A cap for an explosive water charge includes a top surface and a generally cylindrical portion extending downwardly from the top surface. On the outer surface of the generally cylindrical portion are rings and cantilevered, pointed rectangles that enable a water tight fit in the neck of a drinking bottle. The cap is configured to hold a detonator, such as a blasting cap, and two different sizes of tubes of energetic material.

An underwater disruptor comprises a water tight chamber formed by a modified housing, a modified breech, and a modified backplate sealed together by a plurality of O-rings. The underwater disruptor is configured to discharge a firing pin to shoot a water bullet from the modified barrel at a specific underwater explosive threat responsive to receiving a fire command from a remote operator. The water bullet is formed from water ejected from the barrel due to the discharge. The underwater ROV physically hosts the underwater disruptor and is configured to provide video feedback during underwater travel remotely to the specific underwater explosive and to activate shooting of the water bullet responsive to the fire command.

A multidirectional explosive disruptor system including a disruptor container cavity; a disruptor tube having an initiating explosive chamber extending from a disruptor tube open end to a disruptor tube shoulder and a primary explosive chamber extending from the disruptor tube shoulder to a disruptor tube bottom wall; a container cap having a aperture formed therethrough; and a strain relief connector having a body portion with external strain relief connector body threads, the body portion being at least partially insertable through the aperture such that at least a portion of the external strain relief connector body threads extend through the aperture, the external strain relief connector body threads formed so as to interact with internal disruptor tube threads to repeatably threadedly attached the strain relief connector to the disruptor tube.

A disrupter cannon is used to disrupt or destroy explosive devices. A disrupter cannon may launch a liquid (e.g., water) toward an explosive device to disrupt the explosive device. The liquid may be launched through a nozzle. The nozzle may include passages that spread the liquid to for a column of liquid with a cross-section. A nozzle that provides a column of liquid with an oval cross-section may be more effective at disrupting certain types of explosive devices.

A disrupter cannon and a reducer for increasing a pressure of water expelled from the disrupter cannon to disable an explosive device housed in a hardened container.

A liquid disruptor device and a method of manufacturing the same are introduced. The liquid disruptor device comprises a front casing, a liquid seal film, a rear casing, a plane wave generator and a counter-impact cover. The plane wave generator generates a plane blast wave which compresses a liquid contained in the front casing and a liner to not only focus blast energy of the liquid but also allow the liquid to form a liquid knife current for destroying explosives. Hence, the liquid disruptor device displays higher efficiency per unit weight of explosives when detonation thereof occurs at multiple points. Further, a liquid disruptor device module inclusive of at least two liquid disruptor devices combined to assume a geometric shape is introduced.

A delaboration chamber has an outer housing that can be sealed by a removable cover. The delaboration chamber has an inner floor. A first chamber region is formed underneath the inner floor by the inner floor and the outer housing. The first chamber region is filled with a flowable or solid medium. The inner floor has a recess for receiving an explosive object. The cover is connected to the outer housing in a shockproof manner. The cover has a pressure relief that has at least one deflection for the detonation gases.

A fluid jet assembly for washing out material from a cavity. The fluid jet is capable of oscillating in a overlapping revolutions to ensure complete washout of the material in the cavity, preferably an energetic-containing material.

A gas powered fluid gun for propelling a stream or slug of a fluid at high velocity toward a target. Recoil mitigation is provided by a cavitating venturi that reduces or eliminates the associated recoil forces, with minimal or no backwash. By launching a quantity of water in the opposite direction, net momentum forces are reduced or eliminated.

Some variations provide a cut-and-capture system configured for demilitarization of an underwater munition, comprising: a docking platform that is sealably positionable onto an underwater munition; a first manipulator arm to manipulate the docking platform onto the munition; a high-pressure waterjet cutting tool configured to be reversibly sealably placed into the docking platform; a washout tool configured to be reversibly sealably placed in the docking platform, wherein the washout tool generates waste from the munition; a bladder that stores munition waste; a second manipulator arm to manipulate the cutting tool and the washout tool into the docking platform; an abrasive feed subsystem that delivers an abrasive to the cutting tool; and a system control module with electrical and hydraulic control hardware, to control the docking platform, cutting tool, abrasive feed subsystem, the washout tool. Other variations utilize a multifunctional device that contains the cutting tool, the washout tool, and other tools.