JP2004322612A - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming apparatus that can prevent mixture of colors of recording agents, can improve a speed of forming a monochrome image, and can reduce power consumption for forming a color image. <P>SOLUTION: A serial head section 21 having serial heads 21C, 21M, 21Y for respectively ejecting colors of C, M, Y and a line head section 22 having a line head 22K for ejecting a black color are provided at an upstream side and a downstream side in a paper feeding direction (the direction of the outlined arrows) apart from each other to approximately align the nozzle arrangement direction (the direction of the chain line) of the heads with a main scanning direction. The serial head section 21 is supported by a head carriage 23 and is moved in the main scanning direction along a slide shaft 24. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an image forming apparatus that forms an image on a supplied recording sheet with a recording agent (for example, ink in the case of an inkjet recording method).
[0002]
[Prior art]
A conventional image forming apparatus, for example, in an ink jet recording system, includes one or a plurality of heads provided with a plurality of nozzles arranged in one direction, ejects ink from the nozzles, and supplies a supplied recording sheet ( An image is formed on a sheet (hereinafter referred to as a sheet) (for example, see Patent Documents 1 and 2).
There are two types of such image forming apparatuses: a so-called line type image forming apparatus and a serial type image forming apparatus.
[0003]
In the line type image forming apparatus, the length between the nozzle on one end and the nozzle on the other end (hereinafter referred to as a recording width) is defined as the paper width (the length of the paper in a direction perpendicular to the paper supply direction). ) Use a head (line head) having a length equal to or greater than the length. A line-type image forming apparatus that forms a color image includes a head unit in which a plurality of line heads corresponding to inks of respective colors are arranged side by side in a sheet supply direction (hereinafter, a sub-scanning direction). At this time, the direction in which the nozzles of each line head are juxtaposed (hereinafter, referred to as a recording width direction) is arranged so as to substantially coincide with a direction (hereinafter, referred to as a main scanning direction) which intersects at right angles to the sheet supply direction.
In the image forming apparatus as described above, each head is supplied while being fixed, or by swinging each head in the main scanning direction in order to improve image quality, as disclosed in Patent Document 2. An image is formed on paper.
[0004]
On the other hand, a serial type image forming apparatus uses a head whose recording width is shorter than the recording width of a line head (hereinafter, referred to as a serial head). A serial type image forming apparatus that forms a color image includes a head unit in which a plurality of serial heads corresponding to inks of respective colors are arranged adjacent to each other in the main scanning direction. At this time, the recording width direction of each serial head is arranged so as to substantially coincide with the sub-scanning direction.
The image forming apparatus as described above forms an image on a supplied sheet while moving the head unit in the main scanning direction.
In the line type image forming apparatus, since the line head corresponds to the sheet width, there is no need to move the head unit.
[0005]
[Patent Document 1]
JP-A-5-185595
[Patent Document 2]
JP-A-7-276617
[0006]
[Problems to be solved by the invention]
However, the serial-type image forming apparatus has a problem that the image forming speed is low because the head section needs to be reciprocated in the main scanning direction during image formation.
On the other hand, the line-type image forming apparatus has a high image forming speed because there is no need to move the head unit at the time of image formation, but the line head uses a number of nozzles corresponding to the resolution (number of dots) of the image to be formed. It has to be provided, and there is a problem that it is expensive because it is difficult to form a line head. Further, the line head has a larger number of nozzles than the serial head if the resolution is the same, so that a large-capacity power supply is required for the image forming apparatus.
[0007]
Further, even when a line-type image forming apparatus for forming a color image is used, generally, image formation using only K color (hereinafter, referred to as monochrome printing) is C (cyan) and M (magenta). , Y (yellow), and K (black) image formation (hereinafter referred to as full-color printing). However, the power consumed during monochrome printing is about 1/4 of the power consumed during full color printing. That is, the image forming apparatus has a power supply with excessive performance.
As described above, there is a problem that the line type image forming apparatus for forming a color image is expensive.
[0008]
Further, a recording agent (ink) used in the ink jet recording method may have different drying time on paper or absorption time absorbed by paper for each color. In the case where the ink having a fast drying time or the ink having a short absorption time is used at the same time, the conventional image forming apparatus has a problem in that since the heads having the respective inks are adjacent to each other, the respective colors are mixed on the paper, and the color becomes bleeding. Therefore, there is a problem that image quality is deteriorated.
[0009]
Further, the conventional serial type image forming apparatus includes a single head unit having a plurality of (for example, four) heads and moves the head unit, and includes two head units separated from each other. An image forming apparatus in which two head units have a total of four heads and move one head unit (that is, one head moves independently of the other head) is not disclosed. . Further, an image forming apparatus using a line head and a serial head is not disclosed.
[0010]
The present invention has been made in view of such circumstances, and is configured such that two head units having one or a plurality of heads are separated from each other in the sub-scanning direction, and one of the head units is moved in the main scanning direction. In addition, it is possible to prevent color mixing of the recording agent due to a difference in drying time or absorption time, and to improve an image forming speed of image forming such as frequently performed monochrome printing, and to perform full-color printing which requires a plurality of heads. An object of the present invention is to provide an image forming apparatus capable of reducing the power consumption of such image formation.
[0011]
[Means for Solving the Problems]
An image forming apparatus according to the present invention is an image forming apparatus including a head unit having one or a plurality of heads for forming an image on a supplied recording sheet with a recording agent, wherein the two head units are arranged in a recording sheet supply direction. And one of the heads is provided so as to be movable in a direction intersecting the supply direction.
[0012]
In the present invention, the two head units are spaced apart in the sheet supply direction. For this reason, the recording agent is dried or absorbed by the sheet before the sheet from which the recording agent is ejected from the head unit disposed on the upstream side is supplied to the head unit disposed on the downstream side. . As a result, the recording material does not mix with the recording material ejected from the head disposed downstream.
[0013]
In addition, for example, one of the two head units that is movably provided uses one or a plurality of serial heads, and the other uses one or a plurality of line heads. In this case, a head unit having a line head (hereinafter, referred to as a line head unit) is fixed.
At this time, when the image formation is performed by ejecting a recording agent used for image formation that is frequently performed from the line head, image formation is performed using only the line head. The line head section does not need to reciprocate during image formation, and usually completes image formation in one recording scan, so that the image formation speed of the image formation is improved.
[0014]
Further, when performing image formation requiring a multi-color recording agent, since image formation is performed using only a head unit having a serial head (hereinafter, referred to as a serial head unit) or both head units, The power supply capacity is reduced as compared with an image forming apparatus using a head unit having a large number of line heads corresponding to multicolor recording materials. In general, since image formation requiring a multicolor recording agent is not frequently performed, the cost of the apparatus can be reduced by using an inexpensive serial head for the image formation.
[0015]
In the image forming apparatus according to the present invention, in each head, a plurality of nozzles for ejecting a recording agent are juxtaposed in a direction intersecting with the supply direction, and a length of the head of one of the head units in the nozzle juxtaposition direction is provided. Is shorter than the length of the head of the other head in the nozzle juxtaposition direction.
[0016]
In the present invention, for example, of the two head units, the one provided movably is the serial head unit having the serial head, and the other has a recording width longer than the recording width of the serial head. This is a line head unit having a line head. Each head is provided with one or a plurality of heads of the head so that the recording width direction substantially coincides with the main operation direction.
In general, the serial head has a rod shape, and the length in the recording width direction is longer than the length in the direction perpendicular to the recording width direction. Conventionally, the serial head unit is arranged so that the recording width direction substantially coincides with the sub-scanning direction. Therefore, the size of the means for moving the serial head unit (hereinafter, referred to as a carriage unit) in the sub-scanning direction can be reduced. Could not. In the image forming apparatus of the present invention, the size of the carriage in the sub-scanning direction is reduced in order to make the recording width direction substantially coincide with the main scanning direction.
[0017]
When the serial head section is arranged as described above, when forming an image using the serial head section, the image forming apparatus moves the serial head section in the main scanning direction and stops (or moves the serial head section). Rather, an image is formed in a sub-scanning direction along with the movement of the paper on a part of the paper corresponding to the recording width of the serial head. Next, the image forming apparatus moves the serial head unit in the main scanning direction and stops it, and, unlike the above partial area, moves the sheet to another area of the sheet corresponding to the recording width of the serial head. Accordingly, an image is formed in the sub-scanning direction.
[0018]
In the image forming apparatus according to the present invention, the one head unit has N (N is a natural number) heads, the total number of nozzles is S (S is a natural number of 2 or more), and the other one is The head section includes one head having K nozzles (K is a natural number of 2 or more), and the number N, the number S, and the number K are defined by Expression (1).
α × K / (N + 1) ≧ S / N (1)
α: coefficient of 1 or more.
[0019]
In the present invention, for example, of the two head units, the movably provided one has N serial heads, and the total number of nozzles is S serial head units. However, this is a line head unit having one line head and K nozzles.
Since only one line head is used, the image forming apparatus is configured at a lower cost than when a plurality of line heads are used.
[0020]
In Equation (2), K / (N + 1) is the number obtained by dividing the number of nozzles of the line head by the sum of the number of serial heads and the number of line heads, and S / N is included in the serial head. This is the average number of nozzles for each head. The number K of nozzles of the line head always satisfies K> S / N.
When the coefficient α = 1 and K / (N + 1) = S / N, when forming an image only with the line head unit, the consumed power capacity depends on the number of nozzles K = S + S / N.
[0021]
Further, when an image is formed by simultaneously using 1 / (N + 1) nozzles of the number of nozzles and all the nozzles of the serial head among the nozzles of the line head, the power supply capacity consumed is the total number of nozzles. (K / (N + 1) + S) = S + S / N.
In the case described above, power consumption is substantially the same between when an image is formed only by the line head unit and when an image is formed using the line head unit and the serial head unit. For this reason, the image forming apparatus is provided with only a power supply necessary for forming an image only with the line head unit, that is, only a power supply having a necessary and sufficient performance.
[0022]
It is ideal that the coefficient α = 1 and K / (N + 1) = S / N. However, practically, α> 1 (for example, α = 1.2), and the image forming apparatus uses a line A power supply having a capacity α times the power supply required for forming an image only with the head unit is provided.
[0023]
When an image is formed by simultaneously using the line head unit and the serial head unit, the image forming apparatus uses, for example, a serial head unit to print an image on a partial area of a sheet corresponding to the recording width of the serial head. Is formed, and an image is formed in the partial area using a nozzle corresponding to the partial area of the line head of the line head unit. Next, the image forming apparatus forms an image in the other area of the sheet corresponding to the recording width of the serial head by using the serial head moved and stopped in the main scanning direction, and An image is formed in the region of the other portion by using a nozzle corresponding to the region of the portion.
[0024]
The image forming apparatus according to the present invention includes a supply unit that supplies the same recording sheet to each head unit once or a plurality of times, and one-time recording when an image is formed using only the other head unit. Means for selecting whether to form an image by scanning or to form an image by a plurality of recording scans, and as a result of the selection, when forming an image by one recording scan, the supply means includes: A means for supplying the same recording sheet to the head once, and a means for forming an image on the other head using some or all of the nozzles of the nozzles of the head. As a result, when an image is formed by a plurality of recording scans, the supplying unit supplies the same recording sheet to the other head unit a plurality of times, and the other head unit supplies the recording sheet with the recording sheet. L-th time (L is a natural number) During the supply of the M-th time (M is a natural number, M ≠ L), means for forming an image using some of the nozzles included in the head unit is used. Means for forming an image.
[0025]
In the present invention, for example, of the two head units, the one provided movably is the serial head unit, and the other is the line head unit. Further, as the supply means, for example, a roller or an endless belt or the like which is arranged near each head unit and carries a sheet, and a motor or the like for rotating the roller or the belt or the like are provided.
When forming an image using only the line head unit, the image forming apparatus selects the number of print scans (hereinafter, referred to as passes). In this case, whether to form an image by one printing scan (hereinafter, referred to as one pass) or to form an image by plural printing scans (hereinafter, referred to as plural passes) is selected.
[0026]
When forming an image in one pass, the same sheet is supplied once to the line head unit, and an image is formed using all the nozzles corresponding to the sheet width among the nozzles of the line head included in the line head unit. I do. At this time, the image forming speed is high, but the number of nozzles used for image formation is large, so that the temperature rise rate of the line head is high. Particularly, when forming an image continuously on a large number of sheets, the line head Temperature may rise excessively.
[0027]
When an image is formed by a plurality of passes, the same sheet is supplied to the line head unit J times (J is a natural number of 2 or more), and when the sheet is supplied once, the nozzles of the line head included in the line head unit Of these, an image is formed using some of the nozzles obtained by dividing the total number of nozzles corresponding to the paper width into J, and this is repeated J times. At this time, the image forming speed becomes slow (approximately J times of one pass), but the temperature rise rate of the line head is low because many nozzles are not used at the same time during image forming.
[0028]
For this reason, for example, in the case where an image is continuously formed on a large number of sheets, the image forming apparatus may perform image formation in one pass according to whether the number of images formed is an odd number or an even number. Formation and image formation in a plurality of passes are selected, and each image formation is performed alternately. Alternatively, the image forming apparatus detects the temperature of the line head unit, selects image formation in one pass and image formation in a plurality of passes according to the detected temperature, and if the temperature is lower than a predetermined temperature, Image formation is performed in a plurality of passes, and if the temperature is equal to or higher than a predetermined temperature, image formation is performed in a plurality of passes.
As a result, the image forming apparatus suppresses a rise in the temperature of the line head.
[0029]
In the image forming apparatus according to the present invention, the recording agent used in one of the two head units has a drying time on the recording sheet of the recording agent or an absorption time of the recording agent of the recording sheet. The recording time is shorter than the drying time or the absorption time of the recording agent used in the other head.
[0030]
In the present invention, the two head units are spaced apart in the sheet supply direction. For this reason, even when a recording material having a long time to dry on a sheet or a time to be absorbed by a sheet is used for the head portion arranged on the upstream side in the supply direction, the sheet from which the recording agent is ejected is used. By the way, the recording agent dries or is absorbed by the sheet before it is supplied to the head portion arranged on the downstream side. As a result, even when a new recording material is ejected so as to come into contact with the recording material, color mixing of the recording materials on the sheet is prevented.
[0031]
The image forming apparatus according to the present invention is characterized in that the one head unit is arranged upstream of the other head unit in the supply direction.
[0032]
According to the present invention, the head portion disposed on the upstream side in the supply direction ejects the recording agent that is dried on the paper or absorbed by the paper quickly. In this case, the recording agent is surely dried or absorbed by the sheet before the portion of the sheet from which the recording agent has been ejected is supplied to the head portion arranged on the downstream side. Further, the head portion disposed on the downstream side ejects the recording material having a slow drying time or absorption time. In this case, when forming an image in one pass, no new recording agent is ejected. Further, even when forming an image in a plurality of passes, the recording material is surely dried or dried before the paper from which the recording material has been ejected is again supplied to the head portion arranged on the upstream side. It is absorbed by paper.
As a result, even when a new recording agent is ejected so as to come into contact with the recording agent previously ejected on the sheet, the color mixing of the recording agents on the sheet is further prevented.
[0033]
In the image forming apparatus according to the present invention, when an image is formed by a plurality of recording scans using two head units, one of the head units performs recording corresponding to one recording scan. When an image is formed in an area on a sheet, the other head unit is provided with means for forming an image in an area different from the area.
[0034]
According to the present invention, when an image is formed in a plurality of passes by simultaneously using the line head unit and the serial head unit, the image forming apparatus uses, for example, a serial head unit to reduce the recording width of the serial head. An image is formed in a partial area of a corresponding sheet, and a nozzle corresponding to another area different from the partial area of the line head of the line head unit is used to form the image in the other area. Form an image.
That is, since the area of the sheet on which the serial head section forms an image is always different from the area of the sheet on which the line head section forms an image, one head section has already formed an image on the other head section. When an image is formed in the area of the sheet, a time has elapsed in which at least one pass is completed. Therefore, the recording material on the area is surely dried or absorbed by the paper.
[0035]
As a result, even when a new recording agent is ejected so as to come into contact with the recording agent previously ejected on the sheet, the color mixing of the recording agents on the sheet is further prevented.
[0036]
The image forming apparatus according to the present invention includes a unit for prohibiting the other head unit from forming an image when one of the head units forms an image on an area on a recording sheet according to one recording scan. It is characterized by the following.
[0037]
According to the present invention, when an image is formed in a plurality of passes by simultaneously using the line head unit and the serial head unit, when the I-th (I is a natural number) pass, the image forming apparatus is, for example, a serial printer. Using the head unit, an image is formed in a partial area of the paper corresponding to the recording width of the serial head. At this time, the line head unit does not form an image. Further, at the time of the (I + i) -th pass (i is an integer other than 0), an image is formed in the partial area by using a nozzle corresponding to the partial area of the line head. May form an image on another part other than the above part, or may not form an image.
[0038]
That is, since the area of the sheet on which the serial head section forms an image does not match the area of the sheet on which the line head section forms an image, one head section has already formed an image on the other head section. When an image is formed in the area of the sheet, a time has elapsed in which at least one pass is completed. For this reason, the recording agent on the area is surely dried or absorbed by the paper.
As a result, even when a new recording agent is ejected so as to come into contact with the recording agent previously ejected on the sheet, the color mixing of the recording agents on the sheet is further prevented.
[0039]
When an image forming apparatus according to the present invention uses two head units to form an image by a plurality of print scans, the image forming apparatus determines whether to form an image on an area on a print sheet corresponding to each print scan. Means for determining, means for moving a movably provided head portion to a position corresponding to the region determined to form an image, and, after the movement of the head portion, each head portion has an image in the region. Forming means.
[0040]
In the present invention, it is determined whether or not to form an image on an area on a sheet corresponding to each pass, and the serial head is moved and stopped only at a position corresponding to the area where an image is to be formed. An image is formed in the area using two head units. In this case, the serial head is not moved or stopped at a position corresponding to the area where no image is formed.
As a result, when an image is formed using two head units, the image forming speed is improved.
[0041]
The image forming apparatus according to the present invention is characterized in that one or both of the two head units are provided so as to be swingable in a direction intersecting the supply direction.
[0042]
In the present invention, since the head swings in the main scanning direction, an image having a higher resolution than the resolution corresponding to the pitch of the nozzles provided on the head is formed.
Further, the image forming apparatus includes a head having a large nozzle pitch with respect to a dot pitch of an image corresponding to a required resolution. Such a head has a higher yield than a head having a nozzle pitch substantially equal to the dot pitch.
[0043]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the drawings showing the embodiments.
In the present embodiment, a printer capable of executing monochrome printing and full-color printing is exemplified as an image forming apparatus, but the present invention is not limited to this, and may be a copier, a facsimile, a multifunction peripheral thereof, or the like.
[0044]
Embodiment 1.
FIG. 1 is a block diagram illustrating a configuration of an image forming apparatus 1 according to Embodiment 1 of the present invention.
In the figure, reference numeral 10 denotes a CPU, which is a control center of the image forming apparatus 1 and which displays a ROM 11, a RAM 12, an operation state of the image forming apparatus 1, an input instruction to a user, and the like via a bus. And an operation unit 14 including various function keys for the user to operate the image forming apparatus 1 while viewing the display unit 13. The CPU 10 controls each unit of the image forming apparatus 1 in accordance with a control program and data stored in the ROM 11 in advance, temporarily stores data generated at this time or data input from the outside in the RAM 12, and executes various processes. I do.
[0045]
The interface 15 is connected to an image input device such as a personal computer in which image processing software is installed or a digital still camera. The image memory 16 is formed using, for example, a DRAM.
The recording unit 17 includes an image forming unit 2 that forms an image by an inkjet recording method, and a paper feeding unit 3 that supplies sheets to the image forming unit 2 one by one. 21 and a line head unit 22.
The power supply 18 has a power supply capacity that is 1.2 times (a coefficient α to be described later) a power supply capacity required when the image forming unit 2 forms an image in one pass during monochrome printing, and supplies necessary power to each unit. Supply.
[0046]
The CPU 10 stores the image data input by the image input device via the interface 15 in the image memory 16, reads out the image data stored in the image memory 16, and generates an image based on the read image data. The recording unit 17 forms the recording paper on paper using ink and discharges the paper.
[0047]
2 and 3 are a side view and a top view illustrating the configuration of the recording unit 17 (the image forming unit 2 and the sheet feeding unit 3 of the recording unit 17) included in the image forming apparatus 1. FIG.
The image forming unit 2 includes a serial head unit 21 having serial heads 21C, 21M, and 21Y for ejecting C, M, and Y inks, respectively, and a line head unit having a line head 22K for ejecting K ink. 22. The image forming section 2 supports the serial head section 21 and reciprocates in the direction of the white arrow 23a, and the head carriage 23 can reciprocate in the direction of the white arrow 23a along the head carriage 23. A simple slide shaft 24 and the like.
[0048]
In the image forming unit 2 in the present embodiment, the serial head unit 21 has N = 3 serial heads, the total number of nozzles is S, and the line head unit 22 has K nozzles. One line head is provided, and the number N, the number S, and the number K are defined by Expression (2) using a coefficient α = 1.2.
α × K / (N + 1) ≧ S / N (2)
In this case, the serial heads 21C, 21M, and 21Y each use a 600-DPI, 2-inch serial head, and have 1200 (= 600 × 2) nozzles that eject C, M, and Y color inks. Prepare. That is, S = 4800 (= 600 × 2 × 3).
[0049]
The line head 22K uses a 600 DPI, 8-inch serial head, and has K = 4800 (= 600 × 8) nozzles for ejecting K color ink.
As described above, K, S, and N follow the equation of {1.2 × K / (N + 1)} = 1.2 × 1200 = 1440 ≧ S / N = 1200.
[0050]
In the serial heads 21C, 21M, and 21Y, 1200 nozzles are juxtaposed at substantially equal intervals in the direction of the dashed line in the figure, and the recording width of each of the serial heads 21C, 21M, and 21Y is B1 in the figure. The color inks ejected by the serial heads 21C, 21M, and 21Y are dye-based inks, and are absorbed and dried in a short time on general paper on which an image is to be formed.
Further, in the line head 22K, 4800 nozzles are juxtaposed at substantially equal intervals in the dashed line direction in the figure, and the recording width of the line head 22K is B2 in the figure (B2 is four times B1). The ink ejected from the line head 22K is a pigment-based ink (carbon black), and the time to be absorbed by general paper on which an image is to be formed is longer than that of the dye-based ink.
[0051]
Further, the paper feeding unit 3 includes a paper feeding tray 31 arranged below the image forming apparatus 1 and a paper ejection tray 37 arranged above the image forming apparatus 1. Each tray is substantially rectangular in plan view. Further, the paper feed unit 3 includes a pickup roller (call-in roller) 32 disposed at a downstream end of the paper feed tray 31 in the paper feed direction (the direction of the white arrow 3a in the figure).
Further, the paper feed unit 3 is located at the center of the image forming apparatus 1 which is downstream of the paper feed tray 31 in the paper feed direction and upstream of the paper discharge tray 37 in the paper feed direction (the direction of the white arrow 3e in the figure). And a platen roller 35 disposed in the section. The platen roller 35 is provided so as to be rotatable in one direction (the direction of the arrow 35a in the figure) around the rotation shaft 351. The rotation shaft 351 and the paper supply tray 31 and the paper discharge tray 37 are arranged substantially in parallel. Have been.
[0052]
Further, the paper feeding unit 3 includes a paper guide plate 34 and a peeling claw 36 arranged on the peripheral surface of the platen roller 35 in the paper feeding direction (the directions of the white arrows 3b and 3d), respectively. The plate 34 is disposed on the downstream side of the paper feed tray 31 in the paper feed direction, and the peeling claw 36 is disposed near the upstream side of the paper discharge tray 37 in the paper feed direction. The paper feed unit 3 includes a paper feed roller unit 33 between the pickup roller 32 and the paper guide plate 34. Further, the serial head unit 21, the head carriage 23, the slide shaft 24, and the line head unit 22 are respectively disposed between the paper guide plate 34 and the peeling claw 36 in the paper feeding direction (the direction of the white arrow 3c). Are located.
[0053]
In the serial heads 21C, 21M, 21Y and the line head 22K, the juxtaposition direction of the nozzles is the main scanning direction (the axial length direction of the rotation shaft 351 of the platen roller 35; that is, the paper feeding direction (in this case, the white arrow 3c, In the vicinity of the peripheral surface of the platen roller 35, they are separated from each other so as to substantially coincide with the direction perpendicular to the direction 3d). The distance between the serial head unit 21 and the line head unit 22 is determined by the time required for the color ink ejected onto the paper by the serial head unit 21 to be absorbed by the paper and dried, and the circumference of the platen roller 35. It is provided so that the distance is equal to or more than the product of the rotation speed of the surface.
[0054]
The pickup roller 32 has a sector shape when viewed from the side. The paper feed roller unit 33 includes two paper feed rollers that are in contact with each other. The guide plate 34 is supported at one end on the upstream side in the paper feed direction. It is provided to be rotatable in the direction of arrow 34a in the figure. The one end is separated from the platen roller 35, and the other end contacts or separates from the platen roller 35 according to the rotation of the guide plate 34.
Further, the platen roller 35 includes a vacuum pump (not shown), and the peeling claw 36 is supported at one end on the downstream side in the sheet feeding direction that is spaced apart from the platen roller 35, and rotates in the direction of an arrow 36a in the figure. It is movably provided. The one end is separated from the platen roller 35, and the other end contacts or separates from the platen roller 35 according to the rotation of the peeling claw 36.
[0055]
In the paper feed unit 3, the rotation / stop of the pickup roller 32, the paper feed roller unit 33, and the platen roller 35, and the rotation / stop of the paper guide plate 34 and the peeling claw 36 are controlled by the CPU 10. ing.
When an image is formed, sheets are stacked on the paper feed tray 31 by the user, and the pickup roller 32, the paper feed roller unit 33, and the platen roller 35 rotate. The rotating pickup roller 32 calls the sheet stacked on the sheet feeding tray 31 toward the sheet feeding roller unit 33, and the sheet feeding roller unit 33 selectively selects one of the called sheets. Paper is fed to the upper surface of the guide plate 34. At this time, the paper guide plate 34 rotates so that the upper surface of the other end that is not supported by the shaft contacts the rotating platen roller 35, and presses the supplied paper against the platen roller 35.
[0056]
The platen roller 35 vacuum-adsorbs the paper pressed by the paper guide plate 34 with a vacuum pump and supplies the paper to the lower side of the serial head 21, and then supplies the paper to the lower side of the line head 22. It is supplied to the nail 36.
When the image formation is completed, the peeling claw 36 rotates so that the lower surface of the other end that is not pivotally supported contacts the rotating platen roller 35. At this time, the separation claw 36 separates the sheet adsorbed on the platen roller 35, and the separated sheet slides on the upper surface of the separation claw 36 and is discharged to the sheet discharge tray 37. Be loaded.
[0057]
When the image formation is not completed, the peeling claw 36 and the paper guide plate 34 rotate so that the lower surface of the other end that is not pivotally supported is separated from the rotating platen roller 35. At this time, the sheet adsorbed on the platen roller 35 passes below the peeling claw 36 and above the paper guide plate 34 and is again supplied to the serial head 21 and the line head 22 again.
In the above case, when an image is formed in one pass, the paper on the platen roller 35 is supplied to the serial head unit 21 and the line head unit 22 only once in the paper feeding unit 3, and the paper is released from the peeling claw 36. Do not pass underneath. Further, when an image is formed by a plurality of passes (for example, J passes), the paper on the platen roller 35 is supplied J times to the serial head unit 21 and the line head unit 22 and the lower side of the peeling claw 36 is moved to (J− 1) Pass once.
[0058]
In the image forming unit 2, movement / stop of the head carriage 23 and ejection / stop of ink from the nozzles are configured to be controlled by the CPU 10.
At the time of monochrome printing, only the line head 22K is used, and when continuously forming an image on a small number of sheets of a predetermined number (hereinafter, referred to as a first predetermined number) or less, the image forming unit 2 performs one pass. An image is formed in an image forming area (image forming areas D1 to D4) corresponding to the recording width B2 of the line head 22K at the maximum. That is, when forming an image in one pass, the line head 22K is controlled such that all 4,800 nozzles at maximum eject ink.
[0059]
Further, when the number of continuous image formation exceeds the first predetermined number during monochrome printing, when forming an image on a predetermined number of sheets (hereinafter, referred to as a second predetermined number) or less that is larger than the first predetermined number, The image forming section 2 has four passes, each of which includes image forming areas (image forming areas D1, D2,..., D4) corresponding to a maximum of 1/4 of the recording width B2 of the line head 22K per one of the four passes. When the number of image formation exceeds the second predetermined number, an image is formed again in one pass. That is, when forming an image in four passes, the line head 22K has a part (a part corresponding to the image forming areas D1, D2,..., D4) divided into four equal parts in the recording width direction. The nozzle is controlled to eject ink. Hereinafter, nozzles corresponding to the image forming area D1 (image forming areas D2,..., D4) are referred to as nozzles in the first pass (second pass,..., Fourth pass).
[0060]
The first predetermined number and the second predetermined number are respectively the number of the line heads 22K that generate heat at or above a predetermined temperature by continuous image formation in one pass, and the number of line heads 22K by the image formation in four passes. This is the number of sheets to be cooled to a predetermined temperature lower than the above-mentioned temperature or lower.
[0061]
At the time of full-color printing, the serial heads 21C, 21M, 21Y and the line head 22K are used simultaneously, and an image is formed in a maximum of four passes (hereinafter, referred to as four passes). In this case, each of the serial heads 21C, 21M, and 21Y is controlled such that all 1200 nozzles eject ink at maximum per pass, and the line head 22K is divided into four parts (maximum) in the recording width direction. Are controlled to eject ink. That is, at the time of full-color printing, ink is ejected from a maximum of 4800 (= 1200 × 3 + 1200) nozzles per pass.
[0062]
The serial head unit 21 normally stops on the image forming area D1 corresponding to the recording width B1 of the serial heads 21C, 21M, and 21Y (hereinafter, referred to as the position of the first pass). Is formed, first, an image is formed on the image forming area D1. Next, the serial head unit 21 is moved in the main scanning direction along the slide shaft 24 by the head carriage 23, and is moved over the image forming area D2 corresponding to the recording width B1 adjacent to the image forming area D1 (hereinafter, the second pass). , The image is formed in the image forming area D2.
[0063]
Similarly, the serial head unit 21 is intermittently moved in the main scanning direction along the slide shaft 24 by the head carriage 23, and is moved above the image forming area D3 corresponding to the recording width B1 adjacent to the image forming area D2 (3 pass). (The position of the eyes) and the image forming area D4 corresponding to the recording width B1 adjacent to the image forming area D3 (the position of the fourth pass), and then forming an image on the image forming areas D3 and D4. .
Finally, the serial head unit 21 is continuously moved by the head carriage 23 along the slide shaft 24 in the direction opposite to the main scanning direction, and stops at the position of the first pass.
When the serial head unit 21 stops at the position of the i-th pass (i is a natural number of 1 to 4) and forms an image, the line head unit 22 ejects ink from the nozzle of the i-th pass of the line head 22K. Make an image.
[0064]
When performing full-color printing, the CPU 10 detects image data stored in the image memory 16 and determines whether or not to form an image in each of the image forming areas D1, D2,..., D4.
When an image is not formed in an image forming area corresponding to the i-th pass (1 ≦ i <4) (hereinafter referred to as an “i-th pass area”), the serial head unit 21 does not stop at the position of the i-th pass. And (2) stop at the position of the pass, and the serial head unit 21 and the line head unit 22 form an image in the image area corresponding to the position of the (i + 1) th pass. When an image is not formed in the image forming area corresponding to the fourth pass, the serial head unit 21 moves to the position of the first pass and stops, and the serial head unit 21 and the line head unit 22 do not form an image. At this time, the sheet on the platen roller 35 is discharged to the discharge tray 37.
[0065]
For example, when an image is not formed only in the image forming area D3 corresponding to the third pass, the serial head unit 21 stops at the positions of the first pass, the second pass, and the fourth pass to form an image. In this case, the sheet on the platen roller 35 is supplied to the serial head unit 21 and the line head unit 22 only three times (image formation in three passes).
When an image is formed in four passes during monochrome printing, it is determined whether or not an image is to be formed in each of the image forming areas D1, D2,..., D4. The image forming area where no image is formed may be skipped, and the image may be formed and discharged in three or less passes.
[0066]
FIG. 4 is a flowchart illustrating a procedure of a full-color image forming process of the image forming apparatus 1.
When image data is stored in the image memory 16, the CPU 10 detects the image data stored in the image memory 16 and determines whether or not to form an image in each of the image forming areas D1, D2,. Is determined, and the determination result is stored in the RAM 12 (S11).
[0067]
Next, the CPU 10 controls the paper supply unit 3 to supply the paper stacked on the paper supply tray 31 to the platen roller 35 using the pickup roller 32, the paper supply roller unit 33, and the paper guide plate 34. (S12). In this case, the sheet vacuum-adsorbed to the platen roller 35 is supplied to the image forming unit 2 as the platen roller 35 rotates. However, the sheet does not arrive below the serial head unit 21 until the serial head unit 21 stops at the position where an image is to be formed in the process of S16 described later.
The CPU 10 sets the variable i = 1 (S13).
[0068]
Next, the CPU 10 determines whether or not the variable i is 4 or less (S14). If the variable i is 4 or less (YES in S14), the i-th pass area (for example, if i = 1, the image forming area When the image is formed in D1), it is determined whether or not the image is stored in the RAM 12 (S15). When the image is formed (YES in S15), the serial head 21 is moved to the position of the i-th pass. It is moved and stopped (S16). However, when i = 1, the serial head unit 21 has already stopped at the position of the first pass, and thus the CPU 10 stops the serial head unit 21 without moving it.
[0069]
The CPU 10 controls the paper feed unit 3 to supply the paper vacuum-adsorbed to the platen roller 35 to the serial head unit 21 and the line head unit 22 using the paper guide plate 34 and / or the peeling claw 36. (S17).
When the sheet is supplied to the serial head unit 21 with the rotation of the platen roller 35, the CPU 10 causes the serial head unit 21 to form an image in the i-th pass area (S18). When the paper is supplied to the line head unit 22, the CPU 10 causes the line head unit 22 to form an image in the i-th pass area with the i-th pass nozzle (S19). Whether or not the paper has been supplied to each head unit is determined, for example, by the elapsed time after the paper has passed through the paper guide plate 34.
[0070]
If an image is not to be formed in the i-th pass area in the RAM 12 (NO in S15), or after the process of S19 is completed, the CPU 10 adds 1 to a variable i (S21), and proceeds to S14. Then, it is determined whether or not the variable i is 4 or less.
When the variable i is 5 or more (NO in S14), the CPU 10 moves the serial head unit 21 to the position of the first pass and stops it (S22). However, when the serial head unit 21 is stopped at the position of the first pass, the CPU 10 stops the serial head unit 21 without moving it.
[0071]
Finally, the CPU 10 controls the paper feed unit 3 to discharge the sheet vacuum-adsorbed to the platen roller 35 to the sheet discharge tray 37 using the peeling claw 36 (S23). In this case, the CPU 10 determines whether or not to form an image on another sheet. When forming an image, the CPU 10 performs the processing of S11 to S23 on a new sheet stacked on the sheet feed tray 31. If the image is not to be formed on another sheet, the full-color image forming process ends.
[0072]
FIG. 5 and FIG. 6 are flowcharts showing the procedure of the monochrome image forming process of the image forming apparatus 1.
The CPU 10 sets the variable h = 0 (S31).
Next, the CPU 10 controls the paper feed unit 3 to supply the paper stacked on the paper feed tray 31 to the platen roller 35 using the pickup roller 32, the paper feed roller unit 33, and the paper guide plate 34. (S32). In this case, the sheet vacuum-adsorbed to the platen roller 35 is supplied to the image forming unit 2 as the platen roller 35 rotates.
The CPU 10 adds 1 to the variable h (S33).
[0073]
Next, the CPU 10 determines whether or not to form a pixel in one pass by determining whether or not the variable h is equal to or less than a first predetermined number (S34), and h ≦ the first predetermined number (S34). That is, when pixels are formed in one pass) (YES in S34), the sheet vacuum-adsorbed to the platen roller 35 is supplied to the line head unit 22 (S35).
When the sheet is supplied to the line head unit 22 with the rotation of the platen roller 35, the CPU 10 causes the line head unit 22 to form an image (S36). The CPU 10 determines whether or not the sheet has been supplied to each head unit, for example, based on an elapsed time after the sheet has passed the paper guide plate 34.
[0074]
Finally, the CPU 10 controls the paper feed unit 3 to discharge the sheet vacuum-adsorbed to the platen roller 35 to the sheet discharge tray 37 by using the peeling claw 36 (S37). It is determined whether or not an image is to be formed (S38). If an image is to be formed (YES in S38), the process returns to S32, and the process returns to S32 for new sheets stacked on the paper feed tray 31. If the processes of S38 to S38 are performed and an image is not formed on another sheet (NO in S38), the monochrome image forming process ends.
[0075]
If the variable h exceeds the first predetermined number (that is, an image is formed by four passes) (NO in S34), the CPU 10 sets the variable i = 1 (S51).
Next, the CPU 10 determines whether or not the variable i is equal to or less than 4 (S52), and when it is equal to or less than 4 (YES in S52), the CPU 10 controls the sheet feeding unit 3 to apply a vacuum to the platen roller 35. The adsorbed paper is supplied to the line head unit 22 using the paper guide plate 34 and / or the peeling claw 36 (S53). In this case, the supply of the paper to the line head unit 22 is the i-th supply.
When the sheet is supplied to the line head unit 22 with the rotation of the platen roller 35, the CPU 10 causes the line head unit 22 to form an image in the i-th pass area with the i-th pass nozzle (S54). The CPU 10 determines whether or not the sheet has been supplied to each head unit, for example, based on an elapsed time after the sheet has passed the paper guide plate 34.
[0076]
Next, the CPU 10 adds 1 to the variable i (S55), returns the process to S52, and determines whether the variable i is 4 or less.
When the variable i is 5 or more (NO in S52), the CPU 10 controls the sheet feeding unit 3 to transfer the sheet vacuum-adsorbed to the platen roller 35 to the sheet discharge tray 37 using the peeling claw 36. The image is discharged (S56), and it is determined whether or not an image is to be formed on another sheet (S57). If no image is to be formed on another sheet (NO in S57), the monochrome image forming process ends.
[0077]
When forming an image on another sheet (YES in S57), the CPU 10 determines whether or not the variable h is equal to or smaller than a second predetermined number (whether or not to form an image in four passes) (S58).
If the variable h is equal to or smaller than the second predetermined number (images are formed in four passes) (YES in S58), the CPU 10 returns the processing to S32 and executes processing for new sheets stacked on the sheet feeding tray 31. Then, the processes of S32 to S58 are performed. If the variable h is less than or equal to the second predetermined number (the image is formed in one pass) (NO in S58), the CPU 10 returns the processing to S31 and is loaded on the paper feed tray 31. The processing of S31 to S38 is performed on the new sheet.
[0078]
In the image forming apparatus 1 as described above, the color ink ejected from the serial heads 21C, 21M, and 21Y of the serial head unit 21 is applied to the sheet by the time the sheet is supplied to the line head unit 22 at the time of full-color printing. Since the ink is absorbed and dried, even when the ink is ejected from the line head 22K so as to come into contact with the color ink on the paper, it is possible to prevent the respective inks from being mixed on the paper and deteriorating the image quality. I have.
In addition, since the recording width direction of the serial head unit 21 is arranged so as to be substantially coincident with the main scanning direction, the size of the head carriage 23 in the sheet feeding direction is smaller than that of the conventional one.
[0079]
Further, the power supply capacity of the power supply 18 provided in the image forming apparatus 1 has a power supply capacity that is 1.2 times the power supply capacity necessary for frequently performing monochrome printing. The image forming apparatus 1 does not have an excessively high performance power supply because the power supply capacity is necessary for full-color printing that is not performed frequently. As a result, the cost of the image forming apparatus 1 is reduced. In addition, of the four heads required for full-color printing, three are constituted by serial heads and only one line head is used, so that the cost of the image forming apparatus 1 is reduced.
[0080]
In the case where an image is formed in one pass using only the line head unit 22 during monochrome printing, the image forming apparatus 1 has improved the image forming speed.
Further, when forming a large number of images continuously during monochrome printing, image formation in one pass at a high image forming speed and image formation in four passes in which the temperature rise of the line head 22K is suppressed are considered. Since the image formation is performed alternately according to the number of formed images, the image forming apparatus 1 achieves both improvement of the image forming speed and prevention of the heating of the line head 22K.
Furthermore, since the serial head unit 21 is not moved or stopped to a position corresponding to a region where no image is formed, the image forming apparatus 1 improves the image forming speed during full-color printing.
[0081]
Embodiment 2.
In the present embodiment, an image forming apparatus corresponding to the image forming apparatus 1 of the first embodiment is used. Therefore, the same reference numerals are given to portions corresponding to the first embodiment, and description thereof will be omitted.
[0082]
FIG. 7 is a schematic diagram illustrating a procedure of a full-color image forming process of the image forming apparatus according to Embodiment 2 of the present invention.
In the case of forming an image in all of the image forming areas D1 to D4 at the time of full-color printing, in the first embodiment, the serial head 21 and the line head 22 are placed in the image forming area D1 in the first pass and the second pass. The image is formed in the image forming area D2 in the pass,... In the image forming area D4 in the fourth pass. That is, for one pass, the serial head unit 21 and the line head unit 22 form an image in the same image forming area.
[0083]
In the present embodiment, when images are formed in all of the image forming areas D1 to D4 at the time of full color printing, the serial head unit 21 moves the image forming area D1 (1) at the position of the first pass in the first pass P1. In the pass area), the line head unit 22 forms an image in the image forming area D3 (third pass area) using the nozzles in the third pass. Next, in the second pass P2, the serial head unit 21 is in the image forming area D2 (the area of the second pass) at the position of the second pass, and the line head unit 22 is in the image forming area D4 (the nozzle of the fourth pass). An image is formed in each of the areas of the fourth pass).
[0084]
Further, in the third pass P3, the serial head unit 21 is in the image forming area D3 (the third pass area) at the position of the third pass, and the line head unit 22 is in the image forming area D1 ( An image is formed in the first pass area). Finally, in the fourth pass P4, the serial head 21 is placed in the image forming area D4 (the fourth pass area) at the position of the fourth pass, and the line head 22 is placed in the image forming area D2 with the nozzles of the second pass. An image is formed in each (the area of the second pass).
[0085]
FIG. 8 is a flowchart illustrating a procedure of a full-color image forming process of the image forming apparatus.
The CPU 10 controls the paper supply unit 3 to supply the paper stacked on the paper supply tray 31 to the platen roller 35 using the pickup roller 32, the paper supply roller unit 33, and the paper guide plate 34 (S71). ). In this case, the sheet vacuum-adsorbed to the platen roller 35 is supplied to the image forming unit 2 as the platen roller 35 rotates. However, the sheet does not arrive below the serial head unit 21 until the serial head unit 21 stops at the position where an image is to be formed in the process of S74 described below.
The CPU 10 sets the variable i = 1 (S72).
[0086]
Next, the CPU 10 determines whether or not the variable i is 4 or less (S73), and when it is 4 or less (YES in S73), moves the serial head unit 21 to the position of the i-th pass and stops it ( S74). However, when i = 1, the serial head unit 21 has already stopped at the position of the first pass, and thus the CPU 10 stops the serial head unit 21 without moving it.
The CPU 10 controls the paper feed unit 3 to supply the paper vacuum-adsorbed to the platen roller 35 to the serial head unit 21 and the line head unit 22 using the paper guide plate 34 and / or the peeling claw 36. (S75).
[0087]
When the sheet is supplied to the serial head unit 21 with the rotation of the platen roller 35, the CPU 10 causes the serial head unit 21 to form an image in the i-th pass area (S76).
The CPU 10 sets the variable I = i + 2 (S77), determines whether the variable I is 4 or less (S78), and if it is 5 or more (NO in S78), subtracts 4 from the variable I (S78). S79).
After completion of the process in S79, or when the variable I is 4 or less (YES in S78), when the sheet is supplied to the line head unit 22 with the rotation of the platen roller 35, the CPU 10 Next, an image is formed in the region of the I-pass by the nozzle of the I-pass (S81). The CPU 10 determines whether or not the sheet has been supplied to each head unit, for example, based on an elapsed time after the sheet has passed the paper guide plate 34.
[0088]
After the process of S81 is completed, the CPU 10 adds 1 to the variable i (S82), returns the process to S73, and determines whether the variable i is 4 or less.
When the variable i is 5 or more (NO in S73), the CPU 10 moves the serial head unit 21 to the position of the first pass and stops it (S83).
Finally, the CPU 10 controls the paper feed unit 3 to discharge the paper vacuum-sucked on the platen roller 35 to the paper discharge tray 37 using the peeling claw 36 (S84). In this case, the CPU 10 determines whether or not to form an image on another sheet, and when forming an image, performs the processes of S71 to S84 on a new sheet stacked on the paper feed tray 31. If the image is not to be formed on another sheet, the full-color image forming process ends.
[0089]
In the image forming apparatus as described above, the serial head unit 21 and the line head unit 22 do not form an image in the same image forming area in one pass, and one head unit is formed in the same image forming area. After two passes (e.g., about two rotations of the platen roller 35) after forming the image, the other head unit forms the image. Therefore, the ink ejected from each of the serial heads 21C, 21M, and 21Y (or the line head 22K) is absorbed by the sheet before the sheet is supplied to the line head unit 22 (or the serial head unit 21), and the ink is completely absorbed. Even when the ink is ejected from the line head 22K (or the serial heads 21C, 21M, 21Y) so as to come into contact with the ink on the paper, each ink is mixed on the paper and the image quality is reduced. Deterioration is prevented. In this case, since the image formation does not require five or more passes, the image formation speed does not decrease.
[0090]
Further, since the serial head unit 21 and the line head unit 22 do not form an image in the same image forming area for one pass, the distance between the serial head unit 21 and the line head unit 22 is Even if the distance is less than the product of the time required for the color ink ejected onto the paper by the serial head unit 21 to be absorbed by the paper and dried, and the rotation speed of the peripheral surface of the platen roller 35. good. That is, the size of the image forming unit 2 is reduced.
[0091]
Embodiment 3.
In the present embodiment, an image forming apparatus corresponding to the image forming apparatus 1 or 2 of the first embodiment is used. Therefore, the same reference numerals are given to portions corresponding to the first or second embodiment, and the description thereof will be omitted.
FIG. 9 is a schematic diagram illustrating a procedure of a full-color image forming process of the image forming apparatus according to Embodiment 3 of the present invention.
In the case of forming an image in all of the image forming areas D1 to D4 during full-color printing, the image is formed in four passes in the first or second embodiment. However, in the present embodiment, the image is formed in five passes. To form
[0092]
In this case, in the first pass P1, the serial head unit 21 forms an image in the image forming area D1 (the area of the first pass) at the position of the first pass, and the line head unit 22 does not form an image.
Next, in the second pass P2, the serial head unit 21 is in the image forming area D2 (the area of the second pass) at the position of the second pass, and the line head unit 22 is in the image forming area D1 (the nozzle of the first pass). An image is formed in the first pass area). Further, in the third pass P3, the serial head unit 21 is in the image forming area D3 (the third pass area) at the position of the third pass, and the line head unit 22 is in the image forming area D2 ( In the second pass area), an image is formed.
[0093]
Next, in the fourth pass P4, the serial head unit 21 is placed in the image forming area D4 (the fourth pass area) at the position of the fourth pass, and the line head unit 22 is placed in the image forming area D3 ( In the third pass area), an image is formed.
Finally, in the fifth pass P5, the serial head unit 21 does not form an image, and the line head unit 22 forms an image in the image forming area D4 (fourth pass area) using the fourth pass nozzles.
[0094]
FIG. 10 is a flowchart illustrating a procedure of a full-color image forming process of the image forming apparatus.
The CPU 10 controls the paper supply unit 3 to supply the paper stacked on the paper supply tray 31 to the platen roller 35 using the pickup roller 32, the paper supply roller unit 33, and the paper guide plate 34 (S91). ). In this case, the sheet vacuum-adsorbed to the platen roller 35 is supplied to the image forming unit 2 as the platen roller 35 rotates. However, the sheet does not arrive below the serial head unit 21 until the serial head unit 21 stops at the position where an image is to be formed in the process of S95 described later.
The CPU 10 sets the variable i = 1 (S92).
[0095]
Next, the CPU 10 determines whether or not the variable i is 5 or less (S93), and if it is 4 or less (YES in S93), determines whether or not the variable i is 5 (S94). Is less than or equal to 4 (NO in S94), the serial head 21 is moved to the position of the i-th pass and stopped (S95). However, when i = 1, the serial head unit 21 has already stopped at the position of the first pass, and thus the CPU 10 stops the serial head unit 21 without moving it.
The CPU 10 controls the paper feed unit 3 to supply the paper vacuum-adsorbed to the platen roller 35 to the serial head unit 21 and the line head unit 22 using the paper guide plate 34 and / or the peeling claw 36. (S96).
[0096]
When the sheet is supplied to the serial head unit 21 with the rotation of the platen roller 35, the CPU 10 causes the serial head unit 21 to form an image in the i-th pass area (S97).
The CPU 10 sets the variable I = i−1 (S98), then determines whether or not the variable I is 0 (S99). If the variable I is 1 or more (NO in S99), the CPU 10 determines whether the variable I is greater than 1 (S99). When the paper is supplied to the line head unit 22, the line head unit 22 causes the nozzles of the I pass to form an image in the area of the I pass (S101). The CPU 10 determines whether or not the sheet has been supplied to each head unit, for example, based on an elapsed time after the sheet has passed the paper guide plate 34.
[0097]
After completion of the process in S101, or when I is 0 (YES in S99), the CPU 10 adds 1 to the variable i (S102), returns the process to S93, and determines whether the variable i is 5 or less. Is determined.
If the variable i is 5 (YES in S94), the CPU 10 moves the serial head unit 21 to the position of the first pass and stops it (S103), and controls the sheet feeding unit 3 to control the platen roller 35. Is supplied to the serial head unit 21 and the line head unit 22 using the paper guide plate 34 and / or the peeling claw 36 (S104), and the process proceeds to S98.
[0098]
If the variable i is equal to or greater than 6 (NO in S93), the CPU 10 controls the paper feed unit 3 to transfer the sheet vacuum-adsorbed to the platen roller 35 to the discharge tray 37 using the peeling claw 36. It is discharged (S105). In this case, the CPU 10 determines whether or not to form an image on another sheet. When forming an image, the CPU 10 performs the processes of S91 to S105 on a new sheet stacked on the sheet feed tray 31. If the image is not to be formed on another sheet, the full-color image forming process ends.
As described above, when I = 0 (first pass), the process of S101 which is the image forming process by the line head unit 22 is not performed, and when i = 5 (fifth pass), the image forming process by the serial head unit 21 is performed. The process of S97, which is the process, is not performed.
[0099]
In the image forming apparatus as described above, the serial head unit 21 and the line head unit 22 do not form an image in the same image forming area in one pass, and the serial head unit 21 does not form an image in the same image forming area. The line head unit 22 forms an image after a time corresponding to one pass (about one rotation of the platen roller 35) has elapsed since the image formation. For this reason, the color ink ejected from the serial heads 21C, 21M, and 21Y is absorbed by the paper and completely dried before the paper is supplied to the line head unit 22, and comes into contact with the ink on the paper. As described above, even when ink is ejected from the line head 22K, it is possible to prevent the inks from being mixed on the paper and from deteriorating the image quality.
[0100]
Embodiment 4.
In this embodiment, an image forming apparatus corresponding to the image forming apparatus 1 of the first embodiment includes a line head unit 50 instead of the line head unit 22. In the present embodiment, at the time of monochrome printing, an image is formed in four passes for all the image forming areas D1 to D4 using all the nozzles of the line head 22K at the maximum.
In addition, the same reference numerals are given to portions corresponding to the first embodiment, and description thereof will be omitted.
[0101]
FIG. 11 is a side view illustrating a configuration of a line head unit 50 provided in an image forming apparatus according to Embodiment 4 of the present invention.
The line head unit 50 moves the line head 22K arranged so as to substantially coincide with the main scanning direction (the direction of the white arrow in the drawing) in the main scanning direction by 1/600 (reciprocal of 600 DPI which is the dot pitch of the line head 22K). ) A cam 51 and a spring 52 are provided for swinging by inches.
The cam 51 is provided so that the radius continuously increases from the minimum radius to the maximum radius, and is provided such that the cam 51 makes one rotation in the arrow direction from the minimum radius to the maximum radius for every four rotations of the platen roller 35. I have. The difference between the maximum radius and the minimum radius is 1/600 inch.
[0102]
One end of the line head 22 </ b> K contacts the peripheral surface of the cam 51, and the other end is supported by the spring 52. The spring 52 presses the line head 22K against the cam 51 with a predetermined pressure.
In the image forming unit 2, rotation / stop of the cam 51 and ejection / stop of ink from the nozzles are configured to be controlled by the CPU 10.
At the time of monochrome printing, only the line head 22K is used, and the line head 22K is controlled such that all 4,800 nozzles at maximum eject ink in one pass.
[0103]
In the case described above, the line head 22K rotates 1/600/4 inch, that is, 1/600 of the rotation of the cam 51 per one rotation (that is, one pass) of the platen roller 35 due to the change in the radius of the cam 51. The spring 52 is compressed by moving from the cam 51 side to the spring 52 side by 2400 inches. For this reason, the position of the nozzle in the (i + 1) -th pass is shifted by 1/2400 inch in the main scanning direction as compared with the position in the i-th pass (1 = 1, 2, 3, 3).
Then, at the end of the fourth rotation of the platen roller 35, the line head 22K is moved by the spring 52 by 1/600 inch from the spring 52 side to the cam 51 side. As described above, the line head 22K swings 1/600 inch in the main scanning direction.
[0104]
In the image forming apparatus described above, the line head 22K swings 1/600 inch in the main scanning direction by the cam 51 and the spring 52 in accordance with the rotation of the platen roller 35. It has a dot pitch of 2400 DPI, four times the dot pitch of 600 DPI. That is, an image having a resolution four times as high as an image formed in one pass by using the line head 22K can be obtained.
Note that each serial head of the serial head unit 21 may also be configured to swing 1/600 inch in the main scanning direction and obtain an image of 2400 DPI in 16 passes.
[0105]
Embodiment 5.
In the present embodiment, an image forming apparatus corresponding to the image forming apparatus 1 of the first embodiment includes a paper feed unit 4 instead of the paper feed unit 3. In addition, the same reference numerals are given to portions corresponding to the first embodiment, and description thereof will be omitted.
FIG. 12 is a side view illustrating a configuration of a recording unit 17 (the image forming unit 2 and the sheet feeding unit 4 of the recording unit 17) included in the image forming apparatus according to Embodiment 5 of the present invention.
The paper supply unit 4 includes a paper supply tray 41 disposed at one end in the left and right direction in a side view of the image forming apparatus, and a paper discharge tray 47 disposed at the other end. Each tray is substantially rectangular in plan view. Further, the paper feed unit 4 includes a pickup roller (call-in roller) 42 disposed at a downstream end of the paper feed tray 41 in the paper feed direction (the direction indicated by the white arrow in the drawing).
[0106]
Further, the paper feeding unit 4 includes an electrostatic attraction belt 45 disposed at a central portion of the image forming apparatus in the lateral direction when viewed from the side. The electrostatic attraction belt 45 is formed by forming a conductive synthetic rubber into an endless belt, and is disposed on the downstream side in the paper supply direction of the paper supply tray 41 and on the upstream side in the paper supply direction of the paper discharge tray 47, respectively. It is stretched over two rollers 441 and 442. The electrostatic attraction belt 45 rotates in the white arrow direction with the rotation of the roller 441 in the arrow direction. The paper feed tray 41, the paper discharge tray 47, and the upper surface of the electrostatic attraction belt 45 are arranged on substantially one plane.
[0107]
Further, the paper supply unit 4 includes a paper supply roller unit 43 between the pickup roller 42 and the upper surface of the electrostatic attraction belt 45, and a separation claw between the upper surface of the electrostatic attraction belt 45 and the paper discharge tray 47. 46 is provided. The serial head unit 21, the head carriage 23, the slide shaft 24, and the line head unit 22 are spaced apart from each other above the upper surface of the electrostatic attraction belt 45 between the paper feed roller unit 43 and the peeling claw 46. Have been.
[0108]
The pickup roller 42 has a sector shape when viewed from the side, the feed roller unit 43 includes two feed rollers that are in contact with each other, the electrostatic attraction belt 45 is supplied with power from the power supply 18, and the peeling claw 46 is One end on the downstream side in the sheet feeding direction, which is spaced apart from the electro attraction belt 45, is pivotally supported and rotatably provided. The one end is spaced apart from the electrostatic attraction belt 45, and the other end contacts or separates from the electrostatic attraction belt 45 according to the rotation of the peeling claw 46.
[0109]
In the paper feed unit 4, the rotation / stop of each of the pickup roller 42, the paper feed roller unit 43, and the roller 441, and the rotation / stop of the peeling claw 46 are controlled by the CPU 10.
When an image is formed, sheets are stacked on the paper feed tray 41 by the user, the pickup roller 42, the paper feed roller unit 43, and the roller 441 rotate, and further, the electrostatic attraction roller 45 rotates. The rotating pickup roller 42 calls the paper loaded on the paper feed tray 41 toward the paper feed roller unit 43, and the paper feed roller unit 33 selectively quiets one of the called papers. It is supplied to the electro attraction belt 45.
[0110]
The electrostatic attraction belt 45 electrostatically attracts the supplied paper by the power from the power supply 18, supplies the supplied paper to the lower side of the serial head 21, and then supplies the paper to the lower side of the line head 22. It is supplied to the peeling nail 46.
When the image formation is completed, the peeling claw 46 rotates so that the lower surface of the other end that is not pivotally supported contacts the rotating electrostatic attraction belt 45. At this time, the peeling claw 46 peels the sheet adsorbed on the electrostatic attraction belt 45, and the peeled sheet is discharged to the discharge tray 47 while sliding on the upper surface of the peeling claw 46, and is discharged to the discharge tray 47. 47. When the image formation is not completed, the peeling claw 46 rotates so that the lower surface of the other end that is not pivotally supported is separated from the rotating electrostatic attraction belt 45. At this time, the sheet adsorbed on the electrostatic adsorption belt 45 passes below the peeling claw 46 and is again supplied to the serial head unit 21 and the line head unit 22 in order.
[0111]
Similarly to the image forming apparatus 1 according to the first embodiment, the image forming apparatus as described above prevents the image quality from deteriorating due to the mixing of the inks on the paper and the power supply and the plurality of lines having excessive performance. Since the head is not provided, the cost of the apparatus is reduced.
[0112]
【The invention's effect】
According to the image forming apparatus of the present invention, the two head units are spaced apart in the paper supply direction, so that the recording material ejected from the head unit arranged on the upstream side in the paper supply direction, Since the recording agent ejected from the head portion disposed on the downstream side does not mix colors on the paper, the image quality of the image can be improved.
In addition, a line head unit and a movable serial head unit are provided, and a recording agent used for image formation that is frequently performed is ejected to the line head unit, so that the line head unit is used for image formation. It is not necessary to make a reciprocating movement, and the image formation is usually completed in one pass, so that the image formation speed of the image formation can be improved.
[0113]
Further, when performing image formation that requires a multicolor recording material, a large number of line heads corresponding to the multicolor recording material can be formed by performing image formation using both the serial head unit and the line head unit. Since the power supply capacity is smaller than that of the image forming apparatus using the head unit, and an inexpensive serial head can be used, the image forming apparatus can be configured at low cost.
In addition, by arranging the recording width direction of the line head unit and the serial head unit so as to substantially coincide with the main scanning direction, the size of the carriage unit for moving the serial head unit in the sub-scanning direction can be made smaller than that of the related art. be able to.
[0114]
In addition, N serial heads have N serial heads, and the total number of nozzles is S serial head units, so that N, S, and K follow the equation α × K / (N + 1) ≧ S / N, α ≧ 1, It has one line head, and has a line head section with K nozzles. As a result, the power consumed when forming an image using the line head and the serial head is approximately α times the power consumed when forming an image using only the line head. For this reason, the image forming apparatus can be provided with a power source having necessary and sufficient performance.
Also, by using only one line head, the image forming apparatus can be configured at a lower cost than when a plurality of line heads are used.
[0115]
When an image is formed using only the line head unit, the user selects between forming an image in one pass or forming an image in a plurality of passes. Since the same sheet is supplied once to the sheet forming unit and an image is formed using all the nozzles corresponding to the sheet width among the nozzles of the line head of the line head unit, the image forming speed can be improved. it can. When an image is formed in a plurality of passes, the same sheet is supplied to the line head unit a plurality of times, and when the sheet is supplied once, the sheet width of the nozzles of the line head of the line head unit is changed. Since an image is formed by using some of the nozzles obtained by dividing the total number of nozzles corresponding to a plurality of nozzles, an excessive rise in temperature of the line head can be suppressed.
[0116]
Further, the time taken for the head disposed on the upstream side in the supply direction to dry on the paper or the time taken for absorption by the paper depends on the drying time or absorption of the recording agent ejected from the head disposed on the downstream side. By ejecting the recording agent faster than the time, even if the two heads eject the recording agents having different drying times or absorption times, it is possible to further prevent each recording agent from mixing on the paper. Therefore, the image quality of the image can be improved.
[0117]
Further, using the serial head portion, an image is formed in a partial area of the sheet corresponding to the recording width of the serial head, and the other part of the line head portion which is different from the partial area of the line head has Using a nozzle corresponding to the region, an image is formed in the other region. As a result, the area of the paper on which the serial head forms an image in one pass is always different from the area of the paper on which the line head forms an image in one pass. Furthermore, it can be prevented. As a result, the image quality of the image can be improved.
[0118]
Further, an image is formed in a partial area of the sheet corresponding to the recording width of the serial head by using the serial head unit, and at the same time, the line head unit does not form an image. Alternatively, using a line head unit, an image is formed in the partial area by using a nozzle corresponding to a partial area of the paper corresponding to the recording width of the serial head, and at the same time, a line head is formed. The set does not form an image. As a result, since the area of the sheet on which the serial head unit forms an image in one pass does not match the area of the sheet on which the line head unit forms an image, each recording agent is mixed on the sheet. Furthermore, it can be prevented. As a result, the image quality of the image can be improved.
[0119]
When an image is formed using two head units, the serial head is not moved and stopped at a position corresponding to an area where an image is not formed, so that the serial head is moved only to a position corresponding to an area where an image is formed. Since the head is moved and stopped, and an image is formed using two head units in the area, an image forming speed can be improved when an image is formed using two head units.
Further, by swinging the head in the main scanning direction, an image having a higher resolution than the resolution corresponding to the pitch of the nozzles provided in the head can be formed. The present invention has excellent effects, for example, such that a high-resolution image can be formed without using a head having a nozzle pitch substantially equal to the above (a head having a low yield).
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of an image forming apparatus according to Embodiment 1 of the present invention.
FIG. 2 is a side view illustrating a configuration of a recording unit included in the image forming apparatus according to Embodiment 1 of the present invention.
FIG. 3 is a top view illustrating a configuration of a recording unit included in the image forming apparatus according to Embodiment 1 of the present invention.
FIG. 4 is a flowchart illustrating a procedure of a full-color image forming process of the image forming apparatus according to the first embodiment of the present invention.
FIG. 5 is a flowchart illustrating a procedure of a monochrome image forming process of the image forming apparatus according to the first embodiment of the present invention.
FIG. 6 is a flowchart illustrating a procedure of a monochrome image forming process of the image forming apparatus according to the first embodiment of the present invention.
FIG. 7 is a schematic diagram showing a procedure of a full-color image forming process of the image forming apparatus according to Embodiment 2 of the present invention.
FIG. 8 is a flowchart illustrating a procedure of a full-color image forming process of the image forming apparatus according to the second embodiment of the present invention.
FIG. 9 is a schematic diagram showing a procedure of a full-color image forming process of the image forming apparatus according to Embodiment 3 of the present invention.
FIG. 10 is a flowchart illustrating a procedure of a full-color image forming process of the image forming apparatus according to Embodiment 3 of the present invention.
FIG. 11 is a side view illustrating a configuration of a line head unit included in an image forming apparatus according to Embodiment 4 of the present invention.
FIG. 12 is a side view illustrating a configuration of a recording unit included in an image forming apparatus according to Embodiment 5 of the present invention.
[Explanation of symbols]
10 CPU
11 ROM
21 Serial head
21C, 21M, 21Y serial head
22 line head
22K line head
23 Head carriage
24 slide shaft
35 Platen roller
45 Electrostatic suction belt
51 cams
52 spring

Claims (10)

In an image forming apparatus including a head unit having one or a plurality of heads for forming an image on a supplied recording sheet with a recording agent,
An image forming apparatus, wherein two head units are spaced apart in a recording sheet supply direction, and one of the head units is provided so as to be movable in a direction intersecting the supply direction. In each head, a plurality of nozzles for ejecting a recording agent are juxtaposed in a direction intersecting the supply direction, and the length of the head juxtaposition direction of the one head unit is equal to that of the other head unit. The image forming apparatus according to claim 1, wherein the length of the head is shorter than a length of the head in the nozzle arrangement direction. The one head has N (N is a natural number) heads, the total number of nozzles is S (S is a natural number of 2 or more), and the other head is K (K is a natural number). 3. The image forming apparatus according to claim 2, further comprising one head having two or more (natural numbers) nozzles, wherein the number N, the number S, and the number K are defined by Expression (1). 4.
α × K / (N + 1) ≧ S / N (1)
α: coefficient of 1 or more. Supply means for supplying the same recording sheet once or multiple times to each head unit;
When forming an image using only the other head unit, a means for selecting whether to form an image in one recording scan or to form an image in a plurality of recording scans,
As a result of the selection, when an image is formed by one recording scan, the supply unit supplies the same recording sheet once to the other head unit, and the other head unit supplies the same recording sheet. Means for forming an image using some or all of the nozzles included in the head unit,
As a result of the selection, when an image is formed by a plurality of print scans, the supply unit supplies the same recording sheet to the other head unit a plurality of times, and the recording sheet is supplied to the other head unit. Means for forming an image using some of the nozzles of the head portion during the L-th supply (L is a natural number), and the M-th supply (M is a natural number, M ≠ L) The image forming apparatus according to claim 2, further comprising: a unit configured to form an image using another nozzle. The recording agent used in one of the two head units is used for recording in which the drying time of the recording agent on the recording sheet or the absorption time of the recording agent of the recording sheet is used in the other head unit. 5. The image forming apparatus according to claim 2, wherein the drying time or the absorption time of the agent is shorter than the drying time or the absorption time. The image forming apparatus according to claim 5, wherein the one head unit is disposed upstream of the other head unit in the supply direction. When an image is formed by a plurality of print scans using two head units, one of the head units is used to form an image on an area on a print sheet corresponding to one print scan. 7. The image forming apparatus according to claim 2, wherein the other head unit includes means for forming an image in an area different from the area. 8. The image forming apparatus according to claim 7, further comprising: a unit for prohibiting the other head unit from forming an image when one of the head units forms an image on an area on a recording sheet corresponding to one recording scan. The image forming apparatus according to any one of the preceding claims. When an image is formed by a plurality of print scans using two head units, a unit that determines whether to form an image on an area on a print sheet corresponding to each print scan, A moving unit that moves the head unit to a position corresponding to the determined region; and a unit that causes the head unit to form an image in the region after the moving of the head unit. The image forming apparatus according to claim 2, wherein: The head of one or both of the two head units is provided so as to be swingable in a direction intersecting with the supply direction. Image forming apparatus.

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