JP6214747B2 - Image forming apparatus - Google Patents

Description

  The present invention relates to an image forming apparatus such as a copying machine or a printer using an electrophotographic system.

  In an electrophotographic image forming apparatus, in order to support various recording materials, a toner image is transferred from a photosensitive member to an intermediate transfer member (primary transfer), and then transferred from the intermediate transfer member to a recording material (secondary transfer). Thus, an intermediate transfer method for forming an image is known.

  Patent Document 1 describes a conventional configuration of an intermediate transfer system. That is, Patent Document 1 has a configuration in which a primary transfer roller is provided for primary transfer of a toner image from a photosensitive member to an intermediate transfer member, and a power source dedicated to primary transfer is connected to the primary transfer roller. Further, Patent Document 1 has a configuration in which a secondary transfer roller is provided for secondary transfer of a toner image from an intermediate transfer member to a recording material, and a power supply dedicated to secondary transfer is connected to the secondary transfer roller. is there.

  Patent Document 2 has a configuration in which a small power source is connected to the secondary transfer inner roller, and another large power source is connected to the secondary transfer outer roller. Japanese Patent Application Laid-Open No. H11-260260 describes that primary transfer for transferring a toner image from a photosensitive member to an intermediate transfer member is performed by applying a voltage to a secondary transfer inner roller with a small power source.

JP 2003-35986 A JP 2006-259640 A

  However, if a power supply dedicated for primary transfer is arranged, there is a risk of increasing costs. There is a demand for a method of suppressing the cost reduction by omitting a power supply dedicated to primary transfer.

In order to solve the above problems, the present invention comprises an image carrier, an intermediate transfer member carrying a toner image primarily transferred from the image carrier by a primary transfer electric field, and a recording material sandwiched with the intermediate transfer member. a transfer member for transferring the secondary to the recording material the toner image from said intermediate transfer member by the secondary transfer electric field, a power source for applying a voltage before Symbol transfer member, a contact member in contact with the inner peripheral surface of the intermediate transfer body ,
In an image forming apparatus comprising a Zener diode connected between the contact member and ground, the secondary transfer electric field and the primary transfer electric field are formed by applying a voltage to the transfer member of the power source, regardless of the size of your Keru recording material in the direction of conveyance to a linear intersects the widthwise direction of the recording material, said Zener diode when the toner image to be transferred and the primary when the secondary transfer is maintained at the Zener breakdown voltage It is characterized by that.

The present invention, in the structure connected to the contact member in contact with the inner peripheral surface of the intermediate transfer member by omitting the power of the primary transfer exclusively for cost down to the Zener diode, regardless of the width direction of the size of the serial Rokuzai Both primary transfer and secondary transfer can be achieved.

1 is a diagram illustrating a basic configuration of an image forming apparatus. It is a figure which shows the relationship between a transfer potential and an electrostatic image potential. It is a figure which shows the IV characteristic of a Zener diode. It is a figure which shows the block diagram of control. It is a figure which shows the relationship between an inflow current and an applied voltage. It is a figure which shows the relationship between a belt potential and an applied voltage. The relationship between the width of the recording material and the belt potential is shown. The relationship between the recording material passing area and the non-passing area is shown. 2 shows a flowchart of the first embodiment. The relationship between the width of the recording material and the applied voltage is shown. 6 shows a flowchart of Embodiment 2.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, what attached | subjected the same code | symbol in each drawing has the same structure or effect | action, The duplication description about these was abbreviate | omitted suitably.

(Embodiment 1)
[Image forming apparatus]
FIG. 1 shows an image forming apparatus according to the present embodiment. The image forming apparatus employs a tandem system in which the image forming units of the respective colors are arranged independently and in tandem. Further, an intermediate transfer system is employed in which a toner image is transferred from an image forming unit of each color to an intermediate transfer member and then transferred from the intermediate transfer member to a recording material.

  The image forming units 101a, 101b, 101c, and 101d are image forming units that form yellow (Y), magenta (M), cyan (C), and black (K) toner images, respectively. These image forming units are arranged from the upstream side in the moving direction of the intermediate transfer belt 7 in the order of the image forming units 101a, 101b, 101c, and 101d, that is, in order of yellow, magenta, cyan, and black.

  Each of the image forming units 101a, 101b, 101c, and 101d includes photoreceptor drums 1a, 1b, 1c, and 1d as photoreceptors (image carriers) on which toner images are formed. The primary chargers 2a, 2b, 2c, and 2d are charging units that charge the surfaces of the photosensitive drums 1a, 1b, 1c, and 1d. The exposure devices 3a, 3b, 3c, and 3sd have a laser scanner, and expose the photosensitive drums 1a, 1b, 1c, and 1d charged by the primary charger. As the output of the laser scanner is turned on / off based on the image information, an electrostatic image corresponding to the image is formed on each photosensitive drum. That is, the primary charger and the exposure unit function as an electrostatic image forming unit that forms an electrostatic image on the photosensitive drum. Each of the developing devices 4a, 4b, 4c, and 4d includes a container that stores toner of each color of yellow, magenta, cyan, and black, and the electrostatic images on the photosensitive drums 1a, 1b, 1c, and 1d are transferred to the toner. It is a developing means that uses and develops.

  The toner images formed on the photosensitive drums 1a, 1b, 1c, and 1d are primarily transferred to the intermediate transfer belt 7 by primary transfer portions N1a, N1b, N1c, and N1d. In this way, the four color toner images are superimposed and transferred onto the intermediate transfer belt 7. The primary transfer will be described in detail later.

  The photosensitive drum cleaning devices 6a, 6b, 6c and 6d remove residual toner remaining on the photosensitive drums 1a, 1b, 1c and 1d without being transferred by the primary transfer portions N1a, N1b, N1c and N1d.

The intermediate transfer belt 7 is a movable intermediate transfer member to which toner images are transferred from the photosensitive drums 1a, 1b, 1c, and 1d. In the present embodiment, the intermediate transfer belt 7 has a two-layer configuration of a base layer and a surface layer. The base layer is on the inner surface side (stretching member side) and is in contact with the stretching member. The surface layer is the outer surface side (image carrier side) and is in contact with the photosensitive drum. The base layer is made of a resin such as polyimide or polyamide, PEN or PEEK, or various rubbers containing an appropriate amount of an antistatic agent such as carbon black. The base layer of the intermediate transfer belt 7 is formed so that the volume resistivity of the base layer is 10 ² to 10 ⁷ Ω · cm. As the base layer in the present embodiment, a film-like endless belt made of polyimide and having a center thickness of about 45 to 150 μm is used. Further, an acrylic coat having a volume resistivity of 10 ¹³ to 10 ¹⁶ Ω · cm in the thickness direction is applied as a surface layer. That is, the resistance of the base layer is lower than the resistance of the surface layer. The thickness of the surface layer is 0.5 to 10 um. Of course, it is not intended to limit to these numerical values.

  The inner peripheral surface of the intermediate transfer belt 7 is stretched by rollers 10, 11, and 12 as stretching members. The roller 10 is driven by a motor as a driving source and functions as a driving roller for driving the intermediate transfer belt 7. The roller 10 is also a secondary transfer inner roller that presses against the secondary transfer outer roller 13 via an intermediate transfer belt. It functions as a tension roller that applies a constant tension to the intermediate transfer belt 7. Further, the roller 11 also functions as a correction roller that prevents the intermediate transfer belt 7 from meandering. The belt tension with respect to the tension roller 11 is configured to be about 5 to 12 kgf. By applying this belt tension, a nip is formed between the intermediate transfer belt 7 and the photosensitive drums 1a to 1d as primary transfer portions N1a, N1b, N1c, and N1d. The secondary transfer inner roller 62 functions as a driving roller that is driven by a motor excellent in constant speed and circulates and drives the intermediate transfer belt 7.

  The recording material is stored in a paper tray that stores the recording material P. The recording material P is taken out from the paper tray by a pickup roller at a predetermined timing and guided to the registration roller. The recording material P is sent out by the registration roller to the secondary transfer portion N2 that transfers the toner image from the intermediate transfer belt to the recording material in synchronization with the conveyance of the toner image on the intermediate transfer belt.

  The secondary transfer outer roller 13 is a secondary transfer member that presses the secondary transfer inner roller 10 via the intermediate transfer belt 7 to form the secondary transfer portion N2 together with the secondary transfer inner roller 13. The secondary transfer outer roller 13 is a secondary transfer unit and holds the recording material together with the intermediate transfer belt. The secondary transfer unit high-voltage power source 22 as a secondary transfer power source is connected to the secondary transfer outer roller 13 and is a power source that can apply a voltage to the secondary transfer outer roller 13.

  When the recording material P is conveyed to the secondary transfer portion N2, a secondary transfer voltage having a polarity opposite to that of the toner is applied to the secondary transfer outer roller 13, whereby the toner image is transferred from the intermediate transfer belt 7 to the recording material. To do.

  The secondary transfer inner roller 10 is made of EPDM rubber. The diameter of the secondary transfer inner roller is set to 20 mm, the rubber thickness is set to 0.5 mm, and the hardness is set to 70 ° (Asker-C). The secondary transfer outer roller 13 is made of an elastic layer made of NBR rubber, EPDM rubber or the like and a cored bar. The diameter of the secondary transfer outer roller 13 is formed to be 24 mm.

  For removing residual toner and paper dust remaining on the intermediate transfer belt 7 without being transferred to the recording material at the secondary transfer portion N2 on the downstream side of the secondary transfer portion N2 in the direction in which the intermediate transfer belt 7 moves. An intermediate transfer belt cleaning device 14 is provided.

[Formation of primary transfer electric field in a single high pressureless system]
In the present embodiment, a power supply dedicated to primary transfer is omitted for cost reduction. Therefore, in this embodiment, the secondary transfer power source 22 is used to electrostatically transfer the toner image from the photosensitive drum to the intermediate transfer belt 7. (Hereinafter, this configuration is referred to as a high-pressure-less system.)
However, in the configuration in which the roller that stretches the intermediate transfer belt is directly connected to the ground, even when the secondary transfer power supply 210 applies a voltage to the secondary transfer outer roller 64, almost no current flows to the stretch roller side. Current may not flow to the photosensitive drum side. In other words, even when the secondary transfer power supply 210 applies a voltage, no current flows to the photosensitive drums 50a, 50b, 50c, and 50d via the intermediate transfer belt 56, and between the photosensitive drum and the intermediate transfer belt, The primary transfer electric field for transferring the toner image does not work.

  Therefore, in order to make the primary transfer electric field action work in the reversing high pressureless system, a passive element is arranged between all of the stretching rollers 60, 61, 62, 63 and the ground so that a current flows to the photosensitive member side. Is desirable.

  As a result, the potential of the intermediate transfer belt becomes high, and a primary transfer electric field works between the photosensitive drum and the intermediate transfer belt.

In order to form a primary transfer electric field in a system without a high-voltage transfer, it is necessary for the current to flow along the circumferential direction of the intermediate transfer belt by applying a voltage from the secondary transfer power supply 210. However, if the resistance of the intermediate transfer belt itself is high, the voltage drop in the intermediate transfer belt in the moving direction (circumferential direction) in which the intermediate transfer belt moves increases. As a result, current may not easily flow to the photosensitive drums 1a, 1b, 1c, and 1d along the circumferential direction of the intermediate transfer belt. Therefore, it is desirable that the intermediate transfer belt has a low resistance layer. In this embodiment, in order to suppress a voltage drop in the intermediate transfer belt, the surface resistivity of the base layer of the intermediate transfer belt is formed to be 10 ² Ω / □ or more and 10 ⁸ Ω / □ or less. In this embodiment, the intermediate transfer belt has a two-layer structure. This is because disposing a high resistance layer on the surface layer makes it easier to suppress the current flowing in the non-image area and further enhance transferability. Of course, the intention is not limited to this configuration. A single-layer structure can be used, and a three-layer structure or more can also be used.

  Next, the primary transfer contrast, which is the difference between the potential of the photosensitive drum and the potential of the intermediate transfer belt, will be described with reference to FIG.

  FIG. 2 shows a case where the surface of the photosensitive drum 1 is charged by the charging unit 2 and becomes a potential Vd (here, −450 V) of the surface of the photosensitive drum. Further, FIG. 2 shows a case where the surface of the charged photosensitive drum is exposed by the exposure means 3 and the surface of the photosensitive drum becomes Vl (here, assumed to be −150 V). The potential Vd is a potential of a non-image portion where no toner is adhered, and the potential Vl is a potential of an image portion where the toner on the photosensitive drum is adhered. Vitb indicates the potential of the intermediate transfer belt.

  The surface potential of the drum is controlled on the basis of the detection result of a potential sensor disposed in the vicinity of the photosensitive drum on the downstream side of the charging and exposure unit and upstream of the developing unit.

  The potential sensor detects the non-image part potential and the image part potential on the surface of the photosensitive drum, controls the charging potential of the charging unit based on the non-image part potential, and controls the exposure light amount of the exposure unit based on the image part potential. To do.

  By this control, the surface potential of the photosensitive drum can be set to an appropriate value for both the image portion potential and the non-image portion potential.

  A developing bias Vdc (in this case, the DC component is −250 V) is applied to the charged potential on the photosensitive drum by the developing device 4, and the negatively charged toner is developed on the photosensitive drum side.

The development contrast Vca, which is the potential difference between the photosensitive drum Vl and the development bias Vdc, is:
−150 (V) − (− 250 (V)) = 100 (V)
It becomes. The electrostatic image contrast Vcb, which is the potential difference between the image portion potential Vl and the non-image portion potential Vd, is
−150 (V) − (− 450 (V)) = 300 (V)
It becomes. The primary transfer contrast Vtr, which is the potential difference between the image portion potential Vl of the photosensitive drum and the potential Vitb (here, 300 V) of the intermediate transfer belt,
300 (V)-(-150 (V)) = 450 (V)
It becomes.

  In the present embodiment, the potential sensor is arranged with an emphasis on the accuracy of detecting the potential of the photosensitive drum. However, the present invention is not intended to be limited to this configuration. Emphasizing cost reduction, the potential sensor is not disposed, and the relationship between the electrostatic latent image forming condition and the potential of the photosensitive drum is stored in the ROM in advance, and then based on the relationship stored in the ROM. It can also be configured to control the potential of the photosensitive drum.

[Zener diode]
In the transfer high pressureless system, the primary transfer is determined by the primary transfer contrast which is a potential difference between the potential of the intermediate transfer belt and the potential of the photosensitive drum. Therefore, in order to stably form the primary transfer contrast, it is desirable to keep the potential of the intermediate transfer belt constant.

  Therefore, in the present embodiment, a Zener diode is used as a passive element disposed between the stretching roller and the ground.

  FIG. 3 shows the current-voltage characteristics of the Zener diode. A Zener diode has a characteristic that current hardly flows until a voltage equal to or higher than the Zener breakdown voltage Vbr is applied, but current rapidly flows when a voltage equal to or higher than the Zener breakdown voltage is applied. That is, in the range where the voltage applied to the Zener diode 15 is equal to or higher than the Zener breakdown voltage, the voltage drop of the Zener diode 15 causes a current to flow so as to maintain the Zener voltage.

  Utilizing such current-voltage characteristics of the Zener diode, the potential of the intermediate transfer belt 7 is kept constant.

  That is, in this embodiment, the Zener diode 15 is disposed as a passive element between all the stretching rollers 10, 11, 12 and the ground.

  In addition, during the primary transfer, the secondary transfer power supply 22 applies a voltage so that the voltage drop of the Zener diode 15 maintains the Zener breakdown voltage. As a result, the belt potential of the intermediate transfer belt 7 can be kept constant during the primary transfer.

  In the present embodiment, 12 Zener diodes 15 having a Zener breakdown voltage standard value Vbr of 25 V are arranged in series between the stretching roller and the ground. That is, in the range where the voltage applied to the Zener diode maintains the Zener breakdown voltage, the potential of the intermediate transfer belt is kept constant at the total Zener breakdown voltage of each Zener diode, that is, 25 × 12 = 300V.

  Of course, the present invention is not intended to be limited to a configuration using a plurality of Zener diodes. A configuration in which only one Zener diode is used may be employed.

  Of course, the surface potential of the intermediate transfer belt is not intended to be limited to 300V. It is desirable to set appropriately according to the type of toner used and the characteristics of the photosensitive drum.

  Thus, when a voltage is applied by the secondary transfer power source 210, the potential of the Zener diode is maintained at a predetermined potential, and a primary transfer electric field is formed between the photosensitive drum and the intermediate transfer belt. Further, similarly to the conventional configuration, when a voltage is applied by the secondary transfer high-voltage power source, a secondary transfer electric field is formed between the intermediate transfer belt and the secondary transfer outer roller.

[controller]
The configuration of a controller that controls the entire image forming apparatus will be described with reference to FIG. As shown in FIG. 4, the controller has a CPU circuit unit 150. The CPU circuit unit 150 includes a CPU, a ROM 151 and a RAM 152. The secondary transfer portion current detection circuit 204 is a circuit (secondary transfer current detection means) for detecting the current flowing through the secondary transfer outer roller, and the stretching roller inflow current detection circuit 205 (zener diode current detection means) This is a circuit for detecting the current flowing into the stretching roller, the potential sensor 206 is a sensor for detecting the potential of the surface of the photosensitive drum, and the temperature / humidity sensor 207 is a sensor for detecting temperature / humidity.

  Information from the secondary transfer portion current detection circuit 204, the stretching roller inflow current detection circuit 205, the potential sensor 206, and the temperature / humidity sensor 207 is input to the CPU circuit portion 150. The CPU circuit unit 150 controls the secondary transfer power source 22, the development high voltage power source 201, the exposure unit high voltage power source 202, and the charging unit high voltage power source 203 in accordance with a control program stored in the ROM 151. An environment table and a paper thickness correspondence table, which will be described later, are stored in the ROM 151 and reflected by being called by the CPU. The RAM 152 temporarily stores control data and is used as a work area for arithmetic processing associated with control.

[Judgment function]
In the present embodiment, a step for determining the lower limit voltage of the voltage applied by the secondary transfer power source for making the surface potential of the intermediate transfer belt equal to or higher than the zener voltage is executed. This will be described with reference to FIG.

  In this embodiment, in order to determine the lower limit voltage, a stretch roller inflow current detection circuit (zener diode current detection means) that detects a current flowing into the ground via the zener diode 15 is used. The tension roller inflow current detection circuit is connected between the Zener diode and the ground. That is, all the stretching rollers are grounded via the Zener diode and the stretching roller inflow current detection circuit.

  As shown in FIG. 3, the Zener diode has a characteristic that almost no current flows when the voltage drop of the Zener diode is less than the Zener breakdown voltage. Therefore, when the tension roller inflow current detection circuit does not detect current, it can be determined that the voltage drop of the Zener diode is less than the Zener breakdown voltage. When the tension roller inflow current detection circuit detects the current, it can be determined that the voltage drop of the Zener diode maintains the Zener breakdown voltage.

  First, the charging voltages of all the stations Y, M, C, and Bk are applied, and the surface potential of the photosensitive drum is controlled to the non-image portion potential Vd.

  Next, the secondary transfer power supply applies a test voltage. The test voltage applied by the secondary transfer power supply is increased linearly or stepwise. In FIG. 5, V1, V2, and V3 are raised in stages. When the voltage applied by the secondary transfer power supply is V1, the stretching roller inflow current detection circuit does not detect current (I1 = 0 μA). When the voltages applied by the secondary transfer power supply are V2 and V3, the stretching roller inflow current detection circuit detects I2 μA and I3 μA, respectively. Here, from the correlation between the applied voltage and the detected current when the tension roller inflow current detection circuit detects the current, the current inflow start voltage V0 corresponding to the case where the current starts to flow is calculated. That is, the current inflow start voltage V0 is calculated by performing linear interpolation from the relationship of I2, I3, V2, and V3.

  By setting a voltage higher than V0 as the voltage applied by the secondary transfer power supply, the voltage drop of the Zener diode can maintain the Zener breakdown voltage.

  FIG. 6 shows the relationship between the voltage applied by the secondary transfer power source and the belt potential of the intermediate transfer belt at this time.

  For example, in this embodiment, the Zener voltage of the Zener diode is set to 300V. Therefore, when the potential of the intermediate transfer belt is less than 300V, no current flows through the Zener diode, and when the belt potential of the intermediate transfer belt reaches 300V, current starts to flow through the Zener diode. Even if the voltage applied by the secondary transfer power supply is further increased, the belt potential of the intermediate transfer belt is controlled to be constant.

  That is, in the range of less than V0 where the current flow into the Zener diode starts to be detected, the belt potential cannot be controlled with a constant voltage when the secondary transfer bias changes. As long as the secondary transfer bias changes, the belt potential can be controlled at a constant voltage within a range exceeding V0 where the current flow into the Zener diode starts to be detected.

  In this embodiment, before and after the current inflow start voltage is used as the test voltage, but it is not intended to be limited to this configuration. By setting a large predetermined voltage as the test voltage in advance, the test voltage can be configured to exceed the current inflow start voltage. Such a configuration has an advantage that the determination step can be omitted.

  In the present embodiment, the determination function for calculating the current inflow start voltage V0 is executed with emphasis on enhancing the accuracy of calculating the current inflow start voltage. Of course, the intention is not limited to this configuration. Instead of executing the determination function for calculating the current inflow start voltage V0 with an emphasis on suppressing the downtime from becoming longer, the current inflow start voltage V0 may be stored in the ROM in advance. .

[Adjustment function for secondary transfer]
In the present embodiment, a function called ATVC (Active Transfer Voltage Control) for applying an adjustment voltage is executed in order to optimize the secondary transfer electric field for transferring the toner image to the recording material. This is an adjustment function for adjusting for secondary transfer, and is executed when the recording material does not pass through the secondary transfer portion. With ATVC, the correlation between the voltage applied by the secondary transfer power supply and the current flowing through the secondary transfer portion can be grasped.

  The adjustment function is performed by the CPU circuit unit 150 controlling the secondary transfer power source when the recording material does not pass through the secondary transfer unit. That is, the CPU circuit unit 150 functions as an execution unit (adjustment unit) that executes an adjustment function for secondary transfer.

  In ATVC as an adjustment function, a plurality of adjustment voltages Va, Vb, and Vc under constant voltage control are applied by a secondary transfer voltage power source. In ATVC, the currents Ia, Ib, and Ic that flow when the adjustment voltage is applied are detected by the secondary transfer portion current detection circuit 204 (secondary transfer current detection means). As a result, the correlation between voltage and current can be grasped.

[Secondary transfer target current setting]
Based on the correlation between the applied adjustment voltages Va, Vb, and Vc and the measured currents Ia, Ib, and Ic, voltages for supplying the secondary transfer target current It necessary for the secondary transfer Vi is calculated. The secondary transfer target current It is set based on the matrix shown in Table 1.

  Table 1 is a table stored in a storage unit provided in the CPU circuit unit 150. This table sets the secondary transfer target current It according to the absolute water content (g / kg) in the atmosphere. The reason for this will be described. As the amount of water increases, the charge amount of the toner decreases. Therefore, the secondary transfer target current is set so as to decrease as the moisture amount increases. That is, as the moisture amount increases, the secondary transfer target current It decreases. The absolute moisture amount is calculated by the CPU circuit unit 150 from the temperature detected by the temperature / humidity sensor 207 and the relative humidity. In this embodiment, the absolute moisture amount is used, but it is not intended to be limited to this. Humidity can be used in place of the absolute water content.

  Here, the voltage Vi for flowing It is a voltage for flowing It when there is no recording material in the secondary transfer portion. However, the secondary transfer is performed when the recording material exists in the secondary transfer portion. Therefore, it is desirable to consider the resistance of the recording material. Therefore, the recording material sharing voltage Vii shared by the recording material is added to the voltage Vi. The recording material sharing voltage Vii is set based on the matrix shown in Table 2.

Table 2 is a table stored in a storage unit provided in the CPU circuit unit 150. This table sets the recording material sharing voltage Vii according to the absolute moisture content (g / kg) in the atmosphere and the basis weight (g / m ² ) of the recording material. As the basis weight increases, the recording material sharing voltage Vii increases. This is because as the basis weight increases, the recording material becomes thicker, and thus the electrical resistance of the recording material increases. Further, as the absolute water content increases, the recording material sharing voltage Vii decreases. This is because when the absolute moisture content increases, the moisture content of the recording material increases, so that the electrical resistance of the recording material increases. Further, the recording material sharing voltage Vii is larger during automatic duplex printing or manual duplex printing than during simplex printing. The basis weight is a unit indicating the weight per unit area (g / m ² ) and is generally used as a value indicating the thickness of the recording material. The basis weight may be input by the user at the operation unit, or the basis weight of the recording material may be input to the storage unit that stores the recording material. Based on these pieces of information, the CPU circuit unit 150 determines the basis weight.

  The voltage (Vi + Vii) obtained by adding the recording material sharing voltage Vii to Vi for flowing the secondary transfer target current It is the secondary transfer of the secondary transfer voltage controlled at a constant voltage during the secondary transfer process following the adjustment function. The target voltage Vt is set by the CPU circuit unit 150. That is, the CPU circuit unit 150 functions as a setting unit that sets the secondary transfer voltage. As a result, an appropriate voltage value is set according to the atmospheric environment and the paper thickness. Further, during the secondary transfer, the set secondary transfer voltage is applied in a state of constant voltage control, so that the secondary transfer is performed stably even if the width of the recording material changes.

[Secondary transfer voltage setting corresponding to the maximum width recording material]
In order to suppress prolonged downtime, it is desirable to perform primary transfer and secondary transfer in parallel. However, when the primary transfer and the secondary transfer are performed in parallel, if the voltage drop of the Zener diode falls below the Zener breakdown voltage, the primary transfer may become unstable.

  Therefore, in order to achieve both primary transfer and secondary transfer, it is desirable that the voltage drop of the Zener diode maintains the Zener breakdown voltage when the recording material passes through the secondary transfer portion.

  However, in the primary transfer high-pressure-less system, as shown in FIG. 7, the relationship between the voltage applied to the secondary transfer member and the belt potential differs depending on the size of the recording material in the width direction in the secondary transfer portion. Here, the width direction is a direction orthogonal to the transport direction in which the recording material is transported. FIG. 7 shows secondary transfer applied voltages and belt potentials of A4R (width direction 210 mm), A4 (width direction 297 mm), and SRA3 (320 mm) as typical recording material sizes for a predetermined type (plain paper) of recording material. Shows the relationship. As shown in FIG. 7, even if the types of recording materials are the same, the voltage necessary for maintaining the belt potential constant increases as the size in the width direction increases.

  The reason for this will be described. This is because the contact width between the secondary transfer roller and the intermediate transfer belt varies depending on the width in the width direction of the recording material as shown in FIG. FIG. 8A is a diagram showing the recording material width in the A3 size and the contact width between the intermediate transfer belt and the secondary transfer outer roller in the non-passing region where the recording material does not pass. As shown in the figure, the width L21 of the recording material and the contact width L1 between the secondary transfer outer roller and the intermediate transfer belt are shown. Next, FIG. 8B is a diagram showing the recording material width in the A4R size and the contact width between the intermediate transfer belt and the secondary transfer roller in the non-passing area. As shown, the recording material width L22 and the contact width L2 between the secondary transfer outer roller and the intermediate transfer belt are shown. As described above, the relationship between the secondary transfer bias applied to the secondary transfer outer roller and the belt potential of the intermediate transfer belt differs depending on the difference in the contact width between the intermediate transfer belt and the secondary transfer roller depending on the recording material size in the width direction. .

  When the width of the recording material is small, that is, when the contact width is large, current easily flows outside the recording material. For this reason, the shared voltage of the recording material decreases, and the voltage applied to the Zener diode tends to increase. On the other hand, when the width of the recording material is large, that is, when the contact width is small, it is difficult for current to flow outside the recording material. For this reason, the shared voltage of the recording material increases, and the voltage applied to the Zener diode tends to decrease. As described above, when the width (area) of direct contact between the secondary transfer roller and the intermediate transfer belt changes, the relationship between the voltage applied to the secondary transfer member and the belt potential varies depending on the width of the recording material.

  When the width of the recording material is large, if the voltage applied to the Zener diode is reduced, the voltage drop of the Zener diode may be lower than the Zener breakdown voltage. As a result, it becomes difficult to achieve both primary transfer and secondary transfer.

  Therefore, in this embodiment, the secondary transfer voltage is set so as to correspond to the width (area) in which the secondary transfer roller and the intermediate transfer belt are in direct contact, which are determined by the recording material having the maximum width. The maximum width recording material is the maximum width recording material among standard sizes that can be handled by the image forming apparatus, and is determined in advance before shipment. In this embodiment, the standard sizes that can be supported by the image forming apparatus are A4R (width direction 210 mm), A4 (width direction 297 mm), and SRA3 (320 mm). Therefore, the recording material with the maximum width is SRA3. Become.

  Of the relationship between the applied voltage and the belt potential shown in FIG. 7, the shared voltage value of the recording material is calculated based on the relationship between the applied voltage and the belt potential when the maximum width recording material (SRA3) is conveyed. Is done. The calculated voltage value is stored in the ROM 151 of the control unit 20 as a shared voltage for all sizes of plain paper. When plain paper is conveyed, it is added to the voltage value corresponding to the target surface current as a resistance change due to the recording material regardless of the width of the recording material. In this way, a secondary transfer voltage is obtained.

  Since the shared voltage of the recording material added to obtain the secondary transfer voltage is calculated from the relationship when the recording material of the maximum width is transported, no matter which width of the recording material is transported The voltage applied to the Zener diode is suppressed from being lowered. The sharing voltage of the recording material is set in the same manner for other types of recording materials. That is, for other types of recording materials, the shared voltage of the recording material is calculated based on the relationship when the recording material having the maximum width is conveyed.

  FIG. 9 shows a flowchart.

  Prior to the operation of the image forming apparatus, the recording material size and type used from the touch panel or the like are selected by a user instruction (Step 1). Next, when the start button of the image forming apparatus is pressed (Step 2) and the image forming operation is started, the flow of determining the secondary transfer bias is started in a state where the recording material is not conveyed. First, a plurality of secondary transfer biases are applied to the secondary transfer part (Step 3). The secondary transfer voltage corresponding to the target current is determined from the detected current with respect to the applied voltage (Step 4). Further, the Zener diode inflow current at the secondary transfer voltage determined in Step 4 is detected to check whether the belt potential is stable (Step 5).

  The voltage value determined in accordance with the recording material type stored in advance is added to the voltage value determined in Step 4 (Step 6). The voltage value added in Step 6 is applied to the secondary transfer roller as a secondary transfer voltage at the time of recording material in accordance with the recording material timing of the recording material (Step 7), and the toner image is transferred from the intermediate transfer belt to the recording material. The secondary transfer operation is performed (Step 8). Next, if the recording material is continuously fed, the process returns to Step 6 (Step 8), and if the recording material type can be changed, the process returns to Step 1 (Step 9). If it is finished as it is, the image forming operation is finished (Step 10).

  As described above, in the configuration of the one-roll high-voltage-less system, the transfer at the primary transfer portion when the secondary transfer onto the recording material is performed by determining the applied voltage of the secondary transfer roller by the maximum recording material width to be recorded. Transfer defects due to insufficient contrast can be prevented.

(Embodiment 2)
The description overlapping with the first embodiment will be omitted. Differences from the first embodiment will be described.

  In Embodiment 1, the voltage determined based on the maximum width of the recording material is used to obtain the secondary transfer voltage regardless of the size of the recording material to be conveyed. Since it is not necessary to set the voltage for each size, there is an advantage that the setting is simplified.

  In Embodiment 2, a voltage value determined according to the width of the recording material is selected according to the size of the recording material to be conveyed and used to obtain a secondary transfer voltage. There is a merit that the secondary transfer roller is prevented from being applied with an excessive voltage and the life of the secondary transfer outer roller is extended.

In this embodiment, the resistance value of the secondary transfer roller is adjusted to a value of about 1 × 10 ⁶ to 1 × 10 ¹⁰ (Ω). As the rubber material, general rubbers such as nitrile butadiene rubber (NBR), ethylene propylene rubber (EPM, EPDM), epichlorohydrin rubber (CO, ECO), and foams thereof are used. Furthermore, what mix | blended the ion conductive type material is used as a electrically conductive material.

  It is known that the resistance of the ion conductive transfer roller is likely to vary depending on the temperature and humidity in the machine, the energization time, and the applied voltage. If the voltage applied to the secondary transfer roller is high, the resistance increase of the secondary transfer outer roller is accelerated, which may shorten the life.

  Therefore, it is desirable to extend the life of the secondary transfer roller by selecting the secondary transfer applied voltage corresponding to the recording material width.

  FIG. 10 is a graph for explaining the relationship between the secondary transfer voltage and the belt potential. Here, in order to simplify the explanation, explanation will be made focusing on a typical recording material width.

  As shown in FIG. 10, the relationship between the belt potential and the secondary transfer bias in A4R, A4, and SRA3 is different as described in the first embodiment.

  Here, the secondary transfer bias corresponding to A4R is V21, the secondary transfer bias corresponding to A3 is V22, and the secondary transfer bias corresponding to SRA3 is V23.

  Therefore, the shared voltage of the recording material is determined for each width of the recording material. That is, the setting of the shared voltage differs depending on the width of the recording material. Even if the types are the same, the sharing voltage of the recording material having a small width is set to be small, and the sharing voltage of the recording material having a large width is set to be large. Then, each shared voltage is added to a voltage value corresponding to the target surface current as a resistance change due to the recording material. In this way, a secondary transfer voltage is obtained.

  In the present embodiment, the recording material shared voltage added to the secondary transfer voltage is a voltage value calculated based on the relationship when the recording materials of the respective widths are conveyed. Regardless of the width of the recording material to be conveyed, the voltage applied to the Zener diode is suppressed from being lowered.

  Since the shared voltage of the recording material added to obtain the secondary transfer voltage is calculated from the relationship when the recording material of each width is transported, any recording material of any width is transported The voltage applied to the Zener diode is suppressed from being lowered.

  FIG. 11 shows a flowchart.

  Prior to the operation of the image forming apparatus, the recording material size and type used from the touch panel or the like are selected by a user instruction (Step 1).

  Next, when the start button of the image forming apparatus is pressed (Step 2) and the image forming operation is started, the flow of determining the secondary transfer bias is started in a state where the recording material is not conveyed. First, a plurality of secondary transfer biases are applied to the secondary transfer part (Step 3).

  The secondary transfer voltage corresponding to the target current is determined from the detected current with respect to the applied voltage (Step 4). Further, the Zener diode inflow current at the secondary transfer voltage determined in Step 4 is detected to check whether the belt potential is stable (Step 5).

  Here, the voltage value determined in accordance with the recording material type stored in advance by the recording material width selected in Step 1 is added to the voltage value determined in Step 4 (Step 6). The voltage value added in Step 6 is applied to the secondary transfer roller as a secondary transfer voltage in accordance with the timing when the recording material passes (Step 7), and the secondary transfer operation in which the toner image is transferred from the intermediate transfer belt to the recording material. Is performed (Step 8). Next, if the recording material is continuously conveyed, the process returns to Step 7 (Step 9), and if the type of the recording material can be changed, the process returns to Step 1 (Step 10). If it is finished as it is, the image forming operation is finished (Step 11).

  The above is the embodiment 2, but the width in the width direction of the selected recording material type is automatically detected by placing a recording material width detection sensor on the conveyance path from the recording material tray to the secondary transfer unit. Is also possible.

  In the first and second embodiments, the secondary transfer voltage is selected before image formation. However, it is not intended to limit to this configuration. It is also possible to combine this configuration with a control for detecting the Zener inflow current when the recording material passes through the secondary transfer portion and correcting the secondary transfer voltage each time it is detected. If there is no current value that flows into the zener diode while the recording material passes through the secondary transfer portion, it means that the belt potential has not reached the zener potential, so the secondary transfer voltage is set to increase the belt potential. It is also possible to give feedback.

As described above, in the present embodiment, regardless of the width direction of the size of the serial Rokuzai, it is possible to achieve both the primary transfer and secondary transfer. Further, since the voltage corresponding to the recording material width is selected, it is possible to suppress an increase in resistance of the secondary transfer roller even when recording materials having a small size continue in the width direction.

  In the present embodiment, an image forming apparatus that forms an electrostatic image by an electrophotographic method has been described. However, the present invention is not intended to be limited to this configuration. An image forming apparatus that forms an electrostatic image by an electrostatic force method instead of the electrophotographic method can be provided.

Claims (4)

An image carrier;
An intermediate transfer member carrying a toner image primarily transferred from the image carrier by a primary transfer electric field ;
A transfer member that sandwiches the recording material together with the intermediate transfer member and secondarily transfers a toner image from the intermediate transfer member to the recording material by a secondary transfer electric field ;
A power source for applying a voltage before Symbol transfer member,
A contact member that contacts the inner peripheral surface of the intermediate transfer member;
A zener diode connected between the contact member and ground;
In an image forming apparatus comprising:
The secondary transfer electric field and the primary transfer electric field are formed by applying a voltage to the transfer member of the power source,
Regardless of the size of your Keru recording material in the direction of conveyance to a linear intersects the widthwise direction of the recording material, said Zener diode when the toner image to be transferred and the primary when the secondary transfer is maintained at the Zener breakdown voltage An image forming apparatus.   The image forming apparatus according to claim 1, further comprising a Zener diode current detection unit configured to detect a current flowing through the Zener diode. The contact member is an image forming apparatus according to claim 1 or 2, characterized in the Turkey Kas Zhang said intermediate transfer member.   4. The image according to claim 1, wherein the intermediate transfer member has a structure of two or more layers, and the resistance of the surface layer on the image carrier side is higher than the resistance of other layers. 5. Forming equipment.