JP3488328B2 - Transfer belt device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transfer device in an electrophotographic device such as a copying machine, a plain paper facsimile, and a printer, and more particularly to a belt charging type transfer belt device.

[0002]

2. Description of the Related Art As a transfer device of this type, for example, a transfer device described in JP-A-5-113725 is known.
This is an endless dielectric belt 60 as shown in FIG.
Is wound around between two rollers 62 and 64, and is driven by one roller 62 so as to circulate in the direction of the arrow. The driving side roller 62 itself serves as a contact electrode for imparting an electric charge to the dielectric belt 60. It is configured. Further, contact electrodes 66 serving as rotating bodies are also provided on the downstream side of the transfer position in the moving direction of the dielectric belt 60. These contact electrodes 62, 66 are bias power sources for setting a potential capable of electrostatically attracting toner. Connected to 68. By adopting the belt system using the bias roller, the ozone generation amount can be reduced as compared with the case where the transfer charger is used, and the cost can be reduced by using the low power supply. Further, by providing the contact electrode 66 not only on the upstream side but also on the downstream side, compared to the case where the bias potential application position is set only at the position where one roller 62 and the photosensitive drum 70 as the image carrier face each other. As a result, the bias range can be expanded, and the transfer unevenness due to the extreme change of the charged electric charge due to the nonuniform resistance value of the dielectric belt 60 can be avoided.

[0003]

Generally, in a structure in which electric charges are applied by a single bias roller, the position where the bias is applied and the position where the transfer electric field is formed are different.
It is difficult to balance the electric field in the transfer area, and the transferability is not so good. In order to improve this, as described above, a configuration has been proposed in which contact electrodes (bias rollers) are provided on both the upstream side and the downstream side of the transfer position, and transferability has been improved to some extent. However, considering that the relationship between transferability and electric field balance is extremely delicate,
Simply providing contact electrodes on the upstream side and the downstream side to expand the bias region does not necessarily mean that the transfer is performed in a state in which the electric field balance is proper, and there is still room for improving transferability. Is expected to exist.

Further, since the untransferred toner on the photosensitive member is easily moved by the influence of the electric field, when the small gap area between the photosensitive member and the transfer belt (dielectric belt) is reached, the condition is satisfied. Depending on the case, the transfer may start before the position where the photoconductor contacts the transfer belt. Therefore, so-called transfer dust occurs when the recording medium contacts the photoconductor and the transfer belt at the transfer start position almost at the same time, or when the recording medium comes into close contact with the transfer belt first and then enters the transfer area. I have something to do. Therefore, when a bias roller is provided on the upstream side of the transfer position for transfer, transfer dust may occur in the vicinity of the entrance of the transfer area, so caution is required. On the other hand, if a structure in which transfer dust is unlikely to occur near the entrance of the transfer area is apt to break the electric field balance in the transfer area, and there is a problem that transferability is likely to deteriorate.

Therefore, an object of the present invention is to provide a transfer belt device capable of further improving transferability. Further, it is an object of the present invention to provide a transfer belt device capable of obtaining an appropriate electric field balance even when the transfer dust is hardly generated near the entrance of the transfer area, and further improving transferability.

[0006]

According to the consideration of the present inventors, there is an optimum value for the electric field balance in the transfer area,
It is presumed that good transferability can be obtained by performing transfer under this optimum value. Based on this idea, as a result of investigating the relationship between the output current from the upstream bias roller (contact electrode) and the output current from the downstream bias roller, the transfer area is obtained from the upstream bias roller and the downstream bias roller. When the total output current value is constant, when the output current value from the bias roller on the upstream side of the transfer area is the same as or slightly smaller than the output current value from the bias roller on the downstream side, the transferability is relatively high (depending on the worm-eating print). Judgment) was good. Further, when the surface potentials on the upstream side and the downstream side of the back side of the transfer belt in the transfer area were measured, it was found that when the transferability was good, the inclination of the surface potential on the back side of the belt at the transfer position in the moving direction of the transfer belt was small. understood.

The present invention, based on these experimental results,
It aims to transfer under the most appropriate electric field balance. Specifically, in the invention according to claim 1, the image carrier comprises an endless dielectric belt, a driving means for circulatingly moving the dielectric belt, and a means for applying an electric charge to the dielectric belt. An apparatus for transferring image information held on a recording medium, wherein the means for applying an electric charge to the dielectric belt is formed as a contact electrode composed of a rotating body for directly applying an electric charge to the dielectric belt. In the transfer belt device in which at least one transfer position is provided on both the upstream side and the downstream side of the transfer position in the moving direction of the dielectric belt, the transfer current value output from the contact electrode on the upstream side and the downstream side Output from the contact electrode of
Equipped with control means for controlling each transfer current value
And the transfer position in the moving direction of the dielectric belt.
Upstream surface potential that detects the surface potential on the back side of the belt
The upstream surface is provided with a detection means and a downstream surface potential detection means.
Based on the values detected by the surface potential detection means and the downstream surface potential detection means
Then, the surface potential is calculated as follows: "upstream surface potential ≤ downstream side
"Surface potential" of the condition is satisfied and the slope between the surface potentials is small.
The configuration is such that the transfer current values on the upstream and downstream sides are controlled so as to be low . According to the second aspect of the present invention, in order to further improve the transferability, in addition to the above-mentioned configuration for obtaining an appropriate electric field balance, a configuration in which transfer dust is unlikely to occur near the entrance of the transfer region is provided. In the invention according to claim 3, an endless dielectric belt and the dielectric belt are circulated.
Drive means for moving and giving electric charge to the dielectric belt
Image holding means on the image carrier
A device for transferring information onto a recording medium, comprising:
The means for applying electric charge to the belt is directly connected to the dielectric belt.
Formed as a contact electrode consisting of a rotating body that gives an electric charge
In the moving direction of the dielectric belt
Distribute at least one on both the upstream and downstream sides of the transcription position.
In the transfer belt device installed, the contact voltage on the upstream side
Transfer current value output from the pole and output from the contact electrode on the downstream side
Equipped with control means to control each transfer current value
In the moving direction of the dielectric belt
Upstream side that detects the surface potential on the back side of the belt at the transfer position
A surface potential detecting means and a downstream surface potential detecting means,
The control means is a recording medium of the above-mentioned recording medium obtained in advance by experiments or the like.
The optimum value of the surface potential at the time of good transferability corresponding to the size,
The upstream surface potential detecting means and the downstream surface potential detecting means
The value that is output from the
It adopts the structure of performing control .

In the invention according to claim 4, the endless dielectric
Body belt and driving hand that circulates the dielectric belt
A step and means for applying an electric charge to the dielectric belt.
The image information stored on the image carrier is recorded on the recording medium.
It is a device that transfers the electric charge to the dielectric belt.
The means for applying directly applies the electric charge to the dielectric belt.
It is formed as a contact electrode consisting of a rotating body
On the upstream side of the transfer position in the moving direction of the dielectric belt
And at least one is installed on both the downstream side and the downstream side.
Output from the contact electrode on the upstream side of the copying belt device
Transfer current value and the transfer voltage output from the downstream contact electrode.
It also has control means to control each flow value
At the transfer position in the moving direction of the dielectric belt.
Upstream surface potential detector that detects the surface potential on the back side of the belt
A step and a downstream surface potential detecting means, the control means,
Corresponding to the paper type of the above-mentioned recording medium obtained in advance by experiments, etc.
The optimum value of the surface potential when the transferability is good and the above-mentioned upstream surface
Output from potential detecting means and downstream surface potential detecting means
A configuration is adopted in which the value is compared and the control is performed to correct the value to the optimum value . In the invention according to claim 5, endless
Circular movement of this dielectric belt and this dielectric belt
Drive means and means for applying an electric charge to the dielectric belt
And record the image information held on the image carrier
A device for transferring onto a medium, in which the dielectric belt is electrically charged.
A means for applying a load directly charges the dielectric belt.
If it is formed as a contact electrode consisting of a rotating body
Both on the transfer position in the moving direction of the dielectric belt
At least one is placed on each of the upstream and downstream sides.
Output from the contact electrode on the upstream side in the transfer belt device
Transfer current value and the transfer current output from the downstream contact electrode.
It is said that it is equipped with a control means for controlling the respective current values.
At the transfer position in the moving direction of the dielectric belt,
Upstream surface potential detection that detects the surface potential on the back side of the belt
Means and a downstream surface potential detection means, and the control means
Is the environment in which the above-mentioned recording medium was obtained in advance through experiments, etc.
The optimum value of the surface potential when the transferability is good corresponding to
Output from the flow side surface potential detection means and the downstream side surface potential detection means.
The control is performed to compare with the input value and correct to the above optimum value.
It has adopted a structure of " u ".

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A reference example of the present invention will be described below with reference to FIG. The image forming apparatus 2 generally includes a photoconductor 4, a developing device 6, and a transfer belt device 8. Around the photoconductor 4, the charger 10 is sequentially arranged in the rotation direction (arrow direction). An exposure unit 12 and a cleaning device 14 are arranged. The surface of the photoconductor 4 is uniformly charged by the charger 10, and then the exposure unit 12 forms an electrostatic latent image. Next, the electrostatic latent image formed on the surface of the photoconductor 4 is visualized as a toner image (negatively charged) by the developing device 6, and the toner image is sent through the registration rollers 16 and 16 at a timing matching the toner image. It is transferred by the transfer belt device 8 to the recording medium 18 (transfer paper) that comes. After transfer,
The residual toner is removed by the cleaning device 14.

The transfer belt device 8 is roughly composed of an endless dielectric belt 20, a bias roller 22 and a driven roller 24 for circulatingly moving the dielectric belt 20. The bias roller 22 also serves as a driving roller in order to shorten the time during which the photoconductor 4 and the dielectric belt 20 are close to each other with a minute gap. A bias roller 26 is provided downstream of the transfer position in the moving direction of the dielectric belt 20.
Also has a function as a backup roller for increasing the nip width. Bias roller 22 located upstream of the transfer position and bias roller 26 located downstream of the transfer position.
Are formed as contact electrodes made of a rotating body, and are individually connected to the transfer power sources 28 and 30, respectively.

The registration roller 1 is provided near the entrance of the transfer area.
There is provided a guide member 32 for forcibly guiding the leading end of the recording medium 18 that has exited 6 and 16 to come into close contact with the photoconductor 4 prior to the dielectric belt 20. The contact position is a transfer position P where the photosensitive member 4 and the dielectric belt 20 are in contact with each other.
It is set at a position P ₁ which is about 5 mm before ₀ .

Therefore, the recording medium 18 enters the transfer area in a state in which the transfer dust is unlikely to occur due to the guide of the guide member 32. When the recording medium 18 reaches the transfer area, the surface of the recording medium 18 is positively charged by dielectric polarization, and the negatively charged toner image is electrostatically adsorbed and transferred.

The transfer current value output from the upstream bias roller 22 and the transfer current value output from the downstream bias roller 26 are set to have the same polarity, and output from the upstream bias roller 22. The transfer current value is set to be the same or smaller in absolute value than the transfer current value output from the bias roller 26 on the downstream side. The reason is based on the experimental results shown below. The content of the experiment is that the total current output from the two transfer power sources 28 and 30 is constant, and the bias roller 2 on the upstream side of the transfer area is set.
2 and the output current value from the bias roller 26 on the downstream side were shaken to examine the transferability (insect-eaten print, paper width in thrust direction = A3 width of plain paper). The results are as shown in Tables 1 to 4 below. The insect-eating print rank is divided into the following 5 stages (the same applies below). 1 ... Almost worm-eaten state 2 ... Quite a lot of worm-eaten parts 3 ... Some worm-eaten parts are here and there 4 ... Slightly worm-eaten parts are present 5 ... No worm-eaten parts Status

[0014]

[Table 1]

[0015]

[Table 2]

[0016]

[Table 3]

[0017]

[Table 4]

As is clear from the above results, when the total output current value from the bias roller 22 on the upstream side of the transfer area and the bias roller 26 on the downstream side is constant, the output current value from the bias roller 22 on the upstream side is constant. Is comparable to or slightly smaller than the output current value from the downstream bias roller 26, the transferability is relatively good. Further, not only the balance of the output current values from the bias roller 22 on the upstream side of the transfer area and the bias roller 26 on the downstream side, but also the absolute values of the respective values greatly influenced the result. By changing the total output current value while maintaining the balance of the output current values from both bias rollers, better transferability corresponding to each paper type can be obtained. This will be described in detail. In addition to the above-mentioned configuration, the control means 33 as shown in FIG. 2 is provided. The control means 33 includes a CPU 34, an upstream transfer current value detection means 36 which outputs a transfer current value (output current value) from the upstream bias roller 22 to the CPU 34, and similarly, a downstream bias roller 26. Transfer current value is C
A downstream transfer current value detecting means 38 for outputting to the PU 34,
The upstream transfer current value varying means 40 for changing the transfer current value from the upstream bias roller 22 based on the output signal from the CPU 34, and the transfer current from the downstream bias roller 26 based on the output signal from the CPU 34. It is composed of a downstream transfer current value changing means 42 for changing the value and a paper type selection key 44.

When the type of the recording medium 18 is input by the paper type selection key 44, the CPU 34 extracts the corresponding one from the optimal electric field balance values corresponding to the respective paper types stored in advance, and this and the upstream / downstream side. Transfer current value detecting means 36, 38
That controls the upstream and downstream side transfer current value varying means 40, 42 by comparing the output value from. In this reference example , two power supplies are used to separately apply the transfer bias to the bias roller 22 on the upstream side of the transfer area and the bias roller 26 on the downstream side. You can share the output from.

Next, according to claim 1 with reference to FIGS. 3 and 4
And shows an embodiment corresponding to 2. The image forming apparatus 46 shown in the present embodiment is provided with a transfer belt device 48, and is different from the transfer belt device 8 in the above-mentioned embodiment in that it is provided with variable transfer power sources 29 and 31 and a dielectric belt. Control means 54 (FIG. 4) having upstream surface potential detection means 50 and downstream surface potential detection means 52 for detecting the surface potential on the back side of the belt at the transfer position in the moving direction of 20.
Is equipped with. The control means 54 is provided with a CPU 56 to which detection values from the upstream surface potential detection means 50 (electrometer probe) and the downstream surface potential detection means 52 (electrometer probe) are input.
The transfer power sources 29 and 31 are adjusted to control the transfer current values on the upstream and downstream sides so that the condition of “upstream surface potential ≦ downstream surface potential” is satisfied and the slope between the surface potentials becomes small. It has become.

The reason for controlling under the above conditions based on the surface potential of the back side of the belt is based on the following experimental results. The content of the experiment was such that the total output current value from the upstream bias roller 22 and the downstream bias roller 26 was constant at 70 μA, and the output current values from the upper / downstream bias rollers 22 and 26 were varied. The transferability (insect-eaten print, paper width in thrust direction = A3 width of plain paper) was examined. The results are shown in Table 5 below.

[0022]

[Table 5]

It can be seen from Table 5 that the transferability is relatively good in the cases of to. Especially when is the best. In addition, the back side of the belt (upstream side surface potential detecting means 50 ...
When the surface potentials at the point A and the downstream surface potential detecting means 52 ... B point) were measured at the same time, the following results were obtained. When A point = 0.1kV, B point = 1.3kV A point = 0.2kV, B point = 1.1kV A point = 0.5kV, B point = 0.9kV A point = When 0.8 kV and B point = 0.6 kV A point = 1.0 kV and B point = 0.3 kV From the above results, when the transferability is good, the dielectric belt 20
It can be seen that the inclination of the surface potential on the back side of the belt at the transfer position in the moving direction is small. As a result, if the output current values from the upstream and downstream bias rollers 29 and 31 are controlled so that the surface potential on the upstream side is equal to or less than the surface potential on the downstream side and the inclination becomes smaller, better transferability is obtained. The conclusion is that it can be obtained.

Next, Table 6 shows the results when the same experiment was performed with the recording medium 18 having a small size (A4 width) in the thrust direction.

[0025]

[Table 6]

As shown in Table 6, it can be seen that the transferability is relatively good when ,. It was also found that when the size of the recording medium 18 in the thrust direction changes, the balance of the output current values from the upstream / downstream bias rollers 29, 31 also changes when the transferability is relatively good. Further, when the surface potentials of the back side of the belt (upstream side surface potential detecting means 50 ... Point A, downstream side surface potential detecting means 52 ... B point) were also measured at the same time, the following results were obtained. When A point = 0.1kV, B point = 0.8kV A point = 0.3kV, B point = 0.6kV A point = 0.4kV, B point = 0.5kV A point = 0.6 kV, point B = 0.3 kV

From the above results, it can be seen that when the transferability is good, the inclination of the surface potential on the back side of the belt at the transfer position in the moving direction of the dielectric belt 20 is small. As a result, when the size of the recording medium 18 changes, the contact area between the dielectric belt 20 and the photoconductor 4 changes, and the balance of the flow of the transfer current also changes, so the output from the upstream bias roller 29 is always present. Although it is not good to set the current value to be equal to or less than the output current value from the bias roller 31 on the downstream side, the surface potential on the back side of the belt is equal to or less than that on the downstream side and the inclination becomes small. It can be seen that better transferability can be obtained by controlling the output current values from the upper and downstream bias rollers 29 and 31.

The CPU 56 of the control means 54 shown in FIG.
In addition, the optimum value of the surface potential when transferability is good under conditions including the size of the recording medium 18 and the paper type, and the environment, etc., which have been obtained in advance by experiments, is input to the upstream side surface potential detecting means. While comparing the output values from 50 and the downstream surface potential detecting means 52, these values are compared with the optimum value,
A control method can also be used (claims 3, 4,
5 ).

FIG. 5 is a graph showing the relationship between the surface potential on the back side of the belt, the output current, and the charge distribution. For the sake of clarity, the potential of the photoconductor 4 and its change are ignored. The charge distribution is limited to the shape (the area is the same). The relationship between the optimum output current value and the surface potential differs depending on the size, type, environment, etc. of the recording medium (transfer paper). Therefore, the optimum value should be grasped in advance by experiments, etc., and controlled based on the results. If this is set, better transferability can be obtained.

[0030]

According to the first aspect of the present invention, since the control is performed based on the surface potential on the back side of the belt, it is possible to achieve an electric field balance in which worming is unlikely to occur and to improve transferability. it can. According to the second aspect of the invention, in addition to the configuration of the first aspect , the guide member is configured to bring the leading end of the recording medium into close contact with the image carrier prior to the dielectric belt. The occurrence of dust can be uniformly suppressed, and the transferability can be further improved. According to the invention of claim 3, 4 or 5 , the optimum value of the surface potential at the time of good transferability under conditions including the size, type, environment, etc. of the recording medium (transfer paper) that has been grasped in advance by experiments or the like. Since it is configured to control in comparison with, it is possible to obtain an accurate electric field balance,
Transferability can be further improved.

[Brief description of drawings]

FIG. 1 is a schematic side view of a transfer belt device showing a reference example of the present invention.

FIG. 2 is a block diagram of control means for controlling a transfer current value in the transfer belt device shown in FIG.

FIG. 3 is a schematic side view of a transfer belt device showing an embodiment of the present invention .

FIG. 4 is a block diagram of control means for controlling a transfer current value in the transfer belt device shown in FIG.

FIG. 5 is a graph showing the relationship between surface potential, output current value, and charge distribution.

FIG. 6 is a schematic side view of a conventional transfer belt device.

[Explanation of symbols]

4 Photoreceptor 18 as Image Carrier 18 Recording Medium 20 Dielectric Belts 22, 26 Bias Rollers 32 as Contact Electrodes 32 Guide Members 33, 54 Control Means 50 Upstream Surface Potential Detecting Means 52 as Surface Potential Detecting Means 52 Surface Potential Detecting Means Downstream surface potential detection means

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-6-167896 (JP, A) JP-A-6-208306 (JP, A) JP-A-5-80664 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) G03G 15/16

Claims (5)

(57) [Claims] 1. An image information held on an image carrier, comprising an endless dielectric belt, a driving means for circulatingly moving the dielectric belt, and a means for applying an electric charge to the dielectric belt. Is a device for transferring an electric charge to the dielectric belt, wherein the means for applying an electric charge to the dielectric belt is formed as a contact electrode composed of a rotating body for directly applying an electric charge to the dielectric belt, and the dielectric belt is also provided. In the transfer belt device in which at least one transfer position is arranged on both the upstream side and the downstream side of the transfer position in the moving direction, the transfer current value output from the contact electrode on the upstream side and the transfer current value on the downstream side.
Controls the transfer current value output from the contact electrode
A control means is provided and the transfer of the dielectric belt is performed.
Check the surface potential on the back side of the belt at the transfer position in the moving direction.
Outgoing surface potential detection means and downstream surface potential detection hand
The upstream surface potential detecting means and the downstream surface potential.
Based on the detection value of the detection means,
Side surface potential ≦ downstream surface potential ”and
Transfer on the upstream / downstream side so that the slope between surface potentials is reduced
A transfer belt device characterized by controlling an electric current value . 2. The transfer belt device according to claim 1, further comprising a guide member for bringing the recording medium into close contact with the image carrier prior to the dielectric belt on the upstream side of the transfer position. 3. An endless dielectric belt and the dielectric bell.
Drive means to circulate the belt and the electric current to the dielectric belt.
And a means for applying a load and held on the image carrier
A device for transferring the recorded image information onto a recording medium.
The means for applying an electric charge to the dielectric belt is the above-mentioned dielectric belt.
As a contact electrode consisting of a rotating body that directly applies an electric charge to the
And the moving direction of the dielectric belt
At least one on both the upstream side and the downstream side.
In the transfer belt unit disposed the increments, together with and a control means for controlling transfer current value that is output from the contact electrode of the transfer current value and the downstream output from the upstream side of the contact electrodes, respectively, the dielectric Body belt transfer
Check the surface potential on the back side of the belt at the transfer position in the moving direction.
Outgoing surface potential detection means and downstream surface potential detection hand
The control means is provided with a step and is obtained in advance by an experiment or the like.
Surface charge when transferability is good corresponding to the size of the above recording medium
Position optimum value, the upstream surface potential detecting means and the downstream table
Compared with the value output from the surface potential detection means, the above optimum
A transfer belt device characterized by performing control to correct the value . 4. An image information held on an image carrier, comprising an endless dielectric belt, a driving means for circulatingly moving the dielectric belt, and a means for applying an electric charge to the dielectric belt. Is a device for transferring an electric charge to the dielectric belt, wherein the means for applying an electric charge to the dielectric belt is formed as a contact electrode composed of a rotating body for directly applying an electric charge to the dielectric belt, and the dielectric belt is also provided. In the transfer belt device in which at least one transfer position is arranged on both the upstream side and the downstream side of the transfer position, the transfer current value output from the upstream contact electrode and the transfer current output from the downstream contact electrode An upstream surface potential detector for detecting the surface potential on the back side of the belt at the transfer position in the moving direction of the dielectric belt is provided with a control means for controlling each current value. Output means and downstream surface potential detector
The control means is provided with a step and is obtained in advance by an experiment or the like.
Surface potential when the transferability is good corresponding to the paper type of the above recording medium
The optimum value of the above, the upstream surface potential detection means and the downstream surface
Compared with the value output from the potential detection means, the optimum value
A transfer belt device, which is characterized by performing control for correction to 5. An endless dielectric belt and the dielectric bell.
Drive means to circulate the belt and the electric current to the dielectric belt.
And a means for applying a load and held on the image carrier
A device for transferring the recorded image information onto a recording medium.
The means for applying an electric charge to the dielectric belt is the above-mentioned dielectric belt.
As a contact electrode consisting of a rotating body that directly applies an electric charge to the
And the moving direction of the dielectric belt
At least one on both the upstream side and the downstream side.
In the transfer belt device arranged one by one, the transfer current value output from the contact electrode on the upstream side and the transfer current value on the downstream side
Controls the transfer current value output from the contact electrode
A control means is provided and the transfer of the dielectric belt is performed.
Check the surface potential on the back side of the belt at the transfer position in the moving direction.
Outgoing surface potential detection means and downstream surface potential detection hand
The control means is provided with a step and is obtained in advance by an experiment or the like.
Surface when transferability is good corresponding to the environment in which the recording medium is used
Optimum value of electric potential and the above-mentioned upstream side surface potential detecting means and downstream side
Compared with the value output from the surface potential detection means,
A transfer belt device characterized by performing control to correct to an appropriate value .