A system for cooling a missile includes an assembly of Peltier tiles configured to be reversibly attached to the skin of the missile with the cold sides of the Peltier tiles against the skin. The Peltier tiles are electrically powered to cool a portion of the missile skin. A thermally conductive paste or sheets of a heat conductive material may be placed between the Peltier tiles and missile skin. When the missile is launched, the assembly of Peltier tiles detach from the missile.

A system for cooling a missile includes an assembly of Peltier tiles configured to be reversibly attached to the skin of the missile with the cold sides of the Peltier tiles against the skin. The Peltier tiles are electrically powered to cool a portion of the missile skin. A thermally conductive paste or sheets of a heat conductive material may be placed between the Peltier tiles and missile skin. When the missile is launched, the assembly of Peltier tiles detach from the missile.

A launching device and associated methods can be utilized to launch an underwater running body from a platform such as a watercraft. The launching device may include a ramp, which extends along a longitudinal ramp axis, and a propellant deflection unit. The ramp may enclose an underwater running body with a propulsion unit underwater. The launching device may activate the propulsion unit, which then emits a propellant. The propellant deflection unit deflects the emitted propellant into an outlet direction. This outlet direction of the propellant may be directed perpendicularly or obliquely away from the platform.

A low-cost rocket includes an atmospheric flight part and an exo-atmospheric flight part, and uses the atmospheric air part to ascend into the atmosphere through the use of propellers for the atmospheric portion of the flight. The atmospheric flight part separates from the exo-atmospheric flight part in the vicinity of the exo-atmosphere and the exo-atmospheric rocket is launched thereupon. The atmospheric flight part descends through the atmosphere using autorotation of the propellers and, if necessary, a soft landing can be affected by controlling the pitch of the propellers just prior to landing.

A low-cost rocket includes an atmospheric flight part and an exo-atmospheric flight part, and uses the atmospheric air part to ascend into the atmosphere through the use of propellers for the atmospheric portion of the flight. The atmospheric flight part separates from the exo-atmospheric flight part in the vicinity of the exo-atmosphere and the exo-atmospheric rocket is launched thereupon. The atmospheric flight part descends through the atmosphere using autorotation of the propellers and, if necessary, a soft landing can be affected by controlling the pitch of the propellers just prior to landing.

A remote weapon system structured to be interfaced with aerial, ground and sea vehicles or platforms for operation in mission critical conditions, allows for mounting and control of single or multi-shot anti-armor rocket launcher systems and provides optical sighting, laser range finding and fire control to adjust vertical elevation, sight of target and trigger of the ignition system. A tactical gimbal controlled by a high torque motor with dual shafts allows for high positional accuracy and target hold that is stable. A frame shrouds and secures rocket launcher tubes causing them to move in unison with the tactical gimbal as a single or multi-shot system. Ignition of the rocket(s) is achieved by a remote-controlled ignitor.

A method for countering an oncoming threat is disclosed. A location in front of the threat is selected, and a generally spherical volume is defined by a plurality of lines deployed from a centrally located communications unit. Sensors associated with the lines are connected to the communications unit and sense presence of the oncoming threat, whereupon countermeasures are activated responsive to the sensed oncoming threat.

A launch tube of a flying object has a tube, a plurality of rails and a plurality of guides. The tube is configured to store the flying object. The rails are fixed on an inner wall of the tube and configured to contact the flying object. The guides are on the inner wall of the tube. One of the guides is configured to contact the flying object, and evacuate from a region of movement of the flying object, when the flying object moves to leave the one of the guides.

A rail launch mechanism and method for launching a payload is configured to release payload lugs of a payload from a platform. A rack for launching a payload includes multiple rails that separately engage lugs in the respective payload of the rails, and a force actuator for launching the payload by accelerating the payload along the rails, causing the lugs to separate from the respective rails. A launching system for launching the payload from the platform may include a rail, at least one payload release shoe that carries a payload lug along the rail, and a force actuator for accelerating the payload release shoe such that inertia of the payload causes the payload lug to be released from the payload release shoe.

A system and method for acceleration of a flying object, preferably with large take-off mass is described. The system can accelerate an object with a mass of several hundred thousand tons. The system includes the use for object acceleration of free (for the period of direct acceleration) energy of exhaust gases of the system elements' jet engines, pushing-out force of water, force of Earth's gravity, initial movement energy of the compressed spring and vacuum, lifting force of light gases, as well as energy consuming, for the period of acceleration, action of the system elements' jet engines, gunpowder gases and drives. The system and the method include acceleration of an object simultaneously in several systems accelerating one inside the other with the summation and increase of acceleration speed. The main elements of the system: launch barrel, carrier and booster pistons with jet engines, and pushing the pistons support.