Squaring device and counter ejector, and box-manufacturing machine

What is claimed is: 1. A squaring device provided to a counter ejector part that stops flat cardboard boxes fed from an upstream, using a front stop, in a downstream part of a box-manufacturing machine, receives and stacks the flat cardboard boxes in a stacking part in a hopper part, and ejects the stack as a batch, the squaring device comprising: a squaring plate that, while the stacking part retains in a stack position during an retention interval, squares the cardboard boxes stacked on the stacking part, in conjunction with the front stop, the retention interval being set in accordance with a feed speed of the cardboard boxes and a count setting for a stack of the cardboard boxes; and a reciprocation driving unit that drives the squaring plate to reciprocate in directions approaching to or departing from the front stop, wherein: the reciprocation driving unit comprises an actuator provided independently from a feed driving unit for feeding the cardboard boxes, and a control unit that controls the actuator to operate such that an operating speed of the actuator for driving the reciprocations equals a speed setting; the control unit comprises a modification section that modifies the speed setting; the modification section is configured to set the speed setting as a magnification of the squaring speed to the feed speed; and the reciprocation driving unit is configured capable of varying a speed ratio of a squaring speed for reciprocating the squaring plate, to the feed speed. 2. The squaring device according to claim 1 , wherein the stacking part is an elevator base that retains in an elevated position that is the stack position during the retention interval, the retention interval being set in accordance with the feed speed of the cardboard boxes and the count setting for a stack of the cardboard boxes. 3. The squaring device according to claim 1 , wherein the control unit comprises: a data storage section that stores speed setting data that relates the speed setting modified by the modification section, to the feed speed and the count setting at that time; and an automatic setting section that, in response to a change in an order for the box-manufacturing machine, if the speed setting data corresponding to the new order is stored in the data storage section, automatically retrieves a speed setting corresponding to a feed speed and a count setting of the new order, using the speed setting data. 4. The squaring device according to claim 1 , wherein the control unit comprises: a data storage section that stores in advance a series of speed setting data that relates speed settings to corresponding feed speeds and count settings, in a form of a database; and an automatic setting section that, in response to a change in an order for the box-manufacturing machine, automatically retrieves a speed setting corresponding to a feed speed and a count setting of the new order, using the database stored in the data storage section. 5. The squaring device according to claim 1 , wherein a value of two or greater is set as a default value for the magnification value. 6. The squaring device according to claim 1 , wherein, in a low speed region of the feed speed, a value greater than that for a high speed region of the feed speed, is set as a default value for the magnification value. 7. The squaring device according to claim 1 , wherein the actuator comprises: an electric motor, rotations of which are controlled by the control unit; a motion converting mechanism that converts a rotation motion of the electric motor into a reciprocating motion, and transmits the reciprocating motion to the squaring plate; and a linear guide member that guides the squaring plate to reciprocate in a predetermined direction. 8. The squaring device according to claim 7 , wherein the motion converting mechanism comprises: a squaring shaft that rotates, while a position of a rotation axis of the squaring shaft being fixed; an eccentric part comprising an eccentric outer circumferential face that protrudes from an outer periphery of the squaring shaft and has an eccentricity relative to the rotation axis; and a link member comprising a ring part having an inner circumferential surface that slidably engages with the eccentric outer circumferential face at one end, and a coupling part that couples to an end of the squaring plate with a pin at the other end, wherein the motion converting mechanism is configured to convert the rotation motion into the reciprocating motion at an sliding interface between the eccentric outer circumferential face and the inner circumferential surface of the ring part , and to transmit a motion by a belt pulley mechanism between the electric motor and the squaring shaft.