EP3365881A1 - Monitoring low-flying airplanes - Google Patents

Abstract

The invention relates to a system for actuating signal transmitters that are arranged on aviation obstacles, which are obstacles for low-flying airplanes, and signal transmitters for optically warning the airplanes or the pilots thereof, having the following features: a) at least one large-area radar system which is designed to detect airplanes flying at very low altitudes and which is arranged at a location remote from the aviation obstacles, b) at least one computer device which is coupled to the large-area radar system so as to transmit signals and which is designed to evaluate the data provided by the large-area radar system, said data relating to detected airplanes, and to provide such data to other systems via a data connection, and c) at least one data connection between the computer device and multiple aviation obstacles and/or groups of aviation obstacles, wherein d) the computer device is designed to output activation signals for the signal transmitters of aviation obstacles which are being approached by an airplane flying at a low altitude on the basis of the data transmitted by the large-area radar system. The invention further relates to a system for providing data relating to airplanes flying at very low altitudes, to a device comprising a signal transmitter device for aviation obstacles, and to a corresponding actuation device.

Description

 Monitoring low-flying aircraft

The invention relates to a system for operating signalers, which are arranged on aviation obstacles, also a system for providing data on aircraft at low altitudes and a device with a signal device for aviation obstacles and a drive device therefor.

In general, the invention relates to the detection of aircraft at low altitudes, e.g. low-flying helicopters or sports aircraft. The acquisition of data of such aircraft and their provision may e.g. be used for the control of signalers at aviation obstacles, i. e.g. the timely switching on of non-permanent firing systems on wind turbines.

There are already proposals, e.g. DE 20 2004 006 595 IM or DE 20 201 1 050 703 U1, to control the firing of wind turbines according to requirements on the basis of the detection of aircraft by a radar system arranged locally in the area of the wind energy plant or a wind energy park. The associated technical and financial effort is relatively high, especially when it comes to a stand-alone wind turbine or small wind farms.

The invention is therefore based on the object to fundamentally improve the detection of low-altitude aircraft in technical and economic terms and to provide advantageous applications thereof.

This object is achieved according to claim 1 by a system for actuating signalers, which are arranged at aviation obstacles, which are obstacles for low-flying aircraft and have signal transmitter for optical warning of the aircraft or its pilots, having the following features:

(a) at least one large-space radar set up to detect aircraft at low altitudes and located at a distance from the aviation obstacles; b) at least one computer device which is coupled to the large-space radar system for signal transmission and is set up to evaluate the data provided by the large-capacity radar system via detected aircraft and to provide such data to other systems via a data connection;

c) at least one data connection between the computer device and several aviation obstacles and / or groups of aviation obstacles,

d) wherein the computer device is adapted to emit depending on the data transmitted by the large-capacity radar data Einschaltsignale for the signal generator such aviation obstacles to which an aircraft approaches at low altitudes.

Aviation obstacles in this sense are, for example, wind turbines, in particular their towers and rotors, but also other relatively tall structures, e.g. Skyscrapers, towers and other masts, as well as high-tech equipment such as Cranes. Such aviation obstacles are also referred to as flight obstacles. The aviation obstacles must be marked with signal generators, in particular optical signal transmitters for optical warning of the aircraft or its pilots, in order to avoid collisions. Such signalers are also referred to as a firing system or only as a firing.

A group of aviation obstacles may e.g. to be a wind farm.

In marked contrast to the prior art, this proposes a centralized radar surveillance approach for the detection of aircraft at low altitudes. The large-area radar system essential for the invention can detect very large areas with a single radar station or a few radar stations distributed over a large area to be monitored, which are coupled to one another. For example, with one or two radar stations already a federal state such as Schleswig-Holstein or Lower Saxony can be monitored. But also the airspace monitoring at sea, eg for offshore wind farms, can be essential with the invention be optimized. For example, by means of a single radar station on Heligoland, virtually the entire North Sea area in which offshore wind farms are present or planned can be monitored.

Accordingly, the invention offers the technical advantage over the prior art that less device-related installation and maintenance is required. This is accompanied by significant economic benefits. Due to the centralized arrangement of one or fewer radar stations of the large-capacity radar system, in particular at a remote location of the aviation obstacles, the cost of installation of the system at significantly lower cost per wind farm or per wind turbine is reduced. The maintenance costs are distributed much more, so that the maintenance costs per wind farm or wind turbine are considerably lower. The large-capacity radar system can also be operated by an independent company, which is not operator of wind turbines, and in this way provide the necessary turn-on signals for the signalers of aviation obstacles as a service.

The computing device may be in the form of a single, centralized computing device or as distributed computing devices having multiple individual computers. The computer device or its individual computers can each be spatially and / or functionally assigned to a radar station of the large-capacity radar system, i. be arranged there, they may also be arranged wholly or partly at a remote location thereof.

The data connection between the computer device and the aviation obstacles can be designed, for example, as a WAN connection (WAN - Wide Area Network), eg in the sense of an Internet connection. The connection can also be designed as a direct or indirect radio connection, eg via relay stations. A combination may also be provided, eg WAN links for coupling to an aviation obstruction and / or group of aviation obstacles, and a radio link to another aviation obstruction and / or group of aviation obstacles. According to an advantageous development of the invention, the computer device is set up to monitor different, non-intersecting and non-contiguous geographical areas on aircraft at low altitudes based on the data transmitted by the large-area radar system. This has the advantage that the data can already be preselected via the computer device in order to provide the switch-on signals as needed only for specific aviation obstacles or groups thereof, namely where approaching aircraft are detected at low altitudes.

The computing device may e.g. monitor the area within a given radius around an aviation obstruction or a group of aviation obstacles, and issue a turn-on signal to transducers of such aviation obstacles as an aircraft approaches at low altitudes and reaches the radius. The radius can e.g. 4 km.

According to an advantageous embodiment of the invention, the system has the following features:

a) the computer means is arranged to deliver the turn-on signals to the beacons of such aviation obstacles located in different non-intersecting and non-contiguous geographic areas, b) the computer means being adapted to selectively activate the aviation obstacles beacons in the respective geographic location Depend on whether or not the respective geographical area is approaching a low-altitude aircraft.

This has the advantage that via the computer device, a selective control of the signal generator of aviation obstacles depending on the flight activity in each case based on the geographical area, ie the perimeter, of the respective aviation obstacle can be performed. This allows a central management of the control of the signal generator of widely distributed aviation obstacles. According to an advantageous development of the invention, the computer device is set up to segment the provided data about aircraft in the detected area according to geographical areas and to deliver switch-on signals to individual aviation obstacles and / or individual groups of aviation obstacles due to the segmentation of the data. In this way, the selective control of the signal generator can also be controlled automatically distributed very widely arranged aviation obstacles.

According to an advantageous development of the invention, the computer device is set up to transmit the switch-on signals for the signal transmitters in a security-coded manner, in particular with a code with a changing key. In this way, interception and manipulation of the switch-on signals can be prevented.

In addition to the above-described great technical and economic potential of the invention in the field of actuation of aviation obstruction sensors, the invention is of great importance in providing data on aircraft at low altitudes in a general manner. The above object is therefore also achieved according to claim 5 by a facility for providing data on aircraft at low altitudes, having the following features: a) at least one large-capacity radar system, which is set up for detecting aircraft at low altitudes and arranged at a remote location of aviation obstacles is

b) at least one computer device which is coupled to the large-space radar system for signal transmission and is set up to evaluate the data provided by the large-capacity radar system via detected aircraft and to provide such data to other systems via a data connection;

c) at least one data connection between the computer device and other systems,

d) wherein the computer device is adapted to the other depending on the data transmitted from the large-capacity radar system Information about the presence of low-altitude aircraft in the vicinity of the relevant system.

In this way, the realization of a general information service about flying activities at low altitudes is possible. The computing device may transfer the data to other systems, e.g. through a publicly accessible network, especially the Internet. The data may e.g. be provided as part of a service. The information on the presence of aircraft can be advantageously used by a wide variety of users, e.g. pilots of sports aircraft carrying e.g. the occupancy of one's own flight space can be displayed in real time via a display device carried on the aircraft, in particular at low altitudes. This was not possible with previous radar monitors.

Another advantageous application for the above-explained information service on flight activities is the monitoring of larger bird swarms, especially migratory birds. By means of the large-space radar system, such flocks of birds can reliably be detected. The data obtained from this can be used to temporarily switch off wind turbines in the area of the detected flock of birds, so that they are not dangerous for the birds. In this way, further sites for the construction and operation of wind turbines can be developed, which could not be used for nature conservation reasons.

According to an advantageous development of the invention, the computer device can be set up to give the other systems, depending on the data transmitted by the large-capacity radar system, information about the presence of low-altitude aircraft in the vicinity of the respective system, depending on its current position. For this purpose, an indication of the current position of the respective system to which the information is to be provided is transmitted to the computer device. The computer device compares this position information with the corresponding data of the large-capacity radar system and transfers the other System Information about the presence of aircraft eg within a certain radius of its current position.

According to an advantageous embodiment of the invention, the large-capacity radar system for the detection of aircraft at altitudes is set down to at least 150 m, ie. from an upper detection limit, e.g. at 1000 or 2000 m, down to 150 m. According to an advantageous development of the large-capacity radar system is even set up for the detection of aircraft at altitudes down to 100 m or 50 m. Low-flying helicopters can also be detected in this way.

According to an advantageous development of the invention, the large-capacity radar system, in particular a single radar station of the large-area radar system, is set up to detect an area of at least 5000 km ² . In this way, with a single large-capacity radar system and thus with one or a few radar stations, a large area in the order of a north German federal state can be detected. The radar stations are set up for this purpose at particularly suitable geographical locations, in particular at an elevated position. For this purpose, natural terrain conditions can be used, such as terrain surveys (hills or mountains).

The large-capacity radar system can have a plurality of radar stations, in particular radar stations arranged far apart from each other (more than 100 km distance between the radar stations), which are connected to one another and / or to the computer device for data exchange. The large-capacity radar system may alternatively or additionally also comprise radar stations which are close to each other, e.g. are installed in the middle of the area to be detected.

For the switching signals transmitted by the computer device to an aviation obstacle, their local processing at the aviation obstacle is required. That is, the signaler of the aviation obstacle or a The corresponding signaling device with an electronic control device must be able to recognize and evaluate the switch-on signals. For this purpose, it is possible to upgrade or retrofit the corresponding signal generator or signaling device.

Therefore, the object mentioned in claim 10 is also achieved by a device with a signaling device for aviation obstacles, which are obstacles for low-flying aircraft and signal generator for optical warning of the aircraft or its pilots, wherein the signal generator device at least one electronic control device and at least one by the electronic control device has controlled optical signal transmitter, the device additionally having a drive device which is set up to switch the electrical energy supply of the signal generator device or its electronic control device off and on.

This has the advantage that the up or conversion effort can be minimized to the signalers or signaling devices. These do not have to be newly developed or modified by the respective manufacturer depending on the type and design. Instead, a relatively simple and inexpensive constructed control device in the sense of an intermediate adapter in the electrical power supply of the signaling device or its electronic control device are looped. The function of the signaling device can then be switched off or on by the control unit as needed by controlling the electrical power supply.

The drive device is set up to detect switching-on signals transmitted externally via a data connection and, depending on the switch-on signals, to control the switching off and on of the electrical power supply of the signaling device or of its electronic control device.

According to an advantageous embodiment of the invention, the control device for the simulation of data and / or signals from the signal generator device in supplied with electrical energy supplied state, set up. This has the advantage that error detection can also be intercepted by the control device at the same time as a result of manipulation of the electrical energy supply of the signaling device or of its electronic control device. In this way, unnecessary maintenance costs due to false error messages at the aviation obstacles are avoided.

The drive device can additionally be set up to perform its own error detection and to issue its own error message when an error occurs, e.g. to a control device of the aviation obstacle.

The drive device may additionally be set up to store some or all of the data it receives, in particular the switch-on signals for signal transmitters, for a specific period of time in the sense of a data log.

The object mentioned above is therefore also achieved according to claim 12 by a drive device of a device of the type described above.

According to an advantageous embodiment of the invention, it is provided that the system according to the invention and / or the device according to the invention with the signal generator device has a receiving device for receiving transponder signals from aircraft and is further adapted to receive received transponder signals to supplement the data acquired by the large-capacity radar system for the detection of In addition, use aircraft at low altitudes to deliver turn-on signals to aviation obstacle sensors. In this way, the detection reliability of low-flying aircraft can be further increased, especially in places where shadowing of radar signals is to be expected. Thus, in particular, helicopters that land within a wind farm can be detected with the aforementioned development. The transponder data can also be used to filter out over the identifiable altitude flying aircraft, such as commercial aircraft at cruising altitude or at least over 600 m altitude. In this way, due to the radar data possibly recognized as relevant aircraft, but which are actually located at a higher altitude (so-called false positives), can be reduced and an unnecessarily frequent switching on the signal generator can be reduced.

The transponder signals used for this purpose may be broadcast-transmitted transponder signals, i. no particular request from the transponders emitted signals, e.g. DF17 signals transmitted in service ADS-B. Other transponder signals may also be evaluated, e.g. which are sent on demand, e.g. Transponder signals transmitted by radar signals.

For this purpose, locally in the area of the wind farm, i. be present in the region of the device with the signal generator device and the control device, a receiving device for transponder signals. The receiving device for transponder signals may in particular be part of the drive device. Alternatively or additionally, the system for actuating signalers, which has the Großraumradaranlage, have a receiving device for transponder signals. The transponder signals do not have to be received directly from the system according to the invention or the device according to the invention with the signaling device from the aircraft. Also an indirect reception, e.g. On the provision of transponder data via an Internet service, can be advantageously realized.

According to an advantageous development of the invention, it is provided that the system, in particular its computer device, is set up to output shutdown signals for switching off wind energy plants, depending on the data transmitted by the large-area radar system and / or other aircraft at lowest altitude. Furthermore, the drive device can also be set up to supply the drive device shut off associated wind turbine, at least to the extent that the rotor comes to a standstill. For this purpose, the control unit can receive and use the aforementioned shutdown signals for shutting down wind turbines and / or locally generate such shutdown signals, eg by locally receiving the transponder signals.

The invention will be explained in more detail by means of embodiments using drawings.

Show it

1 shows a plant according to the invention from a bird's eye view and

Figure 2 shows the system with a first embodiment of

 Data transfer and

Figure 3 shows the system with a second embodiment of

 Data transfer and

Figure 4 shows a device with a signaling device and a

 A driving.

In the figures, like reference numerals are used for corresponding elements. In all figures, the system according to the invention and its components are shown schematically.

FIG. 1 shows a system 1 for actuating signalers arranged on aviation obstacles. Appendix 1 may also be used as a facility to provide data on aircraft at low altitudes to provide general information service. Accordingly, the following description applies to both applications. The system 1 has a large-capacity radar system 2, which has three spatially distributed radar stations 21 in the illustrated embodiment. Each radar station 21 has a detection area 20, in which aircraft can be detected at low altitudes by means of radar. By way of example it is shown how the radar stations 21 in a German federal state 5, reproduced here by way of example by the outline of Lower Saxony, can be arranged distributed at great distances from one another in order to monitor a large area with a small number of radar stations, in particular a whole federal state 5 ,

The system also has a computer device 3, which is coupled to the large-capacity radar system 2, so that data collected by the large-area radar system 2 or the individual radar stations 21 can be collected via low-flying aircraft and evaluated in the computer device 3. The computing device 3 is also connected to other systems via a data link, e.g. with aviation obstacles, which are shown in the figure 1 by way of example by spatially distributed wind farms in respective areas 4. In each area 4, one or more wind turbines may be present, each of which is an aviation obstacle and accordingly must have a signal generator for warning aircraft or its pilots.

Visible here is the peculiarity that the aviation obstacles or other facilities that are provided to the data collected by the wide-area radar 2 low-flying aircraft, can be distributed anywhere on the area covered by the large-capacity radar 2, i. in particular not directly or very close to the individual radar stations 21 or the computer device 3 must be arranged. Furthermore, the computer device 3 does not necessarily have to be arranged at one of the radar stations 21, but in individual cases this can be done e.g. also be the case for improved space utilization.

The computer device 3 is set up to emit switch-on signals for the signal transmitters of such aviation obstacles to which an aircraft approaches at low altitudes, depending on the data transmitted by the large-area radar system 2. Alternatively or additionally, the computer device 3 may be adapted to, depending on the Large Area Radar System 2 data provided to one or more other systems to provide information on the presence of low-altitude aircraft in the vicinity of the respective system. For example, the data transmitted by the large-area radar system or the evaluated data provided by the computer device to other users, ie to other systems, can be provided via the Internet.

The nature of the data connection between the radar stations 21 with each other and / or with the computing device 3 as well as the nature of the data connection between the computing device 3 and the other systems or aviation obstacles may basically be of any type, e.g. a wired connection, a wired connection, e.g. using existing infrastructures, even using wireless networks such as of mobile networks (mobile telephone networks).

An exemplary first embodiment of the system 1 according to the invention is shown with reference to FIG. 2, in which the distribution of the switch-on signals provided by the computer device 3 for the beacons of the aviation obstacles takes place in the form of a distribution by means of a web service, eg via a WAN connection. For this purpose, the data obtained with the large-capacity radar system 2 can be supplied to the computer device 3 via an eg. The computer device 3 may have, for example, a redundantly running server that executes a web service. The computer device 3 determines, for example, depending on the location of each monitored area a respective astronomical time and switches via a data link 6, for example in the form of push notifications, the signal generator of aviation obstacles 41, such as wind turbines. For this purpose, each aviation obstacle 41 or at least each group 40 of aviation obstacles 41 must have an appropriate data connection to the data connection 6, eg an Internet connection. This Internet connection can be established via an interface device 8 which is arranged in the area of the aviation obstacles 41 or the group 40 of aviation obstacles 41. The interface device 8 may be, for example, a UMTS modem to the Establish data connection via mobile phone, or a DSL modem or a router to establish a data connection using ADSL. Via this data connection, a drive device 7 coupled to the interface device 8, which, like the interface device 8, is arranged in the area of the aviation obstacles 41 or the group 40 of aviation obstacles 41, can subscribe to a web service from the computer device 3. The computer device 3 can then transmit, for example, cyclically, for example at intervals of 500 ms, the subscribed data or the switch-on signals for the signal transmitters of the respective aviation obstacles 41.

To guard against errors, e.g. in the event of an interruption of the data connection 6, the driver 7 may e.g. determine by a time monitoring that there is a fault, and in such cases, as a precaution, automatically switch on the obstruction of the aviation obstruction.

Figure 3 shows an embodiment of the plant 1 in which the data connection 6 is made by radio communication, e.g. by long distance radio. For this purpose, the computer device 3 is connected to a radio transmitter 9. In addition, e.g. In the area of the computer device 3, a device is arranged which converts the data to be transmitted into a radio telegram. In the area of the respective aviation obstacle 41 or the group 40 of aviation obstacles 41, a respective radio receiver 10 is provided, with which the control device 7 or the control devices 7 is coupled. In contrast to the embodiment according to FIG. 2, no external central infrastructure is necessary in this case. The computer device 3 can accordingly also be distributed in the form of individual computer devices in the area of the respective radar station 21. Similarly, a radio transmitter 9 can be installed directly on the radar 2 and e.g. transmit the necessary data unidirectionally over the data connection 6 via broadcast.

The transmission of the data via the data connection 6 can, for example, be such that cyclically, for example at intervals of 500 ms, a radiotelegram is sent from the radio transmitter 9 to the radio receivers 10. At known Position of the respective radio receiver 10, the radio link can also be designed as a radio link to achieve high ranges.

To achieve a long range, a transmission frequency in the VHF range or at lower frequencies can be used for the radio connection.

FIG. 4 shows by way of example the upgrading of an existing aviation obstacle 41 by means of a drive device 7. The aviation obstacle 41 has a signaling device 43 which has an electronic control device 44 and an optical signal transmitter 45, e.g. in the form of a luminaire. In principle, the signal generator device 43 can deliver the optical warning signals via the signal transmitter 45 autonomously from other devices of the aviation obstacle. In many cases, in particular in the case of wind turbines, the signaling device 43 is coupled via line connections 46, 47 with a monitoring and control system 42 of the aviation obstacle 41. In this way, a security check of the signaling device 43 is carried out by the monitoring and control system 42. For example, the signaling device 43 has an error signal output and / or a warning output, e.g. in the form of floating switching contacts. This allows the monitoring and control system 42 to monitor the correct function and condition of the signaling device 43. In order to upgrade such an existing system for the external control by means of the switch-on signals, which are provided by the computer device 3, it is proposed to loop a drive device 7 into the line connections 46, 47. As a result, the retrofit effort is relatively low, especially since usually electrical connectors on the line connections 46, 47 are present, which can be easily solved and connected to corresponding, compatible trained connectors of the drive unit 7.

The drive device 7 has, for example, a power supply and communication part 71, an electronic control unit 72 and a switching device 73. The drive unit 7, electrical energy and data from the computer device 3 are supplied eg via electrical lines 70. Alternatively or additionally, the drive device 7 may also be coupled to an antenna in order to receive the data transmitted by the computer device 3 wirelessly. In addition, the data received from the computer device 3 are prepared for use in the control electronics 72, for example via a radio modem.

The control electronics 72 controls the switching device 73. The switching device 73 is configured in such a way that the line connections 46, 47 which are separated from one another by the control device 7 can be individually switched on, off and / or switched over, so that all signals provided by the signal generator device 43 , which are normally transmitted to the monitoring and control system 42, can be simulated or can be generated artificially by the drive unit 7. In addition, via the switching device 73, the electrical power supply of the signal generator device 43, which is also supplied via the line connections 46, 47, interrupted or turned on.

The switching device 73 can be designed for this purpose, for example, with appropriate relays, contactors or semiconductor switches.

Claims

claims:

System (1) for the operation of signal transmitters (45), which

 Air obstacles (41) which are obstacles for low-flying aircraft and have signal transmitters (45) for optical warning of the aircraft or its pilots, having the following features:

 (a) at least one large - capacity radar installation (2), designed to detect aircraft at low altitudes and located at a distance from the aviation obstacles (41), (b) at least one computer device (3) connected to

 Large radar system (2) is coupled to the signal transmission and for the evaluation of the large-capacity radar system (2)

 provided data on detected aircraft and for providing such data to other systems via a data link (6),

 c) at least one data connection (6) between the

 Computer device (3) and several aviation obstacles (41) and / or groups (40) of aviation obstacles (41),

 d) wherein the computer device (3) is adapted to, depending on the data transmitted by the large-capacity radar system (2) turn-on signals for the signal generator (45)

 Air obstacles (41) to which an aircraft approaches at low altitudes.

Plant according to the preceding claim, characterized in that the computer device (3) is set up on the basis of the data transmitted by the large-area radar system (2) different, not overlapping and not adjacent to each other

 geographical areas (4) to monitor low-altitude aircraft.

Plant according to the preceding claim, characterized by the following features: a) the computer device (3) is adapted to the

 Turn-on signals for the signal generator (45) such

 Aviation obstacles (41) located in different, non-intersecting and non-contiguous geographical areas (4), where

b) the computer device (3) is adapted to the signal transmitter (45) of aviation obstacles (41) selectively in the respective

 geographical area (4) depending on whether the respective geographical area (4) is approaching a low-altitude aircraft.

Plant according to one of the preceding claims, characterized

in that the computer device (3) is set up to segment the provided data via aircraft in the detected area into geographical areas (4) and on the basis of

Segmentation of data switch-on signals to individual

Aviation obstacles (41) and / or individual groups (40) of

Aviation obstacles (41).

Annex (1) for the provision of data on aircraft in

Lowest altitudes, with the following characteristics:

(a) at least one large - capacity radar installation (2), designed to detect aircraft at low altitudes and located at a distance from aviation obstacles (41), (b) at least one computer device (3) compatible with

 Large radar system (2) is coupled to the signal transmission and for the evaluation of the large-capacity radar system (2)

 provided data on recorded aircraft and

 Providing such data to other systems via a

 Data connection (6) is set up,

c) at least one data connection (6) between the

 Computer equipment (3) and other systems,

d) wherein the computer device (3) is adapted, depending on the data transmitted by the large-capacity radar system (2) the data other systems information about the presence of

 Aircraft at low altitudes near each system. 6. Plant according to one of the preceding claims, characterized

 in that the large-area radar system (2) is set up for the detection of aircraft at altitudes of at least 150 meters. 7. Installation according to one of the preceding claims, characterized

in that the large-area radar system (2) is set up to detect an area of at least 5,000 km ² .

8. Installation according to one of the preceding claims, characterized

 in that the large-capacity radar system (2) has several

 Radar stations (21), which together and / or with the

 Computer device (3) are connected for data exchange.

9. Plant according to one of the preceding claims, characterized

 in that the system (1), in particular its computer device (3), is set up in dependence on that of the

 Großraumradaranlage (2) transmitted data and / or other

 Aircraft at lowest altitude characterizing data

 Release shutdown signals for switching off wind turbines.

10. A device with a signaling device (43) for aviation obstacles (41), which are obstacles for low-flying aircraft and

Signaling device (45) for visual warning of the aircraft or its pilots, wherein the signaling device (43) at least one electronic control device (44) and at least one by the electronic control device (44) controlled optical signal transmitter (45), characterized in that the device additionally comprises a drive device (7), which is for switching on and off the electrical power supply of the signaling device (43) or by its electronic control device (44) is set up.

Device according to the preceding claim, characterized

in that the drive device (7) is set up to simulate data and / or signals delivered by the signaling device (43) in the state supplied with electrical energy.

Control device (7) of a device according to one of claims 10 to 11