The present invention relates to an IR illumination device and munitions comprising the same.
Conventional IR (dark) illumination flares are typically illumination hand held rockets, which contain a cool burning flare. The flare compositions are pyrotechnic compositions which undergo chemical reactions, typically combustion. Whilst every effort is made to reduce light output in the visible region, due to the nature of the reaction, some visible light output is usually observed, and there may be smoke or other debris that are visible.
According to a first aspect of present invention there is provided an IR illumination munition device for selective activation where upon activation the device emits IR radiation in the range of wavelengths of from 600 nm to 900 nm, the device comprising: an electrical power source and an array of IR light emitting diodes (IR LEDs), to emit the IR radiation.
Preferably, there is a plurality of light emission units each connected to the electrical power source independently and said light emission units comprise the array of IR light emitting diodes (IR LEDs), and a power converter unit for driving the array.
The device optionally further comprising
In a preferred arrangement, there is provided an IR illumination munition device for selective activation where upon activation the device emits IR radiation in the range of wavelengths of from 750 nm to 900 nm, the device comprising:
an electrical power source;
a plurality of light emission units each connected to the power source independently and said light emission units comprising:
an array of IR light emitting diodes (IR LEDs), to emit the IR radiation;
a power converter unit for driving the array.
Further, the independent coupling of the control unit to each light emission unit, and the provision of a power converter at each light emission unit, tends to provide the device with redundancy in case a part fails in service.
The use of an IR LED, an IR light emitting diode, allows for a light source which is not the product of a pyrotechnic reaction. Pyrotechnic compositions are hazardous, which introduces logistics problems of storage and handling.
A yet further issue is that due to decomposition of the pyrotechnic material in conventional IR flares, often due to moisture ingress, the conventional pyrotechnic IR compositions may have a finite lifetime.
The IR LED may be selected to provide very specific wavelengths, with narrow bandwidths. They have very low power consumption and may be easily integrated onto printed circuits as parts of larger systems.
The range of wavelengths may be independently selected in the near IR, mid IR or Far IR wavelength range. In one arrangement there is provided a first IR LED with a first IR radiation wavelength, and a second IR LED with a second different IR radiation wavelength.
In a further arrangement the array may comprises at least two different wavelength IR light emitting diodes. The IR light emitting diodes may be specifically selected to provide specific wavelengths to work with specific night vision optics. The array and therefore specific IR light emitting diodes may be selectively activated depending on the specific requirement.
The array may be any shape or arrangement, such as for example the IR LEDs may be arranged linearly, random, helical, curved, patterned, within the device. The IR LEDs may be located on the surface or in recessed portions in a housing, to provide protection.
The IR LEDs may be further covered with a layer, coating or sheath to provide protection and/or ruggedness.
Each light emission unit may comprise a capacitive energy store and/or and inductive energy store. Such an energy store may be tuned to deliver power in a particularly responsive manner and so can therefore permit higher switching frequencies of the light emitting element arrays.
There may be provided a capacitor charging means electrically interposed between the power source and each capacitive energy store. The capacitor charging means may be connected to the control unit.
The control unit may be configured for driving at least one of the arrays of light emitting elements in a pulse mode when the device is activated such that in operation the array of light emitting elements may switch between a high power output condition and a low power output condition repeatedly. The pulse mode may be such that the array of light emitting elements may switch between conditions at a predetermined frequency. The low power output mode may be substantially zero watts.
Each array of IR LEDs may comprise at least 5, preferably more than 10, preferably more than 20 IR LEDs.
The power source may be any electrical power source, such as for example an electrical cell, fuel cell, capacitor, preferably a lithium ion battery.
The device may be a hand thrown device, such as a grenade. The device may form part of a munition, such as for example a controlled descent payload capable of being launched from a munition. The device may be attached to or form an integral part of a UAV. The device may form part of an applique for attachment to a body or vehicle.
According to a further aspect of the invention there is provided an IR illumination munition comprising a carrier, a fuze, a controlled descent payload, wherein the payload comprises a device as defined herein.
The operator interface may be configured to enable selection between initiation modes. The initiation modes may comprise any combination of: an instant initiation, a delayed initiation, a wirelessly controlled initiation, such as for example, RF, NFC, Bluetooth, or mechanical force, such as, for example from high-g forces from set-back or high spin rates, which are well known in the art. For launched munitions, such as mortar, shells our under gun launched grenades, the munition may comprise a fuze, which may be set to determine the point of deployment of the payload comprising the device.
The operator interface may be configured to enable selection between activation modes. The activation modes may comprise: a pulse mode where the IR light emitting elements may switch between a high power output condition and a low power output condition repeatedly or a continuous power output mode where the power output is substantially constant. The pulse output may be used to provide a signal or basic communications, instructions.
The device may also further comprise at least one LED or an array of LEDs whose output is outside of the near IR and far IR regions, such as for example the visible light region or UV.
So that the invention may be well understood, embodiments thereof shall now be described with reference to the following figures, of which:
Turning to
The illumination payload device 100 is located in the payload cavity 15, and is retained in place by use of a locking ring 16, which screws into the forward end of main body 24.
The frangible ogive element 17 has a frangible link 17a, in the form of an aluminium thread, which is fastened to the locking ring 16. The frangible ogive element receives the expulsion charge 18 and fuze 19. Upon operation of the fuze 19, the expulsion charge 18 builds up pressure within the frangible ogive element and at the bursting pressure the thread 13 shears and the illumination payload device 100 is expelled from the aft of the main body 24.
The illumination payload device 100 is a modular illumination unit 10, which slides into the payload cavity 15.
With reference to
The housing 130 has a substantially circular front and back face which are substantially parallel and separated by an interconnecting side wall surface. Incorporated into the interconnecting side wall, the housing 130 has facets arranged to extend axially between the substantially circular faces of the cylindrical housing 130. Each of these facets has arranged at it an array of IR LEDs, such as IR LED array 120a. Further, each facet is provided with a PIR sensor 124.
A manual switch 122 is provided at the back face of the housing for selectively switching the device 100 between and ‘on’ mode (where the device 100 may emit IR light if so instructed) and an ‘off’ mode (where the device 100 may not emit light).
Also provided at the back face of the housing 130 is an access panel or port 104 whereby either the power source 106 can be removed (and replaced), or a recharging energy source can be coupled into the source 106 to recharge it.
In operation, the handheld device 100 may be picked up by an operator, switched manually from the ‘off’ mode to the ‘on’ mode using switch 122 and subsequently thrown into an environment. A subsequent instruction received from the wireless transceiver 110 (which may be delivered by a remote control retained by the operator) causes the battery 106 to transfer energy, via the power converter units 116 and/or ultracapacitors 114 to the IR LED arrays 120a and 120b, which then emit IR light to illuminate a scene proximate to the device 100.
With reference to
For instance, an IR light emission unit 201a comprises ultracapacitor array 214a, connected to power converter unit 216a connected to IR LED array 220a.
The device 200 is further provided with an ultracapacitor charger 215 connected to each of the arrays of ultracapacitors 214a, 214b and 214c. The ultracapacitor charger 215 is connected to a power source 206 such that the ultracapacitor charger 215 can receive and manage power from the source 206. The ultracapacitor charger 215 is further connected to a control unit 218 such that it may send and receive signals from the control unit 218.
The control unit 218 is additionally connected to each of the power converter units 216a, 216b and 216c such that it can send and receive signals to and from these units.
Still further, the control unit 218 is connected to various interface units, such as a PIR sensor unit 224 and a wireless control unit 210 (which may be provided as part of a broader operator interface including also a manual remote control unit) such that the control unit 218 may act in dependence on signals received from these.
The control unit 218 comprises a signal generator (not shown) and/or clock for generating a periodic signal that varies between an upper value and a lower value at a predetermined frequency.
Each ultracapacitor array 214a, 214b, and 214c is driven by the ultracapacitor charger 215, under instruction from the control unit 218 such that the charging of the ultracapacitor array is regulated such that should the IR LED array need activation at a predetermined time, the ultracapacitor array is able to discharge through the power converter unit 216 into the IR LED array 220 (and thereby put the device 200 is a high power output mode) in a predetermined manner.
In particular the ultracapacitor arrays may be driven to charge during one phase of a cycle of the periodic signal generated at the control unit 218 and then may be driven to discharge during the second phase of a cycle of the periodic signal.
Accordingly the IR LED arrays may be switched between a high power mode (i.e. as the ultracapacitor array 214 discharges into the IR LED array 220) and a low power mode (i.e. as the ultracapacitor array 214 is charged).
As such, with reference
Thus in this
A power source 306 is connected to each of the power converters 316a, 316b and 316c. A control unit 318 is connected to each of the power converters 316a, 316b and 316c. The control unit 318 is also connected to various interface units, such as a PIR sensor unit 324 and a wireless control unit 310 (which may be provided as part of a broader operator interface including also a manual remote control unit) such that the control unit 318 may act in dependence on signals received from these.
In operation, the device 300 activates at least one of the IR LED arrays 320a, 320b, and 320c when the associated power converter unit 316a, 316b, or 316c is instructed by a signal from the control unit 318 to pass electrical energy from the power source 306 to its associated IR LED array. With energy being transferred from the power source 306 to an IR LED array 302, the device 300 is placed in a high power mode of operation.
The instruction to pass energy between the power source 306 and some or all of the IR LED arrays 320a, 320b, 320c may be in the form of a periodic signal having a first phase of a cycle and a second phase of a cycle such that the first phase of the cycle causes activation of the IR LED arrays 320a, 320b, 320c (i.e. electrical energy is supplied to the IR LED arrays 320a, 320b, 320c) and the second portion of the cycle causes deactivation (i.e. not electrical energy supplied to the arrays).
In general operation any of the devices 100, 200 or 300 may be used as follows.
An operator firstly identifies an enclosure, particularly a building, or an open area containing targets.
The operator then throws or otherwise deploys the device into the building or open area (having first set the device into the ‘on’ mode).
The operator then selects that the device be activated. This selection may be by means of an instruction to the device issued, via an operator-held remote control device, to the wireless transceiver. Alternatively this instruction may have been made prior to deployment of the device by setting a countdown timer (using a clock in the control unit) such that at the end of the countdown, the device is activated.
Upon activation the IR LED arrays are illuminated with IR radiation.
Number | Date | Country | Kind |
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1619313 | Nov 2016 | GB | national |
17151164 | Jan 2017 | EP | regional |
17275064 | May 2017 | EP | regional |
1707421 | May 2017 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2017/053417 | 11/13/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/091874 | 5/24/2018 | WO | A |
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Number | Date | Country | |
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20200056867 A1 | Feb 2020 | US |