There is provided a component mounter for mounting a component on a mounting target object, including: a mounting head comprising a base section having, in the interior thereof, a first gas passage and a second gas passage that does not communicate with the first gas passage; a lifting and lowering mechanism for lifting and lowering the base section; a suction nozzle having a nozzle section disposed below the base section and configured to be lifted up and lowered, as the base section is lifted up and lowered, to pick up the component through a negative pressure supplied to the first gas passage; a biasing section for biasing the nozzle section downwards while permitting the nozzle section to be pushed in towards the base section; and a valve for switching between presence and absence of communication between the second gas passage and the outside depending on whether a push-in amount of the nozzle section has not yet reached or reached a predetermined value; and a detecting device for detecting at least one of a flow rate or a pressure of gas flowing through the second gas passage.

A vacuum head and corresponding method for moving product at the end of a robotic arm includes a housing having a product contact surface. An array of at least two rows and at least three ranks of valves are arranged with respect to the product contact surface. A solenoid is connected with respect to each of the valves to selectively activate air pressure in one or more valves thereby enabling multiple switchable zones on the product contact surface and thereby enable transfer of product between stations.

A holding mechanism includes a Bernoulli pad that holds a plate-shaped body, a hand on which the Bernoulli pad is disposed, a sensor that is disposed on the hand and detects that the plate-shaped body is held under suction by the Bernoulli pad, a lateral movement restriction section disposed on the hand, a tube that connects an air source supplying air to the Bernoulli pad and the Bernoulli pad, an adjustment valve that is disposed in the tube and adjusts a flow rate of air supplied to the Bernoulli pad, and a control section that controls operation of the adjustment valve. The control section gradually increases the flow rate of the air supplied from the adjustment valve to the Bernoulli pad and, when it is detected by the sensor that the plate-shaped body has been held under suction by the Bernoulli pad, fixes the flow rate of the air.

There is provided an automated removal apparatus for selectively removing one or more trimmed portions of a laminated ply in a ply-by-ply fabrication process. The automated removal apparatus includes a rotatable reel having a plurality of retractable vacuum panels attached around the rotatable reel. Each retractable vacuum panel has one or more retractable vacuum pad assemblies, and each retractable vacuum pad assembly has a vacuum pad with a vacuum port and a self-sealing valve. The automated removal apparatus further includes actuator assemblies attached to the plurality of retractable vacuum panels, friction reducing elements attached around the rotatable reel, a drive assembly attached to the rotatable reel, and a pneumatic system attached to the rotatable reel and including a valve manifold operable to control an air flow to the actuator assemblies and to one or more vacuum generators to generate a vacuum flow.

The invention relates to an automated vacuum gripper, a feed unit and a method for conveying flat components (3). The vacuum gripper (1) comprises a support part (5), at least one support part element (7), a plurality of first suction elements (4), which are arranged at the at least one support part element (7) and define a first suction plane; at least one bearing assembly (28) and at least one actuating assembly (29), wherein the at least one support part element (7) is pivotably mounted at the support part (5) by means of the at least one actuating assembly (29) about the at least one bearing assembly (28). The plurality of second elements (4) is arranged at the support part (5) and defines a second suction plane (19). The at least one support part element (7) with its first suction plane defined by the plurality of first suction elements (4) is pivotable from a standby position that is at an angle relative to the second suction plane into a working position that is congruous with the second suction plane, and vice versa.

According to one embodiment, an object holding apparatus includes a suction device, a suction pad, and a proximal sensor. The suction device is configured to suction gas. The suction pad is connected to the suction device, and is configured to hold an object based on suction by the suction device. The proximal sensor is configured to detect that the object is in close proximity to the suction pad. The suction device is controlled to perform suction when the proximal sensor detects that the object is in close proximity to the suction pad.

An assembly and method for moving bulk items from a first location to a second location is disclosed. The items are moved from the first location to the second location through a pick-up head. Vacuum pressure is supplied to the head to pick-up an item at the first location and carry the item to the second location. A detector is located between the first location and the second location to detect if an item has been picked up by the head. If no item is detected, the head is closed to the vacuum pressure through a control mechanism or closure element.

According to one embodiment, an object holding apparatus includes a suction device, a suction pad, and a proximal sensor. The suction device is configured to suction gas. The suction pad is connected to the suction device, and is configured to hold an object based on suction by the suction device. The proximal sensor is configured to detect that the object is in close proximity to the suction pad. The suction device is controlled to perform suction when the proximal sensor detects that the object is in close proximity to the suction pad.

A movable harvesting apparatus includes an end effector including a suction port to suction a harvest object, a vacuum generator, vacuum spaces in which a vacuum is generated by the vacuum generator, a switching valve disposed in a path from the vacuum spaces to the suction port, and a controller to control opening and closing of the switching valve. The harvesting apparatus reduces wasteful energy consumption required for harvesting.

A component is placed by a nozzle of a placing head, which holds the component by means of a negative pressure. A flow path switcher that selectively connects a suction path of the nozzle to a negative pressure source and a positive pressure source is included. During component placement, the flow path switcher switches the nozzle to a positive pressure flow path from a negative pressure flow path to put the nozzle under a positive pressure and detaches the component from the nozzle. Before detection of the component is performed by a component detector, the flow path switcher connects the suction path of the nozzle to the negative pressure flow path to put the suction path under a negative pressure. The component detector that detects the component at a tip of the nozzle is included.