A system for assembling fields from a source substrate onto a second substrate. The source substrate includes fields. The system further includes a transfer chuck that is used to pick at least four of the fields from the source substrate in parallel to be transferred to the second substrate, where the relative positions of the at least four of the fields is predetermined.

A device and a method for aligning substrates. The method includes the steps of detecting alignment marks and aligning substrates with respect to one another in dependence on the detection of the alignment marks. At least two alignment marks are arranged parallel to a direction of a linear movement of the substrates, wherein the alignment of the substrates takes place along a single alignment axis, the alignment axis running parallel to the loading and unloading direction of the substrates.

A substrate transfer system includes a load lock module, an atmospheric transfer module having a first sidewall adjacent to the load lock module and a second sidewall remote from the load lock module, the atmospheric transfer module being connected to the load lock module, and a substrate transfer robot disposed in the atmospheric transfer module. The substrate transfer robot includes a base configured to reciprocate along the first sidewall, a substrate transfer arm disposed on the base, and a flow rectifier surrounding the base, the flow rectifier being configured, upon movement of the base, to create an obliquely downward air flow in a direction opposite to a moving direction of the base.

The wafer trimming device includes a chuck table configured to hold a target wafer via suction, thereby fixing the target wafer, a notch trimmer configured to trim a notch of the target wafer, and an edge trimmer configured to trim an edge of the target wafer. The notch trimmer includes a notch trimming blade configured to rotate about a rotation axis perpendicular to a circumferential surface of the target wafer. The edge trimmer includes an edge trimming blade configured to rotate about a rotation axis parallel to the circumferential surface of the target wafer.

The present disclosure provides a wafer locking mechanism configured to lock a wafer, the wafer locking mechanism comprising: a wafer base, constructed in a form of a frustum shape tapering from a bottom portion thereof towards a top portion thereof, and configured to be elevatable along a direction of an axis thereof; a plurality of rods, which are diametrically aligned in pairs perpendicular to the axis; and a plurality of compression springs, which are respectively sheathed on respective distal ends of the plurality of rods distal to the wafer base, in one-to-one correspondence and extend radially outwards. The plurality of rods are respectively provided with both a plurality of ball-head portions which are located at respective proximal ends thereof proximate to the wafer base and abut against the wafer base, in one-to-one correspondence, and a plurality of jaws which protrude from the respective distal ends along a direction of the axis on a same side of the top portion and are pressed radially inwards by the plurality of compression springs, in one-to-one correspondence.

A pre-jig wafer carrier disc installation/uninstallation device and a method thereof, including a first displacement mechanism, a wafer frame installation/uninstallation mechanism, a wafer installation/uninstallation mechanism, a mask installation/uninstallation mechanism and a robotic arm arranged around the first displacement mechanism. The said mechanisms sequentially stack the wafer frame, the wafer and the mask on the first displacement mechanism to form an assembly. An installation/uninstallation mechanism is disposed at a movable end of the robotic arm. The robotic arm drives the installation/uninstallation mechanism to remove and lock the assembly on an assembly carrier section of a carrier disc for successive processing. After the wafers are processed, the robotic arm drives the installation/uninstallation mechanism to move the assembly back onto the first displacement mechanism. The said mechanisms sequentially disassemble the assembly and recover the mask, the wafer and the wafer frame.

A method includes: receiving a substrate on a first stage by a holder of a substrate transfer mechanism; causing the substrate to pass through a first measurement part, and measuring a first true deviation amount between the holder and the substrate at a first position; causing, when transferring the substrate toward a second stage, the substrate to pass through a second measurement part, and measuring a second true deviation amount between the holder and the substrate at a second position; reflecting a difference between the first and second true deviation amounts to a physical model to correct the physical model; calculating a position correction amount of the holder on the second stage from a thermal displacement amount of the holder at the second position; and controlling the substrate transfer mechanism based on the position correction amount to perform a position correction of the holder.

A mass transfer method includes providing a transfer unit and a semiconductor carrying unit connected therewith, removing an element supporting structure of the semiconductor carrying unit from micro semiconductor elements of the semiconductor carrying unit, partially removing the photosensitive layer to form connecting structures, connecting a package substrate with electrodes of the micro semiconductor elements, breaking the connecting structures to separate the micro semiconductor elements from the transfer substrate. A mass transfer device is also disclosed.

A die placement system provides a tip body and die placement head to ensure planarity of a die to substrate without the need for calibration prior to each pick and place operation. A self-aligning tip incorporated into a tip body aids in die placement/attachment. This tip provides for global correction of planarity errors that exist between a die and substrate, regardless of whether those errors stem from gantry (i.e. die-side misalignment) or machine deck tool (i.e. substrate-side misalignment) misalignment.

A die placement system provides a tip body and die placement head to ensure planarity of a die to substrate without the need for calibration prior to each pick and place operation. A self-aligning tip incorporated into a tip body aids in die placement/attachment. This tip provides for global correction of planarity errors that exist between a die and substrate, regardless of whether those errors stem from gantry (i.e. die-side misalignment) or machine deck tool (i.e. substrate-side misalignment) misalignment.