Abstract: A blast treatment method and an apparatus, which can perform the blast treatment of a treatment subject by using and securely initiating a blasting explosive having fluidity. The blast treatment method includes: a blasting preparation operation of housing a blasting explosive having fluidity in a container and placing the blasting explosive around a treatment subject as well as attaching an initiation device to the container; a housing operation of housing the container, the blasting explosive, and the treatment subject in a chamber; a decompression operation of decompressing the inside of the chamber; and a blasting operation of initiating the blasting explosive and blasting the treatment subject with the blasting explosive. In the decompression operation, the inside of the chamber is decompressed while a gas vent portion regulates the escape of the blasting explosive to the outside of the container and permits the escape of gases in the container to the outside.

Abstract: A blast treatment method for blasting a treatment subject having an outer shell and a chemical agent charged into an interior of the outer shell includes the steps of: disposing an explosive to cover a periphery of the treatment subject; and detonating the explosive from respective end portions of a specific direction toward a predetermined cutting position of the treatment subject between the respective end portions so that detonation waves of the explosive advancing from respective sides of the cutting position collide in the cutting position, wherein, in the step of detonating the explosive, the chemical agent is exposed by cutting the outer shell in the cutting position through detonation of the explosive, and the chemical agent is decomposed using the detonation.

Abstract: Provided is a blast treatment method that can be implemented simply and efficiently blast a treatment subject while preventing fragments of the subject from scattering outward.

Abstract: A system for disabling or degrading electrically initiated explosive devices includes an apparatus for inducing waveforms of varying power and duration into the leads of a bridgewire based blasting cap, thus raising the resistance to render the blasting cap inoperable without requiring detonation, and for polling or confirming electrical performance and operational status of the blasting cap. An operational methodology for neutralizing an explosive device is included.

Abstract: A portable protective shield for an IED or other suspected explosive devices includes a plurality of toroidal rings clamped between a lid and a base of the shield. The device is capable of withstanding high-pressure blast waves, thermal release and/or high-velocity fragments.

Abstract: The invention relates to a pyrotechnic device for the destruction of munitions by an explosive at least partially surrounding the munitions having walls for confining the active products. The device includes an igniter for the controlled ignition of the explosive, the igniter configured to couple explosive detonation waves into the walls of the munitions along at least two opening lines of said walls of the munitions. Application of embodiments of the invention includes controlled destruction of munitions or objects containing pyrotechnic and/or chemical substances.

Abstract: Methods are disclosed for neutralizing weapons carried on a person or in a vehicle. This is accomplished using Nuclear Magnetic Resonance. The information in this abstract is not meant to limit the scope of the claims in any way.

Abstract: An explosive assembly adapted to destruction of artillery and other large ordnance shells; said explosive assembly comprising a pair of hollow half shells; each of said half shells formed with an internal cavity conforming to at least a portion of external surfaces of an ordnance shell to be destroyed.

Abstract: A portable containment chamber for safely disposing of suspected explosive threat devices comprises a cylindrical chamber body and hinged outward-opening access door. The door seals against a tapered seat and extends convexly into the interior of the chamber, whereby blast pressure tends to expand the door into enhanced gas-tight sealing engagement. The mouth of the chamber has an annular locking channel with which the door is locked in closed position by an expandable interconnected locking shoes driven by a crank-and-piston linkage such that all shoes are simultaneously locked and unlocked by movement of a common crank. A two-stage door operating mechanism first moves the unlocked door axially out of sealed position, and then rotates it to one side to provide access to the interior of the chamber. For closing, the sequence of movements is reversed.

Abstract: An assembly for attenuating shock waves is made of two flexible sheets arranged one over the other and joined by a plurality of seams, the flexible sheets being confined to form cells or recessed when joined together. The seams are arranged so as to surround the cells or recesses in the sheets, and the cells or recesses are filled with a shock attenuating material.

Abstract: A protection device comprises a covering including at least a layer of ballistics material, and a layer of an electromagnetic screening material.

Abstract: A method of identifying and optionally neutralizing an undersea object (1, 1?) that might be an undersea mine and that is of known geographical position, in which an undersea intervention robot (4, 4?) is used suspended under an aircraft capable of stationary flight, such as a helicopter (7) or a drone, serving to bring the robot (4, 4?) into register with the object (1, 1?) for identification and possibly for being neutralized, the object is identified, and optionally it is neutralized.

Abstract: A recoil dissipation apparatus may include a linear roller rail and a roller block that is translatable on the linear roller rail with only one degree of freedom. A gear rack may be located adjacent the linear roller rail. A barrel clamp may be fixed to the roller block. A pinion gear may engage the gear rack. The pinion gear may be fixed on a shaft. The shaft may have a rotary viscous damper fixed at one end. The recoil force from a barrel fixed in the barrel clamp may cause translation of the roller block and dissipation of the recoil force by the rotary viscous damper.

Abstract: A kit of modular explosive ordnance disposal components may include five components. The five components may be assembled in various configurations to fire solid slugs, water shots, or fin-stabilized projectiles. Each assembled configuration may include a first component having a generally cylindrical shape, a through-bore, a muzzle end, and a breech end. The muzzle end of the first component may include external threads. The breech end of the first component may include an internally-threaded portion for receiving a .50 caliber breech plug. A .50 caliber cartridge chamber may be formed adjacent the internally-threaded portion. A bore of about one inch in diameter may extend from the .50 caliber cartridge chamber to the muzzle end of the first component.

Abstract: A system and/or method for securing areas (e.g. airport terminals, courtrooms, embassies, borders, property surrounding critical infrastructure, areas within cities/towns, etc.) against terrorists is provided. In certain example embodiments, a system and/or method is provided wherein individuals pass (e.g. walk, drive, etc.) through a gateway before gaining access to a secured area. Signals capable of detonating certain explosives that might be carried by the individuals passing through the gateway are emitted in or proximate the gateway. The gateway may be shielded to minimize damage to the surrounding areas. In certain example embodiments, arc currents are generated to trigger the detonation of explosives. In certain example embodiments, explosives may be detonated using cellular signals.

Abstract: A warhead apparatus, method of making same, and method of detonating same comprising employing a high explosive core, an energetically and physically dense reactive material substantially surrounding the core, and a pressure vessel substantially surrounding the reactive material.

Abstract: A system, a firing apparatus and method for disrupting at least one electrical component of an explosive device are provided. The system has an electrical cartridge, the firing apparatus and an initiator. The electrical cartridge has a projectile at an end thereof deployable into the electrical component(s). The firing apparatus has a barrel, a breech and an electrical contact. The barrel has a firing end aimable toward the electrical component, and a passage therein for receiving the electrical cartridge. The breech is operatively connectable to the barrel. The electrical contact is positionable in the breech in operative contact with the electrical cartridge. The electrical contact is operatively connectable to the initiator. The initiator selectively provides an electrical signal to the electrical cartridge via the electrical contact whereby the electrical cartridge may be activated to deploy the projectile from the firing end of the barrel.

Abstract: Apparatus and methods are provided for purging an airlock cavity created between the airlock access door and the primary explosion chamber opening sealing mechanism. According to one embodiment of the present invention, an airlock device is used to ensure that, in the event toxins are released from the primary explosion chamber opening sealing means, the toxins are properly handled and are not inadvertently released into the atmosphere. In one embodiment, negative pressure is used to vacuum the entrained air within the airlock cavity subsequent to an explosion. To facilitate the sweeping and exhausting of the cavity, an orifice in the access door may be operable to allow the flow of ambient air through the airlock access door.

Abstract: The present invention relates to mechanical devices and methods allowing the safe removal of heavy, difficult to handle fragments from an explosive destruction system (EDS).

Abstract: An apparatus for neutralizing an explosive comprises a housing including at least one relief groove along an outer portion of the housing, and an inner chamber. The inner chamber includes a first hollow section and a second hollow section. The cross-sectional area of the second hollow section is smaller than the cross-sectional area of the first hollow section. A forward section of the housing is adapted to receive a first nose member and a rear section of the housing is adapted to receive a removable fin set.

Abstract: A system and method of detecting, locating, geolocating and providing diagnostics on electronic devices includes use of emission detection apparatus, information collected over a network and template containing emission signatures. Collected unintended emissions are compared to an emission signature in the template preferably constructed from the information collected on the network. Using the known location of the electronic device, the emissions measurement device is then used to detect and identify other devices in the vicinity of the electronic device that is connected to the network. The emission detection apparatus includes a high sensitivity receiver for receiving and analyzing electronic emissions. The network collection apparatus could be any software manifestation known in the art for collecting information about a device such as a cookie or online fingerprinting or a hardware based collection mechanism.

Abstract: A method is provided for recovering and/or exploded an unexploded munition. The method including: providing the munition with a power supply having a piezoelectric material for generating power from an induced vibration; inducing a vibration; monitoring an output from the power supply after the power supply has stopped generating power from a firing of the munition; and generating a beacon signal or detonation signal upon the detection of the output.

Abstract: Provided is a blast treatment method that can be implemented simply and efficiently blast a treatment subject while preventing fragments of the subject from scattering outward.

Abstract: It is intended to provide a pressure container which can prevent dispersion of a hazardous substance or the like to the exterior and ensure a high level of safety with a simple structure. To achieve this object, a pressure container (10) comprises an outer vessel (30) and an inner vessel (40) which receives an impact load produced at the time of blasting disposal operation. The inner vessel (40) is disposed inside the outer vessel (30). The inner vessel (40) has a pressure relieving part (50) which can discharge part of high-pressure gas produced in the inner vessel (40) at the time of the blasting disposal operation into a gap formed between the inner vessel (40) and the outer vessel (30).

Abstract: A liquid-jacketed disrupter comprising a container (101) for receiving liquid and housing a receptacle (120) for explosive material, in which the container comprises one or more indentations (115) which result in the generation of liquid jets upon detonation.

Abstract: A blast treatment method for blasting a treatment subject having an outer shell and a chemical agent charged into an interior of the outer shell includes the steps of: disposing an explosive on the outer side of the outer shell such that a difference occurs in a detonation pressure of the explosive, that acts on the outer shell from an outer side, between one side and another side of a predetermined cutting position of the outer shell and the outer shell is cut by a shearing force generated as a result of the difference in the detonation pressure; and detonating the explosive, wherein, in the step of detonating the explosive, the chemical agent is exposed by cutting the outer shell in the cutting position through detonation of the explosive, and the chemical agent is decomposed using the detonation.

Abstract: A blast treatment method capable of performing blast treatment of a treatment subject with a simple structure, with high efficiency, and at low cost, while inhibiting scattering of harmful substances or the like to the outside. The method includes: inside disposing an inside explosive for blasting a treatment subject around the treatment subject; disposing an outside explosive having a detonation velocity greater than that of the inside explosive at a position outside the inside explosive; and detonating the outside explosive using an initiation device, and initiating the inside explosive by detonation of the outside explosive, thereby performing blast treatment of the treatment subject by initiation of the inside explosive.

Abstract: Provided is a blast treatment method that enables blast treatment of a treatment subject in a sealed container to be carried out easily and safely. This blast treatment method implements: a shaped charge placement step of placing a shaped charge 70 at a location outside a sealed container 40; a blasting explosive placement step of placing a blasting explosive 20 for blasting a treatment subject 10 at a location outside the sealed container 40; a housing step of housing the sealed container 40 in which the treatment subject 10 is housed in a sealable chamber 90; a dividing step of initiating the shaped charge 70 and dividing the sealed container 40 at prescribed dividing surfaces 40a and 40b with the initiated shaped charge 70 to expose the treatment subject 10; and a blasting step of blast-treating the exposed treatment subject 10 with the blast energy of the blasting explosive 20 by initiating the blasting explosive 20 in the sealed chamber 90.

Abstract: A blast treatment method enables easy and safe blast treatment of ammunition having propellant provided with a warhead having a bursting charge and a propulsion unit having a propellant.

Abstract: A blast treatment method and an apparatus, which can perform the blast treatment of a treatment subject by using and securely initiating a blasting explosive having fluidity. The blast treatment method includes: a blasting preparation operation of housing a blasting explosive having fluidity in a container and placing the blasting explosive around a treatment subject as well as attaching an initiation device to the container; a housing operation of housing the container, the blasting explosive, and the treatment subject in a chamber; a decompression operation of decompressing the inside of the chamber; and a blasting operation of initiating the blasting explosive and blasting the treatment subject with the blasting explosive. In the decompression operation, the inside of the chamber is decompressed while a gas vent portion regulates the escape of the blasting explosive to the outside of the container and permits the escape of gases in the container to the outside.

Abstract: A blast treatment method for blasting a treatment subject having an outer shell and a chemical agent charged into an interior of the outer shell includes the steps of: disposing an explosive to cover a periphery of the treatment subject; and detonating the explosive from respective end portions of a specific direction toward a predetermined cutting position of the treatment subject between the respective end portions so that detonation waves of the explosive advancing from respective sides of the cutting position collide in the cutting position, wherein, in the step of detonating the explosive, the chemical agent is exposed by cutting the outer shell in the cutting position through detonation of the explosive, and the chemical agent is decomposed using the detonation.

Abstract: A fluid blade disablement (FBD) tool that forms both a focused fluid projectile that resembles a blade, which can provide precision penetration of a barrier wall, and a broad fluid projectile that functions substantially like a hammer, which can produce general disruption of structures behind the barrier wall. Embodiments of the FBD tool comprise a container capable of holding fluid, an explosive assembly which is positioned within the container and which comprises an explosive holder and explosive, and a means for detonating. The container has a concavity on the side adjacent to the exposed surface of the explosive. The position of the concavity relative to the explosive and its construction of materials with thicknesses that facilitate inversion and/or rupture of the concavity wall enable the formation of a sharp and coherent blade of fluid advancing ahead of the detonation gases.

Abstract: An object of the present invention is to improve durability of a pressure vessel for blasting an article to be treated such as hazardous substance or explosive therein. The pressure vessel 10, means for achieving the object, has an external vessel 31 and an internal vessel 32 installed in the external vessel 31. The external vessel 31 has a strength for retaining pressure caused by blasting the article. The internal vessel 32 receives fragments of the treated article 100 to protect the external vessel 31 against the fragments. The internal vessel 32 preferably covers almost entire internal surface of the external vessel 31.

Abstract: An explosive device that can generate a projectile from the opposite side of a wall from the side where the explosive device is detonated. The projectile can be generated without breaching the wall of the structure or container. The device can optionally open an aperture in a solid wall of a structure or a container and form a high-kinetic-energy projectile from the portion of the wall removed to create the aperture.

Abstract: Detonators comprising a base charge of explosive material present a safety hazard for transportation and storage, especially when a plurality of detonators are packaged together. Disclosed herein are detonator protectors for the explosive ends of detonators that, at least in preferred forms, prevent ejection of shrapnel and/or explosive energy upon detonator actuation. Also disclosed are corresponding detonator assemblies, packages comprising protected detonators or detonator assemblies, and corresponding packaging methods.

Abstract: A method of blasting hazardous substance or explosive in a pressure vessel is provided to improve efficiency while suppressing enlargement of the pressure vessel. To achieve it, the method includes an installing step of installing two or more articles to be treated at a certain spacing in the pressure vessel, an initial blasting step of blasting one of the articles to be treated, and a following blasting step of blasting the article to be treated next to the previously blasted article to be treated after a particular time from the instant of the previous blast. Each of the articles is blasted sequentially through the initial and following blasting steps.

Abstract: A hybrid water cannon that can be configured in either a recoil mode or recoilless mode. A first barrel is attached to a breech block. Either a second barrel or breech plug is also attached to the breech block on a side opposite the first barrel. With the breech plug attached, the water cannon is in a recoil mode. With the second barrel attached, the water cannon is in a recoilless mode. A chamber containing a propellant charge is in communication with both the first and second barrels. Upon ignition, the propellant charge pushes a charge of water from both barrels simultaneously and in opposite directions. The discharge from the first barrel is used to disable the target ordnance. The discharge from the second barrel counters the recoil. The propellant charge is ignited using an ignition charge in a port intersecting the chamber at an angle other than 90 degrees.

Abstract: Systems and methods are presented herein that provide for ignition of explosive devices through electric and/or electromagnetic discharge. In one embodiment, an electrostatic discharge is directionally propagated through air to conduct electric current to the explosive device. The electric current may ignite the explosive device via heat, via triggering of ignition circuitry, via induced electric current conduction to the explosive material therein and/or via direct electric conduction to the explosive material therein. Alternatively, or in addition to, electromagnetic energy may be directionally propagated to the device through a waveguide. Such electromagnetic energy may be in the microwave region and may heat and/or induce electric current in the explosive device. In either instance, the directionally propagated energy may be time varying.

Abstract: A ballistic barrier incorporates a flexible ballistic blanket having a threat side and a protected side, opposing top and bottom edges, and opposing side edges. A plurality of spaced-apart elongated stiffening elements extend longitudinally between opposing top and bottom edges of the ballistic blanket. An elongated structural brace extends laterally between opposing side edges of the ballistic blanket, and is arranged to support the ballistic blanket in a desired lateral configuration.

Abstract: Disclosed is an airbag deployment device that includes a containment vessel and a retention rack disposed within the containment vessel, wherein the retention rack comprises at least one container, and wherein at least one airbag pyrotechnic actuator may be placed within the at least one container and secured through utilization of at least one pin.

Abstract: A safe inspection system for the manual inspection of personal luggage, which comprises an inspection module including at least one inspection member which defines an inspection surface, for supporting a potentially explosive object for manual inspection by an inspector; a blast containment container arranged in a position of immediate communication with the inspection module; and transfer means for effecting the immediate transfer of a suspicious inspected object from the inspection surface to the blast containment container by an inspector without requiring further handling of the object by the inspector, thereby to immediately confine the object within the blast containment container and so as to thus reduce the reduce blast damage in the event that the suspicious object explodes after confinement therewithin. The present invention also includes a kit for converting a blast containment container to a safe inspection system.

Abstract: Disclosed is a method for neutralizing explosives and electronics utilizing a high voltage electrical discharge.

Abstract: Methods and apparatus for providing ballistic protection and stopping high-velocity rounds or explosives and a secure trash can. These and other advantages may be provided by a secure trash can for containing explosions resulting from explosive devices deposited in the secure trash can. The secure trash can includes a curved wall, including an inner liner, a curved ballistic panel, including a three-dimensional core that defines spaces and acts as a truss for ballistic panel and a filler, the filler fills in spaces defined by the three-dimensional core, an outer layer, surrounding the curved ballistic panel, and a base, connected to the curved wall. The secure trash can may also include a lid, placed on the curved wall.

Abstract: Disclosed is a method for neutralizing explosives and electronics utilizing a high voltage electrical discharge.

Abstract: Methods and apparatus for providing ballistic protection and stopping high-velocity rounds or explosives and for constructing protective structures. The apparatus includes a building block, one or more ballistic panels configured to fit within the building block, each ballistic panel includes a three-dimensional core that acts as a truss for the ballistic panel, and a filler. The filler fills in spaces defined by each three-dimensional core and any empty spaces in the building block. The one or more ballistic panels and the filler are inserted into the building block. The building block is shaped to interlock with other building blocks.

Abstract: A rapidly deployable portable convertible blast effects shield/ballistic shield includes a set two or more frusto-conically-tapered telescoping rings operably connected to each other to convert between a telescopically-collapsed configuration for storage and transport, and a telescopically-extended upright configuration forming an expanded inner volume. In a first embodiment, the upright configuration provides blast effects shielding, such as against blast pressures, shrapnel, and/or fire balls. And in a second embodiment, the upright configuration provides ballistic shielding, such as against incoming weapons fire, shrapnel, etc. Each ring has a high-strength material construction, such as a composite fiber and matrix material, capable of substantially inhibiting blast effects and impinging projectiles from passing through the shield.

Abstract: Methods and apparatus for providing ballistic protection and stopping high-velocity rounds or explosives and a secure trash can. These and other advantages may be provided by a secure trash can for containing explosions resulting from explosive devices deposited in the secure trash can. The secure trash can includes a curved wall, including an inner liner, a curved ballistic panel, including a three-dimensional core that defines spaces and acts as a truss for ballistic panel and a filler, the filler fills in spaces defined by the three-dimensional core, an outer layer, surrounding the curved ballistic panel, and a base, connected to the curved wall. The secure trash can may also include a lid, placed on the curved wall.

Abstract: An apparatus useful in the removal of toxic materials from toxic weapon projectiles has a base, a projectile retaining container and a ram. The projectile retaining container has a projectile retainer opening, a ram opening and a drain opening. The projectile retaining container is adapted to retain a toxic weapon projectile in the projectile retainer opening. The ram is adapted to extend into a toxic weapon projectile disposed within the projectile retaining container to crush the projectile's burster well and to thereby release toxic materials to the drain opening in the projectile retaining container. The ram alternatively includes high pressure water nozzles for breaking up any coagulant particles and for thoroughly rinsing the interior side walls of the toxic weapon projectile.

Abstract: It is intended to provide a blasting treatment apparatus which can prevent dispersion of a hazardous substance or the like to the exterior with a simple structure. To achieve this object, a blasting treatment apparatus (1) comprises a pressure container (10) including an outer vessel (31) and an inner vessel (32) and a suction device. The outer vessel (32) has a first sucking part (17) and a second sucking part (18) for interconnecting the interior and the exterior of the outer vessel (31) at an end thereof opposite to a pressure-resistant lid (11) and in an upper wall. The inner vessel (32) has an interconnect hole (16) for interconnecting the interior and the exterior of the inner vessel (32) at a location thereof corresponding to the first sucking part (17).

Abstract: A portable checkpoint system is disclosed that incorporates a configurable freight container to intercept and inspect an approaching vehicle. The container includes a quadrilateral set of walls connectable to form a rectangular box, first and second ends of the walls, a blast plate disposed within the box, and a receptacle for mounting a device. At least one of the ends includes a door. The blast plate is disposed between two interior surfaces of the quadrilateral set of walls for absorbing shock and shrapnel, such as at an oblique angle. The mounted device is an instrument for measuring a characteristic of the vehicle. Another such device is a lamp for illuminating the vehicle. The checkpoint includes an obstacle to direct the vehicle in traffic flow, and a pair of configurable freight containers as described. The obstacle directs the vehicle towards the zone. The containers are disposed substantially parallel to each other and separated apart to form a zone that enables the vehicle to pass there-between.