The disclosure of Japanese Patent Application No. 2019-170122 filed on Sep. 19, 2019 including specification, drawings and claims is incorporated herein by reference in its entirety.
This invention relates to a technique for circulatingly supplying an ink to a discharge head which discharges the ink from a nozzle.
Conventionally, a printing apparatus is known which prints an image by discharging an ink from a nozzle of a discharge head by an inkjet method. In printing using the discharge head in this way, if the ink stays in the discharge head for a long time, the ink may be dried and solidified to clog the nozzle of the discharge head. Accordingly, a printing apparatus described in JP 2011-255580A prints an image by circulatingly supplying an ink to a discharge head and discharging the supplied ink from a nozzle of the discharge head.
Since the ink is dried not only when printing is performed, but also while printing is stopped, the ink needs to be circulated also when printing is stopped. However, the ink may be deteriorated by a load applied thereto according to circulation. Such deterioration of the ink tends to be more accelerated as a circulating flow rate of the ink increases.
This invention was developed in view of the above problem and aims to provide a technique capable of suppressing the deterioration of an ink while suppressing the drying of the ink by circulatingly supplying the ink to a discharge head.
A printing apparatus according to the invention, comprises: a discharge head which discharges an ink from a nozzle; an ink feeding unit which selectively performs normal circulation of supplying the ink to the discharge head by circulating the ink along a circulation channel starting from the discharge head and returning to the discharge head and low-speed circulation of circulating the ink along the circulation channel at a flow rate lower than that in the normal circulation; and a control unit which performs a print mode of printing an image by causing the discharge head to discharge the ink from the nozzle while causing the ink feeding unit to perform the normal circulation and causes the ink feeding unit to perform the low-speed circulation when the print mode is stopped.
An ink circulation method according to the invention, comprises: performing a print mode of printing an image by discharging an ink from a nozzle of a discharge head while performing normal circulation of circulating the ink along a circulation channel starting from the discharge head and returning to the discharge head; and performing low-speed circulation of circulating the ink along the circulation channel at a flow rate lower than that in the normal circulation when the print mode is stopped.
In the invention (printing apparatus, ink circulation method) thus configured, the ink is circulated along the circulation channel at the flow rate lower than that during the execution of the print mode when the print mode is stopped. By circulatingly supplying the ink to the discharge head in this way, the deterioration of the ink can be also suppressed while the drying of the ink is suppressed.
As described above, according to the invention, the deterioration of an ink can be also suppressed while the drying of the ink is suppressed by circulatingly supplying the ink to a discharge head.
The above and further objects and novel features of the invention will more fully appear from the following detailed description when the same is read in connection with the accompanying drawing. It is to be expressly understood, however, that the drawing is for purpose of illustration only and is not intended as a definition of the limits of the invention.
A pre-stage printing path Pa is formed between the most upstream backup roller 25 and the most downstream backup roller 25 in the conveying direction Am, out of the plurality of backup rollers 25. The most upstream and most downstream backup rollers 25 support the printing medium M at the same height, and the backup rollers 25 more inward of the pre-stage printing path Pa support the printing medium M at higher positions.
Further, the pre-stage printing apparatus 2 includes a plurality of print bars B arranged in the conveying direction Am above the printing medium M being conveyed along the pre-stage printing path Pa and facing the front surface of the printing medium M. Specifically, the print bar B is arranged to face the front surface of a part of the printing medium M moving between two adjacent backup rollers 25, and each print bar B discharges an ink in an inkjet method to the front surface of a part of the printing medium M having both sides supported by two backup rollers 25 in this way. In an example shown here, there are provided six print bars B including four print bars B which discharge inks of four process colors (yellow, magenta, cyan, black) and two print bars B which discharge two special color inks (orange, violet). Therefore, the pre-stage printing apparatus 2 can print a color image on the front surface of the printing medium M by the six print bars B which discharge the color inks having mutually different colors.
The printing medium M having the image printed in the pre-stage printing path Pa moves obliquely downward between the most downstream backup roller 25 of the pre-stage printing path Pa and the carry-out roller 23 and reaches the carry-out roller 23. The back surface of the printing medium M is wound by the carry-out roller 23 from below on a side downstream of the plurality of backup rollers 25 in the conveying direction Am. Then, the carry-out roller 23 carries out the printing medium M to the pre-stage drier 3. Note that the carry-out roller 23 is a suction roller which sucks the back surface of the printing medium M and stabilizes the position of the printing medium M in the pre-stage printing path Pa by suppressing the transmission of the vibration of the printing medium M from the pre-stage drier 3 to the pre-stage printing apparatus 2. As a result, the influence of the conveyance of the printing medium M in the pre-stage drier 3 on printing in the pre-stage printing apparatus 2 can be suppressed.
As shown in
Further, the post-stage printing apparatus 6 includes two backup rollers 67 between the conveyor roller 65 and the carry-out roller 63. A post-stage printing path Pc is formed between the two backup rollers 67. Further, the post-stage printing apparatus 6 includes a print bar B facing the front surface of the printing medium M above the printing medium M being conveyed along the post-stage printing path Pc. Specifically, the print bar B is arranged to face a part of the printing medium M moving between the two backup rollers 67, and discharges an ink in the inkjet method to the front surface of the part of the printing medium M having both sides supported by the two backup rollers 67. In an example shown here, the print bar B discharges a white ink. Therefore, the post-stage printing apparatus 6 can print a white background image on the front surface of the printing medium M by the print bar B with respect to the color image printed in the pre-stage printing apparatus 2.
The printing medium M having the image printed in the post-stage printing path Pc moves obliquely upward between the most downstream backup roller 67 of the post-stage printing path Pc and the carry-out roller 63 and reaches the carry-out roller 63. The printing medium M is wound by this carry-out roller 63 from below on a side downstream of the two backup rollers 67 in the conveying direction Am. The carry-out roller 63 carries out the printing medium M to the post-stage drier 7 along a moving path of the printing medium M in the X direction by winding the printing medium M obliquely moving upward from the post-stage printing path Pc in this way. Note that the carry-out roller 63 is a suction roller which sucks the back surface of the printing medium M and stabilizes the position of the printing medium M in the post-stage printing path Pc by suppressing the transmission of the vibration of the printing medium M from the post-stage drier 7 to the post-stage printing apparatus 6. As a result, the influence of the conveyance of the printing medium M in the post-stage drier 7 on printing in the post-stage printing apparatus 6 can be suppressed.
As shown in
As described above, the print bars B provided in the pre-stage printing apparatus 2 and the post-stage printing apparatus 6 discharge the liquids (inks) in the inkjet method. Specifically, a plurality of discharge heads H (
A bar drive mechanism 8 (
As shown in
In correspondence with this, the bar drive mechanism 8 includes a Y-axis rail 81 provided in parallel to the Y direction and a movable member 82 configured to move in the Y direction along the Y-axis rail 81, and the print bar B is attached to the movable member 82. Thus, the print bar B can move between the facing position La and the retracted position Lb by moving in the Y direction, accompanying the movable member 82.
Further, the bar drive mechanism 8 includes elevation rails 83 attached to the movable member 82 and movable members 84 configured to move upward and downward along the elevation rails 83, and the print bar B is mounted on these movable members 84. That is, the print bar B is attached to the movable member 82 via the elevation rails 83 and the movable members 84, and the elevation rails 83, the movable members 84 and the print bar B move in the Y direction as the movable member 82 moves. Furthermore, the print bar B moves upward and downward as the movable members 83 move upward and downward along the elevation rails 83.
Such a bar drive mechanism 8 can drive the print bar B in the Y direction, can move the print bar B upward and downward, and can drive the print bar B as shown in states S1 to S3 of
The ink supply device 9 includes a feed reservoir 91f which stores the ink and feed pipes 92f (feed channels) connecting the feed reservoir 91f and the ink supply ports Hd of the discharge heads H. The ink I flowing out from the feed reservoir 91f to the feed pipes 92f is supplied to the ink supply chambers Hc via the ink supply ports Hd. Further, the ink supply device 9 includes a return reservoir 91r which stores the ink I and return pipes 92r (return channels) connecting the return reservoir 91r and the ink recovery ports He of the discharge heads H. The ink I flowing out from the ink supply chambers Hc of the discharge heads H to the return pipes 92r via the ink recovery ports He is recovered into the return reservoir 91r.
Further, the ink supply device 9 includes a feed heater Taf which heats the ink I in the feed reservoir 91f and a feed thermometer Tbf which detects the temperature of the ink I in the feed reservoir 91f. Similarly, the ink supply device 9 includes a return heater Tar which heats the ink I in the return reservoir 91r and a return thermometer Tbr which detects the temperature of the ink I in the return reservoir 91r.
Furthermore, the ink supply device 9 includes a reservoir communication pipe 94 (reservoir communication channel) connecting the return reservoir 91r and the feed reservoir 91f. This reservoir communication pipe 94 is a pipe allowing communication between the return reservoir 91r and the feed reservoir 91f, and the ink I moves in the reservoir communication pipe 94 from the return reservoir 91r toward the feed reservoir 91f.
A circulation pump 95, a filter 96 and a degasser 97 are provided to the reservoir communication pipe 94. The circulation pump 95, the filter 96 and the degasser 97 are arranged in this order in a flowing direction of the ink I in the reservoir communication pipe 94. The circulation pump 95 is a diaphragm pump and functions to feed the ink I flowing out from the return reservoir 91r to the feed reservoir 91f along the reservoir communication pipe 94. The filter 96 removes solids from the ink I flowing in the reservoir communication pipe 94 before flowing into the feed reservoir 91f, and the degasser 97 removes gases from the ink I flowing in the reservoir communication pipe 94 before flowing into the feed reservoir 91f.
Further, the ink supply device 9 includes a main reservoir 91m capable of storing a large amount of the ink I, and an ink supply pipe 92m connecting the main reservoir 91m and the reservoir communication pipe 94. Specifically, the ink supply pipe 92m connects a part of the reservoir communication pipe 94 between the return reservoir 91r and the circulation pump 95 and the main reservoir 91m. The ink I stored in the main reservoir 91m is supplied into the reservoir communication pipe 94 via the ink supply pipe 92m.
Furthermore, the ink supply device 9 includes a pressure regulation mechanism 98 which regulates pressures to be respectively applied to the feed reservoir 91f and the return reservoir 91r. This pressure regulation mechanism 98 includes a feed-side regulating part 98f which regulates the pressure to be applied to the feed reservoir 91f and a return-side regulating part 98r which regulates the pressure to be applied to the return reservoir 91r. These feed-side regulating part 98f and the return-side regulating part 98r have a common configuration and respectively apply negative pressures generated in negative pressure tanks by decompressing the negative pressure tanks by negative pressure pumps to the feed reservoir 91f and the return reservoir 91r.
In such an ink supply device 9, a feed-side regulator 98f and a return-side regulator 98r (pressure regulation mechanism 98) circulate the ink I along a circulation channel Wc shown by broken lines by generating a negative pressure difference ΔP between the feed reservoir 91f and the return reservoir 91r. Here, the circulation channel Wc is a channel in which the ink I returns from the return reservoir 91r to the feed reservoir 91f via the reservoir communication pipe 94 after the ink I reaches the return reservoir 91r from the feed reservoir 91f by way of the discharge heads H.
Specifically, the feed-side regulator 98f regulates a pressure Pf in the feed reservoir 91f to a negative pressure and the return-side regulator 98r regulates a pressure Pr in the return reservoir 91r to a negative pressure lower than the pressure Pf. In this way, the negative pressure difference ΔP is generated between the pressure Pf in the feed reservoir 91f and the pressure Pr in the return reservoir 91r, and a pressure from the feed reservoir 91f toward the return reservoir 91r is applied to the ink I. Further, during the generation of the negative pressure difference ΔP, a controller 100 prevents a decrease of the negative pressure difference ΔP by operating the circulation pump 95 and causing the circulation pump 95 to discharge the ink I from the return reservoir 91r toward the feed reservoir 91f. The ink I is circulated in the circulation channel Wc by such a negative pressure difference ΔP.
The controller 100 generates the negative pressure difference ΔP between the feed reservoir 91f and the return reservoir 91r by controlling the feed-side regulator 98f and the return-side regulator 98r of the pressure regulation mechanism 98. Particularly, the controller 100 generates two mutually different negative pressure differences ΔP, i.e. a normal negative pressure difference ΔPo and a low negative pressure difference ΔPl. The low negative pressure difference ΔPl is smaller than the normal negative pressure difference ΔPo. Thus, in a state where the normal negative pressure difference ΔPo is generated between the feed reservoir 91f and the return reservoir 91r, the ink I is circulated at a normal flow rate Vo along the circulation channel Wc (normal circulation). On the other hand, in a state where the low negative pressure difference ΔPl is generated between the feed reservoir 91f and the return reservoir 91r, the ink I is circulated at a low-speed flow rate Vl lower than the normal flow rate Vo along the circulation channel Wc (low-speed circulation). Further, the controller 100 also controls the operation of the circulation pump 95 according to a difference between the normal negative pressure difference ΔPO and the low negative pressure difference ΔPl.
This controller 100 controls the temperature of the ink I in the feed reservoir 91f to a predetermined printing temperature Tp by feedback-controlling an output of the feed heater Taf based on the temperature of the ink I detected by the feed thermometer Tbf. Similarly, the controller 100 controls the temperature of the ink I in the return reservoir 91r to the printing temperature Tp by feedback-controlling an output of the return heater Tar based on the temperature of the ink I detected by the return thermometer Tbr.
Further, the controller 100 drives the print bar B by controlling the bar drive mechanism 8. In this way, the print bar B is in any one of the three states S1 to S3 shown in
Further, the printing apparatus 2, 6 includes a user interface 110. The user interface 110 is, for example, constituted by a touch panel display, and functions to receive an input operation of a user and notify various pieces of information to the user. Then, the controller 110 executes a control corresponding to the input operation of the user performed on the user interface 110.
Particularly, the controller 100 controls the following modes performed in the printing apparatus 2, 6. Next, this mode control is described using
In Step S101, the controller 100 confirms whether or not a start instruction has been input to the user interface 110 by the user. Here, a non-heating stop mode (Step S107) to be described later is performed until the start instruction is input. If the input of the start instruction is confirmed (“YES” in Step S101), the controller 100 performs a start-up mode (Step S102). As shown in
Then, when confirming that both the detected temperature of the feed thermometer Tbf and that of the return thermometer Tbr have reached the printing temperature Tp (“YES” in Step S103), the controller 100 performs a print mode (Step S104). As shown in
On the other hand, the content of setting is different between the start-up mode and the print mode for the capping, and the print bar B needs to be located at the facing position La to face the printing medium M in the print mode. Here, to perform the print mode following the start-up mode, the controller 100 moves the print bar B from the retracted position Lb to the facing position La (state S1) after moving the print bar B in contact with the cap C upward (state S2). If a movement of the print bar B to the facing position La is completed in this way, the discharge heads H start to discharge the ink I from the nozzles N and an image is printed on the printing medium M.
In Step S105, the controller 100 judges whether or not the printing of the image by the print mode has been completed and the print mode is to be stopped (Step S105). In the case of stopping the print mode (“YES” in Step S105), it is confirmed whether or not an end instruction has been input to the user interface 110 by the user. For example, the user inputs the end instruction such as when the user goes home after finishing one day operation of the printing apparatuses 2, 6.
If the input of the end instruction is confirmed (“YES” in Step S106), the controller 100 performs the non-heating stop mode (Step S107). As shown in
Further, as shown in
On the other hand, if the input of the end instruction is not confirmed in Step S106 (“NO” in Step S106), the controller 100 confirms whether or not a capping instruction has been input to the user interface 110 by the user to perform the capping every time the print mode is stopped. For example, the user can judge not to input the capping instruction if the print mode is repeated at short intervals and, on the other hand, can judge to input the capping instruction if the print mode is repeated at long intervals.
If the input of the capping instruction is confirmed (“YES” in Step S108), the controller 100 proceeds to Step S110 after performing the capping by lowering the print bar B moved from the facing position La to the retracted position Lb and bringing the print bar B into contact with the cap C (Step S109). On the other hand, unless the input of the capping instruction is confirmed (“NO” in Step S108), the controller 100 proceeds to Step S110 without performing the capping.
As shown in
In Step S111, the controller 100 confirms whether or not an instruction to restart the print mode (Step S104) has been input to the user interface 110 by the user. If the input of the instruction to restart the print mode is confirmed (“YES” in Step S111), return is made to Step S104.
In the embodiment described above, the ink I is circulated along the circulation channel Wc at the low-speed flow rate Vl lower than that during the execution of the print mode when the print mode is stopped (Steps S107, S110). By circulatingly supplying the ink I to the discharge heads H in this way, the deterioration of the ink I can be also suppressed while the drying of the ink I is suppressed.
Particularly in the ink supply device 9 shown in
Further, the feed heater Taf and the return heater Tar (heating unit) which heats the ink I are equipped. The controller 100 heats the ink I by the feed heater Taf and the return heater Tar when the print mode is performed (Step S104). By heating the ink I in this way, the ink I can be stably discharged from the nozzles N.
If a heating time of the ink I becomes longer, the ink I may be dried/solidified to clog the nozzles N of the discharge heads H. To deal with this, a configuration for stopping the heating of the ink I when the print mode is stopped is considered. However, since it takes a long time to heat the ink I, a problem of delaying the restart of the print mode due to the heating of the ink I when the print mode is restarted after the heating of the ink I is stopped as the print mode is stopped is assumed.
In contrast, the controller 100 selectively performs the heating stop mode for causing the pressure regulation mechanism 98 to perform the low-speed circulation while causing the feed heater Taf and the return heater Tar to heat the ink I (Step S110) and the non-heating stop mode for causing the pressure regulation mechanism 98 to perform the low-speed circulation without causing the feed heater Taf and the return heater Tar to heat the ink I (Step S107) when the print mode is stopped. In such a configuration, for example, the print mode can be quickly restarted by selecting the heating stop mode (Step S110) when the print mode is stopped if a time to the next print mode is expected to be short, whereas the drying/solidification of the ink I can be suppressed by selecting the non-heating stop mode (Step S107) when the print mode is stopped if a time to the next print mode is expected to be long.
Further, the user interface 110 which receives an end instruction by the user is equipped. The controller 100 performs the heating stop mode (Step S110) when the print mode is stopped while not receiving the end instruction (“NO” in Step S106), and performs the non-heating stop mode (Step S107) when the print mode is stopped if the user interface 110 receives the end instruction (“YES” in Step S106). In such a configuration, if there is no end instruction from the user, the heating stop mode (Step S110) is performed when the print mode is stopped. Thus, the print mode can be quickly restarted (Step S104). On the other hand, if there is an end instruction from the user, the non-heating stop mode (Step S107) is performed when the print mode is stopped. Thus, the drying/solidification of the ink I can be suppressed. Accordingly, the user may select the heating stop mode (Step S110) if a time to the restart of the print mode is expected to be short and may select the non-heating stop mode (Step S107) if a time to the restart of the print mode is expected to be long. Therefore, the ink I can be properly heated according to the user's situation judgment.
Further, the cap C which performs the capping to cover the nozzles N of the discharge heads H is equipped. The controller 100 causes the cap C to perform the capping when the non-heating stop mode is performed (Step S107). In such a configuration, the nozzles N of the discharge heads H are covered by the cap C at the time of the non-heating stop mode (Step S107), wherefore the drying/solidification of the nozzles N can be more effectively suppressed.
Further, the user interface 110 receives the capping instruction instructing to perform the capping when the heating stop mode is performed (Step S110). Then, the controller 10 causes the cap C to perform the capping (Step S109) when the heating stop mode is performed (Step S110) if the user interface 110 receives the capping instruction (“YES” in Step S108). On the other hand, the controller 100 does not cause the cap C to perform the capping when the heating stop mode is performed (Step S110) if the user interface 110 does not receive the capping instruction (“NO” in Step S108). That is, the print bar B is continuously located at the facing position La from the print mode (Step S104). In such a configuration, the user can suppress the drying/solidification of the ink I in the heating stop mode (Step S110) by giving the capping instruction to the user interface 110. On the other hand, the user can quickly restart the print mode (Step S104) by not giving the capping instruction to eliminate a time required to release the capping. Therefore, the capping can be properly performed according to the user's situation judgment.
Further, the user interface 110 receives the start instruction by the user. The controller 100 performs the start-up mode for causing the pressure regulation mechanism 98 to perform the normal circulation with the cap C caused to perform the capping and causing the feed heater Taf and the return heater Tar to heat the ink I during a period until the start of the print mode (Step S104) associated with the start instruction if the user interface 110 receives the start instruction (“YES” in Step S101). In such a configuration, since the capping is performed during the period until the start of the print mode, the start of the print mode (Step S104) can be waited while the drying/solidification of the ink I is suppressed.
In the embodiment described above, the pre-stage printing apparatus 2 or the post-stage printing apparatus 6 corresponds to an example of a “printing apparatus” of the invention, the pressure regulation mechanism 98 corresponds to an example of an “ink feeding unit” of the invention, the controller 100 corresponds to an example of a “control unit” of the invention, the user interface 110 corresponds to examples of a “first operating unit”, a “second operating unit” and a “third operating unit” of the invention, the cap C corresponds to an example of a “cap” of the invention, the discharge head H corresponds to an example of a “discharge head” of the invention, the nozzle N corresponds to an example of a “nozzle” of the invention, the feed heater Taf and the return heater Tar correspond to an example of a “heating unit” of the invention, the circulation channel We corresponds to an example of a “circulation channel” of the invention, Step S102 corresponds to an example of a “start-up mode” of the invention, Step S104 corresponds to an example of a “print mode” of the invention, Step S107 corresponds to an example of a “non-heating stop mode” of the invention, and Step S110 corresponds to an example of a “heating stop mode” of the invention.
Note that the invention is not limited to the above embodiment and various changes other than the aforementioned ones can be made without departing from the gist of the invention. For example, the mode control can be changed as appropriate. Specifically, the capping may be performed regardless of the type of the mode. Alternatively, the ink I may be heated regardless of the type of the mode or the non-heating stop mode may be performed instead of the heating stop mode in Step S110.
Further, the type of the circulation pump 95 is not limited to the diaphragm pump and a pump other than the diaphragm pump can be used as the circulation pump 95.
Further, a replenishment destination of the ink I from the main reservoir 91m is not limited to the reservoir communication pipe 94. Therefore, the ink I may be replenished from the main reservoir 91m to the feed reservoir 91f via the ink supply pipe 92m or may be replenished from the main reservoir 91m to the return reservoir 91r via the ink supply pipe 92m.
Further, the types of the color inks to be discharged to the printing medium M in the pre-stage printing apparatus 2 are not limited to the above six colors.
Further, a printing apparatus for discharging a white ink may be provided upstream of the pre-stage printing apparatus 2 in the conveying direction Am, and the color inks may be discharged to the printing medium M after the white ink is discharged to the printing medium M.
Further, the white ink may be printed on the printing medium M by analog printing like flexographic printing or gravure printing.
Further, the pre-stage printing apparatus 2 may stop the printing medium M on a platen and discharge the color inks from the nozzles N while the print bars B are operated in an orthogonal direction Ar.
Further, the material of the printing medium M is not limited to a film and may be paper or the like.
Further, the types of the inks are not limited to emulsion inks and may be water-based inks with dispersed pigment or UV (UltraViolet) inks. In the case of using UV inks, light irradiation apparatuses for irradiating ultraviolet rays to the UV inks on the printing medium M are arranged instead of the pre-stage drier 3 and the post-stage drier 7.
The invention is applicable to printing techniques in general.
As described above, the printing apparatus may comprises a heating unit which heats the ink, wherein, the control unit causes the heating unit to heat the ink when the print mode is performed. By heating the ink in this way, the ink can be stably discharged from the nozzle.
If a heating time of the ink becomes longer, the ink may be dried/solidified to clog the nozzle of the discharge head. To deal with this, a configuration for stopping the heating of the ink when the print mode is stopped is considered. However, since it takes a long time to heat the ink, a problem of delaying the restart of the print mode due to the heating of the ink when the print mode is restarted after the heating of the ink is stopped as the print mode is stopped is assumed.
So, the printing apparatus may be configured so that the control unit selectively performs a heating stop mode of causing the ink feeding unit to perform the low-speed circulation while causing the heating unit to heat the ink and a non-heating stop mode of causing the ink feeding unit to perform the low-speed circulation without causing the heating unit to heat the ink when the print mode is stopped. In such a configuration, for example, the print mode can be quickly restarted by selecting the heating stop mode when the print mode is stopped if a time to the next print mode is expected to be short, whereas the drying/solidification of the ink can be suppressed by selecting the non-heating stop mode when the print mode is stopped if a time to the next print mode is expected to be long.
The printing apparatus may further comprises a first operating unit which receives an end instruction by a user, wherein, the control unit performs the heating stop mode while the first operating unit does not receive the end instruction and performs the non-heating stop mode if the first operating unit receives the end instruction when the print mode is stopped. In such a configuration, if there is no end instruction from the user, the heating stop mode is performed when the print mode is stopped. Thus, the print mode can be quickly restarted. On the other hand, if there is an end instruction from the user, the non-heating stop mode is performed when the print mode is stopped. Thus, the drying/solidification of the ink can be suppressed. Accordingly, the user may select the heating stop mode if a time to the restart of the print mode is expected to be short and may select the non-heating stop mode if a time to the restart of the print mode is expected to be long. Therefore, the ink can be properly heated according to the user's situation judgment.
The printing apparatus may further comprises a cap which performs capping to cover the nozzle of the discharge head, wherein, the control unit does not cause the cap to perform the capping when the print mode is performed and causes the cap to perform the capping when the non-heating stop mode is performed. In such a configuration, the nozzle of the discharge head is covered by the cap at the time of the non-heating stop mode, wherefore the drying/solidification of the nozzle can be more effectively suppressed.
The printing apparatus may further comprises a second operating unit which receives a capping instruction instructing the execution of the capping when the heating stop mode is performed, wherein, the control unit causes the cap to perform the capping when the heating stop mode is performed if the second operating unit receives the capping instruction and does not cause the cap to perform the capping when the heating stop mode is performed if the second operating unit does not receive the capping instruction. In such a configuration, the user can suppress the drying/solidification of the ink during the heating stop mode by giving a capping instruction to the second operating unit, whereas the print mode can be quickly restarted by eliminating a time required to release the capping by not giving the capping instruction. Thus, the capping can be properly performed according to the user's situation judgment.
The printing apparatus may further comprises a third operating unit that receives a start instruction by a user, wherein, the control unit performs a start-up mode of causing the ink feeding unit to perform the normal circulation and causing heating unit to heat the ink with causing the cap to perform the capping during a period until the start of the print mode associated with the start instruction if the third operating unit receives the start instruction. In such a configuration, since the capping is performed during the period until the start of the print mode, the start of the print mode can be waited while the drying/solidification of the ink is suppressed.
Although the invention has been described with reference to specific embodiments, this description is not meant to be construed in a limiting sense. Various modifications of the disclosed embodiment, as well as other embodiments of the present invention, will become apparent to persons skilled in the art upon reference to the description of the invention. It is therefore contemplated that the appended claims will cover any such modifications or embodiments as fall within the true scope of the invention.
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Extended European Search Report issued in corresponding European Patent Application No. 20194955.9-1017, dated Jan. 18, 2021. |
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20210086521 A1 | Mar 2021 | US |