The present invention relates to a system for countering or neutralising an unmanned aerial vehicle (UAV) or drone that is driven by propellers. In particular, the invention relates to a programmable airburst projectile that is fired to discharge streamers near a UAV, to disable or bring down the UAV.
Mini-UAV or drones driven by propellers are becoming a common sight; these are deployed commercially (such as, for aerial photography or delivery of a product), for law enforcement (such as, reconnaissance, policing, combat, etc.) or as hobby crafts.
Conventional counter drone measures to intercept and neutralise any undesirable drones have their own limitations. For eg., US patent publication no. 20170237520 describes a portable directional jammer to disrupt navigation of a UAV, for eg. as seen in
In another approach, U.S. Pat. No. 9,175,934, issued to Lockheed Martin Corp., describes an auto-injector countermeasure for non-destructive disabling and control of UAVs. The auto-injector device is mounted on an attack UAV and the countermeasure involves controlling the attack UAV to intercept a target UAV, firing the auto-injector, injecting a disabling substance into the target UAV, exerting control over the target UAV and navigating the target UAV to a location for retrieval.
In yet another eg., US patent publication no. 2016/0023760, by Insitu, Inc., describes a counter-UAV system, which involves an interceptor UAV launched toward a target UAV. The interceptor UAV can disable the target UAV by deploying a net to entangle the target UAV. The counter UAV system requires a ground based launch control, target acquisition, guidance and communication sub-systems, which make the system complex and expensive to deploy.
Despite the above advances, there is still a need to provide another system to bring down an undesirable UAV or drone; preferably, this system is simple to deploy, yet requires little re-training or capital expenses.
The following presents a simplified summary to provide a basic understanding of the present invention. This summary is not an extensive overview of the invention, and is not intended to identify key features of the invention. Rather, it is to present some of the inventive concepts of this invention in a generalised form as a prelude to the detailed description that is to follow.
The present invention seeks to provide a system to counter or disable an undesirable unmanned aerial vehicle (UAV), of type class 1 UAS, which are driven by propellers. Preferably, the system involves determining a distance and direction of an UAV, firing an airburst projectile and dispersing streamers into the flight path of the UAV, and disabling the propellers by entanglement with some of the streamers. This system makes use of an existing 40 mm grenade launcher and requires little or no re-training on its use. Advantageously, this is a non-destructive UAV counter system.
In one embodiment, the present invention provides an air-burst projectile for countering a target unmanned aerial vehicle (UAV) comprising: an ogive connected to a fuze assembly, which fuze assembly is then connected to a shell; wherein the ogive houses: a spinner, with the spinner having compartments in which a streamer, in a coiled up state, is disposed in each compartment; and the fuze assembly comprises a programmable fuze and an electric detonator; so that the spinner and the fuze assembly are located forward of the electric detonator, and when the UAV is determined to be a threat or undesirable, an airburst projectile is fired into a flight path of the UAV, such that when the ogive is burst open by activating the electric detonator, the spinner is ejected, causing the streamers to disperse and the streamers to open up from the coiled up state, thus creating a streamer cloud in the flight path of the UAV.
In another embodiment, the present invention provides a system for countering a target unmanned aerial vehicle (UAV) comprising: operating a laser range finder to determine a distance, speed and direction of the UAV; computing ballistic parameters for an airburst projectile to reach a flight path of the UAV; and firing a grenade launcher to propel the airburst projectile to the desired destination, and detonating the airburst projectile to disperse streamers to create a streamer cloud, so that some of the streamers may be caught by propellers of the UAV, thereby to disable the UAV and to bring the UAV to the ground.
In yet another embodiment, the present invention provides a system for countering a target UAV comprising: establishing or estimating a user distance to a territorial or air-exclusion boundary; entering the user distance into a programming unit (PU) on an associated grenade launcher; and after determining that the UAV is a threat or undesirable, firing the grenade launcher to propel an airburst projectile to the desired destination, and detonating the airburst projectile to create a streamer cloud as a warning shot or fence marking shot.
Preferably, the spinner comprises a rear annular plate being connected along an inner annular edge to a sleeve, and a plurality of partition plates extend radially from the sleeve and being in contact with a face of the rear annular plate, so that the space between adjacent radial partition plates form each compartment. A plurality of the spinners is stacked one on another along an axis that is substantially coaxial with a longitudinal axis of the airburst projectile. The plurality of spinners may be guided along a guide tube.
Preferably, the spinner further comprising a front annular plate, with an inner edge of the front annular plate being connected to a front end of the sleeve. The sleeve may have apertures, with each aperture in fluid communication with an associated compartment. The spinner may comprise a decelerator connected to an outer edge of each of the radial partition plate.
Preferably, the sleeve is elongate and forms a tube. Preferably, a plurality of streamers is packed in each compartment.
Preferably, the streamer is made from a web of material, which may be made from plastic, paper, fibres, fabric or a composite thereof. A streamer may be formed with a blob. The blob may be a bead or a knot.
This invention will be described by way of non-limiting embodiments of the present invention, with reference to the accompanying drawings, in which:
One or more specific and alternative embodiments of the present invention will now be described with reference to the attached drawings. It shall be apparent to one skilled in the art, however, that this invention may be practised without such specific details. Some of the details may not be described at length so as not to obscure the invention. For ease of reference, common reference numerals or series of numerals will be used throughout the figures when referring to the same or similar features common to the figures.
Preferably, an electronic explosive device (EED) or electric ignitable device (EID) or electric detonator is activated to air burst the projectile 130 when the projectile has been ejected a predetermined distance away, is airborne and is safely armed. In another embodiment, the EED, EID or electronic detonator may be used to set off the explosive charge 134 disposed inside the shell 133; the required distance of dispersal of the streamers 170 determines use or amount of the explosive charge 134, or selection of the EED, EID or electric detonator.
In use, after a target UAV 10 is detected, a user fires the laser range finder 104 at the target UAV 10 to determine a distance, speed and direction of the target UAV with respect to the user. The distance, speed and direction of the target UAV 10 are inputted automatically into a CPU of the PU 102 and the ballistic firing parameters required of the grenade/airburst projectile 120 are calculated. When the user determines that the target UAV 10 is a threat or undesirable, a grenade/airburst projectile 120 is fired from the grenade launcher 100; when the projectile 130 is leaving the barrel of the grenade launcher 100, the PU 102 transmits the ballistic firing parameters into a micro-processor located inside the projectile 130, for eg. via radio frequency induction. The ballistic firing parameters include a delay firing time; after being propelled to a safe distance away from the user and the delay firing time has expired, a firing circuit located inside the projectile 130 activates the electric detonator, EED or EID, which may then set off the explosive charge 134 and cause the shaped ogive 131 to disconnect from its cylindrical portion 131a; as a result, the spinner 140 is expelled from the projectile 130. After being separated from the projectile, the spinner 140 slows down in both trajectory and spin speeds, and as a result, the streamers 170 are dispersed out from spinner 140; the streamers 170 also slow down in speed but they open up (from the coiled-up state) to create a streamer cloud in a flight path of the target UAV 10. As a result, some of the streamers 170 become entangled with the propeller blades of the target UAV 10, so that the target UAV becomes disabled and fall to the ground. This counter grenade launching system 200 is shown in
In another use, a user may not utilize a laser range finder but knows, or can estimate, user distance to a territorial boundary or air-exclusion zone. In response to an undesirable UAV 10, a user inputs the known/estimate distance into the PU 102 on the grenade launcher 100 and then launches a projectile 130 to disperse a streamer cloud near the territorial boundary or air-exclusion zone as a warning shot or fence marking shot. In this application, a delay time for activating the electric detonator, EED or EID is entered into a PU 102, which then programs the delay time into the projectile 130 as the projectile is propelled out off a barrel of the grenade launcher 100.
An advantage of this UAV counter system 200 is that the 40 mm grenade launcher 100 may be an existing asset and no additional capital expense is required for the hardware; in addition, a user may be familiar with the use of the 40 mm grenade system and no additional training is also required. Another advantage is the non-destructive nature of this UAV counter system 200.
As described above, in use, after being dispersed, the streamers 170 open up and create a streamer cloud in the flight path of a target UAV 10.
In one embodiment, the streamers 170 are made from webs of materials that are relatively long compared to a width dimension. For illustration, the streamers may have a length of about 30-400 cm, may have a width of about 5-15 mm and a thickness of about 0.01-0.2 mm, preferably about 0.02-0.05 mm. The streamers 170 may be made from a plastic material, paper, fabric, fibres, and so on. Preferably, the paper is waxed, laminated or coated to provide some water resistance to allow the streamers to be deployed in a wet or snowy environment. The fabrics or fibres can be natural and/or synthetic, or a composite. These streamers 170 are very light in weight and they experience large drag forces when dispersed in the air, so that the streamers settle very slowly under gravity. Dispersion of the streamers 170 is also illustrated in
In
While specific embodiments have been described and illustrated, it is understood that many changes, modifications, variations and combinations thereof could be made to the present invention without departing from the scope of the invention. For eg., the above invention may incorporate Applicant's own invention published in U.S. Pat. No. 8,393,539 on the inflight programming of the firing time into an airburst projectile. In addition, the free end of each streamer 170, 170a may be formed with a hook or spiral to facilitate more effective entanglement with propeller blades of the target UAV 10.
Number | Date | Country | Kind |
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10201800999Q | Feb 2018 | SG | national |
Filing Document | Filing Date | Country | Kind |
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PCT/SG2019/050056 | 1/31/2019 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2019/151950 | 8/8/2019 | WO | A |
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Number | Date | Country |
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3109586 | Dec 2016 | EP |
3029279 | Jun 2016 | FR |
Entry |
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ISR; Intellectual Property Office of Singapore; dated May 9, 2019. |
Number | Date | Country | |
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20200363165 A1 | Nov 2020 | US |