A coolant control system of a vehicle includes an opening module configured to determine a coolant valve (CV) opening, a flow control valve (FCV) opening, and a block valve (BV) opening based on at least one of a block temperature difference, a head temperature difference, and a coolant outlet temperature difference. A CV control module is configured to selectively actuate a CV based on the CV opening. The CV regulates coolant flow from the FCV to a radiator and a coolant channel bypassing the radiator. A BV control module is configured to selectively actuate a BV based on the BV opening. The BV regulates coolant flow from the engine block to the FCV. A FCV control module is configured to selectively actuate a FCV based on the FCV opening. The FCV regulates coolant flow from the cylinder head and the BV to the CV.

The cooling apparatus of the internal combustion engine according to the invention executes an incompletely-warmed state control for supplying the cooling water to the cylinder block water passage from the cylinder head water passage without flowing the cooling water through the radiator and supplying the cooling water to the cylinder head water passage from the cylinder block water passage when the temperature of the cooling water is lower than the engine completely-warmed water temperature at which the engine is estimated to be warmed completely.

The invention relates to a thermal management method for operating a thermal management system (100, 102) of an internal combustion engine (10). The thermal management system (100, 102) comprises at least one fluid chamber (12) which is arranged at least partially around a cylinder head (74) of a cylinder (70) of the internal combustion engine (10) and has at least one inlet line (14) and at least one outlet line (16), the fluid chamber (12) being connected to at least one coolant pumping device (20) for pumping a coolant, and to at least one heat sink. According to the invention, a cylinder head temperature sensor and/or a fluid chamber temperature sensor (58) is provided, a volume flow of the coolant delivery device (20) being controllable depending on an engine speed and/or a fluid chamber temperature and/or an engine load, in particular by actuation of at least the first valve (18). According to the thermal management method, when the temperature in the fluid chamber (12) rises, in particular after a warm-up phase and when the engine speed remains constant or drops, the volume flow of the coolant through the heat sink is at least temporarily increased, and when the engine speed remains constant or increases by no more than 100 rpm, with engine load being reduced, in particular by at least 30%, the volume flow of the coolant through the heat sink is not reduced, and in particular is not reduced after at least one minute following the load change, and more particularly is not reduced when a fluid chamber (12) temperature is in the 60 to 100? C. range.

A cooling system selectively cools an engine and an exhaust gas recirculation (EGR) component of the engine. The cooling system includes a plumbing system with a plurality of flow branches, including an engine branch, an EGR branch, and a feed branch. The engine branch defines an engine flow passage through which the coolant flows to cool the engine. The EGR branch defines an EGR flow passage through which the coolant flows to cool the EGR component. The feed branch defines a feed flow passage. The cooling system has a first operating configuration in which the EGR flow passage is configured to receive coolant flow from the engine flow passage. The cooling system has a second operating configuration in which the EGR flow passage is configured to receive coolant flow from the feed flow passage instead of the engine flow passage.

A cooling system for an engine is provided. The cooling system includes coolant flow paths including a first flow path and a second flow path and where coolant circulates, a coolant pump for circulating coolant within the coolant flow paths, a flow rate control valve for adjusting a flow rate of the coolant through the second flow path, a temperature detector for detecting a temperature of the coolant within the first flow path, and a valve controller for adjusting an opening of the flow rate control valve based on the temperature detected by the temperature detector. The first flow path passes through a cylinder head of the engine, and the second flow path branches from the first flow path and passes through auxiliary machinery of the engine.

To enhance responsivity of temperature sensor detecting an engine temperature. A temperature sensor component 40 includes a metal washer 42. The temperature sensor component 40 transfers the engine temperature to a sensor body 46 via the heat transfer washer 42. A cylinder portion 8 of a cylinder block 64 has two bosses 30. The washer 42 of the temperature sensor component 40 is fixed to the boss 30 together with the electronic control unit 20.

A cooling system for an air-cooled engine includes a plurality of electric fans, a plurality of ducts, each duct configured to receive one of the plurality of electric fans, a housing, the housing configured to be coupled to the engine and to include at least one opening, each opening is configured to be coupled to receive one of the plurality of ducts to direct air from the electric fans to a plurality of target locations, a sensor, the sensor is configured to acquire sensor data regarding the operation of the engine, and a processing circuit, the processing circuit is configured to receive the sensor data from the sensor and to control operation of the plurality of electric fans in accordance with the sensor data.

A thermal management method for operating a thermal management system of an internal combustion engine. The thermal management system comprises at least one fluid chamber which is arranged at least partially around a cylinder head of a cylinder of the internal combustion engine and has at least one inlet line and at least one outlet line, the fluid chamber being connected to at least one coolant pumping device for pumping a coolant, and to at least one heat sink. According to a thermal management method, with increasing temperature of the at least one fluid chamber after a warm-up phase at a constant or decreasing engine speed, the coolant flow rate is temporarily increased through the at least one heat sink. At a constant engine speed or at an engine speed increasing at maximum 100 revolutions per minute and with reducing engine load, the coolant flow rate is maintained or increased through the at least one heat sink after the load change within a temperature range of 60 C. to 100 C. of the at least one fluid chamber

A cooling system for an air-cooled engine includes a plurality of electric fans, a plurality of ducts, each duct configured to receive one of the plurality of electric fans, a housing, the housing configured to be coupled to the engine and to include at least one opening, each opening is configured to be coupled to receive one of the plurality of ducts to direct air from the electric fans to a plurality of target locations, a sensor, the sensor is configured to acquire sensor data regarding the operation of the engine, and a processing circuit, the processing circuit is configured to receive the sensor data from the sensor and to control operation of the plurality of electric fans in accordance with the sensor data.

An installation structure of a water temperature sensor configured to detect a temperature of cooling water in an engine is provided. In the installation structure, an outlet of an exhaust port is opened in a front surface of a cylinder head of the engine, and the water temperature sensor is provided at a location adjacent to the outlet of the exhaust port in a front view.