A CNC milling machine includes a chassis unit having vertical seats. A machining unit includes a frontward-rearward movable machining seat located on the vertical seats, a leftward-rightward movable machining seat in front of the frontward-rearward movable machining seat, an upward-downward movable machining seat in front of the leftward-rightward movable machining seat, and a machining tool set at a bottom of the upward-downward movable machining seat. A picking robotic arm unit includes a frontward-rearward movable picking seat located on the vertical seats and in front of the frontward-rearward movable machining seat, a leftward-rightward movable picking seat above the frontward-rearward movable picking seat, an upward-downward movable picking seat adjacent to the leftward-rightward movable picking seat, and a claw set at a bottom of the upward-downward movable picking seat. Coupling achieved with a coupling unit allows the picking robotic arm unit to be driven to move by the machining unit.

A CNC milling machine includes a chassis unit having vertical seats. A machining unit includes a frontward-rearward movable machining seat located on the vertical seats, a leftward-rightward movable machining seat in front of the frontward-rearward movable machining seat, an upward-downward movable machining seat in front of the leftward-rightward movable machining seat, and a machining tool set at a bottom of the upward-downward movable machining seat. A picking robotic arm unit includes a frontward-rearward movable picking seat located on the vertical seats and in front of the frontward-rearward movable machining seat, a leftward-rightward movable picking seat above the frontward-rearward movable picking seat, an upward-downward movable picking seat adjacent to the leftward-rightward movable picking seat, and a claw set at a bottom of the upward-downward movable picking seat. Coupling achieved with a coupling unit allows the picking robotic arm unit to be driven to move by the machining unit.

A folding device for a milling machine includes a base having a workbench formed on top thereof, and two support parts are respectively located on two sides of the workbench so as to be connected to two support boards respectively. A pivot and a fixing bolt extend through the contact face and are fixed to the support part. A driving unit includes a transverse rail and a transverse shaft respectively connected between the two support boards. A slide is slidably connected with the transverse rail and the transverse shaft. A milling machine is connected to the slide which is movable between the two support boards. When the fixing bolts are removed, the milling machine is foldable toward the workbench about the two respective pivots to save transportation space and storage space required.

A levelling machine includes a pair of spaced apart rail assemblies, a gantry assembly and a face mill assembly. The spaced apart rail assemblies define an x axis. The gantry assembly is moveably attached to the pair of spaced apart rail assemblies whereby the gantry assembly defines a y axis. The gantry assembly is moveable in the x axis along the pair of spaced apart rail assemblies. The face mill assembly is moveably attached to the gantry assembly and is moveable in the y axis along the gantry assembly. The face mill assembly has a plurality of saw blades, the saw blades being generally in an x-y plane defined by the x axis and y axis. The saw blades have a plurality of teeth that extend downwardly generally in a z axis. The face mill assembly is moveable in the z axis.

A machine tool is provided with a vertically aligned tool spindle, which is equipped for accommodating tools and which is movable in a vertical direction and in a first horizontal direction. The machine tool further comprises at least one jig for clamping workpieces to be machined. The at least one jig is movable in a second horizontal direction. The tool spindle and the at least one jig are arranged on a common machine frame. There is also provided a workpiece transport device, which is arranged on the machine frame, and which is adapted to perform at least one of introducing unmachined workpieces into the at least one jig and removing machined workpieces from the at least one jig. There is also provided a corresponding method of machining workpieces.

An all-directional profiling machine has a foundation. A profiling device is disposed on the foundation. The profiling device swings leftward and rightward at the same height relative to the foundation. An upright post is disposed at one end of the profiling device and has a terminal portion extending upward. A workbench is pivotally connected to the terminal portion of the upright post. The workbench tilts vertically and swings horizontally relative to the upright post. Therefore, the all-directional profiling machine performs a multi-angle profiling cutting process without demounting a workpiece repeatedly such that the processing of oblique surfaces is quicker, simpler and more precise, so as to not only meet various requirements of different processing angles but also feature enhanced processing efficiency.

A cutting machine is provided, including: a cutting table having a first end and a second end aligned along an X-axis; a cutting tool gantry configured to cut parts from plate supported on the cutting table, the cutting tool gantry spanning the cutting table in a Y-axis perpendicular to the X-axis and being configured to travel along the X-axis between the first end and the second end; and a part transfer apparatus configured to remove cut parts from the cutting table, the part transfer apparatus being configured to travel along the X-axis between the first end and the second end, wherein the part transfer apparatus is able to pass underneath the cutting tool gantry while travelling along the X-axis. Methods of manufacturing and storing parts are also provided, along with a method of identifying when a part is in contact with a finishing apparatus.

A machine for the working of sheet materials is described, which includes a support frame, a supporting head, a working means with rotary tools and a waterjet cutting tool. The machine is provided with fast-couplers that include first and second male fast-couplers respectively disposed on the working means with rotary tools and on the waterjet cutting tool, and first and second female fast-couplers disposed in the supporting head. The female fast-couplers are configured in such a way to permit the alternative coupling with the first male fast-coupler or with the second male fast-coupler.

A water jets cutting machine includes a first rotating seat driven by a first motor to rotate about a first rotation axis, a second rotating seat driven by a second motor to rotate about a second axis, a water jets cutting head, an inertial measurement unit (IMU) for detecting an inclination angle of the water jets cutting head, and a controller connecting the first and second motors and the IMU. The controller is able to control the first and second motors to instantaneously conduct compensation for angular deviation of the water jets cutting head according to attitude and position signals which are fed back to the controller by the IMU.

A machining center configured for machining workpieces includes at least one column, a beam, at least one slider, a first driving member, a second driving member, a first main shaft and a second main shaft. The column can be configured for supporting the beam. The slider can be disposed on the beam and slidable along a length direction of the beam. Both the first main shaft and the second main shaft can be arranged on the slider and located on two opposite sides of the beam. The first driving member can be configured for driving the slider to slide relative to the beam. The second driving member can be configured for driving the first main shaft and the second main shaft to operate. The first main shaft and the second main shaft can be configured for synchronously or asynchronously machining the workpieces.