A drainage pipe un-dissolved waste catch assembly includes a panel that has a rear edge, a front edge, a first lateral edge, a second lateral edge, a top side and a bottom side. The panel has a plurality of apertures therein extending into the top side and through the bottom side. A plate is attached to and extends along the front edge and forms a angle with the top side is between 120 and 150. A coupler is attached to the top side of the panel adjacent to the rear edge and releasably engages a discharge tube such that the panel is positioned below and extends forward of the discharge tube. As waste water flows outwardly of the discharge tube, any un-dissolved materials therein will be retained on the panel.

A lift station maintenance device having as its essential features, a circular housing constructed from bars, interleaving self-centering augers for lifting flushable wipes through the system, spring snap options for retaining the bar in slots in top and base plates, and capability to remove large flushable wipes or equivalent materials from liquid sewage systems without clogging. Also disclosed is a lift station maintenance system.

An anti-vibration arrangement for a condensate pump comprising a housing having a first opening; a pump motor contained within the housing having a pump motor inlet in fluid communication with a pump motor outlet; and a resiliently deformable collar secured within the first opening having an aperture through which the pump motor inlet projects. The resiliently deformable collar comprises an outer portion secured to the housing, an inner portion to support the pump motor inlet and a connecting portion located between the outer portion and the inner portion, such that oscillations of the pump motor cause the connecting portion to deform and allow the inner portion to move in reciprocating manner.

The disclosure provides a filtering device comprising a housing, a blocking member and a screening member. The housing includes a body, an inlet end and an outlet end. The housing forms an accommodation space. The inlet end and the outlet end are respectively formed at two ends of the accommodating space. The inlet end is capable of receiving fluid. The blocking member is capable of splitting the fluid into a plurality of fluids and collecting the non-fluid composition of the secondary fluid having a first size. The screening member is disposed between the inlet end and the blocking member, and the screening member is configured to receive the secondary fluid to limit the non-fluid composition having a second size of the secondary fluid to the screening member. After the secondary fluid passes through the shield and the screening member, the secondary fluid is output from the outlet end.

A gutter guard filtering device built to cover the top of a rainwater gutter opening. The gutter guard filtering device is comprised of an extruded rigid metal or rigid plastic support frame that supports a separate filtering media assembly and a separate rear wing assembly where the filtering media is comprised of a pachinko-style filtering media design or a continuous bead-style filtering media and the rear wing is a sheet metal rear wing assembly. The main body frame contains both front and rear receivers that hold the filtering media, that hold the wing assembly, or hold both filter filtering media and wing together in such a manner as the receivers contain serrations, bosses, or protrusions on the surfaces that come in contact with the filtering media and/or wing assembly in a tongue and groove configuration.

A gutter guard filtering device built to cover the top of a rainwater gutter opening. The gutter guard filtering device is comprised of an extruded rigid metal or rigid plastic support frame that supports a separate filtering media assembly and a separate rear wing assembly where the filtering media is comprised of a pachinko-style filtering media design or a continuous bead-style filtering media and the rear wing is a sheet metal rear wing assembly. The main body frame contains both front and rear receivers that hold the filtering media, that hold the wing assembly, or hold both filter filtering media and wing together in such a manner as the receivers contain serrations, bosses, or protrusions on the surfaces that come in contact with the filtering media and/or wing assembly in a tongue and groove configuration.

A filter assembly for filtering hydraulic fluid in a hydraulically actuated fuel injector is disclosed. The filter assembly includes a plurality of first rollers and a plurality of second rollers. The first rollers are parallelly disposed one after the other, and define first axes disposed in a first plane. The second rollers are parallelly disposed one after the other, and define second axes disposed in a second plane. The first plane is parallel to the second plane. Further, each second roller is disposed between a consecutively arranged pair of first rollers to define one or more filtration zones for filtering the hydraulic fluid.

An exemplary method includes forming a sacrificial layer along sidewalls of an array of trenches that are indented into a substrate, depositing a fill layer over the sacrificial layer, and then creating an array of gaps between the fill layer and the substrate by removing the sacrificial layer along the sidewalls of the trenches, while maintaining a structural connection between the substrate and the fill layer at the floors of the trenches. The method further includes covering the substrate, the fill layer, and the gaps with a cap layer that seal fluid-tight against the substrate and the fill layer. The method further includes indenting a first reservoir and a second reservoir through the cap layer, and into the substrate and the fill layer, across the lengths of the array of gaps, so that the array of gaps connects the first reservoir in fluid communication with the second reservoir.

An exemplary method includes forming a sacrificial layer along sidewalls of an array of trenches that are indented into a substrate, depositing a fill layer over the sacrificial layer, and then creating an array of gaps between the fill layer and the substrate by removing the sacrificial layer along the sidewalls of the trenches, while maintaining a structural connection between the substrate and the fill layer at the floors of the trenches. The method further includes covering the substrate, the fill layer, and the gaps with a cap layer that seal fluid-tight against the substrate and the fill layer. The method further includes indenting a first reservoir and a second reservoir through the cap layer, and into the substrate and the fill layer, across the lengths of the array of gaps, so that the array of gaps connects the first reservoir in fluid communication with the second reservoir.

A filtration system includes a filtration device having filter slats positioned in a linear array and connected via a supporting structure, the filter slats being parallel to one another and being fixed at an angle relative to the linear array; and pores created by the filter slats; a fluid flow chamber to hold the filtration device such that fluid passes through the filtration device, the fluid flow chamber having a filtration channel with an inlet to receive fluid and an expulsion channel in fluid communication with the filtration channel; a filtrate channel in fluid communication with the filtration channel such that fluid passes through the filtration device between the filtration channel and the filtrate channel, the filtrate channel having a filtrate channel outlet; one or more pressure modulating structures in fluid communication with the fluid flow chamber such that the pressure modulating structure modifies pressure in the fluid flow chamber.