JP2004009358A - Printing device, and controlling method for the printing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a printing device and a controlling method therefor which enable high-speed formation of an image of high image quality, by properly and efficiently executing ejection of ink for preventing clogging of a nozzle of a head or the like in particular, regarding the printing device having the heads in a plurality which discharge the ink to print image information. <P>SOLUTION: The printing device having the heads discharging ink to print image information is equipped with a control means which has a printing mode for printing the image information and an ink ejecting mode for ejecting the ink and controls each of the heads, switching over the printing mode and the ink ejecting mode to each other. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a printing apparatus having a plurality of heads for printing image information by discharging ink, and in particular, by performing an ink discharge process for preventing clogging of nozzles of a head, etc., appropriately and efficiently, thereby realizing high-speed printing. The present invention relates to a printing apparatus capable of forming high-quality images and a control method of the printing apparatus.
[0002]
[Prior art]
In recent years, as a printing device that prints image information such as characters, alphanumeric characters, symbols, and images at high speed and with high image quality, extremely small bubbles are generated instantaneously by a heating element in a unit called a head, which uses liquid ink as a head. Bubble system that prints by ejecting from holes (nozzles) of the piezo system, or piezo system that performs printing by ejecting ink by using mechanical distortion of piezoelectric element, that is, collectively called inkjet printer Printing devices are commercially available.
[0003]
In the case of an ink jet printer that prints color image information, it is not possible to mix and eject ink in the head, so for example, a plurality of inks corresponding to the number of ink colors to be used such as yellow, cyan, magenta or black are used. Each head has a plurality of nozzles for ejecting ink droplets in order to print image information with high precision.
[0004]
As described above, ink jet printers print by ejecting liquid ink from nozzles.If ink is always ejected uniformly from all nozzles, ink droplets may form around the nozzles. May be stained by droplets or dust and may not be able to discharge ink normally.
[0005]
In particular, if printing has not been performed for a while, or printing of a specific color has been performed, the ink around the unused nozzles will be exposed to air and dry, causing the ink to become viscous and ejecting. In some cases, it becomes difficult or the nozzles are clogged, so that normal ink cannot be ejected.
[0006]
In general, when the nozzles are clogged due to dust or ink drying, etc. In many cases, ink is not ejected when nozzles are clogged, so white streaks appear on the printed image, not only to noticeably lower the quality, but also to correct the image information accurately. It was a serious defect because it could not be printed on the paper.
[0007]
Therefore, in order to prevent nozzle clogging and the like, generally, when the printing operation is not performed, the head is capped to prevent the adhesion of dust or the like or to make it difficult to dry, but this alone is incomplete, Moreover, even during the printing operation, as described above, there is a high risk that the ink dries and causes clogging. Therefore, usually, for example, the printing operation is performed even before the printing operation is started or during the printing operation. Temporarily suspend, periodically perform an ink discharge process of discharging a predetermined amount of ink from all the nozzles of all the heads, to recover clogging of the nozzles, etc. so that normal ink can always be discharged. The maintenance of the head including the cleaning was performed.
[0008]
In addition, conventionally, since the ink ejection control is complicated, from the viewpoint of simplifying the control, the same ink ejection timing and the same ink ejection waveform are used for both the printing operation involving the ink ejection and the ink ejection processing in the maintenance. In the case of the ejection process, since the control is performed so that the ink is ejected from all the nozzles of all the heads at the same time, the printing operation and the ink ejection process cannot be performed at the same time.
[0009]
In addition, since all the heads need to perform the ink discharging process before starting the printing operation or after the printing operation is completed, the ink discharging processing device capable of receiving and processing the discharged ink can print image information and the like. Therefore, it is necessary to set the head so that all the heads do not exist on a recording member such as a sheet of paper.
[0010]
Therefore, when performing the ink discharge processing, in the method in which ink is discharged from all the nozzles of all the heads at once, the time spent for the ink discharge processing is short, but the ink discharge processing apparatus needs to be installed in all the heads. It was necessary to make it large enough to accommodate, and inevitably made the ink jet printer a large device.
[0011]
In addition, if an attempt is made to reduce the size of the ink discharge processing apparatus to a small size, it is not possible to discharge ink from all the nozzles of all the heads at once, so that the ink discharge processing is performed for each head or for each group of heads. Processing, it takes a lot of processing time to complete the ink ejection processing for all heads including the head movement time, and the more heads, the faster the printing of image information is hindered. There was a problem of doing.
[0012]
In particular, recently, the spread of personal computers and the development of information communication networks such as the Internet have increased the number of digitized color image information. In order to faithfully reproduce and print, the number of ink jet printer heads is further increased, and the printing time tends to be shortened by printing as much image information as possible at one time. There was a need for an early solution to the disposal problem.
[0013]
[Problems to be solved by the invention]
In view of the above problems, the present invention relates to a printing apparatus having a plurality of heads that print image information by discharging ink, and particularly, appropriately and efficiently performs ink discharge processing for preventing clogging of nozzles of a head. Accordingly, it is an object of the present invention to provide a printing apparatus and a control method of the printing apparatus, which can shorten the time and can form a high-quality image at high speed.
[0014]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the invention according to claim 1, in a printing apparatus having a plurality of heads for printing image information by discharging ink, a printing mode for printing the image information and an ink for discharging ink The apparatus has a discharge processing mode, and further includes control means for switching and controlling the print mode and the ink discharge processing mode for each of the plurality of heads.
[0015]
As a result, the ink ejection processing can be executed even during the printing operation, so that the time spent on the ink ejection processing can be reduced by executing the ink ejection processing appropriately and efficiently, and high-speed, high-quality printing can be performed. It is possible to provide a printing device capable of forming a stable image.
[0016]
According to a second aspect of the present invention, in the first aspect of the invention, the print mode has an ink discharge timing and an ink discharge waveform for printing the image information, and the ink discharge processing mode is at least. It is characterized by having an ink ejection timing and an ink ejection waveform for discharging ink.
[0017]
This makes it possible to perform ink ejection suitable for each of the print mode and the ink ejection processing mode. In particular, by increasing the number of ejections in a short time, the efficiency of the ink ejection processing is further increased, and clogging and the like can be performed. Can be recovered early, and high-speed and high-quality image formation can be performed.
[0018]
According to a third aspect of the present invention, in the first or second aspect of the present invention, the control unit determines the number of times of ink ejection in the plurality of heads based on a preset print amount of image information. It is characterized in that the number of heads is determined and the mode is switched to the ink ejection processing mode.
[0019]
As a result, it is not necessary to uniformly perform the ink discharge processing, and the ink discharge processing can be performed with priority given to a head having a high risk of clogging or the like. Thus, a high-quality image can be formed.
[0020]
According to a fourth aspect of the present invention, in the first to third aspects of the present invention, the plurality of heads correspond to at least one of the plurality of heads and are provided with an ink discharge processing means for processing discharged ink. And in a position adjacent to a print area of the image information.
[0021]
As a result, the ink ejection processing device can be installed at a position near the printing area of the recording member, so that the moving time of the head can be shortened, and the moving path of the head for the ink ejection processing can be shortened. The device can be miniaturized.
[0022]
The invention according to claim 5 is a control method of a printing apparatus having a plurality of heads for printing image information by discharging ink, wherein a printing step of printing in a printing mode for printing the image information, An ink discharge processing step of discharging ink in a mode, and a control step of switching and controlling the printing step and the ink discharge processing step for each of the plurality of heads.
[0023]
As a result, the ink ejection processing can be performed at any time, and the time spent in the ink ejection processing can be shortened by performing the ink ejection processing appropriately and efficiently, so that high-speed, high-quality image formation can be performed. It is possible to provide a control method of a printing apparatus which can perform the above.
[0024]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings, but the present invention is not limited thereto.
[0025]
FIG. 1 is an overall schematic diagram of a printing apparatus according to the present invention. FIG. 2 is a block diagram showing a circuit configuration of the present invention. FIG. 3 is a schematic diagram for explaining the ink discharge processing according to the present invention.
[0026]
The configuration of the printing apparatus of the present invention will be described with reference to FIG.
In the drawing, reference numeral 1 denotes a head having nozzles for ejecting ink droplets, 2 denotes a carriage on which the head 1 is mounted, 3 denotes capping means, 4 denotes cleaning means, 5 denotes a recording member, and 11 denotes a printing device. The housing 12 is a slide guide for the carriage 2 to reciprocate.
[0027]
The head 1 ejects ink droplets from a plurality of nozzles each having an extremely small hole to print information such as characters and images (hereinafter, referred to as image information and the like). ), Which is configured to cause a head drive circuit (not shown) to generate mechanical distortion in a piezoelectric element or generate a bubble by a heat source to discharge ink droplets from a nozzle. .
[0028]
When the head 1 is, for example, a head for printing a color image, the four color inks of yellow (Y), magenta (M), cyan (C), and black (K) are converted into dark ink and light ink, respectively. There is a head unit composed of a total of eight heads for forming a higher-definition color image by discharging the ink from nozzles (not shown) separately.
[0029]
Of course, the configuration of the head unit is not limited to eight, but is set according to the specifications of the ink jet printer, the type of ink to be used, and the like. There are only four colors of M, C and K, and a single color depending on the application.
[0030]
The carriage 2 mounts the head 1 to print image information and the like on a recording member 5 such as paper or a resin film or cloth, and reciprocates along a slide guide 12. Driving is controlled via a carriage driving mechanism (not shown) including a gear, a belt, and the like serving as a driving source.
[0031]
The carriage 2 may include a head drive circuit, an ink tank for ejection called an intermediate tank (not shown), and the like in addition to the head 1.
[0032]
The capping means 3 is provided to prevent the peripheral portion of the nozzle of the head 1 from drying too much when the head 1 does not perform a printing operation, so that the ink solidifies and the ink droplets cannot be ejected from the nozzle. Although not shown in detail, it refers to a mechanism or an apparatus for closing a lid (cap) on the nozzle surface side of the head 1. Generally, a moisturizing liquid or ink is contained in the cap. A spongy material moistened with the like is provided.
[0033]
In the embodiment of the present invention, when the carriage 2 is moved to a position where a cap can be formed when the head 1 does not perform a printing operation (hereinafter referred to as a capping position), a capping mechanism (shown in FIG. ) Caps the nozzle surface side of the head 1 so that when capped, a small amount of ink is ejected from the nozzles to prevent the spongy material from drying.
[0034]
The cleaning means 4 is provided for cleaning the nozzles due to droplets of ink droplets discharged from the nozzle peripheral portion of the head 1 (hereinafter referred to as a nozzle surface), paper dust and thread debris of the recording member 5, or dirt or dust in the atmosphere. This is to prevent the ink droplet from being ejected due to the blockage and distorting the ejection direction of the ink droplet. Although not shown in detail, in general, the nozzle surface is made of a rubber spatula. Some are equipped with a suction mechanism that cleans by rubbing or wiping with a sponge-like object, and pressing the cap that is linked to the suction device against the nozzle face side to forcibly suction to clear the nozzle clogging. The operation of cleaning the nozzle surface of the head 1 or suctioning the nozzles by the cleaning means 4 is called a cleaning operation.
[0035]
When cleaning the nozzle surface (not shown) of the head 1, when the head 1 is moved by the carriage 2 to a position where cleaning operation can be performed by the cleaning means 4 (hereinafter referred to as a cleaning position) and stopped, a predetermined value is obtained. The cleaning operation is performed.
[0036]
In addition, as will be described later in detail, in the embodiment of the present invention, as a part of the maintenance operation, for example, the ink discharging process is performed in synchronization with the timing of performing the cleaning operation or independently, and the normal ink is discharged. Discharge is made possible.
[0037]
The recording member 5 is a paper or resin film or cloth for printing image information or the like, and in a large-sized printing device, a member wound in a hollow roll enough to insert a mandrel is used. In many cases, at the time of printing, a predetermined length is repeatedly fed by a feeding device (not shown) according to the printing ability, and after printing, the sheet is cut by a cutter or the like provided on the carriage 2 and used. Depending on the specifications of the printing apparatus, there is a printing apparatus in which a sheet-shaped recording member 5 cut to a predetermined size can be used.
[0038]
The slide guide 12 serves as a guide (guide) for the carriage 2 to reciprocate linearly and accurately. In many cases, the slide guide 12 is provided with a linear encoder or the like to obtain accurate movement information of the carriage 2.
[0039]
The housing 11 forms a printing device, and, in addition to the above-described units and members, not shown, mounts an ink tank, a control circuit, and various sensors and driving devices necessary for printing operation and the like. It is for covering and covering.
[0040]
A printing operation of the printing apparatus according to the embodiment of the present invention will be described.
When a print command is received from a control circuit (not shown) in a state where the head 1 mounted on the carriage 2 is at a capping position (arrow A) facing the capping means 3, the capping means 3 is turned on by a cap (not shown). Is removed from the head 1, and the carriage 2 is moved forward in the order of 2A, 2B and 2C to the left in the figure.
[0041]
When the cleaning position detection sensor (not shown) detects that the carriage 2 has reached the cleaning position (arrow B) facing the cleaning means 4, the control circuit firstly puts a sponge-like container into a container such as a tray. The ink absorber is provided, and an ink discharging process for discharging ink from all nozzles of the head toward an ink discharging processing device (not shown) capable of receiving and processing the discharged ink is executed. Then, the movement of the carriage 2 is stopped, and the cleaning means 4 cleans the nozzle surface of the head 1.
[0042]
When the cleaning means 4 completes the predetermined cleaning operation, the control circuit moves the carriage 2 forward again in the left direction in the figure.
[0043]
When an end face detection sensor (not shown) provided on the carriage 2 detects the side end face of the recording member 5, a preset margin portion or printing range on both sides is determined from a preset width dimension of the recording member 5. Then, the nozzles of the head 1 eject ink from the set print start position, start printing based on data such as image information stored in a memory (not shown) of the control circuit, and at the set print end position. Printing is completed, but the carriage 2 further advances to the second standby position (arrow D), and the second standby position detection sensor (not shown) causes the carriage 2 to reach the second standby position (arrow D). When this is detected, the control circuit stops the movement of the carriage 2.
[0044]
Thereafter, the control circuit starts the backward movement of the carriage 2 in the direction of the first standby position (arrow C), and the end surface sensor provided on the carriage 2 detects the side end surface of the recording member 5 similarly to the forward movement of the carriage 2. Is detected, printing is started from the position passing through the set margin, and printing is ended at the set printing end position. However, the carriage 2 further advances to the first standby position (arrow C) and When the standby position detection sensor (not shown) detects that the carriage 2 has reached the first standby position (arrow C), the control circuit stops the movement of the carriage 2.
[0045]
In other words, the control circuit instructs to repeat printing while reciprocating the carriage 2 within the range between the first standby position (arrow C) and the second standby position (arrow D) during printing. When the printing of data such as information is completed, the nozzle surface of the head 1 is cleaned at the cleaning position (arrow B), the nozzle surface of the head 1 is capped at the capping position (arrow A), and stopped. It instructs to prepare for the printing operation of data such as information.
[0046]
It should be noted that the control circuit performs a cleaning operation once and returns to the printing operation when a preset cleaning time has come, even during printing of data such as image information, during printing.
[0047]
The setting of the cleaning time is set according to the performance and accuracy of the head, and also changes depending on the state of data being printed or no data such as image information to be printed, that is, being in a standby state. However, in the embodiment of the present invention, when ink is continuously ejected from the nozzles of the head, a time period during which the predetermined performance and accuracy are not sufficiently realized is obtained in advance by an experiment, and Is set as a predetermined time, and the cleaning is executed when a predetermined time has elapsed from the time of the previous cleaning.
[0048]
However, the setting of the cleaning timing is not limited to this, and it is sufficient that the predetermined performance and accuracy of the head can be maintained. Therefore, the cleaning timing may be separately set in consideration of the situation such as printing or waiting. The data amount of the image information to be printed or the number of reciprocations of the carriage 2 may be set by another method.
[0049]
Further, in the embodiment of the present invention, the control of the ink ejection processing is performed in synchronization with the cleaning time for the sake of simplicity of description. The cleaning may be performed at a time different from the cleaning time based on the result of determining the number of times of ink ejection from the nozzles based on the above.
[0050]
Further, in the embodiment of the present invention, the capping position (arrow A) from the right end in the drawing is taken into consideration by considering the moving direction of the carriage 2 so that the nozzle surface of the head 1 can be easily cleaned at the time of first printing. Although the position (arrow B) and the moving position are set, the order of the arrangement may be changed in consideration of the arrangement and operation of various units of the printing apparatus, and the arrangement may be reversed. The carriage 2 may be moved from the left end position in the drawing.
[0051]
In the embodiment of the present invention, a plurality of sensors are used to detect the moving position of the carriage 2 and the like. However, the number of sensors and the control method for stopping the movement are not limited to this. The pulse drive method is such that the set pulse is given to a pulse motor or the like to control the drive, or the pulse drive method of controlling the drive by detecting the number of pulses detected by a linear encoder or the like, or the pulse drive method and a sensor are used. Speed control such as acceleration / deceleration and movement position control may be performed by using them together, and the carriage 2 may be controlled to move at a constant speed and stop at an accurate position.
[0052]
The circuit configuration of the printing apparatus according to the present invention will be described with reference to FIG.
In the figure, reference numeral 100 denotes a control circuit of the printing apparatus. The control circuit 100 includes a CPU 110, an information control circuit 120, an interface (I / F) 130, an image processing circuit 140, a drive control circuit 150, a display unit 170, and an operation unit. The drive control circuit 150 includes an input unit 180, a power supply circuit 160, and the like. The drive control circuit 150 includes a head unit 151, a carriage unit 152, a feeding unit 153 for driving the recording member 5 to a printing position, a cleaning unit 154, a capping unit 155, and the like. The information control circuit 120 includes an image data memory 121 for storing image data such as image information, and a print control data memory 122 for storing print control data associated with the image data. External as image information output means via interface (I / F) 130 Which is one of information equipment, for example, are connected to the host computer 200.
[0053]
The CPU 110 includes a control information storage unit (not shown) for storing control information such as a sequence according to a program such as various printing modes and various control modes stored in advance. To control.
[0054]
The various printing modes include, for example, a black and white mode, a color image mode, a high-definition mode for image depiction, a standard mode, a simple mode in which printing of halftone colors is not performed, and a one-direction in which a printing direction can be selected. There are a print mode, a reciprocal print mode, etc., and an edit mode in which the layout of images to be printed can be changed and characters and the like can be entered. It is also possible to respond to various print mode commands from the computer 200 or the like.
[0055]
The information control circuit 120 converts input image information and the like into data suitable for the printing device in order to quickly and smoothly control the input and output of information with an external information device and the flow of information inside the printing device. A circuit having a data conversion function as an information conversion unit for converting, for example, converts input image information into image data suitable for a printing apparatus and stores the image data in the image data memory 121. The print operation and the like of the head unit 151 interlocked with the sending unit 153 are stored in the print control data memory 122 as control data for controlling based on image data.
[0056]
In addition to the image information described above, the information control circuit 120 transmits data and commands relating to an edit mode and a print mode input by the operation input unit 180 or commands for various print modes by the host computer 200 or the like. It also has a function to quickly transmit to various related circuits.
[0057]
The image processing circuit 140 has a function as an image information processing unit that converts image data and print control data into data suitable for a head or a nozzle using the data.
[0058]
For example, at the time of printing, the image data and the print control data stored in the image data memory 121 and the print control data memory 122 are read out via the information control circuit 120. Is transferred to the drive control circuit 150, and the head unit 151 is prepared to start the printing operation on the recording member 5 in conjunction with the carriage unit 152 and the feeding unit 153, and at the same time, the image data is transferred. A color signal or a dot signal for ejecting ink is converted to a dot signal for transfer to a head drive circuit of the head means 151, and preparation is made so that ink can be ejected for each head or nozzle.
[0059]
The drive control circuit 150 drives and controls various units such as a head unit 151, a carriage unit 152, a feeding unit 153, a cleaning unit 154, a capping unit 155, and the like. A maintenance operation such as cleaning or capping and a printing operation for performing printing based on print control data and the like transferred from the image processing circuit 140 are operated based on a preset program or sequence by a command from the CPU 110. I have.
[0060]
In the embodiment of the present invention, the head unit 151 includes a head unit including a plurality of heads (for example, eight heads), a head driving circuit (not shown) for driving each head, and the like. It is installed in.
[0061]
The carriage unit 152 reciprocates during the printing operation, and performs printing on the recording member such as paper supplied by the feeding unit 153 with ink discharged from the head of the head unit 151.
[0062]
The cleaning means 154 cleans the nozzle surface of the head and the like, and the capping means 155 removes and attaches a cap for preventing the head from drying.
[0063]
In particular, in the embodiment of the present invention, the CPU 110 has a print mode for printing image data and an ink ejection processing mode for performing ink ejection processing. By operating the head drive circuit, the print mode and the ink discharge processing mode can be switched and controlled for each head.
[0064]
When the execution of the print mode is instructed by the CPU 110, the drive control circuit 150 activates the head drive circuit of the head unit 151 and performs control so that printing is performed for each head based on the ink discharge timing and the ink discharge waveform for the print mode. When the execution of the ink ejection mode is instructed, the head drive circuit of the head unit 151 is operated by the ink ejection timing and the ink ejection waveform for the ink ejection mode for each head to perform the ink ejection process. Has become.
[0065]
In other words, in the case of the ink discharge processing mode, the purpose is to recover a clogged nozzle or a nozzle likely to be clogged by ejecting ink from the nozzle to a normal state. Unlike the above case, the ink ejection timing and the ink ejection waveform are provided so that the ink can be ejected a plurality of times in a short time, regardless of the image data.
[0066]
In addition, by enabling this mode to be switched for each head, it is possible to execute the ink discharge processing depending on the head even during the printing operation, thereby improving the efficiency of the ink discharge processing and achieving high speed and high image quality. It is possible to perform simple printing.
[0067]
The printing apparatus according to the embodiment of the present invention basically prints data such as image information read from the host computer 200, for example. For example, in the edit mode, if there is a simple addition or deletion of a character such as a title, a comment, or a date, the operation input means 180 stores the character in the image data memory 121. The data such as characters is added to or deleted from the displayed image data on the display unit 170 so that the printing device can print.
[0068]
The display unit 170 is configured as, for example, a liquid crystal display device, and the CPU 110 can display a screen for commanding or inputting data with the operation input unit 180. For example, in the edit mode, addition or deletion of characters or the like is performed. For example, a screen display for editing can be displayed so that the user can confirm the execution status and the like during the operation of the printing apparatus.
[0069]
The operation input unit 180 includes, for example, a keyboard, a mouse, and the like. The operation input unit 180 can select various modes related to the operation of the printing apparatus, and can add or delete characters or the like in the editing mode. Information and data such as various instructions input by the means 180 are determined by the information control circuit 120 and the CPU 110 and the related image processing circuit 140, drive control circuit 150, display means 170, power supply circuit 160, or image data memory 121 , And the print control data memory 122 and the like.
[0070]
When the power is turned on by a power switch (not shown), the power supply circuit 160 starts up the control circuit 100 and the like by a power supply starter circuit (not shown) provided in the power supply circuit 160 to enable printing operation by various means. When the power is turned off by a power switch or a command from the CPU 110, the CPU 110 operates various units to predetermined positions and completes all the operations, and then turns off the power cutoff circuit (see FIG. (Not shown) to turn off all power.
[0071]
With reference to FIG. 3, a description will be given of the ink ejection process according to the embodiment of the present invention. FIGS. 7A and 7B are schematic diagrams for explaining the operation of the head in the ink ejection processing mode.
[0072]
In the drawing, reference numeral 5A denotes a print area of a recording member, 10 denotes a head unit mounted on a carriage (not shown), and reciprocates in the main scanning direction. , Eight heads H2, H3, H4, H5, H6, H7, and a rearmost head H8 are provided at predetermined intervals in this order from the topmost head H1. In order to simplify the drawing, the reference numerals are omitted from the drawings for the heads H2 to H7.
[0073]
Reference numeral 20 denotes an ink discharge processing means for processing the discharged ink, and reference numeral 30 denotes a broken line with reference to the conventional ink discharge processing means. The dashed line indicates the operation path of the head unit 10, and a rightward movement from the left end direction in the drawing to the ink discharging unit 20 via the printing area 5 </ b> A is defined as a main scanning direction.
[0074]
FIG. 3C shows a relationship between an electrical ink ejection timing and an ink ejection waveform given by a control circuit (not shown) to eject ink from each nozzle (not shown) of the head. , T1 is an ink discharge timing in the print mode, W1 is an ink discharge waveform corresponding to the ink discharge timing T1, T2 is an ink discharge timing in the ink discharge processing mode, and W2 is an ink discharge waveform corresponding to the ink discharge timing T2. is there.
[0075]
Although a detailed description is omitted, in the print mode, the ink ejection waveform W1 is taken into consideration in consideration of the movement of the ink in the head and the like so that the ink in the head can always be ejected accurately from the nozzles in a stable state. On the other hand, the ink ejection waveform W2 in the ink ejection processing mode is a simple waveform necessary for ejecting ink because the ink ejection waveform W2 merely recovers nozzle clogging and the like. In addition, the interval C2 of the ink ejection timing T2 is set shorter than the interval C1 of the ink ejection timing T1 in the print mode so that the ink can be repeatedly ejected in a short time.
[0076]
Conventionally, there has been no idea of performing the ink discharging process during the printing operation, and the ink discharging process is performed after all the heads have completed the printing operation. As shown in B), the conventional ink discharge processing device 30 is provided at a position where all the heads are separated from the print area 5A.
[0077]
In the print mode, the head unit 10 reciprocates on the print area 5A. In the ink discharge processing mode, the head unit 10 is moved to another area apart from the print area 5A, and then the ink discharge is performed. Since the discarding process is performed, a moving path of the head unit 10 in the main scanning direction is required in order to perform the ink discharging and discarding process from the head head H1 to the rearmost head H8. And it takes a long time to process, and also hinders miniaturization.
[0078]
However, in the embodiment of the present invention, since the print mode and the ink ejection processing mode can be switched for each head, the ink ejection processing apparatus 20 can be installed near the print area 5A, and the processing can be performed. The time can be greatly reduced.
[0079]
The ink ejection process may be performed before the start of the printing operation or during the printing operation, and is basically performed for all the nozzles of all the heads. In this case, the printing operation can be performed without interrupting the printing operation in the embodiment of the present invention, and may be performed for all the nozzles of all the heads. Is determined as a specific head, it is possible to further shorten the time of the ink discharging process and to achieve an advantage of speeding up the printing operation. These aspects will be described.
[0080]
(1) When the ink ejection process is performed before the printing operation starts
In this case, assuming that the time has elapsed since the end of the previous printing operation, it is assumed that there is a high risk that all the nozzles of all the heads will be clogged. For all nozzles.
[0081]
In FIG. 1A, prior to the start of a printing operation, a control circuit (not shown) sets all the heads to an ink ejection processing mode, and operates a carriage (not shown) to eject the head unit 10 to eject ink. It is moved toward the disposal means 20.
[0082]
For example, when the head position detection sensor (not shown) or the like detects that the leading edge head H1 has reached the ink discharge processing means 20, only the head head H1 has the ink discharge timing T2 in the ink discharge processing mode. And ink ejection waveform W2 to start ink ejection.
[0083]
The leading-edge head H1 discharges a preset amount of ink ejection at a preset plurality of ink ejection timings T2 while continuing to move, thereby completing the ink ejection process.
[0084]
Similarly, the ink ejection process is repeated by sequentially providing the ink ejection timing T2 and the ink ejection waveform W2 in the ink ejection process mode for each head until the head H8 as shown in FIG. When the ink ejection processing is completed, the control circuit temporarily stops the movement of the head unit 10, switches the ink ejection processing mode to the print mode, and starts execution of the print mode.
[0085]
In the embodiment of the present invention, after all the heads are switched to the ink discharge processing mode, the ink discharge processing is performed. For example, for each head that has reached the ink discharge processing means 20, The print mode may be switched to the ink discharge processing mode, and the print mode may be switched again when the ink discharge processing is completed.
[0086]
(2) In the case of performing ink ejection processing during printing operation
The difference from the above-described case of performing the ink discharge processing before the start of printing is that, in this case, the head performing the printing operation and the head performing the ink discharge processing coexist in the head unit 10. That is.
[0087]
In the embodiment of the present invention, when printing of preset image data (hereinafter referred to as printing of a reference amount) is completed from the start of printing, for example, there is a danger that the number of ink ejections is small and clogging or the like occurs. Assuming that a high nozzle is generated, it is assumed that the setting is made such that the ink discharging process is always performed.
[0088]
(B) When performing for all nozzles of all heads
In FIG. 5A, when the printing of the reference amount is completed during the printing operation in the printing mode, the control circuit (not shown) controls the head unit 10 to continue the printing operation and to discharge the ink from the printing area 5A. Move toward.
[0089]
When it is detected, for example, by an end face detection sensor (not shown) that the leading edge head H1 has finished the printing operation based on the printing mode program and the like and has passed the end face of the printing area 5A, the leading edge head H1 is set to the printing mode. Is switched to the ink discharge processing mode.
[0090]
At this time, the head other than the head H1 is in the print mode, and the print mode is set so as not to print in the area other than the print area 5A. Therefore, the head existing in the print area 5A continues the printing operation, The head exceeding 5A is in a state where printing is stopped.
[0091]
For example, when the head position detection sensor (not shown) or the like detects that the leading edge head H1 has reached the ink discharge processing means 20, only the head head H1 has the ink discharge timing T2 in the ink discharge processing mode. And ink ejection waveform W2 to start ink ejection.
[0092]
The leading-edge head H1 continues to move, discharges a predetermined amount of ink discharged at a predetermined plurality of times of ink discharge timing T2 to complete the ink discharge processing, and simultaneously prints from the ink discharge processing mode. Switch the mode to the mode.
[0093]
Similarly, as shown in FIG. 7B, the ink discharge process is repeated for each head until the head head H8 is reached, and when the ink discharge process is completed, the control circuit temporarily moves the head unit 10. Is stopped, and after confirming that the mode has been switched from the ink ejection processing mode to the print mode, the execution of the print mode is restarted.
[0094]
(B) When a specific head is determined and performed
There are various methods for determining a specific head having a high risk of causing nozzle clogging or the like.In the embodiment of the present invention, for example, the control circuit performs, for each image data for printing a reference amount, By discriminating the color signals and dot signals in the data, a head having a nozzle with a small number of ink ejections and a high risk of causing clogging or the like is selected in advance, and when the printing of the reference amount is completed, the ink ejection processing is performed. Is executed.
[0095]
There are various possible orders for performing the ink ejection processing, such as the order of the heads with the highest risk or the order from the most advanced head H1. In general, it is preferable to perform the order of the heads with the highest risk. Therefore, it is assumed that the risk is higher in the order of the head H1 and the head H8.
[0096]
In FIG. 9A, when the printing of the reference amount is completed, the control circuit (not shown) moves the head unit 10 from the printing area 5A to the ink discharge processing means 20 while continuing the printing operation.
[0097]
When it is detected, for example, by an end face detection sensor (not shown) that the leading edge head H1 has finished the printing operation based on the printing mode program and the like and has passed the end face of the printing area 5A, the leading edge head H1 is set to the printing mode. Is switched to the ink discharge processing mode.
[0098]
At this time, since the head other than the most advanced head H1 is in the print mode, the head existing in the print area 5A continues the printing operation, and the head beyond the print area 5A is set not to print in the area other than the print area 5A. Therefore, printing is stopped.
[0099]
For example, when the head position detection sensor (not shown) or the like detects that the leading edge head H1 has reached the ink discharge processing means 20, only the head head H1 has the ink discharge timing T2 in the ink discharge processing mode. And ink ejection waveform W2 to start ink ejection.
[0100]
The leading-edge head H1 continues to move, discharges a predetermined amount of ink discharged at a predetermined plurality of times of ink discharge timing T2 to complete the ink discharge processing, and simultaneously prints from the ink discharge processing mode. Switch the mode to the mode.
[0101]
Subsequently, the heads H2 to H7 reach the ink discharge processing unit 20 beyond the print area 5A, but pass through without switching the mode since they are not identified as specific heads.
[0102]
As shown in FIG. 8B, when the rear end head H8 exceeds the print area 5A by, for example, an end face detection sensor (not shown) or the like, the rear end head H8 is discharged from the print mode by the ink discharging process. Switch to mode. Then, when the head position H1 reaches the ink discharge processing means 20 by, for example, a head position detection sensor (not shown) or the like, the ink discharge processing is performed in the same manner as the head H1.
[0103]
At the same time when the rearmost head H8 completes the ink discharge processing, the mode is switched from the ink discharge processing mode to the print mode, and the control circuit temporarily stops the movement of the head unit 10 and switches from the ink discharge processing mode to the print mode. After confirming that the mode has been switched, execution of the print mode is resumed.
[0104]
The setting of the printing of the reference amount is provided as a reference for facilitating the identification of a specific head, and is generally set based on specifications such as the function and performance of the printing apparatus. Set up environmental conditions, etc., conduct experiments in advance, find the amount of image data, time interval, number of prints, etc. that are likely to cause nozzle clogging, and set them under the most appropriate conditions based on those experimental data. It is desirable to do. Of course, the present invention is not limited to this, and another method may be used.
[0105]
In the case where the ink ejection processing is performed during the printing operation, the head unit 10 is moved toward the ink ejection processing means 20 when the printing of the reference amount is completed in the embodiment of the present invention. When the moving direction of the head unit 10 is determined when the end is approaching, the head unit 10 is moved to the ink discharge processing means 20 when the head unit 10 is moved in the direction toward the ink discharge processing means 20. Thus, the time can be reduced more efficiently.
[0106]
In the embodiment of the present invention, when the head has exceeded the print area 5A, for example, when an end face detection sensor (not shown) or the like detects the head, the head is switched from the print mode to the ink discharge processing mode. However, when the head reaches the ink discharge processing means 20, for example, is detected by a head position detection sensor (not shown) or the like, the head is switched from the print mode to the ink discharge processing mode. The ink ejection may be started by giving the ink ejection timing and the ink ejection waveform in the ejection processing mode.
[0107]
Note that the number of ink ejections, the amount of ink ejection, the ink ejection timing, the ink ejection waveform, and the like for the ink ejection processing are appropriately set based on the performance and functions of the head to be used, the specifications of the printing apparatus, and the like. The degree of clogging is ranked in advance in consideration of environmental conditions and usage conditions, etc., and experiments are performed. The number of ink ejections, the amount of ink ejection, the ink ejection timing, and the ink ejection waveform necessary to recover from the clogging are performed. And the like, and it is desirable to set based on this experimental value.
[0108]
As described above, the printing apparatus of the present invention can switch the print mode and the ink ejection processing mode for each of a plurality of heads, so that even one head can perform the ink ejection processing. In addition, a small-sized ink ejection processing device can be used, and the moving path of the head can be shortened by providing the ink ejection processing device adjacent to the recording member, so that the printing device can be further downsized. Became.
[0109]
In addition, since the print mode and the ink discharge processing mode can be switched for each head at any time, the ink discharge processing can be appropriately and efficiently set in the control program of the printing apparatus. Since the operation and the ink ejection process can be performed in parallel, there is no need to interrupt the printing operation as in the past, greatly reducing the time.In addition, the ink ejection timing and ink ejection waveform suitable for the ink ejection process By discharging ink, clogging and the like can be quickly recovered in a short time.
[0110]
Further, since it is possible to discriminate a head having a high risk of clogging and to execute the ink ejection processing with priority, especially during the printing operation, the time spent for the ink ejection processing is dispersed, and the head is always dispersed. It is now possible to continue high-speed, high-quality printing while maintaining the normal state.
[0111]
【The invention's effect】
According to the present invention, since the print mode and the ink ejection processing mode can be switched and controlled for each head, a small ink ejection processing apparatus can be used, and the ink ejection processing apparatus can be used for recording. Since the moving path of the head can be shortened by being provided adjacent to the member, the size of the printing apparatus can be further reduced.
[0112]
Furthermore, the ink discharge processing can be performed even during the printing operation, and the ink discharge processing can be performed with priority given to a head having a high risk of causing nozzle clogging. It is possible to provide a printing apparatus and a control method of the printing apparatus that can significantly reduce time by appropriately and efficiently executing the processing, and can perform high-speed and high-quality image formation.
[Brief description of the drawings]
FIG. 1 is an overall schematic view of a printing apparatus according to the present invention.
FIG. 2 is a block diagram showing a circuit configuration of the present invention.
FIG. 3 is a schematic diagram for explaining an ink discharging process according to the present invention.
[Explanation of symbols]
1 head
2 carriage
3 Capping means
4 Cleaning means
5 Recorded member
10 Head unit
11 Case
12 slide guide
20 Ink discharge processing means
100 control circuit
110 CPU
120 Information control circuit
130 Interface (I / F)
140 Image processing circuit
150 Drive control circuit
160 power supply circuit
170 Display means
180 Operation input means
200 Host computer

Claims (5)

In a printing apparatus having a plurality of heads for printing image information by discharging ink, a printing mode for printing the image information and an ink discharge processing mode for discharging the ink, and for each head of the plurality of heads And a control means for switching and controlling the printing mode and the ink discharge processing mode. The print mode has an ink discharge timing and an ink discharge waveform for printing the image information, and the ink discharge processing mode has at least an ink discharge timing and an ink discharge waveform for discharging the ink. The printing device according to claim 1, wherein: The control means determines a head having a small number of ink ejections based on a preset print amount of image information among the plurality of heads, and switches to a ink ejection processing mode. 3. The printing device according to 1 or 2. Ink ejection processing means for processing ejected ink corresponding to at least one of the plurality of heads is provided in the main scanning direction of the plurality of heads and at a position adjacent to a print area of the image information. The printing device according to claim 1, wherein In a control method of a printing apparatus having a plurality of heads for printing image information by ejecting ink, a printing step of printing in a print mode for printing the image information, and an ink ejection for ejecting ink in an ink ejection processing mode A control method for a printing apparatus, comprising: a processing step; and a control step of switching and controlling the printing step and the ink ejection processing step for each of the plurality of heads.

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