The invention relates to a detector for small animals, comprising a trigger mechanism and a transmitter actuated by the trigger mechanism for transmitting a detection signal to a monitoring centre.
DE 20 2004 013 928 describes a detector of this type that is configured as a trap. When an animal actuates the trigger mechanism, it will be caught in the trap. In case of a life trap, it must be assured that the animal is attended to in reasonable time so as to prevent the animal from unduly suffering or starving in the trap. The transmitter has the purpose to send an alarm signal to the monitoring centre so as to alert the personnel in the monitoring centre to free the animal from the trap.
It is an object of the invention to provide a detector that can be installed in arbitrary places, regardless of whether or not an electrical power net is available, and which functions with high reliability and requires only little maintenance effort.
In order to achieve this object, according to the invention, the detector comprises a mechano-electrical transducer that is driven by the trigger mechanism and the energy of which powers the transmitter.
Mechano-electrical transducers are known per-se, for example in the form of dynamos, piezoelectric transducers and the like, and they have been used among others in theft protection systems. In the detector according to the invention, such a transducer provides the electric energy that is needed for powering the transmitter. The mechanical energy for driving the transducer is provided by the trigger mechanism. Thus, it is assured that the transmitter will be supplied with energy and will be ready to operate whenever an animal has been detected and a corresponding detection signal or alarm signal is to be sent to the monitoring centre.
The autonomous power supply for the transmitter has the advantage that no electrical power network needs to be available at the place where the detector is to be installed, and no batteries are needed, neither, so that costs for obtaining the batteries, checking the load condition thereof and for disposing used batteries can be avoided.
More specific optional features of the invention are indicated in the dependent claims.
The detector may be used just for detecting the presence of small animals, especially pest, such as mice, rats and the like, e.g. for the purpose of confirming and certifying that the location where the detector or a plurality of detectors have been installed, e.g., a food processing plant, is pest free.
In another embodiment, the detector may be configured as a trap in which the animal that triggers the detector will automatically be trapped.
The trigger mechanism may be so configured that the weight or the movements of the animal are utilised for providing the mechanical energy for driving the transducer. In case of a life trap, it may however be preferable that the trigger mechanism is pre-loaded mechanically by means of a power reservoir, e.g. a spring. In that case, the energy of the power reservoir may be used for driving the transducer and hence for operating the transmitter. Since the trap must be visited by the personnel, anyway, in order to free the trapped animal, it does hardly require any additional effort if the personnel loads the trigger mechanism on that occasion, so that the necessary energy will be stored for the next detection event.
Instead of powering the transmitter directly out of the mechano-electrical transducer, it is also possible to buffer the energy of the transducer in a rechargeable battery. This permits, for example, to equip the trap or the detector with a (GPS) receiver, thereby to enable a remote localisation of the trap or detector and/or to transmit any action commands to the trap. The operating power for the receiver will then also be generated by the transducer.
Possibly, solar cells may be provided for additionally charging the battery. Then, the transducer will assure that, when the detection of an animal has to be signalled, a sufficient amount of energy will in any case be available, irrespective of the illumination condition of the solar cells.
Embodiment examples of the invention will now be described in conjunction with the drawings, wherein:
The tunnel 12 passes through a cellular wheel sluice 14 which, in the example shown, has a cellular wheel 16 with three arms 22 that is rotatably supported on an axle 18. The axle 18 is surrounded by a helical torsion spring 20 which, by means of a locking mechanism that has not been shown, is held in a pre-loaded state in which the cellular wheel 16 is biased in clock sense in
The trigger mechanism 26 further includes a trigger plate 28 that is mounted to be pivotable about a shaft 30 and also passes through a slot in the peripheral wall of the sluice 14 into the interior of the tunnel 12 in such a configuration that it forms part of the bottom of this tunnel. The shaft 30 is the input shaft of a step switch mechanism 32 that may be formed for example by a known ratchet mechanism and has an output shaft 34 that carries a cross with arms 36. One of the four arms of the cross forms the stop 24 for the arm 22 of the cellular wheel.
When an animal, e.g. a mouse, enters into the tunnel 12 and passes over the trigger plate 28, this plate will be tilted downwardly be the weight of the mouse, and the shaft 30 will be rotated accordingly. This causes an advance step of the step switch mechanism 32. In this step, the cross 36 is temporarily set free, so that the stop 24 will yield and the cellular wheel 16 can make a rotation in clock sense under the action of the spring 20. As a result, the mouse that has been present in the tunnel 12 will be caught by the arm 22 and, without being hurt, will be pushed into a space 38 from which it can be removed later after a sliding door 40 has been opened. The output shaft 34 having the arms 36 performs a 90° rotation and is then locked again by the ratchet mechanism in a position in which the next arm of the cross forms the stop 24, and when the cellular wheel 16 has performed a 120° rotation, the next arm of this wheel will be locked at the stop 24. Now, however, the spring 20 will largely be relaxed and must be tensioned again by the maintenance personnel in order for the trap to be ready to operate again.
The mechanical principle of the trap that has heretofore been described has been known as such. The trap that is described here has the particular feature that a mechano-electrical unit 42 has been attached to the casing 10, this unit being configured to transmit a radio signal whenever the trap is triggered. To that end, the unit 42 includes a mechano-electrical transducer 44 that provides the electrical energy for generating the radio signal. A shaft 46 of the transducer 44 extends in parallel with the output shaft of the step switch mechanism 32 through the casing 10 and carries a lever 48 which engages one of the arms 36 of the cross in the condition shown in
In
As soon as the trigger mechanism 26 (
When an animal steps onto the ramp plate 68, this plate will tilt into the position shown in
In a preferred embodiment, the transmitter will emit only a very short radio pulse which does not require much energy and will nevertheless be receivable by a suitable receiver at a distance of 50 to 1000 m from the location of the detector, depending on the presence of buildings or any another obstacles in the environment of the detector.
Thus, in this embodiment, the trigger mechanism does not need to be preloaded again after it has been triggered.
In a modified embodiment, a free end of the ramp plate 68 may rest on the floor (as shown in
Number | Date | Country | Kind |
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20 2008 003 216.4 | Mar 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/001378 | 2/26/2009 | WO | 00 | 8/18/2010 |