An arrangement for subsea cooling of a semiconductor module. The arrangement includes a tank. The tank is filled with a dielectric fluid. The arrangement includes at least one semiconductor module. The at least one semiconductor module is placed in the tank. Each at least one semiconductor module includes semiconductor submodules and is attached to a heat sink. The semiconductor submodules generate heat, thereby causing the dielectric fluid to circulate by natural convection. The heat sink includes a first part having a first thermal resistance from the semiconductor module to the dielectric fluid. The heat sink includes a second part having a second thermal resistance from the semiconductor module to the dielectric fluid. The second thermal resistance is higher than the first thermal resistance. The heat sink is oriented such that, when the arrangement is installed, the first part is configured to lie vertically higher than the second part.

A method for estimating the remaining useful life of a pressure compensator of a subsea arrangement, the method including determining displacement data related to displacements of the pressure compensator during a time period; and estimating the remaining useful life of the pressure compensator in relation to a failure mode of the pressure compensator based on the determined displacement data of the pressure compensator. A system including a subsea arrangement and a control system, a computer program product, and a computer program, are also provided.

A heat exchanging arrangement for a subsea electronic system, the heat exchanging arrangement including a wall section; a corrugation formed in the wall section, the corrugation having two generally opposing internal corrugation surfaces; and at least one heat exchanging element forced against at least one of the internal corrugation surfaces. A subsea electronic system including a heat exchanging arrangement is also provided.

A power converter includes an outer housing formed of dielectric material and including a low voltage compartment and a high voltage compartment is disclosed. The power converter also includes a low voltage DC-to-AC converter disposed in the low voltage compartment, a first coil in the low voltage compartment, a first conductive shield element lining an outer wall of the low voltage compartment, the first conductive shield element being electrically coupled to an electrical input of the DC-to-AC converter and a second conductive shield element lining an outer wall of the high voltage compartment.

Systems (100) and methods (1500) for using a pressure vessel. The methods comprise: obtaining the pressure vessel comprising a shell and an insert having an interference fit with the shell whereby the insert is locked in place within the shell via interfacial pressure; inserting at least one electronic component in a first hollow cavity formed in the insert; mechanically supporting the at least one electronic component using a structural feature of the insert; and transferring heat from the electronic component to an external environment via a heat transfer path that comprises a full surface area of the insert's outer surface abutting the shell's inner surface.

A subsea arrangement including a main enclosure having a main enclosure volume; at least one main pressure compensator having a variable compensation volume in fluid communication with the main enclosure volume and configured to compensate volume variations of an internal fluid in the main enclosure volume; and at least one pressure sensor arranged to measure a pressure of the internal fluid. A method for detecting a malfunction of a subsea arrangement including a main enclosure having a main enclosure volume and at least one main pressure compensator is also provided.

A waterproof housing including a first case, a second case, a welded member, and a waterproof unit is provided. The first case includes a side wall and a groove. The side wall is disposed on an outer periphery of the first case. The groove is disposed on the side wall. The second case is disposed in correspondence with the first case, and the second case includes a first inner wall disposed at an inner side of the second case. The first inner wall and the side wall are disposed in correspondence with each other. The welded member is disposed in correspondence with the first case and the second case, and a joint direction of the welded member is different from an opening direction of the groove. The waterproof unit is disposed in the groove and is partially protruded from the side wall. The first case and the second case are jointed to each other via the welded member. The waterproof unit and the first inner wall are abutted against each other for sealing the first case and the second case.

A waterproof housing including a first case, a second case, a welded member, and a waterproof unit is provided. The first case includes a side wall and a groove. The side wall is disposed on an outer periphery of the first case. The groove is disposed on the side wall. The second case is disposed in correspondence with the first case, and the second case includes a first inner wall disposed at an inner side of the second case. The first inner wall and the side wall are disposed in correspondence with each other. The welded member is disposed in correspondence with the first case and the second case, and a joint direction of the welded member is different from an opening direction of the groove. The waterproof unit is disposed in the groove and is partially protruded from the side wall. The first case and the second case are jointed to each other via the welded member. The waterproof unit and the first inner wall are abutted against each other for sealing the first case and the second case.

An underwater data center system includes a data center is positioned in a water environment and powered by one or more sustainable energy sources. One or more processors are coupled to the data center or included in the data center. A controller is coupled to the one or more data center nodes. A housing member houses the one or more processors under water. One or more cables are coupled to the one or more data center nodes or the sustainable energy source. One or more cable monitoring devices detect a state of the one or more cables.

In at least one embodiment, the liquid circulation system comprises a rotor located within a tank, a stator having a plurality of coils outside the tank, and an exterior tank wall that is non-magnetic and that is located next to the rotor and between the rotor and the stator,
wherein an axis (R) of rotation of the rotor is in parallel with the exterior tank wall, the coils of the stator are arranged along the axis (R) of rotation of the rotor so that the rotor is configured to be rotated by the stator in a touchless manner through the exterior tank wall by means of a varying electromagnetic field driven by the stator to circulate a liquid within the tank.