JP4549523B2 - Recording device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a recording apparatus that performs recording on a recording medium such as recording paper. More specifically, the present invention relates to a serial scan type recording apparatus that records information on a recording medium such as a label sheet or a continuous sheet having a plurality of labels attached to a mount.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, ink jet recording apparatuses that perform recording by forming ink droplets by various methods and attaching them to a recording medium such as recording paper are known. In particular, an ink jet recording apparatus that uses heat as energy for forming discharged droplets can easily arrange a plurality of discharge ports at a high density. Can be obtained at a high speed and colorization of images is easy. This recording method performs recording by ejecting ink onto a recording medium in accordance with a recording signal, and is widely used as a quiet recording method with low running cost.
[0003]
Further, in the case of an ink jet recording apparatus capable of performing color recording, a recording head is provided for each color ink, and ink droplets of each color are ejected from each recording head on the recording medium. By superimposing with each other, a color image is formed on the recording medium. For recording color images, generally, three primary colors of yellow (Y), magenta (M), and cyan (C) are used, and four colors of ink including black (K) are used. In this case, the ink jet recording apparatus is provided with a recording head corresponding to these inks and an ink tank for storing ink to be supplied to each recording head.
[0004]
Further, in recent years, an ink jet recording apparatus using a recording head cartridge having a configuration in which a nozzle row divided for each color ink is formed in the recording head, and an ink tank of each color is integrally provided in the recording head, In order to enable higher image quality, a seven-color configuration in which light yellow (PY), light magenta (PM), and light cyan (PC) are added to the above four inks (Y, M, C, K). Inkjet recording apparatuses have already been realized.
[0005]
In this type of ink jet recording apparatus, a serial scan method in which a recording head is serially scanned in a direction (main scanning direction) intersecting a recording medium conveyance direction (sub-scanning direction) to perform recording on a recording medium on a platen And a line head type in which a long recording head is fixed in a direction crossing the recording medium conveyance direction and recording is performed on the recording medium conveyed on the platen.
[0006]
The latter (line head method) has a conveying means capable of continuously conveying a recording medium, and performs recording by conveying the recording medium below a fixed long recording head. It is possible to record at a very high speed. However, since a long recording head is used, the recording apparatus becomes large, and the long recording head is generally expensive, which increases the cost. .
[0007]
On the other hand, the former (serial scan method) includes a transport unit capable of intermittently transporting the recording medium according to the recording width, and performs recording by repeating transport of the recording medium and scanning of the recording head. Although the recording speed is low, since a small recording head is used, the recording apparatus can be downsized and the cost can be reduced.
[0008]
As an application example of the ink jet recording apparatus as described above, a recording apparatus called a label printer that records information on a recording medium such as a label sheet having a plurality of labels attached to a mount is known. The label printer generally uses a line head system capable of recording at high speed. In recent years, however, the serial scan method has also been used in label printers by taking advantage of its features such as a small size and low cost by increasing the number of nozzles of the recording head to achieve a high recording speed. is there.
[0009]
FIG. 12 is a top sectional view showing a conventional serial scan type label printer, and FIG. 13 is a side sectional view of the label printer shown in FIG.
[0010]
As shown in FIGS. 12 and 13, the conventional label printer conveys a label sheet 107 in which a plurality of labels 109 are continuously attached to the surface of a base paper 108 wound in a roll shape onto a platen 110. The first conveying roller 104 and the information on the label sheet 107 conveyed by the first conveying roller 104 are arranged, and the label 109 is scanned along the guide rail while discharging ink, and the information on the label 109 is detected. And a second transport roller 105 for further transporting the label paper 107 recorded by the recording head 102. Further, the label printer has a discharge roller 106 for discharging the label paper 107 conveyed by the second conveyance roller 105 to the outside.
[0011]
This label printer is disposed downstream of the first transport roller 104 and above the label paper 107 in the transport direction of the label paper 107 by the transport rollers 104 and 105, and in the transport direction by the first transport roller 104. A guide rail (not shown) extending in a direction intersecting the guide rail, and a drive belt 101 wound around two pulleys (not shown) provided near both ends of the guide rail are provided. A carriage 100 fixed to a part of the drive belt 101 and capable of reciprocating along a guide rail is provided. The recording head 102 is formed with a nozzle row divided for each color ink of Y, M, C, and K, and the carriage has four ink tanks each containing the recording head 102 and each color ink. (Not shown) is mounted. The recording head 102 and the ink tank are mounted on this carriage and reciprocally scan along the guide rail.
[0012]
Further, the label printer is provided with a transmission light type TOF (Top of Form) sensor 111 for detecting the leading end of the label 109 at a position upstream of the area below the recording head 102 in the transport direction. Yes. The TOF sensor 111 detects an index indicating a recording position of a form or the like attached to the label 109.
[0013]
In the label printer configured as described above, after the label paper 107 is transported below the recording head 102 by the transport rollers 104 and 105, the carriage is scanned in the direction of the arrow A while ejecting ink from the recording head 102. Then, recording for one recording width of the recording head 102 is performed on the label 109. Thereafter, the label paper 107 is conveyed by one recording width of the recording head 102 by the conveying rollers 104 and 105, and similarly, recording for one recording width of the recording head 102 is performed on the label 109. By repeating this operation, recording is performed on the entire label 109.
In the case of continuously recording on a plurality of labels 109, after recording for one sheet, the label sheet 107 is transported to the recording start position of the next label 109, and recording is performed on the next label 109. Do.
[0014]
FIG. 14 is a diagram for explaining the operation of continuously recording on a plurality of labels using the label printer shown in FIG.
[0015]
When recording is continuously performed on a plurality of labels, first, the label sheet 107 is transported downward of the recording head 102 by the transport roller 104 (see FIG. 12). Then, as shown in FIG. 14A, when the leading edge of the first label 109 is detected by the TOF sensor 111, the conveyance of the label sheet 107 is temporarily stopped. This position becomes the recording start reference position of the label 109. Based on the recording information sent from the host PC (not shown) to the printer, the conveyance of the label paper 107 and the scanning of the recording head 102 (see FIG. 12) are repeated, so that the first label 109 is read. To record.
[0016]
FIG. 14B shows a state in which the recording on the first label 109 has been completed. Since the labels 109 are affixed adjacent to each other on the mount 108, when the recording on the first label 109 is completed, the next label 109 is conveyed to a position where the leading end exceeds the TOF sensor 111. Yes.
[0017]
Therefore, as shown in FIG. 14C, the label sheet 107 is reversely conveyed upstream in the conveyance direction to a position where the leading end of the next label 109 is detected by the TOF sensor 111. Then, by repeating the recording operation and the conveying operation as described above, predetermined information is recorded on each of the plurality of labels 109.
[0018]
[Problems to be solved by the invention]
However, in the recording apparatus as described above, when recording on a plurality of labels, after recording on a certain label, the label paper is reversely transported and the leading end of the next label is aligned. Since it is necessary to do this, the throughput of the recording operation is significantly reduced.
[0019]
Therefore, the present invention provides a recording apparatus capable of recording recording information at a predetermined position on a recording medium without reducing the throughput of the recording operation even when recording is performed on a plurality of recording media. For the purpose.
[0020]
[Means for Solving the Problems]
In order to achieve the above object, the recording apparatus of the present invention comprises: In the specified transport direction Conveying means for conveying the recording medium; A recording head including a plurality of recording elements arranged in the predetermined conveying direction; and Scan in the direction crossing the transport direction Ruki And The recording head scans the recording head with the carriage to record images of a plurality of rasters corresponding to the plurality of recording elements on a recording medium, and the plurality of rasters are recorded by the conveying unit after the recording scan is completed. In a recording apparatus for recording an image according to recording information on a recording medium by alternately and repeatedly performing a conveying operation for conveying the recording medium, an upstream side of a recording position by the recording head in the predetermined conveying direction Detecting means for detecting the trailing edge of the recording medium conveyed by the conveying means, and setting the number of rasters recorded in the last recording scan with respect to the recording medium, and the last recording according to the number of rasters Setting means for setting a range of a recording element of a recording head used in scanning, and the setting means is provided after the recording medium by the detection means. The remaining recording information size is determined according to the detection, and when the remaining recording information size is larger than the size of the remaining recordable area on the recording medium, the raster number of the image in the last recording scan is The number of rasters is set to be smaller than the number of image rasters in the previous recording scan, and the last raster of the image recorded in the last recording scan is the most upstream recording among the plurality of recording elements of the recording head. The range of the recording element used for recording is set so as to be recorded by the element, and the recording unit transported the last recording scan by the transporting unit after the transporting unit has performed the recording scanning immediately before the last recording scan. A transport operation by the transport unit is performed so as to be performed in the element range, and the remaining recording element range is used in the last recording scan. Record the part of the recorded information, the rest does not record It is characterized by that.
[0024]
According to this configuration, the final raster of the recording information recorded in the recordable area of the recording medium is recorded head The recording element on the most upstream side in the conveyance direction of the recording medium among the recording elements. Therefore, record head Since the recording scan is performed only in the area opposite to the recordable area of the recording medium, when the recording is continuously performed in the next recordable area, the recording medium may be transported forward to the next recording start position. . Therefore, it is not necessary to reversely transport the recording medium, and it is possible to correctly record the recording information at a predetermined position on the recording medium without reducing the throughput of the recording operation.
[0025]
Furthermore, it is preferable that the recording information is generated by being processed into a data format that allows the recording means to execute a recording operation.
[0026]
Further, the recording medium may be a label sheet in which a plurality of labels are attached to a mount.
[0027]
The recording unit may be an ink jet recording head that records the recording information on the recording medium by ejecting ink droplets from a nozzle as the recording element.
[0028]
Furthermore, the recording unit may be configured to record a monochrome image or a color image on the recording medium according to the recording information.
[0029]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings.
[0030]
(First embodiment)
FIG. 1 is a diagram showing a schematic configuration of a recording head and the like in the first embodiment of the recording apparatus of the present invention. FIG. 1 shows a state where each nozzle row of the recording head 202 is seen through from above.
[0031]
The recording head 202 in the recording apparatus of the present embodiment includes four nozzle rows 202Y, 202M, and 202C provided for each color ink of yellow (Y), magenta (M), cyan (C), and black (K). , 202K are arranged in parallel. Each nozzle row is composed of 304 nozzles that eject ink droplets at a constant pitch. Therefore, the print head 202 can print 304 rasters for each color in one scan. Further, in the recording apparatus of the present embodiment, when the recording head 202 scan and the intermittent conveyance of the label paper are repeatedly performed, as a rule, the paper is fed by 304 rasters by one intermittent conveyance operation.
[0032]
The drive belt 201 of the recording apparatus of the present embodiment, the TOF sensor 211 as the position detecting means of the present invention, the mount 208, the label 209, and other configurations are the same as those of the conventional recording apparatus shown in FIGS. Since it is the same, detailed description is abbreviate | omitted.
[0033]
The recording operation of the recording apparatus of the present embodiment is also the same as that of the conventional recording apparatus shown in FIG. 12 and the like, while the label paper is transported below the recording head 202 by the transport roller, and then the ink is ejected from the recording head 202. By scanning the carriage in the direction of the arrow A in the figure, recording for one scanning recording width (304 rasters) of the recording head 202 is performed on the label 209. Thereafter, the label paper is conveyed by one scanning recording width of the recording head 202 by the conveying roller, and similarly, recording for one scanning recording width of the recording head 202 is performed on the label 209. By repeating this operation, recording is performed on the entire label 209.
[0034]
FIG. 2 is a diagram for explaining the operation of continuously recording on a plurality of labels using the recording apparatus shown in FIG.
[0035]
First, the label paper is transported below the recording head 202 by the transport roller, and when the leading edge of the first label 209 is detected by the TOF sensor 211 as shown in FIG. To do. This position becomes the recording start reference position of the label 209. Then, based on the recording information sent from the host PC (not shown) to the recording apparatus, recording for one scanning (304 rasters) of the recording head 202 and paper feeding for the recording width during one scanning are repeated. Recording is performed on the first label 109. However, at the time of scanning for forming the final raster of the image recorded on the label 209, recording for 304 rasters is not performed.
[0036]
FIG. 2B shows a state in which the scan for forming the final raster of the image recorded on the label 209 is completed and the recording on the first label 209 is completed. In the recording apparatus of the present embodiment, the final raster is always recorded by the nozzle on the most upstream side in the label sheet transport direction, that is, the 304th nozzle shown in FIG. Then, adjustment of the conveyance amount of the label paper before the final scan and processing of the recording data are performed.
[0037]
As shown in FIG. 2B, when the recording on the first label 209 is completed, the next label 209 is conveyed to a position where the leading end exceeds the TOF sensor 211.
[0038]
Then, as shown in FIG. 2C, the transport amount from the time point when the leading end of the next label 209 is detected by the TOF sensor 211 is controlled, and the recording position of the next label 209 in the recording area of the recording head 202 is controlled. The label paper is conveyed so that is positioned.
As described above, in the recording apparatus according to the present embodiment, the operation of reversely transporting the label sheet is not performed.
[0039]
FIG. 3 is a block diagram of an electrical configuration provided in the recording apparatus of the present embodiment shown in FIG. In the recording apparatus of the present embodiment, a CPU (Central Processing Unit) 500 executes a control program stored in the program memory 501 to control the interface 504 from the host PC to receive recording data. By controlling the motor driver 514 via the drive, various motors M515 to 517 for the transport roller and the discharge roller are driven, and by further controlling the recording control circuit 508 and the data control circuit 518, for each color of the recording head 202. The nozzle rows 202Y, 202M, 202C, and 202K are driven. In this way, label paper is fed, transported and discharged, and the operation of the recording head is controlled.
[0040]
The CPU 500 constitutes a recording area determination means, a carry amount calculation means, and a drive element number calculation means of the present invention, and the recording control circuit 508 and the data control circuit 518 constitute a drive element number setting means of the present invention.
[0041]
Sensors 507 related to the operation control and operator operation keys 506 are also connected to the CPU 500 via the input port 505. The recording data received from the host PC is stored in the data memory 503, and the data stored in the working memory 502 is referred to as appropriate when executing the operation control.
[0042]
FIG. 4 is a conceptual diagram for explaining a development process of recording data in the recording apparatus of the present embodiment.
[0043]
Commands sent from the host PC 600 for drawing barcodes, characters, diagrams, image images, and the like are page buffers 601K, 601C, and 601M for four colors to the data memory 503 (see FIG. 3) in the recording apparatus. , 601Y. When the recording apparatus receives a recording start command from the host PC 600 after the expansion, the image data for 304 rasters is printed for four colors as image data for one scan from the first page of the expanded image data. The data is expanded into buffers 602K, 602C, 602M, and 602Y. Then, the label sheet is conveyed by 304 rasters, and the recording head is scanned to record the 304 rasters. Thereafter, the recorded image data for 304 rasters are cleared, and the image data for the next 304 rasters are developed. In this way, the development of the image data for 304 rasters and the recording for the 304 rasters are repeated, and recording is performed on the entire label. Note that the recording information recorded on the recording medium is generated by being processed into a data format that allows the recording head to execute the recording operation.
[0044]
Next, an operation of continuously recording on a plurality of labels by the recording apparatus of the present embodiment will be described with reference to FIGS. FIG. 5 is a conceptual diagram for explaining the development transition of recording data in the recording apparatus of the present embodiment, and FIGS. 6 to 9 are flowcharts showing steps for continuously recording on a plurality of labels.
[0045]
As described above, when the image data is expanded in the page memory 503 (see FIG. 3) in response to a command from the host PC 600 and the recording start command is received from the host PC 600, the recording apparatus according to the present embodiment is shown in FIG. The recording operation is started, and the recording operation is executed in the order of paper feed processing (S1), recording processing (S2), and conveyance processing (S3).
[0046]
Here, details of each process of the recording operation shown in FIG. 6 will be described for each of the paper feed process (S1), the recording process (S2), and the transport process (S3).
[0047]
In the paper feeding process (S1), as shown in FIG. 7, it is determined whether the recording is the first recording after the power is turned on (S101) or whether the previous recording was abnormally terminated (S102). When it is the first recording and when the previous recording is abnormally ended, the forward rotation of the transport roller is started as it is (S104). If the previous recording is not abnormally ended, the transport roller is reversed by a predetermined number of rasters, and the label to be recorded is moved upstream of the TOF sensor in the transport direction (S103). The forward rotation is started and the label for recording is conveyed to the recording reference position (S104).
[0048]
Then, the forward conveyance of the label paper is continued until the leading edge of the label is detected by the TOF sensor, it is determined whether the leading edge of the label to be recorded is detected by the TOF sensor (S105), and when the leading edge of the label is detected, The size of the label to be recorded (the number of lines L in the conveyance direction of the image data developed in the page buffer) is set in the work area as the number of remaining recording lines a (S106), the paper trailing edge detection flag X, and the final scanning flag Y , And the final recording flag Z are cleared (S107), and the number M of lines for conveying the label from the TOF sensor detection unit to the 304th nozzle position of the recording head is set to the number b of conveying lines of the label paper. Is set in the work area (S108), and the transport roller is rotated forward to transport the label paper (S109).
[0049]
Then, the number of remaining lines a of the image to be recorded on the label is compared with the number of lines c for conveying the label from the trailing edge detection position of the label to the 304th nozzle of the recording head (S110). When c is larger than the remaining line number a, the paper feed process is terminated, and when the line number c is smaller than the remaining line number a, the recording size (line number a) is set to the above-mentioned line number c (S111). ).
[0050]
In the recording process (S2), as shown in FIG. 8, the number b of label sheet conveyance lines is set to 304 as the work area (S201), and the conveyance roller is rotated forward to convey the label sheet (S202).
[0051]
Then, the number of remaining recorded rasters a is compared with the number of recorded rasters (304 rasters) in one scan (S203). If the number of remaining rasters a is larger than 304 rasters (a> 304), the page buffer is used. The data for 304 rasters is transferred to the print buffer (S204), the data for 304 rasters is added to the data pointer of the page buffer (S205), the mask bit is set to 0 (S206), and the new number of remaining recorded rasters a is updated to the raster number “a-304” obtained by subtracting 304 rasters from the remaining recorded raster number a.
[0052]
On the other hand, when the remaining raster number a is 304 rasters or less (a ≦ 304), the data for “304-a” raster is subtracted from the data pointer of the page buffer (S208), and the page buffer is transferred to the print buffer. Data for 304 rasters is transferred (S209), "304-a" is set in the mask bit (S206), and the final scanning flag Y is set (S211).
[0053]
After the above steps, the recording head is scanned to record 304 raster images on the label, and the 304 raster image data is cleared from the print buffer (S211).
[0054]
Then, the number of remaining lines a of the image recorded on the label is compared with the number of lines c for conveying the label from the trailing edge detection position of the label to the 304th nozzle of the recording head (S213). If c is larger than the number of remaining lines a, the recording size (number of lines a) is set to the number of lines c (S214), and the paper trailing edge detection flag X is cleared (S215). If the number of lines c is less than the number of remaining lines a, the sheet trailing edge detection flag X is cleared as it is (S215).
[0055]
Thereafter, based on whether or not the final scanning flag Y is set, it is confirmed whether or not the recording on the first label has been completed (S216). If the final scanning flag Y is not set (Y = 0), the processes from S201 to S215 are repeated.
[0056]
When the final scanning flag Y is set (Y = 1), the recording for the first label is finished, and the next recording is performed based on whether the continuous recording flag Z (see FIG. 9) is set. It is confirmed whether the development of the image data to be recorded on the label is completed (S217). When the continuous recording flag Z is set (Z = 1), a continuous process (S218) for recording on the next label is performed, and the processes from S201 to S217 are repeated. If the continuous recording flag Z is not set (Z = 0), the recording process is terminated.
[0057]
In the transport process (S3), as shown in FIG. 9, a stepping motor (not shown) that drives the transport roller is rotated forward by one step (S301). Then, the label sheet conveyance line number b is subtracted by one line (S302). Further, when the trailing edge of the label sheet is detected by the TOF sensor, that is, when the sheet trailing edge detection flag X is set (X = 1), the 304th printhead from the label trailing edge detection position is detected. The line number c for conveying the label to the nozzle position is subtracted by one line (S303). When the leading edge of the label sheet is detected by the TOF sensor, that is, when the final recording flag Z is set (Z = 1), from the leading edge detection position of the label to the position of the 304th nozzle of the recording head. The number d of lines for carrying the label is subtracted by one line (S304).
[0058]
Then, it is determined whether the trailing edge of the label to be recorded is detected by the TOF sensor (S305). If the trailing edge of the label is detected by the TOF sensor, the current number of conveyance lines b and the TOF detection position are used. The number M of lines for transporting the label to the position of the 304th nozzle of the recording head is compared (S308). When the transport line number b is greater than or equal to the line number M, the new remaining recording line number a is updated to a value “a−M” obtained by subtracting the line number M from the original remaining recording line number a, and the transport line number b. Is set to the number of lines M, the number of lines c is set to 0, and the sheet trailing edge detection flag X and the final scanning flag Y are set (S309). On the other hand, when the transport line number b is smaller than the line number M, the sheet trailing edge detection flag X is set, and the line number c is set to the line number M (S312).
[0059]
Subsequently, it is determined whether the leading edge of the label to be recorded is detected by the TOF sensor (S306). If the leading edge of the label is detected by the TOF sensor, the development of the image data to be recorded on the next label is completed. Whether or not (S310). If the development has not been completed, the continuation recording flag Z is cleared (S311). On the other hand, if the development has been completed, the continuous recording flag Z is set, and the line number d is set to the line number M (S313).
[0060]
Then, based on whether or not the number of conveyance lines b is 0, it is determined whether or not the conveyance of the label sheet is finished (S307). When the number of conveyance lines b is not 0, the processing from S301 is repeated. When the transport line number b is 0, the transport of the label paper is finished.
[0061]
Next, a series of operations for continuously recording on a plurality of labels will be described with reference to FIGS.
[0062]
First, the transport roller is rotated forward (S104), and after the leading edge of the label paper to be recorded is detected by the TOF sensor (S105), as shown in FIG. 9, the trailing edge of the label is detected by the TOF sensor (S305). ) And whether the leading edge of the next label has been detected by the TOF sensor (S306) is checked every time the transport roller motor is driven by one step, and the leading edge of the label sheet is used as the 304th nozzle of the recording nozzle. The sheet is transported to the facing position (S109).
[0063]
When the rear end of the label is detected during forward rotation of the transport roller (S109) (S305), the transport line number b transports the label from the TOF detection position to the position of the 304th nozzle of the recording head. If the number is less than the number M of lines (S308), the paper trailing edge detection flag X is set (X = 1), and the label is printed from the trailing edge detection position of the label to the position of the 304th nozzle of the recording head. The number of lines c to be conveyed is set to the number of lines M (fixed value) (S312), and the line number c is subtracted by one line every time the motor of the conveying roller is driven by one step (S303).
[0064]
When the leading edge of the label is detected during the forward rotation of the transport roller (S109) (S306), the paper leading edge detection flag is set and whether or not the development of the image data recorded on the next label is completed. (S310), and when the development has been completed, the continuous recording flag Z is set, and the label is conveyed from the leading end detection position of the label to the position of the 304th nozzle of the recording head. For this purpose, the number of lines d is set to the number of lines M (fixed value) (S313), and the line number d is subtracted by one line each time the motor of the transport roller is driven by one step (S304).
[0065]
When the leading edge of the label is transported to the position facing the 304th nozzle of the recording nozzle, the trailing edge detection counter (number of lines c) is confirmed, and the number of lines c is not 0 and the page buffer is developed. If the number of lines c is smaller than the number of lines in the transport direction of the recorded data, that is, if the size of the recordable area of the label is smaller than the size of the recorded image, the number of lines c remains. The recording line number a is set to prevent ink from adhering to the mount portion of the label paper beyond the rear end of the label.
[0066]
Next, the label sheet is conveyed to the recording position of the recording head (S202), the data transfer start address is changed from the page buffer to the print buffer based on the size of the number of remaining recording lines a (S203), and the print from the page buffer is performed. Data transfer processing to the buffer (S204, S209) and mask bit setting (S206, S210) for setting the effective range of ink ejection of each nozzle array of the recording head are performed, and printing for 304 rasters is performed ( S211).
[0067]
There are two setting processes according to the remaining recording line number a. When the remaining recording line number a is larger than 304 lines, the data transfer start address is not changed, and reference numeral 700 in FIGS. , 701, data for 304 lines is transferred from the page buffer for each color to the print buffer for each color (S204), data for 304 rasters is added to the data transfer start address (S205), and each color shown in FIG. The mask bits 710K, 710C, 710M, and 710Y are set to 0 (all ejections) (S206), 304 lines are subtracted from the remaining recording line number a (S207), and the recording head is scanned to record on the label (S207). S212).
[0068]
On the other hand, when the remaining recording line number a is 304 lines or less, the data transfer start address is changed to the address obtained by subtracting the subtraction solution of “304-a” from the current data transfer start address, and the page of each color. Data for 304 lines is transferred from the buffer to each color print buffer (S209). As shown in FIG. 5D, the mask bits 710K, 710C, 710M, and 710Y for each color are transferred from the first nozzle (304-). a) The first nozzle is set to be masked so that the image already recorded on the label is not overlapped and recorded. Further, the final scanning flag Y indicating that the recording scanning for the label is the final scanning is set (S211), and the final scanning of the recording head is executed to perform recording (S212).
[0069]
Next, the paper trailing edge detection flag X at the time of conveyance of recording scanning is confirmed (S213), and when the paper trailing edge detection flag X is set, that is, when the TOF sensor detects the trailing edge of the label. In addition, when the number of lines c is smaller than the number of remaining recording lines a, that is, when the size of the recordable area of the label is smaller than the size of the image to be recorded, the number of lines c is set. The remaining recording line number a is set (S214) to prevent ink from adhering to the mount portion of the label paper beyond the rear end of the label.
[0070]
Next, the final scanning flag Y is confirmed (S216). If the final scanning flag Y is not set, the label paper is conveyed for the next recording scan (S202), and the final scanning of the recording head is performed thereafter. The above operation flow is repeated until.
[0071]
When the final scanning is performed and the recording for the first label is completed, the leading end of the next label is detected by the TOF sensor in the transport process (S3) (S306), and the image data recorded on the next label is developed. Is confirmed (S310), the continuous recording flag Z is set (S313), and it is confirmed that the continuous recording flag Z is set in the recording process (S2) (S217). In order to continue recording, continuous processing (S218) is performed, and the next label is transported to the recording start reference position without reversely transporting the label paper (S202), and recording is performed according to the above flow. The continuation process (S218) is a process for conveying the number d of lines from the leading edge detection position of the label to the position of the 304th nozzle of the recording head.
[0072]
On the other hand, when recording is not continuously performed, a paper discharge process is performed, and the recorded label paper is discharged outside the recording apparatus main body.
[0073]
By the above processing, recording is continuously performed on a plurality of labels.
[0074]
In this way, the final raster is always recorded by the 304th nozzle of the recording head, that is, the nozzle on the most upstream side in the paper transport direction in the nozzle row provided in the recording head. Therefore, it is not necessary to perform the reverse conveyance operation even when continuously recording a plurality of labels regardless of the size of the label to be recorded. Therefore, according to the recording apparatus of the present embodiment, it is possible to realize recording information at the correct position on the label without reducing the throughput.
[0075]
(Second Embodiment)
Since each configuration of the recording apparatus of the present embodiment is the same as that of the recording apparatus of the first embodiment, a detailed description of the configuration is omitted.
[0076]
In this embodiment, every time a certain amount of raster data, which is recording data received from the host PC, is accumulated, conveyance of the label paper and recording of raster data by recording scan of the recording head are repeated. In this embodiment, the transport operation and the recording data transfer means are set so that the final raster of the label is always recorded by the 304th nozzle of the recording head.
[0077]
Hereinafter, a recording operation by the recording apparatus of the present embodiment will be described with reference to a data development conceptual diagram shown in FIG. 10 in the recording apparatus of the present embodiment.
[0078]
In the printing apparatus of the present embodiment, raster image commands transferred from the host PC 1200 one raster at a time as print buffers 1201K, 1201C, 1201M, and 1201Y for four colors for one printing scan in the data memory 503 in the printing apparatus. expand. When the image data for 304 rasters is accumulated, the label paper is conveyed by 304 rasters, and the recording head is scanned to perform 304 raster recording. After the recording scan, the print buffer is cleared and the reception of the next raster image command is awaited. The print buffers 1201K to Y for four colors have a capacity for a size (for example, 500 rasters) larger than the raster size for one scan (304 rasters), and the printing apparatus according to the present embodiment stores this print buffer. It is used in a ring shape as shown in FIG.
[0079]
FIG. 11 is a conceptual diagram for explaining development transition of recording data in the recording apparatus of the present embodiment. As described above, the printing apparatus of the present embodiment includes one 500 raster print buffer for each color.
[0080]
As described above, in the present embodiment, raster image commands transferred one raster at a time from the host PC 1200 (see FIG. 10) are developed in a print buffer for four colors. When image data for 304 rasters is accumulated in the print buffer, the label paper is conveyed by 304 rasters, and the recording head is printed and scanned, so that 304 rasters are recorded for each color by one scan. After scanning, the recorded print buffer is cleared and the next raster image command is received.
[0081]
In FIG. 11A, reference numeral 1300 denotes a print buffer that has been cleared by the initialization process before recording.
[0082]
In FIG. 11B, reference numeral 1301 indicates a state in which raster image commands for 304 rasters relating to the first to 304th rasters for the first scan of the first label are developed in the print buffer. In this state, the label sheet is conveyed by 304 raster lines, the recording head is scanned to perform recording, and the print buffer is cleared after recording. In FIGS. 11B to 11E, “S” indicates a transfer start address of print data to the print head, and “E” indicates a final line of transfer of print data to the print head.
[0083]
In FIG. 11C, reference numeral 1302 indicates a state in which raster image commands for 304 rasters related to the 305th to 608th rasters for the second scan of the first label are developed in the print buffer. . In this state, the label sheet is conveyed by 304 raster lines, the recording head is scanned to perform recording, and the print buffer is cleared after recording.
[0084]
In FIG. 11D, reference numeral 1303 denotes raster image commands from the 609th raster of the first label to the last Nth raster (N−609 ≦ 304) in the print buffer up to the position “A” shown in the figure. Shows the state. In this state, the label sheet is conveyed by (N-609) rasters. Then, the position 304 rasters before the “X” position is set as the recording data transfer start address “S” to the recording head, recording is performed by scanning the recording head, and only the print buffer is cleared after recording. To do.
[0085]
In FIG. 11E, reference numeral 1304 indicates a state in which raster image commands for 304 rasters relating to the first to 304th rasters for the first scan of the second label are developed in the print buffer. Recording is performed by repeating the operations shown in FIGS. 11B to 11D for the second and subsequent labels.
[0086]
In the present embodiment, recording is performed on a recording medium such as a label by the above recording process. Also in the present embodiment, the paper leading edge detection method, the paper trailing edge detection method, the paper conveyance process, and the like using the TOF sensor are the same as those in the first embodiment, and thus detailed description thereof is omitted.
[0087]
As described above, when the final line of each label is recorded, by setting the final raster to be recorded by the 304th nozzle of the recording head, a plurality of labels can be printed regardless of the size of the label paper. Even if recording is continuously performed on a single label, the reverse conveyance operation is not performed, so that recording information can be recorded at a correct position on the recording medium without reducing the throughput.
[0088]
(Other embodiments)
In the above description, a serial scan type inkjet recording apparatus having a plurality of nozzle rows provided for each color has been described as an example. However, the recording head is for a single color having a single nozzle row. It may be. However, if the recording head has a plurality of nozzle arrays provided for each color, a monochrome image or a color image can be recorded on the recording medium according to the recording information to be recorded on the recording medium. .
[0089]
Further, the recording method of the recording head is not limited to the ink jet method. The present invention can be widely applied not only to a label printer for recording on a label but also to a general recording apparatus.
[0090]
【The invention's effect】
As described above, the recording apparatus of the present invention is Conveying means for conveying a recording medium in a predetermined conveying direction, a recording head having a plurality of recording elements arranged in the predetermined conveying direction, and a carriage for scanning the recording head in a direction crossing the predetermined conveying direction A recording scan for recording a plurality of raster images corresponding to the plurality of recording elements on a recording medium by causing the recording head to scan by the carriage, and the plurality of the plurality of rasters by the conveying unit after the recording scan is completed. In a recording apparatus that records an image according to recording information on a recording medium by alternately and repeatedly performing a conveying operation for conveying a recording medium for a number of rasters, a recording position by the recording head in the predetermined conveying direction Detecting means for detecting the trailing edge of the recording medium conveyed by the conveying means upstream of the recording medium, and the last recording scan for the recording medium. Setting the number of rasters to be recorded, and setting means for setting the range of recording elements of the recording head used in the last recording scan according to the number of rasters, the setting means by the detection means The remaining recording information size is determined according to the detection of the trailing edge of the recording medium, and if the remaining recording information size is larger than the size of the remaining recordable area on the recording medium, the image of the last recording scan The number of rasters is set to be smaller than the number of image rasters in the previous recording scan, and the last raster of the image recorded in the last recording scan is selected from among the plurality of recording elements of the recording head. A range of recording elements used for recording is set so as to be recorded by the recording element on the most upstream side, and the transporting unit performs a recording scan immediately before the last recording scan. , Performing a transport operation by the transport unit so that the last recording scan is performed in the range of the recording elements transported by the transport unit, and using the set recording element range in the last recording scan Record some of the remaining recording information and do not record the rest Therefore, the recording information can be correctly recorded at a predetermined position on the recording medium without reducing the throughput of the recording operation.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of a recording head in a first embodiment of a recording apparatus of the present invention.
FIG. 2 is a diagram for explaining an operation for continuously recording on a plurality of labels using the recording apparatus shown in FIG. 1;
FIG. 3 is a block diagram of an electrical configuration provided in the recording apparatus according to the first embodiment.
FIG. 4 is a conceptual diagram for explaining a development process of recording data in the recording apparatus according to the first embodiment.
FIG. 5 is a conceptual diagram for explaining development transition of recording data in the recording apparatus of the present embodiment.
FIG. 6 is a flowchart showing a process of continuously recording on a plurality of labels.
FIG. 7 is a flowchart showing a process of continuously recording on a plurality of labels.
FIG. 8 is a flowchart showing a process of continuously recording on a plurality of labels.
FIG. 9 is a flowchart showing a process of continuously recording on a plurality of labels.
FIG. 10 is a conceptual diagram of data expansion in the recording apparatus of the second embodiment.
FIG. 11 is a conceptual diagram for explaining development transition of recording data in the recording apparatus of the second embodiment.
FIG. 12 is a top sectional view showing a conventional serial scan type label printer.
13 is a side sectional view of the label printer shown in FIG.
14 is a diagram for explaining an operation of continuously recording on a plurality of labels using the label printer shown in FIG. 12; FIG.
[Explanation of symbols]
201 Drive belt
202 recording head
202Y, 202M, 202, 202K Nozzle rows
208 Mount
209 label
211 TOF sensor
501 Program memory
502 working memory
503 data memory
504 interface
505 Input port
506 Operation key
507 Sensors
508 Recording control circuit
513 output port
514 Motor driver
515, 516, 517 Motor
518 Data control circuit
600,1200 Host PC

Claims (5)

Conveying means for conveying the recording medium in a predetermined conveying direction ;
A recording head comprising a plurality of recording elements arranged in the predetermined conveying direction;
Wherein the recording head is scanned in a direction intersecting the predetermined conveying direction and a Ruki Yarijji,
The recording head scans the recording head with the carriage to record images of a plurality of rasters corresponding to the plurality of recording elements on a recording medium, and the plurality of rasters are recorded by the conveying unit after the recording scan is completed. In a recording apparatus for recording an image according to recording information on a recording medium by alternately and repeatedly performing a conveying operation for conveying the recording medium,
Detecting means for detecting a rear end of the recording medium conveyed by the conveying means on the upstream side of the recording position by the recording head with respect to the predetermined conveying direction;
Setting means for setting the number of rasters recorded in the last recording scan with respect to the recording medium, and setting the range of recording elements of the recording head used in the last recording scan according to the number of rasters. ,
The setting means determines the remaining recording information size according to the detection of the trailing edge of the recording medium by the detecting means, and the remaining recording information size is larger than the size of the remaining recordable area on the recording medium The number of rasters of the image in the last recording scan is set to be smaller than the number of image rasters in the previous recording scan, and the last raster of the image recorded in the last recording scan is the recording Of the plurality of recording elements of the head, set a range of recording elements used for recording so as to be recorded by the recording element on the most upstream side in the predetermined transport direction,
After the recording scan immediately before the last recording scan, the transport unit performs a transport operation by the transport unit so that the last recording scan is performed in the range of the recording elements transported by the transport unit, A recording apparatus, wherein a part of the remaining recording information is recorded by using the set range of the recording element in a last recording scan, and the rest is not recorded. The record information, the recording unit is generated and processed into a data format capable of performing the recording operation, the recording apparatus according to claim 1. The recording apparatus according to claim 1, wherein the recording medium is a label attached to a plurality of label sheets . Said recording means, said ejecting ink droplets from the nozzles of the recording element is an ink jet recording head for recording of the record information on the recording medium, a recording according to any one of claims 1 3 apparatus. It said recording means in response to the recording information, and is configured to be able to record a monochrome image or a color image on the recording medium, a recording according to any one of claims 1 4 apparatus.

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