Embodiments described herein relate generally to sheet alignment in a sheet conveying device and an image forming system having the same.
An image forming system (e.g., an MFP) includes a sheet conveying device that conveys a sheet along a conveying path. The sheet conveying device may include an aligning mechanism that performs alignment processing for correcting a tilt of the sheet conveyed along the conveying path. For example, the aligning mechanism may perform the aligning processing by causing the sheet to hit against a nip of a pair of stopped rollers and bending the sheet. However, if the skew of the sheet is too large during the aligning processing, the sheet may generate wave in a direction different from the sheet conveying direction when the sheet is bent. If the sheet is conveyed by the pair of rollers in a state in which the sheet waves in that manner, sheet damage such as creases and folded traces is likely to occur in the sheet.
In general, according to an embodiment, a sheet conveying device includes an aligning roller and a sheet guide. The aligning roller is configured to rotate in a forward direction along a sheet conveying direction, and stop rotation or rotate in a reverse direction opposite to the forward direction to align a sheet conveyed thereto with a nip formed with the aligning roller. The sheet guide is disposed along a sheet conveyance path extending to the nip in the sheet conveying direction, and movable between a first position at which the sheet conveyance path has a first width in a thickness direction of the sheet and a second position at which the sheet conveyance path has a second width in the thickness direction less than the first width. The sheet guide is at the first position when the aligning roller stops rotation or rotates in the reverse direction for sheet alignment and at the second position when the aligning roller rotates in the forward direction for sheet conveyance.
A sheet conveying device and an image forming system according to an embodiment are described below with reference to the drawings. In the figures, the same components are denoted by the same reference numerals and signs. In the figures, dimensions and shapes of members are exaggerated or simplified for illustrative purpose.
The image forming apparatus 2 includes a control panel 11, a scanner section 12, a printer section 13, a paper feeding section 14, a paper discharging section 15, and an image-formation control section 16.
The control panel 11 includes various keys for receiving operation of a user. For example, the control panel 11 receives an input to select a type of the post-processing of sheets. The control panel 11 sends information corresponding to the input type of the post-processing to the post-processing apparatus 3.
The scanner section 12 includes a reading section that reads image information of a copying target object. The scanner section 12 sends the read image information to the printer section 13.
The printer section 13 forms an output image (hereinafter referred to as “toner image”) with a developer such as toner on the basis of the image information sent from the scanner section 12 or image information transmitted from an external apparatus. The printer section 13 transfers the toner image onto the surface of the sheet. The printer section 13 applies heat and pressure to the toner image transferred onto the sheet to fix the toner image on the sheet.
The paper feeding section 14 supplies sheets to the printer section 13 one by one in accordance with timing when the printer section 13 forms the toner image.
The paper discharging section 15 conveys the sheet discharged from the printer section 13 to the post-processing apparatus 3.
The image-formation control section 16 controls the operation of the entire image forming apparatus 2. That is, the image-formation control section 16 controls the control panel 11, the scanner section 12, the printer section 13, the paper feeding section 14, and the paper discharging section 15. The image-formation control section 16 is formed by a control circuit including a CPU, a ROM, and a RAM.
The post-processing apparatus 3 is explained.
The post-processing apparatus 3 is disposed adjacent to the image forming apparatus 2. The post-processing apparatus 3 executes, on sheets conveyed from the image forming apparatus 2, the post-processing selected through the control panel 11. For example, the post-processing is stapling or sorting. The post-processing apparatus 3 includes a standby section 21, a processing section 22, a discharging section 23, and a post-processing control section 24. In the embodiment, the sheet is conveyed from the image forming apparatus 2 to the discharging section 23.
The standby section 21 temporarily holds up (buffers) the sheet conveyed from the image forming apparatus 2. For example, the standby section 21 puts a following plurality of sheets on standby while the post-processing of preceding sheets is performed by the processing section 22. The standby section 21 is disposed above the processing section 22. If the processing section 22 becomes vacant, the standby section 21 drops the held-up sheet toward the processing section 22.
The processing section 22 performs the post-processing on sheets. For example, the processing section 22 aligns a plurality of sheets. The processing section 22 performs stapling on the aligned plurality of sheets. Consequently, the plurality of sheets are bound. The processing section 22 discharges the post-processed sheets to the discharging section 23.
The discharging section 23 includes a fixed tray 23a and a movable tray 23b. The fixed tray 23a is provided in an upper part of the post-processing apparatus 3. The movable tray 23b is provided on a side of the post-processing apparatus 3. Sorted sheets can be discharged to the fixed tray 23a and the movable tray 23b.
The post-processing control section 24 controls the operation of the entire post-processing apparatus 3. That is, the post-processing control section 24 controls the standby section 21, the processing section 22, and the discharging section 23. The post-processing control section 24 is implemented by a control circuit including a CPU, a ROM, and a RAM.
For example, the post-processing control section 24 controls switching of a processing mode and a non-processing mode (a normal mode). The processing mode means a mode for performing the post-processing on sheets. For example, the processing mode includes a sort mode and a staple mode. The non-processing mode means a mode for directly conveying sheets without performing the post-processing on the sheets.
The control panel 11 includes a mode selecting section (an operation section) (not illustrated in
A sheet conveying device is described below in detail.
The image forming system 1 includes a sheet conveying device 30 (see
First, the conveying path 31 is explained.
The conveying path 31 is provided along a vertical plane. A sheet is conveyed upward along the conveying path 31. The sheet is conveyed from the paper feeding section 14 (e.g., a paper feeding cassette 32) to the printer section 13 (e.g., an image forming section) via the sheet conveying device 30. In the following explanation, the paper feeding section 14 side (the lower side on the paper surface in
In the following explanation, a direction V1 (the depth direction on the paper surface in
As shown in
The paper feeding cassette 32 stores sheets S.
The pickup roller 33 extracts the sheet S from the paper feeding cassette 32.
The intermediate transfer belt 34, the backup roller 35, the tension roller 36, and the secondary transfer roller 37 configure the printer section 13.
The backup roller 35 supports the intermediate transfer belt 34.
The secondary transfer roller 37 is opposed to the backup roller 35 via the intermediate transfer belt 34.
The conveying mechanism 60 is explained.
The conveying mechanism 60 is provided in an upstream position of the aligning mechanism 40 in the sheet conveying direction Vs. The conveying mechanism 60 includes a conveying roller pair 61 and 62 and a motor 63 for sheet conveyance.
The conveying roller pair 61 and 62 is disposed close to the pickup roller 33. The conveying roller pair 61 and 62 includes a first conveying roller 61 and a second conveying roller 62 opposed to each other. The first conveying roller 61 is driven by the motor 63 for sheet conveyance. The second conveying roller 62 rotates (is driven to rotate) according to rotation of the first conveying roller 61. The conveying roller pair 61 and 62 conveys a sheet supplied from the pickup roller 33 toward a downstream side of the conveying path 31. The conveying rollers 61 and 62 come into contact with the sheet to thereby convey the sheet when the sheet passes through a nip 44 of an aligning roller pair 41 and 42. The conveying rollers 61 and 62 come into contact with the sheet to thereby convey the sheet when the sheet hits against the nip 44.
As shown in
The conveyance guide wall 70 forms the conveying path 31 between the pickup roller 33 and the conveying roller pair 61 and 62.
The linear guide wall 71 forms the conveying path 31 between the conveying roller pair 61 and 62 and the aligning roller pair 41 and 42. The linear guide wall 71 linearly extends along the sheet conveying direction Vs.
The curved guide wall 72 forms the conveying path 31 between the curved guide wall 72 and the linear conveyance guide wall 70. The curved guide wall 72 forms a bending space 73 of a sheet in a position close to the conveying roller pair 61 and 62. The curved guide wall 72 curves to project in a direction away from the linear guide wall 71.
As illustrated in
As illustrated in
In
The aligning mechanism 40 is explained.
As illustrated in
The aligning roller pair 41 and 42 is provided between the conveying roller pair 61 and 62 and the secondary transfer roller 37 (the backup roller 35) in the sheet conveying direction Vs. The aligning roller pair 41 and 42 includes a first aligning roller 41 and a second aligning roller 42 opposed to each other. The first aligning roller 41 and the second aligning roller 42 are in contact with each other to form the nip 44. The aligning mechanism 40 hits a sheet, which is conveyed along the conveying path 31, against the nip 44 to thereby align the position of the leading end of the sheet. The position of the leading end of the sheet means a position at a sheet downstream end in the sheet conveying direction Vs.
The first aligning roller 41 is a driving roller driven by the motor 43 for aligning. The first aligning roller 41 rotates in a forward direction in an arrow R1 direction of
The second aligning roller 42 is a driven roller that rotates (is driven to rotate) according to the rotation of the first aligning roller 41. The aligning roller pair 41 and 42 conveys the sheet supplied from the conveying roller pair 61 and 62 toward the downstream side of the conveying path 31.
As illustrated in
As illustrated in
The conveyance-width changing mechanism 50 is explained.
The conveyance-width changing mechanism 50 is provided in an upstream position of the nip 44 in the sheet conveying direction Vs. In the following explanation, the width of the conveying path 31 near the nip 44 is referred to as “nip vicinity conveyance width”. In
Here, an imaginary straight line (vertical line) passing the conveying roller pair 61 and 62 and the aligning roller pair 41 and 42 is set. The nip vicinity conveyance width is the width of the conveying path 31 near the nip 44 in the second conveyance orthogonal direction V2 and means an interval between the imaginary straight line and the distal end portion of the guide 51. The distal endportion of the guide 51 means an upstream end of the guide 51 in the sheet conveying direction Vs. The conveyance-width changing mechanism 50 sets the nip vicinity conveyance width when the sheet hits against the nip 44 larger than the nip vicinity conveyance width when the sheet passes through the nip 44 after hitting against the nip 44.
The conveyance-width changing mechanism 50 includes a guide 51, position restricting sections 52 and 53, and torque transmitting and interrupting sections 54 and 55 (see
The guide 51 operates in accordance with the rotation of the first aligning roller 41, which is the driving roller. The guide 51 swings around the first aligning shaft 45. The guide 51 swings coaxially with the first aligning roller 41. A swing center of the guide 51 is coaxial with a rotation center of the first aligning roller 41. The guide 51 defines the nip vicinity conveyance width during reverse rotation of the first aligning roller 41 larger than the nip vicinity conveyance width during forward rotation of the first aligning roller 41.
As illustrated in
The guide body 51a has a plate shape extending in the first conveyance orthogonal direction V1. When viewed from the first conveyance orthogonal direction V1 (see
As illustrated in
The coupling pieces 51c are respectively provided at end portions of the guide body 51a. The coupling pieces 51c respectively couple the end portions of the guide body 51a and the end portions of the first aligning shaft 45.
The position restricting sections 52 and 53 include a first stopper 52 and a second stopper 53.
The first stopper 52 is capable of coming into contact with a first end portion of the guide 51 in the first conveyance orthogonal direction V1. The second stopper 53 is capable of coming into contact with a second end portion of the guide 51 in the first conveyance orthogonal direction V1. The second end portion of the guide 51 means an end portion on the opposite side of the first end portion of the guide 51 in the first conveyance orthogonal direction V1. The stoppers 52 and 53 are fixed to the image forming apparatus body.
The stoppers 52 and 53 include first restricting convex sections 56, second restricting convex sections 57, and coupling sections 58.
As illustrated in
The first restricting convex section 56 is capable of coming into contact with a surface F1 (hereinafter referred to as “first surface F1”) of the distal end portion of the guide 51 on the conveying path 31 side. The first restricting convex section 56 defines a terminal end in a swinging direction of the guide 51 during the forward rotation of the first aligning roller 41 (see
The second restricting convex section 57 is capable of coming into contact with a surface F2 (hereinafter referred to as “second surface F2”) of the distal end portion of the guide 51 on the opposite side of the conveying path 31. The second restricting convex section 57 defines a terminal end in the swinging direction of the guide 51 during the reverse rotation of the first aligning roller 41. The second restricting convex section 57 restricts movement of the guide 51 during the reverse rotation of the first aligning roller 41 such that a bending space 74 of the sheet can be formed in a position near the nip 44. If the distal end portion of the guide 51 is in contact with the second restricting convex section 57, the second surface F2 is formed in a linear shape extending to be further apart from the linear guide wall 71 further on the downstream side in the sheet conveying direction Vs.
The torque transmitting and interrupting sections 54 and 55 (see
As illustrated in
A bend of a sheet during aligning processing of the sheet is explained. The following explanation is explanation of a comparative example not including the conveyance-width changing mechanism 50 according to the embodiment.
As illustrated in
As illustrated in
As illustrated in
As illustrated in
An example of a sheet aligning operation according to an embodiment is explained.
As illustrated in
When the first conveying roller 61 rotates in a reverse direction, the sheet S hits against the nip 44. If the sheet S hits against the nip 44, the sheet S bends along the first surface F1 of the distal endportion of the guide 51. Thereafter, the sheet S bends in the space 73 between the linear guide wall 71 and the curved guide wall 72. A bend shape of the sheet S is illustrated in
The second face F2 of the distal end portion of the guide 51 comes into contact with the second restricting convex section 57 (see
An example of a sheet conveying operation according to an embodiment is explained.
As illustrated in
The first conveying roller 61 maintains the forward rotation during the conveying operation of the sheet S. When the first conveying roller 61 rotates in the forward direction and the first aligning roller 41 rotates in the forward direction, the sheet S passes through the nip 44. If the sheet S passes through the nip 44, the sheet S bends in the space 73 further on the downstream side than the distal end portion of the guide 51. That is, the sheet S bends in the space 73 between the linear guide wall 71 and the curved guide wall 72. A bend shape of the sheet S is illustrated in
The first surface F1 of the distal end portion of the guide 51 comes into contact with the first restricting convex section 56 (see
According to the embodiment, the sheet conveying device 30 includes the aligning mechanism 40 and the conveyance-width changing mechanism 50. The aligning mechanism 40 hits the sheet, which is conveyed along the conveying path 31, against the nip 44 to thereby align the position of the distal end of the sheet. The conveyance-width changing mechanism 50 is provided in the upstream position of the nip 44 in the sheet conveying direction Vs. The conveyance-width changing mechanism 50 defines the nip vicinity conveyance width when the sheet hits against the nip 44 to be larger than the nip vicinity conveyance width when the sheet passes through the nip 44 after hitting against the nip 44. The following effect is achieved by the configuration explained above. When the sheet hits against the nip 44, the bending space 74 of the sheet sufficient for the tilt correction of the sheet can be secured near the nip 44. For that reason, by hitting the sheet against the nip 44, it is possible to sufficiently bend the sheet and align the position of the distal end of the sheet. On the other hand, when the sheet passes through the nip 44, the guide 51 acts to stretch the sheets immediately before the sheet enters the nip 44. For that reason, it is possible to prevent waving of the sheet near the nip 44 and cause the sheet to pass through the nip 44 without waving. Therefore, it is possible to prevent sheet damage such as creases and folded traces from occurring in the sheet.
The aligning mechanism 40 includes the first aligning roller 41, which is the driving roller. The first aligning roller 41 reversely rotates when the sheet hits against the nip 44. The first aligning roller 41 rotates in the forward direction when the sheet passes through the nip 44. With the configuration explained above, the following effect is achieved. It is possible to prevent sheet damage such as creases and folded traces in the sheet with a simple configuration in which the reverse rotation and the forward rotation of the first aligning roller 41 are used.
The conveyance-width changing mechanism 50 includes the guide 51 that operates in accordance with the rotation of the first aligning roller 41. The guide 51 defines the nip vicinity conveyance width during the reverse rotation of the first aligning roller 41 to be larger than the nip vicinity conveyance width during the forward rotation of the first aligning roller 41. With the configuration explained above, the following effect is achieved. An apparatus configuration can be simplified compared with when the guide 51 is operated individually and independently from the rotation of the first aligning roller 41.
In addition, the guide 51 swings coaxially with the first aligning roller 41. According to this configuration, the following effect can be achieved. The apparatus configuration can be simplified compared with when the guide 51 is swung around an axis different from the axis of the first aligning roller 41.
The guide 51 is formed longer than the sheet along the first conveyance orthogonal direction V1. According to this configuration, the following effect can be achieved. Compared with when the guide 51 is formed to be equal to or shorter than the sheet along the first conveyance orthogonal direction V1, even if the sheet is obliquely tilted and conveyed, the sheet is more likely to be held by the guide 51 over the entire sheet in the first conveyance orthogonal direction V1. Therefore, it is possible to more effectively prevent waving of the sheet and more effectively prevent sheet damage such as creases and folded traces.
The conveyance-width changing mechanism 50 includes the position restricting sections 52 and 53 that restrict the position of the guide 51 during the forward rotation and during the reverse rotation of the first aligning roller 41. According to this configuration, the following effect can be achieved. The nip vicinity conveyance width can be set to specific widths when the sheet hits against the nip 44 and when the sheet passes through the nip 44. That is, the nip vicinity conveyance width can be more stable between when the sheet hits against the nip 44 and when the sheet passes through the nip 44. Therefore, it is possible to prevent fluctuation in a correction degree of waving of the sheet and more effectively prevent sheet damage such as creases and folded traces.
The position restricting sections 52 and 53 include the first stopper 52 and the second stopper 53. The first stopper 52 is capable of coming into contact with the first end portion of the guide 51 in the first conveyance orthogonal direction V1. The second stopper 53 is capable of coming into contact with the second end portion of the guide 51 in the first conveyance orthogonal direction V1. With the configuration explained above, the following effect is achieved. Compared with when the position restricting sections 52 and 53 include stoppers capable of coming into contact with only one end portion of the guide 51 in the first conveyance orthogonal direction V1, it is possible to stably hold the guide 51 with each of the first stopper 52 and the second stopper 53. That is the nip vicinity conveyance width in the first conveyance orthogonal direction V1 can be more stable. Therefore, it is possible to prevent fluctuation in a correction degree of waving of the sheet and more effectively prevent sheet damage such as creases and folded traces.
The sheet conveying device 30 further includes the first conveying roller 61 provided in the upstream position of the aligning mechanism 40 in the sheet conveying direction Vs. The first conveying roller 61 conveys the sheet respectively when the sheet passes through the nip 44 and when the sheet hits against the nip 44. With the configuration explained above, the following effect is achieved. With a simple configuration that uses the rotation of the first conveying roller 61, it is possible to prevent sheet damage such as creases and folded traces.
The conveying path 31 is provided along the vertical plane. According to this configuration, the following effect can be achieved. In the sheet conveying device 30 including the conveying path 31 provided along the vertical plane, it is possible to prevent sheet damage such as creases and folded traces.
Modifications are explained below.
The conveying path 31 may not be provided along the vertical plane.
As illustrated in
According to this modification, when the sheet hits against the nip 44, the guide 151 is lifted by the bent sheet S (a solid line). For that reason, it is possible to sufficiently bend the sheet S near the nip 44 and align the position of the distal end of the sheet S. On the other hand, when the sheet S passes through the nip 44, the guide 151 presses down the sheet S (a broken line) with the gravity (own weight). For that reason, it is possible to prevent waving of the sheet S near the nip 44 and cause the sheet S to pass through the nip 44 without waving. Therefore, it is possible to prevent sheet damage such as creases and folded traces.
Another modification of the embodiment is explained.
The sheet conveying device 30 may not be disposed between the paper feeding section 14 and the printer section 13. For example, the sheet conveying device 30 may be disposed near a part where the sheet is reversed. The sheet conveying device 30 may be provided any applicable positions in the conveying path of the image forming system (the image forming apparatus and the post-processing apparatus).
The guide 51 may not operate in accordance with the rotation of the first aligning roller 41. For example, the guide 51 may operate individually and independently from the rotation of the first aligning roller 41. For example, the sheet conveying device 30 may include a control section that controls the operation of the guide 51.
The guide 51 may not swing. The guide 51 may advance and retract. For example, the guide 51 may operate to define the nip vicinity conveyance width during the reverse rotation of the first aligning roller 41 to be larger than the nip vicinity conveyance width during the forward rotation of the first aligning roller 41.
The first aligning roller 41 may not reversely rotate when the sheet hits against the nip 44. For example, the first aligning roller 41 may stop when the sheet hits against the nip 44. For example, the first aligning roller 41 may reversely rotate the sheet after the sheet passes through the nip 44. For example, the sheet conveying device 30 may include a control section that controls the rotation of the first aligning roller 41.
The aligning mechanism 40 may not include the aligning roller pair 41 and 42. For example, the aligning mechanism 40 may include an aligning roller and a pad (a roller contact member). For example, the aligning mechanism 40 may include at least one rotating body.
The conveying mechanism 60 may not include the conveying roller pair 61 and 62. For example, the conveying mechanism 60 may include a conveying roller and a pad (a roller contact member). The conveying mechanism 60 may include at least one rotating body.
The guide 51 may not be longer than the sheet in the first conveyance orthogonal direction V1. For example, the guide 51 may have a length equal to or shorter than the sheet in the first conveyance orthogonal direction V1. For example, a plurality of guides 51 may be disposed at an interval in the first conveyance orthogonal direction V1. For example, on a plate extending in the first conveyance orthogonal direction V1, a plurality of ribs functioning as the guides 51 may be provided with an interval in an extending direction of the plate. The number of the disposed guides 51 and disposition positions of the guides 51 may be changed according to requested specifications.
The disposed aligning roller may not be one. Two or more aligning rollers may be disposed. The number of disposed aligning rollers and disposition positions of the aligning rollers may be changed according to requested specifications.
The disposed conveying rollers are not limited to two. One or three or more conveying rollers may be disposed. The number of disposed conveying rollers and disposition positions of the conveying rollers may be changed according to requested specifications.
According to the at least one embodiment explained above, the sheet conveying device 30 includes the aligning mechanism 40 and the conveyance-width changing mechanism 50. The aligning mechanism 40 causes the sheet, which is conveyed along the conveying path 31, to hit against the nip 44 to thereby align the position of the distal end of the sheet. The conveyance-width changing mechanism 50 is provided in the upstream position of the nip 44 in the sheet conveying direction Vs. The conveyance-width changing mechanism 50 defines the nip vicinity conveyance width when the sheet hits against the nip 44 to be larger than the nip vicinity conveyance width when the sheet passes through the nip 44 after hitting against the nip 44. According to the configuration explained above, the following effect can be achieved. When the sheet hits against the nip 44, it is possible to secure the bending space 74 of the sheet sufficient for the tilt correction of the sheet near the nip 44. For that reason, it is possible to sufficiently bend the sheet by the sheet hitting against the nip 44 and align the position of the distal end of the sheet. On the other hand, when the sheet passes through the nip 44, the guide 51 acts to stretch the sheets immediately before the sheets enter the nip 44. For that reason, it is possible to prevent waving of the sheet near the nip 44 and cause the sheet to pass through the nip 44 without waving. Therefore, it is possible to prevent sheet damage such as creases and folded traces.
While certain embodiments have been described these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms: furthermore various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the invention.
This application is a continuation of U.S. patent application Ser. No. 16/363,484, filed on Mar. 25, 2019, the entire contents of each of which are incorporated herein by reference.
Number | Date | Country | |
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Parent | 16363484 | Mar 2019 | US |
Child | 17466361 | US |