JP2012194433A - Charging device and image forming device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress the accumulation of discharge products produced by discharge from a discharging wire in a shield case when sending air into the shield case.SOLUTION: Discharging wires 526a and 526b are provided inside a shield casse 527. A duct 521 sends air from a duct ventilation port 5212 into the shield case 527 through a nozzle 523. A chamber suction port 5221b is provided on an upstream side of the duct ventilation port 5212, and a chamber suction port 5221a is provided on a downstream side of the duct ventilation port 5212. A chamber 522b sucks the air in the nozzle 523 from the chamber suction port 5221b, and a chamber 522a sucks the air in the nozzle 523 from the chamber suction port 5221a. A control section 10 respectively changes the amount of air which the chamber 522b and the chamber 522a suck per unit time, according to a lapse of time.

Description

  The present invention relates to a charging device and an image forming apparatus.

  In an electrophotographic image forming apparatus, a charging device such as a corotron charger or a scorotron charger is widely used in a charging process of a photosensitive drum. The corotron charger is composed of a discharge wire provided along the surface of the photosensitive drum, which is an object to be charged, and a shield case provided so as to surround the discharge wire. A high voltage is applied to the discharge wire. By applying the voltage, a corona discharge is generated around the wire, and a positive or negative charge is given to the object to be charged. In the scorotron charger, a mesh-like grid electrode is provided between the discharge wire and the object to be charged, and the amount of charge given to the object to be charged is adjusted by applying a bias voltage to the grid electrode. It can be done.

  By the way, it is known that discharge products such as ozone and nitrogen oxide are generally generated when corona discharge occurs. For this reason, in Patent Document 1, an air outlet along the discharge wire is provided in the shield case, and air outside the apparatus housing of the image forming apparatus is guided to the air outlet by an air duct and is blown into the shield case. It is described that the discharge product is blown away from the periphery of the discharge wire by a flow. Further, in Patent Document 2, air is compressed by a partition wall provided in an air duct and the pressure is increased and then fed into the shield case, thereby suppressing uneven air flow in the direction in which the discharge wire extends. Are listed.

Japanese Patent Laid-Open No. 07-287436 JP-A-10-198128

  An object of this invention is to suppress that the discharge product produced | generated by the discharge from a discharge wire stays in a shield case, when air is sent in in a shield case.

  According to a first aspect of the present invention, there is provided a charging device having an opening that opens toward an outer peripheral surface of a cylindrical image carrier that rotates about an axis, and the opening is in an axial direction of the image carrier. A shield case that extends, a discharge wire that extends along the axial direction of the image carrier inside the shield case, and charges the image carrier by discharge, and is farther from the image carrier than the discharge wire A blower means for sending air into the shield case from a blower port provided at a position via a nozzle; and a first intake port provided inside the nozzle, wherein the image is more than the blower port. The first suction means for sucking the air inside the nozzle from the first suction port provided on the upstream side in the rotation direction of the holder, and the second suction port provided inside the nozzle. And the image protection rather than the air outlet. A second suction means for sucking air inside the nozzle from a second suction port provided on the downstream side in the rotation direction of the body, and an amount of air sucked per unit time by the first suction means And fluctuating means for fluctuating the amount of air sucked per unit time by the second suction means according to the passage of time.

  The charging device according to a second aspect of the present invention is the charging device according to the first aspect, wherein the changing unit is configured to determine the amount of air sucked per unit time by the first suction unit in the first period. The second suction unit performs control to increase the amount of air sucked per unit time, and in the third period, the amount of air sucked per unit time by the first suction unit is set to the second amount. The suction means performs control to reduce the amount of air sucked per unit time, and further performs the control in the first period and the control in the third period alternately.

  According to a third aspect of the present invention, there is provided the charging device according to the second aspect, wherein the fluctuating means has the second period between the first period and the third period. The difference between the amount of air sucked per unit time by one suction means and the amount of air sucked per unit time by the second suction means is the difference in the first period or the third It has the structure made smaller than the said difference in a period.

  The charging device according to a fourth aspect of the present invention is the charging device according to any one of the first to third aspects, wherein the first suction means is a plurality of first intake air at different positions in the axial direction. A plurality of suction mechanisms for sucking air from the respective ports; and the second suction means includes a plurality of suction mechanisms for sucking air from the plurality of second intake ports at different positions in the axial direction, The fluctuating means is configured to control the amount of air sucked per unit time by a suction mechanism provided in each of the first suction means and the second suction means.

  A charging device according to a fifth aspect of the present invention is the configuration according to any one of the first to fourth aspects, further comprising a detection unit that detects a degree of contamination of the discharge wire, and the variation unit includes the detection unit. When the degree of dirt detected by the means is equal to or greater than a threshold, the first suction means sucks per unit time as compared to the case where the degree of dirt detected by the detection means is less than the threshold. And an amount of air sucked per unit time by the second suction means.

  An image forming apparatus according to a sixth aspect of the present invention comprises: an image holding body that rotates about an axial direction; the charging device according to any one of claims 1 to 5; An exposure unit that forms an electrostatic latent image on the outer peripheral surface of the image holding member that has been charged by the charging device, and a developing unit that develops the electrostatic latent image formed by the exposure unit; A transfer unit that transfers the image developed by the developing unit to a recording medium; and a fixing unit that fixes the image transferred by the transfer unit to the recording medium.

  According to the structure of Claim 1, 6, compared with the case where the quantity of the air in the nozzle attracted | sucked per unit time is constant, the discharge product produced | generated by the discharge from a discharge wire is a shielding case. It can suppress staying in.

  According to the structure of Claim 2, 3, compared with the structure which does not repeat the 1st-3rd period, the grade of the said suppression can be made equal.

  According to the configuration of the fourth aspect, the degree of suppression can be changed according to the axial position of the image carrier.

  According to the configuration of the fifth aspect, the degree of the suppression can be changed according to the degree of contamination of the discharge wire.

1 is a block diagram illustrating a hardware configuration of an image forming apparatus according to an embodiment of the present invention. FIG. 2 is a schematic diagram illustrating a structure of an image forming unit according to the embodiment. FIG. 2 is a schematic cross-sectional view of a charging unit when the image forming apparatus according to the embodiment is viewed from the front. FIG. 2 is a schematic diagram of a charging unit when the image forming apparatus according to the embodiment is viewed from the upper diagonal direction on the back side. It is a figure which shows the simulation result which concerns on the same embodiment. It is a flowchart explaining the drive control which concerns on the same embodiment. It is a mimetic diagram explaining the flow of the air in the shield case concerning the embodiment. It is a figure which shows the simulation result which concerns on the same embodiment. FIG. 10 is a perspective view of a charging unit when an image forming apparatus according to a modification is viewed from the back side. It is an example which shows the content of the drive control information which concerns on a modification.

Embodiments of the present invention will be described below with reference to the drawings. In the following, “lower” means the direction of gravity, and “upper” means the direction opposite to the direction of gravity.
(1) Configuration FIG. 1 is a block diagram illustrating a hardware configuration of the image forming apparatus 1.
The image forming apparatus 1 is an apparatus that forms an image by an electrophotographic method, for example, and includes a control unit 10, a storage unit 20, an operation unit 30, a display unit 40, and an image forming unit 50. The control unit 10 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory), and the CPU executes a program stored in the ROM or the storage unit 20. Thus, each part of the image forming apparatus 1 is controlled. The storage unit 20 is a nonvolatile auxiliary storage device such as an HD (Hard Disk) and stores various programs and data. The operation unit 30 includes a plurality of keys, receives a user operation, and supplies a signal corresponding to the operation to the control unit 10. The display unit 40 includes a display, and displays a processing progress status, information for guiding an operation to a user, and the like based on information supplied from the control unit 10. The image forming unit 50 includes a photosensitive drum 51, a charging unit 52, an exposure unit 53, a developing unit 54, a transfer unit 55, and a fixing unit 56, and forms an image based on the image data on a recording medium. The recording medium refers to a sheet-like medium on which an image is formed by the image forming apparatus 1, and is, for example, paper.

  FIG. 2 is a schematic diagram illustrating the structure of the image forming unit 50. The photosensitive drum 51 is a cylindrical member having a photoconductive layer formed on the surface thereof, and is an example of an image carrier. The photosensitive drum 51 is rotated around the rotation shaft 511 in the direction of the arrow a in the drawing by a drive unit (not shown). In the following description, the extending direction of the rotating shaft 511 of the photosensitive drum 51 is referred to as the axial direction. The charging unit 52 is a corona discharge device called a scorotron, for example, and charges the surface of the photosensitive drum 51 by corona discharge. That is, the charging unit 52 functions as an example of a charging device. The exposure unit 53 is an example of an exposure unit, and forms an electrostatic latent image by irradiating an image-modulated laser beam toward the outer peripheral surface of the photosensitive drum 51. The electrostatic latent image refers to a latent image formed by the difference between the potential of the exposed area and the potential of the unexposed area. The developing unit 54 is an example of a developing unit, and develops an electrostatic latent image formed on the outer peripheral surface of the photosensitive drum 51 with toner to form a toner image. The transfer unit 55 is an example of a transfer unit, and includes a conductive roll that is in contact with the outer peripheral surface of the photosensitive drum 51. A voltage having a polarity opposite to that of the toner image formed on the outer peripheral surface of the photosensitive drum 51 is applied to the roll, whereby the toner image is transferred to the recording medium. The fixing unit 56 includes a pair of rollers, and heats and pressurizes the recording medium using the pair of rollers, thereby fixing the toner image transferred onto the recording medium. That is, the fixing unit 56 functions as an example of a fixing unit.

  By the way, the corona discharge device generates discharge products such as ozone around the discharge wire by corona discharge. When this discharge product adheres to the discharge wire, an oxide is easily generated on the surface of the discharge wire. When oxides are generated on the surface of the discharge wire, so-called discharge unevenness occurs in which the discharge amount is different in the drawing direction of the discharge wire. Since the extending direction of the discharge wire is along the axial direction of the photosensitive drum, so-called charging unevenness occurs in which the charging potential varies in the axial direction of the surface of the photosensitive drum due to the discharge unevenness. As a result, a phenomenon called density unevenness in which the density of the image formed on the recording medium becomes non-uniform occurs. For this reason, for example, as in Patent Document 1 and Patent Document 2, a technique has been proposed in which air is blown out from the periphery of the discharge wire by sending air around the discharge wire. However, if the flow of the supplied air is strong or weak in the direction in which the discharge wire is stretched, the portion of the discharge wire located in the portion where the air flow is weak will be locally oxidized, and that portion is still another part. In some cases, the amount of discharge is smaller than in this part.

  Here, with reference to FIGS. 3 and 4, the structure of the charging unit 52 in the present embodiment will be described. 3 shows a schematic cross-sectional view of the charging unit 52 when the image forming apparatus 1 is viewed from the front. FIG. 4 shows the charging unit 52 when the image forming apparatus 1 is viewed from the upper diagonal direction on the back side. The schematic diagram is shown. The charging unit 52 is a charging device that charges the photosensitive drum 51, and includes a duct 521, a nozzle 523, a shield case 527, chambers 522a and 522b, discharge wires 526a and 526b, a grid electrode 525, and a bias power source. 5241 and a bias power source 5242 are provided.

  The shield case 527 is located between the nozzle 523 and the photosensitive drum 51, and has a second opening 5272 that opens toward the outer peripheral surface of the photosensitive drum 51 and a first opening that faces the nozzle 523. Each of the openings extending along the axial direction of the photosensitive drum 51. Inside the shield case 527, discharge wires 526a and 526b are provided in a state extending in a direction along the axial direction of the photosensitive drum 51 and maintaining a predetermined distance from the surface of the photosensitive drum 51. ing. A bias power source 5241 is connected to the discharge wires 526a and 526b, and a bias voltage is applied from the bias power source 5241. When a bias voltage is applied to the discharge wires 526 a and 526 b, air is ionized by corona discharge, and the generated charges are supplied to the peripheral surface of the photosensitive drum 51. That is, the discharge wires 526a and 526b charge the peripheral surface of the photosensitive drum 51 by corona discharge. At this time, the shield case 527 shields the discharge except for the side of the periphery of the discharge wires 526a and 526b that faces the photosensitive drum 51. The grid electrode 525 is a mesh member that is insulated from the shield case 527 and is provided so as to cover the second opening 5272 of the shield case 527. The grid electrode 525 is located between the discharge wires 526 a and 526 b and the photosensitive drum 51. A bias power source 5242 is connected to the grid electrode 525, and a bias voltage is applied from the bias power source 5242. By applying a bias voltage to the grid electrode 525, the amount of charge supplied to the photosensitive drum 51 is regulated by the discharge wires 526a and 526b, and the charging potential of the photosensitive drum 51 is controlled.

  The nozzle 523 has an opening that opens toward the chambers 522 a and 522 b and the duct 521, and an opening 5231 that opens toward the shield case 527, and each opening extends along the axial direction of the photosensitive drum 51. It extends. The nozzle 523 sends air from the opening 5231 to the first opening 5271 of the shield case 527. When viewed from the axial direction of the photosensitive drum 51, the nozzle 523 becomes wider as it approaches the photosensitive drum 51. The term “width” as used herein refers to the length in a direction perpendicular to each of the perpendiculars drawn from the rotation shaft 511 of the photosensitive drum 51 to the surface of the first opening 5271.

  The duct 521 connects a duct air inlet 5211 which is an opening surface provided on the back surface of the housing of the image forming apparatus 1 and a duct air outlet 5212 which is an opening surface provided in the housing. A duct fan 5213 is provided at the duct inlet 5211. The duct fan 5213 sucks air outside the housing from the duct intake port 5211 into the duct 521, and sends it into the nozzle 523 through the duct blower port 5212. A duct air outlet 5212 of the duct 521 is inserted into the nozzle 523 through an opening at the upper end of the nozzle 523. That is, the duct 521 functions as an example of a blowing unit. The duct blower port 5212 is an example of a blower port, and the opening surface thereof extends along the axial direction of the photosensitive drum 51. The area of the opening surface of the duct air outlet 5212 is narrower than the area of the opening surface of the duct air inlet 5211. In particular, as the duct 521 approaches the duct air outlet 5212, the volume is once reduced, and thereafter, the volume is increased immediately before the duct air outlet 5212. This structure is intended to blow air from the nozzle 523 so as to spread in the shield case 527 after the air sucked from the duct air inlet 5211 has been pressurized through the duct and reaches the duct air outlet 5212. Is. According to Pascal's principle, the fluid in a closed container conveys the pressure per unit area received at a certain point to all other parts of the fluid as it is, regardless of the shape of the container. It is known. As described above, since the pressurized air is sent from the nozzle 523, the strength of the flow rate of the air flow in the longitudinal direction of the nozzle 523 is suppressed as compared with the case where there is no such pressure increase.

  By the way, when the air pressurized in the duct 521 is sent into the shield case 527, the speed of the air sent into the shield case 527 (hereinafter referred to as the flow velocity) is faster than when the air is not pressurized. Here, the inventor conducted an experiment to examine the influence of the increase in the flow velocity. Specifically, the internal space of a member having a shape corresponding to the shield case 527 (hereinafter referred to as a shield case-shaped member) is divided into 1038 sections in a lattice shape, and particles corresponding to discharge products are arranged in the respective sections. Thus, a simulation was performed in which air was sent into the shield case-shaped member for a certain period of time. The result of this simulation is shown in FIG.

  FIG. 5A shows the trajectory of particles in the shield case-shaped member when the flow velocity is fast, and FIG. 5B shows the trajectory of particles in the shield case-shaped member when the flow velocity is slow. Yes. According to this simulation result, the number of particles that have moved out of the shield case-shaped member within a certain period is 185 out of 1038 when the flow rate is fast, and 982 out of 1038 when the flow rate is slow. Met. As described above, the number of particles moved from the inside to the outside of the shield case-shaped member is smaller when the flow velocity is high. The reason is considered as follows. First, when the flow velocity is high, the Reynolds number that characterizes the flow state increases. When the Reynolds number is large, the fluid flow can be divided into a main flow that is a non-viscous flow and a boundary layer that is affected by viscosity. When this boundary layer develops, a phenomenon called exfoliation, that is, a backflow of fluid occurs. This phenomenon causes a decrease in the mainstream flow velocity and a decrease in the mainstream flow rate. Also in the simulation results, it is considered that the situation where the particles easily stay in the shield case-shaped member occurred due to this boundary layer. Therefore, the inventor has provided the chambers 522a and 522b so that the flow of air sent from the nozzle 523 to the shield case 527 is temporally varied.

  Returning to FIG. 3 and FIG. Here, the direction in which the outer peripheral surface of the rotating photosensitive drum 51 approaches as viewed from the duct blower port 5212 is referred to as upstream, and the direction in which the outer peripheral surface moves away is referred to as downstream. A gap is provided between the outer side surface of the duct 521 and the inner side surface of the nozzle 523 where the duct air outlet 5212 is provided. There are one air gap on the upstream side and one on the downstream side of the duct air blowing port 5212. The air gap on the upstream side is called a chamber air inlet 5221b, and the air gap on the downstream side is called a chamber air inlet 5221a. The chamber air inlet 5221b is provided on the upstream side of the position of the duct air outlet 5212, and the chamber air inlet 5221a is provided on the downstream side of the position of the duct air outlet 5212. That is, the chamber intake port 5221b functions as an example of a first intake port, and the chamber intake port 5221a functions as an example of a second intake port.

  The chamber 522b is provided on the outer surface on the upstream side of the duct 521. The space in the chamber 522b is divided into two spaces of an intake chamber 5224b and an exhaust chamber 5225b by a partition plate 5226b provided with a slit. ing. The intake chamber 5224b is a space constituted by a surface where the upper end outer edge of the nozzle 523 and the lower end outer edge of the chamber 522b are coupled, an outer surface on the upstream side of the duct 521, and a partition plate 5226b. The intake chamber 5224b is connected to the exhaust chamber 5225b through a slit in the partition plate 5226b. The exhaust chamber 5225b is a space constituted by the outer surface on the upstream side of the duct 521, the chamber 522b, and the partition plate 5226b. The exhaust chamber 5225 b is connected to a chamber exhaust port 5222 b provided on the back surface of the casing of the image forming apparatus 1. A chamber fan 5223b is provided at the chamber exhaust port 5222b. When the chamber fan 5223b rotates, the chamber 522b sucks the air in the nozzle 523 from the chamber intake port 5221b and discharges the sucked air from the chamber exhaust port 5222b to the outside of the housing via the intake chamber 5224b and the exhaust chamber 5225b. To do. That is, the chamber 522b functions as an example of a first suction unit that sucks air inside the nozzle 523.

  The chamber 522a is provided on the outer surface on the downstream side of the duct 521, and the space in the chamber 522a is divided into two spaces of an intake chamber 5224a and an exhaust chamber 5225a by a partition plate 5226a provided with a slit. ing. The intake chamber 5224a is a space formed by a surface where the upper edge of the nozzle 523 and the lower edge of the chamber 522a are joined, an outer surface on the downstream side of the duct 521, and a partition plate 5226a. The intake chamber 5224a is connected to the exhaust chamber 5225a through the slit of the partition plate 5226a. The exhaust chamber 5225a is a space constituted by the outer surface on the upstream side of the duct 521, the chamber 522a, and the partition plate 5226a. The exhaust chamber 5225 a is connected to a chamber exhaust port 5222 a provided on the back surface of the casing of the image forming apparatus 1. A chamber fan 5223a is provided at the chamber exhaust port 5222a. When the chamber fan 5223a rotates, the chamber 522a sucks the air in the nozzle 523 from the chamber intake port 5221a, and discharges the sucked air from the chamber exhaust port 5222a to the outside of the housing via the intake chamber 5224a and the exhaust chamber 5225a. To do. That is, the chamber 522a functions as an example of a second suction unit that sucks air inside the shield case.

  As described above, inside the nozzle 523, air is fed from the duct blower port 5212 and air is sucked from the chamber intake port 5221a and the chamber intake port 5221b.

<Fan drive control processing>
Next, drive control of the duct fan 5213, the chamber fan 5223a, and the chamber fan 5223b will be described. FIG. 6 is a flowchart for explaining drive control. The control unit 10 determines whether or not it is time to perform the charging process (step S10). If the control unit 10 determines that it is the timing to perform the charging process based on the signal supplied from the operation unit 30 (step S10; YES), the control unit 10 determines the chamber fan 5223a and the chamber fan 5223b from the drive control information D1. A method for controlling the drive is specified (step S20). The drive control information D1 is information for controlling the driving of the chamber fan 5223a and the chamber fan 5223b, and is stored in the storage unit 20 in advance. The drive control information D1 includes, for example, a first period for driving only the chamber fan 5223a, a second period for driving the chamber fan 5223a and the chamber fan 5223b, and a third period for driving only the chamber fan 5223a. The length of each period and the order of each period are included. Here, the first period, the second period, and the third period are all X minutes, and the order of these periods is the order of the first period, the second period, and the third period. And The control unit 10 controls driving of the duct fan 5213, the chamber fan 5223a, and the chamber fan 5223b based on the content of the drive control information D1 (step S30). Note that the control unit 10 drives the duct fan 5213 at least during the entire period during which the charging process is performed.

Here, the control unit 10 controls the driving of each fan based on the drive control information D1, and thereby temporally varies the flow of air sent from the nozzle 523 to the shield case 527 (hereinafter referred to as air flow). Explain the mechanism. FIG. 7 is a schematic diagram for explaining the flow of air. First, in the first period, the controller 10 drives the chamber fan 5223b to cause the chamber 522b to suck the air around the chamber inlet 5221b. In this case, a negative pressure is generated around the chamber inlet 5221b, and as shown by an arrow 7a1 in FIG. 7A, the surrounding air is discharged from the chamber 522b to the outside of the housing. . As a result, the flow path of the air (main flow) sent from the duct 521 is biased to the side (upstream side) where the chamber intake port 5221b is provided, as indicated by the arrow 7a2, in the nozzle 523. Further, the main flow path is biased toward the side where the discharge wire 526 b is provided in the shield case 527. In this case, the development of the boundary layer around the discharge wire 526b is suppressed, and the occurrence of a peeling phenomenon that causes a decrease in the main flow velocity or a decrease in the main flow rate is suppressed. The mainstream air volume of 0.165 m ³ / min, and 0.03 m ³ / min suction amount 0.00m ³ / min, the suction amount of the upstream side of the chamber inlet port 5221a is provided (the downstream side) FIG. 8A shows the result of simulating the air flow in the nozzle 523 in this case. As described above, also in this simulation result, the main flow path is biased to the upstream side. The color image shown in FIG. 8 will be submitted separately.

  Next, in the second period, the control unit 10 drives the chamber fan 5223a and the chamber fan 5223b to cause the chamber 522a to suck air around the chamber intake port 5221a and cause the chamber 522b to draw the air in the chamber intake port 5221b. Aspirate ambient air. In this case, a negative pressure is generated around the chamber intake port 5221a and the chamber intake port 5221b. As shown by arrows 7b1 and 7b2 in FIG. It is discharged from the housing from 522b. As a result, in the nozzle 523, the main flow path is on the side where the chamber intake port 5221a is provided as indicated by the arrow 7b3 and on the side where the chamber intake port 5221b is provided as indicated by the arrow 7b4. Will be biased. Further, the main flow path is divided into a side where the discharge wire 526b is provided and a side where the discharge wire 526a is provided in the shield case 527, respectively. In this case, the development of each boundary layer is suppressed, and the occurrence of the peeling phenomenon is suppressed. The result of simulating the flow of air in the nozzle 523 when the mainstream air volume is 0.165 m 3 / min, the downstream suction volume is 0.006 m 3 / min, and the upstream suction volume is 0.018 m 3 / min. As shown in FIG. As described above, also in this simulation result, the main flow path is close to each of the downstream side and the upstream side.

Next, in the third period, the control unit 10 drives the chamber fan 5223a to cause the chamber 522a to suck the air around the chamber inlet 5221a. In this case, a negative pressure is generated around the chamber inlet 5221a, and as shown by an arrow 7c1 in FIG. 7C, the surrounding air is discharged from the chamber 522a to the outside of the housing. . As a result, the main flow path is biased toward the side where the chamber intake port 5221a is provided in the nozzle 523, as indicated by the arrow 7c2. Further, the main flow path is biased toward the side where the discharge wire 526a is provided in the shield case 527. In this case, the development of the boundary layer around the discharge wire 526a is suppressed, and the occurrence of a peeling phenomenon that causes the main flow velocity to decrease or the main flow rate to decrease is suppressed. The mainstream air volume of 0.165 m ³ / min, simulating the flow of air in the nozzle 523 when the suction amount of 0.03 m ³ / min downstream, the suction amount of the upstream and the 0.0ft ³ / min The result is shown in FIG. As described above, also in this simulation result, the main flow path is biased toward the downstream side.

  Here, in each of the first period, the second period, and the third period, the development of the boundary layer is suppressed for a specific space portion of the shield case 527. For example, the development of the boundary layer around the discharge wire 526b is suppressed in the first period, and the development of the boundary layer around the discharge wire 526b and the boundary layer around the discharge wire 526a is suppressed in the second period. In the third period, the development of the boundary layer around the discharge wire 526a is suppressed. However, if each of these periods lasts sufficiently long, a boundary layer develops in a space portion other than the specific space portion. Therefore, the control unit 10 repeats the first period, the second period, and the third period as described above. As described above, when the first period, the second period, and the third period are repeated, when the air flow fluctuates with time, the air flow in the shield case 527 is disturbed, and the discharge is generated. The retention of things will be suppressed. That is, the control unit 10 is an example of a variation unit, and varies the amount of air sucked per unit time by the chamber 522a and the chamber 522b according to the passage of time, thereby varying the amount of the air with the passage of time. Compared with the case where it does not make it, the retention of a discharge product is suppressed.

(3) Modifications The contents of the embodiment described above may be modified as follows. Each modification shown below may be implemented in combination as necessary.
[Modification 1]
In the above-described embodiment, the control unit 10 performs the first period for driving only the chamber fan 5223a, the second period for driving the chamber fan 5223a and the chamber fan 5223b, and the third period for driving only the chamber fan 5223a. Each of the above is repeated in the order of the first period, the second period, and the third period, but the mode of driving each fan is not limited to this. For example, the control unit 10 may repeat each period in the order of the first period and the third period, or each period in the order of the first period, the second period, the third period, and the second period. May be repeated.

  Further, the control unit 10 may control the amount of air sucked per unit time by the chamber 522b and the chamber 522a by controlling not only whether or not the chamber fans 5223a and 5223b are driven but also the driving force thereof. For example, the control unit 10 performs control to increase the amount of air that the chamber 522b sucks per unit time in the first period to be larger than the amount of air that the chamber 522a sucks per unit time, and performs the third period. , The amount of air sucked per unit time by the chamber 522b is controlled to be smaller than the amount of air sucked by the chamber 522a per unit time, and further, the control in the first period and the control in the third period And may be performed alternately. Further, for example, the control unit 10 determines that the amount of air that the chamber 522b sucks per unit time in the second period between the first period and the third period, and the chamber 522a per unit time. The chamber fans 5223a and 5223b are set so that the difference from the amount of air to be sucked (hereinafter referred to as the difference in suction amount) is smaller than the difference in suction amount in the first period or the difference in suction amount in the third period. The driving force may be controlled. According to this structure, compared with the structure which does not repeat the 1st-3rd period, the grade which suppresses the stay of the discharge product in the shield case 527 is made equal.

[Modification 2]
FIG. 9 is a schematic diagram of the charging unit 52a when the image forming apparatus according to the modification is viewed from the upper oblique direction on the back side. The charging unit 52a is a charging device that charges the photosensitive drum 51, and includes a duct 521, a nozzle 523, a shield case 527, chambers 522c and 522d, discharge wires 526a and 526b, a grid electrode 525, and a bias power source. 5241 and a bias power source 5242 are provided. In FIG. 9, illustration of the shield case 527, the discharge wires 526a and 526b, the grid electrode 525, the bias power source 5241, and the bias power source 5242 is omitted. The chamber 522c is provided on the outer surface on the upstream side of the duct 521, and the chamber 522d is provided on the outer surface on the downstream side of the duct 521. The chamber 522c includes a plurality of suction mechanisms 5227c1 to c3 that suck air from a plurality of chamber intake ports at different positions in the axial direction of the photosensitive drum 51, respectively. The suction mechanisms 5227c1 to c3 each have an independent space, and chamber fans 5223c1 to c3 are provided inside the space. When the chamber fans 5223c1 to c3 rotate, the air inside the nozzle 523 is sucked from the chamber inlet and discharged from the chamber outlet to the outside of the housing. Further, the chamber 522d includes a plurality of suction mechanisms 5227d1 to d3 that suck air from a plurality of chamber intake ports at different positions in the axial direction of the photosensitive drum 51, respectively. The suction mechanisms 5227d1 to d3 each have an independent space, and chamber fans 5223d1 to d3 are provided inside the space. Note that the illustration of the chamber 522d is omitted because it has the same structure as the chamber 522c except for the arrangement.

  Here, the control unit 10 controls the suction amount per unit time in the suction mechanisms 5227c1 to c3 of the chamber 522c based on the content of the drive control information D2 shown in FIG. 10, and the suction mechanisms 5227d1 to d3 of the chamber 522d. The amount of suction per unit time is controlled. It is assumed that the drive control information D2 is stored in the storage unit 20 in advance. As shown in the figure, the drive control information D2 includes a fan ID for identifying the chamber fans 5223c1 to d3 provided in the suction mechanisms 5227c1 to d3, and units in the suction mechanisms 5227c1 to d3 when the chamber fans are driven. The driving force indicating the degree of the amount of air sucked per time is described in association with each other. Based on the content of the drive control information D2, the control unit 10 drives the chamber fan 5223c1 with the fan ID “5223c1” with the driving force “large” and the chamber fan 5223c2 with the fan ID “5223c2” with the driving force “medium”. The chamber fan 5223c3 having the fan ID “5223c3” is driven with the driving force “small”. Further, based on the content of the drive control information D2, the control unit 10 drives the chamber fan 5223d1 with the fan ID “5223d1” with the driving force “large” and drives the chamber fan 5223d2 with the fan ID “5223d2” with the driving force “medium”. And the chamber fan 5223d3 with the fan ID “5223d3” is driven with the driving force “small”. This driving force may be determined based on the result of an experiment or the like performed by the designer. For example, a place where the discharge product tends to stay inside the shield case 527 is “large”, and a place where the discharge product does not stay easily. May be “small” and other locations may be “medium”. According to this configuration, the retention of the discharge product in the shield case 527 is suppressed regardless of the position of the shield case 527.

[Modification 3]
The control unit 10 detects the degree of contamination of the discharge wire 526a or the discharge wire 526b (hereinafter referred to as the discharge wire 526), and when the detected degree of contamination of the discharge wire 526 is equal to or greater than the threshold, the contamination of the discharge wire 526 is detected. The amount of air sucked by the chamber 522a per unit time and the amount of air sucked by the chamber 522b per unit time may be increased as compared with the case where the degree is less than the threshold. That is, the control unit 10 may function as an example of a detection unit that detects dirt on the discharge wire 526. Specifically, the bias power source 5242 applies a bias voltage to the grid electrode 525 and detects the current value of the feedback current from the grid electrode 525. When the discharge wire 526 is contaminated with discharge products or the like, the current value changes. Therefore, the control unit 10 stores the current value detected by the bias power source 5242 in the RAM for a predetermined period, and calculates the rate of change of the current value. And the control part 10 detects the grade of the stain | pollution | contamination of the discharge wire 526 by comparing the predetermined threshold value and the said change rate. When the change rate is equal to or higher than the threshold, the control unit 10 increases the driving force of the chamber fan 5223a or the chamber fan 5223b so that the chamber 522a or the chamber 522b has a unit time. Increase the amount of air sucked around. Further, the control unit 10 may control the driving of the chamber fan in accordance with a potential difference between the grid electrode 525 and the discharge wire 526 (hereinafter referred to as grid potential). When the discharge product adheres to the discharge wire 526 and is dirty, the grid potential is smaller than when the discharge product is not dirty. The controller 10 detects the degree of contamination of the discharge wire 526 by comparing a predetermined threshold value with the grid potential. When the grid potential is less than the threshold, the control unit 10 increases the amount of air sucked per unit time by the chamber 522a or the chamber 522b as compared to the case where the grid potential is greater than or equal to the threshold. According to this configuration, it is possible to change the degree of suppressing the retention of the discharge product in the shield case 527 nozzle 523 according to the degree of contamination of the discharge wire.

[Modification 4]
In the embodiment described above, the control unit 10 controls the amount of air in the nozzle 523 sucked per unit time by the chamber 522a and the chamber 522b by controlling the driving of the chamber fan 5223a and the chamber fan 5223b. It was. However, the controller 10 may control driving other than the chamber fan 5223a and the chamber fan 5223b as long as the device can suck the air in the nozzle 523. For example, the control unit 10 may control the amount of air in the nozzle 523 sucked per unit time by the chamber 522a and the chamber 522b by controlling so-called pump driving.

DESCRIPTION OF SYMBOLS 1 ... Image forming apparatus, 10 ... Control part, 20 ... Memory | storage part, 30 ... Operation part, 40 ... Display part, 50 ... Image forming part, 51 ... Photosensitive drum, 52 ... Charging part, 521 ... Duct, 5211 ... Duct Inlet, 5212 ... Duct fan, 5213 ... Inlet fan, 523 ... Nozzle, 526a, 526b ... Discharge wire, 525 ... Grid electrode, 522a, 522b ... Chamber, 5221a, 5221b ... Chamber inlet, 5222a, 5222b ... Chamber exhaust Mouth, 5223a, 5223b ... chamber fan, 53 ... exposure unit, 54 ... developing unit, 55 ... transfer unit, 56 ... fixing unit

Claims (6)

A shield case having an opening that opens toward an outer peripheral surface of a cylindrical image carrier that rotates about an axis, and the opening extends in the axial direction of the image carrier;
Inside the shield case, a discharge wire that extends along the axial direction of the image carrier and charges the image carrier by discharge;
Blowing means for sending air into the shield case through a nozzle from a blower opening provided at a position farther from the image carrier than the discharge wire;
A first air inlet provided in the nozzle, and the air inside the nozzle is discharged from a first air inlet provided upstream of the air blowing port in the rotation direction of the image carrier. First suction means for sucking;
A second air intake port provided in the nozzle, and the air inside the nozzle is discharged from a second air intake port provided downstream of the air blowing port in the rotation direction of the image carrier. A second suction means for sucking;
Fluctuating means for varying the amount of air sucked per unit time by the first suction means and the amount of air sucked by the second suction means per unit time according to the passage of time. A charging device characterized by that. The varying means is
In the first period, the amount of air sucked per unit time by the first suction means is controlled to be larger than the amount of air sucked by the second suction means per unit time,
In the third period, control is performed so that the amount of air sucked per unit time by the first suction means is smaller than the amount of air sucked by the second suction means per unit time, and The charging device according to claim 1, wherein the control in the first period and the control in the third period are alternately performed. The varying means is
In a second period between the first period and the third period, the amount of air sucked per unit time by the first suction means, and the second suction means per unit time The charging device according to claim 2, wherein a difference from the amount of air sucked into the first is made smaller than the difference in the first period or the difference in the third period. The first suction means includes a plurality of suction mechanisms for sucking air from a plurality of first intake ports located at different positions in the axial direction,
The second suction means includes a plurality of suction mechanisms for sucking air from a plurality of second air inlets at different positions in the axial direction,
4. The apparatus according to claim 1, wherein the fluctuating unit controls a suction amount of air per unit time by a suction mechanism provided in each of the first suction unit and the second suction unit. The charging device according to Item. Comprising detection means for detecting the degree of contamination of the discharge wire;
The fluctuating means may be configured such that when the degree of dirt detected by the detecting means is greater than or equal to a threshold value, the first suction is compared with a case where the degree of dirt detected by the detecting means is less than a threshold value. 5. The electrification according to claim 1, wherein the amount of air sucked per unit time by the means and the amount of air sucked per unit time by the second suction means are increased. apparatus. An image carrier that rotates about an axial direction;
6. The charging device according to claim 1, wherein the image holding member is charged.
An exposure unit that forms an electrostatic latent image on the outer peripheral surface of the image holding member by exposing the outer peripheral surface charged by the charging device;
Developing means for developing the electrostatic latent image formed by the exposure means;
Transfer means for transferring the image developed by the developing means to a recording medium;
An image forming apparatus comprising: a fixing unit that fixes the image transferred by the transfer unit to the recording medium.