A wind paddle sail assembly includes a sail having stiffened upper and lower ends and a paddle or pole having an upper fixed end and a lower portion with a lower free end. A fastener fastens the upper fixed end of the paddle or pole to the upper end of the sail. A downhaul strap fastens the lower end of the sail to the lower portion of the paddle or pole for adjusting tension in the sail. A method for operating a wind paddle sail assembly is also provided.

A wind paddle sail assembly includes a sail having stiffened upper and lower ends and a paddle or pole having an upper fixed end and a lower portion with a lower free end. A fastener fastens the upper fixed end of the paddle or pole to the upper end of the sail. A downhaul strap fastens the lower end of the sail to the lower portion of the paddle or pole for adjusting tension in the sail. A method for operating a wind paddle sail assembly is also provided.

A wind generator for sailboats including a mast (A) provided with crosstrees (C), including: at least one wind generator (1) provided with a distribution of blades (2) arranged to rotate integrally with a shaft (6) of axis (a) in response to receiving a wind flow in an active direction (v) incident to the blades distribution; an electric generator (3) operatively connected to the generator (1) for converting the rotation of the blades (2) into electricity, comprising structure (22, 41) for fixing the generator (1) to a crosstree (C), and with the blades (2) being movable from an open operating position (P1) of maximum incidence of wind flow (F) to a closed non-operating position (P2) of minimum obstruction.

A wind generator for sailboats including a mast (A) provided with crosstrees (C), including: at least one wind generator (1) provided with a distribution of blades (2) arranged to rotate integrally with a shaft (6) of axis (a) in response to receiving a wind flow in an active direction (v) incident to the blades distribution; an electric generator (3) operatively connected to the generator (1) for converting the rotation of the blades (2) into electricity, comprising structure (22, 41) for fixing the generator (1) to a crosstree (C), and with the blades (2) being movable from an open operating position (P1) of maximum incidence of wind flow (F) to a closed non-operating position (P2) of minimum obstruction.

An integrated Kiteboarding canopy self-launching and landing safety system is presented. The system includes a base. The system also includes an attachment mechanism configured to attach to the base, wherein the attachment mechanism is structured to capture a kiteboarding canopy. The system additionally includes a release mechanism positionable on the base, wherein the release mechanism is arranged to be able to release a kiteboarding canopy upon actuation. Further, the system includes a securing mechanism configured to connect with the base, wherein the securing mechanism is configured to secure a kiteboarding canopy upon landing. And, the system also includes a manual and automatic device to control both landing and launching evolutions.

An integrated Kiteboarding canopy self-launching and landing safety system is presented. The system includes a base. The system also includes an attachment mechanism configured to attach to the base, wherein the attachment mechanism is structured to capture a kiteboarding canopy. The system additionally includes a release mechanism positionable on the base, wherein the release mechanism is arranged to be able to release a kiteboarding canopy upon actuation. Further, the system includes a securing mechanism configured to connect with the base, wherein the securing mechanism is configured to secure a kiteboarding canopy upon landing. And, the system also includes a manual and automatic device to control both landing and launching evolutions.

A rigging system (1) for a sailboat comprising: a mast (3) that extends substantially vertical from a hull; a boom (5) that extends substantially horizontal from the mast (3); a vang tube (7) extending between the mast and the boom to resist relative force and/or moment of the boom (5) towards the mast (3), wherein the vang tube (7) is substantially arcuate and a convex side of the actuate vang tube (7) faces an intersection (9) of the boom (5) and the mast (3) and wherein the vang tube (7) is located above the boom (5). A connection (301) for transferring a first force from a spar (307) to a mast (3) of a sailboat, the connection comprising: a connection base (303) having a key portion (305) to be received in a keyway (306), wherein the keyway (306) is part of a sail track (107) of the mast (3); a mount (309) to receive the spar (307), wherein the first force (35) from the spar (307) is transmitted through the mount (309) to the connection base (303); and a restraint (311) to resist a first component force (37) acting on the connection base (303), wherein the first component force (37) is a component of the first force (35) transmitted from the spar (307) that is in a direction parallel to the keyway (306).

A propulsion system for a seagoing vessel includes a rotatable frame and either (a) at least two masts coupled to the frame and each having a sail and a boom, or (b) at least two blades coupled to the frame. The rotatable frame and either the rotatable boom or at least two blades may be locked in position in a locked mode and unlocked and freely rotatable in an unlocked mode. A control system that is in communication in communication with a frame lock and either a boom lock or a blade lock and may be configured to determine when the vertical axis wind turbine should be in either the locked mode or the unlocked mode based on the direction of the wind and a direction that the seagoing vessel is traveling.

A vessel is provided with a mast, sail, and halyard for hoisting the sail. The sail includes dollies configured to be movable along the mast. The mast includes a guide member, the guide dollies configured to cooperate with said guide member, wherein the sail includes rigid panels, articulated two by two; the mast is equipped with a transit part positioned at the end of the guide member, which has a flared lower portion and is open at its opposite ends, wherein during hoisting of the sail, each dolly is received in the transit part and is guided along to leave it through its upper opening and cooperate with the guide member, while during its lowering, each dolly is disengaged from the guide member, is received in the transit part, moves along it, and escapes from it by following the movement of the portion of the sail with which it is integral.

A vessel is provided with a mast, sail, and halyard for hoisting the sail. The sail includes dollies configured to be movable along the mast. The mast includes a guide member, the guide dollies configured to cooperate with said guide member, wherein the sail includes rigid panels, articulated two by two; the mast is equipped with a transit part positioned at the end of the guide member, which has a flared lower portion and is open at its opposite ends, wherein during hoisting of the sail, each dolly is received in the transit part and is guided along to leave it through its upper opening and cooperate with the guide member, while during its lowering, each dolly is disengaged from the guide member, is received in the transit part, moves along it, and escapes from it by following the movement of the portion of the sail with which it is integral.