A device for simultaneously measuring and adjusting the tool holding portion of a spindle. The device has a body defining a datum surface providing a magnetic portion and an indicator portion. A socket extends from the magnetic portion, the socket dimensioned and adapted to receive and seat a first component of the tool holding portion on the magnetic portion. A compressible indicator tip extends in an outward-biased manner from the indicator portion, wherein a distance from the distal end of the indicator tip and the indicator portion of the datum surface is displayed along the body.

A device for simultaneously measuring and adjusting the tool holding portion of a spindle. The device has a body defining a datum surface providing a magnetic portion and an indicator portion. A socket extends from the magnetic portion, the socket dimensioned and adapted to receive and seat a first component of the tool holding portion on the magnetic portion. A compressible indicator tip extends in an outward-biased manner from the indicator portion, wherein a distance from the distal end of the indicator tip and the indicator portion of the datum surface is displayed along the body.

Grinding, lapping and polishing basically work by making scratches in the body being ground, lapped or polished. The scratches typically are linear. The scratches gives rise to a directionality component of friction: the friction coefficient is less in the direction along the scratch than in a direction orthogonal, or across, the scratch. In a wafer handling/chucking situation, one wants the wafer to settle on the chuck, which involves the outer regions of the wafer moving radially with respect to the chuck. One can reduce friction in the radial direction by giving the lapping scratches a preferred orientation, namely, radial. This can be achieved by making the final passes of the lapping tool move predominantly in radial directions.

A replaceable tool holder includes a connector adapted to be engaged with and driven to rotate by a spindle, a tool chuck, of which an end is detachably engaged with the connector and another end is adapted to engage a tool, and an electronic component provided in a chamber inside the tool chuck. The connector is provided with a non-contact power transmission device. A passage is provided in the connector and the tool chuck, wherein a wire is disposed in the passage, transmitting electric power to serve the need of the electronic component. With such design, one connector can be used to connect tool chucks of different types or models. Therefore, a user could, as required, replace the connecting interface between the tool holder and the spindle or the connecting interface between the tool holder and the tool. Furthermore, the electronic component could be steadily supplied with electric power.

A device for clamping a workpiece has a receiving head in a housing connected to a rotary drive with a rigid drive connection between a drive motor and the receiving head, radially adjustable clamping jaws connected to a clamping drive externally clamping the workpiece, and linear drives displacing the clamping jaws and forming the clamping drive driven jointly by a gear transmission with a central gear coaxial to the drive shaft of the receiving head by a separate drive motor. The central gear can be driven synchronously with the receiving head in the clamping position of the clamping jaws, and the rotary drive for the central gear comprises a rigid drive connection between its drive motor and the central gear or a superimposed gear comprising two input shafts drive-connected to the drive motor for the rotary drive of the receiving head and to the drive motor for the central gear.

A device for clamping a workpiece has a receiving head in a housing connected to a rotary drive with a rigid drive connection between a drive motor and the receiving head, radially adjustable clamping jaws connected to a clamping drive externally clamping the workpiece, and linear drives displacing the clamping jaws and forming the clamping drive driven jointly by a gear transmission with a central gear coaxial to the drive shaft of the receiving head by a separate drive motor. The central gear can be driven synchronously with the receiving head in the clamping position of the clamping jaws, and the rotary drive for the central gear comprises a rigid drive connection between its drive motor and the central gear or a superimposed gear comprising two input shafts drive-connected to the drive motor for the rotary drive of the receiving head and to the drive motor for the central gear.

The invention relates to a chuck having a sleeve, a chuck body, a plurality of chuck jaws, an adjusting mechanism configured to adjust relative movement between the chuck jaws and the chuck body, at least one locating member and a pushing mechanism. The locating member is disposed on the chuck body between the adjacent chuck jaws. When the adjusting mechanism drives the chuck jaws to approach to each other relative to the longitudinal axis, the pushing mechanism pushes the locating member to move towards the longitudinal axis. When the adjusting mechanism drives the chuck jaws to move away from each other relative to the longitudinal axis, the pushing mechanism pushes the locating member to move away from the longitudinal axis. Therefore, the operation is more convenient and safer; the aligning effect is precise and reliable, and the pre-tightening force is stable.

The invention relates to a chuck having a sleeve, a chuck body, a plurality of chuck jaws, an adjusting mechanism configured to adjust relative movement between the chuck jaws and the chuck body, at least one locating member and a pushing mechanism. The locating member is disposed on the chuck body between the adjacent chuck jaws. When the adjusting mechanism drives the chuck jaws to approach to each other relative to the longitudinal axis, the pushing mechanism pushes the locating member to move towards the longitudinal axis. When the adjusting mechanism drives the chuck jaws to move away from each other relative to the longitudinal axis, the pushing mechanism pushes the locating member to move away from the longitudinal axis. Therefore, the operation is more convenient and safer; the aligning effect is precise and reliable, and the pre-tightening force is stable.

In a coupling device (1), in particular for a man-machine interface (21) for operating inductively operated chucks (2), the coupling device comprising: an inductively operated chuck (2) for centering a workpiece (3) to be machined in space with at least one movable clamping jaw (4), an electric motor (6) drivingly connected to each of the said jaws (4), the said electric motor (6) being incorporated in the said chuck (2) and each jaw (4) being driven or fixed by the said electric motor (6), a first inductive transmission device (7) assigned to the chuck (2), a carrier or machine frame (10) spatially separated from the chuck (2), a second inductive transmission device (8) assigned to the frame (10), which is arranged in the region of the first inductive transmission device (7) of the chuck and exchanges measuring signals and voltages inductively therewith, and an external control device (11), by means of which command and monitoring data required for the operation and setting of the clamping jaws (4) and for the operation and locking of the electric motors (6) can be entered and/or read,
the intention is to ensure that, independently of the customer-specific electrical devices, complete operation of the chuck (2) and its monitoring during a machining operation is achieved immediately after coupling of the control devices (11) provided by the customer with the chuck.

This is achieved in that at least one programmable interface (21), which is electrically connected to the second inductive transmission device (8) and the control device (11), is provided between the second inductive transmission device (8) and the control device (11), each interface (21) has one or more command and control programs by means of which the chuck (2) can be set or selected by the control device (11), a plurality of measuring sensors (22) are provided which are assigned to the clamping jaws (4), electric motors (6) and/or the chuck (2) and by means of which their operating states are detected and transmitted to the respective interface (21), in that the respective interface (21) compares the actual data stored in the command programs with the measurement data determined by the measuring sensors (22), and in that this comparison of the selected operating state of the chuck (2) with an actual operating state generates data records which are evaluated by the respective interface (21) and forward

In a coupling device (1), in particular for a man-machine interface (21) for operating inductively operated chucks (2), the coupling device comprising: an inductively operated chuck (2) for centering a workpiece (3) to be machined in space with at least one movable clamping jaw (4), an electric motor (6) drivingly connected to each of the said jaws (4), the said electric motor (6) being incorporated in the said chuck (2) and each jaw (4) being driven or fixed by the said electric motor (6), a first inductive transmission device (7) assigned to the chuck (2), a carrier or machine frame (10) spatially separated from the chuck (2), a second inductive transmission device (8) assigned to the frame (10), which is arranged in the region of the first inductive transmission device (7) of the chuck and exchanges measuring signals and voltages inductively therewith, and an external control device (11), by means of which command and monitoring data required for the operation and setting of the clamping jaws (4) and for the operation and locking of the electric motors (6) can be entered and/or read,
the intention is to ensure that, independently of the customer-specific electrical devices, complete operation of the chuck (2) and its monitoring during a machining operation is achieved immediately after coupling of the control devices (11) provided by the customer with the chuck.

This is achieved in that at least one programmable interface (21), which is electrically connected to the second inductive transmission device (8) and the control device (11), is provided between the second inductive transmission device (8) and the control device (11), each interface (21) has one or more command and control programs by means of which the chuck (2) can be set or selected by the control device (11), a plurality of measuring sensors (22) are provided which are assigned to the clamping jaws (4), electric motors (6) and/or the chuck (2) and by means of which their operating states are detected and transmitted to the respective interface (21), in that the respective interface (21) compares the actual data stored in the command programs with the measurement data determined by the measuring sensors (22), and in that this comparison of the selected operating state of the chuck (2) with an actual operating state generates data records which are evaluated by the respective interface (21) and forward