Discussed is an assembly chamber containing a fluid. The assembly chamber includes a bottom portion, a side wall portion formed at a predetermined height on the bottom portion and disposed to surround the bottom portion, and a partition wall part formed on the bottom portion and extending from one inner surface of a plurality of inner surfaces provided in the side wall portion to another inner surface facing the one inner surface. The vertical height of at least a portion of the partition wall part is variable with respect to the bottom portion.

A multiple die container load port may include a housing with an opening, and an elevator to accommodate a plurality of different sized die containers. The multiple die container load port may include a stage supported by the housing and moveable within the opening of the housing by the elevator. The stage may include one or more positioning mechanisms to facilitate positioning of the plurality of different sized die containers on the stage, and may include different portions movable by the elevator to accommodate the plurality of different sized die containers. The multiple die container load port may include a position sensor to identify one of the plurality of different sized die containers positioned on the stage.

A module tray for a semiconductor device includes a base plate, first and second sidewalls extending in a vertical direction from opposite sides of the base plate to define an accommodation space, a dividing wall extending in the vertical direction from the base plate between the first and second sidewalls, first to fourth fastening guides with first to fourth fastening grooves, respectively, on inner surfaces of the first and second sidewalls and opposite side surfaces of the dividing wall, and first to fourth guide grooves on the inner surfaces of the first and second sidewalls and the opposite side surfaces of the dividing wall, respectively, the first to fourth guide grooves having curved concave shapes, and an upper end portion of each of the first to fourth fastening grooves gradually widening toward a top thereof.

A method includes identifying a wafer position for a plurality of die on a wafer, storing the wafer position for each of the plurality of die in a database, dicing the wafer into a plurality of singulated die, positioning each of the singulated die in a die position location on a tray, and storing the die position on the tray for each of the singulated die in the database. The database includes information including the wafer position associated with each die position. The tray is transported to a processing tool, and at least one of the plurality of singulated die is removed from the die position on the tray and processed in the processing tool. The processed singulated die is replaced in the same defined location on the tray that the singulated die was positioned in prior to the processing. Other embodiments are described and claimed.

An apparatus having a first portion including a first front wall, a first rear wall, and a bottom wall integrally coupled to the first front wall and the first rear wall, and pivotal pin structures integrally coupled to and extending from the first rear wall. The apparatus includes a second portion having a second front wall, a second rear wall, and a top wall integrally coupled to the second front wall and the second rear wall, and pin holders integrally coupled to and extending from the second rear wall and at an offset angle with reference to the top wall. The pivotal pin structure includes a base support connected to the first rear wall and a shaft connected to the base support, and the pin holder defines an opening sized and shaped to accept the shaft. The first and second portions are sized and shaped to be pivotally movable between open and closed configurations.

An apparatus having a first portion including a first front wall, a first rear wall, and a bottom wall integrally coupled to the first front wall and the first rear wall, and pivotal pin structures integrally coupled to and extending from the first rear wall. The apparatus includes a second portion having a second front wall, a second rear wall, and a top wall integrally coupled to the second front wall and the second rear wall, and pin holders integrally coupled to and extending from the second rear wall and at an offset angle with reference to the top wall. The pivotal pin structure includes a base support connected to the first rear wall and a shaft connected to the base support, and the pin holder defines an opening sized and shaped to accept the shaft. The first and second portions are sized and shaped to be pivotally movable between open and closed configurations.

The present disclosure provides a method of operating an automatic handling system. The method includes: controlling a handling device to move forward to a load port of a production equipment; receiving a signal of a load request by a receiver of the handling device; controlling an image capturing device of the handling device to capture an image of the load port; determining whether the receiver receives the signal of the load request; and determining whether there is any abnormal condition in the load port.

A system includes a factory interface, a load port connected to the factory interface, and a system controller. The system controller is to, responsive to detecting that a container is received at the load port, determine a type of parts for storage at the container. One or more mapping patterns associated with the determined type of parts is identified. A detection system of robot arm(s) of the factory interface is moved according to the identified mapping pattern(s) to detect one or more parts stored by the container. A mapping of the container is determined based on the movement of the robot arm(s). The mapping indicates regions of the container that stores detected parts and a position of each of the detected parts. Based on the mapping, the robot arm(s) either remove a detected part form the container or place an additional part in the container.