The present invention relates a paper feeding apparatus that is capable of detecting the size of a paper stacked in a paper cassette.
In the related art, an image forming apparatus or a paper feeding apparatus is provided with a mechanism for detecting the size of a paper stacked in a paper cassette. With the enhancement of functionality of the image forming apparatus, the image forming apparatus becomes complicated and has a lot of members. In terms of user's convenience, it is undesirable that the image forming apparatus is increased in height in a height direction. Therefore, it is necessary to reduce the height of the paper cassette in the paper feeding apparatus disposed at a lower end of the image forming apparatus.
With the enhancement of functionality of the image forming apparatus, in order to suppress an error when printing, it is necessary to accurately detect the size of the paper stacked in the paper cassette.
The paper cassette has a sidewall and an end wall that are movable along a width direction of the stacked paper and a longitudinal direction of the paper cassette. Two paper size sensors for detecting the size of the paper stacked in the paper cassette when the paper cassette is inserted into the paper feeding apparatus are provided at a position opposed to the paper cassette on the depth side of the paper feeding apparatus. Each of the paper size sensors detects the size in the paper width direction or the longitudinal direction of the paper cassette by combinations of presses. A control unit detects the paper size on the basis of a combination of the sizes in the paper width direction and the longitudinal direction of the paper cassette detected by the two paper size sensors.
The paper cassette is provided with a movable member that is movable in accordance with the movement of the sidewall, and a movable member that is movable in accordance with the movement of the end wall. The movable members correspondingly press the paper size sensors. At this time, the movable member connected to the sidewall and the movable member connected to the end wall are disposed in the paper cassette with the same rotation fulcrum.
As shown in
When the printing position of an image is misaligned with respect to the paper width direction, it is necessary to shift the paper position in the paper cassette so as to be aligned with the image to be printed (hereinafter, referred to as lateral misalignment correction). When a user executes lateral misalignment correction of a paper, the sidewall is also moved. For this reason, the paper size sensors may detect a size different from a paper size desired to be actually detected or may not specify any size. For this reason, when the user executes the lateral misalignment correction of the paper in the paper cassette, it is also necessary to move the paper size sensors, which leads to complexity.
Instead of the lateral misalignment correction of the paper, a method of correcting the position of an image when printing may be used. In this case, however, it is necessary to set a printable region in the image forming apparatus by an amount corresponding to the amount of lateral misalignment correction. For this reason, the image forming apparatus is increased in size, and manufacturing costs become high. In addition, according to this method, the position of the paper in the paper cassette is not corrected, and accordingly the paper is conveyed into the apparatus at a position different from a normal position. Then, the paper may collide against an unexpected place, and paper jam or bending may occur. When a lateral misalignment adjustment mechanism for the lateral misalignment correction is provided, it is necessary for the user to adjust the paper size sensors.
Accordingly, aspects of the invention provide a paper feeding apparatus that is capable of accurately detecting the size of a paper stacked in a paper cassette without increasing the size of the apparatus.
According to one aspect of the present invention, there is provided a paper feeding apparatus comprising; a cassette main body that stacks a paper therein, a sidewall that moves in a width direction of the cassette main body, an end wall that moves in a longitudinal direction of the cassette main body, a first movable member that is connected at one end thereof to the sidewall, rotates around a shaft axially fixed to the cassette main body in connection with the sidewall, and has a first detection portion at the other end thereof, a second movable member that is connected at one end thereof to the end wall, rotates around a shaft axially fixed to the cassette main body in connection with the end wall, and has a second detection portion at the other end thereof, a first detection unit that has a plurality of detection members and detects the size of the paper in the width direction according to the first detection portion provided in the first movable member, and a second detection unit that has a plurality of detection members and detects the size of the paper in the longitudinal direction according to the second detection portion provided in the second movable member.
Hereinafter, embodiments will be described.
Here, a side on which the paper cassette 201 shown in
The first opening and closing member 70 is a paper convey unit that is provided so as to be connected to the image forming unit body 10. The second opening and closing member 80 is a manual paper feed unit that is provided so as to abut to the first opening and closing member 70.
A control device 2 has a CPU 3, a ROM 4, and a RAM 5. The CPU 3 controls individual sensors and motors on the basis of control information previously recorded in the ROM 4. The RAM 5 temporarily records necessary information.
The paper feeding apparatus 20 is provided with paper feed rollers 101 that, when the paper cassette 201 is inserted, convey a bundle of papers stacked in the paper cassette 201 one by one from the top to the image forming unit 10. The paper feed rollers 101 convey the paper in a Y direction perpendicular to an X direction in which the paper cassette 201 is inserted into the paper feeding apparatus 20.
Near the positions in contact with the side surfaces on the near and depth side of a bundle of papers stacked in the paper cassette 201, a front-side sidewall 202F (near side) and a rear-side sidewall 202R (depth side) are provided. The front-side sidewall 202F (near side) and the rear-side sidewall 202R move in the X direction (hereinafter, referred to as the width direction of the paper cassette 201) perpendicular to the Y direction in which the paper is conveyed.
The front-side sidewall 202F and the rear-side sidewall 202R are formed to be movable, for example, in 1.0 mm pitch by two pinion gears 213 and a pinion gear holding member 212. If one of the front-side sidewall 202F and the rear-side sidewall 202R moves, the other one moves (described with reference to
The paper cassette 201 is provided with a pressing plate 203 that presses the entire paper against the paper feed rollers 101 from the bottom (bottom surface) of the paper cassette 201 in order to make sure conveyance of the paper by the paper feed rollers 101.
At an end opposite to the paper feed rollers 101 in the Y direction (the longitudinal direction of the paper cassette 201) in which the paper stacked in the paper cassette 201 is conveyed, an end wall 204 is provided. The end wall 204 moves back and forth with respect to the longitudinal direction of the paper cassette 201, and regulates the position of the paper cassette 201 in the longitudinal direction. An end of the paper in contact with the end wall 204 is referred to as a paper rear end.
The first movable member 205 and the second movable member 206 are axially supported on the rear surface of the paper cassette 201 through the shaft hole 2053 and the shaft hole 2053, respectively, so as to rotate around a shaft. The rear-side sidewall 202R on the depth side provided in the upper surface of the paper cassette 201 and the second joint groove 2054 of the first movable member 205 disposed on the rear surface of the paper cassette 201 are connected by a first connection member 207. The rear-side sidewall 202R is threadably mounted from the rear-side sidewall 202R side by the first connection member 207. Similarly, the end wall 204 provided in the upper surface of the paper cassette 201 and the second joint groove 2064 of the second movable member 206 disposed on the rear surface of the paper cassette 201 are connected by a second connection member 208. The end wall 204 is threadably mounted from the end wall 204 side by the second connection member 208. As for the first movable member 205 and the second movable member 206, the first joint groove 2052 and the second joint groove 2062 are connected with each other by the second connection member 208.
The paper cassette 201 shown in
If the front-side sidewall 202F and the rear-side sidewall 202R move from the state shown in
If the end wall 204 moves from the state shown in
Next, a description will be provided for a first sensor 102 and a second sensor 103 serving as a detection unit provided on the depth side of the paper feeding apparatus 20 when the paper cassette 201 is inserted into the paper feeding apparatus 20.
In the paper feeding apparatus 20, the first sensor 102 is provided at a position in contact with the comb-teeth member 2051 provided in the first movable member 205 on the depth side of the paper feeding apparatus 20 when the paper cassette 201 is inserted into the paper feeding apparatus 20. In addition, in the paper feeding apparatus 20, the second sensor 103 is provided at a position in contact with the comb-teeth member 2061 provided in the second movable member 206 on the depth side of the paper feeding apparatus 20 when the paper cassette 201 is inserted into the paper feeding apparatus 20.
The first sensor 102 has four protrusion members 1021 serving as detection members that protrude from the depth side to the near side. Similarly, the second sensor 103 has four protrusion members 1031 that protrude from the depth side to the near side. The CPU 3 discriminates the size of the paper cassette 201 in the width direction by combinations of presses of the four protrusion members 1021 provided in the first sensor 102. Similarly, the CPU 3 detects the size of the paper cassette 201 in the longitudinal direction by combinations of presses of the four protrusion members 1031 provided in the second sensor 103. The CPU 3 discriminates the size of the paper stacked in the paper cassette 201 on the basis of the size of the paper cassette 201 in the width direction and the size of the paper cassette 201 in the longitudinal direction.
The first movable member 205 is rotated in accordance with the movements of the front-side sidewall 202F and the rear-side sidewall 202R, and accordingly the comb-teeth member 2051 in contact with the first sensor 102 is change in shape. Therefore, the first sensor 102 detects the size of the paper cassette 201 in the width direction by press patterns of the comb-teeth member 2051 on the four protrusion members 1021 provided in the first sensor 102.
Similarly, the second movable member 206 is rotated in accordance with the movement of the end wall 204, and accordingly the comb-teeth member 2061 in contact with the second sensor 103 is changed in shape. Therefore, the second sensor 103 detects the size of the paper cassette 201 in the longitudinal direction by press patterns of the comb-teeth member 2061 on the four protrusion members 1031 provided in the second sensor 103.
In this embodiment, as shown in
As shown in
The protrusion members 1021 have a columnar shape having a diameter smaller than the height of the boxlike member 1022 of the first sensor 102. The boxlike member 1022 of the first sensor 102 has a height equal to or larger than the thickness of the first movable member 205. Similarly, the protrusion members 1031 have a columnar shape having a diameter smaller than the height of the boxlike member 1032 of the second sensor 103. The boxlike member 1032 of the second sensor 103 has a height equal to larger than the thickness of the second movable member 206.
For this reason, if the first sensor 102 and the second sensor 103 are arranged in the height direction on the same axis of the paper feeding apparatus 20, the boxlike member 1022 of the first sensor 102 and the boxlike member 1022 of the second sensor 103 are superimposed and increase in height. In this embodiment, as shown in
As shown in
An interval a between a center axis in the horizontal direction of the protrusion members 1022 arranged in the first sensor 102 and a center axis in the horizontal direction of the protrusion members 1032 arranged in the second sensor 103 is narrowed, as compared with a case where the first sensor 102 and the second sensor 103 are disposed to overlap each other in the height direction. Therefore, the paper cassette 201 is reduced in height, as compared with the related art example.
The first movable member 205 and the second movable member 206 are disposed in the paper cassette 201 to be axially shifted in the width direction of the paper cassette 201. However, since the paper cassette 201 has a size corresponding to a paper of a stackable maximum size, even if the first movable member 205 and the second movable member 206 are axially shifted in the width direction of the paper cassette 201, there is no case where the structure is increased in size.
Next, a second embodiment will be described.
The first sensor 102 and the second sensor 103 are arranged on the same sensor board 300 in the horizontal direction. The sensor board 300 is structurally detachably fixed and electrically connected to a housing 11 of the paper feeding apparatus 20 so as to be detachable from. The sensor board 300 is adapted to be electrically connected to the paper feeding apparatus 20.
As shown in
A front end of the first sensor board holding portion 2055 is engaged with an opening 3131 provided in the first claw member 313 in a shape smaller than the opening 3131. In addition, the front end of the first sensor board holding portion 2055 is moved to a position opposed to the opening 3131 provided in the first claw member 313 by rotation of the first movable member 205. Similarly, a front end of the second sensor board holding portion 2065 is engaged with an opening 3141 provided in the second claw member 314 in a shape smaller than the opening 3141. In addition, the front end of the second sensor board holding portion 2065 is moved to a position opposed to the opening 3141 provided in the second claw member 314 by rotation of the second movable member 206.
Similarly, if the end wall 204 is moved in the longitudinal direction of the paper cassette 201, the second movable member 206 is rotated around the shaft in accordance with the movement. For this reason, when the end wall 204 is opened in the longitudinal direction of the paper cassette 201, as shown in
In this state, if a serviceman draws out the paper cassette 201 from the paper feeding apparatus 20, the sensor board 300 is drawn out together with the first movable member 205 and the second movable member 206 in a state where the sensor board 300 is held by the first movable member 205 and the second movable member 206. To the contrary, if the serviceman inserts the paper cassette 201 into the image forming apparatus 1 in a state where the sensor board 300 is held by the first movable member 205 and the second movable member 206, the sensor board 300 is placed at a predetermined position in the paper feeding apparatus 20.
If the end wall 204 is in a state other than the full opened state in the longitudinal direction of the paper cassette 201, as shown in
First, the serviceman sets the end wall 204, the front-side sidewall 202F, and the rear-side sidewall 202R of the paper cassette 201 at predetermined positions (Act 101).
Next, the serviceman mounts the paper cassette 201 in the paper feeding apparatus 20 (Act 102). The serviceman puts the end wall 204 in the full opened state in the longitudinal direction of the paper cassette 201, and puts the front-side sidewall 202F and the rear-side sidewall 202R in the full opened state in the width direction of the paper cassette 201. The first movable member 205 and the second movable member 206 rotate around the shaft (Act 103).
Since the first movable member 205 and the second movable member 206 hold the sensor board 300, the serviceman can draw out the sensor board 300 from the paper feeding apparatus 20 together with the paper cassette 201 (Act 104).
Next, a third embodiment will be described.
The first holder boss 305 that is a protrusion provided in the holder member 311 is fitted into the opening 307 of the float member 304. The second holder boss 306 that is a protrusion provided in the holder member 311 is fitted into the opening 308 of the float member 304. The opening 307 and the opening 308 have a diameter larger than those of the first holder boss 305 and the second holder boss 306, respectively. Therefore, the float member 304 has a degree of freedom with respect to the holder member 311. As shown in
If the paper cassette 201 is inserted with the sensor board 300 fixed to the housing 11 of the paper feeding apparatus 20, the first boss 209 and the second boss 210 are individually fitted into the opening 310 and the opening 309 of the sensor board 300. The opening 310 and the opening 309 are provided in the float member 304. In the float member 304, the first sensor 102 and the second sensor 103 are provided as a single body.
Therefore, as shown in
The first boss 209 provided in the paper cassette 201 is fitted into the opening 310 to position the float member 304. The second boss 210 provided in the paper cassette 201 is fitted into the opening 309 to position the float member 304 in the vertical direction and to suppress rotation of the float member 304.
In the related art, the first sensor 102 and the second sensor 103 are fixed to the housing 11. For this reason, the first movable member 205 and the first sensor 102 and the second movable member 206 and the second sensor 103 have a variation in the relative positional relationship due to a cumulative tolerance, assembling accuracy, and part accuracy caused by a lot of parts between parts in contact with each other.
According to the sensor board 300 of this embodiment, the relative positions of the first sensor 102 and the second sensor 103 are reliably determined with respect to the paper cassette 201 by an inexpensive and simple method. For this reason, it is possible to avoid erroneous detection due to misalignment of the first sensor 102 and the second sensor 103.
The first boss 209 and the second boss 210 are individually fitted into the opening 310 and the opening 309 provided in the float member 304. Therefore, with the degree of freedom of the float member 304, the paper cassette 201 can be easily inserted and drawn out. As a result, the user's operational load in inserting and drawing out the paper cassette 201 is reduced.
Next, a fourth embodiment will be described.
As shown in
Even though the CPU 3 determines the paper size from the detection results of the first sensor 102 and the second sensor 103, when the paper sensors 211 determine paper absence, the CPU 3 determines that a paper of a different size (small size) from the paper size detected from the combination of the detection results of the first sensor 102 and the second sensor 103 is stacked. The CPU 3 displays on the control panel 40 serving as a notification unit a purport to urge the user to correctly set the front-side sidewall 202F and the rear-side sidewall 202R or the end wall 204.
With the above configuration, the user can reliably set the front-side sidewall 202F and the rear-side sidewall 202R or the end wall 204 for the paper stacked in the paper cassette 201. Therefore, the paper size detected by the CPU 3 from the combination of the detection results of the first sensor 102 and the second sensor 103 is consistent with the size of the paper stacked in the paper cassette 201.
A description will now be provided for a case where the user stacks a paper of an irregular size in the paper cassette 201, and reliably sets the front-side sidewall 202F and the rear-side sidewall 202R, and the end wall 204 for the paper. The RAM 5 records combinations of detection patterns of the first sensor 102 and the second sensor 103 in advance. Then, the CPU 3 discriminates the paper size by comparing the combination of detection patterns of the first sensor 102 and the second sensor 103 and size associated information in which combinations of detection patterns recorded in the RAM 5 are associated with paper sizes. The irregular size refers to a paper size that the CPU 3 cannot discriminate by comparison of the combination of the detection patterns of the first sensor 102 and the second sensor 103 with information recorded in the RAM 5.
Therefore, when the CPU 3 determines that the detection results of the first sensor 102 and the second sensor 103 are not associated with information recorded in the RAM 5 (not a regular size), the CPU 3 displays on the control panel 40 a purport that the paper size cannot be discriminated.
The user inputs the paper size in accordance with the display on the control panel 40. The CPU 3 records the input paper size in the RAM 5 in association with the combination of detection patterns of the first sensor 102 and the second sensor 103. Thereafter, if the user stacks a paper of a corresponding size in the paper cassette 201, and reliably sets the front-side sidewall 202F and the rear-side sidewall 202R, and the end wall 204 for the paper, the CPU 3 can reliably detect the paper size by comparing the combination of detection patterns of the first sensor 102 and the second sensor 103 with information recorded in the RAM 5. Therefore, as described above, if the user inputs a paper size at one time, when the user stacks a paper of an irregular size in the paper cassette 201, it is not necessary for the control panel 40 to set the paper size.
First, the user stacks a paper in the paper cassette 201 and moves the front-side sidewall 202F, the rear-side sidewall 202R, and the end wall 204 in accordance with the paper size. The paper sensors 211 attached at predetermined positions of the end wall 204, the front-side sidewall 202F, and the rear-side sidewall 202R detect whether or not a paper is present therearound, and determines whether or not the front-side sidewall 202F, the rear-side sidewall 202R, and the end wall 204 are set in accordance with the paper size (Act 201).
If the paper sensors 211 determine that the end wall 204 (or the front-side sidewall 202F and the rear-side sidewall 202R) are correctly set (Act 201, YES), the CPU 3 determines whether or not a combination of detection patterns of the first sensor 102 and the second sensor 103 is associated with information on paper size recorded in the RAM 5 (Act 202).
When the CPU 3 can discriminate the paper size (Act 202, YES), the CPU 3 conveys the paper by the paper feed rollers 101 driven by a paper feed roller motor 400 (Act 203).
If the paper sensor 211 determines that the end wall 204 (or the front-side sidewall 202F and the rear-side sidewall 202R) are not correctly set (Act 201, NO), the CPU 3 displays on the control panel 40 a purport to urge the user to correctly set the end wall 204 (or the front-side sidewall 202F and the rear-side sidewall 202R) in accordance with the paper (Act 204).
After the paper cassette 201 is drawn out from the paper feeding apparatus 20, if the CPU 3 determines that the paper cassette 201 is inserted into the paper feeding apparatus 20 again (Act 205), the process returns to Act 201.
When the paper size cannot be discriminated (Act 202, NO), the CPU 3 displays on the control panel 40 a purport that a paper of an irregular size is stacked (Act 206). That is, the user can draw out the paper cassette 201 to confirm whether or not the size of the paper stacked in the paper cassette 201 is an intended size.
The user draws out the paper cassette 201, determines that the end wall 204 (or the front-side sidewall 202F and the rear-side sidewall 202R) are not correctly set in accordance with the paper, selects NO (Act 207, NO), and correctly sets the end wall 204 (or the front-side sidewall 202F and the rear-side sidewall 202R). Then, if it is determined that the paper cassette 201 is inserted into the paper feeding apparatus 20 again (Act 208), the process returns to Act 201.
When the user draws out the paper cassette 201 and determines that the end wall 204 (or the front-side sidewall 202F and the rear-side sidewall 202R) are correctly set in accordance with the paper (Act 207, YES), if the CPU 3 determines that the paper size is not correct (Act 209, NO), the user inputs the paper size in accordance with the display on the control panel 40 (Act 211). The CPU 3 records the input paper size in the RAM 5 in association with a combination of detection patterns of the first sensor 102 and the second sensor 103 (Act 211). If the CPU 3 determines that the paper size is correct (Act 209, YES), the CPU 3 conveys the paper by the paper feed rollers 101 driven by the paper feed roller motor 400 (Act 210).
With this configuration, when a paper of a size different from the paper size determined by the CPU 3 is stacked in the paper cassette 201, an error is displayed on the control panel 40. Therefore, a paper of a different size is not conveyed to the image forming unit 10. As a result, in the image forming unit 10, it is possible to prevent paper jam or deterioration in printing position accuracy from occurring due to a difference in paper size.
Next, a fifth embodiment will be described.
In the paper cassette 201 sandwiched between the front-side rack portion 2021 and the rear-side rack portion 2022, a first fixing portion 215 and a second fixing portion 216 are provided to be spaced at a predetermined interval from each other in the width direction of the paper cassette 201. The first fixing portion 215 is provided at a position near the front-side sidewall 202F. The second fixing portion 216 is provided at a position near the rear-side sidewall 202R. In the first fixing portion 215 and the second fixing portion 216, grooves are provided at a regular interval (here, 1 mm) along the width direction of the paper cassette 201.
On the rear surface of the pinion gear holding member 212, as shown in
On the rear surface of the pinion gear holding member 212, two holding protrusions 2123 are provided between the first correction member 2121 and the second correction member 2122 along the width direction of the paper cassette 201 when being mounted in the paper cassette 201. The two holding protrusions 2123 provided in the pinion gear holding member 212 hold the pinion gears 213, respectively, when the pinion gear holding member 212 is mounted in the paper cassette 201. In addition, on the rear surface of the pinion gear holding member 212, a position fixing protrusion 2124 is provided at the center in the width direction of the paper cassette 201 when being mounted in the paper cassette 201. The position fixing protrusion 2124 provided in the pinion gear holding member 212 is fitted into a fixing hole 219 when the pinion gear holding member 212 is mounted in the paper cassette 201. The first correction member 2121 of the pinion gear holding member 212 is fastened to the opposing first fixing portion 215 by a screw 217. Similarly, the second correction member 2122 of the pinion gear holding member 212 is fastened to the opposing second fixing portion 216 by a screw 218.
The position fixing protrusion 2124 provided in the pinion gear holding member 212 is fitted into the fixing hole 219 of the paper cassette 201, and the pinion gear holding member 212 is fixed to the paper cassette 201. This fixed state is defined as a normal state. In the normal state, when the paper is stacked in the paper cassette 201, the front-side sidewall 202F and the rear-side sidewall 202R arrange the paper such that the just center of the paper cassette 201 in the width direction becomes the center axis of the paper in the longitudinal direction.
Next, lateral misalignment correction of the paper by the pinion gear holding member 212 will be described.
Here, a description will be provided for a case where the paper stacked in the paper cassette 201 is shifted by 1 mm to the depth side (an arrow direction of
Here, the pinion gear holding member 212 is provided with a movement distance measurement member 221 at an end near the rear-side sidewall 202R in the width direction of the paper cassette 201. A front end of the movement distance measurement member 221 is shaped to be perpendicular to the width direction of the paper cassette 201. As shown in
A left view in
A center view of
The first fixing portion 215, which is opposed to the first correction member 2121 provided in the pinion gear holding member 212, and the second fixing portion 216, which is opposed to the second correction member 2122 provided in the pinion gear holding member 212, are provided with grooves at an interval of 1 mm. Therefore, the user can move the pinion gear holding member 212 and the pinion gears 213 fixed to the pinion gear holding member 212 in an interval of 1 mm.
If the user moves the pinion gear holding member 212 and the pinion gears 213 fixed to the pinion gear holding member 212 by 1 mm toward the rear-side sidewall 202R, the front end of the movement distance measurement member 221 of the pinion gear holding member 212 is located at a scale mark ahead of the predetermined reference scale mark of the scale unit 221 by 1 mm.
A right view of
Therefore, the user can read the value of the scale unit 221 indicated by the front end of the movement distance measurement member 221, thereby easily viewing how much lateral misalignment correction is made.
Here, when the user moves the pinion gear holding member 212 to perform lateral misalignment correction on the front-side sidewall 202F and the rear-side sidewall 202R, the first movable member 205 connected to the rear-side sidewall 202R by the first connection member 207 rotates at a different rotation angle from that in the normal state. Therefore, in a state where lateral misalignment correction is made, a press pattern of the comb-teeth member 2051 of the first movable member 205 against the four protrusion members 1021 is different from a press pattern of the comb-teeth member 2051 of the first movable member 205 against the four protrusion members 1021 in the normal state. The first sensor 102 may erroneously detect the size of the paper cassette 201 in the width direction in a state where lateral misalignment correction is made.
In this embodiment, the first movable member 205 in a state where lateral misalignment correction is made is moved to a position different from the first movable member 205 in the normal state.
As shown in
Here, on the surface of the rear-side sidewall 202R which the first connection member 207 is in contact with, a groove 222 is provided at a regular interval (here, 1 mm) along the same direction as the movement direction of the front-side sidewall 202F and the rear-side sidewall 202R.
As shown in
A left view of
A center view of
When the pinion gear holding member 212 and the pinion gears 213 fixed to the pinion gear holding member 212 are moved from the reference position by 1 mm, the first connection member 207 is also moved from the reference position by 1 mm. Therefore, the first sensor 102 acquires the same pattern as that when in the normal state, the comb-teeth member 2051 of the first movable member 205 presses the four protrusion members 1021.
A right view of
When the pinion gear holding member 212 and the pinion gears 213 fixed to the pinion gear holding member 212 are moved from the reference position by 2 mm, the first connection member 207 is also moved from the reference position by 2 mm. Therefore, the first sensor 102 acquires the same pattern as that when in the normal state, the comb-teeth member 2051 of the first movable member 205 presses the four protrusion members 1021.
As described above, the user moves the first connection member 207 by the same distance according to the movement of the pinion gear holding member 212 and the pinion gears 213 fixed to the pinion gear holding member 212. Therefore, even if lateral misalignment correction is made, there is no case where the first sensor 102 erroneously detects the paper size. In addition, what is necessary is that the user moves the pinion gear holding member 212 and the first connection member 207 by the same distance. Therefore, it is possible to suppress the occurrence of erroneous detection due to a variation in lateral misalignment correction.
The protrusion 2072 provided in the first connection member 207 is used to hold the position of the first connection member 207 in the normal state. For this reason, there is no case where the first connection member 207 is erroneously attached when assembling. Therefore, there is no case where the first sensor 102 erroneously detects the paper size due to an error in assembling. In addition, for lateral misalignment correction of the paper, it is necessary for the user to bend (remove) the position fixing protrusion 2124 of the pinion gear holding member 212 and the protrusion 2072 of the first connection member 207. For this reason, it is possible to prevent the user from executing the lateral misalignment correction of the paper more than necessary, and it is possible to make the user to recognize that both the pinion gear holding member 212 and the first connection member 207 need to be moved in sets.
In this embodiment, the first connection member 207 is fixed to the rear surface of the rear-side sidewall 202R, but it may be fixed so as to movable with respect to the groove portion 2071 provided in the upper surface of the rear-side sidewall 202R.
Next, a sixth embodiment will be described. Here, a case where lateral misalignment correction of the paper by the pinion gear holding member 212 shown in
The link member 220 is, for example, a rod-shaped member that is connected to the pinion gear holding member 212. The link member 220 is provided in a direction from the front-side sidewall 202F toward the rear-side sidewall 202R, and extends to a position beyond the paper tray 20. As shown in the center view of
Here, the sensor board 300 is provided in the housing 11 of the image forming apparatus 1. The sensor board 300 is provided in the housing 11 such that the first sensor 102 and the second sensor 103 are moved in the movement direction of the first link member 220, that is, in a direction perpendicular to the rear-side sidewall 202R and the end wall 204.
Since the first link member 220 is in contact at 45 degrees with a second link member 312 at a predetermined place of the sensor board 300, the sensor board 300 is moved by the same distance in accordance with the movement of the first link member 220. Therefore, when the user executes lateral misalignment correction by using the pinion gear holding member 212, the first link member 220 is also move in the same direction. The first link member 220 moves the sensor board 300, and thus it is possible to prevent the first sensor 102 of the sensor board 300 from erroneously detecting the size of the paper cassette 201 in the width direction when lateral misalignment correction is made. The first link member 220 moves the sensor board 300, thereby correcting an error in size detection due to lateral misalignment correction.
Next, other examples will be described. As shown in
If the pinion gear holding member 212 is moved from the normal state for lateral misalignment correction, a press pattern of the comb-teeth member 2051 of the first movable member 205 against the four protrusion members 1021 is different from a press pattern of the comb-teeth member 2051 of the first movable member 205 against the four protrusion members 1021 in the normal state.
Here, when the pinion gear holding member 212 is in the normal state, the RAM 5 records size associated information in which press patterns of the four protrusion members 1021 provided in the first sensor 102 are associated with the paper sizes in the width direction of the paper cassette 201. In addition, when the pinion gear holding member 212 undergoes lateral misalignment correction in units of 1 mm from the normal state, the RAM 5 records size associated information in which press patterns of the four protrusion members 1021, which vary depending on the amount of movement due to lateral misalignment correction, are associated with the paper sizes.
Hereinafter, a specific example will be described.
A description will be provided for a case where the user moves the front-side sidewall 202F and rear-side sidewall 202R in accordance with a paper size A in the normal state. The comb-teeth member 2051 of the first movable member 205 presses the protrusion a and the protrusion c, for example, from among the four protrusions 1021. The CPU 3 compares a press pattern of the four protrusion members 1021 of the first sensor 102 with size associated information recorded in the RAM 5, in which the press patterns are associated with the paper sizes. When the press pattern is consistent with the size associated information, the CPU 3 determines that a paper of size A is stacked in the paper cassette 201.
Similarly, the user moves the front-side sidewall 202F and the rear-side sidewall 202R in accordance with a paper size B in the normal state. The comb-teeth member 2051 of the first movable member 205 presses the protrusion b and the protrusion d, for example, from among the four protrusion members 1021. When the press pattern is consistent with the size associated information recorded in the RAM 5, the CPU 3 determines that a paper of size B is stacked in the paper cassette 201.
Here, a description will be provided for a case where the user moves the pinion gear holding member 212 by 1 mm from the normal state by lateral misalignment correction. The user moves the front-side sidewall 202F and the rear-side sidewall 202R in accordance with the paper size A in a state where lateral misalignment correction is made by 1 mm. At this time, unlike the normal state, the comb-teeth member 2051 of the first movable member 205 presses the protrusion b and the protrusion d from among the four protrusion members 1021. When, the press pattern is consistent with the size associated information recorded in the RAM 5, and thus the CPU 3 erroneously determines that a paper of size B is stacked in the paper cassette 201.
In this embodiment, the RAM 5 records the size associated information in which in the normal state, the press pattern of the protrusions b and d from among the four protrusion members 1021 is associated with the paper size B. In addition, the RAM 5 records the size associated information in which, in a state where lateral misalignment correction is made by 1 mm, the press pattern of the protrusions b and d from among the four protrusion members 1021 is associated with the paper size A.
If the movement distance measurement member 221 determines that the pinion gear holding member 212 undergoes lateral misalignment correction by 1 mm, when comparing the press pattern by the first movable member 205 with the size associated information, the CPU 3 acquires from the RAM 5 size associated information when lateral misalignment correction is made by 1 mm and executes the comparison.
Similarly, the RAM 5 records size associated information in which, when the pinion gear holding member 212 undergoes lateral misalignment correction by 2 mm from the normal state, press patterns of the four protrusion members 1021 are associated with the paper sizes. The same is applied to a case where the pinion gear holding member 212 undergoes lateral misalignment correction by 3 mm or more from the normal state.
Therefore, if the movement distance measurement member 221 serving as a correction sensor measures a movement distance of the pinion gear holding member 212 for lateral misalignment correction, when comparing the press pattern by the first movable member 205 with size associated information, the CPU 3 acquires size associated information according to the movement distance subjected to lateral misalignment correction from the RAM 5 and executes the comparison.
As described above, since the RAM 5 has size associated information according to the movement distance subjected to lateral misalignment correction, the CPU 3 can reliably discriminate the size of a paper actually stacked in the paper cassette 201. In this example, the RAM 5 records size associated information, in which press patterns of the first movable member 205 against the sensors of the first sensor 102 are associated with the paper size, according to the movement distance subjected to lateral misalignment correction, but the same is applied to the press patterns of the second movable member 206 against the sensors of the second sensor 103.
With the above-described configuration, lateral misalignment correction and accurate paper size detection by the first sensor 102 can be compatibly achieved.
In the foregoing example, a plurality of protrusion members 1021 are provided in the first sensor 102, and the comb-teeth member 2051 of the first movable member 205 presses the protrusion members 1021. Alternatively, instead of the protrusion members 1021, an optical sensor or a magnetic sensor may be provided. In this case, instead of the comb-teeth member 2051, a plurality of holes or metal pieces transmitting light may be provided to the first movable member 205. The same is applied to the second sensor 103 or the second movable member 206.
This application claims the benefit of U.S. Provisional Applications No. 60/971,237, filed Sep. 10, 2007; No. 60/971,238, filed Sep. 10, 2007; No. 60/971,246, filed Sep. 10, 2007; No. 60/972,237, filed Sep. 13, 2007; No. 60/988,733, filed Nov. 16, 2007; and No. 60/988,751, filed Nov. 16, 2007.
Number | Date | Country | |
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60971237 | Sep 2007 | US | |
60971238 | Sep 2007 | US | |
60971246 | Sep 2007 | US | |
60972237 | Sep 2007 | US | |
60988733 | Nov 2007 | US | |
60988751 | Nov 2007 | US |