A method of supporting a chain stopper on a vessel, a chain stopper assembly for a vessel, and a vessel. The method of supporting a chain stopper on a vessel may comprise the steps of connecting a swivel element to the support structure on the vessel such that the swivel element is pivotable around a first axis perpendicular to a substantially horizontal axis; and coupling a chain stopper element to the swivel element such that the chain stopper element is pivotable relative to the swivel element around the substantially horizontal axis.

The invention relates to a system (2), having: a buoyant buoy (4), and a floating hose (6) which has a plurality of buoyant hose segments (8) which are coupled in series. The buoy (4) has a liquid outlet connection (12) which is connected to the floating hose (6), so that the floating hose (6) is arranged in a geometrical arrangement with respect to the buoy (4). A plurality of node units (18) are fastened in a distributed manner to the floating hose (6) and the buoy (4). Each node unit (18) is designed to establish, by means of an associated radio unit, a respective radio link (22, 24, 26, 28) to each of at least two of the further radio units of the respective node units (18, 42, 44, 46, 48), so that a radio network (30) is created. Each node unit (18) is designed to determine a relative distance (32, 34, 36, 38) from each further node unit (18) on the basis of the respective radio link.

A distributed acoustic anti-unmanned boat intelligence system (DAAUBS) for detecting unmanned boats (UB) approaching protected sites includes a plurality of airborne defense agents (ADAs) and a base station. Each ADA is equipped with air balloons, tethers, buoys, a directional microphone array, a first computing device, and a transceiver. The first computing device causes at least processor to determine information regarding each approaching UB. The base station includes a control center configured with a wideband communications link configured to communicate with the transceiver of each ADA. The DAAUBS control center includes a second computing device performing an intelligence method. The second processor receives and aggregates the data of each approaching UB and performs adaptive noise cancellation to remove environmental background noise. The second processor uses a deep learning classifier to classify at least one of a type and size of the UB.

A distributed acoustic anti-unmanned boat intelligence system (DAAUBS) for detecting unmanned boats (UB) approaching protected sites includes a plurality of airborne defense agents (ADAs) and a base station. Each ADA is equipped with air balloons, tethers, buoys, a directional microphone array, a first computing device, and a transceiver. The first computing device causes at least processor to determine information regarding each approaching UB. The base station includes a control center configured with a wideband communications link configured to communicate with the transceiver of each ADA. The DAAUBS control center includes a second computing device performing an intelligence method. The second processor receives and aggregates the data of each approaching UB and performs adaptive noise cancellation to remove environmental background noise. The second processor uses a deep learning classifier to classify at least one of a type and size of the UB.

A mooring ball system comprising: a mooring ball; a collar attached to the top of the mooring ball; an extendible, retractable, and lockable mast attached to the collar, and extending from the top of the mooring ball; a hook attached near or at the top of the mast; a chain attached to the mooring ball; a mooring line attached to the chain; a loop located at one end of the mooring line; and where the loop is configured to removeably attach to the hook, and where the loop is further configured to be removed from the hook and attached to a watercraft. A mooring apparatus comprising: a collar configured to attach to the top of a mooring ball; an extendible, retractable, and lockable mast configured to attach to the collar, and configured to extend from the top of the mooring ball; and a hook attached near or at the top of the mast.

A mooring ball system comprising: a mooring ball; a collar attached to the top of the mooring ball; an extendible, retractable, and lockable mast attached to the collar, and extending from the top of the mooring ball; a hook attached near or at the top of the mast; a chain attached to the mooring ball; a mooring line attached to the chain; a loop located at one end of the mooring line; and where the loop is configured to removeably attach to the hook, and where the loop is further configured to be removed from the hook and attached to a watercraft. A mooring apparatus comprising: a collar configured to attach to the top of a mooring ball; an extendible, retractable, and lockable mast configured to attach to the collar, and configured to extend from the top of the mooring ball; and a hook attached near or at the top of the mast.

A mooring apparatus (10) for automatic mooring and parking a 10-70 feet long watercraft that is built from two dock-finger units (20) fixed to the dock (2). The dock-finger units (20) are equipped with flexible tentacle elements (80) for positioning the watercraft (4) by keeping continuous contact with the hull (6). and they are also equipped with automatic-operated locking mechanisms (40) for catching and locking the watercraft (4), The mooring apparatus (10) has a control panel (90) with a built-in programmable processor (98) and a communication unit (98) that can be accessed from anywhere by communication means, and connected to the harbour IT system.

A system for temporarily connecting an underwater station arranged on the bed of a body of water and a surface facility has an elongated conducting member with one end connected to the underwater station and one free end selectively and temporarily connectable to the surface facility; a marker buoy; and a cable connected to the free end of the elongated conducting member and to the marker buoy to quickly recover the free end of the elongated conductor element when it is necessary to connect the underwater station via the elongated conducting member to the surface facility.

Systems and processes for recovering a condensate from a conduit. In one embodiment, the system can include a floating buoy that can include a fluid swivel assembly coupled thereto. The system can also include a floating conduit, a first gas transfer conduit, and a second gas transfer conduit that can be configured to transfer a gas discharged from a vessel storage tank to a pipeline end manifold located at a subsea location. The system can also include a first condensation conduit, a pump, and a second condensation conduit that can be configured to transfer at least a portion of any condensate that accumulates within an internal volume of the floating conduit at a low point between the vessel storage tank and the first gas transfer conduit into a flow path defined by a first swivel section of the fluid swivel assembly, a storage tank, or a combination thereof.

A mooring buoy reservation system is disclosed. The system comprises a mooring buoy that has the ability to enable or disable a tie up point on the buoy. The buoy has a microprocessor in communication with a server. And the server is in communication with a boat device. Also a method of a subscriber reserving a buoy through the server, paying for the buoy's use, and mooring to an enabled buoy is disclosed.