DE4013921C1 - Air pressure measuring device for aeroplane - has infrared energy source e.g. laser diode with driver feeding converter e.g. solar cell and storage capacitor - Google Patents

Abstract

The air manometer has a piezo-electric sensor (6) which is towed by a connecting fibre optic cable (3,5). Sensor signals are frequency modulated (7), pulsed by a transmitter (8) and fed by a cable (3,5) to the receiver (9) for demodulation and presentation by a processor (4). An infra-red energy source (10) eg a power led or laser diode with driver (11) feeds converter (12) which can be a solar cell and storage capacitor (13) for energization of the complete manometer (1) via cable (3,5). USE/ADVANTAGE - Enables reliable measurements of external air pressure with minimum volume of equipment and storage space. Lightweight build of remote manometer sensor imposes only small tensile stress in cable during flight. Is largely unaffected by magnetic fields or lightning strokes.

Description

The invention relates to a device for air pressure measurement for aircraft in the form of a towing system, consisting of an air pressure detection system, which Line connected to the plane and one Processing of measured values.

Such devices are used to within Air pressure measuring devices arranged on the aircraft calibrate. This calibration is usually like this carried out that an approximately 90 m long measuring hose, the open in the area of its end facing away from the aircraft is being dragged behind the plane. The opening the measuring hose is therefore outside the essentially caused by the aircraft  Air turbulence. The air pressure is directly the measuring device arranged inside the aircraft fed.

This measurement procedure is cumbersome to do on the one hand lead, on the other hand, it has the disadvantage that for the hose winch and the hose guide a raise space is required.

From US-PS 38 36 841 is a towing system for one Airplane known, with the help of mineral deposits in the Area of an earth's surface can be detected. The towing system generates an electromagnetic for this table field and determines field changes by Interactions with magnetizable parts or through an overlay with other electromagnetic Fields. The measurement is made with the help of a very low temperature chilled dipoles.

From DE-AS 17 73 682 it is known in the area an aircraft pressure measurements using an except half of the aircraft arranged measuring device to take. For this purpose, it is enclosed by a housing provided chamber and in a wall of the Ge houses are entry openings for a transmission static pressure. The openings in the Area of the wall are designed as bores, the longitudinal axes of which oppose those acting on them Air flow are inclined. The device is in in the immediate vicinity of the aircraft in the area an outer skin of the aircraft.

DE-AS 20 54 954 is also a measuring device device for determining the pressure outside a flight known stuff. The arrangement of the Measuring device in the area of an immediate environment  the outer skin of the aircraft. Between the measuring device tion and the outer skin of the aircraft extends just a mast that leads to a rigid connection serving the measuring device with the aircraft and a minimum distance between the measuring device and the aircraft guaranteed.

From DE-PS 29 45 019 it is known an example as used for pressure measurement in a measuring device Subdivide main body and a sensor and a glass between the main part of the device and the sensor Arrange fiber cables for connection. Over the glass Among other things, fiber cables are used for energy supply of the sensor. A conversion of optical energy into electrical energy takes place with the help of a photodiode.

The use of piezoresistive sensors for the printer version is known from DE-OS 38 23 303. These Encoders are used for pressure recording in the area used by motor vehicle tires and are part of a Vehicle monitoring system.

The measuring device known from the prior art conditions are not suitable for the requirements sufficient measurement accuracy as the requirements after avoiding disabilities of aerodyna do not mix properties of the aircraft at one used measuring device. Furthermore is not immediately apparent in what way known from non-generic areas of technology Detailed solutions for devices for measuring air pressure can be used for aircraft.

The object of the present invention is to provide a to improve the direction of the generic type in such a way that air pressure measurement in a simple way  can be carried out and the measuring device only one takes up little storage volume.

This object is achieved in that the air pressure detection is designed as a sensor, one over the fiber optic cable Line with transmitter communicating with a receiver charged and in the area of the aircraft an ener Power supply is arranged over the fiber cable with one in the field of air pressure detection provided energy converter is connected.

The use of one for the occurring tensile load appropriately designed fiber optic cables for further transmission tion of the supply energy and the measurement data made possible light a space-saving accommodation of the device when not in use. In addition, are falsifications effects of the measurement result not expected along the line. The glass fiber rather, cable is both against pressurization as well as against lightning or electromagnetic Insensitive to influences (EMC). Through the energy transfer Carriage from aircraft to air pressure recording can be a lightweight design in the area of air pressure detection  realized and thus a high tensile load on the glass fiber cables can be avoided.

According to a preferred embodiment is pre suggest that in the field of energy supply a the fiber optic cable feeding laser diode is arranged. But it is also possible that in the field of energy supply a high-performance LED is arranged. In particular, it is provided that the high-performance LED a training emitting light in the infrared range having. These components make it easier Way a light feed into the fiber optic cable possible.

It is envisaged that the energy converter as one converting optical energy into electrical energy Solar cell is formed. Beyond that it is advantageous that the energy converter with a memory capacitor is connected.

To ensure low energy consumption it is proposed that the transmitter as a pulse transmitter is trained. It is also contemplated that a measurement signal between the sensor and the transmitter frequency-modulating modulator is arranged.

According to an advantageous further development, it is possible that the sensor is designed as a piezoresistive sensor is.

In addition, it is provided that in the area of Transmitter a transmitter diode feeding the fiber optic cable is arranged.

An embodiment of the invention is in one Block diagram with the essential components of the Device shown schematically.

A device for measuring air pressure consists essentially of an air pressure detection ( 1 ), a line ( 3 ) connecting the air pressure detection ( 1 ) to an aircraft ( 2 ) and a measured value processing device ( 4 ). The line ( 3 ) is designed as a glass fiber cable ( 5 ). The air pressure detection (1) comprises an air pressure detecting sensor (6) and an input connected to the sensor (6) modulator (7), which converts a supplied by the sensor (6) measuring voltage in a transmission signal frequency. The modulator (7) fed with the frequency-modulated signal, a transmitter (8), which feeds the frequency-modulated measurement signal in the glass fiber reinforced fiber cables (5) and decouples the modulator (7) against the fiber-optic cable (5). In the area of the aircraft ( 2 ), the modulated measurement signal is fed to a receiver ( 9 ) connected to the glass fiber cable ( 5 ), which is connected to the measurement value processing ( 4 ).

An energy supply ( 10 ) is arranged in the area of the aircraft ( 2 ) in order to supply the air pressure detection ( 1 ) with energy. The power supply ( 10 ) can be designed, for example, as a laser diode or a high-performance LED, which preferably emits light in the infrared range. The energy supply ( 10 ) is fed by a driver ( 11 ). The energy emitted by the energy supply ( 10 ) is introduced into the glass fiber cable ( 5 ), which is connected to an energy converter ( 12 ) in the area of the air pressure detection ( 1 ). The energy converter ( 12 ) transforms the light energy supplied via the glass fiber cable ( 5 ) into electrical energy. In particular, it is thought to form the energy converter ( 12 ) as a solar cell. To ensure a loadable supply of the sensor ( 6 ) and the modulator ( 7 ), the energy converter ( 12 ) is connected to a storage capacitor ( 13 ), which absorbs energy that is not required at a specific operating time and provides this energy for operating times with increased energy requirements.

The sensor ( 6 ) is designed as a piezoresistive sensor that has a working range of approximately 100 to 1500 mb. The measurement data are transmitted to the aircraft ( 2 ) in pulse mode with approximately 4 to 5 transmissions per second. As a result of this pulse operation, the air pressure detection ( 1 ) has only a low energy requirement, so that an energy output of approximately 5 mW from the energy supply ( 10 ) is sufficient. Before further processing of the measurement signal, demodulation takes place in the area of the aircraft ( 2 ). The frequency-modulated measurement signal is fed into the glass fiber cable ( 5 ) by means of a transmitter diode which is arranged in the region of the transmitter ( 8 ) and which emits light in the infrared region.

Claims (10)

1. Device for air pressure measurement for aircraft in the form of a towing system, consisting of an air pressure detection which is connected to the aircraft via a line and a measured value processing, characterized in that the air pressure detection ( 1 ) is designed as a sensor ( 6 ), One communicates with the transmitter ( 8 ) via the line ( 3 ) designed as a glass fiber cable ( 5 ) and communicates with a receiver ( 9 ), and a power supply ( 10 ) is arranged in the area of the aircraft ( 2 ) and is connected via the glass fiber cable ( 5 ) is connected to an energy converter ( 12 ) provided in the area of air pressure detection ( 1 ). 2. Device according to claim 1, characterized in that in the region of the energy supply ( 10 ) is a fiber optic cable ( 5 ) feeding laser diode is arranged. 3. Device according to claim 1, characterized in that a high-power LED is arranged in the region of the energy supply ( 10 ). 4. The device according to claim 3, characterized net that the high-performance LED a light in Has infrared range emitting training. 5. Device according to one of claims 1 to 4, characterized in that the energy converter ( 12 ) is designed as an optical energy in electrical energy converting solar cell. 6. Device according to one of claims 1 to 5, characterized in that the energy converter ( 5 ) is connected to a storage capacitor ( 13 ). 7. Device according to one of claims 1 to 6, characterized in that the transmitter ( 8 ) is designed as a pulse transmitter. 8. Device according to one of claims 1 to 7, characterized in that between the sensor ( 6 ) and the transmitter ( 8 ) is arranged a measuring signal frequency modulating modulator ( 7 ). 9. Device according to one of claims 1 to 8, characterized in that the sensor ( 6 ) is designed as a piezoresistive encoder. 10. Device according to one of claims 1 to 9, characterized in that in the region of the transmitter ( 8 ) is arranged a fiber optic cable ( 5 ) feeding transmitting diode.