A method for rapidly stacking and dropping sheets is provided. The method comprises receiving a plurality of sheets from a sheet delivery device onto a landing platform of a stacking and dropping apparatus. The method also comprises lowering the landing platform from an original upper position. Lowering comprises maintaining a drop height between the sheet delivery device and a stack of delivered sheets. The method also comprises sending a delay signal that comprises a command to delay the receiving of the plurality of sheets from the sheet delivery device. The delay signal is sent in response to a detection of a predetermined stack height of the stack of delivered sheets. The method also comprises sending a movement signal, immediately following the sending of the delay signal. The movement signal comprises a command to move the landing platform, such that the plurality of sheets are received by a catch tray unit. The method also comprises dropping, utilizing the catch tray unit, the plurality of sheets onto a sheet receiving device. The method also comprises returning, automatically, the landing platform to the original upper position. The method also comprises sending a resume signal, that includes a command to the sheet delivery device to resume sheet delivery. The delay signal, movement signal and resume signal are sent by a central processor component of the stacking and dropping apparatus.

An apparatus including a log accumulator is provided. The log accumulator can have logs load therein while they travel along a path that is generally parallel to a path along which the logs are separated from a building stream of sheets, such as when exiting a folder. The logs may be loaded into buckets of the accumulator without requiring lateral accelerations out of a mechanism transferring the separated logs to the accumulator. Similarly, logs may be initially removed from buckets of the accumulator without requiring lateral accelerations. Further, an accumulator unloading apparatus may initially index the logs perpendicular to a length to clear the path of the buckets of the accumulator and then accelerate the logs parallel to a length of the logs once removed from the path of the buckets.

A depalletizing machine for picking up and moving groups of articles, specifically bundles of blanks, includes a containing structure internally provided with at least one receiving area for a movable magazine containing one or more groups of articles. The machine also includes at least one access opening for allowing the magazine to be inserted into, or removed from, the receiving area. The machine also includes a collection zone configured for receiving a succession of groups of articles from the movable magazine and for moving the groups of articles towards the outside of the machine. The machine also includes at least one sensor configured for detecting a position of the movable magazine within the at least one receiving area and a pickup head configured to pick up groups of articles from the movable magazine and transferring them into the collection zone. The machine also includes a control unit configured for setting a predetermined law of motion for the pickup head as a function of at least one information item obtained from the sensor, regarding the position of the movable magazine.

A printer for printing plate-like media, in particular for printing marker cards with markers for marking electrical appliances includes a housing and at least one input station for the marker cards to be printed The printer further includes a printing station with a printing device and an output station for printed marker cards. The output station has a magazining device which has one or more guide devices so that the output station, with the magazining device, can be drawn from a position pushed into the housing into a position outside the housing and can be pushed back into the housing of the printer, Each guide device also has its own stacking unit which is pivotably mounted.

A sheet stacking system includes a conveyor having a discharge end, a hopper at the discharge end configured to receive the sheets ejected from the discharge end and guide the sheets as they fall in a cascade path onto a platform associated with the hopper, the falling sheets forming a main stack on the platform, the hopper including a backstop facing the discharge end of the conveyor such that the sheets ejected from the discharge end impact against the backstop before forming the main stack, and a first accumulator having at least one first support extending through the backstop and shiftable from a retracted position to an extended position, the at least one first support being movable vertically relative to the backstop in the extended position from a raised location outside the cascade path to a lowered location in the cascade path.

A banknote storage handling device 300 includes a lid unit opening/closing mechanism 410 that moves a lid unit 170 to an open position by moving to a spaced position in a state where the lid body 171 is latched, a loading table 450 that is configured to receive and load paper sheet bundles Bs moved outward from a lateral opening by a paper sheet bundle moving member in accordance with movement of the lid unit to the open position when at a lifted standby position, and to be capable of being lowered from the standby position to a lowered position in a state where the paper sheet bundles are loaded thereon, and a loading table movement mechanism 560 that moves the loading table located at the lowered position to a predetermined paper sheet bundle discharge position.

Personnel saving of a process from a printer to a sheet processing machine is achieved. A general printing management device is connected to be communicable with a conveyance management device that manages a plurality of automatic guided vehicles each conveying a stacker in which paper ejected from a printer is stackable. The general printing management device generates conveyance instruction information for conveying a stacker in which paper ejected from the printer is stacked from a sheet receiving position of the printer to a sheet supply position of a next processing machine, based on job information in which a manufacturing process procedure for manufacturing a printed product is registered, and transmits the conveyance instruction information to the conveyance management device.

A magazine for packs of blanks includes a vertical channel configured for inserting and extracting packs of blanks, a succession of groups of supporting parts movable between a retracted position to allow the packs of blanks to move along the channel towards a portion under the supporting part, and an at least partly extracted position, in which the supporting part intercepts a pack of blanks moving down the channel and provides a steady support for the pack of blanks, and transmission means configured to automatically move each supporting part from the retracted position to the at least partly extracted position when the supporting part immediately below it intercepts a respective pack of blanks, thereby defining the steady support.

A paper sheet handling apparatus includes: a first stopper that is in contact with a first partition at a lower limit position of the first partition; and a pressing portion that is fixed to a second partition and raises and lowers the first partition integrally with the second partition using a frictional force generated by pressing a guide. The second partition descends integrally with the first partition, and after the first partition comes into contact with the first stopper, the second partition descends independently of the first partition against the frictional force to a position where the pressing portion faces the recessed portion that cancels the frictional force. The second partition, when ascending from the position where the pressing portion faces the recessed portion to a position where the pressing portion no longer faces the recessed portion, ascends integrally with the first partition due to the frictional force.