DE102021106648A1 - System and method for simulating different aircraft configurations with an electric aircraft - Google Patents

Abstract

The invention relates to a system and a method for simulating different aircraft configurations with an electric aircraft which has M propellers (11, 21) each driven by an electric motor (12, 22), M ≥ 1. There are N adjustable operating elements (31-34, 5), N ≥ 1, which generate control signals depending on their setting position. A control unit (4) is also provided, which is designed to control the M propellers (11, 21) with regard to speed (n) and propeller angle (α ) to control. The control unit (4) is designed to map the M propellers (11, 21) to K aircraft engines (61, 62) to be simulated, K≧1 and K≦M, and the propeller or propellers (11, 21) that each form an aircraft engine (61, 62) to be simulated, driven at the same speed (n) and set the same propeller angle (α) for this. For each aircraft engine (61, 62) to be simulated, the speed (n) of the propeller or propellers (11, 21), which form the aircraft engine (61, 62) to be simulated, is determined by the setting position of one of the N operating elements (31, 33) is set, and for each aircraft engine (61, 62) to be simulated, the propeller angle (α) of the propeller or propellers (11, 21) that form the aircraft engine (61, 62) to be simulated is set by the setting position of a further control element ( 31, 33) or set automatically.

Description

The invention relates to a system and a method for simulating different aircraft configurations with an electric aircraft.

As part of the flight training, it is necessary for the student pilots to fly different types of aircraft, in particular single-engine aircraft, multi-engine aircraft and/or turbine-powered aircraft.

Traditionally, flight training begins on good-natured aircraft types that are easy to fly mechanically and can be operated with little effort. During the first flight hours, engine operation and engine monitoring are usually partly taken over by the flight instructor in order to slowly increase the demands on the student pilot and not to overwhelm him. During advanced training and conversion to other classes and class ratings such as Single Engine Piston (SEP), Multi Engine Piston (MEP), Single Engine Turbine (SET) or even for instruction in complex systems such as variable-pitch propellers, more complex aircraft with these types of propulsion and/or systems are used.

A frequent change of type, however, is associated with a change of habits of the pilot and a consequent increase in the flight hours required to master the respective type. There is thus a need to effectively familiarize a student pilot with different types of aircraft.

The object of the present invention is to reduce the effort associated with the training of trainee pilots.

This object is achieved by a system for simulating different aircraft configurations having the features of claim 1 and a method having the features of claim 19. Developments of the invention are specified in the dependent claims.

Thereafter, according to a first aspect, the present invention provides a system for simulating different aircraft configurations, comprising an electric aircraft having M propellers each driven by an electric motor, M ≥ 1, the propeller blades of the propeller each having an adjustable propeller angle.

It is envisaged that the system will comprise N adjustable operating elements, N ≥ 1, which generate control signals depending on their setting position. The controls can be operated manually by a pilot or flight student. A control unit is also provided, which is designed to control the M propellers with regard to speed and propeller angle on the basis of the control signals generated by the N operating elements.

The control unit is designed to map the M propellers to K aircraft engines to be simulated, K≧1 and K≦M, and to drive the propeller or propellers, which each form an aircraft engine to be simulated, at the same speed and for them the same propeller angle set. If several propellers form an aircraft engine to be simulated, these propellers thus form a group, with the propellers of the group being driven at the same speed and with the same propeller angle. For example, if the electric aircraft has four propellers and two aircraft engines are simulated, then two propellers are used to simulate one aircraft engine, i. H. two propellers are mapped onto an aircraft engine. There are thus two groups of two propellers each, which are each driven at the same speed and the same propeller angle to simulate an aircraft drive. However, it is also within the scope of the invention that an aircraft engine is simulated by only one propeller. In principle, the number of simulated aircraft engines can be arbitrary.

The invention further provides that, for each aircraft engine to be simulated, the speed of the propeller or propellers, which respectively form the aircraft engine to be simulated, is set by the setting position of one of the N operating elements. Each aircraft engine to be simulated is therefore assigned an operating element via which the rotational speed of the propeller assigned to the aircraft engine under consideration can be adjusted, as a result of which the thrust of the simulated aircraft engine can be adjusted. The speed can be set by directly specifying the speed of the respective electric motor or alternatively by setting the power or the torque of the respective electric motor.

Furthermore, for each aircraft engine to be simulated, the propeller angle of the propeller or propellers that form the aircraft engine to be simulated is set by the setting position of a further operating element or automatically by the control unit.

The invention is based on the idea of using an electric aircraft with an electric drive for simulating a plurality of aircraft configurations, with the different aircraft configurations being characterized by a different number and/or a different type of aircraft engine. For example, single-engine piston aircraft (SEP), twin-engine piston aircraft (MEP) and single-engine gas turbine engine aircraft (SET) represent different aircraft configurations within the meaning of the present invention. Obtaining class ratings for these aircraft configurations (SEP, MEP, SET) is under Only one type of aircraft can be used.

By using the system of the present invention, both beginner and advanced training, as well as class ratings for different engines, can be replicated using only one electric aircraft. The invention enables flight schools, for example, to reduce the number of aircraft types for the aircraft configurations mentioned. This results in a higher utilization of the fleet. As a secondary effect, the reduced number of aircraft types to be maintained results in lower costs for spare parts inventory and maintenance.

A further advantage associated with the invention consists in the fact that the familiarity of the flight student with the flight characteristics of the type used means that it is only necessary to get used to the new engine behavior. As a result, the training time in the form of the required flight hours can be reduced, which in turn is reflected in lower training costs.

The controls are designed, for example, as a lever or as a slide. The setting position of the lever or slider is fed to the control unit as an electrical signal. The blade angle of the propeller blades of the propeller is referred to as the propeller angle.

One embodiment of the invention provides that the M propellers precisely simulate an aircraft engine, K=1, with an adjustable first operating element being provided, the setting position of which sets the speed of the propellers. All propellers are driven at the same speed and have the same propeller angle, so that a symmetrical thrust is guaranteed. The electric aircraft behaves like a single-engine piston aircraft.

One embodiment provides for the propeller angle of the M propeller to be set automatically by the control unit. The trainee pilot only specifies the speed of the propeller or the thrust of the simulated aircraft engine via the first control element.

Alternatively, the propeller angle can be adjusted. In this case, the system provides an adjustable second control element, whereby the setting position of the second control element determines the propeller angle of the M propellers. The electric aircraft behaves like a twin-engine aircraft with a piston engine and variable-pitch propeller. A so-called fixed speed control or "constant speed control" can be provided, according to which the propeller speed is either constantly controlled by adjusting the propeller blades and the thrust is thus only changed by the torque applied to the propeller, or according to which the propeller speed is controlled by varying the the torque applied to the propeller is kept constant and thus the thrust is changed by adjusting the propeller blades.

One embodiment provides that the second operating element can be locked, in which case the propeller angle of the M propeller is automatically adjusted by the control unit. A mode with only one control element can thus be displayed via such a locking function when two control elements are present.

According to a further exemplary embodiment, it is provided that the M propellers simulate two aircraft engines, K=2, where M≧2. It is envisaged that the M propellers will be mapped to two aircraft engines to be simulated. Two adjustable controls are provided, with the setting position of one control element determining the speed of the propeller or propellers that form the one aircraft engine to be simulated. The setting position of the other control element determines the speed of the propeller or propellers that form the other aircraft engine to be simulated.

In this way, a twin-engine aircraft is simulated, with the thrust of each simulated aircraft engine being separately adjustable by the associated operating element using the central controller.

One embodiment provides for the propeller angle of the M propellers to be automatically adjusted by the control unit on the one hand for the propeller or propellers that form the one aircraft engine to be simulated and on the other hand for the propeller or propellers that form the other aircraft engine to be simulated to be set. The electric aircraft behaves like a twin-engine aircraft without variable-pitch propellers or propeller levers.

Alternatively, it is provided that the system has two further adjustable controls, the setting position of one further control element defining the propeller angle of the propeller or propellers that form the one aircraft engine to be simulated, and the setting position of the other further control element defining the propeller angle of the propeller or propellers, which form the one aircraft engine to be simulated. The electric aircraft thus behaves like a twin-engine aircraft with propeller controls for each simulated aircraft engine.

It can be provided that the control unit is designed to set the propeller angle in beta mode or in reverse mode. In the so-called beta mode, the pitch angle of the propeller blades is specified directly via the control element. In reverse mode, a negative pitch angle of the propeller blades is set. Reverse mode results in braking rather than forward thrust of the aircraft.

A further embodiment provides that the two further adjustable operating elements can be locked, in which case the propeller angle of the respective propeller is automatically set by the control unit. With such a locking function, a mode with only two controls for the thrust can be displayed if there are two additional controls for setting the propeller angle.

A further embodiment of the invention provides that the system can be configured for two modes, firstly a piston engine mode in which the control signals generated by the N operating elements cause the propeller to be controlled without a time delay, and secondly a gas turbine mode in which the control unit is designed to implement defined deceleration profiles in the control of the propellers in gas turbine mode. For example, you can choose between the two modes via an operating menu. The piston engine mode is the default mode. By selecting the gas turbine mode it is possible to simulate the more sluggish behavior of turbines. For this purpose, a specific response behavior is stored in the control unit in the form of delay profiles.

In this case, an embodiment variant provides that the more sluggish response behavior in the gas turbine mode can be switched off for safety reasons. For this purpose, a manual emergency actuation is provided, when the system is actuated, if it is in gas turbine mode, it is transferred to piston engine mode. The manual override provides an "override" mode that allows a return to piston engine mode. The "override" mode can significantly increase safety compared to turbine-powered aircraft, since the power is immediately available when needed.

According to one embodiment variant, the manual emergency actuation is provided by a separate operating element, for example an “override” button on one of the operating elements. Alternatively, it can be provided that the manual emergency actuation is triggered when one of the operating levers is moved to an end stop. If, for example, a thrust lever is moved to its end stop, it automatically switches back to the other operating mode so that the full power of the propellers is available without a time delay.

According to a further embodiment of the invention, the control unit is also designed to carry out a magnet check for each aircraft engine to be simulated, taking into account at least one ignition lock operating element that has different positions, the control unit being designed to read the position of the ignition lock -Control element to simulate the system behavior with a single ignition or a double ignition.

This variant of the invention allows, in particular, the simulation of a magnet check in piston engines that have dual ignition with two ignition circuits, it being customary to turn an ignition lock key on the right ignition circuit, the left ignition circuit and both ignition circuits, with a speed drop between the values of both ignition circuits and to check the values of one ignition circuit at a time. The control unit is designed to simulate such a speed drop depending on the position of the ignition lock operating element.

A further embodiment of the invention provides that the N adjustable controls are provided in the form of different, interchangeable control links that have a different number of mechanically actuated controls, with at least one control link with one control element and one control link with two controls being provided. For example, three different control links with one, two and four operating elements can be provided. A control link with an operating element is used, for example, to simulate a single-engine aircraft with a piston engine and without a variable-pitch propeller. A control backdrop with two controls is used for this, for example set to simulate a single-engine airplane with a piston engine and variable pitch propeller or to simulate a twin-engine airplane with automatic setting of the propeller angles. For example, a control panel with four controls is used to simulate a twin-engine aircraft that has thrust and propeller angle controls for both engines.

In principle, it is conceivable to use a control link with the maximum required number of operating elements and to provide the operating elements with the exception of one with a locking function. In this way, all aircraft configurations can be simulated in cooperation with the control unit. However, with such a configuration there is a risk that the trainee pilot will confuse the individual operating elements. It may therefore be preferable to provide interchangeable control scenes that only have the number of operating elements that are required for the current simulation when flying with the electric aircraft.

According to a further embodiment, it is provided that the system has a man-machine interface which, in addition to the N operating elements, includes a configurable display, the display showing displays, switches and/or measuring devices and/or providing them for operation. These are conventional displays, switches and/or measuring devices arranged in a cockpit. Provision can be made for these to be read out electronically via the control unit.

A variant of this provides that the configurable display has a representation of the speed for at least one simulated aircraft engine. This is particularly advantageous for the already mentioned magnet check for a visual inspection of a speed drop.

Furthermore, the control unit can be designed to receive control signals from a battery management system and to take them into account when controlling the propeller. In this case, for example, control can take place in such a way that the longest possible flight route can be realized, taking into account the remaining battery power.

• - ein Luftfahrzeug mit einem als Kolbenmotor ausgebildeten Flugzeugtriebwerk;
• - ein Luftfahrzeug mit zwei jeweils als Kolbenmotor ausgebildeten Flugzeugtriebwerken;
• - ein Luftfahrzeug mit einem als Gasturbinentriebwerk ausgebildeten Flugzeugtriebwerk;
• - ein Luftfahrzeug mit zwei jeweils als Gasturbinentriebwerk ausgebildeten Flugzeugtriebwerken.

As already mentioned, the individual aircraft configurations differ in a different number and/or a different type of simulated aircraft engine. Exemplary embodiments of this provide that the aircraft configurations include at least one of the following configurations:

• - an aircraft with an aircraft engine designed as a piston engine;
• - An aircraft with two aircraft engines each designed as a piston engine;
• - an aircraft with an aircraft engine designed as a gas turbine engine;
• - An aircraft with two aircraft engines each designed as a gas turbine engine.

If gas turbine engines are simulated, they can be turboprop engines.

• - Steuern auf der Grundlage von N Bedienelementen erzeugter Steuersignale die M Propeller im Hinblick auf Drehzahl und Propellerwinkel, wobei
• - die M Propeller auf K zu simulierende Flugzeugtriebwerke, K ≥ 1 und K ≤ M abgebildet werden,
• - der oder die Propeller, die jeweils ein zu simulierendes Flugzeugtriebwerk bilden, mit der gleichen Drehzahl angetrieben und für diese der gleiche Propellerwinkel eingestellt wird,
• - für jedes zu simulierende Flugzeugtriebwerk die Drehzahl des oder der Propeller, die das zu simulierende Flugzeugtriebwerk bilden, durch die Einstellposition eines der N Bedienelemente eingestellt wird, und
• - für jedes zu simulierende Flugzeugtriebwerk der Propellerwinkel des oder der Propeller, die das zu simulierende Flugzeugtriebwerk bilden, durch die Einstellposition eines anderen der N Bedienelemente oder automatisch eingestellt wird.

According to a further aspect of the invention, the present invention relates to a method for simulating different aircraft configurations with an electric aircraft which has M propellers each driven by an electric motor, M ≥ 1, the propeller blades of the propeller each having an adjustable propeller angle. The procedure includes:

• - Control, based on control signals generated by N controls, the M propellers in terms of speed and propeller angle, where
• - the M propellers are mapped to K aircraft engines to be simulated, K ≥ 1 and K ≤ M,
• - the propeller or propellers, which each form an aircraft engine to be simulated, are driven at the same speed and the same propeller angle is set for them,
• - for each aircraft engine to be simulated, the speed of the propeller or propellers forming the aircraft engine to be simulated is set by the setting position of one of the N controls, and
• - for each aircraft engine to be simulated, the propeller angle of the propeller or propellers forming the aircraft engine to be simulated is set by the setting position of another of the N controls or automatically.

One embodiment provides that the method is carried out consecutively for different aircraft configurations that differ in the number and/or the type of aircraft engines to be simulated.

The embodiment variants explained with regard to the system according to the invention also exist in a corresponding manner for the method according to the invention.

In a further aspect of the invention, the present invention relates to a computer program with program code for carrying out the method steps of the method according to the invention when the computer program is run on a computer. Such a computer is in particular the named control unit.

• 1 eine schematische Darstellung eines Ausführungsbeispiels eines Systems zur Simulation unterschiedlicher Luftfahrzeugkonfigurationen mit einem Elektroflugzeug, das im dargestellten Ausführungsbeispiel zwei jeweils von einem Elektromotor angetriebene Propeller aufweist; und
• 2 ein Ablaufdiagramm eines Verfahrens zur Simulation unterschiedlicher Luftfahrzeugkonfigurationen.

The invention is explained in more detail below with reference to the figures of the drawing using an exemplary embodiment. Show it:

• 1 a schematic representation of an embodiment of a system for simulating different aircraft configurations with an electric aircraft, which in the illustrated embodiment has two propellers each driven by an electric motor; and
• 2 a flowchart of a method for simulating different aircraft configurations.

the 1 shows schematically the essential components of a system for simulating different aircraft configurations, the simulation being carried out with an electric aircraft.

The electric aircraft under consideration has M electric aircraft engines 1, 2, which each consist of an electric drive unit 10, 20 and a propeller 11, 21 driven by the drive unit 10, 20. The drive unit 10, 20 in each case comprises an electric motor 12, 22, which is provided with an alternating current via an inverter 13, 23. The rectifiers 13, 23 are supplied with power via a direct current line 14 via a battery 17.

The propellers 11, 12 are each driven by the drive unit 10, 20 at a speed n. They have propeller blades 110, 210 which are adjustable with regard to their propeller angle α. The propellers 11, 12 are variable pitch propellers in which the propeller angle α, also referred to as the blade angle or setting angle, can be adjusted during operation so that an adaptation to different operating conditions can take place. Variable pitch propellers are known, for example, in which the propeller blades can be adjusted hydraulically.

The electric aircraft under consideration comprises only electric aircraft engines 1, 2, the number of aircraft engines shown being to be understood merely as an example. For example, it can alternatively be provided that only a single aircraft engine is present. Alternatively, more than two aircraft engines can be provided.

The present invention provides for simulating different aircraft configurations with the existing electric aircraft engine or engines, for example aircraft configurations with a single-engine aircraft with a reciprocating engine (SEP), with a multi-engine aircraft with a reciprocating engine (MEP), or with a single-engine turbine aircraft (SET). the 1 shows schematically two such non-electric aircraft engines 61, 62 to be simulated, this representation being only an example and alternatively only one aircraft engine to be simulated or more than two aircraft engines to be simulated can be provided.

The system of 1 also includes a plurality of operating elements 31-34, which are designed, for example, in the form of an operating lever or a slide and are used to set the speed or the propeller angle of the propellers 11, 12. There are in the 1 four differently configured man-machine interfaces 9a-9d for the flight pilot (hereinafter referred to as HMI - "Human Machine Interface") shown, which have a different number of controls 31-34 depending on the configuration. That's how it shows in the 1 HMI 9a shown on the left has two operating elements 31, 33. The HMI 9b arranged to the right has only one control element 31 . The HMI 9c arranged to the right has four operating elements 31-34. The right-hand HMI 9d in turn has two operating elements 31, 32.

In addition to the operating elements 31-34, each HMI 9 includes displays, switches and/or measuring devices 91, 92 shown schematically, which are typically present in a cockpit and can be operated and/or read by a pilot. The displays also include a separately shown speed display 95.

The operating elements 31-34 are, in the illustrated embodiment, but not necessarily, integrated into physically interchangeable engine control scenes 81-84. The interchangeable engine control scenes 81-84 allow the number of operating elements 31-34 required for this type of aircraft to be provided in the HMI 9 in a simple manner for flight with a selected aircraft type which corresponds to a simulated aircraft configuration. The control link 81 thus includes an operating lever. The control link 82 includes two operating levers 31, 33. The control link 83 includes four operating levers 31-34 and the control link 94 includes two operating levers 31, 32. If no engine control links are provided, it can be provided, for example, that the individual control levers 31-34 can be removed and placed individually.

The HMI 9a-9d is coupled to the electric aircraft engines 1, 2 via a control unit 4. Communication between the HMI 9, the control unit 4 and the electric aircraft drives 1, 2 takes place via a control bus 15. The control unit 4 controls the propeller angle α of the propellers 11, 21 and the speed n of the respective electric motor 12, 22 or Propellers 11, 21. The speed n can be set by directly specifying the speed of the respective electric motor 11, 22 or alternatively by setting the power or the torque of the respective electric motor 11, 22.

The control unit 4 comprises, for example, a processor and a non-volatile storage medium in which computer programs are stored which, when executed by the processor, cause the control unit 4 to take into account control signals which the control unit 4 receives from the HMI 9a-9d, in particular the operating elements 31- 34 receives to control the electric aircraft engines 1, 2 with regard to the speed n and the propeller angle α.

In addition to control signals from the HMI 9a-9d, in particular control signals from the operating elements 31-34, the control unit 4 receives control signals from one or more electrical ignition locks 5, with an electrical ignition lock 5 preferably being assignable to each aircraft engine 61, 62 to be simulated.

The electric ignition lock 5 is used to simulate a magnet check for an aircraft engine 61, 62 to be simulated, an aircraft engine with a piston engine being assumed as the aircraft engine. It is known that piston engines in aircraft engines have dual ignition. Two spark plugs work on each cylinder, independently igniting the air-fuel mixture in the combustion chamber. Before starting, a safety procedure is run through in which the ignition key activates one ignition circuit, then activates both ignition circuits and then activates the other ignition circuit. The speed drop is recorded. With two properly working ignition circuits, the fuel burns much faster than with one. If an ignition circuit fails, the engine no longer delivers full power. If there is no speed drop at all on an ignition circuit during this procedure, this is a sign of a fault and a start should be aborted.

This procedure is simulated by the electric ignition lock 5, which has four different positions for "Off" (position 51), for activating one ignition circuit (position 52), for activating the other ignition circuit (position 53) and for activating both ignition circuits (position 54). The speed represented by the speed display 95 is observed. In internal combustion engines, both ignition circuits are activated by ignition magnets. The procedure is simulated using the electric aircraft engines 1, 2, in which the control unit 4 is designed to simulate the system behavior in the event of a double ignition by reading out the position 51-54 of the electric ignition lock 5 and to indicate a corresponding speed on the speed display 95.

Furthermore, the control unit 4 receives control signals from a battery management system 16 that controls the battery 17 and transmits control signals to the control unit 4 for suitable battery management. Furthermore, the control unit 4 can provide control signals to the battery management system 16 .

The control of the system for simulating different aircraft configurations is explained below using the operating elements 31-34 used by way of example using several exemplary embodiments.

First of all, the configuration according to the HMI 9b is considered, according to which exactly one adjustable operating element 31 is provided. It is envisaged that exactly one non-electric aircraft engine 61 will be simulated. This means that the existing two propellers 11, 21 are mapped onto an aircraft engine 61 to be simulated, with both propellers 11, 21 being driven at the same speed n and with the same propeller angle α, so that a symmetrical thrust is provided and a single-engine aircraft is simulated with a piston engine.

It is obvious that, alternatively, a larger number or just one propeller could also be provided in order to simulate such an aircraft engine 61 .

The speed of the propellers 11, 21, which is identical as explained, is set by the operating element 31, the operating element 31 being designed, for example, as a lever whose position or setting position sets the speed n of the propellers 11, 21 (so-called power lever or thrust lever ). The operating element 31 generates electrical control signals depending on its setting position and transmits them to the control unit 4, which is based on these control signals Speed n of the propellers 11, 21 and thus the thrust of the simulated aircraft engine 61 controls.

In the exemplary embodiment considered, no separate adjustment lever is provided for setting the propeller angle α, so that the control unit 4 sets the propeller angle automatically.

Another exemplary embodiment is the configuration according to the HMI 9a. Here it is provided that the system has, in addition to the operating element 31 for the thrust, another operating element 33 for setting the propeller angle α, which can also be designed as an operating lever or slide. Such a control element can also be referred to as a propeller adjustment lever. It is again assumed that the two existing propellers 11, 21 are mapped onto an aircraft engine 61 to be simulated, with both propellers 11, 21 being driven at the same speed n and with the same propeller angle α, so that a symmetrical thrust is provided.

The additional control element 33 can now also be used to set the propeller angle α. The aircraft behaves like a twin-engine aircraft with a piston engine and variable-pitch propeller. In one embodiment, the propeller adjustment can be operated by the pilot via a constant speed control.

In an embodiment variant it can be provided that the operating element 33 is designed to be lockable. This allows the configuration according to HMI 9b to be produced in a simple manner.

Another exemplary embodiment is the configuration according to the HMI 9c, according to which four different operating elements 31-34 are provided. It is provided that the two propellers 11, 21 simulate two different aircraft engines 61, 62. Accordingly, each propeller 11, 21 simulates an aircraft engine 61, 62. However, this is only to be understood as an example. For example, it could alternatively be provided that a total of four or six electric aircraft engines with controllable pitch propellers are provided, with two or three propellers then simulating an aircraft engine 61, 62.

Again, the control unit 4 is programmed and designed in such a way that the propeller or propellers simulating an aircraft engine 61, 62 are driven at the same speed n and at the same propeller angle α, so that for each simulated aircraft engine a thrust can be defined. This simulates a twin-engine piston aircraft.

The operating element 31 is used to set the speed of one propeller 11 and thus to simulate the thrust of one simulated aircraft engine 61. The other operating element 32 is used to set the speed of the other propeller 21 and thus to simulate the thrust of the other simulated aircraft engine 62. For this purpose, the operating elements 31, 32, as explained, generate control signals to the control unit 4 according to their current position.

The two other controls 33, 34 are used to set the propeller angle of the two propellers 11, 21. The propeller angle of the propeller 11 and thus the propeller angle of the simulated aircraft engine 61 is set via the control element 33. The propeller angle of the propeller 12 and thus the propeller angle of the simulated aircraft engine 62 are set via the operating element 34 .

A variant embodiment of this provides that the operating elements 33, 34 for setting the propeller angle are designed to be lockable. As a result, the HMI 9a with two operating levers can be simulated in a simple manner with the HMI 9c with four operating levers.

The HMI 9d shows an embodiment variant in which only two power levers 31, 32 are provided, with which the speed n of one propeller 11 and the speed n of the other propeller 21 is controlled. The propeller angle is set automatically by the control unit 4 .

The configuration of the HMI 9d is particularly suitable for simulating aircraft engines 61, 62 designed as gas turbine engines. Gas turbine engines are characterized by a time-delayed response to cessation of thrust. Here it is provided that the system can be configured for two modes, a piston engine mode in which the control signals generated by the operating elements 31-34 cause the propellers 11, 12 to be controlled without a time delay, and a gas turbine mode which defines the activation Delay profiles in the control unit 4 triggers. The deceleration profiles cause the response of the electric engines 1, 2 to correspond to the response of a gas turbine engine. In this way, the more sluggish behavior of gas turbine engines can be simulated.

The setting of a gas turbine mode can be configured before the electric aircraft takes off, for example via the HMI 9d.

It is provided that on the control levers or thrust levers 31, 32 each have a manual emergency operation is arranged in the form of a button 7 or the like. When the emergency control 7 is actuated, the system automatically switches back from the gas turbine mode to the piston engine mode, so that the propellers 11, 21 can respond as quickly as possible. This is a safety feature to be able to use the full power of the engines 1, 2 in dangerous situations.

The manual emergency actuation can also be implemented in a different way than by a separate operating element 7 . For example, it can be provided that the manual emergency actuation is triggered when one of the operating levers 31, 32 is moved to its end stop.

the 2 12 illustrates the method steps that are carried out by the control unit 4. The procedural steps generally serve to adjust the existing propellers 11, 21 with regard to speed n and propeller angle α on the basis of the control signals generated by the operating elements 31-34, 5.

According to step 201, the given M propellers 11, 21 are mapped onto K aircraft engines 61, 62 to be simulated, where K≧1 and K≦M. According to step 202, the propeller or propellers 11, 21, which form an aircraft engine 61, 62 to be simulated, are each driven at the same speed n and the same propeller angle α. If several propellers form an aircraft engine to be simulated, these propellers are therefore driven at the same speed n and with the same propeller angle α.

According to step 203, for each aircraft engine 61, 62 to be simulated, the speed of the propeller or propellers 11, 21, which form the aircraft engine to be simulated, is set by the setting position of one of the N operating elements 31, 33. This simulates the thrust of the aircraft engine 61, 62 to be simulated.

According to step 204, for each aircraft engine 61, 62 to be simulated, the propeller angle α of the propeller or propellers 11, 21, which form the aircraft engine 61, 62 to be simulated, is set by the setting position of a further operating element 31, 33 or automatically. This sets the propeller angle of the aircraft engine 61, 62 to be simulated.

According to step 205, the method can be carried out consecutively for different aircraft configurations which differ in the number and/or the type of aircraft engines 61, 62 to be simulated.

It should be understood that the invention is not limited to the embodiments described above, and various modifications and improvements can be made without departing from the concepts described herein. It is further pointed out that any of the features described can be used separately or in combination with any other features, provided they are not mutually exclusive. The disclosure extends to and encompasses all combinations and sub-combinations of one or more features described herein. If ranges are defined, these include all values within these ranges as well as all sub-ranges that fall within a range.

Claims (20)

System for simulating different aircraft configurations with an electric aircraft, which has M propellers (11, 21) each driven by an electric motor (12, 22), M ≥ 1, the propeller blades (110, 210) of the propeller (11, 21) each having one having an adjustable propeller angle (α), characterized by - N adjustable operating elements (31-34, 5), N ≥ 1, which generate control signals depending on their setting position, - a control unit (4) which is designed to, on the basis of the control signals generated by the N operating elements (31-34, 5) to control the M propellers (11, 21) with regard to speed (n) and propeller angle (α), the control unit (4) being designed to ○ the M propellers ( 11, 21) to map aircraft engines (61, 62) to be simulated on K, K ≥ 1 and K ≤ M, ○ the propeller or propellers (11, 21), each of which forms an aircraft engine (61, 62) to be simulated, with the drive the same speed (s) and for this the same Adjust the propeller angle (α), ○ for each aircraft engine (61, 62) to be simulated, the speed (n) of the propeller or propellers (11, 21), which form the aircraft engine (61, 62) to be simulated, by the setting position of one of the Set N controls (31, 33), and ○ for each aircraft engine (61, 62) to be simulated, the propeller angle (α) of the propeller or propellers (11, 21) that form the aircraft engine (61, 62) to be simulated, by the Setting position of another control element (31, 33) or set automatically. system after claim 1 , characterized in that the M propellers (11, 21) precisely simulate an aircraft engine (61), K = 1, with an adjustable first control element (31) being provided, the setting position of which determines the speed (n) of the propellers (11, 21 ) sets. system after claim 2 , characterized in that the propeller angle (α) of the M propellers (11, 21) is automatically adjusted by the control unit (4). system after claim 2 , characterized in that the system has an adjustable second control element (33), the adjustment position of the second control element (33) defining the propeller angle (α) of the M propellers (11, 21). system after claim 4 , characterized in that the control unit (4) is designed to regulate the propeller (11, 21) by changing the propeller angle (α) to a constant speed (n). system after claim 4 or 5 , characterized in that the second operating element (33) can be locked, for which case the propeller angle (α) of the M propellers (11, 21) is automatically adjusted by the control unit (4). system after claim 1 , characterized in that the M propellers (11, 21) simulate two aircraft engines (61, 62), K = 2, where M ≥ 2 and - the M propellers (11, 21) on two aircraft engines (61, 62 ) are mapped, - two adjustable operating elements (31, 32) are provided, the setting position of one operating element (31) determining the speed (n) of the propeller or propellers that form the one aircraft engine (61) to be simulated, and the setting position of the other operating element (32) determines the speed(s) of the propeller(s) forming the other aircraft engine (62) to be simulated. system after claim 7 , characterized in that the propeller angle (α) of the M propellers (11, 21) by the control unit (4) on the one hand for the propeller or propellers that form the one aircraft engine (61) to be simulated, and on the other hand for the or the Propellers, which form the other aircraft engine to be simulated (62), is automatically adjustable. system after claim 7 , characterized in that the system has two further adjustable operating elements (33, 34), the propeller angle (α) of the one or more propellers forming the one aircraft engine (61) to be simulated being adjusted via the setting position of one further operating element (33), can be defined and the propeller angle (α) of the propeller or propellers that form the one aircraft engine (62) to be simulated can be defined via the setting position of the other additional control element (34). system after claim 9 , characterized in that the two further adjustable operating elements (33, 34) can be locked, for which case the propeller angle (α) of the respective propeller (11, 21) can be automatically adjusted by the control unit (4). System according to one of the preceding claims, characterized in that the system can be configured for two modes, firstly a piston engine mode in which the control signals generated by the N operating elements (31-34) control the propellers (11, 21) without Cause time delay, and on the other hand a gas turbine mode, wherein the control unit (4) is designed to implement defined delay profiles in the control of the propellers (11, 21) in the gas turbine mode. system after claim 11 , characterized in that the system has a manual override, upon actuation of which the system, in the event that it is in gas turbine mode, is transferred to piston engine mode. system after claim 12 , characterized in that the manual emergency actuation can be triggered by a separate operating element (7) or by one of the operating levers (31-34) being moved to an end stop. System according to one of the preceding claims, characterized in that the control unit (4) is also designed to carry out a magnet check for each aircraft engine to be simulated, taking into account at least one ignition lock operating element (5) which has different positions (51-54). (61, 62), the control unit (4) being designed to simulate the system behavior in the case of a single ignition or in the case of a double ignition by reading out the position (51-54) of the ignition lock operating element (5). System according to one of the preceding claims, characterized in that the N adjustable operating elements (31-34) are provided in the form of different, interchangeable control links (81-84) which have a different number of mechanically actuatable operating elements (31-34), at least one control link (81) with an operating element (31) and one control link (82, 84) with two operating elements (31, 33; 31, 32) being provided. System according to any one of the preceding claims, characterized in that the system is a man-machine interface (9a-9d) which, in addition to the N operating elements (31-34), comprises a configurable display, the display showing displays, switches and/or measuring devices (91, 92) and/or providing them for operation. system after Claim 16 , characterized in that the configurable display has a representation (95) of the speed (n) of a simulated aircraft engine (61, 62). System according to one of the preceding claims, characterized in that the control unit (4) is also designed to receive control signals from a battery management system (16) and to take them into account when controlling the propellers (11, 21). Method for simulating different aircraft configurations with an electric aircraft which has M propellers (11, 21) each driven by an electric motor (12, 22), M ≥ 1, the propeller blades (110, 210) of the propeller (11, 21) each having one having an adjustable propeller angle (α), the method comprising: - Control on the basis of N controls (31-34, 5) generated control signals, the M propeller (11, 21) in terms of speed (n) and propeller angle (α), where - the M propellers (11, 21) are mapped to K aircraft engines (61, 62) to be simulated, K ≥ 1 and K ≤ M, - the propeller or propellers (11, 21), which each form an aircraft engine (61, 62) to be simulated, are driven at the same speed (n) and the same propeller angle (α) is set for them, - for each aircraft engine (61, 62) to be simulated, the speed of the propeller or propellers (11, 21) forming the aircraft engine to be simulated is set by the setting position of one of the N operating elements (31, 33), and - for each aircraft engine (61, 62) to be simulated, the propeller angle (α) of the propeller or propellers (11, 21) forming the aircraft engine (61, 62) to be simulated, by the setting position of another of the N controls (31, 33 ) or set automatically. Computer program with program code for carrying out the method steps claim 19 , when the computer program is executed in a computer.

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