A compound fork device includes a first prong and a second prong spaced apart from the first prong. Each of the first and second prongs has an upper surface and a lower surface which is depressed relative to the upper surface. The upper surfaces of the first and second prongs are configured to cooperatively retain a first type container. The lower surfaces of the first and second prongs are configured to cooperatively retain a second type container having a configuration different from that of the first type container. A method and a system using the compound fork device are also disclosed.

A soft pneumatic module includes a first frame defining a first path portion, a second frame opposite to the first frame and defining a second path portion, a retainer connected to the first frame and the second frame, a plurality of first crease parts disposed along a circumference of the first frame at two sides of the retainer and obliquely disposed inward from the first frame, and a plurality of second crease parts connected to the plurality of first crease parts and the second frame, disposed along a circumference of the second frame at the two sides of the retainer, and expanded along with the plurality of first crease parts as a fluid is injected into the soft pneumatic module.

A retainer apparatus configured to releasably retain an article, comprising a face plate member each having a front face; a plurality of vacuum cups and a plurality of support pins each extending distally relative to the front face, respectively; wherein the vacuum cups and the support pins are laterally spaced from one another; wherein the plurality of vacuum cups retain the article to the retainer apparatus in a presence of vacuum; wherein the plurality of support pins are extendable/retractable relative to the face plate member, wherein each of the support pins have a longitudinal axis, respectively, and are configured to contact the article to support the article against movement along the longitudinal axis and support the article against movement transverse to the longitudinal axis; and a locking mechanism configured to inhibit the support pins from being retractable and extendable when the locking mechanism is engaged.

Disclosed is a device for the automatic removal of rejected eggs from an incubation tray, whereby the device includes a suction power above the egg to suck up the egg, and the device further includes a blowing power against the bottom of the egg to blow away the egg, whereby the blowing power blows an air flow or overpressure against the bottom of the egg. Also disclosed is a method for the automatic removal of one or more rejected eggs from an incubation tray.

A robotically-operated gripping device is provided and includes a frame assembly, a vacuum device, a clamping device, and a robotic arm. The vacuum device is connected to the frame assembly and configured to selectively attach to and position at least a portion of an object. The clamping device is connected to the frame assembly and provided for selectively clamping the object attached to the vacuum device. The robotic arm is connected to the frame assembly and provided for selectively positioning the vacuum device and the gripping device.

Provided is a workpiece conveying system configured to convey a sheet-like workpiece to a downstream step, including: a workpiece conveyor configured to lift through attraction holding, by a workpiece holding unit, an uppermost workpiece W of a stack, and convey the uppermost workpiece W of the stack to the downstream step one by one; and a conveyed workpiece number detector configured to detect the number of workpieces W held by the workpiece holding unit at a detection timing, at which the workpiece W held and raised by the workpiece holding unit in accordance with a normal workpiece conveying operation performed by the workpiece conveyor reaches an upper limit position of raising the workpiece W, and at which a moving speed component of the workpiece W in a raising direction is 0.

According to the present invention, provided is an unmanned construction system for an access floor comprising an installation frame (10), a pad (20) attached to the installation frame (10), and a floor (30) coupled to the pad (20), the unmanned access floor construction system comprising a construction robot connected to a control server (1) by wired or wireless communication, wherein the construction robot comprises: a pad installation robot (100) for attaching the pad (20) to the installation frame (10); a floor installation robot (200) for mounting the floor (30) on the pad (20); and a bolting robot (300) for fastening the pad (20) to the floor (30) by using a fastening means (40).

A self-propelled gripper is installed on a robotic arm. The robotic arm includes a body and a tip axis. The self-propelled gripper includes a housing, a rotation element, a moving element, and at least one claw body. The housing is fixed on the body. The rotation element is disposed in the housing and secured with the tip axis. The moving element is movably disposed in the housing and is connected to the rotation element. The moving element includes at least one slot. The claw body is pivoted on the housing and partially extends in the corresponding slot. When the rotation element rotates along with the tip axis, the rotation element drives the moving element to process a linear motion along a rotation central line so that the claw body pivotally rotates on the housing.

A first adapter of an end-effector exchange device includes a piston driven by supply and discharge of air, a cam member integrally coupled to the piston, and an engagement ball configured to be in contact with a side surface of a cam portion of the cam member. A second adapter includes a separation operation hole into which a release operation tool is inserted, the release operation tool being configured to come into contact with a side surface of the cam portion is inserted.

A system for providing a thermal interface material on a tray for an electric vehicle battery includes a material dispensing system (MDS) and a vision system. The MDS includes a set of pumps, a robotic dispensing system (RDS), and a controller. The set of pumps includes a first pump to house a first material and a second pump to house a second material different from the first material. The RDS is fluidly coupled to the set of pumps and dispenses a third material on the tray in a defined pattern, where the third material is a mixture of the first and second materials. The vision system is configured to capture a first set of images. The controller is configured to determine a nozzle offset of the RDS based on the first set of images and control a position of the RDS based on the nozzle offset.