A powered fastener driver includes a cylinder and a piston positioned within the cylinder. The piston is moveable between a top-dead-center position and a bottom-dead-center position. The piston has a non-circular shape.

A pneumatic tool includes a drive mechanism configured to drive by an air pressure of compressed air, a head valve having a first chamber configured to reserve compressed air that is supplied from an air source, and configured to drive the drive mechanism, according to a state of the compressed air in the first chamber, a trigger valve configured to actuate the head valve by exhausting the compressed air in the first chamber, and a control valve configured to disable actuation of the trigger valve.

A switch device for a nail gun includes a body having a main chamber and a cylinder is received in the main chamber. A main path communicates with the cylinder. A recess is formed in the body and a valve is received in the recess. An end member is connected to the rear end of the body. An air way communicates between the recess and the end member. A first release path communicates the recess and outside of the body. A communication path communicates between the main chamber and the recess. A switch member is located at the communication path. By operating the switch member, the features of single mode and automatic mode of the nail gun is controlled.

A pneumatic fastener driving tool that forces pressurized gas from a gas supply source into a chamber above a piston enclosed in a working cylinder. During an operational cycle, the pressurized gas is released, forcing the piston to fire. The firing valve seals the pressurized gas utilizing two rolling diaphragm seals, thereby providing less breakdown of hardware and removing the need for lubricant within the firing valve. These diaphragm seals exhibit a smaller diameter than prior diaphragms used in similar pneumatic fastener driving tools.

The invention relates to a pneumatic expulsion device (10) for expelling objects (14) or fluid substances from a reservoir by means of a drive piston (18) which is subjectable to a gas volume compressible in a compression chamber (23), the drive piston (18) being provided with a drive mechanism for compressing the gas volume and with a trigger for expanding the compressed gas volume. The compression chamber (23) is provided with a relief mechanism for temporarily venting the compression chamber (23) and with a filling mechanism (41) for filling the vented compression chamber (23) with compressed air.

A fastener driver includes a housing having a handle portion. A motor is positioned within the housing. The fastener driver further includes an air compressor including a compressor cylinder and a compressor piston movable within the compressor cylinder in a reciprocating manner to compress air within the compressor cylinder. The fastener driver further includes a drive train converting torque from the motor to a linear force applied to the compressor piston, causing the compressor piston to move in the reciprocating manner. At least a portion of the drive train extends through the handle portion of the housing.

A switch device for a nail gun includes a body having a main chamber and a cylinder is received in the main chamber. A main path communicates with the cylinder. A recess is formed in the body and a valve is received in the recess. An end member is connected to the rear end of the body. An air way communicates between the recess and the end member. A first release path communicates the recess and outside of the body. A communication path communicates between the main chamber and the recess. A switch member is located at the communication path. By operating the switch member, the features of single mode and automatic mode of the nail gun is controlled.

A driving tool drives a fastener by a striking mechanism which is operated by a fluid. The driving tool includes a trigger, a contact arm, a contact lever and a regulator. The trigger and the contact arm receive manipulations and the contact lever switches operating states of the striking mechanism according to operations of the trigger and the contact arm. The regulator switches operating states of the contact lever according to the contact arm. The regulator includes a regulation member and a controller. The regulation member regulates the contact lever at an operation standby position where the contact lever is operated by the contact arm. The controller operates the regulation member and includes first and second cylinders. The first cylinder operates the regulation member. The second cylinder to which a fluid operating the striking mechanism is partially supplied and generates a driving force for driving the first cylinder.

A driving tool drives a fastener supplied to a nose using a striking mechanism. The driving tool includes a trigger, a contact arm, a contact lever and a regulator. The trigger receives a manipulation which operates the striking mechanism. The contact arm reciprocates and receives another manipulation which operates the striking mechanism. The contact lever operates according to operations of the trigger and the contact arm and switches operating states of the striking mechanism. The regulator regulates a movement of the contact lever in a range from an operable position where the striking mechanism is operable by the contact lever to an operation standby position where the contact lever is operable by the contact arm, according to a reciprocating movement of the contact arm, and switches operating states of the contact lever according to the contact arm.

A compressed air nailer comprises a control line configured to trigger a driving process when a valve pin is displaced relative to a valve sleeve into an actuated position. The valve sleeve is configured to move between a triggering position and a locked position. A switching surface is coupled to at least one of a trigger and a placing sensor and configured to actuate the valve pin. An outer sleeve is configured to guide the valve sleeve. The switching surface is positioned at a switching surface position relative to the outer sleeve when both the trigger and the placing sensor are actuated. The switching surface is configured to displace the valve pin into the actuated position when the valve sleeve is positioned in the triggering position. The switching surface does not displace the valve pin into the actuated position when the valve sleeve is positioned in the locked position.