An air vent dial for an automobile includes an air vent housing having an air path and a damper for opening or closing the air path; a dial housing provided in the air vent housing and having an opening and holding projections; and a dial assembly having a dial knob to be fitted into the opening and a rear fixing plate connected to the damper through a link member to control the opening and closing degrees of the damper. The dial housing has the holding projections at positions corresponding to opening and closing positions of the damper. The dial assembly has a dial elongated hole and fixing projection projecting inwards and contacting the holding projections while being guided and moving along the rear outer peripheral surface of the dial housing at outside of the rear fixing plate having the dial elongated hole.

An air vent dial for an automobile includes an air vent housing having an air path and a damper for opening or closing the air path; a dial housing provided in the air vent housing and having an opening and holding projections; and a dial assembly having a dial knob to be fitted into the opening and a rear fixing plate connected to the damper through a link member to control the opening and closing degrees of the damper. The dial housing has the holding projections at positions corresponding to opening and closing positions of the damper. The dial assembly has a dial elongated hole and fixing projection projecting inwards and contacting the holding projections while being guided and moving along the rear outer peripheral surface of the dial housing at outside of the rear fixing plate having the dial elongated hole.

A valve device includes: an opening and closing section capable of being switched between an open state and a closed state, and a drive section having a rectilinearly moving mechanism configured to move a rectilinearly movable member in forward and backward directions; a transmission section configured to bring the opening and closing section to the closed state when the rectilinearly movable member is moved forward and to bring the opening and closing section to the open state when the rectilinearly movable member is moved backward; and a switching section capable of being switched between a connected state in which the movement of the rectilinearly movable member in the forward and backward directions is able to be transmitted to the transmission section and a disconnected state in which the movement of the rectilinearly movable member in the forward and backward directions is unable to be transmitted to the transmission section.

A valve device includes: an opening and closing section capable of being switched between an open state and a closed state, and a drive section having a rectilinearly moving mechanism configured to move a rectilinearly movable member in forward and backward directions; a transmission section configured to bring the opening and closing section to the closed state when the rectilinearly movable member is moved forward and to bring the opening and closing section to the open state when the rectilinearly movable member is moved backward; and a switching section capable of being switched between a connected state in which the movement of the rectilinearly movable member in the forward and backward directions is able to be transmitted to the transmission section and a disconnected state in which the movement of the rectilinearly movable member in the forward and backward directions is unable to be transmitted to the transmission section.

A number of variations may include a product comprising: a linkage system comprising: a first and second lever; a first interconnecting component and second interconnecting component operably connected to the first and second levers; a link bar having a first end with a first opening for receiving the first or second interconnecting component, and providing a clearance between the first opening and the first or second interconnecting component and; a second end with a second opening for receiving the first or second interconnecting component and providing a clearance between the second opening and the first or second interconnecting component; and a biasing device having a first and second end for engagement with the first and second interconnecting components and at least one section to allow for increasing or decreasing its length, wherein when the first or second end of the biasing device is engaged with one of the first or second interconnecting component and an external force is applied to one of the first or second ends of the biasing device to cause the biasing device to either increase or decrease in length to allow engagement with one of the first or second interconnecting component and to store energy, and wherein when the external force is removed from the biasing device, the stored energy of the biasing device provide a force that causes the first and second interconnecting components to move in a direction that overcomes the clearances between the first and second interconnecting components and the first and second openings of the link bar and provides contact between the first and second interconnecting components and the first and second openings of the link bar and wherein the contact is maintained by the force provided by the stored energy.

A number of variations may include a product comprising: a linkage system comprising: a first and second lever; a first interconnecting component and second interconnecting component operably connected to the first and second levers; a link bar having a first end with a first opening for receiving the first or second interconnecting component, and providing a clearance between the first opening and the first or second interconnecting component and; a second end with a second opening for receiving the first or second interconnecting component and providing a clearance between the second opening and the first or second interconnecting component; and a biasing device having a first and second end for engagement with the first and second interconnecting components and at least one section to allow for increasing or decreasing its length, wherein when the first or second end of the biasing device is engaged with one of the first or second interconnecting component and an external force is applied to one of the first or second ends of the biasing device to cause the biasing device to either increase or decrease in length to allow engagement with one of the first or second interconnecting component and to store energy, and wherein when the external force is removed from the biasing device, the stored energy of the biasing device provide a force that causes the first and second interconnecting components to move in a direction that overcomes the clearances between the first and second interconnecting components and the first and second openings of the link bar and provides contact between the first and second interconnecting components and the first and second openings of the link bar and wherein the contact is maintained by the force provided by the stored energy.

A remotely operated hydraulic system is configured to engage an unloader in a semi-trailer. The remotely operated hydraulic system includes a solenoid mechanically coupled to the semi-trailer. The solenoid is further mechanically coupled to at least one air input line and at least one air output line. A receiver is electrically coupled to the solenoid and communicatively coupled to a remote control. The receiver is configured to open and close the solenoid based on a signal from the remote control. An air cylinder is mechanically coupled to the at least one air output line and a manual valve. Receiving air into the air cylinder operates to open the manual valve. A motor is mechanically coupled to the air cylinder and the unloader; wherein hydraulic pressure from the manual valve is configured to turn the motor and thus the unloader.

A remotely operated hydraulic system is configured to engage an unloader in a semi-trailer. The remotely operated hydraulic system includes a solenoid mechanically coupled to the semi-trailer. The solenoid is further mechanically coupled to at least one air input line and at least one air output line. A receiver is electrically coupled to the solenoid and communicatively coupled to a remote control. The receiver is configured to open and close the solenoid based on a signal from the remote control. An air cylinder is mechanically coupled to the at least one air output line and a manual valve. Receiving air into the air cylinder operates to open the manual valve. A motor is mechanically coupled to the air cylinder and the unloader; wherein hydraulic pressure from the manual valve is configured to turn the motor and thus the unloader.

A tub spout assembly is configured to be supported within the overflow opening in the sidewall of a bathtub. The tub spout assembly illustratively includes an overflow body defining an overflow passageway, and an inlet tube supported by the overflow body and defining an inlet passageway. A spout is fluidly coupled to the inlet tube and defines a spout outlet to dispense water from the inlet tube into the bathtub. A spout cover illustratively receives the spout and includes an inner wall defining at least one opening. The at least one opening is illustratively in fluid communication with the overflow passageway and the inlet passageway. Illustratively, a diverter assembly is supported by the spout and is configured to selectively open and close fluid communication between the inlet passageway to the spout outlet.

A tub spout assembly is configured to be supported within the overflow opening in the sidewall of a bathtub. The tub spout assembly illustratively includes an overflow body defining an overflow passageway, and an inlet tube supported by the overflow body and defining an inlet passageway. A spout is fluidly coupled to the inlet tube and defines a spout outlet to dispense water from the inlet tube into the bathtub. A spout cover illustratively receives the spout and includes an inner wall defining at least one opening. The at least one opening is illustratively in fluid communication with the overflow passageway and the inlet passageway. Illustratively, a diverter assembly is supported by the spout and is configured to selectively open and close fluid communication between the inlet passageway to the spout outlet.