Gun attacks in schools, churches, workplaces and other public gathering places have become all too commonplace. With effective methods of preventing attacks being virtually non-existent, the danger of a gun attack in nearly any public space is real and cannot be dismissed. Despite the increasing frequency of such attacks, there is currently a lack of an effective way to defend oneself against such an attack that is inconspicuous and non-threatening in the environment in which it is deployed.
The vast majority of our population and the areas we frequent are unprotected, leaving countless innocent children and adults vulnerable to unspeakable attacks. Victims often have no or very little warning of the danger. This compounds the problem, as any solution to protect against an attack must have immediate activation. There are only milliseconds available to present a defense. Once an attack starts, it then becomes a matter of protection until law enforcement and public safety personnel help to stop the aggression. The first victim currently has nothing for an immediate defense, the courageous are left exposed while seeking to help others, and taking cover is all too often ineffective.
With respect to schools, in the event of an active shooter, students, teachers and staff are generally trained to get out of the area of the shooter as quickly as possible. However, there may not always be a safe or readily apparent escape route, and the location of the shooter may not be known. Pursuing an escape route could inadvertently put you within sight of the shooter. On the other hand, staying in place or hiding may trap you within one area, and may render you defenseless if the shooter discovers you.
The root causes of attacks and the solutions proposed to prevent such attacks have recently been a subject of heated public debate. However, the effectiveness and the ability to implement any of the currently proposed social and legal changes are in question and will likely take an extended period of time.
The present invention provides an effective, easily accessible and inconspicuous means to defend oneself against a gunfire attack in a school or other public space, that requires little training or special knowledge and experience. Inconspicuous ballistic armor is provided that is incorporated into and disguised within common articles within a particular environment. One implementation of the invention, suitable for a school environment, is a ballistic armor or shield in the form of a desktop calendar. A relatively lightweight, ballistic shield having the approximate size dimensions of a desktop calendar is provided. The ballistic shield is formed with hand and arm straps on a rear surface, to allow a student or staff member to easily hoist the ballistic shield and use it as an effective and mobile shield or barrier against a gunfire, knife or other attack. An actual desktop calendar is attached to the front or upward-facing surface of the ballistic panel, such that in ordinary, everyday use, the ballistic shield inconspicuously rests on the desk surface and can be actually used as a desktop calendar, yet can be easily and immediately picked up and deployed in an active shooter situation.
A second embodiment of the invention includes a thin sheet of hardened steel that is affixed to a ballistic shield core. The thin sheet of hardened steel includes edge regions that wrap around and extend to the rear of the shield, such that hand holds and arm straps may be fastened to the edge regions of the hardened steel, with no requirement of any holes or fasteners extending through the ballistic material of the core itself.
Another embodiment of the invention includes an autonomous alert and protection system via connection of the shields on a particular campus or other location to the Internet of Things (IoT). When shield motion of a pre-defined acceleration and time is detected by the system, the system “awakens” and an alert is immediately and wirelessly sent by a processor on the shield to a central server, which in turn alerts first responders. On the shields themselves, audio and visual alert capabilities are provided that are activated in the event of detection of motion of at least one shield in the campus or other environment. Within the processing chip, edge processing is used to store data and perform computations that include maps and pre-recorded audio. Software on a user-connected computer or mobile device is connected to the central server, and generates an online map of the campus or other environment including locations and movement of the shields. Each shield is depicted as an icon on the online map, with its color or appearance indicating whether the shield is moving, its rate of motion and whether the user of the shield has pressed a button indicating that an attacker is in sight. The various types of data gathered by the shield and sent to the server can be used to generate a grid overlaid on the map showing the probable attacker location and predictive movement of the attacker (i.e., similar to a hurricane tracking grid). This data includes which shields are moving, at which locations, and at what rates, the order of movement of the shields, and which shields are signaling that an attacker has been seen and is in sight.
The present invention provides inconspicuous ballistic armor that can be easily incorporated into, assume the form of, or be disguised as common articles within a given environment. The environment may be any public gathering space, including, without limitation, elementary schools, middle schools, high schools, colleges and universities, churches, theaters, arenas and businesses. The ballistic armor should be of sufficient size and dimension to provide an effective barrier or shield against a gun, knife or other attack. In one embodiment of the invention, the inconspicuous ballistic armor takes the form of a desktop calendar that may be placed on top of a teacher's or student's desk and, in ordinary, everyday use, be used as a desktop calendar.
In one embodiment, ballistic shield 10 comprises a high strength and lightweight material such as Kevlar® brand para-aramid synthetic fiber formed into a ridged panel. Alternatively, or in combination, thin, flexible ballistic composites made from two or more layers of unidirectional fibers held in place by flexible resins, steel, aluminum or alumina ceramic may be used. For example, shield 10 may be formed from a strong, flexible ultra-high molecular weight polyethylene (UHMwPE) material such as Endumax® brand fiber and/or Dyneema® brand fiber, and/or from a lightweight, high strength fiber such as Spectra Shield® brand fiber. Any of these materials may be used alone or in any combination to provide the desired level of ballistic performance. In one implementation, the UHMwPE material from which shield 10 is formed is Endumax® from Teijin Aramid B.V.
As shown in
In addition, shield 10 may be covered with vinyl wrap, thereby enabling virtually any surface appearance to be placed on the shield. Shield 10 may have the look and texture of carbon fiber, brush metal or wood grain, for example. The vinyl wrap may be a solid color, a poster print, or any desired map or design.
In one implementation of the smaller shield embodiment of
In another implementation of the smaller shield embodiment of
In a further implementation of the smaller shield embodiment of
In one implementation of the larger shield embodiment of
In another implementation of the larger shield embodiment of
In a further implementation of the larger shield embodiment of
In another implementation of the larger shield embodiment of
In a further implementation of the larger shield embodiment of
It should be noted that the weights discussed above are for the shield alone. Once the ballistic armor is fully assembled with hand and arm straps, hardware for attaching the straps, etc., as discussed below, the weight of the fully assembled armor will be increased by approximately one pound.
In order to make the ballistic armor easily recognizable as ballistic armor, despite its inconspicuous appearance as an ordinary article in its environment, an identification icon 14 or other indicator may also be provided on the front surface of shield 10. In the illustrated embodiment, which of course is merely one example and not limiting, identification icon 14 takes the form of a small red icon or logo in the upper right corner of shield 10. Identification icon 14 may be of a glow-in-the-dark material. Thus, a person finding themselves in an active shooting situation will easily be able to recognize the article as ballistic armor, and quickly obtain and deploy it.
As shown in
Straps 16 and 18 may be formed from any suitable material including, without limitation, nylon, polypropylene, cotton, polyester, Nomex®, Kevlar®, polybenzimidazole (PBI) fiber, Vectran® and Dyneema®. In one implementation, straps 16 and 18 are formed from a combination of nylon and synthetic rubber that allows the straps to stretch by as much as 50%. In one implementation, VELCRO® brand VELSTRETCH® loop fasteners are used. Alternatively, straps 16 and 18 may be formed from a non-stretch loop, or a combination of stretch and non-stretch materials.
Straps 16 and 18 are riveted, bolted or attached to the rear surface of shield 10. As shown in
As shown in
In a second embodiment of the invention, in addition to a core formed from a ballistic material as described above, the shield also includes a sheet of hardened steel affixed to its front surface. A shield 50 according to the second embodiment of the invention is illustrated in
Shield 50 is characterized by a sheet 54 of hardened steel that is installed over the front surface of core 52. In one implementation, hardened steel sheet 54 is an abrasion-resistant (AR) steel such as Hardox® 450 manufactured by SSAB and has a thickness of 0.028 inches. Hardened steel sheet 54 is illustrated in more detail in
To further secure core 52 with mechanical fasteners, steel tabs 63 bent at a ninety degree angle may be added to each corner in order to prevent up and down core movement. See, for example,
To facilitate the attachment of arm straps and hand holds on the rear of shield 50, fastener pins 64 are installed through rear edge 62 of hardened steel sheet 54. In one implementation, as shown in
Hardened steel sheet 54 is fixed to core 52 by applying an epoxy resin between core 52 and steel sheet 54, and then clamping sheet 54 to core 52 while the epoxy resin hardens. In addition, core 52 and steel sheet 54 are preferably encapsulated by a protective coating layer 66 (
The combination of a core formed from an ultra-high molecular weight polyethylene and thin sheet of hardened steel over the front surface of the core provides a synergistic effect in dispersing the force of an impinging bullet. A bullet that strikes shield 50 first impacts hardened steel sheet 54. The bullet is slowed down by sheet 54 and forms a hole through sheet 54. As the bullet forms a hole and passes through sheet 54, edges of the steel sheet surrounding the hole in the sheet flair out and push into the material of the immediately adjacent core 52. This phenomenon is known as bullet “spalling”. The steel fingers and fragments pushing into core 52 interact with the core material to create a synergistic effect, further slowing the bullet down and trapping it within core 52.
The use of a protective coating layer 66 such as Line-X® coating serves to further strengthen and protect shield 50. Protective coating layer 66 encapsulates shield 50, and protects steel sheet 54 from rusting. Importantly, the protective coating also captures bullet fragments created when the bullet hits the shield (bullet “splashing”), thereby protecting the user of the shield and other bystanders from bullet shrapnel and fragments.
In one optional implementation, shown in
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The combination of an ultra-high molecular weight polyethylene (UHMwPE) core with a thin sheet of abrasion-resistant (AR) steel is advantageous and has applications beyond the shield described above. This combination may be used to provide ballistic protection in, for example, vehicles such as aircrafts and ships, body armor and helmets. In one implementation, the combination of an UHMwPE core and thin sheet of AR steel is implemented in an interior door panel or as a replacement for an interior door panel of a police car in order to provide ballistic protection. In one model, the panel is removable and has arm and handhold straps, so as to be usable for mobile ballistic protection. Additionally, the panel could have a dropdown panel extension to provide leg and feet ballistic protection when sheltering behind an open door.
The use of a thin sheet of abrasion-resistant steel allows reduction of the otherwise required thickness of the UHMwPE core. For example, if a UHMwPE core alone having a thickness of twelve inches is required to meet a certain threat level, the use of abrasion-resistant hardened steel with the UHMwPE core reduces the thickness of the core that is required to meet the threat level. For example, if used in combination with a sheet of AR steel having a thickness of ⅜ inches, the UHMwPE core may require a thickness of only nine inches (rather than twelve inches without the AR steel sheet). Thus, the use of a sheet of hardened AR steel in combination with a UHMwPE core advantageously addresses supply issues that may arise with respect to UHMwPE materials for the core, thereby providing supply and cost savings. In addition, the use of a steel sheet in combination with the UHMwPE core is advantageous in that attachment points can be provided through the steel virtually anywhere on the product without the necessity of putting fasteners through the core itself, or otherwise affecting the integrity of the core.
The use of a D30 interior (padding) in combination with the thin AR steel placed on a UHMwPE core provides yet further advantages, especially in personal armor applications (i.e. helmets, body armor, shields) where weight, bulk and level III protection is an even greater concern.
In an alternative implementation, the shield is made without steel on the front, except for a two inch board around the edges. This advantageously reduces the weight of the shield.
In one implementation, the ballistic armor incorporates digital chip technology that enables the armor to be an Internet of Things (IoT) connected device. Connecting the armor to the Internet enables movement of the armor to be autonomously tracked. This is of critical importance in an active attack situation for law enforcement or others to see mapped movements of the armor in real time. Thus, a tangible safety product (the shield) is provided and coupled with an IoT safety system that works without human intervention (autonomously). In a school or campus environment, situational awareness may be provided for 1-200+ shields per campus. Other applications could include fire extinguishers, defibrillators, etc.
In the event of an attack, the critical and best first move is immediate protective use of the shield to protect oneself and others from the attacker. Next, in order to provide immediate situational awareness to others on campus and first responders, an alert is sent out from the shield via the IoT connection. An accelerometer is built into the shield or processor in order to detect movement and rate of movement (acceleration) of the shield. The processor includes a GPS connection that determines and provides the location of the shield. When shield motion of a pre-defined acceleration and time is detected by the system, the system “awakens” and an alert is immediately sent by the processor on the shield to a central server which in turn alerts first responders.
Software on the shield processor stores data, performs computations and communicates with software on a user-connected computer or mobile device that is connected to the central server, and generates an online map of the campus or other environment including locations and movement of the shields. Within the processor, edge processing is used to store data and perform computations that includes maps and pre-recorded audio. The processor is highly capable and enables real time speeds. It has the ability of two way communications, including an accelerometer and blue tooth, wifi, cell and GSP connections. The processor also provides compass direction and gyroscopic direction.
In one implementation, a chip is utilized that includes four processors. One of the processors is an on-shield server. Another processor is used only for the asleep/awake process, thereby allowing for only micro amps of energy to be used while asleep, with the ability to wake up the processors on other shields in the event of an attack. In addition, each shield has its own battery. Since each shield has its own battery and processing capability, the shields can communicate with each other without the need of an outside power source.
Maps may be pre-loaded in order to assist response time and geo-fencing and may be integrated with mapping software or mobile applications already present on the device. Such software and mobile applications typically have great values of their own, and the addition of situational awareness information to the application during an attack or emergency situation combines to create an unmatched powerful solution. Integration with an existing mapping application is also advantageous in that, since the user likely already uses the application regularly, the user will likely already have proficiency and ease of use with the application.
The shields may be depicted on the map by icons such as rectangles or any other appropriate icon. The shield icon may change its color or otherwise have its appearance altered in the event of movement of the represented shield. For example, any shield in which movement has been detected may change from gray to green on the map. In addition, colors or words may be used to depict the rate of movement of the shield (ranging from low to rapid) detected by the accelerometer. For example, words (“stop”, “walk”, “run”, “stairs”, etc.) or icon colors/appearance may be used to depict the type of movement. Shield movement may be tracked room-by-room, and the timing order in which movement of various shields occurs may also be tracked. The percent of moving and non-moving shields may also be displayed based on accelerometer data.
On the shields themselves, audio and visual alert capabilities are provided that are activated in the event of detection of motion of at least one shield in the campus or other environment. For example, the shield may include visual alerts such as a light or other visual indicator, and audio alerts such as a buzz or vibration, and an alert status announcement. The shield may also include a display screen for displaying alert status messages.
The shields also include an “Attacker-In-Sight” button to be pressed by the user of the shield when the attacker is in sight. The pressing of this button causes a signal to be sent by the shield to the central server, which in turn changes the shield icon on the online map to indicate that an attacker is in sight of that particular shield. For example, a dot may be placed next to the shield icon to indicate attacker-in-sight. In one implementation, anytime the attacker-in-sight button is pressed, a blue dot tracks with the shield icon, and if the button is repeatedly and rapidly pressed, a red dot is placed next to the shield to indicate in real time that the attacker is within close proximity to that shield. The percentage of “red” shields and “blue” shields may also be displayed.
The various types of data gathered by the shield and sent to the server can be used to generate a grid overlaid on the map showing the probable attacker location and predictive movement of the attacker (i.e., similar to a hurricane tracking grid). This data includes which shields are moving, at which locations, and at what rates, the order of movement of the shields, and those shields signaling an attacker-in-sight.
At the first movement of any shield, all shields on the campus light and buzz alerting everyone of an attack and room-by-room tracking of each shield is initialized. The attacker in-sigh button can be used to send additional notifications. Audio/visual instructions to “stay-in-place” or real-time directional guidance through a safe escape path is provided to each affected individual. Mobile devices show arrowed paths to safety and audio direction instructions guide each person away from the danger area. The mapped danger/safe area grids are also shared with first responders, enabling targeted response zones and shortening response times. Autonomous and manual inputs are configured based on campus needs, including the amount of movement required to alert, timeframes to alert, who is alerted, and what information is provided to each group.
Thus, the present invention provides autonomous alerts and campus wide “room-by-room” location tracking of each shield that is displayed and shared online. Two-way alert communications between the shield and online system are provided, facilitating real-time situational awareness for on-campus individuals and first responders. The instant physical protections of the shields and the improved response time through IoT technology is a powerful combination, since every fraction of a second of improved responsiveness can mean a life saved. In an attack, the quickest possible protection and response is critical. The short time available for mounting an effective response is coupled with a rapidly changing and complex environment, with the level of complexity directly tied to the number of people affected within confined areas. These difficult facts highlight the importance of not only instant and adaptable physical protections, but the value of real-time situational awareness for all effected people and responders.
The present invention provides inconspicuous ballistic armor disguised as an ordinary, everyday article in the environment in which it is deployed. Although the description has focused primarily on an implementation of a ballistic shield disguised as a desktop calendar, limitless other implementations are possible. To mention just a few alternative implementations, without limitation, the ballistic armor could be implemented as a hanging shield in which artwork is mounted on a front surface thereof, and hand/arm straps are affixed to a rear surface. The ballistic armor could be implemented as a cafeteria or restaurant tray with hand/arm straps on a rear surface thereof. In an environment including seating, the ballistic armor could be implemented as an easily detachable seat cushion, with the cushion attached to a front surface of the ballistic shield, and hand/arm straps attached to a rear surface of the ballistic shield. In sum, the crux of the present invention, which is a ballistic shield or barrier having an everyday article affixed to a front surface thereof, and hand/arm straps affixed to a rear surface thereof, may take on virtually limitless configurations.
In yet another alternative implementation, the ballistic armor is implemented as a white board, cork board, or standing display, and is mounted on wheels to be easily moved by rolling. The ballistic armor may be mounted, for example, on a stand such as a flat panel TV stand with wheels to permit rolling. An implementation in which a larger shield is mounted on a stand with wheels is advantageous in that the weight and larger size of the shield can be more easily handled; the use of wheels and possibly brakes makes the shield more mobile and easily movable; a larger area of protection is provided; and a height adjustable stand permits easy height adjustments of the shield.
This application claims the benefit of priority under 35 USC 119(e) of U.S. provisional application No. 62/772,332, filed on Nov. 28, 2018, U.S. provisional application No. 62/680,289, filed on Jun. 4, 2018, and U.S. provisional application No. 62/638,714, filed on Mar. 5, 2018.
Number | Date | Country | |
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62772332 | Nov 2018 | US | |
62680289 | Jun 2018 | US | |
62638714 | Mar 2018 | US |