A substrate transport device includes an arm, an end effector coupled to the arm, a driver configured to lift the arm so that the end effector receives a substrate, and a controller configured to control an output of the driver to change a lifting speed of the arm. While lifting the arm at a first speed to lift the end effector toward the substrate, the controller changes the lifting speed to a second speed that is lower than the first speed when the end effector starts to raise a height position of the substrate.

A gripper arrangement adapted for gripping a cleanroom container, such as a FOUP, FOSB or reticle container and a method therefore, includes: a gripper adapted to grip the cleanroom container; a lifting unit comprising a first motor for lifting the gripper; at least one cord connecting the gripper with the lifting unit, wherein the at least one cord is driven by the first motor; a second motor for rotating at least a portion of the gripper with respect to the lifting unit around the vertical axis; wherein the gripper comprises engagement elements and the lifting unit comprises complementary engagement elements adapted to engage with the engagement elements for preventing a rotation around the vertical axis of the gripper with respect to the lifting unit; wherein the gripper comprises an upper gripper element and a lower gripper element; wherein the lower gripper element is adapted for supporting the top flange of the cleanroom container; and the lower gripper element comprises an opening that can be passed over the upper flange of the cleanroom container and at least one recess formed at least partially around the opening for accommodating the upper flange of the cleanroom container.

Systems, methods, and computer-readable media are disclosed for container transporters and related item manipulation devices. In one embodiment, an example item manipulation device may include a support platform, and a conveyance surface attached to the support platform and configured to convey a container at least a portion of a distance from a first side of the support platform to a second side of the support platform, where the conveyance surface defines at least a portion of a container passage through which a container can be conveyed. The item manipulation device may include a manipulator comprising a first arm disposed along a longitudinal axis of the item manipulation device and a second arm disposed along the longitudinal axis of the item manipulation device, where the manipulator is engageable with the container to move the container at least partially onto the conveyance surface.

An emptying system for emptying a box of food products comprising: —a box overturning robot (2) comprising gripping means (20); —acquisition means (3) for acquiring at least one image of at least one part of the box; —a control unit (4) that moves said gripping means (20) in function of the information arising from said acquisition means (3) for grasping the box by said gripping means (20).

A robot and a robot-based container storage and removal method. The robot comprises: a master control processing unit (110), a pick-and-place mechanism (120) and a marker detection unit (130), wherein according to target storage and removal position information of a target inventory container, the master control processing unit (110) controls a robot body to move to a first horizontal position and controls the pick-and-place mechanism (120) to move to a first height position; when the robot body and the pick-and-place mechanism (120) stop moving, the marker detection unit (130) determines a target pick-and-place marker from a target inventory support to which the target inventory container belongs; and the master control processing unit (110) also calibrates the position of the pick-and-place mechanism (120) according to the position of the target pick-and-place marker, so as to control the calibrated pick-and-place mechanism (120) to perform a storage operation or a removal operation on the target inventory container. By means of the solution, a pick-and-place position of a pick-and-place mechanism (120) of the robot can be precisely positioned and moved, such that the pick-and-place mechanism (120) can quickly and accurately store or remove a target inventory container.

A hand for holding the substrate includes a hand main body and a plurality of seating members mounted on the hand main body and on which the substrate is to be seated. Each of the plurality of seating member includes a shaft member supported to the hand main body and a lever member that is supported to the shaft member and includes a first end portion including a seating portion on which the substrate is to be seated and a second end portion disposed on a side opposite to the first end portion across the shaft member. At least a part of the plurality of seating members further includes a biasing member for giving a force of rotating the lever member to the lever member such that the second end portion moves downward and a seating sensor configured to detect an upward movement of the second end portion.

An apparatus, system and method for providing an optical coupler. The optical coupler may be a miniature fiber optic coupler, which may include: a housing having dimensions of less than 4 mm×4 mm×4 mm; an input into the housing capable of receiving a fiber optic sending line; a sending line prism having dimensions of less than 2 mm×2 mm within the housing in optical communication with the sending line; a receiving line prism having dimensions of less than 2 mm×2 mm in optical communication with the sending line prism at a corresponded angle in a range of 30 to 60 degrees and capable of receiving a signal incoming on the sending line and redirecting the received signal; and a receiving line in optical communication with the receiving line prism and capable of receiving and outputting the redirected received signal.

Harvesting tools are disclosed which may comprise a gripper including a set of finger elements constructed and arranged to envelop a target object pertaining to agricultural produce, and a manipulator carriage configured to actuate the gripper during operation to grasp the target object. Related systems and methods are also disclosed.

According to a first aspect of the present invention, there is provided a container for an automated storage system. The container has a base which extends across an area that has a center point and an imaginary center axis that extends through the center point. The container also has a casing with a bottom end connected to the base and a top end opposing the bottom end and defining an opening for accessing the container. The casing extends from the base in a direction which has a component parallel to the center axis. A rim extends from the second end of the casing away from the center axis. A bottom-facing skirt extends from the rim, whereby a gripping space is formed between the casing, rim and skirt of the container.

Object manipulation in warehouses and logistics facilities is a challenging task because of the unstructured environment. The unstructured environment can have items/objects with different form factors, weight, shape, and size. Traditionally, multiple robots have been used to handle for specific task to be performed by an individual robot which requires high floor. This leads to higher cost and infrastructure. Embodiments of the present disclosure provide a gripper apparatus that addresses a single gripper design handling multiple parcels, wherein the apparatus consists of ‘m’ fingers parallel to each other and can be independently controlled through actuators, each finger has a force sensors feedback and also actuators which are controlled with force. Each finger comprises a linear slider for actuation for gripping objects and wherein bottom fingers are moved to provide enough gravity support. Further, apparatus comprises bellows attached to each finger end for grasping object using pneumatic grasping mechanism.