JP5572607B6 - Transfer device and image forming apparatus - Google Patents

Description

  The present invention provides a transfer material in which a visible image on the surface of a latent image carrier is held on the front surface of the belt member or on this while supplying a transfer bias to the back surface of the belt member that moves endlessly by a transfer brush. The present invention relates to a transfer brush used in a transfer device that transfers to a sheet. The present invention also relates to a transfer apparatus using such a transfer brush, and an image forming apparatus such as a copying machine, a facsimile, and a printer.

  Conventionally, in this type of image forming apparatus, as a transfer brush as a brush member, a conductive brush portion made up of a plurality of raised brushes erected on the surface of a metal support plate has a predetermined electric resistance. Is generally used. As the plurality of raised brushes constituting the brush portion, those made of conductive rayon or nylon are used as disclosed in Patent Document 1. In the transfer brush having such a configuration, it is easy to cause vertical black streaks as shown in FIG. 24 to appear in the halftone portion (halftone portion) of the output image. This vertical black stripe is formed so as to extend in the moving direction of the belt member (in the direction of arrow E in the figure), and has a pattern as if it was scratched by the brushed brush.

  Further, the present inventor has found that some image forming apparatuses using the transfer brush as described above are likely to cause an abrupt image density change in the halftone portion of the output image. As shown in FIG. 25, this abrupt change in image density means that the image density of the halftone portion of the output image increases sharply at a predetermined position in the moving direction of the belt member (the direction of arrow E in the figure). It is a phenomenon that becomes. In the figure, the portion where the image density has suddenly changed in the output image is shown enlarged, but this portion is near the rear end of the transfer material in the conveyance direction. For example, when a drum-shaped photosensitive member having a diameter of 100 [mm] is used as the latent image carrier, an abrupt image density change occurs around 314 [mm] from the leading edge of the A3 size paper.

  On the other hand, when this inventor earnestly researched about the cause which produces the above-mentioned vertical black stripe, it discovered the following. That is, the plurality of raised portions in the brush portion of the transfer brush each have a certain degree of variation in the electric resistance value. In the transfer brush having a relatively small variation, a current is allowed to flow almost uniformly from each raised portion toward the belt member. However, in a transfer brush with a relatively large variation in electrical resistance value, raising with a small electrical resistance value gives priority to a current flow over raising with a large electrical resistance value. Then, this current flows to the latent image carrier such as a photoconductor via the belt member, and the surface of the latent image carrier is reversely charged in a streak shape. This streak-shaped reversely charged portion generated in the latent image carrier is not sufficiently neutralized by the neutralization lamp. For this reason, on the surface of the latent image carrier that is uniformly charged after static elimination, the potential of the portion that has been reversely charged in a streak shape before static elimination is considerably lower than the other locations. In the developing process, a larger amount of developing material (for example, toner) adheres to the former part than in the latter part, thereby appearing as vertical black stripes.

  The inventor has also found that the abrupt image density change described above appears at the following position. That is, at the point where the surface of the latent image carrier such as a photoconductor has just made one turn after the transfer bias is applied to the transfer brush, the visible image is transferred from the latent image carrier. is there. The change in image density appears at this position because the charge due to the excessive leakage of current from the transfer brush to the latent image carrier via the belt member is not sufficiently eliminated in the static elimination process, so This is because the uniform charging potential on the body surface is lower than usual.

  Furthermore, the present inventor has found through experiments described later that when the transfer brush having a relatively low electrical resistance value is used, the above-described sudden change in image density is likely to occur.

  The present invention has been made in view of the above background, and an object of the present invention is to provide a brush member capable of suppressing vertical black stripes and a rapid change in image density as compared with the prior art, and a transfer apparatus using the same. And an image forming apparatus.

In order to achieve the above object, the invention of claim 1 is directed to a belt device that moves an endless belt member endlessly while being stretched by a plurality of stretching members, and a plurality of raised hairs and a loop of the belt member. A transfer brush disposed so as to be in contact with the back surface which is an inner surface, and a transfer bias applied to the transfer brush is guided from the transfer brush to the back surface of the belt member, A transfer device for transferring a visible image carried on the surface of the image carrier in contact with the surface to the front surface of the belt member or a transfer material held by the belt member, wherein a plurality of the transfer brushes Each of the raised brushes is made of a material in which a conductive resistance adjusting agent is dispersed in a polyamide resin, and is brought into contact with the entire area of the brush surface that is a contact area with the belt member in the transfer brush. A stainless steel (SUS304) holding member for holding the transfer brush is connected via an ammeter by connecting a Tenres (SUS304) electrode and a bias power source via an electric resistance of 20 [MΩ]. In the state of ground connection, a DC bias of 2 [kV] is applied between the electrical resistance and the holding member by the bias power source, and the current value when 1 minute has passed after the application is used as the brush VI value. The value obtained by converting the brush VI value obtained by reading from the meter per unit area of the brush surface is 4.3 [μA / cm ² ] or less, and the entire area of the brush surface in the belt member moving direction is And a small electrode that contacts the brush surface in the belt member width direction with a length of 10 mm is brought into contact with one end portion of the brush surface in the belt member width direction. The bias power source is connected to the small electrode and the bias power source with an electric resistance of 20 [MΩ] interposed therebetween, and the holding member holding the transfer brush is grounded via an ammeter. After applying a DC bias of 2 [kV] between the electric resistance and the holding member, the small electrode is moved from one end side to the other end side in the belt member width direction at a speed of 10 [mm / sec]. The maximum value of the plurality of scan currents obtained by sequentially reading the current value of the ammeter as a scan current at a time interval of 100 [times / sec] while being moved is converted per unit area of the brush surface. value is, it is 56.5 [μA / cm2] or less, in a state of detaching the transfer brush, of the entire area in the circumferential direction of the belt member, the image bearing member and the above belt member A metal roller is brought into contact with a region downstream of the contact portion in the belt moving direction and in contact with the transfer brush before removal, a bias power source is connected to the metal roller, and a plurality of the tension members are connected. Among them, an electric wire that is disposed on the upstream side in the belt movement direction with respect to the contact portion and connected to a stretching member adjacent to the metal roller on the upstream side in the belt movement direction, and an electric wire connected to the image carrier And an electric resistance of 20 [MΩ] is interposed between the connecting portion and the image carrier, and the connecting portion is connected to the ground via an ammeter, and the belt member and the image carrier. When a DC bias of 2 [kV] is applied between the metal roller and the ammeter by the bias power source while driving at the same linear speed as that at the time of the print job, and 1 minute has elapsed after the application. In The belt VI values obtained by the work of reading from the ammeter as belt VI value current values, value converted per unit area of the belt surface of the belt member, 0.18~3.5 [μA / cm ² ], the transfer current applied to the transfer brush is 110 to 200 [μA], and the belt member is made of a conductive resin on the front surface side of a belt base made of conductive rubber. A surface layer is formed, the surface resistivity on the back side is 10 ⁷ to 10 ¹⁰ [Ω / □] in JISK6911, and the surface resistivity on the front side is 10 ⁸ to 10 ¹³ [Ω in JISK6911. / □], and its volume resistivity is 10 ⁷ to 10 ¹¹ [Ω · cm] according to JISK6911.
According to a second aspect of the present invention, there is provided a belt device that moves an endless belt member endlessly while being stretched by a plurality of tension members, and a back surface that is provided with a plurality of raised portions and that is the inner surface of the loop of the belt member. A transfer brush arranged to be in contact with the transfer brush, and a transfer bias applied to the transfer brush is guided from the transfer brush to the back surface of the belt member while contacting the front surface of the belt member. A transfer device for transferring a visible image carried on the surface of the image carrier to a front surface of the belt member or a transfer material held by the belt member, wherein the plurality of raised brushes on the transfer brush are respectively Stainless steel (SUS3) made of a material in which a conductive resistance adjusting agent is dispersed in a polyamide resin, and in contact with the entire area of the brush surface, which is a contact area with the belt member in the transfer brush. 4) Connect the electrode made of the product and the bias power source via an electric resistance of 20 [MΩ], and connect the holding member made of stainless steel (SUS304) holding the transfer brush to the earth via an ammeter. In this state, a DC bias of 2 [kV] is applied between the electric resistance and the holding member by the bias power source, and the current value when 1 minute has elapsed after the application is used as the brush VI value from the ammeter. A value obtained by converting the brush VI value obtained by the reading operation per unit area of the brush surface is 4.3 [μA / cm ² ] or less, and is in contact with the entire area of the brush surface in the belt member moving direction. At the same time, a small electrode that contacts the brush member in the belt member width direction at a length of 10 mm is brought into contact with one end portion of the brush surface in the belt member width direction, and the small electrode and via A power source is connected via an electric resistance of 20 [MΩ], and the holding member for holding the transfer brush is connected to the ground via an ammeter, and the electric resistance and the power are supplied by the bias power source. After applying a DC bias of 2 [kV] to the holding member, the small electrode is moved from one end side to the other end side in the belt member width direction at a speed of 10 [mm / sec] Dividing the average value with respect to a value obtained by subtracting the average value from the maximum value of the plurality of scan current values obtained by sequentially reading the current value of the ammeter as a scan current at a time interval of 100 [times / sec] Ripple, which is a value obtained by multiplying 1 and 100, is less than 34 [%], a transfer current applied to the transfer brush is 110 to 200 [μA], and the belt member is conductive. Go Surface layer made of a conductive resin is formed on the front surface side of the belt substrate made of, the surface resistivity of the back surface side, at ^{10 7 ~10 10 [Ω / □} ] In K6911, the front surface The surface resistivity on the side is 10 ⁸ to 10 ¹³ [Ω / □] in JISK6911, and the volume resistivity is 10 ⁷ to 10 ¹¹ [Ω · cm] in JISK6911. .
According to a third aspect of the present invention, there is provided a belt device that moves an endless belt member endlessly while being stretched by a plurality of tension members, and a back surface that is provided with a plurality of raised portions and that is the inner surface of the loop of the belt member. A transfer brush arranged to be in contact with the transfer brush, and a transfer bias applied to the transfer brush is guided from the transfer brush to the back surface of the belt member while contacting the front surface of the belt member. A transfer device for transferring a visible image carried on the surface of the image carrier to a front surface of the belt member or a transfer material held by the belt member, wherein the plurality of raised brushes on the transfer brush are respectively It is made of a material in which a conductive resistance adjusting agent is dispersed in a polyamide resin, and after attaching metal clips to both ends of the raised brush, the distance between the clips is adjusted to adjust the distance between 100 to Applying a tension of 00 [gf], a bias of 200 [V] was applied between both clips in this state, and the unit length of the above-mentioned raising determined based on the result of reading the current value one minute later with an ammeter The electrical resistance value in the vicinity is 3.0 × 10 ¹⁰ [Ω / mm] or more, and contacts the entire area of the brush surface in the belt member movement direction, and 10 mm in the belt member width direction of the brush surface. A small electrode that contacts with the length of the belt member width direction of the brush surface, and connects the small electrode and the bias power source with an electric resistance of 20 [MΩ] interposed therebetween, and After the holding member holding the transfer brush is grounded via an ammeter, a DC bias of 2 [kV] is applied between the electric resistance and the holding member by the bias power source, Electric While moving the pole from one end side to the other end side in the belt member width direction at a speed of 10 [mm / sec], the current value of the ammeter is sequentially set as a scan current at a time interval of 100 [times / sec]. A value obtained by converting a maximum value of the plurality of scan currents obtained by the reading operation per unit area of the brush surface is 56.5 [μA / cm 2] or less, and the belt member in the transfer brush is in contact with the belt member. A stainless steel (SUS304) electrode that is in contact with the entire area of the brush surface, which is a contact area, and a bias power source are connected via an electrical resistance of 20 [MΩ] and the transfer brush is held. 2) a DC via of 2 [kV] between the electrical resistance and the holding member by the bias power source in a state where the made holding member is grounded via an ammeter. A value obtained by converting the brush VI value obtained by reading from the ammeter as a brush VI value a current value when 1 minute has elapsed after application is converted per unit area of the brush surface, 4.3 [μA / cm ² ] or less, and with the transfer brush removed, out of the entire area in the circumferential direction of the belt member, the belt movement direction is more than the contact portion between the image carrier and the belt member. A metal roller is brought into contact with an area that is in contact with the transfer brush before removal and a bias power source is connected to the metal roller, and more than the contact portion of the plurality of stretching members. An electric wire that is disposed upstream of the belt movement direction and that is adjacent to the metal roller on the upstream side of the belt movement direction is connected to an electric wire connected to the image carrier. An electrical resistance of 20 [MΩ] is interposed between the connecting portion and the image carrier, the connecting portion is connected to the ground via an ammeter, and the belt member and the image carrier are printed. The current value when 1 minute has elapsed after the application of a DC bias of 2 [kV] between the metal roller and the ammeter by the bias power source while driving at the same linear velocity as the job. Is a value obtained by converting the belt VI value obtained by reading from the ammeter as a belt VI value per unit area of the belt surface of the belt member is 0.18 to 3.5 [μA / cm ² ]. The transfer current applied to the transfer brush is 110 to 200 [μA], and the belt member is a surface layer made of conductive resin on the front surface side of a belt base made of conductive rubber. Formed Is, the surface resistivity of the back surface side, at ^{10 7 ~10 10 [Ω / □} ] In K6911, the surface resistivity of the table surface side, at ^{10 8 ~10 13 [Ω / □} ] In K6911 The specific volume resistivity is 10 ⁷ to 10 ¹¹ [Ω · cm] according to JISK6911.
According to a fourth aspect of the present invention, there is provided a belt device that moves an endless belt member endlessly while being stretched by a plurality of tension members, and a back surface that is provided with a plurality of raised portions and that is the inner surface of the loop of the belt member. A transfer brush arranged to be in contact with the transfer brush, and a transfer bias applied to the transfer brush is guided from the transfer brush to the back surface of the belt member while contacting the front surface of the belt member. A transfer device for transferring a visible image carried on the surface of the image carrier to a front surface of the belt member or a transfer material held by the belt member, wherein the plurality of raised brushes on the transfer brush are respectively It is made of a material in which a conductive resistance adjusting agent is dispersed in a polyamide resin, and after attaching metal clips to both ends of the raised brush, the distance between the clips is adjusted to adjust the distance between 100 to Applying a tension of 00 [gf], a bias of 200 [V] was applied between both clips in this state, and the unit length of the above-mentioned raising determined based on the result of reading the current value one minute later with an ammeter The electrical resistance value in the vicinity is 3.0 × 10 ¹⁰ [Ω / mm] or more, contacts the entire area of the belt surface in the belt member movement direction of the brush surface, and 10 mm in the belt member width direction of the brush surface. A small electrode that is in contact with the brush member at one end in the belt member width direction of the brush surface, the small electrode and the bias power source are connected with an electric resistance of 20 [MΩ] interposed therebetween, and After the holding member holding the transfer brush is grounded via an ammeter, a DC bias of 2 [kV] is applied between the electric resistance and the holding member by the bias power source, and then the small electrode The current value of the ammeter is sequentially read as a scan current at a time interval of 100 [times / sec] while moving at a speed of 10 [mm / sec] from one end side to the other end side in the belt member width direction. The ripple which is a value obtained by dividing the average value and multiplying by 100 with respect to the value obtained by subtracting the average value from the maximum values of the plurality of scan current values obtained by the work is less than 34%. A stainless steel (SUS304) electrode that is in contact with the entire area of the brush surface that is a contact area with the belt member in the transfer brush, and a bias power source are connected via an electric resistance of 20 [MΩ], and A stainless steel (SUS304) holding member for holding the transfer brush is grounded via an ammeter and the electric resistance and the holding member are The brush VI value obtained by the operation of applying a DC bias of 2 [kV] in between and reading the current value from the ammeter as the brush VI value when 1 minute has elapsed after the application is used as the unit of the brush surface The value converted per area is 4.3 [μA / cm ² ] or less, the transfer current applied to the transfer brush is 110 to 200 [μA], and the belt member is made of conductive rubber. A surface layer made of a conductive resin is formed on the front surface side of the belt substrate made of JIS K6911 and has a surface resistivity of 10 ⁷ to 10 ¹⁰ [Ω / □]. The surface resistivity on the side is 10 ⁸ to 10 ¹³ [Ω / □] in JISK6911, and the volume resistivity is 10 ⁷ to 10 ¹¹ [Ω · cm] in JISK6911. .
According to a fifth aspect of the present invention, in the transfer device according to any one of the first to fourth aspects, a transfer roller that rotates while contacting the back surface of the belt member is provided, and the brush member is disposed in the circumferential direction of the belt member. Of the entire area, the transfer roller is in contact with a belt extending region between the transfer roller and a stretching member that stretches the belt member on the upstream side in the belt moving direction. .
According to a sixth aspect of the present invention, there is provided the transfer device according to the fifth aspect, wherein the brush member is disposed in a region in the belt extension region downstream of the contact region between the belt member and the image carrier in the belt moving direction. It is made to contact | abut.
The invention according to claim 7 is the transfer device according to any one of claims 1 to 6, wherein the brush member has a moisture content of 9.0% or less in an environment of 20 ° C. and 95% RH as the brush member. It is characterized by using a certain thing.
The invention of claim 8 is characterized in that, in the transfer device of claim 7, the raised hair is one in which carbon is uniformly dispersed in the cross-sectional direction.
The invention of claim 9 is the transfer device according to any one of claims 1 to 8, wherein the endless belt member is stretched endlessly while being stretched by a plurality of tension members, and the brush portion of the transfer brush The front end side of the belt member is brought into contact with the back surface, which is the inner surface of the loop of the belt member, and the transfer bias applied to the transfer brush is guided from the front end side of the brush portion to the back surface of the belt member. A visible image of the surface of the image carrier that is in contact with the surface is transferred to the front surface of the belt member or a transfer material held by the belt member. Of the two equally divided regions, the maximum value of the image carrier side scan current, which is the scan current value measured using an insulating tape attached to a region located closer to the image carrier But on It is characterized in that less than the maximum value of the scan current measured by using the small electrode that is not adhered to the insulating tape.
The invention according to claim 10 is an image carrier that carries a visible image on a surface that moves endlessly, a latent image forming unit that forms a latent image on the surface, and a developing unit that develops the latent image on the surface. An image forming apparatus comprising: a transfer unit that transfers a visible image obtained by development onto a front surface of a belt member that moves endlessly or a transfer material held by the belt member. The transfer apparatus according to any one of 9 is used.
According to an eleventh aspect of the present invention, in the image forming apparatus according to the tenth aspect, the transfer device having an effective transfer charge density of 1.06 × 10 ⁻⁷ [C / cm ² ] or less is used. It is a feature.
According to a twelfth aspect of the present invention, in the image forming apparatus according to the tenth aspect, the transfer charge density from the power source that outputs a transfer bias applied to the belt member is larger than the effective transfer charge density and is 2 .67 × 10 ⁻⁷ [C / cm ² ] or less is used.
The image forming apparatus according to claim 13 is the image forming apparatus according to claim 10, wherein a transfer charge density from a power source that outputs a transfer bias applied to the belt member is 5.87 × 10 ⁻⁸ [C / Cm ² ] and 2.67 × 10 ⁻⁷ [C / cm ² ] or less .

The present inventor conducted an experiment to examine the relationship between the electrical resistance characteristics, vertical black stripes, and abrupt image density change using a plurality of transfer brushes that exhibit various electrical resistances. The electrical resistance characteristics were evaluated based on the brush VI value, the maximum scan current value, the ripple of the scan current value, and the like. The brush VI value is an electric resistance of 20 [MΩ] between an electrode brought into contact with the entire area of a brush surface formed by a plurality of raised tips constituting the brush portion of the transfer brush and a bias power source. Is a value of a current generated when a bias of 2 [kV] is applied between the electric resistance and the conductive support by a bias power source in a state where a gap is interposed. Further, the scan current value is a state in which an electric resistance of 20 [MΩ] is interposed between the electrode in contact with one end in the longitudinal direction of the brush surface (corresponding to the belt width direction) and the bias power source. A current generated when a bias of 2 [kV] was applied between the electric resistance and the conductive support by a bias power source was sequentially measured while moving the electrode toward the other end in the longitudinal direction of the brush surface. Value. The ripple of the scan current value is a percentage obtained by subtracting the average value from the maximum value of the scan current and dividing the subtraction result by the average value. Focusing on the relationship between these electrical resistance characteristics and vertical black stripes and abrupt changes in image density, the value obtained by converting the brush VI value per unit area of the brush surface is 2. Use a transfer brush that exhibits an electric resistance characteristic of 5 [μA / cm ² ] or less and a value obtained by converting the maximum scan current per unit area of the brush surface to 22.0 [μA / cm ² ] or less. Thus, it has been found that vertical black lines and abrupt changes in image density can be suppressed as compared with the prior art. Further, the transfer brush exhibiting electric resistance characteristics in which the value obtained by converting the brush VI value per unit area of the brush surface is 2.5 [μA / cm ² ] or less and the ripple of the scan current value is 34 [%] or less. However, it was found that vertical black streaks and rapid image density changes can be suppressed more than before. Therefore, among the inventions of claims 1 to 9, the invention including all of the invention-specific matters of claim 1 or claim 2 can suppress vertical black stripes and a rapid change in image density as compared with the prior art.

Further, in a transfer brush whose brushed material is made of a material in which a conductive resistance adjusting agent such as carbon is dispersed in a nylon (polyamide resin) base material, the value obtained by converting the brush VI value per unit area of the brush surface is 4 It has been found that the vertical black streak and the abrupt change in image density can be suppressed as compared with the prior art by satisfying the conditions described below, which are not more than .3 [μA / cm ² ]. In other words, the value obtained by converting the maximum value of the scan current per unit area of the brush surface is 56.5 [μA / cm ² ] or less, or the ripple of the scan current value is 34 [%] or less. is there. Therefore, among the inventions of claims 1 to 9, even if all of the invention-specific matters of claim 3 or claim 4 are provided, vertical black lines and abrupt image density change can be suppressed as compared with the prior art. .

1 is a schematic configuration diagram illustrating a printer according to a first embodiment. FIG. 2 is an exploded perspective view showing a part of the transfer device of the printer. FIG. 3 is a perspective view showing the transfer device and a part of the housing of the printer. The side view which shows the transfer brush of the transfer apparatus. The perspective view which shows the transfer brush. The schematic diagram for demonstrating the measuring method of brush VI value. The schematic diagram for demonstrating the measuring method of a scanning electric current value. The side view which shows the transfer brush of the state which made the small electrode block contact. FIG. 3 is a schematic diagram for explaining a method for measuring a photoconductor side scan current value. The block diagram for demonstrating the measuring method of a belt VI value. (A), (b), (c), (d), (e) is a schematic diagram showing vertical black stripes of ranks 1, 2, 3, 4, 5; The graph which shows the relationship between the brush VI value and the maximum value of a scanning current at the time of using the paper conveyance belt of belt VI value 49-59 microamperes, and the transfer brush made from nylon. The graph which shows the relationship between the brush VI value and the maximum value of a scanning current at the time of using the paper conveyance belt of belt VI value 9-13microA, and the transfer brush made from nylon. The graph which shows the relationship between the brush VI value and the maximum value of a scanning current at the time of using the paper conveyance belt of belt VI value 49-59 microamperes, and the transfer brush made from rayon. The graph which shows the relationship between the brush VI value and the maximum value of a scanning current at the time of using the paper conveyance belt of belt VI value 9-13microA, and the transfer brush made from rayon. 6 is a graph showing the relationship between the maximum value of the photoconductor-side scan current and the maximum value of the scan current when a paper conveying belt having a belt VI value of 9 to 13 μA and a nylon transfer brush are used. 6 is a graph showing the relationship between the maximum value of the photoconductor-side scan current and the maximum value of the scan current when a paper conveying belt having a belt VI value of 49 to 59 μA and a transfer brush made of rayon are used. 6 is a graph showing the relationship between the maximum value of the photoconductor-side scan current and the maximum value of the scan current when a paper conveying belt having a belt VI value of 9 to 13 μA and a transfer brush made of rayon are used. The graph which shows the relationship between the ripple of a scanning electric current value at the time of using the paper conveyance belt of belt VI value 49-59microA, and the rank of a vertical black stripe. The graph which shows the relationship between a photoconductor side scan electric current value and a measurement position. The graph which shows the relationship between a scanning current value and a measurement position. The graph which shows the relationship between the brush VI value of the transfer brush made from nylon, and the atomic resistance value per unit length of raising. A chart showing various properties of 6 nylon and 12 nylon. The schematic diagram which shows an example of the halftone part which caused the vertical black stripe. The schematic diagram which shows an example of the halftone part which caused the rapid image density change. The graph which shows the relationship between the brush VI value and the maximum value of a scanning current at the time of using the paper conveyance belt of belt VI value 70-90 microamperes, and the transfer brush made from nylon. The graph which shows the relationship between the brush VI value and the maximum value of a scanning current at the time of using the paper conveyance belt of belt VI value 5-7 microamperes, and the transfer brush made from nylon. The graph which shows the relationship between the brush VI value and the maximum value of a scanning current at the time of using the paper conveyance belt of belt VI value 70-95 microamperes, and the transfer brush made from rayon. The graph which shows the relationship between the brush VI value and the maximum value of a scanning current at the time of using the paper conveyance belt of belt VI value 70-95 microamperes, and the transfer brush made from rayon. 6 is a graph showing the relationship between the maximum value of the photoconductor-side scan current and the maximum value of the scan current when a paper conveying belt having a belt VI value of 5 to 7 μA and a nylon transfer brush are used. 7 is a graph showing the relationship between the maximum value of the photoconductor-side scan current and the maximum value of the scan current when a paper conveying belt having a belt VI value of 70 to 95 μA and a nylon transfer brush are used. 6 is a graph showing the relationship between the maximum value of the photoconductor-side scan current and the maximum value of the scan current when a paper conveying belt having a belt VI value of 70 to 95 μA and a transfer brush made of rayon are used. When using a transfer brush made of rayon having a brush VI value of 16.1 μA in an environment of room temperature 10 ° C. and 15% RH, the paper type, belt VI value, transfer current target value, output voltage value, The graph which shows the relationship with a power supply output current. When using a transfer brush made of rayon with a brush VI value of 38.0 μA in an environment of room temperature of 32 ° C. and 80% RH, the paper type, belt VI value, transfer current target value, output voltage value, The graph which shows the relationship with a power supply output current. When using a nylon transfer brush having a brush VI value of 20.0 μA in an environment of room temperature of 10 ° C. and 15% RH, the paper type, belt VI value, transfer current target value, output voltage value, The graph which shows the relationship with a power supply output current. When using a nylon transfer brush having a brush VI value of 34.2 μA in an environment of room temperature of 32 ° C. and 80% RH, the paper type, belt VI value, transfer current target value, output voltage value, The graph which shows the relationship with a power supply output current.

Hereinafter, a first embodiment of an electrophotographic printer which is an image forming apparatus to which the present invention is applied will be described.
First, the basic configuration of the printer according to the first embodiment will be described. FIG. 1 is a schematic configuration diagram showing the printer. In the figure, around a drum-shaped photosensitive member 1 as a latent image carrier, there are a charging roller 2, an optical writing unit 3, a developing device 4 as a developing means, a transfer device 10, a drum cleaning device 5, a static elimination lamp 6 and the like. Is arranged.

  The photoreceptor 1 is rotationally driven in a clockwise direction in the drawing (in the direction of arrow A in the drawing) by a driving unit (not shown). Then, the charging roller 3 to which a charging bias is applied by a power source (not shown) is uniformly charged to a negative polarity in the dark. The surface potential of the photoreceptor 1 after uniform charging is, for example, −800 [V]. An electrostatic latent image corresponding to an image signal is formed on the surface of the photoreceptor 1 in such a potential state by optical scanning with the light-modulated laser light L emitted from the optical writing unit 3 serving as a latent image forming unit. Is formed. The surface potential of the electrostatic latent image portion is, for example, −130 [V], and the surface potentials of the other background portions are −800 [V] without change.

  To the electrostatic latent image formed on the photosensitive member 1, a negatively charged toner is attached by the developing device 4. By this adhesion, the electrostatic latent image on the photoreceptor 1 is developed into a visible toner image. This toner image is transferred onto the transfer paper P, which is a transfer material, by the transfer device 10. After the transfer, the surface of the photoreceptor 1 is discharged by a charge removing lamp 6 after the transfer residual toner is removed by the drum cleaning device 5.

  The transfer device 10 includes an endless belt member 11 including a paper conveying belt 11, a driving roller 12, a driven roller 13, and the like, and a transfer bias device including a transfer roller 19, a transfer brush 20, a transfer bias power source 31, and the like. It has.

  The belt device is endless in the counterclockwise direction (arrow B direction) in the figure by a driving roller 12 that is rotated by driving means (not shown) while the paper conveying belt 11 is stretched by a driving roller 12 and a driven roller 13. Move it. The front surface of the belt extending portion between the solid driving roller 12 and the driven roller 13 is brought into contact with the photosensitive member 1 to form a transfer nip.

  The transfer roller 19 of the transfer bias device is made of a metal such as stainless steel and is disposed so as to rotate while being in contact with the back surface of the paper transport belt 11. This contact location is a belt extension location between the drive roller 12 and the driven roller 13 and is a location downstream of the transfer nip in the belt movement direction.

  The transfer brush 20 of the transfer bias device includes a metal holder 21 that is a conductive support, a brush portion 22 that includes a plurality of raised brushes fixed to the surface of the metal holder 21 with a conductive adhesive, and the like. The front end side of the brush portion 22 is disposed so as to contact the back surface of the paper transport belt 11. This contact location is a belt extension location between the drive roller 12 and the driven roller 13 and is a location upstream of the transfer roller 19 in the belt movement direction.

  In the transfer brush 20, a transfer bias power supply 31 is connected to a metal holder 21 made of stainless steel or the like via a first ampermeter 30. On the other hand, the driven roller 13 that stretches while supporting the paper conveying belt 11 on the back surface thereof is made of a metal such as stainless steel, and the metal shaft member is connected to the electric wire via a sliding contact (not shown). Is connected. The drive roller 12 that stretches while supporting the paper transport belt 11 on its back surface is also connected to the metal shaft member via an unillustrated sliding contact. The electric wire extending from the shaft member of the driven roller 13 and the electric wire extending from the shaft member of the drive roller 12 are connected to each other and then connected to the transfer bias power source 31 via the second ampermeter 32.

  Part of the electric charge that has flowed from the transfer bias power source 31 to the paper transport belt 11 through the first ampermeter 30, the metal holder 21, and the brush unit 22 moves in the belt circumferential direction on the back surface of the paper transport belt 11. Thus, the driving roller 12 and the driven roller 13 are reached. Then, the air flows from the driving roller 12 and the driven roller 13 to the ground via the second ampermeter 30 and the transfer bias power source 31. Further, the remainder of the electric charge that has flowed from the brush unit 22 to the paper conveyance belt 11 flows into the photoreceptor 1 by moving the paper conveyance belt 11 in the thickness direction. The current value resulting from this flow, that is, the transfer current value, is substantially the same as the value obtained by subtracting the current measurement value from the second ampermeter 32 from the current measurement value from the first ampermeter 30.

  The transfer bias power supply 31 has a constant current control circuit (not shown) inside. The constant current control circuit outputs a value obtained by subtracting the current measurement value obtained by the second ampermeter 32 from the current measurement value obtained by the first ampermeter 30, that is, the transfer current value is stabilized at a predetermined target value. Change the voltage value. By such control (hereinafter referred to as constant current control), the transfer current value during the image forming operation is kept substantially constant.

The paper transport belt 11 is formed by forming a surface layer made of conductive resin on the front side of a belt base made of conductive rubber. The surface resistivity on the back side is adjusted to 10 ⁷ to 10 ¹⁰ [Ω / □] according to JISK6911. Further, the surface resistivity on the front surface side is adjusted to 10 ⁸ to 10 ¹³ [Ω / □] according to JISK6911. Further, the volume resistivity is adjusted to 10 ⁷ to 10 ¹¹ [Ω · cm] according to JISK6911.

  In a region not shown, a paper feed unit is provided. This paper feed unit is located in the direction of arrow C in FIG. To send. The transferred transfer paper P enters the transfer nip while being held on the upper stretched surface of the paper transport belt 11 of the transfer device 10. Then, the toner image on the photoreceptor 1 is transferred by the influence of the transfer current and the nip pressure described above.

  The transfer paper P onto which the toner image has been transferred in this way is transferred to a fixing device disposed in a region (not shown) on the left side of the drawing with respect to the transfer device 10, where the toner image is fixed. After being applied, it is discharged out of the machine.

  FIG. 2 is an exploded perspective view showing a part of the transfer device 10. In FIG. 1, the transfer device 10 has a roller support 14 that rotatably supports a driving roller 12 and a driven roller 13 at both ends. The transfer brush 20 is screwed and fixed to the roller support 14 in a state where the paper transport belt 11 is not attached. The paper transport belt 11 is wound around the roller support 14 after the transfer brush 20 is fixed with screws. As shown in FIG. 3, one end side (not shown) of the metal first bias terminal 15 and the second bias terminal 16 is fixed to the roller support 14 around which the paper transport belt 11 is wound. A fixed side end (not shown) of the first bias terminal 15 is electrically connected to the metal holder 21 of the transfer brush 10 inside the loop of the paper transport belt 11. Further, a fixed side end (not shown) of the second bias terminal 16 is connected to a metal shaft member of the driven roller 13 inside the loop of the paper transport belt 11.

  As shown in FIG. 3, the free end sides of the first bias terminal 15 and the second bias terminal 16 face the lower stretched surface of the paper transport belt 11 with a predetermined gap therebetween. When the transfer device 10 to which the bias terminal is fixed is attached to the printer main body as indicated by an arrow in FIG. 3, the first bias terminal 15 is brought into close contact with the first contact terminal 17 fixed to the printer main body side. It is done. Further, the second bias terminal 16 is brought into close contact with the second contact terminal 18 fixed to the printer main body side. The first contact terminal 17 is connected to the transfer bias power source 31 via the first ampermeter 30 shown in FIG. The second contact terminal 18 is connected to the ground via the second ampermeter 32 and the transfer bias power supply 31.

Next, an experiment conducted by the inventor in order to complete the printer will be described. First,
[Preparation 1]
The present inventor prepared a plurality of transfer brushes (20) exhibiting various electric resistance characteristics. These transfer brushes (20) have the same configuration except that the brushed material constituting the brush portion (22) is different, and have a form as shown in FIGS.

  FIG. 4 is a side view showing the transfer brush 20. In the figure, each raised portion constituting the brush portion 22 of the transfer brush 20 is fixed to a stainless steel (SUS304) metal holder 21 via a conductive double-sided tape 23. The conductive double-sided tape 23 is made of a material that exhibits substantially the same conductivity as metal. The protruding amount t1 of each napping from the upper surface of the conductive double-sided tape 23 is 5.8 [mm]. Further, the thickness t2 from the tip of the brush portion 22 composed of each raised portion to the back surface of the metal holder 21 is 6.8 [mm]. The brush width W1, which is a dimension in the short direction of the brush portion 22 (corresponding to the belt moving direction), is 5 [mm]. A plate member 24 made of an insulating material is cantilevered to the metal holder 21, and the free end of the plate member 24 is in contact with one end side in the short direction of the brush portion 22. The plate member 24 is for preventing the brush portion 22 whose tip is in contact with the back surface of the paper conveyance belt (not shown) from excessively bending each raised portion as the paper conveyance belt moves in the direction of the arrow. . The free end is brought into contact with the brush portion 22 at a position lower by about 2 [mm] than the brush tip.

  FIG. 5 is a perspective view showing the transfer brush 20. In the drawing, the brush length L1 which is the dimension in the longitudinal direction (corresponding to the belt width direction) of the brush portion 22 is 297.5 [mm]. The brush width W1 is 5 [mm] as described above. The present inventor prepared a plurality of transfer brushes 20 having the dimensional configuration shown in FIGS. 4 and 5 and having different electric resistance characteristics. Each raised brush constituting the brush portion 22 of the transfer brush 20 is made of a material in which carbon powder, which is conductive electrical resistance, is dispersed in a rayon base material or a nylon (6 nylon) base material. Hereinafter, the transfer brush 20 made of a material in which carbon powder is dispersed in a rayon base material as each raised brush is referred to as a rayon transfer brush 20. Further, the transfer brush 20 made of a material in which carbon powder is dispersed in a nylon base material is referred to as a nylon transfer brush 20 as each raised brush.

  Here, the rayon refers to a regenerated fiber obtained by dissolving cellulose to form a colloidal solution and drawing it from the pores into the coagulation liquid. Nylon is an arbitrary long-chain synthetic polyamide whose main chain has repeating amide groups and whose structural units are arranged in the axial direction.

  For all the transfer brushes 20 prepared in advance, the brush VI value, the scan current value, the ripple of the scan current value, the photoconductor-side scan current value (latent image carrier-side scan current value), and the unit length of the raising The electrical resistance value was investigated.

  The brush VI value was measured as follows. That is, as shown in FIG. 6, a stainless steel (SUS304) electrode block 103 brought into contact with the entire brush surface of the transfer brush 20 (the surface formed by the tips of each raised brush) and the bias power source 102 are connected by electric wires. To do. At this time, an electric resistance 101 of 20 [MΩ] is interposed between the electrode block 103 and the bias power source 102. Further, the stainless steel (SUS304) metal holder 21 of the transfer brush 20 is grounded via the ampere meter 100. In this state, a DC bias of 2 [kV] is applied between the electric resistance 101 and the metal holder 21 (strictly, the ampermeter 100). And the electric current value of the ampere meter 100 when 1 minute passes after application is read. This read value is defined as a brush VI value. The electrode block 103 is in contact with the entire region in the longitudinal direction of the brush surface as shown in the figure, and is also in contact with the entire region in the short direction of the brush surface, although not shown in the drawing. . Further, the electric wires extending from the electric resistance 101 toward the electrode block 103 were fixed to the electrode block 103 by screwing. Further, the electric wires extending from the ampermeter 100 toward the metal holder 21 were also fixed to the metal holder 21 by screwing.

  The scan current value was measured as follows. That is, as shown in FIG. 7, a small electrode block 104 (planar area on the contact side with the brush = 10 mm × 10 mm) and a bias power source 102 are connected to each other by an electric wire. . At this time, an electric resistance 101 of 20 [MΩ] is interposed between the small electrode block 104 and the bias power source 102. Further, the metal holder 21 of the transfer brush 20 is grounded via the ampermeter 100. In this state, a DC bias of 2 [kV] is applied between the electric resistance 101 and the metal holder 21 (strictly, the ampermeter 100). Then, while moving the small electrode block 104 in contact with the brush surface from one end side to the other end side in the brush longitudinal direction (corresponding to the belt width direction) at a speed of 10 mm / sec, The current value is read sequentially. Each read value at this time is set as a scan current value. The small electrode block 104 is in contact with the brush surface with a length of 10 mm in the brush longitudinal direction. Further, as shown in FIG. 8, the entire brush width W1 in the short-side direction of the brush (corresponding to the belt moving direction), that is, a length of 5 [mm] is brought into contact with the brush surface. The reading speed of the current value of the ampermeter 100 was set to 100 [times / sec] (measurement interval = every 0.1 mm of the small electrode block was moved).

  The ripple of the scan current value was obtained as follows. That is, the average value of the scan currents is obtained based on each scan current value and the number of readings (measurement times). Further, the maximum value of the scan current is specified based on each scan current value. Then, an official solution of “(maximum value−average value) / average value × 100%” was obtained as a ripple of the scan current value.

  The photoconductor side scan current value was measured as follows. That is, as the small electrode block 105 to be brought into contact with the brush surface of the transfer brush 20, the one shown in FIG. 9 is prepared. The electrode block 105 has an insulating tape 106 attached to the left region in the drawing of the region divided in half in the brush width direction, and the right region in the drawing is exposed as pure stainless steel. The electrode block 105 is brought into contact with the brush surface as shown in the drawing, and the bias is applied only to the region on the right side in the drawing, which is the region closer to the photosensitive member (not shown), in the region where the brush surface is equally divided in the brush width direction. To be able to supply. In this state, the value of the amperometer (100) is sequentially read while moving the small electrode block 105 from one end side to the other end side in the longitudinal direction of the transfer brush 20 in the same manner as the scan current value. Each read value at this time is set as a photoconductor side scan current value.

  About the electrical resistance value per unit length of raising (henceforth a raw yarn resistance value), it measured as follows. That is, after all the experiments described below are completed, 100 brushes are randomly extracted from the transfer brush 20 one by one. And after measuring the electric resistance value of these raising | fluffing and converting into the resistance value per unit length, what calculated | required the average value per 100 pieces was made into the yarn resistance value. This raw yarn resistance value was obtained for all the transfer brushes 20. In addition, about the electrical resistance value of raising, it measured as follows. That is, after attaching metal clips to both ends of the raised hair, the distance between the clips is adjusted to apply a tension of 100 to 200 [gf] to the raised hair. In this state, a bias of 200 [V] was applied between both clips, and the electric resistance value was obtained based on the result of reading the current value one minute later with an ammeter.

[Pre-experiment preparation 2]
A printer tester having the same configuration as the printer shown in FIG. 1 was prepared. A plurality of paper conveying belts 11 exhibiting various electric resistance characteristics were prepared as the paper conveying belt 11 to be mounted on the printer testing machine. The belt VI value was measured for all of these paper transport belts 11.

  The belt VI value was measured as follows. That is, first, the paper transport belt 11 is attached to the printer testing machine with the transfer brush 20 removed. Then, as shown in FIG. 10, the metal roller 110 is brought into contact with the back surface (the inner surface of the loop) of the paper transport belt 11 in a region where the transfer brush 20 is normally contacted. A bias power source 111 is connected to the shaft member of the metal roller 110. Further, the electric wire connected to the driven roller 13 and the electric wire connected to the metal shaft member of the photosensitive member 1 are connected. At this time, an electric resistance 112 of 20 [MΩ] is interposed between the connecting portion of the two wires and the shaft member of the photoreceptor 1. And the connection part of both electric wires is connected to earth | ground via the ampere meter 113, and the paper conveyance belt 11 and the photoreceptor 1 are each driven by the same linear velocity as an actual machine. In this state, the bias power supply 111 applies a DC bias of 2 [kV] between the metal roller 110 and the ampere meter 113, reads the current value of the ampere meter 113 one minute after application, and then reads the belt. Let it be VI value. Note that the linear velocity of the paper conveyance belt 11 and the photosensitive member 1 in the actual machine is set to 400 to 650 [mm / sec]. The target value of the current for constant current control is set to 85 to 150 [μA]. In an experiment for evaluating the rank of vertical black stripes, which will be described later, the linear velocity is set to 500 [mm / sec], and the target value of the transfer current is set to 110 [μA].

[Experiment 1]
One of a plurality of transfer brushes 20 prepared in advance and one of a plurality of paper transport belts 11 prepared in advance are attached to the printer tester. Then, while performing constant current control in a state where the target value of the transfer current is set to 85 to 150 [μA], a test image is output, and whether or not there is an abrupt image density change in the halftone portion of the test image is checked. It was. For the test image, an image was output so that a 2 × 2 (two by two) solid halftone portion was formed on the entire surface of the transfer paper with respect to the A3 size transfer paper.

  It was evaluated whether or not a sudden change in image density was visually recognized in the solid halftone portion of the test image printed out. Such evaluation was repeated while appropriately replacing the transfer brush 20 and the paper transport belt 11. Then, it was found that when a transfer brush 20 having a relatively small brush VI value is used, it is difficult to cause an abrupt change in image density. It has also been found that when the medium conveying belt 11 having a relatively large belt VI value is used as the paper conveying belt 11, it is difficult to cause an abrupt change in image density.

[Experiment 2]
A test image was output in the same manner as in Experiment 1 to examine the presence or absence of an abrupt image density change in the halftone part, and the rank of vertical black stripes appearing in the halftone part was evaluated in five stages of 1 to 5.

  The ranks of vertical black stripes were determined by visual inspection of the examiner. Then, the vertical black stripes in the state shown in (a), (b), (c), (d), and (e) of FIG. 11 were evaluated as ranks 1, 2, 3, 4, and 5. In addition, the width which is the length in the short direction of the vertical black stripe is rank 1 (a) = about 3.0 mm, rank 2 (b) = about 2.5 mm, rank 3 (c) = about 2.0 mm, Rank 4 (d) = about 1.5 mm and rank 5 (e) = about 1.0 mm. Naturally, the higher the rank value, the less noticeable the vertical black stripes. At rank 4 or higher, the presence / absence of the test image cannot be visually recognized unless it is very close to the test image. Therefore, rank 4 or higher is an allowable range in image quality. In other words, it can be said that the vertical black streak can be effectively suppressed by setting the rank to 4 or higher.

Table 1 below shows the brush characteristic value and the maximum scan current when the combination of the paper conveying belt 11 having a belt VI value of 70 to 95 [μA] and the nylon transfer brush 20 is employed. 4 shows the relationship between the vertical black stripe rank evaluation and the presence or absence of a sudden change in image density. FIG. 26 is a graph showing this relationship. In addition, the area | region shown with the oblique line in the graph has shown the area | region which can suppress sudden image density change to such an extent that it cannot suppress visually, while suppressing vertical black stripes effectively. The same applies to FIGS. 13 to 19 described later. Also, the belt VI value of 70 to 95 [μA] means that when the belt VI value is measured at a plurality of locations in the belt circumferential direction, the plurality of measured values become 70 to 95 [μA]. Show.

Table 2 below shows the brush characteristic value and the maximum scan current when the combination of the paper conveying belt 11 having a belt VI value of 49 to 59 [μA] and the nylon transfer brush 20 is adopted. 4 shows the relationship between the vertical black stripe rank evaluation and the presence or absence of a sudden change in image density. FIG. 12 is a graph showing this relationship.

Table 3 shown below shows the brush characteristic values when the combination of the paper transfer belt 11 having a belt VI value of 9 to 13 [μA] and the nylon transfer brush 20 is employed, and the rank evaluation of vertical black stripes. And the presence or absence of an abrupt image density change. FIG. 13 is a graph showing this relationship.

Table 4 below shows the brush characteristic value and the vertical black stripe rank evaluation when the combination of the paper conveying belt 11 having a belt VI value of 5 to 7 [μA] and the nylon transfer brush 20 is adopted. And the presence or absence of an abrupt image density change. FIG. 27 is a graph showing this relationship.

Table 5 below shows the brush characteristic values and the vertical black stripe rank evaluation when the combination of the paper conveying belt 11 having a belt VI value of 70 to 95 [μA] and the rayon transfer brush 20 is adopted. And the presence or absence of an abrupt image density change. FIG. 28 is a graph showing this relationship.

Table 6 below shows the brush characteristic values and the vertical black stripe rank evaluation when the combination of the paper conveying belt 11 having a belt VI value of 49 to 59 [μA] and the transfer brush 20 made of rayon is adopted. And the presence or absence of an abrupt image density change. FIG. 14 is a graph showing this relationship.

Table 7 below shows the brush characteristic values and the vertical black stripe rank evaluation when the combination of the paper conveying belt 11 having a belt VI value of 9 to 13 [μA] and the transfer brush 20 made of rayon is adopted. And the presence or absence of an abrupt image density change. FIG. 15 is a graph showing this relationship.

Table 8 shown below shows the brush characteristic values when the combination of the paper conveying belt 11 having a belt VI value of 5 to 7 [μA] and the transfer brush 20 made of rayon is employed, and rank evaluation of vertical black stripes. And the presence or absence of an abrupt image density change. FIG. 29 is a graph showing this relationship.

  From these results, the following can be said. That is, if the belt VI value is in an appropriate range, a transfer brush 20 having a brush VI value of 38.0 [μA] or less and a maximum scan current value of 11.00 [μA] or less is used. As a result, regardless of the brushed base material resin (rayon or nylon), it is possible to effectively suppress vertical black stripes and a rapid change in image density.

Here, even if the material of raising is the same, if the size of the brush surface of the brush part 22 is different, the electric resistance of the entire brush will be different. For this reason, unless the brush VI value and the scan current are converted per unit area of the brush surface, the resistance characteristics of the entire brush cannot be expressed accurately. In Experiment 2, the brush VI value was measured with the electrode block (103) in contact with the entire area of the brush surface. Therefore, the brush VI value of 38.0 [μA] is 38.0 μA ÷ (0.5 cm × 29.75 cm) = 2.55 [μA / cm ² ] when converted per unit area of the brush surface. In consideration of the fact that vertical black stripes are less likely to occur as the brush VI value becomes smaller, it is appropriate to round down the second decimal place to 2.5 [μA / cm ² ] or less.

In this experiment 2, a small electrode block (104) having a plane area of 10 mm × 10 mm on the contact side with the brush was scanned in a state where the brush surface of the brush part 22 having a brush width W1 of 5 mm was in contact with the brush. The current value is measured. Therefore, the maximum value of the scan current of 11.00 [μA] is 11.00 μA ÷ (0.5 cm × 1.0 cm) = 22.00 [μA / cm ² ] when converted per unit area of the brush surface. Become. Considering that vertical black stripes are less likely to occur as the maximum value of the scan current becomes smaller, it is appropriate to round down the second decimal place to 22.0 [μm / cm ² ] or less.

Therefore, in the printer according to the first embodiment, as the transfer brush 20, a value obtained by converting the brush VI value per unit area of the brush surface (hereinafter referred to as the brush VI unit area converted value) is 2.5 [μA / cm ² ] or less, and the value obtained by converting the maximum value of the scan current per unit area of the brush surface (hereinafter referred to as the maximum scan unit area converted value) is 22.0 [μA / cm ² ] or less. ing.

Table 9 shown below shows the maximum value of the photoconductor-side scan current and the scan current when a combination of the paper transport belt 11 having a belt VI value of 5 to 7 [μA] and the nylon transfer brush 20 is employed. The relationship between the maximum value of, the rank evaluation of vertical black stripes, and the presence or absence of a sudden change in image density is shown. FIG. 30 is a graph showing this relationship.

Table 10 shown below shows the maximum value of the photoconductor-side scan current and the scan current when the combination of the paper transport belt 11 having a belt VI value of 9 to 13 [μA] and the nylon transfer brush 20 is employed. The relationship between the maximum value of, the rank evaluation of vertical black stripes, and the presence or absence of a sudden change in image density is shown. FIG. 16 is a graph showing this relationship.

Table 11 shown below shows the maximum value of the photoconductor-side scan current and the scan current when a combination of the paper transport belt 11 having a belt VI value of 70 to 95 [μA] and the nylon transfer brush 20 is employed. The relationship between the maximum value of, the rank evaluation of vertical black stripes, and the presence or absence of a sudden change in image density is shown. FIG. 31 is a graph showing this relationship.

Table 12 shown below shows the maximum value of the photoconductor side scan current and the scan current when the combination of the paper transport belt 11 having a belt VI value of 70 to 95 [μA] and the transfer brush 20 made of rayon is adopted. The relationship between the maximum value of, the rank evaluation of vertical black stripes, and the presence or absence of a sudden change in image density is shown. FIG. 32 is a graph showing this relationship.

Table 13 below shows the maximum value of the photoconductor-side scan current and the scan current when the combination of the paper conveying belt 11 having a belt VI value of 49 to 59 [μA] and the transfer brush 20 made of rayon is adopted. The relationship between the maximum value of, the rank evaluation of vertical black stripes, and the presence or absence of a sudden change in image density is shown. FIG. 17 is a graph showing this relationship.

Table 14 shown below shows the maximum value of the photoconductor side scan current and the scan current when the combination of the paper conveyance belt 11 having a belt VI value of 9 to 13 [μA] and the transfer brush 20 made of rayon is adopted. The relationship between the maximum value of, the rank evaluation of vertical black stripes, and the presence or absence of a sudden change in image density is shown. FIG. 18 is a graph showing this relationship.

  From these results, in addition to the brush VI value being 38.0 [μA] or less and the maximum scan current value being 11.00 [μA] or less, the transfer brush 20 has the following conditions. It turns out that the evaluation rank of a vertical black stripe can be improved more by comprising. That is, the condition is that the maximum value of the photoconductor-side scan current is smaller than the maximum value of the scan current. Therefore, in the printer according to the first embodiment, the transfer brush 20 having such conditions is used.

  Next, a printer according to a second embodiment to which the invention is applied will be described. Since the basic configuration of the printer according to the second embodiment is the same as that of the first embodiment, the description thereof is omitted.

  FIG. 19 is a graph showing the relationship between the vertical black streak evaluation rank and the scan current ripple in Experiment 2 described above. This graph plots both the results when using a rayon transfer brush 20 and the results when using a nylon transfer brush. From this graph, it can be seen that if the transfer brush 20 has a scan current ripple of less than 34%, the vertical black stripe evaluation rank can be kept within the allowable range of 4 or 5. Considering together with the results shown in FIGS. 12 to 15 described above, the transfer brush 20 has a brush VI value of 38.0 [μA] or less (2.5 μA or less per unit area), and a ripple. If a material with 34 [%] is used, it is possible to effectively suppress vertical black stripes and abrupt image density changes regardless of the brushed base resin. Therefore, in the printer according to the second embodiment, a transfer brush 20 having such a condition is used. In consideration of safety, the ripple is desirably 22%.

  If a transfer brush 20 made of rayon is used, even if the conditions described so far are satisfied, it is not always possible to reliably suppress vertical black stripes and sudden image density changes. Specifically, as shown in Table 7, Table 8, FIG. 15, and FIG. 29, when the transfer brush 20 made of rayon is used, the belt VI value of the paper conveying belt 11 is 49 [μA] or more. And more specifically 49 to 95 [μA], both vertical black stripes and abrupt image density changes can be suppressed. However, when a belt having a belt VI value of 13 [μA] or less is used as the paper transport belt 11, a sudden change in image density cannot be suppressed even if vertical black stripes can be suppressed.

Here, even if the belt material is the same, the electrical resistance of the entire belt differs if the size of the belt is different. For this reason, unless the belt VI value is converted per unit area of the belt surface, the resistance characteristic of the entire belt cannot be expressed accurately. In the printer testing machine, the area of the transfer nip is 0.8 cm × 34.2 cm. Then, the belt VI value of 49.0 [μA] is 49.0 μA ÷ (0.8 cm × 34.2 cm) = 1.8 [μA / cm ² ] when converted per unit area of the belt surface. The belt VI value of 95.0 [μA] is 95.0 μA ÷ (0.8 cm × 34.2 cm) = 3.5 [μA / cm ² ] when converted to a unit area of the belt surface.

Therefore, in the printer of the first embodiment or the second embodiment, when a transfer brush 20 made of rayon is used, a value obtained by converting the belt VI value per unit area of the transfer nip as the paper conveying belt 11 is obtained. What is 1.8-3.5 [μA / cm ² ] is used.

  As described above, the various experiments described so far have been performed under the conditions in which the target value of the transfer current subjected to constant current control is set to 110 [μA]. Next, the inventors conducted various similar experiments with the rayon transfer brush 20 while gradually increasing the target value, and up to 130 [μA] is the same as in the case of 110 [μA]. I was able to get the results. When various similar experiments were performed with the nylon transfer brush 20, the same results as in the case of 110 [μA] were obtained up to 200 [μA]. Therefore, if the target value of the transfer current is set to 130 [μA] or less and the brush VI value, the belt VI value, the maximum value of the scan current, etc. are appropriately set, the vertical black streak is set regardless of the type of the material of the raising. And a sudden change in image density can be reliably suppressed.

Regarding the relationship between the transfer current Id [μA] actually flowing from the belt to the photosensitive member and the transfer charge density at that time (hereinafter referred to as effective transfer charge density), “effective transfer charge density = Id / (V × L1)”. "Can be expressed by the relational expression. It can be considered that Id in this relational expression is the same as the target value of the transfer current. V is the moving speed [mm / sec] of the paper transport belt 11. L1 is the length [mm] of the transfer brush 20 in the belt width direction. Based on this relational expression, the effective transfer charge density when the target value of the transfer current is set to 130 [μA] is calculated as “130 / (630 × 297.5) = 6.93 × 10 ⁻⁴ [μC / Cm ² ] = 6.93 × 10 ⁻⁸ [C / cm ² ] ”. Therefore, if the effective transfer charge density is 6.93 × 10 ⁻⁸ [C / cm ² ] or less and the brush VI value, belt VI value, maximum scan current value, etc. are appropriately set, Regardless of the type, both vertical black stripes and abrupt image density changes can be reliably suppressed.

Therefore, in the printer according to the first embodiment or the second embodiment, as the transfer device 10, an effective transfer charge density of 6.93 × 10 ⁻⁸ [C / cm ² ] or less is used.

  Generally, the output current value from the transfer bias power supply 31 is larger than the transfer current value. This is because part of the current output from the transfer bias power supply 31 does not flow to the photoconductor, but flows from the stretching roller or the like to the ground. Therefore, the transfer charge density corresponding to the output current from the transfer bias power supply 31 is made larger than the effective transfer charge density.

  Next, the present inventors prepare a plurality of paper transport belts 11 having different belt VI values, a plurality of transfer brushes 20 having different brush VI values, and a plurality of different transfer materials. Experiments were conducted to investigate the relationship between the voltage value of the transfer bias and the output current value from the transfer bias power supply 31 (hereinafter referred to as power supply output current).

Table 15 below shows the paper type (type of transfer material) and belt when the transfer brush 20 made of rayon having a brush VI value of 16.1 μA is used in an environment of room temperature of 10 ° C. and 15% RH. It shows the relationship among the VI value, the transfer current target value, the output voltage value (output voltage value) from the power supply, and the power supply output current. FIG. 33 is a graph showing such a relationship.

Table 16 below shows the paper type, belt VI value, and transfer current when the rayon transfer brush 20 having a brush VI value of 38.0 μA is used in an environment of room temperature of 32 ° C. and 80% RH. It shows the relationship between the target value, the output voltage value (output voltage value) from the power supply, and the power supply output current. FIG. 34 is a graph showing such a relationship.

Table 17 shown below shows the paper type, belt VI value, and transfer current when the nylon transfer brush 20 having a brush VI value of 20.0 μA is used in an environment of a room temperature of 10 ° C. and 15% RH. It shows the relationship between the target value, the output voltage value (output voltage value) from the power supply, and the power supply output current. FIG. 35 is a graph showing such a relationship.

Table 18 below shows the paper type, belt VI value, and transfer current when the nylon transfer brush 20 having a brush VI value of 64.2 μA is used in an environment of a room temperature of 32 ° C. and 80% RH. It shows the relationship between the target value, the output voltage value (output voltage value) from the power supply, and the power supply output current. FIG. 36 is a graph showing such a relationship.

As already described, the transfer bias 20 made of rayon has a narrower allowable range of transfer bias than the transfer brush 20 made of nylon. The condition of the allowable transfer current when using the rayon transfer brush 20 was 130 [μA] as described above. In various combinations of brush VI values and paper types, the maximum value of the power output current when the transfer current target value is set to the upper limit of 130 [μA] is 460 [μA] from FIG. 33 and FIG. Recognize. Note that, as shown in Table 15 and Table 16, these figures include the results when a transfer current value larger than this is applied instead of 130 [μA]. The maximum value of the power supply output current remains below 460 [μA]. When the transfer charge density is determined from the maximum value of the power supply output current, “460 / (630 × 297.5) = 2.45 × 10 ⁻⁷ [C / cm ² ]” is obtained.

When the target value of the transfer current is smaller than 110 [μA], transfer failure may occur depending on the environment. Therefore, the lower limit value of the transfer current is 110 [μA]. In order to obtain a transfer current of 110 [μA], it is necessary to output a larger current from the transfer bias power supply 31. When 110 [μA] is converted into the transfer charge density, “110 / (630 × 297.5) = 5.87 × 10 ⁻⁸ [C / cm ² ]” is obtained.

Therefore, in the printer according to the first embodiment or the second embodiment, as the transfer device 10, the transfer charge density from the transfer bias power supply 31 is larger than 5.87 × 10 ⁻⁸ [C / cm ² ] and 2 .45 × 10 ⁻⁷ [C / cm ² ] or less is used.

  Next, a printer according to a third embodiment to which the invention is applied will be described. Since the basic configuration of the printer according to the third embodiment is the same as that of the first embodiment, the description thereof is omitted.

From the results shown in Tables 1 to 8, FIGS. 12 to 15, and FIGS. 26 to 29, the transfer brush 20 made of rayon is more likely to generate vertical black stripes than the transfer brush 20 made of nylon. I understand that In the case of the latter transfer brush 20, the lower limit of the allowable brush VI value is increased from 38.0 [μA] to 64.2 [μA], and the lower limit of the maximum allowable scan current is 11.00 [μA]. To 28.25 [μA]. The fact that the lower limit can be raised means that the range of allowable electrical resistance values of the brush is widened, that is, the material selection range of the brush portion is widened. The brush VI value of 64.2 [μA] is 64.2 μA ÷ (0.5 cm × 29.75 cm) = 4.32 [μA / cm ² ] when converted per unit area of the brush surface. Taking into consideration that vertical black streaks are less likely to occur as the brush VI value becomes smaller, it is appropriate to round down the second decimal place to 4.3 [μA / cm ² ] or less. Further, the maximum value of the scan current of 28.25 [μA] is 28.25 μA ÷ (0.5 cm × 1.0 cm) = 56.50 [μA / cm ² ] when converted per unit area of the brush surface. Become. Considering that vertical black stripes are less likely to occur as the maximum value of the scan current becomes smaller, it is appropriate to round down the second decimal place to 56.5 [μm] or less.

In the case of the transfer brush 20 made of nylon, the lower limit of the allowable brush VI value is increased from 38.0 [μA] to 64.2 [μA], and the lower limit of the maximum allowable scan current is 11.00. [ΜA] can be increased to 28.25 [μA]. The fact that the lower limit can be raised means that the range of allowable electrical resistance values of the brush is widened, that is, the material selection range of the brush portion is widened. The brush VI value of 64.2 [μA] is 64.2 μA ÷ (0.5 cm × 29.75 cm) = 4.32 [μA / cm ² ] when converted per unit area of the brush surface. Taking into consideration that vertical black streaks are less likely to occur as the brush VI value becomes smaller, it is appropriate to round down the second decimal place to 4.3 [μA / cm ² ] or less. Further, the maximum value of the scan current of 28.25 [μA] is 28.25 μA ÷ (0.5 cm × 1.0 cm) = 56.50 [μA / cm ² ] when converted per unit area of the brush surface. Become. Considering that vertical black stripes are less likely to occur as the maximum value of the scan current becomes smaller, it is appropriate to round down the second decimal place to 56.5 [μm] or less.

  Further, from the results shown in Tables 1 to 8, FIGS. 12 to 15, and FIGS. 26 to 29, the transfer brush 20 made of rayon has a wider belt VI value range than the transfer brush 20 made of nylon. I know you get. Specifically, in the case of the transfer brush 20 made of rayon, as described above, even if the brush VI value and the maximum value or ripple of the scan current are defined, the belt VI value is 13 [μA] or less. Will cause a sudden change in image density in the halftone area. That is, it is necessary to use the paper transport belt 11 having a relatively high belt VI value (relatively low electrical resistance value). On the other hand, in the case of the transfer brush 20 made of nylon, if the brush VI value and the maximum value or ripple of the scan current are defined, the vertical black streak is spread over a wide belt VI value of 5 to 95 [μA]. And a rapid change in image density can be suppressed. The lower the belt VI value, the more likely it is to cause an abrupt change in image density, and it has been proved that the appropriate range of the belt VI value is at least 5 to 95 [μA]. This indicates that a wider variety of materials can be applied as the material used for the paper transport belt 11, and the degree of freedom in designing the paper transport belt 11 is higher than that of the transfer brush 20 made of rayon. Become.

Therefore, in the printer according to the third embodiment, as the transfer brush 20, a brushed base material resin made of nylon (polyamide resin) made of nylon and having the following conditions is used. Yes. That is, the brush VI unit area converted value is 4.3 [μA / cm ² ] or less, and the maximum scan unit area converted value is 56.5 [μA / cm ² ] or less.

When the belt VI value of 5 [μA] is converted per unit area of the belt surface, 5 μA ÷ (0.8 cm × 34.2 cm) = 0.18 [μA / cm ² ]. When the belt VI value of 95.0 [μA] is converted per unit area of the belt surface, 95.0 μA ÷ (0.8 cm × 34.2 cm) = 3.5 [μA / cm ² ]. Therefore, in the printer of the third embodiment, when a transfer brush 20 made of nylon is used, the value obtained by converting the belt VI value per unit area of the transfer nip as the paper conveying belt 11 is 0.18 to 3. What is 5 [μA / cm ² ] is used.

In the printer of the fourth embodiment to be described later, for the same reason, the value obtained by converting the belt VI value per unit area of the transfer nip as the paper transport belt 11 is 0.18 to 3.5 [μA / cm ^2. ] Is used.

  The reason why the transfer brush 20 made of rayon is easier to generate vertical black stripes than the transfer brush 20 made of nylon is considered as follows. That is, FIG. 20 is a graph showing the relationship between the photoconductor-side scan current value and its measurement position (position in the brush longitudinal direction) in Experiment 2 described above. FIG. 21 is a graph showing the relationship between the scan current value and the measurement position in Experiment 2 described above. In these figures, the two curves labeled R1 and R2 both show the measurement results with the transfer brush 20 made of rayon. In addition, the other three curves all show the measurement results with the nylon transfer brush 20. From these graphs, it can be seen that the transfer brush 20 made of rayon has a greater variation in electrical resistance value in the longitudinal direction than the transfer brush 20 made of nylon. When there is such a variation, the transfer current flows intensively at the brush portion where the electrical resistance value increases in the longitudinal direction, and vertical black stripes are easily generated.

  As described above, the raised yarn used for the brush portion 22 of the transfer brush 20 is a raw yarn in which carbon is dispersed in a base material resin. As such a raw yarn, when a dedicated thread for use in the transfer brush 20 is manufactured, the manufacturing cost of the transfer brush 20 is extremely increased. For this reason, it is desirable to use a general-purpose thread that is available in the general market. Nylon yarns with various electrical resistance values are commercially available. In the case of rayon yarns, those with electrical resistance values suitable for use as raising brushes of the transfer brush 20 are commercially available. You can get only those whose electrical resistance value is lower than the appropriate value. Therefore, in the case of raw yarn made of rayon, the electrical resistance value is increased by a special treatment and used as raising, but such treatment can increase the electrical resistance value uniformly in the length direction of the raw yarn. Can not. Inevitably, a portion where the electrical resistance value can hardly be increased in the length direction is generated. In the transfer brush 20, the raised hair made from such a portion has a much smaller electric resistance value than the raised hair made from other locations, and therefore, the transfer current flows intensively. This is the reason why it becomes easy to generate vertical black lines with the transfer brush 20 made of rayon.

Next, a fourth embodiment of a printer to which the present invention is applied will be described. Since the basic configuration of the printer according to the fourth embodiment is the same as that of the first embodiment, the description thereof is omitted.
As described above with reference to Tables 1 to 4, FIGS. 12 to 13, and FIGS. 26 to 27, when a transfer brush 20 made of nylon is used, An abrupt change in image density can be suppressed. That is, the brush VI value is 64.2 [μA] (4.3 μA / cm ² per unit area) or less. Further, as described above with reference to FIG. 19, if a transfer brush 20 having a scan current ripple of less than 34% is used, the vertical black stripe evaluation rank is an allowable range of 4 or 5. It can be seen that Therefore, in the fourth embodiment, the transfer brush 20 is made of nylon and has these conditions.

Table 19 shown below shows the relationship between the brush VI value and the yarn resistance value per unit length of the raised brush of the nylon transfer brush 20. FIG. 22 is a graph showing such a relationship.

In the graph of FIG. 22, the transfer brush 20 made up of brushed brushes having a brush VI value of 64.2 [μA] or less can suppress an abrupt change in image density. From the graph, the raising has a condition that the yarn resistance value per unit length of the raising is 3.0 × 10 ^ “10” ^ [Ω / mm]. Therefore, in the printers of the third and fourth embodiments, the transfer brush 20 having such conditions is used.

  As described above with reference to Tables 10 to 14, FIGS. 17 to 18, and FIGS. 31 to 32, the transfer brush 20 has a condition that the maximum value of the photoconductor-side scan current is smaller than the maximum value of the scan current. The evaluation rank of vertical black stripes can be further improved. Therefore, in the printers according to the first to fourth embodiments described so far, the transfer brush 20 having such a condition is used.

For reference, the properties of 6 nylon (trade name) and rayon are shown in Table 20 below.

Table 20 shows that the transfer brush 20 made of nylon has a 9 . It turns out that it is 0% or less. On the other hand, in the transfer brush 20 made of rayon, it is about 12.3 to 25% in an environment of 20 ° C. and 95% RH. Nylon is a material with a low moisture content compared to rayon.

  Various properties of 6 nylon and 12 nylon are shown in FIG. 6 nylon has carbon dispersed uniformly in the cross-sectional direction, whereas 12 nylon has carbon dispersed only around the peripheral edge in the cross-sectional direction.

As described in the first and second embodiments, when the nylon transfer brush 20 is used, 110 to 200 [μA] is an allowable range of the transfer current. When the effective transfer charge density is obtained from 200 [μA] which is the upper limit value of this allowable range, it is “200 / (630 × 297.5) = 1.06 × 10 ⁻⁷ [C / cm ² ]”. Therefore, in the printers according to the third and fourth embodiments using the nylon transfer brush 20, the effective transfer charge density is 1.06 × 10 ⁻⁷ [C / cm ² ] or less, and the brush VI is used. By appropriately setting the value, the belt VI value, the maximum value of the scan current, etc., it is possible to reliably suppress both vertical black lines and abrupt image density changes.

Therefore, in the printer according to the third embodiment or the fourth embodiment, the transfer device 10 that has an effective transfer charge density of 1.06 × 10 ⁻⁷ [C / cm ² ] or less is used.

When the transfer brush 20 made of nylon is employed and the transfer current is set to the upper limit of 200 [μA], the maximum value of the power supply output current is specified from Table 17, Table 18, FIG. 35, and FIG. , 500 [μA]. When the transfer charge density is determined from the maximum value of the power supply output current, “500/630 × 297.5” = 2.67 × 10 ⁻⁷ [C / cm ² ] ”is obtained. Further, in order to obtain 110 [μA] which is the lower limit value of the transfer current, as described above, a transfer charge density of 5.87 × 10 ⁻⁸ [C / cm ² ] or more is output from the transfer bias power source 31. You will need it.

Therefore, in the printer of the third embodiment or the fourth embodiment using the nylon transfer brush 20, the transfer charge density from the transfer bias power supply 31 is 5.87 × 10 ⁻⁸ [C / cm] as the transfer device 10. ² ] and 2.67 × 10 ⁻⁷ [C / cm ² ] or less.

  So far, the printer for transferring the toner image on the photoreceptor 1 to the transfer paper held on the front surface of the paper conveying belt as the belt member has been described. However, the present invention is also applied to the following printers. Is possible. That is, the printer transfers the toner image on the photoreceptor 1 to an intermediate transfer belt as a belt member.

  As described above, in the printers according to the third embodiment and the fourth embodiment, the transfer brush 20 is made of nylon, so that the brush VI value and the maximum scanning current are maximum as compared to the case of using rayon. The appropriate range of the value and the scan current ripple can be widened to improve the design freedom of the transfer brush 20. Furthermore, the appropriate range of the belt VI value can be widened to improve the degree of freedom in selecting the material for the paper transport belt 11.

Further, in the printer according to the third embodiment or the fourth embodiment, the transfer brush 20 having an electric resistance value of 3.3 × 10 ¹⁰ [Ω / mm] or more in the unit length of the raising is used for the experiment. By using the same transfer brush 20 that has obtained good results, it is possible to form a good image in which vertical black lines and abrupt changes in image density are not noticeable.

  In the printer according to each embodiment, since the transfer brush 20 has a maximum photoconductor-side scan current smaller than the maximum scan current, vertical black lines and abrupt image density changes are caused. Furthermore, it can suppress reliably.

In the printer according to the first embodiment or the second embodiment, the value obtained by converting the belt VI value per unit area of the transfer nip is 1.8 to 2.2 [μA / cm ² , as the paper conveying belt 11. Therefore, even when a transfer brush 20 made of rayon is used, vertical black stripes and a rapid change in image density can be suppressed.

Further, in the printer according to the first embodiment or the second embodiment, the value obtained by converting the belt VI value per unit area of the transfer nip formed by the contact between the belt and the photoconductor as the paper transport belt 11 is obtained. Since what is 1.8 to 3.5 [[mu] A / cm < ² >] is used, for the reasons described above, it is possible to more reliably suppress the occurrence of vertical black stripes and abrupt image density changes.

Further, in the printer according to the first embodiment or the second embodiment, as the transfer device 10, an effective transfer charge density of 6.93 × 10 ⁻⁸ [C / cm ² ] or less is used. As already described, it is possible to avoid the occurrence of vertical black stripes and abrupt image density changes caused by inappropriate transfer bias condition settings.

In the printer according to the first embodiment or the second embodiment, the transfer charge density from the transfer bias power source 31 that outputs the transfer bias applied to the paper transport belt 11 is 5.87 × 10 ⁻⁸ as the transfer device. because of the use of those in [C / cm ^2] greater than and ^{2.45 × 10 -7 [C / cm} 2] or less, while suppressing the occurrence of Tatekuro streaks or sudden change in image density more reliably Further, it is possible to suppress the occurrence of transfer failure due to insufficient transfer charge density.

Further, in the printer according to the third embodiment or the fourth embodiment, the value obtained by converting the belt VI value per unit area of the transfer nip formed by the contact between the belt and the photosensitive member as the paper transport belt 11 is obtained. Since 0.18-3.5 [[mu] A / cm < ² >] is used, it is possible to more reliably suppress the occurrence of vertical black stripes and sudden image density changes for the reasons described above.

Further, in the printer according to the third embodiment or the fourth embodiment, since the transfer device 10 uses an effective transfer charge density of 1.06 × 10 ⁻⁷ [C / cm ² ] or less, As already described, it is possible to avoid the occurrence of vertical black stripes and abrupt image density changes caused by inappropriate transfer bias condition settings.

In the printer according to the third embodiment or the fourth embodiment, the transfer charge density from the transfer bias power source 31 that outputs the transfer bias applied to the paper transport belt 11 is 5.87 × 10 ⁻ as the transfer device 10. ⁸ [C / cm ² ] larger than 2.67 × 10 ⁻⁷ [C / cm ² ] or less is used, so that the occurrence of vertical black stripes and sudden image density changes can be suppressed more reliably. On the other hand, it is possible to suppress the occurrence of transfer failure due to insufficient transfer charge density.

1 Photoconductor (latent image carrier)
3 Optical writing unit (latent image forming means)
4 Developing device (Developing means)
10 Transfer Device 11 Paper Conveying Belt (Belt Member)
12 Drive roller (stretching member)
13 Followed roller (stretching member)
20 Transfer brush (brush member)
21 Metal holder (conductive support)
22 Brush part P Transfer paper (transfer material)

JP-A-9-281768

Claims (13)

A belt device that moves an endless belt member endlessly while being stretched by a plurality of stretching members, and a transfer device that has a plurality of raised portions and is arranged so as to contact the back surface that is the inner surface of the loop of the belt member A transfer bias applied to the transfer brush from the transfer brush to the back surface of the belt member, and is carried on the surface of the image carrier that is in contact with the front surface of the belt member. A transfer device for transferring the visible image to the front surface of the belt member or a transfer material held by the belt member,
The plurality of raised brushes in the transfer brush are each made of a material in which a conductive resistance adjusting agent is dispersed in a polyamide resin,
A stainless steel (SUS304) electrode that is in contact with the entire area of the brush surface that is a contact area with the belt member in the transfer brush and a bias power source are connected via an electric resistance of 20 [MΩ], and With a stainless steel (SUS304) holding member holding the transfer brush connected to the ground via an ammeter, a DC bias of 2 [kV] is applied between the electric resistance and the holding member by the bias power source. A value obtained by converting the brush VI value obtained by reading from the ammeter as a brush VI value when the current value is applied for 1 minute after application is converted per unit area of the brush surface is 4. 3 [μA / cm ² ] or less,
A small electrode that is in contact with the entire area of the brush surface in the belt member movement direction and is in contact with the brush member in the belt member width direction with a length of 10 mm is brought into contact with one end portion of the brush surface in the belt member width direction. The bias power supply is connected in a state where the small electrode and the bias power supply are connected via an electric resistance of 20 [MΩ] and the holding member holding the transfer brush is grounded via an ammeter. After applying a DC bias of 2 [kV] between the electric resistance and the holding member, the small electrode is moved at a speed of 10 mm / sec from one end side to the other end side in the belt member width direction. , The maximum value of the plurality of scan currents obtained by the operation of sequentially reading the current value of the ammeter as a scan current at a time interval of 100 [times / sec] Value converted per unit area, is at 56.5 [μA / cm ^2] or less,
With the transfer brush removed, the transfer brush is located downstream in the belt moving direction from the contact portion between the image carrier and the belt member in the entire circumferential direction of the belt member and before the removal. A metal roller is brought into contact with a region that has been in contact with the metal roller, and a bias power source is connected to the metal roller. Among the plurality of stretching members, the metal roller is disposed upstream of the contact portion in the belt movement direction. An electric wire connected to a stretching member adjacent on the upstream side in the belt moving direction is connected to an electric wire connected to the image carrier, and 20 [MΩ between the joint and the image carrier. In the state where the belt member and the image carrier are respectively driven at the same linear velocity as that in the print job, the connecting portion is connected to the ground via an ammeter. Then, a DC bias of 2 [kV] was applied between the metal roller and the ammeter, and the current value obtained when 1 minute had elapsed after the application was read from the ammeter as the belt VI value. A value obtained by converting the belt VI value per unit area of the belt surface of the belt member is 0.18 to 3.5 [μA / cm ² ],
The transfer current applied to the transfer brush is 110 to 200 [μA],
and,
In the belt member, a surface layer made of a conductive resin is formed on the front side of a belt base made of conductive rubber, and the surface resistivity on the back side is 10 ⁷ to 10 ¹⁰ [Ω / □ in JISK6911. ], The surface resistivity of the front surface side is 10 ⁸ to 10 ¹³ [Ω / □] in JISK6911, and the volume resistivity is 10 ⁷ to 10 ¹¹ [Ω · cm] in JISK6911. A transfer device characterized by that. A belt device that moves an endless belt member endlessly while being stretched by a plurality of stretching members, and a transfer device that has a plurality of raised portions and is arranged so as to contact the back surface that is the inner surface of the loop of the belt member A transfer bias applied to the transfer brush from the transfer brush to the back surface of the belt member, and is carried on the surface of the image carrier that is in contact with the front surface of the belt member. A transfer device for transferring the visible image to the front surface of the belt member or a transfer material held by the belt member,
The plurality of raised brushes in the transfer brush are each made of a material in which a conductive resistance adjusting agent is dispersed in a polyamide resin,
A stainless steel (SUS304) electrode that is in contact with the entire area of the brush surface that is a contact area with the belt member in the transfer brush and a bias power source are connected via an electric resistance of 20 [MΩ], and With a stainless steel (SUS304) holding member holding the transfer brush connected to the ground via an ammeter, a DC bias of 2 [kV] is applied between the electric resistance and the holding member by the bias power source. A value obtained by converting the brush VI value obtained by reading from the ammeter as a brush VI value when the current value is applied for 1 minute after application is converted per unit area of the brush surface is 4. 3 [μA / cm ² ] or less,
A small electrode that is in contact with the entire area of the brush surface in the belt member movement direction and is in contact with the brush member in the belt member width direction with a length of 10 mm is brought into contact with one end portion of the brush surface in the belt member width direction. The bias power supply is connected in a state where the small electrode and the bias power supply are connected via an electric resistance of 20 [MΩ] and the holding member holding the transfer brush is grounded via an ammeter. After applying a DC bias of 2 [kV] between the electric resistance and the holding member, the small electrode is moved at a speed of 10 mm / sec from one end side to the other end side in the belt member width direction. The average value is subtracted from the maximum value of the plurality of scan current values obtained by sequentially reading the current value of the ammeter as a scan current at a time interval of 100 [times / sec] Ripple is a value obtained by the multiplication division and 100 of the average value for the value is less than 34 [%],
The transfer current applied to the transfer brush is 110 to 200 [μA],
and,
In the belt member, a surface layer made of a conductive resin is formed on the front side of a belt base made of conductive rubber, and the surface resistivity on the back side is 10 ⁷ to 10 ¹⁰ [Ω / □ in JISK6911. ], The surface resistivity of the front surface side is 10 ⁸ to 10 ¹³ [Ω / □] in JISK6911, and the volume resistivity is 10 ⁷ to 10 ¹¹ [Ω · cm] in JISK6911. A transfer device characterized by that. A belt device that moves an endless belt member endlessly while being stretched by a plurality of stretching members, and a transfer device that has a plurality of raised portions and is arranged so as to contact the back surface that is the inner surface of the loop of the belt member A transfer bias applied to the transfer brush from the transfer brush to the back surface of the belt member, and is carried on the surface of the image carrier that is in contact with the front surface of the belt member. A transfer device for transferring the visible image to the front surface of the belt member or a transfer material held by the belt member,
The plurality of raised brushes in the transfer brush are each made of a material in which a conductive resistance adjusting agent is dispersed in a polyamide resin,
After attaching metal clips to both ends of the raised hair, the distance between the clips is adjusted to apply a tension of 100 to 200 [gf] to the raised hair. The electrical resistance value per unit length of the above-mentioned raising determined based on the result of reading the current value after 1 minute with an ammeter was 3.0 × 10 ¹⁰ [Ω / mm] or more. There,
A small electrode that is in contact with the entire area of the brush surface in the belt member movement direction and is in contact with the brush member in the belt member width direction with a length of 10 mm is brought into contact with one end portion of the brush surface in the belt member width direction. The bias power supply is connected in a state where the small electrode and the bias power supply are connected via an electric resistance of 20 [MΩ] and the holding member holding the transfer brush is grounded via an ammeter. After applying a DC bias of 2 [kV] between the electric resistance and the holding member, the small electrode is moved at a speed of 10 mm / sec from one end side to the other end side in the belt member width direction. , The maximum value of the plurality of scan currents obtained by the operation of sequentially reading the current value of the ammeter as a scan current at a time interval of 100 [times / sec] Value converted per unit area, is at 56.5 [μA / cm ^2] or less,
A stainless steel (SUS304) electrode that is in contact with the entire area of the brush surface that is a contact area with the belt member in the transfer brush and a bias power source are connected via an electric resistance of 20 [MΩ], and With a stainless steel (SUS304) holding member holding the transfer brush connected to the ground via an ammeter, a DC bias of 2 [kV] is applied between the electric resistance and the holding member by the bias power source. A value obtained by converting the brush VI value obtained by reading from the ammeter as a brush VI value when the current value is applied for 1 minute after application is converted per unit area of the brush surface is 4. 3 [μA / cm ² ] or less,
With the transfer brush removed, the transfer brush is located downstream in the belt moving direction from the contact portion between the image carrier and the belt member in the entire circumferential direction of the belt member and before the removal. A metal roller is brought into contact with a region that has been in contact with the metal roller, and a bias power source is connected to the metal roller. Among the plurality of stretching members, the metal roller is disposed upstream of the contact portion in the belt movement direction. An electric wire connected to a stretching member adjacent on the upstream side in the belt moving direction is connected to an electric wire connected to the image carrier, and 20 [MΩ between the joint and the image carrier. In the state where the belt member and the image carrier are respectively driven at the same linear velocity as that in the print job, the connecting portion is connected to the ground via an ammeter. Then, a DC bias of 2 [kV] was applied between the metal roller and the ammeter, and the current value obtained when 1 minute had elapsed after the application was read from the ammeter as the belt VI value. A value obtained by converting the belt VI value per unit area of the belt surface of the belt member is 0.18 to 3.5 [μA / cm ² ],
The transfer current applied to the transfer brush is 110 to 200 [μA],
and,
In the belt member, a surface layer made of a conductive resin is formed on the front side of a belt base made of conductive rubber, and the surface resistivity on the back side is 10 ⁷ to 10 ¹⁰ [Ω / □ in JISK6911. ], The surface resistivity of the front surface side is 10 ⁸ to 10 ¹³ [Ω / □] in JISK6911, and the volume resistivity is 10 ⁷ to 10 ¹¹ [Ω · cm] in JISK6911. A transfer device characterized by that. A belt device that moves an endless belt member endlessly while being stretched by a plurality of stretching members, and a transfer device that has a plurality of raised portions and is arranged so as to contact the back surface that is the inner surface of the loop of the belt member A transfer bias applied to the transfer brush from the transfer brush to the back surface of the belt member, and is carried on the surface of the image carrier that is in contact with the front surface of the belt member. A transfer device for transferring the visible image to the front surface of the belt member or a transfer material held by the belt member,
The plurality of raised brushes in the transfer brush are each made of a material in which a conductive resistance adjusting agent is dispersed in a polyamide resin,
After attaching metal clips to both ends of the raised hair, the distance between the clips is adjusted to apply a tension of 100 to 200 [gf] to the raised hair. The electrical resistance value per unit length of the above-mentioned raising determined based on the result of reading the current value after 1 minute with an ammeter was 3.0 × 10 ¹⁰ [Ω / mm] or more. Yes,
A small electrode that is in contact with the entire area of the brush surface in the belt member movement direction and is in contact with the brush member in the belt member width direction with a length of 10 mm is brought into contact with one end portion of the brush surface in the belt member width direction. The bias power supply is connected in a state where the small electrode and the bias power supply are connected via an electric resistance of 20 [MΩ] and the holding member holding the transfer brush is grounded via an ammeter. After applying a DC bias of 2 [kV] between the electric resistance and the holding member, the small electrode is moved at a speed of 10 mm / sec from one end side to the other end side in the belt member width direction. The average value is subtracted from the maximum value of the plurality of scan current values obtained by sequentially reading the current value of the ammeter as a scan current at a time interval of 100 [times / sec] Ripple is a value obtained by the multiplication division and 100 of the average value for the value is less than 34 [%],
A stainless steel (SUS304) electrode that is in contact with the entire area of the brush surface that is a contact area with the belt member in the transfer brush and a bias power source are connected via an electric resistance of 20 [MΩ], and With a stainless steel (SUS304) holding member holding the transfer brush connected to the ground via an ammeter, a DC bias of 2 [kV] is applied between the electric resistance and the holding member by the bias power source. A value obtained by converting the brush VI value obtained by reading from the ammeter as a brush VI value when the current value is applied for 1 minute after application is converted per unit area of the brush surface is 4. 3 [μA / cm ² ] or less,
The transfer current applied to the transfer brush is 110 to 200 [μA],
and,
In the belt member, a surface layer made of a conductive resin is formed on the front side of a belt base made of conductive rubber, and the surface resistivity on the back side is 10 ⁷ to 10 ¹⁰ [Ω / □ in JISK6911. ], The surface resistivity of the front side is 10 ⁸ to 10 ¹³ [Ω / □] in JISK6911, and the volume resistivity is 10 ⁷ to 10 ¹¹ [Ω · cm] in JISK6911. A transfer device characterized by being. In the transfer device according to any one of claims 1 to 4,
A transfer roller that rotates while contacting the back surface of the belt member;
The brush member is disposed in a belt extension region between the transfer roller and a tension member that stretches the belt member on the upstream side in the belt movement direction, out of the entire region in the circumferential direction of the belt member. A transfer device characterized by being brought into contact. The transfer device according to claim 5.
The transfer apparatus, wherein the brush member is brought into contact with a region in the belt extending direction downstream of the contact region between the belt member and the image carrier in the belt extension region. The transfer device according to any one of claims 1 to 6,
2. A transfer apparatus according to claim 1, wherein the brush member has a brushed water content of 9.0% or less in an environment of 20 ° C. and 95% RH. The transfer device according to claim 7.
2. A transfer apparatus according to claim 1, wherein the raised hair is one in which carbon is uniformly dispersed in a cross-sectional direction. The transfer device according to any one of claims 1 to 8,
While the endless belt member is endlessly moved while being stretched by a plurality of stretching members, the front end side of the brush portion of the transfer brush is brought into contact with the back surface, which is the loop inner surface of the belt member, and applied to the transfer brush. The visible image of the surface of the image carrier that is in contact with the front surface of the belt member is guided to the front surface of the belt member while guiding the transfer bias from the front end side of the brush portion to the back surface of the belt member. Transfer to the surface or transfer material held by this
The scan current measured by using an insulating tape attached to a region located closer to the image carrier among the two regions divided in the belt member moving direction as the small electrode. A transfer device, wherein the maximum value of the image carrier side scan current, which is a value, is smaller than the maximum value of the scan current measured using the small electrode to which the insulating tape is not attached. An image carrier that carries a visible image on an endless moving surface, a latent image forming unit that forms a latent image on the surface, a developing unit that develops the latent image on the surface, and a visible image obtained by development In an image forming apparatus comprising a transfer means for transferring to a front surface of a belt member that moves endlessly or a transfer material held by the belt member,
An image forming apparatus using the transfer device according to claim 1 as the transfer unit. The image forming apparatus according to claim 10.
An image forming apparatus, wherein the transfer apparatus has an effective transfer charge density of 1.06 × 10 ⁻⁷ [C / cm ² ] or less. The image forming apparatus according to claim 10.
As the transfer means, a transfer charge density from a power source that outputs a transfer bias applied to the belt member is set to be larger than the effective transfer charge density and equal to or less than 2.67 × 10 ⁻⁷ [C / cm ² ]. An image forming apparatus characterized by comprising: The image forming apparatus according to claim 10.
As the transfer means, a transfer charge density from a power source that outputs a transfer bias applied to the belt member is larger than 5.87 × 10 ⁻⁸ [C / cm ² ] and 2.67 × 10 ⁻⁷ [C / cm ² ] or less is used.

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