JP6114885B2 - Wiping member, nozzle wiping unit, and image forming apparatus - Google Patents

Description

  The present invention relates to a wiping member, a nozzle wiping unit, and an image forming apparatus.

  Patent Document 1 discloses a cleaning mechanism for cleaning (wiping) the nozzle surface of an inkjet recording head with a cleaning sheet (wiping member). In addition, as an example of the cleaning sheet, a long-fiber non-woven fabric or a fabric knitted with ultrafine fibers is described. Patent Documents 2 to 4 describe the material and the like of the wiping member for wiping the nozzle, as in Patent Document 1.

JP 2008-137266 A JP 2005-21809 A JP 2014-104746 A JP 2004-202773 A

  By the way, when the nozzle surface is wiped with the wiping member, bubbles (air) may be caught in the nozzle, so that a streak may occur in the printed image immediately after the maintenance. Here, it has been found that if printing is performed after a maintenance period and printing is performed after the maintenance, streak generation is suppressed, but another solution is desired from the viewpoint of productivity.

  In view of the above-described facts, an object of the present invention is to provide a wiping member, a nozzle wiping unit, and an image forming apparatus that can suppress the occurrence of streaks during printing immediately after maintenance.

In order to solve the above-mentioned problem, the wiping member according to the first aspect of the present invention is a wiping member for wiping the nozzle surface of an ejection head provided with a nozzle for ejecting droplets of water-based ink, and is dropped on the wiping member. When the water absorption time, which is the time until the 0.05 ml of pure water absorbed by the wiping member, is t, and the optical density measured with the wiping member placed on a black plate is D, Satisfy the condition of
t ≧ 2.0 seconds D ≧ 0.110

According to the wiping member according to the first aspect of the present invention, by setting the water absorption time to 2.0 seconds or more, when the wiping member comes into contact with the nozzle surface, the water-based ink droplets are absorbed at an appropriate speed. Can do. Here, when the water absorption time is earlier than 2.0 seconds, the droplets are quickly absorbed by the wiping member, and air easily enters the nozzle. For this reason, it can suppress that a bubble is caught in a nozzle by setting it as the wiping member whose water absorption time is 2.0 second or more.

  In addition, by setting the optical density measured with the wiping member placed on the black plate to be 0.110 or more, the air that has entered between the wiping member and the nozzle surface when wiping the nozzle surface can be released. . That is, as the optical density increases, the amount of light reflected from the plate increases. That is, since the wiping member becomes sparse, air easily passes therethrough. Thereby, it can suppress that the air between a wiping member and a nozzle surface permeate | transmits a wiping member, and a bubble is caught in a nozzle. Thus, by using a wiping member having a water absorption time of 2.0 seconds or more and an optical density of 0.110 or more, bubbles are prevented from being caught in the nozzle, and streaks are generated during printing immediately after maintenance. Can be suppressed. The term “black plate” as used herein is a concept that includes not only strictly achromatic black, but also a wide range of plates that are colored to such an extent that the optical density does not change significantly.

  The wiping member according to the second aspect of the present invention has a water absorption time of 9.0 seconds or less in the wiping member according to the first aspect.

According to the wiping member of the second aspect of the present invention, by using the wiping member having a water absorption time of 9.0 seconds or less, the water- based ink droplets adhering to the nozzle surface can be appropriately absorbed, and the nozzle It can suppress that the maintainability of this falls.

  The wiping member according to the third aspect of the present invention has an optical density of 0.126 or less in the wiping member according to the first aspect or the second aspect.

  According to the wiping member according to the third aspect of the present invention, by using the wiping member having an optical density of 0.126 or less, the wiping member can be prevented from becoming too sparse, and the maintainability of the nozzle is lowered. Can be suppressed.

  A nozzle wiping unit according to a fourth aspect of the present invention includes the wiping member described in any one of the first aspect to the third aspect, a sending part that continuously feeds the wiping member, and the sent-out said part A winding unit that winds up the wiping member; and a pressing unit that is provided between the feeding unit and the winding unit and presses the wiping member against the nozzle surface of the ejection head.

According to the nozzle wiping unit according to the fourth aspect of the present invention, the belt-like wiping member sent out from the delivery unit is pressed against the nozzle surface of the ejection head by the pressing unit, and drops of water-based ink adhering to the nozzle surface. Wipe away. And the wiping member which wiped off the droplet is wound up by a winding part. Thereby, a nozzle surface can be wiped off efficiently with a wiping member.

  The nozzle wiping unit according to the fifth aspect of the present invention is the nozzle wiping unit according to the fourth aspect, wherein a cleaning liquid applying unit that applies a cleaning liquid to the wiping member is provided.

  According to the nozzle wiping unit of the fifth aspect of the present invention, the nozzle surface can be effectively wiped by wiping the nozzle surface with the wiping member provided with the cleaning liquid.

According to a sixth aspect of the present invention, there is provided an image forming apparatus including: a discharge head including a nozzle that discharges water-based ink droplets onto a recording medium; and the discharge head is moved between an image forming position and a maintenance position. An ejection head moving mechanism; and the nozzle wiping unit according to the fourth aspect or the fifth aspect, which is provided between the image forming position and the maintenance position and is disposed to face the ejection head. The nozzle surface of the ejection head is wiped by the wiping member during the movement of moving from the image forming position to the maintenance position and during the movement of the ejection head moving from the maintenance position to the image forming position.

According to the image forming apparatus of the sixth aspect of the present invention, the nozzle surface can be wiped by the wiping member of the nozzle wiping unit while the ejection head is moved by the head moving mechanism.
That is, the nozzle surface can be wiped off efficiently during maintenance.

The image forming apparatus according to a seventh aspect of the present invention is an image forming apparatus according to a sixth aspect, the discharge head is configured as droplets of a plurality of water-based inks are discharged at different positions on the recording medium Yes.

According to the image forming apparatus according to a seventh aspect of the present invention, droplets of a plurality of aqueous inks Ru are discharged at the same position on the recording medium, as compared with an image forming apparatus that performs so-called multiple-writing, the printing speed Can be improved.

An image forming apparatus according to an eighth aspect of the present invention is the image forming apparatus according to the sixth aspect or the seventh aspect, wherein the ejection head extends over the entire area in the width direction of the recording medium, and is performed in one scan. A one-line image is formed.

According to the image forming apparatus of the eighth aspect of the present invention, the printing speed can be improved as compared with a so-called shuttle scan type image forming apparatus that performs printing while repeatedly moving the ejection head.

  As described above, the wiping member, the nozzle wiping unit, and the image forming apparatus according to the present invention can suppress the generation of streaks during printing immediately after maintenance.

1 is an overall configuration diagram of an image forming apparatus according to an embodiment. FIG. 2 is a schematic plan view schematically showing an image forming unit and a maintenance unit of the image forming apparatus shown in FIG. 1. It is a schematic side view which shows schematically the nozzle wiping unit which concerns on embodiment. It is a graph which shows the relationship between the presence or absence of a streak, optical density, and water absorption time.

  Embodiments according to the present invention will be described below with reference to the accompanying drawings. In the present embodiment, an example in which the present invention is applied to an image forming apparatus that uses water-based pigment ink will be described. In the drawings, components having the same function are denoted by the same reference numerals, and description thereof will be omitted as appropriate.

(Overall configuration of image forming apparatus)
As shown in FIG. 1, the image forming apparatus 10 according to the present embodiment is configured to record an image on a single-sheet recording medium (paper) P using an aqueous pigment ink by an inkjet method. The image forming apparatus 10 includes a paper feeding unit 12 that feeds the recording medium P, a transport unit that transports the recording medium P, a processing liquid applying unit 14, a processing liquid drying processing unit 16, and an image forming unit 18. The heating / drying processing unit 20, the UV irradiation processing unit 22, the cooling processing unit 23, a paper discharge unit 24 for discharging the recording medium P, and a control unit are included.

(Paper Feeder)
The paper feed unit 12 is configured to feed the recording media P loaded on the paper feed tray 30 to the processing liquid application unit 14 one by one. The paper feed unit 12 mainly includes a paper feed base 30, a soccer device 32, a paper feed roller pair 34, a feeder board 36, a front pad 38, and a paper feed drum 40.

  The recording medium P is placed on the paper feed table 30 in a bundle state in which a large number of sheets are stacked. The paper feed table 30 is provided so as to be movable up and down by a paper feed table elevating device (not shown). Further, the paper feed table elevating device is controlled to be driven in conjunction with the increase / decrease of the recording media P loaded on the paper feed table 30. The paper feed table 30 is moved up and down so that the recording medium P located at the top of the bundle is always located at a certain height.

  The recording medium P is not particularly limited, but general-purpose printing paper used in general offset printing or the like (so-called high-quality paper, coated paper, art paper, or other paper mainly composed of cellulose) can be used.

  The soccer device 32 picks up the recording media P loaded on the paper feed tray 30 one by one from the top and feeds them to the paper feed roller pair 34. The soccer device 32 includes a suction foot 32A provided so as to be movable up and down and swingable. The upper surface of the recording medium P is sucked and held by the suction foot 32A, and the recording medium P is conveyed from the paper feed table 30 to the paper feed roller pair 34. At this time, the suction foot 32A sucks and holds the top surface of the recording medium P positioned at the top of the bundle to pull up the recording medium P, and the leading end of the recording medium P that is pulled up constitutes a paper feed roller pair 34. It is set as the structure inserted between a pair of roller 34A and roller 34B.

  The pair of paper feed rollers 34 includes a pair of upper and lower rollers 34A and 34B that are pressed against each other. One of the pair of upper and lower rollers 34A and 34B is a driving roller (for example, roller 34A) and the other is a driven roller (for example, roller 34B). The drive roller is connected to a motor (not shown) and is driven to rotate by the rotation of the motor. The motor is driven in conjunction with the feeding of the recording medium P. When the recording medium P is fed from the soccer device 32, the driving roller is rotated in accordance with the timing. The recording medium P inserted between the pair of upper and lower rollers 34 </ b> A and 34 </ b> B is nipped by the rollers 34 </ b> A and 34 </ b> B and sent out in the direction in which the feeder board 36 is installed.

  The feeder board 36 is formed to correspond to the recording medium width, and is configured to guide the recording medium P sent out from the paper feed roller pair 34 to the front pad 38. The feeder board 36 is installed to be inclined downward, and the recording medium P placed on the conveying surface of the conveying path of the feeder board 36 is slid along the conveying surface and guided to the front pad 38. .

  On the feeder board 36, a plurality of tape feeders 36A, which transport the recording medium P and have the transport direction as a longitudinal direction, are provided at intervals in the width direction. The tape feeder 36A is formed in an endless shape and is configured to rotate using a motor (not shown) as a drive source. The recording medium P placed on the conveyance surface of the feeder board 36 is conveyed on the feeder board 36 by the tape feeder 36A.

  On the feeder board 36, a retainer 36B and a roller 36C are installed. A plurality of retainers 36 </ b> B are arranged in the longitudinal direction along the conveyance surface of the recording medium P (two in the present embodiment). The retainer 36B is configured by a leaf spring having a width corresponding to the width of the recording medium, and is pressed against and brought into contact with the conveyance surface. The recording medium P conveyed on the feeder board 36 by the tape feeder 36A passes through the retainer 36B so that the unevenness is corrected. The roller 36C is disposed between an upstream retainer 36B and a downstream retainer 36B disposed in the transport direction. The roller 36 </ b> C is pressed against the conveying surface of the recording medium P. The recording medium P is conveyed between the retainers 36B while the upper surface is pressed by the rollers 36C.

  The front pad 38 corrects the posture of the recording medium P. The front pad 38 is formed in a plate shape, and a plate-like surface is disposed orthogonal to the conveyance direction of the recording medium P. The front pad 38 is connected to a motor (not shown), and is driven by this motor to be swingable. When the leading edge of the recording medium P conveyed on the feeder board 36 comes into contact with the front pad 38, the conveying posture of the recording medium P is corrected (so-called skew prevention is performed). The front pad 38 is swung in conjunction with the feeding of the recording medium P to the paper feeding drum 40, and the recording medium P whose transport posture is corrected is delivered to the paper feeding drum 40.

  The paper supply drum 40 receives the recording medium P supplied from the feeder board 36 via the front pad 38 and conveys it to the processing liquid application unit 14. The paper feed drum 40 is formed in a cylindrical shape and connected to a motor (not shown), and rotates by the driving force of this motor. Further, a gripper 40A is provided on the outer peripheral surface of the paper supply drum 40, and the leading end of the recording medium P is gripped by the gripper 40A. The paper feed drum 40 conveys the recording medium P to the treatment liquid applying unit 14 while winding the recording medium P on the peripheral surface by gripping and rotating the tip of the recording medium P with the gripper 40A.

(Processing liquid application part)
The processing liquid application unit 14 applies a predetermined processing liquid to the surface (image forming surface) of the recording medium P. The treatment liquid application unit 14 mainly applies a treatment liquid application drum 42 that conveys the recording medium P, and a treatment liquid application that applies a predetermined treatment liquid to the image forming surface of the recording medium P conveyed by the treatment liquid application drum 42. And a unit 44. The treatment liquid applied to the surface of the recording medium P has a function of aggregating the color material (pigment) in the ink ejected (droplet ejected) onto the recording medium P by the image forming unit 18 disposed on the downstream side in the transport direction. It has a flocculant.

  The treatment liquid application drum 42 conveys the recording medium P conveyed from the paper supply drum 40 of the paper supply unit 12 to the treatment liquid drying processing unit 16. The treatment liquid application drum 42 is formed in a cylindrical shape and is connected to a motor (not shown), and is rotated by the driving force of this motor. A gripper 42A is provided on the outer peripheral surface of the treatment liquid application drum 42, and the leading end of the recording medium P is gripped by the gripper 42A. The treatment liquid application drum 42 conveys the recording medium P to the treatment liquid drying processing unit 16 while winding the recording medium P on the peripheral surface by gripping and rotating the tip of the recording medium P with the gripper 42A. . When the treatment liquid application drum 42 rotates once, one recording medium P is conveyed. The processing liquid application drum 42 and the paper feed drum 40 are controlled in rotation by matching the timings of receiving and delivering the recording medium P with each other. That is, the treatment liquid application drum 42 and the paper feed drum 40 are driven with their peripheral speeds matched, and are driven with the positions of the grippers 40A and 42A matched.

  The treatment liquid application unit 44 applies the treatment liquid to the surface of the recording medium P conveyed by the treatment liquid application drum 42. The processing liquid application unit 44 mainly pumps up the application roller 44A for applying the processing liquid to the recording medium P, the processing liquid tank 44B for storing the processing liquid, and the processing liquid stored in the processing liquid tank 44B, The pumping roller 44 </ b> C is supplied to the application roller 44 </ b> A.

  In this embodiment, the processing liquid is applied by a roller, but the method of applying the processing liquid is not limited to this. In addition to the treatment liquid, a method of applying using an inkjet head or a method of applying using a spray may be employed.

(Processing liquid drying processing part)
In the treatment liquid drying processing unit 16, the recording medium P having the treatment liquid applied to the surface is dried. The processing liquid drying processing unit 16 mainly performs drying air on the image forming surface of the recording medium P transported by the processing liquid drying processing drum 46 that transports the recording medium P, the paper transport guide 48, and the processing liquid drying processing drum 46. And a processing liquid drying processing unit 50 for spraying and drying.

  The processing liquid drying processing drum 46 is configured to receive the recording medium P from the processing liquid application drum 42 of the processing liquid application unit 14 and convey the recording medium P to the image forming unit 18. The treatment liquid drying treatment drum 46 is constituted by a frame assembled in a cylindrical shape, is connected to a motor (not shown), and is rotated by the driving force of this motor. A gripper 46A is provided on the outer peripheral surface of the processing liquid drying processing drum 46, and the leading end of the recording medium P is gripped by the gripper 46A. The processing liquid drying processing drum 46 conveys the recording medium P to the image forming unit 18 by gripping and rotating the leading end of the recording medium P with the gripper 46A. Note that the processing liquid drying processing drum 46 in the present embodiment is configured such that grippers 42A are disposed at two locations on the outer peripheral surface, and the two recording media P are conveyed by one rotation. The rotation of the processing liquid drying processing drum 46 and the processing liquid applying drum 42 is controlled by matching the timings of receiving and transferring both recording media P. That is, the processing liquid drying processing drum 46 and the processing liquid application drum 42 are driven with their peripheral speeds matched, and are driven with the positions of the grippers 42A and the grippers 46A of each other.

  The paper transport guide 48 is disposed around the outer periphery of the processing liquid drying processing drum 46 along the transport path of the recording medium P. The paper transport guide 48 guides the recording medium P so as not to be detached from the processing liquid drying processing drum 46 (transport path).

  The processing liquid drying processing unit 50 is installed inside the processing liquid drying processing drum 46 and is configured to perform drying processing by blowing dry air toward the surface of the recording medium P conveyed by the processing liquid drying processing drum 46. ing. Thereby, the solvent component in the processing liquid is removed, and an ink aggregation layer is formed on the surface of the recording medium P. In the present embodiment, two processing liquid drying processing units 50 are arranged in the processing liquid drying processing drum, and the drying air is directed toward the surface of the recording medium P conveyed by the processing liquid drying processing drum 46. It is configured to spray.

(Image forming part)
The image forming unit 18 discharges ink droplets of colors M, K, Y, and C onto the image forming surface of the recording medium P, and records a color image on the image forming surface of the recording medium P (printing or drawing). ) Configuration. The image forming unit 18 mainly presses the image forming drum 52 that conveys the recording medium P and the recording medium P that is conveyed by the image forming drum 52 so that the recording medium P adheres to the peripheral surface of the image forming drum 52. An inkjet head 56K, 56Y, 56M, and 56C (hereinafter, generic names) as an example of an ejection head that ejects M, K, Y, and C ink droplets (droplets) onto the recording medium P. In this case, the ink jet head 56 is called), an inline sensor 58 that reads an image recorded on the recording medium P, a mist filter 60 that captures ink mist, and a drum cooling unit 62.

  The image forming drum 52 is configured to receive the recording medium P from the processing liquid drying processing drum 46 of the processing liquid drying processing unit 16 and to transport the recording medium P to the heat drying processing unit 20. The image forming drum 52 is formed in a cylindrical shape, is connected to a motor (not shown), and rotates by the driving force of this motor. A gripper 52A is provided on the outer peripheral surface of the image forming drum 52, and the leading end of the recording medium P is gripped by the gripper 52A. The image forming drum 52 conveys the recording medium P to the heating and drying processing unit 20 while winding the recording medium P around the peripheral surface by gripping and rotating the tip of the recording medium P with the gripper 52A. In addition, a large number of suction holes (suction holes) (not shown) are provided in a predetermined pattern on the peripheral surface of the image forming drum 52. The recording medium P wound around the peripheral surface of the image forming drum 52 is sucked through the suction holes, so that the recording medium P can be conveyed while being sucked and held on the peripheral surface of the image forming drum 52. Thereby, the recording medium P can be conveyed with high smoothness.

  Note that the suction from the suction hole is performed only within a certain range, and the recording medium P is sucked between a predetermined suction start position and a predetermined suction end position. The suction start position is set to the installation position of the recording medium pressing roller 54. The suction end position is set on the downstream side of the installation position of the inline sensor 58, and is set, for example, at a position where the recording medium P is delivered to the heat drying processing unit 20. In other words, at least at the installation position (image forming position) of the inkjet head 56 and the installation position (image reading position) of the inline sensor 58, the recording medium P is set to be sucked and held on the peripheral surface of the image forming drum 52. . Further, the adsorption method is not limited to the adsorption method using negative pressure, and may be an adsorption method using electrostatic adsorption.

  Further, the image forming drum 52 in the present embodiment is provided with grippers 52A at two locations on the outer peripheral surface, so that two recording media P can be conveyed by one rotation. The rotation of the image forming drum 52 and the processing liquid drying processing drum 46 is controlled by matching the timings of receiving and transferring both recording media P. That is, the image forming drum 52 and the processing liquid drying processing drum 46 are driven with the peripheral speeds matched, and are driven with the positions of the grippers 46A and the grippers 52A matched.

  The recording medium pressing roller 54 is disposed in the vicinity of the receiving position of the recording medium P of the image forming drum 52 (the position where the recording medium P is received from the processing liquid drying processing drum 46). The recording medium pressing roller 54 is constituted by a rubber roller, for example, and is installed in press contact with the peripheral surface of the image forming drum 52. The recording medium P transferred from the processing liquid drying processing drum 46 to the image forming drum 52 is nipped by passing through the recording medium pressing roller 54 and is brought into close contact with the peripheral surface of the image forming drum 52.

  The four inkjet heads 56K, 56Y, 56M, and 56C are arranged on the outer peripheral surface of the image forming drum 52 along the conveyance path of the recording medium P at a constant interval. Each of the inkjet heads 56K, 56Y, 56M, and 56C is configured by a line head corresponding to the recording medium width, and the nozzle surface is disposed to face the peripheral surface of the image forming drum 52. Each of the inkjet heads 56K, 56Y, 56M, and 56C discharges ink droplets from the nozzle row formed on the nozzle surface toward the image forming drum 52, thereby causing the recording medium P to be conveyed by the image forming drum 52. Form an image.

  Here, in this embodiment, as an example, the inkjet head 56 is configured such that a plurality of ink droplets are ejected to different positions on the recording medium P. That is, it is configured not to perform multiple writing. Further, the inkjet head 56 is configured to perform image formation by a single pass method in which an image of one line is formed by one scanning.

  As shown in FIG. 2, the four inkjet heads 56K, 56Y, 56M and 56C are supported by a head support frame 84, and an image forming position A for forming an image and a maintenance position B for performing maintenance. It can be moved between each other. Between the image forming position A and the maintenance position B, nozzle wiping units 86K, 86Y, 86M and 86C (hereinafter collectively referred to as “nozzle wiping unit 86”) are arranged. Details of the nozzle wiping unit 86 will be described later.

  An in-line sensor 58 is installed on the downstream side in the transport direction from the rearmost inkjet head 56K. The in-line sensor 58 is configured to read images recorded by the inkjet heads 56K, 56Y, 56M, and 56C. The inline sensor 58 is constituted by a line scanner, for example.

  A contact prevention plate 59 installed in the vicinity of the inline sensor 58 is provided on the downstream side of the inline sensor 58. The contact prevention plate 59 can prevent the recording medium P from coming into contact with the in-line sensor 58 when the recording medium P is lifted or broken due to a conveyance failure or the like.

  The mist filter 60 is disposed between the rearmost inkjet head 56Y and the in-line sensor 58, and sucks air around the image forming drum 52 to capture the ink mist. By capturing the ink mist, the ink mist is prevented from entering the in-line sensor 58, and the occurrence of image reading defects and the like is effectively prevented.

  The drum cooling unit 62 is configured to cool the image forming drum 52 by blowing cool air to the image forming drum 52. The drum cooling unit 62 mainly includes an air conditioner (not shown) and a duct 62 </ b> A that blows cool air supplied from the air conditioner onto the peripheral surface of the image forming drum 52. The duct 62 </ b> A is configured to cool the image forming drum 52 by blowing cool air to the image forming drum 52 in a region other than the conveyance region of the recording medium P. In the present embodiment, since the recording medium P is conveyed along the arcuate outer peripheral surface of the upper half of the image forming drum 52, the duct 62 </ b> A has cold air in the region of the lower half of the image forming drum 52. Is sprayed to cool the image forming drum 52. Specifically, the air outlets (not shown) of the duct 62 </ b> A are arranged in an arc shape so as to cover the substantially lower half of the image forming drum 52.

(Heat drying processing part)
The heat drying processing unit 20 performs a drying process on the recording medium P after image recording, and removes the liquid component remaining on the surface of the recording medium P. The heat drying processing unit 20 mainly applies a back tension (tension) to the chain gripper 64 as an example of a transport unit that transports the recording medium P on which an image is recorded, and the recording medium P transported by the chain gripper 64. A back tension applying mechanism 66 and a drying unit 68 for heating and drying the recording medium P conveyed by the chain gripper 64 are configured.

  The chain gripper 64 is a paper transport mechanism commonly used in the heat drying processing unit 20, the UV irradiation processing unit 22, and the paper discharge unit 24. The chain gripper 64 receives the recording medium P transferred from the image forming unit 18, The paper is conveyed to the paper discharge unit 24.

  The chain gripper 64 mainly includes a first sprocket 64A installed in the vicinity of the image forming drum 52 and a second sprocket 64B installed in the paper discharge unit 24. An endless chain 64C is wound around the first sprocket 64A and the second sprocket 64B. Further, a plurality of chain guides (not shown) for guiding the running of the chain 64C are provided, and a plurality of grippers 64D are attached to the chain 64C at regular intervals. The first sprocket 64A, the second sprocket 64B, the chain 64C, and the chain guide are each configured as a pair, and are disposed on both sides in the width direction of the recording medium P. Further, the gripper 64D is installed over a pair of chains 64C provided.

  The first sprocket 64A is installed close to the image forming drum 52 so that the recording medium P delivered from the image forming drum 52 can be received by the gripper 64D. The first sprocket 64A is rotatably supported by a bearing (not shown), and is connected to a motor (not shown) via a gear. The chain 64C wound around the first sprocket 64A and the second sprocket 64B travels by driving this motor.

  The second sprocket 64 </ b> B is installed in the paper discharge unit 24 so that the recording medium P received from the image forming drum 52 can be collected by the paper discharge unit 24. That is, the installation position of the second sprocket 64B is the end of the conveyance path of the recording medium P by the chain gripper 64. The second sprocket 64B is pivotally supported by a bearing (not shown) and is rotatably provided.

  The chain 64C is formed in an endless shape and is wound around the first sprocket 64A and the second sprocket 64B.

  The chain guide is disposed at a predetermined position and guides the chain 64C to travel along a predetermined route. In the present embodiment, the second sprocket 64B is disposed at a higher position than the first sprocket 64A. For this reason, a travel route in which the chain 64C is inclined in the middle is formed. Specifically, a travel path is configured by the first horizontal transport path 70A, the inclined transport path 70B, and the second horizontal transport path 70C.

  70 A of 1st horizontal conveyance paths are set to the same height as 1st sprocket 64A, and chain 64C wound around 1st sprocket 64A is set so that it may run horizontally. The second horizontal conveyance path 70C is set to the same height as the second sprocket 64B, and the chain 64C wound around the second sprocket 64B is set to travel horizontally. The inclined conveyance path 70B is set between the first horizontal conveyance path 70A and the second horizontal conveyance path 70C, and is set so as to connect the first horizontal conveyance path 70A and the second horizontal conveyance path 70C.

  The chain guide is disposed so as to form the first horizontal conveyance path 70A, the inclined conveyance path 70B, and the second horizontal conveyance path 70C. Specifically, it is disposed at at least a junction point between the first horizontal conveyance path 70A and the inclined conveyance path 70B and a junction point between the inclined conveyance path 70B and the second horizontal conveyance path 70C.

  A plurality of grippers 64D are attached to the chain 64C at a constant interval. The attachment interval of the gripper 64D is set in accordance with the reception interval of the recording medium P from the image forming drum 52. That is, it is set in accordance with the receiving interval of the recording medium P from the image forming drum 52 so that the recording medium P sequentially delivered from the image forming drum 52 can be received from the image forming drum 52 at the same timing.

  The chain gripper 64 is configured as described above. As described above, when a motor (not shown) connected to the first sprocket 64A is driven, the chain 64C travels. The chain 64C travels at the same speed as the peripheral speed of the image forming drum 52. In addition, the timing is adjusted so that the recording medium P delivered from the image forming drum 52 can be received by each gripper 64D.

  The back tension applying mechanism 66 applies a back tension (tension) to the recording medium P that is conveyed while its tip is held by the chain gripper 64. The back tension applying mechanism 66 mainly includes a guide plate 72 as a conveyance path disposed in the heat drying processing unit 20.

  The guide plate 72 is a hollow box plate having a width corresponding to the width of the recording medium P. A number of suction holes (not shown) are formed on the upper surface of the guide plate 72. Further, an exhaust pipe for discharging air sucked from a number of suction holes by a suction fan is connected to the lower side of the guide plate 72.

  The guide plate 72 configured as described above is arranged along the conveyance path of the recording medium P by the chain gripper 64 and constitutes the conveyance path of the recording medium P. Specifically, it is disposed along the chain 64C that travels along the first horizontal conveyance path 70A, and is spaced apart by a predetermined distance from the chain 64C. For this reason, the recording medium P conveyed on the outer peripheral side of the chain 64C by the chain gripper 64 is conveyed while being dragged in a state where the surface opposite to the drawing surface is attracted to the upper surface of the guide plate 72.

  A large number of suction holes formed on the upper surface of the guide plate 72 suck the portion excluding the front end portion of the recording medium P gripped by the gripper 64D when the suction fan sucks the hollow portion (inside) of the guide plate 72. To do. As a result, back tension (tension) is applied to the recording medium P conveyed by the chain gripper 64.

  As described above, since the guide plate 72 is disposed along the chain 64C that travels along the first horizontal transport path 70A, back tension is applied while the recording medium P is transported along the first horizontal transport path 70A. Is done.

  A plurality of drying units 68 are arranged along the first horizontal conveyance path 70A. In the present embodiment, as an example, four drying units 68 are provided along the first horizontal conveyance path 70A. Thereby, while the recording medium P passes under the four drying units 68, the drying unit 68 blows heated air (warm air) onto the recording medium P, and the recording medium P is heated and dried.

The number of drying units 68 is set according to the processing capacity of the drying unit 68, the conveyance speed of the recording medium P, and the like. That is, the number of installation as can be dried while the recording medium P received from the image forming unit 18 is being conveyed first horizontal conveyance path 70A is set.

  The heat drying processing unit 20 is configured as described above. The recording medium P delivered from the image forming drum 52 of the image forming unit 18 is received by the chain gripper 64. The chain gripper 64 grips the leading end portion of the recording medium P with the gripper 64 </ b> D and lifts it from the guide plate 72, and transports the recording medium P in a state where the trailing end portion of the recording medium P is in contact with the guide plate 72. The recording medium P delivered to the chain gripper 64 is first transported along the first horizontal transport path 70A. In the process of being transported along the first horizontal transport path 70A, hot air is blown from the drying unit 68 to the recording medium P, and a heat drying process is performed. At this time, the recording medium P is dried while being applied with the back tension (tension) by the back tension applying mechanism 66, so that it is possible to suppress the occurrence of drying unevenness and wrinkles.

(UV irradiation processing part)
The UV irradiation processing unit 22 irradiates the drawing surface of the recording medium P on which the ink has been ejected with ultraviolet rays as an example of active energy rays to cure the ink and fix the image. Here, the active energy ray refers to an energy ray that can generate a starting species in the ink composition by irradiation, and widely includes α rays, γ rays, X rays, ultraviolet rays, visible rays, electron rays, and the like. Among them, ultraviolet rays and electron beams are preferably used from the viewpoint of curing sensitivity and device availability, and ultraviolet rays are more preferred.

  The UV irradiation processing unit 22 is mainly transported by a chain gripper 64 that transports the recording medium P, a back tension applying mechanism 66 that applies back tension to the recording medium P transported by the chain gripper 64, and the chain gripper 64. And a UV irradiation unit 74 for irradiating the recording medium P with ultraviolet rays. Further, the chain gripper 64 and the back tension applying mechanism 66 are used in common with the heat drying processing unit 20.

  The UV irradiation unit 74 is disposed opposite to the guide plate 72 on the inner peripheral side of the chain 64C on the downstream side in the transport direction from the drying unit 68, and ultraviolet rays (UV) are applied to the drawing surface of the recording medium P that has passed through the heat drying processing unit 20. ).

(Cooling processing part)
The cooling processing unit 23 cools the recording medium P that has been heat-dried by the heat-drying processing unit 20 and irradiated with ultraviolet rays by the UV irradiation processing unit 22. The cooling processing unit 23 mainly serves as an example of a chain gripper 64 that transports the UV-irradiated recording medium P and a transport surface that supports the recording medium P transported by the chain gripper 64 and is in sliding contact with the recording medium P. A support plate 82 and a blower unit 78 for blowing air to the recording medium P conveyed by the chain gripper 64 are configured.

  As described above, the chain gripper 64 is used in common with the heat drying processing unit 20 and the UV irradiation processing unit 22. The support plate 82 is disposed along the chain 64C that travels along the first horizontal conveyance path 70A and the inclined conveyance path 70B.

  A plurality of the air blowing units 78 are arranged to face the support plate 82 (conveying surface). In the present embodiment, as an example, two air blowing units 78 face the supporting plate 82 arranged in the first horizontal conveyance path 70A. A blower unit 78 is provided, and three blower units 78 are provided so as to face the support plate 82 arranged in the inclined conveyance path 70 </ b> B, and air is blown from each of the blower units 78 to the recording medium P. The surface (drawing surface) of the recording medium P is cooled. The cooled recording medium P is transported to the second horizontal transport path 70C.

(Output section)
The paper discharge unit 24 is configured to collect the recording medium P that has undergone a series of image forming processes. The paper discharge unit 24 mainly includes a chain gripper 64 that conveys the recording medium P on which ink has been fixed, and a paper discharge tray 76 that stacks and collects the recording medium P. The paper discharge tray 76 is provided with a sheet pad (front sheet pad, rear sheet pad, lateral sheet pad, etc.) for orderly stacking the recording media P. In addition, a discharge tray lifting device (not shown) is provided on the discharge tray 76 so that the recording medium P can be moved up and down. In the paper delivery platform lifting / lowering device, the elevation drive is controlled in conjunction with the increase / decrease of the recording media P collected on the paper delivery platform 76, so that the topmost recording media P is always positioned at a certain height. Has been adjusted to.

(ink)
As the ink used in the present embodiment, for example, an aqueous ultraviolet ink that is cured by irradiation with ultraviolet rays as light is used. The aqueous ultraviolet ink preferably contains a pigment, polymer particles, a water-soluble polymerizable compound that is polymerized by active energy rays, and a photopolymerization initiator. In such an aqueous ultraviolet ink, when cured by being irradiated with ultraviolet rays, the image has excellent abrasion resistance and the image has high film strength. Note that the coloring material may include a dye.

(Nozzle wiping unit)
Next, the nozzle wiping unit 86 will be described with reference to FIGS. Although FIG. 3 shows the nozzle wiping unit 86K, the other nozzle wiping units 86Y, 86M, and 86C have the same configuration. As shown in FIG. 2, the nozzle wiping unit 86 is disposed between an image forming position A for forming an image and a maintenance position B for performing maintenance of the inkjet head 56. The nozzle wiping units 86K, 86Y, 86M, and 86C are arranged at positions facing the respective inkjet heads 56K, 56Y, 56M, and 56C.

  Here, the image forming position A is set in the image forming unit 18 of FIG. In FIG. 2, for convenience of explanation, only the main part is shown, and the illustration of the image forming drum 52 and the processing liquid drying processing drum 46 for conveying the recording medium P is omitted, but the inkjet head 56K. , 56Y, 56M, and 56C, an image forming drum 52 is disposed (see FIG. 1). At this image forming position A, image formation is performed by ejecting ink onto the recording medium P conveyed from the upstream side in the conveying direction.

  On the other hand, the maintenance position B is set on the side opposite to the image forming position A across the nozzle wiping unit 86. At the maintenance position B, caps 90K, 90Y, 90M for covering the nozzle surfaces 57K, 57Y, 57M, 57C (hereinafter collectively referred to as “nozzle surface 57”) of the respective inkjet heads 56K, 56Y, 56M, 56C. , 90C (hereinafter, collectively referred to as “cap 90”). Here, the head support frame 84 that supports the inkjet head 56 is provided with a moving mechanism (discharge head moving mechanism) (not shown). The moving mechanism moves the inkjet head 56 between the image forming position A and the maintenance position B. It can be moved between each other. When the image forming apparatus 10 is stopped for a long time, the inkjet head 56 supported by the head support frame 84 is moved to the maintenance position B, and the nozzle surface 57 of the inkjet head 56 is covered with the cap 90. Non-discharge due to drying can be prevented.

  As shown in FIG. 3, the nozzle wiping unit 86 provided between the image forming position A and the maintenance position B moves the belt-shaped nozzle wiping sheet (web) 120 as a wiping member to the inkjet head 56K. The nozzle surface 57K of the inkjet head 56K is wiped off by being brought into contact therewith.

  The nozzle wiping unit 86 mainly includes a nozzle wiping sheet 120, a feeding-side web core 102 as a feeding unit, a winding-side web core 104 as a winding unit, and a plurality of guide rollers 106A, 106B, 106C, 106D, 106E, 106F and 106G (hereinafter collectively referred to as “guide roller 106”), a pressing roller 110 as a pressing portion, and a cleaning liquid applying mechanism 93 as a cleaning liquid applying portion.

  The delivery-side web core 102 is a cylindrical member that extends horizontally and is supported so as to be rotatable around an axis. A nozzle wiping sheet 120 is wound around the outer peripheral surface of the delivery-side web core 102 in a roll shape. Yes. On the other hand, the winding-side web core 104 is a columnar member that extends horizontally and is supported so as to be rotatable around an axis. The nozzle wiping sheet that is fed from the feeding-side web core 102 and wipes the nozzle surface 57K. 120 is wound into a roll. Further, the winding-side web core 104 is connected to a motor (not shown), and when this motor is driven, the winding-side web core 104 rotates around the axis and winds the nozzle wiping sheet 120. And the nozzle wiping sheet | seat 120 is continuously sent out from the sending side web core 102 by winding up the nozzle wiping sheet | seat 120. FIG.

  A guide roller 106 is disposed in the conveyance path of the nozzle wiping sheet 120 from the sending side web core 102 to the winding side web core 104. The nozzle wiping sheet 120 is stretched over guide rollers 106A, 106B, 106C, 106D, and 106E in this order. Further, the nozzle wiping sheet 120 is wound around the outer peripheral surface of the winding-side web core 104 through a guide roller 106F and a guide roller 106G disposed above and below.

  Here, a pressing roller 110 is disposed between the guide roller 106C and the guide roller 106D. The pressing roller 110 is formed in a cylindrical shape having a larger diameter than the guide roller 106 and is urged upward by an urging means (not shown). During the movement of the inkjet head 56K moving from the image forming position A to the maintenance position B and during the movement of the inkjet head 56K moving from the maintenance position B to the image forming position A, the pressing roller 110 is moved. The nozzle wiping sheet 120 is pressed against the nozzle surface 57K of the inkjet head 56K to wipe the nozzle surface 57K.

  In the present embodiment, the band-shaped nozzle wiping sheet 120 is used as the wiping member. However, the wiping member is not limited to this, and is not limited to a sheet-like member as long as the nozzle surface 57 of the inkjet head 56 can be wiped off. For example, a wiping member thicker than the nozzle wiping sheet 120 may be used. Further, the pressing force of the pressing roller 110 is not particularly limited, and the nozzle wiping sheet 120 may be pressed to such an extent that it contacts the nozzle surface 57.

  The nozzle wiping unit 86 is provided with a cleaning liquid application mechanism 93. The cleaning liquid application mechanism 93 mainly includes a storage tank 94 that stores the cleaning liquid 108, a pump 96, a dropping unit 100, and a tube 98.

  The storage tank 94 stores the cleaning liquid 108, and the pump 96 is driven so that the cleaning liquid 108 in the storage tank 94 can be pumped up. One end of the tube 98 extends into the storage tank 94 via the pump 96, and the other end of the tube 98 extends to the vicinity of the guide roller 106B. A dropping unit 100 is provided at the other end of the tube 98, and a predetermined amount of cleaning liquid 108 can be dropped (applied) from the dropping unit 100 to the nozzle wiping unit 86.

  In the present embodiment, the cleaning liquid applying mechanism 93 that drops and applies the cleaning liquid 108 to the nozzle wiping unit 86 is provided. However, the present invention is not limited to this, and a device for applying the cleaning liquid may be provided separately from the nozzle wiping unit 86. Good. Moreover, you may comprise so that a washing | cleaning liquid may be provided by another method. For example, the cleaning liquid 108 may be applied to the nozzle wiping sheet 120 using a roller or the like.

(Cleaning solution)
In this embodiment, as an example of the cleaning liquid 108, a component having the following composition is mixed and adjusted with nitric acid so as to have a pH of 7.8 (25 ° C.).
-DEGmBE (water-soluble organic solvent) 20.0 mass%
・ DEG (humectant) ・ ・ ・ 10.0 mass%
・ Imidazole (pKa = 7.0, basic compound) 0.5 mass%
・ Benzotriazole: 0.2% by mass
・ Ion-exchanged water: Remaining amount when 100% by mass as a whole

(Nozzle wiping sheet)
Next, the nozzle wiping sheet 120 will be described. The nozzle wiping sheet 120 is formed in a long shape, and is composed of, for example, a sheet woven with ultrafine fibers such as polyethylene terephthalate, polyethylene, and nylon.

The nozzle wiping sheet 120 is configured to satisfy the following condition when the water absorption time is t and the optical density measured in a state where the nozzle wiping sheet 120 is placed on a black plate is D.
t ≧ 2.0 seconds D ≧ 0.110

(Measurement of water absorption time)
The water absorption time of the nozzle wiping sheet 120 was measured as follows. First, the nozzle wiping sheet 120 is laid on a container such as a cup so as to cover the opening of the container. At this time, both sides of the measurement unit in the nozzle wiping sheet 120 are in contact with air and do not sag. Next, a droplet of pure water is dropped with a syringe from about 10 cm above the nozzle wiping sheet 120. The dripping amount at this time is 0.05 ml. And time until the specular reflection of the droplet dripped on the nozzle wiping sheet | seat 120 was lose | eliminated was measured.

(Optical density)
The optical density (reflection density) of the nozzle wiping sheet 120 was measured with a reflection densitometer (X-rite 404) manufactured by X-rite. The measurement was performed with the nozzle wiping sheet 120 placed on a black plate. In addition, the reflection densitometer was calibrated before the measurement, and the measurement was performed so that no tension was applied to the nozzle wiping sheet 120 and the aperture was positioned above the nozzle wiping sheet 120 during the measurement. In consideration of the measurement error, the average value of the measured values measured at three locations was used as the optical density.

  In the present embodiment, the water absorption time of the nozzle wiping sheet 120 is measured by the above method, but other methods may be adopted as long as the measurement method can obtain the same result. For example, you may employ | adopt the dripping method etc. of the water absorption test method of the textiles prescribed | regulated by Japanese Industrial Standard (JISL1907).

  In addition, the water absorption time of the nozzle wiping sheet 120 is not particularly limited as long as it is 2.0 seconds or more, but is preferably 9.0 seconds or less. That is, by using the nozzle wiping sheet 120 having a water absorption time of 9.0 seconds or less, it is possible to appropriately absorb ink droplets or the like adhering to the nozzle surface 57. For this reason, it can suppress that the maintainability of the nozzle surface 57 of the inkjet head 56 falls.

  Further, the optical density of the nozzle wiping sheet 120 is not particularly limited as long as it is 0.110 or more, but is preferably 0.126 or less. In other words, by using the nozzle wiping sheet 120 having an optical density of 0.126 or less, the nozzle wiping sheet 120 is not excessively sparse, and the maintenance performance of the nozzle surface 57 can be suppressed from decreasing.

(Function and effect)
Next, the operation and effect of this embodiment will be described. In the image forming apparatus 10 according to the present embodiment, as shown in FIG. 2, when the inkjet head 56 moves from the image forming position A to the maintenance position B, and moves to move from the maintenance position B to the image forming position A. During the movement of at least one of the times, the nozzle surface 57 is wiped by the nozzle wiping sheet 120.

  Here, as shown in FIG. 3, the nozzle wiping sheet 120 delivered from the delivery-side web core 102 is pressed against the nozzle surface 57K of the inkjet head 56K by the pressing roller 110, and the liquid such as ink adhered to the nozzle surface 57K. Wipe off the drops. The nozzle wiping sheet 120 from which the liquid droplets have been wiped reaches the take-up web core 104 and is taken up. Thereby, the nozzle surface 57K can be wiped with the nozzle wiping sheet 120 efficiently. Further, since the cleaning liquid 108 is applied by the cleaning liquid applying mechanism 93, the nozzle surface 57K can be wiped off effectively.

  By the way, when the nozzle surface 57 is wiped with a conventional nozzle wiping sheet, bubbles (air) may be involved in the nozzles, thereby causing streaks in the printed image immediately after maintenance. Here, if printing is performed after maintenance has been performed, the generation of streaks can be suppressed, but the productivity (number of processed sheets) may be reduced.

In the present embodiment, the nozzle wiping sheet 120 having a water absorption time t of 2.0 seconds or more and an optical density D measured in a state where the nozzle wiping sheet 120 is placed on a black plate is 0.110 or more is used. It is possible to suppress bubbles from being caught in the nozzles of the inkjet head 56. As a result, the occurrence of streaks during printing immediately after maintenance can be suppressed. That is, when the water absorption time is 2.0 seconds or more, when the nozzle wiping sheet 120 comes into contact with the nozzle surface 57, it is possible to absorb liquid droplets such as ink at an appropriate speed.

  In addition, since the nozzle wiping sheet 120 having an optical density measured by the above-described measuring method of 0.110 or more has a structure that allows air to easily pass through, the nozzle wiping sheet 120, the nozzle surface 57, Even if air enters between the two, the nozzle wiping sheet 120 can be permeated to let the air escape to the outside. Thereby, it can suppress that a bubble is caught in a nozzle.

  The above effect was confirmed by conducting the following experiment. First, the nozzle surface 57 was wiped with a nozzle wiping sheet, and correction based on the nozzle check pattern and the auto calibration pattern was performed. Thereafter, 10 solid color charts were printed. The paper size at this time was 750 mm × 532 mm. Next, the printed image was visually confirmed to check for streaks. Here, only the streak caused by bubbles entrained in the nozzle was checked. Specifically, the presence or absence of a streak that occurred in the middle of the image and whose location was not fixed was confirmed. This is because the streaks that occur in the entire area of the image or the streaks that occur only at a specific nozzle are likely to be other causes such as non-ejection due to drying.

  The graph shown in FIG. 4 shows the relationship between the presence or absence of streaks, the water absorption time of the used nozzle wiping sheet, and the optical density. From the graph of FIG. 4, in the nozzle wiping sheet in which the water absorption time t is 2.0 seconds or more and the optical density D is 0.110 or more, this is because air bubbles are caught in the nozzles from the printed image. No streak was observed.

  Here, as one of the causes of the streaks generated in the nozzle wiping sheet whose water absorption time t is shorter than 2.0 seconds, droplets such as ink are quickly absorbed into the nozzle wiping sheet, and air easily enters the nozzle. It is thought that it became. Further, even when the water absorption time t is 2.0 seconds or more, in the case of a nozzle wiping sheet having an optical density D of less than 0.110, the air that has entered between the nozzle wiping sheet and the nozzle surface cannot be released. In addition, it is considered that air enters the nozzle and streaks are generated.

  As described above, if the water absorption time t is 2.0 seconds or more and the optical density D is 0.110 or more from the experimental results shown in FIG. It was confirmed that streaks could be suppressed.

  In addition, since the image forming apparatus 10 of the present embodiment is configured not to perform multiple writing, the printing speed is higher than that of an image forming apparatus that performs so-called multiple writing in which ink is ejected to the same position on the recording medium P. Can be improved. Further, by adopting the single pass method as in the present embodiment, it is possible to improve the printing speed as compared with the so-called shuttle scan type image forming apparatus that performs printing while repeatedly moving the inkjet head.

(Other examples)
As mentioned above, although this invention was demonstrated using the said embodiment, this invention is not limited to the said embodiment, In the range which does not deviate from a summary, it can change variously. For example, the conveyance drum of the image forming apparatus 10 according to the present embodiment is configured to convey two recording media P by one rotation (double cylinder), but is not limited thereto, and is not limited thereto. Is not particularly limited. For example, the structure (3 times cylinder) which conveys 3 sheets may be sufficient. Moreover, it is good also as a structure which conveys only 1 sheet by 1 rotation.

  In the present embodiment, the configuration using an inkjet head that ejects ink as droplets has been described. However, the present invention is not limited to this, and a nozzle is used as a wiping member that wipes an ejection head that includes nozzles that eject other droplets. A wiping sheet 120 may be used.

10 Image forming apparatus 56K, 56Y, 56M, 56C Inkjet head (ejection head)
57K, 57Y, 57M, 57C Nozzle surface 86K, 86Y, 86M, 86C Nozzle wiping unit 93 Cleaning liquid application mechanism (cleaning liquid application part)
102 Sending side web core (sending part)
104 Winding side web core (winding part)
110 Pressing roller (pressing part)
108 Cleaning liquid 120 Nozzle wiping sheet (wiping member)
A Image forming position B Maintenance position P Recording medium

Claims (8)

A wiping member for wiping the nozzle surface of an ejection head provided with a nozzle for ejecting water-based ink droplets,
The optical density measured with the wiping member placed on a black plate, where t is the water absorption time, which is the time until 0.05 ml of pure water dripped onto the wiping member is absorbed by the wiping member. A wiping member that satisfies the following conditions when D is satisfied.
t ≧ 2.0 seconds D ≧ 0.110   The wiping member according to claim 1, wherein the water absorption time t is 9.0 seconds or less.   The wiping member according to claim 1 or 2, wherein the optical density D is 0.126 or less. The wiping member according to any one of claims 1 to 3,
A delivery unit that continuously delivers the wiping member;
A winding unit for winding the wiping member that has been sent out;
A pressing portion provided between the delivery portion and the winding portion and pressing the wiping member against the nozzle surface of the discharge head;
Nozzle wiping unit.   The nozzle wiping unit according to claim 4, wherein a cleaning liquid applying unit that applies a cleaning liquid to the wiping member is provided. An ejection head having a nozzle for ejecting water-based ink droplets onto a recording medium;
An ejection head moving mechanism for moving the ejection head between an image forming position and a maintenance position;
The nozzle wiping unit according to claim 4 or 5, wherein the nozzle wiping unit is provided between the image forming position and the maintenance position and is disposed to face the ejection head.
Have
The nozzle surface of the discharge head during at least one of the movement when the discharge head moves from the image forming position to the maintenance position and the movement of the discharge head from the maintenance position to the image forming position An image forming apparatus for wiping with a wiping member. The image forming apparatus according to claim 6, wherein the ejection head is configured to eject a plurality of water-based ink droplets to different positions on a recording medium.   The image forming apparatus according to claim 6, wherein the ejection head extends across the entire width of the recording medium, and forms an image of one line by one scan.