A system. The system includes a prelubrication system, a filtration system, a valve, a sensor and a control module. An inlet of the valve shares a common junction with an outlet of a component of the prelubrication system and an inlet of a component of the filtration system. The sensor is configured to detect a triggering condition. The control module is coupled to the valve, and is configured to control operation of the valve based on the detected triggering condition.

A system. The system includes a prelubrication system, a filtration system, a valve, a sensor and a control module. An inlet of the valve shares a common junction with an outlet of a component of the prelubrication system and an inlet of a component of the filtration system. The sensor is configured to detect a triggering condition. The control module is coupled to the valve, and is configured to control operation of the valve based on the detected triggering condition.

The present invention provides a fluid injection system (11) which transitions between a maintenance mode wherein an outlet (15) is closed and no fluid is discharged through the outlet, and an operation mode, wherein the outlet is open and fluid is discharged through the outlet. The fluid injection system injects a first fluid transported in a first pipeline (21) with a second fluid, wherein there is a temperature differential between the first fluid and the second fluid. The fluid injection system comprises a holding tank (49) for storing the second fluid, a cooling means (35) to cool the second fluid, and a pump (39) for delivering the second fluid into the first pipeline. The second fluid mixes with the first fluid in the first pipeline to provide a combined third fluid having a temperature within a predetermined temperature range, wherein the third fluid is maintained within the predetermined temperature range when the fluid injection system is in either mode such that the temperature of the third fluid made available to an outlet is within the predetermined temperature range.

The present invention provides a fluid injection system (11) which transitions between a maintenance mode wherein an outlet (15) is closed and no fluid is discharged through the outlet, and an operation mode, wherein the outlet is open and fluid is discharged through the outlet. The fluid injection system injects a first fluid transported in a first pipeline (21) with a second fluid, wherein there is a temperature differential between the first fluid and the second fluid. The fluid injection system comprises a holding tank (49) for storing the second fluid, a cooling means (35) to cool the second fluid, and a pump (39) for delivering the second fluid into the first pipeline. The second fluid mixes with the first fluid in the first pipeline to provide a combined third fluid having a temperature within a predetermined temperature range, wherein the third fluid is maintained within the predetermined temperature range when the fluid injection system is in either mode such that the temperature of the third fluid made available to an outlet is within the predetermined temperature range.

A system (200) for pumping a multi-phase feed mixture includes a separation section (230) having a separation tank (206), a mixing section (240), and a pumping section (250). The separation tank (206) has a feed mixture entrance (204) and a liquid outlet (215) located at different axial positions along a wall of the separation tank (206). A gas line (212) extends through the separation tank (206) from a gas inlet (217) located in an interior of the separation tank to a gas outlet (218) located outside of the separation tank (206). The mixing section (240) includes a fluid suction chamber (220) surrounding the gas outlet (218), and a liquid line (216) fluidly connects the liquid outlet (215) to the fluid suction chamber (220). The pumping section (250) includes a pump (226), and a diffuser (222) fluidly connects the fluid suction chamber (220) to a pump inlet (224).

A high pressure volumetric fluid metering device for controlling the flow of fluid from a high pressure fluid supply source to a process line includes a modulator configured to pump a predetermined volume of high pressure fluid at a predetermined flow rate and an oscillator in fluid communication with the high pressure fluid supply source. The oscillator is configured to selectively direct high pressure fluid from the high pressure fluid supply source toward the modulator and further configured to direct the predetermined volume of high pressure fluid pumped out of the modulator toward an oscillator outlet. The metering device further includes a differential pressure regulator configured to substantially maintain the pressure differential across the modulator and oscillator.

A slurry-transporting facility equipped with a plurality of pump-equipment circuits, whereby a stop of slurry supply to a transport destination at the time of switchover between the pump-equipment circuits for use is prevented to make an efficient operation possible. The slurry-transporting facility includes: pipe arrangements which branch out from a feed tank into the plurality of circuits; a transport pump provided in each of the pipe arrangement; a first valve provided upstream from the transport pump; a second valve provided downstream from the transport pump; and a uniting pipe arrangement formed by joining of the pipe arrangements at a predetermined position and connected to a LT heater. The uniting pipe arrangement is provided with a third valve configured to control the transportation of ore slurry to the LT heater and a pressure gauge configured to measure a pressure in the uniting pipe arrangement.

A slurry-transporting facility equipped with a plurality of pump-equipment circuits, whereby a stop of slurry supply to a transport destination at the time of switchover between the pump-equipment circuits for use is prevented to make an efficient operation possible. The slurry-transporting facility includes: pipe arrangements which branch out from a feed tank into the plurality of circuits; a transport pump provided in each of the pipe arrangement; a first valve provided upstream from the transport pump; a second valve provided downstream from the transport pump; and a uniting pipe arrangement formed by joining of the pipe arrangements at a predetermined position and connected to a LT heater. The uniting pipe arrangement is provided with a third valve configured to control the transportation of ore slurry to the LT heater and a pressure gauge configured to measure a pressure in the uniting pipe arrangement.

A cassette is provided for installation in a dialysis monitor to pump a treatment solution through a dialyzer. The cassette is a unitary component with a hydraulic manifold (53) and a pneumatic manifold (54) integrated into a body (52). The body (52) has connectors for connecting the hydraulic manifold (53) to the dialyzer and the pneumatic manifold (54) to a pneumatic pressure source. A set of solution pumps is integrated in the cassette, and each solution pump includes a pump cavity inside the body. The solution pumps are operable to displace the treatment solution through the hydraulic manifold (53) to and/or from the dialyzer by action of a reciprocating gas-liquid interface in the pump cavity (30) of the respective solution pump. The gas-liquid interface is formed directly between a gaseous substance and the treatment solution. A valve arrangement (58) is attached to the body (52) and operable to control admission of the gaseous substance and the treatment solution to the pump cavity (30) so as to reciprocate the gas-liquid interface and thereby pump the treatment solution through the hydraulic manifold (53). The cassette is configured to pump the treatment solution without moving parts inside the body (52).

A cassette is provided for installation in a dialysis monitor to pump a treatment solution through a dialyzer. The cassette is a unitary component with a hydraulic manifold (53) and a pneumatic manifold (54) integrated into a body (52). The body (52) has connectors for connecting the hydraulic manifold (53) to the dialyzer and the pneumatic manifold (54) to a pneumatic pressure source. A set of solution pumps is integrated in the cassette, and each solution pump includes a pump cavity inside the body. The solution pumps are operable to displace the treatment solution through the hydraulic manifold (53) to and/or from the dialyzer by action of a reciprocating gas-liquid interface in the pump cavity (30) of the respective solution pump. The gas-liquid interface is formed directly between a gaseous substance and the treatment solution. A valve arrangement (58) is attached to the body (52) and operable to control admission of the gaseous substance and the treatment solution to the pump cavity (30) so as to reciprocate the gas-liquid interface and thereby pump the treatment solution through the hydraulic manifold (53). The cassette is configured to pump the treatment solution without moving parts inside the body (52).