Abstract: An oil filter may include a housing. The housing may include an inlet, an outlet, and a filter element. The filter element may be located downstream of the inlet and upstream of the outlet. Additionally, the filter element may include a filtering material and a tracer material.

Abstract: The present disclosure relates to a filter element for use in a fluid filter system is disclosed herein. The filter element comprises a filter medium having a longitudinal axis between a first end and a second end, and an end cap assembly attached to the first end of the filter medium. The end cap assembly includes a first end cap aligned with the longitudinal axis and proximate to the first end of the filter medium; a first member concentric with and disposed radially apart from the first end cap and the filter medium and axially between the first end cap and the second end of the filter medium; and a plurality of arms connecting the first end cap with the first member, each arm configured to align the filter element with respect to the container and base plate by absorbing alignment discrepancies between at least the base plate and container.

Abstract: A system comprising a drain for a fuel-water separator (FWS) assembly and a sensor is disclosed. The sensor may include a sensing element that is attached to the drain, wherein, when the drain engages the FWS assembly, a cavity is formed by an endcap at least partially within the FWS assembly and by at least one of the drain or the sensor, wherein the sensing element is exposed within the cavity, wherein a first side of the cavity is at least partially open, and wherein a second side of the cavity is formed by at least one of the drain or the sensor, wherein the cavity is configured to receive fluid through the first side and collect the fluid in the cavity to trigger the sensing element. Numerous other aspects and systems are disclosed.

Abstract: An adapter is provided for fluidly coupling a hose to a housing of a filter assembly having a drain body connected to the housing. The adapter has a retaining cap that is disposed about a central axis and is configured to couple with the drain body. A hose barb body is disposed rotatably about the central axis. The hose barb body has a tapered portion that is configured to receive at least a portion of the drain body therein, and a cylindrical portion that extends from the tapered portion. The cylindrical portion is configured to allow selective coupling of a hose thereon. A retaining collar is disposed about the central axis and has a shoulder that is configured to bear the hose barb body thereon. Multiple resilient tabs upstanding from the shoulder have ends laterally extending away from the central axis for engaging with the retaining cap.

Abstract: A filter assembly may include a canister and a filter element received in the canister. The filter element may include filter media configured to promote separation of a first fluid from a second fluid having different characteristics than the first fluid as fluid passes through the filter media. The filter element may further include a first end cap, a second end cap, and a tubular member extending between the first and second end caps. The filter assembly may further include a flow cap associated with the first end cap of the filter element. The flow cap may include an inlet portion configured to provide flow communication between an inlet port of a filter base and the tubular member of the filter element, and an outlet portion configured to provide flow communication between an outlet port of the filter base and an exterior portion of the filter element.

Abstract: An oil filter may include a housing. The housing may include an inlet, an outlet, and a filter element. The filter element may be located downstream of the inlet and upstream of the outlet. Additionally, the filter element may include a filtering material and a tracer material.

Abstract: A system comprising a drain for a fuel-water separator (FWS) assembly and a sensor is disclosed. The sensor may include a sensing element that is attached to the drain, wherein, when the drain engages the FWS assembly, a cavity is formed by an endcap at least partially within the FWS assembly and by at least one of the drain or the sensor, wherein the sensing element is exposed within the cavity, wherein a first side of the cavity is at least partially open, and wherein a second side of the cavity is formed by at least one of the drain or the sensor, wherein the cavity is configured to receive fluid through the first side and collect the fluid in the cavity to trigger the sensing element. Numerous other aspects and systems are disclosed.

Abstract: A flow cap may include an outer ring, an inner ring, an inlet portion, and an outlet portion. The inlet portion may include first portions of the outer and inner rings, and a plurality of arms extending between the first portions of the outer and inner rings, wherein the arms at least partially define an inlet aperture configured to provide flow communication between an inlet port of a filter base and an interior portion of a filter element. The outlet portion may include second portions of the outer and inner rings, and a plate including an outlet aperture providing flow communication between an outlet port of the filter base and an exterior portion of the filter element. The outlet portion may also include a wall, wherein the plate and the wall prevent flow communication between fluid entering the inlet portion and fluid entering the outlet portion.

Abstract: A fuel water separator is provided. The fuel water separator includes a filter having a top end cap and a bottom end cap. A sensor is coupled to the top end cap of the filter. A probe is configured to be coupled to the sensor and to the bottom end cap. The probe is configured to be positioned outside the filter between the top end cap and the bottom end cap.

Abstract: A flow cap may include an outer ring, an inner ring, an inlet portion, and an outlet portion. The inlet portion may include first portions of the outer and inner rings, and a plurality of arms extending between the first portions of the outer and inner rings, wherein the arms at least partially define an inlet aperture configured to provide flow communication between an inlet port of a filter base and an interior portion of a filter element. The outlet portion may include second portions of the outer and inner rings, and a plate including an outlet aperture providing flow communication between an outlet port of the filter base and an exterior portion of the filter element. The outlet portion may also include a wall, wherein the plate and the wall prevent flow communication between fluid entering the inlet portion and fluid entering the outlet portion.

Abstract: A filter assembly may include a canister and a filter element received in the canister. The filter element may include filter media configured to promote separation of a first fluid from a second fluid having different characteristics than the first fluid as fluid passes through the filter media. The filter element may further include a first end cap, a second end cap, and a tubular member extending between the first and second end caps. The filter assembly may further include a flow cap associated with the first end cap of the filter element. The flow cap may include an inlet portion configured to provide flow communication between an inlet port of a filter base and the tubular member of the filter element, and an outlet portion configured to provide flow communication between an outlet port of the filter base and an exterior portion of the filter element.

Abstract: A filter element may include a canister, a first cap coupled to a first end of the canister, and a second cap coupled to a second end of the canister. The filter element may also include an outer tubular member extending between the first cap and the second cap. The filter element may further include an inner tubular member at least partially inside the outer tubular member, and filter media configured to promote separation of a first fluid from a second fluid. The filter media may extend between the first cap and the second cap. The filter element may be configured such that fluid entering the filter element flows between the inner tubular member and the outer tubular member, and through the filter media. The filter element may be configured such that a portion of the fluid may flow from a first side of the second cap to a second side of the second cap, but not into the inner tubular member.

Abstract: A filter element may include a canister, a first cap coupled to a first end of the canister, and a second cap coupled to a second end of the canister. The filter element may further include an outer tubular member extending between the first cap and the second cap, and an inner tubular member. The outer and inner tubular members may each include a plurality of apertures. The filter element may further include filter media configured to promote separation of a first fluid from a second fluid as fluid passes through the filter media. The filter element may be configured such that fluid entering the filter element flows between an interior surface of the canister and an exterior surface of the filter media and through the filter media, such that a portion of the fluid flows into the outer tubular member but not into the inner tubular member.

Abstract: A filter element may include an outer tubular member and an inner tubular member at least partially inside the outer tubular member. The filter element may also include a first cap and a second cap coupled to respective first and second ends of the outer tubular member. The filter element may further include filter media configured to promote separation of a first fluid from a second fluid. The filter media may extend between the first cap and the second cap. The first cap may be configured such that fluid entering the filter element flows between the inner tubular member and the outer tubular member, and through the filter media. The filter element may be configured such that a portion of the fluid may flow from a first side of the second cap to a second side of the second cap, but not into the inner tubular member.

Abstract: A system for detecting a pressure differential between an inlet and an outlet of a filter element may include a housing configured to be associated with a filter element coupled to a filter base of a filter assembly. The system may further include a first sensor configured to provide signals indicative of pressure associated with at least one of an inlet port and an outlet port of the filter element. The system may further include a controller configured to receive the signals from the first sensor, and determine a pressure differential between the inlet port and the outlet port of the filter element based on the signals. The system may be configured such that a flow path of fluid flowing between the inlet port and the outlet port does not include flowing through a portion of the filter base.