In some examples, a substrate handling system includes a sheet processing machine and at least one alignment device that includes at least four stops. At least one stop is configured as a front stop, at least one stop is configured as a rear stop, and at least two stops are configured as lateral stops. The at least two lateral stops are arranged opposite one another, and the at least one front stop and the at least one rear stop are arranged opposite one another. The alignment device includes at least one support element that is configured as a propping element for propping at least one partial stack of sheets in the alignment device. Further, at least one respective support element is arranged at the at least two lateral stops and at the at least one rear stop.

A substrate handling system including an infeed system for feeding stacked substrates and including a processing machine for processing stacked substrates, and in particular a printing press for printing stacked substrates. A robot cell is provided between the infeed system and the processing machine. The robot cell comprises one or two gripper systems, each for handling a plurality of substrates. The robot cell is configured in such a way, that selectively differently stacked substrates, which are feedable by the infeed system, can be handled.

Disclosed is an automated insert feeding system and related methods, capable of removing bulk-packaged items from a tray or other package, and separating the bulk-packaged items individually for distribution into individual packages in high speed reliable fashion. The disclosed systems can also be loaded with multiple packages of the pre-packaged items for automatic feeding into the system which allows human operators to load several packages and allow the system to work unattended, thereby reducing man-hours spend on the process.

Disclosed is an automated insert feeding system and related methods, capable of removing bulk-packaged items from a tray or other package, and separating the bulk-packaged items individually for distribution into individual packages in high speed reliable fashion. The disclosed systems can also be loaded with multiple packages of the pre-packaged items for automatic feeding into the system which allows human operators to load several packages and allow the system to work unattended, thereby reducing man-hours spend on the process.

A machine (100) for unstacking objects (10) includes a belt mechanism (110, 120, 121, 130) having a conveyor belt (110), a first drive mechanism (115) for driving the conveyor belt (110), a second drive mechanism (120, 121) for shifting the conveyor belt (110) between a forwarded position and a retracted position, and a third drive mechanism (130) for adjusting a height position of the conveyor belt (110). Further, the machine (100) includes a gripper mechanism (150, 160) having a gripper (150) and a fourth drive mechanism (160) for moving the gripper (150) between different height positions. A controller of the machine (100) is configured to control the gripper mechanism (150, 160) to grip an end portion of an uppermost object (10) of a stack (20) and lift the end of the uppermost object (10), to control the second drive mechanism (120, 121) and the third drive mechanism (130) to position a forward end of the conveyor belt (110) below the lifted end portion of the uppermost object (10), and to control the first drive mechanism (110) and the second drive mechanism (120, 121) to operate in a coordinated manner by shifting the conveyor belt (110) towards the forwarded position while at the same time driving the conveyor belt (110) in a backwards direction to draw the uppermost object (10) onto the conveyor belt (110).

A machine (100) for unstacking objects (10) includes a belt mechanism (110, 120, 121, 130) having a conveyor belt (110), a first drive mechanism (115) for driving the conveyor belt (110), a second drive mechanism (120, 121) for shifting the conveyor belt (110) between a forwarded position and a retracted position, and a third drive mechanism (130) for adjusting a height position of the conveyor belt (110). Further, the machine (100) includes a gripper mechanism (150, 160) having a gripper (150) and a fourth drive mechanism (160) for moving the gripper (150) between different height positions. A controller of the machine (100) is configured to control the gripper mechanism (150, 160) to grip an end portion of an uppermost object (10) of a stack (20) and lift the end of the uppermost object (10), to control the second drive mechanism (120, 121) and the third drive mechanism (130) to position a forward end of the conveyor belt (110) below the lifted end portion of the uppermost object (10), and to control the first drive mechanism (110) and the second drive mechanism (120, 121) to operate in a coordinated manner by shifting the conveyor belt (110) towards the forwarded position while at the same time driving the conveyor belt (110) in a backwards direction to draw the uppermost object (10) onto the conveyor belt (110).

A divider for dividing a pack of flat-folded cartons into a plurality of stacks of flat-folded cartons, the divider comprising a magazine adapted to hold the carton pack, where the magazine includes a stop member, and where the divider includes a pusher member and a holder foot, where the magazine is arranged in an inclined position, where the pusher member is adapted to compress the carton pack between the pusher member and the stop member, where the holder foot is adapted to bear on the upper side of the compressed carton pack, and where the pusher member is adapted to release the pressure on the carton pack when the holder foot bears on the upper side of the carton pack, thereby creating a low density area adjacent a first carton stack.

An image forming apparatus includes a sheet storing cassette, a lift mechanism, a sheet feeding portion, a remaining quantity sensing portion, and a control portion. The control portion, during continuous sheet feeding by the sheet feeding portion, controls the lift mechanism to make a sheet stacking plate ascend to a lifted position where sheets make contact with the sheet feeding portion, and feeds a foregoing sheet and then, at a sheet feeding timing a predetermined time thereafter, starts feeding the following sheet. The control portion makes the sheet feeding timing earlier as the remaining quantity of the sheets sensed by the remaining quantity sensing portion decreases.

An image forming apparatus includes a sheet storing cassette, a lift mechanism, a sheet feeding portion, a remaining quantity sensing portion, and a control portion. The control portion, during continuous sheet feeding by the sheet feeding portion, controls the lift mechanism to make a sheet stacking plate ascend to a lifted position where sheets make contact with the sheet feeding portion, and feeds a foregoing sheet and then, at a sheet feeding timing a predetermined time thereafter, starts feeding the following sheet. The control portion makes the sheet feeding timing earlier as the remaining quantity of the sheets sensed by the remaining quantity sensing portion decreases.

A print device comprising an input tray to receive a print media stack, and a load stop arm to manage print media feed, from the input tray, into a media loading path for printing. The load stop arm is to rotate between a media stacking state and a media feed state to manage the print media feed. The load stop arm comprising a trigger protrusion to move from a default position to a trigger position when the load stop arm rotates to the media stacking state in a low stack condition. The low stack condition indicates reduction of print media in the print media stack to an amount below a threshold value. Further, a media detection assembly is in contact with the trigger protrusion to enable generation of a low media signal to indicate the low stack condition when the trigger protrusion moves to the trigger position