A coolant supply unit includes a plurality of pumps, a casing that includes a coolant inlet port, a plurality of branch ports that respectively convey coolant to the plurality of pumps, a plurality of flow merging ports through which the coolant from the plurality of pumps merges, and a coolant outlet port; and a separating wall that is provided inside the casing and that separates the inside of the casing into a distribution chamber that is in communication with the inlet port and the branch ports, and a flow merging chamber that is in communication with the flow merging ports and the outlet port.

A coolant supply unit includes a plurality of pumps, a casing that includes a coolant inlet port, a plurality of branch ports that respectively convey coolant to the plurality of pumps, a plurality of flow merging ports through which the coolant from the plurality of pumps merges, and a coolant outlet port; and a separating wall that is provided inside the casing and that separates the inside of the casing into a distribution chamber that is in communication with the inlet port and the branch ports, and a flow merging chamber that is in communication with the flow merging ports and the outlet port.

A well pump assembly has an upper plunger and a lower plunger. A working fluid conduit extends between the upper and lower plunger. An upper piston in the working fluid conduit is connected with the upper plunger. A lower piston in the working fluid conduit is connected with the lower plunger. A downstroke working fluid is located between the upper and lower pistons in the working fluid conduit. An upstroke conduit extends between an upper port in the working fluid conduit above the upper piston and a lower port in working fluid conduit below the lower piston. An upstroke working fluid fills the upstroke conduit and the working fluid conduit above the upper piston and below the lower piston.

A well pump assembly has an upper plunger and a lower plunger. A working fluid conduit extends between the upper and lower plunger. An upper piston in the working fluid conduit is connected with the upper plunger. A lower piston in the working fluid conduit is connected with the lower plunger. A downstroke working fluid is located between the upper and lower pistons in the working fluid conduit. An upstroke conduit extends between an upper port in the working fluid conduit above the upper piston and a lower port in working fluid conduit below the lower piston. An upstroke working fluid fills the upstroke conduit and the working fluid conduit above the upper piston and below the lower piston.

A drive system for a cryogenic pump is provided including a spool housing having a plurality of valves disposed therein about a pump axis and a tappet housing including a plurality of tappet bores, each tappet bore in communication with a respective one of the plurality of valves. A collection cavity collects hydraulic fluid from the tappet bores. A pump flange includes a fluid inlet and a fluid outlet. An inlet manifold directs hydraulic fluid received through the fluid inlet to each of the plurality of valves. An outlet manifold directs hydraulic fluid from each of the valves and the collection cavity to the fluid outlet.

A bi-directional pump system that can be configured for a plurality of operating modes. The bi-directional pump system includes a plurality of bi-directional pumps each having their own valving system that are connected to a common high pressure manifold, a low pressure manifold and a suction manifold. Via the respective valve systems, each pump can be configured into: (1) a single-acting pumping mode; (2) a double-acting pumping mode; (3) an inactive free motion mode; and (4) an inactive rigid mode. One exemplary application of the bi-directional pump system is on an articulated wave energy conversion system that consists of three floating barges: a front barge, a center barge and a rear barge where the front barge and center barge are hingedly connected as are the center barge and the rear barge. A first set of the bi-directional pumps span the first hinge connection and the second set of bi-directional pumps span the second hinge connection. The bi-directional pump system intakes sea water and, using wave energy, outputs a high pressure flow of sea water for water desalination and/or for driving electrical generators.

A bi-directional pump system that can be configured for a plurality of operating modes. The bi-directional pump system includes a plurality of bi-directional pumps each having their own valving system that are connected to a common high pressure manifold, a low pressure manifold and a suction manifold. Via the respective valve systems, each pump can be configured into: (1) a single-acting pumping mode; (2) a double-acting pumping mode; (3) an inactive free motion mode; and (4) an inactive rigid mode. One exemplary application of the bi-directional pump system is on an articulated wave energy conversion system that consists of three floating barges: a front barge, a center barge and a rear barge where the front barge and center barge are hingedly connected as are the center barge and the rear barge. A first set of the bi-directional pumps span the first hinge connection and the second set of bi-directional pumps span the second hinge connection. The bi-directional pump system intakes sea water and, using wave energy, outputs a high pressure flow of sea water for water desalination and/or for driving electrical generators.

A hydraulic drive system for a construction and/or thick matter pump system includes a first drive cylinder and a second drive cylinder, a first directional valve and a second directional valve, and a flushing hydraulic liquid device. The first directional valve is configured to connect the first drive cylinder to the second directional valve by way of a first switching position and to connect the second directional valve to the flushing hydraulic liquid device by way of a second switching position. The second directional valve is configured to connect the second drive cylinder to the first directional valve by way of a first switching position and to connect the first directional valve to the flushing hydraulic liquid device by way of a second switching position.

A hydraulic drive system for a construction and/or thick matter pump system includes a first drive cylinder and a second drive cylinder, a first directional valve and a second directional valve, and a flushing hydraulic liquid device. The first directional valve is configured to connect the first drive cylinder to the second directional valve by way of a first switching position and to connect the second directional valve to the flushing hydraulic liquid device by way of a second switching position. The second directional valve is configured to connect the second drive cylinder to the first directional valve by way of a first switching position and to connect the first directional valve to the flushing hydraulic liquid device by way of a second switching position.

A hydraulic drive system for a construction and/or thick matter pump system includes a first drive cylinder and a second drive cylinder, a first directional valve and a second directional valve, and a flushing hydraulic liquid device. The first directional valve is configured to connect the first drive cylinder to the second directional valve by way of a first switching position and to connect the second directional valve to the flushing hydraulic liquid device by way of a second switching position. The second directional valve is configured to connect the second drive cylinder to the first directional valve by way of a first switching position and to connect the first directional valve to the flushing hydraulic liquid device by way of a second switching position.