A structural repair patch system for repairing a damaged product surface, the system comprising: an application member, a patch member and at least one containing member. The patch member further comprises a reinforced element with a reinforced element top surface and a reinforced element bottom surface, an adhesive element incorporated into the reinforced element and or positioned on the reinforced element bottom surface and a smooth surface element, located on the reinforced element top surface, which is conformable to the surface and texture of an undamaged surface of the product. The at least one containing member forms a sealed enclosure containing the patch member.

A structural repair patch system for repairing a damaged product surface, the system comprising: an application member, a patch member and at least one containing member. The patch member further comprises a reinforced element with a reinforced element top surface and a reinforced element bottom surface, an adhesive element incorporated into the reinforced element and or positioned on the reinforced element bottom surface and a smooth surface element, located on the reinforced element top surface, which is conformable to the surface and texture of an undamaged surface of the product. The at least one containing member forms a sealed enclosure containing the patch member.

An aft-mounted dive platform system includes at least one hull portion rigidly affixed to a hull of a boat. A dive platform is coupled to the at least one hull portion and is positioned, at least partially, behind at least one propeller drive system affixed to the stern of the boat. The at least one hull portion includes a first hull portion and a second hull portion. The first hull portion includes: a first inner portion surface positioned proximate a first side of the at least one propeller drive system and a first outer portion surface positioned proximate a first outer surface of the hull of the boat; wherein the first outer portion surface of the first hull portion is recessed with respect to the first outer surface of the hull of the boat.

An apparatus includes a buoyant frame that surrounds a space, and a net mounted to the buoyant frame such that the net extends across the space. The frame includes a plurality of linear segments, each including a respective structural member, foam, and a shell that covers the structural member and the foam. The apparatus may be placed on the surface of water adjacent to a boat to catch tools, replacement parts, etc. that may be dropped during boat repair or maintenance, thereby saving expensive tools and parts from being lost or damaged.

An apparatus includes a buoyant frame that surrounds a space, and a net mounted to the buoyant frame such that the net extends across the space. The frame includes a plurality of linear segments, each including a respective structural member, foam, and a shell that covers the structural member and the foam. The apparatus may be placed on the surface of water adjacent to a boat to catch tools, replacement parts, etc. that may be dropped during boat repair or maintenance, thereby saving expensive tools and parts from being lost or damaged.

The present disclosure relates to a subsea device for installing a seal and a corresponding method. More precisely, the seal referred to in an embodiment of the present disclosure includes an elastomeric seal temporarily installed, until a definitive repair is possible to solve the leak of fluids, such as oil, identified, for example, in large-sized vessel structures.

The present disclosure relates to a subsea device for installing a seal and a corresponding method. More precisely, the seal referred to in an embodiment of the present disclosure includes an elastomeric seal temporarily installed, until a definitive repair is possible to solve the leak of fluids, such as oil, identified, for example, in large-sized vessel structures.

A floating VAWT comprising a wind turbine body having a lower body portion and an upper body portion; at least one blade attached to the upper body portion for converting wind energy to rotation of the wind turbine body; and an energy converter attached to the wind turbine body for converting the rotation of the wind turbine body to electrical energy. The energy converter comprises a first energy converter part, and a second energy converter part to be kept relatively stationary in relation to the first energy converter part. The energy converter is attached to the wind turbine body by means of a first releasable mechanical coupling between the first energy converter part and the lower body portion of the wind turbine body, and a second releasable mechanical coupling between the first energy converter part and the upper body portion of the wind turbine body.

Disclosed is a method (200) of assembling a vessel overboard discharge assembly (600), the method (200) comprising: inserting (210) a tubular insert (500) into an overboard discharge pipe (300) so that a space (400) is defined between the tubular insert (500) and the overboard discharge pipe (300): blocking (221) an outboard opening (401) into the space (400) at an outboard end (301) of the space (400): and providing (280) in the space (400) an adhesive (450) and/or chocking material (450) for adhering and/or chocking the tubular insert (500) in the overboard discharge pipe (300).

Disclosed is a method (200) of assembling a vessel overboard discharge assembly (600), the method (200) comprising: inserting (210) a tubular insert (500) into an overboard discharge pipe (300) so that a space (400) is defined between the tubular insert (500) and the overboard discharge pipe (300): blocking (221) an outboard opening (401) into the space (400) at an outboard end (301) of the space (400): and providing (280) in the space (400) an adhesive (450) and/or chocking material (450) for adhering and/or chocking the tubular insert (500) in the overboard discharge pipe (300).