A substrate treating apparatus is provided. The substrate treating apparatus includes an atmospheric pressure transfer module provided with a first transfer robot having a first hand with a substrate placed thereon; a vacuum transfer module provided with a second transfer robot having a second hand with a substrate placed thereon; a load-lock chamber positioned between the atmospheric pressure transfer module and the vacuum transfer module, and having an inner space convertible between an atmospheric pressure and a vacuum atmosphere; a process chamber coupled to the vacuum transfer module and treating the substrate; and a ring carrier supported by the first transfer robot or the second transfer robot for a transfer of a ring member. The ring carrier comprises a plate having the ring member placed thereon and at least one leg protruding from a bottom surface of the plate and placed at the first hand or the second hand.

A semiconductor wafer processing system includes a stocker having an interior surface, a wafer carrier disposed within the stocker, a wafer shelf disposed within the wafer carrier for storing a semiconductor wafer, and a discharge circuit including a first conductor electrically coupled to the wafer shelf and a first current controller electrically coupled to the first conductor and to the interior surface of the stocker.

Disclosed are techniques and systems for automatically determining and correcting the levelness of a wafer handling robot end effector. The systems may use a tilt sensor or a gravitational field sensor which may be calibrated to the wafer handling robot. The output from the tilt sensor may be used to determine or estimate the tilt of an end effector of the wafer handling robot and to perform correctional positioning to reduce or eliminate the tilt, to automatically teach certain positions that have reduced tilt, to perform health checks on the robot, provide feedback to a user, etc.

An apparatus and method for drying semiconductor wafers. The apparatus includes a tank that holds hold a liquid, a first lifting assembly, and a second lifting assembly. The first lifting assembly lifts and lowers a first wafer carrier and one or more semiconductor wafers supported thereon between a first lowered position in which the one or more semiconductor wafers are completely submerged in the liquid in the tank and a first raised position in which an upper portion of the one or more semiconductor wafers are not submerged in the liquid in the tank. The second lifting assembly has a second wafer carrier that engages the upper portion of the one or more semiconductor wafers and continues to lift the one or more semiconductor wafers until an entirety of the one or more semiconductor wafers is no longer submerged in the liquid in the tank.

Disclosed herein are systems and methods relating to a transfer chamber for an electronic device processing system. The transfer chamber can include a first magnetic levitation track having a face-up orientation and a second magnetic levitation track spaced from the first magnetic levitation track and having a face-down orientation. The system can include substrate carriers that move along the first and second magnetic levitation tracks where each substrate carrier includes a magnet on a bottom portion to interact with a first magnetic field and a second magnet on a top portion to interact with a second magnetic field. The system also can include at least one lift pin assembly to move the substrate carriers in a vertical direction between the first and second magnetic levitation tracks.

A substrate conveying robot has a robot arm including an end effector having a substrate holding unit holding a substrate, arm drive unit for driving the robot arm, an elevating drive unit for elevatingly driving the end effector, a robot control unit controlling the arm drive unit, the elevating drive unit, and the substrate holding unit, and a substrate detection unit having a substrate detection unit which detects a vertical position of the substrate and elevates coordinately with an elevating operation of the end effector. By this configuration, a vertical position of a substrate to be conveyed is detected with high accuracy so that a robot operation can be controlled based on the detection result.

The inventive concept provides a substrate treating apparatus. The substrate treating apparatus includes a plurality of treating chambers performing a respective treatment on a substrate therein; a transfer chamber having a robot transferring the substrate between the plurality of treating chambers; a detection unit mounted on the robot and configured to detect a substrate state; and a controller for controlling the detection unit, wherein the detection unit comprises: an imaging member for imaging the substrate; and a driving member for moving the imaging member, and wherein the controller controls the detection unit to image and store an image of the substrate at an optimal position and determines whether an image of the substrate is a normal state based on the image obtained in the optimal position, the optimal position determined based on a process variable of the treating chamber.

Embodiments relate to a device for correcting a robotic arm, including: a first robotic arm positioned in a vacuum transmission chamber; a first jig wafer comprising a first wafer body and a first jig positioned on a front surface of the first wafer body; a first distance measuring sensor positioned at a center position of a back surface of the first wafer body and configured to detect whether a center of the first jig wafer is aligned with a center of a wafer chuck; a second distance measuring sensor positioned on the front surface of the first wafer body and on an outside of the first jig and configured to detect a lifting height of the first robotic arm when the first robotic arm controls a pick-and-place operation the first jig wafer on an upper surface of the wafer chuck.

A carrier system and method carries an object to an object mounting member provided with an object mounting section. The system includes: a measurement device which obtains information related to a flatness of the object; a carrier member that carries the object; and a controller which controls a driving speed of the carrier member using the information related to the flatness of the object obtained by the measurement device.

An annealing apparatus includes a heater plate and a cooler plate disposed in a chamber, a delivering robot, a sensor and circuitry. The delivering robot is configured to deliver a wafer between the heater plate and the cooler plate in the chamber. The sensor is located on the delivering robot and configured to output a first signal in response to a motion of the delivering robot. The circuitry is coupled to the sensor and configured to detect whether an abnormality of the delivering robot occurs according to the first signal.