A handle is coupled to an industrial machine tool, along with a method of operating the industrial machine tool via the handle. The handle comprises a housing, a first switch, and a second switch. The housing includes a first side, a second side, a top end, and a bottom end, the first side facing toward the industrial machine tool and the second side facing away from the industrial machine tool. The first switch actuates a float mode for the industrial machine tool, the float mode being a mode in which movement of a moveable portion of the industrial machine tool is power assisted for an operator of the industrial machine tool. The second switch actuates a machining portion, coupled to the moveable portion of the industrial machine tool, to perform a machining process on a workpiece.

A spindle apparatus according to the present disclosure includes a housing, a spindle rotatably installed in the housing, a tool releasably engaged with one end of the spindle and having an insert tip movable in a radial direction of the tool, a first draw-bar movably mounted in the spindle, and a second draw-bar movably mounted in the first draw-bar. The tool and one end of the first draw-bar are releasably engaged with the one end of the spindle by a movement of the first draw-bar, and the insert tip is configured to move in the radial direction by a movement of the second draw-bar.

A spindle apparatus according to the present disclosure includes a housing, a spindle rotatably installed in the housing, a tool releasably engaged with one end of the spindle and having an insert tip movable in a radial direction of the tool, a first draw-bar movably mounted in the spindle, and a second draw-bar movably mounted in the first draw-bar. The tool and one end of the first draw-bar are releasably engaged with the one end of the spindle by a movement of the first draw-bar, and the insert tip is configured to move in the radial direction by a movement of the second draw-bar.

A device for striking a tool shank with a controlled force includes a tip configured to contact the shank, a plunger configured to be retracted a pullback distance from the tip and to exert a force on the tip proportional to the pullback distance when released, and a control mechanism configured to control the pullback distance. A method of reducing run-out in a machine tool comprises placing the tool in a tool holder, measuring the run-out using an indicator, identifying a high spot, manipulating the control mechanism of the striking device to select the force based on the shank diameter, and striking the shank on the high spot using the striking device.

A device for striking a tool shank with a controlled force includes a tip configured to contact the shank, a plunger configured to be retracted a pullback distance from the tip and to exert a force on the tip proportional to the pullback distance when released, and a control mechanism configured to control the pullback distance. A method of reducing run-out in a machine tool comprises placing the tool in a tool holder, measuring the run-out using an indicator, identifying a high spot, manipulating the control mechanism of the striking device to select the force based on the shank diameter, and striking the shank on the high spot using the striking device.

An air bearing slide (20) arranged on a rotational table (11) includes a movable table (40) that has a workpiece placement surface (42a) and that floats due to pressure of compression air to be movable horizontally in any direction. A workpiece auto-centering apparatus includes: a plurality of stopper apparatuses (30) that include an abutment portion (31a) against which a workpiece W can abut to center the workpiece W, and a pressing apparatus that presses the workpiece (W) such that the workpiece (W) abuts against the abutment portion (31a) of the stopper apparatuses (30). Thus, the workpiece auto-centering apparatus and auto-centering method have a simple configuration and can perform a workpiece centering operation in short cycle time.

A base assembly for a power tool, such as a router, includes a base member, an adjustment mechanism, and a lock member. The base member is configured to accept a motor housing of the power tool. The adjustment mechanism is configured to adjust a position of the motor housing relative to the base member via rotation of a first contact portion of the adjustment mechanism. The lock member is moveable relative to the adjustment mechanism between a first position that prevents rotation of the adjustment mechanism and a second position that permits rotation of the adjustment mechanism. The lock member includes a second contact portion positioned proximate to the first contact portion and configured to be actuated to position the lock member in the second position. The position of the motor housing is adjusted by simultaneously actuating the first contact portion and the second contact portion.

A barrel cam device includes a barrel cam, an output table that includes a plurality of cam followers that engage with the barrel cam, and that rotates by rotation of the barrel cam, and a clamp device that clamps the output table when the output table is stopping.

A barrel cam device includes a barrel cam, an output table that includes a plurality of cam followers that engage with the barrel cam, and that rotates by rotation of the barrel cam, and a clamp device that clamps the output table when the output table is stopping.

A work method for a Cartesian machine tool includes the following steps

starting machining of a workpiece;

carrying out a machining cycle; and

carrying out a qualification operation, i.e., an operation to check a relative positioning system, on board the machine tool, by way of comparison with a positioning system with absolute reference for calibration, which is adapted to check the displacement of the indications of the positioning systems on board the machine, i.e., of the relative reference system, with respect to the positions of an absolute reference system for calibration. The method further includes the steps of

checking the outcome of the qualification operation,

If the qualification operation is passed successfully, then proceed with an operation to measure the workpiece prior to finishing.

If the qualification is not passed, then proceed with a compensation step, which includes one or more compensation operations.