includes at least one processing unit 102 and at least one memory 104, which may be linked via a bus 106. Depending on the exact configuration and type of computing system environment, memory 104 may be volatile (such as RAM 110), non-volatile (such as ROM 108, flash memory, etc.) or some combination of the two. Computing system environment 100 may have additional features and/or functionality. For example, computing system environment 100 may also include additional storage (removable and/or non-removable) including, but not limited to, magnetic or optical disks, tape drives and/or flash drives. Such additional memory devices may be made accessible to the computing system environment 100 by means of, for example, a hard disk drive interface 112, a magnetic disk drive interface 114, and/or an optical disk drive interface 116. As will be understood, these devices, which would be linked to the system bus 306, respectively, allow for reading from and writing to a hard disk 118, reading from or writing to a removable magnetic disk 120, and/or for reading from or writing to a removable optical disk 122, such as a CD/DVD ROM or other optical media. The drive interfaces and their associated computer-readable media allow for the nonvolatile storage of computer readable instructions, data structures, program modules and other data for the computing system environment 100. Those skilled in the art will further appreciate that other types of computer readable media that can store data may be used for this same purpose. Examples of such media devices include, but are not limited to, magnetic cassettes, flash memory cards, digital videodisks, Bernoulli cartridges, random access memories, nano-drives, memory sticks, other read/write and/or read-only memories and/or any other method or technology for storage of information such as computer readable instructions, data structures, program modules or other data. Any such computer storage media may be part of computing system environment 100.
A number of program modules may be stored in one or more of the memory/media devices. For example, a basic input/output system (BIOS) 124, containing the basic routines that help to transfer information between elements within the computing system environment 100, such as during start-up, may be stored in ROM 108. Similarly, RAM 110, hard drive 118, and/or peripheral memory devices may be used to store computer executable instructions comprising an operating system 126, one or more applications programs 128 (which may include the functionality disclosed herein, for example), other program modules 130, and/or program data 122. Still further, computer-executable instructions may be downloaded to the computing environment 100 as needed, for example, via a network connection.
An end-user may enter commands and information into the computing system environment 100 through input devices such as a keyboard 134 and/or a pointing device 136. While not illustrated, other input devices may include a microphone, a joystick, a game pad, a scanner, etc. These and other input devices would typically be connected to the processing unit 102 by means of a peripheral interface 138 which, in turn, would be coupled to bus 106. Input devices may be directly or indirectly connected to processor 102 via interfaces such as, for example, a parallel port, game port, firewire, or a universal serial bus (USB). To view information from the computing system environment 100, a monitor 140 or other type of display device may also be connected to bus 106 via an interface, such as via video adapter 132. In addition to the monitor 140, the computing system environment 100 may also include other peripheral output devices, not shown, such as speakers and printers.
The computing system environment 100 may also utilize logical connections to one or more computing system environments. Communications between the computing system environment 100 and the remote computing system environment may be exchanged via a further processing device, such a network router 152, that is responsible for network routing. Communications with the network router 152 may be performed via a network interface component 154. Thus, within such a networked environment, e.g., the Internet, World Wide Web, LAN, or other like type of wired or wireless network, it will be appreciated that program modules depicted relative to the computing system environment 100, or portions thereof, may be stored in the memory storage device(s) of the computing system environment 100.
The computing system environment 100 may also include localization hardware 186 for determining a location of the computing system environment 100. In some instances, the localization hardware 156 may include, for example only, a GPS antenna, an RFID chip or reader, a WiFi antenna, or other computing hardware that may be used to capture or transmit signals that may be used to determine the location of the computing system environment 100.
While this disclosure has described certain embodiments, it will be understood that the claims are not intended to be limited to these embodiments except as explicitly recited in the claims. On the contrary, the instant disclosure is intended to cover alternatives, modifications and equivalents, which may be included within the spirit and scope of the disclosure. Furthermore, in the detailed description of the present disclosure, numerous specific details are set forth in order to provide a thorough understanding of the disclosed embodiments. However, it will be obvious to one of ordinary skill in the art that systems and methods consistent with this disclosure may be practiced without these specific details. In other instances, well known methods, procedures, components, and circuits have not been described in detail as not to unnecessarily obscure various aspects of the present disclosure.
Some portions of the detailed descriptions of this disclosure have been presented in terms of procedures, logic blocks, processing, and other symbolic representations of operations on data bits within a computer or digital system memory. These descriptions and representations are the means used by those skilled in the data processing arts to most effectively convey the substance of their work to others skilled in the art. A procedure, logic block, process, etc., is herein, and generally, conceived to be a self-consistent sequence of steps or instructions leading to a desired result. The steps are those requiring physical manipulations of physical quantities. Usually, though not necessarily, these physical manipulations take the form of electrical or magnetic data capable of being stored, transferred, combined, compared, and otherwise manipulated in a computer system or similar electronic computing device. For reasons of convenience, and with reference to common usage, such data is referred to as bits, values, elements, symbols, characters, terms, numbers, or the like, with reference to various presently disclosed embodiments.
It should be borne in mind, however, that these terms are to be interpreted as referencing physical manipulations and quantities and are merely convenient labels that should be interpreted further in view of terms commonly used in the art. Unless specifically stated otherwise, as apparent from the discussion herein, it is understood that throughout discussions of the present embodiment, discussions utilizing terms such as “determining” or “outputting” or “transmitting” or “recording” or “locating” or “storing” or “displaying” or “receiving” or “recognizing” or “utilizing” or “generating” or “providing” or “accessing” or “checking” or “notifying” or “delivering” or the like, refer to the action and processes of a computer system, or similar electronic computing device, that manipulates and transforms data. The data is represented as physical (electronic) quantities within the computer system's registers and memories and is transformed into other data similarly represented as physical quantities within the computer system memories or registers, or other such information storage, transmission, or display devices as described herein or otherwise understood to one of ordinary skill in the art.
In an illustrative embodiment, any of the operations described herein may be implemented at least in part as computer-readable instructions stored on a computer-readable medium or memory. Upon execution of the computer-readable instructions by a processor, the computer-readable instructions may cause a computing device to perform the operations.
The foregoing description of illustrative embodiments has been presented for purposes of illustration and of description. It is not intended to be exhaustive or limiting with respect to the precise form disclosed, and modifications and variations are possible in light of the above teachings or from practice of the disclosed embodiments. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.
This application is a 371 National Stage application of International PCT Application No. PCT/US2022/050260, filed Nov. 17, 2022, which claims the benefit of U.S. Provisional Patent Application No. 63/280,585, filed Nov. 17, 2021, the entire contents of each of which are hereby incorporated by reference in their entireties.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US2022/050260 | 11/17/2022 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 63280585 | Nov 2021 | US |
