The present invention is directed broadly to a marine vessel (10) comprising a deck (12) mounted to a hull (14) together with a sail (16) coupled to the marine vessel (10) via a mast base assembly (18). The mast base assembly (18) comprises a mast tilt assembly (22). The mast base assembly (18) also comprises a mast base mounting (20) to which the mast tilt assembly (22) is pivotally mounted for movement about a tilt axis (24) between stowed and operative positions. The mast base assembly (18) further comprises a sail slew assembly (26) mounted to the sail (16) associated with the marine vessel (10). The sail slew assembly (26) is operatively coupled to the mast tilt assembly (22) for slewing of the sail (16). The sail (16) is rotated or slewed about a slew axis (28) of the mast tilt assembly (22) to reorient the sail (16) relative to the marine vessel (10).

The present disclosure is directed generally toward sailing vessels. One example is a catamaran with one or more pivoting masts per hull member, which may pivot from a generally perpendicular upright position, to a generally flat stowed position toward the bow of the hulls. The masts are capable of sustaining a plurality of sails, which may travel 180 degrees with respect to the hulls.

This amphibious vehicle is provided with a body (11), a traveling device (12) that causes the body (11) to travel on land, a sailing device (13) that causes the body (11) to sail on water, a front flap (31) of which the distal end is inclined upward and the proximal end is rotatably supported by a horizontal shaft (34) on the front end of the body (11), a hydraulic damper (32) serving as a damping member that damps displacement of the front flap (31) relative to the body (11), and a compression coil spring (33) serving as a restoring member that restores the position of the front flap (31) relative to the body (11).

A transfer system for a composite material including: a nonwoven as carrier material and a textile layer of reinforcing fibers, wherein the reinforcing fibers consist of mono- or multifilaments or tapes and the carrier material is adhesively bonded to the layer of reinforcing fibers.

The invention relates to a wing type rigid sail fragmented into independent segments, where general principle involves diving the rigid sail into different segments that can position themselves independently from neighboring segments, depending on the wind received, with the profile of the sail controlled following two independent but complementary methods, where the segments at the front of the sail are linked together by their front flap, through a process that allows adjusting their relative freedom, playing on the angle that each segment can take compared to neighboring segments, and on the back of the sail sheet, the rope allowing sail adjustment links each segment by its back flap, top to bottom, allowing for adjustment of the opening up of the sail while keeping the desired flexibility of the sail.

The articulating bowsprit permits deployment of sails from a point forward of the bow on sailing vessels. The unique characteristics include: simple installation and removal for stowage, high degree of flexibility for optimal point of attachment including deck or side mounting, ability for fixed length or telescoping configurations, horizontal support of bowsprit with deck mounting brackets, and pinned connections at each end which eliminates torque.

The articulating bowsprit permits deployment of sails from a point forward of the bow on sailing vessels. The unique characteristics include: simple installation and removal for stowage, high degree of flexibility for optimal point of attachment including deck or side mounting, ability for fixed length or telescoping configurations, horizontal support of bowsprit with deck mounting brackets, and pinned connections at each end which eliminates torque.

An autonomous sailing vessel may include a hull, a mast, a sail, and a rudder. The mast may be mechanically coupled to the hull. The sail may be mechanically coupled to the mast. The rudder may be mechanically coupled to the hull. A heading of the autonomous sailing vessel may be regulated by actively controlling the rudder without actively controlling the sail. Alternatively or additionally, the autonomous sailing vessel may include an anticapsize stabilizer tank, a lidar system, and/or marine mammal monitoring and identification.

A system for autonomous ocean data collection includes at least one sensor capable of collecting sensor data, at least one transmission device, and at least one computing device comprising one or more hardware processors and memory coupled to the one or more hardware processors, the memory storing one or more instructions which, when executed by the one or more hardware processors, cause the at least one computing device to generate data for transmission based on the sensor data collected by the at least one sensor, and cause the at least one transmission device to transmit the data.

A sail includes at least three sides, namely two longitudinal sides respectively called luff and leach, as well as a lower transverse side called foot consisting of an assembly of panels having transverse edges parallel to the foot and longitudinal edges parallel to the luff and the leach, each panel being hinged to the adjoining panel around an axis parallel to the foot. Each of the panels includes reinforcing elements distributed into the two following groups: (a) a first group in which they extend parallel and in proximity to said transverse edges, and (b) a second group in which they extend parallel and in proximity to the longitudinal edges of the panel. They are connected two by two by connection parts in the continuation of the reinforcing elements of the second group, so that the forces assumed by the reinforcing elements are transmitted longitudinally from one panel to another.