EP1677592A1

EP1677592A1 - Method and device to drive away birds

Info

Publication number: EP1677592A1
Application number: EP04766372A
Authority: EP
Inventors: Andreas Guenther; Johann Landmann; Andreas Hilburg
Original assignee: Individual
Current assignee: Individual
Priority date: 2003-08-06
Filing date: 2004-07-29
Publication date: 2006-07-12
Also published as: WO2005013686A1; DE10336406A1

Abstract

The invention relates to a device and to a method to drive away birds, especially pigeons, by generating a magnetic field. In order to develop a device and a method of said type which drives birds away in an optimum manner, a winding (1) of an electric conductor comprising at least one coil (2,3,4) is disposed on the area where the birds are to be driven away from, and a current, especially an alternating current, is fed into the electric conductor through an electric control device (7).

Description

Description METHOD AND DEVICE FOR DISPLACING BIRDS Technical environment

The invention relates to an apparatus and a method for driving away birds, especially pigeons, by generating a magnetic field.

Various pigeon dropping devices and methods have been proposed to reduce or prevent damage to buildings or health damage to residents of buildings from excretions of these birds. For example, the publication DE 100 45 629 AI suggests arranging electrically conductive wires on an insulating base, which are fed with a high pulse voltage but low current by means of a voltage clock generator. Similar to an electric pasture fence or electric fence for hoofed animals, the birds are kept away from the electric conductors by electric shocks. The disadvantage is that the electric shock can also disturb other living things such as pets and people.

A device for generating a magnetic field scaring the birds is known for example from the publications EP 0 651 944 B1 and EP 0 781 507 B1. Magnetic parts are attached to movable supports here. The magnetic parts generate a static magnetic field, which at most varies slightly due to the movement of the magnetic parts on the movable supports. The sense of orientation of the pigeons, which is sensitive to the earth's magnetic field, is stimulated by the magnetic field generated by the magnetic parts. Most pigeons find such a stimulus uncomfortable and avoid the presence of these magnetic fields. However, there is a risk that certain animals are insensitive to the magnetic fields generated by the magnetic parts and cannot be deterred by such a scaring device with a static magnetic field. Disclosure of the invention

The object of the invention is to provide an apparatus and a method with an increased effectiveness in driving out birds, especially pigeons.

This object is achieved in that the to drive out birds, especially pigeons, has a winding of an electrical conductor with at least one turn, which is attached to the place from which the birds are to be driven, and further an electrical Has control device which feeds a current, in particular an alternating current, into the electrical conductor.

[006] Accordingly, a method for driving out birds solves, in particular Pigeons, the task by the following steps: - Attaching a winding of an electrical conductor with at least one turn in a place from which the birds are to be driven out, and - Feeding a current into the electrical conductor.

As is known, current flows through conductor windings generate a magnetic field by magnetic induction. This effect is used in electrical engineering e.g. used in a component known as a "coil". In the present case, one or more conductor windings are attached to the place that is to be freed from pigeons. By feeding in a current, preferably an alternating current, which changes over time, a magnetic field is induced which excites the sense of orientation of the pigeons, which is sensitive to the earth's magnetic field. By using a conductor winding to generate a magnetic field by means of a current flowing through the conductor, the strength of the magnetic field can be predetermined by the current flowing through the conductor winding and, if necessary, can be varied in time. The course of the field strength of the magnetic field can be optimized in such a way that the effect is as disruptive as possible for the birds to be driven away.

[008] An alternating current with strong, high-frequency signal components is preferably fed in. A signal with steep changes in slope, i.e. sharp kinks in the signal curve usually have very pronounced high-frequency components in frequency analysis. It can be assumed that a change in the strength of the magnetic field which is generated by such a current signal and which results from the strong changes in the current signal particularly disturbs pigeons. For example, the voltage profile of the alternating current can have a triangular shape (sawtooth voltage) or a rectangular shape. The voltage curve can be impressed arbitrarily by modern converter technology in order to generate a signal that is most effective for the birds to be scared away, i.e. has the greatest deterrent effect.

To modulate the alternating current signal, a modulation circuit (converter) can be provided in the control unit, which enables the generation of various types of signal curves according to the known converter technology. The control device can preferably be controlled digitally.

In practice, the conductor winding can have a modular structure and preferably has a plurality of turns. In particular, the use of a construction of the conductor winding in practice is proposed which consists of several modules, each module having a number of conductor sections which corresponds to the number of turns. Two complementary parts of a plug connection can be attached to the two ends of each module, by means of which the modules can be fastened to one another and the conductor sections of the modules conductively to one another are connectable. In a practical embodiment, one end of a module has a plug arrangement and one end of a module has a socket arrangement for receiving the plug arrangement, so that any number of modules can be connected in series to create a winding of the desired size. In practice, a connector is provided through which ends of the conductor winding can be connected to the control device. The connection piece has at a printed circuit multi-turn winding comprises: - an input terminal that is conductively connected to the initial section of the first turn - pus bridge I _^, by - an output terminal which is electrically connected to the end portion of the last turn, and an end portion of one turn is connected to the start portion of the next turn.

In practice, the control device can be connected to a rechargeable battery (accumulator) which forms the voltage source and current source for the control device. The accumulator can be charged by a solar cell arrangement. Alternatively, the control unit can be fed via the public power grid. Brief description of drawings

[013] Embodiments of the invention will be described below with reference to the accompanying drawings. The drawings show in: FIG. 1 a schematic diagram of the structure of a device according to the invention, FIG. 2 exemplary signal profiles for the voltage of the excitation current of the device, FIG. 3 various further examples for a possible signal profile of the excitation current, FIG. 4 a plan view of a conductor track module the device according to the invention,

FIG. 5 shows a circuit diagram of the conductor track module from FIG. 4; 6 shows a plan view of a connecting piece of the device according to the invention and FIG. 7 shows a circuit diagram of the connecting piece from FIG. 6.

The device according to the invention and shown in FIG. 1 for scaring away pigeons consists of a winding 1 which comprises three turns 2, 3, 4 of an electrical conductor. The beginning section 5 of the first turn 2 and the end section 6 of the last conductor turn 4 are each connected to a connecting terminal of a control device 7.

The control unit 7 feeds an alternating current into the conductor windings 2, 3, 4 Winding to generate a dynamic, ie time-varying magnetic field. The control unit 7 is connected to a current source 8. In the present case, the public electricity supply network is used as the current source 8. As an alternative to the power supply network, a rechargeable battery (accumulator) can also be used as the power source 8. The rechargeable battery can be powered by solar cells.

The control unit 7 is a programmable converter which can generate a suitable alternating current from the current of the current source in order to generate the desired magnetic field. A digitally programmable converter is preferably used, the signal curve of which can be freely selected within wide limits.

The winding 1 is laid at the location from which the pigeons are to be driven out. These are in particular balconies, window sills, roof areas and similar building areas. By feeding a current into the conductor turns 2, 3, 4 of the winding 1, a magnetic field is created in the vicinity of the winding 1, in particular in the area surrounded by the winding 1. The senses of pigeons, which detect the earth's magnetism, are sensitive to this magnetic field. If the area from which the birds are to be kept is too large to generate a sufficiently strong magnetic field with one winding, a plurality of windings 1 can be provided distributed over this area.

2 shows, by way of example, signal profiles of the voltage of the electrical current which is fed into the winding 1 by the control device 7. It is not necessary to continuously generate a magnetic field. The alternating current can be fed into the winding 1 by the control device 7 in order to generate the magnetic field in pulses with several voltage oscillations. The pulse duration can be a few seconds. The time interval between two pulses can be several seconds or even minutes. Despite the pauses between the impulses, the magnetic field is sufficient to keep the building structure free from birds. As a rule, the birds memorize the places where they are disturbed. Even if a bird settles in one place with the device according to the invention in a pulse pause, it will be driven away by the next magnetic pulse after a few seconds or a minute or two.

2 also shows that different pulse shapes can be used and combined with one another. The first two voltage pulses shown have a rectangular waveform and, for example, comprise two periods. In practice, it will usually be necessary to feed pulses with several periods. The last pulse shown has a sawtooth-shaped voltage curve. Both waveforms are only shown as examples. The actual voltage curves of the feed current for the electrical winding 1 can deviate widely from those shown in FIG. 2.

3 also shows an example of a number of alternative possibilities for the voltage profile, which can be both single-phase and two-phase. In addition to the sawtooth shape and the rectangular shape, an exponentially increasing sawtooth, a trapezoidal shape, a direct current, signals in the form of an isosceles triangle, sinusoidal shape and composite shapes are shown. The signal shape should be selected depending on the sensitivity of the birds to different dynamic magnetic field strength profiles and also depending on the impedance of the winding 1 itself. By combining different pulse shapes, different characteristics of the magnetic field can be realized, which are particularly disturbing for a certain group of birds. This increases the reliability and effectiveness of the device.

In the case of new construction measures or renovation measures, the winding 1 can be integrated into the structure of a building. For example, cable ducts in which the windings 1 are laid can be provided in floor or roof surfaces. The windings 1 can also be integrated directly into a building structure such as a screed or a roof surface.

In another practical alternative, the winding 1 is designed as a retrofittable component which can be attached to the affected building structure and removed again. A winding which can be attached and removed in this way preferably consists of several modules which can be connected to one another.

4-7 show the components of a modular system according to the invention for producing the winding 1. FIGS. 4 and 5 show a module 9, which consists of a certain length of a flat cable 10, in the insulation 3 conductor sections 2 ' , 3 ', 4' are embedded. Parts 11, 15 of a plug connection are attached to the two ends of the flat cable 10. The first plug part 11 has three electrically conductive plug contacts 12, 13, 14. The plug contacts 12, 13, 14 are also called contact pins and consist of electrically conductive metal. The plug contacts 12, 13, 14 are electrically conductively connected to the conductor sections 2 ', 3', 4 '. The second socket part 15 has three contact sockets 16, 17, 18, which are electrically conductively connected to the other ends of the conductor sections 2 ', 3', 4 'of the flat cable 10. The contact sockets 16, 17, 18 also consist of electrically conductive metal. The plug part 11 and the socket part 15 are shaped such that the plug contacts 12, 13, 14 of a module 9 can be inserted into the contact sockets 16, 17, 18 of a second module. The plug-in part 11 and the socket part 15 can preferably be firmly connected to one another, for example screwed together or positively connected to one another via other connecting elements (notches, holding brackets etc.).

[024] For arranging the device according to the invention on a surface with a certain size, the required number of modules 9 are connected to one another via their plug connection parts 11, 15. The flat cable 10 is sufficiently flexible to be laid along any contours of the place to be protected from the birds. A connection piece 19 is provided for connecting the winding thus formed to the control unit 7.

The connector 19 is shown in Fig. 6. It consists of a housing 20, the first end of which forms a plug part 21 with three plug contacts 22, 23, 24 and the second end of which forms a socket part 25 with three plug sockets 26, 27, 28. With the plug part 21 of the connector 19, the socket part 15 of the first module 9 is connected. With the socket part 25 of the connector 19, the plug part 11 of the last module 9 of the winding 1 is connected.

Furthermore, the connection piece 19 has two further plug contacts 29, 30, which form the input connection and the output connection of the connection piece 19. The input connection 29 is connected to a first terminal of the control device. The output connection 30 is connected to a second terminal of the control device.

Fig. 7 shows the connection of the various contacts of the connector 19. The input terminal 29 is connected to the start section 5 of the first turn 2 of the winding (see Fig. 1) via the plug contact 22. The output connection 30 is conductively connected to the end section 6 of the last turn 4 of the winding (see FIG. 1) via the contact socket 28. The end of the first turn 1 leads to the contact socket 26, which is connected to the plug contact 23 via a conductor bridge 31. The second turn 3 (FIG. 1) is connected to the plug contact 23. The end of the second turn 3 (FIG. 1) is connected via the contact socket 27 and a conductor bridge 32 to the plug contact 24, which is connected to the start of the third turn 4.

The conductor bridges 31, 32 are attached within the housing 20 of the connector 19. The housing 20 and the parts 11, 15, 21, 25 of the plug connections are preferably designed to be sealed, so that they are protected against moisture and weather influences.

Reference symbol list: 1 winding 2 conductor turn 2 'conductor section 3 conductor turn 3' conductor section 4 conductor turn 4 'conductor section 5 initial section End section control unit power source module flat cable plug part plug contact plug contact plug contact socket part contact socket contact socket contact socket connection piece housing plug part plug contact plug contact plug contact socket part contact socket contact socket contact socket plug contact, input connection plug contact, output connection 1 conductor bridge conductor bridge

Claims

Expectations

Device for expelling birds, especially pigeons, by generating a magnetic field, characterized by a winding (1) of an electrical conductor with at least one turn (2,3,4), which is attached to the place from which the birds to be sold, and by an electrical control unit (7) which feeds a current, in particular an alternating current, into the electrical conductor.

Device according to claim 1, characterized in that the alternating current is fed in as a signal with strong high-frequency components.

Device according to claim 1 or 2, characterized in that the voltage profile of the alternating current has a triangular or sawtooth shape.

Device according to claim 1 or 2, characterized in that the voltage profile of the alternating current has a rectangular shape.

Device according to one of the preceding claims, characterized in that the control device (7) has a modulation circuit for modulating the AC signal.

Device according to one of the preceding claims, characterized in that the control device (7) is digitally controllable.

Device according to one of the preceding claims, characterized in that the conductor winding (1) is of modular construction.

Device according to one of the preceding claims, characterized in that the conductor winding (1) has a plurality of turns (2,3,4).

Apparatus according to claim 7 and 8, characterized in that a certain number of turns (2,3,4) from modules (9) with said number of corresponding conductor sections (2 ', 3', 4 ').

Device according to claim 9, characterized in that two complementary parts (11, 15) of a plug connection are attached to the two ends of each module (9), by means of which the modules (9) can be fastened to one another and the conductor sections (2 ', 3 ', 4') of the modules (9) can be conductively connected to one another.

Device according to one of claims 7 to 10, characterized in that it comprises a connecting piece (19) through which two ends of the conductor winding (1) can be connected to the control device (7).

Device according to claim 11, characterized in that the connecting piece (19) has the following: an input connection (29) which is conductively connected to the initial section (5) of the first turn (2), - An output terminal (30) which is conductively connected to the end section (6) of the last turn (4), - and conductor bridges (31, 32) through which an end section of one turn (1 or 2) with the beginning section of the next Winding (2 or 3) is connected.

[013] Device according to one of the preceding claims, characterized in that the control device (7) is connected to an accumulator as a voltage source.

Device according to spoke 13, characterized in that the accumulator is charged by at least one solar cell.

A method for driving away birds, in particular pigeons, by generating a magnetic field, characterized by the following steps: - applying a winding of an electrical conductor with at least one turn to the place from which the birds are to be driven, and - feeding a current , in particular an alternating current, in the electrical conductor.

[016] Method according to claim 15, characterized in that, for attaching the conductor winding, several modules (9) are connected to one another, which have individual conductor sections. [017] The method of claim 15 or 16, characterized in that a control device is connected to the electrical conductor, which feeds the alternating current.