Systems and methods for vacuum extraction for material sorting applications are provided. In one embodiments, a vacuum object sorting system comprises: a vacuum extraction assembly that includes at least one vacuum extractor device having an inlet and an outlet, wherein the at least one vacuum extractor device is configured to convert a controlled compressed air stream into a channeled vacuum airflow entering the inlet and exiting the outlet; and an object recognition device coupled to sorting control logic and electronics, wherein the controlled compressed air stream is controlled in response to a signal generated by the object recognition device; wherein the at least one vacuum extractor device is configured to capture a target object identified by the sorting control logic and electronics utilizing the channeled vacuum airflow, and further utilizing the channeled vacuum airflow, to pass the target object through the inlet and outlet to a deposit location.

There is provided a crane including a main body, a tower derrickably supported by the main body, a jib derrickably supported by the tower, an assist member that assist the jib to move along a ground, and a determination unit that determines whether or not the jib is stopped when the tower is lowered in a lowering work state where the jib is assisted by the assist member.

A control system and method for a vacuum attachment system has a programmable controller that interprets feedback from vacuum level sensors and battery sensors to responsively provide warnings and limit or alter machine functions to reduce risk exposure. Vacuum levels and vacuum level change over time are used to evaluate conditions such as vacuum generator function, excessive altitude, vacuum system condition and leakage due to incompatibility of attachment device and load. Warnings are engaged if parameters or limits are not met. At designated/calculated thresholds and conditions the device can adjust its utilization of resources to ensure the safest condition. If conditions are detected that indicate a reduced ability to maintain the attachment, the programmable controller may limit functions such as preventing the operator from initiating another attachment.

A system including a programmable motion device and an end effector for grasping objects to be moved by the programmable motion device is disclosed. The system includes a vacuum source that provides a high flow vacuum such that an object may be grasped at an end effector opening while permitting a substantial flow of air through the opening, and a dead-head limitation system for limiting any effects of dead-heading on the vacuum source in the event that a flow of air to the vacuum source is interrupted.

The invention relates to a method for conveying components and to an automated vacuum gripper (1) for components (3), in particular sheet metal parts, comprising a plurality of suction elements (4), which are arranged at a preferably movable support part (5), a first vacuum generator (8) for forming a first vacuum circuit (9), a second vacuum generator (10) for forming a second vacuum circuit (11), at least one switching element connected to a system controller (14) for automated switching of the first vacuum circuit (9) to the second vacuum circuit (11), at least one compressed air supply (15) connected to at least the first and the second vacuum generators (8), at least one sensor device (16, 17), wherein the first vacuum generator (8) is associated with a first predeterminable group (12) of suction elements (4), and the second vacuum generator (10) is connected to a vacuum tank (18) for forming a second vacuum circuit (11), which may be activated in case of emergency and is redundant to the first vacuum circuit (9), and wherein at least one first sensor device is (16) is formed for monitoring the vacuum at least at the first vacuum circuit (9), and at least one second sensor device (17) has an optical sensor for detecting a relative movement of the component (3) during a conveying operation.

Systems and methods for vacuum extraction for material sorting applications are provided. In one embodiments, a vacuum object sorting system comprises: a vacuum extraction assembly that includes at least one vacuum extractor device having an inlet and an outlet, wherein the at least one vacuum extractor device is configured to convert a controlled compressed air stream into a channeled vacuum airflow entering the inlet and exiting the outlet; and an object recognition device coupled to sorting control logic and electronics, wherein the controlled compressed air stream is controlled in response to a signal generated by the object recognition device; wherein the at least one vacuum extractor device is configured to capture a target object identified by the sorting control logic and electronics utilizing the channeled vacuum airflow, and further utilizing the channeled vacuum airflow, to pass the target object through the inlet and outlet to a deposit location.

The invention relates to a vacuum adhesion system, comprising at least one suction cup having a suction surface for attaching to a surface at least one system module, comprising at least one vacuum pump connecting to the suction cup for applying a vacuum to the suction surface for providing suction adhesion at least one indicator or sensor for indicating or measuring a pressure differential in the suction cup at least one interface for communicating the measured pressure differential or a value based thereon and a processor for controlling the vacuum adhesion system.

Systems and methods for vacuum extraction for material sorting applications are provided. In one embodiments, a vacuum object sorting system comprises: a vacuum extraction assembly that includes at least one vacuum extractor device having an inlet and an outlet, wherein the at least one vacuum extractor device is configured to convert a controlled compressed air stream into a channeled vacuum airflow entering the inlet and exiting the outlet; and an object recognition device coupled to sorting control logic and electronics, wherein the controlled compressed air stream is controlled in response to a signal generated by the object recognition device; wherein the at least one vacuum extractor device is configured to capture a target object identified by the sorting control logic and electronics utilizing the channeled vacuum airflow, and further utilizing the channeled vacuum airflow, to pass the target object through the inlet and outlet to a deposit location.

A system including a programmable motion device and an end effector for grasping objects to be moved by the programmable motion device is disclosed. The system includes a vacuum source that provides a high flow vacuum such that an object may be grasped at an end effector opening while permitting a substantial flow of air through the opening, and a dead-head limitation system for limiting any effects of dead-heading on the vacuum source in the event that a flow of air to the vacuum source is interrupted.

A holding head is provided for a vacuum holding device for handling a plate-shaped workpiece about an axis. An arrangement of operating elements on a base body of the holding head includes at least three operating elements connected as actuating elements in a double actuation circuit for releasing the plate-shaped workpiece. Two of the actuating elements are arranged on sides of the arrangement opposite to one another with respect to the position of the axis and the third actuating element is designed ring-shaped and surrounds the axis circumferentially.