A method of controlling a robot arm for performing coffee drip includes: an arrangement checking operation of checking an arrangement of a dripper, a coffee powder container, a cup, and a kettle; a coffee powder providing operation of, when the arrangement of the cup is sensed, gripping the coffee powder container and providing a coffee powder contained in the coffee powder container to the dripper, by using the robot arm; a dripping operation of, when the coffee powder is provided to the dripper, gripping the kettle and performing a drip operation using any one of a plurality of predetermined methods, by using the robot arm; and a discharging operation of, when the dripping operation is completed, gripping the cup and transferring the cup to a discharge position.

A centering unit for diagnostics laboratory transporting compartment is presented. The centering unit for diagnostics laboratory transporting compartment comprises at least two arms with grippers for centering diagnostics laboratory transporting compartments of different diameters. For accurate and reliable centering of laboratory transporting compartments, the two arms are biased with a single elastic member. A laboratory system and a method for centering diagnostics laboratory transporting compartment and diagnostics laboratory transporting compartment holder are also disclosed.

A pipe storage system can include a plurality of pipe storage bays established between adjacent pipe storage arms, a plurality of protrusions extending from the pipe storage arms into each pipe storage bay, the plurality of protrusions establishing a plurality of channels, wherein each channel is established between a pair of adjacent protrusions, and a plurality of latches, wherein the latches are movable from between a retracted position in which the latches are retracted to establish series of first pipe storage openings between opposing channels and an extended position in which the latches extend into the pipe storage bay to establish a series of second pipe storage openings between opposing protrusions.

A gripper provides for gripping labware having a variety of diameters and shapes. The gripper includes a support structure having a center axis, a motor, and a gripper stage. The gripper stage includes a plurality of blades, each of the blades having a) a first end through which a blade rotation axis extends, the blade rotation axis being fixed relative to the support structure and offset from the center axis, b) a second end that is circumferentially and radially moveable to rotate the blade about the blade rotation axis, and c) a center portion. The gripper stage also includes a ring structure coupled to the motor to rotate the ring structure around the center axis. The ring structure, as it rotates, moves the second end of each blade to rotate the blade about the blade rotation axis of the blade to shift the center portion towards the center axis to contact an outer portion of a vessel extending along the center axis.

The present invention will provide a device in which the gripping action is achieved by a compliant membrane manipulated by electromagnetic forces. The gripping force provided by the present invention is best suited for delicate objects, as it gently applies the gripping force necessary for displacement. This is accomplished through a chamber, a membrane, a plunger attached to the membrane, and a solenoid configured to manipulate the plunger, and thus, the membrane.

An end effector (400) for a robotic arm, the end effector (400) comprising: two pipe engaging jaws (404), each jaw comprising an inner contour configured for engaging a pipe section, wherein at least one jaw (404) is a fixed jaw; wherein the end effector (400) is configured to restrict radial movement of the pipe section while permitting axial movement.

A centering unit for diagnostics laboratory transporting compartment is presented. The centering unit for diagnostics laboratory transporting compartment comprises at least two arms with grippers for centering diagnostics laboratory transporting compartments of different diameters. For accurate and reliable centering of laboratory transporting compartments, the two arms are biased with a single elastic member. A laboratory system and a method for centering diagnostics laboratory transporting compartment and diagnostics laboratory transporting compartment holder are also disclosed.

Disclosed herein is a robot gripper for manufacturing coffee beverages. The robot gripper is coupled to an end of a handling robot arm. The robot gripper includes: a rotating bracket rotatably coupled to an end of the robot arm; a first gripping unit coupled to one side of the rotating bracket, and configured to grip a cup or a cup lid; a second gripping unit coupled to the opposite side of the rotating bracket, and configured to grip a milk pitcher; air chucks coupled to both sides of the rotating bracket, respectively, and configured to drive the first and second gripping units, respectively; and a pressure head fastened to one side of the second gripping unit, and configured to couple a cup lid to the top of a cup by pressing the cup lid placed on the top of the cup.

A method and an automatic degate system includes a fixture configured to receive a workpiece, a registration device configured to position the workpiece in a predetermined orientation and position, and a robotic arm. The robotic arm is configured to move in at least a gripping direction. The robotic arm includes a gripping device configured to engage the workpiece at predetermined locations after being moved in the gripping direction. The robotic arm also includes a support bracket, a plurality of elongate rods each having a predetermined length and extending orthogonally from the support bracket, and a respective cutting puck coupled to a distal end of each of the plurality of elongate rods. The cutting pucks configured to remove a biscuit of excess material from the workpiece while being moved in the gripping direction.

Systems and methods for clearing a top drive from an operational area of the mast such that operations may be performed along the rail without interference from the top drive. Systems and methods of the present disclosure provide for arranging the top drive in a parked configuration outside of, or generally behind, the mast. A guide rail may be arranged within an operational area of a mast and may have a pair of interchangeable rail sections, each of which may be configured for arrangement in either an operating configuration, where the rail section may be positioned within the operational area of the mast to form part of the rail, or a parked configuration, where the rail section may be positioned outside of the operational area. Each interchangeable rail section may be pivotable about an axis and may be arranged on a pivotable gate of the mast.