A thermal management assembly includes a fluidic command device connected to a first and second pump group and having four inlet and outlet ports and an auxiliary duct connecting the pump groups. The fluidic command device is configurable in a first configuration, in which working fluid flows into the first inlet port and out of the first outlet port, flowing into the first pump group, the auxiliary duct and the second pump group, a second configuration, in which working fluid flows into the second inlet port and out of the second outlet port, flowing in the pump groups, preventing flow in the auxiliary duct, and a third configuration, in which working fluid flows into the third inlet port and out of the third outlet port, flowing into the first pump group, and into the fourth inlet port and out of the fourth outlet port, flowing into the second pump group.

An apparatus and process for distributing coolant fluid through first and second coolant loops comprising a pump having a first outlet port connected to the first coolant loop and a second outlet port connected to the second coolant loop and valve located in the pump housing switchable to direct coolant fluid to either the first or the second outlet port individually or to the first and second outlet ports concurrently. Coolant fluid is pumped by the pump at an unrestricted rate of flow is circulated through the first coolant loop at a rate of flow less than the unrestricted rate of flow when the valve connects the first outlet port to the first coolant loop and circulated through the second coolant loop at a rate of flow less than the unrestricted rate of flow when the valve connects the second outlet port to the second coolant loop. The coolant fluid is circulated through the first and the second coolant loops at a rate of flow less than the unrestricted rate of flow when the valve connects the first and the second outlet ports concurrently to the first and second coolant loops and which the rates of flow through the first and the second coolant loops jointly equal the unrestricted rate of flow.

In accordance with at least one aspect of this disclosure, a system, includes a fuel line defining a fuel inlet and a fuel outlet, configured to provide fuel from a fuel tank to an engine. A boost pump, including a boost impeller, is disposed in the fuel line configured to drive fuel from the fuel inlet to the fuel outlet and operatively connected to the boost pump via a drive shaft. The system includes a fluid line defining a fluid inlet and a fluid outlet, configured to provide fluid from a fluid source to a fluid destination. A fluid turbine is disposed in the fluid line configured to alter a pressure of the fuel line between the fuel inlet and the fuel outlet.

A fallback prevention valve apparatus, system and method is described. An electric submersible pump (ESP) fallback prevention system includes an ESP assembly positioned in a downhole well, the ESP assembly including production tubing extending between a centrifugal pump and a surface of the downhole well such that during operation of the ESP assembly production fluid flows upward from the centrifugal pump through the production tubing to the surface, the production tubing including a fallback valve actuatable by the flow of production fluid, the fallback valve actuatable between an open position, wherein production fluid flowing upward through the fallback valve actuates the fallback valve into the open position, and a closed position, wherein production fluid flowing downward through the fallback valve actuates the fallback valve into the closed position, the closed position blocking sand carried by the production fluid from falling into the centrifugal pump.

The present invention concerns a medical pump comprising: a. A hard housing comprising a top (24) and bottom (1) hard shells, within which a rigid wall (3) and a movable membrane (2) create three distinct chambers; wherein i. said movable membrane tightly separates said second (29) and third (22) chambers ii. said first and third chambers have a watertight interface iii. said second chamber (29) is designed to contain a fluid iv. said first chamber (23) comprises a first venting mean (20) which is arranged to provide a fluidic communication between said first chamber (23) and the external environment; v. said third chamber (22) comprises a second venting mean which is arranged to provide a fluidic communication between said third chamber (22) and the external environment b. A pumping element (4) located in the first chamber (23) c. A least one pressure sensor which measure the pressure gradient between the first chamber (23) and the second chamber (29) d. A fluid pathway which permits: i. a first fluid connection (27) between said second chamber (29) and said pumping element ii. a second fluid connection (28) between said pumping element and a patient line (30).

The present discloses a pump apparatus having a first pump and at least one controller. The at least one controller is suitable for generating a first control signal for controlling the first pump. The at least one controller is suitable for generating a second control signal for controlling operation of a second pump. The second pump is external to the pump apparatus. One or more pump connection port is provided in the pump apparatus for outputting the second control signal to the second pump. The present disclosure also relates to a vacuum system comprising a pump apparatus of the type described herein.

An integrated water pump and valve device in which a water pump and a valve are integrally controlled by a single controller, and the water pump and the valve are integrated, thereby reducing an overall size.

Method for detecting failure including possible under or over delivery of a micropump having at least an inlet valve, a pumping chamber with an inner pressure sensor and an outlet valve, said method comprising the determination of the pump tightness via the measurement of the pressure by said inner pressure sensor in said pumping chamber at least at certain intervals when the pump is inactive and the comparison with a value of reference.

A hydraulic system includes at least one circulation pump assembly (2) provided with a speed controller (26), at least one hydraulic circuit (A, B) connected to the circulation pump assembly (2) as well as at least one mechanical switch device (86, 88; 120, 122) which is mechanically subjected to pressure by a fluid in the hydraulic circuit (A, B) and which can be moved into at least two different switch positions. The mechanical switch device (86, 88; 120, 122) moves by the circulation pump assembly (2) hydraulic coupling via the fluid. The speed controller is configured to initiate a movement of the switch device (86, 88; 120, 122), by at least one hydraulic force acting upon the switch device (86, 88; 120, 122) and causing a movement of the switch device (86, 88; 120; 122) via the hydraulic circuit, via a speed adaptation of the circulation pump assembly (2).

Disclosed herein are embodiments of magnetically controlled valve and pump systems that can be used to control and facilitate fluid flow in fluidic devices. Various types of magnetically controlled valves and pumps are described as well as methods of magnetically-controlling such valves and pumps.