The invention relates to an outer pipe (1) of an outlet (4) of a volute (3) of a heat transfer pump (2), particularly arranged in a recess defined in a heat engine of a vehicle, the outer pipe (1) being provided on an outer surface (9) of the cylinder housing (8) of the engine and comprising a first component (5a) capable of guiding the heat-transfer fluid from said outlet (4) to an inlet (6) of an inner circuit (7) for circulating the heat-transfer fluid defined in the cylinder housing (8).

A closure element is provided for closing a recess in a heat-transfer-fluid pump that is contained in an engine of a vehicle. In particular, in a cylinder block of the engine, the closure element including an element for guiding the flow of heat transfer fluid to an inlet of the pump.

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.

An internal combustion engine of a motor vehicle is provided. The internal combustion engine includes a coolant, a liquid/gas heat exchanger, a coolant-temperature-dependent control element, an equalizing tank, fluidic connections between the components, and a coolant pump. At least one direct or at least one activation-dependent fluidic connection or at least one force-transmitting connection is set up between a medium in the equalizing tank and a medium of at least one other media path or media circuit of the motor vehicle.

Methods and systems are provided for a cooling arrangement. In one example, the cooling arrangement comprises flowing coolant to only an upper portion of a cylinder head during a cold-start. The cooling arrangement comprises flowing coolant to a cylinder block, a lower portion of the cylinder-head, and the upper portion of the cylinder head outside of the cold-start.

A rotary piston engine having a casing and a rotary piston rotating in the casing, wherein the casing comprises a casing wall enclosing the rotating rotary piston, in which casing wall a cavity is disposed for a cooling medium to flow through, and wherein an insertion bush for a spark plug is arranged in the casing wall through the cavity, and wherein the insertion bush is arranged in such a way as to be in direct contact with a cooling medium flowing through the cavity.

A rotary piston engine having a casing and a rotary piston rotating in the casing, the casing comprising a central casing part with a casing wall enclosing the rotating rotary piston, the central casing part being covered by a first cover part and a second cover part on opposite sides to form a closed casing interior, and the central casing part comprising an inner cooling channel, the first cover part comprises a first outer cooling channel and the second cover part comprises a second outer cooling channel, into which a cooling medium flows via an inlet, which cooling medium flows out of the same via an outlet, and wherein the inlet comprises a metering element configured to supply a varying amount of coolant to the inner cooling channel and respectively to the first outer cooling channel and the second outer cooling channel.

A method of operating a vehicle climate system includes, by a controller, responsive to a same blower motor request, operating a blower motor at a first speed responsive to a heater core isolation valve (HCIV) directing coolant used to heat a cabin to an engine. The method further includes, by the controller, responsive to the same blower motor request, operating the blower motor at a second speed less than the first speed responsive to the HCIV directing the coolant to an electric heater and not to the engine.

A coolant pump for a vehicle includes an impeller mounted at one side of a shaft and configured to pump a coolant, a pulley mounted at the other side of the shaft and configured to receive torque, a pump housing including an inlet into which the coolant inflows and an outlet of which the coolant flows out, a slider disposed to be movable in a longitudinal direction of the shaft so as to selectively block or open the outlet and a driver configured to move the slider, where a passage which supplies the coolant to at least one heat exchange element is formed on the pump housing.

This disclosure pertains to a control device for the coolant flow in a cooling circuit of an internal combustion engine with the following characteristics: a housing with an inlet opening, an outlet opening and a movable control element for varying the flow-through cross section of the channel; an annular seal arrangement comprising a sealing frame and a sealing ring is seated between a sealing surface of the housing and a sealing surface of the control element. According to this disclosure, it is proposed that the sealing ring rests against a plane sealing surface of the housing in a sealing fashion and meets this plane sealing surface along a contact line that encloses a first surface area. Depending on the flow direction through the seal arrangement, the sealing ring features a surface section that has a defined circumference referred to the length of the contact line between the sealing ring and the housing. The sealing surface of the sealing frame is perpendicularly projected into a plane of projection and thereby has an inner and/or outer boundary line, which respectively encloses a second or third surface area that has a certain relation to the first surface area.