An electronic circuit component mounting head which mounts electronic circuit components to a circuit substrate is provided. The mounting head includes a rotating/raising/lowering axis held on a head main body as to be capable of rotation and of being raised/lowered, a suction nozzle held on the rotating/raising/lowering axis as to be capable of being raised/lowered and not capable of being rotated relatively, and the rotating/raising/lowering axis and suction nozzle can be rotated as necessary by an electric motor. A raising/lowering driving member is held on head main body as to be capable of being raised/lowered, and is raised/lowered by a first linear motor. A first engaging section of the raising/lowering driving member is engaged with the rotating/raising/lowering axis, and a second engaging section of a second linear motor is held on the raising/lowering driving member engaged with suction nozzle.

The disclosure shows a mounting apparatus including a primary pedestal with a mounting stage installed thereon, a gantry frame supported on the primary pedestal, mounting heads supported on the gantry frame in a manner movable in the Y direction, a secondary pedestal arranged apart from the primary pedestal, and a Y-direction load receiver installed on the secondary pedestal in a manner movable in the X direction and immovable in the Y direction, in which an X-direction stator is attached to the secondary pedestal, and in which one end of a Y-direction stator attached to the gantry frame and the Y-direction load receiver are connected using a connection member, thereby suppressing vibration of the primary pedestal caused when the plurality of mounting heads are moved in the X and Y directions.

A system includes a computing device with circuitry and memory with instructions for execution by the circuitry. The instructions include monitoring signals indicative of a non-uniform distance between a transfer head and a receiving substrate, and, in response to the monitored signals, actuating one or more actuators towards the transfer head or the receiving substrate to deform the transfer head or the receiving substrate.

A pick-and-place spindle module comprises: a modular body structure including a first receiving location configured to receive a spindle; a first z-axis motor configured to move a spindle received in the first receiving location in a z-axis; a first theta motor configured to rotate a spindle received in the receiving location; a first motion control chip each attached to the body structure, the first motion control chip configured to control the first z-axis motor and the first theta motor; and a mechanical attachment mechanism, the mechanical attachment mechanism configured to facilitate attachment of the modular body structure to a spindle bank.

A pick-and-place dispensing head comprises: a body structure having a z-axis motor attachment location and a linear track; a z-axis motor attached to the body structure at the axis motor attachment location, the z-axis motor configured to exact movement in a z-axis; a body attached to the linear track and operably connected to the z-axis motor such that the body moves along the linear track when the z-axis motor is actuated; a theta motor operably connected to the first body; a receiving location operably connected to the body; and an optical detector extending from the first body configured to detect upward z-axis movement of a received pick-and-place spindle relative to the body.

A component mounting machine including a head provided with multiple nozzles to pick up the components; a raising and lowering device to individually raise and lower the multiple nozzles; a moving device to move the head relative to the board in a plane perpendicular to a raising and lowering direction of the nozzles; and a control device to perform, as a pickup operation for causing the nozzle to pick up a component, a first pickup operation of controlling the moving device and the raising and lowering device so as to lower a single one of the nozzles above the component supply section to pick up one of the components using that nozzle, and a second pickup operation of controlling the moving device and the raising and lowering device so as to simultaneously lower multiple of the nozzles above the component supply section to pick up multiple of the components simultaneously using the multiple nozzles.

A component supply device includes a transport path that guides a component connected body from a component insertion port on an upstream side in a component feeding direction to a component supply position on a downstream side, the component connected body including a plurality of axial components arranged and connected at a predetermined pitch, the plurality of axial components each having a lead, and a feed mechanism that pitch-feeds the component connected body along the transport path to the downstream side. The feed mechanism includes a feed member which has a plurality of feed hooks disposed at the predetermined pitch along the component feeding direction, a rotating shaft which is connected to one end side of the feed member, and a moving mechanism which is connected to the feed member through the rotating shaft and reciprocates the rotating shaft along the component feeding direction. A length of one feed hook among the plurality of feed hooks is longer than a length of an other feed hook among the plurality of feed hooks, the other feed hook being adjacent to the one feed hook on the rotating shaft side.

This patent application relates to apparatus and methods for enhanced microelectronic device handling. Apparatus comprises a pick arm having a pick surface configured for receiving a microelectronic device thereon, drives for moving the pick arm and reorienting the pick surface in the X, Y and Z planes and about a horizontal rotational axis and a vertical rotational axis, and a sensor device carried by the pick arm and configured to detect at least one of at least one magnitude of force and at least one location of force applied between the pick surface and a structure contacted by the pick surface or a structure and a microelectronic device carried on the pick surface. Related methods are also disclosed.

A component mounting machine including a head unit that has a head main body configured to hold multiple pickup members each capable of picking up a component at a predetermined interval along a predetermined circumference and to be capable of rotating forward and reverse directions; a moving device configured to move the head unit; a lifting and lowering device configured to lift and lower a pickup member; a component supply device configured to be capable of supplying the component to the pickup member; and a control device configured to control those described above. The control device performs a control such that the pickup members pick up the components supplied by the component supply device, and each component is mounted on a board after a completion of the pickup, while performing an operation of rotating the head main body and an operation of moving the head unit together.

A component mounting machine that performs mounting of components by moving a mounting head attached to slide using linear motor, stator of the linear motor that is forms of magnets arranged side by side is arranged on base, movable element is fixed to a slide so as to pass through the stator, and bracket for holding a portion of wires for supplying power to the linear motor and wire protector is fixed to the movable element. Since the bracket is located at a position close to the axis line of the movable element, the rotational moment acting on the slide due to the deformation resistance of the wires and the wire protector caused by the movement of the slide is reduced, and appropriate movement of the slide is ensured.