There is provided a robot for machine tool which can work with a large power and torque when necessary while not attaching a large-size motor to the robot and while having a thin arm, as well as a machine tool having the robot. An in-machine robot of a machine tool includes an input shaft, a transfer shaft, a bevel gear, and an end effector. The input shaft is connected to a tool of the machine tool, and a driving force of the tool is transferred to the end effector. The end effector is a hand or the like, and a workpiece is gripped or rotated with the hand using the driving force of the tool. A plurality of the input shafts are provided, and a suitable input shaft is connected to the tool as appropriate.

A vehicle wheel positioning device, including a frame, a jacking cylinder and two sliding sleeves fixed on a bottom plate, the outputting end of the jacking cylinder is connected with a top plate, and a belt pulley connected to a servo motor via a shaft. A vehicle wheel may be positioned via the top plate during a vehicle wheel finish turning automation processing, without switching programs for automation production of the wheel with different wheel widths and different offset distances.

A high-precision two-part flat chuck device includes: a base, a cylinder, a sliding plate, a first clamping plate and a second clamping pate. A piston rod of the cylinder is connected with the sliding plate. Precision sliding rails are arranged at two sides of the base, and two sides of the sliding plate are respectively matched with the precision sliding rails in a sliding manner. An accommodating groove is arranged in a middle part of the sliding plate. The first and second clamping plates are symmetrically distributed in the accommodating groove along a center of the sliding plate, and a spring is arranged between the first and second clamping plates. Side surfaces of the first and second clamping plates are inclined planes, and chucks matched with each other are arranged at end parts of the first and seconding clamp plates.

In a transport system, a gripper includes long-side grippers aligned in a long-side direction of a workpiece which is cut, by machining/cutting, into a product and a skeleton including an outer frame with an overall rectangular shape and a crossbar inside the outer frame, so that both ends thereof are connected to two shorter sides facing each other, and extending in the long-side direction, the long-side grippers gripping longer sides of the outer frame of the skeleton, and short-side grippers aligned in a short-side direction with respect to the workpiece and that grip shorter sides of the outer frame. At least one of the short-side grippers moves in the short-side direction and grips the shorter sides of the outer frame. A lifter lifts or lowers the gripper gripping the outer frame and the product to separate the outer frame and the crossbar from the product.

A system and method for using a robotic arm and a part gripping jaw to tend a CNC machine. A robotic arm picks up a part gripping jaw and used the jaw to grip a part, and moves the part into a vise in the CAN machine. The part gripping jaw has features which the vise engages, and secures the part in the part gripping jaw for processing in the CNC machine. The system and method includes a novel racking system, robotic end of arm tool, jaw grippers and vise system. The jaw grippers that hold the part are moved from the rack system, with the part to be processed, by the robot, to the vise where the vise uses the jaw grippers to secure the part for processing. After the part is processed, the robot removes the part from the vise with the jaw grippers and stores the part back into the rack system using the jaw grippers.

A muntin bar fabrication system can be used to efficiency produce a wide variety of different types of muntin bars, allowing the fabrication of both standard and custom muntin bar assemblies for doors, windows, and other fenestration products. In some examples, the fabrication system includes a muntin bar stock storage assembly that holds multiple different types of muntin bar stock. The system also includes a muntin bar stock extraction device that extracts one of the different types of muntin bar stock from the storage assembly and conveys the extracted muntin bar stock to a feed device. The feed device feeds the extracted piece of muntin bar stock into a cutting system that includes a multi-axis cutter. The cutting system that performs one or more cutting operations on the extracted muntin bar stock so as to fabricate one or more individual muntin bars from the extracted muntin bar stock.

A system and method for using a robotic arm and a part gripping jaw to tend a CNC machine. A robotic arm picks up a part gripping jaw and used the jaw to grip a part, and moves the part into a vise in the CAN machine. The part gripping jaw has features which the vise engages, and secures the part in the part gripping jaw for processing in the CNC machine. The system and method includes a novel racking system, robotic end of arm tool, jaw grippers and vise system. The jaw grippers that hold the part are moved from the rack system, with the part to be processed, by the robot, to the vise where the vise uses the jaw grippers to secure the part for processing. After the part is processed, the robot removes the part from the vise with the jaw grippers and stores the part back into the rack system using the jaw grippers.

The invention relates to tool tongs for the releasable holding of a tool, for example in a machine tool. The invention is characterized in that the tool tongs are formed by a tongs basic element and a tongs clamping element interacting and connected with the tongs basic element, wherein in the tool holding position the tongs basic element and the tongs clamping element hold the tool clampingly at its gripping elements, wherein the tongs basic element and/or the tongs clamping element is/are formed of flat material or plate-like material, such as, for example, steel sheet or the like.

A device for loading and unloading a machine tool for machining gears, in particular a hard fine machining machine, with a workpiece includes: a base, a carrier arranged on the base and which is rotatable with respect to the base about a first axis of rotation, a gripping device arranged on the carrier for gripping and releasing the workpiece, wherein the gripping device has at least two gripper arms which are each pivotable independently of one another about a second axis of rotation, and the gripper arms are pivotable relative to one another about the second axis of rotation in such a way that the gripper arms can assume relative to one another a gripping position for gripping the workpiece and a release position for releasing the workpiece, and the gripper arms are pivotable about the second axis of rotation synchronously with one another at least in the gripping position.

The invention relates to a method for loading and unloading an internally toothed workpiece or a workpiece that is to be provided with internal toothing into/out of a clamping position, in which the workpiece, which is held by a retaining device, is brought into the clamping position by means of a conveying movement so that said workpiece, when clamped, has internal toothing cut by a gear cutting tool that occupies a cutting chamber and, after cutting, said workpiece, which is held by the retaining device, is returned from the clamping position in a return movement, wherein, prior to cutting, the retaining device is permitted to carry out an evasive movement that is different from the return movement/reverse conveying movement and that frees the cutting chamber, or the cutting chamber is already kept free of the retaining device as soon as the clamping position is reached.