A control method of a coolant control valve unit that rotates a cam using torque of a motor and allowing a profile formed on the cam to push a rod to allow the valve formed on the rod to open/close a coolant passage, including steps of: rotating the cam by operating the motor; detecting a rotation position of the cam; determining a stuck state in which the cam or the motor is not rotated while the motor is operated; and performing an escape mode in which if it is determined that the cam or the motor is in the stuck state, the motor outputs a predetermined torque to the cam side in a predetermined rotation direction to escape the cam from the stuck state.

A control system for a coolant control valve unit, which includes a cam and a valve that opens and closes a coolant passage in conjunction with rotation of the cam, includes: a motor controlling the rotation of the cam; and a controller configured to correct a target valve opening degree of the valve using a correction value according to a degree of wear of the valve, to determine a target rotational angle of the cam using the target valve opening degree corrected by the correction value, and to control an operation of the motor according to the target rotational angle of the cam.

The present invention discloses a water discharge structure having a reset function which includes a body internally provided with a water flowing channel, a water outflow end of the body is provided with a first water outflow channel and a second water outflow channel; a button arranged on the body, and a reset spring arranged between the button and the body; a movable element coupled with and fitting the button; and a center shaft coupled with and fitting the movable element, an end of the center shaft is provided with a blocking element, a third spring is provided between an end of the center shaft and the body, and the body is internally provided with a reset device to drive the movable element to reset. A pull-out head includes the above-mentioned water discharge structure having a reset function, and the present invention has the function of memory.

An evaporative emissions control system includes a first vent valve configured to selectively open and close a first vent, a second vent valve configured to selectively open and close a second vent, a fuel level sensor configured to sense a fuel level in the fuel tank, a pressure sensor configured to sense a pressure in the fuel tank, an accelerometer configured to measure an acceleration of the vehicle, and a controller configured to regulate operation of the first and second vent valves to provide pressure relief for the fuel tank. The controller is programmed to determine if a refueling event is occurring based one signals indicating the fuel level is increasing, the pressure in the fuel tank is increasing, and the vehicle is not moving, and open at least one of the first and second vent valves based on determining the refueling event is occurring.

A scenting device for scenting a vehicle interior may include at least one aromatic substance container holding a supply of an aromatic substance. The device may also include a feeding duct for feeding air to the at least one aromatic substance container and a discharge duct for discharging air enriched with the aromatic substance. The device may further include at least one scenting path for enriching air with the aromatic substance from the at least one aromatic substance container. The device may include a bypass duct branching off from the feeding duct and bypassing the at least one aromatic substance container. The device may also include a bypass valve and at least one container valve. The device may include a camshaft including a bypass cam configured to actuate the bypass valve and at least one container cam configured to actuate the at least one container valve.

The integrated flow control valve according to the present disclosure is a cam-lift type integrated flow control valve, and an additional valve is integrally formed with at least one of a plurality of valves, this additional valve is configured to be moved upward and downward in response to vertical movement of the corresponding valve to open and close an additional outlet except for a plurality of outlets which are opened and closed by the plurality of valves. In an engine system according to the present disclosure, a flow of coolant flowing into a heater, an oil cooler, a radiator and an exhaust gas heat exchanger in the engine system is integratedly controlled through control of the above described integrated control valve, so that it is possible to effectively control a flow rate of coolant as well as a temperature of coolant.

In one embodiment, a thermal management module is disclosed that includes: a housing defining a plurality of ports and at least one camshaft opening, the housing defining at least one chamber; a camshaft extending through the at least one camshaft opening into the chamber, the camshaft including a plurality of cams; a plurality of seal assemblies each surrounding a respective port of the plurality of ports; and a plurality of stoppers each arranged with a respective port of the plurality of ports. In one aspect, at least one port of the plurality of ports includes a guidance finger adapted to guide a respective stopper of the plurality of stoppers. In another aspect, openings defined by at least two ports of the plurality of ports overlap in an axial direction of the openings.

A coolant control valve unit includes: a housing in which a coolant passage is formed; an elastic member supporting the valve unit elastically so that the coolant passage is closed by the valve unit; a holder supporting the elastic member; and a fixing portion that fixes the holder to the housing.

A control system for a coolant control valve unit, which includes a cam and a valve that opens and closes a coolant passage in conjunction with rotation of the cam, includes: a motor controlling the rotation of the cam; and a controller configured to correct a target valve opening degree of the valve using a correction value according to a degree of wear of the valve, to determine a target rotational angle of the cam using the target valve opening degree corrected by the correction value, and to control an operation of the motor according to the target rotational angle of the cam.

A multi-button waterway switching mechanism includes a fixed portion provided with a waterway switching unit and a driving mechanism. The waterway switching unit includes two valve cores that can move relative to the fixed portion, and the driving mechanism is provided with three buttons spaced side by side and parallel to the sliding direction of the fixed portion, the three buttons are divided into two first button and a second button, the two first button respectively drivingly connected to the two valve cores, the driving mechanism further comprises a transmission member, the second button drivingly connects the transmission member, and the transmission member drivingly connected to the two valve cores.