This disclosure relates to a sheet processing device and an image forming apparatus, and, specifically, relates to binding sheets without using staples.
In the related art, an image forming apparatus such as a copier, a laser beam printer, a facsimile, and a complex machine thereof, includes a sheet processing device that performs processing of binding sheets on which images are formed. In such an image forming apparatus, if a sheet bundle is bound by the sheet processing device, in general, the sheet bundle is bound using metal staples. Then, since staple processing using such staples can reliably bind a plurality of output papers in a position which is designated by a user, staple processing is employed in many sheet processing devices.
However, when the sheets in which a staple processing is performed are inserted into a shredder, it requires work to remove the staples and is troublesome. In addition, if the sheet bundle which is bound with the staples is recycled, it is necessary to recover the sheets by removing the staples and separating the sheets and the staples, which is troublesome.
Thus, a sheet processing device has been proposed in which recycling is emphasized and the sheets are bound without using staples. For example, such a sheet processing device has been proposed in JP-A-2010-189101 in which a binding process is performed in a sheet bundle by a binding portion including convex upper teeth and concave lower teeth.
In the sheet processing device, after the sheets are bound and aligned, the lower teeth and the upper teeth of the binding unit are engaged with each other, uneven portions are formed in a part of the sheet bundle in a thickness direction, fibers of overlapped sheets are tangled with each other, and then the sheet bundle is bound. Moreover, in the sheet processing device, the fibrous sheets are bound without using staples. It is noted that, hereinafter, a binding method for binding the fibrous sheet bundle without using such staples is referred to as stapleless binding.
In the sheet processing device in which stapleless binding is performed, the lower teeth are mounted on one end portion of a fixed lower arm and the upper teeth are mounted on one end portion of an upper arm that is supported by the lower arm to be swingable in a vertical direction. Then, when binding the sheet bundle, the lower teeth and the upper teeth are engaged with each other by swinging the upper arm, thereby binding the sheet bundle.
However, when performing stapleless binding, in order to reliably perform stapleless binding, it is necessary to apply a great load to the lower teeth and the upper teeth in the sheet processing device. The load increases if a binding area of the teeth is increased which increases a binding force. Furthermore, as in a copier, the fibers of the sheet dry in a process of printing by applying heat on the sheet, so that fibers are unlikely to be tangled with each other. Thus, in order to reliably perform stapleless binding even if the fibers of the sheet are dry, it is necessary to apply a great load to the lower teeth and the upper teeth.
On the other hand, if such a great load is applied, large stress is applied to the arms on which the lower teeth and the upper teeth are mounted. In order to withstand such large stress, in general, the arm is created by bending a metal plate in a U-shape. Load-bearing is high as the U-shape is great and load-bearing can be high as a thickness of the metal plate forming the U shape is thick.
In recent years, since a demand for downsizing the sheet processing device and the image forming apparatus is increased, a small sized arm is desired. Thus, in order to reduce a size of an external shape of the arm to be as small as possible and to increase load-bearing, it is necessary to increase the thickness of the metal plate, but if the thickness of the metal plate is increased in a state where the size of the external shape is reduced, it is difficult to form the arm by press working.
For example, a through-hole through which a shaft is inserted for supporting the upper arm to be swingable with respect to the lower arm in the vertical direction is formed in the upper arm. However, in a case where the through-hole is formed in the upper arm, if a distance between a top surface of the U-shaped arm and the through-hole is not twice the thickness of the plate, the through-hole is deformed during a bending process after hole making. It is noted that, if the distance cannot be ensured, it is necessary to form the through-hole by a secondary process after bending is performed and manufacturing cost is greatly increased.
That is, in order to hold load-bearing in a state where the size of the external shape of the arm is extremely reduced to downsize the apparatus, the thickness of the metal plate may be increased, but if the thickness is increased, since the secondary process of the hole is necessary, there is a limit to reduce the size of the arm.
According to an aspect of this disclosure, there is provided a sheet processing device including a first teeth portion, a second teeth portion that clamps and binds a sheet bundle with the first teeth portion, a first support portion supporting the first teeth portion, a shaft, and a second support portion supporting the second teeth portion. The second support portion includes first and second arm members integrally supported to be capable of swinging around the shaft between a binding position in which the second teeth portion clamps and binds the sheet bundle with the first teeth portion and a standby position in which the second teeth portion is apart from the first teeth portion. The second arm member is provided over the first arm member so as to cover a part of the first arm member.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Hereinafter, an embodiment of this disclosure will be described in detail with reference to the drawings.
As illustrated in
Here, the image forming portion 900B includes photoconductive drums 18a to 18d that form toner images of four colors of yellow, magenta, cyan, and black, and an exposing unit 906 that forms an electrostatic latent image on the photoconductive drum by applying a laser beam based on image information. It is noted that, the photoconductive drums 18a to 18d are driven by a motor (not illustrated) and a primary charger, a developer, and a transfer charger which are not illustrated respectively are disposed in a periphery thereof. The photoconductive drums 18a to 18d are unitized as process cartridges 901a to 901d.
Furthermore, the image forming portion 900B includes an intermediate transfer belt 902 that is driven to rotate in an arrow direction, a secondary transfer unit 903 that sequentially transfers a full color image formed in the intermediate transfer belt 902 to a sheet P, and the like. Then, respective color toner images on the photoconductive drums are sequentially transferred to the intermediate transfer belt 902 in a superimposed manner by applying a transfer bias to the intermediate transfer belt 902 by transfer chargers 902a to 902d. Thus, the full color image is formed on the intermediate transfer belt.
A secondary transfer unit 903 is configured of a secondary transfer counter roller 903b that supports the intermediate transfer belt 902 and a secondary transfer roller 903a that abuts the secondary transfer counter roller 903b through the intermediate transfer belt 902. In addition, a sheet feeding cassette 904 is disposed in a lower portion of the image forming portion 900B and the sheet P stacked on the sheet feeding cassette 904 is fed by a pickup roller 908. Furthermore, a registration roller 909 is provided on a downstream side of the pickup roller 908 in a direction of conveyance. The apparatus body 900A is provided with a CPU circuit portion 200 that is a control portion.
Next, an image forming operation of the image forming apparatus 900 having such a configuration is described. When the image forming operation is started, first, the laser beam is applied through the exposing unit 906 based on image information from a personal computer (not illustrated) and the like, and surfaces of the photoconductive drums 18a to 18d which are constantly charged at a predetermined polarity and potential are sequentially exposed. Thus, electrostatic latent images are formed on the photoconductive drums 18a to 18d. Thereafter, the electrostatic latent images are developed by a toner and are visualized.
For example, first, the laser beam is applied to the photoconductive drum 18a through a polygon mirror of the exposing unit 906 and the like by an image signal of a yellow component color of the document. The electrostatic latent image of yellow is formed on the photoconductive drum 18a. Then, the electrostatic latent image of yellow is developed by a yellow toner of the developer and is visualized as a yellow toner image. Thereafter, the toner image reaches the primary transfer unit in which the photoconductive drum 18a and the intermediate transfer belt 902 abut in association with the rotation of the photoconductive drum 18a. Here, as described above, if the toner image reaches the primary transfer unit, the yellow toner image on the photoconductive drum 18a is transferred to the intermediate transfer belt 902 by a primary transfer bias applied to a transfer charger 902a (primary transfer).
Next, a portion carrying the yellow toner image of the intermediate transfer belt 902 is moved and a magenta toner image formed on the photoconductive drum 18b by this time in a similar manner described above is transferred on the yellow toner image carried by the intermediate transfer belt 902. Similarly, as the intermediate transfer belt 902 moves, a cyan toner image and a black toner image are respectively transferred to and overlapped the yellow toner image and the magenta toner image in the primary transfer unit. Thus, the full color toner image is formed on the intermediate transfer belt 902.
Furthermore, the sheets P stacked on the sheet feeding cassette 904 are delivered one by one by the pickup roller 908 in parallel with the toner image forming operation. Then, the sheet P reaches the registration roller 909, is timed by the registration roller 909, and then is conveyed to the secondary transfer unit 903. Thereafter, in the secondary transfer unit 903, four color toner images on the intermediate transfer belt 902 are collectively transmitted onto the sheet P by a secondary transfer bias applied to the secondary transfer roller 903a (secondary transfer).
Next, the sheet P to which the toner image is transferred is guided by a conveyance guide 920 from the secondary transfer unit 903 and is transported to a fixing portion 905. The toner image is fixed to the sheet P by receiving heat and pressure when passing the fixing portion 905. Thereafter, the sheet P to which such a toner image is fixed passes through a discharge passage 921 provided on a downstream side of the fixing portion 905, is discharged by a pair of discharging rollers 918, and is conveyed to the finisher 100.
The finisher 100 sequentially captures the sheets discharged from the apparatus body 900A, aligns a plurality of captured sheets, and performs bundling of the sheets in one bundle. If necessary, there is a binding process for binding an upstream end (hereinafter, referred to as trailing end) in a sheet discharging direction of the sheet bundle that is bundled. Then, as illustrated in
Furthermore, the intermediate processing tray 107 is provided with front and back aligning panels 109a and 109b that regulate (align) both side end positions of the sheet transported to the intermediate processing tray 107 in a width direction (depth direction). It is noted that, the front and back aligning panels 109a and 109b that align the side end positions of the sheet stacked on the intermediate processing tray 107 in the width direction are driven by an alignment motor M253 illustrated in
Furthermore, the front and back aligning panels 109a and 109b are usually moved to a receiving position in which the sheet is received by the alignment motor M253 driven by a detection signal of an alignment home position (hereinafter, referred to HP) sensor (not illustrated). Then, when regulating both of the side end positions of the sheet stacked on the intermediate processing tray 107, the alignment motor M253 is driven, the front and back aligning panels 109a and 109b are moved along the width direction, and abut both side ends of the sheet stacked on the intermediate processing tray 107.
Furthermore, a take-in paddle 106 is disposed on a downstream side above the intermediate processing tray 107 in the direction of conveyance. Here, the take-in paddle 106 is positioned in a standby position in which the take-in paddle 106 is waiting at an upper portion not interfering with a discharging sheet by driving a paddle elevating motor M252 based on detection information of a paddle HP sensor S243 illustrated in
Furthermore, if the sheet is discharged to the intermediate processing tray 107, the take-in paddle 106 is moved downward by reverse driving of the paddle elevating motor M252 and is rotated in a counterclockwise direction by a paddle motor (not illustrated) at appropriate timing. The sheet is taken-in by the rotation and a trailing end of the sheet abuts a trailing end stopper 108. Here, in the embodiment, an aligning unit 130 aligning the sheets stacked on the intermediate processing tray 107 is configured of the take-in paddle 106, the trailing end stopper 108, and the front and back aligning panels 109a and 109b. It is noted that, for example, if an inclination of the intermediate processing tray 107 is large, the sheet can abut the trailing end stopper 108 without using the take-in paddle 106 or a knurled belt 117 described below.
It is noted that, as illustrated in
Furthermore, the finisher 100 includes a pair of inlet rollers 101 to capture the sheet into the apparatus and a discharging roller pair 103. The sheet P discharged from the apparatus body 900A is transferred to the pair of inlet rollers 101. It is noted that, at this time, transfer timing of the sheet is also detected simultaneously by an inlet port sensor S240. Then, the sheet P transferred to the pair of inlet rollers 101 is discharged sequentially to the intermediate processing tray 107 by the discharging roller pair 103 and then abuts the trailing end stopper 108 by the take-in paddle 106 or the knurled belt 117. Thus, alignment of the sheet in the direction of sheet conveyance is performed and the sheet bundle in which an aligning process is performed is formed.
It is noted that, the processing portion 139 has a trailing end dropper member 105 and as illustrated in
The processing portion 139 has a neutralization needle 104 that neutralizes the charged sheet and a batch holder 115. The batch holder 115 is rotated by a batch holding motor M255 illustrated in
Furthermore, the binding portion 100A includes a stapleless binding unit 102. Here, as illustrated in
Furthermore, the stapleless binding unit 102 includes a gear 1024 that is rotated by the stage gears 1022 and 1023. Furthermore, the stapleless binding unit 102 includes a lower arm 10212 illustrated in
Here, the gear 1024 is mounted on a rotation shaft 1026 to be relatively unrotatable. The rotation shaft 1026 is rotatably supported by the lower arm 10212 and the frame 10213. Then, a cam 1027 is fixed to the rotation shaft 1026 and the cam 1027 is provided between the upper arm 1029 and the lower arm 10212. Thus, if the stapleless binding motor M257 is rotated, the rotation of the stapleless binding motor M257 is transmitted to the rotation shaft 1026 through the gear 1021, the stage gears 1022 and 1023, and the gear 1024, and then the cam 1027 rotates.
As described above, in the embodiment, a moving unit 102A illustrated in
Here, as illustrated in
In
If the upper arm 1029 is pressed up by the cam 1027, the upper arm 1029 swings around the shaft 10211 as a supporting point and an end portion of the upper arm 1029 on a side opposite to the cam 1027 is lowered. Thus, the upper teeth 10210 are lowered and, as illustrated in
That is, when the binding process is performed on the sheet bundle, the upper arm 1029 is swung, the sheets are engaged with each other and pressed by the upper teeth 10210 of the upper arm 1029 and the lower teeth 10214 of the lower arm 10212, and thereby the sheet bundle is fastened. Here, a position of the cam 1027 is detected by a cam sensor S247 illustrated in
Furthermore, the CPU circuit portion 200 is connected to an image signal control unit 206 and the image signal control unit 206 is connected to an external PC (computer) 208 through an external interface 209. If print data is received from the external PC 208, the external interface 209 develops the data to a bit map image and outputs the image data to the image signal control unit 206.
Then, the image signal control unit 206 outputs the data to a printer control unit 207 and the printer control unit 207 outputs the data from the image signal control unit 206 to an exposure control portion (not illustrated). It is noted that, an image of a document read by an image sensor (not illustrated) provided in the image reading apparatus 950 is output from an image reader control unit 205 to the image signal control unit 206. The image signal control unit 206 outputs an image output to the printer control unit 207.
Furthermore, the CPU circuit portion 200 is connected to an operating unit 210 and the operating unit 210 has a plurality of keys for setting various functions regarding the image formation, a display portion for displaying a setting state, and the like. Then, the operating unit 210 outputs a key signal corresponding to an operation of each key by a user to the CPU circuit portion 200 and displays corresponding information based on a signal from the CPU circuit portion 200 to the display portion.
The CPU circuit portion 200 controls the image signal control unit 206 in accordance with the control program contained in ROM 202 and setting of the operating unit 210, and controls the original conveying unit 950A (see
It is noted that, in the embodiment, a finisher control unit 220 is mounted on the finisher 100 and performs drive control of the finisher 100 by exchanging information with the CPU circuit portion 200. Furthermore, the finisher control unit 220 is disposed in the apparatus body 900A integrally with the CPU circuit portion 200 and the finisher 100 may be controlled directly from the apparatus body 900A side.
Furthermore, the finisher control unit 220 drives a conveyance motor M250, a tray elevating motor M251, the paddle elevating motor M252, the alignment motor M253, the assist motor M254, the batch holding motor M255, the stapleless binding motor M257, a STP moving motor M258, and the like through a driver 225.
Furthermore, the finisher control unit 220 is connected to the inlet port sensor S240, a paper discharge sensor S246, the tray HP sensor S241, the tray lower limit sensor S242, the paddle HP sensor S243, the assist HP sensor S244, and the batch holder HP sensor S245. Furthermore, the finisher control unit 220 is connected to the cam sensor S247 and a current detection sensor S248. Then, the finisher control unit 220 drives the alignment motor M253, the stapleless binding motor M257, and the like based on the detection signal from each sensor.
However, the finisher control unit 220 controlling the operation of the stapleless binding unit 102 firstly detects a position of the cam 1027 by the cam sensor S247 if stapleless binding is performed to the sheet bundle. Then, when receiving the sheet before stapleless binding is performed, as illustrated in
It is noted that, the upper arm 1029 provided to be swingable around the shaft 10211 is biased in a direction coming into pressure contact with the cam 1027 by a biasing member (not illustrated). Then, when the cam 1027 is positioned at the bottom dead point, as illustrated in
Furthermore, when binding operation is performed, the stapleless binding motor M257 is rotated normally and the upper arm 1029 is swung in the counterclockwise direction around the shaft 10211 by the cam 1027. Then, as illustrated in
It is noted that, when the stapleless binding motor M257 is rotated forward, the finisher control unit 220 detects an amount of a current flowing through the stapleless binding motor M257 based on a signal from the current detection sensor S248. The current flowing through the stapleless binding motor M257 reaches a predetermined current value when the cam 1027 is positioned at the top dead point and stapleless binding of the sheets is completed. Thus, if the current flowing through the stapleless binding motor M257 reaches the predetermined current value, the finisher control unit 220 stops driving of the stapleless binding motor M257. Furthermore, thereafter, if the stapleless binding motor M257 is rotated reversely, the cam 1027 reaches the bottom dead point, and this is detected by the cam sensor S247, the finisher control unit 220 stops the rotation of the stapleless binding motor M257.
Next, a sheet binding processing operation of the finisher 100 according to the embodiment is described. As illustrated in
Next, the sheet P transferred to the pair of inlet rollers 101 is transferred from the pair of inlet rollers 101 to the discharging roller pair 103, is conveyed while the leading end portion of the sheet P lifts the trailing end dropper member 105, and simultaneously is discharged to the intermediate processing tray 107 while being neutralized by the neutralization needle 104. The sheet P discharged to the intermediate processing tray 107 by the discharging rollers 103 is pressed from above by the weight of the trailing end dropper member 105 and thereby a time when the trailing end portion of the sheet P drops to the intermediate processing tray 107 is reduced.
Next, the finisher control unit 220 performs control of an inside of the intermediate processing tray 107 based on a signal of the trailing end of the sheet P detected by the paper discharge sensor S246. That is, as illustrated in
After the sheet P transported by the take-in paddle 106 is transported to the trailing end stopper 108, the knurled belt 117 is rotated while slipping with respect to the sheet P and thereby biasing the sheet P to the trailing end stopper 108 the entire time. Thus, the sheet P abuts the trailing end stopper 108 and thereby it is possible to perform a skew correction of the sheet P. Next, as described above, after the sheet P abuts the trailing end stopper 108, the finisher control unit 220 drives the alignment motor M253, moves the aligning plate 109 in the width direction perpendicular to the sheet discharge direction, and aligns the position of the sheet P in the width direction. A series of the operation is repeatedly performed with respect to a predetermined number of the sheets to be binding-processed and thereby as illustrated in
Next, after such an aligning operation is performed, if a binding mode is selected, the binding process is performed by the binding unit 100A. Thereafter, as illustrated in
It is noted that, thereafter, as illustrated in
It is noted that, during the operation, if the stacking tray 114 is lowered and shields the tray lower limit sensor S242 from light, a full stack of the stacking tray 114 is informed from the finisher control unit 220 to the CPU circuit portion 200 of the image forming apparatus 900 and the image formation is stopped. Thereafter, if the sheet bundle on the stacking tray 114 is removed, after the stacking tray 114 is lifted until shielding the tray HP sensor S241 from light, the stacking tray 114 is lowered and thereby the tray HP sensor S241 is transmitted through. Thus, the paper surface position of the stacking tray 114 is determined again. Thus, the image formation of the image forming apparatus 900 is restarted.
Next, when stapleless binding is performed, a stapleless binding operation control of the finisher control unit 220 is described with reference to a flowchart illustrated in
Then, the position of the cam 1027 is detected by the cam sensor S247 illustrated in
Next, the finisher control unit 220 determines whether or not to perform the stapleless binding operation (ST5). If stapleless binding is performed (Y of ST5), the finisher control unit 220 normally rotates the stapleless binding motor M257 (ST6) and swings the upper arm 1029 around the shaft 10211 by the cam 1027 in the counterclockwise direction. Thereafter, if the cam 1027 is further rotated and reaches the position indicated in
Here, the finisher control unit 220 determines whether the current flowing through the stapleless binding motor M257 reaches a predetermined current value based on a signal from the current detection sensor S248 (ST7). Then, if it is detected that the current reaches the predetermined current value (Y of ST7), the stapleless binding motor M257 is rotated reversely (ST8). Thus, the cam 1027 is rotated reversely. Therefore, the upper arm 1029 swings around the shaft 10211 in a clockwise direction and the upper teeth 10210 move in a direction separated from the lower teeth 10214.
Next, the finisher control unit 220 determines whether the cam 1027 reaches the HP by the cam sensor S247 (ST9). Then, if it is determined that the cam 1027 does not reach the HP (N of ST9), the stapleless binding motor M257 is continuously rotated reversely (ST8). Thereafter, if it is detected that the cam 1027 is positioned at the HP by the cam sensor S247 (Y of ST9), the stapleless binding motor M257 is stopped (ST10). Thus, the binding operation of the sheet bundle is completed. Furthermore, if the binding operation is not performed, the process proceeds from ST5 to ST10, and the stapleless binding motor M257 continues a stop state.
As illustrated in
As illustrated in
As illustrated in
Furthermore, the side surface portions 11b and 11c of the first arm 1029A that is the first arm member are respectively provided with long round holes 1029A3 and 1029A3 through which a fixing shaft 10218 passes. Similarly, the side surface portions 12b and 12c of the second arm 1029B that is the second arm member are respectively provided with through-holes 1029B3 and 1029B3 through which the fixing shaft 10218 passes. The fixing shaft 10218 passes through the long round hole 1029A3 and the through-hole 1029B3, and one end of the fixing shaft 10218 is caulked into the through-hole 1029B3 of the second arm 1029B. Then, the first arm 1029A and the second arm 1029B are connected by the shaft 10211 and the fixing shaft 10218, and are relatively positioned.
As shown in
The support end 1029A1 of the first arm 1029A projects downward more than the support end 1029B1 of the second arm 1029B, and the support end 1029B1 is distant from the upper teeth block portion 10216. Thereby, while the upper teeth 10210 is supported by the first arm 1029A through the upper teeth block portion 10216, it is not supported by the second arm 1029B in a state when no pressure is applied. It is noted that in the state when no pressure is applied, the extension portion 10216b overlaps horizontally with the support end 1029A1 of the first arm 1029A and with the support end 1029B1 of the second arm 1029B.
Meanwhile, as shown in
It is noted that, the upper teeth block 10216 is mounted on the first arm 1029A and the support end 1029A1 of the first arm 1029A is protruded downward more than the support end 1029B1 of the second arm 1029B. This is because of a consideration of processing variation by pressing. If processing variation is considered, it is difficult to make the support end 1029A1 of the first arm 1029A and the support end 1029B1 of the second arm 1029B in the equal plane at all times. However, the support end 1029A1 of the first arm 1029A and the support end 1029B1 of the second arm 1029B may be provided in the equal plane.
Here, in the embodiment, as described below, since the plate thickness of the first arm 1029A is thinner than the plate thickness of the second arm 1029B, the first arm 1029A is likely to be deflected more than the second arm 1029B. Thus, when performing stapleless binding, the first arm 1029A on which the upper teeth block 10216 is mounted is protruded upward and is deflected, and thereby it is possible to stably support the upper teeth block 10216 (upper teeth 10210) by the first arm 1029A and the second arm 1029B in the pressed state described above. That is, when the upper arm 1029 is positioned in the binding position, the second arm 1029B regulates deflection of the first arm 1029A.
It is noted that, in the embodiment, in the state of
If the distances L1 and L2 are short, the through-holes 1029A2 and 1029B2 may be deformed when performing bending after hole making. Here, when the plate thickness of the first arm 1029A and the second arm 1029B is t and a radius of the inner side surface of the bending portion is R, if L1, L2≥2t+R, it is possible to prevent deformation of the through-holes 1029A2 and 1029B2 even if bending is performed after hole making.
It is noted that, in the embodiment, the plate thickness t of the first arm 1029A is 1.5 mm and an inner radius R of bending is 0.75 mm. Since it is necessary to set the inner radius R of bending ½ or more of the plate thickness t to ensure durability of the mold in pressing, the inner radius R is 0.75 mm that is ½ of the plate thickness t. As a result, in order to prevent the deformation of the through-hole 1029A2, a length of the distance L1 is 3.75 mm (=1.5 mm×2+0.75 mm) considering the plate thickness t and the inner radius R of bending.
Furthermore, the plate thickness of the second arm 1029B is 2.0 mm. Furthermore, since it is necessary to set the inner radius R of bending ½ or more of the plate thickness t to ensure durability of the mold in pressing, the inner radius R is 1.0 mm that is ½ of the plate thickness t. As a result, in order to prevent the deformation of the through-hole 1029B2, the length of the distance L2 is 5.5 mm that is greater than 5.0 mm (=2.0 mm×2+1.0 mm) considering the plate thickness t and the inner radius R of bending. That is, the length of the distance L2 is set to be smaller than three times (2.0 mm×3=6.0 mm) the plate thickness t of the second arm 1029B.
Here, if the upper arm 1029 is not the double structure of the first arm 1029A and the second arm 1029B, and the plate thickness t of one structure is 3.5 mm, it is necessary to make the inner radius R of bending 1.75 mm. In this case, in order to prevent the deformation of the through-hole, a distance from the top plate portion to the through-hole is 8.75 mm (=3.5 mm×2+1.75 mm).
It is noted that, since load-bearing is increased by increasing the plate thickness t, if the plate thickness t is decreased to 3.0 mm in accordance with a desired load-bearing when binding by clamping the sheet bundle, the inner radius R becomes 1.5 mm. In this case, the distance from the top plate portion to the through-hole becomes 7.5 mm (=3.0 mm×2+1.5). As described above, the distance from the top plate portion to the through-hole is shorter in the value (=5.5 mm) of the distance L2 indicating the distance when the upper arm 1029 is the double structure than the distance (=7.5 mm) when the upper arm 1029 is single structure. Thus, it is possible to reduce the external shape of the upper arm 1029. That is, if load-bearing is equal, it is possible to reduce the external shape of the upper arm 1029 in the double structure more than the single structure.
As described above, in the embodiment, the upper arm 1029 is configured of the U-shaped first arm 1029A and the second arm 1029B mounted to cover a part of the first arm 1029A. Then, if the upper arm 1029 is configured of the first arm 1029A and the second arm 1029B, even if the plate thicknesses of the first arm 1029A and the second arm 1029B are respectively thin, it is possible to obtain desired load-bearing by receiving the load by the first arm 1029A and the second arm 1029B.
Furthermore, the plate thicknesses of the first arm 1029A and the second arm 1029B are thinner than that of the single structure that is configured to have load-bearing equal to the upper arm 1029 configured of the double structure. Thus, it is possible to reduce the distance from the through-holes 1029A2 and 1029B2 to the top plate portion of the upper arm 1029, and to downsize the upper arm 1029. That is, the upper arm 1029 is configured of the first arm 1029A and the second arm 1029B, and the plate thicknesses of the first arm 1029A and the second arm 1029B are thin, and thereby it is possible to downsize the upper arm 1029 at low cost.
It is noted that, in the above description, the upper arm 1029 has the double structure, the number of overlapping U-shaped arms is not limited to the embodiment and it is possible to obtain the same effects also in a triple structure or more.
Furthermore, in the embodiment, since the U shape of the lower arm 10212 is larger than the U shape of the upper arm 1029, load-bearing is also large by setting the plate thickness of the lower arm 10212 thicker than that of the second arm 1029B. Thus, the lower arm 10212 can ensure the strength without being made by the double structure, but the lower arm 10212 may have the double structure. That is, in the above description, a case where the upper arm 1029 has the double structure is described, but if at least one of the upper arm 1029 and the lower arm 10212 has the double structure, it is possible to downsize the arm having the double structure.
Furthermore, in the embodiment, the lower arm 10212 is fixed and the upper arm 1029 is capable of swing, but the configuration is not limited to the embodiment. For example, the upper arm 1029 is fixed, and the lower arm 10212 may be capable of swing, and may have the double structure. For example, both the upper arm 1029 and the lower arm 10212 may be capable of swing and may have the double structure.
Furthermore, in the embodiment, in a state where the upper arm 1029 is positioned in the binding position, the upper teeth block 10216 mounted on the first arm 1029A is configured to abut the second arm 1029B, but the configuration is not limited to the embodiment. For example, the first arm 1029A receiving the load from the upper teeth block 10216 is deformed, the deformed first arm 1029A is configured to abut the second arm 1029B, and the second arm 1029B may be configured to receive the load of the upper teeth block 10216 through the first arm 1029A.
Furthermore, the second arm 1029B may be welded to the first arm 1029A. Furthermore, the upper teeth block 10216 and the first arm 1029A may be integrally formed.
Furthermore, in the embodiment, the upper teeth block 10216 is mounted on the first arm 1029A, but the upper teeth block 10216 is mounted on the second arm 1029B, and the first arm 1029A may receive the loads of the second arm 1029B and the upper teeth block 10216.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2014-137418, filed Jul. 3, 2014, and Japanese Patent Application No. 2015-126586, filed Jun. 24, 2015, which are hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2014-137418 | Jul 2014 | JP | national |
2015-126586 | Jun 2015 | JP | national |
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20160002000 A1 | Jan 2016 | US |