EP3023730A1 - Stun grenade - Google Patents

Abstract

Blinding grenade for emitting a short-time light pulse, wherein by a housing (2) with a plurality of or arranged therein light sources (5), a control device (16) and a light source (5) and the control device (16) supplying energy storage (21), wherein the lighting means (5) are controllable via the control device (16) for emission of the light pulses.

Description

The invention relates to a stun grenade for the emission of a short-time light pulse.

Such a stun grenade is used for the short-term glare and irritation of people or optical devices by a short-term, extremely bright flash of light, ie a light pulse of high intensity is generated, the people standing in the surrounding field or electronic devices that work with optical sensors to temporary incorrect measurements enticed. So far, stun grenades are used in which the light pulse or flash of light is generated by means of an explosive chemical reaction. Such a stun grenade is usually either thrown by hand, but can also be fired if necessary. After use, such a stun grenade can not be reused. The emission of the flash of light takes place with high intensity for a very short time and thus has a temporary effect. Due to the high radiation density emitted, the glare persists even after ignition of the stun grenade for some time.

The disadvantage is the possibility that only a single flash of light can be generated with such a stun grenade. In addition, caused by the chemical reaction of the starting materials harmful reaction products respectively aggressive substances in the explosion, as of course, the blinding grenade is disposed of as such after ignition.

The invention is therefore based on the problem of specifying an improved contrasting garnet.

To solve this problem, a flashbangle for emitting a short-term light pulse is provided according to the invention, characterized by a housing with a plurality of or arranged therein electronic light emitting means, a control device and an energy storage device which supplies the lighting means and the control device, wherein the lighting means can be controlled via the control device for emission of the light pulse.

The blinding grenade according to the invention is characterized in that the light pulse is generated electronically controlled, and therefore is not based on a chemical explosive reaction. For this purpose, the stun grenade has a housing that is designed in size so that the grenade simply spent by hand, so can be thrown. If the shell should be fired, so the housing is designed accordingly, with other types of movement, such as a drop and the like are conceivable. In any case, a plurality of lighting means are provided on or in the housing, which are controlled via a control device in order to generate the light pulse. Due to this electronic control, it is possible, on the one hand, to generate a light pulse of high intensity, which has the corresponding glare or irritation effect. On the other hand, of course, there is also the possibility to generate the light pulse several times in succession, as of course its intensity and pulse duration can be varied. This can be defined in a simple manner by appropriate programming of the control device. Since it is an electronically controlled system, therefore, no harmful reaction products or corresponding waste, since the stun grenade as described can be easily reused. The possibility of administering multiple light pulses or reuse ultimately depends only on the capacity of the energy store.

The frequency spectrum of the light pulse should be in the range of 280 nm to 1 mm. Preferably, the frequency spectrum extends over a relatively broadband spectral range, which comprises at least the range of visible light, but preferably also in particular the infrared range detected after many optical devices operate using infrared sensors. Also, the emitted spectral range may include the UV range, as the application requires.

The preferred bulbs are those based on semiconductors, with LEDs in particular being suitable for this, but also laser diodes. With appropriate semiconductor-based bulbs, it is readily possible to generate a light pulse of high intensity or brightness, so that the desired blend or irritation effect is given. Especially LEDs are suitable for this, since it is about Accordingly, small components that are also readily and inexpensively available. They can be controlled in a simple manner and require relatively little power, so that corresponding multiple pulses can be generated easily.

Modern LEDs or laser diodes are able to emit light with a relatively broadband spectral range, including white light. Such LEDs have, for example, a corresponding additional luminescent layer. By using such LEDs, therefore, a very broadband light pulse can be generated from the spectral range. Alternatively to the use of such, white light emitting LEDs, a broadband light pulse can also be generated by color mixing. For this purpose, three different light-emitting LEDs or laser diodes can be combined to form a so-called RGB cluster, with the individual combined LEDs / laser diodes emitting red, green and blue light in this case (other color mixtures are also conceivable in order to cover a corresponding spectral range). By correspondingly simultaneous control, a corresponding broadband light thus results through color mixing. Such RGB clusters, in particular based on LEDs of newer generation, are readily available as finished components. They also have the advantage that, with appropriate design of the control device, the individual color components of the mixed light can be weighted differently, so that consequently not only white light, but also light with a corresponding color focus can be "mixed".

Preferably, the lighting means are provided in the form of separate light-emitting arrays, wherein a plurality of arrays are arranged distributed on or in the housing. In order to generate a highly intense light pulse, a plurality of individual light-emitting elements are consequently combined to form a corresponding array, that is, for example, several LEDs or RGB-LED clusters are combined in an array and several such arrays are provided distributed on the housing. The individual arrays or their luminous means are correspondingly driven via the control device, with all the illuminants of an array, for example, being driven simultaneously. Consequently, the light output multiplies, so that an extremely intense light pulse can be generated.

Furthermore, it can be provided to associate the light sources, in particular the arrays, with optical elements for influencing the emitted light. Such optical Elements may be, for example, lenses, prisms or fixed or movable mirrors. Depending on the element used, it is possible to carry out a beam widening, a beam splitting, a beam focusing or beam shaping, thus influencing the spatial light distribution in some way. If, for example, a corresponding beam expansion takes place via a lens, then the area which is detected by the light emitted by an array can be significantly widened. This is particularly advantageous if a plurality of such arrays are provided on the housing, so that the emitted light pulse is emitted into an extremely large solid angle range by appropriate beam expansion and corresponding superposition of the individual arrayspecific light emissions, resulting in a circumferential spatial irritation effect. Alternatively, as a result, the individual Arraypulse can be bundled accordingly to generate a directed, so spatially limited light pulse, for example in the context of interference in RGB LED clusters and the like.

The light sources, in particular the arrays, are preferably arranged in a reflector. This reflector ensures a high luminous efficacy, but at the same time it also allows beam guidance in a certain way. The reflector may be cup-shaped, so that the light source or the array is seated on the reflector bottom. It may be rectangular in cross-section, which makes it possible to arrange corresponding reflectors with the bulbs next to each other and thus to occupy a large area of the housing compact. However, a round or otherwise three-dimensionally shaped reflector is equally conceivable.

The reflector can furthermore be closed by way of an optical element, in particular a lens. That is, in this way results in a quasi-closed unit, wherein the optical element, such as the lens is arranged on the reflector and therefore associated directly with the light source. Such a unit can then be readily installed on the housing side accordingly.

A particularly expedient development of the invention provides for the lighting means, in particular the arrays, to be controlled by the control device in a programmable pattern. As described, the stun grenade is characterized by the fact that it is electronically controlled or operates with regard to the generation of light pulses. The control device, a correspondingly programmed CPU, can now be provided with any desired control programs via which the control of the individual lamps or arrays takes place. This is a synchronous control of all bulbs possible to control all lamps in time synchronously. Also, individual bulbs can be controlled in a specific time sequence from the totality of the bulbs, as the bulbs can be controlled in succession in corresponding groups. There are different repetition rates or different repetition times definable, as well as intensity variations are readily possible. This means that ultimately the light emission can be virtually arbitrarily controlled, it can be permanent, time-limited, regular, irregular or modulated.

Furthermore, the control device may include a possibly adjustable on the operator side timer. This timer can be used to specify a defined delay, which is either fixed, which means that the timer starts automatically when the grenade is activated. But it can also be adjusted if necessary, including, for example, a corresponding adjustment control is provided on the grenade to program the controller respectively the timer in this regard. A defined delay may be required depending on the purpose.

As the timer is optionally manually programmable, of course, the controller is programmable with respect to the processed over them control pattern of the individual lamps. This means that it is possible to select a suitable program on the part of the control device, which is the basis for the subsequent light pulse generation, via a suitable control element. About this can be adjusted on the spot, as the "ignition" should take place, so how should the light emission.

The lighting means, in particular the arrays, are preferably pulsed controllable via the control device, which is energy-saving. They can also be operated modulated, which increases the efficiency of the system.

Although, if provided, a defined or variable delay can be specified via a built-in timer, it is sometimes desirable in certain situations to "ignite" the stun grenade only if a person to be irritated or equipment is actually nearby, the stun grenade however, to deposit before. To make this possible expediently provided in or on the housing a distance sensor for detecting the distance of the stun grenade to an adjacent object, wherein the control device controls the lighting means, in particular the arrays in dependence of the distance information. Such a distance sensor detects an approach of a person to the stun grenade. If the person is within a defined range of distance to the stun grenade, the ignition takes place. This means that the flash of light is only generated when a person to be irritated, who possibly carries with him equipment to be influenced, is nearby. Optionally, the distance sensor - of course, can also be provided more distance sensors - designed for a local resolution, that is, that also can be determined from which direction the person approaches. There is then the possibility, as a result of the corresponding programmability of the control device or their intelligence, to control only those light sources which emit a light pulse in the direction of the person or in the direction from which the person approaches. It then takes place only a local control of the bulbs.

A further advantageous development of the stun grenade provides that a communication device comprising at least one receiver communicating with the control device for receiving control signals or programming information given by an external transmitter is provided in the housing. This communication device allows remote control of the stun grenade via an external remote control device. For example, it is possible to spend the stun grenade and watch from a safe distance to see if there is a scenario that requires the stun firing. If this is detected, a corresponding signal can be transmitted via a corresponding remote control transmitter, which is received by the communication device, whereupon the flashbangle is ignited. Remote programming may also be effected via this, that is to say that a corresponding program deposited by the control device of the grenade is selected via the remote control device if, after an analysis of the given scenario, it is clear how the glare is to take place, that is to say which glare pattern , what intensity, if any, which frequencies from the spectrum, etc. are desired.

In a further development of the invention, the communication device may also be a communicating with the control device transmitter for transmitting Include signals. This transmitter makes it possible for the grenade-side control device to also enter bidirectional communication with an external control device. If, for example, several stun grenades have been spent in one area, the stun grenades can communicate with one another via the transmitters and receivers, so that a synchronization of several such stun grenades with regard to the operation is possible. Of course, a bi-directional communication with an external remote control device can of course also take place. About this, therefore, a grenade system can be constructed, in which not only the individual grenades work with any programmable working patterns, but in which the grenades are operated differently in time with each other. A master-slave operation in conjunction with a higher-level remote control device is hereby readily feasible.

In order to prevent a stun grenade, which is no longer in its own power of disposal, being used against oneself, a device for self-destruction, in particular for destroying the control device, is expediently provided in the housing via the control device. This self-destruct device can be, for example, a small detonator, which is activated accordingly and explodes, over which the stun grenade is irreparably damaged. This self-destruct function can in particular be triggered remotely, ie via an external remote control device, if it is detected that the flashbangle can no longer be recovered.

Furthermore, an operation-activating, operator-side operated switch can be provided. With this switch, the stun grenade is activated. Optionally, as a switch, a keypad may be provided, via which an activation code must be entered in order to activate the grenade, so that any abuse can be excluded.

As described, the stun grenade comprises a housing, various electronic components and the corresponding bulbs. In order to be able to build up the stun grenade in a simple manner, the housing preferably consists of two interconnectable, a cavity enclosing spherical or cup-shaped half-shells on which the bulbs are arranged, wherein the shell-side bulbs each have a common plug connection with the control device or a driver are connectable. The housing consisting of the two shell halves encloses a cavity in which the electronic components, ie control device,

Energy storage, communication device, etc. are arranged. On the outside of the housing, the corresponding lamps are installed, preferably in the form of the arrays receiving, closed via an optical element reflectors, which are inserted into corresponding receptacles on the housing, which consists for example of plastic. For easy contacting, the individual lamps are combined with their connecting lines in a common connector, which is plugged together with the control device or a driver module. If the blinding grenade has a spherical shape, then it is possible to arrange the bulbs over a large area on the outer sides of the spherical shells. Inside each ball half-shell is then a corresponding connector which is connected to the control device, so that the contacting is particularly simple. It is then only necessary to connect the two housing halves together, which can be done for example by simply screwing or latching.

The energy store is preferably rechargeable, which means that it is preferably an accumulator. Alternatively, of course, a normal battery can be used. In particular, in the case of a rechargeable energy storage device, it is expedient if a charging connection is provided on the housing, so that the housing for charging the energy storage device does not have to be opened. The device is thus reusable.

Fig. 1

eine Prinzipdarstellung einer erfindungsgemäßen Blendgranate, hier exemplarisch in kubischer Form,

Fig. 2

eine vergrößerte Prinzipdarstellung zur Erläuterung der im Granateninneren verbauten Betriebselektronik nebst einiger Leuchtmittel,

Fig. 3

eine Aufsicht auf ein Leuchtmittel in Form eines LED-Arrays, angeordnet in einem Reflektor,

Fig. 4

eine Seitenansicht der Anordnung aus Fig. 3 mit zwei vergrößerten Array-Detailansichten, und

Fig. 5

eine Prinzipdarstellung einer Blendgranate in Ring- oder Kugelform.

Further advantages, features and details of the invention will become apparent from the embodiments described below and with reference to the drawings. Showing:

Fig. 1

a schematic representation of a stun grenade according to the invention, here by way of example in cubic form,

Fig. 2

an enlarged schematic diagram for explaining the built-in grenade inside operating electronics together with some bulbs,

Fig. 3

a plan view of a lamp in the form of an LED array, arranged in a reflector,

Fig. 4

a side view of the arrangement Fig. 3 with two enlarged array detail views, and

Fig. 5

a schematic representation of a stun grenade in ring or spherical form.

Fig. 1 shows a stun grenade 1 according to the invention for the emission of a short-time light pulse. The stun grenade 1 comprises a housing 2, consisting of two half-shells 3, 4, each preferably made of plastic. In the example shown, the housing 2 is cubic, but it could equally well be spherical, that is, the half-shells 3, 4 then quasi dome-shaped. On the housing 2 and each half-shell 3, 4, a plurality of individual light-emitting means 5 are arranged, which emit their light generated in each case to the outside. The lamps 5 are, as will be discussed below, preferably realized in the form of LED arrays and arranged in corresponding reflectors, so that there are manageable units that can be easily installed according to the housing side. On the housing 2 and the half-shells 3, 4 corresponding recesses or receptacles may be provided, in each of which a light source is placed together with reflector, so that the Halbschalenbestückung is correspondingly easy. A corresponding housing design is readily possible in the production of plastic.

In the interior of the housing 2, a corresponding cavity is defined by the half-shells 3, 4, in which the entire operating electronics, which will be described in detail below, is housed. On the outside of the housing, a switch 6 is provided in the illustrated embodiment, which may also be a keypad, via which the operation of the stun grenade 1 is activated and via which, if necessary, an access code to prevent abuse is entered. Furthermore, a charging connection 7 is shown by way of example in order to be able to charge a rechargeable energy store located inside the housing without having to open the housing 2.

Fig. 2 shows in the form of a schematic representation of a stun grenade 1, wherein here the illuminants 5 are shown in a circular arrangement by way of example. Instead of a rectangular case, as in Fig. 1 is shown, of course, an annular or spherical housing as described conceivable, connected to a corresponding geometric arrangement of the lighting means. 5

As described, each luminous means 5 consists of a high-power LED or a high-power LED array 8, which is arranged by way of example on a corresponding carrier 9. The LED array is located in a reflector 10, the cup-like and the upper side via an optical element 11, here a lens 12, is completed. The lens 12 is therefore located immediately above the LED array 8 and consequently influences the light pulse emitted by the LED array 8. The supply lines 13 of several or all of a respective half-shell 3, 4 built-in lighting means 5 are brought together for example in a connector 14 so that they are not to be connected individually. In the example, only a few bulbs are merged, of course, all bulbs 5 are connected accordingly. The connector 14 is connected to an LED driver 15, which in turn is connected to a control device 16 which controls the entire operation of the stun grenade 1. The controller 16 has a timer 17 to define a delay, which delay may either be pre-set and selected as part of the activation of the flashbangle 1. Alternatively, the delay can also be programmed as desired, for example by remote control. For this purpose, a communication device 18 is provided, comprising a receiver 19 and a transmitter 20. The communication device 18 communicates with the controller 16. About the receiver 19, the flashbangle 1 from a higher-level control device, ie a remote condition respectively a master, corresponding control or programming commands received, which are then processed by the controller 16. In the control device 16, a plurality of work programs are stored in a suitable memory, with which different, from programming forth quasi arbitrary operating or control patterns for the individual lamps 5 are stored. By way of this, the lighting means can all be controlled synchronously, in time-defined sequence, in groups, with different intensity, or direction-selective, so that ultimately the emitted light pulse can be shaped or formed as it were. Also, corresponding repetition rates can be defined via the respectively selected program, etc.

Via the transmitter 20, there is the possibility that the control device 16 communicates bidirectionally either with a higher-level remote control device or with other blinding grenades 1 in the vicinity, respectively their control devices. This allows the various stun grenades to be synchronized in operation, so that, controlled purely electronically, the various stun grenades 1 integrated in the system can be controlled as it were depending on the situation.

The power supply via an energy storage 21, which is preferably a rechargeable battery, which can be charged as described via the charging port 7. The control device 16 is associated with the switch 6, via which the stun grenade 1 can be activated or the access code can be entered when the switch 6 is a keypad or the like.

Furthermore, at least one distance sensor 22 is provided, whereby naturally also several such distance sensors can be installed in different positions on the housing 2. By means of these distance sensors, a distance to a nearby object is detected after the blinding grenade 1 has been moved. In particular, an approximation of a person can be detected here. The control device 16 receives the corresponding measured distance signal of the sensor 22. If it emerges that the person is within a defined range of distance to the stun grenade 1, the control device can correspondingly control the light source 5 in order to generate the light pulse. Because then it is ensured that the person to be irritated in a sufficient distance range to the blinding grenade 1, and consequently the optimal irritation effect is achievable.

Finally, a device 23 for self-destruction is provided, which can be controlled by radio, for example via the external higher-level remote control device. If a stun grenade 1 is irretrievably lost, it can be ensured by triggering the self-destruction device 23, which includes, for example, a small detonator, which then detonates, that the stun grenade 1 becomes completely inactive and can not be used against itself.

The communication via the communication device 18 is carried out either optically or by radio, in each case wirelessly, for which purpose the receiver 19 and the transmitter 20 are designed accordingly respectively at a corresponding position in the housing 2 are installed.

Fig. 3 shows a schematic diagram of the light source 5, here in the form of an LED or an LED array 8 with at least two LEDs, which is included together with the carrier 9 in a rectangular reflector 10 here. The reflector 10 has, see Fig. 4 , sloping wall surfaces on. It consists of metal or plastic and has on its insides corresponding mirror surfaces. Following the reflector shape, corresponding recesses can be provided on the housing halves 3, 4 as described be, in which the reflectors are used to mount them together with light sources 5 and the lenses 12, which will be discussed below, in a simple manner.

In the LED array 8, it can, see Fig. 4 to act an array of white light emitting LEDs 24. As can be seen, the LEDs 24 are arranged in the most dense packing in the array.

As an alternative to using white light emitting LEDs, RGB LED clusters 25 can also form the array. Each RGB LED cluster 25 consists of three LEDs, one of which emits a red light, a second green light and a third blue light. It comes in this way for color mixing and thus for the corresponding generation of white light.

The spectrum or the spectral range of the light emitted by the LED array 8 should be between 280 nm to 1 mm. This means that the spectral range is between UVB and far infrared. In any case, the spectral range of the emitted light should detect the range of visible light, and preferably extend into the infrared range, since many optical devices operate with infrared sensors. It is also conceivable to arrange LED arrays next to one another which serve different spectral ranges. Thus, a first LED array 8 can be installed, which emits white light in the visible spectral range. Adjacent, an LED array 8 can be installed, which emits primarily in the infrared range. In this way, an extremely broadband spectral range can be covered.

The reflector 10 is, see Fig. 2 , completed via the lens 12. This is glued in the reflector, for example. The lens shape corresponds to the reflector shape. The reflector can replace the in Fig. 3 also be round, according to the lens 12 shown.

By means of the control device 16 or the LED driver 15, all luminous means 5 installed on the housing side, that is to say the LED arrays 8, can be activated separately. The one or more lighting means 5 which are to be controlled depends on the program to be executed by the control device 16. This means that ultimately any drive sequences are possible, ie a synchronous control of all LED arrays 8, the control of individual LED arrays 8, the group-wise control of the LED arrays 8, the intensity variation, the control only selected local Groups depending on the detection of the distance sensor 22 and the like, as of course, appropriate repetitions are readily possible, as long as the supply is ensured by the energy storage 21. It is therefore possible to emit a wide variety of light generation patterns.

Fig. 5 shows, finally, a further embodiment of a stun grenade 1, in which the lighting means 5 are arranged with their reflectors 10 and lenses 12 in ring form. This means that the housing would be annular in this case, respectively, would be designed as a box-like disc, unlike according to Fig. 1 , in which a square housing is shown. A same configuration would also be given in a ball design of the housing, even then the lamps would be 5 positioned in a similar arrangement, but distributed over the entire spherical surface of the housing. As already Fig. 5 suggests, a plurality of individual light sources 5 together with reflectors 10 and lenses 12 is arranged on the housing, depending on the size or area of the housing 100 or more such bulbs 5 may be installed, since in particular LED arrays are known to be very small building, despite the possibility to be able to emit high intensity LED light with high intensity. Consequently, an extremely high packing density can be achieved, resulting in the possibility of emitting a light pulse with extremely high intensity or brightness.

LIST OF REFERENCE NUMBERS

1

flashbang

2

casing

3

half shell

4

half shell

5

Lamp

6

switch

7

charging port

8th

LED array

9

carrier

10

reflector

11

element

12

lens

13

supply line

14

Connectors

15

LED driver

16

control device

17

timer

18

communicator

19

receiver

20

transmitter

21

energy storage

22

distance sensor

23

Facility

24

LED

25

RGB LED clusters

Claims (15)

Blinding grenade for the emission of a short-term light pulse,
characterized by a housing (2) with a plurality of light sources or means (5) arranged thereon, a control device (16) and an energy store (21) supplying the lighting means (5) and the control device (16), the lighting means (5) being connected via the Control device (16) are controllable for emitting the light pulses. Glare grenade according to claim 1,
characterized,
that the frequency spectrum of the light pulse is in the range of 280 nm to 1 mm. Glare grenade according to claim 1 or 2,
characterized,
that light sources (5) are provided on a semiconductor basis. Glare grenade according to claim 3,
characterized,
that the luminous means (5) LEDs (24, 25) or laser diodes, and
in that the lighting means (5) each comprise one or more LEDs or that the lighting means (5) represent the color clusters or spectral clusters comprising laser diodes. Glare grenade according to claim 4,
characterized,
in that the lighting means (5) are each three LEDs or RGB clusters (25) comprising the laser diodes. Glare grenade according to one of the preceding claims,
characterized,
in that the lighting means (5) are provided in the form of separate light-emitting means arrays (8), wherein a plurality of arrays (8) are arranged distributed on or in the housing (2). Glare grenade according to one of the preceding claims,
characterized,
in that the illuminants (5), in particular the arrays (8), are associated with optical elements (11) for influencing the emitted light. Glare grenade according to claim 7,
characterized,
in that lenses (12), prisms or fixed or movable mirrors are provided as optical elements (11). Glare grenade according to one of the preceding claims,
characterized,
in that the lighting means (5), in particular the arrays (8), are arranged in a reflector (10). Glare grenade according to claims 8 and 9,
characterized,
that the reflector (10) via an optical element (11), in particular a lens (12) is closed. Glare grenade according to one of the preceding claims,
characterized,
in that the lighting means (5), in particular the arrays (8), can be controlled via the control device (16) in a programmable pattern. Glare grenade according to claim 11,
characterized,
that the control device (16), optionally adjustable an operator side, comprises timer (17). Glare grenade according to one of the preceding claims,
characterized,
in that the lighting means (5), in particular the arrays (8), can be driven in a pulsed manner via the control device (16). Glare grenade according to one of the preceding claims,
characterized,
that a distance sensor (22) for detecting the distance of the stun grenade (1) is provided to an adjacent object on or in the housing (2), wherein the control means (16) the light sources (5), in particular the array (8) in dependence of the Indicates distance information. Glare grenade according to one of the preceding claims,
characterized,
in that a communication device (18) comprising at least one receiver (19) communicating with the control device (16) for receiving control signals or programming information given by an external transmitter is provided in the housing (2).

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