An apparatus (10) for handling drill water comprises a funnel (12) and a spillway (16) which act in concert to receive and then separate a slurry mixture into constituent drill cuttings and spent rinse water. The funnel (12) collects the falling slurry mixture, which is channelled via conduit (56) into a spillway (16). The spillway (16) is fitted with a dewatering grate (80) onto which the slurry mixture from the funnel (12) is channelled. The flow of slurry mixture is moderated by a baffle (78) which both catches and discharges slurry mixture delivered by the conduit (56). The slurry mixture is discharged over the dewatering grate (80), which drains the spend rinse water into a section of the spillway (16), and discharges the drill cuttings away from the grate (80).

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.

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.

Proposed is a steam trap device strainer including: an intake pipe through which condensate water flows inside; a pressure gauge disposed at a side of the intake pipe; an intake chamber communicating with the intake pipe; a filter net disposed at a center in the intake chamber and configured to remove foreign substances; a foreign substance outlet formed at a lower portion of the intake chamber to discharge foreign substances; an intermediate channel formed over the filter net and laterally bending and extending; and a discharge pipe communicating with the intake chamber through the intermediate channel to discharge condensate water. The steam trap device further includes an intermediate chamber disposed at a bending of the intermediate channel, an adjuster assembly disposed in the intermediate chamber and having a plurality of perpendicular tunnels, and a temperature sensor disposed on a side of the discharge pipe in the strainer.

Proposed is a steam trap device strainer including: an intake pipe through which condensate water flows inside; a pressure gauge disposed at a side of the intake pipe; an intake chamber communicating with the intake pipe; a filter net disposed at a center in the intake chamber and configured to remove foreign substances; a foreign substance outlet formed at a lower portion of the intake chamber to discharge foreign substances; an intermediate channel formed over the filter net and laterally bending and extending; and a discharge pipe communicating with the intake chamber through the intermediate channel to discharge condensate water. The steam trap device further includes an intermediate chamber disposed at a bending of the intermediate channel, an adjuster assembly disposed in the intermediate chamber and having a plurality of perpendicular tunnels, and a temperature sensor disposed on a side of the discharge pipe in the strainer.

A gutter protection assembly includes a frame, stanchions, and a mesh. The frame includes a rear brace and a supporting flange. The supporting flange is detachably attached to a front lip of a gutter using fasteners. The frame is defined by a series of alternating parallel ridges and a series of parallel channels such that each of the parallel channels define equally spaced openings. Each of the two self-supported stanchions include a base portion, an elongate stem portion inclined relative to the base portion, and two jaw portions extending from an end of the elongate stem portion that include a support clip for receiving adjacent portions of parallel ridges of the frame to define a space between a rear lip of the gutter and the rear brace of the frame. A mesh covers the frame to filter debris through the gutter.

A gutter protection assembly includes a frame, stanchions, and a mesh. The frame includes a rear brace and a supporting flange. The supporting flange is detachably attached to a front lip of a gutter using fasteners. The frame is defined by a series of alternating parallel ridges and a series of parallel channels such that each of the parallel channels define equally spaced openings. Each of the two self-supported stanchions include a base portion, an elongate stem portion inclined relative to the base portion, and two jaw portions extending from an end of the elongate stem portion that include a support clip for receiving adjacent portions of parallel ridges of the frame to define a space between a rear lip of the gutter and the rear brace of the frame. A mesh covers the frame to filter debris through the gutter.

To inhibit damage to or failure of the bladder within a bladder-type pulsation dampener, an internal passage of a bladder saver device carrying pumped fluid from the pulsation bleed plate mounted within the internal passage and movable between a first position in which the pulsated fluid flow is unencumbered by the bleed plate and a second position in which the pulsated fluid flow is restricted by the bleed plate.

To inhibit damage to or failure of the bladder within a bladder-type pulsation dampener, an internal passage of a bladder saver device carrying pumped fluid from the pulsation bleed plate mounted within the internal passage and movable between a first position in which the pulsated fluid flow is unencumbered by the bleed plate and a second position in which the pulsated fluid flow is restricted by the bleed plate.

A marine propulsion device has an engine; an exhaust manifold for conveying exhaust gas from the engine; a cooling water jacket on the exhaust manifold, wherein a cooling water passage for conveying cooling water alongside the exhaust manifold is defined between the cooling water jacket and exhaust manifold; and a cooling water sprayer that sprays cooling water into the exhaust manifold. A manually serviceable cooling water strainer configured to strain cooling water supplied from the cooling water passage to the cooling water sprayer. The manually serviceable cooling water strainer can be manually coupled to and manually uncoupled from the marine propulsion device without use of a tool.