1. Field of the Invention
The present invention relates to a technique of realizing skew detection of a sheet with a simple configuration, in a sheet carrying apparatus that carries a sheet.
2. Description of the Related Art
Conventionally, a technique of detecting a paper jam by using plural sensors arranged on a sheet carrying path in a sheet carrying apparatus that carries a sheet has been known. The plural sensors arranged as described above detect passage timing of the forward edge or rear edge of a sheet carried along the carrying path. When this passage timing has exceeded a preset allowable limit value, it is determined that sheet clogging (so-called a jam) has occurred.
In order to detect a skew (slanting) of a sheet, there is also a known technique of arraying plural sensors in a direction orthogonal to the carrying direction (see
There is also a known technique of detecting the time for the forward edge of a sheet to pass between a sensor that detects passage of the sheet and an edge sensor that detects a lateral shift of the sheet, then comparing this time with the passage time in the same sensor section in a normal state (without a skew), and detecting the quantity of skew from the result of the comparison (JP-A-2005-350155).
However, in the technique described in JP-A-10-53355, since the plural sensors must be arrayed in a direction orthogonal to the carrying direction in order to detect the skew of a sheet, there is a problem that the number of sensors in the entire apparatus is increased.
Meanwhile, in the technique described in JP-A-2005-350155, since the edge sensor is used to detect the quantity of skew, there is a problem that the quantity of skew changes depending on the sheet size in the lateral direction (sheet width). Recently, the miniaturization of the apparatus causes reduction in the length of the carrying path and increase in the sheet carrying speed. Therefore, there may be inconvenience with the edge sensor that has limitations in its installation conditions, for example, a predetermined spacing to the registration roller is required in the carrying direction.
Moreover, in the technique described in JP-A-2005-350155, if the carrying time is changed by wear of a roller or the like, the carrying time of a sheet to be a detection target is influenced by the change in the carrying time due to the roller and the quantity of skew cannot be accurately determined.
It is an object of an embodiment of the invention to provide a technique that enables detection of the state of a sheet skew or the like without adding a special sensor or the like in the sheet carrying apparatus if possible.
To solve the above problems, a sheet carrying state determining device according to an aspect of the invention includes: a detection information acquiring unit configured to acquire information about sheet detection timing by two sensors that are arranged at different positions from each other in a sheet carrying direction and arranged at positions different from each other in a direction orthogonal to the sheet carrying direction; and a determining unit configured to determine a skew of a carried sheet in accordance with the information acquired by the detection information acquiring unit.
A sheet carrying state determining method according to another aspect of the invention includes: acquiring information about sheet detection timing by two sensors that are arranged at different positions from each other in a sheet carrying direction and arranged at positions different from each other in a direction orthogonal to the sheet carrying direction; and determining a skew of a carried sheet in accordance with the acquired information.
Hereinafter, embodiments of the invention will be described with reference to the drawings.
First, an image forming apparatus having a sheet carrying state determining device according to an embodiment of the invention will be described.
Specifically, an image forming apparatus 201 has a control unit 101, a photoconductive drum 102, a charging unit 103, a scanning exposure unit 104, a developing unit 105, a transfer charger 106, a stripping charger 107, a cleaner 108, a paper feeding unit 109, a sheet carrying unit 110, a fixing unit 111, a paper discharge unit 112, a cassette 113, a paper discharge tray 114, a paper feeding roller 115, a CPU 801 and a memory 802.
The photoconductive drum 102 has its photoconductive surface turn in a sub scanning direction (the circumferential direction of the photoconductive drum 102). In the vicinity of the photoconductive surface of the photoconductive drum 102, first, the charging unit 103 is arranged. The charging unit 103 uniformly charges the surface of the photoconductive drum 102.
The scanning exposure unit 104 emits light or turns off in accordance with an image signal while scanning with a semiconductor laser, not shown, provided in the scanning exposure unit 104. A laser beam emitted from this semiconductor laser is turned into light that scans in a main scanning direction (the direction parallel to the rotation axis of the photoconductive drum 102) by a deflector such as a polygon mirror.
The laser beam is cast onto the photoconductive drum 102 by an optical system including lenses and so on. As the laser beam is cast onto the charged photoconductive surface of the photoconductive drum 102, the potential at the irradiated part is lowered and an electrostatic latent image is formed there.
The developing unit 105 applies a developer to the photoconductive drum 102 and thus forms a developer image on the photoconductive drum 102.
The cassette 113 is provided in the bottom part of the image forming apparatus 201. The paper feeding roller 115 separates sheets 130 in the cassette 113 one by one and send each sheet to the paper feeding unit 109. The paper feeding unit 109 supplies sheet 130 to a transfer position on the photoconductive drum 102. The transfer charger 106 transfers the developer image to the supplied sheet 130. The stripping charger 107 strips the sheet 130 from the photoconductive drum 102.
The sheet 130 with the developer image transferred thereto is carried to the fixing unit 111 by the sheet carrying unit 110. The fixing unit 111 fixes by heating the developer image transferred onto the sheet 130, to the sheet 130. The paper discharge unit 112 discharges the sheet 130 with the image printed thereon onto the discharge tray 114.
After the transfer of the developer image to the sheet 130 is finished, the developer remaining on the photoconductive drum 102 is removed by the cleaner 108. The photoconductive drum 102 restores its initial state and enters a standby state for the next image forming processing.
As the above process operation is repeated, the image forming operation in the image forming apparatus 201 is continuously carried out.
These four sensors are, for example, optical sensors. When the sensors have detected the forward edge of the sheet 130 carried in the carrying direction, the sensors turn to the ON-state. When the sensors have detected the rear edge of the sheet 130, the sensors turn to the OFF-state.
The control unit 101 determines the time point when each sensor turns to the ON-state, as “ON time”, and the time point when each sensor turns to the OFF-state, as “OFF time”. Thus, the passage of the sheet 130 over each sensor is detected.
As can be seen from
The paper feeding sensor 11 and the carrying sensor 12 are arranged at different positions from each other in a direction orthogonal to the carrying direction of the sheet 130. The carrying sensor 12 and the intermediate carrying sensor 13 are arranged at substantially the same positions in the direction orthogonal to the carrying direction of the sheet 130. Of course, their positions are not limited to these. For example, any two of the paper feeding sensor 11, the carrying sensor 12 and the intermediate carrying sensor 13 may be arranged at substantially the same positions in the direction orthogonal to the carrying direction of the sheet 130.
The detection information acquiring unit 701 has the function of acquiring information about sheet detection timing by at least two sensors.
The determining unit 702 has the function of determining a skew of a carried sheet in accordance with the information acquired by the detection information acquiring unit 701. Specifically, the determining unit 702 determines whether the sheet movement time between two sensors each is normal or not, in accordance with the result of comparing the movement time of the sheet between two sensors each and the sheet movement time in a state where the sheet is carried normally between the two sensors, provided from the information acquired from the paper feeding sensor 11, the carrying sensor 12 and the intermediate carrying sensor 13 by the detection information acquiring unit 701. The determining unit 702 then determines the presence or absence of a skew of the sheet in accordance with the combination of normality or abnormality between two sensors each.
Here, the “sheet movement time” refers to the time from when the forward edge of the sheet is detected at the detection position by the sensor situated upstream in the sheet carrying direction (for example, the paper feeding sensor 11) until the forward edge of the sheet is detected at the detection position by the sensor situated downstream in the sheet carrying direction (for example, the carrying sensor 12). Of course, the detection of the sheet to acquire the sheet movement time need not necessarily be carried out by detection of the forward edge of the sheet, and may be carried out by detection of the rear edge of the sheet.
The notification control unit 703 has the function of causing the display unit 704 to give a notification through screen display in the case where the rotation angle of the skew calculated by the determining unit 702 has a predetermined value or more.
The display unit 704 is formed by, for example, a liquid crystal display, CRT display, or EL display. The display unit 704 has the function of showing the information about processing contents in the sheet carrying state determining device 7 or the image forming apparatus 201 through screen display. The display unit 704 may also be realized by, for example, a touch panel display or the like.
The CPU 801 has the function of carrying out various kinds of processing in the sheet carrying state determining device 7 and the image forming apparatus 201. The CPU 801 is also responsible for realizing various functions by executing programs stored in the memory 802. The memory 802 is formed by, for example, a ROM or RAM. The memory 802 has the function of storing various information and programs used in the sheet carrying state determining device 7 and the image forming apparatus 201.
Next, a method of detecting a skew of a sheet according to this embodiment will be described.
In this manner, between the sensors situated at different positions from each other in the direction orthogonal to the sheet carrying direction, the carrying time changes in proportion to the skew angle of the carried sheet (see
First, the determining unit 702 determines whether the time for the forward edge (or rear edge) of the sheet 130 to pass the section (X2) between the carrying sensor 12 and the intermediate carrying sensor 13 is normal or not (S101).
If it is determined in S101 that the time is abnormal, it is determined that the carrying time is delayed by other factors than a skew. Therefore, the notification control unit 703 causes the display unit 704 to display a notification to the serviceman on the screen (S105).
On the other hand, if it is determined in S101 that the time is normal, the processing goes to S102. The determining unit 702 determines whether the time for the forward edge (or rear edge) of the sheet 130 to pass the section (X1) between the paper feeding sensor 11 and the carrying sensor 12 is normal or not (S102).
If it is determined in S102 that the time is abnormal, it is determined that the sheet is skewed. Therefore, the display unit 704 shows a screen display (notification) to draw attention (S104).
On the other hand, if it is determined in S102 that the time is normal, it is determined that no error has occurred and that the sheet is carried in the normal state (S103).
The determining unit 702 detects the time for the forward edge (or rear edge) of the sheet 130 to pass the section (X1) between the paper feeding sensor 11 and the carrying sensor 12 and thus can calculate the angle (θ=arc tan(t×V÷1)) and direction (clockwise or counterclockwise) in which the sheet 130 is skewed.
In this manner, the determining unit 702 calculates the rotation angle of the skew of the sheet in accordance with the time difference between the sheet movement time between the paper feeding sensor 11 and the carrying sensor 12 (the first section X1) provided from the information acquired by the detection information acquiring unit 701 and the sheet movement time without a skew between the paper feeding sensor 11 and the carrying sensor 12.
In this embodiment, the paper feeding sensor 11 is arranged with a right shift with respect to the carrying sensor 12 in the direction orthogonal to the sheet carrying direction. Therefore, if the sheet movement time between the paper feeding sensor 11 and the carrying sensor 12 provided from the information acquired by the detection information acquiring unit 701 is shorter than the sheet movement time without a skew between the paper feeding sensor 11 and the carrying sensor 12, the determining unit 702 determines that the sheet is skewed to the right (clockwise) with respect to the sheet carrying direction.
As the time for the forward edge (or rear edge) of the sheet 130 to pass between the carrying sensor 12 and the intermediate carrying sensor 13 arrayed linearly with respect to the carrying direction (the second section X2) is detected, it can be determined that the carrying time is delayed by other factors than a skew. By making a determination based on the combination these two kinds of changes in the carrying time, it is possible to detect a skew.
The determining unit 702 determines the skew of the sheet on the basis of the sheet movement time in the first section X1 between the paper feeding sensor 11 and the carrying sensor 12 in the sheet carrying direction, and determines the other factors (wear of a roller or the like) that influence the sheet carrying state than the skew on the basis of the sheet movement time in the second section X2 between the carrying sensor 12 and the intermediate carrying sensor 13.
That is, comparison is made with the carrying time when the sheet is normally carried, to detect the presence or absence of other jam factors than the skew, and determination is based on the combination with the present or absence of change in the carrying time in the case of using the detection method to detect a skew. Thus, the skew and other paper jam factors can be discriminated.
Next, a method of arranging each sensor in this embodiment will be described.
In the above description of the skew detection method, skew detection is carried out by using the second section (X2) between the carrying sensor 12 and the intermediate carrying sensor 13, and the first section (X1) between the paper feeding sensor 11 and the carrying sensor 12. However, a sensor arrangement method that enables skew detection is not limited to this arrangement method.
However, when a sensor layout that holds θ1=θ2 (pattern 4) is employed, changes in the carrying time due to a skew and due to other factors than a skew cannot be separately detected. This is because, when a skew has occurred, no change is observed in the difference in the time for the forward edge (or rear edge) of the sheet 130 to pass between the paper feeding sensor 11 and the carrying sensor 12 from the normal state and the difference in the time for the forward edge (or rear edge) of the sheet 130 to pass between the carrying sensor 12 and the intermediate carrying sensor 13 from the normal state.
As can be understood from the above, it is preferable that the straight line connecting the first sensor to the second sensor of the three sensors and the straight line connecting at least one of the first sensor and the second sensor to the third sensor have different inclination angles with respect to the sheet carrying direction.
To detect the difference in the carrying time of one msec for the skew angle of the sheet of one degree compared to the case where the sheet is normally carried, it is preferable that, when the sheet carrying speed is V mm/sec, two sensors arranged at positions shifted from each other in the direction orthogonal to the sheet carrying direction (for example, the paper feeding sensor 11 and the carrying sensor 12) are installed in such a manner that their positional shift is 0.0573×V mm or more.
Next, the case of detecting a skew that occurs at the time of feeding a sheet will be described.
Thus, according to the above skew detection method, in the case where the sheet has been skewed in the paper feeding unit 109, the time for the forward edge (or rear edge) of the sheet 130 to pass between the paper feeding sensor 11 and the carrying sensor 12 increases or decreases compared to the normal state, whereas the time for the forward edge (or rear edge) of the sheet 130 to pass between the carrying sensor 12 and the intermediate carrying sensor 13 does not change compared to the normal state.
In the case where the sheet carrying time is changed by wear of a roller or the like in the sheet carrying path, the carrying time changes in both the section between the paper feeding sensor 11 and the carrying sensor 12 and the section between the carrying sensor 12 and the intermediate carrying sensor 13. Therefore, with the configuration of
Next, the case of detecting a skew occurring upstream of a registration roller 117 that caries out skew correction and adjustment of carrying timing of the carried sheet will be described.
As shown in
In the case where the sheet carrying time is changed by wear of a roller or the like, the carrying time changes in the two carrying sections between the intermediate carrying sensor 13 and the registration sensor 14 and between the carrying sensor 12 and the intermediate carrying sensor 13. Therefore, with the configuration of
Now, the case of detecting a skew generated in a sheet on which image forming processing has been carried out will be described.
In the configuration shown in
Thus, with the skew detection method as described above, if the sheet is skewed at the time of printing, the time for the forward edge (or rear edge) of the sheet 130 to pass between the pre-transfer sensor 15 and the winding sensor 16 (S401) and the time for the forward edge (or rear edge) of the sheet 130 to pass between the winding sensor 16 and the paper discharge sensor 17 (S402) increase or decrease compared to the normal state.
However, if the passage time between the pre-transfer sensor 15 and the winding sensor 16 increases compared to the normal state (S403), the passage time between the winding sensor 16 and the paper discharge sensor 17 decreases compared to the normal state, and vice versa.
In the case where the carrying time is changed by wear of a roller or the like, the carrying time similarly changes in the two carrying sections between the pre-transfer sensor 15 and the winding sensor 16 and between the winding sensor 16 and the paper discharge sensor 17.
Thus, even if the sheet is skewed at the time of printing, the skew at the time of printing can be detected and measures can be taken such as causing the display unit 704 or a control panel or the like, not shown, provided in the image forming apparatus 201, to display a warning related to the sheet carrying state (S405, S406).
The steps of the above processing in the sheet carrying state determining device are realized as the CPU 801 executes a sheet carrying state determination program stored in the memory 802.
The sheet to be a carrying target in the above embodiment may be, for example, a copy sheet (normal paper). The sheet is not limited to this. As a matter of course, an OHP film, a coated sheet, a thick paper or the like as a printing medium can be employed.
Moreover, as a matter of course, the image forming apparatus 201 according to the above embodiment not only carries out image forming processing on a sheet, but also may have an image scanning device and a communication function and have the functions of a digital multi-function peripheral including scanning, reading and copying an image with designated resolution and sheet size, receiving an image by FAX or e-mail, and receiving a printed image through a network.
In the above embodiment, it is assumed that a sheet is carried within the image forming apparatus. However, it does not necessarily have to be an image forming apparatus. An apparatus that carries a sheet and has plural sensors for detecting the sheet as a carrying target (for example, an automatic document feeder (ADF) or the like) can achieve the similar advantages to those of the embodiment.
As described above, according to the embodiment, a skew of a sheet can be detected by using sensors arranged in a typical layout, without increasing the number of sensors over the number of sensors that are normally arranged in the sheet carrying device.
In a sensor layout having at least two sensor sections where the inclination between two sensors with respect to the sheet carrying direction is different from each other, the carrying time in each sensor section is compared to the carrying time at the time of normal carrying in the same section, and the results of the comparison of the two or more sensor section are combined for determination. Thus, other paper jam factors and a skew can be separately determined.
Moreover, since the paper detection sensors are used, the quantity of skew can be detected irrespective of sheet size and this can contribute to improvement in the degree of freedom in the sensor layout and the degree of freedom in design.
In the embodiment, the functions that carry out the invention have been recorded in the apparatus in advance. However, the configuration of the functions is not limited to this. The similar functions may be downloaded to the apparatus from a network. Alternatively, the similar functions stored in a recording medium may be installed into the apparatus. The recording medium may be in any form as long as it can store programs and is readable by the apparatus, for example, a CD-ROM or the like. The functions that are installed or downloaded in advance may be realized in cooperation with the operating system (OS) in the apparatus.
Although the specific embodiment of the invention has been described in detail, it would be obvious to those skilled in the art that various changes and modifications can be made without departing from the spirit and scope of the invention.
As described above in detail, according to the invention, a technique can be provided that enables detection of the state of a sheet skew or the like without adding a special sensor or the like in the sheet carrying apparatus if possible.
Number | Name | Date | Kind |
---|---|---|---|
4971304 | Lofthus | Nov 1990 | A |
5169140 | Wenthe, Jr. | Dec 1992 | A |
5278624 | Kamprath et al. | Jan 1994 | A |
5322273 | Rapkin et al. | Jun 1994 | A |
5533721 | Takashimizu | Jul 1996 | A |
5678159 | Williams et al. | Oct 1997 | A |
5697608 | Castelli et al. | Dec 1997 | A |
6988725 | Rapkin | Jan 2006 | B2 |
7322575 | Sauer et al. | Jan 2008 | B2 |
7422210 | Dejong et al. | Sep 2008 | B2 |
20080240820 | deJong et al. | Oct 2008 | A1 |
Number | Date | Country | |
---|---|---|---|
20090057992 A1 | Mar 2009 | US |
Number | Date | Country | |
---|---|---|---|
60969140 | Aug 2007 | US |