This application claims priority under 35 U.S.C 119 from Japanese Patent Application No. 2008-081765 filed Mar. 26, 2008.
1. Technical Field
The present invention relates to an image forming apparatus and an image forming method.
2. Related Art
In ordinary electrophotographic image forming apparatuses, typified by copying machines and laser printers, toner images are formed on the surface of an image carrier (photoreceptor drum or the like) in a charging process, an exposure process, and a developing process. These toner images are then transferred and fixed onto a member to be transferred in a transfer process and a fixing process. Any developer or the like that remains on the surface of the image carrier after the transfer process is removed (cleaned) in a cleaning process.
An aspect of the present invention is an image forming apparatus including: a rotatable image carrier; a charging unit that contacts a surface of the image carrier and charges the surface of the image carrier; an exposing unit that exposes the surface of the image carrier and forms a latent image; a developing unit that develops the latent image formed on the surface of the image carrier with a developer; a transfer unit that transfers a developed toner image onto a transfer receiving member; a cleaning unit that is provided with: a plate shaped cleaning member having a free end that faces upward, a corner portion of the free end contacting the surface of the image carrier, the cleaning member cleaning off developer remaining on the surface of the image carrier after transfer by the transfer unit, and a developer pooling member provided between the cleaning member and the transfer unit, that temporarily pools the cleaned off developer at the free end of the cleaning member; and a friction coefficient reducing unit that reduces a friction coefficient at the surface of the image carrier and that reduces the coefficient of friction during a non-image forming period to less than a coefficient of friction during an image forming period.
Exemplary embodiments of the present invention will be described in detail based on the following figures wherein:
Explanation will now be given of a first exemplary embodiment of the image forming apparatus of the present invention, with reference to the figures.
The image forming units 10 in the present exemplary embodiment correspond to color image forming, the image forming units 10Y, 10M, 10C, and 10K are provided respectively forming toner images corresponding to four colors, Yellow (Y), Magenta (M), Cyan (C), and Black (K). When it is necessary to discriminate Y, M, C, K below then the labels Y, M, C, and K will be given in the explanation, but when discrimination is not required the labels Y, M, C, and K will be omitted.
Each of the image forming units 10 (it should be noted that the configuration of each of the image forming units 10 are similar, and so the suffixes denoting the color of the units are omitted in the explanation) is provided with a photoreceptor drum 12 serving as an example of an image carrier (referred to below simply as photoreceptor 12). The photoreceptor 12 rotates at a specific speed in the direction of arrow F while contacting the intermediate transfer belt 30.
There is a contact type charger (charging roll) 13 provided at the periphery of the photoreceptor 12, as shown in
An exposing unit 14 is provided downstream in the rotation direction F of the photoreceptor 12 from the charging roll 13. The exposing unit 14 is configured with an LED array in which plural LEDs (Light Emitting Diodes) are arranged, and the exposing unit 14 irradiates a light beam L which is modulated with image data onto the photoreceptor surface 12A that has been uniformly charged by the charging roll 13. As the result, a latent electrostatic image is thereby formed on the photoreceptor surface 12A.
A developing unit 15 is provided downstream in the rotation direction F of the photoreceptor 12 from the exposing unit 14. The developing unit 15 stores a developer that includes negative charged toner, and a lubricant (for example zinc stearate or the like) charged with the opposite polarity to the toner (i.e. positive). There is a developing roll 18 provided in the developing unit 15 for supplying developer onto the photoreceptor surface 12A. The latent electrostatic image formed on the photoreceptor surface 12A is developed by the developer being supplied from the developing unit 15, thereby forming a toner image.
A transfer roll 16 is provided downstream in the rotation direction F of the photoreceptor 12 from the developing unit 15. A voltage of the opposite polarity to that of the toner is applied to the transfer roll 16, and the toner on the photoreceptor surface 12A is transferred onto the intermediate transfer belt 30.
Toner images each of different colors that have been formed on each of the image forming units 10 are respectively transferred onto the intermediate transfer belt 30 so as to be superimposed on each other. A color toner image is thereby formed on the intermediate transfer belt 30.
There is an eraser lamp 170 provided downstream in the rotation direction F of the photoreceptor 12 from the transfer roll 16. The eraser lamp 170 is provided for erasing charge from the photoreceptor surface 12A. The photoreceptor surface 12A after the toner image has been transferred is irradiated from the eraser lamp 170, and erasing charge is carried out on the photoreceptor surface 12A by the light.
There is a cleaning device 40 (cleaning unit), which is provided with a cleaning blade 42 (referred to below as blade 42), provided downstream in the rotation direction F of the photoreceptor 12 from the transfer roll 16. The cleaning device 40 is for cleaning residual toner that was not transferred onto the intermediate transfer belt 30 by the transfer roll 16 and has remained on the photoreceptor surface 12A and, and for cleaning electrical discharge generated substance that is generated during electrical discharge and adheres to the photoreceptor surface 12A. The residual toner and electrical discharge generated substance on the photoreceptor surface 12A is cleaned off by the cleaning device 40.
There is a transfer device 38 provided downstream in the conveying direction E of the intermediate transfer belt 30 from the four image forming units 10. The transfer device 38 is an example of a transfer unit and includes two opposing rollers 34 and 36. The toner image formed on the intermediate transfer belt 30 is transported between the rollers 34 and 36, the toner image on the intermediate transfer belt 30 is transferred onto paper P that is also transported between the rollers 34 and 36 from a paper tray 39 provided in the image forming apparatus 150.
There is a fixing device 31, including a pressure roller 37 and a heat roller 35, provided as a fixing unit on the transporting path of the paper P. The paper P transported into the fixing device 31 is nipped and transported by the pressure roller 37 and the heat roller 35, and the toner on the paper P is fused and fixed to the paper P. The desired image is thereby formed on the paper P. The paper P on which the image is formed is then discharged from the image forming apparatus 150.
There is a belt cleaning device 33 for the intermediate transfer belt disposed on the intermediate transfer belt 30. Toner remaining on the intermediate transfer belt 30, which was not transferred onto paper P by the transfer device 38, is collected by the belt cleaning device 33.
(Cleaning Device)
A detailed explanation will now be given of the cleaning device 40. There is, as shown in
The width of the blade 42 (the dimension along the rotational axial direction of the photoreceptor drum 12) is set to be the width of the image forming region of the photoreceptor surface 12A (the dimension along the rotational axial direction of the photoreceptor drum 12), or a greater width. Consequently the residual toner and electrical discharge generated substance from the image forming region of the photoreceptor surface 12A is separated by the blade 42 and cleaned off from the photoreceptor surface 12A.
The front face of the blade plate 48 (the face on the photoreceptor drum 12 side) in one end side joins together with the back face of the blade 42 (the face on the opposite side to that of the photoreceptor drum 12), and the back face of the blade plate 48 in the other end side is fixed, with screws or other fastening, to one piece of the fixing 46.
As shown in
When the amount of toner pooled within the toner pooling region TP exceeds a particular amount, as shown in
An opening may be provided in the toner pooling sheet 52, such that the toner within the toner pooling region TP can be discharged to within the housing 41 through the opening. The compacted state of toner within the toner pooling region TP may be relieved by separation of the back face 48U from the lower edge portion 52D and by the opening.
The toner discharged from within the toner pooling region TP to inside the housing 41 is pushed in one direction side within the housing 41 by a conveying member 49, which includes spiral vanes, provided within the housing 41 and serving as a conveying member, and the toner is discharged from a non-illustrated outlet to be conveyed to a separately provided toner collection device.
(Controller)
The image forming apparatus 150 is provided with a controller 151 for controlling each device therein, as shown in
The controller 151 controls the charging power source 152 of the image forming apparatus 150 in accordance with the flow chart shown in
(Operation During Image Forming)
When it is determined to be an image forming time (Y) at step 106, the routine proceeds to step 108, and a control current value α is derived from the alternating current shoulder current value K multiplied by a multiplier ratio (extra ratio) m. The routine then proceeds to step 112, and control is carried out such that the alternating current value of the oscillating voltage of the charging power source 152 becomes the control current value α. It should be noted that since the multiplier ratio m is a value that changes depending on the thickness of the photoreceptor drum 12, the environmental conditions (temperature, humidity) within the image forming apparatus 150, and the specification of the charging roll 13 (resistance value) and the like, preferable values for the ratio for the various conditions are determined by experimentation in advance, and the optimum value of the ratio is chosen according to the various conditions when the image forming apparatus 150 is used.
(Operation During Non-Image Forming)
When determination at step 106 is that it is a non-image forming time (N), the routine proceeds to step 110, and the control current value α is derived from the alternating current shoulder current value K multiplied by a multiplier ratio m′. It should be noted that multiplier ratio m′ is set a value which is lower than multiplier ratio m. The routine proceeds to step 112, and control is carried out such that the alternating current value of the oscillating voltage of the charging power source 152 becomes control current value α. Consequently, the control current value α when not image forming becomes lower than the value thereof when image forming, in other words, since the alternating current value of the oscillating voltage that the charging power source 152 applies to the charging roll 13 when not image forming is lower than that when image forming, the electrical discharge stress received by the photoreceptor surface 12A also becomes lower when not image forming than when image forming. The coefficient of friction of the photoreceptor surface 12A is thereby less when not image forming than when image forming. The multiplier ratio m is preferably within the range of 1.2 to 1.4, and in the present exemplary embodiment the multiplier ratio m is set to 1.28. If the multiplier ratio m is 1.28 then the multiplier ratio m′ is preferably set to 1.13 (a value 15% lower than multiplier ratio m). In the present exemplary embodiment operation during non-image forming is executed in the interval between formation of one image and formation of another image when carrying out successive image forming, and the interval between formation of one image and formation of another image is determined by detecting the edge of sheet of paper by a non illustrated sensor.
(Shoulder Current Value Detection)
The shoulder current value detection mentioned above is, specifically, performed by increasing or decreasing (varying) the alternating current value of the oscillating voltage (AC+DC voltage), with a state in which the direct current voltage component of the oscillating voltage (AC+DC voltage) applied to the charging roll 13 by the charging power source 152 is held constant (DC voltage constant), the direct current component of the charging roll 13 at this time is detected by the direct current detector 153, the alternating current value at a point k is derived, (see
(Operation during Later-Rotation)
After the image forming operation is complete, as shown in the timing chart in
Note that a period “prior to rotation” of the image carrier is from when a image forming start signal is received up until image forming starts, and a period “later rotation” of the image carrier is from completion of image forming operation up until the next image forming start signal is received.
The motor power source 160 for applying voltage to the drive motor 162 of the photoreceptor drum 12, the motor power source 154 for applying voltage to the drive motor 162 of the developing roll 18, and the developer charging power source of the developing unit 15, are all controlled by the controller 151 such that the voltage application is ceased until the minus charge of the photoreceptor surface 12A disappears.
Explanation will now be given of the operation of the first exemplary embodiment of the present exemplary embodiment.
When the image forming apparatus 150 is performing successive image forming, the adherent matter (residual toner and adherent matter) adhering to the photoreceptor surface 12A is separated from the photoreceptor surface 12A by the edge 42E of the blade 42, and pools to form a toner pool within the toner pooling region TP.
By the way, in the charging roll 13 as the contact type charger, although there is less ozone generated than with a non-contact type charger (corotron or scorotron), there is a lot of electrical discharge stress to the photoreceptor surface 12A, and there is a tendency for the coefficient of friction of the photoreceptor surface 12A to readily increase. If the coefficient of friction of the photoreceptor surface 12A rises, the free end of the blade 42 is dragged along by the rotation of the photoreceptor drum 12, and the force pulling the blade 42 toward the downstream side in the rotation direction of the photoreceptor drum 12 is applied to the toner in the toner pool, thereby, the edge 42E of the blade 42 is readily pushed way from the photoreceptor surface 12A. As a result the toner pool readily bursts through (toner slips past the edge 42E of the blade 42). However, in the image forming apparatus 150 of the present exemplary embodiment, the operation during non-image forming is executed during non-image forming (in the interval between formation of one image and formation of another image) and so the state of the toner pool that is tending toward bursting through is to some extent reset (moderated), since the coefficient of friction of the photoreceptor surface 12A is reduced. So, toner slipping past the blade 42 is consequently suppressed.
When, as in the present exemplary embodiment, an upward facing free end of the blade 42 with respect to vertical is used, the toner pool formed on the top side of the free end of the blade 42 has a poor turnover of toner, and due to the effect of gravity a strong force readily acts in the direction in which the toner pool bursts through, with a tendency for the toner pool to readily burst through. Therefore, the action of resetting the state of the toner pool in the present exemplary embodiment exhibits a good effect. In contrast, if a downward facing free end of a blade with respect to vertical is used, in the toner pool formed below the free end of the blade the toner readily falls due to gravity, so, a strong pressure (force) is not readily applied in the free end of the blade in the direction in which the toner pool bursts through. Accordingly, such an action is not obtained resetting the state of the toner pool as is achieved with an upward facing blade.
In addition electrical discharge stress received by the photoreceptor surface 12A is reduced since the controller 151 sets the value for multiplying the alternating current shoulder current value K as the multiplier ratio m′ (non-image forming multiplier ratio) from the multiplier ratio m (image forming multiplier ratio), for during non-image forming (in the interval between formation of one image and formation of another image). Consequently the coefficient of friction of the photoreceptor surface 12A is reduced during the non-image forming periods. It should be noted that if the coefficient of friction of the photoreceptor surface 12A is lowered too much during image forming operation then this can lead to the required external additive (lubricant etc.) slipping through from the free end of the blade 42. Since this would worsen the cleaning ability of the blade 42, the action to lower the coefficient of friction of the photoreceptor surface 12A is preferably executed during non-image forming.
Also, application of the oscillating voltage to the charging roll 13 is ceased after stopping the eraser lamp 170 in the later-rotation period. With respect to this, even if the photoreceptor surface 12A is not being charged by the charging roll 13, the photoreceptor surface 12A still remains in a negative charged state for a while. Positive charged lubricant is supplied onto the photoreceptor surface 12A at this time by the developing roll 18. Then, the developing roll 18 is stopped, so, the coefficient of friction between the blade 42 and the photoreceptor surface 12A is lowered for the time up to when the developing roll 18 and the photoreceptor drum 12 are stopped.
In the first exemplary embodiment, the alternating shoulder current value K is set as the alternating current value at the point k when direct current value becomes constant, however, the present invention is not limited thereto. For example, a voltage detector may be provided for detecting the surface potential of the photoreceptor drum 12, the alternating current value of the oscillating voltage of the charging power source 152 is increased or decreased (varied), and the alternating current value derived at a point when the surface potential of the photoreceptor drum 12 becomes constant. This alternating current value may then be used as the alternating current shoulder current value.
In the first exemplary embodiment, the value for multiplying the alternating current shoulder current value K as the multiplier ratio m is set to the multiplier ratio m′ (operation during non-image forming) for the interval between formation of one image and formation of another image during successive image forming, however, the present invention is not necessarily limited to such a configuration. The operation during non-image forming may be executed in the period prior to rotation or in the period later rotation. Further, the operation during non-image forming may be executed during all of the period prior to rotation, the period later rotation and the period between formation of one image and formation of another image in successive image forming or the operation during non-image forming may be executed during a combination of at least of two of these periods. Obviously, performing of the operation during later-rotation of the present exemplary embodiment is not limited to at the period later rotation of the photoreceptor drum 12 and may be executed during the period between formation of one image and formation of another image in successive image forming.
Furthermore, in the above exemplary embodiment the multiplier ratio for multiplying the alternating current shoulder current value K is different during image forming and during non-image forming, however, the present invention is not necessarily limited to such a configuration; for example a coating device (not shown in the figures) for coating the photoreceptor surface 12A with a lubricant (such as zinc stearate) may be provided between the transfer roll 16 and the cleaning device 40, such that a lubricant is coated on the photoreceptor surface 12A during non-image forming, thereby lowering the coefficient of friction of the photoreceptor surface 12A during non-image forming. In such a case it would obviously not be necessary to include lubricant in the developer.
Exemplary embodiments have been given above to explain the embodiment of the present invention, however, these are only examples of exemplary embodiments, and various modifications and variations are possible without departing from the spirit of the present invention. Obviously the scope of the present invention is not limited to the exemplary embodiments.
(Test)
Explanation will next be given of tests (Comparative Examples 1 and 2, and Example 1) which are performed to confirm the improved effect of the present invention using modified three copy-printer machines (DCC 450; manufactured by FUJIXEROX). The machines that are modified are common in that the DC current value flowing to the photoreceptor drum can be monitored while the AC current of the charging power source is increased or decreased (varied). The AC current value of the DC current value saturation point can thereby be measured.
(Test Condition)
In the tests, the image patterns are set with a successive image portion and a continuous non-image portion in the photoreceptor drum rotation axial direction, and a run test is executed equivalent to 30 KPV. The amounts of abrasion (wearing) at positions in the photoreceptor drum rotation axial direction on the surface of the photoreceptor drum for the number of cycles of the photoreceptor drum are measured, giving an abrasion rate of nm/kcycle. The environment conditions (temperature and humidity) in the tests are set at high temperature and high humidity (28° C., 85% RH) in which a compacted toner state is readily generated by the pool of the toner in the toner pooling region TP above the blade end portion, with the print conditions set with the print mode for 100 successive sheets of print.
The modified machine of Comparative Example 1 is one in which a member equivalent to a dam member of the image forming apparatus of the first exemplary embodiment is removed, and the multiplier ratio is set to a constant value independent of whether operation is during image forming or during non-image forming. The charging condition of the photoreceptor drum is set such that a control current value α which is obtained by the AC current value K of the point k at which the DC current value is saturated being multiplied by a multiplier ratio of 1.28, is set as the AC current value of the oscillating voltage of the charging power source, and applied to the charging roll. Result of the test for Comparative Example 1 is shown in
In the modified machine for Comparative Example 2, in the image forming apparatus of the first exemplary embodiment, the operation during non-image forming is removed. That is, the multiplier ratio is set to a specific constant value independent of whether operation is during image forming or non-image forming. The charging conditions of the photoreceptor drum are similar to those of Comparative Example 1. The result of Comparative Example 2 is shown in
The modified machine of Example 1 is configured similar to that of the image forming apparatus of the first exemplary embodiment. The charging condition of the photoreceptor drum is set such that a control current value α is obtained by the AC current value K of the point k at which the DC current value is saturated being multiplied by a multiplier ratio of 1.28 during image forming, and a control current value α is obtained by the AC current value K of the point k at which the DC current value is saturated being multiplied by a multiplier ratio of 1.13 during non-image forming (charging condition which would generate a white spot, color spot, of about 1 mm), and each control current value α is set as the AC current value of the oscillating voltage of the charging power source, and applied to the charging roll. The result of Example 1 is shown in
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