A pump assembly (1) for a vehicle cooling system comprising an impeller (20) and an impeller shaft (200) extending along an impeller axis (X-X). The pump assembly (1) comprises an electric drive (30) and a mechanical drive (40). The pump assembly (1) also comprises transmission means (5) comprising a kinematic transmission assembly (50) comprising an impeller gear (52), a first command gear (53), operatively connected to the electric drive (30) and to the impeller gear (52), and a second command gear (54) operatively connected to the mechanical drive (40) and to the impeller gear (52). Wherein said impeller gear (52) is driven in rotation by the first command gear (53) or by the second command gear (54).

Aa valve arrangement for a cooling system of a vehicle includes a housing having at least two cooling-liquid ports, and a valve element, which can be adjusted between an open position in which it opens up a connection between the cooling-liquid ports and a closed position in which it separates the connection between the cooling-liquid ports. A drive is provided for adjusting the valve element between the open position and the closed position, wherein the drive includes an electric motor, which motor drives an actuation element which actuates the valve element, wherein the actuation element moves along a circular path section in the course of an adjustment of the valve element between the open position and the closed position.

A valve arrangement for a cooling system of a vehicle includes a housing having at least two cooling-liquid ports, and a valve element, which can be adjusted between an open position in which it opens up a connection between the cooling-liquid ports and a closed position in which it separates the connection between the cooling-liquid ports. A drive is provided for adjusting the valve element between the open position and the closed position, wherein the drive includes an electric motor, which motor drives an actuation element which actuates the valve element, wherein the actuation element moves along a circular path section in the course of an adjustment of the valve element between the open position and the closed position.

An engine cooling system may include a water pump for circulating coolant flowing in through a radiator flow path and a bypass flow path to an engine side through an engine cooling flow path, and a thermostat arranged at a fore end of the water pump. The engine cooling flow path is formed to be dualized and divided into a main flow path and a sub-flow path, and the thermostat controls flow rate of the coolant flowing out to the main flow path and the sub-flow path in response to temperature of the coolant flowing into the thermostat.

A parallel hybrid vehicle includes: an engine serving as a drive source for travel of the parallel hybrid vehicle; an electric motor serving as a drive source for travel of the parallel hybrid vehicle; and a water pump that causes a cooling liquid to circulate in a cooling path. The water pump is connected to the engine to receive power from the engine and is connected to the electric motor to receive power from the electric motor.

An axial flux motor water pump comprising a housing, a cover attached to the housing, a stator mounted within the housing, the stator comprising a plurality of stator poles mounted in a ring, each stator pole comprising an electric wire winding, a rotor journalled to the housing in cooperating relation to the stator on a single bearing, an impeller fixed to an end of the rotor, a plurality of magnets mounted to an end of the rotor in cooperative relation to the stator poles, a seal between the rotor and housing whereby the stator and magnets are in a dry zone, the stator enrobed in thermal potting within the housing; and power electronics contained in the cover.

A cooling apparatus for an internal combustion engine includes a pump, a radiator, a flow rate adjustment valve, a bypass passage, and a controller. The flow rate adjustment valve includes a valve member that rotates to change an open degree of the flow rate adjustment valve and a valve member biasing component that biases the valve member in a valve-closing direction in which the open degree decreases. The valve member rotates in a valve-opening direction in which the open degree increases when a pressure difference increases between positions upstream and downstream of the valve member in a flow direction of coolant in the circulation circuit and rotate in the valve-closing direction when the pressure difference decreases. The controller increases the pump discharge amount as a target radiator flow rate that is a target of an amount of coolant passing through the radiator increases.

Methods and systems are provided for a coolant circuit. In one example, the coolant circuit comprises high and low-temperature radiators, where only one pump is configured to conduct coolant through the entire coolant circuit.

A flow passage device includes a circulation flow passage, a swing valve provided in the circulation flow passage, an energizing part, and a lock mechanism including a lock pin. The lock pin is configured so as to hinder the swing valve from opening, and to allow the swing valve to open. The swing valve is configured so as to rotate from a first valve position to a second valve position. The lock mechanism is configured so as to set a locked state and to set an unlocked state. The lock pin is configured so as to protrude as being energized by pressure of the fluid on an upstream side of the swing valve, and to retract as being energized by pressure of the fluid on a downstream side of the swing valve.

A heat pump and a heater core are provided at a heating coolant water circuit connected to an engine. As heating thermal amount control, the control of decreasing the output of the heat pump and increasing the output of the engine with an increase in an engine outlet water temperature detected by an engine outlet water temperature sensor, thereby ensuring a target heating thermal amount. Thus, in response to a decrease in a heat generation efficiency of the heat pump with an increase in the engine outlet water temperature, the output of the heat pump is decreased so that fuel economy can be improved while the output of the engine is increased so that the target heating thermal amount can be ensured.