JP2013134413A - Air duct, air blowing device, and image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an air duct capable of taking in air blown from an air blower from an inlet; discharging the air from an outlet to a portion in a longitudinal direction of a long corona discharger to which the air is to be blown so as to flow along a direction orthogonal to the longitudinal direction; and suppressing, as an air duct having the inlet and the outlet formed into different opening shapes, discharge from the corona discharger from being unstable under the influence of the air discharged from the outlet of the air duct.SOLUTION: An air duct includes a most-downstream suppression unit provided at a most-downstream position in a direction to lead air in a passage space in a passage part so that the passage part is sealed with an air permeable member. The air permeable member in the most-downstream suppression unit is configured to be in a state where an air permeation rate in an area where the air is discharged to directly reach a discharge generating member arranged along a longitudinal direction of a corona discharger is reduced relative to air permeation rates of other areas.

Description

  The present invention relates to a blower tube, a blower, and an image forming apparatus.

  In an image forming apparatus that forms an image composed of a developer on a recording sheet, for example, a process of charging or discharging a latent image holder such as a photoconductor, a process of transferring an unfixed image to a recording sheet, and the like Use a corona discharger that performs corona discharge.

  In the corona discharger, a blower that blows air toward the component parts in order to prevent unnecessary substances such as paper dust and discharge products from adhering to the component parts such as the discharge wire and the grid electrode is provided. It may be added. The blower in this case is generally composed of a blower that sends air and a duct (blower pipe) that guides the air sent from the blower to a target structure such as a corona discharger.

  Conventionally, various improvements and the like have been made for the air blower and the like so that air can be uniformly blown in the longitudinal direction of the components such as the discharge wires. In particular, as such a blower device, a configuration in which the shape of the passage space through which the air of the duct flows is formed in a special shape, or a configuration in which a rectifying plate for adjusting the direction of air flow is installed in the passage space of the duct The air blower etc. which employ | adopt another structure which is illustrated below instead of employ | adopting are proposed.

  As an air duct for guiding the air of the blower fan to the corona discharge device, a partition wall is formed in the air duct along the longitudinal direction of the corona discharge device (shield case), and the front side of the partition wall Thus, there are known a blower and a corona discharge device that employ an air duct that temporarily increases the pressure of the air flow (air flow) sent from the blower fan (Patent Document 1).

  According to Patent Document 1, according to the air blower and the corona discharge device, the air flow flowing through the duct is made uniform along the longitudinal direction of the shield case when passing through the partition wall, and becomes a uniform flow. It is shown that it will be blown into the case. Further, Patent Document 1 shows that the partition wall may be constituted by an air filter provided so as to block the flow path in the air duct.

JP-A-10-198128

  In the present invention, the air sent from the blower is taken in from the inlet, and the air is caused to flow along the direction perpendicular to the longitudinal direction with respect to the longitudinal portion of the long corona discharger to be blown. As an air blower tube that is taken out from the outlet and formed with different opening shapes at the inlet and outlet, it is possible to suppress the discharge of the corona discharger from becoming unstable due to the influence of the air coming out of the outlet of the air blower tube. The present invention provides a blower tube that can be used, and also provides a blower device and an image forming apparatus using the blower tube.

The blast tube of this invention (A1)
An inlet for taking in air;
It is arranged in a state facing a longitudinal portion of a long corona discharger to be blown with air taken from the inlet, and has a long opening shape parallel to the longitudinal portion of the corona discharger, and the inlet And an outlet having a different opening shape,
A passage portion formed with a passage space for flowing air between the inlet and the outlet;
A plurality of suppressing portions that are provided in different portions in the direction of flowing air in the passage space in the passage portion and suppress the flow of air;
A state in which the passage space in the most downstream portion is blocked with a breathable member interspersed with a plurality of ventilation portions at least in the downstream portion of the passage space in the passage space of the passage portion in the air flow direction as the plurality of suppressing portions. The most downstream restraint configured to be
The air permeable member in the most downstream restraint portion is configured such that the air permeability of the area where the air exits so as to directly reach the discharge generating member disposed along the longitudinal direction of the corona discharger is the air permeability of the other area. It is configured to be in a relatively lowered state.

The blast pipe of this invention (A2) is a blast pipe of the above-mentioned invention A1, wherein the area configured to relatively reduce the air permeability of the breathable member is a short opening shape of the outlet. When the width dimension around the discharge generating member along the hand direction is W (mm) and the shortest distance between the outer surface of the breathable member and the discharge generating member is L (mm), the following conditional expression:
W ≧ 0.15 × L
Is satisfied.

Moreover, the air blower of this invention (B1)
A blower that sends air;
An inlet for taking in air sent from the blower and a longitudinal portion of a long corona discharger to which the air taken in from the inlet should be blown are arranged in parallel with the longitudinal portion of the corona discharger. An outlet having an opening shape different from the inlet, a passage portion formed with a passage space for flowing air by connecting between the inlet and the outlet, and a passage in the passage portion Provided in different parts in the direction of flowing the air in the space, and provided with a blower pipe having a plurality of suppressing portions for suppressing the flow of air,
The air-permeable member in which the plurality of ventilation portions are scattered in the passage space in the most downstream portion at least in the downstream portion of the passage space in the direction in which the air flows in the passage portion as the plurality of suppressing portions in the blower pipe. Provide the most downstream suppression part configured to be in a closed state,
The air permeable member in the most downstream restraint portion is configured such that the air permeability of the area where the air exits so as to directly reach the discharge generating member disposed along the longitudinal direction of the corona discharger is the air permeability of the other area. It is configured to be in a relatively lowered state.

The air blower of this invention (B2) is the air blower of the above invention B1, wherein the area configured to relatively reduce the air permeability of the air permeable member of the air duct is the outlet. When the width dimension centered on the discharge generating member along the short direction of the opening shape is W (mm), and the shortest distance between the outer surface of the breathable member and the discharge generating member is L (mm), Conditional expression,
W ≧ 0.15 × L
Is satisfied.

Furthermore, the image forming apparatus of the present invention (C1) includes a long corona discharger to be blown with air and a blower for blowing air toward a longitudinal portion of the corona discharger.
The blower device includes the blower pipe of the invention A1 or A2.

The image forming apparatus of the present invention (C2) includes a long corona discharger to be blown with air and a blower for blowing air toward a longitudinal portion of the corona discharger.
The air blower is composed of the air blower of the invention B1 or B2.

  According to the blower tube of the invention A1 and the blower device of the invention B1, it is possible to suppress the discharge of the corona discharger from being unstable due to the influence of the air exiting from the outlet of the blower tube.

  In the blower of the above-mentioned invention A2 and the blower of the above-mentioned invention B2, the discharge of the corona discharger is unstable due to the influence of the air coming out from the outlet of the blower tube, compared to the case where the configuration of the invention is not provided. Can be suppressed more appropriately.

  According to the image forming apparatuses of the inventions C1 and C2, the discharge of the corona discharger becomes unstable due to the influence of the air coming out from the outlet of the blower tube as compared with the case where the configuration of the invention is not provided. It is possible to prevent the occurrence of poor image quality.

It is explanatory drawing which shows the outline | summary of the ventilation duct which concerns on Embodiment 1 etc., the ventilation apparatus using the same, and an image forming apparatus. FIG. 2 is a schematic perspective view illustrating a charging device including a corona discharger provided in the image forming apparatus of FIG. 1. It is a schematic perspective view which shows the outline | summary of the ventilation duct applied to the charging device of FIG. It is sectional drawing which follows the QQ line of the air blower (air blow duct) of FIG. It is the schematic which shows a state when the air blower of FIG. 3 is seen from upper direction. It is a figure which shows a state when the air blower of FIG. 3 is seen from the downward direction (exit). FIG. 5 shows a configuration of a specific area of the air-permeable member constituting the most downstream suppressing portion of the air duct of FIG. 4, (a) is an explanatory view showing a state viewed from the outlet side of the air duct, and (b) is It is sectional drawing which shows a part in the exit of (a). (A) is sectional explanatory drawing which shows the specific area of a breathable member, (b) is the structure (for example, the airflow rate was made into zero) in which the air permeability of the specific area in the breathable member of (a) was reduced relatively It is sectional explanatory drawing which shows the example set. It is explanatory drawing which shows the operation state etc. of the air blower (blower duct) of FIG. It is a graph which shows the result of the test regarding the performance characteristic of the ventilation duct of FIG. The other example of a structure (example which forms a thing with a relatively small opening area as a ventilation part) which reduces the air permeability of the specific area of the breathable member which consists of a porous member is shown, (a) is an air duct. Explanatory drawing which shows the state seen from the exit side, (b) is sectional drawing which shows a part in the exit of (a). FIG. 5 shows still another configuration example (example in which the number of holes is thinned out as a ventilation portion) for reducing the air permeability of a specific area of a breathable member made of a porous member, and (a) is from the outlet side of the air duct. Explanatory drawing which shows the state seen, (b) is sectional drawing which shows a part in the exit of (a). The example of a structure in case the breathable member and the charging device (two discharge wires) are installed in an inclined state is shown, and (a) is a cross-sectional explanatory view showing a specific area of the breathable member in that case (B) is sectional explanatory drawing which shows the structure (for example, the air permeability was set to zero) which reduced the air permeability of the specific area in the air permeable member of (a) relatively. It is sectional drawing which shows the other structural example of a ventilation duct. It is a schematic sectional drawing which shows a ventilation duct etc. at the time of comprising a most downstream suppression part with the air permeable member which consists of a porous member. The structural example (example which mounts | wears with the shielding frame material with respect to the air permeable member) which reduces the air permeability of the specific area of the air permeable member which consists of a porous member is shown, (a) is the exit side of a ventilation duct Explanatory drawing which shows the state seen from (b) is sectional drawing which shows a part in the exit of (a). It is upper surface explanatory drawing which shows the various example of a ventilation duct.

  DESCRIPTION OF EMBODIMENTS Hereinafter, modes for carrying out the present invention (simply referred to as “embodiments”) will be described with reference to the accompanying drawings.

[Embodiment 1]
1 to 3 show an air duct according to Embodiment 1, an air blower using the air duct, and an image forming apparatus. FIG. 1 shows an outline of the image forming apparatus, and FIG. 2 shows a charging device used as the image forming apparatus, which is a long target structure to which air should be abutted by the blower duct or blower. 3 has shown the outline | summary of the ventilation duct or the air blower.

  As shown in FIG. 1, the image forming apparatus 1 forms a toner image composed of toner as a developer in an internal space of a casing 10 composed of a support frame, an exterior cover, and the like. As an example, the image forming unit 20 for transferring to the paper 9, the paper feeding device 30 for storing and transporting the paper 9 supplied to the image forming unit 20, and the toner image formed by the image forming unit 20 are fixed to the paper 9. A fixing device 35 is installed. In the first embodiment, a single image forming unit 20 is illustrated as an example. However, for the image forming unit, for example, when a color image forming apparatus is used, a plurality of image forming units are applied. You may make it the structure to carry out.

  The image forming unit 20 is configured using, for example, a known electrophotographic system, and includes a photosensitive drum 21 that rotates in a direction indicated by an arrow A (a clockwise direction in the drawing), and a photosensitive member. A charging device 4 that charges a peripheral surface, which is an image forming area of the drum 21, to a required potential, and light (dotted line with an arrow) based on image information (signal) input from the outside to the surface of the photosensitive drum 21 after charging. , An exposure device 23 that forms an electrostatic latent image having a potential difference, a developing device 24 that develops the electrostatic latent image into a toner image with toner, and a transfer device 25 that transfers the toner image onto a sheet 9. The cleaning device 26 mainly removes toner remaining on the surface of the photosensitive drum 21 after transfer.

  Of these, a corona discharger is used as the charging device 4. As shown in FIG. 2 and the like, the charging device 4 including the corona discharger includes a rectangular top plate 40a and a side plate 40b that hangs down from a long side extending along the longitudinal direction B of the top plate 40a. , 40c and a shield case (covering member) 40 having an external shape, two end support members (not shown) attached to both end portions (short side portions) in the longitudinal direction B of the shield case 40, and the two Two corona discharge wires 41A and 41B that are attached between the end support bodies so as to pass through the inner space of the shield case 40 and extend almost linearly, and the lower opening of the shield case 40, A grid-like grid electrode (electric field adjusting plate) 42 is provided which covers the lower opening and is attached in a state of being present between the corona discharge wire 41 and the peripheral surface of the photosensitive drum 21. And it has, and a corona discharger so-called scorotron type. Reference numeral 40d shown in FIG. 4 and the like is a partition wall that partitions a space in which the two corona discharge wires 41A and 41B are arranged.

  Further, the charging device 4 is in a state where the two corona discharge wires 41 </ b> A and 41 </ b> B are opposed to the peripheral surface of the photosensitive drum 21 with a predetermined interval (for example, a discharge gap) and the rotation axis of the photosensitive drum 21. They are arranged so as to be present at least in the image formation target area along the direction. Further, the charging device 4 is configured to apply a charging voltage to each of the discharge wires 41A and 41B (between the photosensitive drum 21) from a power supply device (not shown) when an image is formed.

  In addition, the charging device 4 is applied to the corona discharge wires 41 and the grid electrodes 42 with the use thereof, such as paper dust of the paper 9, discharge products generated by corona discharge, and substances (unnecessary items) such as toner external additives. As a result of adhesion and contamination, corona discharge may not be performed sufficiently or uniformly, and charging defects such as uneven charging may occur. For this reason, the charging device 4 is provided with a blower device 5 for abutting air against the discharge wire 41 and the grid electrode 42 in order to prevent or suppress unwanted substances from adhering to the discharge wire 41 and the grid electrode 42. ing. An opening 43 for taking in air from the blower 5 is formed on the upper surface 40 a of the shield case 40 of the charging device 4. The opening 43 is formed so that the opening shape is rectangular. The details of the blower 5 will be described later.

  The sheet feeding device 30 accommodates a plurality of sheets 9 of a required size and type used for image formation in a stacked state, and a sheet container 31 such as a tray type or a cassette type, and the sheet container And a delivery device 32 that sends out the paper 9 stored in the paper 31 one by one toward the transport path, and sends out the paper 9 one by one when the paper feeding time comes. A plurality of paper containers 31 are provided according to the usage mode. A one-dot chain line with an arrow in FIG. 1 indicates a conveyance path through which the sheet 9 is mainly conveyed. The sheet conveyance path is composed of a plurality of sheet conveyance roll pairs 33a and 33b, a conveyance guide member (not shown), and the like.

  The fixing device 35 is heated in a roll form, a belt form, or the like in which a surface temperature is heated and held at a required temperature by a heating unit inside a housing 36 in which an introduction port and a discharge port through which the sheet 9 passes are formed. A rotating body 37 and a pressurizing rotating body 38 such as a roll form or a belt form rotating in contact with a required pressure so as to substantially follow the axial direction of the heating rotating body 37 are provided. The fixing device 35 introduces and passes the sheet 9 after the toner image has been transferred to a contact portion (fixing processing portion) formed by contact between the heating rotator 37 and the pressure rotator 38. Fixing.

  Image formation by the image forming apparatus 1 is performed as follows. Here, a basic image forming operation when an image is formed on one side of the sheet 9 will be described as an example.

  In the image forming apparatus 1, when the control device or the like receives an image forming operation start command, in the image forming unit 20, the peripheral surface of the photosensitive drum 21 that starts rotating is charged to a predetermined polarity and potential by the charging device 4. The At this time, in the charging device 4, a charging voltage is applied to the two corona discharge wires 41 </ b> A and 41 </ b> B, and an electric field is formed between the discharge wires 41 </ b> A and 41 </ b> B and the peripheral surface of the photosensitive drum 21. Then, corona discharge is generated, whereby the peripheral surface of the photosensitive drum 21 is charged to a required potential. At this time, the charging potential of the photosensitive drum 21 is adjusted by the grid electrode 42.

  Subsequently, exposure based on image information is performed from the exposure device 23 on the peripheral surface of the charged photosensitive drum 21 to form an electrostatic latent image having a required potential difference. Thereafter, when the electrostatic latent image formed on the photosensitive drum 21 passes through the developing device 24, the electrostatic latent image is developed with the toner charged in the required polarity supplied from the developing roll 24a, and the toner image is developed. As visualized.

  Next, when the toner image formed on the photoconductive drum 21 is conveyed to the transfer position facing the transfer device 25 by the rotation of the photoconductive drum 21, it is supplied from the paper supply device 30 through the conveyance path at this timing. The paper 9 is transferred by the transfer device 25. The peripheral surface of each photosensitive drum 21 after the transfer is cleaned by a cleaning device 26.

  Subsequently, the sheet 9 on which the toner image is transferred in the image forming unit 2 is transported so as to be introduced into the fixing device 35 after being peeled off from the photosensitive drum 21, and pressed with the heating rotator 37 in the fixing device 35. When passing through the contact portion with the rotating body 38, the toner image is melted and fixed on the paper 9 by being heated under pressure. After the fixing is completed, the sheet 9 is discharged from the fixing device 35 and is transported and stored in a paper discharge storage unit (not shown) formed outside the housing 10 or the like.

  As described above, a single-color image composed of one color toner is formed on one side of one sheet 9, and the basic image forming operation is completed. When there is an instruction for a plurality of image forming operations, the above-described series of operations are similarly repeated for the number of sheets.

  Next, the blower 5 will be described.

  As shown in FIGS. 1 and 3, the blower 5 is a blower 50 having a rotating fan that sends air, and a blower that takes in the air sent from the blower 50 and directs it to the charging device 4 to be blown and ejects it. And a duct 51.

  As the blower 50, for example, a radiant flow type blower fan is used, and is driven and controlled so as to send a required amount of air. As shown in FIGS. 3 to 6, the air duct 51 includes an inlet 52 for taking in air sent from the blower 50 and a longitudinal direction B of the long charging device 4 to which air taken in from the inlet 52 should be blown. The outlet 53 is arranged in a state facing the portion (the upper surface 40 a of the shield case 40) and discharges the air so as to flow along the direction orthogonal to the longitudinal direction B, and the air is connected between the inlet 52 and the outlet 53. And a passage portion 54 in which a passage space 54a is formed.

  The passage portion 54 of the air duct 51 has a rectangular tube shape in which one end portion is opened with an inlet 52 and the other end portion is closed, and the entire portion extends along the longitudinal direction B of the charging device 4. The guide passage 54A and a portion near the other end of the guide passage 54A are bent and extended substantially at a right angle in a substantially horizontal direction (a direction substantially parallel to the coordinate axis X) with the width of the passage space widened. The formed rectangular tube-shaped first bending passage portion 54B and the vertical direction (coordinate axis Y and the coordinate axis Y) from the one end portion of the first bending passage portion 54B toward the charging device 4 while maintaining the same width of the passage space. And a second bending passage portion 54C formed so as to be finally bent and extended in a substantially parallel direction). An outlet 53 having an opening shape slightly narrower than the cross-sectional shape of the passage space at the end portion is formed at the end portion of the second bent passage portion 54C (however, the length in the longitudinal direction of the rectangular shape is substantially the same). is there.). The passage spaces 54a of the first bending passage portion 54B and the second bending passage portion 54C are both set to have substantially the same width (dimension along the longitudinal direction B).

  The inlet 52 of the air duct 51 is formed so that the opening shape is substantially square. A connection duct 55 is connected to the inlet 52 to connect the blower 50 and send air from the blower 50 to the inlet 52 of the blower duct 51 (FIG. 3). Further, the outlet 53 of the air duct 51 is formed so that its opening shape is a long shape (for example, a rectangle) parallel to the longitudinal direction B portion of the charging device 4. For this reason, the air duct 51 has a relationship in which the inlet 52 and the outlet 53 are formed in different opening shapes. In addition, even when the inlet 52 and the outlet 53 have the same shape, when the opening areas are different from each other (when they are similar in shape), they are included in the relationship of being formed with different opening shapes. .

  Here, in the air duct 51 in which the inlet 52 and the outlet 53 are formed in different opening shapes as described above, the cross-sectional shape of the passage space 54 a is in the middle of the passage portion 54 that connects the inlet 52 and the outlet 53. There is a part to be changed. Incidentally, in this air duct 51, the cross-sectional shape of the substantially square passage space 54a of the introduction passage portion 54A has a rectangular passage space that extends only in the horizontal direction (regardless of the height) in the first bent passage portion 54B. The cross-sectional shape is changed to 54a. In other words, the cross-sectional shape of the passage space 54a of the introduction passage portion 54A is the cross-sectional shape of the passage space 54a that is abruptly widened in the first bent passage portion 54B.

  Further, in the case of the air duct 51 in which such a portion where the cross-sectional shape of the passage space 54a changes is present, the air flow is disturbed in the portion where the cross-sectional shape changes, such as separation or vortex. Therefore, even if air having a uniform wind speed is taken in, the air speed from the outlet 53 tends to be uneven. In addition, the tendency that the wind speed of the air exiting from the outlet finally becomes non-uniform in this way changes the direction in which the air flows (progresses) in the air duct 51 regardless of whether or not the cross-sectional shape of the passage space 54a changes. The case occurs almost similarly.

  FIGS. 17A to 17C show typical examples 510A to 510C of air ducts in which the inlet 52 and the outlet 53 are formed in different opening shapes. In the figure, the air taken into the inlet 52 in each duct 510 is shown. Each state of the wind speed and the wind speed of the air exiting from the outlet 53 is indicated by the length of the arrow. In FIG. 17, each air duct 510 is shown as viewed from the upper surface side. Further, in the figure, when the lengths of the arrows are the same, it indicates that the wind speed is the same, and when the lengths are different, it indicates that the wind speed is different. Furthermore, the dotted line in a figure has shown the passage space (side wall part which forms) of each duct. Incidentally, the air ducts 510B and 510C are also structural examples in which the direction in which the air flows is changed in the middle and at least one of the cross-sectional shape and the cross-sectional area of the passage space is changed. In addition, the air duct 510D shown in FIG. 17d is a configuration example in which the inlet 52 and the outlet 53 are formed in the same opening shape (and the same opening area), and only the direction in which the air flows is changed in the middle. It is a duct.

  Therefore, as shown in FIG. 3 to FIG. 6 and the like, the air duct 51 of the air blower 5 has air at different parts in the flow direction of the passage space 54a of the passage portion 54 (the direction of the arrow indicated by the symbol E). Two restraining portions 61 and 62 for restraining the flow of are provided. Of the two restraining parts, the restraining part 62 is the most downstream restraining part provided at the most downstream part in the direction of flowing air in the passage space 54 a of the passage part 54, and the other restraining part 61 is the It is the 1st upstream suppression part provided in the site | part located in the upstream of the direction which flows air rather than the most downstream suppression part 62 among the passage spaces 54a.

  The first upstream suppressing portion 61 is provided at a substantially intermediate position in the direction in which air flows in the passage space 54a of the first bending passage portion 54B. The first upstream suppressing portion 61 blocks a part of the passage space 54a in a state along a direction parallel to the longitudinal direction of the opening shape of the outlet 53 (the same direction as the longitudinal direction B of the charging device 4). The outlet 53 has a gap 63 having a shape extending in the longitudinal direction of the opening shape.

  The first upstream suppressing portion 61 in the first embodiment is configured by allowing a plate-like partition member 64 to exist in the passage space 54a of the bending passage portion 54B without changing the outer shape of the first bending passage portion 54B. Has been. Specifically, the partition member 64 closes the upper space portion in the passage space 54a of the first bending passage portion 54B, and the lower end portion 64a of the partition member is required for the bottom (inner wall) of the passage space 54a. It arrange | positions so that it may be in the state which opened the space | interval H, and, thereby, the structure where the clearance gap 63 exists in the lower part of the channel | path space 54a is formed. The partition member 64 is formed by integrally molding the same material as that of the duct 51, or is formed of a material different from that of the duct 51.

  The height H, the path length M, and the width (length in the longitudinal direction) J of the gap 63 are from the viewpoint of making the air velocity of the air flowing from the introduction passage portion 54A into the first bending passage portion 54B as uniform as possible. It is selected and set in consideration of the size (capacity) of the duct 51 and the flow rate per unit time of air to be passed through the duct 51 or the charging device 4. For example, the height H of the gap 63 is not limited to the same dimension in the width direction, and can be set to a dimension that is uniformly or partially changed from the above viewpoint. In FIG. 4 and the like, the height H of the gap 63 is set so that the height H1 at the end near the entrance and the height H2 at the end away from the entrance are set to substantially the same value (that is, the width of the gap 63). The same dimension in the direction).

  On the other hand, the most downstream suppressing portion 62 is formed by closing the passage space (opening) at the terminal end (exit 53) of the second bent passage portion 54C by the air-permeable member 70 having the plurality of ventilation portions 71. ing.

  As shown schematically in FIG. 6, each of the plurality of ventilation portions 71 is a through hole extending so that each opening shape is substantially circular and penetrates linearly. The plurality of ventilation portions 71 are arranged at equal intervals along the longitudinal direction (B) of the opening shape of the outlet 53, for example, and are arranged at equal intervals in the short direction C perpendicular to the longitudinal direction. (For example, 4 or more) are arranged so as to exist. Accordingly, the plurality of ventilation portions 71 are formed so as to be scattered all over the passage space at the end of the second bending passage portion 54 </ b> C or the opening shape of the outlet 53. For this reason, the air permeable member 70 in Embodiment 1 is a perforated plate formed so that a plurality of ventilation portions (through holes) 71 are dotted on a plate-like member. Further, the plurality of ventilation portions 71 are preferably formed so as to be scattered substantially uniformly (with a substantially constant density) with respect to the opening region of the outlet 53, but the air flowing out from the outlet 53 As long as it does not appear uneven, it may be formed so as to exist in a slightly dense state.

  The breathable member 70 is formed by integrally molding the same material as the duct 51, or is formed of a material different from the duct 51 and attached to the outlet 53. The opening shape, opening size, hole length, and hole existence density of the ventilation portion (through hole) 71 are selected from the viewpoint of making the air velocity of the air flowing out from the second bending passage portion 54C through the outlet 53 as uniform as possible. Also, the dimension (capacity) of the duct 51 and the flow rate per unit time of air to be passed through the duct 51 or the charging device 4 are set.

  Further, in the blower duct 51 of the blower 5, even when the two suppressing portions 61 and 62 are provided, the corona discharge in the charging device 4 may be unstable due to the influence of the blown air. For this reason, from the viewpoint of suppressing the instability of the corona discharge due to the influence of the air blowing, the air-permeable member 70 in the most downstream suppressing portion 62 of the air duct 51 is shown in FIGS. The air permeability D (Da, Db) of the specific areas 70a, 70b through which the air directly reaches the discharge wires 41A, 41B arranged along the longitudinal direction B of the charging device 4, It is configured to be in a state (Da <Dm, Db <Dm) where the air permeability Dm of the area 70m other than the specific area is relatively lowered.

  The specific areas 70a and 70b in which the air directly reaches the discharge wires 41A and 41B in the breathable member 70 are, for example, as shown in FIG. 8A, a passage space 54a at the outlet 53 of the air duct 51. Assuming a case where the entirety is closed by a breathable member 70X formed by distributing a plurality of ventilation portions 71 substantially evenly, out of the air (arrows indicated by two-dot chain lines) from each ventilation portion 71 This is a region in a range where there are ventilation portions 71a and 71b in which air Ex that protrudes into and collides with either of the discharge wires 41A and 41B is present. As shown in FIG. 7 and the like, the specific areas 70a and 70b are portions having a planar shape (mainly a long rectangular shape) extending along the longitudinal direction (B) of the outlet 53 with a predetermined width.

  The air permeability D generally indicates a ratio of air passing through the air permeable member 70. More specifically, for example, when the air-permeable member 70 is a perforated plate in which a plurality of through holes 71 are formed as described above, the air permeability D is the opening of all the through holes 71 with respect to the total area of the surface of the perforated plate. It becomes the occupation ratio of the area (the total value of all opening areas of each hole). That is, the air permeability D in this case is represented by the expression “(opening area of all through holes / total area of plate members) × 100”. Further, the air permeability D when the air-permeable member 70 is a member other than this will be described later.

  As shown in FIGS. 4, 7 and the like, the breathable member 70 in the first embodiment has specific areas 70a and 70b at both ends in the short direction C of the outlet 53, and the specific area 70a. , 70 b are set to “zero”. Specifically, as shown in FIG. 4, FIG. 7, FIG. 8 (b), etc., the ventilation sections (through holes) 71a, 71b for emitting the air Ex are not formed in the specific areas 70a, 70b. It is composed. For this reason, since the air does not pass through the specific areas 70a and 70b, the air permeability D becomes zero. In FIG. 7, the symbol Wn indicates the dimension (width) along the short direction C of the opening shape of the outlet 53, and the symbols Wa and Wb indicate the dimension (width) along the short direction C of the specific areas 70a and 70b. .

  On the other hand, the air permeability Dm of the area 70m other than the specific area is obtained from the opening area of all the through portions (holes) 71 formed in the area of the area 70m. In addition, the opening area of all the penetration parts 71 is the value which multiplied the number of the through-holes 71 to the one opening area, when all the penetration parts (holes) 71 are formed with the same opening area. Become.

  Incidentally, the air permeability D of the specific areas 70a and 70b is generally preferably set to a value that is reduced by at least 10% or more with respect to the air permeability of the other areas 70c. Further, it is desirable to increase the degree of decrease in the air permeability D of the specific areas 70a and 70b as the wind speed of the air exiting from the outlet 53 increases.

  Hereinafter, the operation of the blower 5 will be described.

  In the blower device 5, when the drive setting time such as during the image forming operation is reached, the blower 50 is first rotationally driven to send out a required amount of air. Air (E) sent from the started blower 50 is taken into the passage space 54 a of the passage portion 54 from the inlet 52 of the blower duct 51 through the connection duct 55.

  Subsequently, as shown in FIGS. 5 and 9, the air (E) taken into the air duct 51 is sent to flow into the passage space 54b of the first bent passage portion 54B through the passage space 54a of the introduction passage portion 54A. (See dotted arrows E1a, E1b, etc. in FIG. 5). The air (E1) sent to the first bending passage portion 54B passes through the gap 63 of the first upstream suppression portion 61 and its traveling direction (air flowing direction) is changed to a substantially perpendicular direction. move on.

  At this time, the air (E2) when passing through the gap 63 of the first upstream suppression portion 61 is suppressed in its flow by the gap 63 of the first upstream suppression portion 61 (the pressure increases), and the gap It tries to flow out from 63 in a uniform state. Moreover, the air (E2) that flows through the gap 63 and flows into the passage space 54c of the second bending passage portion 54C is almost in the same direction as the longitudinal direction (B) of the outlet 53 when flowing out from the gap 63 of the suppressing portion 61. Aligned in the orthogonal direction.

  Next, the air (E2) that has flowed into the passage space 54c of the second bending passage portion 54C through the gap 63 of the first upstream suppression portion 61, as indicated by arrows E2a and E2b, is the passage space of the introduction passage portion 54A. By flowing into the passage space 54c of the second bending passage portion 54C having a larger volume than the space of the gap 54a and the gap 63, it stays in a state of turning in the passage space 54c of the second bending passage portion 54C. The unevenness of the wind speed is reduced.

  Finally, as shown in FIG. 9, the air (E2) that flows and stays in the second bending passage portion 54C is vented to constitute the most downstream suppression portion 62 provided at the end of the bending passage portion 54C or at the outlet 53. By passing through a plurality of ventilation portions (holes) 71 in the sex member 70, the air is blown out from the outlet 53 in a state in which the traveling direction is changed (see the direction and length of the arrow E3 in FIG. 9).

  At this time, the air (E3) blown out from the outlet 53 passes through a plurality of ventilation portions 71 formed in a zone 70m other than the specific zone of the breathable member 70 that is relatively narrower than the opening area of the outlet 53. As a result, the flow is suppressed (the pressure is also increased at this time) and sent out. In addition, the air (E3) blown out from the outlet 53 is scattered in the area 70m of the breathable member 70 which is narrower than the opening area of the outlet 53, and a plurality of ventilation portions 71 formed under the same conditions. Is passed through the outlet 53 in a uniform state corresponding to the surface of a region substantially close to the planar shape of the area 70n of the breathable member 70. Furthermore, the air (E3) blown out from the outlet 53 is sent out by changing the traveling direction in a direction substantially orthogonal to the longitudinal direction of the outlet 53.

  On the other hand, in the specific areas 70a and 70b of the air permeable member 70 constituting the most downstream suppressing portion 62 at the outlet 53, the air permeability Da and Db are both set to "zero" and the air vent portion 71 does not exist. The air (E3) is not emitted.

  As described above, all the air (E3) exiting from the plurality of ventilation portions 71 in the area 70m of the breathable member 70 constituting the most downstream suppressing portion 62 has a traveling direction substantially orthogonal to the longitudinal direction B of the outlet 53. And the wind speed is almost uniform. In addition, the wind speed of the air (E4) exiting from the outlet 53 is substantially uniform in the longitudinal direction (B) of the opening shape (rectangle) of the outlet 53, and is also substantially uniform in the short direction C. become.

  Then, the air (E3) sent out from the outlet 53 of the blower duct 51 is blown into the case 40 through the opening 43 formed in the upper surface 40a of the shield case 40 of the charging device 4, as shown in FIG.

  At this time, since there are specific areas 70a and 70b of the air-permeable member 70 constituting the most downstream suppressing portion 62 from the outlet 53 of the air duct 51, it proceeds to reach the discharge wires 41A and 41B of the charging device 4 directly. Such air (Ex: see FIG. 8a) is not generated. Actually, the air that comes out of the ventilation portion 71 in the area 70m other than the specific area of the air-permeable member 70 and is blown into the case 40 enters the case 40 in a state where at least the discharge wires 41A and 41B are avoided. The grid electrode 42 attached so as to be present in the lower opening 40 is sprayed.

  Thereby, since the two discharge wires 41A and 41B are not strongly blown so that the air exiting from the ventilation part 71 of the air-permeable member 70 in the air duct 51 directly collides, the outlet 53 of the air duct 51 It does not move due to the wind force of the air that comes out. As a result, in the charging device 4 to which the air duct 51 and the air blowing device 5 using the air duct 51 are applied, the corona discharge is unstable due to the influence of the air that the discharge wires 41A and 41B exit from the outlet 53 of the air duct 51. It is suppressed.

  Therefore, when charging is performed by the charging device 4, the peripheral surface of the photosensitive drum 21 is uniformly charged (uniformly in both the axial direction and the circumferential direction along the rotation direction A) without uneven charging. It becomes possible to do. In addition, the toner image formed by the image forming unit 20 including the charging device 4 and the image finally formed on the paper 9 may cause image quality failure due to charging failure such as uneven charging in the charging device 4. A good reduced image can be obtained. The poor image quality is streaky density unevenness that occurs along the rotation direction of the photosensitive drum 21, that is, the feeding direction of the paper 9. For example, when a portion where discharge (light emission) becomes strong in the discharge wire 41 due to the blowing from the blower 5 occurs, the charging potential of the corresponding portion of the photosensitive drum 21 corresponding to the portion becomes relatively high. As a result, in the obtained image, the density of the image portion (striped portion) corresponding to the corresponding portion is relatively lighter than that of the peripheral portion.

  In addition, in the charging device 4 to which the air duct 51 and the air blowing device 5 using the air duct 51 are applied, not only during the charging operation but also when the air is blown from the air blowing device 5 in other than the charging operation, the charging is performed by the air blowing. It is possible to prevent the separated unnecessary material from adhering to the discharge wire 41 and the like. Further, in the image forming apparatus 1 provided with the charging device 4, it is possible to suppress the occurrence of charging failure (charging unevenness, etc.) due to adhesion of unnecessary substances to the discharge wire 41 or the like in the charging device 4. The occurrence of image quality defects due to such charging defects is also suppressed.

  FIG. 10 shows the results of a test examining the performance characteristics of the air duct 51 (the state of the discharge wire by the air exiting from the outlet 53).

  The test uses the air duct 51 having the following configuration as the air duct 51 according to the first embodiment, and is set so as to satisfy the following conditions with respect to the charging device 4 (FIG. 2) in the first embodiment. In addition, when a required amount of air is introduced from the blower 50 into the air duct 51 and blown toward the discharge wire 41 of the charging device 4, the charging device 4 is in an operating state by supplying a charging voltage. The discharge wire 41 (actually one wire 41B) in FIG.

The entire shape of the air duct 51 is as shown in FIGS. 3 to 6, the inlet 52 has a substantially square opening shape of 22 mm × 23 mm, and the outlet 53 has a rectangular shape of 17.5 mm × 350 mm. The one having an opening shape was used. In addition, the first upstream suppressing portion 61 is configured by arranging a substantially flat partition member 64 so that a gap 63 having a height H of 1.5 mm, a path length M of 4 mm, and a width J of 345 mm exists. Further, the most downstream suppressing portion 62 has a porous member 70 provided with vent holes 71 having a hole diameter of 1 mm and a length of 3 mm under the condition that the density is 0.402 / mm ² (≈40.2 / cm ² ). Was present so as to close the outlet 53 of the air duct 51.

  And as the said air duct 51, about the air permeable member 70 which comprises the most downstream suppression part 62 of the exit 53, the width W (Wb) of the specific area (70b) which reduces an air permeability relatively (it makes it zero here) ) Is a state in which predetermined areas of the air-permeable member 70 are closed as shown in FIG. 4 and FIG. 8B so that the linear distance L is multiplied by several values (coefficients) shown in the above table. The thing which attached each (thing which does not form the vent hole 71) was prepared. Subsequently, the air ducts 51 to which the various air permeable members 70 are attached in this way are connected to the outer surface of the air permeable member 70 constituting the most downstream suppressing portion 62 of the outlet 53 and the discharge wire 41 (actually, the charging device 4). Were installed such that the linear distance L (Lb) to one of the wires 41B) was the value shown in the table of FIG. Note that the linear distance L is a dimension with the vertical center line (two-dot chain line K shown in FIG. 8 and the like) as a vertical projection from the discharge wire 41 to the outer surface of the air-permeable member 70 substantially at the center (intermediate point). is there.

  From the blower 50, common air is used so that the air velocity of the air exiting from the end position P2 (post position) located at the downstream side in the rotation direction A of the photosensitive drum 21 at the outlet 53 of the blower duct 51 is about 5 m / sec. And introduced. The wind speed was measured with an anemometer (Degree Controls Inc .: UAS1200LP).

  As shown in FIG. 10, the linear distance L (Lb) between the outer surface of the air-permeable member 70 in the air duct 51 and the discharge wire 41 (actually one wire 41B) of the charging device 4 is “30 mm” and “35 mm”. In any case, the width W (Wb) of the area 70 (70b) where the air permeability of the breathable member 70 is relatively lowered is set to “0.15 · L (= 0.15 × L)” and “0”. .20 · L ”, no fluctuation in discharge light emission of the discharge wire 41 (41B) in the charging device 4 was observed.

Further, from the result shown in FIG. 10, the width W (mm) of the area 70 in which the air permeability of the air-permeable member 70 in the air duct 51 is relatively lowered is as follows with respect to the shortest distance L. It can be seen that it is effective to set the value to satisfy the formula (1).
W ≧ 0.15 × L (1)

  The upper limit value of the width W (mm) of the zone 70 is appropriately set within a range that does not impair the original air blowing performance required for the air duct 51. For example, when using the breathable member 70 with L = 30 mm and the entire width of the breathable member 70 (or the outlet 53): Wn = 20 mm, the upper limit value of the width W may be set to a value of 7 mm.

[Other embodiments]
In the air duct 51 according to the first embodiment, as means for lowering the air permeability of the specific area (70a, 70b) that relatively lowers the air permeability D of the air-permeable member 70 made of the perforated plate, FIG. As illustrated in FIG. 12, means for changing and setting the condition of the ventilation portion (through hole) 71 may be applied.

  In the configuration example shown in FIG. 11, the specific area (70a, 70b) in which the air permeability D is relatively lowered has a relatively small opening area (the through hole) 71 in the other area 70m. In this example, a through hole 72 is formed, and the air permeability D is relatively lowered. In the configuration example shown in FIG. 12, the total number of holes is thinned out in the specific area (70a, 70b) in which the air permeability D is relatively lowered than the ventilation part (through hole) 71 in the other area 70m. This is an example in which the ventilation portion (through hole) 71a is formed so that the formation density is in a rough state, and thereby the air permeability D is relatively lowered. In the case of the latter configuration example, the ventilation portion (through hole) 71a has a relatively smaller opening area than the ventilation portion (through hole) 71 in the other area 70m as in the configuration example shown in FIG. The portion (through hole) 72 may be formed.

  In the first embodiment, the air-permeable member 70 (corresponding to “the opening of the outlet 53 of the air duct 51”) made of a porous plate in the air duct 51 is also the two discharge wires 41 </ b> A of the charging device 4. , 41b is illustrated as being arranged in a state substantially parallel to, for example, as shown in FIG. 13, for example, as shown in FIG. It may be arranged in a state where at least one of 41b is inclined. Reference numerals 70c and 70d in FIG. 13a have ventilation portions (through holes) 71 through which air (Ex) is emitted so as to directly reach the discharge wires 41A and 41b among the breathable members 70X arranged in an inclined state. Indicates a specific area.

  Even when the air duct 51 is disposed in an inclined relationship as in the above-described example, the width W (W of a specific area (for example, 70c, 70d) in which the air permeability D of the air permeable member 70 is relatively lowered. , Wd) can be set by applying the conditional expression (1) described above. Symbols Lc and Ld in FIG. 13b indicate the shortest distances between the lower surface of the air-permeable member 70 disposed in an inclined state and the discharge wires 41A and 41b.

  Moreover, in Embodiment 1, as the ventilation duct 51 of the air blower 5, there is no 2nd bending channel | path part 54C (refer FIG. 4 etc.), for example, as shown in FIG. It is also possible to apply a blower duct 51B composed of only the portion 54B. In this blower duct 51B, a terminal end extending linearly in the vertical direction (a direction substantially parallel to the coordinate axis Y) from one end portion of the first bending passage portion 54B so as to approach the charging device 4 while maintaining the same width of the passage space. An outlet 53 having an opening shape slightly narrower than the cross-sectional shape of the passage space 54a at the end portion is formed in the portion (lower surface portion).

  In the air duct 51B, the first upstream suppressing portion 61 and the most downstream suppressing portion 62 (see FIG. 4 and the like) in Embodiment 1 are provided, and the air-permeable member 70 constituting the most downstream suppressing portion 62 is provided. The air permeability D (De, Df) in the specific area (70e, 71f) is relatively lower than the air permeability D (Dm) in the other area 70m.

  Furthermore, as the air duct 51, the shape of the whole is not limited to the case illustrated in the first embodiment, and other shapes can be applied. For example, the air duct 510 ( 510A-510C) may be applied. Moreover, although the case where the two suppression parts 61 and 62 were provided was shown in Embodiment 1 as the suppression part in the ventilation duct 51 of the air blower 5, you may provide three or more. In addition, the suppression unit includes the most downstream suppression unit, all of which change the cross-sectional shape in the passage space 54a of the passage portion 54 of the duct 51 and the direction in which air flows in the passage space 54a. It is preferable to provide it at a site after (for example, immediately after).

  Moreover, about the most downstream suppression part 62 in the ventilation duct 51, although the case where it comprised using the air permeable member 70 which consists of a perforated board in Embodiment 1, the most downstream suppression part 62 is a filter etc., for example. It is also possible to use a breathable member 75 typified by a porous member such as a non-woven fabric (one in which the plurality of vent portions 71 are irregularly formed gaps) applied to the above.

  FIG. 15 shows the blower duct 51 in the case where the most downstream suppressing portion 62 is configured using a breathable member 75 made of a porous member. Even when the air-permeable member 75 made of such a porous member is applied, it is effective to form a specific area (75 g, 75 h) in the air-permeable member 75 where the air permeability D is relatively lowered.

  In the configuration example shown in FIG. 15, as a means for reducing the air permeability D (Dg, Dh) of the specific area (75 g, 75 h) of the air permeable member 75, for example, a part thereof is shielded on the outer surface of the air permeable member 75. This is done by mounting a frame member 76 to be attached. In other words, the frame member 76 has shielding frame portions 76a and 76b formed in portions corresponding to specific areas (75g and 75h) of the air-permeable member 75, and portions other than the shielding frame portions formed as openings 76c. It is. By mounting the frame member 76, the air that has passed through the ventilation portion 71 of the breathable member 75 is blown out of the outlet 53 from the opening portion 76c of the frame member. On the other hand, in the shielding frame portions 76a and 76b of the frame material corresponding to the specific areas (75g and 75h) of the air-permeable member 75, the passage of air is blocked by the shielding frame portions 76a and 76b. Thereby, the air which reaches | attains directly to discharge wire 41A, 41B does not generate | occur | produce.

  Other means can be applied as means for reducing the air permeability D (Dg, Dh) of the specific area (75 g, 75 h) of the air-permeable member 75 made of the porous member. Other means include, for example, a configuration in which the thickness of the specific area is about 50% thicker than the other areas, or the physical property of the air permeability D of the specific area relatively smaller than the air permeability D of the other area. The structure etc. which are formed with the porous member which shows are mentioned.

  Incidentally, as a method for measuring the air permeability D of a specific area of the air permeable member 75 made of a porous member, for example, “Fragile for evaluating the air permeability of woven fabric (nonwoven fabric, etc.) based on L1096 of Japanese Industrial Standard (JIS)” It can be carried out according to the “shape measuring method”. Specifically, the air permeability of a specific area of the air-permeable member 75 constituting the most downstream suppression unit 62 is measured using a Frazier-type air permeability tester, and the ratio of the area 75m other than the specific area to the air permeability. By obtaining (percentage), the air permeability D of a specific area can be obtained.

  In addition, the charging device 4 to which the blowing device 5 is applied may be a charging device of a type in which the grid electrode 24 is not installed, a so-called corotron type charging device. Further, one charging device 4 or three or more charging devices 4 may be used as the discharge wires 41. Further, the charging device 4 may be a so-called pin coroton type charging device that uses, as a discharge generating member, a member in which a minute unevenness (sawtooth projection) is formed on one long side of a rectangular thin metal plate. . Further, as a long corona discharger to which the blower 5 is applied, in addition to a corona discharger for charging the photosensitive drum 21, for example, a corona discharger for discharging the photosensitive drum 21 or the like, or other than a photosensitive drum It may be a corona discharger that charges or removes a charged object.

  The image forming apparatus 1 is not particularly limited in the configuration of the image forming method and the like as long as the image forming apparatus 1 is provided with a long corona discharger to which the blower 5 needs to be applied. If necessary, an image forming apparatus that forms an image made of a material other than the developer may be used.

DESCRIPTION OF SYMBOLS 1 ... Image forming apparatus 4 ... Charging apparatus (corona discharger)
5 ... Blower 41 ... Discharge wire (discharge generating member)
50 ... Blower 51, 51B, 510A-510C ... Blower duct (blower pipe)
52 ... Inlet 53 ... Outlet 54 ... Passage 54a ... Passage space 61 ... First upstream restraint (one of the restraints)
62 .. most downstream suppression part (one of a plurality of suppression parts)
70 ... Breathable members 70a to 70h ... Specific area (area where air comes out directly)
70m ... Other area 71 ... Ventilation part B ... Longitudinal direction E ... Air (flow)

Claims (6)

An inlet for taking in air;
It is arranged in a state facing a longitudinal portion of a long corona discharger to be blown with air taken from the inlet, and has a long opening shape parallel to the longitudinal portion of the corona discharger, and the inlet And an outlet having a different opening shape,
A passage portion formed with a passage space for flowing air between the inlet and the outlet;
A plurality of suppressing portions that are provided in different portions in the direction of flowing air in the passage space in the passage portion and suppress the flow of air;
A state in which the passage space in the most downstream portion is blocked with a breathable member interspersed with a plurality of ventilation portions at least in the downstream portion of the passage space in the passage space of the passage portion in the air flow direction as the plurality of suppressing portions. The most downstream restraint configured to be
The air permeable member in the most downstream restraint portion is configured such that the air permeability of the area where the air exits so as to directly reach the discharge generating member disposed along the longitudinal direction of the corona discharger is the air permeability of the other area. It is comprised so that it may be in the state lowered relatively rather than. The area of the air permeable member configured to have a relatively reduced air permeability has a width dimension W (mm) centered on the discharge generating member along the short direction of the opening shape of the outlet. ), Where L (mm) is the shortest distance between the outer surface of the breathable member and the discharge generating member, the following conditional expression:
W ≧ 0.15 × L
The blast tube according to claim 1, wherein: A blower that sends air;
An inlet for taking in air sent from the blower and a longitudinal portion of a long corona discharger to which the air taken in from the inlet should be blown are arranged in parallel with the longitudinal portion of the corona discharger. An outlet having an opening shape different from the inlet, a passage portion formed with a passage space for flowing air by connecting between the inlet and the outlet, and a passage in the passage portion Provided in different parts in the direction of flowing the air in the space, and provided with a blower pipe having a plurality of suppressing portions for suppressing the flow of air,
The air-permeable member in which the plurality of ventilation portions are scattered in the passage space in the most downstream portion at least in the downstream portion of the passage space in the direction in which the air flows in the passage portion as the plurality of suppressing portions in the blower pipe. Provide the most downstream suppression part configured to be in a closed state,
The air permeable member in the most downstream restraint portion is configured such that the air permeability of the area where the air exits so as to directly reach the discharge generating member disposed along the longitudinal direction of the corona discharger is the air permeability of the other area. It is comprised so that it may be in the state lowered relatively rather than. An area configured to relatively reduce the air permeability of the air permeable member of the air duct is a width dimension centered on the discharge generating member along the short direction of the opening shape of the outlet. Is W (mm), and the shortest distance between the outer surface of the breathable member and the discharge generating member is L (mm), the following conditional expression:
W ≧ 0.15 × L
The air blower according to claim 1, wherein: A long corona discharger to be blown with air, and a blower that blows air toward a longitudinal portion of the corona discharger,
An image forming apparatus, wherein the blower device includes the blower pipe according to claim 1. A long corona discharger to be blown with air, and a blower that blows air toward a longitudinal portion of the corona discharger,
An image forming apparatus, wherein the blower is configured by the blower according to claim 3.

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