Disclosed is a method for the automated transfer of an intraocular lens (1) comprising an optical lens body (10) and two haptics (11) attached to a peripheral edge of the optical lens body (10) and extending outwardly from the peripheral edge of the optical lens body (10). The method comprises the steps of: picking the intraocular lens (1) up at a start location; moving the intraocular lens (1) to a destination location; releasing the intraocular lens (1) at the destination location,
wherein picking the intraocular lens (1) up at the start location comprises gripping the intraocular lens (1) only at the haptics (11) of the intraocular lens (1).

Disclosed is a method for the automated transfer of an intraocular lens (1) comprising an optical lens body (10) and two haptics (11) attached to a peripheral edge of the optical lens body (10) and extending outwardly from the peripheral edge of the optical lens body (10). The method comprises the steps of: picking the intraocular lens (1) up at a start location; moving the intraocular lens (1) to a destination location; releasing the intraocular lens (1) at the destination location,
wherein picking the intraocular lens (1) up at the start location comprises gripping the intraocular lens (1) only at the haptics (11) of the intraocular lens (1).

A vacuum chuck system may include a vacuum chuck and a vacuum stopper collection and dispensing system. The vacuum chuck may include a ceramic plate with a retaining surface. The retaining surface may include a plurality of depressions and a plurality of openings, each of the openings being disposed on a bottom surface of one of the depressions and fluidly coupled to a vacuum pump. Vacuum stoppers may be used to seal one or more of the openings so as to restrict the vacuum area of the vacuum chuck. The vacuum stopper collection and dispensing system may be used to collect vacuum stoppers from and dispense vacuum stoppers onto the retaining surface. In addition or in the alternative, an electromagnet or a robotic arm may be used to move a vacuum stopper from a blocking position to a non-blocking position on the retaining surface.

Robotic systems with variable gripping mechanisms, and related systems and methods are disclosed herein. In some embodiments, the robotic system includes a robotic arm and an object-gripping assembly coupled to the robotic arm. The object-gripping assembly can include a main body coupled to the robotic arm through an external connector on an upper surface of the main body and a vacuum operated gripping component coupled to a lower surface of the main body. The object-gripping assembly can also include a variable-width gripping component coupled to the main body. The variable-width gripping component is movable between a fully folded state, a plurality of extended states, and a clamping state to grip a variety of target objects of varying shapes, sizes, weights, and orientations.

Robotic systems with variable gripping mechanisms, and related systems and methods are disclosed herein. In some embodiments, the robotic system includes a robotic arm and an object-gripping assembly coupled to the robotic arm. The object-gripping assembly can include a main body coupled to the robotic arm through an external connector on an upper surface of the main body and a vacuum operated gripping component coupled to a lower surface of the main body. The object-gripping assembly can also include a variable-width gripping component coupled to the main body. The variable-width gripping component is movable between a fully folded state, a plurality of extended states, and a clamping state to grip a variety of target objects of varying shapes, sizes, weights, and orientations.

A tool-holding arm includes a plurality of links and a tool coupling that removably secures a tool to the tool-holding arm. A first fluid spring provides a gravity-counteracting force to the tool-holding arm. A locking mechanism selectively locks the first fluid spring. An adjustment mechanism selectively adjusts an amount of the gravity-counteracting force provided by the first fluid spring.

A tool-holding arm includes a plurality of links and a tool coupling that removably secures a tool to the tool-holding arm. A first fluid spring provides a gravity-counteracting force to the tool-holding arm. A locking mechanism selectively locks the first fluid spring. An adjustment mechanism selectively adjusts an amount of the gravity-counteracting force provided by the first fluid spring.

A suction cup for engaging and lifting an object is disclosed, comprising a lip, a bellows, and an upper portion sealingly connected to the bellows for connecting an inner volume of the suction cup to a source of vacuum, which cup, in an operative state, is capable of being locked in an at least partly compressed state of the lip and/or bellows. Locking is accomplished by air entrapped in a sealed exterior volume formed between the lip and bellows and/or between one or more segments of the bellows in an operative state being evacuated through one or more through open holes provided in the lip and/or bellows when vacuum is connected to the suction cup. A corresponding lip and a corresponding bellows for use in the suction cup are also disclosed.

A vacuum device for a material handling system includes a vacuum device body and a sealing element. The vacuum device body has a vacuum passageway in which a vacuum is generated in response to activation of a pressurized air supply that forces pressurized air through a venturi device. The sealing element moves to a sealing position to substantially seal the vacuum passageway when the air supply is activated, and is urged toward the sealing position via pressurized air that is diverted from an inlet of the vacuum device to the sealing element. The sealing element moves to substantially vent the vacuum passageway when the air supply is deactivated. The vacuum passageway may be in fluid communication with a vacuum cup, which seals against the object when the sealing element is at the sealing position and the vacuum generating device generates at least a partial vacuum in the vacuum passageway.

A vacuum device for a material handling system includes a vacuum device body and a sealing element. The vacuum device body has a vacuum passageway in which a vacuum is generated in response to activation of a pressurized air supply that forces pressurized air through a venturi device. The sealing element moves to a sealing position to substantially seal the vacuum passageway when the air supply is activated, and is urged toward the sealing position via pressurized air that is diverted from an inlet of the vacuum device to the sealing element. The sealing element moves to substantially vent the vacuum passageway when the air supply is deactivated. The vacuum passageway may be in fluid communication with a vacuum cup, which seals against the object when the sealing element is at the sealing position and the vacuum generating device generates at least a partial vacuum in the vacuum passageway.