The recovery device comprises a floating cradle configured to receive and support the vehicle, the cradle having an entrance for the vehicle situated at a rear end of the cradle and delimited between two lateral portions, the cradle being configured or capable of being configured with a rear lateral extension extending toward the rear from one of the two lateral portions, the other lateral portion having no rear lateral extension.

The recovery device comprises a floating cradle configured to receive and support the vehicle, the cradle having an entrance for the vehicle situated at a rear end of the cradle and delimited between two lateral portions, the cradle being configured or capable of being configured with a rear lateral extension extending toward the rear from one of the two lateral portions, the other lateral portion having no rear lateral extension.

A device for recovering a vessel at sea from a surface station, the recovery device includes a cradle with negative buoyancy, intended to support the vessel, a lifting device comprising an upper frame and a set of hangers connecting the cradle to the upper frame, lengths of the hangers being variable so as to make it possible to raise and lower the cradle, a guide float capable of having a predetermined positive buoyancy, the guide float being interposed between the cradle and the upper frame so that the cradle is intended to support the guide float during the raising of the cradle, the guide float being configured and connected to the cradle in order to guide the vessel moving on the surface of the water with a speed of movement comprising a positive component along an axis x associated with the upper frame, toward a front part of the guide float when the guide float has the predetermined positive buoyancy, the guide float being in connection with three degrees of freedom in rotation with the cradle.

A device for recovering a vessel at sea from a surface station, the recovery device includes a cradle with negative buoyancy, intended to support the vessel, a lifting device comprising an upper frame and a set of hangers connecting the cradle to the upper frame, lengths of the hangers being variable so as to make it possible to raise and lower the cradle, a guide float capable of having a predetermined positive buoyancy, the guide float being interposed between the cradle and the upper frame so that the cradle is intended to support the guide float during the raising of the cradle, the guide float being configured and connected to the cradle in order to guide the vessel moving on the surface of the water with a speed of movement comprising a positive component along an axis x associated with the upper frame, toward a front part of the guide float when the guide float has the predetermined positive buoyancy, the guide float being in connection with three degrees of freedom in rotation with the cradle.

A system for deploying and recovering an autonomous underwater device (AUD) using a surface carrier ship, includes, in addition to the carrier ship, a subaquatic vehicle (SV) guided by a connection wire connected to the carrier ship, the SV able to be positioned in a storage configuration wherein the SV is fixedly but removably joined to the carrier ship in a storage zone, or in a configuration for use, in which the SV, separated from the carrier ship, is in the water and at a distance from the carrier ship while remaining connected by the connection wire, the SV including propulsion, guiding and stabilizing systems and a station for receiving the AUD allowing it to be removably attached to the SV, the receiving station and the AUD including a complementary automated docking unit allowing the AUD to automatically dock with the receiving station during recovery and attach itself thereto.

A method is provided that includes acquiring positional information regarding a pallet being translated on a conveyance system with an encoding sensor disposed proximate to the conveyance system. The method also includes receiving, with at least one processor, the positional information from the encoding sensor. Further, the method includes determining timing information using the positional information. The timing information corresponds to when a substrate disposed on the pallet will be in a print zone of a print head. The method further includes controlling the print head to print on the substrate when the substrate is in the print zone and passing beneath the print head.

A method is provided that includes acquiring positional information regarding a pallet being translated on a conveyance system with an encoding sensor disposed proximate to the conveyance system. The method also includes receiving, with at least one processor, the positional information from the encoding sensor. Further, the method includes determining timing information using the positional information. The timing information corresponds to when a substrate disposed on the pallet will be in a print zone of a print head. The method further includes controlling the print head to print on the substrate when the substrate is in the print zone and passing beneath the print head.

Disclosed is an active compensation system, intended to compensate at least partially for the effect of an undulating movement on a load, advantageously in a vertical direction, preferably for the active compensation of the swell. The active compensation system includes: — an electrical supply electrically connected to electrical storage unit; — electrical energy dissipating unit; and - a controller for discharging the electrical storage unit during a first phase of the undulating movement, to participate in the electrical supply of the electrical motor in addition to the power supply, and to recharge the electrical storage via the electrical supply during a second phase of the undulating movement.

Disclosed is an active compensation system, intended to compensate at least partially for the effect of an undulating movement on a load, advantageously in a vertical direction, preferably for the active compensation of the swell. The active compensation system includes: — an electrical supply electrically connected to electrical storage unit; — electrical energy dissipating unit; and - a controller for discharging the electrical storage unit during a first phase of the undulating movement, to participate in the electrical supply of the electrical motor in addition to the power supply, and to recharge the electrical storage via the electrical supply during a second phase of the undulating movement.

There is described a hoisting system and method of lifting that make use of a particular fibre rope. The fibre rope includes a plurality of magnets that are embedded within the fibre rope and spaced apart along the rope with a known axial distance between the magnets. The system may include a fibre rope hoisting speed sensor, and a magnetic field sensor that can sense the presence of the magnetic field of the embedded magnets. Using the sensors, the hoisting speed of the rope may be determined by: measuring the time between the passing of consecutive magnets by using the magnetic field sensor; calculating the distance between consecutive magnets using the hoisting speed sensor and the measured time between the passing of the consecutive magnets; and comparing the calculated distance between the magnets with an original, predefined distance between the magnets.