The present invention relates to an image forming apparatus configured to control an image forming condition according to a surface property of a recording material.
Conventionally, an image forming apparatus such as a copying machine or a printer, which includes a sensor for determining a type of a recording material, has been provided. Such an image forming apparatus automatically determines a type of a recording material and controls a transfer condition (e.g., a transfer voltage and/or a conveyance speed of a recording material in a transfer period) and a fixing condition (e.g., a fixing temperature and/or a conveyance speed of a recording material in a fixing period) according to the determination result.
An image forming apparatus discussed in Japanese Patent Application Laid-Open No. 2010-283670 emits light to a recording material being conveyed at a constant speed and captures light reflected on the recording material as an image through a complementary metal oxide semiconductor (CMOS) line sensor. Then, the image forming apparatus determines a type of the recording material based on the captured image and controls the image forming condition. With this configuration, a high-quality image can be formed on the recording material.
An image forming apparatus discussed in Japanese Patent Application Laid-Open No. 2013-179532 determines whether there is a breakage or a hole on a recording material by detecting a surface state of the recording material being conveyed therethrough. According to the technique discussed in Japanese Patent Application Laid-Open No. 2013-179532, when a speed of the recording material is accelerated or decelerated, an amount of irradiation light or a reading speed, i.e., a so-called shutter speed, is adjusted according to the speed of the recording material. With this configuration, a surface state of the recording material can be detected with a brightness and/or resolution similar to those of the case where the recording material is conveyed at a constant speed.
However, adjusting the reading speed on a real time basis according to the conveyance speed of the recording material, and finely adjusting the amount of irradiation light as discussed in Japanese Patent Application Laid-Open No. 2013-179532, complicates the operation for detecting the surface state of the recording material. Further, in consideration of the responsiveness of the normally-used light-emitting diode (LED), it can be difficult to make the amount of irradiation light accurately follow the change of the conveyance speed of the recording material.
Various embodiments of the present application are directed to an image forming apparatus capable of forming an image of high quality by determining an image forming condition according to a surface state of a recording material without executing a complicated detection operation even in a case where a speed of the recording material is accelerated or decelerated.
According to one embodiment, an image forming apparatus includes a conveyance unit configured to convey a recording material, an irradiation unit configured to radiate light on the recording material being conveyed by the conveyance unit, an image capturing unit configured to capture a plurality of times the light radiated by the irradiation unit and reflected on the recording material as surface images, an image formation unit configured to form an image on a recording material, and a control unit configured to control an image forming condition of the image formation unit, wherein the conveyance unit accelerates or decelerates a conveyance speed of the recording material in at least a part of an image capturing period during which the image capturing unit captures the surface images the plurality of times, and wherein the control unit obtains a feature quantity from a plurality of the surface images captured by the image capturing unit and controls the image forming condition based on the obtained feature quantity and a threshold value set according to the conveyance speed of the recording material in the image capturing period.
Further features will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Hereinbelow, an exemplary embodiment will be described with reference to the appended drawings.
<Description of Configurations of Image Forming Apparatus>
According to one exemplary embodiment, an electro-photographic laser beam printer 100 (hereinbelow, referred to as “printer 100”) will be described as an example of an image forming apparatus.
The printer 100 is a tandem-type color printer capable of forming a color image on a recording sheet 120 (recording material) by overlapping toner in four colors of yellow (Y), magenta (M), cyan (C), and black (K). A cassette 101 is a container for storing the recording sheet 120. A conveyance path of the recording sheet 120 is indicated by a dashed line in
Photosensitive drums 104Y, 104M, 104C, and 104K (hereinbelow, referred to as “drums 104” or “a drum 104” unless otherwise necessary) for carrying toner are rotated by a driving source (not illustrated) in a direction indicated by an arrow in
Primary transfer rollers 109Y, 109M, 109C, and 109K (hereinbelow, referred to as “primary transfer rollers 109” or “a primary transfer roller 109” unless otherwise necessary) primarily transfer the toner images formed on the drums 104 onto an intermediate transfer belt 103 (hereinbelow, referred to as “belt 103”). The belt 103 is rotated by a driving roller 150 in a direction indicated by an arrow in
A feeding-conveyance motor 206 (hereinbelow, referred to as “motor 206”) serves as a driving source for driving the rollers that feed and convey the recording sheet 120. The rollers that feed and convey the recording sheet 120 and the motor 206 constitute a conveyance unit. A recording material detection unit 210 (hereinbelow referred to as “detection unit 210”) detects a property of the recording sheet 120 in order to determine a type of the recording sheet 120. The detection unit 210 is configured of a surface property detection unit 204 that detects a surface property (concavo-convex state) of the recording sheet 120 as a property of the recording sheet 120. A control unit 200 controls an operation of the printer 100. A central processing unit (CPU), a random access memory (RAM), and a read only memory (ROM) are mounted on the control unit 200. The RAM (storage unit) is used for temporarily storing data necessary to control the printer 100. A program for controlling the printer 100 and various kinds of data are stored in the ROM (storage unit). The operation of the control unit 200 will be described below in detail.
<Configuration of Recording Material Detection Unit>
Next, the detection unit 210 will be described in detail.
When a surface image of the recording sheet 120 is captured by the surface property detection unit 204, a series of image capturing operations is executed repeatedly while the recording sheet 120 is being conveyed as illustrated in
<Calculation Method of Feature Quantity and Determination Method of Image Forming Condition>
Next, description will be given of a method in which the control unit 200 calculates a feature quantity indicating a surface property of the recording sheet 120 from the surface image captured by the surface property detection unit 204.
In the present exemplary embodiment, a parallel difference integration value will be calculated as a feature quantity. The parallel difference integration value is a value in which an amount of change of output values of a plurality of pixels arranged in each of the columns parallel to the conveyance direction of the recording sheet 120 is integrated with each other. Herein, an amount of change of output values of a plurality of pixels arranged in a predetermined column can be acquired through a method described below. For example, pixels of (1, 1), (2, 1), . . . , (511, 1), and (512, 1) are arranged consecutively, and exist in a first column. The control unit 200 calculates an absolute value of a difference of output values of the pixels (1, 1) and (2, 1), and acquires an absolute value of a difference of output values of the pixels (2, 1) and (3, 1). Then, the absolute values of the two differences are integrated. In this way, by continuously executing the calculation for acquiring and integrating an absolute value of a difference of output values of two pixels adjacent in the conveyance direction with respect to all of the pixels existing in the first column, the control unit 200 obtains an amount of change C1 of the output values of the plurality of pixels in the first column. The control unit 200 further executes similar calculation with respect to the other columns (the second to two-hundredth columns), and eventually obtains a parallel difference integration value C by integrating the amounts of change C1 to C200 of all of the columns. In addition, the control unit 200 may obtain the amount of change of the output values of a plurality of pixels in a predetermined column by calculating a maximum value and a minimum value of the output values of the plurality of pixels arranged in the predetermined column and calculating an absolute value of a difference of the maximum value and the minimum value.
The control unit 200 can determine a type (surface property) of the recording sheet 120 based on the parallel difference integration value. For example, the control unit 200 determines that the recording sheet 120 is a so-called gloss paper having a smooth surface if the parallel difference integration value is small, and determines that the recording sheet 120 is a so-called rough paper having a rough surface if the parallel difference integration value is large. Further, the control unit 200 determines that the recording sheet 120 is a plain paper if the parallel difference integration value is a value between the above two values. Then, the control unit 200 controls the image forming condition of the image formation unit according to the determined type of the recording sheet 120 (surface property).
Since the gloss paper has a resistance value lower than that of the rough paper when the thicknesses thereof are the same, a transfer current and a transfer voltage necessary for transferring a toner image onto the gloss paper are higher than in a case of the rough paper. Accordingly, the control unit 200 controls the values of the transfer current and the transfer voltage to satisfy the relationship of “rough paper<plain paper<gloss paper”. Further, a fixing temperature necessary for fixing a toner image to the gloss paper is lower than that of the rough paper. Accordingly, the control unit 200 controls the fixing temperature of the fixing unit 118 to satisfy a relationship of “gloss paper<plain paper<rough paper”. As described above, a quality of the image formed on the recording sheet 120 can be improved by controlling the various image forming conditions according to the type (surface property) of the recording sheet 120.
For example, a conveyance speed of the recording sheet 120, a voltage value applied to each of the primary transfer rollers 109 and the secondary transfer roller 108, a temperature for fixing an image on the recording sheet 120 at the fixing unit 118 may be considered as the image forming conditions. Herein, the conveyance speed of the recording sheet 120 is a so-called processing speed including a rotation speed of the primary transfer rollers 109 or the secondary transfer roller 108 and a rotation speed of a fixing roller that constitutes the fixing unit 118. Further, the conveyance speed of the recording sheet 120 also includes a speed at which the recording sheet 120 is fed from the feeding port (e.g., the cassette 101 or the manual feed tray 111) to the conveyance path. Furthermore, the control unit 200 may directly control the image forming condition from a calculated feature quantity value without determining the type (surface property) of the recording sheet 120.
<Timing Chart>
Subsequently, a sequence for actually determining the image forming condition of the recording sheet 120 will be described. In the present exemplary embodiment, images are consecutively formed on a plurality of recording sheets 120. Hereinbelow, the sequence will be described separately with respect to the case where an image is formed on the first recording sheet 120 and the case where images are formed on the second and the subsequent recording sheets 120.
<Image Forming Operation for the First Recording Sheet>
In
When the image is formed on the first recording sheet 120, the control unit 200 controls a speed (processing speed) of the recording sheet 120, a value of the voltage applied to the secondary transfer roller 108, and a fixing temperature of the fixing unit 118 based on a detection result of the first recording sheet 120 detected by the surface property detection unit 204. Therefore, the first recording sheet 120 is stopped temporarily before the leading end thereof reaches the secondary transfer roller 108. More specifically, the first recording sheet 120 is stopped temporarily at the timing at which the leading end of the first recoding sheet 120 reaches the position P illustrated in
The control unit 200 determines the image forming condition of the first recording sheet 120 during the stop period. When the image forming condition is determined, the image formation unit starts forming toner images on the drums 104 and the belt 103. After the stop period has passed, the first recording sheet 120 is conveyed again at a determined processing speed Vps while adjusting the conveyance timing with that of the toner image formed on the belt 103. Thereafter, the secondary transfer roller 108 transfers the toner image onto the first recording sheet 120 at a determined voltage value, and the fixing unit 118 fixes the toner image to the first recording sheet 120 at a determined fixing temperature. The recording sheet 120 on which the toner image has been formed is discharged to the outside of the printer 100 from a discharge port.
As illustrated in
<Image Forming Operation for the Second and the Subsequent Recording Sheets>
In
When images are to be formed on the second and the subsequent recording sheets 120, a detection result of the first recording sheet 120 is used not only for the conveyance speed of the recording sheet 120 but also for the voltage value applied to the secondary transfer roller 108. With this configuration, productivity of the printer 100 is improved because the second and the subsequent recording sheets 120 do not have to be temporarily stopped at the stop position P positioned in the upstream of the secondary transfer roller 108. When images are formed on the second and the subsequent recording sheets 120, the control unit 200 controls the fixing temperature of the fixing unit 118 based on detection results of the second and the subsequent recording sheets 120 detected by the surface property detection unit 204. Since the fixing temperature is controlled according to the individual differences of the second and the subsequent recording sheets 120, it is possible to prevent unnecessary power consumption. Further, the fixing temperature of the fixing unit 118 has already been increased to a predetermined temperature based on the detection result of the first recording sheet 120. Therefore, it is not necessary to temporarily stop the second and the subsequent recording sheets 120 in order to make a fine adjustment on the fixing temperature based on the detection results of the second and the subsequent recording sheets 120. The fixing unit 118 fixes the toner images to the second and the subsequent recording sheets 120 at the finely-adjusted fixing temperatures. The recording sheets 120 on which the toner images have been formed are discharged to the outside of the printer 100 from the discharge port.
Now, the acceleration/deceleration control will be described in detail. When a preceding recording sheet 120 is ready to be conveyed by the process member such as the secondary transfer roller 108 to which the motor 206 does not contribute after the registration sensor 116 has detected the trailing end of the preceding recording sheet 120, the acceleration/deceleration control can be executed on the following recording sheet 120. Then, the control unit 200 determines whether the timing at which the leading end of the following recording sheet 120 is detected by the registration sensor 116 is earlier or later than a reference timing. Herein, the reference timing refers to a timing at which a toner image is transferred onto a desired position on the following recording sheet 120 by the secondary transfer roller 108 if the following recording sheet 120 is conveyed at the processing speed Vps without any change. When the control unit 200 determines that the detection timing detected by the registration sensor 116 is different from the reference timing, the control unit 200 changes the conveyance speed of the recording sheet 120 from the processing speed Vps in order to transfer the toner image to a desired position on the following recording sheet 120.
For example, when the following recording sheet 120 is considerably brought out at the feeding port (the cassette 101 or the manual feed tray 111), the detection timing of the registration sensor 116 becomes earlier than the reference timing. In this case, the control unit 200 decelerates the conveyance speed of the following recording sheet 120 from the processing speed Vps. On the other hand, when the following recording sheet 120 slips while being fed by the feeding roller 102 or 121, the detection timing of the registration sensor 116 is later than the reference timing. In this case, the control unit 200 accelerates the conveyance speed of the following recording sheet 120 from the processing speed Vps.
In the present exemplary embodiment, the surface property detection unit 204 executes the detection also in a period during which the speed of the recording sheet 120 is changed, so that the image capturing period is extended as illustrated in the timing charts in
<Normalization of Feature Quantity According to Number of Image Capturing Times>
A vertical axis of the graph in
In the graph in
<Relationship between Speed of Recording Sheet and Normalized Feature Quantity>
y=a×x+b (1)
In the formula 1, a value “x” represents a conveyance speed ratio of the average speed of the recording sheet 120 when a reference conveyance speed V is 1, and a value “y” represents a parallel difference integration value normalized by the reference number of image capturing times.
In summary, the control unit 200 calculates the parallel difference integration value from the image captured by the surface property detection unit 204 and normalizes the parallel difference integration value with the reference number of image capturing times. Then, the control unit 200 obtains the average speed of the recording sheet 120 in the image capturing period, and determines the type (surface property) of the recording sheet 120 by using the determination table in
In addition, although the number of image capturing times of the surface property detection unit 204 has been changed in order to capture the same range of the recording sheet 120, the present exemplary embodiment is not limited thereto. When the surface property detection unit 204 consistently executes the same number of times (reference number of times) of image capturing, the control unit 200 can determine the type (surface property) of the recording sheet 120 by using the determination table in
<Functional Block Diagram of Control Unit>
The control unit 200 includes a motor control unit 205, a profile generation unit 207, and a detection timing determination unit 209. The profile generation unit 207 generates speed profile information of the recording sheet 120 based on the timing at which a leading end of the recording sheet 120 is detected by the registration sensor 116. In the present exemplary embodiment, as illustrated in
The surface property detection unit 204 executes image capturing of the recording sheet 120 based on the detection timing transmitted from the detection timing determination unit 209. The acquired image information is transmitted to the feature quantity calculation unit 203, so that the above-described parallel difference integration value is calculated as a feature quantity that indicates a surface property of the recording sheet 120. The control unit 200 further includes a correction unit 208, a judgment unit 201, and a determination unit 214. The correction unit 208 corrects the feature quantity calculated by the feature quantity calculation unit 203 based on the number of image capturing times calculated by the number of image capturing times calculation unit 211. The judgment unit 201 judges a type (surface property) of the recording sheet 120 based on the feature quantity corrected by the correction unit 208 and the average speed of the recording sheet 120 calculated by the average speed calculation unit 212. The determination unit 214 determines the image forming condition according to the type (surface property) of the recording sheet 120 judged by the judgment unit 201.
<Description of Flowchart>
Next, a flowchart according to the present exemplary embodiment illustrated in
In step S1, the control unit 200 sets reference parameters. In the present exemplary embodiment, a reference conveyance speed V, a reference number of image capturing times N, and a light receiving period T for executing the image capturing one time are set as 100 mm/sec, 512 times, and 0.423 msec, respectively.
In step S2, based on the timing at which the leading end of the recording sheet 120 is detected by the registration sensor 116, the control unit 200 sets speed profile information and image capturing start and end timings of the surface property detection unit 204.
In step S3, the control unit 200 sets surface property detection parameters. The surface property detection parameters are an image capturing range L of the recording sheet 120 (i.e., a length in the conveyance direction of the recording sheet 120) and an image capturing period Dt of the surface property detection unit 204.
In step S4, the control unit 200 determines correction coefficients for correcting the feature quantity. Based on the speed profile information set in step S2, the control unit 200 calculates an average speed Vave of the recording sheet 120 in the image capturing period as a correction coefficient through the following formula 2. Further, the control unit 200 acquires a number of image capturing times M during the image capturing period Dt as a correction coefficient through the following formula 3.
Vave=L/Dt (2)
M=Dt/T (3)
In step S5, the surface property detection unit 204 starts image capturing of the recording sheet 120 at the image capturing start timing determined in step S2, and executes image capturing a plurality of times until the image capturing end timing determined in step S2 (NO in step S5). In step S5, when the image capturing is ended (YES in step S5), the processing proceeds to step S6. In step S6, the control unit 200 calculates a parallel difference integration value C_int from the captured surface image as the feature quantity. Then, the control unit 200 normalizes the parallel difference integration value C_int by the reference number of image capturing times N set in step S1 and the number of image capturing times M acquired in step S4. The normalized parallel difference integration value Crev is calculated by the following formula 4.
Crev=C_int×(N/M) (4)
In step S7, the control unit 200 determines the type of the recording sheet 120 based on the normalized parallel difference integration value Crev acquired in step S6 and the average speed Vave calculated in step S4. The type of the recording sheet 120 can be determined by the determination table illustrated in
In addition, in a case where an image is formed on the first recording sheet 120, the parameters are uniquely determined in steps S2 to S4 based on the distance between the surface property detection unit 204 and the stop position P on the conveyance path, the maximum processing speed Vmax, and a deceleration degree of the motor 206. Accordingly, the above operation may be executed by using preset parameters stored in the ROM based on the configuration of the printer 100. For example, the operation may be executed by using a preset average speed Vave stored in advance in the ROM based on the configuration of the printer 100.
On the other hand, in a case where images are formed on the second and the subsequent recording sheets 120, a timing at which a leading end of the recording sheet 120 is detected by the registration sensor 116 is different at each time. Accordingly, the profile generation unit 207 has to generate the speed profile information with respect to each of the second and the subsequent recording sheets 120. In other words, in steps S2 to S4, the control unit 200 has to calculate various parameters with respect to each of the second and the subsequent recording sheets 120.
As described above, according to the present exemplary embodiment, it is possible to provide an image forming apparatus capable of forming a high-quality image by determining an image forming condition according to a surface state of a recording material without executing a complicated detection operation even in a case where a speed of the recording material is accelerated or decelerated. Further, a shortening of the FPOT and an improvement in productivity of the second and the subsequent recording materials can be expected, and an image capturing range can be widened.
As illustrated in
Further, in the above-described exemplary embodiment, although the detection unit 210 is fixedly mounted on the printer 100, the detection unit 210 may be detachably mounted to the printer 100. If the detection unit 210 is detachably mounted thereon, for example, a user can easily replace the detection unit 210 when any trouble has occurred therein. Alternatively, the detection unit 210 may be simply and additionally mountable to the printer 100.
Further, in the above-described exemplary embodiment, the detection unit 210 and the control unit 200 may be integrated into a recording material determination apparatus and detachably mounted on the printer 100. As described above, if the detection unit 210 and the control unit 200 can be replaced integrally, the user can easily replace the detection unit 210 with a detection unit having a new function when a function thereof is updated or added. Further, the detection unit 210 and the control unit 200 may be simply integrated so as to be additionally mountable on the printer 100.
Further, in the above-described exemplary embodiment, although a laser beam printer has been described as an example, the image forming apparatus to which the present invention is applied is not limited thereto, and thus the image forming apparatus may be a printer of another printing system such as an inkjet printer, or may be a copying machine.
While exemplary embodiments have been described, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
Number | Date | Country | Kind |
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2015-234285 | Nov 2015 | JP | national |
The present application is a continuation of U.S. patent application Ser. No. 15/360,804, filed on Nov. 23, 2016, which claims priority from Japanese Patent Application No. 2015-234285 filed Nov. 30, 2015, which is hereby incorporated by reference herein in its entirety.
Number | Name | Date | Kind |
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20080175606 | Okada | Jul 2008 | A1 |
20140056630 | Kanno | Feb 2014 | A1 |
Number | Date | Country |
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2013179532 | Sep 2013 | JP |
Entry |
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JP-2013179532-A, Machine Translation, Komiya, Japan, 2013. |
Number | Date | Country | |
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20190377280 A1 | Dec 2019 | US |
Number | Date | Country | |
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Parent | 15360804 | Nov 2016 | US |
Child | 16548186 | US |