JP2006130926A - Image forming device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a compact image forming device having a high operability which can stably and efficiently carry a sheet by a simple constitution. <P>SOLUTION: This image forming device is equipped with a recording station 2 including a platen unit 5 and a carriage unit 4. In this case, the platen unit 5 carries the sheet from a sheet roll 101, which is freely rotatably held at a sheet feeding station 1, downward by a platen roller 501, and sucks the sheet by a suction means 504 to a flat platen board 502. The carriage unit 4 records an image on the sheet sliding on the platen board which is pushed out by the platen roller while being sucked to the platen board by an image recording means 401. The recording station is arranged under the feeding station in such a manner that the platen unit or the carriage unit during an image recording may be overlapped in the vertical direction with at least a part of the sheet roll in the feeding station. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an image forming apparatus that is applied to, for example, a printer, a plotter, and the like and can continuously record a desired image on sheets of various sizes.

  Conventionally, the following two methods are known as methods for forming images on sheets of various sizes (for example, sheets of A series size such as A4, A3, A2, A1, A0, etc.).

  The first method is a method in which only a sheet roll corresponding to an A0 plate width (a sheet wound in a roll shape) is set in the image forming apparatus and cut into a desired size after the image formation. The second method is a method in which a plurality of sheet rolls having a width corresponding to each size are set in an image forming apparatus, and each sheet is cut to a desired length after image formation.

  The present invention is configured by improving the second method. In such a method, when a desired image is formed on sheets of various sizes ranging from A4 to A0, three types of sheets having different widths are provided. A roll is required. Specifically, in these sheet rolls, a sheet roll having a width of 297 mm corresponds to the A4 and A3 sizes, a sheet roll having a width of 594 mm corresponds to the A2 size, and a sheet roll having a width of 841 mm corresponds to the A1 and A0 sizes. To do. In these sheet rolls, for example, if the length per roll is 150 m, the A0 size sheet roll generally has a weight of about 10 kg.

  The conventional image forming apparatus is provided with a three-stage pull-out tray on the lower part of the apparatus or on the operation side so that these three sheet rolls can be mounted. And a roller for pulling out a desired sheet from each sheet roll held in the section.

  In such a conventional image forming apparatus, a desired sheet pulled out by each roller is configured to be conveyed to a recording unit by a predetermined conveying unit after passing through a sheet path. The leading end of the sheet conveyed by the conveying means on the downstream side of the unit is pressed to hold the positional relationship of the sheet with respect to the recording unit of the recording unit in an appropriate state. In the recording unit, the platen roller may be a sheet supporting portion, or a guide functioning as a recording surface may be provided between the platen roller and the downstream conveying unit.

  Further, the carriage disposed in the conventional image forming apparatus is provided with a sheet detection unit and a recording unit, and the sheet detection unit is disposed at a position aligned with the recording unit in the carriage moving direction. The position of the carriage is configured to be detected by a standby position detection unit and a movement position detection unit including a linear encoder.

  According to such a conventional image forming apparatus, it is determined whether or not the sheet is skewed by detecting a plurality of side end positions of the sheet by the sheet detecting unit while slightly reciprocating the sheet. . At this time, if the sheet is not skewed, image recording is subsequently performed. Then, after the image recording is completed, the sheet is cut by the cutting means arranged on the downstream side in the sheet conveying direction, and the next image recording operation is started after the sheet is returned again. The cut sheets are dropped into a sheet storage stocker or are sorted and stored in a sorter for each sheet size.

  However, in the conventional image forming apparatus, a large space is required to provide a three-stage drawer tray on the operation side, and most of the area on the operation side is occupied by these drawer trays. There are also defects. As a result, since the discharge side of the image-recorded sheet must be provided on the non-operation side opposite to the operation side, there arises a problem that operation from one direction (operation side) of the apparatus becomes difficult.

  Further, in the conventional image forming apparatus, when a sheet jam occurs, it is necessary to pull out the corresponding pull-out tray, and it takes time and troubles such that the sheet is torn off halfway when pulling out the pull-out tray. Even if the corresponding pull-out tray can be pulled out, in order to release the portion where the sheet is nipped, it is necessary to turn to the non-operation side of the apparatus and open the sheet jamming processing door, which is complicated.

  In order to eliminate such a problem, it is conceivable to provide a cutting means for each pull-out tray, but there is also a problem that the apparatus is increased in size and cost. Furthermore, when all the pull-out trays are pulled out, the stability of the apparatus also deteriorates.

  As a countermeasure for these, it is conceivable that the apparatus is configured such that the pull-out trays cannot be pulled out at the same time, but this deteriorates the operability of the apparatus.

  In addition, in the conventional image forming apparatus, since a heavy sheet roll is set on a pull-out tray at the lower part of the apparatus, the mounting posture is impossible, and the user is burdened when setting the sheet roll. Yes. Furthermore, since the sheet transport distance to the recording unit is increased by providing the pull-out tray, it takes a long time to reach the recording unit, and errors in the sheet position when passing through the recording unit are remarkable. There is also a problem of appearing in

  SUMMARY An advantage of some aspects of the invention is to provide a compact image forming apparatus having high operability and capable of stably and efficiently transporting a sheet with a simple configuration. There is to do.

In order to achieve such an object, an image forming apparatus according to the present invention includes a sheet roll in an image forming apparatus in which a sheet roll on which a sheet on which an image is recorded is wound is held by a sheet roll holding unit. A sheet feeding station having at least one sheet roll holding unit that holds the sheet roll rotatably, a platen roller that conveys a sheet from the sheet roll downward, and a sheet conveyed downward is adsorbed to a flat platen board. A carriage unit having at least an image recording unit that performs image recording on a sheet that slides on the platen board so as to be pushed out by a platen roller during suction on the platen board. A recording station comprising: a recording station comprising: The platen unit in the recording station or the carriage unit during image recording is arranged so as to vertically overlap at least a part of the sheet roll in the sheet feeding station. ,
It is characterized by that.

  According to an image forming apparatus according to the present invention, in an image forming apparatus that holds a sheet roll on which a sheet on which an image is recorded is wound in a roll shape, by the sheet roll holding unit: the sheet roll that holds the sheet roll rotatably A sheet feeding station having at least one holding unit; a platen roller having a platen roller that conveys a sheet from a sheet roll downward, and an adsorption unit that adsorbs the sheet conveyed downward to a flat platen board A recording station having at least a carriage unit having image recording means for recording an image on a sheet sliding on the platen board so as to be pushed out by a platen roller during suction onto the platen board. The recording station is under the sheet feeding station And the platen unit in the recording station or the carriage unit during image recording is arranged so as to overlap with at least a part of the sheet roll in the sheet feeding station in the vertical direction. Thus, it is possible to provide a compact image forming apparatus having high operability capable of stably and efficiently transporting a sheet with a simple configuration.

  Hereinafter, an image forming apparatus according to an embodiment of the present invention will be described with reference to the accompanying drawings. The image forming apparatus according to the present exemplary embodiment is configured to be able to record a desired image on a sheet having a predetermined size. As the sheet, for example, recording paper, paper, plastic film, cloth, or the like can be applied.

  In the following description of the embodiments, an image forming apparatus to which a sheet is applied as an image recording sheet will be described as an example.

  As shown in FIG. 1, the image forming apparatus according to the present exemplary embodiment has a plurality of roll papers in which paper of a predetermined size is wound in a roll shape (in FIG. 1, only two roll papers denoted by reference numerals 101 and 102 are shown. However, in this embodiment, as shown in FIG. 2, the first to third roll papers 101, 102, and 103 correspond to each other) and the paper feeding station 1 feeds the paper. A recording station 2 that records a desired image on a sheet (101, 102, or 103), and a processing station 3 that discharges the sheet on which the image has been recorded by the recording station 2.

  In the present embodiment, the first roll paper 101 is configured by winding a sheet 101 having a width of 841 mm, for example, and the second roll paper 102 is configured by rolling a sheet 102 having a width of 594 mm, for example. It is assumed that the third roll paper 103 is configured by winding a sheet 103 having a width of 297 mm in a roll shape, for example.

  The recording station 2 includes a platen unit 5 provided so as to extend in a direction perpendicular to the paper transport direction T, and a carriage unit 4 that records a desired image on the paper while moving along the platen unit 5. Has been placed.

  As shown in FIG. 5, a platen roller 501 is disposed in the platen unit 5 of the recording station 2 in a direction perpendicular to the paper transport direction T. The platen roller 501 is a first aluminum-made plate disposed oppositely. The second frames 201 and 202 are rotatably supported.

  The first and second frames 201 and 202 are respectively provided with positioning notches on the upstream side and the downstream side in the paper transport direction T. These positioning notches are formed by, for example, milling or wire cutting means. The ends of the upstream stay 505 and the downstream stay 506 made of aluminum with high straightness are positioned and fixed.

  A plurality of aluminum platen boards 502 arranged in a direction orthogonal to the paper transport direction T are fixed to the end surfaces on the operation surface side Z of the upstream and downstream stays 505 and 506. Each of these platen boards 502 is formed with a plurality of windows 502a for the platen roller 501 and air suction holes 502b (about 2 mm in diameter). Note that the plurality of platen boards 502 are attached to the upstream and downstream stays 505 and 506 so as to achieve and maintain a high degree of flatness along the paper transport direction T.

  By using a plurality of platen boards 502 in this way, it is possible to obtain a highly accurate flatness as compared with the case of using one large platen board 502, and there is also a problem of “warping”. The design can be made difficult to occur.

  The platen roller 501 applied to the present embodiment is a stepped roller, and when a plurality of platen boards 502 are fixed to the end surfaces on the operation surface side Z of the upstream and downstream stays 505 and 506, the maximum outer peripheral portion thereof. Is exposed from the window 502a of the platen board 502. In this case, the maximum diameter surface of the platen roller 501 depends on the component accuracy of the first and second frames 201 and 202, the upstream and downstream stays 505 and 506, the platen roller 501, and the platen board 502. The platen board 502 is positioned on substantially the same plane as the surface on the operation surface side Z (that is, the surface facing the carriage unit 4).

  Further, a lid 503 is attached to the upstream and downstream stays 505 and 506 so as to face the plurality of platen boards 502, and the inner surface (that is, the plurality of platen boards 502 is attached to the lid 503). A plurality of suction means 504 are provided on the facing surfaces.

  According to such a platen unit 5, a plurality of platen boards 502, first and second frames 201 and 202, upstream and downstream stays 505 and 506, and a lid 503 constitute a suction chamber. .

  As shown in FIG. 1, a paper feed station 1 is provided above the recording station 2. The paper feed station 1 includes first to third roll papers 101 and 102 as shown in FIG. , 103 can be mounted.

  Specifically, as shown in FIGS. 1, 2, and 4, the first roll paper 101 is arranged at a predetermined interval between the first and second frames 201 and 202 (see FIG. 4). A stainless steel first feed roller 104 and a first support roller 110 are rotatably supported.

  The first paper feed roller 104 includes a paper feed roller shaft 104a protruding from both ends thereof, and these paper feed roller shafts 104a can freely rotate to the first and second frames 201 and 202 via bearings 104b. It is supported by. Further, sleeves 113 and 114 are rotatably fitted to these paper feed roller shafts 104a, and the fitted portions have a low coefficient of friction.

  The first support roller 110 (see FIG. 2) is rotatably supported by the first and second frames 201 and 202 via shafts (not shown) protruding from both ends thereof. A sleeve (not shown) is fitted rotatably. Flange 101a, 101b is detachably attached to both sides of the first roll paper 101, and the sleeves 113, 114 of the first paper feed roller 104 and the first support roller are attached to the flanges 101a, 101b. The first roll paper 101 is rotatably supported on the first paper feed roller 104 and the first support roller 110 by being placed on the sleeve 110.

  In this case, the sleeve 113 of the first paper feed roller 104 is configured to rotatably hold the flange 101a of the first roll paper 101 and to position the first roll paper 101 in the width direction. . The other sleeve 114 is configured to rotatably hold the flange 101b, and both sleeves of the first support roller 110 are configured to rotatably hold the flanges 101a and 101b. Further, in order to smoothly convey the paper, the outer peripheral diameter of each sleeve is smaller than the outer peripheral diameter of the central portion of the first paper feed roller 104.

  In addition, a pinch roller 107 for nipping the paper 101 is pressed against the central portion of the first paper feed roller 104 so as to be able to contact and separate. The surface friction coefficient is increased. As this processing method, for example, a method of press-fitting rubber or a method of coating alumina powder is conceivable. However, in the case of guiding and conveying a wide-size sheet 101 as in this embodiment, A roller that is difficult to bend is required. The method of press-fitting rubber is preferably a method of coating alumina powder with a coating thickness of about 150 μm or less because the roller diameter is reduced by the thickness of the rubber and the strength is lowered.

  A driving belt 116 for transmitting a driving force from a motor 117 provided outside the first frame 201 is hung on the paper feeding roller shaft 104a of the first paper feeding roller 104, and the clutch 115 is engaged. The first sheet feeding roller 104 is configured to be rotatable in a predetermined direction. The motor 117 is configured to rotate the platen roller 501 forward and backward via a worm mechanism. In this case, the driving force from the motor 117 is not transmitted to the first support roller 110, and is configured to rotate as the flanges 101 a and 101 b of the first roll paper 101 rotate. ing.

  As shown in FIG. 2, the second and third roll papers 102 and 103 are configured to be mounted in parallel with the first roll paper 101, and specifically, the second roll paper 102. Is supported rotatably on the second paper feed roller 105 and the second support roller 112 (see FIG. 1), and the third roll paper 103 is composed of the third paper feed roller 106 and the third support roller. 111 is rotatably supported. Further, the second and third roll papers 102 and 103 are subjected to a process in which the pinch rollers 108 and 109 are pressed against the center of the second and third roll papers 102 and 103 so that at least the friction coefficient thereof is increased. The configurations of the second and third paper feed rollers 105 and 106 and the second and third support rollers 112 and 111 are the same as those of the first paper feed roller 104 and the first support roller 110. The drawings and description are omitted.

  As shown in FIG. 4, the driving force transmitted from the motor 117 to the driving belt 116 via the worm mechanism is selectively applied to the second and third paper feeding rollers 105 and 106 via the clutch 115. It is comprised so that it may be transmitted. As a result, the first to third paper feed rollers 104, 105, and 106 can be independently rotated by selective driving of the clutch 115.

  The arrow Z shown in FIGS. 1 and 2 indicates the operation surface side, and the first to third paper feed rollers 104, 105, 106 applied to the present embodiment have the longest width. The heavy first roll paper 101 is disposed close to the operation surface side Z, and the second and third roll papers 102 and 103 are parallel to the first roll paper 101 on the back side and do not overlap each other in the width direction. Is arranged. In this case, the first roll paper 101 and the second and third roll papers 102 and 103 are mounted so as to overlap each other in the width direction.

  3A and 3B show variations when the arrangement state of the first to third roll papers 101, 102, and 103 applied to this embodiment is viewed from above the apparatus. In this way, by arranging the second and third roll papers 102 and 103 having a small size width in parallel with the first roll paper 102 having the maximum width at positions where they do not overlap each other in the width direction, a plurality of papers can be obtained in a small space. It becomes possible to arrange the roll paper at the same time. FIG. 3C shows a variation in the case where a fourth roll paper 103 ′ is further arranged in addition to the first to third roll papers 101, 102, 103.

  Next, a configuration for guiding and conveying the sheets 101, 102, 103 from the first to third roll sheets 101, 102, 103 to the recording station 2 will be described with reference to FIGS.

  As shown in FIGS. 13 and 14, the pinch rollers 107, 108, and 109 that are pressed by the first to third paper feed rollers 104, 105, and 106 are respectively supported in a swingable manner. The three guide guides 118, 119, and 120 are rotatably held in brackets 118a, 119a, and 120a attached to the swinging tip portions.

  The first to third guide guides 118, 119, and 120 are supported so as to be swingable in directions orthogonal to the axial directions of the first to third paper feed rollers 104, 105, and 106, respectively. The biasing springs 118b, 119b, and 120b disposed in the vicinity of 118a, 119a, and 120a are always biased toward the first to third paper feeding rollers 104, 105, and 106 against their own weight. . As a result, the pinch rollers 107, 108, and 109 are pressed against the outer peripheral surfaces of the first to third paper feed rollers 104, 105, and 106, respectively.

  In a state where the respective pinch rollers 107, 108, 109 are in close contact with the outer peripheral surfaces of the first to third paper feed rollers 104, 105, 106, the first guide guide 118 has the first and second guides 118. A first transport path is configured to face the first fixed guide 122 fixed to the frames 201 and 202 (see FIG. 4). The second guide guide 119 is opposed to the second fixed guide 121 fixed to the first and second frames 201 and 202 to form a second transport path. The third guide guide 120 (see FIG. 14) is opposed to the second fixed guide 121 and constitutes a third path.

  These first to third transport paths are configured to join each other at the position of the guide bar 208 held by the first and second frames 201 and 202.

  A plurality of pinch holders 209 configured to be rotatable by a predetermined angle are held on the guide bar 208 at predetermined intervals, and drive pinch rollers 507 (see FIG. 14) are respectively provided at the tip portions of the pinch holders 209. Is supported rotatably. Specifically, as shown in FIGS. 16 to 18, each pinch holder 209 is fastened to the guide bar 208 via a metal fitting 213. One end of each metal fitting 213 is engaged with a hole 209a (see FIGS. 17 and 18) of each pinch holder 209 formed on the opposite side to each paper conveyance path, and a central portion thereof is a screw 701 (FIG. 16 and FIG. 18). Each of such metal fittings 213 biases and supports the spring 214 accommodated in the hole 209a of each pinch holder 209 by one end thereof, and restricts the rotation range of each pinch holder 209 by the other end. It is configured as follows. Since each pinch holder 209 is restricted from moving in the axial direction by the metal fitting 213, the pinch holder 209 does not move in the axial direction of the guide bar 208.

  The guide bar 208 to which such a pinch holder 209 is attached is connected to the lever 212 via a link mechanism 211 provided outside the first frame 201. For this reason, as shown in FIGS. 17 and 18, the drive pinch roller 507 of each pinch holder 209 can be brought into and out of contact with the platen roller 501 by rotating the lever 212 in the direction of the arrow in the drawing. Specifically, when the lever 212 is rotated from the state indicated by the two-dot chain line in FIG. 17 to the state indicated by the solid line, the guide bar 208 is slightly rotated via the link mechanism 211. By rotating each metal fitting 213 in accordance with the rotation of the guide bar 208, the urging force of the spring 214 acts on each pinch holder 209. At this time, the urging force of the spring 214 is applied and each pinch holder 209 is urged in the direction of the platen roller 501, whereby the drive pinch roller 507 provided in each pinch holder 209 is pressed against the platen roller 501. become. When the lever 212 is rotated in the reverse direction, the pinch holder 209 moves in a direction away from the platen roller 501, so that each drive pinch roller 507 is separated from the platen roller 501.

  As shown in FIG. 16, a sleeve 210 is rotatably fitted between the plurality of pinch holders 209 on the guide bar 208. The outer peripheral surfaces of these sleeves 210 are defined at substantially the same position as the partial arc-shaped portion 209b (see FIGS. 17 and 18) of the outer peripheral surface of each pinch holder 209 on the paper conveyance path side, and the other portions are The sleeves 210 are formed so that the outer peripheral surfaces of the sleeves 210 slightly protrude from the outer peripheral surfaces of the pinch holders 209 so that the sheets 101, 102, and 103 positively come into contact with the respective sleeves 210.

  According to such a configuration, each pinch holder 209 functions as a sheet guide unit that guides the sheets 101, 102, and 103 conveyed through the first to third conveyance paths by bending them at the arc-shaped portion 209b. And also has a function as contact / separation means for bringing each drive pinch roller 507 into and out of contact with the platen roller 501. As a result, the path length from the first to third paper feed rollers 104, 105, 106 to the platen roller 501 can be shortened to the shortest.

  In the present embodiment, the first to third paper feed rollers 104, 105, 106 are closer to the operation surface than the conveyance path merging position (that is, the platen board 502) in the vicinity of the arcuate portion 209 b of each pinch holder 209. The first to third roll papers 101, 102, and 103 are disposed on the operation surface side Z as a whole. In particular, the first roll paper 101 is set on the movement space of the carriage unit 4. As a result, it is possible to secure a large space for accommodating the carriage unit 4 of the recording station 2 without changing the overall size of the apparatus, that is, the floor occupation area of the apparatus. Further, since the arrangement positions of the first to third roll papers 101, 102, 103 are set to the operation surface side Z as a whole, the setting operation of the first to third roll papers 101, 102, 103 is facilitated. Therefore, the operability can be improved.

  Further, as shown in FIG. 14, the sheets 101, 102, 103 conveyed through the first to third conveyance paths are bent at the arc-shaped portion 209b and smoothly guided to the conveyance path joining position. Is provided with a thin member 207.

  This thin member 207 is mainly used to bend the leading edge of the paper 101 conveyed from the first conveying path in the direction opposite to the curl direction, and is made of a stainless steel plate having a thickness of about 0.5 mm. It has a fulcrum nearer to the surface side Z and is configured to contact the pinch holder 209 or the sleeve 210 with its own weight. Note that the tip portion on the side opposite to the fulcrum has a shape that is partially bent toward the sleeve 210 and extends to a position close to the conveyance path merging point.

  As described above, according to the configuration for guiding and conveying the sheets 101, 102, 103 from the first to third roll sheets 101, 102, 103 to the recording station 2, the first guide guide 118 is attached with the biasing spring 118b. After pressing down against the force, the leading edge of the first roll paper 101 is inserted between the first paper feed roller 104 and the pinch roller 107 to nip. At this time, the rotational driving force of the platen roller 501 that is rotationally driven by the motor 117 is transmitted to the first paper feed roller 104 via the drive belt 116 and the clutch 115 to cause the first paper feed roller 104 to rotate forward. . As a result, the sheet 101 is conveyed along the first conveyance path formed by the first guide guide 118 and the first fixed guide 122.

  Thereafter, the leading end portion of the sheet 101 conveyed to the conveyance path joining position in the vicinity of the pinch holder 209 is guided while being pressed by the thin member 207 on the sleeve 210 with its own weight. Since the thin member 207 has an appropriate weight, the sheet 101 proceeds along the thin member 207 without buckling and without pushing up the thin member 207. Furthermore, since the sleeve 210 is rotatable with respect to the guide bar 208, the paper 101 is smoothly conveyed on the sleeve 210.

  Subsequently, the leading end portion of the sheet 101 is bent between the second fixed guide 121 and the sleeve 210 and guided between the platen board 502 and the pinch holder 209, and then the platen roller 501 and the drive pinch. It is nipped with a roller 507 and conveyed to an image recording area described later.

  Similarly, the front end of the second roll paper 102 is also pushed down against the urging force of the urging spring 119b by pushing the second guide guide 119 between the second paper feed roller 105 and the pinch roller 108. Can be nipped. At this time, the sheet 102 is formed by the second guide guide 119 and the second fixed guide 121 by transmitting the rotational driving force of the platen roller 501 to the second paper feed roller 105 via the clutch 115. The second transport path is transported. The leading end portion of the sheet 102 is bent between the second fixed guide 121 and the sleeve 210 and guided between the platen board 502 and the pinch holder 209, and then the platen roller 501 and the drive pinch roller 507. Are conveyed to an image recording area described later.

  Further, as shown in FIG. 14, the leading edge of the third roll paper 103 also pushes down the third guide guide 120 against the urging force of the urging spring 120b to pinch the third paper feeding roller 106 and the third paper feeding roller 106. A nip can be formed between the rollers 109. At this time, the sheet 103 is formed by the third guide guide 120 and the second fixed guide 121 by transmitting the rotational driving force of the platen roller 501 to the third paper feed roller 106 via the clutch 115. The third transport path is transported. The leading end portion of the sheet 103 is bent between the second fixed guide 121 and the sleeve 210 and guided between the platen board 502 and the pinch holder 209, and then the platen roller 501 and the drive pinch roller 507. Are conveyed to an image recording area described later.

  As shown in FIG. 13, in the image recording area provided in the recording station 2, the suction chamber of the platen unit 5 is pulled to a negative pressure by the suction means 504 (see FIG. 5). For this reason, air is sucked into the chamber from a large number of holes 502b (see FIG. 5) formed in the platen board 502.

  These many holes 502b are respectively formed from the window 502a (see FIG. 5) through which the platen roller 501 and the drive pinch roller 507 are nipped to the downstream side in the paper transport direction T (see FIG. 5).

  The sheets (101, 102, 103) pushed out by the platen roller 501 and the drive pinch roller 507 are maintained in a flat state while being attracted to the platen board 502, and slide so as to be pushed out on the platen board 502. go. The sheet sliding surface (surface on which the sheet slides) of the aluminum platen board 502 is anodized so that the friction coefficient is low.

  Further, the positional relationship between the curl direction of each of the sheets 101, 102, and 103 and the platen board 502 is such that the edge part of the leading end of the sheet is in contact with the platen board 502 and the center of the sheet generated in the Z direction on the operation surface side by the curl. The bulging portion is in a relationship of separating from the platen board 502.

  In the sheets 101, 102, and 103 conveyed in such a state, the air in the bulging portion at the center of the sheet is sucked by the suction unit 504, so that the sheets 101, 102, and 103 are in close contact with the platen board 502. .

  A large number of holes 502b in the platen board 502 can be formed in a range of about 1 to 4 mm in diameter. According to experiments, a diameter of about 2 mm is good with little deformation of the paper. The numerous holes 502b are densely formed in the vicinity of the side in the paper width direction and the most downstream side of the platen board 502 (in the vicinity of the cutter 205), and are roughly formed in other places.

  By forming a large number of holes 205b in this way, the effect of closely attaching the paper side portion that is likely to float to the platen board 502 is enhanced. In addition, when cutting with a cutter 205 described later, the effect of holding the sheets 101, 102, 103 on the upstream side of the cutter 205 so as not to move is enhanced.

  Further, as shown in FIG. 13, the cutter 205 is attached to a downstream stay 506 (see FIG. 5) constituting the suction chamber, and is fixed extending in the paper width direction (direction perpendicular to the paper conveyance direction). A blade 205a and a moving blade 205b that cuts the sheets 101, 102, and 103 by moving along the fixed blade 205a are provided.

  Disposed on the downstream side of the cutter 205 is a pair of paper discharge rollers 206 that are rotatably contacted with each other. The pair of paper discharge rollers 206 includes a drive roller 206a that is pressed against a non-recording surface of the paper, and a paper recording surface. And a driven roller 206b that is in pressure contact therewith. The driven roller 206b is disposed so as to come into pressure contact with the sheet recording surface before the ink is dried. Therefore, a needle-like protrusion (not shown) having a sharp tip is provided on the outer peripheral surface of the driven roller 206b so that the ink does not adhere to the outer peripheral surface of the driven roller 206b.

  According to such a configuration, when cutting the sheets 101, 102, and 103 with the cutter 205, the upstream side of the sheet with respect to the cut portion is sucked and held on the platen board 502 by the suction force of the suction chamber as described above. At the same time, the downstream side of the sheet is pinched by the pair of discharge rollers 206. As a result, it is possible to suppress misalignment of the paper during cutting. Furthermore, by attaching the cutter 205 directly to the suction chamber, the suction chamber and the cut portion can be brought close to each other. As a result, it becomes possible to perform a highly accurate cutting process on the cut portion of the sheet positioned and held on the suction chamber.

  As shown in FIG. 5, the suction chamber is partitioned at least at one place in the paper width direction by a separator 508 having a shape avoiding the platen roller 501. It should be noted that a suction action is exerted by the suction means 504 for each region partitioned by the separator 508. In this embodiment, a separator 508 is disposed at a boundary portion between the second roll paper 102 and the third roll paper 103, and two suction means 504 are provided in an area belonging to the second roll paper 102. And one suction means 504 is provided in an area belonging to the third roll paper 103.

  According to such a configuration, when transporting the first roll paper 101 having the maximum width, a total of three suction means 504 are caused to act simultaneously. On the other hand, when transporting the third roll paper 103 having the minimum width, only one suction means 504 arranged in the area delimited by the separator 508 is operated, while the second roll When transporting the paper 102, the remaining two suction means 504 are operated.

  By providing the separator 508 in this manner, it becomes possible to prevent the suction force of the suction chamber from becoming uneven due to the width of the paper to be conveyed, and it is possible to consume only the necessary power. Furthermore, by selectively operating only the necessary suction means 504 in this way, it is possible to suppress the generation of noise as low as possible.

  Next, the carriage unit 4 provided in the recording station 2 will be described with reference to FIGS.

  The carriage unit 4 is configured to be movable along the platen board 502 while facing the platen board 502 of the platen unit 5 (see FIG. 2). Therefore, openings 201a and 202a through which the carriage unit 4 can pass are formed in the first and second frames 201 and 202 to face each other (see FIG. 5).

  Two linear guides 203 and 204 extending in a direction perpendicular to the paper transport direction T are provided at positions adjacent to the openings 201 a and 202 a and close to the platen unit 5. Yes. These linear guides 203 and 204 extend in parallel with each other along the sheet transport direction T and in parallel with the platen board 502.

  Such linear guides 203 and 204 are fixed to the first and second frames 201 and 202 in a state in which both end portions protrude outward from the first and second frames 201 and 202.

  The carriage unit 4 is slidably held by these two linear guides 203 and 204 via bearings, and the carriage unit 4 is placed outside the first frame 201 during standby before operating the apparatus. It is comprised so that it may be located in the provided home position (refer FIG. 7).

  The carriage unit 4 is provided with an image recording unit 401 that ejects four colors of ink. In the image recording unit 401, four recording heads having a plurality of nozzles (not shown) capable of ejecting ink are arranged along the paper transport direction T. Specifically, the image recording unit 401 sequentially includes a recording head K that ejects black ink, a recording head C that ejects cyan ink, a recording head M that ejects magenta ink, and a yellow ink. The recording heads Y for jetting are arranged. These recording heads are arranged so that the respective inks do not overlap in the sliding direction of the carriage unit 4 (that is, the direction orthogonal to the paper transport direction T). Each recording head is positioned so as to be maintained at a constant distance (about 1 mm) from the platen board 502 while the carriage unit 4 is sliding. The recording head applied to this embodiment is an ink jet head, and the number of nozzles is, for example, 256 channels for each ink.

  The plurality of nozzles of such a recording head are formed such that the distance between the nozzles is, for example, 360 (DPI) along the paper transport direction T. In this case, the recording width of one color ink is about 18 mm. The recording heads applied to the present embodiment are arranged at a pitch that is 5/4 times that of the image recording unit 401. For this reason, the width of the image recording unit 401 is about 90 mm. As a result, the platen board 502 applied to the present embodiment is positioned in a planar manner so that the distance to each recording head is kept constant over at least the width of the image recording unit 401.

  The carriage unit 4 includes an ink cartridge 4a containing ink of each color and an ink tank 4b. The ink in the ink cartridge 4a is configured to be supplied to the recording head via the ink tank 4b. Yes.

  In the carriage unit 4, a sensor S 4 that detects the sheets 101, 102, and 103 is disposed to face the platen board 502.

  In particular, as shown in FIG. 7, the sensor S4 defines the positional relationship on the basis of the case where the carriage unit 4 is positioned at the home position. It is provided at the position closest to the paper.

  Here, a method for detecting the position of the carriage unit 4 will be described.

  As shown in FIG. 8, it is assumed that the carriage unit 4 is currently positioned at a home position (see FIG. 7) provided outside the first frame 201. At this time, by operating a drive mechanism (not shown), the carriage unit 4 reciprocates along the platen board 502 in the direction of the arrow while being guided by the linear guides 203 and 204.

  The carriage unit 4 is provided with a rear sensor 404 so as to be able to read a scale (not shown) of a linear scale 405 stretched over a width equal to or greater than a reciprocating section. Note that the scales are recorded on the linear scale 405 at intervals corresponding to the recording density of each recording head, for example.

  The pulse signal read by the linear sensor 404 is input to an encoder pulse counter 407 via a control circuit (CPU) 406, and the pulse output is counted. Furthermore, a home position sensor 408 connected to the control circuit 406 is provided at the above-described home position (see FIG. 7), and detects whether or not the carriage unit 4 is at the home position.

  Then, the control circuit 406 counts the pulse output of the encoder pulse counter 407 based on the output of the home position sensor 408, whereby the current position of the carriage unit 4 is detected.

  In this embodiment, the first to third roll papers 101, 102, 103 (see FIG. 2) are positioned in the paper width direction by corresponding sleeves 113 (see FIG. 4). Therefore, the position and width of the paper side edge for each roll paper correspond to the position of the scale of the linear scale 405. A memory (ROM) 409 connected to the control circuit 406 stores in advance the position and width of each sheet side with respect to the home position for each roll sheet based on the counter value of the encoder pulse counter 407. ing. Each of the sheets 101, 102, and 103 changes in size with changes in environmental temperature and humidity, but the data stored in the memory 409 is a counter value based on the nominal size.

  Next, a method for measuring the leading edge position of each sheet by the sensor S4 of the carriage unit 4 will be described with reference to FIGS. In FIG. 9, the X axis indicates the moving direction of the carriage unit 4, and the Y axis in FIG. 9 indicates the reciprocating direction of each sheet as the platen roller 501 rotates.

  FIG. 9 shows a state in which the sensor S4 is moving relative to each of the sheets 101, 102, and 103. In the following description, as an example, measurement of the leading end position of the sheet 101 is performed. A method will be described. Since the same measurement method can be applied to the other sheets 102 and 103, the description thereof is omitted.

  When the platen roller 501 is rotated by the motor 117, a pulse synchronized with the rotation of the motor 117 is output from the encoder 117a. The pulse output from the encoder 117 a is input to the motor pulse counter 410 via the control circuit 406. At this time, the pulse output is counted by the motor pulse counter 410 and the leading edge position of the paper 101 is detected.

  In FIG. 9, the method for detecting the leading end position of the sheet on the downstream side of the platen roller 501 has been described. However, the approximate position of the leading end of the sheet corresponds to each sheet 101, 102, 103 on the upstream side of the platen roller 501. It can be detected by the provided sensors S1, S2 and S3. Further, the control circuit (CPU) 406, the encoder pulse counter 407, the memory (ROM) 409, and the motor pulse counter 410 described above are included in the control device 7 disposed behind the platen unit 5 of the recording station 2. The control device 7 is constantly cooled by the air sucked by the suction chamber during the operation of the device.

  Further, referring to FIG. 9, a method for measuring the posture of each sheet by detecting the side end position and the leading end position of each sheet 101, 102, 103 using the sensor S4 of the carriage unit 4 will be described. I will explain.

  First, the leading edge of each sheet is detected by the corresponding sensors S1, S2, S3, and the platen roller 501 is rotationally controlled based on the detected data, so that the leading edge of each sheet is located downstream of the sensor S4 and the image recording unit. Positioned upstream of 401.

  Next, the carriage unit 4 is moved from the home position along the X-axis direction. At this time, when the side end position A on the one end side of the sheet is detected by the sensor S4, the scale of the linear scale 405 (see FIG. 8) is read by the linear sensor 404 (see FIG. 8), thereby the side end position from the home position. Measure the distance to A. Then, the measured value by the linear sensor 404 is compared with the stored value in the memory 409 (see FIG. 8). In this case, if the comparison value is within the pre-stored allowable range, the measurement is continued as it is. On the other hand, if the comparison value exceeds the allowable range, the paper is regarded as skewed, and the paper position Error handling is performed.

  When continuing the measurement, the sensor S4 detects the leading edge position B on the one end side of the sheet while feeding the sheet in the upstream direction, and then based on the number of pulses from the motor pulse counter 410 (see FIG. 8). A distance BC from the position C where the sheet is stopped to the leading end position B is measured.

  Next, while reading the scale of the linear scale 405 (see FIG. 8) by the linear sensor 404 (see FIG. 8), the carriage unit 4 is moved to the position D near the other end of the sheet. Subsequently, the front end position E in the vicinity of the other end side is detected by the sensor S4 while the sheet is conveyed in the downstream direction, and then the front end from the vicinity position D based on the number of pulses from the motor pulse counter 410 (see FIG. 8). The distance DE to position E is measured.

  Then, by obtaining the difference between the measured distance DE and the distance BC, the inclination amount, that is, the posture of the leading end of the sheet is measured. If this inclination amount (difference between the distance DE and the distance BC) is larger than a pre-stored allowable range, the paper is considered to be skewed, the paper position error process is executed, and is within the allowable range. If so, continue the measurement.

  To continue the measurement, the carriage unit 4 is further moved toward the other end side of the sheet while reading the scale of the linear scale 405 (see FIG. 8) by the linear sensor 404 (see FIG. 8). At this time, when the side edge position F on the other end side of the sheet is detected by the sensor S4, the scale on the linear scale 405 (see FIG. 8) is read by the linear sensor 404 (see FIG. 8), thereby A distance AF from the end position A to the side end position F on the other end side of the sheet is measured.

  Then, the number of movement pulses of the carriage unit 4 between the distances AF is compared with the number of pulses corresponding to the sheet width stored in advance, and if this difference is within the allowable range, the measurement is terminated, and is outside the allowable range. If it does, paper size defect processing is executed.

  Since the moving range of the image recording unit 401 during the measurement of the sheet posture is restricted to the area indicated by the diagonally downward slanting line in FIG. 9, the sheet and the image recording unit 401 do not overlap each other. Therefore, even when the paper is skewed and wrinkled, it is possible to avoid contact between the image recording unit 401 and the paper, so that each recording head provided in the image recording unit 401 is not damaged. Even when a wide sheet is conveyed, the skew can be detected accurately in a short time by moving the sheet slightly. In addition, since the paper is reciprocated slightly just downstream of the platen roller 501, even if the paper enters the platen roller 501 and is skewed, the paper is not damaged. Note that the above-described sheet orientation measurement is set to be performed at the time of automatic conveyance immediately after each roll paper is set in the apparatus, before the image recording operation, or at the end of the image recording operation.

  Next, the operation of setting the first to third roll papers 101, 102, 103 used in this embodiment in the image forming apparatus will be described.

  In the image forming apparatus of the present embodiment, as shown in FIGS. 1 and 2, the widest and heaviest first roll paper 101 can be set on the operation surface side Z (position side closest to the operator). The second and third roll papers 102 and 103, which are relatively light, can be set in parallel behind the first roll paper 101. According to such a configuration, since the heaviest first roll paper 101 can be set on the operation surface side Z, the operator can easily and easily perform the setting operation of each roll paper. There is an advantage.

  As shown in FIG. 15, when setting the first to third roll papers 101, 102, 103, first, after opening the top cover 801 covering the paper feed station 1, the first roll paper The flanges 101a and 101b attached to both ends of the 101 are placed on the sleeves 113 and 114 of the first paper feed roller 104 (see FIG. 4). Similarly, the corresponding flanges of the second and third roll papers 102 and 103 are placed on the sleeves of the second and third paper feed rollers 105 and 106 (see FIG. 2). As a result, the first roll paper 101 is rotatably supported on the first paper feed roller 104 and the first support roller 110, and the second and third roll papers 102 and 103 are similarly turned on. The second and third paper feed rollers 105 and 106 and the second and third support rollers 112 and 111 are rotatably supported (see FIGS. 1 and 2).

  Next, after pulling out the leading end portion of the first roll paper 101, the first guide guide 118 is once pushed down against the urging force of the urging spring 118b, and the paper 101 pulled out from the first roll paper 101 is drawn. Is inserted between the first paper feed roller 104 and the pinch roller 107 and nipped. Similarly, for the second and third roll papers 102 and 103, as shown in FIGS. 13 and 14, after the leading end portion is pulled out, the second and third guide guides 119 and 120 are urged by the urging spring 119b. , 120b is pushed down against the urging force of 120b, and the leading ends of the papers 102.103 drawn from the second and third roll papers 102, 103 correspond to the second and third paper feed rollers 105, 106, respectively. Between the pinch rollers 108 and 109 to be nipped. When the top cover 801 is closed after setting the first to third roll papers 101, 102, 103 in this way, the movement of the first to third guide guides 118, 119, 120 is detected by a detection sensor (not shown). Is detected, and it is determined that the first to third roll papers 101, 102, and 103 are set.

  The operation performed by the operator is until the top cover 801 is closed, and thereafter, it is detected that the top cover 801 is closed, and paper check is performed by the sensors S1, S2, and S3.

  If the corresponding sensors S1, S2, S3 do not detect the leading ends of the sheets 101, 102, 103, the first through third motors 117 and the clutch 115 (refer to FIG. 4) are selectively driven. The paper feed rollers 104, 105, and 106 are rotated in the forward direction, and the respective sheets are conveyed until the sensors S1, S2, and S3 detect the leading ends of the respective sheets. In this case, if each sensor S1, S2, S3 does not detect the leading edge of the paper even if a certain amount of paper is conveyed while counting the number of pulses by the motor pulse counter 410 (see FIG. 8), it is determined as a paper setting error. If the leading edge of each sheet has already been detected by each sensor S1, S2, S3 when each roll sheet is set, the first to third sheet feeding rollers 104, 105, 106 are once rotated in the reverse direction. Re-detect the leading edge of the paper.

  As described above, when the leading ends of the respective sheets are detected by the respective sensors S1, S2, and S3, the respective sheets are positioned at the standby positions by stopping the conveyance of the sheets 101, 102, and 103.

  Thereafter, by selectively sending out each sheet, an image forming process is performed on a sheet having a desired size. In the following description, only a processing operation on the sheet 101 will be described as an example. Since the same applies to the other sheets 102 and 103, the description thereof is omitted.

  After the sensor S1 detects the leading edge position of the paper 101, the first paper feed roller 104 is driven. At this time, after the leading end portion of the sheet 101 is guided from the sensor S1 to the guide bar 208, the traveling direction of the sheet 101 is reduced by the thin member 207 that rides on its own weight on a sleeve 210 that is rotatably provided on the guide bar 208. be changed. Thereafter, the sheet 101 guided by the pinch holder 209 and the platen board 502 is nipped by the platen roller 501 and the drive pinch roller 507 and conveyed toward the suction chamber. Since the suction chamber is decompressed by the suction means 504, the paper 101 slides in the paper transport direction T while being in close contact with the platen board 502.

  Subsequently, when the leading end portion of the sheet 101 passes through the cutter 205, the leading end portion of the sheet 101 is detected by the sensors S5 and S6 that are disposed at substantially the same position as the pair of discharge rollers 206 on the downstream side of the cutter 205. The

  Since the distance from the sensor S1 to the sensors S5 and S6 is preset, by counting the number of pulses output from the encoder 117a (see FIG. 8) of the motor 117 with the encoder pulse counter 407 (see FIG. 8), A paper conveyance error can be detected. Specifically, the number of pulses output from the encoder 117a from the sensor S1 to the sensors S5 and S6 is stored in advance in the memory (ROM) 409 of the control device 7 (see FIG. 8). Whether or not the sheet 101 has been conveyed by a predetermined amount by counting the number of pulses output from the encoder 117a during conveyance by the encoder pulse counter 407 and comparing the counted value with the number of pulses stored in advance. Can be detected.

  Thereafter, after the leading end of the sheet 101 passes through the sensors S5 and S6 and is conveyed by a predetermined amount, the conveyance of the sheet 101 is stopped. At this time, the cutter 205 is operated to cut off the leading edge of the paper. The leading edge of the cut paper is discharged through the paper discharge roller pair 206. As a result, the front end of the paper can be made a clean cut surface without scratches. The sheet 101 remaining after cutting is returned to the standby position described above by rotating the platen roller 501 in the reverse direction. Even during the returning operation, the leading end of the sheet is returned by the suction unit 504 while being attracted to the platen board 502.

  According to such a configuration, since the cutter 205 is disposed on the downstream side of the platen board 502, the paper powder at the time of cutting is free-falling and scattered in the direction of the image recording unit 401 (see FIG. 9). Absent. Further, since the paper dust adhering to the returned paper front end portion is also sucked by the suction means 504 (see FIG. 5) when passing through the suction chamber, the paper dust at the time of cutting is prevented from adhering to the paper 101. The

  The peripheral speed of each of the paper feed rollers 104, 105, 106 is set to be about 1% faster than the platen roller 501, and the peripheral speed of the paper discharge roller pair 206 is set to be 5% faster than the platen roller 501. . Accordingly, when the front end of the sheet is nipped between the platen roller 501 and the drive pinch roller 507 during conveyance in the sheet conveyance direction T, the conveyance operation by each sheet feeding roller is canceled by the clutch 115 (see FIG. 4), and the platen The sheet is conveyed only by the rotation operation of the roller 501. Further, when the sheet is conveyed in the reverse direction, the clutch is driven, and the sheet is conveyed by both the platen roller 501 and each sheet feeding roller.

  Next, an operation for recording an image on the widest first roll paper 101 will be described.

  After the sheet 101 stopped at the standby position by the setting operation described above is fed out for a fixed length, the platen roller 501 and the drive pinch roller 507 have its leading end portion downstream of the sensor S4 of the carriage unit 4 and the image. It is positioned upstream of the recording unit 401. At this time, as described above, the sensor S4 checks the width and position of the sheet 101 and the inclination state of the leading edge. This is to detect the state in advance when the paper 101 shrinks due to an environmental change during standby or when an abnormality such as skew occurs during conveyance from the standby position to the image recording unit 401. If there is a problem with this check, a paper setting error is issued and the paper 101 is fed back until the leading edge of the paper 101 is removed from the first paper feed roller 104. On the other hand, if there is no problem, an image recording operation described later is started.

  Next, a case where image recording is performed in the order of black (K), cyan (C), magenta (M), and yellow (Y) will be described.

  The leading edge of the sheet is detected by the sensor S4, the sheet 101 is conveyed to a position where the leading edge faces the recording head K that ejects black ink, and only the black ink is recorded on the sheet 101 while reciprocating the carriage unit 4. To do.

  In the reciprocal recording mode, after the forward operation of the carriage unit 4 is completed, the platen roller 501 is intermittently driven to transport the leading end of the paper 101 to a position facing the recording head C that ejects cyan ink. During the backward operation, black and cyan inks are recorded on the paper 101.

  Before proceeding to the forward operation again, the front end of the paper 101 is conveyed to a position facing the recording head M that ejects magenta ink, and in the forward operation, inks of three colors of black, cyan, and magenta are recorded on the paper 101.

  Before proceeding to the next backward operation, the front end of the paper 101 is conveyed to a position facing the recording head Y that ejects yellow ink, and in the backward operation, all four colors of ink are recorded on the paper 101.

  During such an image recording operation, the sheet 101 is intermittently conveyed in synchronism with the movement of the carriage unit 4 while being in close contact with the platen board 502, and then nipped by the discharge roller pair 206.

  As described above, since the image recording can be started before the front end of the paper 101 is nipped by the paper discharge roller pair 206, it is possible to minimize the non-recording portion formed at the front end portion of the paper 101. At the end of the image recording, the printing is finished from black, and finally the yellow printing is finished, contrary to the order described above.

  After the image recording is completed, the sheet 101 is conveyed until the cutting boundary portion is positioned at the cutter 205 position. At this time, the carriage unit 4 is moved to the home position, and a protective cap is put on the surface of each recording head, and then the cutting boundary portion is cut by the cutter 205.

  Thus, since the cutting process is performed after the protective cap is put on the surface of each recording head, it is possible to prevent the paper dust generated during the cutting from adhering to the surface of each recording head.

  Next, an operation for continuously recording different images on the common sheet 101 will be described.

  In the case where the next image recording is started following the end of the first image recording, it is assumed that the sheet 101 is intermittently conveyed by the feed length L. At this time, if the cutting boundary portion of the recorded image area already recorded on the paper 101 passes the cutting position of the cutter 205 while the paper 101 is conveyed by the feed length L, the paper 101 is fed. The length L is not conveyed. That is, the sheet 101 is conveyed by a length a (a <L) at which the cutting boundary portion of the recording image area is positioned at the cutting position of the cutter 205.

  When the sheet 101 is conveyed by the length a (a <L), the carriage unit 4 is retracted to the home position before cutting. Then, after each recording head is protected with a protective cap, cutting processing of the cutting boundary portion of the paper 101 is performed.

  After the cutting process, the surrounding paper dust falls freely, and the operation of the apparatus is stopped for a period of time until it is sucked into the suction means 504 and removed, and then the sheet 101 is length b (b = La). Only carry. As a result, the sheet 101 is conveyed by the feed length L.

  Thereafter, after removing the protective cap from each recording head, the next image recording is started again.

  By controlling in this way, different images can be continuously recorded on the common sheet 101, so that the image recording time can be shortened. Further, since the protective caps are put on the respective recording heads at the time of cutting, paper dust that may interfere with image recording does not adhere to the recording heads.

  In such an image recording operation, an image recording operation in the leading and trailing edge marginless mode will be described. In this case, the marginless mode is selected by an operation panel (not shown) of the image forming apparatus.

  In the no margin mode, image recording is started from a position where a margin is previously inserted at the leading end of the paper 101. In this case, the length of the margin is the minimum length by which the sheet 101 can be discharged by the discharge roller pair 206.

  In this marginless mode, the leading margin portion is cut by the cutter 205 in accordance with the image recording start position. In this case as well, as in the conventional sheet trailing edge cutting sequence, the length a (a <L) is first conveyed with respect to the feed length L, the image leading edge position is cut, and the remaining length b is then cut. Transport only (b = La). During cutting, the carriage unit 4 is retracted to the home position, and the trailing edge margin of the paper 101 is cut in accordance with the end position of the image recording area. However, the previous image may protrude from the leading edge of the next image recording paper 101 due to an error during paper conveyance. In this case, a margin is provided at the leading end of the next image recording sheet 101, and the margin is cut. As a result, the projected image is removed together with the margin. However, in this case, useless paper for removing the protruding recording image is generated on the paper 101 at the front and rear end of the recording image area.

  Next, an operation for simultaneously recording images on the second and third roll papers 102 and 103 will be described with reference to FIG.

  In a plotter or the like, generally, an input image is rearranged for each size by a function called an auto layout function according to the size of the input image, and printing is performed efficiently.

  In this embodiment, an A2 size image and an A1 size image are recorded on the second roll paper 102 having a width of 594 mm, and at the same time, an A4 size image and an A3 size image are recorded on the third roll paper 103 having a width of 297 mm. Record.

  As shown in FIG. 6, images of each size indicated by reference signs A to F are recorded for each sheet on the sheets 102 and 103 conveyed from the second and third roll sheets. . In addition, the dotted line part in a figure has shown the cutting | disconnection boundary part cut | disconnected by the cutter 205. FIG.

  Prior to image recording, the inclination state of the leading ends of the sheets 102 and 103 is separately checked (skew detection) by the method described above. Then, the image recording data is corrected so that the relationship between the respective leading end positions and image recording is in a constant state with respect to the sheets 102 and 103.

  As described above, by simultaneously recording a plurality of images on the respective sheets 102 and 103, the stop time at the moving end of the carriage unit 4 is relatively saved, so that the recording time can be shortened. The

  When the cutting boundary portion of the recorded image recorded in this way passes through the cutting position of the cutter 205, the cutting boundary portion is first sent without sending a normal constant feed amount at a time, as in the above-described operation. The sheets 102 and 103 are conveyed until the sheet is positioned at the cutting position of the cutter 205.

  When the cutting boundary portion of the paper 102 or 103 is positioned at the cutting position of the cutter 205, the movable blade 205b disposed in the gap L is operated to cut the cutting boundary portion of the paper to be cut. Thereafter, the sheets 102 and 103 are conveyed by the remaining amount. As a result, the sheets 102 and 103 are conveyed by a fixed feed amount. Here, the fixed amount is a feed amount when cutting is not performed.

  The movable blade 205b (see FIG. 13) of the cutter 205 is connected to the two sheets 102 and 103 so that the cutter 205 acts only on the sheet to be cut out of the sheets 102 and 103 being simultaneously conveyed. It arrange | positions in the clearance gap L between. The sheet 102 is cut by moving the movable blade 205b from the gap L to one side, and the sheet 103 is cut by moving the moving blade 205b to the other side.

  On the other hand, when a cutter 205 that reciprocates in the paper width direction is used, the position of the movable blade 205b of the cutter 205 is detected and temporarily stopped between the gaps L. When cutting the maximum width sheet 101, the blade may be stopped outside the sheet width.

  In the type in which the cutter 205 is attached to the carriage unit 4 and the blade selectively enters and exits the paper path to cut the paper, the blade is selectively used only for the paper 102 or 103 that needs to be cut. May be used.

  In this way, when image recording is simultaneously performed on a plurality of sheets 102 and 103 by using the auto layout function, the feed length to the next cutting boundary portion is calculated for each sheet before image recording. If the difference in feed length is less than a certain value, image formation is performed simultaneously, but if it exceeds a certain value, simultaneous recording is not performed. By controlling in this way, both sheets are prevented from being conveyed for a long time while an image is recorded only on one of the sheets.

  Next, the processing station 3 that processes a sheet on which an image of a predetermined size is recorded and cut by the cutter 205 as described above will be described.

  As shown in FIG. 1, the processing station 3 is disposed below the paper discharge roller pair 206 and includes a table 301 on which sheets 101, 102, and 103 can be placed. The table 301 is arranged with one end of the operation surface side Z raised so as to form an acute angle with respect to the paper transport direction T (a transport guide 303 described later).

  Further, the processing station 3 includes a conveyance guide 303 that guides the sheets 101, 102, and 103 discharged from the discharge roller pair 206 almost directly downward, and a side opposite to the sheet conveyance side of the conveyance guide 303. A plurality of fans 304 provided across the paper width direction and a nip roller 302 provided rotatably at the lower end of the conveyance guide 303 are provided.

  Further, the table 301 is rotatably supported at one end on the operation surface side Z, and the tip extended near the nip roller 302 is biased toward the nip roller 302 by a biasing spring 306 disposed below the table 301. Has been. As a result, the top surface of the table 301 is always in pressure contact with the nip roller 302.

  In particular, as shown in FIG. 19, an arcuate stop 305 is disposed near the tip of the table 301 so as to be orthogonal to a tangent line passing through the contact point of the nip roller 302 with which the table 301 is in pressure contact.

  As shown in FIG. 10A, after the image-recorded sheets 101 or 102 and 103 are discharged by the discharge roller pair 206, the non-recording surface side of the sheet is guided by the conveyance guide 303 and descends downward. Go. Since the paper is roll paper, the leading edge is curled slightly toward the conveyance guide 303 side with a curl.

  As shown in FIG. 10B, when the leading edge of the sheet comes off from the conveyance guide 303, the leading edge abuts on the contact portion between the table 301 and the nip roller 302 with the help of the curl. Then, the nip roller 302 is slightly rotated by a driving motor (not shown) at the timing when the leading edge of the sheet is sufficiently in contact. Note that the amount of rotation at this time is sufficient if the leading end of the sheet is nipped between the nip roller 302 and the table 301 and the leading end contacts the stopper 305.

  After the leading edge of the sheet comes into contact with the stopper 305 and stops, the sheet and the nip roller 302 are relatively slipped. Since the friction coefficient of the nip roller 302 is set slightly larger than the friction coefficient between sheets, the sheet does not buckle.

  Even after the leading edge of the sheet comes into contact with the stopper 305, the trailing edge of the sheet is sequentially recorded and conveyed. Therefore, when a predetermined amount of recording is completed, the central portion of the sheet is separated from the conveying guide 303 to form a loop.

  As shown in FIG. 10C, the conveyance guide 303 is between the time when the front end of the paper is nipped by the nip roller 302 and the time when the rear end of the paper is cut by the cutter 205 and separated from the paper discharge roller pair 206. The fan 304 provided on the sheet is driven, and the trailing edge of the sheet is pushed toward one end of the table 301 by the wind pressure.

  As shown in FIG. 10D, particularly in a long sheet, the trailing edge of the sheet hangs down from the table 301 and the leading edge is held between the nip rollers 302 and held.

  As illustrated in FIG. 10E, the above-described operation is sequentially repeated, so that the sheets with the leading end of the sheet sandwiched between the nip rollers 302 are sequentially stacked on the table 301.

  At this time, the table 301 is sequentially pushed down in accordance with the thickness of the plurality of sheets stacked, but the biasing spring 306 has a weight corresponding to the thickness of the plurality of sheets stacked on the table 301 and It has an urging force that is equal to or greater than the amount of force that holds the portion where the trailing edge of the plurality of sheets does not drop.

  The table 301 applied to this embodiment is divided at least at the boundary between the sheets 102 and 103, and the table 301 is independently energized. Therefore, for example, even when a large amount of roll paper 103 is used and only a small amount of roll paper 102 is used, the top surfaces of the respective sheets stacked on the table 301 are positioned at substantially the same position. Accordingly, even when a wide sheet such as the roll sheet 101 is stacked on the stacked sheets 102 and 103, the upper surfaces of the sheets 102 and 103 are almost at the same position, so that the sheet 101 is stable without trouble. And placed. Further, such a table 301 has an advantage that sheets having different lengths can be sequentially stacked. Further, since the trailing edge of the sheet is pushed out from the sheet stacking position by the wind pressure of the fan 304, the trailing edge of the sheet does not interfere with the leading edge of the next stacked sheet.

  Next, a processing station 3 according to a modification of the present embodiment will be described with reference to FIGS.

  As shown in FIG. 11, the processing station 3 of the present modification includes a plurality of paper discharge trays for storing recorded paper for each paper size below the paper discharge roller pair 206, and the paper discharge roller pair 206. On the other hand, it is configured to be able to reciprocate horizontally in the operation side Z direction (arrow direction in the figure).

  Each of the paper discharge trays is inclined at a predetermined angle, and has a paper storage opening at one end facing the paper discharge roller pair 206 and a paper outlet at the other end. Yes.

  As shown in FIG. 12, in these paper discharge trays, for example, when A4 and A3 size recorded paper is cut from a paper sheet 297 mm wide, the paper discharge tray 601 provided on the operation surface side Z is A4 size paper. A paper discharge tray 602 provided on the back side of the paper discharge tray 601 when viewed from the operation surface side Z is configured to store A3 size paper. Further, for example, A2-size paper cut from the paper 102 having a width of 594 mm is configured to be stored in a paper discharge tray 603 arranged in parallel in the paper width direction of the paper discharge tray 602. Further, for example, when A1 and A0 size sheets are cut from the sheet 101 having a width of 841 mm, these A1 and A0 size sheets are discharged to the back side of the discharge trays 602 and 603 arranged in parallel. It is configured to be stored in 604.

  For this reason, the processing station 3 is controlled to move in a predetermined direction by a predetermined amount so that a paper discharge tray of a desired size is positioned below the paper discharge roller pair 206 in accordance with the size of the paper to be discharged. .

  Further, the discharge tray 604 for storing A1 and A0 size sheets is designed for A1 size. Therefore, when storing A0 size paper, after the leading edge of the paper reaches the bottom of the paper discharge tray 604, the processing station 3 is sequentially moved to the operation surface side Z in synchronization with the paper discharge operation. Thus, the paper discharge control is performed so that the rear end of the paper hangs downward from the storage port of the paper discharge tray 604. As a result, since the A0 size paper is stored in a substantially folded state, the storage opening of the paper discharge tray 604 is provided with an arcuate portion 604b that does not damage the paper. A paper presser 605 is provided at the outlet of each paper discharge tray. In addition, each paper discharge tray is arranged so that a large size of paper can be stored from the front side to the back side when viewed from the operation surface side Z, so the paper provided at the lower end of each paper discharge tray All the outlets are exposed to the operation surface side Z. For this reason, even when a sheet is being stored, a sheet of a desired size can be taken out without moving the processing station 3. Further, since the discharge trays are arranged in the paper width direction in accordance with the arrangement of the first to third roll papers 101, 102, and 103 set in the apparatus, the depth dimension of the processing station 3 can be reduced. Become. As a result, the amount of movement of the processing station 3 can be reduced, and the processing station 3 does not protrude and move from the apparatus.

  Next, an operation for removing a paper jam will be described.

  As shown in FIG. 15, first to third roll papers 101, 102, and 103 are arranged in the paper feed station 1 of the image forming apparatus of the present embodiment, and all the roll papers are placed in the top cover 801. It is settled.

  The top cover 801 is configured such that the back of the apparatus is rotatably supported when viewed from the operation surface side Z, and the front of the apparatus can be opened. In the recording station 2, a front cover 802 configured to be openable around the lower portion is disposed on the operation surface side Z facing the platen board 502.

  Further, as shown in FIG. 16, a lever 212 extends to the side of each roll paper 101, 102, 103 via a link mechanism 211 provided outside the first frame 201, as shown in FIG. 16. ing. Since the lever 212 is connected to the guide bar 208 via the link mechanism 211, the drive pinch roller 507 can be separated from the platen roller 501 by operating the lever 212 after the top cover 801 is opened. Yes (see FIG. 17). As a result, the upstream side of each sheet is nipped by the paper feed rollers 104, 105, 106 and the pinch rollers 107, 108, 109, and the downstream side is nipped by the paper discharge roller pair 206.

  The nip force of the paper discharge roller pair 206 is extremely small compared to the conveyance force of other rollers (not shown). Therefore, by manually rotating the paper feed roller of the roll paper that has caused the paper jam, the front end of the paper that has caused the paper jam can be easily pulled back to the roll paper.

  Further, the first to third guide guides 118, 119, 120 are pushed down against the urging force of the urging springs 118b, 119b, 120b (see FIGS. 13 and 14), so that the sheet feeding roller and the pinch roller It is possible to release the nip force acting on the paper. As a result, the leading edge of the paper causing the paper jam can be easily pulled back to the roll paper.

  In this case, the first transport path (see FIG. 13) formed by the first guide guide 118 and the first fixed guide 122 opens directly from the operation side Z ″ (see FIG. 15) by opening the top cover 801. In addition, a second conveyance path (see FIG. 13) formed by the second guide guide 119 and the second fixed guide 121, and the third guide guide 120 and the second fixed guide 121 are visible. The third conveyance path formed by (see FIG. 14) can be directly viewed from above the apparatus L (see FIG. 15) by opening the top cover 801.

  Therefore, even when the above-described paper jam occurs, the paper can be easily and reliably removed while visually checking.

  Further, the carriage unit 4 of the recording station 2 is controlled so as to retract to a home position (see FIG. 17) provided outside the first frame 201 when a paper jam occurs. Therefore, by opening the front cover 802 (see FIG. 15), it is possible to perform the paper jam removal process while directly viewing the vicinity of the platen board 502 from the operation surface side Z.

  Further, in the processing station 3 (see FIG. 15) applied to the present embodiment, on the lower operation surface side Z ′ facing the conveyance guide 303 on the downstream side of the paper discharge roller pair 206, there are apparatus constituent members. Since it is not arranged, the paper jam processing can be easily performed from the lower operation side Z ′.

  On the other hand, the processing station 3 (see FIGS. 11 and 12) according to the modified example of the present embodiment is controlled so that the entire processing station 3 exceeds the normal moving distance and retracts to the back of the apparatus when a paper jam occurs. ing. In this case, the paper discharge tray 601 that is disposed closest to the operation surface side is retracted to the back of the paper discharge roller pair 206, so that the paper jam removal process on the downstream side of the paper discharge roller pair 206 can be easily performed. Is possible. Further, even when a paper jam occurs in each paper discharge tray, the entire processing station 3 can be pulled out beyond the normal movement range to the operation surface side by a command from an operation panel (not shown). As a result, it is possible to easily perform the paper jam removal process in each paper discharge tray while directly viewing the storage opening of each paper discharge tray.

  In addition, the following problems are raised in this specification.

  1. In the conventional image forming apparatus, a large space is required to provide a three-stage drawer tray on the operation side, and a large area on the operation side is occupied by these drawer trays. is there. As a result, since the discharge side of the image-recorded sheet must be provided on the non-operation side opposite to the operation side, there arises a problem that operation from one direction (operation side) of the apparatus becomes difficult.

  2. Further, in the conventional image forming apparatus, when a sheet jam occurs, it is necessary to pull out the corresponding pull-out tray, and it takes time and troubles such that the sheet is torn off halfway when pulling out the pull-out tray. Even if the corresponding pull-out tray can be pulled out, in order to release the portion where the sheet is nipped, it is necessary to turn to the non-operation side of the apparatus and open the sheet jamming processing door, which is complicated.

  3. In order to eliminate such a problem, it is conceivable to provide a cutting means for each pull-out tray, but there is also a problem that the apparatus is increased in size and cost. Furthermore, when all the pull-out trays are pulled out, the stability of the apparatus also deteriorates.

  4). As a countermeasure for these, it is conceivable that the apparatus is configured such that the pull-out trays cannot be pulled out at the same time, but this deteriorates the operability of the apparatus. In addition, in the conventional image forming apparatus, since a heavy sheet roll is set on a pull-out tray at the lower part of the apparatus, the mounting posture is impossible, and the user is burdened when setting the sheet roll. Yes. Furthermore, since the sheet conveyance distance to the recording unit is increased by providing the pull-out tray, it takes a long time for the sheet to reach the recording unit, and errors in the sheet position when passing through the recording unit are remarkable. There is also a problem of appearing in

  5. Further, according to the conventional image forming apparatus, while the sheet is slightly reciprocated, a plurality of side edge positions of the sheet are detected by the sheet detecting unit to determine whether the sheet is skewed. However, the sheet moving length in the transport direction is a slight amount compared to the width dimension of the sheet. For this reason, it is difficult to detect skew with high accuracy. In addition, when detecting whether the length in the sheet width direction is corrected after skew detection, the recording means moves on the sheet. For this reason, when sagging occurs in the sheet, the recording unit may be damaged by the recording unit coming into contact with the sheet.

  6). In addition, when an ink jet recording method is used in a conventional image forming apparatus, the time until ink droplets reach the sheet from the recording head unless the distance between the recording head of the recording unit and the sheet is maintained constant. Variation occurs. Since the carriage is controlled to perform a printing operation while moving, the positional accuracy at which the ink droplets land on the sheet deteriorates when the above-described variations occur.

  7. In a conventional image forming apparatus, recording is performed using the platen roller or a guide on the downstream side as a platen surface. When the recording width of the recording unit is large and high-speed recording is desired, the curvature of the platen roller is set. A platen roller with a large diameter is required because it cannot be ignored. As a result, a large space for accommodating the platen roller is required, and the apparatus becomes large.

  8). In addition, when the sheet is supported by the downstream guide, the sheet may float from the guide. In addition, it is difficult to maintain the guide with a constant accuracy over the entire width because it is affected by a problem of component accuracy and a problem of thermal expansion due to the use environment. For example, in the method of adsorbing and conveying a sheet to a belt, it is difficult to adsorb the sheet to the belt without slipping due to the influence of the inertia of the sheet. Furthermore, there has been a problem that the conveyance of the belt is not constant due to slip or the like. Further, for example, in a method of forming a platen board by adsorbing a sheet to a suction box, a load is applied to the sheet conveyed during sheet conveyance, and the sheet may be buckled during conveyance. Further, when the sheet is conveyed also on the downstream side of the recording unit, image recording cannot be performed until the sheet reaches the downstream side conveying unit, so that the recording efficiency is deteriorated and an unrecorded portion is generated at the leading end of the sheet. Therefore, there is a problem that the effective recording area is limited.

  9. Also, in an image forming apparatus that performs recording while reciprocating the carriage, if the width of the conveyed sheet is narrow, the time required to reverse the carriage at the end of the sheet is less than the actual recording time. Since it becomes long, it was not possible to record an image efficiently.

  10. In addition, in an image forming apparatus that stores recorded sheets by size using a sorter or the like, if the sheet size is large, the sorter itself occupies a large space, which is inconvenient for actual use. It was. On the other hand, in the type in which the sheet is dropped into the stocker and stored, the lower sheet is crushed by the weight of the sheet dropped from above, and there is a problem that wrinkles occur.

  11 Inkjet sheets are mainly used for coated paper, but this coated paper is liable to generate paper dust when cut. In particular, a lot of paper dust adheres to the vicinity of the cut surface of the coated paper and the cutter. Therefore, when paper is unwound after cutting, after being cut, or when it is fed again, This causes a problem that it adheres to the recording head. In this way, when paper dust adheres to the recording head, the ink is not ejected normally, but the problem of paper dust is particularly noticeable in an apparatus having a cutting means above the recording portion.

  The present specification includes the following inventions.

1. In order to simultaneously set a plurality of sheet rolls configured by winding a plurality of sheets having different width dimensions in a roll shape on the upper surface of the apparatus,
Of the plurality of sheet rolls, a first sheet roll holding portion that rotatably holds a maximum width sheet roll;
The other plurality of sheet rolls are held substantially in series and rotatably so that they are parallel to the maximum width sheet roll held by the first sheet roll holding section and overlap at least partially in the sheet width direction. An image forming apparatus comprising: a second sheet roll holding unit.

(Constitution)
As shown in FIGS. 1 and 3, the plurality of sheet rolls correspond to the first to third roll papers 101, 102, and 103, and the first sheet roll holding portion is the first roll having the maximum width. The first paper supply roller 104 and the first support roller 110 that hold the paper 101 rotatably correspond to this. The second sheet roll holding unit also includes second and third paper feed rollers 105 and 106 and second and third support rollers 112 that rotatably hold the second and third roll papers 102 and 103. 111.

(Action / Effect)
By arranging multiple sheet rolls in the paper width direction and arranging other small size paper in parallel with the maximum width paper, it is possible to efficiently place multiple sheet rolls in a small space. It becomes. Further, since it is not necessary to set a heavy sheet roll below the apparatus, it can be mounted in a standing posture, and the user is not forced to bear an unreasonable posture. Furthermore, since the sheet roll holding unit holding the sheet roll has a function of conveying paper, the number of parts is reduced, and space saving and cost reduction can be realized.

  1-1. 2. The image forming apparatus according to claim 1, wherein the first sheet roll holding unit is disposed closer to an operation surface side for operating the image forming apparatus than the second sheet roll holding unit. .

(Constitution)
This is the same as the configuration of 1 above.

(Action / Effect)
Since the heavy sheet roll having the maximum width is close to the operation surface side, operability such as replenishment of a plurality of roll sheets can be improved.

  1-2. Between the first sheet roll holding part and the second sheet roll holding part, a merging part for merging the sheets fed from these sheet roll holding parts is provided, and from the merging part, 2. The image forming apparatus according to 1 or 1-1, wherein a conveyance path for guiding the sheet sent to the merging unit to an image recording unit that performs image forming processing extends.

(Constitution)
As shown in FIGS. 13 and 14, the joining portion is a position where the first to third transport paths join each other, and is near the guide bar 208 held by the first and second frames 201 and 202. The position is applicable. The first transport path is configured by the first guide guide 118 and the first fixed guide 122, and the second transport path is configured by the second guide guide 119 and the second fixed guide 121, and the third The conveyance path is configured by a third guide guide 120 and a second fixed guide 121.

(Action / Effect)
Since the sheet feeding length from the first and second sheet roll holding units to the image recording unit is substantially equal, a conveyance error is likely to occur only in the sheet held in any of the sheet roll holding units, There is no problem that the transport time to the image recording unit becomes extremely long.

2. A flange that is detachably attached to both ends of a sheet roll formed by winding a sheet into a roll;
An image forming apparatus comprising: a roller that rotatably supports the sheet roll by placing the flange; and a roller that conveys the sheet and controls the rotation of the sheet roll.

(Constitution)
As shown in FIG. 4, for example, flanges 101a and 101b are detachably attached to both sides of the first roll paper 101, and the sleeves 113 of the first paper feed roller 104 corresponding to the flanges 101a and 101b are attached. , 114 and the first support roller 110, the first roll paper 101 is rotatably supported on the first paper feed roller 104 and the first support roller 110. become.

  In this case, the sleeve 113 of the first paper feed roller 104 is configured to rotatably hold the flange 101a of the first roll paper 101 and to position the first roll paper 101 in the width direction. . The other sleeve 114 is configured to rotatably hold the flange 101b, and both sleeves of the first support roller 110 are configured to rotatably hold the flanges 101a and 101b. Further, in order to smoothly convey the paper, the outer peripheral diameter of each sleeve is smaller than the outer peripheral diameter of the central portion of the first paper feed roller 104.

(Action / Effect)
Since the rotational driving force can be transmitted to the sheet roll only by placing the sheet roll on the roller, the mounting property of the sheet roll can be improved. Further, since the roller itself also serves as a support member for supporting the sheet roll, other support members such as bearings can be omitted, and the configuration can be simplified, the apparatus can be made compact, and space can be saved.

  2-1. 3. The image forming apparatus according to 2, wherein the roller includes a positioning unit that engages with a flange of the sheet roll to position the sheet roll.

(Constitution)
As shown in FIG. 4, the roller positioning unit is configured to hold the flange 101a of the first roll paper 101, for example, so as to be rotatable, and to position the first roll paper 101 in the width direction. This corresponds to the sleeve 113 of the sheet feeding roller 104.

(Action / Effect)
Since the sheet roll is positioned by placing the flange on the roller, the positioning member is not required, the configuration is simplified, the apparatus is made compact, and the space is saved.

  2-2. In the above 2 or 2-1, the roller includes a paper feed roller for feeding a sheet fed from the sheet roll, and flange receivers provided on both sides of the paper feed roller. The image forming apparatus described.

(Constitution)
As shown in FIG. 4, the flange receiver corresponds to, for example, sleeves 113 and 114 provided on both sides of the first paper feed roller 104.

(Action / Effect)
It is the same as the operation and effect of the above 2-1.

2 '. In an image forming apparatus that forms an image on a sheet fed from a sheet roll,
A pair of conveying rollers for nipping and conveying the sheet fed from the sheet roll;
An image forming apparatus comprising: a holding portion that is provided on at least one roller of the conveying roller pair and positions and holds the sheet roll.

(Constitution)
As shown in FIG. 4, the conveyance roller pair is pressed so as to be able to contact with and separate from the first paper supply roller 104 that rotatably supports the first roll paper 101, for example. The holding unit corresponds to the pinch roller 107, and the holding unit rotatably holds the flange 101a of the first roll paper 101 and positions the first roll paper 101 in the width direction. The sleeve 113 of the paper roller 104 is applicable.

(Action / Effect)
It is the same as the operation and effect of the above 2-1.

3. In an image forming apparatus that forms an image on a sheet,
A platen provided on the outer surface of the negative pressure chamber and sucking and holding the sheet through a plurality of small holes formed on the surface;
A recording unit disposed opposite to the platen and recording an image on a sheet conveyed on the platen;
An image forming apparatus comprising: a conveying unit that is provided upstream of the small hole of the platen in the sheet conveying direction and that extrudes and conveys the sheet in the sheet conveying direction.

(Constitution)
As shown in FIG. 5, the negative pressure chamber is configured by a plurality of platen boards 502, first and second frames 201 and 202, upstream and downstream stays 505 and 506, and a lid 503. This corresponds to the suction chamber. The platen corresponds to a plurality of aluminum platen boards 502 arranged in the direction orthogonal to the paper transport direction T on the end surface on the operation surface side Z of the upstream and downstream stays 505 and 506. Further, the small holes in the platen correspond to air suction holes 502b having a diameter of about 2 mm formed on the platen board 502. The recording unit corresponds to the carriage unit 4 that moves along the platen board 502. As shown in FIG. 14, the conveying means corresponds to a platen roller 501 that is rotatably provided in the suction chamber and a drive pinch roller 507 that is press-contacted to the platen roller 501 so as to be able to contact and separate.

(Action / Effect)
By configuring so that the sheet is extruded and conveyed, an image can also be formed on the leading end portion of the sheet. As a result, it is possible to eliminate the non-recording portion of the sheet and suppress the generation of waste paper. Note that the pulling conveyance requires a pulling margin at the leading end portion of the sheet, and thus has a drawback that an image cannot be formed at the leading end portion.

3 '. In an image forming apparatus for forming an image on a sheet by a recording unit,
A platen provided on the outer surface of the negative pressure chamber and sucking and holding the sheet through a plurality of small holes formed on the surface;
And a conveying unit that is provided in the negative pressure chamber and conveys the sheet in contact with the sheet on substantially the same plane as the platen surface through an opening formed in the platen. Image forming apparatus.

(Constitution)
As shown in FIG. 5, the platen opening corresponds to a plurality of windows 502 a for the platen roller 501 formed on the upstream side of the air suction hole 502 b of the platen board 502. The rest of the configuration is the same as 3 above.

(Action / Effect)
By arranging the conveying means in the negative pressure chamber and conveying the sheet while being in contact with the sheet in substantially the same plane as the platen surface, the sheet can be moved without buckling between the conveying means and the platen. Can be transported.

3 ″. A stay fixed to the frame of the image forming apparatus main body;
A platen fixed to this stay,
Recording means for forming an image on a sheet on the platen;
An image forming apparatus, comprising: a guide fixed to the frame and holding the recording unit.

(Constitution)
As shown in FIG. 5, the frame corresponds to the first and second frames 201 and 202 constituting the suction chamber, and the stay corresponds to the upstream and downstream stays 505 and 506 constituting the suction chamber. As shown in FIG. 1, the guide corresponds to two linear guides 203 and 204 that extend in a direction orthogonal to the paper transport direction T so as to move the carriage unit 4 along the platen board 502. . The rest of the configuration is the same as 3 above.

(Action / Effect)
Since the recording means and the platen are both fixed to the frame of the apparatus main body, the positional accuracy between the recording means and the recording surface can be improved.

  3-1. 4. The image forming apparatus according to any one of 3, 3 ′, and 3 ″, wherein the platen is subjected to a friction reduction process on a sheet conveying surface thereof.

(Constitution)
Low friction treatment refers to an alumite treatment that forms a porous film on the surface of aluminum.

(Action / Effect)
Since the sheet conveying surface of the platen is subjected to the low friction treatment, even if the sheet is pushed onto the platen by the conveying means, the sheet does not buckle.

  3-2. The image forming apparatus according to any one of 3 to 3-1, wherein the platen is divided into a plurality of pieces in the sheet width direction.

(Constitution)
This is the same as the configuration of 3 above.

(Action / Effect)
The platen can be formed with higher accuracy than a single large platen. In addition, it is possible to make a design in which the problem of “warping” hardly occurs.

  3-3. The image forming apparatus according to 3 ″, wherein the platen is formed of a material having substantially the same thermal expansion coefficient as the stay to which the platen is attached.

(Constitution)
The material for the platen and stay is, for example, aluminum.

(Action / Effect)
Since the platen is not deformed by thermal expansion, the flatness of the platen can be maintained under various environmental temperatures.

4). A guide path having a merging portion for merging and guiding the sheets fed from a plurality of sheet roll holding portions capable of holding a plurality of sheet rolls configured by winding a plurality of sheets in a roll shape;
A sheet conveying means that is provided on the downstream side of the merging portion of the guide path and conveys the sheet while sandwiching the sheet by causing a pressing member to act on the sheet that has passed through the merging portion;
The pressing member is detachably held with respect to the sheet conveying unit, and has a guide surface for guiding the sheet sent from the plurality of sheet roll holding units to the joining unit in the direction of the sheet conveying unit. An image forming apparatus comprising: a holding member.

(Constitution)
As shown in FIGS. 1 and 3, the plurality of sheet rolls correspond to the first to third roll papers 101, 102, and 103, and the plurality of sheet roll holding units are the first to third paper feed rollers. 104, 105, 106 and the first to third support rollers 110, 112, 111 are applicable. As shown in FIGS. 13 and 14, the guide route corresponds to the first to third transport routes, and the joining portion is a position where the first to third transport routes meet each other, and The position in the vicinity of the guide bar 208 held by the second frames 201 and 202 is applicable. As shown in FIG. 14, the pressing member corresponds to the drive pinch roller 507, and the sheet conveying means corresponds to the platen roller 501 provided in the suction chamber. 17 and 18, the holding member corresponds to the pinch holder 209 supported by the guide bar 208, and the guide surface of the holding member is formed on the outer peripheral surface of the pinch holder 209 on the sheet conveyance path side. This corresponds to the partial arc-shaped portion 209b.

(Action / Effect)
There is no need to separately provide the pressing member contacting / separating means, and the apparatus can be made compact by shortening the distance from the joining portion to the conveying means. In addition, space saving at the junction is achieved. In addition, since the sheet guide surface at the junction is formed on the holding member that holds the pressing member, it is possible to simultaneously release the pressure on the conveying unit and release the guide surface at the junction.

  4-1. The holding member is a plurality of holders swingably held by a rod-like support member, and a sleeve that is rotatably fitted to the support member is provided between the holders. 5. The image forming apparatus as described in 4 above.

(Constitution)
As shown in FIG. 16, the support member is a guide bar 208 rotatably supported by the first and second frames 201 and 202, and the plurality of holders are a plurality of pinches held by the guide bar 208. The holder 209 is applicable. Further, the sleeve corresponds to the sleeve 210 that is rotatably fitted between the plurality of pinch holders 209 held by the guide bar 208.

(Action / Effect)
The sheet conveyance resistance can be reduced by the sleeve.

  4-2. Among the guide paths extending from the plurality of sheet roll holders, at least one guide path is provided with an elastic member disposed to face the guide surface so as to press the sheet. The image forming apparatus described in 4 or 4-1.

(Constitution)
As shown in FIG. 14, the elastic member is joined to the conveyance path so that the sheets 101, 102, 103 conveyed through the first to third conveyance paths are bent and smoothly guided by the arc-shaped portion 209b. This corresponds to the thin member 207 provided at the position. This thin member 207 is mainly used to bend the leading edge of the paper 101 conveyed from the first conveying path in the direction opposite to the curl direction, and is made of a stainless steel plate having a thickness of about 0.5 mm. It has a fulcrum nearer to the surface side Z and is configured to contact the pinch holder 209 or the sleeve 210 with its own weight. Note that the tip portion on the opposite side of the fulcrum has a shape bent by one part toward the sleeve 210 and extends to a position close to the conveyance path merging point.

(Action / Effect)
Even in the direction opposite to the curl of the sheet roll, the sheet can be conveyed without buckling.

5. In an image forming apparatus for forming an image on a sheet,
Recording means for recording an image on the sheet while moving in a direction intersecting the sheet conveying direction;
A sheet roll disposed on the moving space of the recording means;
An image forming apparatus comprising: guide means for guiding the sheet fed from the sheet roll so as to face the recording means.

(Constitution)
As shown in FIG. 13, the first roll paper 101 corresponds to the sheet roll disposed in the movement space of the carriage unit 4 as the recording unit.

(Action / Effect)
For example, in a printer that forms an image while the recording head moves in the width direction of the sheet, such as an ink jet printer, it is necessary to secure a moving space of the recording head over the entire width of the sheet in the apparatus. Therefore, the floor projected area of this space cannot be omitted from the floor occupied area of the apparatus. That is, if the sheet roll is disposed in the vertical direction with respect to the moving space, at least the floor exclusive area of the apparatus due to the sheet roll can be prevented from increasing.

6). In an image forming apparatus that forms an image on a sheet conveyed along a sheet conveyance path,
A recording unit that records an image on a sheet is held and moved in a direction crossing the sheet conveyance path to form a band-like recording area by the recording unit, and at the time of standby, the recording unit is moved from the sheet conveyance path. A carriage to be retracted;
A sheet sensor provided in the carriage on the upstream side in the sheet conveyance direction from the recording unit and on the sheet conveyance path side from the recording unit in a standby state so as to face the sheet;
Control means for controlling the conveyance of the sheet and the movement of the carriage,
An image forming apparatus that detects sheet information prior to a recording operation.

(Constitution)
As shown in FIG. 7, the carriage unit 4 as a carriage is controlled to be positioned at a home position provided outside the first frame 201 at the time of standby. The sheet sensor is a sensor S4 provided in the carriage unit 4. The sensor S4 defines the positional relationship with respect to the case where the carriage unit 4 is positioned at the home position. Thus, it is provided on the upstream side in the paper transport direction T and at a position closest to the paper. As shown in FIGS. 8 and 13, the control means corresponds to a control device 7 disposed behind the platen unit 5 of the recording station 2.

(Action / Effect)
Sheet information such as sheet skew, misalignment, and sheet size can be obtained without causing the recording means and the sheet to face each other. (If sheet information is detected with the sheet facing the recording means, the recording means may be damaged.)
6-1. 7. The image forming apparatus according to claim 6, wherein the control unit further controls sheet conveyance based on an output of a sheet sensor provided in a sheet conveyance path upstream of the recording area.

(Constitution)
As shown in FIGS. 13 and 14, the sheet sensor corresponds to sensors S1, S2, and S3 for detecting the leading end positions of the sheets 101, 102, and 103 provided on the upstream side of the platen roller 501.

(Action / Effect)
The initial stop position (standby position) at the start of sheet measurement can be controlled easily and in a short time.

  6-2. When simultaneously transporting a plurality of sheets, sheet information is detected for each sheet based on the output of the sheet sensor obtained when the sheet and carriage are moved by the control means prior to the recording operation. The image forming apparatus according to any one of the above 6 to 6-1, wherein:

(Constitution)
As shown in FIG. 6, the plurality of sheets correspond to sheets 102 and 103 that are simultaneously fed from the second and third roll sheets 102 and 103. The sheet sensors correspond to sensors S2 and S3.

(Action / Effect)
The effect of applying the effects 6 and 6-1 to the simultaneous recording on a plurality of sheets can be obtained.

7). A feeding means for simultaneously feeding a plurality of sheets to the recording unit at a predetermined interval in the sheet width direction;
A carriage that reciprocates a recording unit that forms an image on a sheet in a direction that intersects a conveyance direction of the plurality of sheets;
An image forming apparatus that forms an image across the plurality of sheets when the carriage is moved once based on image file information to be recorded on each sheet.

(Constitution)
As shown in FIG. 6, in this configuration, images of A2 size and A1 size are recorded on the second roll paper 102 having a width of 594 mm, and at the same time, A4 size is recorded on the third roll paper 103 having a width of 297 mm. A3 size images are recorded.

(Action / Effect)
Since images can be simultaneously recorded on a plurality of sheets, high-speed recording is achieved.

8). A feeding unit that feeds the sheet to the recording unit, a carriage that reciprocates the recording unit opposite to the sheet in a direction perpendicular to the sheet conveyance direction over a width of the sheet, and a plurality of continuous image file information to be recorded on the sheet Based on the above, in a device that performs recording control on a sheet while synchronizing the carriage movement operation and the intermittent conveyance of the sheet,
A sheet cutting means in the direction perpendicular to the sheet conveyance direction is provided downstream of the image recording unit, and the image file information includes the length in the conveyance direction of the image and cutting information at the end thereof, and different files are formed on the same sheet by the image forming means. During continuous recording, the paper is controlled to be intermittently conveyed by a length L (where L> 0) in conjunction with the reciprocation of the carriage when not cut, and the recording operation is temporarily interrupted during cutting, and the end of the file Has a control unit that controls the conveyance of the length α (where 0 <α <L) as it reaches the cutting position, and after the sheet is cut by the cutting unit, the sheet is conveyed again by L-α, and then the linkage with the image forming unit is resumed. An image forming apparatus.

(Action / Effect)
When recording continuous image files, the recording is interrupted for each file, and after cutting the paper, the paper is returned to the paper winding side, the paper is fed again, and the continuous recording is performed without starting the recording. Since the recording of only the missing operation is interrupted, the recording time can be shortened.

8-1. A feeding unit that feeds a plurality of sheets to the recording unit, a carriage that reciprocates the recording unit opposite to the sheet in a direction perpendicular to the sheet conveying direction over a width of the sheet, and a plurality of images to be recorded on the plurality of sheets In a device that controls recording on a plurality of sheets while synchronizing the movement of the carriage and the intermittent conveyance of the sheets based on the file information.
There is a paper cutting means in the paper conveyance orthogonal direction downstream of the image recording section, and the image file information includes the length of the image in the conveyance direction and cutting information at the end of the image. In addition, intermittent conveyance control of multiple sheets is performed, the presence / absence of cut information within the intermittent conveyance distance is determined, and if there is cutting information, the recording operation is temporarily interrupted and the end edge of the file having the cutting information is positioned at the cutting position. The feed control is performed as soon as it comes to the paper, and the cutting means is selectively operated only on the paper on which the file having the cut information is recorded, so that the cutting operation is repeated. An image forming apparatus comprising: a control unit that resumes interlocking with the image forming unit after conveying the remaining length.

(Action / Effect)
The configuration can be simplified because only the necessary portions can be cut by selectively operating the common cutting means on each paper without having different cutting means for simultaneously recording paper. .

  8-2. A protection device that covers the recording means at the standby position is provided. Prior to the cutting operation, the carriage is moved to the standby position, the recording device is covered by the protection device, and the next sheet is conveyed after a predetermined time has elapsed after the cutting operation is completed. 8. The image forming apparatus as described in 8 or 8-1, which is controlled to shift to an operation.

(Action / Effect)
When the head is covered with a protective device, and when a recorded file portion is cut continuously during different file recording, paper dust is generated and adheres to the head, and recording is not adversely affected. Also, paper dust is flying in the device immediately after the end of cutting, and after a predetermined time has elapsed, the next recording operation is resumed, so that the paper dust falls to the lower part of the device or is sucked up by suction means. It will not adhere to.

9. Conveying means for conveying the roll paper forward and backward to the recording unit, paper cutting means provided on the downstream side of the recording unit, and suction means for sucking and adsorbing the paper to the platen facing the recording means in the recording unit In a device that waits by feeding back the tip of the roll paper remaining after cutting the paper to the upstream side from the recording unit,
An image forming apparatus, wherein the suction unit is operated during a part of time during which a sheet is reversely fed during or after a sheet cutting operation.

(Action / Effect)
Even after the recording is finished, the suction means is operated to cut, or the paper tip after cutting is passed through the suction portion and returned to the roll paper winding holding side, so that the paper dust floating in the machine at the time of cutting is sucked by the suction means. I can do it. In particular, the paper dust adhering to the leading edge of the paper at the time of cutting can be removed by the suction means. As a result, it is possible to prevent paper dust from adhering to the recording head and adversely affecting recording.

1 is a diagram schematically showing an overall configuration of an image forming apparatus according to an embodiment of the present invention. FIG. 5 is a perspective view showing a state in which first to third roll papers are set in a paper feeding station. (A)-(c) is a top view which shows the variation of the some roll paper set to a paper feeding station, respectively. FIG. 4 is a partial cross-sectional view illustrating a state in which a first roll paper is positioned and set on a first paper feed roller. The disassembled perspective view which shows the structure of the suction chamber provided in the recording station. FIG. 5 is an operation explanatory diagram when images are simultaneously recorded on a plurality of roll papers. The figure which shows the state in which the carriage unit is located in the home position. The perspective view which shows schematically the structure of the position detection circuit of a carriage unit. FIG. 10 is an operation explanatory diagram when measuring the sheet posture by a sensor of the carriage unit. (A)-(e) is a figure which shows each process of the paper discharge process in a processing station in order. The side view which shows the structure of the processing station which concerns on a modification. FIG. 12 is a perspective view of the processing station of FIG. 11. Sectional drawing which shows the internal structure of a paper feed station and a recording station. FIG. 3 is a cross-sectional view illustrating a configuration around a merging portion between a paper feeding station and a recording station. The fragmentary sectional view which shows the state in which the top cover and the front cover are opened and the inside is exposed. The fragmentary sectional view which shows the state in which the end of the guide bar provided in the confluence | merging part vicinity is connected to the lever via the link mechanism. It is a side view of the structure shown in FIG. 16, Comprising: The figure which shows the state in which the drive pinch roller is contacting / separating with the platen roller by lever operation. (A) is sectional drawing which shows the state in which the drive pinch roller is contacting the platen roller, (b) is sectional drawing which shows the state in which the drive pinch roller is separated from the platen roller. The perspective view with which the positional relationship of the nip roller provided in the processing station, the table, and the stopper was partially shown.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Paper feed station, 2 ... Recording station, 3 ... Processing station, 4 ... Carriage unit, 5 ... Platen unit, 7 ... Control apparatus, 101, 102 ... Roll paper, 104 ... 1st paper feed roller, 105 ... 1st Two sheet feed rollers 106 ... Third sheet feed roller 107, 108, 109 ... Pinch roller 110 ... First support roller 111 ... Second support roller 113, 114 ... Sleeve 201 ... First 202, second frame, 203, 204 ... linear guide, 205 ... cutter, 206 ... pair of discharge rollers, 209 ... pinch holder, 301 ... table, 306 ... biasing spring, 401 ... image recording unit, 501 ... Platen roller, 502 ... Platen board, 504 ... Suction means, 505 ... Upstream stay, 506 ... Downstream stay, 507 ... Drive pin Chirora, 601, 602, 603, 604 ... discharge tray, S1 ... sensor, S4 ... sensor, Z ... operation side.

Claims (9)

In an image forming apparatus that holds a sheet roll on which a sheet to be image-recorded is wound in a roll shape by a sheet roll holding unit,
A sheet feeding station having at least one sheet roll holding portion for rotatably holding the sheet roll;
A platen roller that conveys the sheet from the sheet roll downward, a platen unit having an adsorption means for adsorbing the sheet conveyed downward to a flat platen board, and during adsorption to the platen board A recording station having a carriage unit including at least an image recording unit that records an image on the sheet sliding on the platen board so as to be pushed out by the platen roller;
Comprising at least
The recording station is provided below the sheet feeding station, and the platen unit in the recording station or the carriage unit during image recording is set to at least a part of the sheet roll in the sheet feeding station. Placed so as to overlap vertically
An image forming apparatus. The sheet roll holding unit includes at least a first sheet roll holding unit and a second sheet roll holding unit that rotatably hold the sheet roll,
The first sheet roll holding unit is provided on the operation surface side of the image forming apparatus, and the first sheet roll holding unit and the second sheet roll holding unit are parallel to each other and in the width direction of the sheet. Provided such that the sheet rolls are held in an overlapping manner,
The first sheet roll holding unit can hold a sheet roll that is longer in the width direction than the second sheet roll holding unit.
The image forming apparatus according to claim 1. The sheet roll holding unit includes at least a first sheet roll holding unit and a second sheet roll holding unit that rotatably hold the sheet roll,
The first sheet roll holding unit is provided on the operation surface side of the image forming apparatus, and the first sheet roll holding unit and the second sheet roll holding unit are parallel to each other and in the width direction of the sheet. Provided such that the sheet rolls are held in an overlapping manner,
The first sheet roll holding part can hold a heavier sheet roll than the second sheet roll holding part,
The image forming apparatus according to claim 1. The sheet roll holding unit includes a feeding roller rotatably supported with respect to the frame of the sheet feeding station, and a support roller fixedly supported with respect to the frame of the sheet feeding station,
The feeding roller has sleeves inserted on the feeding roller and rotatable with respect to the feeding roller on both sides,
The support roller has sleeves on both sides that are inserted into the support roller and rotatable with respect to the support roller.
The sheet roll is rotatably held on each sleeve of the feeding roller and on each sleeve of the support roller.
The image forming apparatus according to claim 1, wherein the image forming apparatus is an image forming apparatus. The sheet roll holding unit includes a feeding roller rotatably supported with respect to the frame of the sheet feeding station, and a support roller fixedly supported with respect to the frame of the sheet feeding station,
The feeding roller has sleeves inserted on the feeding roller and rotatable with respect to the feeding roller on both sides,
The support roller has sleeves on both sides that are inserted into the support roller and rotatable with respect to the support roller.
The sheet roll is rotatably held on each sleeve of the feeding roller and on each sleeve of the support roller, and the sheet roll is configured by the feeding roller and a pinch roller that presses the feeding roller. The sheet is conveyed,
The image forming apparatus according to claim 1, wherein the image forming apparatus is an image forming apparatus. The sheet feeding station has a plurality of sheet roll holders,
The recording station has a merging unit that merges the sheets of the sheet rolls conveyed from the sheet roll holding unit,
The merging unit has a conveying unit that conveys each sheet while being sandwiched between one and the other rollers,
The one roller of the conveying means is provided so as to be able to contact and separate from the other roller,
A roller holding portion for holding the one roller guides conveyance of the sheets of the joining portion;
The image forming apparatus according to claim 1. The recording station is provided with each frame disposed substantially perpendicular to the installation surface of the image forming apparatus and spaced apart from each other in the width direction of the sheet.
Each of the frames is provided with a stay and a guide that are orthogonal to the frame and spaced apart in the vertical direction of the image forming apparatus and provided in parallel with each other.
In each of the guides, the carriage unit having the image recording means is supported so as to be movable along the guides.
Each stay pinches and fixes the platen unit that sucks and holds the sheet to the platen board so as to face the carriage unit,
The platen board is provided in parallel to the guides, and is divided into a plurality of parts in the width direction of the sheet.
The image forming apparatus according to claim 1. The recording station includes a reciprocating means for reciprocating the carriage unit in the width direction of the sheet, a detecting means mounted on the carriage unit, and a detecting unit that generates information about the sheet based on information of the detecting means. And control means for controlling the conveyance of the sheet and the reciprocating means,
The carriage unit is moved to a retracted position retracted from the sheet transport path by the control means when image recording is not performed,
When the carriage unit is disposed at the retracted position, the detection unit causes the image recording unit to be closer to the conveyance path side than the side end portion on the conveyance path side in the sheet width direction. Provided further upstream than the upstream end in the sheet conveyance direction of the conveyance path,
The image forming apparatus according to claim 1. The recording station has cutting means for cutting the sheet in the width direction of the sheet;
A processing station is further provided vertically below the recording station,
The processing station includes a storage unit that stores the sheet cut by the cutting unit,
The storage portion is provided so that the sheet after image recording can be taken out from the operation surface side of the image forming apparatus.
The image forming apparatus according to claim 1.

Images