JP5511482B2 - Sheet feeding apparatus and image forming apparatus - Google Patents

Description

  The present invention relates to a sheet feeding apparatus that feeds sheets and an image forming apparatus such as a copying machine, a facsimile machine, a printer, and a multifunction machine including the sheet feeding apparatus.

  2. Description of the Related Art Conventionally, an image forming apparatus such as a printer, a facsimile machine, or a copying machine is provided with a sheet feeding device for feeding sheets. For example, in the case of a laser beam printer, a sheet stacking unit for stacking sheets or a manual sheet stacking unit is provided, and these sheet stacking units are stacked by a sheet feeding device provided respectively. Sheet is fed. For example, the manual sheet stacking unit applies a feeding force to the uppermost sheet by the feeding roller, and separates and feeds the sheets one by one by the friction separation unit.

  By the way, in the manual feeding device, by providing a mechanism for fixing the side regulating member at the width position of a commonly used standard sheet (A4, B4, LTR, etc.), the movement of the side regulating member due to the feeding operation is provided. Is configured to regulate. This is because when the sheet is fed from the sheet stacking unit, a force that causes the sheet to skew is applied due to the difference in the left and right balance of the separation pressure in the separation unit, which is regulated by the side regulating member. The skew is prevented. For example, as a means for regulating the side regulating member, there is one that applies a load such as a spring to the movement of the side regulating member and regulates the movement of the side regulating member due to the feeding operation (see Patent Document 1).

JP 11-59922 A

  In recent years, users have desired high printing accuracy and media flexibility (high compatibility with sheet size and sheet type) for image forming apparatuses, and accordingly, sheet feeding apparatuses include a wide variety of sheets. It is desired to feed the paper stably.

  However, in the conventional sheet feeding apparatus, the side regulating member cannot be fixed when the user uses an indeterminate size sheet that is not generally used, and the sheet is side regulated along with the feeding operation. In some cases, the member is moved. In this case, since the width of the sheet cannot be regulated by the side regulating member, the sheet is skewed. As a result, the sheet enters the image forming apparatus main body obliquely, so that the image and the sheet position do not coincide with each other, and a printing position accuracy defect such as a shift in the sheet width direction or a skewed image occurs. .

  Similarly, in a device that regulates the movement of the side regulating member by applying a load such as a spring, it is considered that creep deformation is caused by a load such as a spring, so the load cannot be increased, and depending on the type of sheet, feeding The movement of the side regulating member due to the operation may not be regulated. In addition, the position of the side regulating member may be moved from the normal position by a load such as a spring, which may cause the sheet position to not be set accurately and may impair the same printing accuracy as described above.

  Therefore, the present invention provides a sheet feeding apparatus that satisfies the media flexibility and can perform stable feeding regardless of the sheet size and satisfies the printing accuracy, and an image forming apparatus including the sheet feeding apparatus. For the purpose.

  The present invention provides a sheet stacking unit for stacking sheets, a regulating member that moves to a position corresponding to the size of the sheet on the sheet stacking unit to regulate the side edge position of the sheet, and the movement of the regulating member A holding device that holds the regulating member at a position corresponding to the size of the sheet on the sheet stacking unit via the rack unit, in a sheet feeding device including a moving rack unit and a pinion that meshes with the rack unit The holding mechanism has a worm wheel as the pinion and a worm gear rotatably supported in mesh with the worm wheel, and the worm gear and the worm wheel are separated from the worm wheel. The rotation of the worm wheel can be regulated by the worm gear when the rotational load applied to the worm gear is less than a predetermined value. The worm gear is characterized in that it is configured to be reversibly rotated by the worm wheel when the such that, and the rotational load exceeds the predetermined value.

  According to the present invention, by using the rotational load of the worm gear, even when an irregular size sheet is used, the restricting member is moved in an analog manner in accordance with the position of the side edge of the sheet, and the restricting member The side end position can be properly regulated. Also, depending on whether the rotational load applied to the worm gear is less than a predetermined value or exceeds a predetermined value, the rotation of the worm wheel can be regulated or the worm gear can be reversibly rotated. Can be moved flexibly. Thereby, the media flexibility can be satisfied, stable feeding can be performed, and high printing accuracy can be achieved.

1 is a perspective view illustrating a sheet feeding device according to a first embodiment of the present invention. FIG. 3 is a perspective view illustrating the manual sheet stacking unit in a state in which no sheets are stacked according to the first embodiment as viewed obliquely from above. FIG. 3 is a perspective view illustrating a back surface of a manual sheet stacking unit according to the first embodiment. The perspective view which shows the back surface of the sheet | seat stacking unit for manual feeding in 1st Embodiment in the state seen from another direction. 1A and 1B show a sheet feeding apparatus according to a first embodiment, in which FIG. 1A is a cross-sectional view illustrating a state before starting a feeding operation, and FIG. The details of the worm gear and the worm wheel are shown, (a) is a side view showing the meshed state of the worm gear and the worm wheel, (b) is a cross-sectional view showing the meshed state of the worm gear and the worm wheel, (c) is a tooth part of the worm gear. Enlarged enlarged view. The perspective view which shows the back surface of the sheet | seat stacking unit for manual feed in 2nd Embodiment which concerns on this invention. FIG. 10 is a perspective view showing a manual sheet stacking unit in a state where there is no sheet stacking in a third embodiment according to the present invention as viewed obliquely from above. FIG. 10 is a perspective view illustrating a back surface of a manual sheet stacking unit in a state where there is no sheet stacking according to a third embodiment. FIG. 10 is a perspective view illustrating a back surface of a manual sheet stacking unit in a third embodiment with a sheet stacking state. The manual sheet stacking unit in 3rd Embodiment is shown, (a) is sectional drawing which shows the state in which the sheet | seat is not mounted, (b) is sectional drawing which shows the state in which the sheet | seat is mounted. The worm gear and the joint part of a worm pushing member in a 3rd embodiment are shown, (a) is a top view showing the state where a joint is not connected, and (b) is a top view showing the state where a joint is connected. The perspective view which shows the back surface of the sheet | seat stacking unit for manual feed in the 4th Embodiment which concerns on this invention in an unlocked state. The back surface of the sheet | seat stacking unit 470 of 4th Embodiment is shown, (a) is a rear view which shows the state before the locking of a side control member, (b) is a rear view which shows the state after the lock of a side control member. 1 is a schematic sectional view showing an image forming apparatus according to the present invention.

<First Embodiment>
Hereinafter, a sheet feeding apparatus according to the present invention and an image forming apparatus including the sheet feeding apparatus will be described with reference to the drawings. FIG. 15 is a schematic sectional view showing an image forming apparatus according to the present invention. FIG. 1 is a perspective view showing a sheet feeding apparatus 100 according to the first embodiment of the present invention.

  FIG. 15 is a schematic sectional view of a color laser printer as an example of an image forming apparatus. In FIG. 15, 1 is a color laser printer, and 1A is a printer body. The printer main body 1A is provided with an image forming unit 1B that forms an image on a sheet P fed from a manual feed tray 174 (and 274, 374, and 474 described later) that is a sheet stacking unit. Further, the printer main body 1A is provided with an intermediate transfer portion 1C, a fixing device 5, a sheet feeding device 1D for feeding the sheet S, and a sheet feeding device 100 for feeding a manually fed sheet P. Yes. Further, the printer body 1A is provided with a control unit (CPU) 23 that controls the entire image forming operation of the printer body 1A. The color laser printer 1 is configured to be able to form an image on the back surface of the sheet P. For this reason, the sheet P on which the image is formed on the front surface (one surface) is reversed and conveyed again to the image forming unit 1B. A re-transport unit 1E is provided.

  The image forming unit 1B is arranged in a substantially horizontal direction and includes four process stations 60 (60Y, 60M, 60C, 60K). The process stations 60Y, 60M, 60C, and 60K form toner images of four colors of yellow (Y), magenta (M), cyan (C), and black (Bk), respectively. The process station 60 includes photosensitive drums 11 (11Y, 11M, 11C, and 11K) that carry toner images of four colors, yellow, magenta, cyan, and black, and that are driven by a stepping motor (not shown). The process station 60 includes a charger 12 (12Y, 12M, 12C, 12K) that uniformly charges the surface of the photosensitive drum.

The image forming section 1B, on the photosensitive drum 11 rotating at a constant speed, by irradiating a laser beam based on the image signal d _1, a scanner 13 for forming an electrostatic latent image corresponding to the image signal d ₁ (13Y , 13M, 13C, 13K). In the process station 60, a developing device 14 (14Y, 14M, 14C, 14K) that visualizes a toner image by attaching yellow, magenta, cyan, and black toner to the electrostatic latent image formed on the photosensitive drum. ) Is provided. The charger 12, the scanner 13, the developing device 14, and the like are arranged around the photosensitive drum 11 along the rotation direction. The image forming unit 1B is provided with primary transfer rollers 35 (35Y, 35M, 35C, and 35K) that constitute a primary transfer unit.

  A secondary transfer outer roller 41 is disposed so as to face the secondary transfer inner roller 32. The secondary transfer outer roller 41 abuts on the lowermost surface of the intermediate transfer belt 31, and sandwiches and conveys the sheet P conveyed by the registration roller pair 76 together with the intermediate transfer belt 31. When the sheet P passes through the nip portion between the secondary transfer outer roller 41 and the intermediate transfer belt 31, the toner on the intermediate transfer belt 31 is applied to the sheet P by applying a bias to the secondary transfer outer roller 41. The image is secondarily transferred.

  The fixing device 5 fixes the toner image formed on the sheet P to the sheet P via the intermediate transfer belt 31, and the sheet P holding the toner image is subjected to heat and pressure when passing through the fixing device 5. Is added to fix the toner image. The sheet on which the toner image is fixed by the fixing device 5 is discharged onto the paper discharge tray 66.

  The sheet feeding apparatus 1D is provided at the lower part of the printer main body, and feeds paper feeding cassettes 61 to 64 that are sheet storage units for storing the sheets P, and feeds the sheets P stacked and stored in the paper feeding cassettes 61 to 64, respectively. Rollers 61a to 64a. On the downstream side of the paper feed rollers 61a to 64a, the sheet P fed by the paper feed rollers 61a to 64a is separated and fed one by one, and the paper feed rollers 61b to 64b are opposed to each other. Separating rollers 61c to 64c are arranged. These are the retard separation method, but may be a friction separation method such as pad separation.

  Further, the manual sheet feeding apparatus 100 includes a manual tray 174 as a sheet stacking unit for stacking sheets P, and a feeding roller 110 for feeding the sheets P stacked on the manual tray 174. . A separation unit 150 is disposed at a position facing the feeding roller 110. The feeding roller 110 and the separation unit 150 constitute a separation feeding unit that separates and feeds the sheets P stacked on the manual feed tray 174 one by one. Reference numeral 73 denotes a pair of conveying rollers that feeds the sheet P separated and fed from the sheet feeding cassettes 62 to 64 to the conveying vertical path 81. Reference numeral 78 denotes a first reverse roller pair, 79 denotes a second reverse roller pair, 82 denotes a paper discharge conveyance path, 83 denotes a reverse induction path, 84 denotes a switchback path, and 85 denotes a double-side conveyance path.

  When the image forming operation is started, the sheet P is fed out from the paper feed cassettes 61 to 64 by the paper feed rollers 61a to 64a, and is fed by the paper feed transport rollers 61b to 64b and the separation rollers 61c to 64c facing each other. Separate sheets are fed one by one. Thereafter, the sheet P is conveyed to the registration roller pair 76 via the conveyance vertical path 81 and the conveyance roller pair 74. The registration roller pair 76 conveys the sheet P to the transfer position of the secondary transfer unit 29 in synchronization with the toner image on the intermediate transfer belt 31 and the sheet P conveyed from the separation feeding unit 67.

  On the other hand, in the case of manual sheet feeding, the sheets P stacked on the manual tray 174 are separated and fed one by one by a separation feeding unit including a feeding roller 110 and a separation unit 150, and a pair of conveyance rollers 75, It is conveyed to the registration roller pair 76 via the conveyance path 39. The conveyance roller pair 75 conveys the sheet P separated and fed by the separation feeding unit 67.

  Here, the registration roller pair 76 temporarily stops the conveyed sheet, and then conveys the sheet to the secondary transfer unit 29 including the secondary transfer inner roller 32 and the secondary transfer outer roller 41. That is, the registration roller pair 76 has a function of correcting skew by following the leading edge of the sheet P by forming a loop by the sheet P being abutted. The registration roller pair 76 conveys the sheet P to the secondary transfer unit 29 at a predetermined timing in accordance with the timing of image formation on the sheet P, that is, the toner image carried on the intermediate transfer belt 31. It has a function.

  Next, a configuration related to feeding of the sheet feeding apparatus 100 will be described in detail. As shown in FIG. 1, the feeding roller 110 is rotatably supported in a state of extending in the width direction (front-back direction in FIG. 15) orthogonal to the sheet feeding direction (left direction in FIG. 15). It is engaged with the feeding shaft 120 and rotates integrally with the rotation of the feeding shaft 120. A feed roller 130 is rotatably attached to the feed shaft 120 on both sides of the feed roller 110 on the feed shaft 120. A feeding gear 140 is fixed to one end of the feeding shaft 120. Rotation from a drive source (not shown) is transmitted to the feed gear 140.

  The separation unit 150 disposed at a position facing the feeding roller 110 includes a separation pad 151 for separating the sheet P and a separation pad holder 152 for supporting the separation pad 151. The separation unit 150 is pressed in the direction of the feeding roller 110 by a spring (not shown), and the separation pad 151 and the feeding roller 130 are in contact with each other before feeding.

  A feed roller positioning unit 160 is disposed adjacent to the feed roller 130 on both sides of the feed roller 110. The feed roller positioning unit 160 rotates integrally with the rotation of the feed shaft 120 by engaging with the feed shaft 120. Lifting cams 171 for raising and lowering the manual feed tray 174 are engaged with both ends of the feeding shaft 120 so as to rotate integrally with the feeding shaft 120.

  FIG. 2 is a perspective view illustrating a manual sheet stacking unit 170 in the sheet feeding apparatus 100. The sheet stacking unit 170 has a manual feed tray 174 for stacking sheets P. The manual feed tray 174 is biased in the direction of the lifting cam 171 shown in FIG. 1 by a spring (not shown). Arranged and configured as follows. The manual feed tray 174 is provided with a manual feed tray sliding portion 172 for sliding with the lifting cam 171 shown in FIG. 1 at both ends in the width direction orthogonal to the sheet feeding direction. Further, on both sides in the width direction orthogonal to the sheet feeding direction, side regulating members 173 and 178 for positioning the sheet width direction and regulating the rotation of the sheet P by the feeding operation are arranged. The side regulating members 173 and 178 move to a position corresponding to the size of the sheet P on the manual feed tray 174 so as to approach or separate from each other in the width direction orthogonal to the sheet feeding direction, and the side edge position of the sheet P is set. A regulating member to be regulated is configured.

  Next, the configuration of the sheet stacking unit 170 will be described. As shown in FIG. 2, the side regulating members 173 and 178 are attached to the manual feed tray 174 so as to be movable in parallel with the width of the sheet P.

  3 and 4 are rear perspective views of the sheet stacking unit 170. FIG. As shown in both figures, the sheet stacking unit 170 is provided with a worm gear 175, a worm wheel 176, and a gear 177.

  The worm gear 175 is rotatably supported on the back surface of the manual feed tray 174 by bearing portions 174a and 174b formed to protrude from the back surface of the manual feed tray 174 so as to follow the sheet feeding direction at a substantially central portion on the back surface of the manual feed tray 174. . The worm wheel 176 is fixed to the gear 177 while being coaxially disposed with the gear 177 supported by the shaft in the thickness direction of the manual feed tray 174, and is rotatably attached to the manual feed tray 174 together with the gear 177. Yes. The worm wheel 176 constitutes a pinion that meshes with the rack portions 173a and 178a.

  The side regulating members 173 and 178 have a portion that extends in the width direction perpendicular to the sheet feeding direction on the back surface of the manual feed tray 174, and the extended portion is accompanied by the movement of the side regulating members 173 and 178. Moving rack portions 173a and 178a are formed.

  Next, the mechanism of the sheet stacking unit 170 will be described. FIG. 3 is a perspective view showing the back surface of the sheet stacking unit 170 in the present embodiment.

  As shown in FIG. 3, when the user narrows the interval between the side regulating members 173 and 178 in accordance with the size of the sheet P, the side regulating members 173 and 178 are moved in the direction of arrow A. As a result, the rack portions 173a and 178a also move in the direction of the arrow A, so that the gear 177 in FIG. 4 rotates in the direction of the arrow B, and the worm wheel 176 fixed coaxially with the gear 177 rotates the gear 177. Along with this, it rotates in the same direction (arrow B direction). Then, the worm gear 175 engaged with the worm wheel 176 rotates in the arrow C direction in accordance with the rotation of the worm wheel 176. When the interval between the side regulating members 173 and 178 is increased, each component moves in the direction opposite to the arrow.

  Next, an operation related to feeding of the sheet feeding apparatus 100 according to the present embodiment will be described. 5A and 5B are cross-sectional views of the sheet feeding apparatus 100. FIG. 5A is a cross-sectional view of the sheet feeding apparatus 100 before the feeding operation starts, and FIG. 5B is a main sheet at the start of feeding. A cross-sectional view of the feeding device 100 is shown.

  As shown in FIG. 5A, when the uppermost sheet of the sheets P stacked on the manual feed tray 174 is sent out, rotation is transmitted to the feeding gear 140 shown in FIG. The feed gear 140 is engaged with the feed shaft 120 and rotates together with the feed shaft 120 in the direction of arrow D in FIG. As the feed shaft 120 rotates, the feed roller 110, the feed roller positioning unit 160, and the lifting cam 171 rotate in the same direction. By the rotation of the lifting cam 171, the manual tray 174 having the manual tray sliding portion 172 in contact therewith rises in the direction of arrow E in the drawing in accordance with the rotation of the lifting cam 171. Then, the uppermost sheet P stacked on the manual feed tray 174 is moved to a position where it abuts on the feeding roller 110.

  As shown in FIG. 5B, the separating unit 150 is positioned by the rotated feed roller positioning unit 160. Here, the gap between the feeding roller 110 and the separation unit 150 is set to about 0.5 to 2.0, for example.

  Then, the uppermost sheet P of the sheets P stacked on the manual feed tray 174 comes into contact with the feeding roller 110 and starts feeding. Further, the uppermost sheet P is fed by the feeding roller 110 by rotating the feeding roller 110 by a driving unit (not shown) from the state of FIG. Further, the sheet P enters the gap between the feeding roller 110 and the separation unit 150 formed by the feeding roller positioning unit 160, and is fed and conveyed into the printer main body 1A.

  Next, the meshing shape of the worm gear 175 and the worm wheel 176 will be described. FIG. 6 is a detailed view of the worm gear 175 and the worm wheel 176. (A) is a state diagram of the meshing shape of the worm gear 175 and the worm wheel 176, (b) is a sectional view of the meshing shape of the worm gear 175 and the worm wheel 176, and (c) is an enlarged view of a tooth portion of the worm gear 175.

As shown in FIG. 6, the force required to rotate the worm gear 175 out of the forces applied to the teeth of the worm wheel 176 when the worm wheel 176 in the configuration of the present embodiment is a driving source is expressed by the following equation (A): (When bearing friction is not considered)
F = Fw (cosαsinγ−μcosγ) (A)
Where F is the tangential force of the worm (force required to rotate the worm gear 175), Fw is the force perpendicular to the tooth surface, γ is the reference cylinder advance angle, α is the tooth right angle pressure angle, μ is the worm gear 175 and the worm This is the friction coefficient of the wheel 176.

  In the present embodiment, a holding mechanism is configured by a worm wheel 176 as a pinion and a worm gear 175 that is rotatably supported while meshing with the worm wheel 176. This holding mechanism holds the side regulating members 173 and 178 at positions corresponding to the sheet size on the manual feed tray 174 (on the sheet stacking portion) via the rack portions 173a and 178a. The worm gear 175 and the worm wheel 176 are configured so that the rotation of the worm wheel 176 can be restricted by the worm gear 175 when the rotational load applied from the worm wheel 176 to the worm gear 175 is less than a predetermined value. Further, the worm gear 175 and the worm wheel 176 are configured such that the worm gear 175 can be reversibly rotated by the worm wheel 176 when the rotational load exceeds the predetermined value.

  That is, when the tangential force F of the worm gear 175 is larger than 0 (predetermined value) (that is, when the rotational load by the worm wheel 176 exceeds the predetermined value), the worm gear 175 is rotated from the worm wheel 176 side. The tangential force F is a force (rotational load) necessary for rotating the worm gear 175. On the other hand, when the tangential force F of the worm gear 175 is smaller than 0 (predetermined value), the worm gear 175 cannot be rotated from the worm wheel 176 side, and the worm gear 175 is self-locked.

  From the above formula (A), it can be seen that there are three factors that cause the self-locking: the reference cylinder advance angle γ, the tooth right angle pressure angle α, and the friction coefficient μ. Therefore, the tangential force F of the worm gear 175 is set to a value close to 0 so that the rotational load of the worm gear 175 can be obtained, and the worm gear 175 has a shape in which the number of threads is increased and the worm diameter is reduced. Further, a material having low frictional resistance is used for both the worm wheel 176 and the worm gear 175.

  For example, the tooth right angle pressure angle α is 20 ° which is generally widely used, and the material of the worm wheel 176 and the worm gear 175 is polyacetal (POM) which is one of widely used resins. The case where is used will be described. Polyacetal (POM) has excellent mechanical properties, high tensile and bending strength, toughness and excellent elasticity, a low coefficient of friction, and excellent heat resistance and wear resistance.

  Since the friction coefficient of POM is about 0.3, the reference cylinder advance angle γ for preventing the worm gear 175 from self-locking must be set to 18 ° or more from the above formula (A). Therefore, the reference cylinder advance angle γ of the worm gear 175 is set to 18 ° to 20 ° so that the rotational load of the worm gear 175 can be obtained. Further, when the frictional resistance is further reduced by applying grease to the POM surfaces made of the worm wheel 176 and the worm gear 175 under the same conditions as described above, the friction coefficient becomes about 0.1. From the above formula (A), the setting of the reference cylinder advance angle γ for preventing the worm gear 175 from self-locking must be 6 ° or more. Accordingly, the reference cylinder advance angle γ is set to 6 ° to 8 °.

  In the present embodiment, the worm gear 175 is configured to restrict the rotation of the worm wheel 176 when the tangential force F (rotational load) applied from the worm wheel 176 to the worm gear 175 is less than a predetermined value (0). Further, the worm gear 175 is configured to reversibly rotate when the tangential force F (rotational load) exceeds a predetermined value (0). To achieve this, the coefficient of friction between the worm gear 175 and the worm wheel 176 is set to a predetermined value of 0.1, and the reference cylinder advance angle γ of the worm gear 175 is set to a predetermined angle of 6 ° to 8 °. It is set to °.

  As described above, the shapes of the worm gear 175 and the worm wheel 176 and the frictional resistance of the worm wheel 176 and the worm gear 175 are set so that the rotational load of the worm gear 175 can be obtained. Accordingly, the side regulating members 173 and 178 can be moved by the user's operation, and the movement of the side regulating members 173 and 178 can be regulated by the force applied by the skew feeding of the fed sheet. . Accordingly, when the sheet P having an arbitrary size is set on the manual feed tray 174, the width of the sheet P can be reliably regulated by the side regulating members 173 and 178. Depending on the feeding operation, the sheet P can be regulated by the side regulating members 173 and 178. Never move. As a result, the fed sheet P does not enter the printer main body 1A at an angle. Therefore, the positions of the image and the sheet P coincide with each other, and the printing accuracy is poor such as misalignment in the sheet width direction or skewed image. Can be prevented. Therefore, it is possible to provide the sheet feeding apparatus 100 excellent in media flexibility without impairing the printing accuracy, and the color laser printer 1 including the sheet feeding apparatus 100.

  As described above, by utilizing the rotational load of the worm gear 175, the side regulating members 173 and 178 are moved in an analog manner in accordance with the position of the side edge of the sheet P even when an indefinite size sheet is used. be able to. Then, the side end positions can be properly regulated by the side regulating members 173 and 178. Further, depending on whether the rotational load applied to the worm gear 175 is less than a predetermined value or exceeds a predetermined value, the rotation of the worm wheel 176 can be restricted, or the worm gear 175 can be reversibly rotated. Thereby, the side regulating members 173 and 178 can be moved and regulated reliably according to the sheet P of various sizes of regular and irregular sizes, and the media flexibility can be satisfied and stable feeding can be performed. And high printing accuracy can be achieved.

  Instead of the above configuration, reversible rotation in which the worm gear 175 is rotated from the worm wheel 176 side can also be enabled by setting the torsion angle of the worm gear 175 to be larger than the repose angle (friction angle). . The requirements in that case include a relatively small diameter of the worm gear 175, a relatively large number of worm gears 175 (the number of threads), and the use of a high-performance extreme pressure lubricant.

<Second Embodiment>
Next, a second embodiment according to the present invention will be described with reference to FIG. In the present embodiment, the description of the same configuration as in the first embodiment is omitted. The description of the feeding operation similar to that in the first embodiment is also omitted. FIG. 7 is a perspective view showing the back surface of the sheet stacking unit 270 of the present embodiment.

  First, the configuration of the manual sheet stacking unit 270 in this embodiment will be described. As shown in FIG. 7, the side regulating members 273 and 278 of the present embodiment are separated from the manual feed tray 274 in accordance with the width of the sheet P so as to approach or separate from each other in the width direction orthogonal to the sheet feeding direction. It is attached so that it can move in parallel. The sheet stacking unit 270 is provided with a worm gear 275 of the present embodiment and a gear 277 that is a worm wheel as a pinion. In this embodiment, the gear 277 and the worm gear 275 constitute a holding mechanism.

  The worm gear 275 is rotatable to the back surface of the manual feed tray 274 so as to be along the sheet feeding direction at a substantially central portion of the back surface of the manual feed tray 274 by bearing portions 274a and 274b formed to protrude from the back surface of the manual feed tray 274 in this embodiment. It is supported. A gear 277 which is a worm wheel as a pinion has a helical gear shape and is rotatably attached to the manual feed tray 274 by a shaft in the thickness direction of the manual feed tray 274.

  The side regulating members 273 and 278 have a portion that extends in the width direction orthogonal to the sheet feeding direction on the back surface of the manual feed tray 274, and the extended portion is accompanied by the movement of the side regulating members 273 and 278. Moving rack portions 273a and 278a are formed. The rack portions 273a and 278a are formed as a helical tooth-shaped rack portion so as to mesh with the helical gear of the gear 277.

  Next, the mechanism of the sheet stacking unit 270 in this embodiment will be described. That is, when the user narrows the interval between the side regulating members 273 and 278 in accordance with the size of the sheet P, the user moves the side regulating members 273 and 278 in the arrow G direction. As a result, the rack portions 273a and 278a move to rotate the gear 277 in the arrow H direction in FIG. 7, and the worm gear 275 engaged with the gear 277 rotates in the arrow I direction. On the other hand, when the interval between the side regulating members 273 and 278 is widened, each component moves in the direction opposite to the arrow.

  In the present embodiment, the meshing shape of the worm gear 275 and the gear 277 is a helical tooth shape, but the meshing is the same as in the first embodiment described above, and the above formula (A) holds. The description is omitted.

  The shape of the worm gear 275 and the frictional resistance between the worm gear 275 and the gear 277 in this embodiment are set so that the rotational load of the worm gear 275 can be obtained. Accordingly, the side regulating members 273 and 278 can be moved by the user's operation, and the movement of the side regulating members 173 and 178 can be regulated by the force applied by the skew feeding of the fed sheet. . Thus, when the sheet P of an arbitrary size is set on the manual feed tray 174, the side regulating members 273 and 278 can surely regulate the width of the sheet P, and depending on the feeding operation, the sheet P is changed to the side regulating member 173. 178 is not moved.

  As a result, the sheet P does not enter the printer main body 1A obliquely, and the position of the image coincides with the position of the sheet P, thereby preventing the occurrence of poor printing accuracy such as misalignment in the paper width direction or skewed image. be able to. Therefore, it is possible to provide the sheet feeding apparatus 100 including the sheet stacking unit 270 that has excellent media flexibility without impairing the printing accuracy. Furthermore, by using the helical gear as the gear 277, it is possible to provide the sheet feeding apparatus 100 including the sheet stacking unit 270 that is easy to manufacture and that can be manufactured at a low cost. By using worms and helical gears for the regulating member interlocking mechanism and using the rotational load of the worm gear 275, the media flexibility is satisfied, stable feeding is performed, high printing accuracy, low cost, and miniaturization are achieved. Can be achieved.

<Third Embodiment>
Next, a third embodiment according to the present invention will be described with reference to FIGS. In the present embodiment, the description of the same configuration as in the first embodiment is omitted. The description of the feeding operation similar to that in the first embodiment is also omitted.

  First, the configuration of the sheet stacking unit 370 of this embodiment will be described. FIG. 8 is a perspective view of the sheet stacking unit 370 according to this embodiment in a state where no sheets are stacked. That is, as shown in FIG. 8, the side regulating members 373 and 378 move in parallel with the manual feed tray 374 in accordance with the width of the sheet P so as to approach or separate from each other in the width direction orthogonal to the sheet feeding direction. It is attached as possible. A through hole 371 penetrating in the vertical direction is formed at the center of the manual feed tray 374 near the printer main body 1A. In addition, a lock flag 381 is rotatably attached to the support portion 374 c on the back side of the manual feed tray 374 so that the tip portion protrudes from the through long hole 371.

  FIG. 9 is a rear perspective view of the sheet stacking unit 370 in the present embodiment in a state where no sheets are stacked, and FIG. 10 is a rear perspective view of the sheet stacking unit 370 in a state where sheets are stacked. 11A and 11B show the sheet stacking unit 370, where FIG. 11A is a cross-sectional view of a state in which no sheet P is placed on the sheet stacking unit 370, and FIG. 11B is a cross-sectional view of a state in which the sheet P is placed on the sheet stacking unit 370. It is.

  As shown in FIGS. 9 and 10, the sheet stacking unit 370 includes a worm gear 375, a worm wheel 376, a gear 377 (see FIG. 11), a worm pushing member 382, a worm pushing spring 383, and a worm pushing spring seat 384. Has been. In the present embodiment, the worm wheel 376 and the worm gear 375 constitute a holding mechanism.

  The worm gear 375 is rotatably supported on the back surface of the manual feed tray 374 so as to be along the sheet feeding direction at a substantially central portion on the back surface of the manual feed tray 374 by bearing portions 374a and 374b formed to protrude from the back surface of the manual feed tray 374. . The worm wheel 376 as a pinion is fixed to the gear 377 in a state where it is coaxially arranged with the gear 377 supported by the shaft in the thickness direction of the manual feed tray 374, and is rotatable with respect to the manual feed tray 374 together with the gear 377. It is attached.

  The side regulating members 373 and 378 of the present embodiment have portions extending in the width direction perpendicular to the sheet feeding direction on the back surface of the manual feed tray 374, and the extending portions include the side regulating members 373 and 378. Rack portions 373a and 378a that move with the movement are formed.

  As shown in FIGS. 9 and 11, a worm push member 382 is supported on the support portion 374c so as to be slidable in the axial direction of the worm gear 375, and the lock flag 381 is rotatable along the sheet feeding direction. It is supported by the axis | shaft 372 so that it may become. A worm push spring seat 384 is rotatably supported by a shaft 379 in the vicinity of the lower end portion of the lock flag 381 that is pivotally supported by the support portion 374c. Between the worm push member 382 and the worm push spring seat 384, a worm push spring 383 connected to each end is contracted. Accordingly, the worm push member 382 and the worm push spring seat 384 are moved along the support portion 374c as shown in FIG. 11 when the lock flag 381 is rotated about the shaft 372, so that the manual feed tray The 374 can be translated.

  FIG. 12 shows a joint portion between the worm gear 375 and the worm pushing member 382 of this embodiment, (a) shows a state where the joint is not connected, and (b) shows a state where the joint is connected. Yes. As shown in FIGS. 12 (a) and 12 (b), engaging surfaces 375a and 382a that can engage with each other in the form of a concave-convex joint are provided at the opposite ends of the worm gear 375 and the worm pushing member 382. ing. The joint shape of these engagement surfaces 375a and 382a is a saw blade, so that the worm gear 375 rotates in the direction of arrow R when the side regulating members 373 and 378 are rotated in a narrowing direction (FIG. 12B). ). Further, the joint shape of the engagement surfaces 375a and 382a is made into a saw blade shape, so that the worm gear 375 rotates in the direction of arrow S when the side regulating members 373 and 378 rotate in the expanding direction (FIG. 12B). Make it impossible.

  Next, the mechanism of the sheet stacking unit 370 of this embodiment will be described. As shown in FIG. 9, when the interval between the side regulating members 373 and 378 is reduced in accordance with the size of the sheet P, the side regulating members 373 and 378 are moved in the direction of arrow J, respectively. As a result, the rack portions 373a and 378a move in a direction in which the rack portions 373a and 378a approach each other, whereby the gear 377 is rotated in the arrow K direction.

  Then, the worm wheel 376 rotates in the same direction (arrow K direction) with the rotation of the gear 377, and the worm gear 375 rotates in the arrow L direction by receiving the rotation (rotational load) of the worm wheel 376. On the other hand, when the interval between the side regulating members 373 and 378 is increased in a state where the sheet P is not stacked on the manual feed tray 374, the respective parts move in the directions opposite to the arrows.

  As shown in FIG. 11A, in a state where the sheet P is not placed on the manual feed tray 374, the lock flag 381 does not rotate, and therefore the worm push spring seat 384 does not move. The worm push spring 383 connected and arranged between the worm push member 382 and the worm push spring seat 384 is a compression spring. In the state shown in FIGS. It has become. Therefore, there is a gap between the engagement surface 375a at the end of the worm gear 375 and the engagement surface 382a at the end of the worm push member 382, and the joint is not connected.

  As shown in FIG. 11B, when the sheet P is placed on the sheet stacking unit 370, the lock flag 381 is pressed by the weight of the sheet P and rotates in the clockwise direction in FIG. As a result, the worm push spring seat 384 that is rotatably connected to the lock flag 381 and is slidably supported by the support portion 374c moves in the arrow M direction. When the worm push spring seat 384 moves in the arrow M direction, the worm push member 382 is elastically pressed via the worm push spring 383 and moves in the arrow M direction. For this reason, the engagement surface 382a at the end of the worm push member 382 contacts the engagement surface 375a at the end of the worm gear 375 and the projections and recesses engage with each other, whereby the worm push member 382 is connected to the worm gear 375. At this time, the worm push spring 383 is compressed so as to obtain an arbitrary pressure from the free length, and locks the rotation of the worm gear 375.

  Here, the joint of the worm gear 375 and the worm pushing member 382 in this embodiment will be described. First, a state in which the joint of FIG. 12A is not connected, that is, a state in which the sheet P is not placed on the manual feed tray 374 will be described. In this state, the worm gear 375 has a rotation direction (arrow O direction) corresponding to the direction in which the side restriction members 373 and 378 are narrowed, and a rotation direction (arrow Q direction) corresponding to the direction in which the side restriction members 373 and 378 are expanded. Both of them can be rotated.

  Next, a state where the joints in FIG. 12B are connected, that is, a state where the sheet P is placed on the manual feed tray 374 will be described. In this state, the worm gear 375 that rotates in the direction in which the side regulating members 373 and 378 are narrowed can be rotated in the direction of the arrow R by the saw blade shape of the engagement surfaces 375a and 382a. However, the rotation of the worm gear 375 rotating in the direction in which the both side regulating members 373 and 378 spread is disabled in the direction of arrow S.

  That is, when the worm gear 375 rotates in the arrow R direction, a force is applied to the saw-tooth-shaped slope, so that the worm pushing member 382 receives a force in the arrow T direction. The worm push member 382 overcomes the pressure of the worm push spring 383 and retreats in the arrow T direction against the spring force of the worm push spring 383, so that the worm gear 375 can be rotated.

  On the other hand, when the worm gear 375 rotates in the arrow S direction, a force is applied to the vertical surface of the saw blade shape, so that the worm pushing member 382 does not receive a force in the arrow T direction. Therefore, the worm pushing member 382 is not retracted, and therefore the worm gear 375 cannot be rotated and is locked.

  In the present embodiment, a restraining position (position shown in FIGS. 11B and 12B) that inhibits rotation of the worm gear 375 and an allowable position (positions shown in FIGS. 11A and 12A). ) And a worm push member 382 as a rotation restraining member movable. Furthermore, a lock flag 381 is provided as a moving operation member that moves the worm pushing member 382 to the restraining position with a predetermined trigger. The worm push member 382 and the lock flag 381 constitute a rotation control mechanism. In this rotation control mechanism, the sheet P is stacked on the manual feed tray 374 which is a sheet stacking portion, and the predetermined trigger is used.

  In the present embodiment, the rotation control mechanism allows the rotation of the worm gear 375 when the side regulating members 373 and 378, which are regulating members, move in a narrowing direction corresponding to the small size sheet. Further, when the side restricting members 373 and 378 move in the expanding direction corresponding to the large size sheet, the rotation of the worm gear 375 can be suppressed or the rotation of the worm gear 375 can be allowed or suppressed.

  Accordingly, the same effects as those of the first embodiment can be obtained, and the side regulating members 373 and 378 can be narrowed even when the sheet P is placed on the manual feed tray 374, so that the media flexibility can be further satisfied and stabilized. High printing accuracy can be achieved. Further, since the rotation of the worm gear 375 is suppressed by locking the worm pushing member 382 and the worm wheel 376 and the gear 377 are not rotated, the sheet P does not move the side regulating members 373 and 378 by the feeding operation. For this reason, the width of the sheet P having an arbitrary size can be reliably regulated by the side regulating members 373 and 378.

<Fourth Embodiment>
Next, the structure which suppresses rotation of the worm gear 375 in 4th Embodiment is demonstrated. In the present embodiment, the description of the same configuration as that of the first embodiment is omitted. Also, description of the feeding operation similar to that of the first embodiment is omitted.

  First, the configuration of the sheet stacking unit 470 of the present embodiment will be described. FIG. 13 is a rear perspective view of the sheet stacking unit 470 in the present embodiment in an unlocked state.

  The side regulating members 473 and 478 of this embodiment are attached to the manual feed tray 474 so as to be movable in parallel with the width of the sheet P. The side regulating members 473 and 478 have a portion extending in the width direction orthogonal to the sheet feeding direction on the back surface of the manual feed tray 474, and the extended portion is accompanied by the movement of the side regulating members 473 and 478. Moving rack portions 473a and 478a are formed.

  The sheet stacking unit 470 is provided with a worm gear 475, a worm wheel 476, a gear (not shown) coaxial with the worm wheel 476, a worm push member 482, a worm push spring 483, a worm push spring seat 484, and a lock lever 485. Yes. In the present embodiment, the worm wheel 476 and the worm gear 475 constitute a holding mechanism.

  The worm gear 475 is rotatably supported on the back surface of the manual feed tray 474 so as to follow the sheet feeding direction at a substantially central portion of the back surface of the manual feed tray 474 by bearing portions 474a and 474b formed to protrude from the back surface of the manual feed tray 474. . A worm wheel 476 as a pinion is fixed to this gear while being coaxially arranged with the gear (not shown) supported by the shaft in the thickness direction of the manual feed tray 474, and rotates with respect to the manual tray 474 together with the gear. It is attached freely.

  Between the worm push member 482 and the worm push spring seat 484, a worm push spring 483 connected to each end is contracted. Each end portion of the worm gear 475 and the worm pushing member 482 has a joint shape that meshes with each other, similar to that described with reference to FIGS. The worm push member 482 and the worm push spring seat 484 are attached to the manual feed tray 474 so as to be movable in parallel by the same support method as in FIGS. The lock lever 485 is rotatably attached to the manual feed tray 474 by a shaft 474c. One end of the lock lever 485 is supported so as to protrude outward from the slide support groove 479 formed at one edge of the manual feed tray 474 in the width direction orthogonal to the sheet feeding direction. The other end of this is pivotally supported by one end of a worm push spring seat 484.

  Next, the mechanism of the sheet stacking unit 470 of this embodiment will be described. As shown in FIG. 13, when the interval between the side regulating members 473 and 478 is reduced in accordance with the size of the sheet P, the side regulating members 473 and 478 are moved in the arrow U direction. As a result, the rack portions 473a and 478a move in the same direction to rotate a gear (not shown) in the arrow V direction, and the worm wheel 476 rotates in the same direction (arrow V direction). Then, in accordance with the rotation of the worm wheel 476, the worm gear 475 engaged with the worm wheel 476 rotates in the arrow W direction. On the other hand, when the interval between the side restricting members 473 and 478 is widened in a state where the rotation of the worm gear 475 is not inhibited, the respective parts move in directions opposite to the arrows.

  Next, a mechanism for locking the side regulating members 473 and 478 by the user will be described. 14A and 14B show the back surface of the sheet stacking unit 470, where FIG. 14A shows a state before the side regulating members 473 and 478 are locked, and FIG. 14B shows a state after the side regulating members 473 and 478 are locked.

  As shown in FIG. 14A, the joint between the worm gear 475 and the worm pushing member 482 is not connected and a gap is left. In the case of locking, the user moves the lock lever 485 in the arrow X direction after adjusting the widths of the side regulating members 473 and 478 in accordance with the width of the sheet P in this state. As a result, the lock lever 485 rotates about the shaft 474c, and the worm push spring seat 484 is moved in the arrow Y direction.

  As shown in FIG. 14B, when the worm push spring seat 484 moves in the arrow Y direction, the worm push member 482 also moves in the arrow Y direction via the worm push spring 483. As a result, the worm push spring 483 is compressed to a state where an arbitrary pressure can be obtained from the free length, the joint portion of the worm push member 482 is connected to the joint portion of the worm gear 475, and the worm gear 475 is locked (FIG. 12A). ), (B)).

  As described above, in the present embodiment, rotation that can move between the restraining position (position shown in FIG. 14B) for inhibiting the rotation of the worm gear 475 and the allowable position (position shown in FIG. 14A). A worm push member 482 is provided as a restraining member. Further, a lock lever 485 is provided as a moving operation member that moves the worm push member 482 to the restraining position with a predetermined trigger. In this embodiment, a rotation control mechanism is constituted by the worm push member 482 and the lock lever 485. In this rotation control mechanism, the lock lever 485 is manually operated as the predetermined trigger.

  This rotation control mechanism allows the rotation of the worm gear 375 when the side regulating members 373 and 378, which are regulating members, move in a narrowing direction corresponding to the small size sheet. Further, when the side restricting members 373 and 378 move in the expanding direction corresponding to the large size sheet, the rotation of the worm gear 375 can be permitted or inhibited because the rotation of the worm gear 375 is inhibited.

  In the present embodiment described above, the same effect as in the first embodiment can be obtained, and the effect that the worm wheel 476 is not rotated when the rotation of the worm gear 475 is suppressed by locking the worm pushing member 482 can be obtained. . Accordingly, the sheet P does not move the side regulating members 473 and 478 by the feeding operation, and the width regulation of the sheet P having an arbitrary size can be reliably performed by the side regulating members 473 and 478.

  Each of the first to fourth embodiments described above is an example of application to the manual sheet feeder 100 of an electrophotographic printer. However, the present invention is not limited to this, and the same effect can be obtained when applied to a manual sheet feeding device of an ink jet printer and a document feeding device of a document reading device. Further, the same effect can be obtained even when the present invention is applied to a side regulating member of a paper feed cassette that is detachably provided in the image forming apparatus by storing sheets.

DESCRIPTION OF SYMBOLS 1B ... Image forming part, 100 ... Sheet feeding apparatus, 173, 178, 273, 278, 373, 378, 473, 478 ... Restriction member (side restriction member), 173a, 178a ... Rack part, 174, 274, 374 474 ... Sheet stacking unit (manual feed tray), 175, 275, 375, 475 ... Holding mechanism, worm gear, 176, 277 ... Holding mechanism, pinion (worm wheel, gear), 376, 476 ... Holding mechanism, pinion (worm wheel) , 381, 382 ... rotation control mechanism (moving operation member (lock flag), rotation suppression member (worm pushing member)), 482, 485 ... rotation control mechanism (rotation inhibition member (worm pushing member), moving operation member (lock lever) )), P ... sheet

Claims (7)

A sheet stacking unit for stacking sheets, a regulating member that moves to a position corresponding to the size of the sheet on the sheet stacking unit to regulate the side edge position of the sheet, and a rack unit that moves as the regulating member moves And a sheet feeding device provided with a pinion meshing with the rack portion,
A holding mechanism for holding the regulating member at a position corresponding to the size of the sheet on the sheet stacking unit via the rack unit;
The holding mechanism includes a worm wheel as the pinion, and a worm gear rotatably supported in a state of meshing with the worm wheel,
The worm gear and the worm wheel are configured so that the rotation of the worm wheel can be regulated by the worm gear when the rotational load applied from the worm wheel to the worm gear is less than a predetermined value, and the rotational load has the predetermined value. The sheet feeding device is configured so that the worm gear can be reversibly rotated by the worm wheel when exceeding.   The rotation of the worm wheel can be regulated by the worm gear when the rotational load is less than the predetermined value, and the worm gear can be reversibly rotated by the worm wheel when the rotational load exceeds the predetermined value. The friction coefficient between the worm gear and the worm wheel is set to a predetermined value, and the reference cylinder advance angle of the worm gear is set to a predetermined angle. Sheet feeding device. A rotation control mechanism that allows and inhibits rotation of the worm gear;
The rotation control mechanism allows rotation of the worm gear when the restricting member moves in a direction corresponding to a small size sheet, and allows the rotation of the worm gear when the restricting member moves in a direction corresponding to a large size sheet. The sheet feeding device according to claim 1, wherein rotation of the worm gear is suppressed.   The rotation control mechanism includes a rotation suppression member that can move between a suppression position that suppresses rotation of the worm gear and an allowable position, and a movement operation member that moves the rotation suppression member to the suppression position. The sheet feeding apparatus according to claim 3.   5. The sheet feeding according to claim 4, wherein the rotation control mechanism moves the rotation suppression member to the suppression position when a sheet is stacked on the sheet stacking unit. apparatus.   5. The sheet feeding apparatus according to claim 4, wherein the rotation control mechanism moves the rotation suppression member to the suppression position when the movement operation member is manually operated. . The sheet feeding device according to any one of claims 1 to 6,
An image forming apparatus comprising: an image forming unit that forms an image on a sheet fed from the sheet stacking unit.

Images