Process and apparatus for applying noise reducing elements to tyres for vehicle wheels. The apparatus includes a loading station of stacks of noise reducing elements, an extraction station of noise reducing elements from each stack placed downstream of the loading station, and a conveyor placed downstream of the extraction station and extending along a predefined path. The conveyor is configured for supporting and advancing in a row the noise reducing elements extracted from the stacks which are then applied to a radially inner surface of the tyres. The extraction of each of the noise reducing elements contemplates: retaining a first noise reducing element placed at the base of a stack; raising the remaining noise reducing elements of the stack from the first noise reducing element; moving away the first noise reducing element according to a set path; and lowering the remaining noise reducing elements of the stack.

A modular radial impeller drum for cooling print media in a printing device are disclosed. For example, the modular radial impeller drum includes a plurality of impeller modules coupled together to form a surface to transport the print media. Each one of the plurality of impeller modules includes a cylindrical outer surface, a cylindrical center axis inside of the cylindrical outer surface, and a plurality of impeller blades coupled between the cylindrical outer surface and the cylindrical center axis, wherein the plurality of impeller blades the plurality of impeller modules is varied across a length of the modular radial impeller drum.

A modular radial impeller drum for cooling print media in a printing device are disclosed. For example, the modular radial impeller drum includes a plurality of impeller modules coupled together to form a surface to transport the print media. Each one of the plurality of impeller modules includes a cylindrical outer surface, a cylindrical center axis inside of the cylindrical outer surface, and a plurality of impeller blades coupled between the cylindrical outer surface and the cylindrical center axis, wherein the plurality of impeller blades the plurality of impeller modules is varied across a length of the modular radial impeller drum.

A modular radial impeller drum for cooling print media in a printing device are disclosed. For example, the modular radial impeller drum includes a plurality of impeller modules coupled together to form a surface to transport the print media. Each one of the plurality of impeller modules includes a cylindrical outer surface, a cylindrical center axis inside of the cylindrical outer surface, and a plurality of impeller blades coupled between the cylindrical outer surface and the cylindrical center axis, wherein the plurality of impeller blades the plurality of impeller modules is varied across a length of the modular radial impeller drum.

Provided is a technique capable of detecting the amount of a stack of discharged print media and increasing print speed. A printing apparatus includes a displacement member configured to be in contact with the discharged print media and be displaced according to the amount of the stack of the print media, and detects the stack amount based on the displacement of the displacement member. The apparatus performs a first or second detection operation based on the detected stack amount. In the first detection operation, after a specified number of print media are discharged with the displacement member positioned at the evacuation position where it does not come into contact with a print medium, the displacement member is brought into contact with the print media to detect the stack amount. In the second detection operation, the stack amount is detected with the displacement member in contact with the print media.

A scanner includes a reading unit that reads an image of a paper, a medium feeding portion that is capable of selecting a first feeding mode in which a separation feeding for separately feeding a paper bundle in which a plurality of sheets of paper is overlapped with each other is performed and a second feeding mode in which a non-separation feeding for collectively feeding the paper bundle without separating is performed, and a pair of first transporting rollers and a pair of second transporting rollers that transport the paper fed by the medium feeding portion, in a case in which the medium feeding portion feeds the paper in the second feeding mode, a first driven roller and a second driven roller respectively constituting the pair of first transporting rollers and the pair of second transporting rollers are driven in a rotation direction where the paper is transported.

A reloading supply system includes a loading cart (100) and a machine (200). The loading cart has a first material tray (120) that includes a first combed surface (122) configured to retain a supply material in the first material tray. The machine has a second material tray (220) that includes a second combed surface (222) configured to retain the supply material in the second material tray after the supply material is transferred from the first material tray of the loading cart to the second material tray of the machine. Teeth (124) of the first combed surface are configured to pass by teeth (224) of the second combed surface. The first combed surface and the second combed surface are configured such that the supply material in the first material tray is transferred to the second material tray as the teeth of the first combed surface pass by the teeth of the second combed surface.

A transport device stacks partial book blocks along a transport path formed of transfer paths, and includes: a first transfer path at a start of the transport device; a first separating element downstream of the first transfer path and upstream of a second transfer path; a second separating element downstream of the second transfer path and upstream of a processing machine that is operatively connected to the transport device; and a transition path which is arranged either upstream or downstream of the second separating element and within which a book block product that is to be introduced therein is transferable from a transport position where it is lying flat and into a transport position where it is guided standing up. At least one of the transfer paths is equipped with at least one sheet stack feed unit and/or at least one collator-feeder.

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.

Provided is an image forming apparatus capable of easily changing a scheduled stacking position of any image forming job. An image region in which an overall arrangement mode of the image forming apparatus and sheet discharge apparatus is displayed and a list region in which standby jobs are listed are displayed on a monitor screen. In the image region, a sheet bundle of the selected standby job is displayed on a tray that is set as the scheduled stacking position of the selected standby job. When the sheet bundle is selected and dragged and dropped by a mouse pointer on the monitor screen, the tray being set as the scheduled stacking position is changed, and a position at which the sheet bundle is displayed is also changed.