A positioning system includes a centrally mounted robot within a work area. Workpiece holders are independently moveable relative to the robot between working positions on opposite sides of the robot and a shared loading and unloading position. The system permits the robot to continuously operate without a need to wait for movement between the loading position and the working position. Furthermore, the system can be used as a single workpiece system while maintenance or hardware change is being performed on one of the workpiece holders. The workpiece holders move between the work positions and the loading and unloading position in a rotation and sliding fashion.

A positioning system includes a centrally mounted robot within a work area. Workpiece holders are independently moveable relative to the robot between working positions on opposite sides of the robot and a shared loading and unloading position. The system permits the robot to continuously operate without a need to wait for movement between the loading position and the working position. Furthermore, the system can be used as a single workpiece system while maintenance or hardware change is being performed on one of the workpiece holders. The workpiece holders move between the work positions and the loading and unloading position in a rotation and sliding fashion.

According to the present invention, the operating rate of a machine tool can be increased. Solution is made by a machine tool including a processing chamber surrounded by cover walls to perform processing of a workpiece to be processed, an equerre a part of which is arranged inside the processing chamber, the equerre fixing the workpiece, an opening arranged at a part of the cover walls for access to an inside of the processing chamber, and shutter doors movable between open positions where opening of the opening is performed so that the inside of the processing chamber communicates with an outside of the processing chamber, and closed positions where closing of the opening is performed so that the inside of the processing chamber is isolated from the outside of the processing chamber.

A flay assembly for separating a workpiece from a manufacturing fixture has a horizontal beam assembly and a pair of vertical beam assemblies. The horizontal beam assembly includes a horizontal beam having a horizontal drive motor. Each vertical beam assembly includes a vertical beam operably engaged to the horizontal drive motor and has a workpiece attachment assembly operably engaged to a vertical drive motor. The workpiece attachment assembly has an attachment mechanism attachable to the workpiece. The horizontal drive motor and the vertical drive motors are operable in a manner to move the vertical beams away from each other along a horizontal drive axis while simultaneously moving each workpiece attachment assembly along a vertical drive axis to cause the attachment mechanisms to pull the workpiece side portions away from the manufacturing fixture while a center support of the horizontal beam maintains a workpiece crown in contact with the manufacturing fixture.

A flay assembly for separating a workpiece from a manufacturing fixture has a horizontal beam assembly and a pair of vertical beam assemblies. The horizontal beam assembly includes a horizontal beam having a horizontal drive motor. Each vertical beam assembly includes a vertical beam operably engaged to the horizontal drive motor and has a workpiece attachment assembly operably engaged to a vertical drive motor. The workpiece attachment assembly has an attachment mechanism attachable to the workpiece. The horizontal drive motor and the vertical drive motors are operable in a manner to move the vertical beams away from each other along a horizontal drive axis while simultaneously moving each workpiece attachment assembly along a vertical drive axis to cause the attachment mechanisms to pull the workpiece side portions away from the manufacturing fixture while a center support of the horizontal beam maintains a workpiece crown in contact with the manufacturing fixture.

A remote jig control system may comprise a jig configured to place a car body to a particular position, a wireless magnetic sensor installed in the jig, a control panel wirelessly connected with the wireless magnetic sensor via first wireless communication to receive state information about the jig from the wireless magnetic sensor, a gateway connected with the control panel via the first wireless communication to receive the state information, a user terminal connected with the gateway via second wireless communication to receive the state information; and monitoring server configured to receive the state information from the gateway and store the state information, wherein the control panel is configured to be controlled through the user terminal to generate a jig control signal corresponding to the state information.

A remote jig control system may comprise a jig configured to place a car body to a particular position, a wireless magnetic sensor installed in the jig, a control panel wirelessly connected with the wireless magnetic sensor via first wireless communication to receive state information about the jig from the wireless magnetic sensor, a gateway connected with the control panel via the first wireless communication to receive the state information, a user terminal connected with the gateway via second wireless communication to receive the state information; and monitoring server configured to receive the state information from the gateway and store the state information, wherein the control panel is configured to be controlled through the user terminal to generate a jig control signal corresponding to the state information.

A machining center includes a machine bed, a work table unit, a sliding unit, a first driving unit, a conveying member, a second driving unit and a loading seat. The machine bed has a machining zone and a transferring zone. The first driving unit is operable for driving the conveying member to move along a conveying axis which extends in a first direction, thereby driving the loading seat to move along first adjusting axes which extend in the first direction between the transferring and machining zones. The second driving unit is operable for driving the loading seat to move along second adjusting axes which extend in a second direction, which is perpendicular to the first direction and which is substantially vertical.

A machining center includes a machine bed, a work table unit, a sliding unit, a first driving unit, a conveying member, a second driving unit and a loading seat. The machine bed has a machining zone and a transferring zone. The first driving unit is operable for driving the conveying member to move along a conveying axis which extends in a first direction, thereby driving the loading seat to move along first adjusting axes which extend in the first direction between the transferring and machining zones. The second driving unit is operable for driving the loading seat to move along second adjusting axes which extend in a second direction, which is perpendicular to the first direction and which is substantially vertical.

An invertible part loading system includes a pallet adapted for holding articles for machining, a frame adapted for receiving the pallet, and latching mechanisms adapted for holding the pallet within the frame. A support structure is adapted to support the frame above a machining tool. An axle rotatably couples the frame with the support structure for allowing the pallet to be inverted, enabling the articles to face the machining tool from above, which allows chips of material to fall away from the articles. The axle rotates about a pivot axis aligned centrally through the frame. The pallet is adapted for rapid transfer on and off the part loading system via a compatible loading and storage assembly to reduce machining down time between swapping pallets. A two-sided pallet may be adapted to enable switching between parts, or between two sides of the same part, by inverting the pallet via the axle.