1. Field of the Invention
The present invention relates to a sheet conveying apparatus provided in an image forming apparatus such as a copying machine or a printer.
2. Description of the Related Art
As an image forming apparatus according to the related art, Japanese Patent Laid-Open No. 11-143155 discloses an image forming apparatus having a configuration in which a plate spring member applies a force to a conveying follower roller facing a conveying driving roller.
Japanese Patent Laid-Open No. 2008-213982 discloses a configuration in which a bearing is provided with a boss and a wound spring is mounted on the boss to apply a force to a roller.
Japanese Patent Laid-Open No. 2008-170825 discloses a configuration in which an axial portion of an inverting roller is inserted into an insertion groove in which the upper side of a bearing is opened and the upper end opening portion of the insertion groove is blocked with a dustproof sheet.
In Japanese Patent Laid-Open No. 11-143155, when a conveying follower roller is detached to perform maintenance or repair, a plate spring member is removed in a positional relation among a guide plate, the conveying follower roller, and the plate spring member, and then the conveying follower roller is detached. Therefore, when the conveying follower roller is installed on the inside of an exterior cover, the exterior cover has to be detached and the guide plate has to be detached in order to detach the conveying follower roller. Therefore, there is a problem that an extensive disassembly operation is performed.
In Japanese Patent Laid-Open No. 2008-213982, since the wound spring is mounted on the boss installed in the bearing of the roller, the boss contributes to stability of the applied force generated by the wound spring. The semicircular bearing receiving an axial portion of the roller receives an impact caused when the front ends of various sheets with different thicknesses passing through a sheet conveying path collide against a nip portion of a pair of rollers. Further, sheet powders produced from the sheets are deposited on a semicircular rubbing surface receiving the axial portion of the roller, and thus the bearing receives an impact caused when the front ends of the sheets collide against the depositions. Furthermore, the bearing receives an impact caused when the rear ends of the sheets are separated from the pair of rollers. Due to such influences, there is a probability that the axial portion of the roller is separated from the semicircular rubbing surface receiving the axial portion of the roller.
When one roller is installed on the inside of the exterior cover, there is a problem that a separate component is necessary to prevent the roller installed on the side of an apparatus body from being detached.
In Japanese Patent Laid-Open No. 2008-170825, the dustproof sheet is attached to prevent the axial portion from coming off or rattling. Thus, since a protruding object or the like is covered with the dustproof sheet and a sheet conveying surface becomes gentle, the curled front end of the sheet can be prevented from being caught. However, when the inverting roller or the axial portion is exchanged, the dustproof sheet is removed. When exchanging the inverting roller or the axial portion is completed, a glue of a pasting surface of the dustproof sheet is cleaned up, and thus a new dustproof sheet is re-covered. Therefore, a component cost may increase, and a sheet may be hooked due to an erroneous work for attaching the dustproof sheet in some cases since the work is not stable.
In order to solve the problems described above, the invention provides an image forming apparatus in which a work for mounting and detaching a follower rotating member facing a conveying rotating member can be easily performed and a sheet can be satisfactorily conveyed.
In order to accomplish the above-mentioned aspect, as a representative configuration, the present invention provides a sheet conveying apparatus comprising: a follower rotating member that is pressed to a conveying rotating member and rotates in a following manner; a bearing that movably supports the follower rotating member to be rotatable; a pressing portion that applies a force to the bearing to press the follower rotating member to the conveying rotating member; and a wire spring that includes both ends locked to locking portions and a middle abutted to the bearing and holds the bearing against a pressing force of the pressing portion.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
An image forming apparatus including a sheet conveying apparatus according to an embodiment of the invention will be described in detail with reference to the drawings.
First, the configuration of the image forming apparatus including the sheet conveying apparatus according to a first embodiment of the invention will be described with reference to
An image forming apparatus 100 illustrated in
The image forming portions 1 forms respective color toner images of yellow Y, magenta M, cyan C, and black K on photosensitive drums 11Y, 11M, 11C, and 11K serving as image bearing members and performs primary transfer to the same image position on the intermediate transfer belt 31.
The intermediate transfer belt 31 is suspended by a driving roller 33, a tension roller 34, and a transfer counter roller 32 used to perform secondary transfer and are rotated. On the internal periphery side of the intermediate transfer belt 31, primary transfer rollers 35Y, 35M, 35C, and 35K performing the primary transfer are disposed at positions facing the photosensitive drums 11, respectively.
A charging roller 12Y that uniformly charges the surface of the photosensitive drum 11Y and an exposure device 13Y that exposures the surface of the photosensitive drum 11Y and forms an electrostatic latent image are provided around the photosensitive drum 11Y that forms a toner image of the yellow Y. A development device 14Y that forms a toner image by transitioning toner to the electrostatic latent image onto the surface of the photosensitive drum 11Y and a cleaning member 15Y that removes the toner remaining on the photosensitive drum 11Y after the primary transfer of the toner image are also provided.
Configurations in which toner images of the respective colors of the magenta M, the cyan C, and the black K are formed are the same as that in the case of forming the toner image of the yellow Y described above. Therefore, the suffix Y in the above description is substituted with M, C, and K and the overlapping description of each color will not be repeated.
On the other hand, a sheet S accommodated in a sheet cassette 61, 62, 63, or 64 is conveyed to a sheet conveying path 81 by rotating any of a feeding roller 71, 72, 73, or 74. A conveying roller 142 serving as a conveying rotating member installed on the body side (apparatus body side) of the image forming apparatus 100 is rotatably driven on the sheet conveying path 81 by a motor or the like serving as a driving source (not illustrated) installed in the body of the image forming apparatus 100.
A follower roller 107 serving as a follower rotating member that is pressed against the conveying roller 142 and is rotated in a follow manner is provided on the side (door side) of a door 101 that can be opened and closed with respect to the body (apparatus body) of the image forming apparatus 100. The sheet S sent to the sheet conveying path 81 is nipped by the conveying roller 142 and the follower roller 107 and is conveyed.
A registration roller 75 conveys the sheet S to a secondary transfer nip portion in which the secondary transfer roller 41 and the transfer counter roller 32 are abutted through the intermediate transfer belt 31 at an appropriate timing with the toner image on the intermediate transfer belt 31.
Next, the sheet S to which the toner image on the intermediate transfer belt 31 is transferred through an operation of the secondary transfer roller 41 in the secondary transfer nip portion is born on a conveying belt 42 and is conveyed to a fixing device 5. The toner image is fixed to the surface of the sheet S so that the full-color image can be fixed through heating and pressurizing by the fixing device 5. Thereafter, the sheet S is discharged to a discharge tray 65 through a discharge path 82. The toner remaining on the intermediate transfer belt 31 is removed by a cleaning member 99 and is received inside a waste-toner container 36.
As illustrated in
When the sheet S is jammed in the sheet conveying path 81, the user can remove the jammed sheet S by opening the door 101 since the door 101 is formed on one side of the sheet conveying path 81.
At the time of a maintenance service, the user holds a concave portion 109 of the door 101 formed on the side of the sheet conveying path 81 with his or her hand, as illustrated in
A frame casing of the image forming apparatus 100 is configured by a combination of constituent components such as a front right post 128, an upper right stay 129, an upper left stay 130, a rear side plate 113, and a bottom plate 131 illustrated in
In
Here, the sheet S separated one by one passes through a feeding guide 141, is nipped in a nip portion 145 in which the conveying roller 142 and the follower roller 107 are abutted, and is conveyed. The sheet S sent to the sheet conveying path 81 is further conveyed toward an upper sheet conveying path 81a which is the downstream side of a sheet conveying direction.
Likewise, the sheet S fed from the sheet cassette 62 on the lower side is conveyed from a lower sheet conveying path 81b. The conveying guide plate 106 facing the conveying roller 142 is disposed to be substantially vertical with respect to the body of the image forming apparatus 100. A reinforcing stay 132 is mounted on the opposite side to the conveying roller 142.
The stay 132 mounted on the conveying guide plate 106 is provided with bearing guides 132f and 132g that slidably guide a bearing 137 axially supporting a rotation shaft 107a of the follower roller 107 so that the rotation shaft 107a is rotatable.
As illustrated in
Hook portions 135a formed at both ends of a wire spring 135 illustrated in
As illustrated in
A pair of flexible arm portions 135e is formed which is perpendicular to the pressing portions 135c, is disposed at a predetermined inclination angle with respect to the hook arm portions 135b, and can restrain the bearing 137 in an axial direction so as to face a side surface (end surface) 137d of the bearing 137. Further, a semicircular flexible portion 135d is formed which is connected to the pair of flexible arm portions 135e and formed in the middle of the line spring 135. The line spring 135 according to this embodiment is formed as the U-shaped flexible portion 135d by the pair of flexible arm portions 135e and the semicircular flexible portion 135d.
The bearing guides 132f and 132g formed in the stay 132 guide the bearing 137 such that the bearing 137 can move in a direction (right and left directions of
The conveying guide plate 106 formed of an electrogalvanized steel plate or the like and guiding the conveying of the sheet S is formed on the inner surface of the door 101. A detachable hole 106a is formed within a sheet conveying width (within a range of a width in a direction perpendicular to the conveying direction of the sheet S) of the conveying guide plate 106 in which the sheet S is conveyed.
The line spring 135, the bearing 137, the follower roller 107, and the coil spring 136 are configured to be integrally mounted and detached from the detachable hole 106a. When the line spring 135, the bearing 137, the follower roller 107, and the coil spring 136 are integrally mounted and detached from the detachable hole 106a, the door 101 is opened from the body (apparatus body) of the image forming apparatus 100.
The hook portions 135a of the line spring 135 are mounted and detached from the notches 132h and 132i formed at the ends of the bearing guides 132f and 132g formed in the stay 132. Thus, the line spring 135, the bearing 137, the follower roller 107, and the coil spring 136 are configured to be integrally mounted and detached.
As illustrated in
Three detachable holes 106a according to this embodiment are vertically arranged in parallel. A pair of two follower rollers 107 formed of a material such as a POM (Polyoxymethylene) resin having a good slippery property is disposed to the right and left inside each detachable hole 106a. A total of six follower rollers 107 are arranged inside the detachable holes 106a arranged vertically in three lines in the door 101.
The exterior cover 108 formed of a resin and serving as an outer surface is formed outside of the door 101.
Retractable hinges capable of mounting and detaching the door 101 on and from the body of the image forming apparatus 100 are used as the hinges 102 and 103 formed vertically on the back side of the door 101. The retractable hinges are fitted to be mounted on hinge shaft portions 112a of the rotation center of the hinges 102 and 103 rotating at the time of opening and closing the door 101 in upper and lower thrust directions so as to be inserted and detached.
The hinge 112 fixed to the body side of the image forming apparatus 100 is fixed to the end of the rear side plate 113, which is the frame casing of the body of the image forming apparatus 100 illustrated in
As illustrated in
The hinges 102 and 103 attached to the rear side plate 113 illustrated in
As illustrated in
The shaft 134 is maintained to be rotatable through the bearings 147 provided in the door 101, and thus a force is normally applied to the hook portions 104 and 111 in a direction in which locks are hung on the holding projections 149 by torsion coil springs 148. When the knob 105 is rotated against the applying force of the torsion coil springs 148, the hook portions 104 and 111 are taken off from the holding projections 149, so that the door 101 can be opened.
The reinforcing stays 132 are arranged in three lines to the right and left in parallel on the rear surface side of the conveying guide plate 106 of the door 101. The stays 132 are screwed to be fixed to screw holds formed in fixed pedestals 101a formed on the internal surface of the door 101 illustrated in
The follower rollers 107 are accommodated and arranged in the concave portions 132n of the stay 132 having a hat-like cross section to be bilaterally symmetric centering on a center line 151 of the sheet conveying width illustrated in
The stays 132a to 132c all have the same shape and the rotation shafts 107a of the follower rollers 107 are axially supported by the bearings 137.
Screw seating surfaces 132e formed from curved portions curved and erected through sheet-metal processing are formed at the ends of the stay 132 in its length direction, as illustrated in
The bearing 137 is molded using a POM (Polyoxymethylene) resin, a PA (Polyamide) resin, a fluorine-based resin, or the like having good lubricity for the bearing guides 132f and 132g and abrasion resistance. To achieve high durability and a maintenance-free property, a sintered metallic molded component such as an iron-based sintered component, an iron-copper-based sintered component, or a copper-based sintered component having a good slidable property may be used. Further, a ball bearing or the like that slides to the bearing guides 132f and 132g may be provided.
As illustrated in
The bearing 137 is slidably fitted to be maintained between the bearing guides 132f and 132g formed by curving parts of the stay 132 from the spring seating surface 132k by 90 degrees by sheet-metal processing.
As illustrated in
As illustrated in
The conveying guide plate 106 and the stay 132 are fastened to a burring caulking portion 106d to be integrally fixed. As illustrated in
In the middle of the stay 132 in the length direction, a pair of follower rollers 107 is disposed to be bilaterally symmetric centering on a center line 151 of the sheet conveying width of the sheet S passing through the sheet conveying path 81, as illustrated in
To integrate the conveying guide plate 106 and the stay 132, caulking holes 132d are formed in a fixed piece 132m of the stay 132 illustrated in
The follower roller 107 is configured as a stepped roller that has a middle with a large diameter in the length direction and both right and left ends with a small diameter in the length direction. Both ends of the rotation shaft 107a of the follower roller 107 are axially supported to be rotatably by the bearing 137. As illustrated in
As illustrated in
As illustrated in
The bearing 137 is configured to be slidable along the bearing guides 132f and 132g, and thus is configured to be slidably moved smoothly.
As illustrated in
One end of the coil spring 136 is press-fitted into the boss 137b formed in the spring abutting surface 137c of the bearing 137 to be maintained by a tightening force applied in the inner diameter direction of the coil spring 136. Thus, the coil spring 136 is supported so that the axial direction of the coil spring 136 is substantially perpendicular to the spring seating surface 132k of the stay 132.
The line spring 135 according to this embodiment includes the hook portions 135a to lock the line spring 135 into the notches 132h and 132i formed in the bearing guides 132f and 132g of the stay 132. The line spring 135 further includes the hook arm portions 135b supporting the hook portions 135a. The line spring 135 further includes the pressing portions 135c abutted to the spring reception surface 137a of the bearing 137. The wire spring 135 further includes the flexible portion 135d generating the restoring force to balance the load caused due to the pressurizing force of the coil spring 136. The wire spring 135 further includes the flexible arm portions 135e connecting the flexible portion 135d to the pressing portions 135c and flexibly opened and closed.
A spring line material such as the stainless SUS 304, WPB, SWPB, or SWIC can be used as the material of the wire spring 135.
As the wire spring 135 according to this embodiment, a wire spring which has an outer diameter of 0.5 mm as a line diameter, a 1.7 mm length of the flexible arm portion 135e, and a 2 mm radius of the flexible portion 135d is formed of a cheap SWIC material for which plating is not necessary in a subsequent process.
Next, referring to
First, an order will be described in which the wire springs 135, the bearings 137, the follower rollers 107, and the coil springs 136 are integrally mounted on the detachable hole 106a formed in the conveying guide plate 106.
First, by using two bearings 137 as one set, one end of the coil spring 136 is mounted to be maintained on the boss 137b formed in the spring abutting surface 137c of each bearing 137 in advance.
Next, the bearing 137 is mounted on both ends of the rotation shaft 107a of the follower roller 107. Then, the follower roller 107, the bearing 137, and the coil spring 136 are integrally set. In this state, the bearing 137 is accommodated inside the concave portion 132n of the stay 132, while being inserted between the right and left bearing guides 132f and 132g provided on the stay 132 from the detachable hole 106a formed in the conveying guide plate 106.
When the follower roller 107 is accommodated inside the concave portion 132n of the stay 132, the flexible portion 135d of the wire spring 135 faces and comes into contact with the side end of the rotation shaft 107a of the follower roller 107 in the length direction. Thus, when the follower roller 107 is mounted and detached, position deviation in the direction of the rotation shaft 107a can be prevented between the follower roller 107 and the bearing 137. Therefore, when the bearing 137 is inserted between the bearing guides 132f and 132g, position adjustment can be realized easily, and thus workability is improved.
The bearing 137 is inserted between the bearing guides 132f and 132g. Then, the other end of the coil spring 136 of which one end is fitted to be maintained into the boss 137b formed in the spring abutting surface 137c of the bearing 137 engages to be fitted into the emboss 132j protruding from the spring seating surface 132k of the stay 132. Then, the coil spring 136 is guided to the emboss 132j and reaches the spring seating surface 132k.
Next, the hook portions 135a of the wire spring 135 are hooked to engage with the notches 132h and 132i formed in the front ends of the bearing guides 132f and 132g, while the pressing portions 135c of the wire spring 135 is abutted to the spring reception surface 137a of the bearing 137.
Thus, as illustrated in
When the pressurizing force of the coil spring 136 is applied to the wire spring 135 through the bearing 137, the wire spring 135 is curved. Then, in the notches 132h and 132i formed in the front ends of the bearing guides 132f and 132g, a component force of the inside direction vector in which a pair of hook portions 135a of the wire spring 135 is attracted in the inside direction works. Thus, the wire spring 135 is not deviated due to the pressurizing force of the coil spring 136.
In this embodiment, in the coil spring 136, there is no sheet S and the pressurizing force of 2.7 N (about 275 gf) is set at the abutting position of the follower roller 107 to the conveying roller 142, as illustrated in
Next, an order will be described in which the wire springs 135, the bearings 137, the follower rollers 107, and the coil springs 136 are integrally detached from the detachable hole 106a formed in the conveying guide plate 106.
First, the user inserts his or her hand into the detachable hole 106a formed in the conveying guide plate 106 and takes off the hook portions 135a of the wire spring 135 from the notches 132h and 132i formed at the front ends of the bearing guides 132f and 132g. Thus, the bearings 137 are extruded by the pressurizing force of the coil springs 136 and the follower rollers 107 can be easily detached in the direction of an arrow a in
As described above, the detachable hole 106a is formed in the conveying guide plate 106 provided on the inside surface side of the door 101 to integrally detach the wire springs 135, the bearings 137, the follower rollers 107, and the coil springs 136. Thus, the follower rollers 107, the bearings 137, the coil springs 136 mounted on the bearings 137, and the wire springs 135 can be mounted and detached from the inside surface side of the conveying guide plate 106.
As illustrated in
In general, when about one million sheets S of the A4 size were conveyed, the durability life of an image forming apparatus was finished about ten years ago from the current. This case is an example when an MFP (Multifunction Printer or Multifunction Peripheral) or the like of a medium-speed machine class is used. Currently, when about three million sheets S of the A4 size are conveyed, the durability life of an image forming apparatus is finished.
To use the image forming apparatus 100 longer, improvement and optimization of individual components are designed and a maintenance-free apparatus is in progress.
On the other hand, an improvement in the maintenance property by a serviceman is also preferable. It is desirable to reduce an initial cost which is a price of an image forming apparatus including production equipment and die investment reflected to the sale price of a product and a running cost relevant to maintenance, service, and supply after installation for a user. Maintenance such as easy exchange at the time of cleaning or checking up an apparatus is required to be improved.
In this embodiment, the hook portions 135a of the wire spring 135 are detached from the notches 132h and 132i formed in the front ends of the bearing guides 132f and 132g provided in the stay 132. Thus, it is possible to easily exchange or clean and check up the components of the follower roller 107, the bearing 137, and the coil spring 136. Therefore, since the maintenance time can be shortened, the contribution to the maintenance efficiency can be achieved.
In correspondence with the change in the position of the follower roller 107 provided on the side of the door 101, the position of the bearing 137 is slid and moved between the bearing guides 132f and 132g. At this time, the pressing portions 135c of the wire spring 135 normally come into contact with the spring reception surface 137a of the bearing 137 by the restoring force (elastic force) of the wire spring 135 and follow the movement of the bearing 137. Thus, the sheet conveying path 81 is disposed normally at the most retracted position without interference of the wire spring 135 and the bearing 137 to the conveyed sheet S.
A thick sheet used in the image forming apparatus 100 is regulated by a basis weight which is a weight per unit area and 45 g/m2 to 230 g/m2 is generally considered to be thick. The basis weight of the sheet S used in the image forming apparatus 100 according to this embodiment is 200 g/m2 and thickness of the sheet S is about 0.41 mm. Accordingly, the follower roller 107 nipping the sheet S against the conveying roller 142 at the fixed position is moved to the right direction of
Likewise, the bearing 137 axially supporting the rotation shaft 107a of the follower roller 107 is also moved to the right direction of
A spring constant of the coil spring 136 according to this embodiment is 0.44 N/mm (about 45 gf/mm). Thus, when the follower roller 107 is moved to the right direction of
As illustrated in
When the follower roller 107 is separated from the conveying roller 142, as illustrated in
When the follower roller 107 is separated from the conveying roller 142, as illustrated in
Thus, a sum of the pressurizing forces of the twelve coil springs 136 is 32.36 N (about 3.3 kgf). Further, a spring tolerance of the coil spring 136 is about ±10%. Therefore, when the spring tolerance of the coil spring 136 is the maximum, the maximum pressurizing force of the sum of the pressurizing forces of the twelve coil springs 136 is 35.60 N (about 3.63 kgf).
When a conveying guide formed of a resin according to the related art is used, the maximum pressurizing force of the sum of the pressurizing forces of the twelve coil springs 136 may not be sufficient for the reinforcement of the conveying guide. Therefore, the flexibility of about 2 mm occurs. Further, even when a reinforcing rib is added to the conveying guide, a load is applied for a long time. Therefore, an elastic repulsive force gradually decreases due to aging deterioration and permanent deformation occurs before long. Accordingly, the flexibility gradually increases. Accordingly, in a case of a high durable MFP (Multifunction Printer or Multifunctional Peripheral), the sheet conveying force gradually decreases. Thus, there is a problem that the sheet S may be skew-fed.
In this embodiment, by providing the conveying guide plate 106 formed of a metal plate with the reinforcing stay 132, the deformation caused due to the maximum pressurizing force of the sum of the pressurizing forces of the twelve coil springs 136 can be reduced to about 0.05 mm. Therefore, durability may be achieved even when the coil springs are changed over time.
Further, the stability of the pressurizing force to the follower roller 107 can be contributed, the stability increases for conveying the sheet S that much. Therefore, the performance rarely deteriorates even for long-time change and a product specification can be satisfied.
In the sheet conveying path 81, when the sheet S is a thick sheet, the follower roller 107 is pushed in the right direction of
Accordingly, the maximum clearance dimension of the follower roller 107 is at least set such that the outer circumferential surface of the follower roller 107 is set to the side of the conveying roller 142 (the left side of
In the above-described configuration, the movement operation in the pressurizing direction of the coil spring 148 of the bearing 137 pressurized by the coil spring 136 by the restoring force of the wire spring 135 is smoothly performed.
Thus, a stepped difference between the outer diameter of the follower roller 107 and the bearing 137 can be determined such that the sheet S at least does not interfere with the bearing 137 and the follower roller 107 can be reliably maintained by space-saving.
The hook portions 135a of the wire spring 135 are mounted and detached from the notches 132h and 132i of the bearing guides 132f and 132g provided in the stay 132. Thus, since the wire spring 135, the bearing 137, the follower roller 107, and the coil spring 136 can be easily mounted and detached, assembly and disassembly becomes easy at the time of manufacturing a product, maintenance, and repair service. Therefore, workability is improved.
Next, the configurations of a sheet conveying apparatus and an image forming apparatus including the sheet conveying apparatus according to a second embodiment of the invention will be described with reference to
When the maximum amount of displacement of the bearing 137 increases or the sheet conveying speed is required to be faster, the pressurizing force of the coil spring 136 increases in some cases. In this case, it is necessary to appropriately modify the spring shape of the wire spring 135 to meet the demand.
In
In this embodiment, as illustrated in
The bearing 137 is pressurized to the left direction of
In this embodiment, the open angle of one pair of flexible arm portions 135e centering on the flexible portion 135d of the wire spring 135 can be widened. Thus, when the change in the position of the bearing 137 in the pressurization direction of the bearing 137 by the coil spring 136 is large, the influence of the restoring force of the wire spring 135 can be reduced and the following range of the bearing 137 can be expanded. Since the other configuration is the same as the configuration of the first embodiment, it is possible to obtain the same advantages.
Next, the configurations of a sheet conveying apparatus and an image forming apparatus including the sheet conveying apparatus according to a third embodiment of the invention will be described with reference to
By forming the torsion coil spring portion 135f in the flexible portions 135d, the line length of the wire spring 135 is lengthened, and thus both a torsion force and a flexible force generated by the torsion coil spring portion 135f are combined.
Thus, the numerical value of the spring constant of the wire spring 135 can be further reduced. Therefore, in the movement of the bearing 137 in the pressurization direction by the coil spring 136, the spring pressure applied to the spring reception surface 137a of the bearing 137 can be set to be closer in the pressurization direction by the coil spring 136.
Accordingly, the restoring force of the wire spring 135 for the high-speed change in the sheet conveying speed at the time of conveying the sheet can be set to be closer in the pressurization direction by the coil spring 136, and thus followability of the bearing 137 for the change in the position of the bearing 137 can be improved. Further, the durability of the wire spring 135 can be lengthened.
The optimum shape of the wire spring 135 can be selected so as to be suitable for all of the conditions such as the position condition of the used follower roller 107, the pressurizing force of the coil spring 136, and a dimensional tolerance. Since the other configuration is the same as the configuration of each embodiment described above, it is possible to obtain the same advantages.
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 modifications, equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2012-101865, filed Apr. 26, 2012, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2012-101865 | Apr 2012 | JP | national |