The vehicle front structure includes a radiator located in a vehicle front so that air passes through a vehicle rear, a radiator fan located in the vehicle rear of the radiator so as to generate an air flow flowing from the vehicle front to the radiator, an engine located in the vehicle rear of the radiator fan, and an engine soundproof cover having a front cover portion for covering a portion of a front surface of the engine, and guiding the air passing through the radiator fan to flow upward of the engine by using the front cover portion.

An embodiment multi-way coolant valve includes an outer housing including a first outer inlet, a second outer inlet, a third outer inlet, a fourth outer inlet, a first outer outlet, and a second outer outlet, an inner housing rotatably provided within the outer housing and configured to define a coolant flow path, and a driving unit connected to a first rotation center of the inner housing and configured to selectively rotate the inner housing within the outer housing, wherein, as the inner housing rotates by a preset interval according to a selected mode of a vehicle, the first outer inlet or the second outer inlet selectively communicates with the first outer outlet, and the third outer inlet or the fourth outer inlet selectively communicates with the second outer outlet.

The present disclosure relates to a system for controlling an air flow rate into a vehicle engine room. The system includes: an air intake port receiving an exterior air at a front portion of the vehicle and supplying the air into the engine room; air ducts formed at both sides of the air intake port and introduce the exterior air into a wheel side in order to improve aerodynamic characteristic; a control valve configured to selectively convey the air flowed in the air intake port into the air ducts; a radiator disposed between the air intake port and the engine room; and a control portion configured to control the control valve based on an operating state of vehicle. The air ducts are selectively communicated with the air intake port and disposed at upstream of the radiator.

An electric water pump having a motor with an axially moveable rotor unit. A rotary pump member is fixed for axial movement with the rotor unit to vary its position within a pump chamber so as to vary the flow rate through the pump chamber.

A coolant control valve unit includes a wall including a passage disposed at a predetermined position from one surface to another surface, a valve disposed to be inserted into the passage and open and close the passage according to a movement position, and an actuator opening and closing the passage through the valve by pushing or pulling the valve by using a stem connected with the valve, wherein one side and another side of the wall are formed to have a height difference in a movement direction or in an opposite movement direction so that a portion of the passage is opened and a remaining part of the passage is closed by the valve when the valve moves along the passage.

Provided herein are systems and methods for cooling an electric drivetrain of an electric vehicle. The electric drivetrain can include an inverter, a gearbox and a motor. A first cooling system can use ethylene glycol and water (EGW) based coolant, and can include an EGW coolant loop to distribute the EGW based coolant to remove heat from a cold plate of the inverter, a housing of the gearbox, and a housing of the motor. A second cooling system can use an oil based coolant, and can include an oil coolant loop to distribute the oil based coolant to remove heat from internal components and the housing of the gearbox, and to remove heat from internal components and the housing of the motor. The second cooling system can include an oil coolant pump to control a flow of the oil based coolant through the oil coolant loop.

A control device for a vehicle includes a grille shutter ECU that is connected to a LIN communication line and controls driving of a grille shutter, and an engine ECU that is connected to the LIN communication line so as to be able to establish communication with the grille shutter ECU. In the case of detecting an abnormality in the communication, if a predetermine threshold time or more has elapsed since a start of the vehicle, and if cumulative time that a detection result of a vehicle speed sensor is equal to or more than a predetermined vehicle speed threshold value, is equal to or more than a cumulative threshold value, and a number of starts of the vehicle is equal to or more than a predetermined trip number, the engine ECU determines that the detected abnormality is a failure in the LIN communication.

A degas bottle for a motor vehicle coolant system is provided. The degas bottle has a body defining an enclosed cavity bounded by an upper wall, a lower wall and a side wall extending between said upper and lower walls. An inlet extends into an upper region of the cavity proximate the upper wall and an outlet extending outwardly from a lower region of the cavity proximate the lower wall. An interior wall is disposed in the enclosed cavity. The interior wall extends from the upper wall toward the lower wall to a free end spaced from the lower wall. The interior wall has a vent opening proximate the upper wall and extends to the side wall on opposite sides of the inlet. A baffle is disposed between the interior wall and the inlet. The baffle extends from one of the upper wall or the lower wall to a free end spaced from the other of the upper wall or the lower wall.

Examples of techniques for controlling the flow of a coolant fluid through a cooling system of an internal combustion engine are disclosed. In one example implementation, a method includes calculating, by a processing device, a minimum zone flow rate of the coolant fluid for a zone of a cooling system of the internal combustion engine. The method further includes converting, by the processing device, the minimum zone flow rate into a desired actuator position for a flow control valve to enable the flow control valve to provide the minimum zone flow rate of the coolant fluid to the zone of the cooling system. The method further includes enabling, by the processing device, the flow control valve to change from a current actuator position to the desired actuator position.

An engine is provided with a cylinder block and a pump cover cooperating to define a volute chamber for a coolant pump. An impeller is connected to a drive shaft and positioned within the volute chamber. An insert is positioned within the volute chamber directly adjacent to a cutwater along a portion of the outer wall, with the insert positioned between the cutwater and the impeller. A method is provided where, in response to pre-determining a first coolant pump displacement, a first impeller is positioned within a volute chamber defined by a block and a cover. In response to pre-determining a second coolant pump displacement being less than the first displacement, an insert is affixed along the wall adjacent to the cutwater and a second impeller is positioned within the chamber.