1. Field of the Invention
The present invention relates to an inkjet printing apparatus that prints an image using ink supplied via an ink supply line from an ink tank, and also to a method of controlling such an inkjet printing apparatus.
2. Description of the Related Art
Among inkjet printing apparatuses that print an image onto a print medium by using a print head able to eject ink, there are apparatuses that supply ink to a print head via a tube or other ink supply pipe from an ink tank located at a position distanced from the print head. The inkjet printing apparatus that supplies ink via such an ink supply pipe has advantages such as increased freedom in ink tank placement, or easier enlargement of ink tank volume. However, since most elastic materials used for ink supply pipes have gas permeability properties, there is a risk that air bubbles may penetrate inside an ink supply pipe over long periods of use. In the case where such air bubbles accompany the flow of ink and flow into the interior of a print head, there is a risk of causing faulty ink ejection or other negative effects in the print head. For this reason, it is necessary to eliminate air bubbles that have penetrated into an ink supply pipe in this way.
As one method of discharging air bubbles inside an ink supply pipe, Japanese Patent Laid-Open No. H08-207315 (1996) describes a method that uses a configuration wherein ink inside a print head is forcibly suctioned out and discharged from a print head nozzle (a suction discharge operation). Namely, the elapsed time since the last suction discharge operation is measured, and the next suction discharge operation is performed when the measured time exceeds a fixed value. In so doing, air bubbles inside a print head are suctioned out and discharged together with ink.
In Japanese Patent Laid-Open No. H08-207315 (1996), only air bubbles that have permeated the material of an ink supply line are considered, and by managing time using a timer, air bubbles that have permeated and penetrated the material of the ink supply line are suctioned and discharged every time a fixed amount of time elapses. For this reason, the air bubble penetration volume cannot be ascertained with regard to air bubbles that are pushed in during ink tank installation or air bubbles whose penetration volume cannot be uniformly managed by time management only, and timings at which to perform suction discharge operations cannot be optimally set.
The present invention provides an inkjet printing apparatus and a method of controlling an inkjet printing apparatus whereby the performing of a suction discharge operation for air bubbles that have penetrated inside an ink supply line can be suppressed to a minimum necessary number of times and whereby the ink discharge volume that accompanies air bubble suction discharge operations can be kept low.
In the first aspect of the present invention, there is provided an inkjet printing apparatus that prints an image by using a print head able to eject ink, supplied from an ink tank via an ink supply line, from an ejection port, comprising:
an estimator configured to individually estimate air bubble penetration volumes by which air bubbles penetrate into the ink supply line for a plurality of penetration factors by which air bubbles penetrate into the ink supply line; and
a suction discharge unit configured to suction out and discharge an air bubble inside the print head and inside the ink supply line by causing negative pressure to be exerted on the ejection port from the outside, when the sum of air bubble penetration volumes individually estimated for the plurality of penetration factors becomes equal to or greater than a predetermined volume.
In the second aspect of the present invention, there is provided a method of controlling an inkjet printing apparatus that prints an image by using a print head able to eject ink, supplied from an ink tank via an ink supply line, from an ejection port, comprising steps of:
individually estimating air bubble penetration volumes by which air bubbles penetrate into the ink supply line for a plurality of penetration factors by which air bubbles penetrate into the ink supply line; and
suctioning and discharging an air bubble inside the print head and inside the ink supply line by causing negative pressure to be exerted on the ejection port from the outside, when the sum of air bubble penetration volumes individually estimated for the plurality of penetration factors becomes equal to or greater than a predetermined volume.
According to the present invention, an air bubble penetration volume is estimated for each of a plurality of penetration factors by which air bubbles penetrate into an ink supply line, and an air bubble suction discharge operation is conducted when the sum of these penetration volumes has become a given volume or more. For this reason, air bubbles inside an ink supply line can be suctioned and discharged by a minimum necessary number of suction discharge operations. As a result, faulty ink ejections or other negative effects in a print head due to air bubbles that have penetrated inside the ink supply line can be avoided and a high-quality image can be printed, while in addition, the volume of ink discharged along with air bubble suction discharges can be decreased.
Further features of the present invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).
Hereinafter, embodiments of the present invention will be described in detail and with reference to the drawings.
In
A plurality of nozzles able to eject ink are formed on the print head 13. These nozzles are formed such that nozzle lines corresponding to each ink color extend in a direction that intersects (and in the case of the present example, is orthogonal to) the main scan direction. Each respective nozzle is able to eject ink by using an electrothermal conversion element (heater) or piezo element. In the case of using the electrothermal converter, a bubble is formed in the ink due to the heat produced, and the bubble-forming energy can be used to eject ink from an ejection port at the nozzle tip.
By alternately repeating print scans, which eject ink from nozzles while the print head 13 moves in the main scan direction together with the carriage 14, and operations that convey a print medium P in the sub scan direction, an image can be successively printed onto the print medium P. In this way, the printing apparatus of the present example functions as what is called a serial scan printing apparatus. In the case where maintenance of the print head 13 is required, the carriage 14 moves to a position over a suction cap 15. The suction cap 15 can ascend and descend by a driving source (not illustrated), and by ascending during maintenance, the suction cap 15 fits tightly against and caps the nozzle formation surface of the print head 13 where the nozzles are formed. The suction cap 15 is joined to a suction pump 16, which is able to depressurize the inside of the suction cap 15 during suction recovery operations. By depressurizing the inside of the suction cap 15 with the suction pump 16, ink inside the print head 13 can be suctioned from the nozzles of the print head 13 and discharged inside the suction cap 15. In other words, by causing negative pressure to act on the ports at the nozzle tips from the outside, air bubbles inside the print head and inside the ink supply lines can be suctioned out and discharged together with ink. Suctioned and discharged ink is discharged and stored in a waste ink absorber (not illustrated) inside the inkjet printing apparatus via a discharge pipe 17.
According to such a suction and discharge operation, thickened ink and air bubbles inside the ink supply lines between the main tanks and the print head 13 and inside the print head 13 can be discharged. Furthermore, by causing the suction pump 16 to operate in a state where the open-closed valve 8 is closed, depressurization inside the ink supply lines from the main tanks to the print head 13 and inside the print head 13 can be increased, as discussed later.
A CPU 100 controls respective parts of the apparatus and executes data processing via a main bus line 105. In other words, the CPU 100, following a program stored in ROM 101, executes printing operations by controlling data processing, driving of the print head, and driving of the carriage. The CPU 100 is able to communicate with an external host apparatus via an interface 104. As discussed later, a process that estimates air bubble penetration volumes for individual air bubble penetration factors and a process that controls a suction discharge operation on the basis of those estimated air bubble penetration volumes can be executed under control by the CPU 100. Also, at least part of these processes may also be executed by the external host apparatus coupled via the interface 104. RAM 102 is used as a work area for data processing, etc. by the CPU 100. Also, the RAM 102 can temporarily save information such as print data for a plurality of scans, parameters related to recovery operations (including suction discharge operations) for maintaining a good ink ejection state in the print head, and parameters related to ink supply operations. An image input unit 103 temporarily holds an image input from the host apparatus via the interface 104. Non-volatile memory 116 stores an operational history of the printing apparatus, including the times at which recovery process operations were conducted and their number, etc.
A reference numeral 117 denotes a temperature sensor and a reference numeral 118 denotes a humidity sensor which detect the temperature and humidity of the environment in which the printing apparatus is placed, with the detection results being processed as control factors for ink ejection operations from the print head and recovery operations of the print head. A supply system control circuit 106 follows a supply process program stored in the RAM 102 to control a supply system motor 107, which causes the pressure pump 5 to operate. By the operation of the pressure pump 5, ink inside the main tanks is pressurized as discussed earlier. A recovery system control circuit 108 follows a recovery process program stored in the RAM 102 to control a recovery system motor, which executes a recovery process operation by the ascending and descending of the suction cap 15 and the suction pump 16 discussed earlier. A head driving control circuit 112 causes ink to be ejected from the print head 13 in order to print an image (ink ejection operations). A carriage driving control circuit 114 controls movement of the carriage 14 in the main scan direction in accordance with print data input from the image input unit 103.
The main tank 1 is configured to house an ink pack 22 inside a main tank enclosure 21, and is able to supply ink inside the ink pack 22 into the printing apparatus via an ink communication pipe 23. The ink communication pipe 23 is supported by the main tank enclosure 21, and communicates with a supply tube 7 (see
In the case where ink is expended via the filter 44 and negative pressure rises inside the negative pressure chamber 45 during printing operations and maintenance operations (including suction discharge operations), etc., the supply restriction valve 42 opens and the ink chamber 43 and the negative pressure chamber 45 communicate with each other, as in
As discussed later, the ink supply line reaching from the main tank to the sub-tank includes air bubbles penetrating from the outside through the walls of the supply tube 7 and air bubbles that are pushed in during ink tank installation. If such air bubbles penetrate into the ink supply line and reach the print head, there is a risk that the print head may become unable to eject ink normally, and desired printing may not be possible. In the present example, a suction discharge operation (also called a “choke suction operation”) is executed in order to eliminate air bubbles that have penetrated inside the ink supply line in this way.
First, in step S1 the pressure pump 5 is stopped, and pressurization inside the ink supply line is canceled. In so doing, the open-closed valve 8 enters the closed state as in
After the suction pump 16 has been driven the given amount, in step S4 operation of the pressure pump 5 is initiated. Due to the pressure pump 5 operating, the open-closed valve 8 enters the open state as in
Due to the choke suction operation like the above, the air bubble residing inside the sub-tank or the air bubble residing inside the ink supply line in the vicinity of the sub-tank can be suctioned out from the nozzles of the print head and discharged. Since ink is also discharged together with air bubbles in the choke suction operation, it is preferable to limit the number of times the operation is executed to the minimum necessary number. Thus, in the present embodiment, the total air bubble volume inside the ink supply line is estimated, and the choke suction operation is conducted only in the case where the air bubble volume has exceeded a given value. The method for estimating air bubble volume inside the ink supply line may be taken to involve computing penetration air bubble volumes for individual air bubble penetration factors, and taking their sum to be the total air bubble volume.
Hereinafter, a method for estimating air bubble volume inside an ink supply line will be explained.
One example of a factor by which air bubbles penetrate into an ink supply line is the factor by which air bubbles penetrate from the outside through the walls of an ink supply line such as a supply tube 7 (first penetration factor). The volume A of air bubbles penetrating from the outside through the walls of the ink supply line in this way can be estimated on the basis of the elapsed time since the choke suction operation was last conducted. In other words, the elapsed time from the time when the choke suction operation was last conducted up to the current time is measured by a timer, and the air bubble volume A is predicted according to the following equation 1 based on the measured time “T” and the air bubble penetration volume per unit time “a” in which air bubbles penetrate from the outside through the walls of the ink supply line.
A=T×a (1)
Another example of a factor by which air bubbles penetrate into the ink supply line is the factor by which air bubbles are pushed in during main tank installation (second penetration factor).
In
The volume B of an air bubble that penetrates during installation of a main tank (hereinafter also called the “next main ink tank”) can be estimated on the basis of the amount of remaining ink in a main tank (hereinafter also called the “last main ink tank”) that was removed from the ink channel before installing the next ink tank. In other words, air bubble volumes b1, b2, b3, . . . , corresponding to the amount of remaining ink in the last main ink tank are computed from the air bubble volume table in
B=b1+b2+b3+ (2)
In the present embodiment, the previously discussed choke suction operation is executed when the sum of these air bubble volumes A and B has exceeded a prescribed value. The prescribed value is the volume obtained by subtracting the residual air bubble volume in the ink supply line during initial ink filling and after the choke suction operation from the air bubble volume that can be held inside the sub-tank.
First, in step S11, the elapsed time T since the choke suction operation was last conducted is acquired, and in step S12, the air bubble volume A is computed according to the above equation 1. In the next step S13, the air bubble volume B is computed according to the above equation 2. After that, the sum of the air bubble volumes A and B is compared to the previously discussed prescribed value. When the value of the former is equal to or greater than the value of the latter, the choke suction operation is executed in step S15. When the value of the former is less than the value of the latter, the process ends without executing the choke suction operation. In other words, the choke suction operation is executed upon the condition of the sum of the air bubble volumes A and B being equal to or greater than the predetermined volume.
As above, penetrating air bubble volumes are estimated for individual air bubble penetration factors for the ink supply line, and when the sum of those air bubble volumes reaches a volume requiring an air bubble discharge operation (choke suction operation), that discharge operation (choke suction operation) is conducted. As a result, by conducting the necessary minimum number of air bubble discharge operations, adverse effects on printing operations due to air bubble penetration can be avoided, while the volume of ink discharged together with air bubbles can be kept low.
One type of air bubble that penetrates into the ink supply line is an air bubble that penetrates as ink evaporates from the joint of the ink supply line while the main tank is not installed.
In
When the main tank is installed as in
C=Tc×c (3)
The ink evaporation volume per unit time c is affected by the temperature and humidity of the environment in which the printing apparatus is placed. For this reason, the ink evaporation volume per unit time “c” is determined according to the detection results of the temperature sensor 117 and the humidity sensor 118 inside the printing apparatus.
In the present embodiment, the air bubble volume C is computed in addition to the air bubble volumes A and B in the first embodiment discussed earlier, and the choke suction operation is executed when their sum becomes equal to or greater than a prescribed value. Similarly to the case of the first embodiment, the prescribed value in this case is the value obtained by subtracting the residual air bubble volume in the ink supply line during initial ink filling and after the choke suction operation from the air bubble volume that can be held inside the sub-tank.
Another penetration factor by which air bubbles penetrate into the ink supply line is the factor by which dissolved gas in ink separates out to form an air bubble (third penetration factor). The temperature rises once ink is supplied from the main tank to the ink supply line, and when gas dissolved in the ink exceeds a saturation point, the gas separates out inside the ink supply line as an air bubble. The volume that separates out as an air bubble (air bubble volume) D can be estimated from the volume of the ink supply line and the temperature rise since the last suction discharge operation (the temperature rise from the temperature during the last suction operation to the current temperature). The volume of the ink supply line is fixed. Consequently, an air bubble separation volume table associating temperature rises and air bubble volumes D is stored in ROM 101 inside the printing apparatus (see
In the present embodiment, the air bubble volume D corresponding to the temperature change is computed in addition to the air bubble volumes computed in the first and second embodiments discussed earlier, and the choke suction operation is executed when their sum becomes equal to or greater than a prescribed value set as the air bubble volume that can be held in the sub-tank.
The present invention may be widely applied not only to the serial scan printing apparatus discussed above, but also to various types of printing apparatus, such as full-line type printing apparatus which use a long print head extending across the entire horizontal print area in the printing medium. The configuration of ink supply lines is arbitrary, and is not necessarily limited to a specific configuration that includes elastic supply tubes. Also, it is not strictly necessary to provide the sub-tank along the ink supply line.
Also, the present invention is able to estimate air bubble penetration volumes according to at least two penetration factors from among the first, second, and third air bubble penetration factors discussed above, and execute the suction discharge operation when their sum becomes equal to or greater than a given volume. The present invention may also respectively estimate air bubble penetration volumes according to a plurality of penetration factors which include the first, second, and third air bubble penetration factors discussed above, and execute the suction discharge operation when their sum becomes equal to or greater than a given volume.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2010-192349, filed Aug. 30, 2010, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2010-192349 | Aug 2010 | JP | national |
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Number | Date | Country |
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08-207315 | Aug 1996 | JP |
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Entry |
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Office Action in Japanese Patent Application No. 2010-192349, dates Mar. 11, 2014. |
Number | Date | Country | |
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20120050426 A1 | Mar 2012 | US |