A container refrigeration apparatus includes a CA system which controls the composition of the air in the container. The CA system includes a gas supply device which supplies nitrogen-enriched air, an intake duct which guides outside air to a first space on a suction side of an interior fan, and an exhaust duct which guides air in a second space on the blowout side of the interior fan out of a container. The exhaust duct has an inlet at a location where the flow of the air blown from the interior fan is blocked by a fan housing.

The invention relates to an energy supply (11) for supplying an energy consumer with electrical energy. The energy supply (11) comprises a mounting device (20) as well as a battery (29), a charger device (30) and a load connection (33). The energy supply (11) also comprises an energy connection for connecting an energy source, and an energy converter (31) for converting the energy received at the energy connection into a form of electrical energy which is suitable for charging the battery (29). The energy which is stored in the battery (29) can then be made available at the load connection (33) for supplying one or more energy consumers which are connected thereto. The mounting device (20) is provided here with connecting devices (23, 24) which are compatible with those attachment devices with which corresponding transportation containers can usually be connected to a transportation vehicle. It is therefore possible to arrange such an energy supply (11) for transporting a transportation container between the latter and the appropriate transportation vehicle, wherein for example the kinetic energy of the moved transportation vehicle can be utilised for the charging of the battery (29) in that e.g. the rotation of the wheel axle of the vehicle is converted into electrical energy with a hydraulic generator.

A cooler mounting system is provided. The cooler mounting system includes at least one front bracket system and at least on rear bracket system. Each bracket system includes at least one arm portion and a base portion. The mounting system also includes a cooler that includes a front rail portion located on a front face of the cooler and a rear rail portion located on a rear face of the cooler.

An apparatus includes a pipe tee with an inlet proximate a first valve, an outlet proximate a second valve, and an inlet-outlet. The inlet receives slush ice when the first valve is open and the second valve is closed. The outlet transmits fluid when the second valve is open and the first valve is closed. The inlet-outlet receives fluid when the second valve is open and the first valve is closed and transmits slush ice when the first valve is open and the second valve is closed. A second pipe tee has an inlet coupled to the outlet of the pipe tee that receives fluid when the second valve is open and the first valve is closed, a first outlet that transmits water, separated from the fluid, when the second valve is open and the first valve is closed, and a second outlet that transmits air, separated from the fluid, when the second valve is open and the first valve is closed.

An apparatus includes a pipe tee with an inlet proximate a first valve, an outlet proximate a second valve, and an inlet-outlet. The inlet receives slush ice when the first valve is open and the second valve is closed. The outlet transmits fluid when the second valve is open and the first valve is closed. The inlet-outlet receives fluid when the second valve is open and the first valve is closed and transmits slush ice when the first valve is open and the second valve is closed. A second pipe tee has an inlet coupled to the outlet of the pipe tee that receives fluid when the second valve is open and the first valve is closed, a first outlet that transmits water, separated from the fluid, when the second valve is open and the first valve is closed, and a second outlet that transmits air, separated from the fluid, when the second valve is open and the first valve is closed.

Sealed and thermally insulating tank incorporated into a polyhedral bearing structure, the tank having a plurality of tank walls, a thermally insulating barrier and a sealed membrane, a first bearing wall and second bearing wall forming an edge corner, the thermally insulating barrier of a first tank wall having a row of edging blocks, a row of anchor strips anchored to the second bearing wall by a row of anchor rods, a first and second of edging blocks each having a groove formed in thickness of said edging block, a first and a second of said anchor rods being housed respectively in the groove of the first and second edging blocks, one anchor strip in the row of anchor strips is supported overlapping the first edging block and the second edging block, the anchor strip being coupled to the first anchor rod and to the second anchor rod.

Sealed and thermally insulating tank incorporated into a polyhedral bearing structure, the tank having a plurality of tank walls, a thermally insulating barrier and a sealed membrane, a first bearing wall and second bearing wall forming an edge corner, the thermally insulating barrier of a first tank wall having a row of edging blocks, a row of anchor strips anchored to the second bearing wall by a row of anchor rods, a first and second of edging blocks each having a groove formed in thickness of said edging block, a first and a second of said anchor rods being housed respectively in the groove of the first and second edging blocks, one anchor strip in the row of anchor strips is supported overlapping the first edging block and the second edging block, the anchor strip being coupled to the first anchor rod and to the second anchor rod.

The present invention relates to an apparatus and a system for managing and securing cargo tubs in stacks in a cargo hold of a vessel, such as a fishing vessel. The functional components of the apparatus and system comprise means such as rails or transport lanes, wagons and pushing structures as transport means for securely managing stacks of tubs in the cargo hold both during sailing and off-loading.

An apparatus includes a pipe tee with an inlet proximate a first valve, an outlet proximate a second valve, and an inlet-outlet. The inlet receives slush ice when the first valve is open and the second valve is closed. The outlet transmits fluid when the second valve is open and the first valve is closed. The inlet-outlet receives fluid when the second valve is open and the first valve is closed and transmits slush ice when the first valve is open and the second valve is closed. A second pipe tee has an inlet coupled to the outlet of the pipe tee that receives fluid when the second valve is open and the first valve is closed, a first outlet that transmits water, separated from the fluid, when the second valve is open and the first valve is closed, and a second outlet that transmits air, separated from the fluid, when the second valve is open and the first valve is closed.

An apparatus includes a pipe tee with an inlet proximate a first valve, an outlet proximate a second valve, and an inlet-outlet. The inlet receives slush ice when the first valve is open and the second valve is closed. The outlet transmits fluid when the second valve is open and the first valve is closed. The inlet-outlet receives fluid when the second valve is open and the first valve is closed and transmits slush ice when the first valve is open and the second valve is closed. A second pipe tee has an inlet coupled to the outlet of the pipe tee that receives fluid when the second valve is open and the first valve is closed, a first outlet that transmits water, separated from the fluid, when the second valve is open and the first valve is closed, and a second outlet that transmits air, separated from the fluid, when the second valve is open and the first valve is closed.