1. Field of the Invention
The present invention relates to an inkjet recording apparatus and a control method for the inkjet recording apparatus.
2. Description of the Related Art
When ink is ejected from an ejection opening of a recording head of an inkjet recording apparatus, ink mist that is not landed on a recording medium is generated. The ink mist is deposited on an ejection opening surface of the recording head or the like and may prevent the ink ejected from the ejection opening from landing at a normal position. The ink mist deposited on the ejection opening surface is normally removed by a wiper blade.
In recent years, a technology for solidifying the ink on the recording medium by using ultraviolet rays, micro waves, heat, or the like has been developed to perform recording on the recording medium that does not have an ink receptor layer. In the above-described configuration, thermal fixing ink or the like which is easily be solidified on the recording medium by the heat or the like is used. According to such configuration too, the ink mist deposited on the ejection opening surface is firmly solidified on the ejection opening surface and may prevent the ink from the ejection opening from landing at a normal position. Since the ink mist according to the above-described inkjet recording technology is firmly solidified, it is difficult to remove the ink mist by a normal wiper blade in some cases.
U.S. Pat. No. 6,692,100 discloses a recording apparatus in which a sheet-like member is supplied to a position facing the ejection opening surface, and this sheet-like member is abutted against the ejection opening surface to perform wiping, so that the ejection opening surface is cleaned. U.S. Pat. No. 6,692,100 also discloses that the sheet-like member that has once been used for the wiping is reeled by a reeling roller, so that an unused part of the sheet-like member is supplied to the position facing the ejection opening surface.
Incidentally, since the sheet-like member is reeled for every wiping operation in the recording apparatus according to U.S. Pat. No. 6,692,100, even a site of sheet-like member where the contamination is moderate and the ejection opening surface can be cleaned again may be reeled in some cases. To elaborate, the sheet-like member is not reeled at an appropriate timing in accordance with a degree of contamination of the sheet-like member in the recording apparatus according to U.S. Pat. No. 6,692,100, and much of the sheet-like member may be consumed beyond necessity.
On the other hand, it is also conceivable to perform the reeling operation for every certain number of the wiping operations, but in such case, much of the contamination caused by the wiping operation is accumulated at a predetermined site of the sheet-like member. For this reason, even when the wiping operation is performed at this predetermined site, the ink solidified on the ejection opening surface may not sufficiently be removed.
According to an aspect of the present invention, there is provided an inkjet recording apparatus that can reduce a use amount of the sheet-like member by performing a control to reel the sheet-like member at an appropriate timing while the wiping operation for keeping the satisfactory ejection opening surface is performed.
According to another aspect of the present invention, there is provided an inkjet recording apparatus including: an inkjet recording head including an ejection opening surface from which ink is ejected; a wiping unit configured to wipe the ejection opening surface; a changing unit configured to perform a changing operation for changing a wiping area of the wiping unit; an obtaining unit configured to obtain a value related to an ink amount ejected from the inkjet recording head; and a control unit configured to cause the changing unit to perform the changing operation on the basis of the value related to the ink amount which is obtained by the obtaining unit.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Hereinafter, exemplary embodiments of the present invention will be described with reference to the drawings.
The recording medium P is held at a spool 6. The recording medium P held in the spool 6 is conveyed towards a platen 4 by a feed roller which is not illustrated in the drawing. The feed roller is driven by a feed motor 5 which will be described below. The recording medium P is conveyed along the conveyance direction Y on the platen 4.
When the recording medium P is conveyed to a recording position facing the recording head 9 mounted to the carriage 2, the carriage 2 is moved in the main scanning direction X along a guide shaft 8. During this movement, ink is ejected from the recording head 9. Ejection opening columns 11 to 16 which will be described are provided on the recording head 9. While the ink is ejected from the ejection opening columns 11 to 16, a recording operation is performed at certain band widths corresponding to ranges of the ejection opening columns 11 to 16. A timing at which the ink is ejected is determined on the basis of a position signal obtained by an encoder 7.
After the recording operation at the recording position is ended, the recording medium P is conveyed at a predetermined amount along the conveyance direction Y, and a new area of the recording medium P faces the recording head 9. The recording operation is also performed at the certain band widths corresponding to the ranges of the ejection opening columns 11 to 16 on the new area of the recording medium P.
The ejection opening columns 11 to 16 are respectively constituted by a plurality of ejection openings 11a to 16a. The ejection openings 11a to 16a are respectively arranged in the conveyance direction Y. Ink colors are, for example, black (Bk), light cyan (Lc), cyan (C), light magenta (Lm), magenta (M), and yellow (Y). The ejection openings 11a to 16a eject ink of a color allocated to each ejection opening among the ink of the plurality of colors. The ejection openings 11a to 16a eject the ink by head generated by a heater. The ink may be fixed on the recording medium P by the heat.
The ink is supplied to the ejection openings 11a to 16a from ink introduction units 22 via ink paths inside the recording head 9. The ink is supplied from an ink tank 14 which will be described below to the ink introduction units 22 via a tube 13 which will be described below.
The recovery unit 23 includes a wiper 26, a cap 27, and the like. The cap 27 is elevated and lowered by an elevating and lowering mechanism which is not illustrated in the drawing. When the cap 27 is elevated, the ejection opening surface 10 is capped.
The sheet-like member 31 is pressed up by the abutting member 33, so that the sheet-like member 31 abuts against the ejection opening surface 10. Next, the ejection opening surface 10 and the wiping unit 30 are relatively moved in a state in which the sheet-like member 31 abuts against the ejection opening surface 10, so that the ejection opening surface 10 is wiped by the sheet-like member 31.
By reeling the sheet-like member 31 by the reeling roller 32, a portion of the sheet-like member 31 at a position facing the ejection opening surface 10 is reeled. This site of the sheet-like member 31 at the position facing the ejection opening surface 10 corresponds to a wiping area for wiping the ejection opening surface 10.
The console 106 includes a setting input unit for a user to perform various settings of the inkjet recording apparatus 1 and a display unit that displays a message to the user. The home position sensor group 107 includes a home position sensor that detects that the carriage 2 is at the home position, a capping sensor that detects that the ejection opening surface 10 is capped by the cap 27, and the like.
The MPU 102 controls the inkjet recording apparatus 1 while following a control program stored in a controlling ROM 105. A RAM 103 is used as a work area of the MPU 102 and stores received signals to temporarily store various data. A font generating ROM 104 stores pattern information such as a character or a record corresponding to code information and outputs various pattern information corresponding to input code information. The print buffer 121 stores a storage capacity for a predetermined number of rows of the recording data and temporarily stores the recording data expanded to the RAM 103 or the like.
The ejection number of the ink ejected from the recording head 9 is measured by the MPU 102 or the like from the stored data in the print buffer 121 or the like.
The controlling ROM 105 can also store fixed data corresponding to data used in the control. Herein, the data used in the control is data for determining on whether the wiping operation is performed or the like.
The RAM 103, the font generating ROM 104, the controlling ROM 105, and the print buffer 121 are controlled by the MPU 102 via an address bus 117 and a data bus 118.
A capping motor 113 is a drive source for the elevating and lowering operation of the cap 27, the movement operation of the wiper 26, or the like. A carriage motor 3 moves the carriage 2. The feed motor 5 conveys the recording medium P along the conveyance direction Y. A wiping unit motor 122 rotates the reeling roller 32 and collects the sheet-like member 31 into the reeling roller 32. Motor drives 114, 115, 116, and 123 respectively drive the capping motor 113, the carriage motor 3, the feed motor 5, and the wiping unit motor 122 in accordance with a control of the MPU 102.
A sheet sensor 109 detects a leading end and a trailing end of the recording medium P. A head driver 111 drives a recording element of the recording head 9 in accordance with the recording information signal transmitted from the host computer 100. A power supply unit 120 supplies power to each unit of the control circuit 130. The power supply unit 120 includes an AC adopter and a battery as a drive power supply apparatus.
A weighing scale 12 weighs a weight of the ink tank 14 which will be described below and transmits a measurement result to the PPI 101.
When it is determined that the recording data for the one scanning is accumulated in the print buffer 121, while the carriage 2 is moved from the home position to the back position, the recording operation for the one scanning is executed. After the start of the recording operation, while the moving platform 61 is moved in the conveyance direction Y, the wiping unit 30 is located on the extension line in the main scanning direction X of the platen 4. This is because auxiliary ejection of the ink is performed towards the wiping unit 30 from the recording head 9 mounted to the carriage 2. When it is determined that the recording data for the next one scanning is accumulated in the print buffer 121, while the carriage 2 is moved from the back position to the home position, the recording operation for the one scanning is executed. After the execution of the recording operation for the two scannings by this reciprocating operation, the wiping operation by the wiping unit 30 is executed.
In the wiping operation, first, as illustrated in
The used area of the sheet-like member 31 is collected by rotating the reeling roller 32. By executing a changing operation for reeling the used area, an unused area of the sheet-like member 31 faces the ejection opening surface 10.
As illustrated in
After the recording operation in step S2, it is determined whether or not the wiping operation is executed in step S3. According to the present exemplary embodiment, the wiping unit 30 is not provided at the back position. For this reason, the wiping operation by the recording head 9 is not executed after the recording operation in the moving direction from the home position to the back position by the recording head 9. Therefore, No is determined in step S3 for the first time, and the flow proceeds to step S9.
In step S9, it is checked whether or not the recording data exists. In a case where the recording data does not exist, No is determined in step S9, the recording processing is ended. In a case where the recording data exists, Yes is determined in step S9. The flow returns to step S2, and the recording operation is executed again.
The carriage 2 is positioned at the back position by the recording operation in step S2 for the first time. For this reason, in the recording operation in step S2 for the second time, the recording operation in the moving direction from the back position to the home position is performed by the recording head 9 mounted to the carriage 2. After that, it is determined whether or not the wiping operation is executed in step S3. After the recording operation in step S2 for the second time, the carriage 2 is located at the home position. For this reason, it is possible to execute the wiping operation by the recording head 9.
When it is determined that the wiping operation is executed in step S3, the flow proceeds to step S4, and the wiping operation is executed. After the wiping operation is executed in step S4, it is determined whether or not the total ejection number DT is higher than or equal to a wiping operation threshold DL of 2.0×109 in step S5. When the relationship of DT DL is not established, that is, DT<DL, the flow proceeds to step S9, and it is checked whether or not the recording data exists. When the relationship of DT DL is established, that is, when DT is higher than or equal to the threshold DL, the flow proceeds to step S6, and the reeling operation of the sheet-like member 31 is executed.
In a case where the relationship of DT DL is not established, it is determined that the wiping area of the sheet-like member 31 does not lose the wiping capability. Therefore, it is determined that the ejection opening surface 10 can be cleaned by the same wiping area again. Without executing the reeling operation of the sheet-like member 31 in step S6, the flow proceeds to step S9, and the recording operation is continued.
In a case where the relationship of DT DL is established, it is determined that the wiping area of the sheet-like member 31 has already lost the wiping capability. Therefore, the ejection opening surface 10 is not cleaned by the same wiping area again. For this reason, by executing the reeling operation of the sheet-like member 31 in step S6, the wiping area where the wiping capability of the sheet-like member 31 has lost is collected. Subsequently, an unused site of the sheet-like member 31 is unreeled to the position facing the ejection opening surface 10 of the recording head 9 as the wiping area. The ejection opening surface 10 is wiped by this unused site of the sheet-like member 31.
After the sheet-like member 31 is reeled in step S6, the total ejection number DT that has been measured from step S1 is reset to 0 in step S7. After the total ejection number DT is reset in step S7, the measurement of the total ejection number DT is started again in step S8 similarly as in step S1.
The total ejection number DT1 after one reciprocation is 1×109, the total ejection number DT2 after two reciprocations is 1.5×109, the total ejection number DT4 after four reciprocations is 1.5×109. Since these values are all lower than the wiping operation threshold DL of 2.0×109, the reeling operation of the sheet-like member 31 is not executed.
In contrast to this, the total ejection number DT3 after three reciprocations is 2.5×109, and the total ejection number DT5 after five reciprocations is 3×109. Since these values are all higher than or equal to the wiping operation threshold DL of 2.0×109, the reeling operation of the sheet-like member 31 is executed after three and five reciprocations.
According to the present exemplary embodiment, the reeling operation of the sheet-like member 31 is performed in accordance with each ejection number of the ink from each of the ejection opening columns 11 to 16 of the ejection opening surface 10. Components similar to those according to the first exemplary embodiment will be omitted for the following description.
The ink mist is deposited in the vicinity of the ejection opening that ejects the ink corresponding to the generation source of the ink mist. For this reason, the ink mist of the ink ejected by each of the ejection opening columns 11 to 16 itself is also deposited on the ejection opening surface 10 in the vicinity of each of the ejection opening columns 11 to 16. Therefore, along with the increase in the ejection number of the ink from each of the ejection opening columns 11 to 16, the contamination amount of the ejection opening surface 10 in the vicinity of each ejection opening column. According to the present exemplary embodiment, the contamination of the vicinity of each of the ejection opening columns 11 to 16 is estimated from the ejection number of each of the ejection opening columns 11 to 16.
The steps related to the recording operation in steps S12 to S14 are similar to steps S2 to S4 of
After the wiping operation in step S14, a maximum ejection number Dmax among the ejection numbers for the respective ejection opening columns is calculated in step S15. Next, in step S16, it is determined whether or not the maximum ejection number Dmax is higher than or equal to a wiping operation threshold DLmax of the ejection number for each ejection opening column. According to the present exemplary embodiment, the wiping operation threshold DLmax for the ejection numbers for the respective ejection opening columns is 5×108.
The processing after the determination in step S16 is similar to the processing after the determination in step S5 of
The maximum ejection number Dmax after the one reciprocation is 5×107, the maximum ejection number Dmax after the two reciprocations is 2.5×108, and the maximum ejection number Dmax after the four reciprocations is 1.5×108. Since these values are all lower than the wiping operation threshold DLmax of 5×108, the reeling operation of the sheet-like member 31 is not executed.
In contrast to this, the maximum ejection number Dmax after the three reciprocations is 5.5×108, the maximum ejection number Dmax after the five reciprocations is 5×108. Since these values are all higher than or equal to the wiping operation threshold DLmax of 5×108, the reeling operation of the sheet-like member 31 is executed after the three reciprocations and the five reciprocations.
According to the present exemplary embodiment, the contamination on the part for wiping each ejection opening column is determined on the basis of the ejection number D of the ink of each ejection opening column, and the reeling operation is executed in accordance with the determination result. For that reason, it is possible to execute the reeling operation at a more appropriate timing.
According to the present exemplary embodiment, the reeling operation of the sheet-like member 31 is performed in accordance with the ink ejection number for each area obtained by dividing the ejection opening surface 10 in a direction intersecting with the wiping direction. Components similar to those according to the first and second exemplary embodiments will be omitted for the following description.
Each of the areas obtained by dividing the ejection opening surface 10 is contaminated by the ink mist of the ink ejected by the ejection opening itself provided in the corresponding divided area. Therefore, the contamination amount on each divided area is increased along with the increase in the ejection number of the ink from the ejection opening on the divided area. According to the present exemplary embodiment, the contamination on each divided area is estimated from the ejection number the ejection opening on the divided area.
When it is determined that the recording data for the one scanning is accumulated in the print buffer 121, while the carriage 2 is moved from the home position to the back position, the recording operation for the one scanning is executed. According to the present exemplary embodiment, since the wiping unit 30 is arranged at the back position, after the recording operation by the recording head 9 from the home position to the back position is performed, the wiping operation by the recording head 9 is executed. After the wiping operation, when it is determined that the recording data for the next one scanning is accumulated in the print buffer 121, while the carriage 2 is moved from the back position to the home position, the recording operation for the next one scanning is executed.
In the wiping operation according to the present exemplary embodiment, first, as illustrated in
In step S23, it is determined whether or not the wiping operation of the recording head 9 is executed. According to the present exemplary embodiment, since the wiping unit 30 is located at the back position, the wiping operation by the recording head 9 is executed after the recording operation in the moving direction from the home position to the back position by the recording head 9. Therefore, Yes is determined in step S23 for the first time, and the flow proceeds to step S24.
After the wiping operation is executed in step S24, the flow proceeds to step S25. In step S25, a maximum ejection number DLAmax is calculated among the ejection numbers of the respective areas. Next, in step S26, it is determined whether or not a maximum ejection number DAmax is higher than or equal to the wiping operation threshold DLAmax of 2×1010.
The processing after the determination in step S26 is similar to the processing after the determination in step S5 of
DAmax of the maximum ejection number DA1 after the one reciprocation is 5×109, DAmax of the maximum ejection number DA2 after the two reciprocations is 1×1010, and DAmax of the maximum ejection number DA4 after the four reciprocations is 1.5×1010. Since these values are all lower than the wiping operation threshold DLAmax of 2×1010, the reeling operation of the sheet-like member 31 is not executed.
In contrast to this, DAmax of the maximum ejection number DA3 after the three reciprocations is 6×1010, and DAmax of the maximum ejection number DA5 after the five reciprocations is 5×1010. Since these values are all higher than or equal to the wiping operation threshold DLAmax of 2×1010, the reeling operation of the sheet-like member 31 is executed after the three reciprocations and the five reciprocations.
According to the present exemplary embodiment, the determination on the contamination on the wiping part is made on the basis of the ejection number DA of the ink for each divided area, and the reeling operation is executed in accordance with the determination result. For that reason, it is possible to execute the reeling operation at an appropriate timing in a so-called lateral wiping configuration.
According to the present exemplary embodiment, the reeling operation is performed in accordance with the ink consumption consumed in the recording operation. Components similar to those according to the first to third exemplary embodiments will be omitted for the following description.
The ink consumption is obtained from a weight change of the ink tank 14 which is caused by the recording operation. The weight change of the ink tank 14 is obtained by the weighing scale 12 arranged on a bottom surface of the ink tank 14. The weight of the ink tank 14 is measured by the weighing scale 12 before and after the recording operation, and the weight of the ink in the ink tank 14 which has been reduced by the recording operation is obtained. The weight of the ink which has been reduced by the recording operation is set as the ink consumption consumed in the recording operation.
This ink consumption is not limited to the weight of the ink and may be a volume of the ink which is calculated from the weight of the ink. In addition, the ink consumption may also be a volume of the ink which is obtained by multiplying the ejection number of ink droplets by the volume of the ink droplet. Moreover, a configuration may also be adopted in which a large number of pins for detecting the remaining amount are provided to the ink tank 14 so that a height of the ink liquid level may finely be obtained. In this configuration, the volume of the ink consumption is obtained from the height change of the ink liquid level detected by the pins and the cross-sectional area of the ink tank 14.
The steps related to the recording operation in steps S32 to S34 are similar to steps S2 to S4 of
The processing after the determination in step S35 is similar to the processing after the determination in step S5 of
The ink consumption threshold CL is determined through a method similar to the method of determining the wiping operation threshold DL from
The configuration is not limited to the ejection number of the ink according to the present exemplary embodiment, but also the reeling operation of the sheet-like member 31 can appropriately be controlled in accordance with the ink consumption.
Exemplary embodiments of the present invention can widely be applied to various inkjet recording apparatuses configured to recording an image by using a recording head that can eject ink from an ejection opening. Therefore, the inkjet recording apparatus is not limited to the apparatus including a serial head and may also be an apparatus including a line head.
The ejection number is not limited to the ejection number of the ink actually ejected from the recording head 9 and may also be an ejection number estimated from the recorded image data. For example, the ejection number may be an ejection number estimated from RGB data or CMYK data of the recorded image or the like.
In addition, the configuration of changing the site corresponding to the wiping area of the wiping member according to the exemplary embodiments of the present invention is not limited to the configuration of reeling the sheet-like member. For example, a configuration of cutting and collecting the contaminated site instead of reeling the contaminated site of the sheet-like member may also be adopted.
It is noted that the generation amount of the ink mist varies depending on a distance between the recording head and the recording medium, a humidity, a block driving order, an ink type, a drop measure of one ink droplet, an ejection frequency, and a speed of the recording head. For this reason, the value related to the ink amount may also be corrected by taking these parameters into account.
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. 2013-103450, filed 15 May, 2013, which is hereby incorporated by reference wherein in its entirety.
Number | Date | Country | Kind |
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2013-103450 | May 2013 | JP | national |