A vacuum system for use with a deoxygenator system includes a housing, a movable assembly positioned within the housing, and a biasing mechanism coupling the movable assembly to the housing. The movable assembly is movable between a first position and a second position within the housing to form a low pressure area between the housing and the movable assembly. A control system including at least one pressure source is arranged in fluid communication with the low pressure area. The control system is operable to selectively communicate fluid from the at least one pressure source to the housing to form the low pressure area.

A fuel supply system has a fuel tank, a first fuel pump, and a first oxygen removal unit. The first fuel pump delivers fuel from the fuel tank into the first oxygen removal unit. A valve downstream of the first oxygen removal unit is operable to selectively deliver fuel back to the fuel tank in a bypass position or downstream to a use in a use position. A controller programmed to control the valve and the first fuel pump maintains the valve in the bypass position when an associated gas turbine engine is not operating. The controller moves the valve to the use positon when the associated gas turbine engine is operating. A gas turbine engine and a method of operating a fuel supply system are also disclosed.

An oxygen removal system for removing dissolved oxygen from fuel within a fuel system includes a first housing, a second housing, a membrane filter, a piston assembly, and an outlet cap. The first housing extends along a first axis between a first housing first end and a first housing second end. The second housing is disposed about the first housing. The membrane filter is disposed between the first housing and the second housing. The piston assembly has a piston housing that is disposed about the second housing. The piston assembly is arranged to generate a vacuum to remove a fluid from the membrane filter.

A system for use in a gas turbine engine fuel supply has an internal fuel filter having an internal bore and an external surface. A chamber within the internal bore of the fuel filter for receives a fuel and allows fuel to pass radially outwardly across the fuel filter. An oxygen removal unit is outwardly of the external surface of the fuel filter, such that fuel passes through the fuel filter, encounters the oxygen removal unit such that oxygen can be removed from the fuel, an outlet port for removed oxygen, and a separate outlet port for fuel having passed over the fuel filter and the oxygen removal unit.

A vacuum assembly includes a housing and a movable assembly positioned within the housing. Movement of the movable assembly relative to the housing creates a low pressure area. A fluid flow conduit is in fluid communication with the low pressure area. A leakage valve is disposed within the fluid flow conduit and is movable between a first position and a second position to restrict a flow through the fluid flow conduit upon detection of an undesired fluid within the low pressure area.

A system for degassing a hydrocarbon fluid from a hydrocarbon liquid has a plurality of hollow tube membranes. The hollow tube membranes are formed of a plastic providing an inner support body and an outer selective layer which is denser than the inner support body. The inner support body is formed of spherulitic structures. A fuel supply system and a method ae also disclosed.

A hollow fiber cartridge for a hollow fiber membrane degassing system, comprising a tube bundle of selectively permeable membrane tubes having inner channels, the bundle including two ends, and a tube sheet at each end of the tube bundle binding the ends of tube bundle. The tube sheets are configured to mount the tube bundle within a housing of the degassing system. The tube sheets are comprised of one or more of at least one Fluorosilicone, at least one Fluorocarbon, or at least one Polysulfide.

A fluid degassing device includes a first housing, a second housing disposed within the first housing, a first flow circuit defined by the second housing and the first housing between a first flow circuit opening and a second flow circuit opening of the first flow circuit, and a tube bundle of selectively permeable membrane tubes disposed in the first flow circuit between the second housing and first housing. The tube bundle is disposed at least partially around a circumference of the second housing and the first flow circuit is defined between the first flow circuit opening of the first flow circuit and the second flow circuit opening such that fuel flows rotationally around the second housing through the tube bundle.

A fluid degassing device includes a first housing, a second housing disposed at least partially within the first housing, and a first flow circuit defined by the second housing and first housing and the first housing, wherein the second housing includes a second housing opening of the first flow circuit and the first housing includes a first housing opening of the first flow circuit. The device includes a tube bundle of selectively permeable membrane tubes disposed in the first flow circuit between the second housing and first housing. The tube bundle is disposed at least partially around a circumference of the second housing. The tube bundle is configured to be in fluid communication with a second flow circuit to fluidly communicate with an inner channel of the tubes of the tube bundle.

A fuel deoxygenation system includes a boost pump and an oxygen collector. The collector includes an input port fluidly connected to an output of the boost pump, an output port in fluid communication with the input port, and one or more hollow fiber tubes disposed within the oxygen collector, the hollow fiber tubes having an oxygen permeable membrane disposed thereon. The system also includes a nitrogen source in fluid communication with the one or more hollow fiber tubes that causes the formation of a nitrogen containing sweep gas channel within the one or more hollow fiber tubes.