Systems and methods are provided for using an additively manufactured vehicle, such as an UUV, with additively manufactured modules. The vehicle may be configurable such that additively manufactured modules or components may be detachably connected to the vehicle by hand, without the use of tools. Such modules may include connectors adapted to securely attach additional modules that may be detached by hand, without the use of tools. The additively manufactured modules may include ball bearings for rotating modules such as propellers and thrusters, and clips or tabs for detachable connection. The modules may include optical components for communications between a swarm of unmanned vehicles. Such optical modules for underwater vehicles may utilize nephelometry and/or turbidimetry to improve communications parameters based on scattered light measurements.

A watercraft may have a shaped charge and a gas chamber. The gas chamber may be adjacent to the shaped charge in a direction of action of the shaped charge. The gas chamber can be varied in length in the direction of action of the shaped charge. Further, the shaped charge may be movable parallel to the direction of action of the shaped charge. A threaded rod can be used to move the shaped charge. In some cases a length of the gas chamber is variable between 0.1-times and 10.0 times a diameter of the shaped charge. The watercraft may be configured in some instances as an unmanned underwater vehicle.

A watercraft may include a first shaped charge as well as a second shaped charge. The second shaped charge may be positioned behind the first shaped charge in an effective direction of the first shaped charge. The effective direction of the first shaped charge and an effective direction of the second shaped charge may run to a common target point. At least one of the first shaped charge or the second shaped charge is movable. Further, a distance sensor may be configured to detect a distance between the watercraft and an object positioned in front of the watercraft. An electronic evaluation and control system can process the distance that is detected by the distance sensor and move at least one of the first shaped charge or the second shaped charge based on the distance that is detected.

A watercraft may include a first shaped charge as well as a second shaped charge. The second shaped charge may be positioned behind the first shaped charge in an effective direction of the first shaped charge. The effective direction of the first shaped charge and an effective direction of the second shaped charge may run to a common target point. At least one of the first shaped charge or the second shaped charge is movable. Further, a distance sensor may be configured to detect a distance between the watercraft and an object positioned in front of the watercraft. An electronic evaluation and control system can process the distance that is detected by the distance sensor and move at least one of the first shaped charge or the second shaped charge based on the distance that is detected.

The invention relates to an activation device for an electric battery unit, in particular, for a battery part of a torpedo. The invention also relates to a battery unit with activation devices of this type. An activation device incorporates an operating supply connection, to which an operating supply reservoir can be connected. A movably arranged cutting element can be pneumatically actuated via a pneumatic connection of the activation device by means of an actuation element, wherein a sealing element arranged in the path of travel of the cutting element controls the operating supply connection. In order to guarantee a safe storage, ready for operation, and a safe activation of a battery unit, it is provided in accordance with the invention that the activation device incorporates a pneumatic outlet, which can be fluidically connected to the pneumatic connection, depending on the position of the actuation element.

The invention relates to an activation device for an electric battery unit, in particular, for a battery part of a torpedo. The invention also relates to a battery unit with activation devices of this type. An activation device incorporates an operating supply connection, to which an operating supply reservoir can be connected. A movably arranged cutting element can be pneumatically actuated via a pneumatic connection of the activation device by means of an actuation element, wherein a sealing element arranged in the path of travel of the cutting element controls the operating supply connection. In order to guarantee a safe storage, ready for operation, and a safe activation of a battery unit, it is provided in accordance with the invention that the activation device incorporates a pneumatic outlet, which can be fluidically connected to the pneumatic connection, depending on the position of the actuation element.

A projectile launch detector, including a body, a mast and a blade rigidly connected to the mast; the mast being capable of sliding between a retracted configuration and a deployed configuration, and capable of pivoting between a first and a second angular position. The detector may further includes a first elastic return element to return the mast to the deployed configuration relative to the body; and a first associated sensor; and a second elastic return element to return the mast to the first angular position relative to the body; and a second associated sensor.

A watercraft may include a first shaped charge as well as a second shaped charge. The second shaped charge may be positioned behind the first shaped charge in an effective direction of the first shaped charge. The effective direction of the first shaped charge and an effective direction of the second shaped charge may run to a common target point. At least one of the first shaped charge or the second shaped charge is movable. Further, a distance sensor may be configured to detect a distance between the watercraft and an object positioned in front of the watercraft. An electronic evaluation and control system can process the distance that is detected by the distance sensor and move at least one of the first shaped charge or the second shaped charge based on the distance that is detected.

A watercraft may include a first shaped charge as well as a second shaped charge. The second shaped charge may be positioned behind the first shaped charge in an effective direction of the first shaped charge. The effective direction of the first shaped charge and an effective direction of the second shaped charge may run to a common target point. At least one of the first shaped charge or the second shaped charge is movable. Further, a distance sensor may be configured to detect a distance between the watercraft and an object positioned in front of the watercraft. An electronic evaluation and control system can process the distance that is detected by the distance sensor and move at least one of the first shaped charge or the second shaped charge based on the distance that is detected.

A projectile launch detector including a body, a mast and a blade rigidly connected to the mast; the mast being capable of sliding between a retracted configuration and a deployed configuration, and capable of pivoting between a first and a second angular position. The detector may further include a first elastic return element to return the mast to the deployed configuration relative to the body; and a first associated sensor; and a second elastic return element to return the mast to the first angular position relative to the body; and a second associated sensor.