This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2014-087252 filed on Apr. 21, 2014.
The present invention relates to a binding component that binds a plurality of sheets of paper drilled with holes to make a booklet.
Conventionally, there is a binding component that is referred to as a binder for binding commercially available loose-leaf papers or papers punched by a punch.
Such a binding component has a configuration in which a plurality of annular ring parts is connected by a back part. Each of the ring parts divided into multiple pieces is connected by a flexible hinge portion so that the ring part can be opened and closed.
For example, JP-A-2000-289376 discloses a configuration in which a two-split ring part is connected by a flexible hinge portion. Further, JP-B-5023588 discloses a configuration in which a three-split ring part is connected by a flexible hinge portion, for example.
Furthermore, JP-A-2002-502728 discloses a configuration in which a lock mechanism is provided in a hinge portion, for example.
In the configuration in which the split ring part is connected by the flexible hinge portion, a load is applied to the hinge portion when a booklet bound by a binding component is dropped, for example, and a load is thus applied to the ring part. As a result, there is a possibility that the hinge portion is damaged and the ring part is thus separated.
By providing a lock mechanism in the hinge portion, it is possible to receive a load from a certain direction. However, it is difficult to correspond to a load from any direction.
The present invention is made to improve the above-described issues and an object thereof is to provide a binding component that is capable of preventing the damage of the hinge portion.
A binding component of the present invention includes ring back portions, first ring arm portions, second ring arm portions and a back part. Each ring back portion is configured to be an annular ring part. Each first ring arm portion is configured to be the annular ring part and connects to one end of the ring back portion by a hinge portion. Each second ring arm portion is configured to be the annular ring part and connects to the other end of the ring back portion by a hinge portion. The ring back portions are connected to the back part at predetermined intervals. Each ring part includes fitting portions (i) at a place where the first ring arm portion and the ring back portion are connected to each other and (ii) at a place where the second ring arm portion and the ring back portion are connected to each other. The fitting portions are configured to be fitted by an operation of opening and closing the first ring arm portion and the second ring arm portion with (i) the hinge portion of the one end of the ring back portion as a support point and (ii) the hinge portion of the other end of the ring back portion as a support point. Each fitting portion includes at least one first fitting convex portion, at least one first fitting concave portion, at least one second fitting convex portion and a second fitting concave portion. The at least one first fitting convex portion is at an end of the first ring arm portion or at an end of the second ring arm portion. The said end is opposite to the ring back portion. The at least one first fitting concave portion is at the one end of the ring back portion opposite to the first ring arm portion or at the other end of the ring back portion opposite the second ring arm portion. The first fitting convex portion is configured to be fitted into the first fitting concave portion. The at least one second fitting convex portion is at the one end of the ring back portion opposite to the first ring arm portion or at the other end of the ring back portion opposite the second ring arm portion. The second fitting concave portion is at the end of the first ring arm portion or the end of the second ring arm portion. The second fitting convex portion is configured to be fitted into the second fitting concave portion. The first fitting convex portion includes a first convex-side load receiving surface at an outwardly facing surface opposite to the first fitting concave portion. The first fitting concave portion includes a first concave-side load receiving surface at an inwardly facing surface opposite to the first convex-side load receiving surface. The second fitting convex portion includes a second convex-side load receiving surface at an outwardly facing surface opposite to the second fitting concave portion. The second fitting concave portion includes a second concave-side load receiving surface at an inwardly facing surface opposite to the second convex-side load receiving surface. The first fitting convex portion includes a third convex-side load receiving surface at a width direction surface opposite to the first fitting concave portion. The first fitting concave portion includes a third concave-side load receiving surface at a width direction surface opposite to the third convex-side load receiving surface.
In the binding component of the present invention, when the first fitting convex portion is fitted into the first fitting concave portion by an operation of closing the first ring arm portion and the second ring arm portion, the first convex-side load receiving surface of the first fitting convex portion comes into contact with the first concave-side load receiving surface of the first fitting concave portion. Further, the third convex-side load receiving surface of the first fitting convex portion comes into contact with the third concave-side load receiving surface of the first fitting concave portion.
Further, when the second fitting convex portion is fitted into the second fitting concave portion, the second convex-side load receiving surface of the second fitting convex portion comes into contact with the second concave-side load receiving surface of the second fitting concave portion.
As a result, in the operation of closing the first ring arm portion and the second ring arm portion, the first fitting convex portion and the first fitting concave portion, and the second fitting convex portion and the second fitting concave portion serve as a guide in a width direction and a thickness direction.
Further, when a load of the impact such as dropping is applied, from any direction, to places where the first ring arm portion and the ring back portion are connected to each other and where the second ring arm portion and the ring back portion are connected to each other, this load is received by a combination of any one of the convex-side load receiving surfaces and the concave-side load receiving surfaces, so that the load applied to the hinge portion is reduced.
According to the binding component of the present invention, the concavo-convex shapes of the fitting portion are started to fit each other by the closing operation of the first ring arm portion and the second ring arm portion, so that the closing operation of the first ring arm portion and the second ring arm portion is guided. The first ring arm portion and the second ring arm portion can be closed at an accurate position.
When the first ring arm portion and the second ring arm portion are closed and thus the ring part becomes an annular shape, the concavo-convex shapes of the fitting portion are fitted each other to receive a load when a force is applied from the outside, for example. Accordingly, it is possible to suppress the damage of the hinge portion or the like.
Hereinafter, an illustrative embodiment of a binding component of the present invention will be described with reference to the drawings.
<Configuration Example of Binding Component of Present Embodiment>
Each of the ring parts 2A includes a ring back portion 20 connected by the back part 3A, a first ring arm portion 20R connected to one end of the ring back portion 20 and a second ring arm portion 20L connected to the other end of the ring back portion 20. Each of the ring parts 2A is configured as an annular shape by a combination of three members of the ring back portion 20, the first ring arm portion 20R and the second ring arm portion 20L.
The ring parts 2A are stored in a paper processing device (to be described later) in a state where the first ring arm portion 20R and the second ring arm portion 20L are opened. The first ring arm portion 20R and the second ring arm portion 20L are closed by a binding operation in the paper processing device, so that a booklet is bound. Further, the first ring arm portion 20R and the second ring arm portion 20L are manually opened and closed, so that papers are added and removed.
The ring back portion 20 has an arc shape that configures a portion of the annular ring part 2A. The first ring arm portion 20R has an arc shape that configures a portion of the annular ring part 2A. The first ring arm portion 20R is connected to one end of the arc of the ring back portion 20 in a circumferential direction by a hinge portion 21R. The second ring arm portion 20L has an arc shape that configures a portion of the annular ring part 2A. The second ring arm portion 20L is connected to the other end of the arc of the ring back portion 20 in the circumferential direction by a hinge portion 21L.
The hinge portion 21R is a place where the first ring arm portion 20R and the ring back portion 20 are connected to each other. The hinge portion 21R is configured by integrally molding a thin-shape portion on an outer peripheral side of the arc of the first ring arm portion 20R and the ring back portion 20. The thin-shape portion has a deformable thickness.
The first ring arm portion 20R is rotatably connected to the ring back portion 20 by the deformable hinge portion 21R, and the hinge portion 21R serves as a support point. In this way, the first ring arm portion 20R of the ring part 2A is opened and closed by a rotation operation using the hinge portion 21R as a support point.
The hinge portion 21L has the same configuration as the hinge portion 21R. The hinge portion 21L is a place where the second ring arm portion 20L and the ring back portion 20 are connected to each other. The hinge portion 21L is configured by integrally molding a thin-shape portion on an outer peripheral side of the arc of the second ring arm portion 20L and the ring back portion 20. The thin-shape portion has a deformable thickness.
The second ring arm portion 20L is rotatably connected to the ring back portion 20 by the deformable hinge portion 21L, and the hinge portion 21L serves as a support point. In this way, the second ring arm portion 20L of the ring part 2A is opened and closed by a rotation operation using the hinge portion 21L as a support point.
The ring part 2A includes a fitting portion 22R on an inner peripheral side of the arc of the first ring arm portion 20R and the ring back portion 20. The fitting portion 22R is a place where the first ring arm portion 20R and the ring back portion 20 are connected to each other. Further, the ring part 2A includes a fitting portion 22L on an inner peripheral side of the arc of the second ring arm portion 20L and the ring back portion 20. The fitting portion 22L is a place where the second ring arm portion 20L and the ring back portion 20 are connected to each other.
The fitting portion 22R has a concavo-convex shape that is engageable and fitted by a rotation operation of the first ring arm portion 20R, which uses the hinge portion 21R as a support point. Similarly, the fitting portion 22L has a concavo-convex shape that is engageable and fitted by a rotation operation of the second ring arm portion 20L, which uses the hinge portion 21L as a support point.
In the ring part 2A, the fitting by the concavo-convex shape of the fitting portion 22R and the fitting by the concavo-convex shape of the fitting portion 22L are started by a closing operation of the first ring arm portion 20R and the second ring arm portion 20L. In this way, the opening and closing operation of the first ring arm portion 20R and the second ring arm portion 20L is guided.
Further, the ring part 2A forms an annular shape when the first ring arm portion 20R and the second ring arm portion 20L are closed. In this case, the concavo-convex shape of the fitting portion 22R is fitted and the concavo-convex shape of the fitting portion 22L is fitted to receive a load when a force is applied from the outside, for example. As a result, the damage of the hinge portion 21R and the hinge portion 21L or the like is suppressed.
Subsequently, the fitting portion 22R and the fitting portion 22L, which are capable of receiving a load, are described in detail. Here, in the ring back portion 20, the first ring arm portion 20R and the second ring arm portion 20L, a radial direction of the arc of the annular ring part 2A is referred to as a thickness and an extension direction of a center axis of the arc of the annular ring part 2A is referred to as a width.
The fitting portion 22R includes a first fitting convex portion 23 at an end of the first ring arm portion 20R opposite to the ring back portion 20 that is connected to the first ring arm portion 20R by the hinge portion 21R. Further, the fitting portion 22R includes a first fitting concave portion 24 at an end of the ring back portion 20 opposite to the first ring arm portion 20R that is connected to the ring back portion 20 by the hinge portion 21R. The first fitting convex portion 23 is fitted into the first fitting concave portion 24.
Additionally, the fitting portion 22R includes second fitting convex portions 25 at an end of the ring back portion 20 opposite to the first ring arm portion 20R. Further, the fitting portion 22R includes second fitting concave portions 26 at an end of the first ring arm portion 20R opposite to the ring back portion 20. The second fitting convex portions 25 are fitted into the second fitting concave portions 26.
The first fitting convex portion 23 is configured by a convex portion at the center of the first ring arm portion 20R in a width direction. The convex portion is projected toward the ring back portion 20. The first fitting concave portion 24 is configured by a concave portion at the center of the ring back portion 20 in a width direction. An inner peripheral surface of the concave portion and an end of the concave portion opposite to the first ring arm portion 20R are open. The concave portion has a shape into which the first fitting convex portion 23 is fitted.
The second fitting convex portions 25 are configured by convex portions at both sides of the first fitting concave portion 24 in the width direction of the ring back portion 20. The convex portions are projected toward the first ring arm portion 20R. The second fitting concave portions 26 are configured by concave portions at both sides of the first fitting convex portion 23 in the width direction of the first ring arm portion 20R. An inner peripheral surface of the concave portions and an end of the concave portions opposite to the ring back portion 20 are open. The concave portions have a shape into which the second fitting convex portions 25 are fitted.
The first fitting convex portion 23 includes a first convex-side load receiving surface 23a. The first convex-side load receiving surface 23a is formed at an outwardly facing surface of the annular ring part 2A opposite to the first fitting concave portion 24. The first fitting concave portion 24 includes a first concave-side load receiving surface 24a. The first concave-side load receiving surface 24a is formed at an inwardly facing surface of the annular ring part 2A opposite to the first convex-side load receiving surface 23a of the first fitting convex portion 23.
The second fitting convex portion 25 includes a second convex-side load receiving surface 25a. The second convex-side load receiving surface 25a is formed at an outwardly facing surface of the annular ring part 2A opposite to the second fitting concave portion 26. The second fitting concave portion 26 includes a second concave-side load receiving surface 26a. The second concave-side load receiving surface 26a is formed at an inwardly facing surface of the annular ring part 2A opposite to the second convex-side load receiving surface 25a of the second fitting convex portion 25.
The first fitting convex portion 23 includes a third convex-side load receiving surface 23b. The third convex-side load receiving surface 23b is formed at both sides in the width direction of the annular ring part 2A and is opposite to the first fitting concave portion 24. The first fitting concave portion 24 includes a third concave-side load receiving surface 24b. The third concave-side load receiving surface 24b is formed at an inwardly facing surface in the width direction of the annular ring part 2A and is opposite to the third convex-side load receiving surface 23b of the first fitting convex portion 23.
In the present example, the first fitting concave portion 24 is formed adjacent to and on the inner side of the second fitting convex portion 25. Accordingly, the third concave-side load receiving surface 24b is configured as a surface facing the inner side of the first fitting concave portion 24 and facing the inner side of the second fitting convex portion 25.
When the first ring arm portion 20R and the second ring arm portion 20L are closed and the annular ring part 2A is thus formed, the first fitting convex portion 23 in the fitting portion 22R is fitted into the first fitting concave portion 24 at a place where the first ring arm portion 20R and the ring back portion 20 are connected to each other. Further, the second fitting convex portion 25 is fitted into the second fitting concave portion 26.
When the first fitting convex portion 23 is fitted into the first fitting concave portion 24, the first convex-side load receiving surface 23a of the first fitting convex portion 23 comes into contact with the first concave-side load receiving surface 24a of the first fitting concave portion 24. Further, the third convex-side load receiving surface 23b of the first fitting convex portion 23 comes into contact with the third concave-side load receiving surface 24b of the first fitting concave portion 24.
Additionally, when the second fitting convex portion 25 is fitted into the second fitting concave portion 26, the second convex-side load receiving surface 25a of the second fitting convex portion 25 comes into contact with the second concave-side load receiving surface 26a of the second fitting concave portion 26.
In this way, the first fitting convex portion 23 and the first fitting concave portion 24 are fitted in a concavo-convex shape that is formed in a thickness direction of the first ring arm portion 20R and the ring back portion 20. Further, the second fitting convex portion 25 and the second fitting concave portion 26 are fitted in a concavo-convex shape that is formed in the thickness direction of the first ring arm portion 20R and the ring back portion 20. In addition, the first fitting convex portion 23 and the first fitting concave portion 24, and the second fitting convex portion 25 and the second fitting concave portion 26 are fitted in a concavo-convex shape that is formed in a width direction of the first ring arm portion 20R and the ring back portion 20.
The fitting portion 22R is configured in such a way that, in the opening and closing operation using the hinge portion 21R as a support point, the pathway of the first fitting convex portion 23 does not overlap with the first fitting concave portion 24 and the pathway of the second fitting convex portion 25 does not overlap with the second fitting concave portion 26. Accordingly, in the operation of opening and closing the first ring arm portion 20R with the hinge portion 21R as a support point, the fitting portion 22R is configured so as to be engageable without being locked and without interference.
The fitting portion 22L has the same configuration as the fitting portion 22R. The fitting portion 22L includes the first fitting convex portion 23 and the second fitting concave portion 26 at an end of the second ring arm portion 20L opposite to the ring back portion 20 that is connected to the second ring arm portion 20L by the hinge portion 21L.
Further, the fitting portion 22L includes the first fitting concave portion 24 and the second fitting convex portion 25 at an end of the ring back portion 20 opposite to the second ring arm portion 20L that is connected to the ring back portion 20 by the hinge portion 21L. The first fitting convex portion 23 is fitted into the first fitting concave portion 24 and the second fitting convex portion 25 is fitted into the second fitting concave portion 26.
The first fitting convex portion 23, the first fitting concave portion 24, the second fitting convex portion 25 and the second fitting concave portion 26 of the fitting portion 22L have the same configuration as those of the fitting portion 22R. The first convex-side load receiving surface 23a and the first concave-side load receiving surface 24a, and the third convex-side load receiving surface 23b and the third concave-side load receiving surface 24b are formed at opposite surfaces of the first fitting convex portion 23 and the first fitting concave portion 24. Further, the second convex-side load receiving surface 25a and the second concave-side load receiving surface 26a are formed at opposite surfaces of the second fitting convex portion 25 and the second fitting concave portion 26.
When the first ring arm portion 20R and the second ring arm portion 20L are closed and the annular ring part 2A is thus formed, the first fitting convex portion 23 of the fitting portion 22L is fitted into the first fitting concave portion 24 at a place where the second ring arm portion 20L and the ring back portion 20 are connected to each other. Further, the second fitting convex portion 25 is fitted into the second fitting concave portion 26.
When the first fitting convex portion 23 is fitted into the first fitting concave portion 24, the first convex-side load receiving surface 23a of the first fitting convex portion 23 comes into contact with the first concave-side load receiving surface 24a of the first fitting concave portion 24. Further, the third convex-side load receiving surface 23b of the first fitting convex portion 23 comes into contact with the third concave-side load receiving surface 24b of the first fitting concave portion 24.
Additionally, when the second fitting convex portion 25 is fitted into the second fitting concave portion 26, the second convex-side load receiving surface 25a of the second fitting convex portion 25 comes into contact with the second concave-side load receiving surface 26a of the second fitting concave portion 26.
In this way, the first fitting convex portion 23 and the first fitting concave portion 24 are fitted in a concavo-convex shape that is formed in a thickness direction of the second ring arm portion 20L and the ring back portion 20. Further, the second fitting convex portion 25 and the second fitting concave portion 26 are fitted in a concavo-convex shape that is formed in the thickness direction of the second ring arm portion 20L and the ring back portion 20. In addition, the first fitting convex portion 23 and the first fitting concave portion 24, and the second fitting convex portion 25 and the second fitting concave portion 26 are fitted in a concavo-convex shape that is formed in a width direction of the second ring arm portion 20L and the ring back portion 20.
The fitting portion 22L is also configured in such a way that, in the opening and closing operation using the hinge portion 21L as a support point, the pathway of the first fitting convex portion 23 does not overlap with the first fitting concave portion 24 and the pathway of the second fitting convex portion 25 does not overlap with the second fitting concave portion 26. Accordingly, in the operation of opening and closing the second ring arm portion 20L with the hinge portion 21L as a support point, the fitting portion 22L is configured so as to be engageable without being locked and without interference.
Subsequently, a configuration which locks the first ring arm portion 20R and the second ring arm portion 20L will be described in order to maintain the annular form after the first ring arm portion 20R and the second ring arm portion 20L are closed and the annular ring part 2A is thus formed.
The ring part 2A includes a first locking portion 27a at a leading end in a circumferential direction of the arc of the first ring arm portion 20R. The first locking portion 27a includes a locking claw 27c in a concave guide portion 27b.
The concave guide portion 27b is configured by a concave portion at an outer peripheral side of the first ring arm portion 20R. The concave portion is open at the leading end side and both sides in the width direction of the first ring arm portion 20R. The locking claw 27c is formed on the inner side of the concave guide portion 27b. The locking claw 27 has a hook shape whose leading end has a triangular shape and is projected outward.
The ring part 2A includes a second locking portion 27d at a leading end in a circumferential direction of the arc of the second ring arm portion 20L. The second locking portion 27d includes a claw receiving portion 27f in a convex guide portion 27e.
The convex guide portion 27e is configured by a convex portion at the leading end of the second ring arm portion 20L. The convex portion has a shape that is fitted into the portion of the annular ring part 2A located between the concave guide portions 27b of the first locking portion 27a. The claw receiving portion 27f is configured by a hole portion at the convex guide portion 27e. The locking claw 27c of the first locking portion 27a is fitted and locked into the hole portion when the convex guide portion 27e is fitted between the concave guide portions 27b of the first locking portion 27a.
Subsequently, the back part 3A for connecting the ring parts 2A and the ring back portions 20 of the ring parts 2A connected by the back part 3A will be described in detail. The back part 3A extends linearly. At predetermined intervals, the ring back portions 20 of the ring parts 2A are provided integrally with the back part 3A.
Each of the ring back portion 20 is provided with a first slit 28a and a second slit 28b. The first slit 28a is configured by an opening along a circumferential direction of the arc of the ring back portion 20. The opening penetrates an inner peripheral side and an outer peripheral side of the ring back portion 20. The first slit 28a is open at the position where the back part 3A is provided.
The second slit 28b is not open at the position where the back part 3A is provided. The second slit 28b is configured by an opening at both sides of the back part 3A along the circumferential direction of the arc of the ring back portion 20. The opening penetrates the inner peripheral side and the outer peripheral side of the ring back portion 20.
The first slit 28a and the second slit 28b are provided with bridges 28c extending along the circumferential direction of the arc of the ring back portion 20. A part of the opening is connected by the bridges 28c.
In the binding component 1A, the first slits 28a are respectively provided at the ring parts 2A on both end sides along the extension direction of the back part 3A. Preferably, the first slit 28a is provided, at least, at one ring part 2A on each of both end sides along the extension direction of the back part 3A. More preferably, the first slits 28a are provided at two or more ring parts 2A on each of both end sides along the extension direction of the back part 3A. Further, it is preferable that the first slit 28a is provided also on the central side in the extension direction of the back part 3A.
The second slit 28b is respectively provided at the ring parts 2A other than the ring parts 2A where the first slit 28a is provided.
As a result, in the binding component 1A, the portion where the first slit 28a is provided is deformed when a load is applied by the impact such as dropping, so that the impact is absorbed. Further, by providing the second slit 28b, rigidity for preventing the deformation of the back part 3A in a binding operation of a binding device (to be described later) is secured.
<Usage Example of Binding Component of Present Embodiment>
A plurality of binding components 1A are stacked in a state where the first ring arm portions 20R and the second ring arm portions 20L are open. In the state where the first ring arm portions 20R and the second ring arm portions 20L are open, the first fitting convex portions 23 of the fitting portion 22R and the fitting portion 22L protrude upward from the end of the first ring arm portion 20R and the end of the second ring arm portion 20L and the second fitting convex portions 25 thereof protrude upward from both ends of the ring back portion 20.
The first fitting convex portion 23 and the second fitting convex portion 25 have a shape and a size so that these convex portions are fitted into a clearance E. The clearance E is formed between the adjacent binding components 1A stacked in a stack direction vertically in a state where the first ring arm portions 20R and the second ring arm portions 20L are open and a plurality of binding components 1A are stacked in the stack direction.
As a result, in the state where the binding components 1A are stacked and stored, the height in the stack direction is suppressed, so that it is possible to reduce the space required for storage.
Further,
Hereinafter, an operation of closing the first ring arm portions 20R and the second ring arm portions 20L is described. The first ring arm portions 20R and the second ring arm portions 20L are moved and displaced in a closing direction in a binding operation or the like of a paper processing device (to be described later).
As shown in
The first fitting convex portion 23 and the first fitting concave portion 24 are fitted in a concavo-convex shape that is formed in a thickness direction of the first ring arm portion 20R and the ring back portion 20. Further, the second fitting convex portion 25 and the second fitting concave portion 26 are fitted in a concavo-convex shape that is formed in the thickness direction of the first ring arm portion 20R and the ring back portion 20.
As a result, in the process of closing the first ring arm portion 20R, the first fitting convex portion 23 and the first fitting concave portion 24, and the second fitting convex portion 25 and the second fitting concave portion 26 serve as a guide in a thickness direction. Accordingly, the first ring arm portion 20R and the ring back portion 20 are prevented from being positional-deviated in the thickness direction.
Similarly for the second ring arm portion 20L, in the process of closing the second ring arm portion 20L, the first fitting convex portion 23 and the first fitting concave portion 24, and the second fitting convex portion 25 and the second fitting concave portion 26 serve as a guide in a thickness direction. Accordingly, the second ring arm portion 20L and the ring back portion 20 are prevented from being the positional-deviated in the thickness direction.
Further, the first fitting convex portion 23 and the first fitting concave portion 24 are fitted in a concavo-convex shape that is formed in a width direction in the first ring arm portion 20R and the ring back portion 20, and the second fitting convex portion 25 and the second fitting concave portion 26 are fitted in a concavo-convex shape that is formed in a width direction in the second ring arm portion 20L and the ring back portion 20.
As a result, in the process of closing the first ring arm portion 20R, the first fitting convex portion 23 and the first fitting concave portion 24, and the second fitting convex portion 25 and the second fitting concave portion 26 serve as a guide in a thickness direction. Accordingly, the first ring arm portion 20R is prevented from being positional-deviated in an axial direction of a rotation operation with the hinge portion 21R as a support point. Further, the first ring arm portion 20R is prevented from being positional-deviated in a twisted direction at the hinge portion 21R.
Similarly for the second arm portion 20L, in the process of closing the second ring arm portion 20L, the first fitting convex portion 23 and the first fitting concave portion 24, and the second fitting convex portion 25 and the second fitting concave portion 26 serve as a guide in a thickness direction. Accordingly, the second ring arm portion 20L is prevented from being positional-deviated in an axial direction of a rotation operation with the hinge portion 21L as a support point. Further, the second ring arm portion 20L is prevented from being positional-deviated in a twisted direction at the hinge portion 21L.
As shown in
As described above, in the process of closing the first ring arm portion 20R and the second ring arm portion 20L, the positional deviation in the width direction and the thickness direction of the first ring arm portion 20R and the second ring arm portion 20L are suppressed by the first fitting convex portion 23 and the first fitting concave portion 24, and the second fitting convex portion 25 and the second fitting concave portion 26.
As a result, in the operation of locking the first locking portion 27a and the second locking portion 27d, the positional deviation between the first locking portion 27a and the second locking portion 27d is suppressed, and the locking claw 27c and the claw receiving portion 27f are securely locked.
When the first ring arm portion 20R and the second ring arm portion 20L are closed and the annular ring part 2A are thus formed, in the fitting portion 22R, the first fitting convex portion 23 is fitted into the first fitting concave portion 24 and the second fitting convex portion 25 is fitted into the second fitting concave portion 26.
When the first fitting convex portion 23 is fitted into the first fitting concave portion 24, the first convex-side load receiving surface 23a of the first fitting convex portion 23 comes into contact with the first concave-side load receiving surface 24a of the first fitting concave portion 24. Further, the third convex-side load receiving surface 23b of the first fitting convex portion 23 comes into contact with the third concave-side load receiving surface 24b of the first fitting concave portion 24.
Additionally, when the second fitting convex portion 25 is fitted into the second fitting concave portion 26, the second convex-side load receiving surface 25a of the second fitting convex portion 25 comes into contact with the second concave-side load receiving surface 26a of the second fitting concave portion 26.
As a result, when a load of the impact such as dropping is applied to a place where the first ring arm portion 20R and the ring back portion 20 are connected to each other, for example, a load of pressing the ring back portion 20 inwardly and a load of pressing the first ring arm portion 20R outwardly are received by the contact of the first convex-side load receiving surface 23a of the first fitting convex portion 23 and the first concave-side load receiving surface 24a of the first fitting concave portion 24.
Further, a load of pressing the ring back portion 20 outwardly and a load of pressing the first ring arm portion 20R inwardly are received by the contact of the second convex-side load receiving surface 25a of the second fitting convex portion 25 and the second concave-side load receiving surface 26a of the second fitting concave portion 26.
In addition, a load of pressing the first ring arm portion 20R or the ring back portion 20 in an axial direction of a rotation operation with the hinge portion 21R as a support point is received by the contact of the third convex-side load receiving surface 23b of the first fitting convex portion 23 and the third concave-side load receiving surface 24b of the first fitting concave portion 24.
Accordingly, when a load of the impact such as dropping is applied, from any direction, to a place where the first ring arm portion 20R and the ring back portion 20 are connected to each other, this load is received by a combination of any one of the convex-side load receiving surfaces and the concave-side load receiving surfaces, so that the load applied to the hinge portion 21R is reduced. Accordingly, the damage of the hinge portion 21R is prevented and therefore it is possible to prevent the first ring arm portion 20R from being separated from the ring back portion 20.
Similarly, in the second ring arm portion 20L, the same effect is obtained by the fitting portion 22L. For example, a load of pressing the ring back portion 20 inwardly and a load of pressing the second ring arm portion 20L outwardly are received by the contact of the first convex-side load receiving surface 23a of the first fitting convex portion 23 and the first concave-side load receiving surface 24a of the first fitting concave portion 24.
Further, a load of pressing the ring back portion 20 outwardly and a load of pressing the second ring arm portion 20L inwardly are received by the contact of the second convex-side load receiving surface 25a of the second fitting convex portion 25 and the second concave-side load receiving surface 26a of the second fitting concave portion 26.
In addition, a load of pressing the second ring arm portion 20L or the ring back portion 20 in an axial direction of a rotation operation with the hinge portion 21L as a support point is received by the contact of the third convex-side load receiving surface 23b of the first fitting convex portion 23 and the third concave-side load receiving surface 24b of the first fitting concave portion 24.
Accordingly, when a load of the impact such as dropping is applied, from any direction, to a place where the second ring arm portion 20L and the ring back portion 20 are connected to each other, this load is received by a combination of any one of the convex-side load receiving surfaces and the concave-side load receiving surfaces, so that the load applied to the hinge portion 21L is reduced. Accordingly, the damage of the hinge portion 21L is prevented and therefore it is possible to prevent the second ring arm portion 20L from being separated from the ring back portion 20.
Further, in the binding component 1A, the portion where the first slit 28a is provided is deformed when a load is applied by the impact such as dropping, so that the impact is absorbed. Particularly, by providing the first slits 28a to the ring parts 2A located at both ends in the extension direction of the back part 3A, the back part 3A is curvedly deformed when a booklet is falling from its corner, for example. In this way, it is possible to absorb the impact.
On the contrary, in the present embodiment, the first convex-side load receiving surface 23a of the first fitting convex portion 23 comes into contact with the first concave-side load receiving surface 24a of the first fitting concave portion 24, and the second convex-side load receiving surface 25a of the second fitting convex portion 25 comes into contact with the second concave-side load receiving surface 26a of the second fitting concave portion 26, as shown in
<Modified Example of Binding Component of Present Embodiment>
On the contrary, in the modified example shown in
Also in the configuration shown in
Additionally, when the second fitting convex portion 25 is fitted into the second fitting concave portion 26, the second convex-side load receiving surface 25a of the second fitting convex portion 25 comes into contact with the second concave-side load receiving surface 26a of the second fitting concave portion 26.
Accordingly, in the process of closing the first ring arm portion 20R and the second ring arm portion 20L, the first fitting convex portion 23 and the first fitting concave portion 24, and the second fitting convex portion 25 and the second fitting concave portion 26 serve as a guide in a width direction and a thickness direction.
Further, when a load of the impact such as dropping is applied, from any direction, to places where the first ring arm portion 20R and the ring back portion 20 are connected to each other and where the second ring arm portion 20L and the ring back portion 20 are connected to each other, this load is received by a combination of any one of the convex-side load receiving surfaces and the concave-side load receiving surfaces, so that the load applied to the hinge portions 21L, 21R is reduced.
In the modified example shown in
Also in the configuration shown in
Additionally, when the second fitting convex portion 25 is fitted into the second fitting concave portion 26, the second convex-side load receiving surface 25a of the second fitting convex portion 25 comes into contact with the second concave-side load receiving surface 26a of the second fitting concave portion 26.
Accordingly, in the process of closing the first ring arm portion 20R and the second ring arm portion 20L, the first fitting convex portion 23 and the first fitting concave portion 24, and the second fitting convex portion 25 and the second fitting concave portion 26 serve as a guide in a thickness direction.
Further, when a load of the impact such as dropping is applied, from any direction, to places where the first ring arm portion 20R and the ring back portion 20 are connected to each other and where the second ring arm portion 20L and the ring back portion 20 are connected to each other, this load is received by a combination of any one of the convex-side load receiving surfaces and the concave-side load receiving surfaces, so that the load applied to the hinge portions 21L, 21R is reduced.
<Configuration Example of Paper Processing Device>
A paper processing device 4A includes a first conveying path 40 for conveying a paper 100A and a second conveying path 41 branched from the first conveying path 40. The paper processing device 4A constitutes a conveying route that is referred to as a switchback type or the like for reversing a conveying direction of papers in the middle. Here, the papers refer to general terms including one sheet of paper 100A, a paper bundle 100B obtained by integrating the paper 100A, and a booklet 100C obtained by binding the paper bundle 100B by the binding component 1A, or the like.
Further, the paper processing device 4A includes a punching unit 5 for drilling a hole in the paper 100A, a binder unit 6 for binding the paper bundle 100B and making a booklet, a discharging unit 7 for conveying the bound booklet 100C or the like, and a paper discharge stacker 8 for storing the booklet 100C or the like. The paper bundle 100B is obtained by aligning a plurality of sheets of paper drilled with holes.
The first conveying path 40 is disposed at an upper side of the paper processing device 4A. The first conveying path 40 includes a plurality of feed rollers 40a that is rotationally driven, a plurality of guide rollers 40b facing the feed rollers 40a, and a guide member (not shown), or the like. The first conveying path 40 constitutes a linear conveying route for conveying the paper between a feeding port 40c and a discharge port 40d. The conveying route is substantially horizontal.
The first conveying path 40 includes a switching blade 40e for switching a conveying direction A. The switching blade 40e is disposed at a downstream side in the conveying direction A from the feeding port 40c side toward the discharge port 40d side. A branch portion 40f of the first conveying path 40 and the second conveying path 41 is formed. Further, in the first conveying path 40, a reversal holding unit 40g is formed between the downstream of the branch portion 40f and the discharge port 40d.
At the branch portion 40f, the second conveying path 41 is branched downward from the first conveying path 40. The second conveying path 41 includes a plurality of feed rollers 41a that is rotationally driven, a plurality of guide rollers 41b facing the feed rollers 41a, and a guide member (not shown), or the like.
The second conveying path 41 is branched in an opposite direction with respect to the conveying direction A of the first conveying path 40. The second conveying path 41 is communicated with the reversal holding unit 40g by the operation of the switching blade 40e.
The switching blade 40e is rotationally driven to move between a position retracted from the first conveying path 40 and a position protruding into the first conveying path 40.
When the switching blade 40e is switched to the position retracted from the first conveying path 40, the paper 100A, which is conveyed in the first conveying path 40 in the conveying direction A from the feeding port 41c, is moved through the switching blade 40e and conveyed to the reversal holding unit 40g.
On the contrary, when the switching blade 40e is switched to the position protruding into the first conveying path 40, the paper 100A is conveyed in the first conveying path 40 in a conveying direction B from the reversal holding unit 40g while reversing the conveying direction. Then, the paper 100A is sent to the second conveying path 41 from the first conveying path 40 by the guide of the switching blade 40e.
As a result, the second conveying path 41 constitutes a conveying route where the conveying direction of the paper 100A that is conveyed in the conveying direction A from the feeding port 40c side to the discharge port 40d side through the first conveying path 40 is switched to the conveying direction B at the reversal holding unit 40g and the paper 100A is switched back downward from the first conveying path 40.
The first conveying path 40 includes a paper detection sensor 40h at the reversal holding unit 40g. The paper detection sensor 40h detects whether or not a rear end of the paper 100A that is conveyed in the conveying direction A through the first conveying path 40 is conveyed up to the position where the paper passes through the switching blade 40e.
The punching unit 5 is disposed in the second conveying path 41. The punching unit 5 includes an abutting shutter 50 for aligning the position of leading ends in the conveying direction of the paper 100A, a width aligning mechanism 51 for aligning the paper 100A in the lateral direction and a punch blade 52 for drilling holes in the paper 100A, or the like.
The abutting shutter 50 is configured to open and close the punching unit 5 by moving between a protruding position where the abutting shutter 50 protrudes into the second conveying path 41 and a retracted position where the abutting shutter 50 is retracted from the second conveying path 41. In the protruding position, the paper 100A sent to the punching unit 5 is abutted against the abutting shutter 50. In the retracted position, the paper 100A can pass through the abutting shutter 50. When the abutting shutter 50 protrudes into the second conveying path 41, the leading end of the paper 100A conveyed through the second conveying path 41 is abutted against the abutting shutter, so that the leading end of the paper 100A is restricted to a predetermined position.
The width aligning mechanism 51 includes a width aligning guide at one side of the left and right to the conveying direction of the paper 100A and a reference guide at the other side thereof. The width aligning guide moves in a direction of approaching and separating from the reference guide, so that the paper 100A sent to the punching unit 5 is abutted against the reference guide.
The punch blade 52 is configured to reciprocate in a direction perpendicular to the plane of the paper 100A conveyed through the second conveying path 41. The aligning of the paper 100A is carried out by the abutting shutter 50 and the width aligning mechanism 51. In this state, predetermined holes are drilled in the paper 100A when the punch blade 52 is reciprocated.
Meanwhile, in order to collect punch debris generated when drilling holes in the paper 100A by the punch blade 52, a punch debris stacker 53 is provided below the punching unit 5.
The binder unit 6 is an example of a binding means and is disposed at a downstream side of the punching unit 5. The binder unit 6 includes a paper aligning part 60, a binding component stacker 61, and a binding part 62. The paper aligning part 60 is configured to align and integrate a plurality of sheets of paper with holes drilled by the punching unit 5. The binding component stacker 61 is configured to store the binding component 1A for binding the papers. The binding part 62 is configured to bind, by the binding component 1A, the paper bundle 100B that is aligned and integrated by the paper aligning part 60.
The paper aligning part 60 includes, in a paper temporary holding portion 60a, an abutting shutter 60b for aligning the position of leading ends in the conveying direction of the paper, a width aligning mechanism 60c for aligning the position in the lateral direction of the paper, a paddle mechanism 60d for causing the paper to be abutted against the abutting shutter 60b, and a clamp mechanism 60e for holding booklets such as the booklet 100C or the paper bundle 100B.
The abutting shutter 60b is configured to open and close the temporary holding portion 60a by moving between a protruding position where the abutting shutter 60b protrudes into the temporary holding portion 60a and a retracted position where the abutting shutter 60b is retracted from the temporary holding portion 60a. In the protruding position, the paper sent to the paper aligning part 60 is abutted against the abutting shutter 60b. In the retracted position, the booklet can pass through the abutting shutter 60b.
The width aligning mechanism 60c includes a width aligning guide at one side of the left and right to the conveying direction of the paper and a reference guide at the other side thereof. The width aligning guide moves in a direction of approaching and separating from the reference guide, so that the paper sent to the binder unit 6 is abutted against the reference guide.
The paddle mechanism 60d includes a paddle roller where a plurality of tongue pieces is arranged in a circumferential direction. The paddle roller is rotationally driven. The paddle roller scrapes the paper sent to the paper aligning part 60 and causes the paper to be abutted against the abutting shutter 60b that protrudes into the temporary holding portion 60a. Meanwhile, a rotation shaft of the paddle roller is inclined in a guide direction of the fixed side of the width aligning mechanism 60c. Further, the paddle roller applies a force to the paper sent to the paper aligning part 60. The force causes the paper to be abutted in the guide direction of the fixed side of the width aligning mechanism 60c.
The clamp mechanism 60e clamps and holds the paper bundle 100B that is sent to the paper aligning part 60 and aligned by the abutting shutter 60b, the width aligning mechanism 60c and the paddle mechanism 60d. The clamp mechanism 60e is configured to move the paper bundle 100B held to a predetermined processing position.
A plurality of binding components 1A is vertically stacked and stored in the binding component stacker 61. The binding component stacker 61 is provided at its bottom with an outlet for the binding component 1A. The binding component stacker 61 is configured to feed the binding component 1A one by one in cooperation with the binding part 62.
The binding part 62 includes a binding mechanism 62a for feeding and binding the binding component 1A stored in the binding component stacker 61. The binding part 62 is rotated about a rotation supporting point 62b by being rotationally driven. In this way, the binding part 62 moves between a binding component feeding position where the binding mechanism 62a faces the binding component stacker 61 and a paper binding position where the binding mechanism 62a faces the paper aligning part 60.
At the position where the binding mechanism 62a faces the binding component stacker 61, the binding mechanism 62a is configured to extract and hold the binding component 1A from the binding component stacker 61. At the position where the binding mechanism 62a faces the paper aligning part 60, the binding mechanism 62a is configured to bind, by the binding component 1A, the paper bundle 100B aligned and held by the paper aligning part 60.
The binder unit 6 includes a paper detection sensor 63 in a conveying route from the paper aligning part 60 to the discharging unit 7. The paper detection sensor 63 is an example of a paper detection means. The paper detection sensor 63 detects whether or not the booklets, such as the booklet 100C that is aligned by the paper aligning part 60 and bound by the binding component 1A or the paper bundle 100B that is aligned by the paper aligning part 60 but not bound, are conveyed to the discharging unit 7.
The discharging unit 7 is disposed at a downstream side of the binder unit 6. The discharging unit 7 constitutes the paper processing device 4A that receives booklets by using the binder unit 6 as a first device. The paper processing device 4A reverses the conveying direction of the booklets and discharges the booklets to the paper discharge stacker 8.
The paper processing device 4A includes a belt conveying mechanism 70 and a belt conveying mechanism 74, or the like. The belt conveying mechanism 70 receives the booklets from the binder unit 6, switches the conveying direction of the booklets and conveys the booklets. The belt conveying mechanism 74 receives the booklets from the belt conveying mechanism 70 and discharges the booklets to the paper discharge stacker 8.
In the belt conveying mechanism 70, an endless conveying belt equipped with a receiving tool 70a is wound around a pair of pulleys that is rotationally driven. The receiving tool 70a of the belt conveying mechanism 70 has a shape of supporting an end surface side of the booklets. When the belt conveying mechanism 70 is rotationally driven in a predetermined direction, the receiving tool 70a protrudes from a guide surface and moves in the conveying direction.
In the belt conveying mechanism 70, a lower end that is one end in the conveying direction of the booklet is pivotally supported to a frame of the paper processing device 4A via a first rotation supporting point 73a.
The belt conveying mechanism 70 is pivoted about the first rotation supporting point 73a. The belt conveying mechanism 70 moves between a paper receiving position (indicated by a broken line in
In the belt conveying mechanism 74, an endless conveying belt equipped with a receiving tool 74a is wound around a pair of pulleys that is rotationally driven. The receiving tool 74a of the belt conveying mechanism 74 has a shape of supporting an end surface side of the booklets. The receiving tool 74a moves in the conveying direction when the belt conveying mechanism 74 is rotationally driven in a predetermined direction.
Here, in the belt conveying mechanism 74, a pulley 74b on the first paper discharge path 10 side is extended to a position where the pulley enters the first paper discharge path 10. The belt conveying mechanism 74 can convey the booklet between the first paper discharge path 10 that is displaced to the paper discharging position and the second paper discharge path 11.
The paper discharge stacker 8 is disposed at a downstream side of the discharging unit 7 and includes a stacking stage 80. The stacking stage 80 includes a tray 81 that can be pulled out in the front direction of the device. The stacking stage 80 is configured to be vertically lifted by a stage lifting mechanism 80a.
As described above, in the paper processing device 4A having a switchback type conveying route, a desired conveying route can be configured by a combination of linear conveying routes or curved conveying routes having a large radius without providing a conveying route where the booklets, such as the booklet 100C that is obtained by integrating and binding a plurality of sheets of paper 100A or the paper bundle 100B that is obtained by integrating a plurality of sheets of paper 100A, are tightly bent.
<Operation Example of Paper Processing Device>
Next, an operation example where the paper is bound by the paper processing device 4A will be described with reference to each drawing.
The paper processing device 4A is connected to a copying machine or the like (not shown). The paper 100A that is subjected to a predetermined processing such as printing is fed one by one to the paper processing device 4A from the feeding port 40c. In an operation of binding the paper by the binding component 1A, a conveying process of conveying the paper 100A to the punching unit 5 is performed, a drilling process is performed by the punching unit 5 and then an aligning process is performed by the binder unit 6.
In the conveying process of conveying the paper 100A to the punching unit 5, the feed rollers 40a in the first conveying path 40 are rotationally driven. The feed rollers 40a are rotated in a forward rotation direction and the paper 100A in the first conveying path 40 is thus conveyed in the conveying direction A.
As a result, the paper 100A fed to the first conveying path 40 is sandwiched between the guide roller 40b and the feed roller 40a that is rotationally driven in the forward rotation direction. The paper 100A is guided by a guide member (not shown) and conveyed in the conveying direction A from the feed port 40c to the discharge port 40d through the first conveying path 40.
A rear end of the paper 100A that is conveyed in the conveying direction A through the first conveying path 40 is detected by the paper detection sensor 40h. When it is determined that the paper 100A is moved through the switching blade 40e and conveyed to the reversal holding unit 40g, the conveying of the paper 100A is temporarily stopped.
After the conveying of the paper 100A is temporarily stopped, the switching blade 40e is rotationally driven. In this way, the conveying route from the reversal holding unit 40g to the second conveying path 41 is opened, so that the conveying direction is switched.
When the switching blade 40e is rotationally driven and the conveying direction is thus switched to the second conveying path 41, the feed rollers 40a are rotated in a rearward rotation direction and the paper 100A in the first conveying path 40 is thus conveyed in the conveying direction B. Further, the feed rollers 41a in the second conveying path 41 are rotationally driven. The feed rollers 41a are rotated in a direction in which the paper 100A in the second conveying path 41 is conveyed to the punching unit 5.
In this way, the conveying direction of the paper 100A that is temporarily held in the reversal holding unit 40g is switched, so that the paper is conveyed in the conveying direction B. Then, the paper 100A is guided by the switching blade 40e and sent from the first conveying path 40 to the second conveying path 41.
The paper 100A sent to the second conveying path 41 is sandwiched between the feed roller 41a and the guide roller 41b, guided by a guide member (not shown) and conveyed to the punching unit 5 through the second conveying path 41.
In order to perform the drilling process of drilling holes in the paper 100A, the punching unit 5 causes the abutting shutter 50 to protrude into the conveying route of the paper 100A and drives the width aligning mechanism 51.
In this way, a leading end of the paper 100A conveyed to the punching unit 5 is abutted against the abutting shutter 50 and a side end thereof is abutted against a reference guide (not shown), so that the alignment of the paper is performed.
When the alignment of the paper 100A is performed, the punch blade 52 is driven to drill predetermined holes in the paper 100A. Then, the abutting shutter 50 is opened. When the abutting shutter 50 is opened, the paper 100A that is drilled by the punching unit 5 is conveyed to the binder unit 6.
In order to perform the aligning process of integrating and aligning a predetermined number of papers 100A drilled with holes, first, the binder unit 6 causes the abutting shutter 60b to protrude into the temporary holding portion 60a and drives the width aligning mechanism 60c and the paddle mechanism 60d.
In this way, a leading end of the paper 100A that is drilled by the punching unit 5 and conveyed to the binder unit 6 is abutted against the abutting shutter 60b and a side end thereof is abutted against a reference guide (not shown), so that the alignment of the paper is performed.
When the alignment of the paper 100A is performed, the clamp mechanism 60e is closed. When the clamp mechanism 60e is closed, the paper 100A aligned is clamped and held by the clamp mechanism 60e without causing a positional deviation.
Then, the conveying process, the punching process and the aligning process, which are described above, are repeated until a predetermined number of papers 100A are aligned and integrated in the temporary holding portion 60a.
When the papers 100A drilled with holes are sequentially conveyed to the temporary holding portion 60a and a predetermined number of papers 100A is aligned and held by the clamp mechanism 60e, a series of conveying process, punching process and aligning process are stopped.
In the binder unit 6, the binding part 62 is on standby at a binding component extraction position. Then, in order to perform the binding process of binding a predetermined number of papers 100A by the binding component 1A, the binding mechanism 62a is driven. The binding mechanism 62a grasps a back part 3A (shown in
When the binding component 1A is extracted from the binding component stacker 61, the binding part 62 is rotationally driven. As shown in
Subsequently, the clamp mechanism 60e is driven and the paper bundle 100E aligned and held is moved to a predetermined processing position. The binding mechanism 62a is driven to press the first ring arm portion 20R and the second ring arm portion 20L (as shown in
When the paper bundle 100B is bound by the binding component 1A in the binder unit 6 and the booklet 100C is thus made, the binding part 62 is pivoted about the rotation supporting point 62b and moved to the binding component extraction position in order to perform the process of discharging the booklet 100C. Subsequently, the belt conveying mechanism 70 is pivoted about the first rotation supporting point 73a and moved to the paper receiving position, as shown in
When the belt conveying mechanism 70 is moved to the paper receiving position, the clamp mechanism 60e is opened. When the clamp mechanism 60e is opened, the booklet 100C held in the temporary holding portion 60a by the clamp mechanism 60e drops, by its own gravity, to a conveying route formed by the belt conveying mechanism 70, as shown in
When a rear end of the booklet 100C dropping from the temporary holding portion 60a is detected by the paper detection sensor 63 and it is determined that the booklet 100C is normally conveyed to the belt conveying mechanism 70, the belt conveying mechanism 70 is rotationally driven. Accordingly, as shown in
When the belt conveying mechanism 70 is moved to the paper discharging position, the belt conveying mechanism 70 is rotationally driven. When the belt conveying mechanism 70 is rotationally driven, the receiving tool 70a supports the booklet 100C and moves toward the belt conveying mechanism 74, so that the booklet 100C is conveyed to the belt conveying mechanism 74.
When the belt conveying mechanism 74 is rotationally driven, the receiving tool 74a receives the booklet 100C supported by the receiving tool 70a of the belt conveying mechanism 70, as shown in
When the receiving tool 74a is moved to a predetermined position, the booklet 100C that is conveyed by the belt conveying mechanism 74 is discharged to the paper discharge stacker 8 from a discharge portion 75c, as shown in
When the booklet 100c is conveyed to the paper discharge stacker 8, the stack stage 80 is lowered by a predetermined amount. In this way, a space for receiving the next booklet 100C is secured on the tray 81.
The present invention is applied to the binding component for binding a paper.
Number | Date | Country | Kind |
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2014-087252 | Apr 2014 | JP | national |
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