JP5311208B2 - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming apparatus which can adequately suck a recording medium even when the recording medium changes in size, and which can restrict useless consumption of power and noise. <P>SOLUTION: A recording medium suction region 102 is changed by moving a partition wall on the basis of the detection result of a width detecting means. When the recording medium suction region is reduced, a suction amount per unit time of a recording medium suction fan 106 as a recording medium suction means is decreased. On the other hand, when the recording medium suction region is enlarged, the suction amount per unit time of the recording medium suction fan 106 is increased. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to an image forming apparatus such as an ink jet copying machine, a facsimile, a printer, and the like.

  2. Description of the Related Art Conventionally, an ink jet type image forming apparatus that forms an image on a recording medium by discharging ink droplets from a nozzle of a liquid discharge head serving as an ink discharge means is known. Inkjet image forming apparatuses form an image by ink droplets ejected from a liquid ejection head directly landing on a recording medium. Therefore, in order to achieve high image quality, the ink droplets are recorded on the recording medium. It is necessary to improve the landing position accuracy. Also, some ink droplets ejected from the nozzles of the liquid ejection head do not land on the recording medium and float in the case of the apparatus as a minute ink mist. The floating ink mist, which is fine particles, may adhere to the sensor in the case of the apparatus and cause erroneous detection of the sensor. Further, the floating ink mist may adhere to the recording medium and stain the recording medium.

  Patent Document 1 describes the following image forming apparatus. That is, a platen that is a recording medium carrier that carries a recording medium is provided in an ink ejection region where the liquid ejection head ejects ink. The platen has a width equal to or larger than the maximum width of the recording medium on which the image can be formed, and is formed with suction holes. A recording medium suction duct that communicates with a suction hole that is within the maximum width of the recording medium on which the apparatus can form an image, and a mist suction duct that communicates with a suction hole that is outside the maximum width of the recording medium on which the apparatus can form an image. It has been. The recording medium suction duct is equipped with a recording medium suction fan as recording medium suction means, and the mist suction duct is an image forming apparatus equipped with a mist suction fan as fine particle suction means. The recording medium conveyed to the platen is attracted to the platen by the suction force of the recording medium suction fan. Thereby, the distance between the liquid discharge head and the recording medium can be kept constant, and the landing position accuracy can be improved. Ink mist is sucked from the suction hole of the platen outside the maximum width of the recording medium on which the image can be formed by the suction force of the mist suction fan. Thereby, the ink mist which floats in a case can be reduced and it can suppress that an ink mist adheres to a sensor or a recording medium.

Further, in Patent Document 1, the left end of the recording medium conveyed into the apparatus is detected, and the suction hole on the right side of the left end is set as a recording medium suction hole for sucking the recording medium with a recording medium suction fan. Further, there is also described an aspect in which the suction hole on the left side is set as a mist suction hole for sucking ink mist with a mist suction fan. The recording medium suction hole on the right side of the left end of the recording medium faces the recording medium transported to the platen, and the recording medium transported to the platen is adsorbed by the recording medium suction hole. On the other hand, the mist suction hole on the left side from the left end of the recording medium does not face the recording medium conveyed to the platen, and can suck ink mist while the recording medium is conveyed on the platen. If the width of the recording medium changes, the position of the left end of the recording medium also changes, so the settings of the recording medium suction hole and the mist suction hole are changed. As a result, when the width of the recording medium changes, the width of the recording medium suction area where the recording medium suction fan sucks air from the recording medium suction hole, and the width of the mist suction area where the mist suction fan sucks ink mist from the mist suction hole. The width changes.
JP 2006-227771 A

However, Japanese Patent Laid-Open No. 2004-228688 describes how to use the suction hole on the right side of the left end of the recording medium as the recording medium suction hole for sucking the recording medium with the recording medium suction fan, or mist on the suction hole on the left side of the left end. There is no description of a specific mode of making a mist suction hole for sucking ink mist by a suction fan.
Further, as described above, the width of the recording medium suction area where the recording medium suction fan sucks air from the suction hole of the platen according to the width of the recording medium and the mist suction where the mist suction fan sucks ink mist from the suction hole of the platen. In the case where the width of the area is changed, the following problem occurs. That is, even if the width of the recording medium changes and the width of the recording medium suction area for sucking the recording medium changes, the suction amount per unit time of the recording medium suction fan remains constant. For this reason, when the width of the recording medium is large, the width of the recording medium suction area is widened, and the number of recording medium suction holes corresponding to the recording medium suction fan is increased. As a result, the suction force of each recording medium suction hole decreases. Therefore, the recording medium cannot be satisfactorily adsorbed to the platen by the suction force of the suction holes. As a result, there arises a problem that the recording medium is lifted, the distance between the liquid discharge head and the recording paper is changed, and good landing accuracy cannot be obtained.
In addition, when the width of the recording medium is small, the width of the recording medium suction area is narrowed, the number of recording medium suction holes corresponding to the recording medium suction fan is reduced, and the suction force of the recording medium suction holes per one increases. To do. In this case, the suction force of the suction hole becomes equal to or higher than the suction force necessary for favorably attracting the recording medium to the platen, and the suction force of the suction hole becomes excessive. As a result, the recording medium suction fan is rotated more than necessary, and an excessive suction force is generated by the recording medium suction fan, resulting in wasted power consumption. Further, since the recording medium suction fan is rotated more than necessary, wind noise is generated more than necessary, and unnecessary noise is also generated.

  The present invention has been made in view of the above problems, and an object of the present invention is to satisfactorily suck a recording medium even when the size of the recording medium changes, and to suppress wasteful power consumption and noise. It is an object of the present invention to provide an image forming apparatus.

In order to achieve the above object, the invention of claim 1 is directed to an ink ejection unit that ejects ink toward a recording medium to form an image on the recording medium, a recording medium carrier that carries the recording medium, A recording medium suction means for sucking air from a suction hole formed in the recording medium carrier to attract the recording medium to the recording medium carrier, and at least outside a maximum width of the recording medium that the apparatus can convey In an image forming apparatus comprising fine particle suction means for sucking fine particles floating in the apparatus from the suction hole of the recording medium carrier formed on the recording medium, width detection means for detecting the width of the recording medium, and the recording medium A suction area changing means for changing a recording medium suction area where the suction means sucks air from the suction hole based on a detection result of the width detection means, and the recording medium according to the recording medium suction area A recording medium suction amount adjusting means for adjusting the amount of suction per unit time of the pull tab stage, extending in the conveying direction of the recording medium, the fine particles and the recording medium suction area, said fine particles suction means for sucking particles from the suction holes A partition wall that partitions the suction area is provided, and the partition wall is configured to be movable in a width direction, and the recording medium suction area is moved by moving the partition wall based on a detection result of the width detection unit. The suction area changing means is configured to be changed .
According to a second aspect of the present invention, in the image forming apparatus of the first aspect, when the recording medium suction area is enlarged, the recording medium suction amount adjusting means is a suction amount per unit time of the recording medium suction means. When the recording medium suction area is reduced, the amount of suction per unit time of the recording medium suction means is adjusted to decrease.
According to a third aspect of the present invention, in the image forming apparatus according to the first or second aspect, the length in the width direction of the recording medium suction region is the same as the length in the width direction of the recording medium detected by the width detecting unit. Thus, the suction area changing means is configured to change the recording medium suction area.
According to a fourth aspect of the present invention, in the image forming apparatus according to any one of the first to third aspects, the fine particle suction amount correcting unit corrects the suction amount per unit time of the fine particle suction unit based on the printing rate and the paper type. Is provided.
The invention of claim 5 is the one of the image forming apparatus 請 Motomeko 1 to 4, wherein in response to particulate suction area, microparticles suction amount adjusting means unit for adjusting the amount of suction per unit time of the fine suction means Is provided.
According to a sixth aspect of the present invention, in the image forming apparatus according to the fifth aspect , the fine particle suction amount adjusting means increases the suction amount per unit time of the fine particle suction means when the fine particle suction area is enlarged. When the fine particle suction area is reduced by adjustment, the fine particle suction means is adjusted so that the suction amount per unit time is reduced.
According to a seventh aspect of the present invention, in the image forming apparatus according to any one of the first to sixth aspects, the recording medium passes through the recording medium carrying member through an ink ejection area where the ink ejection means ejects ink. The conveyance member is configured to carry and convey the recording medium.
According to an eighth aspect of the present invention, in the image forming apparatus according to any one of the first to seventh aspects, the fine particle amount detection means for detecting the fine particle amount around the ink ejection region and the detection result of the fine particle amount detection means And a recording medium conveyance control means for controlling conveyance of the recording medium to the ink discharge area.
According to a ninth aspect of the present invention, in the image forming apparatus of the eighth aspect , when the amount of fine particles detected by the fine particle amount detecting means is a predetermined value or more, the conveyance of the recording medium to the ink discharge area is stopped. The recording medium conveyance control means is configured.

According to the present invention, since the suction amount per unit time of the recording medium suction unit is adjusted according to the recording medium suction region, the suction region changing unit sets the recording medium suction region based on the detection result of the width detection unit. When reduced, the suction amount per unit time of the recording medium suction means can be reduced. When the recording medium suction area is reduced, the number of suction holes is reduced. Therefore, even if the suction amount per unit time of the recording medium suction means is reduced, the suction force per suction hole can be kept good. it can. Therefore, when the recording medium suction area is reduced, by reducing the suction amount per unit time of the recording medium suction unit, the recording medium can be sucked well and the power consumption and noise of the recording medium suction unit can be suppressed. It becomes possible.
Further, when the suction area changing means expands the recording medium suction area based on the detection result of the width detection means, the suction amount per unit time of the recording medium suction means can be increased. When the recording medium suction area is enlarged, the number of suction holes increases, and the suction force of each suction hole decreases. Therefore, when the recording medium suction area is enlarged, even if the recording medium suction area is enlarged and the number of suction holes is increased by increasing the suction amount per unit time of the recording medium suction means, the suction hole per one is increased. It is possible to suppress a decrease in the suction force. Thereby, even if the recording medium suction area is enlarged, the recording medium can be satisfactorily sucked to the recording medium carrier.

  According to the present invention, even when the size of the recording medium changes, the recording medium can be satisfactorily sucked, and wasteful power consumption and noise can be suppressed.

Hereinafter, an inkjet printer will be described as an embodiment of an inkjet image forming apparatus to which the present invention is applied.
FIG. 1 is a schematic front view of the inkjet printer 100, and FIG. 2 is a schematic top view of the inkjet printer 100. In FIG. 2, the paper discharge guide unit 80 is not shown.
The ink jet printer 100 includes a paper feed tray 20 that stacks and feeds recording media P, a paper discharge tray 30 that discharges and stacks printed recording media P, and conveys the recording medium from the paper feed tray 20 to the paper discharge tray 30. The apparatus main body etc. provided with the conveyance part 50 etc. which carry out. A head portion 40, a sub tank 43, a main tank 44, and the like are provided on the upper portion of the apparatus main body 10.

  The head unit 40 includes a liquid discharge head 41Y serving as an ink discharge unit that discharges yellow (Y), magenta (M), cyan (C), and black (K) ink onto the recording medium while being arranged in the recording medium moving direction. 41M, 41C, and 41K (see FIG. 2). Each of the liquid discharge heads 41Y, 41M, 41C, and 41K is a line head in which nozzles are arranged along the entire width in the width direction of the recording medium. In addition, the structure of the head part 40 is not restricted to this. For example, a plurality of liquid ejection heads that eject the same color ink may be arranged in a line in the width direction of the recording medium P, or may be staggered. On the upper portion of the head portion 40, branch pipes 42Y, 42M, 42C, and 42K for supplying ink liquids to the liquid discharge heads of the respective colors are provided corresponding to the liquid discharge heads 41Y, 41M, 41C, and 41K. Yes. Conveying tubes 45Y, 45M, 45C, and 45Y are connected to the branch pipes 42Y, 42M, 42C, and 42K, respectively, and the other end of each of the conveying tubes 45Y, 45M, 45C, and 45K is a liquid to which the branch pipe corresponds. Connected to the discharge head. A sub tank 43 is disposed upstream of the branch pipes 42Y, 42M, 42C, 42K in the direction of ink liquid movement. , C, K nozzle meniscuses can be maintained at a negative pressure suitable for holding ink. Further, a main tank 44 for storing ink is disposed upstream of the sub tank 43 in the ink liquid movement direction. The branch pipes 42Y, 42M, 42C, 42K, the sub tank 43, and the sub tank 43 and the main tank 44 are all connected by a transfer tube. The head unit 40 is slidable to the upper part of a head cleaning device 60 described later.

The apparatus main body 10 is composed of front and rear side plates and stays (not shown), and includes a conveyance unit 50, a head cleaning device 60, and the like inside the apparatus main body.
The conveyance unit 50 is a recording medium carrier, and has an endless belt-like conveyance belt 51 that is a conveyance member. The conveyance belt 51 is stretched around the driving roller 53 and the driven roller 52 with appropriate tension. . As shown in FIG. 4, the transport belt 51 is provided with a plurality of suction holes 51a. As shown in FIG. 1, the driving roller 53 is rotationally driven at a predetermined rotational speed by a driving motor (not shown), and accordingly, the conveying belt 51 is also rotated at a predetermined speed. Further, the transport unit 50 includes an entrance guide roller 23 that presses the recording medium P against the transport belt 51 at a position facing the driven roller 52. Further, the transport unit 50 includes an exit guide roller 24 that presses the recording medium P against the transport belt 51 at a position facing the drive roller 53. As shown in FIG. 2, a plurality of entrance guide rollers 23 and exit guide rollers 24 are provided in the width direction of the recording medium P, and are supported by their own weight on a guide member (not shown) that guides the recording medium P. The conveyance unit 50 is supported by the apparatus main body so as to be rotatable in the arrow B direction with the driven roller 52 as a fulcrum. In addition, the transport unit 50 includes a suction device 110. The suction device 110 will be described later.

  As shown in FIG. 1, a paper discharge guide unit 80 is provided on the left side (downstream in the recording medium movement direction) of the transport unit 50 in the drawing. The paper discharge guide unit 80 includes a paper discharge guide plate 81 that guides the recording medium P facing the surface opposite to the image forming surface of the recording medium P and a paper discharge roller pair 82. The roller pair 82 is supported by the paper discharge guide plate 81. An end portion of the paper discharge guide plate 81 is supported rotatably with respect to the apparatus main body.

A head cleaning device 60 is provided below the paper discharge guide portion 80. The head cleaning device 60 has four caps 61Y, 61M, 61C, and 61K for individually capping the nozzle surfaces of the four droplet discharge heads (41Y to 41K). Each cap 61Y, M, C, and K is provided with a suction hole (not shown), and suction pumps 62Y, 62M, 62C, and 62K are connected to the suction holes. Further, the head cleaning device 60 includes a wiper blade (not shown) for wiping ink droplets adhering to the nozzle surface.
At the time of non-image formation, the paper discharge guide unit 80 is in the position of the dotted line in the figure, and the conveyance unit 50 is in the position of the dotted line in the figure. The head unit 40 is located at a position facing the head cleaning device 60, and the caps 61Y, M, C, K of the head cleaning device 60 cap the nozzle surfaces of the liquid discharge heads 41Y, 41M, 41C, 41K. The nozzle is kept moist. The head cleaning device 60 has a function of improving ejection failure by sucking out bubbles and dust adhering to the nozzles with the suction pumps 62Y, M, C, and K with the nozzle surface capped. Specifically, when an ejection failure occurs and an image failure occurs, the user instructs the execution of nozzle cleaning by operating the apparatus. When a control unit (not shown) receives this nozzle cleaning signal, the nozzle surfaces of the liquid discharge heads 41Y, 41M, 41C, 41K are capped with caps 61Y, 61M, 61C, 61K, and then the suction pumps 62Y, 62M, 62C, 61K. Is driven to suck out bubbles and dust adhering to the nozzle together with ink, thereby improving ejection failure. When the ejection failure is improved, the caps 61Y, 61M, 61C, and 61K are separated from the nozzle surface. Then, the wiper blade (not shown) is moved upward to move the head unit 40 to the ink discharge area. Then, the wiper blade wipes the nozzle surfaces of the liquid discharge heads 41Y, 41M, 41C, 41K, and the nozzle surfaces are cleaned. After the nozzle surface is cleaned, the head unit 40 is moved again to the area facing the head cleaning device 60, and the nozzle surfaces of the liquid discharge heads 41Y, 41M, 41C, 41K are moved with the caps 61Y, 61M, 61C, 61K Capping.

  A particle counter 1 serving as a fine particle amount detection unit is provided on the side surface of the head unit 40 on the upstream side in the recording medium moving direction. The tube 1a extending from the particle counter 1 passes through the inside of the head portion 40 and is connected to a connection hole provided between the M color liquid discharge head 41M and the C color liquid discharge head 41C on the lower surface of the head portion 40. Yes. Air in the ink discharge area is sucked from the tube 1a, and the number of fine particles (ink mist, paper dust, etc.) is measured by the particle counter 1 using the sucked air.

  FIG. 3 is a schematic perspective view of the periphery of the paper feed tray 20. As shown in the figure, the paper feed tray 20 has a pair of side fences 25. When one side fence 25 is moved inward in the width direction of the recording medium P by manual operation, the other side fence is also moved inward in the width direction by an equal distance, and one side fence is moved outward in the width direction of the recording medium by manual operation. The other side fence is also configured to move outward in the width direction by an equal distance. By causing the side fences 25 to abut both ends of the recording medium, it is possible to prevent the recording medium P from being skewed and to arrange the recording medium P in the center of the paper feed tray 20. As a result, regardless of the size of the recording medium placed on the paper feed tray 20, it is possible to convey the recording medium P so that the central portion of the recording medium P comes to the central portion of the conveying belt 51.

One side fence is provided with a conductive slider 26. The slider 26 has a plurality of terminals 26a. Inside the paper feed tray 20 is provided a paper size detection plate 27 that contacts the terminal 26a of the slider 26. A detection terminal (not shown) for connecting to the terminal 26a of the slider is provided at a position where the terminal 26a of the slider 26 of the paper size detection plate 27 slides, and on this detection terminal, An insulating sheet member 28 in which various holes are formed is provided. A bias is applied to the upper terminal in the drawing of the paper size detection plate 27 from a power supply device (not shown), and the upper terminal in the drawing of the paper size detection plate 27 is always on the upper portion in the drawing of the slider. A bias is applied to the slider 26 in contact with the terminal 26b.
When the side fence 25 is slid, the slider 26 slides on the paper size detection plate 27. When the side fence 25 comes into contact with the end of the recording medium P on the paper feed tray, the slider 26 stops at a predetermined position of the paper size detection plate 27. At this time, some of the terminals 26 a of the slider 26 are in contact with the detection terminals of the paper size detection plate 27, and some of the terminals 26 a of the slider 26 are detected by the sheet member 28 of the paper size detection plate 27. Contact with is blocked. A bias is applied from the slider 26 to the detection terminal of the paper size detection plate 27 in contact with the terminal 26a of the slider. Depending on the stop position of the slider 26, the combination of detection terminals of the paper size detection plate 27 with which the terminal 26a of the slider 26 contacts is different. A control unit (not shown) grasps which detection terminal of the paper size detection plate 27 is in the ON state (bias is applied), and determines the recording medium P on the paper feed tray by combining the detection terminals in the ON state. Detect width. That is, the slider 26, the paper size detection plate 27, and the control unit constitute a width detection unit that detects the width of the recording medium P.

FIG. 4 is a schematic configuration diagram of the suction device 110.
The suction device 110 is opposed to a surface (back surface) opposite to the recording medium carrying surface of the conveyance belt 51 serving as a recording medium carrier, and is provided with a suction duct 111 having the same width as the conveyance belt 51. The suction duct 111 is provided with a pair of partition walls 104 extending in the recording medium conveyance direction so as to be movable in the width direction of the suction duct 111. The suction duct 111 is connected to a recording medium suction area 102 for sucking the recording medium P. The first particle suction region 101a and the second particle suction region 101b are divided. A first suction port 106b is provided at the center of the bottom surface of the suction duct 111, and a particle capturing member 106a that captures particles such as ink mist and paper dust is attached to the first suction port 106b. Yes. A recording medium suction fan 106, which is a recording medium suction means for sucking the recording medium P, is disposed close to the first suction port 106b. A second suction port 103b is provided in the first fine particle suction region 101a on one end in the width direction (the lower side in the drawing) of the bottom surface of the suction duct 111. The second suction port 103b is also provided with a particle capturing member 103a. In addition, a first fine particle suction fan 103, which is a fine particle suction means for sucking fine particles such as ink mist and paper dust, is disposed close to the second suction port 103b. A third suction port 105b is provided in the second fine particle suction region 101b on the other end in the width direction of the bottom surface of the suction duct 111 (upper side in the drawing). The third suction port 105b is also provided with a particulate trapping member 105a, and a second particulate suction fan 105 serving as a particulate suction means is disposed close to the third suction port 105b.

  The width of the transport belt 51 is larger than the maximum width of the recording medium P that can be transported by the apparatus, and even if the recording medium P having the maximum width that can be transported by the apparatus is transported, the end of the transport belt 51 The recording medium P is not blocked by the suction holes 51a formed in the above. Thus, even if the recording medium P having the maximum width that can be transported by the apparatus is transported, the first and second particulate suction fans 103 and 105 cause particulates such as ink mist and paper dust from the suction holes 51a at both ends of the transport belt. Can be aspirated. Fine particles such as ink mist and paper powder sucked from the suction holes 51a of the conveyor belt 51 by the first fine particle suction fan 103 are captured by the fine particle capturing member 103a provided in the second suction port 103b. Further, fine particles such as ink mist and paper dust sucked from the suction holes 51a of the conveyor belt 51 by the second fine particle suction fan 105 are captured by the fine particle capturing member 105a provided in the third suction port 105b. Further, between the sheets, ink mist and paper dust are sucked from the suction holes 51a in the recording medium suction area, and are captured by the fine particle capturing member 106a provided in the first suction port 106b.

  The pair of partition walls 104 are provided so as to be movable in the width direction of the suction duct 111 by a partition actuator (not shown), and the width of the recording medium suction region 102 of the suction duct 111 is the width of the recording medium P carried on the transport belt 51. The partition 104 is moved based on the detection result of the above-described width detection means so as to be the same width as the width. Specifically, when the width of the recording medium is narrow, a partition actuator (not shown) is driven to move the partition from the position shown in FIG. 4 to the position shown in FIG. Narrow the area. Since the partition is moved so that the recording medium suction area is the same as the width of the recording medium to be conveyed, the suction holes outside the recording medium width do not become suction holes corresponding to the recording medium suction fan. As a result, the recording medium can be satisfactorily sucked even if the suction amount per unit time of the recording medium suction fan is smaller than that in which the suction holes outside the recording medium width correspond to the recording medium suction fan. As a result, the rotation speed of the recording medium suction fan can be suppressed, and the lifting of the recording medium can be suppressed, compared to the case where the suction hole outside the recording medium width corresponds to the recording medium suction fan. Therefore, power consumption of the recording medium suction fan and noise of the recording medium suction fan can be suppressed.

FIG. 6 is a control block diagram of the ink jet printer.
In the figure, the control unit 200 has a CPU (Central Processing Unit) as a calculation means, a RAM (Random Access Memory) as a nonvolatile memory, a ROM (Read Only Memory) as a temporary storage means, and the like. The control unit 200 controls the entire apparatus, and various devices and sensors are connected. In the figure, only the devices and sensors related to the feature points of the printer 100 are shown. The control unit 200 realizes the function of each unit based on a control program stored in the RAM. Specifically, the control unit 200 detects the width of the recording medium P on the paper feed tray 20 from the ON / OFF state of the detection terminal of the paper size detection plate 27. Further, the control unit 200 controls the partition wall actuator 203 based on the detected width information of the recording medium P on the paper feed tray 20, and the width of the recording medium suction area 102 of the suction duct 111 is set on the paper feed tray 20. The partition 104 is moved so as to be the same as the width of the recording medium P. As a result, the recording medium suction area 102 is changed. That is, the control unit 200 functions as a suction area changing unit. Further, the control unit 200 adjusts the rotational speed of the recording medium suction fan 106 based on the detected width information of the recording medium P on the paper feed tray. By adjusting the rotation speed of the recording medium suction fan 106, the suction amount per unit time is adjusted. That is, the control unit 200 also functions as a recording medium suction amount adjusting unit.
Further, the control unit 200 adjusts the rotation speeds of the first and second fine particle suction fans 103 and 105 based on the detected width information of the recording medium on the paper feed tray. By adjusting the rotation speeds of the first and second fine particle suction fans 103 and 105, the suction amount per unit time is adjusted. That is, the control unit 200 also functions as fine particle suction amount adjusting means. Further, the control unit 200 corrects the fine particle suction amount for correcting the rotational speeds of the first and second fine particle suction fans 103 and 105 based on the printing rate calculated from the image data and the paper type information input to the operation panel 201. It also functions as a correction means. Further, the control unit 200 controls the transport of the recording medium P to the ink ejection area by controlling the transport motor 202 for driving the paper feed roller 21 based on the detection result of the particle counter 1. That is, the control unit 200 also functions as a recording medium conveyance control unit.

Next, an image forming operation of the ink jet printer 100 of this embodiment will be described.
FIG. 7 is a control flow of the image forming operation.
When image data as image information is received from an external device such as a personal computer (not shown) via a communication cable or the like, the head cleaning device 60 is lowered and the head unit 40 is moved to the ink ejection area as shown in FIG. . When the head unit 40 moves to the ink discharge area, the transport unit 50 is rotated from the dotted line position to the solid line position in the figure, and the conveyance guide unit 80 is rotated from the dotted line position to the solid line position in the figure. Move.
Next, the control unit 200 detects the width of the recording medium P on the paper feed tray 20 from the ON / OFF state of the detection terminal of the paper size detection plate 27 (S1). Next, the control unit 200 checks whether or not the detected width of the recording medium P on the paper feed tray 20 is the same as the width of the recording medium used at the previous image formation (S2). When the detected width of the recording medium P on the paper feed tray 20 is the same as the width of the recording medium used at the previous image formation (YES in S2), the recording medium suction fan 106 is rotated to perform the recording medium suction operation. The first and second fine particle suction fans 103 and 105 are rotated to start the fine particle suction operation (S5). On the other hand, when the detected width of the recording medium P on the paper feed tray 20 is different from the width of the recording medium P used at the previous image formation (NO in S2), the detected recording medium P on the paper feed tray 20 is used. Based on the width information, the partition actuator 203 is driven to move the partition and change the recording medium suction area 102 (S3).

  When the partition 104 is moved and the recording medium suction area 102 is changed, if the rotation speed of the recording medium suction fan 106 is the same as that at the previous image formation, the conveying belt 51 on the recording medium suction area. The suction force of the suction hole 51a changes. More specifically, when the recording medium suction area 102 is expanded from the previous image formation, the number of suction holes corresponding to the recording medium suction fan 106 is increased. As the number of suction holes corresponding to the recording medium suction fan 106 increases, the suction force of each suction hole decreases. As a result of the suction force of the suction holes being reduced, the recording medium P cannot be satisfactorily sucked, and the recording medium P may be lifted from the transport belt 51 and come into contact with the nozzle surface of the liquid ejection head. Further, the distance between the liquid discharge head and the recording medium varies, and ink droplets do not land at a predetermined position on the recording medium, which may cause image defects. Further, when the recording medium suction area 102 is narrower than the previous image formation, the number of suction holes corresponding to the recording medium suction fan 106 is reduced. As a result of the reduction in the number of suction holes corresponding to the recording medium suction fan 106, the suction force of each suction hole increases, and the force for sucking the recording medium P becomes excessive. As a result, useless power consumption and useless noise occur.

  As a result of the movement of the partition wall 104, the first and second fine particle suction areas 101a and 101b also fluctuate, and the suction force of the suction holes 51a of the transport belt 51 on the first and second fine particle suction areas also changes. More specifically, when the recording medium suction area 102 is expanded from the previous image formation, the first and second fine particle suction areas 101a and 101b are narrowed. As a result, the number of suction holes corresponding to the first fine particle suction fan 103 and the number of suction holes corresponding to the second fine particle suction fan 105 are reduced. As a result of the reduction of the suction holes corresponding to the fine particle suction fans 103 and 105, the suction force of each suction hole becomes excessive. As a result, the ink droplets ejected from the droplet ejection head may be affected by the suction force of the suction holes corresponding to the fine particle suction fans 103 and 105, and the landing position may be shifted. Further, when the recording medium suction area 102 becomes narrower than the previous image formation, the first and second fine particle suction areas 101a and 101b are widened (see FIG. 5). For this reason, the number of suction holes corresponding to the first fine particle suction fan 103 and the number of suction holes corresponding to the second fine particle suction fan 105 are increased. As a result of the increase in the number of suction holes corresponding to the fine particle suction fans 103 and 105, the suction force of each suction hole decreases, and fine particles such as floating ink mist and paper dust cannot be satisfactorily sucked.

  Therefore, in the image forming apparatus according to the present embodiment, when the partition 104 moves and the recording medium suction area 102 and the first and second fine particle suction areas 101a and 101b are changed, the rotational speed of the recording medium suction fan 106 and The rotational speed settings of the first and second fine particle suction fans 103 and 105 are changed to change the suction amounts per unit time of the recording medium suction fan 106 and the first and second fine particle suction fans 103 and 105 (S4). ). Specifically, the control unit 200 determines the number of rotations of the recording medium suction fan 106 and the number of rotations of the first and second fine particle suction fans 103 and 105 based on the detected width of the recording medium P on the paper feed tray 20. To change. When the detected width of the recording medium P on the paper feed tray 20 is wider than the width of the recording medium P at the time of previous image formation, the recording medium suction area 102 is widened. Increase the suction volume per unit time. By increasing the amount of suction per unit time of the recording medium suction fan 106, a decrease in the recording medium suction force per suction hole can be suppressed even when the recording medium suction area 102 is widened. It can be adsorbed to the conveyor belt 51. On the other hand, since the first and second fine particle suction areas 101a and 101b are narrowed, the rotation speed of the first and second fine particle suction fans 103 and 105 is decreased to reduce the suction amount per unit time. By reducing the amount of suction per unit time, an increase in suction force per suction hole can be suppressed even when the first and second fine particle suction regions 101a and 101b are narrowed, and suction for sucking fine particles is performed. It is possible to suppress the landing position of the ink droplets ejected from the liquid ejection head from being shifted by the force. Further, since the rotation speed of the first and second fine particle suction fans 103 and 105 can be suppressed, power consumption can be suppressed and noise of the first and second fine particle suction fans 103 and 105 can be suppressed. . When the detected width of the recording medium P on the paper feed tray 20 is smaller than the width of the recording medium P at the previous image formation, the recording medium suction area 102 is narrowed. Reduce the amount of suction per unit time by lowering the rotation speed. Even if the suction amount per unit time of the recording medium suction fan 106 is reduced, the recording medium suction force per suction hole can be kept good, and the recording medium P can be attracted to the transport belt 51 well. . Further, since the number of rotations of the recording medium suction fan 106 is reduced, power consumption can be suppressed and noise of the recording medium suction fan 106 can be suppressed. On the other hand, since the first and second fine particle suction areas 101a and 101b are widened, the number of suction per unit time is increased by increasing the rotation speed of the first and second fine particle suction fans 103 and 105. By increasing the amount of suction per unit time, a decrease in suction force per suction hole can be suppressed even if the first and second fine particle suction regions 101a and 101b expand, and floating ink mist and paper dust Fine particles such as can be sucked well.

  The rotation speed of the recording medium suction fan 106 and the rotation speeds of the first and second fine particle suction fans 103 and 105 are set, for example, by the size of the recording medium P, the rotation speed of the recording medium suction fan 106, and the first and second fine particles. A lookup table associated with the rotational speeds of the suction fans 103 and 105 is stored in a memory such as a RAM, and the corresponding size is determined from the detected size information of the recording medium P on the paper feed tray 20 and the lookup table. The number of rotations of the recording medium suction fan 106 and the number of rotations of the first and second fine particle suction fans 103 and 105 are found. Then, the number of rotations of the found recording medium suction fan 106 and the number of rotations of the first and second fine particle suction fans 103 and 105 are set.

  In addition, in the case of an image with a high printing rate, there are many ink droplets ejected by the liquid ejection head, so that the floating ink mist increases. On the other hand, in the case of an image with a low printing rate, since the ink droplets ejected by the liquid ejection head are small, the floating ink mist is also small. Thus, the amount of ink mist that is fine particles floating varies depending on the printing rate. Depending on the type of paper, there are recording media that tend to produce fine paper dust, and recording media that do not easily produce paper dust. When a recording medium that easily generates paper dust is transported, the amount of paper dust floating in the apparatus increases. When a recording medium that does not easily generate paper dust is transported, the amount of paper powder floating in the apparatus decreases. Thus, the amount of fine particles floating in the apparatus varies depending on the printing rate and paper type. For this reason, in the case of an image with a high printing rate or a paper type in which paper dust is likely to be produced, the fine particles that float sufficiently at the rotation speeds (suction amounts) of the first and second fine particle suction fans 103 and 105 set above. Can not be removed. In addition, when the image has a low printing rate or is a paper type that does not easily generate paper dust, the set rotation speeds (suction amounts) of the first and second fine particle suction fans 103 and 105 are excessive, and power consumption is reduced. Waste and useless noise are generated. Therefore, the rotational speeds of the first and second fine particle suction fans 103 and 105 may be set in consideration of the printing rate and paper type information.

  The control unit 200 calculates a printing rate based on the image data. As for the paper type, when the recording medium is set in the paper feed tray 20, the user operates the operation panel 201 to input the paper type information of the recording medium on the paper feed tray 20. The control unit 200 sets the rotational speeds of the first and second fine particle suction fans 103 and 105 based on the detected width of the recording medium P on the paper feed tray 20, and then based on the printing rate and paper type information. Then, the rotational speed of the fine particle suction fans 103 and 105 is corrected. In the case of an image with a high printing rate or a recording medium with a lot of paper dust, the rotation of the first and second fine particle suction fans 103 and 105 set based on the detected width information of the recording medium on the paper feed tray 20 The number is corrected to increase the number of rotations. As a result, the suction force of the suction hole corresponding to the first fine particle suction fan 103 is increased, and the suction force of the suction hole corresponding to the second fine particle suction fan 105 is increased. As a result, fine particles floating in the apparatus can be satisfactorily suppressed. On the other hand, in the case of an image with a low printing rate or a recording medium with a small amount of paper dust, the rotation of the first and second fine particle suction fans 103 and 105 set based on the detected width information of the recording medium on the paper feed tray. The number is corrected so as to decrease the rotation speed. Thereby, power consumption of the first and second fine particle suction fans can be suppressed, and noise such as wind noise can be reduced.

  Specifically, a lookup table in which the printing rate and the correction value are associated is stored in a memory such as a RAM, and the corresponding correction value is found from the calculated printing rate and the lookup table. Based on the found correction value, the rotational speeds of the first and second fine particle suction fans 103 and 105 are corrected. Similarly, a lookup table in which the input paper type information and the correction value are associated with each other is stored in a memory such as a RAM, and the corresponding correction value is found from the paper type and the lookup table. Based on the found correction value, the rotational speeds of the first and second fine particle suction fans 103 and 105 are corrected.

  When the rotation speed of the recording medium suction fan 106 and the rotation speeds of the first and second fine particle suction fans 103 and 105 are set, the recording medium suction fan 106 is rotated to start the recording medium suction operation, and the first and first The fine particle suction fans 103 and 105 are rotated to start the fine particle suction operation (S5).

  Next, the control unit 200 feeds the recording medium on the paper feed tray to the ink ejection area (S6). Specifically, the conveyance motor 202 is driven to start the rotation of the paper feed roller 21, and the uppermost recording medium in the recording medium bundle stacked on the paper feed tray 20 is fed out toward the separation roller 22. The recording medium P fed out from the paper feed tray 20 by the paper feed roller 21 is separated into one sheet by the separation roller 22 and conveyed to the conveyance unit 50. The recording medium P conveyed to the conveyance unit 50 is pressed against the conveyance belt 51 by the entrance guide roller 23. The recording medium P carried on the conveyance belt is attracted to the front surface of the conveyance belt 51 by the recording medium suction fan 106 and is conveyed along with the endless movement of the conveyance belt 51.

  When the recording medium P is transported to the ink discharge area, the control unit 200 as control means controls the liquid discharge heads 41Y, 41M, 41C, 41K based on the image data, and discharges ink droplets from predetermined nozzles. Then, an image is formed on the recording medium (S7). The recording medium P on which the image is formed is conveyed by the conveyance belt 51 to the sheet discharge guide unit 80, and is surrounded by the end fence 32 and the side fence 31 of the sheet discharge tray 30 by the sheet discharge roller pair 82 of the conveyance guide unit 80. The paper is discharged to the selected area.

  Next, it is checked whether or not the image forming operation is finished (S8). If the image forming operation is finished (YES in S9), the recording medium suction fan 106 and the first and second fine particle suction fans 103 and 105 are driven. Then, the recording medium suction operation and the particulate suction operation are stopped (S9). Next, the conveyance part 50 is rotated to the position of the dotted line shown in FIG. Further, the paper discharge guide unit 80 is rotated to the position of the dotted line in the figure. Then, the head unit 40 is moved to a position facing the head cleaning device 60, the head cleaning device 60 is moved upward, and the liquid discharge heads 41Y, M, C, and K nozzle surfaces are caps 61Y, M, C, Capping at K ends the image forming operation.

  On the other hand, when there is the next image data (NO in S8), the particle counter 1 measures the amount of particles (fine particles) around the ink ejection area (S10). When the amount of particles is greater than or equal to the first set value (NO in S11), many fine particles such as paper dust and ink mist are floating in the ink ejection area. For this reason, if the next image formation is performed immediately, the amount of fine particles such as ink mist and paper dust increases more and more around the ink discharge area, which increases the risk of contaminating the apparatus and the recording medium. Further, when the recording medium is transported to the ink ejection area in a state where there are many fine particles such as ink mist and paper dust around the ink ejection area, there is a high possibility that the ink mist adheres to the recording medium and the recording medium becomes dirty. Therefore, in this case, the recording medium P on the paper feed tray is not transported to the ink ejection area until the amount of particles around the ink ejection area is less than the second set value (S12 to S13). The second set value is smaller than the first set value and is a stricter value. Even when the conveyance of the recording medium is stopped, the recording medium suction fan 106 is continuously driven without being stopped. As a result, fine particles such as floating paper dust and ink mist can be sucked even in the recording medium suction region 102, so that the amount of particles (fine particles) around the ink discharge region is made less than the second set value in a short period of time. Can do.

  When the amount of particles around the ink ejection area is less than the second set value, the driving of the transport motor 202 is started to rotate the paper feed roller 21 to feed the recording medium on the paper feed tray to the ink ejection area, Image formation is performed (S6 to S8).

  Next, a modified example of the suction device 110 will be described.

[Modification 1]
8 and 9 are schematic configuration diagrams of the suction device 110a of the first modification.
In the suction device 110 a of the first modification, the first particulate suction duct 112 b is provided in one partition 104, and the second particulate suction duct 112 a is provided in the other partition 104. The fine particle suction ducts 112a and 112b are respectively provided with suction ports 103b and 105b, and the fine particle capturing members 103a and 105a are attached to the suction ports 103b and 105b, respectively. The first fine particle suction fan 103 is attached to the first fine particle suction duct 112a so as to be close to the suction port 103b of the first fine particle suction duct 112a. The second fine particle suction fan 105 is attached to the second fine particle suction duct 112b so as to be close to the suction port 105b of the second fine particle suction duct 112b.

  As shown in FIGS. 8 and 9, when the partition 104 is moved so that the width of the recording medium suction area 102 is the same as the width of the recording medium P on the paper feed tray, the particulate suction duct 112a, 112b moves in the suction duct 111 in the width direction. In the suction device 110a of the first modification, even if the width of the recording medium suction area 102 changes, the width of the fine particle suction area does not change. Therefore, it is not necessary to change the rotational speeds of the first and second fine particle suction fans 103 and 105 based on the detected width information of the recording medium on the paper feed tray. As a result, in the suction device 110a of the first modification, the reference rotational speeds of the first and second fine particle suction fans may be corrected according to the printing rate and the paper type. Further, since the fine particle suction area does not expand as shown in FIG. 5, it is not necessary to increase the rotation speed of the first and second fine particle suction fans 103 and 105 when transporting a narrow recording medium. Therefore, the power consumption of the first and second fine particle suction fans 103 and 105 can be suppressed and the noise of the first and second fine particle suction fans 103 and 105 can be suppressed as compared with the suction device 110 of the embodiment. .

[Modification 2]
10 and 11 are schematic configuration diagrams of the suction device 110b according to the second modification.
The suction device 110b of Modification 2 includes a connecting duct 113 that connects the first fine particle suction region 101a and the second fine particle suction region 101b provided with the recording medium suction region 102 interposed therebetween, and is provided with one fine particle suction fan. In 114, the fine particles are sucked from the suction holes corresponding to both the fine particle suction regions 101a and 101b. As shown in FIGS. 10 and 11, one end of the connection duct 113 is connected to the second suction port 103b of the suction duct 111, and the other end of the connection duct 113 is connected to the third suction port 105b. . A particulate suction port 113a is provided at the center of the connecting duct 113, and a particulate capturing member 108a is attached to the particulate suction port 113a. A fine particle suction fan 114 is provided so as to be close to the fine particle suction port 113a. In the suction device 110b of the second modification, the number of particulate suction fans, the motor that rotationally drives the particulate suction fan, and the like can be reduced, and the cost can be reduced compared to the suction device 110 of the embodiment.

[Modification 3]
12 and 13 are schematic configuration diagrams of the suction device 110c according to the third modification.
The suction device 110c of Modification 3 is provided with a plurality of recording medium suction fans 106, first fine particle suction fans 103, and second fine particle suction fans 105 in the recording medium conveyance direction.
In the suction device 110c of the third modification example, as shown in FIG. 12, when the recording medium suction area 102 is wide, all the recording medium suction fans 106 are driven, and as shown in FIG. Is narrow, one of the plurality of recording medium suction fans 106 is driven to rotate. In this way, the amount of suction per unit time of the recording medium suction means is adjusted by changing the number of recording medium suction fans 106 to be driven according to the size of the recording medium suction area 102. That is, in the configuration of the third modification, the plurality of recording medium suction fans 106 constitute a recording medium suction unit.
As shown in FIG. 12, when the fine particle suction regions 101a and 101b are narrow, one of the plurality of first fine particle suction fans 103 provided in the first fine particle suction region 101a is driven to rotate to suck the second fine particle suction. One of the plurality of second fine particle suction fans 105 provided in the region 101b is rotationally driven. On the other hand, as shown in FIG. 13, when the particulate suction area is wide, all of the first particulate suction fan 103 and all of the second particulate suction fan are driven to rotate. In this way, the amount of suction per unit time of the particulate suction means is adjusted by changing the number of the particulate suction fans to be driven according to the size of the particulate suction area.

  The present invention can also be applied to an image forming apparatus in which a plate-like platen provided so as to face the liquid discharge head supports a recording medium in an ink discharge region. In this case, a suction hole is provided in a platen that is a recording medium carrier, and a suction duct of a suction device is provided so as to face the back surface of the platen. The suction duct is partitioned into a recording medium suction region and a fine particle suction region by a partition wall as described above. The width of the platen is wider than the maximum width of the recording medium that can be transported by the apparatus so that the fine particles can be sucked from the suction hole of the platen even if the recording medium having the maximum width that can be transported by the apparatus is transported. It has become. In such an image forming apparatus, as described above, when the partition is moved based on the width of the recording medium on the paper feed tray, the suction amount per unit time of the recording medium suction fan and the unit time of the fine particle suction fan Change the suction amount. As a result, the recording medium can be satisfactorily adsorbed to the platen, and the recording medium can be prevented from floating from the platen. Further, fine particles can be favorably sucked from the suction hole of the platen.

  As described above, according to the image forming apparatus of this embodiment, when the recording medium suction area 102 is reduced, the suction amount per unit time of the recording medium suction fan 106 serving as a recording medium suction unit is reduced. As a result, the recording medium can be satisfactorily sucked, and the power consumption and noise of the recording medium suction fan 106 can be suppressed. Further, when the recording medium suction area 102 is enlarged, the suction amount per unit time of the recording medium suction fan 106 is increased. As a result, even if the recording medium suction area 102 is enlarged, the suction force of each suction hole can be prevented from decreasing, and the recording medium can be satisfactorily sucked onto the transport belt 51 serving as a recording medium carrier. Can do.

  Further, the control unit 200 serving as the suction area changing unit changes the recording medium suction area 102 so that the length in the width direction of the recording medium suction area is the same as the length in the width direction of the recording medium detected by the width detection means. Therefore, the suction hole outside the recording medium width does not correspond to the recording medium suction fan. As a result, the recording medium can be satisfactorily sucked even if the suction amount per unit time of the recording medium suction fan is smaller than that in which the suction holes outside the recording medium width correspond to the recording medium suction fan. As a result, the rotation speed of the recording medium suction fan can be suppressed, and the lifting of the recording medium can be suppressed, compared to the case where the suction hole outside the recording medium width corresponds to the recording medium suction fan. Therefore, power consumption of the recording medium suction fan and noise of the recording medium suction fan can be suppressed.

  Further, the control unit 200 serving as the particulate suction amount correcting unit corrects the suction amount per unit time of the particulate suction fan serving as the particulate suction unit based on the printing rate and the paper type. As a result, if the image has a high printing rate or transports a recording medium that produces a lot of paper dust, the fine particles can be prevented from floating finely by correcting the suction amount per unit time of the fine particle suction fan. can do. Also, for images with low printing rates or when transporting recording media with low paper dust, the power consumption of the fine-particle suction fan and the fine-particle suction can be adjusted by reducing the suction amount per unit time of the fine-particle suction fan. The noise of the fan can be suppressed and fine particles suspended can be suppressed well.

  In addition, since the recording medium suction area is changed by moving the partition partitioning the recording medium suction area and the fine particle suction area, the recording medium suction area can be changed with a simple configuration.

  Further, since the control unit 200 as the fine particle suction amount adjusting means adjusts the suction amount per unit time of the fine particle suction fan in accordance with the fine particle suction region, the recording medium suction region and the fine particle suction region are partitioned as described above. As a result of moving the partition and changing the recording medium suction area, even if the fine particle suction area fluctuates, the suction force from the suction hole is prevented from being excessive or the suction force from the suction hole is reduced. Thus, fine particles can be sucked well, and power consumption and noise of the fine particle suction fan can be suppressed.

  Further, when the fine particle suction area is enlarged, the control unit 200 adjusts so that the suction amount per unit time of the fine particle suction fan is increased, so that the fine particle suction area is enlarged and the suction force of the suction hole is reduced. Can be suppressed. Thereby, the floating fine particles can be satisfactorily sucked. Further, the control unit adjusts the suction amount per unit time of the fine particle suction fan to be reduced when the fine particle suction area is reduced, so that the suction force of the suction hole can be suppressed from being excessive, It is possible to suppress the ink droplets ejected from the liquid ejection head as the liquid ejection means from being affected. Further, by reducing the suction amount per unit time of the particulate suction fan, the power consumption and noise of the particulate suction fan can be suppressed.

  Further, the control unit 200 as a recording medium conveyance control unit controls conveyance of the recording medium to the ink ejection region based on the detection result of the particle counter 1 as the fine particle amount detection unit that detects the amount of fine particles around the ink ejection region. Thus, the recording medium can be transported when there is not a little ink mist or paper dust in the apparatus. Thereby, it is possible to suppress the ink from being attached to the recording medium and soiling the recording medium. Moreover, it is possible to suppress a large amount of ink mist and paper dust from floating in the apparatus.

1 is a schematic front view of an ink jet printer according to an embodiment. FIG. 2 is a schematic top view of the inkjet printer. FIG. 3 is a schematic perspective view around a paper feed tray. The schematic block diagram of a suction device. FIG. 3 is a schematic configuration diagram of a suction device when a narrow recording medium is conveyed. The control block diagram in an inkjet printer. FIG. 3 is a control flow diagram of an image forming operation in the inkjet printer. The schematic block diagram of the suction device of the modification 1. FIG. The schematic block diagram of the suction device of the modification 1 when a narrow recording medium is conveyed. The schematic block diagram of the suction device of the modification 2. FIG. FIG. 10 is a schematic configuration diagram of a suction device according to a second modification when a narrow recording medium is conveyed. The schematic block diagram of the suction device of the modification 3. FIG. FIG. 10 is a schematic configuration diagram of a suction device according to Modification 3 when a narrow recording medium is conveyed.

Explanation of symbols

1: Particle counter 20: Paper feed tray 21: Paper feed roller 22: Separation roller 23: Entrance guide roller 24: Exit guide roller 25: Side fence 26: Slider 27: Paper size detection plate 28: Sheet member 30: Ejection Paper tray 40: Head units 41Y, 41M, 41C, 41K: Liquid discharge head 43: Sub tank 44: Main tank 50: Conveying unit 51a: Suction hole 51: Conveying belt 52: Driven roller 53: Drive roller 60: Head cleaning device 100 : Inkjet printer 101a: First particulate suction area 101b: Second particulate suction area 102: Recording medium suction area 103: First particulate suction fans 103a, 105a, 106a, 108a: Particulate capturing member 104: Partition 105: Second particulate suction Fan 106: Recording medium suction fan 110: Suction device 111: suction duct 112a: first particle suction duct 112b: second particle suction duct 113: connection duct 114: fine suction fan 200: control unit 201: control panel 202: conveying motor 203 conveying motor 203 bulkhead actuator P: recording medium

Claims (9)

Ink ejection means for ejecting ink toward the recording medium to form an image on the recording medium;
A recording medium carrier for carrying the recording medium;
A recording medium suction means for sucking air from the suction holes formed in the recording medium carrier, and for adsorbing the recording medium to the recording medium carrier;
In an image forming apparatus comprising: a fine particle suction unit that sucks fine particles floating in the apparatus from at least a suction hole of the recording medium carrier formed outside the maximum width of the recording medium that can be conveyed by the apparatus;
Width detecting means for detecting the width of the recording medium;
A suction area changing means for changing a recording medium suction area in which the recording medium suction means sucks air from the suction hole based on a detection result of the width detection means;
A recording medium suction amount adjusting means for adjusting a suction amount per unit time of the recording medium suction means according to the recording medium suction area ;
A partition that extends in the conveyance direction of the recording medium, and that partitions the recording medium suction area and a fine particle suction area in which the fine particle suction means sucks fine particles from the suction holes;
The partition wall is configured to be movable in the width direction,
An image forming apparatus according to claim 1, wherein the suction area changing means is configured to change the recording medium suction area by moving the partition wall based on a detection result of the width detection means . The image forming apparatus according to claim 1.
The recording medium suction amount adjusting means adjusts so that the suction amount per unit time of the recording medium suction means increases when the recording medium suction area is enlarged,
An image forming apparatus, wherein when the recording medium suction area is reduced, an adjustment is made so that a suction amount per unit time of the recording medium suction means is reduced. The image forming apparatus according to claim 1 or 2,
The suction area changing unit is configured to change the recording medium suction area such that the length in the width direction of the recording medium suction area is the same as the length in the width direction of the recording medium detected by the width detection unit. An image forming apparatus. The image forming apparatus according to any one of claims 1 to 3,
An image forming apparatus comprising fine particle suction amount correction means for correcting the suction amount per unit time of the fine particle suction means based on a printing rate and a paper type . 請 Motomeko 1 to 4 in any of the image forming apparatus,
An image forming apparatus comprising: a fine particle suction amount adjusting unit that adjusts a suction amount per unit time of the fine particle suction unit according to the fine particle suction region. The image forming apparatus according to claim 5 .
The fine particle suction amount adjusting means adjusts the suction amount per unit time of the fine particle suction means to be increased when the fine particle suction area is enlarged,
An image forming apparatus, wherein when the fine particle suction area is reduced, an adjustment is made so that a suction amount per unit time of the fine particle suction means is reduced. The image forming apparatus according to claim 1 to 6,
An image forming apparatus characterized in that the recording medium carrier is a conveying member that carries and conveys the recording medium so that the recording medium passes through an ink ejection area where the ink ejection means ejects ink. . The image forming apparatus according to claim 1 to 7,
Fine particle amount detection means for detecting the amount of fine particles around the ink discharge area;
An image forming apparatus comprising: a recording medium conveyance control unit configured to control conveyance of the recording medium to the ink discharge area based on a detection result of the fine particle amount detection unit. The image forming apparatus according to claim 8 .
An image forming apparatus comprising: the recording medium conveyance control unit configured to stop conveyance of the recording medium to the ink ejection area when the amount of fine particles detected by the fine particle amount detection unit is equal to or greater than a predetermined value. .

Images