Provided is a document conveying apparatus that properly discharges documents regardless of the amount of documents stacked on a discharge tray without complicated construction of a transmission mechanism for transmitting a driving force to conveying rollers. A conveying roller pair is provided at an end portion on an upstream side. A swing mechanism swings a discharge mechanism centered around a drive shaft of the conveying roller pair. An upper surface height measuring unit measures the height of the upper surface of documents stacked on the discharge tray. A control unit, by causing the swing mechanism to swing the discharge mechanism according to the height measured by the upper surface height measuring unit, performs control so that the difference between a discharge port and the upper surface of the documents stacked on the discharge tray is within a specified range.

An image reading device includes: a controller which performs a first drive operation for rotating the discharge roller, and a second drive operation for moving the discharge guide between the third position and the fourth position. The controller stops the first drive operation when performing the second drive operation, and stops the second drive operation when performing the first drive operation.

An image reading device includes: a discharge guide including a discharge opening for discharging the sheet conveyed by the conveyance guide to the discharge tray, the discharge guide being configured to move from a third position to a fourth position according to the decrease in the number of the sheet to be supported by the supply tray, the fourth position being higher than the third position; a discharge roller configured to discharge the sheet through the discharge opening; and a first drive source which generates a first drive force for moving the discharge guide between the third position and the fourth position, wherein the first drive force is also used for rotating the discharge roller.

A sheet conveyance unit includes a sheet inlet port, an inlet guide, and a guide switching mechanism. The inlet guide has an upper guide and a lower guide below the upper guide. The guide switching mechanism switches a position of the inlet guide between a conveyance position at which the upper guide and the lower guide face each other with a first distance and a separation position at which the upper guide and the lower guide are spaced from each other by a second distance greater than the first distance. To connect the sheet conveyance unit to the sheet discharge unit, the inlet guide is disposed to the separation position before the discharge guide is inserted between the upper guide and the lower guide, and is disposed to the conveyance position after the discharge guide is inserted between the upper guide and the lower guide.

An image reading apparatus includes: a supply tray, which supports sheets to be supplied and includes a movable plate configured to move from a first position to a second position as the sheet supported by the supply tray is decreased, the second position being higher than the first position; a discharge tray; a conveyance guide; a reading sensor; a discharge unit, which includes a discharge opening to discharge the sheet conveyed by the conveyance guide to the discharge tray and is configured to move from a third position to a fourth position as the sheet supported by the paper feed tray is decreased, the fourth position being higher than the third position; and a first drive source, which generates a drive force, wherein the discharge unit is configured to move by receiving the drive force and to transmit the drive force to the movable plate.

A discharge unit includes a first discharge guide which guides the sheet conveyed by the conveyance guide, a second discharge guide which includes the discharge opening, and guides the sheet guided by the first discharge guide toward the discharge tray, and a discharge roller and a discharge pinch roller which are provided in the second discharge guide. The first discharge guide is rotatable around a first axis which is parallel with an axial direction of the discharge roller. The second discharge guide is connected to the first discharge guide to be rotatable around a second axis which is parallel with the first axis. An angle at which the second discharge guide is inclined with respect to a sheet supporting surface in the discharge tray is constant while the discharge unit is moving from the third position up to the fourth position.

A paper reversing apparatus includes a main conveyance path, a reversing path, first and second guiding plates and a hardware processor. The reversing path is disposed so as to form a predetermined angle with respect to the main conveyance path. Paper enters the reversing path from the main conveyance path and leaves the reversing path to the main conveyance path by being sent backward. When paper enters the reversing path, the processor moves the first guiding plate to a position for the paper to follow the first guiding plate and moves the second guiding plate to a position to avoid the paper. When paper leaves the reversing path, the processor moves the second guiding plate to a position for the paper to follow the second guiding plate and moves the first guiding plate to a position to avoid the paper.

An image forming apparatus includes an image forming section, a discharging roller pair, a plurality of trays, a guide member, and a controller. The image forming section forms an image on each of a plurality of sheets. The discharging roller pair discharges each of the sheets. The sheets discharged by the discharging roller pair are to be stacked on the trays (first through third trays). The guide member guides each of the sheets from the discharging roller pair toward a discharge destination tray among the plurality of trays. Every time the discharging roller pair discharges one of the sheets, the controller controls the guide member to change the discharge destination tray. The trays are configured such that leading ends of the sheets are superposed on one another.

A method for franking packages individually supplied from a stack on a conveyor line to a franking machine, such as envelopes, mailing bags, sleeves, cards, labels, printed products, or the like, which are removed at the lower side of the stack for separation and which are supplied on the upstream conveyor line to a printing mechanism of the franking machine and which, after printing of the packages, are discharged from the franking machine. The packages are supplied on the conveyor portion via a switch to the franking machine and after printing are supplied counter to the supply direction from the printing mechanism of the franking machine via the transposed switch of a depositing device which is provided therebelow for printed packages.

An image reading apparatus includes: a supply tray; a discharge tray, which is positioned below the supply tray to support the sheet; a conveyance guide, which conveys the sheet from the supply tray to the discharge tray; a reading sensor, which reads an image on the sheet conveyed on the conveyance guide; a discharge unit, which includes a discharge port to discharge the sheet conveyed by the conveyance guide to the discharge tray and is configured to move from a third position to a fourth position, the fourth position being higher than the third position; a first drive source, which generates a drive force; and a second drive source, which generates a drive force, wherein the movable plate is moved by the drive force from the first drive source, and the discharge unit is moved by the drive force from the second drive source.