EP3761273A1 - Method for data acquisition and storage for aviation devices and device for carrying out this method - Google Patents

Abstract

The invention relates to a method and a device for data acquisition and storage for aviation equipment, in particular for paragliders. When a flight starts, a time measurement is automatically triggered by means of at least one sensor (8, 9, 10) and stopped again when a landing. In particular by means of a first sensor (8) for measuring a geographical altitude position or the air pressure. In addition, further sensors (9, 10) can be present as brightness sensors and / or vibration sensors. The flight time of all flights is saved. This allows the useful life of this aviation equipment to be determined and recorded. It is also possible to save further data on the aviation equipment, such as test reports or the like.

Description

The present invention relates to a method for data acquisition and storage for aviation equipment, in particular for paragliders. It also relates to an apparatus for carrying out this method.

Essentially, the present case is about aviation sports equipment that has a flying sail and is held in the air by the air flow. These are mainly paragliders and the like. Their flying sails consist of a canopy made of light fabric, which takes on a plump airfoil-like shape due to the ram air of a forward movement. In addition, there are carrying or suspension lines that establish a connection between the pilot's belt and canopy, as well as control lines, with the help of which the canopy can be deformed for the purpose of control. In principle, kites, sails or even balloons are also to be considered as aviation equipment.

Due to the fact that the paragliders are made of extremely light fabric, there is an increased sensitivity compared to aircraft with a fixed wing. This applies to both visible damage, such as cracks caused by vegetation, stones or fences during take-off or landing, as well as compared to damage that is not visible at first glance. Material fatigue due to wear and tear, aging or solar radiation can significantly impair the strength, stability and safety of a paraglider. In order to counter the last-mentioned risks, it is known to test its air permeability or porosity by means of test devices to be attached to the tissue. There was also an unsuccessful attempt to record the period of safe use of a paraglider using a UV strip that is more sensitive than the fabric of the canopy. Ultimately, however, there has so far been no reliable way of determining the specific and extremely safety-relevant service life and stress on a paraglider. However, this information is not only important for the user himself, but also, for example, for a rental company or for a buyer of a used paraglider. Last but not least, also for manufacturers and sellers of aviation equipment, testing bodies, supervisory authorities, insurance companies and associations.

On the basis of these findings, the invention has the task of creating a method and a device for data acquisition and storage for aviation sports equipment, which provide information about their use.

The method according to the invention corresponds to the characterizing features of claim 1. The device is evident from claim 13. Further Advantageous embodiments of the inventive concept are evident from the dependent claims.

By means of the method according to the invention and by means of the corresponding device, the safety-relevant service life of an aviation device, in particular a paraglider, can be determined. Thanks to the other claimed technical features, a distinction can also be made between the pure flight time and the manipulation time on the ground or ground handling. This means that the total flight time, the total ground handling time and the number of flights, even with the respective take-off and landing times, can be recorded and saved. The respective average temperature and / or average humidity per flight could also be recorded.

The device runs automatically and should not be able to be manipulated, that is, it should not be able to be switched on or off manually in order to inadmissibly influence the stored and safety-relevant flight and manipulation time.

In addition, the storage and / or data acquisition can be designed in such a way that data, files or documents belonging to the aviation equipment can be stored. The latter data can be information about the manufacturer, dealer, owner. In addition, the storage of test reports, check protocols, instructions and the like can be made possible by a Appropriate software must be prepared for easy input and filing. This can be done by transferring data via an external device.

The device according to the invention preferably has a second sensor, namely a brightness sensor. It is also advantageous if the device according to the invention has a third sensor, namely a vibration sensor. The device according to the invention can preferably have a temperature sensor and / or a humidity sensor.

Preferred variants of the device according to the invention provide that in addition to the first device on the aviation equipment, a second, external device as well as means for data transmission between these two devices are present, for example via radio technology such as Bluetooth or WLAN. Furthermore, preferred embodiments of the device according to the invention provide that the memory of the first device is designed to store data and / or files that can be transmitted by means of the second device.

Preferred exemplary embodiments of the invention are described in more detail below with reference to the drawing. This shows, purely schematically, the device according to the invention and its mode of operation on an aviation device, in particular using the example of a paraglider.

The aviation equipment, or the paraglider, has a flying sail 1 in the usual form of a canopy made of light fabric. As usual, a top surface 2 and a bottom surface 3 are provided, profile ribs (not shown) being arranged in the cavity in between. Lines 4, 5 and 6, namely gallery lines, catch lines and main lines, lead down to risers (not visible here), where the pilot is during the flight.

The carrying straps and any seat can be detached, for example by means of a snap hook, and are therefore not an integral part of the actual paraglider. Devices arranged on it would therefore not allow any reliable statement about the use of the paraglider per se. Especially not if they can be operated manually.

According to the invention, a first device 7 with at least one sensor 8, 9 and 10 belonging to the device is provided on the aviation equipment or paraglider. Their control or software as well as the storage of the data will be discussed later. The representation is only to be understood as a pure functional diagram. The device 7, including the sensor (s) 8, 9 and 10, is preferably installed directly by the manufacturer of the aviation equipment or the paraglider and in practice does not protrude from the flying sail 1 as shown. The device 7 is smaller in size than drawn and must in no case be the technical and negatively influence the flying behavior of the paraglider through their arrangement, shape or weight. For example, it can have a size of 60 x 60 x 15 mm. The device 7, which is as compact and flat as possible, can be firmly glued to the top surface 2, the position shown here being intended only as an example and not the only possibility. It could advantageously be arranged centrally on the inside in the upper surface 2. The multi-part representation of the device 7 is only used to explain the various functions; in fact, it is more likely to be accommodated in a single, impact-resistant and waterproof housing. Batteries in the form of button cells can be used for power supply and should last 4 - 5 years. However, technical progress can also enable other types of energy supply. An operational reliability of -10 ° C to + 40 ° C is preferred.

The primary task of the sensors is to recognize the use, i.e. the movement, of the aviation equipment. For this purpose there is at least one first sensor 8 on the aviation sports device, with which a time measurement can be triggered, as well as an associated memory. In a preferred and advantageous embodiment, the first sensor 8 is a pressure or air pressure sensor or a suitable measuring device. It is also conceivable to measure a geographic position, in particular the altitude position of the aviation equipment and its change. So any facility would be useful, for example also a geographic location device that can serve this purpose and make movements recognizable.

The first sensor 8 can be used to detect whether a flight is taking place. If the altitude position, here the atmospheric pressure, is constant at first and a peak occurs, i.e. a pressure peak or a measurement deflection, then this is a start movement. If the pressure then becomes constant again, it was just a starting exercise. If the altitude or the pressure changes after this measurement deflection in the positive or negative direction, it is the start of an actual flight. If the altitude or the pressure becomes constant again after a recognized take-off, then this is the landing. The time span between take-off and landing is stored in a memory 11 of the device 7 as a completed flight, the flight time being recognizable in hours and minutes, for example. In addition, the start time and the landing time can also be saved, for example in the form of date and time. It goes without saying that for this purpose the device 7 must have a time measuring device and / or a corresponding software suitable for time measuring.

In order to avoid any incorrect measurements, a second sensor 9 in the form of a brightness sensor can be present. If there is no light, but rather dark, i.e. the aviation equipment or the paraglider is being transported in a vehicle or backpack, the changes in altitude or air pressure detected during this time can be ignored. You are too do not save any further. This saves energy and storage space. In addition, it could be used to measure how long the aviation equipment was exposed to brightness or solar radiation.

A vibration sensor can be provided as the third sensor 10. This recognizes whether the aviation equipment or the paraglider is moved or only stored. No computer or storage capacity is required either. Vibrations in light, but without the corresponding changes in height / pressure, can be viewed and stored as manipulation time on the ground or ground handling.

Other sensors are also conceivable. For example, a temperature sensor and / or a humidity sensor. This could also be used to record and save the temperature and weather conditions under which the flights took place.

It makes sense to make the data recorded by the sensors 8, 9 and 10 and stored in the memory 11 of the first device 7 legible as information by a second external device 12 not connected to the aviation equipment or paraglider. The second device 12 can be a special terminal but also a commercially available communication device, for example a mobile phone with a corresponding app and touchscreen operation.

The memory 11 can contain an EEPROM, that is to say an electronically erasable, programmable read-only memory. Better still an NFC-EEPROM with an NFC, i.e. a non-volatile, electronic memory module. For test and diagnostic purposes, an interface or a serial interface can be provided, via which the first device 7 can be accessed.

For data transmission, the device can alternatively or additionally have a transmission device for short distances using radio technology, for example Bluetooth. A WLAN / LAN is also possible as a third interface, with which data via the second device 12 can also be exchanged with a further, external storage device, namely a database, for example a cloud.

If the further data and files already mentioned are to be able to be stored on the first device 7, up to and including the PDF document, a memory chip or an SD card and a Bluetooth interface are useful.

In terms of software, the equipment and components of the device according to the invention in conjunction with an external database would also enable a signal or a display to be activated when the aviation equipment or the paraglider was reported as stolen. This would not only improve flight security but also theft security.

Another safety-relevant feature could be a passive reflector that can be recognized by search and location devices. In the event of a crash, this would simplify and speed up the search for and location of an injured pilot. Of course, a device for transmitting an emergency signal could also be provided, that is to say a position transmitter, which would be triggered, for example, by the first sensor 8, that is to say the air pressure sensor, and a corresponding control. In general, a position transmitter can also be useful outside of emergencies, for example in connection with a photo or film drone.

Of course, however, it is within the scope of the invention to implement this in detail differently than shown schematically, provided a time measurement, at least one sensor 8 triggering this or a location device and a memory 11 are present. In principle, any combinations of the further features described are possible within the scope of the dependent claims. In particular with regard to the various sensors 8, 9, 10 as well as the data storage and mutual possibilities of data transmission.

In any case, it is ensured in a simple and forgery-proof manner that the data about the aviation equipment or the paraglider and its proper use as well as the period of this use, namely the number and duration of the flights, are stored and can be accessed for control and security purposes.

For safety reasons, the described storage in a memory 11 directly on the aviation equipment itself is to be preferred. An unsolvable arrangement directly on the flying sail 1 most effectively excludes undesired manipulations which falsify the data, since the lines and straps attached to the flying sail 1 are interchangeable.

Theoretically, a largely external storage of at least longer-term data would also be conceivable, but provided that - for example by means of suitable coding - these data can be clearly assigned to a specific aviation equipment. The options for data transmission and storage would be available and have been described.

Legend for the reference numbers

1

Flying sails

2

Top sail

3

Bottom sail

4th

Gallery lines

5

Suspension lines

6th

Main lines

7th

First set-up (on the aviation equipment)

8th

First sensor (altitude or barometric pressure sensor)

9

Second sensor (brightness sensor)

10

Third sensor (vibration sensor)

11

Storage

12

Second facility (external)

Claims (15)

A method for data acquisition and storage for aviation equipment, in particular for paragliders, characterized by a time measurement triggered automatically at the start of a flight by means of at least one sensor (8, 9, 10) and / or at least one location device and by storage of the flight time of all flights with the purpose of determining and recording the useful life of this aviation sports device. Method according to Claim 1, characterized in that the data are recorded in a memory (11) arranged on a flying sail (1) of the aviation sports device. Method according to Claim 2, characterized in that the storage device (11) is arranged in a non-detachable manner on the flying sail (1). Method according to one of Claims 1 to 3, characterized in that the time measurement is triggered and stopped using at least one location device which is designed to locate or measure a geographical position, in particular an altitude position. Method according to one of Claims 1 to 4, characterized in that an air pressure sensor is used as the first sensor (8). Method according to Claim 4 or 5, characterized in that a measurement deflection that has changed compared to a previously constant altitude or a constant air pressure is recorded as a flight start if the altitude or the air pressure subsequently change in a positive or negative direction. Method according to Claim 6, characterized in that a return to a constant altitude or a constant air pressure after a recorded flight start is recorded as a landing and the time span between take-off and landing is stored as a flight that has taken place. Method according to Claim 4 or 5, characterized in that a measurement deflection that has changed compared to a previously constant altitude or a constant air pressure is recorded as a starting exercise if the altitude or the air pressure are constant again after this measurement deflection. Method according to one of Claims 1 to 8, characterized in that a brightness sensor is used as the second sensor (9) with the purpose of determining changes in height or pressure due to transport. Method according to one of Claims 1 to 9, characterized
characterized in that a vibration sensor is used as the third sensor (10). Method according to one of Claims 1 to 10, characterized
characterized in that the recorded flight data, for example also the number of flights with take-off and landing times and the manipulation time on the ground, are transmitted to an external memory by data transmission, the data being either exclusively or additionally stored in the external memory. Method according to claim 11, characterized by a
Transmission of the data encoded in such a way that they can be clearly assigned to a specific aviation equipment. Device for carrying out the method according to a
of Claims 1 to 12, characterized by at least one first device (7) to be arranged on the aviation equipment, having a time measuring device, at least one first sensor (8, 9, 10) and at least one memory (11) for storing the recorded data. Device according to claim 13, characterized in that
that the at least one device (7) has a controller or software for capturing the data and assigning them to flight or manipulation movements of the aviation equipment. Device according to claim 13 or 14, characterized
characterized in that the first sensor (8) is an altitude or an air pressure sensor.

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