DE102020128092A1 - Motion detector with multiple motion sensors - Google Patents

Abstract

Motion detector, in particular for detecting the movement of animals, with a housing, central data processing, an energy store and at least two sensors, characterized in that the sensors are arranged in such a way that they cover a total coverage area that is larger than the coverage area of a single sensor.

Description

The present invention relates to a motion detector for detecting the movement of animals, having a plurality of sensors arranged essentially circumferentially in a housing and having a correspondingly large overall coverage area.

The motion detector according to the invention is particularly suitable for tracking down animals, especially in forestry, when hunting or for photographers. It can be extremely useful for hunters to use motion detectors to detect game in order to be able to monitor a large catchment area at night.

Motion detectors or game detectors for detecting the movement of animals have been known and available for a long time. The solutions available on the market usually have a motion sensor in a housing that can be positioned at a suitable location. The motion detector typically has a coverage area of approximately 90°-120°. Ranges commonly used are around 15 m. With a motion detector with a coverage area of, for example, 112° and a range of 15 m, an area of a good 115 m ² can be monitored.

The housing with the motion sensor is positioned at a point to be monitored and put into operation. The housing is usually attached to a tree for this purpose, for example by hanging it from a branch or by tying it to the trunk of the tree with a strap. As soon as the motion detector detects a movement of a game in its coverage area, the motion detector sends a signal to a receiver via central data processing and a transmitter unit connected to it. This receiver then reproduces a signal recognizable to the user, which is usually optical or acoustic.

The disadvantages of the solutions available on the market are the limited coverage area and the sometimes impractical installation of the motion detectors.

This is particularly disadvantageous when large areas are to be monitored or when the motion detectors have to be moved frequently and only short-term monitoring is required as a result.

The object of the present invention is therefore to provide a motion detector that has an enlarged coverage area, is easy to set up and align and still allows the usual handling, especially for the hunter.

At least one of the objects of the invention is achieved with a motion detector according to claim 1.

A core concept of the invention is to equip a motion detector with a number of motion sensors whose coverage areas overlap or adjoin one another in such a way that a total coverage area of 360° is possible.

Further advantages of the motion detector according to the invention result from the features of the dependent claims.

The motion detector according to the invention comprises a housing with more than one motion sensor arranged therein, central data processing for control and communication between the components and at least one energy store. For a total coverage area of 360°, a circumferential arrangement of the motion sensors, in particular in one plane in the housing, has proven to be suitable. For a motion sensor with a 112° coverage area, four evenly spaced motion sensors are sufficient to cover a closed circle or all cardinal directions around the axis of the motion detector. With a range of 15 m, a total area of over 700 m ² can be covered. However, it is also possible to use more or fewer than four motion sensors and thus change the coverage area. For example, it may be useful to use two opposing motion sensors, creating a coverage area in the shape of a butterfly.

In an advantageous variant of the motion detector according to the invention, the housing is designed in several parts. In the simplest case, the housing consists of two parts or modules that can be connected or screwed together, for example, by means of an external and internal thread. It has proven to be advantageous if the movement sensors and the power supply are accommodated in different parts of the housing and can be brought into electrical contact with one another when the housing parts are screwed together or connected. This has the advantage that the user can carry several identically constructed housing parts with energy supplies, in particular rechargeable batteries. For example, if a battery is empty or faulty, the motion detector can continue to be operated with a spare battery. The loading of Batteries are preferably charged using a USB connection. Commercially available batteries or photovoltaic charging can also be used.

A further advantage of the multi-part housing is the possibility of actuating a rotary switch by rotating the housing parts relative to one another. It is possible, for example, to provide the battery housing part with a spring contact so that this is guided onto a contact surface when the housing part is rotated and the motion detector is switched on in this way.

Another advantage of the multi-part housing is that the motion detector can be designed to be modular and expandable. It can be of great advantage if further components or modules can be inserted between the two housing parts. For example, the housing can be essentially cylindrical and rotated or screwed along the main axis. With a suitable choice of the connections, in particular with the same corresponding external and internal threads, it is then possible for further housing parts or modules with a suitable thread to be inserted between the other housing parts. This modular design offers significant advantages in terms of the range of functions of the motion detector. With suitable uniform connections, various electrical components and functional units can be connected to the central data processing of the motion detector, which expand and improve the range of functions as required.

Modules that expand or improve functions can contain, for example, data storage devices, cameras, additional energy storage devices, flashlights, microphones, additional sensors, interfaces, photovoltaic surfaces, lasers or any other components or functional units that are useful in this context.

In a further embodiment of the motion detector according to the invention, it is particularly advantageous in the case of a multi-part or modular structure if the interior of the housing is protected against the ingress of moisture, water and/or other contamination by means of suitable seals. O-rings are particularly suitable for sealing in the area of threaded flanges and other circular connection points. These can be made of rubber, plastic or metal.

In the case of rigid connections that do not have to be loosened, it can also make sense to glue the housing parts to one another or to other components.

In a further advantageous variant of the motion detector according to the invention, at least one transmission or communication unit, such as a radio transmitter and/or receiver, is connected to the central data processing unit. The transmission unit serves to send a signal to a receiver when a movement is detected, so that the user is informed about the detected movement. A dedicated receiver can be provided for this purpose, which has its own energy store and, when the signal is received, forwards acoustic, electromotive or visual feedback to the user. It is also conceivable that a smartphone with a suitable app serves as the receiver. In this particularly advantageous case, there is no need for an expensive additional receiver. In addition to a radio connection, any other practicable connection is of course also conceivable, such as WLAN, Bluetooth, infrared, mobile radio and the like.

In a preferred variant of the motion detector according to the invention, this has a positioning device, in particular in the form of a tripod. With a coverage area of 360°, it does not make sense to attach the motion detector to a tree, as the tree would significantly reduce the possible coverage area. In addition, finding and attaching to a suitable tree can be time-consuming and impractical. It is also possible that there is no suitable tree. It is therefore extremely advantageous if the motion detector can be placed directly on the floor, as a result of which the motion sensors are or can be sufficiently spaced from the installation surface by the tripod. So that the motion detector can stand freely and does not fall over, tripods with telescopic legs are particularly suitable. Since the motion detector is usually set up close to the ground, a rigid tripod or a so-called ground spike can also be suitable. A ground spike is essentially a stick with a point that can be driven into the ground to provide sufficient stability. Of course, other setup devices can also be advantageous, for example tripods with flexible legs, as are often used for smartphones or cameras.

The installation device can also be designed so that it can be separated from the housing, so that a suitable tripod can be selected for installation depending on the situation. In the case of the monopod or the ground spike, for example, it is advantageous if only the spike is first driven into the ground with a hammer or stone, for example, and only then is the housing with the motion sensors attached to the ground spike so that it can be damaged by the impacts of the ground spike Hammers or stones is not damaged. In another particularly preferred embodiment At least one joint is arranged between the installation device and the housing, with which the entire covering area can be aligned in relation to the floor surface. In this way, the angle between the base surface and the housing can be adjusted in such a way that the coverage area is aligned evenly and symmetrically around the motion detector. Lockable swivel or ball joints are particularly suitable for this. Locked joints without a manual locking device can also be advantageous. In the event that the floor is approximately horizontal and level, it can be advantageous if the joint has a zero point lock so that further alignment is then no longer necessary since the ideal angle can be set directly.

It has proven to be particularly advantageous if the motion detector has means that enable or facilitate alignment parallel or perpendicular to the installation or floor surface. For this purpose, the housing or a housing module can be equipped with at least one laser whose beam path is aligned normal to the axis of the housing. As a result, the laser provides information about the angle between the motion detector and the floor surface, thus enabling ideal and symmetrical alignment even on sloping floor surfaces. For example, the motion detector can also have more than one, e.g. three, lasers that shine in different directions. However, a module with a single rotatable laser can also be provided, for example, which can be rotated in any direction and is thus suitable for identifying the entire coverage area.

In a further advantageous embodiment, a means that can generate acoustic and/or optical signals is connected to the central data processing unit. If a suitable control unit and a suitable receiver are connected to the central data processing unit, it can be advantageous if these signals can be triggered remotely. This is particularly advantageous for finding the motion detector in the dark or in dense vegetation. The signal can then be triggered, for example, by the dedicated receiver or by the smartphone app.

If the device generates acoustic and/or visual signals, other information can also be shared in this way. It can be advantageous, for example, if the means provides information about the state of charge of the energy store by beeping after the motion detector has been switched on. During operation, this means can also be used to warn of a low charge level. This warning can also be sent over the air to a remote receiver such as a cellular phone.

The invention is explained below with reference to figures in which preferred configurations of the motion detector according to the invention are shown. However, the invention is not limited to these embodiments.

• 1 Gehäuse eines erfindungsgemäßen Bewegungsmelders mit mehreren über den Umfang des Gehäuses angeordneten Bewegungssensoren;
• 2 Gesamtabdeckungsbereich durch Überlappen der Abdeckungsbereiche der einzelnen Bewegungssensoren;
• 3a u. 3b Bewegungsmelder mit Aufstellvorrichtungen und Gelenken;
• 4a u. 4b Bewegungsmelder mit aufgeschraubtem Gehäuse und elektrischen Kontakten;
• 5a u. 5b Querschnitt durch den Bewegungsmelder;
• 6a u. 6b Korrekte und falsche Ausrichtung des Bewegungsmelders auf einer abschüssigen Fläche;
• 7: Bewegungsmelder mit zusätzlichem Modul.

Show it

• 1 Housing of a motion detector according to the invention with a plurality of motion sensors arranged around the circumference of the housing;
• 2 Total coverage area by overlapping the coverage areas of the individual motion sensors;
• 3a and . 3b motion detector with mounting devices and joints;
• 4a and . 4b motion detector with housing screwed on and electrical contacts;
• 5a and . 5b cross-section through the motion detector;
• 6a and . 6b Correct and incorrect orientation of the motion detector on a sloping surface;
• 7 : Motion detector with additional module.

In 1 a motion detector 1 according to the invention is shown with a multi-part housing. The multi-part housing consists essentially of two housing parts 3, 4 and two motion sensors 2a, 2b shown on the front and two other motion sensors 2c, 2d, not shown, on the back. The movement sensors are arranged circumferentially and evenly in the upper area of the housing part 3 . The lower housing part 4 is connected to the upper housing part 3 at the connection point 5 and accommodates an energy store 4a such as one or more rechargeable batteries.

2 shows the total coverage area 12 of the motion detector 1. The total coverage area 12 results from the partially overlapping coverage areas 11a-d of the individual motion sensors 2a-d. In this embodiment, the motion sensors 2a-d have a coverage angle 13a-d of 112°. The movement sensors 2a-d are connected to a central data processing unit 15. Due to the design, the coverage areas 11a-d only begin to overlap at a certain point. The beginning of the overlap 14a-d can by arranging the Central data processing 15 or the motion sensors are influenced in its position. After the beginning of the overlap 14a-d, the total coverage area 12 is 360° in this embodiment.

In the 3a and 3b exemplary embodiments are shown with an installation device or a tripod. 3a shows a motion detector 1 with a ground spike with a tip 23. The tip serves to introduce the ground spike into the ground, so that the motion detector 1 can be set up anywhere with suitable soil. A tree and the fastening means required for it are therefore advantageously not required. A joint 21, which can be locked in particular, is used to align the covering area in relation to the ground. In another variant, a flexible leg 22 can also be used to set a suitable alignment angle.

In the 3b variant shown has a tripod 24 as a mounting device. The individual legs of the tripod 24 can be extended and retracted telescopically. As a result, the motion detector is particularly stable even on very uneven surfaces or on impassable terrain. Of course, this variant can also be equipped with suitable joints in order to enable fine adjustment of the covering area to the floor surface.

the 4a and 4b show an open or unscrewed housing of the motion detector according to the invention. The upper housing part 3 can be connected to the lower housing part 4 via a threaded flange 32 . The lower part 4 has a spring-loaded contact pin 31 on its end face, which is used to contact the battery housed in the housing part 4 .

In 4b the underside of the unscrewed upper housing part 3 can be seen. The contact surface 33 arranged there is used for the electrical connection of the electrical components arranged in the upper housing part 3 . The thread 32 can be provided with detents so that a rotary switch is created. At a first point of the grid, the contact surface 33 and the spring-loaded contact pin 31 are not connected and the motion detector is consequently switched off. By rotating the two housing parts 3.4 relative to one another, the housing can be transferred to a second position in which the contact pin 31 and the contact surface 33 are connected and the motion detector is switched on in this way. In this exemplary embodiment, an expansion module (not shown) can also be inserted between the two housing parts 3, 4, provided that it has a suitable thread and suitable connections. In this way, the functionality of the motion detector 1 can be significantly expanded or existing functions can be improved.

the 5a and 5b show a cross-sectional view through a motion detector according to the invention. O-ring seals 41 are provided to seal resealable openings and closures. The housing parts that should not or do not have to be separated regularly can also be sealed by gluing 42 . This makes the housing of the motion detector waterproof. In addition, the interior and the electronics are protected from dirt.

the 6a and 6b show the alignment of the motion detector or the coverage area 12 with a sloping floor surface 53. 6a shows the correct orientation. Due to the beam path of the laser 51 running parallel to the floor surface 53, the motion detector can be positioned in such a way that a symmetrical, large and uncut coverage area 12 is also ensured on a slope or the like. 6b on the other hand, shows the incorrect alignment of the motion detector. The beam path of the laser 52 is substantially horizontal to sea level. This would be the case in particular if the alignment were to be carried out using a level or a plumb bob and the joint 21 is in the zero-point lock. The resulting coverage area is then truncated, small, and overall unfavorable. However, due to the course of the beam path of the laser 51, 52, the user knows exactly how the coverage area is to be aligned.

the 7 shows another possible embodiment of the motion detector 1 according to the invention, in which between the housing parts 3 and 4 a further module 9 is placed or screwed in between. This module 9 can contain other functional units, such as cameras, lasers, radio units, etc., for example. Of course, such functional units can also be arranged in the housing parts 3 and/or 4 .

Reference List

1

motion detector

2a, 2b, 2c, 2d

motion sensors

3

housing part

4

housing part

4a

energy storage

5

Connection point of the housing parts

11a, 11b, 11c, 11d

Coverage area of a single motion sensor

12

total coverage area

13a, 13b, 13c, 13d

coverage angle

14a, 14b, 14c, 14d

Beginning of the overlap

15

Central data processing

20

tripod

21

joint

22

flexible leg

23

Monopod as ground spike with tip

24

Tripod with telescopic legs

31

Spring-loaded contact pin

32a, 32b

thread

33

contact surface

41

O ring seals

42

bonding

51

Beam path of the laser

52

Beam path of the laser

53

footprint

Claims (16)

Motion detector (1), in particular for detecting the movement of animals, with a housing (3, 4), central data processing, an energy store (4a) and at least two motion sensors (2a, 2b, 2c, 2d), characterized in that the sensors (2a, 2b, 2c, 2d) are arranged in the housing (3, 4) in such a way that they cover a total coverage area (12) that is larger than the coverage area (11a, 11b, 11c, 11d) of a single sensor (2a, 2b, 2c, 2d). Motion detector (1) after claim 1 , characterized in that the motion detector (1) has at least three, in particular four, sensors (2a, 2b, 2c, 2d) which are arranged in such a way that the associated coverage areas together cover a total coverage area of at least 300°, preferably 330° to 360°, particularly preferably 360°. Motion detector (1) after claim 1 or 2 , characterized in that the housing consists of at least two parts (3, 4) which can be connected to one another, in particular by means of a thread, and the energy store (4a), in particular an accumulator, and the sensors (2a, 2b, 2c, 2d ) are arranged in different housing parts (3, 4). Motion detector (1) after claim 3 , characterized in that a switch for activating and deactivating the motion detector (1) is provided, which can be actuated in particular by rotating the housing parts (3, 4) relative to one another. Motion detector (1) according to one of Claims 1 until 4 , characterized in that functional units, in particular in the form of data storage, camera, additional energy storage, infrared flashlight, microphone, additional sensors, electronic interfaces, communication unit and/or laser are arranged in one or both housing parts (3, 4). Motion detector (1) according to one of the preceding claims, characterized in that the motion detector (1), in particular its housing (3, 4), can be expanded in a modular manner by further housing parts or modules (9) and in this way further functional units, in particular in the form of data storage, camera, additional energy storage, infrared flashlight, microphone, additional sensors, electronic interfaces, communication unit, laser or other electrical components that expand or improve the range of functions of the motion detector, can be connected to the central data processing and/or the energy storage (4a). are, it being possible for several functional units to be arranged in one housing part (9). Motion detector (1) according to one of the preceding claims, characterized in that the interior of the housing (3, 4) is protected against ingress of moisture by means of seals (41), in particular O-rings, and/or adhesive bonding (42) of the housing parts (3, 4). and/or contamination is protected. Movement detector (1) according to one of the preceding claims, characterized in that the central data processing unit is connected to a transmission unit, in particular a radio transmitter, which transmits a signal when a movement is detected. Motion detector (1) according to one of the preceding claims, characterized in that the motion detector (1) is a tripod (20), in particular in the form of a monopod (23) or three leg stand (24) in such a way that the housing (3, 4) with its sensors (2a, 2b, 2c, 2d) can be set up at a distance from the installation surface (53). Motion detector (1) according to one of the preceding claims, characterized in that the housing (3, 4) can be moved relative to the stand (20) and can be arranged in various positions, with this being in particular between the stand (20) and the housing (3, 4) at least one joint (21) is arranged, with which the housing (3, 4) with its sensors (2a, 2b, 2c, 2d) can be positioned relative to the installation surface (53), and thus the overall coverage area (12) can also be determined or adjustable. Motion detector (1) after claim 10 , characterized in that the joint (21) is a lockable rotary joint or ball joint, in particular with a zero-point lock. Motion detector (1) according to one of the preceding claims, characterized in that at least one laser is or can be arranged on the motion detector (1) which is used to align the motion detector (1) relative to the installation surface and thus the coverage area (11a-d) or of the overall coverage area (12). Motion detector (1) according to one of the preceding claims, characterized in that at least one means, in particular in the form of a loudspeaker and/or microphone, is provided in order to emit a remotely triggered acoustic and/or optical signal. Motion detector (1) according to one of the preceding claims, characterized in that after activation of the motion detector (1) there is an acoustic and/or visual status report on the state of charge of the energy store (4a). Motion detector (1) according to one of the preceding claims, characterized in that the energy store (4a) can be charged via a USB connection. Receiver for a motion detector (1) according to one of the preceding claims, characterized in that the receiver is a radio receiver or a smartphone and generates a visual, acoustic or electromotive signal on receiving the signal sent by the transmitter unit.

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