A pump shelter including a housing, the housing having insulating structures for insulating an interior of the housing from external elements. A pump system is positioned within the housing and operable for pumping a fluid. A heating system is also positioned within the housing for heating the interior of the housing. A lighting system provides lighting for the interior of the housing. A power supply system provides power to at least one of the pump system, the heating system and the lighting system. Hose elements are removably connectable to the pump system. The pump shelter is readily and quickly available for rapid deployment in a fire or flooding scenario under various climate conditions.

A heat circulation pump includes a pump housing (1) with a pump impeller driven by an electric motor. The electric motor is arranged in a motor housing (8) connected to the pump housing (1). A plastic terminal box (12) is fixed to the motor housing (8) and houses electric and/or electronic components of the engine control and electrically connects the motor, a ground contact arranged on the motor housing (8), and a plug or a socket (34) arranged on the outside of the terminal box (12). The ground contact arranged on the motor housing is connected in an electrically conductive manner to a ground contact of the plug or socket (34) and to at least one conductor inside the terminal box (12). The electric connection between the ground contact arranged on the motor housing (8) and the ground contact of the plug or socket (34) is arranged outside of the terminal box (12).

Provided is a fluid pump assembly. The pump has a pair of housings magnetically coupled to each other. The first housing contains a drive motor and a magnetic assembly. The second housing contains a magnetic assembly and a blade for imparting movement to a fluid. As the first magnetic assembly is rotated by the drive motor, the magnetic connection to the assembly in the second housing causes the second magnet to rotate, driving the blade.

A pump system for pumping water for pools or other flow systems including a pump, a motor, an electronic assembly, and a cooling system. The cooling system provides heat transfer from the pump system to the process flow. The cooling system includes a heat-pipe arrangement designed to transfer heat to one or more heat sinks.

A pump assembly is presented including a motor housing holding a motor, a wet-end housing and a heat transfer interface positioned between a front end of the motor housing and the wet-end housing. The heat transfer interface establishes a first thermal conduction path between the motor housing and the wet-end housing so that a portion of heat generated by the motor is absorbed by the heat transfer interface and a second thermal conduction path between a controller module of the pump assembly and the wet-end housing so that heat generated by the controller module is also absorbed by the heat transfer interface. The pump assembly may include a first and second partial rim members for establishing the first and second thermal conduction paths. Mounting brackets at different radial locations about the motor housing may allow the pump assembly to be mounted in different orientations.

The invention is applicable to a motor pump. The motor pump (MP) includes an impeller (1), a pump casing (2), a motor stator (6), a motor casing (3), a heat radiation member (20), and a substrate (50) arranged in an accommodation space (SP).

Disclosed are a heating pump cover and a heating pump. The heating pump cover comprises a cover body, a temperature control device, a raised part, and a heating body. The cover body has a first surface configured to be in contact with liquid on which the heating body is arranged and a second surface opposite to the first surface on which the temperature control device and the raised part are arranged. The raised part forms grooves on the first surface and the temperature control device is arranged on the raised part. The part of the heating body locates in the grooves has a first region which is in contact with the inner wall of the groove and a second region which is arranged interval with the inner wall of the groove.

A centrifugal reservoir pump for processing a hydrogen stream in an aircraft. In particular, a centrifugal reservoir pump including a pump casing, a hydrogen stream inlet, a rotor being rotatably arranged in the interior part of the pump and including rotor vanes for accelerating the hydrogen stream, and two hydrogen stream outlets. Further provided is a tank unit including the centrifugal reservoir pump and a reservoir for hydrogen. Further provided is an aircraft including a centrifugal reservoir pump or a tank unit. Further provided is a method of processing hydrogen in an aircraft.

A pump assembly such as a centrifugal pump assembly includes a lantern arranged between a pump housing and a motor housing. Surface enlarging elements are arranged at the lantern for increasing heat dissipation and/or enhancing cooling air flow.

An electric coolant pump for providing an automotive cooling circuit with a coolant includes an electric motor to drive the electric coolant pump, a pump housing, a separating can, a printed circuit board, and permanently height-adjusted supporting elements. The separating can includes a substantially plane separating can bottom wall which lies in a cross plane, and a substantially cylindrical separating can shell which fluidically separates a wet zone from a dry zone. The printed circuit board is arranged substantially parallel to and not in direct contact with the separating can bottom wall so that an axial gap exists which is filled with a heat conductive means. The supporting elements axially support the plane printed circuit board. Each supporting element has a distal tip which is trimmed to define a height-constant axial gap having a nominal gap height between the printed circuit board and the separating can bottom wall.