JP4839503B2 - Inkjet recording apparatus and inkjet recording method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an ink jet recording apparatus and an ink jet recording method , and more particularly to an ink jet recording apparatus and an ink jet recording method capable of shortening a recording time.
[0002]
[Prior art]
An ink jet recording apparatus that records an image by ejecting ink onto a roll-like or sheet-like recording medium generally scans an ink head that ejects ink onto the recording medium across the width direction of the recording medium, The operation of recording an image by ejecting ink during the scanning process and the operation of conveying the recording medium by a predetermined amount along a direction substantially orthogonal to the scanning direction are sequentially repeated to obtain a desired image on the recording medium. An image is recorded and formed.
[0003]
[Problems to be solved by the invention]
When recording and forming a plurality of images with such an ink jet recording apparatus, it is required to reduce the recording time and perform high-speed recording.
[0004]
Usually, the ink jet recording apparatus starts the movement of the recording head from a stopped state at one end portion in the scanning direction, stops at the other end portion in the scanning direction, and ends one operation. At this time, if the scanning speed of the recording head fluctuates during image recording, the ink ejection direction fluctuates and the ink landing position on the recording medium fluctuates. Therefore, the scanning speed of the recording head is kept constant during image recording. Is normal. For this reason, the recording head is set to a constant speed state after a certain acceleration time from the stop state before the actual recording starts to eject ink, and recording is performed when the recording head is in this constant speed state. . Further, after the recording is finished, the recording stops after a certain deceleration time.
[0005]
The acceleration at the time of acceleration and deceleration has an upper limit determined by the mass of the recording head and the output of the driving means for scanning the recording head, and cannot be accelerated or decelerated at an acceleration exceeding the upper limit. For this reason, the smaller the image to be recorded, the lower the effective main scanning rate of the recording head (the ratio of the time in the constant speed state to the total scanning time), resulting in lower processing efficiency.
[0006]
Accordingly, the present invention provides an ink jet recording apparatus and an ink jet recording method capable of efficiently recording even a small size image and shortening the recording time.
[0007]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the invention according to claim 1 scans from a state where the recording head is stopped to stop again through acceleration driving, constant speed driving, and deceleration driving, so that the constant speed of the recording head is reached. In an inkjet recording apparatus that records an image by ejecting ink from a recording head toward a recording medium during driving,
Comprising control means for controlling the scanning width and scanning speed in constant speed driving;
In the case where recording is performed on a recording medium having a relatively narrow width in the recording head scanning direction, the control unit is relatively According to another aspect of the present invention, there is provided an ink jet recording apparatus characterized in that the scanning width is controlled to be narrow according to the width of a narrow recording medium , and the scanning speed is controlled to be slow according to the following formula .
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency.
[0010]
According to the present invention, the recording time can be shortened according to the width of the recording medium.
[0011]
According to a second aspect of the invention for solving the above-described problem, the recording head is scanned from the stopped state to the stop again through acceleration driving, constant speed driving, and deceleration driving, and the recording head is operated at a constant speed. In an inkjet recording apparatus that records an image by ejecting ink from a recording head toward a recording medium during driving,
Comprising control means for controlling the scanning width and scanning speed in constant speed driving;
In the case of recording a recording image having a relatively narrow width in the recording head scanning direction, the control means performs the relative processing for recording a recording image having a relatively wide width in the recording head scanning direction . According to another aspect of the present invention, there is provided an ink jet recording apparatus characterized in that the scanning width is controlled to be narrow according to the width of an extremely narrow recorded image and the scanning speed is controlled to be slow according to the following formula .
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency.
[0012]
According to the present invention, the recording time can be shortened according to the width of the recorded image.
[0013]
According to a third aspect of the present invention for solving the above-described problem, the recording head is scanned from the stopped state to the stop again through acceleration driving, constant speed driving, and deceleration driving, so that the constant speed of the recording head is reached. In an inkjet recording apparatus that records an image by ejecting ink from a recording head toward a recording medium during driving,
It is possible to perform recording by scanning the recording head across a plurality of recording media arranged in parallel along the recording head scanning direction,
Comprising control means for controlling the scanning width and scanning speed in constant speed driving;
In the case of recording on a recording medium having a relatively small number of columns, the control means records the number of columns of the relatively small recording medium as compared to the case of recording on a recording medium having a relatively large number of columns. Accordingly, the ink jet recording apparatus is characterized in that the scanning width is controlled to be narrow and the scanning speed is controlled to be slow according to the following formula .
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency.
[0014]
According to the present invention, the recording time can be shortened according to the number of columns of the recording medium.
[0016]
According to a fourth aspect of the invention for solving the above problem, the recording head is scanned from the stopped state to the stop again through acceleration driving, constant speed driving, and deceleration driving, and the width of the recording medium itself. In an inkjet recording method for recording an image by ejecting ink from a recording head toward a recording medium during constant speed driving of the recording head over
When recording is performed on a recording medium having a relatively narrow width in the recording head scanning direction by the control means for controlling the scanning width and scanning speed in the constant speed driving, the recording medium having a relatively wide width in the recording head scanning direction. In contrast, when the recording is performed , the scanning width is controlled to be narrow according to the width of the relatively narrow recording medium , and the scanning speed is controlled to be slow according to the following formula. This is an ink jet recording method.
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency.
According to the present invention, the recording time can be shortened according to the width of the recording medium.
According to a fifth aspect of the present invention for solving the above problem, the recording head is scanned from the stopped state to the stop again through acceleration driving, constant speed driving, and deceleration driving, so that the constant speed of the recording head is reached. In an inkjet recording method for recording an image by ejecting ink from a recording head toward a recording medium during driving,
When a recording image having a relatively narrow width in the recording head scanning direction is recorded by the control means for controlling the scanning width and the scanning speed in the constant speed driving, the recording image having a relatively wide width in the recording head scanning direction is used. In the case of performing the above recording, the scanning width is controlled to be narrow according to the width of the relatively narrow recording image , and the scanning speed is controlled to be slow according to the following formula. This is an ink jet recording method.
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency.
According to the present invention, the recording time can be shortened according to the width of the recorded image.
According to a sixth aspect of the present invention for solving the above-described problem, the recording head is scanned from the stopped state to the stop again through acceleration driving, constant speed driving, and deceleration driving, so that the constant speed of the recording head is reached. In an inkjet recording method for recording an image by ejecting ink from a recording head toward a recording medium during driving,
It is possible to perform recording by scanning the recording head across a plurality of recording media arranged in parallel along the recording head scanning direction,
When recording is performed on a recording medium with a relatively small number of columns by the control means for controlling the scanning width and scanning speed in constant speed driving, compared with the case of recording on a recording medium with a relatively large number of columns. The inkjet recording method is characterized in that the scanning width is controlled to be narrow according to the relatively small number of columns of the recording medium , and the scanning speed is controlled to be slow according to the following equation .
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency.
According to the present invention, the recording time can be shortened according to the number of columns of the recording medium.
[0017]
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0018]
First, the overall configuration of an embodiment of an ink jet recording apparatus according to the present invention will be described.
[0019]
FIG. 1 is a front configuration diagram showing an outline of an ink jet recording apparatus, FIG. 2 is a side configuration diagram thereof, 1 is a recording medium supply means, and 2 is a conveyance means for conveying a recording medium supplied from the recording medium supply means 1 Reference numeral 3 denotes recording means for recording on the recording medium, and 4 denotes a paper discharge tray for storing the recorded recording medium.
[0020]
The recording medium supply unit 1 includes a paper feeding tray on which a plurality of recording media 10 cut into a sheet having an appropriate size are stacked. A paper feed roller 11 and a paper feed motor 12 for driving the paper feed roller are provided on the downstream side of the recording medium supply unit 1, and the recording medium supply unit 1 drives the recording medium by driving the paper feed roller 11. 10 is conveyed to the conveyance means 2 mentioned later.
[0021]
The conveyance means 2 is provided on the conveyance path of the recording medium 10, and includes a single conveyance roller 21 extending over the recording medium 10 and a pressure roller 22 for pressing the recording medium 10 against the conveyance roller 21. , And a conveyance motor 23 for driving the conveyance roller 21. The recording medium 10 supplied from the recording medium supply unit 1 is conveyed in the downward direction in the figure by the rotation of the conveying roller 21 while being sandwiched between the conveying roller 21 and the pressure roller 22.
[0022]
By supplying each recording medium 10 in this way, a conveyance path is formed.
[0023]
An optical recording medium detection sensor S1 that detects the presence / absence of the recording medium 10 is provided in each conveyance path so that the presence / absence of the recording medium 10 can be detected.
[0024]
The recording means 3 is arranged on the downstream side of the conveying means 2 and ejects ink droplets from a plurality of nozzles onto the recording medium 10 on the surface side (recording surface side) of the recording medium 10. A recording head 31 for recording and forming an image, a carriage 33 movably attached along a scanning guide 32 laid horizontally so as to be substantially orthogonal to the conveyance direction (sub-scanning direction) of the recording medium 10, The carriage 33 is configured to move the carriage 33.
[0025]
The recording head 31 includes, for example, a plurality of ink tanks in which inks such as Y (yellow), M (magenta), C (cyan), and K (black) are stored, and ink in each ink tank as droplets. Are provided on the carriage 33. When the carriage 33 is driven by the carriage motor 34, the recording medium 10 is conveyed in the direction of conveyance. It moves along the direction (main scanning direction) substantially orthogonal and across each recording medium 10. The amount of movement of the recording head 31 is detected by a linear encoder (not shown).
[0026]
On the back side of the recording medium 10 on which image recording is performed by the recording head 31, a platen 35 is disposed along the main scanning direction and across the recording medium 10 so as to face the recording head 31.
[0027]
As shown in FIG. 2, the platen 35 is formed in a box shape in which a plurality of suction holes are provided at a predetermined interval and a predetermined arrangement (not shown) on the surface facing the back surface of the recording medium 10. The inside of the recording medium 10 is sucked by suction means (not shown) such as a suction fan or a suction pump so that the inside becomes negative pressure, the recording medium 10 is adsorbed on the surface provided with the suction hole, and the recording head 31 records the image. Prevent lifting.
[0028]
The recording medium 10 on which a predetermined image is recorded by the recording means 3 is discharged and stored in a discharge tray 4 disposed on the downstream side.
[0029]
Next, the electrical configuration of the ink jet recording apparatus will be described with reference to the block diagram shown in FIG.
[0030]
In the figure, reference numeral 100 denotes a host device, which possesses image data (parameters such as image recording size, image data color-separated into YMCK, etc.) to be recorded in the ink jet recording apparatus shown in the present embodiment. It consists of a computer. Image data sent from the host device 100 is taken into the ink jet recording apparatus via the interface unit 101.
[0031]
Reference numeral 102 denotes an image memory that temporarily stores image data fetched from the host device 100, 103 denotes a memory write controller that controls writing of the image data to the image memory 102, and 104 controls reading of the image data stored in the image memory 102. A memory read controller 105 is a head driver that drives and controls ink ejection of the recording head 31 in accordance with image data read from the image memory 102 by the memory read controller 104.
[0032]
Reference numeral 106 denotes a non-volatile memory for correcting parameters for correcting the conveyance amount due to an error in the diameter of the paper feed roller 11 (see FIG. 1) and paper feed timing due to an error in the attachment position of the paper feed roller 11. Parameters are calculated and stored in advance.
[0033]
107 controls the interface unit 101, the image memory 102, the memory write controller 103, and the memory read controller 104 to fetch image data information from the host device 100 and detect parameters and recording media stored in the nonvolatile memory 106. The CPU controls the head driver 105, the paper feed motor 12, the transport motor 23, and the carriage motor 34 in accordance with the sensor S1 and the image data.
[0034]
The interface unit 101, the image memory 102, the memory write controller 103, the memory write controller 104, the head driver 105, the nonvolatile memory 106, and the CPU 107 constitute a control means.
[0035]
The CPU 107 selects one of the image data related to the plurality of images sent from the host device 100 and stored in the image memory 102 according to the position of the recording unit 3 in the scanning direction. Data related to the image is sent to the recording means 3.
[0036]
Next, the control of the scanning speed of the recording head 31 in the CPU 107 will be described.
[0037]
In the present invention, the CPU 107 changes the scanning speed of the recording head 31 in accordance with the recording width. Generally, the recording time for the recording medium by the recording head is determined by the following relationship.
[0038]
(Recording time) = (Carriage scanning time) × (Number of scanning times)
Here, since the same image is recorded in the same ink jet apparatus (the number of scans), the (recording time) depends on (carriage scanning time), so the carriage scanning time will be described below.
[0039]
(Carriage scanning time t ₀ ) = (recording head acceleration time t ₁ ) + (recording head constant speed scanning time tc) + (recording head deceleration time t ₂ )
Therefore, if the scanning speed of the head is Vc, the acceleration of the recording head is a ₁ , the deceleration of the recording head is a ₂ , the width of the recording head is W _h , and the recording width is W _m ,
t ₁ = Vc / a ₁ , tc = (W _m + W _h ) / Vc, t ₂ = Vc / a ₂
Because
t ₀ = t ₁ + tc + t ₂ = vc / a ₁ + (W _m + W _h ) / Vc + Vc / a ₂
It becomes.
[0040]
Here, when the equation is transformed, finally [0041]
[Equation 3]
Therefore, the minimum value of t ₀ is
[Expression 4]
And Vc at that time is
[0043]
[Equation 5]
[0044]
Actually, it is effective if it is about 0.5 to 2 times this,
[0045]
[Formula 6]
Scan with. Here, k is a constant in the range of 0.5-2.
However, assuming that the maximum drive frequency of the printhead is fmax and the print pixel pitch is P, Vc = Pfmax is the maximum speed in the printhead drive constraint and must not be exceeded.
[0046]
Note that the recording pixel pitch P referred to here is an interval in units of pixels to be recorded in one scan. In general, as shown in FIG. 9, there is known a method of forming an image while shifting the recording position by a plurality of scans. In this case, the pixel pitch P ₁ to be recorded by one scan and the final value are determined. pixel pitch _{P 2} of the image are different. The recording pixel pitch P of the present invention, a driving pitch of the recording head, is that the former P _1.
[0047]
Conventionally, Vc = Pfmax is set as a standard regardless of the width of the recording medium and the width of the image to be recorded. However, in the present invention, surprisingly, depending on the recording width, the carriage scanning time can be shortened by scanning at a lower speed than the conventional speed Pfmax, which is the maximum speed due to the print head drive constraint. As a result, the recording time can be shortened.
[0048]
Thus, the present invention is to change the scanning speed of the recording head in accordance with the recording width.
[0049]
In the present invention, the recording width means a width determined by the width of the recording medium, the width of the recording image, the number of columns of the recording medium to be recorded, or a combination thereof.
[0050]
The case where the scanning speed of the recording head is changed in accordance with the width of the recording medium refers to a case where the width of the recording medium itself is different as shown in FIGS. 1 and 4, for example, a borderless image, that is, the width of the recording medium itself. The present invention can be applied to the case where images having the same width to be recorded on the recording medium are recorded.
[0051]
The case where the scanning speed of the recording head is changed in accordance with the width of the recording image is applicable when the width of the image 100 to be recorded is different regardless of the width of the recording medium 10 as shown in FIG. is there.
[0052]
The case where the scanning speed of the recording head is changed in accordance with the number of columns of the recording medium means that, for example, as shown in FIG. 6, recording is performed simultaneously with one recording head on a plurality of recording media conveyed in parallel. In the apparatus as shown in FIG. 6, a plurality of (two) rows of recording media are recorded simultaneously, and as shown in FIG. 7, the same apparatus as in FIG. 6 is used to record only one row of recording media. This is applicable when the number of columns of the recording medium is different.
[0053]
Here, the apparatus shown in FIG. 6 and FIG. 7 will be briefly described, which is the same as FIG. 1 in that one recording head 31 is scanned and recording is performed, but the recording medium supply means is arranged in parallel. The plurality of recording medium supply means 1A, 1B respectively supply the recording media 10A, 10B to form a plurality of rows of conveying paths in parallel along the scanning direction of the recording head 31, and both the recording heads It is conveyed in a direction substantially orthogonal to the 31 scanning direction. Corresponding to each of the recording media 10A and 10B, paper feed rollers 11A and 11B, paper feed motors 12A and 12B for driving the paper feed rollers, and pressure-bonding rollers 22A and 22B are provided correspondingly. In addition, detection sensors S1A and S1B are provided on the respective transport paths.
[0054]
In addition to the block diagram of FIG. 3 as shown in the block diagram of FIG. 8, the electrical configuration of the recording medium detection sensors S1A and S1B and the paper feed motors 12A and 12B is set according to the number of columns of the recording medium. It is added accordingly.
[0055]
Hereinafter, the scanning speed of the recording head in the case where 1) the width of the recording medium, 2) the width of the recording image, and 3) the number of columns of the recording medium to be recorded are different will be described with specific examples.
[0056]
1) When the widths of the recording media are different Since FIGS. 1 and 4 are common inkjet recording apparatuses, the recording head width W _h , recording head acceleration and deceleration a ₁ and a ₂ , recording head The maximum drive frequency fmax and the recording pixel pitch P are respectively
W _h = 50 mm,
a ₁ = a ₂ = 5 m / s ² ,
fmax = 50 kHz,
P = 35 μm (equivalent to 720 dpi)
Then, Pfmax = 1.75 m / s.
[0057]
The width Wm ₁ of the recording medium in FIG. 1, the width Wm ₂ is Wm ₁ = 100 mm each recording medium of FIG. 4, and Wm ₂ = 1300 mm.
[0058]
First, considering the recording medium of FIG. 1, if the speed determined by the width of the recording medium is k = 1,
[0059]
[Expression 7]
It becomes.
[0060]
The scanning time at this time is t _{0 (min)} = Vc / a ₁ + (W _m + W _h ) / Vc + Vc / a ₂ = 0.490 s.
[0061]
Incidentally, when the recording head is scanned at Pfmax = 1.75 m / s determined by the maximum driving frequency of the recording head, t _{0 (Pfmax)} = Vc / a ₁ + (W _{m 1} + W _h ) / Vc + Vc / a ₂ = 0.786s.
[0062]
Next, considering the recording medium of FIG. 4, if k = 1, W _{m 2} = 1300 mm.
[Equation 8]
This exceeds the upper limit of 1.75 m / s for driving the recording head, so Vc = 1.75 m / s.
[0064]
The scanning time at this time is t _{0 (min)} = Vc / a ₁ + (W _m + W _h ) / Vc + Vc / a ₂ = 1.47 s.
[0065]
Therefore, even when recording is performed using the same apparatus, the scanning speed of the recording head is Vc = 0.612 m / s when recording a relatively narrow recording medium as shown in FIG. When recording a recording medium having a wide target width, it is possible to perform accurate recording in a short time by changing the scanning speed of the recording head in accordance with the width of the recording medium, such as Vc = 1.75 m / s.
2) When the width of the recorded image is different [0066]
In FIG. 5, the length in the width direction of the recorded image is W _g1 = 300 mm in (a), and the length in the width direction of the recorded image is W _g2 = 1500 mm in (b).
[0067]
First, in the case of (a), if k = 1, W _g1 = 300 mm.
[0068]
[Equation 9]
[0069]
The scanning time at this time is t _{0 (min)} = Vc / a ₁ + (W _m + W _h ) / Vc + Vc / a ₂ = 0.748 s.
[0070]
Incidentally, when scanning at a speed Vc = 1.75 m / s determined by the maximum drive frequency of the recording head, t _{0 (Pfmax)} = Vc / a ₁ + (W _m + W _h ) / Vc + Vc / a ₂ = 0.90 s. It will also take.
[0071]
Next, in the case of (b), if k = 1, W _g2 = 1500 mm.
[0072]
[Expression 10]
[0073]
Since Pfmax = 1.75 m / s, which is the upper limit for driving the recording head, is exceeded, Vc = 1.75 m / s.
[0074]
The scanning time at this time is t _{0 (min)} = Vc / a ₁ + (W _m + W _h ) / Vc + Vc / a ₂ = 1.59 s.
[0075]
Accordingly, even when recording is performed using the same apparatus, the scanning speed of the recording head is Vc = 0.935 m / s when recording a relatively narrow recording image as shown in FIG. When recording a relatively wide recording image as in b), the scanning speed of the recording head is changed in accordance with the width of the recording image, such as Vc = 1.75 m / s. Recording is possible.
[0076]
3) When the number of columns of recording media to be recorded is different, the apparatus conditions of the apparatus in FIG. 6 are as follows: recording head width W _h , recording head acceleration and deceleration a ₁ and a ₂ , recording head maximum drive frequency fmax, Each recording pixel pitch P is
Wh = 50 mm,
a ₁ = a ₂ = 5 m / s ² ,
fmax = 50 kHz,
P = 35 μm (equivalent to 720 dpi)
Then, Pfmax = 1.75 m / s.
[0077]
Therefore, if the constant speed travel distance in the case of FIG. 6 is Wt ₁ = 1300 mm and the constant speed travel distance in the case of FIG. 7 is Wt ₂ = 600 mm,
[0078]
First, in the case of FIG. 6, if k = 1, Wt ₁ = 1300 mm.
[0079]
[Expression 11]
[0080]
Since Pfmax = 1.75 m / s, which is the upper limit for driving the recording head, is exceeded, Vc = 1.75 m / s.
[0081]
The scanning time at this time is t _{0 (min)} = Vc / a ₁ + (W _m + W _h ) / Vc + Vc / a ₂ = 1.47 s.
[0082]
Next, in the case of FIG. 7, if k = 1, Wt ₂ = 600 mm.
[0083]
[Expression 12]
[0084]
The scanning time at this time is t _{0 (min)} = Vc / a ₁ + (W _m + W _h ) / Vc + Vc / a ₂ = 1.02 s.
[0085]
Incidentally, when scanning at a speed Vc = 1.75 m / s determined by the maximum drive frequency of the recording head, t _{0 (Pfmax)} = Vc / a ₁ + (W _m + W _h ) / Vc + Vc / a ₂ = 1.07 s. It will also take.
[0086]
Therefore, even when recording is performed using the same apparatus, the scanning speed of the recording head is Vc = 1.75 m / s when recording a plurality of rows of recorded images as shown in FIG. 6, and a single row as shown in FIG. When recording a recorded image, accurate recording can be performed in a short time by changing the scanning speed of the recording head according to the number of columns of the recorded image, such as Vc = 1.275 m / s.
[0087]
In the above embodiment, the case where the recording medium is cut in advance with a predetermined length has been described. However, a long recording medium can be used, and in that case, a cutting means for appropriately cutting the recording medium after recording is provided. Thus, it may be cut into a predetermined length.
[0088]
【The invention's effect】
As described above, according to the present invention, in recording under the same apparatus conditions, accurate recording can be performed in a short time by changing the scanning speed according to the recording width.
[Brief description of the drawings]
FIG. 1 is a front configuration diagram showing an outline of an inkjet recording apparatus. FIG. 2 is a side configuration diagram showing an outline of an inkjet recording apparatus. FIG. 3 is a block diagram for explaining an electrical configuration of the inkjet recording apparatus. FIG. 5 is a front configuration diagram illustrating an example of a recording state using an ink jet recording apparatus. FIG. 5A is a diagram illustrating a state in which a narrow-width recorded image is recorded, and FIG. 5B is a diagram illustrating a state in which a wide-width recorded image is recorded. FIG. 6 is a front configuration diagram illustrating an example of a recording state using an inkjet recording apparatus having a plurality of conveyance paths. FIG. 7 is a front view illustrating another example of a recording state using an inkjet recording apparatus having a plurality of conveyance paths. FIG. 8 is a block diagram for explaining another example of the electrical configuration of the ink jet recording apparatus. FIG. 9 is a diagram for explaining the recording pixel pitch.
1: recording medium supply means 11: paper feed roller 12: paper feed motor 2: transport means 21: transport roller 22: pressure roller 3: recording means 31: recording head 32: scanning guide 33: carriage 34: carriage motor 35: platen 4: Discharge tray 100: Host device 101: Interface unit 102: Image memory 103: Memory write controller 104: Memory read controller 105: Head driver 106: Non-volatile memory 107: CPU
S1: Recording medium detection sensor

Claims (6)

The recording head is scanned from the stopped state to stop again through acceleration driving, constant speed driving, and deceleration driving, and ink is ejected from the recording head toward the recording medium during constant speed driving of the recording head. In an inkjet recording apparatus for recording an image,
Comprising control means for controlling the scanning width and scanning speed in constant speed driving;
In the case where recording is performed on a recording medium having a relatively narrow width in the recording head scanning direction, the control unit is relatively An ink jet recording apparatus characterized by controlling the scanning width to be narrow according to the width of a particularly narrow recording medium and controlling the scanning speed to be slow according to the following formula .
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency. The recording head is scanned from the stopped state to stop again through acceleration driving, constant speed driving, and deceleration driving, and ink is ejected from the recording head toward the recording medium during constant speed driving of the recording head. In an inkjet recording apparatus for recording an image,
Comprising control means for controlling the scanning width and scanning speed in constant speed driving;
In the case of recording a recording image having a relatively narrow width in the recording head scanning direction, the control means performs the relative processing for recording a recording image having a relatively wide width in the recording head scanning direction . An ink jet recording apparatus characterized in that the scanning width is controlled to be narrow according to the width of an extremely narrow recorded image , and the scanning speed is controlled to be slow according to the following equation .
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency. The recording head is scanned from the stopped state to stop again through acceleration driving, constant speed driving, and deceleration driving, and ink is ejected from the recording head toward the recording medium during constant speed driving of the recording head. In an inkjet recording apparatus for recording an image,
It is possible to perform recording by scanning the recording head across a plurality of recording media arranged in parallel along the recording head scanning direction,
Comprising control means for controlling the scanning width and scanning speed in constant speed driving;
In the case of recording on a recording medium having a relatively small number of columns, the control means records the number of columns of the relatively small recording medium as compared to the case of recording on a recording medium having a relatively large number of columns. Accordingly, the inkjet recording apparatus is controlled so that the scanning width is narrowed and the scanning speed is controlled to be slow according to the following formula .
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency. Acceleration drive the recording head from a state that is stopped, the constant speed drive, through the reduction drive is scanned to reach the stop again, the recording medium from the recording head during the constant speed driving of the recording head across the width of the recording medium itself In an inkjet recording method for recording an image by ejecting ink toward
When recording is performed on a recording medium having a relatively narrow width in the recording head scanning direction by the control means for controlling the scanning width and scanning speed in the constant speed driving, the recording medium having a relatively wide width in the recording head scanning direction. In contrast, when the recording is performed , the scanning width is controlled to be narrow according to the width of the relatively narrow recording medium , and the scanning speed is controlled to be slow according to the following formula. Inkjet recording method.
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency. The recording head is scanned from the stopped state to stop again through acceleration driving, constant speed driving, and deceleration driving, and ink is ejected from the recording head toward the recording medium during constant speed driving of the recording head. In an inkjet recording method for recording an image,
When a recording image having a relatively narrow width in the recording head scanning direction is recorded by the control means for controlling the scanning width and the scanning speed in the constant speed driving, the recording image having a relatively wide width in the recording head scanning direction is used. In the case of performing the above recording, the scanning width is controlled to be narrow according to the width of the relatively narrow recording image , and the scanning speed is controlled to be slow according to the following formula. Inkjet recording method.
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency. The recording head is scanned from the stopped state to stop again through acceleration driving, constant speed driving, and deceleration driving, and ink is ejected from the recording head toward the recording medium during constant speed driving of the recording head. In an inkjet recording method for recording an image,
It is possible to perform recording by scanning the recording head across a plurality of recording media arranged in parallel along the recording head scanning direction,
When recording is performed on a recording medium with a relatively small number of columns by the control means for controlling the scanning width and scanning speed in constant speed driving, compared with the case of recording on a recording medium with a relatively large number of columns. An ink jet recording method comprising: controlling the scanning width to be narrow according to the relatively small number of columns of the recording medium, and controlling the scanning speed to be slow according to the following formula .
However, Vc does not exceed Pfmax.
In the above formula, Vc is a scanning velocity in the constant speed drive of the recording head, a ₁ is the acceleration of the recording head, a ₂ is the deceleration of the recording head, P is a recording pixel pitch, fmax denotes the head maximum driving frequency.