A three-way connector includes a body provided with an inlet, a first outlet in line with the inlet, a first waterway defined to communicate the inlet with the first outlet and a second outlet communicating with the inlet and the first outlet via a second waterway vertically defined relative to the first waterway. A filter assembly is received inside the first waterway and having a texture in line with the first waterway.

A three-way connector includes a body provided with an inlet, a first outlet in line with the inlet, a first waterway defined to communicate the inlet with the first outlet and a second outlet communicating with the inlet and the first outlet via a second waterway vertically defined relative to the first waterway. A filter assembly is received inside the first waterway and having a texture in line with the first waterway.

A method for filtering one or more of run-off fluid, chemical spills and facility discharge, the method including: storing a first portion of the one or more of run-off fluid, chemical spills and facility discharge in a first compartment; discharging additional fluid from an overflow in the first compartment when a volume capacity of the first compartment is full; in a second compartment in fluid communication with the first compartment, filtering the one or more of run-off fluid, chemical spills and facility discharge stored in the first compartment that is not discharged through the overflow, and discharging filtered fluid from the second compartment.

A filter unit to be utilized in a continuous flow engine wherein the filter unit is adapted to filter a fluid stream, preferably a gas stream, wherein the filter unit provides a strainer part providing two strainer surfaces, wherein at least one of the two strainer surfaces is not planar. A kit contains a filter unit of this type and a counterpart adapted receive the filter unit, wherein the counterpart is adapted to be used as part of the continuous flow engine. A method utilizes such filter unit or kit.

Systems and apparatuses for allowing passive urine recovery are disclosed. An exemplary commode liner that allows for passive urine recovery comprises a first layer comprising a first top side configured to receive a bio-waste material, a first bottom side, and a plurality of apertures spanning the first top side and the first bottom side, wherein the plurality of apertures passively promote a unidirectional movement of a liquid portion of the bio-waste material from the first top side to the first bottom side. The liner further comprises a second layer attached to the first layer, wherein the second layer is attached to the first layer such that a space is created between a second top side of the second layer and the first bottom side of the first layer, wherein the space is configured to hold a liquid portion of the bio-waste material received at the first top side.

Embodiments of the present disclosure could generally provide a relatively easily squeezable beverage bottle that allows control of the flow rate of the liquid being dispensed to the user. The bottle could provide sufficient radial rigidity—or resistance to squeezing—to return to its original shape (or “bounce back”) at a suitable rate without experiencing permanent deformation or denting and to withstand the rigors of filling, shipping, transporting, dispensing, etc. The present disclosure generally provides a beverage bottle filtering system that provides adequate filtering of water taken from the bottle at a suitable rate. In one embodiment, the present disclosure could include a support system to adequately secure the filter media within a filter housing while ensuring a sufficient compression fit and seal of filter media within filter system to eliminate “bypass flow” (i.e., water that might leak past filter system) and prevent consumption of unfiltered water.

Embodiments of the present disclosure could generally provide a relatively easily squeezable beverage bottle that allows control of the flow rate of the liquid being dispensed to the user. The bottle could provide sufficient radial rigidity—or resistance to squeezing—to return to its original shape (or “bounce back”) at a suitable rate without experiencing permanent deformation or denting and to withstand the rigors of filling, shipping, transporting, dispensing, etc. The present disclosure generally provides a beverage bottle filtering system that provides adequate filtering of water taken from the bottle at a suitable rate. In one embodiment, the present disclosure could include a support system to adequately secure the filter media within a filter housing while ensuring a sufficient compression fit and seal of filter media within filter system to eliminate “bypass flow” (i.e., water that might leak past filter system) and prevent consumption of unfiltered water.

Systems and methods for filter orientation on a control valve are provided. In particular, systems and methods are provided for rotationally orienting a filter retention feature with respect to an application fluid passageway to control forces and stresses exerted on the filter retention feature. Additionally, methods for manufacturing a control valve are provided that enable a rotational relationship between a filter retention feature and an application fluid passageway to be constrained.

Systems and methods for filter orientation on a control valve are provided. In particular, systems and methods are provided for rotationally orienting a filter retention feature with respect to an application fluid passageway to control forces and stresses exerted on the filter retention feature. Additionally, methods for manufacturing a control valve are provided that enable a rotational relationship between a filter retention feature and an application fluid passageway to be constrained.

An aircraft fuel deoxygenation system includes a boost pump, a contactor-separator, and a centrifuge-separator pump. The boost pump is adapted to receive fuel from a fuel source and inert gas from an inert gas source, and is configured to mix the fuel and inert gas and supply a fuel/gas mixture. The contactor-separator is coupled to receive the fuel/gas mixture and is configured to remove oxygen from the fuel and thereby generate and supply deoxygenated fuel with entrained purge gas and separated purge gas. The centrifuge-separator pump is coupled to receive the deoxygenated fuel with entrained purge gas and is configured to separate and remove the entrained purge gas from the deoxygenated fuel and supply the deoxygenated fuel and additional purge gas.