The present disclosure relates generally to an apparatus and a method for affecting movement of a land vehicle. More particularly, the present disclosure relates to apparatuses, systems and methods for deterring, slowing, disabling, restraining and/or immobilizing a motor vehicle by entangling one or more tires of the vehicle.
Conventional devices for restricting the movement of land vehicles include barriers, tire spike strips, caltrops, snares and electrical system disabling devices. For example, conventional spike strips include spikes projecting upwardly from an elongated base structure that is stored as either a rolled up device or an accordion type device. These conventional spike strips are tossed or thrown on a road in anticipation that an approaching target vehicle will drive over the spike strip. Successfully placing a conventional spike strip in the path of a target vehicle results in one or more tires of the target vehicle being impaled by the spike(s), thereby deflating the tire(s) and making the vehicle difficult to control such that the driver is compelled to slow or halt the vehicle.
Conventional spike strips may be used by first response personnel, law enforcement personnel, armed forces personnel or other security personnel. It is frequently the case that these personnel must remain in close proximity when deploying spike strips. For example, a conventional method of deploying a spike strip is to have the personnel toss the spike strip in the path of an approaching target vehicle. This conventional method places the security personnel at risk insofar as the driver of the target vehicle may try to run down the security personnel or the driver may lose control of the target vehicle while attempting to maneuver around the spike strip and hit the security personnel. Further, rapidly deflating only one of the steering tires may cause a target vehicle to careen wildly and possibly strike nearby security personnel, bystanders, or structures.
There are a number of disadvantages of conventional spike strips including difficulty deploying the strip in the path of a target vehicle and the risk that one of the spikes could injure security personnel while deploying or retracting the strip. The proximity of the security personnel to the target vehicle when it runs over strip places the security personnel at risk of being struck by the target vehicle. Further, allowing the strip to remain deployed after the target vehicle passes the strip places other vehicles at risk of running over the strip.
Specific details of embodiments according to the present disclosure are described below with reference to devices for deflating tires of an oncoming land vehicle. Other embodiments of the disclosure can have configurations, components, features or procedures different than those described in this section. A person of ordinary skill in the art, therefore, will accordingly understand that the disclosure may have other embodiments with additional elements, or the disclosure may have other embodiments without several of the elements shown and described below with reference to the figures.
Certain embodiments according to the present disclosure deploy the device 10 in the expected pathway of a target vehicle, e.g., the car C. The undeployed device 10 may be placed on the ground, e.g., on or at the side of the road R, and then armed. For example, the device 10 can be armed by making a power source available in anticipation of deploying the device 10. The device 10 is deployed, e.g., extended across the expected pathway of the target vehicle, as the vehicle approaches the device 10. The device 10 may be deployed when the target vehicle is a short distance away, e.g., less than 100 feet. This may avoid alerting the driver to the presence of the device 10 and thus make it more likely that the target vehicle will successfully run over the device 10. Similarly, remotely or automatically deploying the device 10 may reduce the likelihood that the driver will notice the device 10 or take evasive action to avoid running over the device 10. Remotely deploying the device 10 also allows the device operator (not shown) to move away from the target vehicle and thereby reduce or eliminate the likelihood of the vehicle striking the operator.
As shown in
The undeployed or stacked arrangement of the netting package 30 shown in
The segments 32 and/or the second hinges 36 can include a base section comprised of fiberglass, corrugated plastic or cardboard, wood, or another material that is suitably strong and lightweight. For example, G10 is an extremely durable makeup of layers of fiberglass soaked in resin that is highly compressed and baked. Moreover, G10 is impervious to moisture or liquid and physically stable under climate change. The base section of the segment 32 should provide a platform suitable for supporting an assembly that includes inflatable hoses, netting, and spikes, as will be described below. The size of the segments 32 may affect how far the netting package 30 extends in the deployed arrangement, e.g., shorter segments 32 may result in a shorter netting package 30 being deployed for a narrow roadway.
The inflator device 40 includes inflatable bladders 42 (two inflatable bladders 42a and 42b are shown in
The inflator device 40 may also include a sensor (not shown) for sensing an approaching vehicle and automatically deploying the netting package 30. Examples of suitable sensors may include magnetic sensors, range sensors, or any other device that can sense an approaching vehicle and deploy the netting package 30 before of the vehicle arrives at the device 10. The inflator device 40 may alternatively or additionally include a remote actuation device (not shown) for manually deploying the netting package 30. The sensor and/or the remote actuation device may be coupled to the device 10 by wires, wirelessly, or another communication system for conveying a “deploy signal” to the device 10. Examples of wireless communication technology include electromagnetic transmission (e.g., radio frequency) and optical transmission (e.g., laser or infrared).
A drain valve 422 coupled to the supply line 416 downstream of the accumulator tank 420 can drain residual pressure in the accumulator tank 420 by opening the supply line 416 to the atmosphere. A gauge 424 can be coupled to the supply line 416 between the supply valve 412 and the drain valve 422 to indicate the pressure in the accumulator tank 420.
Compressed gas for deploying the netting package 30 can flow along a deployment line 430 that couples the supply accumulator tank 420 and the manifold 46. A deployment valve 432 is positioned along the deployment line 430 between the supply accumulator tank 420 and the manifold 46 to control flow of the compressed gas to the netting package 30. According to certain embodiments of the present disclosure, the deployment valve 432 can include a 0.5 inch NPT normally closed solenoid valve with an approximately 15 millimeter orifice, a 1500 psi pressure capability, and can be actuated by a direct current signal, e.g., 24 volts. A signal to deploy the netting package 30 energizes the solenoid of the deployment valve 432 to allow compressed gas in the accumulator tank 420 to flow through the deployment line 430 and the manifold 46 to the bladders 42, thereby deploying the netting package 30. A vent valve 440 coupled to the deployment line 430 downstream of the deployment valve 432 and/or coupled to the manifold 46 can vent compressed gas in the bladders 42 to the atmosphere. According to certain embodiments of the present disclosure, the vent valve 440 can include a 0.125 inch NPT normally closed solenoid valve with an approximately 1.2 millimeter orifice and can also be actuated by a 24 volt direct current signal. A signal to vent the bladders 42 energizes the solenoid of the vent valve 440 to release to atmosphere the gas in the bladders 42, for example, before and/or during operation of the retractor device 60.
The electronics for the control of the device 10 can include at least two options for triggering deployment: (1) a wireless frequency operated button (“FOB”) and/or (2) a wired control box. Embodiments of option 1 according to the present disclosure can include a three-channel, 303 MHz wireless radio frequency board (e.g., Model Number RCR303A manufactured by Applied Wireless, Inc. of Camarillo, Calif.) in the housing 20 and a three-button FOB (e.g., Key Chain Transmitter KTX303Ax also manufactured by Applied Wireless, Inc.) that can be separated and remotely located from the housing 20. Some other embodiments use radio frequency transmission equipment having a LINX RXM-418-LR 418 MHz receiver, CMD-KEY#-418-S5 transmitter, and LINX LICAL-DEC-MS001 decoder (which decodes the encrypted digital string sent by the transmitter). The wireless transmissions can be encoded at 24 bits (allowing for 16.7 million unique addresses) to negate the possibility of cross-talk between another nearby unit. Embodiments of option 2 according to the present disclosure can include a control box that can be separated and remotely located from the housing 20 but remains electrically coupled via a cable. Both options may be incorporated into the device 10 to provide a backup for controlling deployment of the netting package 30.
The electronic circuit 500 can also include circuitry to handle the timing and control of operational events. Such a circuit may be useful if, for example, there is a difference in voltage provided by the wired control box 540 (e.g., approximately 14-17 volts direct current) versus the voltage required to operate the deployment valve 432 and/or vent valve 440 (e.g., approximately 24 volts direct current). This other circuit operates based on operator input for each event from either the wireless radio frequency board 530 (i.e., option 1) and/or the wired control box 540 (i.e., option 2).
As can be seen in
Atop the backing 805, each segment will include netting 810, a portion of which will be exposed at the side where the small hinge 820a is located when the segments are in the stacked configuration. Additionally, the segments each contain a plurality of spikes, quills or other penetrators 840 capable of penetrating into the tires of the targeted oncoming vehicle. As can be seen, when the segments are in the stacked configuration, the spikes point toward the opposing segment. Sufficient spacing must be provided such that, when the segments are in the stacked configuration, they are not penetrating into the opposing segment in a manner that would prevent the segments from unfurling when the deployment hoses are being inflated.
As shown, the segments also include a spike ramp 850 at a leading edge of the backing 805. The spike ramp may be incorporated within the backing or may be made of a different material. The spike ramp holds a plurality of spikes in place, at an angle that facilitates having the spikes penetrate into the tires of an oncoming vehicle when the segments are unfurled for deployment.
As shown in
Lastly,
The net 810 can have meshes that, in the contracted, folded arrangement of the net, have an approximately diamond shape with a major axis M1 between distal opposite points approximately three to four times greater than a minor axis M2 between proximal opposite points. For example, the size of individual meshes in the widthwise direction may be approximately one inch in the contracted arrangement, e.g., stowed configuration, of the net 700, and the size of individual meshes in the lengthwise direction may be approximately 3.5 inches in the contracted arrangement of the net. Certain other embodiments according to the present invention may have approximately square shaped meshes.
The net 810 may be assembled according to known techniques such as using “Weavers Knots” and/or a “Fisherman's Knot” to join lengths of cord and form the mesh. Certain embodiments according to the present disclosure may include coating the net material with an acrylic dilution, e.g., one part acrylic to 20 parts water, to aid in setting the knots and prevent them from slipping or coming undone.
It may be desirable to provide a widthwise stretch ratio of approximately 3:1. Accordingly, each mesh is reshaped or stretches in the widthwise direction, e.g., parallel to the wheel track of the target vehicle, to a dimension approximately three times greater than its initial dimension. For example, a net having a 1.75 inch by 1.75 inch mesh size (unstretched) may be approximately 3.75 inches measured on the bias (stretched) when the net is entangled around the wheels of a target vehicle in the fully deployed configuration of the device 10. According to this example, approximately 65 inches of the contracted net that is captured by the wheel track of the target vehicle is expanded to approximately 245 inches that may become entangled on features of the undercarriage of the target vehicle approximately within its wheel track.
The netting may also include a first strip 910 along a leading edge 904a of the net 810, a second strip 920 along a trailing edge 904b of the net 810, and/or lengthwise strips 930 (individual lengthwise strips 930a and 930b are shown in
The first, second and/or lengthwise strips 910, 920 and 930 may maintain the approximate size and approximate shape of the net 810 in its contracted configuration, e.g., in a stowed configuration of the device. The second strip 920 that is secured to the trailing edge 904b of the net 810 may aid in cinching the net onto the wheels of the target vehicle so as to seize rotation of the entangled wheel(s) and thereby immobilize the target vehicle. The lengthwise strips 930 also may aid in cinching the netting onto the wheels of the target vehicle and/or minimize net flaring as the net 810 wraps around the wheels of the target vehicle.
A method according to embodiments of the present disclosure for implementing a vehicle immobilizing device will now be described. A vehicle immobilizing device 10 is to be positioned in along the side of a roadway. In some embodiments, the device can be permanently left in position at the roadside, and may be disguised. In other instances, the device can be transported in the trunk of an automobile, such as a police car or military vehicle. When the police or military are engaged in a chase and need to restrain a vehicle, the device 10 can then be quickly positioned along the roadway in the expected path of the vehicle. When the device is in an undeployed state, it may be a completely enclosed box, resembling, for example, a suitcase. In this undeployed state, the segments contained therein, which include the netting 810, are in a stacked position inside the housing, as depicted in
Once the target vehicle is in close proximity to the device 10, the device can be deployed, either by a sensor, manually, or via remote control. Upon deployment, the inflator is powered and begins to quickly pump air into the deployment hoses 830. Because the hoses are folded multiple times, the hoses are inflated in sections. As each section is inflated, segments begin to rotate about the hinges 820a and 820b so as to unfold and lie end to end. Because the device is positioned along the roadway, the segments then lay in a linear fashion across the roadway, just at, or near the time that the target vehicle is approaching.
As the vehicle's tires make contact with segments of the device, the tires are lifted slightly by the spike ramp 850 and then make contact with at least one spike 840. In a preferred embodiment, the spikes 840 are placed sufficiently close together such that the vehicle's tires contact multiple spikes. The spikes penetrate into the front tires of the vehicle and become lodged in those tires. This cause the spikes to become dislodged from the spike clip/retainer 855 in the spike ramp 850.
As the spikes are drawn around the circumference of the tire, the base of the spikes pulls the spike tethers 860, which in turn is connected to the netting 810. The netting is then pulled from the segments. The netting has been folded in a manner that it will be drawn out from the net packaging in a continuous motion. As the netting is drawn from the device 10, it proceeds to wrap around the tire as it continues to rotate. The netting then proceeds to twist and becomes entangled around the rotating tires. The entangled snaring members then will continue to twist until leverage against the under carriage of the vehicle brings the tires to a stop. Accordingly, the vehicle can be slowed and stopped in a controlled and non-lethal manner.
The above detailed description of embodiments is not intended to be exhaustive or to limit the invention to the precise form disclosed above. Also, well-known structures and functions have not been shown or described in detail to avoid unnecessarily obscuring the description of the embodiments of the present disclosure. While specific embodiments of, and examples for, the invention are described above for illustrative purposes, various equivalent modifications are possible within the scope of the invention, as those skilled in the relevant art will recognize. As an example, certain embodiments of devices according to the present disclosure may include a pressure generator disposed in a device control housing with other operating elements, such as, but not limited to, a pressure delivery manifold, control circuitry to arm and deploy, a proximity detector, a signal receiving and sending circuit and any other hardware, software or firmware necessary or helpful in the operation of the device. As another example, the device may be housed in a clamshell-type briefcase or ammunition box type housing and include a pressure manifold and a pressure-generating device, such as compressed gas or a gas generator connected to the manifold. In other embodiments more than one manifold and more than one pressure generating device, or any combination thereof, may be included in the device.
Unless the context clearly requires otherwise, throughout the description and the claims, the words “comprise”, “comprising”, and the like are to be construed in an inclusive sense, as opposed to an exclusive or exhaustive sense; that is to say, in the sense of including, but not limited to. Additionally, the words “herein”, “above”, “below”, and words of similar connotation, when used in the present disclosure, shall refer to the present disclosure as a whole and not to any particular portions of the present disclosure. Where the context permits, words in the above Detailed Description using the singular or plural number may also include the plural or singular number respectively. The word “or”, in reference to a list of two or more items, covers all of the following interpretations of the word: any of the items in the list, all of the items in the list, and any combination of the items in the list.
While certain aspects of the invention are presented below in certain claim forms, the inventors contemplate the various aspects of the invention in any number of claim forms. Accordingly, the inventors reserve the right to add additional claims after filing the application to pursue such additional claim forms for other aspects of the invention.
The present application is a continuation of U.S. patent application Ser. No. 14/477,805 titled “Apparatus And Method For Rapidly Immobilizing A Land Vehicle” filed on Sep. 4, 2014 now U.S. Pat. No. 9,255,367, which claims priority to and benefit from U.S. Provisional Patent Application No. 61/873,812 titled “Apparatus And Method For Rapidly Immobilizing A Land Vehicle” filed on Sep. 4, 2013, the entire content of each of which is herein expressly incorporated by reference.
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20160153156 A1 | Jun 2016 | US |
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61873812 | Sep 2013 | US |
Number | Date | Country | |
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Parent | 14477805 | Sep 2014 | US |
Child | 15018630 | US |