1. Field of the Invention
The present invention relates to a conveying apparatus which conveys a sheet via a conveying path including a curved portion and which corrects the direction of the sheet so that a side of a leading end of the sheet is orthogonal to a conveying direction, and a recording apparatus with the conveying apparatus mounted therein.
2. Description of the Related Art
In a known configuration of recording apparatuses represented by printers, copiers, and facsimile machines, sheets are conveyed using a conveying path with a curved internal space in order to reduce the size of the apparatus. In such a recording apparatus, a sheet may be pushed hard against an outer side of the conveying path due to the rigidity of the sheet and thus conveyed while being subjected to great conveying resistance. This increases the likelihood of causing the sheet to skew. Thus, such a recording apparatus desirably performs an operation of correcting the direction of the sheet so that a side of a leading end of the sheet is orthogonal to a conveying direction, what is called an skew correcting operation, before recording an image on the sheet. A known common skew correcting operation reverses a main conveying roller (roller) engaged with the sheet. During the skew correcting operation, a loop (flexible portion) of the sheet is formed in the internal space of the conveying path. The loop comes into abutting contact with the outer side of curvature of the conveying path. Then, a force is exerted in conjunction with the abutting contact and causes a leading end of the sheet to be pushed into the main conveying roller. Japanese Patent Application Laid-Open No. H08-157107 discloses an apparatus that can adjust the above-described pressing force according to the rigidity of the sheet. The apparatus disclosed in Japanese Patent Application Laid-Open No. H08-157107 includes an upstream guide formed of a thin elastic plate and a downstream plate formed of a rigid plate and biased toward an inner side of the conveying path by a spring; the upstream and downstream guides are arranged on the outer side of a curvature of the conveying path. In this apparatus, during the skew correcting operation, less rigid sheets come into abutting contact with the upstream guide and are pushed into an skew correcting roller by the elastic force of the upstream guide. More rigid sheets come into abutting contact with the downstream guide and are pushed into a registration roller by a downstream elastic force that is greater than that of the upstream guide. During the skew correcting operation, the apparatus disclosed in Japanese Patent Application Laid-Open No. H08-157107 provides a space in the conveying path in which the sheet is deflected or flexed and can push the sheet into the registration roller with an appropriate force according to the rigidity of the sheet.
When a conveying operation and an skew correcting operation are performed within a curved conveying path in the same manner as that of the apparatus disclosed in Japanese Patent Application Laid-Open No. H08-157107, a narrow conveying path (a short distance between the inner guide and the outer guide) facilitates the abutting contact of the loop of the sheet with the conveying path and is thus suitable for the skew correcting operation. However, in this case, conveying resistance of the sheet is increased, possibly affecting the conveying operation. In contrast, a wide conveying path (a long distance between the inner guide and the outer guide) serves to reduce the conveying resistance of the sheet and is thus suitable for the conveying operation. However, this makes the abutting contact of the loop of the sheet with the conveying path difficult, possibly hindering the skew correcting operation from being stably achieved.
Thus, an object of the present invention is to provide a conveying apparatus that enables both a reduction in conveying resistance and a stable skew correcting operation, and a recording apparatus with the conveying apparatus.
To accomplish the object, a conveying apparatus according to the present invention includes a conveying path with a curved path through which a sheet is passed,
a roller provided downstream of the conveying path in a conveying direction of the sheet, the roller being rotated in a first direction to enable execution of a conveying operation of conveying the sheet in the conveying direction and being rotated in a second direction opposite to the first direction to enable execution of an skew correcting operation of forming a loop of the sheet, and
a guide member which guides the sheet using an inner side of a curvature of the conveying path and which can move toward the inner side of the curvature of the conveying path when subjected by the sheet during the conveying operation to a force stronger than during the skew correcting operation.
The present invention enables both a reduction in conveying resistance and a stable skew correcting operation.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Preferred embodiments of the present invention will now be described in detail in accordance with the accompanying drawings.
(Exemplary Embodiment 1)
As illustrated in
The inclined surface member 102 will be described below in detail.
First, the abutting member 103 will be described.
Now, the separating member 111 will be described.
The link mechanism 120 moves the separating member 111 from a projecting position to a retracted position. The projecting position is where the protrusions on the protruding surface 111a projects with respect to the slope 102a of the inclined surface member 102 and where the uppermost sheet being conveyed comes into abutting contact with the protruding surface 111a. The retracted position is where the protrusions on the protruding surface 111a are retracted (hidden) with respect to the slope 102a of the inclined surface member 102. The link mechanism 120 will be described below.
According to the present exemplary embodiment, the link mechanism 120 includes a pair of link members 114 and 115. A central portion of the link member 114 is pivotally movably coupled to a central portion C of the link member 115. A fitting hole K1 formed at an upper end of the link member 114 is fitted over a shaft of the separating member 111. The link member 114 is rotatably attached to the separating member 111. The link member 115 includes a fitting hole formed at a lower end thereof and in which a slide shaft K2 is fitted. The separating member 111 includes a slot 111c formed at a position lower than a shaft fitted in the fitting hole K1. The slide shaft K2 can slide along the slot 111c in a direction intersecting the advancing direction D.
A straight line G1 (see
The link member 114 includes a fitting hole formed at a lower end thereof. The fitting hole is pivotally movably fitted over a slide shaft S2 that slides in the direction of arrow E in
The separating member 111 includes a spring member 116 attached to a side thereof opposite to the protruding surface 111a. The spring member 116 presses the separating member 111 to hold the separating member 111 in the above-described projecting position. The pressing force of the spring member 116 acts in a direction opposite to the direction of the abutting force of the sheet P.
If the fed sheet P comes into abutting contact with the separating member 111 located at the projecting position and the abutting force received by the separating member 111 from the sheet P is greater than the pressing force of the spring member 116, the slide shaft S2 and the slide shaft K2 simultaneously slide in the direction of arrow E in
Now, a configuration of the reverse conveying portion 20 will be described.
The inner guide unit 201 includes an inner guide 204 of a conveying path 200 with a curved internal space through which the sheet is passed, and a conveying roller unit 203 attached to the inner guide 204. The conveying roller unit 203 will be described.
The conveying roller unit 203 includes a conveying roller 207 that is a rotor conveying the sheet in the conveying direction, a conveying arm 208 with a conveying roller 207 and a drive transmitting unit, a conveying shaft 209 that serves to transmit a drive force, and a clutch 210. An outer peripheral portion of the conveying roller 207 is formed of a high-friction member such as rubber and supported by the conveying arm 208. A roller 224 (see
The conveying arm 208 is configured to be able to swing because a shaft integrated with the conveying arm 208 is supported by holes Xa and Xb (see
Rotation of the conveying input gear 211 releases the clutch spring 214 to allow the conveying shaft 209 to rotate. As a result, the conveying roller gear 212 rotates via the gear 213 fixed to the conveying shaft 209. In conjunction with the conveying roller gear 212, the conveying roller 207 rotates counterclockwise as seen in
Now, the outer guide unit 202 will be described.
The conveying pinch roller unit 206 includes a conveying pinch roller 215 that cooperates with the conveying roller 207 in conveying the sheet and a conveying pinch roller holder 216 to which the conveying pinch roller 215 is rotatably attached. The conveying pinch roller holder 216 is configured to be able to be swing because a shaft integrated with the pinch roller holder 216 is supported by a hole formed in the outer guide 205. The conveying pinch roller holder 216 includes a conveying pinch roller spring 217 provided on a back surface side thereof. The conveying pinch roller spring 217 presses the conveying pinch roller 215 toward the conveying roller 207 via the conveying pinch roller holder 216. The position of the conveying pinch roller holder 216 is regulated by a rotation regulating portion Z provided on the outer guide 205.
The conveying pinch roller 215 and the conveying pinch roller holder 216 remain stationary until an abutting force X (see
In the conveying roller unit 203, the conveying arm 208 includes a preload spring 218 attached thereto (see
In the above-described inner guide 204, an auxiliary guide member 220 is provided on an inner side a curvature of the conveying path 200.
The auxiliary guide member 220 includes two shafts 220a and 220b extending in directions that intersect in the conveying direction. The shaft 220a is supported by a hole Ya formed in the inner guide 204. On the other hand, the shaft 220b is supported by a hole Yb formed in the inner guide 204. The auxiliary guide member 220 is attached to the inner guide 204 so as to be rotatable around the shafts 220a and 220b. The shaft 220b includes an auxiliary guide spring member 221 attached to an outer peripheral surface thereof and which is a torsion coil spring. The auxiliary guide spring 221 is engaged with the auxiliary guide member 220 at one end thereof. The auxiliary guide spring 221 is engaged with the inner guide 204 at the other end thereof. The auxiliary guide spring 221 biases the auxiliary guide member 220 toward a direction opposite to the conveying direction. The auxiliary guide member 220 includes a protrusion (not illustrated in the drawings) located at a lower end thereof so that the point of the contact between the protrusion and the inner guide 204 serves as a stopper to receive the bias force of the auxiliary guide spring 221. Thus, while no sheet is conveyed, the auxiliary guide member 220 is held in an upright posture with respect to the inner guide 204.
Furthermore, the control portion 901 instructs an image forming portion motor driver 912 to supply power to an image forming portion motor 913. An image forming portion 914 is connected to the image forming portion motor 913. A sheet feeding drive transmission mechanism 910 is connected to the image forming portion 914 and the above-described conveying drive transmission mechanism 908. The sheet feeding drive transmission mechanism 910 selectively switches between transmission and non-transmission of power from the conveyance drive transmission mechanism 908 to a sheet feeding mechanism 500 according to the position of the carriage 18 in the image forming portion 914. As a result, the sheet feeding mechanism 500 and the conveying roller 207 can be synchronously/asynchronously driven.
The rotational state and loading state of each of the above-described motors and the conveying state of the sheet P are detected by sensors of a sensor group 915 including the plurality of sensors, provided at various parts in the ink jet recording apparatus 10. Information detected by the sensor group 915 is transmitted to the control portion 901. The control portion 901 controls the motors based on signals received from one of the PC 902 and the operation panel 903 and the detection information received from the sensor group 915.
After a sheet feeding operation is started, the control portion 901 determines whether or not the sheet P has been conveyed by a predetermined amount (step S2). The predetermined amount is the minimum required amount of conveyance which is required for the leading end of the sheet P to reach the pair of main conveying rollers 16. Then, the control portion 901 determines whether or not a sensor 222 included in the sensor group 915 has detected the arrival of the sheet P at the pair of main conveying rollers 16 before a predetermined time elapses (step S3). If the arrival of the sheet P has not been detected, the control portion 901 allows the operation panel 903 to indicate sheet absence error (step S11), thus urging a user to re-feed a sheet P. Upon receiving the re-fed sheet through an error reset key provided on the operation panel 903 (step S12), the control portion 901 returns to the operation in step S1.
In step S3, when the sensor 222 detects when the leading end of the sheet P is about to reach the pair of main conveying rollers 16, the control portion 901 allows an skew correcting operation to be performed (step S4 and step S5). After the skew correcting operation is performed, the control portion 901 allows the pair of main conveying rollers 16 and the image forming portion 914 to perform an image forming operation (step S6 to step S8). When the image forming operation is terminated (step S9), the control portion 901 allows a discharging operation of discharging the sheet P to be performed (step S10).
The contents of the conveying operation and skew correcting operation of the main conveying roller 223, one of the pair of main conveying rollers 16, will be described below in detail.
The main conveying roller:the sheet feeding roller:the conveying roller:the conveying roller:the sheet discharging roller=1:0.65:0.65:1
First, the sheet feeding roller 106, the conveying roller 207, and the main conveying roller 223 rotate in a direction in which the sheet P is conveyed in the conveying direction, to start a sheet feeding operation. In this case, the direction of rotation of the main conveying roller 223 is referred to as a first direction.
The sheet feeding roller 106 and the inclined surface member 102 separate the uppermost sheet P from the sheets P stacked in the sheet feeding tray 101 with recorded surfaces thereof down. The separated uppermost sheet P is conveyed through the inclined surface member 102 to the conveying roller 207 by the sheet feeding roller 106.
Upon reaching the conveying roller 207, the sheet P is conveyed further downstream in the conveying direction by the sheet feeding roller 106 and the conveying roller 207. When conveyed by a predetermined amount after passing through the conveying roller 207, the sheet P leaves the sheet feeding roller 106 and is conveyed only by the conveying roller 207. Thereafter, when the sheet P passes through the conveying path 200, the sensor 222 detects the leading end of the sheet P. Thereafter, when the sheet P is conveyed by a predetermined amount after passing a position where the leading end of the sheet P is detected, the conveying roller 207 is stopped. The predetermined amount varies depending on the type of the sheet P such as plain paper or photographic paper. The present exemplary embodiment sets the predetermined amount such that the leading end of the sheet P is positioned 6.5 mm downstream of the conveying roller 223 in the conveying direction for plain paper and 4 mm downstream of the conveying roller 223 in the conveying direction for photographic paper.
The sheet P supported by the auxiliary guide member 220 is conveyed along the conveying guide member 108 to the main conveying roller 223 by rotation of the conveying roller 207 (see
Then, when the main conveying roller 223 starts to rotate in a second direction opposite to the first direction, the leading end of the sheet P is returned to upstream of a nip portion between the main conveying roller 223 and a follower rollerfollower, which form the pair of main conveying rollers 16. Since the conveying roller 207 is stopped, a loop of the sheet P is formed in the internal space of the conveying path 200 (see
Then, when the main conveying roller 223 starts to rotate in the first direction, the loop formed in the middle of the sheet P is gradually eliminated due to a difference in velocity between the main conveying roller 223 and the conveying roller 207. Moreover, when tension is applied to the sheet P between the main conveying roller 223 and the conveying roller 207, the conveying roller 207 is rotated at a speed equal to the speed of the main conveying roller 223 via the sheet P. This eliminates the conveying resistance of the sheet P, which acts on the conveying roller 207, and the force that brings the conveying roller 207 into abutting contact with the sheet P is exerted only by the preload spring 218. Hence, only a weak force is exerted by the conveying roller 207 and the conveying pinch roller 215 in sandwiching the sheet between the rollers 207 and 215. Thus, the sheet is likely to slide with respect to the conveying roller 207 and the conveying pinch roller 215. A reaction force involved in the twist of the sheet P causes the sheet P to slide against the conveying roller 207 and the conveying pinch roller 215. This eliminates the twisted loop of the sheet P.
Until the sheet P reaches the main conveying roller 223, the auxiliary guide member 220 is kept in an upright position by the bias force of the auxiliary guide spring member 221 so as to narrow the conveying path against a force R resulting from the weight of the sheet P and acting in the vertical direction. Also when the sheet P sandwiched between the main conveying roller 223 and the follower roller is conveyed downstream, the auxiliary guide member 220 is kept in the upright position by the bias force of the auxiliary guide spring member 221 so as to narrow the conveying path against the force resulting from the weight of the sheet P and acting in the vertical direction. While the main conveying roller 223 is performing an skew correcting operation (rotating in the second direction), the auxiliary guide member 220 receives, from the sheet P, the force resulting from the weight of the sheet P and acting in the vertical direction (see
To move the auxiliary guide member 220, which is movable as described above, the sheet P needs to come into contact with the auxiliary guide member 220. However, meeting the following relationship enables improvement of the reliability with which the sheet P comes into contact with the auxiliary guide member 220.
e×B>D
The velocity ratio e indicates the velocity ratio of the conveying roller 207 to the main conveying roller 223 during the conveying operation. The conveying distance B indicates the conveying distance over which the sheet P is conveyed in the direction opposite to the conveying direction. The minimum distance D indicates the minimum distance from the outer guide 205 to the upper end of the auxiliary guide member 220.
According to the present exemplary embodiment, during the skew correcting operation, the auxiliary guide member 220 functions to narrow the conveying path 200. This enables the loop of the sheet P to reliably come into abutting contact with the outer guide 205 to stabilize the skew correcting operation. On the other hand, during the conveying operation, the auxiliary guide member 220 functions to widen the conveying path 200 to enable a reduction in conveying resistance. During the conveying operation, the sheet P is in contact with the auxiliary guide member 220, but the above-described rotational configuration reduces the conveying resistance. This enables both a reduction in conveying resistance and a stable skew correcting operation to be achieved.
(Exemplary Embodiment 2)
A recording apparatus according to Exemplary Embodiment 2 will be described. The following description focuses on differences from the ink jet recording apparatus 10 according to the above-described Exemplary Embodiment 1. The present exemplary embodiment is different from Exemplary Embodiment 1 in the auxiliary guide member 220 of the conveying apparatus 11.
While the main conveying roller 223 is performing a skew correcting operation, the auxiliary guide member 220 takes an upright posture with respect to the inner guide 204. After the skew correcting operation, when the main conveying roller performs a conveying operation, the auxiliary guide member 220 is deformed so as to be deflected toward the conveying direction by a force received from the sheet P as illustrated in
According to the present exemplary embodiment, as is the case with Exemplary Embodiment 1, the auxiliary guide member 220 functions to narrow the conveying path 200 during the skew correcting operation and to widen the conveying path 200 during the conveying operation. This enables both a reduction in conveying resistance and a stable skew correcting operation to be achieved.
Moreover, compared to Exemplary Embodiment 1, the present exemplary embodiment simplifies the driving configuration for the auxiliary guide member 220, enabling a reduction in costs.
The above-described exemplary embodiments perform the skew correcting operation by reversing the main conveying roller 223 after conveying the sheet in the conveying direction using the pair of main conveying rollers 16. The present invention is applicable to any other skew correcting operation. Another skew correcting operation is as follows. The sheet P is conveyed by the conveying roller 207 so that the leading end of the sheet P comes into abutting contact with both the main conveying roller 223 and follower roller of the stopped pair of main conveying rollers 16 upstream of and in proximity to the nip portion between the main conveying roller 223 and the follower roller. The sheet P is further conveyed by the conveying roller 207 so that a loop is formed between the conveying roller 207 and the pair of main conveying rollers 16. Then, the leading end of the sheet P is pressed against both the main conveying roller 223 and the follower roller. One side of the leading end is aligned with a longitudinal direction of the main conveying roller 223. Such a method may be used to correct possible skew. Furthermore, at this time, the skew correcting operation can be similarly performed even when the main conveying roller 223 is rotated in the direction opposite to the conveying direction.
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. 2011-179610, filed Aug. 19, 2011, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2011-179610 | Aug 2011 | JP | national |
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Number | Date | Country | |
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20130043648 A1 | Feb 2013 | US |