Driver tool

The invention claimed is: 1. A driving tool configured to drive an object by striking it, comprising: a motor, a cylinder having a cylinder chamber, a first piston slidably disposed within the cylinder chamber, the first piston having an elongated driving part connected to a sliding part and configured to strike the object, a compression device having a compression chamber, a second piston slidably disposed within the compression chamber, the second piston being configured to be driven by the motor and to generate compressed air by changing an internal volume of the compression chamber, a compressed air supply passage defining a compressed air communication path between the compression chamber and the cylinder chamber, a valve member, a crank mechanism configured to be driven by the motor to reciprocate the second piston within the compression chamber, and a rotatably-driven cam member connected to the crank mechanism, a relay member that mechanically connects the cam member with the valve member, and is configured to convert rotation of the cam member into linear motion and to transmit the linear motion to the valve member, wherein: the first piston is configured to be moved by the compressed air supplied from the compression chamber into the cylinder chamber from an initial position to strike the object, the valve member is configured to open and close the compressed air supply passage according to an amount of cam lift of the cam member, and the amount of cam lift of the cam member is set such that the compressed air supply passage is held open by the valve member until the first piston has struck the object and has returned to the initial position. 2. The driving tool as defined in claim 1 , wherein the amount of cam lift of the cam member is set such that the valve member opens the compressed air supply passage when the air in the compression chamber is maximally or substantially maximally compressed. 3. The driving tool as defined in claim 1 , wherein the cam member is constituted by a combination of a plurality of cam plates, and the amount of cam lift relative to the relay member is determined by the combination of the cam plates. 4. The driving tool as defined in claim 3 , wherein a position of at least one of the cam plates is adjustable, and an opening timing of the compressed air supply passage by the valve member is configured to be adjustable by adjusting the position of the at least one of the cam plates. 5. The driving tool as defined in claim 3 , further comprising: a plurality of cam followers respectively contacting the plurality of cam plates, wherein rotation of the cam plates is individually transmitted to the relay member via the respective cam followers. 6. The driving tool as defined in claim 1 , wherein: the cylinder and the compression device are each formed as a cylindrical cylinder having a longitudinal axis and an outer wall, the cylindrical cylinders are disposed in parallel to each other such that the longitudinal axes of the cylindrical cylinders extend in a first direction, and the relay member is arranged to extend in the first direction between the outer wall of the cylinder and the outer wall of the compression device. 7. A driving tool configured to drive an object by striking it, comprising: a motor, a cylinder having a cylinder chamber, a first piston slidably disposed within the cylinder chamber, the first piston having an elongated driving part connected to a sliding part and configured to strike the object, a compression device having a compression chamber, a second piston slidably disposed within the compression chamber, the second piston being configured to be driven by the motor and to generate compressed air by changing an internal volume of the compression chamber, a compressed air supply passage defining a compressed air communication path between the compression chamber and the cylinder chamber, a valve member, a relay member that mechanically connects the motor with the valve member and is configured to move the valve member when the motor is driven, a crank mechanism configured to be driven by the motor to reciprocate the second piston within the compression chamber, and a rotatably-driven cam member connected to the crank mechanism, wherein: the first piston is configured to be moved by the compressed air supplied from the compression chamber into the cylinder chamber from an initial position to strike the object, the crank mechanism has a crank shaft, the cam member is configured to be rotatably driven around the crank shaft, the relay member is configured to move in a direction crossing an axial direction of the crank shaft so as to convert the rotation of the cam member into linear motion and to transmit the linear motion to the valve member, and the valve member is configured to open and close the compressed air supply passage according to an amount of cam lift of the cam member by moving in the crossing direction. 8. The driving tool as defined in claim 7 , wherein the amount of cam lift of the cam member is set such that the valve member opens the compressed air supply passage when the air in the compression chamber is maximally or substantially maximally compressed. 9. The driving tool as defined in claim 7 , wherein the cam member is constituted by a combination of a plurality of cam plates, and the amount of cam lift relative to the relay member is determined by the combination of the cam plates. 10. The driving tool as defined in claim 9 , wherein a position of at least one of the cam plates is adjustable, and an opening timing of the compressed air supply passage by the valve member is configured to be adjustable by adjusting the position of the at least one of the cam plates. 11. The driving tool as defined in claim 9 , further comprising: a plurality of cam followers respectively contacting the plurality of cam plates, wherein rotation of the cam plates is individually transmitted to the relay member via the respective cam followers. 12. The driving tool as defined in claim 7 , wherein: the cylinder and the compression device are each formed as a cylindrical cylinder having a longitudinal axis and an outer wall, the cylindrical cylinders are disposed in parallel to each other such that the longitudinal axes of the cylindrical cylinders extend in a first direction, and the relay member is arranged to extend in the first direction between the outer wall of the cylinder and the outer wall of the compression device. 13. A driving tool configured to drive an object by striking it, comprising: a motor, a cylinder having a cylinder chamber, a first piston slidably disposed within the cylinder chamber, the first piston having an elongated driving part connected to a sliding part and configured to strike the object, a compression device having a compression chamber, a second piston slidably disposed within the compression chamber, the second piston being configured to be driven by the motor and to generate compressed air by changing an internal volume of the compression chamber, a compressed air supply passage defining a compressed air communication path between the compression chamber and the cylinder chamber, a valve member, a crank mechanism configured to be driven by the motor to reciprocate the second piston within the compression chamber, a rotatably-driven cam member connected to the crank mechanism, and a relay member that mechanically connects the cam member with the valve member, wherein: the first piston is configured to be moved by the compressed air supplied from the compression chamber into the cylinder chamb