JPS6334467B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a transfer device for an electrophotographic copying machine, particularly a color electrophotographic copying machine.

In a color electrophotographic copying machine, each visible image formed on a photoreceptor is separately superimposed and transferred onto the same transfer paper to obtain a single copy.

A bias type transfer device is one of the transfer devices of such a color copying machine. This is a conductive transfer drum that rotates in pressure contact with a photoreceptor drum.
A bias voltage having a polarity opposite to that of the toner image on the photoreceptor is applied to transfer the toner image to the transfer paper on the transfer drum. The advantages of this device are that the transfer paper is held securely on the transfer drum, the transfer drum is easy to control, the transfer paper has good transport performance, and the bias application during transfer is easy to control. etc. Disadvantages include, first of all, that the transfer drum lacks precision and material safety. In the case of this apparatus, conductive rubber is often used as the material of the transfer drum in order to bring the transfer drum into close contact with the photoreceptor and apply a bias voltage. For this reason, it is difficult to increase precision due to its hardness and conductivity, and it also lacks material stability due to changes over time. In addition, this device suffers from problems such as worm-eaten and hollow spots in image quality due to abnormal discharge during transfer. This occurs when the contact pressure of the transfer drum against the photoreceptor is increased in order to obtain sufficient adhesion. Furthermore, if a carrier such as iron powder is mixed into the toner image in order to bring the transfer drum into pressure contact with the photoreceptor, the surface of the photoreceptor or the transfer drum may be damaged by this hard carrier. Furthermore, since the surface resistance of the transfer drum easily changes due to environmental changes such as temperature and humidity, the transfer characteristics are sensitive to these changes.

Another type of transfer device is a charge type transfer device. In this method, a portion of a loop-shaped flexible dielectric supported by several rotating bodies is brought into contact with the photoconductor, and a corona charger having an imperial polarity opposite to that of the toner image is placed on the inside of the loop-shaped flexible dielectric. be. The transfer paper is electrostatically brought into close contact with the dielectric sheet and is conveyed, and the toner image is transferred to the transfer paper side by the opposite polarity charge applied from the corona charger. Overall, this device has extremely stable image quality, but the positioning and conveyance of the transfer paper are unstable and color shift is likely to occur. In addition, the entire device becomes very complex, making it difficult to control and lacking in reliability.

As described above, bias type and charge type transfer devices each have advantages and disadvantages. SUMMARY OF THE INVENTION It is an object of the present invention to provide a transfer device for an electrophotographic copying machine that eliminates the above-mentioned drawbacks and incorporates the advantages of bias-type and charge-type transfer devices.

A feature of this invention is that the transfer drum is constructed by wrapping a flexible transfer paper support sheet around a drum frame body obtained by cutting out a cylinder leaving both ends of the cylinder and a continuous band-like connecting part at both ends. However, the image on the photoreceptor is transferred to the transfer paper by supporting the transfer paper with this transfer drum.

According to this invention, the following effects can be obtained.

() Since the transfer paper is in close contact with the transfer paper support sheet and the transfer paper is reliably conveyed, there will be no color shift even when used in a color copying machine for overlapping transfer.

() Since both ends of the transfer drum body are rigid, it is easy to achieve accuracy and the material is stable.

() The transfer drum body is brought into pressure contact with the photoreceptor, but the pressure contact is only at both ends of the transfer drum body, and the contact pressure in the middle part is low, so even if carrier is mixed in the toner image, the photoreceptor or transfer due to this There is no damage to the drum. In addition, the image quality is good and stable because the hollow phenomenon caused by high contact pressure does not occur.

() The device is easy to manufacture because there is no need to consider the precise distance relationship between the photoreceptor and the transfer drum.

() The structure of the transfer section is simple and small, and the entire copying machine can be made small and simple.

The present invention will be explained below with reference to illustrated embodiments.

First, an outline of a color electrophotographic copying machine equipped with a bias type transfer device will be explained with reference to FIG. The photosensitive drum 1 rotates at a constant speed in a counterclockwise direction. A photoconductive layer is provided on the surface of the photosensitive drum 1, and this surface serves as a corona charger 2.
is uniformly charged to a predetermined polarity. When an original image is projected by the exposure optical system 3 onto the surface of the photoreceptor which retains an electric charge, the electric charge is dissipated according to the density of the image area of the original image, and an electrostatic latent image is formed there.
This electrostatic latent image is visualized by the developing device 4. In the case of a color copying machine, at least three developing devices are provided: a device 5 for yellow development, a device 6 for magenta development, and a device 7 for cyan development. Accordingly, the exposure optical system 3 is equipped with color separation filters having blue, green, and red colors. In addition to this, the developing device may be equipped with a device for black development in order to adjust the image tone.

Development is performed for each color. That is, when a color original image is first projected onto the surface of a photoreceptor using a blue filter, an electrostatic latent image consisting of a yellow component, which is a complementary color to blue, is formed. This is visualized by the yellow developing device 5. The yellow developing device 5 contains a developer consisting of yellow toner and carrier iron powder, and the two are stirred and mixed to be triboelectrically charged, so that the toner has a polarity opposite to that of the electrostatic latent image. charged. The toner and carrier are both attracted to the developing roller 5a and conveyed to a developing position close to the photoreceptor 1. At the development position, only the toner charged to the opposite polarity is attracted to the electrostatic latent image and becomes a visible image.

While the yellow developing device 5 is performing development, the other developing devices 6 and 7 are moving away from the surface of the photoreceptor 1, and the yellow toner image on the photoreceptor moves toward the transfer position.

The transfer drum 8 has the same diameter as the photoreceptor drum 1, and rotates in the same direction and at the same speed at the contact point where it comes into pressure contact with the photoreceptor drum 1, that is, at the transfer position. The transfer drum 8 is electrically conductive, and a bias DC power source 9 is connected to it. The DC power source 9 is connected so that the transfer drum side has a polarity opposite to that of the toner charge. The transfer drum 8 is provided with a transfer paper gripper 10.
The leading edge of the transfer paper 12 fed from the paper feed cassette 11 is held in this claw. The transfer paper is wound onto the drum as the transfer drum rotates, and is brought into close contact with the drum surface by the electric charge on the drum surface. The timing of image formation on the photosensitive drum 1 and the timing of feeding the transfer paper 12 to the transfer drum 8 are synchronized, and the leading edge of the developed image and the leading edge of the transfer paper coincide at the transfer position.

The conductive support under the surface of the photosensitive drum 1 and one pole of the bias power supply 9 are both grounded.
Therefore, at the transfer position, an electric field is generated between the transfer drum 8 and the photoreceptor drum 1 via the transfer paper, and an electric charge having the opposite polarity to the toner is applied from the transfer drum 8 to the transfer paper. The toner image is transferred to the transfer paper.

After the yellow toner image is transferred to the transfer paper, the toner remaining on the photoreceptor drum is removed by a cleaning device 13, and the residual charge is similarly removed by a neutralizing corona charger 14. The surface of the photosensitive drum 1 is uniformly charged again by the charging corona charger 2, and the exposure optical system 3
Exposure is performed using a green filter. The electrostatic latent image is then developed by a magenta developing device 6 and transferred onto transfer paper.

On the other hand, after the yellow image has been transferred to the transfer drum, the charges on the transfer paper are removed by the action of the charge eliminating corona charger 15. The transfer drum continues to rotate and returns to the transfer position without being affected by the stripping claws 16 and the cleaning device 17.

Subsequently, when the cyan image obtained by exposure by the red filter and development by the cyan developing device 7 is transferred to the transfer paper, the gripping claws 10 of the transfer drum come off and release the holding of the leading edge of the transfer paper.
Subsequently, the leading edge of the transfer paper is peeled off from the transfer drum 8 by a peeling claw 16, and the transfer paper is directed to a fixing device 18, where the toner image on the transfer paper is permanently fixed. The transfer drum from which the transfer paper has been removed is cleaned by a cleaning device 17.

Next, the transfer drum used in this invention is transferred to a second transfer drum.
This will be explained with reference to the figures. The drum frame 21 is basically made by cutting a large part of a resin cylinder in the middle, leaving both end parts 22, 23 and a continuous belt-like connecting part 24 parallel to the axis, which is a part of the circumferential surface. It becomes. The width of the part to be cut out is slightly larger than the maximum width of the document to be used. This cut portion is covered by wrapping a conductive or insulating transfer paper support sheet 25 having a width slightly larger than the cut portion from one side of the connecting portion 24 to the other side. The leading and trailing ends of the sheet 25 are fixed to the connecting portion 24 with double-sided adhesive tape or the like. The connecting portion 24 is provided with a notch groove 26 in the longitudinal direction for attaching a transfer paper holding device.

Here, the outline of the transfer paper holding device 27 will be explained with reference to FIG. The groove 26 is located on the transfer paper supply side 2.
4a has an uneven shape with several concave portions 26a and convex portions 26b, and the opposite side 24b has a linear shape. Note that the convex portion is a slope. A shaft 29 whose both ends are supported by both sides of the drum body is disposed in the groove, and a presser pawl 30 is fixed at a position facing the recess 26a of the groove 26. The presser claw 30 is attached to the lower sheet removing portion 30a.
has a width that fits in the recess 26a, and the upper sheet retaining part 30b has the same width as the sheet removing part and its tip is bent downward, and the sheet holding part 30c is on the right side of the upper sheet retaining part 30b, and the convex part of the groove 26 26b. An operating lever 31 is fixed to both ends of the shaft 29, and is controlled by an external cam or the like (not shown). A torsion coil spring 32 provided on the shaft 29 is connected to the operating lever 31 and the connecting portion 2 so that the holding portion 30c of the holding pawl 30 is given a rotational habit in a direction such that the holding portion 30c of the holding claw 30 comes into pressure contact with the convex portion 26b of the groove.
4b.

When the presser pawl 30 is on standby, the presser portion 30c is separated from the convex portion 26b, as shown in FIG. When the transfer sheet S is inserted between the two, the leading edge of the sheet hits the stop portion 30b and stops. Subsequently, when the lever 31 is actuated, the presser portion 30c comes into pressure contact with the convex portion 26b and presses the sheet S, as shown in FIG. When the sheet is to be removed from the drum after the series of steps is completed, the actuating lever 31 is rotated to the opposite side, and the removing portion 30a removes the sheet S from the convex portion 26b as shown in FIG.

Next, an example of a device for supporting the transfer drum configured as described above will be explained with reference to FIG. The transfer drum 41 is provided with three rollers 43, 4 that are in contact with the inner peripheral surface of both ends of the transfer drum provided on a support lever 42.
4,45. The lever 42 extends outside the transfer drum and rotates around a shaft 46 provided in the middle. The shaft 46 is supported by a stationary member (not shown). A tension coil spring 47 is provided at the lower end of the lever 42.
The transfer drum 41 is brought into pressure contact with the photosensitive drum 48.

The coil spring 47 ensures and controls the transfer pressure of the transfer drum 41. Therefore, compared to the conventional method of obtaining the necessary transfer pressure by accurately determining the distance between the axes between the transfer drum and the photoreceptor drum in advance, it is possible to obtain the necessary transfer pressure much more easily and simply. Furthermore, compared to the case where the distance between the axes is determined, there is no fluctuation in the transfer pressure due to eccentricity of the drum, etc. Furthermore, by separating the transfer drum from the photoreceptor drum, the transfer drum and the photoreceptor drum can be easily removed.

FIG. 8 is a sectional view taken along line A-A in FIG. 7. The axial positioning of the transfer drum 41 is performed by engagement between the chevrons on the circumferential surfaces of the rollers 45, 44, and 43 and the V-grooves 49 provided on the inner circumferences of the side portions 22 and 23 of the transfer drum 41. Alternatively, this can be accomplished by using rollers with flanges on both sides, the flanges of which are in contact with both end faces of the drum. The transfer drum 41 is driven by meshing between a gear 51 fixed to a drive shaft 50 of the photosensitive drum 48 and a gear 52 fixed to the outer periphery of one side of the transfer drum.
The transfer drum can also be driven by engagement with a friction wheel. In addition, the said roller can also be provided in contact with the drum side outer circumferential surface, end surface, etc.

FIG. 9 shows a bias type transfer device equipped with the above-described transfer drum and its support device. A conductive sheet is used for the transfer paper support sheet 25 of the transfer drum 41, and the conductive sheet 2
5 is connected to a bias DC power supply 61. The center portion of an L-shaped lever 62 is loosely fitted to the shaft 46, which is the center of rotation of the transfer drum support lever 42, and a squeezing roller 63 is fixed to one end thereof. The other end of the lever 62 is supported by tension coil springs 64 and 65 from both sides.
A solenoid (not shown) is connected to the other end of the spring 65.

Transfer paper sheets 68 and 69 of different sizes are stored in the paper feed cassettes 66 and 67, respectively.
Either one is selected and sent to the transfer drum 41 through the paper feeder 70. The feeding of the transfer paper by the paper feeding device 70 and the rotation of the transfer drum 41 are synchronized, and the leading edge of the fed transfer paper is held in the transfer paper holding device 27 of the transfer drum 41. The transfer paper held in the transfer drum 41 is wound onto the conductive sheet 25 of the drum by the rotation of the transfer drum, and brought into close contact with the sheet by the squeezing roller 63. The leading edge of the transfer paper is on the photoreceptor drum 4.
Upon reaching the contact point with the transfer drum 8, that is, the transfer position, a solenoid connected to the spring 65 is actuated, causing the squeezing roller 63 to separate from the transfer drum. When the first transfer of the image to the transfer paper is completed, the charge on the surface of the transfer paper is removed by the discharge light corona charger 71. Stripping claw 72 and cleaning device 73
is normally away from the transfer drum surface. When the final transfer is completed, the transfer paper holding device 27 removes the leading edge of the transfer paper, and the transfer paper is peeled off from the transfer drum by a peeling claw 72 in contact with the drum, and is sent to a fixing device (not shown). Meanwhile, the surface of the transfer drum is cleaned by a cleaning device 73.

The cleaning device 73 includes a conventionally known scraping roller 74 made of urethane or sponge, a scraping plate 75 in contact with the scraping roller 74, a wiping roller 76 made of rubber or metal, and a cleaner pad in contact with the wiping roller 76. 77, the entire device swings around a shaft 78, and the scraping roller 74 is configured to be able to approach and separate from the surface of the transfer drum. The cleaning device 73 is
Usually separated from the transfer drum. The top of the transfer drum is cleaned when the transfer paper is not held on the transfer drum, that is, from the first transfer paper clamping step to the transfer step at the transfer position, and after the transfer paper is peeled off from the transfer drum.

However, even with such a conventional device, the cleaning effect can be greatly improved by combining it with the transfer drum according to the present invention. This is because the transfer drum is generally contaminated with developer or the like at a location other than where the transfer paper is located on the transfer drum and within the length of the developing roller. In the transfer drum of this invention, the first
As shown by the diagonal lines in FIG. (However, in this example, the length of the developing roller is the same as the width of the sheet 25.) However, in the transfer drum 41 of the present invention, both side portions 22 and 23 and the intermediate connecting portion 24 are rigid, and the remaining portions are rigid. This is a flexible portion made up of a thin sheet 25. Therefore, as shown in FIG.
When the transfer drum 41 is pressed against the transfer drum 41, both sides 22 and 23 of the drum and a connecting portion (not shown) are pressed more strongly than other parts, effectively wiping away dirt adhering to those parts. . Also,
Since the roller 74 does not come into strong pressure contact with the entire surface of the transfer drum, there is little loss of torque during cleaning, which makes the device more economical. Note that the same effect can be obtained by using a cleaning blade instead of the cleaning roller 74, or they may be used in combination.

FIG. 12 shows only the essential parts of another embodiment of the bias type transfer device according to the present invention. In this embodiment, the transfer paper support sheet 25 is lifted from the transfer drum 41 near the transfer position by a transfer surface adjustment lever 81 so that the photoreceptor and the transfer paper come into surface contact during transfer.

During transfer, it is desirable that the photoreceptor and the transfer paper are in surface contact. In bias type transfer, if this is a line contact, transfer omissions are likely to occur. In order to solve this problem, it is necessary to dramatically improve the precision of parts such as the drum, or to use a soft material such as rubber for the transfer drum. In any case, it lacks economic efficiency and stability.

According to this invention, since a special transfer drum is used, even if high transfer pressure is applied to the transfer drum,
This pressure is not applied directly to the middle portion where the transfer paper is located, but rather to both ends thereof. Therefore,
There is no instability in transfer pressure like when using soft rubber, and the stable, low transfer pressure prevents hollow spots during transfer. Further, since the intermediate portion is flexible, it can be lifted and easily brought into surface contact with the photoreceptor.

In the embodiment shown in FIG. 12, the leading end of the transfer paper support sheet 25 is fixed to the transfer drum, while the rear end is movable on the transfer drum. As shown in FIG. 13, a Z-shaped hook 82 is fixed to the rear end of the sheet 25, and this hook 82 comes to engage with a long hole 83 provided in the side portion 23 of the transfer drum. ing. 1st
In FIG. 2, the adjustment lever 81 is rotatably provided on the transfer drum support lever 42, and is given a rotational habit of lifting the sheet 25. A stopper is provided at a suitable position close to the adjustment lever 81, and by adjusting the stopper, the amount of lifting of the sheet, that is, the amount of contact of the sheet with the photoreceptor can be changed. The adjustment lever 81 may be a plurality of blades, for example as shown in FIG.
is fixed to. A lever 8 is attached to both ends of the shaft 84.
A tension coil spring 86 is in contact with one end of the lever 85, and a stopper screw 87 is in contact with the side surface of the other end. By adjusting this screw 87, the lifting angle of the blade 81 can be changed.

FIG. 15 shows a charge type transfer device which is another embodiment of the present invention. The difference from the bias type is that a dielectric sheet is used for the transfer paper support sheet 25, a direct current corona charger 91 for transfer is used instead of the bias power supply, and a A corona charger 92 for static elimination is used. Components common to the bias type transfer device are given the same reference numerals.

The transfer corona charger 91 is connected to the transfer drum 4.
1 is attached to a transfer drum support lever 42 at a position opposite to the inner transfer position. The corona charger 91 is a normal DC corona charger,
Guide member 91a attached to support lever 42
The shield case 91b is removable.

In conventional charge-type transfer devices in which a corona charger is placed inside a dielectric sheet, the positional relationship between the corona charger fixed in a predetermined position and the moving dielectric sheet is fixed, but due to the movement of the dielectric sheet, Their positional relationship may shift, which may also change the transfer characteristics.

In this embodiment, since the transfer corona charger 91 is attached to the lever 42 that supports the transfer drum 41, the positional relationship between the corona charger 91 and the dielectric sheet 25 does not shift, and stable transfer characteristics can be maintained. Obtainable.
Further, by adjusting the mounting position of the corona charger 91, the positional relationship with the dielectric sheet 25 can be easily adjusted, and the mounting is simple, the operability is good, and the support is reliable.

The charge eliminating corona charger 92 is for removing charges on the dielectric sheet 25, and is applied with an alternating current or a voltage in which alternating current and direct current are superimposed. In order to effectively eliminate static electricity, a counter electrode plate 93 is attached to the transfer drum support lever 42 close to the inside of the corresponding transfer drum. Similar to the cleaning device 73, the charge eliminating corona charger 92 is used when the transfer paper is not held on the transfer drum, that is, from the first transfer paper clamping process to the transfer process at the transfer position, and when the transfer paper is peeled off from the transfer drum. It will start working after

In this charge type transfer device as well, as in the bias type described above, the transfer paper support sheet 25 can be lifted using a similar mechanism to bring the transfer paper into surface contact with the photoreceptor 48. In addition, the cleaning effect is also improved.

As mentioned above, publicly known techniques can be employed for the parts not explained in detail in this specification, and various changes can be made to the embodiments within the scope of the spirit of the invention.

[Brief explanation of the drawing]

Fig. 1 is a schematic configuration diagram showing an example of a color copying machine using a bias type transfer device, Fig. 2 is a schematic perspective view of a transfer drum used in the present invention, and Fig. 3 is a schematic diagram showing a color copying machine installed on the transfer drum. 4 to 6 are diagrams for explaining the operation of the transfer paper holding device, FIG. 7 is a schematic diagram of the transfer drum supporting device according to the present invention, and FIG. 8 is a schematic perspective view of the transfer paper holding device according to the present invention. ,
Sectional view taken along line A-A in Figure 7, No. 9
10 is an explanatory diagram showing a contaminated portion of the transfer drum, FIG. 11 is an explanatory diagram illustrating cleaning by a cleaning roller, and FIG. 12 is a diagram illustrating cleaning by a cleaning roller. , Diagram 13 for explaining another embodiment of the present invention
Figures 1 and 14 are diagrams explaining the details.
FIG. 5 is a schematic diagram of a charge type transfer device according to the present invention. 21...Drum body of transfer drum, 25...Transfer paper support sheet, 27...Transfer paper holding device, 41...
...Transfer drum, 42...Transfer drum support lever,
43, 44, 45...Transfer drum support roller, 48
...Photosensitive drum, 63...Stretching roller.

Claims (1)

[Scope of Claims] 1. By rotating a transfer drum whose peripheral surface is in pressure contact with a rotating photoreceptor multiple times together with the photoreceptor, the image on the photoreceptor is transferred to a transfer paper supported by the transfer drum. In an electrophotographic copying machine that performs overlapping transfer, the above-described method is applied to a drum frame body in which a cylinder is cut out leaving only both sides of the cylinder and a band-like connecting part that is continuous with both ends of the cylinder and is a part of the circumferential surface parallel to the axis. a transfer drum configured by wrapping a flexible transfer paper support sheet so as to cover the entire excised portion of the transfer paper; a transfer paper holding means for holding the transfer drum; a transfer drum support means for supporting the transfer drum in a state in which the transfer drum is in pressure contact with the photoreceptor; and a transfer paper support sheet whose leading end is held by the transfer paper support means. A transfer device for an electrophotographic copying machine, comprising: a transfer means for transferring an image on the photoreceptor to a transfer paper wrapped around the transfer paper;