A method to rapidly form a reconfigurable multihull multiplatform floating vessel includes installing a plurality of pin connectors on a plurality of longitudinal hulls, installing a plurality of joints on the plurality of longitudinal hulls, positioning the plurality of longitudinal hulls with the plurality of pin connectors and the plurality of joints proximate each other, mounting a first moveable planar platform having a first end and a second end with the first moveable planar platform mounted a preset distance above a load line of the first longitudinal hull, mounting a second moveable planar platform having a first end and a second end, forming a platform void extending between pairs of moveable planar platforms to provide increased safety for equipment and personnel on the moveable planar platform by preventing impact together of longitudinal hulls, and forming a hull void extending between pairs of longitudinal hulls.

A structure for stabilizing a barrel on a pontoon vessel includes a deck structure. First And second hull frame members are affixed to the deck structure and extend therealong. In spaced relationship to each other. A first and second conduit extends along a respective hull frame member; the first conduit being spaced from the second conduit by a distance to receive a portion of a barrel therebetween and each conduit contacting the barrel above a barrel central line. A strap having a first end anchored near the first conduit, and tracing a path from the anchor beneath, and in contact with, the barrel disposed between the first conduit in the second conduit, along the second conduit, and returning to the first conduit by tracing a path from the second conduit to the first conduit beneath and in contact with the barrel.

A structure for stabilizing a barrel on a pontoon vessel includes a deck structure. First And second hull frame members are affixed to the deck structure and extend therealong. In spaced relationship to each other. A first and second conduit extends along a respective hull frame member; the first conduit being spaced from the second conduit by a distance to receive a portion of a barrel therebetween and each conduit contacting the barrel above a barrel central line. A strap having a first end anchored near the first conduit, and tracing a path from the anchor beneath, and in contact with, the barrel disposed between the first conduit in the second conduit, along the second conduit, and returning to the first conduit by tracing a path from the second conduit to the first conduit beneath and in contact with the barrel.

A pontoon boat includes first and second pontoons on the port and starboard sides of the boat and a main deck attached to the top of the pontoons. A front wave deflector extends forwards and upwards from the front of the main deck at an angle. The front wave deflector is held above the water and does not contact the water while the pontoon boat is floating in or moving through calm water. The front wave deflector contacts the tops of waves when the pontoon boat is navigating rough water and pushes the water beneath the pontoon boat deck. This allows the pontoon boat to navigate rough water without loss of momentum and without excessive up and down pitching.

A pontoon boat includes first and second pontoons on the port and starboard sides of the boat and a main deck attached to the top of the pontoons. A front wave deflector extends forwards and upwards from the front of the main deck at an angle. The front wave deflector is held above the water and does not contact the water while the pontoon boat is floating in or moving through calm water. The front wave deflector contacts the tops of waves when the pontoon boat is navigating rough water and pushes the water beneath the pontoon boat deck. This allows the pontoon boat to navigate rough water without loss of momentum and without excessive up and down pitching.

Disclosed are a self-righting unmanned ship suitable for adverse sea conditions and a self-righting working mode thereof, belonging to the field of unmanned ship equipment and techniques. The unmanned ship comprises a main hull, a self-righting deck, an equipment and pipeline mast, a propeller, a radar, an air inlet and exhaust system, and a main engine system. Through the design of a watertight deck, the hull of the unmanned ship has a self-righting function, avoiding the possibility of the unmanned ship itself turning over, without installing additional self-righting equipment. Meanwhile, the internal structure and the self-righting working mode of the unmanned ship make it possible for the hull to automatically turn off the main engine and the air inlet and exhaust system when the heeling angle of the hull exceeds a certain angle, making the whole ship watertight.

Disclosed are a self-righting unmanned ship suitable for adverse sea conditions and a self-righting working mode thereof, belonging to the field of unmanned ship equipment and techniques. The unmanned ship comprises a main hull, a self-righting deck, an equipment and pipeline mast, a propeller, a radar, an air inlet and exhaust system, and a main engine system. Through the design of a watertight deck, the hull of the unmanned ship has a self-righting function, avoiding the possibility of the unmanned ship itself turning over, without installing additional self-righting equipment. Meanwhile, the internal structure and the self-righting working mode of the unmanned ship make it possible for the hull to automatically turn off the main engine and the air inlet and exhaust system when the heeling angle of the hull exceeds a certain angle, making the whole ship watertight.

The embodiments herein provide a tool for assisting users while docking a boat. According to an embodiment herein, a boarding aid mechanism for a boat for assisting a passenger while docking a boat includes a clamp, a vertical slide arm and a dock arm. The clamp is secured to one side of the boat. The vertical slide arm is mechanically coupled to the clamp using a pin. The vertical slide arm comprises a rubber handgrip for supporting and balancing the passenger. The dock arm is an L shaped structure extending from the vertical slide arm. The dock arm is slid into the vertical slide arm and further the vertical slide arm is secured to the clamp.

The embodiments herein provide a tool for assisting users while docking a boat. According to an embodiment herein, a boarding aid mechanism for a boat for assisting a passenger while docking a boat includes a clamp, a vertical slide arm and a dock arm. The clamp is secured to one side of the boat. The vertical slide arm is mechanically coupled to the clamp using a pin. The vertical slide arm comprises a rubber handgrip for supporting and balancing the passenger. The dock arm is an L shaped structure extending from the vertical slide arm. The dock arm is slid into the vertical slide arm and further the vertical slide arm is secured to the clamp.

A method to rapidly form a reconfigurable multihull multiplatform floating vessel includes installing a plurality of pin connectors on a plurality of longitudinal hulls, installing a plurality of joints on the plurality of longitudinal hulls, positioning the plurality of longitudinal hulls with the plurality of pin connectors and the plurality of joints proximate each other, mounting a first moveable planar platform having a first end and a second end with the first moveable planar platform mounted a preset distance above a load line of the first longitudinal hull, mounting a second moveable planar platform having a first end and a second end, forming a platform void extending between pairs of moveable planar platforms to provide increased safety for equipment and personnel on the moveable planar platform by preventing impact together of longitudinal hulls, and forming a hull void extending between pairs of longitudinal hulls.