A system for supplying dry air to a fuel tank to remove moisture and inhibit contamination includes a dry air supply assembly having an air compressor and an air dryer configured to remove moisture from air supplied by the air compressor to the air dryer, and includes a fluid pump mounted within the fuel tank above a fuel level, with the fluid pump receiving dried air from the air dryer. A suction line extends from the fluid pump and includes an open end disposed at a bottom of the fuel tank. The fluid pump is adapted to receive dried air from the air dryer as a motive force to draw liquid from the bottom of the tank into the opening and up the suction line to the fluid pump, and discharge liquid from the fluid pump above the fuel level within the fuel tank.

A system for supplying dry air to a fuel tank to remove moisture and inhibit contamination includes a dry air supply assembly having an air compressor and an air dryer configured to remove moisture from air supplied by the air compressor to the air dryer, and includes a fluid pump mounted within the fuel tank above a fuel level, with the fluid pump receiving dried air from the air dryer. A suction line extends from the fluid pump and includes an open end disposed at a bottom of the fuel tank. The fluid pump is adapted to receive dried air from the air dryer as a motive force to draw liquid from the bottom of the tank into the opening and up the suction line to the fluid pump, and discharge liquid from the fluid pump above the fuel level within the fuel tank.

Devices are provided for ventilating and/or removing volatile chemicals from liquid (e.g. water) stored in a liquid-containing storage tank (e.g. water-storage tank). The devices include a first fluid flow path that is physically isolated from a second fluid flow path and a convection device for moving a first fluid along the first fluid flow path toward at a desired destination and for exhausting the first fluid at the desired destination at a desired velocity. Methods are also provided for ventilating and/or removing volatile chemicals from liquid (e.g. water) stored in liquid-containing storage tanks (e.g. water-storage tanks). The methods involve blowing a first fluid through a ventilation device into a liquid-containing storage device at a velocity sufficient to achieve a desired mass transfer rate of volatile chemicals from the liquid in the liquid-containing storage device to air in the headspace and flowing the contaminated air back through the ventilation device.

Devices are provided for ventilating and/or removing volatile chemicals from liquid (e.g. water) stored in a liquid-containing storage tank (e.g. water-storage tank). The devices include a first fluid flow path that is physically isolated from a second fluid flow path and a convection device for moving a first fluid along the first fluid flow path toward at a desired destination and for exhausting the first fluid at the desired destination at a desired velocity. Methods are also provided for ventilating and/or removing volatile chemicals from liquid (e.g. water) stored in liquid-containing storage tanks (e.g. water-storage tanks). The methods involve blowing a first fluid through a ventilation device into a liquid-containing storage device at a velocity sufficient to achieve a desired mass transfer rate of volatile chemicals from the liquid in the liquid-containing storage device to air in the headspace and flowing the contaminated air back through the ventilation device.

Provided is a containing system which includes a first frame structure, a plurality of first discharge units in the first frame structure, extending in a first direction, and fixedly coupled to the first frame structure in a second direction perpendicular to the first direction, a second frame structure detachably coupled to the first frame structure in the first direction, a first containing unit fixedly supported on the second frame structure and spaced apart from the first frame structure, a second containing unit connected to the first containing unit and spaced apart from the first frame structure, a plurality of second discharge units connected to the second containing unit, aligned with the first discharge units in the first direction, and spaced apart from the first discharge units, and a pressure control unit connected to the first containing unit and controlling a first air pressure in the first containing unit to counterbalance a second air pressure outside the first containing unit.

Apparatus to wirelessly monitor a position of a hatch are disclosed. An example apparatus includes a hatch to be coupled to a fluid tank, a latch to secure the hatch in a closed position, and a sensor to detect whether the latch is securing the hatch in a closed position.

A rectangular or square fluid container having a baffle assembly configured to fit inside an interior volume within the fluid container. The fluid container is capable of being pressurized and has a number of valves or ports on a top wall thereof, which valves or ports allow for the fluid container to be filled with a fluid, for the fluid container to be pressurized, and for the removal of fluid from the fluid container.

A storage tank isolation system for a storage tank includes a vertical riser attached to a top of the storage tank and having a cover with an aperture and a connecting member extending from a side of the vertical riser. A distal end of the connecting member is parallel to the top of the storage tank and attached to a storage hatch. The storage tank isolation system includes a valve assembly, which includes a stem extending through the aperture in the cover, a valve plate attached to the stem, and a valve seat sealed to the vertical riser at a position below a connection to the connecting member. The valve plate is moves with the stem from an open position in which the valve plate is held within the vertical riser at a position equal to or above the connection to the connecting member and a closed position.

The invention relates to bung plug (10) having an integrated pressure compensation means for arrangement in a container lid of a liquid container, the bung plug (10) having a valve housing (15) below a plug depression (12), the valve housing (15) being provided with air passage openings (39, 40) and having a receiving pin (16) arranged centrically in the valve housing (15) for arranging a valve diaphragm (17) whose diaphragm hub (18) is arranged on the receiving pin (16), a radially outward ring edge (19) of the valve diaphragm (17) being in contact with a ring shoulder (20) of the valve housing (15), the diaphragm hub (18) being arranged between a depression bottom (14) of the plug depression (12) and a lid hub (22) of a surge lid (21) arranged on the receiving pin (16) and provided with air passage openings (39, 40), a surge disk (32) being provided between the surge lid (21) and the valve diaphragm (17), wherein the surge disk (32) and the surge lid (21) are realized as a unit and the surge lid (21) has a mounting disk (26) arranged at an axial distance from the surge disk (32) for mounting in the valve housing (15), said mounting disk (26) having an outer mounting edge for forming an engagement connection with a mounting seat arranged at an inner side (29) of a housing wall (30) of the valve housing (15).

A liquid tank system comprises a main liquid tank, an outlet communicating between a fluid circuit and the main liquid tank, an inlet communicating between the fluid circuit and the main liquid tank, and an auxiliary cavity. First vent passage and second vent passage(s) communicate between the main liquid tank and the auxiliary cavity and allows liquid and gas to flow from the main liquid tank to the auxiliary cavity. The second vent passage has a flow control device regulating flow through the second vent passage and having a set point at which it allows liquid and gas to flow from the main liquid tank to the auxiliary cavity only when a pressure in the main liquid tank is beyond a threshold. The liquid tank system has an attitude envelope in which the liquid tank system is configured such that, in use, the flow control device blocks flow through the second vent passage when an end of the first vent passage in the main liquid tank is above a liquid level, and the flow control device allows gas and/or fluid flow through the second vent passage when main fluid tank pressure is above the threshold and the end of the first vent passage in the main liquid tank is below the liquid level.