This invention relates to an image forming apparatus, such as a printer, facsimile, copier, and the like, that forms images by use of an electrophotographic method to develop electrostatic latent images with colored particles (toner), and to a method for detecting the detection characteristics of an optical reflection density sensor which is used in the image forming apparatus.
In the electrophotographic image forming field of copiers and laser printers, to stabilize the supply of toner to developers (replacement of developers) and the formation of images, the image forming apparatus forms a reference test pattern for controlling the image forming conditions on a photosensitive element or an intermediate transfer element under a preset operating condition, detects the quantity of toner on the test pattern, controls the supply of toner to the developer or the image forming condition (such as the charging potential, the exposure intensity, and the developing bias on the photosensitive element) and thus controls the quality of the recorded image.
In the steps of detecting the quantity of toner on the test pattern and controlling the image forming conditions, it is important that the detection characteristics of the optical reflection density sensor are stable with time. However, the detection characteristics of the optical reflection density sensor in actual use tend to deteriorate because of time-lapse deterioration of the light emitting diode (LED) that is used as is a light source for illuminating the test pattern and the light receiving photo diode (PD) that is used as a detection element and because of time-lapse contamination of the optical system. To suppress this influence, the detection characteristics of the optical reflection density sensor must be detected before the quantity of attached toner is detected.
One of the known methods for detecting the detection characteristics of the optical reflection density sensor is disclosed in Japanese Application Patent Laid-open Publication Hei 07-225501. Using a calibration reflector as a reference, this method detects the intensity of light reflected by the reflector and effects control to keep the result of detection at a preset value.
Another known detecting method is disclosed in Japanese Application Patent Laid-open Publication Hei 01-197777. Using a reflection density sensor having a characteristic in which the detection output is reduced as more toner attaches, this method forms a high-density test pattern toner image containing 1.5 to 3 times the usual quantity of toner attachment on the toner retainer by increasing the developing bias, detects the quantity of toner attached to the test pattern toner image and corrects the detection output.
Among the conventional methods for detecting the detection characteristics of an optical reflection density sensor, the detection method using a reference calibration reflector requires a driving mechanism for retracting the calibration reflector when the characteristic detection is not being implemented. This increases the required amount of mounting space and the number of parts. Therefore, it is hard to apply this method to a small inexpensive image forming apparatus.
Further, the method which uses a high-density test pattern toner image cannot detect such a high-density test pattern toner image when the high-density test pattern toner image cannot be formed by increasing the developing bias. This decreases the control precision. As one of the reasons why a high-density test pattern image cannot be formed, we can assume that this is due to deterioration of the developing ability of the developers that form the test pattern toner image.
An object of this invention is to provide a method of detecting the detection characteristics of a high-precision optical reflection density sensor of the type that is suitably applicable to a small inexpensive image forming apparatus and an image forming apparatus using this characteristics detecting method.
In more detail, according to this invention, a test pattern toner image of sufficiently high density is formed and high-precision characteristic detection of the optical reflection density sensor is enabled without using a calibration reflector that must be moved for service and for retraction.
This invention relates to an image forming apparatus comprising an image retainer, a charger, an exposure unit, a plurality of developers, an optical reflection density sensor, and a controller that is designed to control the image retainer, the charger, the exposure unit, and the developers under a preset reference image forming condition to electrophotographically form a reference test-pattern toner image for controlling the image forming condition on the image retainer, to detect the quantity of toner attached to the reference test-pattern toner image (for controlling the image forming condition) from the detection output of the reflection density sensor, and to use the result of detection for control of the succeeding image forming condition. The controller is configured to electrophotographically form a test-pattern toner image for detecting the detection characteristics of the reflection density sensor on the image retainer, to detect the detection characteristics of the reflection density sensor from the detection output of the reflection density sensor that detects the quantity of toner attached to the test pattern toner image (for detecting the detection characteristics of the reflection density sensor), and to calibrate the detection output characteristics of the reflection density sensor according to the result of detection. The controller also is configured to control the image retainer, the charger, the exposure unit, and the developers to form a test-pattern toner image for detecting detection characteristics of the reflection density sensor by superimposing multiple toner images formed by the developers.
The reflection density sensor further comprises a light source which emits invisible light and an element for detecting the invisible light, and the developers are configured to form a color toner image.
One of the developers contains black toner, and the controller effects control to form a black toner image on the top of the toner layers of the test-pattern toner image for calibration of the reflection density detection characteristics.
A method is used for detecting the detection characteristics of a reflection density sensor in an image forming apparatus comprising an image retainer, a charger, an exposure unit, a plurality of developers, an optical reflection density sensor, and a controller that is designed to control the image retainer, the charger, the exposure unit, and the developers to electrophotographically form a test-pattern toner image for detecting the detection characteristics of a reflection density sensor on the image retainer under a preset reference image forming condition, to detect the detection characteristics of the reflection density sensor in accordance with the detection output of the reflection density sensor that detects the quantity of toner attached to the test-pattern toner image (for detecting the detection characteristics of the reflection density sensor), and to calibrate the detection output characteristics of the reflection density sensor from the result of detection. The controller controls the image retainer, the charger, the exposure unit, and the developers to form a test-pattern toner image for detecting the detection characteristics of the reflection density sensor by superimposing multiple toner images formed by the developers.
The reflection density sensor consists of a light source which emits invisible light and an element for detecting the invisible light, and the developers are configured to form a color toner image.
The controller effects control to form a black toner image on the top of the toner layers of the test-pattern toner image for detecting the detection characteristics of the reflection density sensor.
In accordance with this invention, a test-pattern toner image for detection (calibration) of the detection output characteristics of an optical reflection density sensor is produced by superimposing toner images that have been developed by a plurality of developers into an image formed of multiple toner image layers. With this, the image forming apparatus of this invention can obtain toner images having the required quantity of toner. Therefore, this invention can provide a method for detecting the detection characteristics of an optical reflection density sensor that is suitably applicable to a small and inexpensive image forming apparatus and an image forming apparatus using this detection characteristics detecting method.
The image forming apparatus of this invention consists of an image retainer, a charger, an exposure unit, a plurality of developers, an optical reflection density sensor, and a controller. The controller is designed to control the image retainer, the charger, the exposure unit, and the developers under a preset reference image forming condition to electrophotographically form a reference test-pattern toner image for controlling the image forming condition on the image retainer, to detect the quantity of toner attached to the resulting test-pattern toner image from the detection output of the reflection density sensor, and to use the result of detection for control of the succeeding image forming condition. Further, the controller is designed to control the image retainer, the charger, the exposure unit, and the developers to electrophotographically form a test-pattern toner image for detecting the detection characteristics of the reflection density sensor on the image retainer, to detect the detection characteristics of the reflection density sensor from the detection output of the reflection density sensor that detects the quantity of toner attached to the test pattern toner image (for detecting the detection characteristics of the reflection density sensor), and to calibrate the detection output characteristics of the reflection density sensor in accordance with the result of detection.
The reflection density sensor consists of a light source which emits invisible light and an element for detecting the invisible light. The developers are configured to form a color toner image. The controller controls the image retainer, the charger, the exposure unit, and the developers to form a test-pattern toner image for detecting the detection characteristics of the reflection density sensor by superimposing multiple toner images formed by developers.
[Embodiment 1]
In
In this embodiment 1, the intermediate transfer drum 7 operates as an image retainer.
The color developer 6 is a dry developer containing powder toner as color particles. Developers 6a, 6b, 6c, and 6d respectively carry yellow, magenta, cyan, and black toners in this order. Each of the developers 6a, 6b, 6c, and 6d is usually retracted away from the endless photosensitive belt 2. When a latent image of a color on the endless photosensitive belt 2 comes to the developing position, the developer for that color moves toward the developing position to develop the latent image.
As shown in
To implement this electrophotographic process, the driving circuit 203 performs the drive control as explained below.
The driving circuit 203 performs the steps of controlling the main driving motor 21 to rotate the endless photosensitive belt 2 and the intermediate transfer drum 7, causing the charger 4 to evenly charge the surface of the endless photosensitive belt 2, controlling the laser exposure 5 to expose the surface of the endless photosensitive belt 2 according to the recording image information and to form an electrostatic latent image of a selected color toner color, selectively causing a color developer 6 (6a to 6d) containing toner of a color corresponding to the color of the latent image formed on the surface of the endless photosensitive belt 2 to develop the latent image into a toner image, and transferring the toner image from the endless photosensitive belt 2 to the intermediate transfer drum 7 in the area between the guide rollers 3c and 3d. In the recording of a color image, the controller keeps the transfer roller 13 and the drum cleaner 17 in a retracted state, forms toner images of colors in sequence on the endless photosensitive belt 2 and transfers the toner images from the endless photosensitive belt 2 onto the surface of the intermediate transfer drum 7 to form a single multi-color image on the drum 7.
After a toner image of the required colors is formed on the intermediate transfer drum 7, the driving circuit 203 further operates to drive the feed roller 11 to take out a recording sheet 10 from inside the paper feed tray 9, transports the sheet 10 toward the toner image transfer position 7a so that the sheet 10 reaches a position where it can receive the toner image on the intermediate transfer drum 7, moves the transfer roller 13 to press the sheet 10 against the intermediate transfer drum 7 when the sheet 10 touches the surface of the intermediate transfer drum 7 at the toner image transfer position 7a, and causes the transfer roller 13 to generate a transferring electric field. With this, the color toner image is transferred from the intermediate transfer drum 7 to the sheet 10.
Another transferring method, such as a pressure-transfer method and a corona transfer method, can be used to transfer a color toner image from the intermediate transfer drum 7 to the sheet 10. After the toner image is transferred onto the sheet 10, the drum cleaner 17 is moved toward the drum 7 to remove the left-over toner from the drum surface.
After passing through the toner image transfer position 7a, the sheet 10 on which the image has been transferred separates from the intermediate transfer drum 7 and enters the fixer 14. The fixer 14 heats the sheet 10 and the toner image on the sheet 10 to fix the toner image and ejects the fixed sheet to the outside of the image forming apparatus.
Prior to the implementation of this electrophotographic process to form images, the image forming apparatus 1 forms a test-pattern toner image 19 for controlling the image forming condition on the intermediate transfer drum 7 by a similar electrophotographic process. The controller 20 detects the quantity of toner on the test-pattern toner image 19 using the reflection density sensor 18, and it controls the image forming condition for image recording as a result of this detection. In other words, the controller implements the control processing by detecting the detection characteristics of the reflection density sensor 18 and calibrating the detection output characteristic of the reflection density sensor so that the quantity of the attached toner may be detected at a high precision from the detection output of the reflection density sensor 18. Here, “calibration of the detection output characteristics” includes “adjusting the reflection density sensor 18 to output exact detection output signals,” “converting the detection output signal from the reflection density sensor 18 into an exact detection output signal by multiplying it by a coefficient,” and “changing a coefficient for controlling the image forming condition by the detection output signal output from the reflection density sensor 18.”
Calibration of the detection output characteristics of the optical reflection density sensor 18 will be explained below. The optical reflection density sensor 18 consists of a light emitting diode LED (not shown in the figure), which emits invisible light and illuminates a test-pattern toner image 19, and a photo detector (PD), which is an element used to detect the invisible light reflected on the test-pattern toner image 19. The sensor 18 is provided at a position located opposite to the path of the test-pattern toner image 19, which is formed on the intermediate transfer drum 7 and which moves together with the drum 7. The light-receiving sensitivity (detection output characteristics) of the PD of the reflection density sensor can be controlled by adjusting the current fed to the LED.
The controller 20 determines a required current of the LED sufficient to illuminate the intermediate transfer drum 7, actuates the reflection density sensor with this LED current, and obtains a detection output signal of light reflected on the surface of the intermediate transfer drum 7.
Then, the controller 20 implements the electrophotographic process, forms an electrostatic latent image of the test-pattern for detecting the detection characteristics of the reflection density sensor on the photosensitive endless belt, develops this electrostatic latent image, transfers the formed toner image onto the surface of the intermediate transfer drum 7, and forms a test-pattern toner image 19 for detecting the detection characteristics of the reflection density sensor.
The test pattern toner image 19 consists of multiple toner layers corresponding to superimposed toner images of a plurality of colors (to be explained later). When the test pattern toner image 19 moves to a location just opposite the reflection density sensor 18, the controller receives a detection output signal from the reflection density sensor 18. This detection signal is used for calibration as follows.
One of the methods for calibrating the detection characteristics is to control the current supplied to the LED to produce a detection output signal of light reflected on the test pattern toner image 19 (for detecting the detection characteristics of the reflection density sensor) which is equal to a preset value.
Another method is to calculate a difference (error rate “a”) between a preset value to be output from the reflection density sensor 18 (opposite to the test pattern toner image 19) and a detection output signal which is actually output from the reflection density sensor 18 when the toner image 19 moves to a location just opposite the reflection density sensor, and to compute the error rate “a” for the succeeding detection output signal.
In this case, the error rate “a” is expressed by:
“a”=Vmark/Vmes
where Vmark is a value output from the reflection density sensor 18 located opposite to the test pattern toner image 19 (for detecting the detection characteristics of the reflection density sensor), and Vmes is a value of the actual output detection output signal.
The detection output signal value V after calibration is expressed by:
V=Voutדa”
where Vout is the value of the detection output signal of the reflection density sensor 18.
Still another method is to use a detection output signal of light reflected on a blank area having no toner image on the intermediate transfer drum 7 in addition to the above-described calibration method. This calibration method calibrates the LED current of the reflection density sensor 18 and causes the reflection density sensor 18 to re-detect light reflected on a blank area having no toner image on the intermediate transfer drum 7. This detected value is Vbase.
The calibration of the detection output signal uses a ratio of a preset value Vmark (output from the reflection density sensor 18 at a location opposite to the test pattern toner image 19 for detecting the detection characteristics of the reflection density sensor) to the detection output value Vbase obtained from the blank area of the intermediate transfer drum 7. The value V of the detection output signal after calibration is expressed by:
V=(Vout−Vbase)/(Vmark−Vbase)
After calibrating the reflection density sensor 18, this method forms a test-pattern toner image 19 for controlling the image forming condition under the developing and transferring conditions required to control the image density. Then, this method detects the quantity of the attached toner from the detection output signal of the reflection density sensor and determines the image forming conditions for image recording according to the result of detection.
Next, we will explain the test-pattern toner image 19 which is used for detecting the detection characteristics of the reflection density sensor 18 for calibration of the sensor 18. This test-pattern toner image 19 is required to have much more toner than the test pattern toner image 19 (for detecting the detection characteristics of the reflection density sensor) which is used to control the image density (image forming condition) of recorded images.
So, in order to reliably form a test pattern toner image 19 (for detecting the detection characteristics of the reflection density sensor) having enough toner, we prepared the test pattern toner image 19 for this embodiment by adjusting the development parameters to make a single toner layer contain more toner than usual (e.g. by increasing the developing bias, reducing the processing speed, or increasing the toner supply) and superimposing two or more of such toner images.
Here, we will explain a method of reliably forming a test pattern toner image 19 (for detecting the detection characteristics of the reflection density sensor) whose toner quantity is stable.
When black toner is used to form such a test pattern toner image (for detecting the detection characteristics of the reflection density sensor), the toner image formed of black toner must be placed on the top of the multi-layer color image.
As explained above, by preparing a test pattern toner image 19 (for detecting the detection characteristics of the reflection density sensor) by superimposing toner images of different colors, we can prevent a reduction in the quantity of attached toner when the developers 6a to 6c fall in their developing abilities and further correct uneven toner consumption of the developers 6a to 6c.
The developers 6a to 6c that are actually used to form a test pattern toner image 19 (for detecting the detection characteristics of the reflection density sensor) should preferably be controlled individually according to detection signals from their toner quantity indicators (not shown in the figure) that are provided as a standard.
When a developer whose toner supply is very little (indicated “Almost empty” or “Empty” by its toner quantity indicator) is used to develop an electrostatic latent image for formation of a test pattern toner image 19 (for detecting the detection characteristics of the reflection density sensor), the toner image 19 may have insufficient toner. In such a case, we can form a stable toner image having enough toner by using only developers storing enough toner, instead of using developers whose toner quantity indicators indicate “Almost empty” or “Empty”, and developing an electrostatic latent image for formation of a test pattern toner image 19 (for detecting the detection characteristics of the reflection density sensor).
When an image is to be formed with three toner-image layers, toner image layers of three colors are basically used and arranged in an order in which the developers 6a to 6c can develop and superimpose toner images efficiently. If one of the developers 6a to 6c is almost empty, we use two non-empty developers once and one of these non-empty developers once more to form the three toner-image layers without using the almost-empty developer. If two of the developers 6a to 6c are almost empty, we use the remaining non-empty developer three times to form the three toner-image layers without using the almost-empty developers.
When an image is to be formed with two toner-image layers, we use two developers 6a to 6c whose colors are stable with time and environmental change to form the two toner image layers. If one of the selected developers is almost empty, we use two non-empty developers to form the two toner-image layers. If the two selected developers are almost empty, we use the remaining non-empty developer twice to form the two toner-image layers in a manner similar to the formation of a three-layer image.
[Embodiment 2]
The image forming apparatus 1 of
In other words, the image forming apparatus 1 has a plurality of photosensitive drums 2a to 2d. Each photosensitive drum (2a to 2d) has a charger (4a to 4d) that evenly charges the surface of the respective photosensitive drum, a laser exposure unit (5a to 5d) that exposes the evenly-charged photosensitive drum (2a to 2d) to form an electrostatic latent image in the form of a recording image or a test pattern image thereon, and a color developer (6a to 6d) that develops the electrostatic latent image into a visible toner image on the surface of the photosensitive drum (2a to 2d). These photosensitive drums 2a to 2d are disposed almost linearly along one run of the intermediate transfer belt 7. The intermediate transfer belt 7 is well tensioned by the guide rollers 22a to 22c provided in the internal side of the belt 7 so as to move in contact with the photosensitive drums 2a to 2d. In this configuration, toner images respectively formed on the photosensitive drums 2a to 2d are transferred to the intermediate transfer belt 7. After the toner images are transferred from the photosensitive drums 2a to 2d to the intermediate transfer belt, the left-over toner on each photosensitive drum (2a to 2d) is removed by the drum cleaner (8a to 8d). The paper feeding mechanism for feeding recording sheets 10 is similar to that of
The color developer 6 is a dry developer using powder toner as color particles. Developers 6a, 6b, 6c, and 6d respectively use yellow, magenta, cyan, and black toners in this order.
The controller 20 is configured similarly to the Embodiment of
The controller 20 performs the steps of evenly charging the surfaces of the photosensitive drums 2a to 2d by means of the chargers 4a to 4d after the drum surfaces are cleaned by the drum cleaners 8a to 8d, exposing the surfaces of the photosensitive drums 2a to 2d by the laser exposure units 5a to 5d according to image information to form electrostatic latent images of relevant colors, and developing the latent images of the colors on the photosensitive drums 2a to 2d by developers 6a to 6d into toner images of relevant colors. The controller 20 performs these steps independently and in parallel for each color. The toner images of relevant colors are transferred onto the intermediate transfer belt 7 sequentially in the order of the arrangement of the developers 6a to 6d to form a multi-color toner image on the intermediate transfer belt 7.
The multi-color toner image on the intermediate transfer belt 7 is transferred to a recording sheet which is taken up and delivered from the paper feed tray 9, heated and fixed to the sheet by the fixer 14. The fixed sheet is ejected out of the image forming apparatus.
During image recording, the belt cleaner 17 is in contact with the intermediate transfer belt 7 to clean the belt (to remove left-over toner and contaminants). However, when the detection characteristics of the reflection density sensor 18 are detected, or when an image forming condition is set (to control the image density) for image recording, the belt cleaner 17 is retracted away from the intermediate transfer belt 7 so as not to disturb the reference test pattern image for controlling the image forming condition or the test pattern image for detecting the detection characteristics of the reflection density sensor on the intermediate transfer belt 7. The detection characteristics of the reflection density sensor are detected in a manner similar to that of Embodiment 1.
Since the image forming apparatus 1 of Embodiment 2 forms toner-image layers of different colors, the time required to form a three-color toner image can be reduced to one third of the time period required to prepare three toner images individually and superimpose them into one three-color image.
The image forming apparatus 1 of Embodiment 2 has the same effect as that of Embodiment 1.
[Embodiment 3]
The image forming apparatus 1 of
The color developer 6 is a dry developer using powder toner as color particles. The developers 6a, 6b, 6c, and 6d respectively use yellow, magenta, cyan, and black toners in this order.
The controller 20 is configured similarly to that of the Embodiment of
The controller 20 performs the steps of moving the endless photosensitive belt 2, cleaning the endless photosensitive belt 2 by use of the belt cleaner 24, retracting the belt cleaner 24 away from the endless photosensitive belt 2, evenly charging the surface of the endless photosensitive belt 2 by use of the charger 4, exposing the surface of the endless photosensitive belt 2 by means of the laser exposure unit 5 according to image information to form an electrostatic latent image of a first color (e.g. yellow), moving the developer 6a of the color (e.g. yellow) to develop the yellow toner image on the endless photosensitive belt 2, and repeating these steps to respectively form toner images of the other colors on the yellow toner image on the endless photosensitive belt 2.
The multi-color toner image on the endless photosensitive belt 2 is transferred to a recording sheet 10, which is transported up and delivered from the paper feed tray 9, heated and fixed to the sheet by the fixer 14. The fixed sheet is ejected out of the image forming apparatus.
The belt cleaner 24 is moved so as to be in contact with the belt cleaner 24 to remove toner left on the endless photosensitive belt 2 after the toner image is transferred to the recording sheet 10.
When the detection characteristics of the reflection density sensor 18 are detected, or when an image forming condition is set (to control the image density) for image recording, the reference test pattern image for controlling the image forming condition or the test pattern image for detecting the detection characteristics of the reflection density sensor is formed in a similar manner. The detection characteristics of the reflection density sensor 18 are detected also in a manner similar to that of Embodiment 1.
The image forming apparatus 1 of Embodiment 3 has the same effect as that of Embodiment 1.
Although the image forming apparatus of each embodiment employs a dry electrophotographic method, this invention is applicable to an image forming apparatus using a wet electrophotographic method as well.
Number | Date | Country | Kind |
---|---|---|---|
2003-282989 | Jul 2003 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5103260 | Tompkins et al. | Apr 1992 | A |
5122835 | Rushing et al. | Jun 1992 | A |
Number | Date | Country |
---|---|---|
1-197777 | Aug 1989 | JP |
7-225501 | Aug 1995 | JP |
Number | Date | Country | |
---|---|---|---|
20050025510 A1 | Feb 2005 | US |