JP2637104B2 - Image forming device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Field of Industrial Application) The present invention relates to a recording apparatus including a step of irradiating a charged recording medium with light to form an electrostatic latent image.

(Prior Art) Conventionally, this type of recording apparatus includes a drum-shaped photoconductor 700 as an image carrier, for example, as shown in FIG. Along the rotation direction shown, the charger 701, the exposure unit 702, the developing unit 703, the transfer charger 704, the peeling charger 705, the cleaner 706, and the static eliminator 7
07 are sequentially arranged, the photoreceptor 700 is uniformly charged by the charger 701, an electrostatic latent image is formed in the exposure unit 702, and the developing unit 703 visualizes the latent image with toner, which is a colored powder, and transfers the image. Charger 70
4. Transfer to a transfer member P such as plain paper in 4 and release charger 7
At step 05, the toner (transfer residual toner) 708 remaining on the photoreceptor 700 after the transfer is cleaned by the cleaner 706, the latent image is erased by the charge remover 707, and one process is completed.

However, if the untransferred toner 708 is scraped off with the blade 709 and simply collected inside the cleaner 706, the cleaner 706 becomes full of toner and usually becomes unusable after recording 2000 to 3000 sheets.

Therefore, some devices use cleaner 7 together with photoconductor 700.
06 may be discarded, but the cost of consumables will increase.In addition, frequently used devices such as printers, which cannot be used immediately for devices with high toner consumption, such as graphic images, must be replaced. I don't like it because it doesn't work.

In consideration of the above, normally, as shown in FIG. 41, a toner conveying screw called a toner collecting auger 710 is provided in the cleaner 706 so that the collected toner is sent to a toner collecting box (not shown) outside the cleaner 706. Has become.

However, since this collection box occupies a place in the apparatus, it cannot be provided with a large one, and it is not preferable because it needs to be replaced after recording several thousand sheets. Further, the toner is spilled on a part at the time of removal, and the hands, clothes, floor and the like of the exchanger may be stained.

In addition, the blade 709 of the cleaner
700 is easily scratched, OPC (Organic Photo Condacto)
r) Inexpensive and harmless but soft photoreceptor 700, such as a photoreceptor, has a very short life. Therefore, a photoreceptor such as a small-diameter drum that takes several revolutions to record one sheet will have a shorter replacement cycle. This is not desirable, and has been an obstacle to downsizing the equipment.

On the other hand, a two-rotation, one-copy (print) type in which the same apparatus is switched between a developing step and a cleaning step and a dedicated cleaning unit is eliminated has been developed, but this eliminates the trouble of discharging toner. In order to separate the developing device from the developing process and the cleaning process, the outer circumference of the photoconductor must be longer than the recording paper, and the photoconductor 700 becomes large, which has a drawback that it is a major obstacle to downsizing the apparatus.

(Problems to be Solved by the Invention) As described above, in the conventional apparatus, there are a cleaner and a waste toner box for cleaning the transfer residual toner. It is an obstacle to the development. Further, the photosensitive member is damaged by a cleaning member such as a blade, and the life of the photosensitive member is shortened. Further, the conventional type which does not require a cleaner has a problem that the size of the apparatus cannot be reduced due to an increase in the diameter of the photosensitive member, and the processing speed is slow.

The present invention has been made on the basis of the above circumstances, and its object is to reduce the diameter of the photoconductor and eliminate the need for a dedicated cleaner, thereby making it possible to reduce the size and cost of the apparatus and to reduce the cost. SUMMARY OF THE INVENTION It is an object of the present invention to provide an image processing apparatus having a long service life and capable of forming an image reliably.

[Constitution of the Invention] (Means for Solving the Problems) The present invention has been made based on the above-mentioned problems, and has a charging means for charging an image carrier rotating in a predetermined direction to a specific polarity; Exposure means for exposing the image carrier charged by the charging means to form an electrostatic latent image, and a developer for supplying a developer having the same polarity as the specific polarity to the image carrier A conveying member, and a developer remaining on an unexposed portion of the image carrier with respect to the developer conveying member is directed to the developer conveying member, and the developer is exposed on an exposed portion of the image carrier. A first voltage application unit that applies a bias voltage for generating an electric field such that the developer travels from the conveyance member, and supplies the developer from the developer conveyance member to an exposure unit of the image carrier to supply the developer. Simultaneously with visualizing the electrostatic latent image, Reversal developing type cleaning and developing means for collecting the residual developer adhering to the unexposed portion of the carrier to the developer conveying member, and a developer on the image carrier developed by the cleaning and developing means A transfer unit for transferring an image to a recording medium, on the downstream side of the transfer unit along the rotational direction of the image carrier, and on the upstream side of the charging unit,
A memory removing member provided in contact with the surface of the image carrier and disturbing a residual developer remaining on the image carrier after the transfer is performed on the recording medium by the transfer unit; For disturbing the residual developer in the member,
And a second voltage applying unit for applying a bias voltage having a polarity opposite to the specific polarity.

(Operation) In other words, according to the present invention, the developing means transfers the residual developer adhering to the unexposed portion of the image carrier toward the developer carrying member and transports the developer to the exposed portion of the image carrier. By applying a bias voltage that generates an electric field that causes the developer to travel from the member, the electrostatic latent image is developed and the residual developer is cleaned. Since there is no need to provide such a device, it is possible to reduce the size and cost of the apparatus, extend the life of the image carrier, and eliminate the need for cumbersome operations such as replacing a waste toner box, as well as to collect residual developer (toner). Since the toner is re-used, the number of times of toner replenishment is reduced, and maintenance becomes extremely easy. Furthermore, the diameter of the image carrier can be reduced, and the apparatus can be reduced in size and cost, as compared with the conventional two-rotation, one-copy (print) operation in which the same apparatus is switched between the developing step and the cleaning step.

Further, since a memory removing member is provided upstream of the charging unit and downstream of the transfer unit so as to disturb the residual colored powder remaining on the image carrier after the transfer, even if the residual colored powder exists, Clear images can be formed without leaving any images.

Embodiment An embodiment of the present invention will be described below with reference to FIGS. 1 to 38. FIG. 1 is a schematic configuration diagram of an electrophotographic recording apparatus using a semiconductor laser as an image forming apparatus of the present invention.

The recording device (Laser Page Printa) is connected to a host system (not shown), which is an external output device such as a computer or a word processor, via a transmission controller such as an interface circuit.

When a print start signal is received from the host system, an image forming operation is started, recorded on a recording medium, and outputted.

This recording apparatus has the following configuration. That is, in the figure, reference numeral 1 denotes an apparatus main body, in which a drum-shaped photosensitive member 2 as an image carrier is arranged. Around the photoreceptor 2, a pre-exposure unit 8, a charging unit 3, an exposure unit 4, a developing unit 5, a transfer unit 6, and a memory removing member 7, which will be described later, are sequentially arranged.

In the lower part of the apparatus main body 1, a sheet P as a recording medium fed from a sheet feeding cassette 9 via a sheet feeding unit 10 is transferred to an image transfer unit between the photosensitive member 2 and the transfer unit 6.
11, a paper discharge tray 12 provided on the upper surface of the apparatus main body 1.
The paper transport path 13 leading to the sheet is formed.

Further, an aligning roller pair 14 is provided on the upstream side of the image transfer section 11 of the paper transport path 13, and a fixing device is provided on the downstream side.
15 and a paper discharge roller pair 16 are arranged.

When the host system receives a print start signal, the drum-shaped photosensitive member 2 rotates and the photosensitive member 2 is rotated.
Is charged by the charging means 3. Next, the charged photosensitive body 2 is scanned and exposed to the laser beam a modulated by receiving the dot image data from the host system by using an exposing means 4 including an optical system including a polygon scanner described later. Form a latent image.

The electrostatic latent image is developed by the developing means 5 and visualized. Next, the developed image is transferred onto the sheet P conveyed from the sheet cassette 9 by using the transfer means 6, the developed image is fixed on the sheet P by the fixing device 15, and the sheet is discharged onto the discharge tray 12. ing.

Further, in the present invention, in order to simplify the conventional electrophotographic process, a reversal developing method of developing an exposed portion and a method of removing transfer residual toner simultaneously with the development are employed. At this time, the change of the surface potential of the photoconductor 2 and the state of the toners b on the photoconductor 2 are changed as shown in FIG.

That is, the photoconductor 2 is charged to minus -500 V by the charging means 3 (see FIG. 2A). At this time, the toners b... On the photoconductor 2 that have not been transferred in the previous process are also charged. At this time, the photoconductor 2 under the toner b is also charged. This is clear from the experimental results that the surface potential is maintained at 80 to 90% or more even when the toners b are removed with a urethane blade or the like.

Next, the photoreceptor 2 receives the dot image data from the host system and modulates it, as described above.
Receives the scanned laser beam a, attenuates the surface potential and forms an electrostatic latent image (see FIG. 2B). At this time, the surface potential of the exposed portion becomes -50 V (room temperature). Here, the photoreceptor 2, charging means 3, and exposure means 4 are devised as follows.

As shown in FIG. 3, the photoreceptor 2 has a charge generation layer 21 and a charge transport layer 2 on a double-sided aluminum cylinder 20 (0.8 mm thick) having an outer diameter of 30 mm.
It is applied in the order of 2.

The charge generation layer 21 is formed by applying τ-type phthalocyanine (manufactured by Toyo Ink) and butyral resin at a weight ratio of 1: 1 to a thickness of 0.1 μm. The charge transport layer 22 is made of 9-ethylcarbazole-3-carboxaldehyde-methylhydrfuzone (ECMP) (manufactured by Inui Chemicals) and polyarylate (U-100)
[Unitika] was applied at a weight ratio of 0.65 to a thickness of 17 μm. This charge transport layer 22 is transparent to visible light and a semiconductor laser, and is located above the charge generation layer 22, so that even if toner particles b of 30 μm or less exist on the surface, as shown in FIG. When the photoreceptor 2 is exposed to light 25, the shadow of the toner particles b is hardly formed on the charge generation layer 21 due to the diffracted light 26 and the reflected and scattered light 27 in the transport layer 22, or is thin enough to cause no practical problem. Can only be done in. However, when the diameter of the toner particles b is 30 μm or more, image defects occur as white spots on the solid black. In addition, the transport layer 22 can be made of any material as long as it is transparent to the exposure light source and has a carrier transport function.
For example, a material in which a pyrazoline derivative is dispersed in a polycarbonate resin, a material in which an oxadiazole derivative or an oxazole derivative is dispersed in an acrylic resin, or a material in which a triphenylmethane derivative is dispersed in a polycarbonate resin may be used. If the thickness is not larger than the average particle size of the toner b, it causes image defects. Further, as shown in FIG. 5, the thickness is preferably 30 μm or less in view of residual potential characteristics. Also,
The photoreceptor 2 basically has a charge transport layer 22 on a charge generation layer 21.
As shown in FIG. 6, a protective layer 30 and the like may be provided between the generating layer 21 and the substrate 28 on the surface of the undercoat layer 29 or the transport layer 22. As shown in FIG. 7, the photoreceptor 2 used in this embodiment has a half-exposure dose of 6.2 erg / cm ² . Here, the appropriate value of the laser light amount is determined based on the following grounds.

This process does not perform a dedicated cleaner or an independent process for cleaning, and performs electrostatic exposure and cleaning simultaneously. Therefore, image exposure is performed from above the untransferred toner existing on the photoconductor 2. Therefore, in some cases, a portion where the transfer residual toner exists may be exposed.

Normally, the half-exposure amount of the surface potential of the photosensitive member 2 (6.2 erg / c in this embodiment)
If the exposure amount is about 3 to 4 times of m ² ), the amount of light is sufficient as the latent image potential for the image (for example, 2 in FIG. 7).
4.8 erg / cm ² ), the toner b serves as a filter for a portion where a few transfer residual toners are collected, and the portion is insufficiently exposed to the photoconductor 2. In this case, when the pattern of the exposed portion is a solid pattern, even if the untransferred toner b becomes a filter and the exposure becomes insufficient, the toner b adheres so as to surround the portion at the time of development. It is buried by b and does not actually cause a problem.

However, when the exposure amount is the conventional amount, a black and white pair line of one dot width as shown in FIG. 8B (a) or a checkered pattern by every other dot exposure as shown in FIG. 8A (a). In the case of such a pattern, as shown in (b) of FIGS. 8A and 8B, the portion to be developed is chipped according to the pattern of the transfer residual toner b on the photoconductor 2, and the chipped portion of the image is
As shown by (c) in FIGS. A and B, it becomes visible as a negative pattern.

Here, it has been found through experiments that this problem can be solved by increasing the amount of laser light and lowering the potential of the photoconductor 2 even if there is a filter effect of the toner b.
In this experiment, a commercially available copier Leo Dry BD
Using a toner (T-50P) for 7815 (manufactured by Toshiba Corporation), image formation was performed while changing the laser light amount. As a result, it was necessary to expose at least five times or more the half-reduced exposure amount. It was clarified that even in OPC having a charge transport layer on the amount of generation, a dot-pattern pattern of a neka memory was generated due to the filter effect of the toner b remaining after transfer. For this reason, in this embodiment, a light amount of 42 erg / cm ² which is about seven times is used.

The charging means 3 and the transfer means 6 are composed of scorotrons as shown in FIGS. 9 and 10. 60
The surface of the μm diameter corona wire 41 is made of white tungsten so that a minus corona does not occur unevenly.

The corona wire 41 is fixed to a metal fitting 44 to which a power supply pin 43 is screwed through a tension spring 42.
The power supply pin 43 and the metal fitting 44 are fixed in a power supply terminal 45.

On the other hand, the other end of the corona wire 41 is fastened to a plastic hook 46 and fixed to a terminal 47. The terminals 45 and 47 are covered with terminal covers 48 and 49, respectively, so that high-pressure parts are not exposed.

On the other hand, the casing 50 is made of 0.3 mm
As shown in FIG. 11 and FIG. 11, the side facing the photoreceptor 2 is a mesh, and the grid of the scorotron charger is used.
Although the grid 50a is integrated with the side cases 50b and 50c, the grid 50a can maintain sufficient accuracy, such as its flatness, without using any special parts, although it has a simple structure that plays a role as 50a.

Further, since the same bias voltage is applied to both side cases 50b and 50c when corona discharge is performed (described later), the corona current flowing in both side cases 50b and 50c also decreases, and the charger has high current efficiency. Further, as will be described later, since the opening opposite to the grid 50a (the back side of the charger case) is an opening, air flow is good and ozone or the like is not generated. There are advantages such as lowering of the surface potential and occurrence of image blur.

The casing 50 is connected to the anode of the 560V Zener diode 51, and is connected to the charger guide 52 through the cathode of the Zener diode 51. on the other hand,
The charger guide 52 is connected to a ground terminal of the main body (not shown).

Therefore, when a high voltage (−5 kV) is applied to the corona wire 41 from a high-voltage transformer (not shown) of the apparatus main body through the power supply pin 43, corona discharge occurs in the casing 50, and current flows in the casing 50. Due to the rectifying characteristic of the Zener diode 51, the potential of the casing rises to -560V and is kept constant.

For this reason, the grid 50a naturally has a voltage of -560 V, so that the surface potential of the photosensitive member 2 which is 2 mm away from the grid 50a is
It is kept constant at -500 V, which is slightly lower than the potential of. In the figure, 53 is a handle of the charger, and 54 and 55 are springs.

By the way, when the discharge opening (here, the grid 50a is shown) of the charging means 3 to the photoreceptor 2 is directed sideways, obliquely, or upward as in the present embodiment, the carrier adhered to the photoreceptor 2 is covered by the casing 50. In many cases, the corona wire 41 and the casing 50 may be short-circuited.

Further, when the charging means 3 is a scorotron as in this embodiment, the carrier dropped from the photoreceptor 2 may pinch the grit 50a, causing a discharge failure and an image failure.

Therefore, in this embodiment, as shown in FIG. 12, the magnet 60 is attached to the outside of the upper side case 50b,
The carrier adhered on the upper surface was attracted to the magnet 60 to prevent the carrier from entering the casing 50.

The tip of the special magnet 60 is preferably closer to the photoconductor 2 side than the end of the side case 50b.
Is the end distance y between the magnet 60 and the photoconductor 2 is 0.5 mm to 2 mm
When the pressure is larger than this, the suction force of the carrier is weak, and when the pressure is smaller than this, the carrier gradually gathers and is pressed against the photoreceptor 2 to cause damage, or the carrier spike is formed, and the amount of the spike is constant. If it reaches the amount, it adheres to the grid 50a and enters the casing 40, which is not preferable.

However, if the extreme end distance is between 0.5 and 2 mm, A4 paper 10
There is no problem at all within the printing of 10,000 sheets, and it is good and practically effective.

Further, in the charging means 3 used in this embodiment, the discharge opening is slightly upward from the horizontal direction as described above.
This is for the following reasons. In this embodiment, the photosensitive member 2
Because the OPC photoreceptor is used with negative charge, the polarity of the charged corona is negative.

The cause of this negative corona is still unknown,
In particular, a large amount of ozone gas (O ₃ ) is generated. Ozone gas has a strong oxidizing effect.

On the other hand, the OPC photoreceptor is very weak to ozone gas, and deteriorates when exposed to a large amount or a long time of ozone gas.
Image defects such as image deletion, image blur, and potential drop occur.

Therefore, if the discharge-side opening of the charging path is directed downward, the ozone gas, which is heavier than air, will always flow onto the photoconductor 2 while charging the photoconductor 2, and the photoconductor 2 is likely to deteriorate. Further, even when the photosensitive member 2 is stopped, the ozone gas stagnated in the charging means 3 flows to the photosensitive member 2 to locally deteriorate the photosensitive member 2.

Therefore, in this embodiment, as shown in FIG.
Sideways or with the opening facing up and the grid 50
A gap 7 is formed in the rear and lower casing 50 opposite to a.
1. An ozone vent hole 70 is provided to allow ozone to escape from the back of the charging means 3 so that the photoreceptor 2 does not flow.

Here, the gap 71 or the hole 70 provided in the charging unit 3 may be a surface corresponding to the lower side of the casing 50. That is, the charging means 3 is moved laterally or the discharge opening 60a so that the ozone of the charging means 3 performing the negative corona does not flow to the photoreceptor 2.
The opening 70 through which the ozone escapes may be provided with a hole 70 or a gap 71 on the surface opposite to the discharge opening or the lower surface of the casing 50. In particular, it is effective for a scorotron for negative charging having a large discharge current.

 Next, the exposure means 4 will be described.

First, as shown in the configuration diagram of FIG. 1 and the plan view of FIG. 14, the exposure means 4 includes a polygon scanner 83 comprising a polygon mirror 81 and a mirror motor 82, an fθ lens
84, a correction lens 85, reflection mirrors 86 and 87 for scanning the scanned laser beam to a predetermined position, a beam detector 88, and the like are fixed so that a beam on the photoconductor 2 due to erroneous attachment of a laser optical path length is formed. The difference in diameter and the difference in scanning speed can be minimized, and the laser can be easily adjusted before or after incorporating the exposure means 4 into the body.

FIG. 15 is a side view, in which the slit 90 from which the laser beam a is emitted from the exposure means 4 to the photoreceptor 2 is connected to the photoreceptor 2.
, The toner b scattered by the developing means 5 and the carrier adhering to the photoreceptor 2 may fall on the slit 90.

Therefore, in the present embodiment, a transparent glass 91 for dust prevention is adhered on the slit 90 to prevent foreign matter from entering the optical system constituting the exposure unit 4.

However, even if there is a dust-proof transmission glass 91, when a carrier or scattered toner is deposited on the transmission glass 91, the laser beam a as small as several tens of μm is transmitted through the transmission glass 91.
Photoreceptor 2 by toner and carrier adhered and deposited on 91
It will not be irradiated above.

For this reason, only defective images having white stripes in the case of reversal development as in the present embodiment and black stripes in the case of regular development can be obtained.

Therefore, as shown in FIG. 15, a transparent conductive film of ITO (Ind
Ion Tin Oxide) film 93 provided with a toner adhesion prevention film 94
Are arranged on the transmission glass 91. A bias voltage having the same polarity as the toner b, here a negative voltage is applied to the ITO film because the toner b is negative, and the scattered toner b causes the laser beam a to pass through the transparent glass on the slit 90 from the housing 80 of the exposure means 4. The sticking to 91 is electrically repelled and prevented.

Here, the applied voltage 95 is -400V. Here, any material can be used for the transparent conductive film 93 as long as it transmits the exposure light.

Further, magnets 96 and 97 are provided on the toner adhesion preventing film 94 except for an optical path portion through which the laser a is transmitted, except for a portion having the same width as the slit 90 or a portion slightly wider than the slit 90. These magnets 96 and 97 are
The carrier that has dropped is attached to prevent the carrier from attaching to the toner adhesion preventing film 93 and the transmission glass 91 on the optical path.

Also, are the magnets 96 and 97 dropped to earth,
A voltage 100 having a polarity opposite to that of the toner is applied, and the toner b is prevented from falling on the optical path similarly to the toner adhesion preventing film (ITO film) 93. Here, +300 V is applied to the voltage 100. In the figure, reference numerals 101 and 102 denote insulating members, which are made of polyethylene terephthalate of 75 μm in this embodiment.

Furthermore, in this embodiment, the magnets 96 and 97 to which the scattered toner b and the carrier adhere, the insulating members 101 and 102, and the toner adhesion preventing film 94 can be removed without being fixed to the optical system of the exposure unit 4. By making it detachable in this way, it is possible to take out and clean or replace it periodically or as needed. And, here, each of the above members 92, 93,
101, 96, 97, and 102 are integrated with the developing means 5 (not shown), and are taken out and discarded simultaneously with the developing means 5 and the photosensitive member 2.
It is devised to be exchanged.

Next, the electrostatic latent image on the photoreceptor 2 is developed by the developing means 5. At this time, the toner b unnecessary for the image adhering to the photoreceptor 2 as a transfer residue is simultaneously cleaned by the developing means 5. Is done.

 Hereinafter, the principle, conditions and the like will be described including experimental data.

This cleaning simultaneous development process (Cleaning & Deve
The point is that the loping process (CDP) is performed by reversal development. This is because the polarity of the toner is the same as the polarity of the toner, so that the polarity of the toner is not inverted by the charging unit 3.

On the other hand, as shown in FIG. 39, when the cleaning process is performed by the regular development, the following is performed. In this case, if a negatively charged photoreceptor is used, the polarity of the toner is positive, but first, the remaining toner to be transferred becomes negative with the opposite polarity during the charging process. In the exposure process, a portion corresponding to the background (white background) in FIG. 39 (B) is irradiated with light. However, the light normally goes under the toner, and the potential of the pack ground portion under the toner is attenuated. I will. Next, when the unexposed portion is developed with the toner of the positive polarity, the transfer residual toner in the unexposed portion of the photoconductor is electrostatically removed, and the pattern to be developed comes off in a negative shape, resulting in a black negative,
The memory image becomes defective.

Further, the negative transfer residual toner in the exposed portion is not attracted to the developing device, and thus remains on the photosensitive member. Further, in some cases, a phenomenon occurs in which the positive polarity toner in the developer is sucked. In the transfer step (D), the transfer residual toner on the exposed portion remains on the photosensitive member without being transferred because of the same polarity as the transfer charge. Therefore, every time the process cycle is repeated, the transfer residual toner on the photoconductor increases. Further, since the positive polarity toner sucked by the transfer residual toner is transferred, an image before one rotation of the photoconductor tram appears on a white background portion of the transferred image (white positive memory). That is, in the regular development system, the transfer residual toner on the photosensitive member increases each time the process cycle is repeated, and the occurrence of black negative memory and white positive memory increases. That is, this is because simultaneous development with cleaning is very difficult in regular development, and easy in reversal development.

Further, in this method, paper debris adhered to the photoreceptor is taken into the developing device because the photoreceptor is cleaned by the developing device. Therefore, one component such as a polar one-component system in which the developing sleeve and doctor blade must be narrowed to several hundred microns to form a thin layer of developer on the developing sleeve, and a non-magnetic one-component system in which the doctor blade slides on the sleeve In the method, when a large number of sheets are printed, paper dust enters between the doctor blade and the developing sleeve, and a uniform developer layer cannot be formed on the sleeve, so that image defects are likely to occur.

On the other hand, since the two-component developing method does not have such a problem, no image defect was generated even when 50,000 or more sheets were printed.
In other words, the two-component developing method has a longer maintenance period of the developing device and is preferable for the present method.

However, in this CDP, certain process conditions are required to obtain good quality images. Figure 16 is an explanatory view of the contents (the term) as used herein, referred to potential when the photosensitive member 2 reaches the developing position remains unexposed which is charged by the charging means 3 and the charge potential V _o, an exposure means 4 potential after exposure V _er potential attenuated exposed by the difference of the development potential V _D of the potential applied to the developing roller 110 of the developing unit 4 and the developing bias V _b and referred potential after exposure V _er and the developing bias V _b = V _b -V _er, cleaning potential difference between the charging potential V _o and the developing bias _{V b V CL = V o -V} b
Call.

In this embodiment V _b also contemplates While photoreceptor 2 using OPC for negative charging positively charged _{type, V er, V b -V er} , the V _o -V _b promote talk as an absolute value.

The first quadrant in FIG. 17 is a plot of measured data with the development potential _Vb - _{er on} the horizontal axis and the image density on the vertical axis.
It is understood that the above is necessary.

On the other hand, in the second quadrant, the horizontal axis represents the developing potential _Vb , and the vertical axis represents the charging potential.
Each plot point indicates V _o , and each plot point indicates an occurrence state of a memory by an image of the photosensitive member 2 one rotation before due to a cleaning failure in the image on the paper P.

Here, it has been found that when the developing potential is higher than 300 V, a memory of a black pattern is generated on a white background due to a cleaning failure (hereinafter referred to as a white background memory). This means that the image density does not increase even if the development potential exceeds 300 V,
It is considered that the actual amount of toner b attached is increasing, and the transfer residual toner is also increasing at the same time.

Next, the third quadrant, in which the horizontal axis represents the cleaning potential V ₀ −V _b and the vertical axis represents the charging potential V _o , the degree of generation of a memory image on the paper P is shown.

Here, when the cleaning potential V _CL = V _o −V _b is zero, a blank memory is surely generated due to defective cleaning, and it has been found that at least 50 V or more is required.

However, when the cleaning potential is increased, a positive charge is reversely injected from the developing roller to the toner, and the toner b, which has changed from a negative polarity to a positive polarity, adheres to an unexposed portion (negatively charged portion) of the photoconductor 2. Then, it becomes a filter and reduces the exposure amount of the exposure unit, causing causes of image defects such as an uneven exposure image and the occurrence of an image one round before the photosensitive member 2 as a positive memory in a dot pattern. . Therefore, the maximum cleaning potential slightly depends on the toner b, the carrier and the combination thereof.
It turned out that 300V or less was preferable.

The developing means 5 includes a developing roller as shown in FIG.
A portion of the developing magnetic brush 111 formed on the surface of the developing roller 110 is in sliding contact with the photoreceptor 2, that is, upstream of the developing position 113 (meaning with respect to the rotation direction).
A doctor 114 provided in a process unit integrated with the photoreceptor 2 to regulate the thickness of the developer magnetic brush 111, a developer agitator 116 stored in a developer storage unit 115, and replenished from a toner replenisher 120 Agitating / conveying the toner
The transfer body 117 is housed in a casing 121, and the photosensitive body 2 is further incorporated therein.

Further, the developing roller 110 is provided with a magnetic roll 118 which is provided at an angle α (about 50 °) with respect to a horizontal line L passing through the rotation center of the photoreceptor 2 and a counterclockwise direction in the external fitting diagram of the magnetic roll 118. And a sleeve 119 that rotates.

The magnetic roll 118 has three magnetic pole portions 131, 132, and 133, of which the magnetic pole portions 131 and 133 are S poles, the magnetic pole portion 132 is an N pole of 1000 gauss, and the angle θ ₁ between the magnetic pole portion 131 and the magnetic pole portion 132 is 150 °, angle θ between magnetic pole part 132 and magnetic pole part 133
₂ is set to 120 °.

Further, in this embodiment, magnets 96 and 97 for preventing the scattering toner and carrier from adhering to the optical slit 90 and a toner adhesion preventing film 94 are fixed, and are integrated with the developing unit including the photoconductor.

The electrostatic latent image on the photoreceptor 2 is visualized by the toner b of the developing unit 5 and then transferred onto the sheet P by the transfer unit 6 (see FIG. 2D).

 Here, the following measures are taken.

The process speed (photoconductor peripheral speed) of this embodiment is 36 mm / s.
It is about 1/4 slower than ec and normal copiers (process speed is about 14 Cmm / sec for A4 paper 15 sheets / min). With such a slow process speed,
If a corotron charger conventionally used as a transfer means is used, the following problems occur.

Since the corona current is small, the voltage applied to the corona wire is low, close to the discharge starting point, and becomes unstable against contamination and environmental changes.

The value of the applied voltage or the output current of the corona for performing good transfer of the character portion and the solid portion (the portion with a large area of toner) is different, and it is difficult to obtain a good quality transfer image in both portions.

These causes are caused by a longer process time due to a lower process speed.

Basically, when the toner b is transferred, the potential of the paper P is
It is sufficient to apply a charge to the paper P until the potential reaches a potential for electrostatically attracting the paper P.

Therefore, since the process speed is low, a good transfer current is generated when the voltage applied to the corona wire is about 3.5 to 4 kV, and when the voltage is higher than that, excessive transfer occurs.
However, the voltage of 3.5 to 4 kV is almost the starting voltage of corona discharge as shown in FIG.
Discharge or not depending on the degree of adhesion of dirt, etc., resulting in poor stability and lack of stability.

Further, in order to examine the difference in the transfer condition between the character portion and the solid portion image, solid or a large number of characters are printed in a certain area, and a visible image is formed by the toner b on the photoconductor 2,
In the case of non-transfer, the amount of toner adhering on the photoreceptor 2 after being transferred to the paper P is sampled on the tape with a fixed area cellophane tape (manufactured by Nichiban), and the sampled tape is melted with a certain amount of toluene to increase the transmittance. From the measurement, the transfer efficiency was calculated by the following equation.

FIG. 20 shows a process speed of 36 mm / sec used in this embodiment.
The transfer efficiency of the character (line) image portion and the solid portion when the voltage applied to the corona wire is changed by using the corotron as the transfer means 6 of the apparatus is examined. % Of the applied voltage. That is, as long as the corotron is used, it can be inevitable that the image density of either the character or the solid image decreases.

The reason for this is that, as shown in FIG. 21, the potential of the sheet P and the movement of the electric charge, the sheet P is separated from the photoconductor 2 in the solid portion because the toner b is interposed between the photoconductor 2 and the end portion. , Except for the electric charge received from the transfer corona, the potential of the paper P hardly decreases, and the toner b is transferred to the paper P by an electric force.

On the other hand, in the character portion, since the width of the toner image is narrow, the charge on the paper P on the toner b is absorbed by the opposite charge of the unexposed portion of the photoconductor 2 next to the toner image, and the potential of the paper P rises. Absent.

For this reason, if the transfer of the solid portion is appropriate, the potential of the paper P in the character portion decreases, and the transfer efficiency deteriorates. Conversely, if the potential of the character portion paper P is to be increased, the solid portion potential is too high, and the solid portion toner b receives the leak current from the paper P, the polarity is reversed, and the toner b is hardly transferred. Become. That is, the transfer becomes excessive.

In order to eliminate such a problem, a scorotron charger similar to the charging unit 2 was used for the transfer unit 6. By using a scorotron charger, a voltage of 5 kV or more can be used for the corona wire 41, so that the discharge is stabilized and the occurrence of charger unevenness due to dirt or the like can be prevented. Further, since the potentials of the transfer paper in the solid portion and the character portion can be controlled to the same potential, a transfer image in which both the solid portion and the character portion are good can be obtained.

FIG. 22 shows that the transfer efficiency of the character portion and the solid portion when using the scorotron was examined in the same manner as when using the corotron, and that the control was sufficient, and both the solid and the character simultaneously performed good transfer at the same time. (Transfer efficiency of 80% or more) This shows that both areas can be widened. The shape of the scorotron is almost the same as that of the charged one.

Here, the scolontron for transfer is open downward with respect to the photoreceptor 2, but since it is a positive corona, ozone is hardly generated and there is no problem unlike the negative charging. Here, the appropriate value of the grid voltage of the scorotron was examined by measuring the transfer efficiency.

Table 1 shows the transfer efficiency of various transfer papers determined by changing the grid voltage.

According to this, good transfer (efficient
It turned out that the area of the grid voltage was different.

Therefore, in order to perform good transfer on all types of paper, it is necessary to switch the voltage of the grid to at least two types of voltages according to the paper. In this embodiment, the output of the grid transformer is switched to two levels of 1200 V for envelopes and +700 V for other papers by a signal. Needless to say, the switching of the grid voltage may be performed in multiple stages according to various types of paper.

Here, as one of the considerations when the transfer means 6 is a scorotron, there is a countermeasure against contamination of the grid of the scorotron. Normally, the transfer means 6 is attached to the lower side of the photoconductor 2. Therefore, the opening is directed upward, and the paper P passes above it. On this occasion,
Inevitably, the toner b on the photoconductor 2 and the paper dust of the paper P fall onto the transfer unit 6. When the transfer means 6 is a scorotron, the toner b is inevitably placed on the grid 50a.
In addition, paper dusts are dropped and adhered, and during printing of several thousand to tens of thousands of sheets, the grid becomes heavily stained, mesh eyes are clogged, and transfer failure is likely to occur.

Therefore, in the present embodiment, the transfer position is set above the photoconductor 2, and
By providing the transfer means 6 of the scorotron above, the opening on the grid 50a side is directed downward, thereby preventing the above-described contamination of the grid 50a (see FIG. 1).

Here, the path of the sheet P around the transfer unit 6 will be described. Conventional copiers and printers that transfer a toner image to a sheet of paper P usually use a photoconductor 70 as shown in FIG.
A guide member 720 for guiding the sheet P to zero and a guide member 721 for guiding the sheet P after transfer to a fixing device (not shown) are grounded via an element 722.

Where element 722 is a high resistance or zener diode,
A constant voltage element such as a varistor or a circuit equivalent thereto. When the paper P becomes highly water-containing paper due to high humidity or the like, a self-bias voltage is generated by a current flowing to the guide members 720 and 721 through the paper P to generate a high water content paper. However, a value having such a value that good transfer can be obtained is used. Usually a barista
1kV, about several tens MΩ for resistance.

The reason why these elements 722 are necessary is that when the guide members 720 and 721 are grounded, the electric charge of the transfer corona applied to the paper P is transmitted to the paper P and leaks to the ground when the humidity is high, and the potential of the paper P transfers the toner b. This is because the potential does not increase to the level required for the operation.

However, a guide member to prevent deterioration of transferability in high humidity
The method of applying a voltage to 720 and 721 or applying a self-bias voltage by a resistor or a constant voltage element is effective when the transfer unit 704 is a corotron.

The transferability was examined by changing the Zener diode, the varistor, the resistance, the voltage by the power supply, and the like for the guide plate 150 and the conductive guide roller 151 in FIG. As a result, it was found that the transferability varies depending on the potential of the guide plate 152 and the guide roller 151 even in the scorotron.

 Table 2 is a table of evaluation of the results.

It was found that when a voltage was applied to the guide members 152 and 150 in the case of using a scorotron, transfer defects due to excessive transfer were likely to occur.

For this reason, the guide member for the paper path of the paper P
Applying a self-bias to the voltage 152, 150 with a voltage, a resistor, or a constant voltage element causes excessive transfer in scorotron transfer, which is a bad result. Rather, most preferred is ground (earth) or float (electrically insulated). Therefore, in this embodiment, the guide plate 152 and the guide roller 151 are connected to the ground, and the other contact portions are made of an insulating member (for example, ABS resin).

The system for simultaneous development and development is affected by the characteristics of the toner b. Here, the following experiment was conducted to examine the characteristics of the toner b. Charge and exposure are performed on the photoreceptor 2 to which the toner b is not adhered to form an electrostatic latent image and perform reversal development to form an image.

The reflection density stuck to white paper take the toner image to the mending tape (3M Co.) on the photosensitive member 2 at this time measurement which is referred to as D _o. Next, in the same manner as described above, an image is formed on the photoreceptor 2, and the image is lightly removed and recharged without transferring. After passing through the developing means 5 for cleaning without exposing, the toner image is taken on a mending tape and the density at this time, which is taken on white paper, is
D _CL . Then, the cleaning efficiency ξ can be expressed as ξ = 1−D _CL / D _d .

Here, during the production of the toner, the charge efficiency (μc / g) of the toner b in the developer is changed by changing the addition ratio of the charge amount controlling agent, carbon, and the like, and changing the frictional charge characteristics with the carrier. The result was as shown in Fig. 23. Here, the charge amount is a value obtained by agitating a carrier and a toner and frictionally charging the carrier and the toner, and measuring the charge with a blow-off measuring device (manufactured by Toshiba Chemical).

Normally, the case where the amount of the transfer residual toner is large is a case where the image density is high, which is about 1.4. The transfer efficiency is about 75 to 90%. Assuming that the lower transfer efficiency is 75%, the density of the untransferred toner remaining on the photoreceptor 2 (mending tape method) is D _p / (D _d + D _p ) = η 1.6 / (D _d) +1.6) = 0.75 D _p : Transfer density D _d : Transfer residual density η: Transfer efficiency is about 0.53. If this amount is present on the photoreceptor 2, it becomes a memory without cleaning, but if it is reduced to 0.1 on the photoreceptor 2 by simultaneous development and cleaning, there is no problem on the transferred image.

Here, D _CL = 0.1 and D _d = 0.52 in the equation of the cleaning efficiency.
代 入 = 1−D _CL / D _d = 1−0.1 / 0.53 ≒ 0.81, which indicates that a cleaning efficiency of about 80% or more is sufficient. Here, it can be seen from FIG. 23 that in order to obtain a cleaning efficiency of 80% or more, the charge amount of the toner b in the developer (blow-off method) should be 18 to 28 μc / g.

Here, photoconductor 2 peculiar to cleaning simultaneous development (CDP)
The type and cause of the memory in which the pattern developed one cycle before appears on the next image portion will be described.

There are three types of memories: a black positive pattern (white positive) on a white background, a negative pattern on a halftone (black negative) made of a set of dots or lines, and a halftone dot pattern made of a set of dots or lines. This is a positive pattern (black positive) on a halftone (see FIG. 24).

The cause of the white positive occurs when cleaning potential V _CL is the difference in cleaning is poor charging potential and the developing bias V _B is too small.

The black negative memory is caused by insufficient exposure due to the transfer residual toner image.

The black positive memory is caused by an excessively high cleaning potential and low toner resistance.

FIG. 25 shows the principle of generating a black negative memory which is likely to appear on a halftone like a halftone dot pattern formed by an aggregate of dots or lines, in which the vertical axis represents the surface potential and the horizontal axis represents the distance.

(A) shows that there is a small amount of untransferred toner in the charging step (a
3 shows the surface potential of the photoreceptor 2 with some (b) and no (c, d) at all.

(B) shows the surface potential when the laser spot is irradiated on the photosensitive member 2 at intervals of every other dot, and (c, d)
Since part (2) is a normal exposure, the potential attenuates substantially equal to the laser exposure width. In part (a), since the amount of toner remaining after transfer is small, the potential under the toner is considerably attenuated by transmitted light, diffracted light, and the like, and is close to the potential of the exposed portion where no toner exists. On the other hand, in the case where the transfer residual toner is large (part b), since the light does not hit the photoreceptor part under the toner and the potential does not attenuate, the portion where the potential attenuates becomes narrower or completely absent.

(C) and (d) show the potential diagram when the exposure state of (b) is reversed and the pattern on the paper P after the heat fixing, and there is no transfer residual toner (parts c and d). A toner image is formed in a pattern having a diameter (width) substantially the same as the exposure spot diameter (width). However, in the portion (b) containing a large amount of untransferred toner, the portion where the potential is attenuated is smaller than the exposure spot diameter (width). The resulting pattern is small or completely absent. Then, the transfer residual toner is cleaned (collected to the developing device). Therefore, if a portion with a large amount of toner remaining after transfer forms a pattern of characters or numbers, it becomes a white negative memory (portion in FIG. 24).

On the other hand, when the transfer residual toner is scattered (part a), the potential under the toner is also attenuated or attenuated to some extent, so that the toner remains attached without being cleaned, so that the pattern after development is not much different from (c, d). Thus, a pattern image having substantially the same diameter (width) as the exposure spot is obtained. Even if the potential under the toner is not sufficiently attenuated, if the size of the toner particles is about one or two, the exposure spot diameter is the diameter of the toner particles (usually 8 to 12 μm).
m), which is as large as 60 μm (density of 400 dots / inch) and the layer thickness of the developed toner is large, so that the toner is buried at the time of development or fixing and poses no substantial problem.

By the way, the cause of the black negative memory is caused by the filter effect of the transfer residual toner as described above. However, the solid light image, the halftone image, and the laser light amount for lines of 5 dot lines or more (400 dots / inch or more) Black negative memory does not occur due to the configuration of the photoconductor, the transmittance of the toner, and the like. However, four or less dot lines are likely to occur. In particular, the edge portion of the line is remarkable, and looks like a whitish white character when represented by a character composed of four or less dot lines.

Here, when the transfer remaining pattern of the character image on the photoreceptor 2 is adhesively transferred to a mending tape (manufactured by 3M),
As shown in FIG. 26, a large amount of untransferred toner is present at the boundary between the developed portion and the non-developed portion.

FIG. 27 is a cross section taken along the line XX of the transfer residual pattern in FIG. 26, and it can be seen that a large amount of the residual transfer toner at the boundary is left in a laminated state. Incidentally, reference numeral 160 shown in FIG. 27 is a tape. Therefore, almost no light passes through this boundary portion, which causes black negative memory.

The untransferred toner remaining at the boundaries between the characters and the line patterns is broken to form a single layer without memory.
Alternatively, the black negative memory is obstructed by removing the laminated portion by electrostatic attraction.

Therefore, the memory removing member 7 acting as described above is transferred to the transfer means 6.
And upstream of the charging means 3.

In this embodiment, the memory removing member 7 is shown in FIGS.
As shown in Fig. 30, Fig. 30, rayon contains carbon to a specific resistance of 10 ⁶ Ω · cm and has a thickness of 6D (denier).
The bristles were made into a bundle of 100 pieces, the density was 86 bundles / inch, satin weave, two layers of weft were pulled out, and a conductive brush 200 with a spike length of 9 mm was formed. It is assumed that the polyester film 201 is attached so as to protrude d (1.0 mm) from the tip of the brush 200, and θ (15 °) with respect to the photoconductor 2
The developing means 5 and the developing means 5
It was fixed so as to be integrated with the photoreceptor 2 and the charging means 3. Reference numeral 203 denotes a metal fitting for holding the fiber bundles 202.

The shape of the memory removing member 7 basically has only to be in contact with the surface of the photoconductor 2. For example, as shown in Fig. 31
There is an effect even if you put 130 on your stomach. In this case blade 130
The material may be urethane mixed with carbon, metal fittings, or semiconductor powder to have a specific resistance of 10 ⁹ Ω · cm or less, or phosphor bronze or stainless steel of 0.1 mm or less to have flexibility. However, the blade tends to form a gap with the photoreceptor when a lump of toner or carrier particles pass through.

Therefore, a more preferable shape is a fixed brush shape.
That is, the toner is scattered when the brush is rotated or moved left and right. Examples of the material of the brush 202 include rayon, nylon, acrylic, polyester, and the like made conductive by mixing carbon or metal powder, carbonized phenol resin (Kynol (trade name)), stainless fiber, and the like. is there.

Here, the resistance dependence of the brush 200 as a memory removing member was examined. A 30φ OPC photoreceptor rotating at a peripheral speed of 36 mm / sec is first subjected to pre-exposure, charged as −500 V by a charging scorotron charger as a charging means 3, and the 30φ developing sleeve 119 is rotated at a rotation speed of 140 rpm. 2, the electrostatic latent image formed by the exposure is simultaneously developed with the cleaning and transferred to the paper P by the transfer charger as the transfer means 6.

After the transfer, it is passed through a brush 200 fixed to the developing unit, and this is set as one cycle, and continuous printing is performed.
The transferred image was evaluated.

In this embodiment, reversal development is performed, and the surface potential of the photoreceptor 2 after transfer does not exceed the charging potential because the transfer charger as the transfer means has the opposite polarity to the charging. Since it is a scorotron, there should be basically no potential fluctuation.In fact, if the same image is printed for a long time, as shown in Fig. 38, a difference occurs in the residual potential due to light fatigue between the exposed part and the visible exposed part. Red density LED was used for the purpose of forced fatigue because the density was uneven when the image was printed.

 The resistance dependence of the brush was investigated.

The brush used here is a single filament (fiber)
Is a 3D (denier) one bundled into a single yarn 1
Pile weave brush 205 at a density of 00,000 brushes / inch ² (Fig. 32
A, FIG. 32B, and FIG. 32C). In the drawing, reference numeral 206 denotes a base fabric weft, 207 denotes a base fabric warp, and 208 denotes a pile. Here 10 under specific resistance 20 ° C. 60% RH environment of the brush 205 is ⁰ Omega · cm to 10
^When the test was performed by changing the resistance to ¹² Ω · cm, the one having a specific resistance of 10 ⁶ Ω · cm or less was effective for a black negative memory on a halftone (dot) pattern as shown in Table 3. However, in practice, a resistor with a resistance of 10 ⁹ Ω · cm or less that can remove a white positive was sufficient.

Further, it was necessary to apply a positive or negative bias to the black negative memory.

Here, when the transfer residue after passing through the brush 205 was transferred and sampled with a mending tape, as shown in FIG. 33, if the voltage was 0 V or a float, the pattern of the transfer residue toner after passing through the brush was slightly thinner. Memory is generated on the image almost unchanged.

However, with a negative bias of the same polarity as the toner, the border of the character pattern becomes thinner, while the brush develops the toner-free portion at the center of the line of the remaining transfer pattern, resulting in a thinner character pattern as a whole. .

However, this does not appear as memory on the image.
If the positive bias is opposite to the polarity of the toner, the boundary of the character pattern becomes thin, and no memory is generated on the image. The polarity of the toner is a polarity obtained by frictional charging with the carrier. Here, the memory removal brush does not diffuse the toner pattern of the character characteristics remaining after the transfer, but the brush once electrostatically sucks the toner, and then spontaneously bleeds out to the photoconductor to attach the toner to the photoconductor. Was found to have changed. If only the toner position is changed, it is considered that a means for positively diffusing the toner should be provided instead of the memory removing brush. In that case, however, the apparatus itself becomes large and the toner itself becomes large. Problems such as scattering occur, which is not preferable. In addition, as a result of the 20,000-sheet image running test, toner hardly accumulated in the brush.

On the other hand, the white positive memory in which the untransferred toner was not cleaned properly due to the transfer omission due to the lifting, wrinkling, or folding of the paper had no effect unless the OV, the float, or the positive voltage was applied.

From these, it was found that the bias for the brush 205 had to be positive. Therefore, the positive bias voltage is changed from 100V to 1000V.
The effect of removing the transfer residual toner pattern and the memory on the paper P was examined by changing the pattern to 100 V or higher. However, when + 700V or more is applied, the voltage leaks due to a slight defect of the OPC photoconductor (it seems to be a pinhole), and it turns out that a hole is made in the photoconductor 2, and the appropriate voltage is from +100 to + 700V. Is a range that can be substantially used.

In this embodiment, in order to reduce the size and cost of the apparatus, the diameter of the photoreceptor 2 is reduced to 30%, and only the separation using a paper strainer (rigidity) is used. 6) is applied, and the portion is positively charged until the potential of the photoreceptor 2 is +700 to 1200 V which is close to the transfer grid voltage (FIG. 34).

Therefore, the negative polarity toner b attached to the brush 205
Develops the positively charged portion through which the paper P has not passed. In particular, the toner b remarkably adheres to the portion near the leading edge and the rear of the sheet P, and appears as streak-like white positive and black negative memories on the image (see the sheet interval mark in Table 3). To prevent this, a positive bias is applied to the brush 205, and only when the paper P passes under the transfer means (transfer charger) 6 as shown in the flowchart of FIG. Turn on the power supply to the corona wire 41
However, it was possible to solve the problem that the exposed portion of the photosensitive member 2 before and after the transfer paper was not positively charged.

The printer of this example can print up to A3 paper.
When printing paper narrower than paper, for example, B5 paper, both sides of the paper P of the photoconductor 2 (because of the device that always feeds the center of the paper at the same position regardless of the paper size) are positively charged.
In this case, there is no paper at this portion during printing, so there is no problem at all.

As will be described later, it was also found that it is preferable that the brush shape be a satin weave.

Here, the bias power applied to brush 200 (205) is turned on.
The timing of the operation will be described. Since a positive voltage (a voltage of the opposite polarity to the charging) is applied to the brush 200 (205),
Basically, the photoconductor 2 is positively charged. For this reason, the surface of the photoreceptor 2 that has passed the brush 200 (205) to which a voltage has been applied does not necessarily receive the charging corona by the charging unit 3, and if that portion passes through the developing unit 5, the toner (the negative electrode) of the developer in the developing unit 5 ) B is attached and becomes solid black. Such solid black cannot be completely cleaned and poses a problem. Therefore, the negative charge by the brush may be changed to the negative charge by the charger. Photoconductor 2 from brush contact position to charging position
When the time periphery reaches the a T _BM, the time to turn ON the charging from the ON brush biasing power source must be less than T _BM. In this embodiment, as shown in FIG. 35, charging and brush bias ON are performed simultaneously.

In addition, such a problem also occurs in a print end temple. Therefore, brush bias is turned off at the end of printing
The discharging of the charging means 3 must not be stopped until the surface of the photoconductor 2 at the time when the condition (2) has passed the charging position. That is, the time for turning off the charging must be longer than _TBM .

Next, the effect on the memory by changing the fiber thickness of the brush 200 (205) was examined. The image and the transfer residual toner image on the photoreceptor after passing through the brush were examined. Could not be removed. At 100D or less, no memory was generated, and the transfer residual toner image had no dark portion at the boundary. In conclusion, the fiber thickness is preferably 100D or less.

The density of the brush 200 (205) is 1000 piles / inch ² or more for piles and has no effect unless the thickness is 0.5 mm or more. For satin weaves, 10 to 1000 fibers are used. It was found that non-brushed yarns were woven as warp yarns or weft yarns at a rate of 10 bundles / inch or more at a rate of one bundle, resulting in uneven memory removal effect. The memory removal effect is almost determined by the brush resistance, fiber thickness, density, etc. However, it has been found that toner actually drops (scatters) depending on the brush shape and contact method for practical use of the device. .

Here, the pile weave brush 205 (see FIG. 32A) and 1
Bundle 100 fibers with 3D thickness, 1 per inch
Satin brush 200 as warp at a density of 27 bundles (Fig. 28 reference) and was intended length l _A, the thickness W (satin weave sheets), the angle theta, the contact position l _B (see Figure 29) The number of toner particles scattered or dropped on the charging means 3 composed of a scorotron was examined by printing 1000 sheets (A4 landscape) under different conditions.

As a result, as shown in FIG.
36, and the pile 50 of the pile weave brush 205 shown in FIG. 36B dripped much toner, and the grid 50a of the charging means 3 made of scorotron was stained black. In addition, there is a problem that hair breakage sometimes occurs, short-circuits with the grid 50a of the charging means 3, and generates a solid black image. It is not preferable that the brush 200 made of satin weave such that the tip of the brush 200 comes into contact with the photoreceptor 2 as shown in FIG.

On the other hand, as shown in FIG. 29, when the satin brush 200 was applied to the stomach instead of the tip, toner drop was significantly reduced. The optimum application condition is as shown in FIG.
Point where the center line L of the brush 200 intersects with the outer diameter circle of the photoreceptor 2 in a state where the brush 200 is fully extended (because the brush which applies pressure once deforms for a while) without any external force. Where P is a tangent line to the photoreceptor 2 in the brush direction at the point P, the brush length l _A is 4 mm or more, the contact point P is a distance l _B from the brush tip point of 2 mm or more, and the mounting angle θ
If it was not less than 70 mm, the toner dropped much and the effect was reduced.

Also, a backing film 201 is provided on the surface of the brush 200 opposite to the surface that is in contact with the photoreceptor 2 to prevent the bristles of the brush 200 from spreading. No fall occurred.

The backing film 201 is an insulating material, and may be made of any material such as polyester, urethane, high-density polyethylene, polypropylene, butadiene rubber, butyl rubber, silicon rubber, polyacetal, or fluororesin which has a thickness of 2 mm or less. However, the tip of the film 201 is the same as or greater than the tip of the brush 200 (1.5 in this embodiment).
It was necessary to stick out and it was not effective if retracted.

This is considered to be because if the fiber is spread at the tip, the toner adheres to each fiber having a diameter of several tens of microns, and drops or scatters due to a subtle change in air flow or vibration.

However, according to the above configuration, since the developing unit develops the electrostatic latent image and simultaneously cleans the transfer residual toner, there is no need to provide a dedicated cleaner unit as in the related art. This not only reduces costs and extends the life of the photoconductor, but also eliminates the need for cumbersome operations such as replacing the waste toner box, and also reduces the number of toner replenishments because the untransferred toner is collected and reused, reducing maintenance. It becomes very easy. Furthermore, the same apparatus is switched between the developing step and the cleaning step to perform two rotations /
The diameter of the photoconductor can be reduced, and the size and cost of the apparatus can be reduced as compared with those of copy (print).

Further, a memory removing member is provided on the upstream side of the charging unit and on the downstream side of the transfer unit, and a large amount of residual toner remaining on the photoreceptor after transfer is once electrostatically suctioned and then naturally spouted out. Even if there is residual toner, a clear image can be formed without leaving the previous image.

[Effects of the Invention] As described above, in the present invention, in addition to the cleaning / developing means for performing simultaneous development and cleaning, a memory removing member for disturbing the residual developer is provided between the charging means and the transfer means. A bias voltage having a polarity opposite to the charging polarity of the developer is applied to the removing member. In addition, by applying a bias voltage having a polarity opposite to the charging polarity of the developer, the residual developer on the photoconductor is once electrostatically attracted to the memory removing member and naturally falls on the photoconductor. The position of the toner is changed. In this way, by changing the position of the developer, the residual developer that is present as a lump on the photoconductor can be dispersed thinly and uniformly on the photoconductor. This allows the residual developer to be charged from above,
Even during exposure, a clear electrostatic latent image without charge unevenness or exposure unevenness can be formed, and simultaneous development and cleaning without a memory image can be performed.

[Brief description of the drawings]

FIG. 1 is a block diagram showing the entire recording apparatus of the present invention, and FIG.
FIG. 3 is an explanatory view schematically showing a change in the surface potential of the recording apparatus of the present invention and the state of the toner on the photosensitive member according to the process, FIG. 3 is a sectional view of the photosensitive member, and FIG. Fig. 5 is an explanatory diagram showing the irradiation state when
FIG. 6 is a diagram showing a relationship between environmental conditions and residual potential when the L film thickness is changed, FIG. 6 is a schematic cross-sectional view of the photoconductor, FIG. FIG. 8A is an explanatory diagram for explaining the effect of insufficient light exposure when the exposure pattern is a single pine pattern, and FIG. 8B is a diagram for explaining the effect of insufficient light exposure when the exposure pattern is one line. FIG. 9, FIG. 9 is an exploded perspective view of the charger used in the apparatus of the present invention, FIG. 10 is a sectional view of the charger, FIG. 11 is a partially enlarged view of a grid portion of the charger, and FIG. FIG. 13 is an explanatory view of a means for preventing inconvenience caused by a drop of the carrier of the charger, FIG. 13 is an explanatory view showing the flow of ozone in the charger, and FIG. 14 is a plan view of an optical system used in the apparatus of the present invention. Figure,
FIG. 15 is a side view of the optical system, FIG. 16 is a view for explaining the contents of the surface potential, and FIG. 17 shows the relationships between the development potential and the image density, the development potential and the charging potential, and the cleaning potential and the charging potential. FIG. 18 is a schematic sectional view of a developing device used in the apparatus of the present invention, FIG. 19 is a diagram showing a relationship between an applied voltage and a discharge current at the time of transfer, and FIG. 20 is a character portion by a corotron charger. FIG. 21 is a diagram showing the relationship between the applied voltage of the solid portion image and the transfer efficiency, FIG. 21 is an explanatory diagram showing the potential of the transfer paper and the state of charge leakage, and FIG. 22 is a diagram showing the relationship between the applied voltage and the transfer efficiency by the scorotron charger. FIG. 23 is a diagram showing the relationship between the charge amount and the cleaning efficiency, FIG. 24 is an explanatory diagram showing an example of a memory pattern which is likely to appear on the transfer paper, and FIG. 25 is a diagram showing the potential of the photoconductor when a black negative memory occurs. Explanatory diagram showing the relationship between transfer residual toner, FIG. 26 FIG. 27 is a view showing an example of a remaining transfer pattern, FIG. 27 is an explanatory view showing the state of the toner in the XX section of FIG. 26, and FIG. 28 is a satin weave brush constituting a memory removing member which is a main part of the present invention. FIG. 29 is a view showing the state of attachment of the brush, FIG. 30 is a view showing the state of the backing film of the brush, and FIG. 31 is a memory removing member which is a main part of the present invention constituted by a blade. Illustration of the case, FIG. 32A
Is a perspective view of a pile weaving brush constituting a memory removing member as a main part of the present invention, FIG. 32B is a partially enlarged view of the pile weaving brush, FIG. 32C is a partial sectional view of the pile weaving brush,
FIG. 33 is an explanatory diagram showing a transfer residual pattern after passing through a brush arrangement portion, FIG. 34 is a diagram showing a surface potential on a photoreceptor after transfer when a transfer corona is continuous, and FIG. FIG. 36A is an explanatory diagram of a case where the tip of a pile weaving brush is used in contact, and FIG. 36B is an explanatory diagram of a case where a belly of a pile weaving brush is used. Fig. 37 is an explanatory diagram when the tip of the satin weave brush is used in contact, Fig. 38 is a diagram showing the state of the potential after exposure, and Fig. 39 is a change in the surface potential when performing regular development and simultaneous cleaning FIG. 40 is a diagram schematically showing the state of the toner on the photosensitive member according to the process, FIG. 40 is an explanatory diagram of the configuration of the conventional device, and FIG. 41 is an explanatory diagram showing the transfer paper transfer path of the conventional device. 2 photoreceptor (image carrier), 3 charger (charging means), 4 optical system (exposure means), b toner (colored powder), 6 transfer device (transfer means), 7 Memory removal unit 130 Blade 200 Satin brush 201
... backing film, 205 ... pile weave brush.

Claims (1)

(57) [Claims] A charging means for charging the image carrier rotating in a predetermined direction to a specific polarity; and exposing the image carrier charged by the charging means to light,
An exposure unit that forms an electrostatic latent image; a developer transport member that supplies a developer having a charge of the same polarity as the specific polarity to the image carrier; and A bias that generates an electric field such that the residual developer adhering to the unexposed portion of the image carrier is directed to the developer transport member, and the developer is directed to the exposed portion of the image carrier from the developer transport member. A first voltage applying unit for applying a voltage, wherein the developer is supplied from the developer conveying member to an exposure unit of the image carrier to visualize the electrostatic latent image, and at the same time, the image carrier A reversal developing type of cleaning and developing means for collecting the residual developer adhering to the unexposed portion to the developer conveying member, and a developer image on the image carrier developed by the cleaning and developing means. Transfer means for transferring to a recording medium, and the image bearing Provided in contact with the surface of the image carrier on the downstream side of the transfer unit and the upstream side of the charging unit along the rotation direction, and the transfer on the recording medium was performed by the transfer unit. A memory removing member for disturbing the residual developer remaining on the image carrier, and a second voltage for applying a bias voltage having a polarity opposite to the specific polarity for disturbing the residual developer to the memory removing member. An image forming apparatus, comprising: