Patent Grant
10286659
This application claims the benefit of priority to Japanese Patent Application No. 2017-094124 filed on May 10, 2017. The entire contents of this application are hereby incorporated herein by reference.
The present invention relates to inkjet printers.
An inkjet printer equipped with a heating means for drying the ink ejected onto a recording medium is well known. For example, JP 1998-086353 A discloses an inkjet printer that carries out pre-heating, mid-printing heating, and post-heating with a single heating means. As disclosed in JP 1998-086353 A, a problem with inkjet printers has been in the way drying of the ink ejected on a recording medium should be facilitated to fix the ink onto the recording medium. The introduction of the heating means that facilitates drying of ink by heating the recording medium is one example of the way to solve the above problem.
Naturally, in inkjet printers, more problems associated with drying and fixing of ink arise when the amount of ink to be landed on the recording medium is greater. Even with such an inkjet printer equipped with a heating means as described in JP 1998-086353 A, drying of the ink is not quick enough when the amount of ink to be landed on the recording medium. Consequently, an ink dot that has not been dried sufficiently is overlaid with a next droplet of ink, causing various problems such as ink feathering. Meanwhile, demands for higher print density have been increasing. In certain circumstances, it may be attempted to form a plurality of ink dots at the same spot on the recording medium in a multilayered manner beyond the resolution of the inkjet printer. When attempting such high-density printing, drying of ink is a major problem.
In view of the foregoing, preferred embodiments of the present invention provide inkjet printers that make it possible to produce high-quality image in high-density printing.
An inkjet printer according to a preferred embodiment of the present invention includes a first ink head including a plurality of first nozzles arrayed along a sub-scanning direction and ejecting a first ink onto a recording medium, and a controller controlling the first ink head to form ink dots of the first ink on the recording medium. The controller is configured or programmed to include an m number of data setters ranging from a first data setter to an m-th data setter, where m is a natural number equal to or greater than 2, and the m number of print controllers ranging from a first print controller to an m-th print controller. Upon receiving data for the ink dots of the first ink, the first data setter sets a first dot group including some or all of the ink dots of the first ink. Upon receiving the data for the ink dots of the first ink, an n-th data setter sets an n-th dot group including some or all of the ink dots of the first ink, where n is a natural number in a range of from 2 to m. The first print controller controls the first ink head to form the first dot group on the recording medium. The n-th print controller controls the first ink head to form the n-th dot group over an (n−1) dot group. The first to the m-th data setters set the first to the m-th dot groups so that at least some of ink dots belonging to the first to the m-th dot groups overlap each other.
The above-described inkjet printer achieves high-density printing by overlapping at least some of ink dots each other. As a result, it is possible to produce high-quality images in high-density printing as well by controlling drying conditions of ink. The above-described inkjet printer ejects ink on one region of a recording medium the m number of times separately. It controls the amount of ink to be ejected at each time of ejection to control drying conditions of ink. In other words, by ejecting the ink a plurality of separate times, the above-described inkjet printer adjusts the amount of ink ejected at each time of ink ejection to an appropriate amount that allows the ink to dry by the time of next ink ejection. Thus, the just-described inkjet printer makes it possible to manage drying conditions of ink appropriately. This makes it possible to produce high-quality images with less ink feathering or the like also by high-density printing.
The above and other elements, features, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of the preferred embodiments with reference to the attached drawings.
Hereinbelow, inkjet printers according to some preferred embodiments of the present invention will be described with reference to the drawings. It should be noted, however, that the preferred embodiments described herein are, of course, not intended to limit the present invention. The features and components that exhibit the same effects are denoted by the same reference symbols, and repetitive description thereof may be omitted as appropriate. In the following description, with respect to the user standing in front of the inkjet printer, a direction toward the user relative to the inkjet printer is defined as “frontward”, and a direction away from the user relative to the inkjet printer is defined as “rearward”. In the drawings, reference character Y represents the main scanning direction, and reference character X represents the sub-scanning direction X that is orthogonal to the main scanning direction Y. Reference characters F, Rr, L, R, U, and D in the drawings represent front, rear, left, right, up, and down, respectively. These directional terms are, however, merely provided for convenience in description, and are not intended to limit in any way the manner in which the inkjet printer should be arranged.
The recording medium 5 is an object on which images are to be printed. The recording medium 5 is not limited to a particular material. The recording medium 5 may be paper, such as plain paper or inkjet printing paper. The recording medium 5 may also be a transparent sheet made of such a material as resin or glass. The recording medium 5 may also be a sheet made of such a material as metal or rubber.
As illustrated in
A platen 12 is disposed below the carriage 25. The platen 12 extends along the main scanning direction Y. The recording medium 5 is to be placed on the platen 12. Pinch rollers 31 that press the recording medium 5 downward from above are provided above the platen 12. The pinch rollers 31 are disposed rearward relative to the carriage 25. The platen 12 is provided with grit rollers 32. The grit rollers 32 are disposed below the pinch rollers 31. The grit rollers 32 are provided at positions that face the pinch rollers 31. The grit rollers 32 are connected to a feed motor 33 (see
Each of the four ink heads, the first ink head 40 to the fourth ink head 70, ejects a process color ink to produce color images. In the present preferred embodiment, the first ink head 40 ejects cyan ink. The second ink head 50 ejects magenta ink. The third ink head 60 ejects yellow ink. The fourth ink head 70 ejects black ink. It should be noted that the number of the ink heads is not limited to 4. Moreover, the color tone of each of the process color inks used herein is not limited to any particular color tone.
As illustrated in
Each of the nozzle arrays 42 to 72 of the ink heads 40 to 70 is divided into a plurality of partial nozzle arrays arrayed along the sub-scanning direction X. In the first ink head 40, the nozzle array 42 is divided into three partial nozzle arrays 42a, 42b, and 42c. In the following, the partial nozzle array indicated by reference character 42a is referred to as a first nozzle array 42a, the partial nozzle array indicated by reference character 42b as a second nozzle array 42b, and the partial nozzle array indicated by reference character 42c as a third nozzle array 42c. The first nozzle array 42a includes five of the nozzles 41 that are disposed most upstream X1 with respect to the sub-scanning direction X. The second nozzle array 42b includes five of the nozzles 41 that are disposed second most upstream X1 with respect to the sub-scanning direction X, next to the five nozzles 41 belonging to the first nozzle array 42a. The third nozzle array 42c includes five nozzles of the nozzles 41 that are disposed most downstream X2 with respect to the sub-scanning direction X. Each of the first nozzle array 42a, the second nozzle array 42b, and the third nozzle array 42c contains the same number (5 herein) of nozzles 41. The first nozzle array 42a, the second nozzle array 42b, and the third nozzle array 42c have an equal or substantially equal length along the sub-scanning direction X. The rest of the ink heads, the ink heads 50 to 70, have the same nozzle array configuration as that of the first ink head 40. More specifically, in the second ink head 50, the nozzle array 52 is divided into a first nozzle array 52a, a second nozzle array 52b, and a third nozzle array 52c. In the third ink head 60, the nozzle array 62 is divided into a first nozzle array 62a, a second nozzle array 62b, and a third nozzle array 62c. In the fourth ink head 70, the nozzle array 72 is divided into a first nozzle array 72a, a second nozzle array 72b, and a third nozzle array 72c. All the above-mentioned nozzle arrays contain an equal number (five) of nozzles. Also, all the nozzle arrays have an equal or substantially equal length along the sub-scanning direction X. The first nozzle array 42a of the first ink head 40, the first nozzle array 52a of the second ink head 50, the first nozzle array 62a of the third ink head 60, and the first nozzle array 72a of the fourth ink head 70 are disposed at aligned positions with respect to the sub-scanning direction X. The second nozzle arrays and the third nozzle arrays are also disposed likewise.
The first ink head 40 to the fourth ink head 70 are provided with actuators (not shown) disposed therein, each of which is equipped with, for example, a piezoelectric element. The actuators are electrically connected to the controller 100. The actuators are controlled by the controller 100. By actuating the actuators, ink is ejected toward the recording medium 5 from the plurality of nozzles 41 of the first ink head 40, the plurality of nozzles 51 of the second ink head 50, the plurality of nozzles 61 of the third ink head 60, and the plurality of nozzles 71 of the fourth ink head 70.
The first ink head 40, the second ink head 50, the third ink head 60, and the fourth ink head 70 are allowed to communicate with ink cartridges (not shown) respectively by ink supply passages (not shown). The ink cartridges may be provided detachably, for example, in a right end portion of the printer main body 10a. The materials of the inks are not limited in any way, and it is possible to use various types of materials that have conventionally been used as the ink materials for inkjet printers. The inks may be solvent-based pigment inks or aqueous pigment inks. The inks may also be aqueous dye inks, ultraviolet curing pigment inks that cure when irradiated with ultraviolet rays, or the like.
In the present preferred embodiment, each of the nozzle arrays 42 to 72 of the ink heads 40 to 70 is divided into three partial nozzle arrays, but the number of the partial nozzle arrays per one nozzle array is not limited to 3. The number of the partial arrays in a nozzle array may be four or more, or may be two. The above-described dividing arrangement of the nozzle arrays is made merely by control operations, and it does not mean that there is a structural difference between the nozzle arrays.
As illustrated in
As illustrated in
The configuration of the controller 100 is not limited to a particular configuration. The controller 100 may be a microcomputer, for example. The hardware configuration of the microcomputer is not limited in any way. For example, the microcomputer may include an interface (I/F) that receives print data or the like from external apparatuses such as a host computer, a central processing unit (CPU) that executes control program instructions, a read only memory (ROM) that stores programs executed by the CPU, a random access memory (RAM) used as a working area to deploy the programs, and a storage, such as a memory, that stores the foregoing programs and various data. The controller 100 need not be provided inside the printer main body 10a. The controller 100 may be, for example, a computer that is provided external to the printer main body 10a and is communicatively connected to the printer main body 10a via a wired or wireless communication.
The converter 101 performs what is called a screening process. The screening process is a process that converts image data into patterns of ink dots. A print image produced by an inkjet printer is formed as an aggregate of ink dots of various process color inks. In the inkjet printer 10 according to the present preferred embodiment, an image is converted into ink dot patterns of four colors, cyan, magenta, yellow, and black. The converter 101 may be provided in the printer main body 10a or may be provided in, for example, an external computer. It should be noted that, in the following description, an aggregate of ink dots that is generated by the converter 101 is referred to as the “entire ink dot aggregate” when appropriate, and an ink dot aggregate of a specific color is referred to as the “entire ink dot aggregate of cyan ink”, for example.
The mode selector 102 selects a mode of printing. In the present preferred embodiment, the print modes are categorized as a “normal print mode” and a “high-density print mode”. In the normal print mode, the printer 10 forms an ink dot pattern generated by the converter 101 on the recording medium 5 as it is. The normal print mode is a mode for performing printing that is normally performed with conventionally known printers. In the high-density print mode, the printer 10 forms, on the recording medium 5, an ink dot pattern in which ink dot patterns generated by the converter 101 are partially overlapped with each other. The details of the high-density print mode will be described later. Note that, with the mode selector 102 according to the present preferred embodiment, selection of a print mode is carried out by the operator via an operation panel screen image displayed on, for example, the operation panel 150 or a display device of an external computer. However, the method of selecting a print mode is not limited thereto. For example, the print mode may be incorporated in the print data in advance. It is also possible that the print mode may be automatically selected by the mode selector 102.
The normal print controller 103 controls the printing operations in the normal print mode. The normal print controller 103 is connected to the carriage motor 24, the feed motor 33, the first ink head 40, the second ink head 50, the third ink head 60, and the fourth ink head 70, and by controlling them, the normal print controller 103 performs normal printing. The normal print controller 103 is also connected to the heater 35, and by controlling the temperature of the heater 35, it controls drying of ink after ejection.
The high-density print controller 110 controls the printing operations in the high-density print mode. The high-density print controller 110 is also connected to the carriage motor 24, the feed motor 33, the first ink head 40, the second ink head 50, the third ink head 60, the fourth ink head 70, and the heater 35, and by controlling them, the high-density print controller 110 performs high-density printing. Although the details will be described later, a plurality of print layers are printed on the recording medium 5 by overlaying the print layers on top of each other in the high-density print mode. The high-density print controller 110 is configured or programmed to include a first print controller 110a, a second print controller 110b, and a third print controller 110c.
The first print controller 110a controls printing of a first print layer in the high-density print mode. The first print layer is the lowermost one of the print layers that are formed by overlaying print layers on top of each other in the high-density print mode. The ink dots that form the first print layer are made up of a portion or all of the entire ink dot aggregate. The ink dots that form the first print layer are formed of various color inks ejected from the nozzles of the first nozzle arrays, each of which is the most upstream one of the three nozzle arrays with respect to the sub-scanning direction X in each ink head. Specifically, the first print controller 110a controls ejection of cyan ink from the nozzles 41 belonging to the first nozzle array 42a of the first ink head 40. The first print controller 110a also controls ejection of magenta ink from the nozzles 51 belonging to the first nozzle array 52a of the second ink head 50. Likewise, the first print controller 110a controls ejection of yellow ink from the nozzles 61 belonging to the first nozzle array 62a of the third ink head 60. The first print controller 110a also controls ejection of black ink from the nozzles 71 belonging to the first nozzle array 72a of the fourth ink head 70. In addition to the just-described ink ejection control, the first print controller 110a controls operations of the carriage motor 24 to control movements of the carriage 25. The details of the just-described control will be described later.
The second print controller 110b controls printing of a second print layer in the high-density print mode. The second print layer is a print layer that is formed directly above the first print layer, among the print layers that are formed by overlaying print layers on top of each other in the high-density print mode. The ink dots that form the second print layer are also made up of a portion or all of the entire ink dot aggregate. Also, the ink dots forming the second print layer are formed of various color inks ejected from the nozzles of the second nozzle arrays. The second print controller 110b controls ejection of cyan ink from the nozzles 41 belonging to the second nozzle array 42b of the first ink head 40. The second print controller 110b also controls ejection of magenta ink from the nozzles 51 belonging to the second nozzle array 52b of the second ink head 50. The second print controller 110b also controls ejection of yellow ink from the nozzles 61 belonging to the second nozzle array 62b of the third ink head 60. The second print controller 110b also controls ejection of black ink from the nozzles 71 belonging to the second nozzle array 72b of the fourth ink head 70. In addition to the just-described ink ejection control, the second print controller 110b controls operations of the carriage motor 24 to control movements of the carriage 25.
The third print controller 110c controls printing of a third print layer in the high-density print mode. The third print layer is a print layer that is formed directly above the second print layer, among the print layers that are formed by overlaying print layers on top of each other in the high-density print mode. In the present preferred embodiment, the third print layer is the topmost one of the print layers that are formed by overlaying print layers on top of each other in the high-density print mode. The ink dots that form the third print layer are also made up of a portion or all of the entire ink dot aggregate. The ink dots that form the third print layer are formed of various color inks ejected from the nozzles of the third nozzle arrays. The third print controller 110c controls ejection of cyan ink from the nozzles 41 belonging to the third nozzle array 42c of the first ink head 40. The third print controller 110c also controls ejection of magenta ink from the nozzles 51 belonging to the third nozzle array 52c of the second ink head 50. The third print controller 110c also controls ejection of yellow ink from the nozzles 61 belonging to the third nozzle array 62c of the third ink head 60. The third print controller 110c also controls ejection of black ink from the nozzles 71 belonging to the third nozzle array 72c of the fourth ink head 70. In addition to the just-described ink ejection control, the third print controller 110c controls operations of the carriage motor 24 to control movements of the carriage 25.
The foregoing describes that each of the first print controller 110a to the third print controller 110c controls the operations of ink heads 40 to 70 and the carriage motor 24. However, it is also possible that these components may be controlled by one or a plurality of controllers that receive instructions from the first print controller 110a to the third print controller 110c. For example, ink ejection from the ink heads may be controlled in such a manner that each of the nozzle arrays may be controlled separately. Also, the carriage motor may be controlled collectively by a single system.
Upon receiving data for the entire ink dot aggregate generated by the converter 101, the data setter 120 sets the ink dots that are caused to form by the print controllers 110a to 110c. The data setter 120 includes a first data setter 120a, a second data setter 120b, and a third data setter 120c. Based on the data for the entire ink dot aggregate, the first data setter 120a sets the ink dots that are caused to form by the first print controller 110a, in other words, the ink dots to be formed in the first print layer. Based on the data for the entire ink dot aggregate, the second data setter 120b sets the ink dots that are caused to form by the second print controller 110b, in other words, the ink dots to be formed in the second print layer. Based on the data for the entire ink dot aggregate, the third data setter 120c sets the ink dots that are caused to form by the third print controller 110c, in other words, the ink dots to be formed in the third print layer. The method in which the data setter 120 assigns ink dots to each of the print layers will be detailed later.
The data input interface 130 allows the operator to input a proportion of the ink dots assigned to each of the print layers by the data setter 120, with respect to the entire ink dot aggregate. The data input interface 130 displays an operation panel screen image on, for example, the operation panel 150 or a display device of an external computer. The proportion of the ink dots assigned to each of the print layers by the data setter 120 with respect to the entire ink dot aggregate is input by the operator through the just-mentioned operation panel screen image, for example. The data input interface 130 includes a first data input interface 130a, a second data input interface 130b, and a third data input interface 130c. The first data setter 120a sets the ink dots for the first print layer so that the proportion of the ink dots to be formed in the first print layer with respect to the entire ink dot aggregate becomes equal to the proportion that has been input to the first data input interface 130a. Likewise, the second data setter 120b sets the ink dots for the second print layer so that the proportion of the ink dots to be formed in the second print layer with respect to the entire ink dot aggregate becomes equal to the proportion that has been input to the second data input interface 130b. The third data setter 120c sets the ink dots for the third print layer so that the proportion of the ink dots to be formed in the third print layer with respect to the entire ink dot aggregate becomes equal to the proportion that has been input to the third data input interface 130c.
Printing in the normal print mode (i.e., normal printing) is carried out in the following manner. In the normal printing, the normal print controller 103 drives the carriage motor 24 so as to cause the carriage 25 to move along the main scanning direction Y and also drives the actuators to eject inks from the first ink head 40 to the fourth ink heads 70, to cause inks of various colors to land on the recording medium 5. The normal print controller 103 also controls the feed motor 33 so that the recording medium 5 is delivered consecutively frontward F (i.e., toward downstream X2 along the sub-scanning direction X). The ink on the recording medium 5 delivered by the feed motor 33 is consecutively heated and dried by the heater 35. The normal print controller 103 causes the carriage 25 to move along the main scanning direction Y one time or a plurality of times by the time the recording medium 5 is sent frontward F one time.
It should be noted that, in the normal printing described above, all the ink dots are formed individually at different positions on the recording medium 5. In other words, for the formation positions of the ink dots, only one ink dot is formed at each of the formation positions. The density of the ink dots in this condition is the density of the ink dots in the normal print mode. Although it is possible to increase the density of ink dots by increasing the resolution of image data (i.e., by reducing the pixel size), its upper limit cannot exceed the range of the resolution that can be achieved by the printer 10. When the resolution of image data is set high, the printer 10 performs printing at the set resolution in a method such as so-called multi-pass printing. However, depending on the image to be printed or depending on the type of the recording medium, it is possible that a print in which ink dots are arranged at a higher density than the resolution of the printer 10 may be desired.
For that purpose, the printer 10 according to the present preferred embodiment is provided with the mode selector 102, which allows to select a high-density print mode, and the high-density print controller 110, which control printing operations in high-density printing, so as to be able to form ink dots at a higher density than the density of the ink dots of the image data. In the high-density print mode, one region is repeatedly printed a plurality of times. In the present preferred embodiment, one region is repeatedly printed three times. An image produced by overprinting three times contains overlapping ink dots in some area. In other words, two or more ink dots are overlapped with each other at at least some of the positions where ink dots are to be formed. By overlapping two or more ink dots with each other at some of the positions where ink dots are to be formed, the printer 10 according to the present preferred embodiment achieves high-density printing. An advantage of the method of performing high-density printing by overlapping some of the ink dots, as in the present preferred embodiment, is that it does not increase the amount of required print data, as compared with the method of performing high-density printing by increasing the print resolution.
Hereinafter, the ink dot group that is formed in the first print layer, which is the lowermost layer of the print layers that are formed by repeating the overlapping printing three times, is referred to as a “first dot group”. Also, the ink dot group that is formed in the second print layer, which is formed directly over the first print layer, is referred to as a “second dot group”. The ink dot group that is formed in the third print layer, which is the topmost layer of the print layers that are formed by repeating the overlapping printing three times, is referred to as a “third dot group”. The first dot group is set by the first data setter 120a based on the data for the entire ink dot aggregate. The second dot group is set by the second data setter 120b. The third dot group is set by the third data setter 120c. The first print controller 110a of the high-density print controller 110 controls the first ink head 40 to the fourth ink head 70 and the carriage motor 24 to form the first dot group on the recording medium 5. The second print controller 110b controls the first ink head 40 to the fourth ink head 70 and the carriage motor 24 to form the second dot group over the first print layer. The third print controller 110c controls the first ink head 40 to the fourth ink head 70 and the carriage motor 24 to further form the third dot group over the second print layer. By performing ink ejection a plurality of times separately as described above, it is possible to adjust the amount of ink ejected per one time to an appropriate amount. As a result, it is possible to produce high-quality images even in high-density printing. More specifically, even when ink is ejected repeatedly over the same locations, problems such as ink feathering are unlikely to occur because the ejection amount of the ink for the lower layer is set at an appropriate amount and therefore the ink has already been dried.
In the printer 10 of the present preferred embodiment, the ink dots for the first dot group, the second dot group, and the third dot group are formed by various color inks ejected from the nozzles in the first nozzle arrays, the nozzles in the second nozzle arrays, and the nozzles in the third nozzle arrays, respectively. In the plurality of ink heads 40 to 70, the first nozzle arrays are the nozzle arrays disposed most upstream X1 with respect to the sub-scanning direction X. In the plurality of ink heads 40 to 70, the second nozzle arrays are the nozzle arrays disposed second most upstream X1 with respect to the sub-scanning direction X, next to the first nozzle arrays. In the plurality of ink heads 40 to 70, the third nozzle arrays are the nozzle arrays disposed most downstream X2 with respect to the sub-scanning direction X. As described above, the printer 10 according to the present preferred embodiment is configured or programmed so that the order of the nozzle arrays along the sub-scanning direction X agrees with the order in which the print layers are printed, and it is able to perform high-density printing continuously.
Hereinbelow, the process by which the printer 10 according to the present preferred embodiment performs high-density printing will be described.
The first print coverage, the second print coverage, and the third print coverage needs to be set so that the total thereof exceeds 100%. If the total of the first print coverage, the second print coverage, and the third print coverage does not exceed 100%, the operation panel screen displays an error message and rejects the input value, for example.
After the first print coverage, the second print coverage, and the third print coverage have been input, the data setter 120 sets the first dot group, the second dot group, and the third dot group, for example, according to the following procedure.
As described above, the first dot group Da, the second dot group Db, and the third dot group Dc include “sparse” ink dots that are randomly extracted from the entire ink dot aggregate D0. Therefore, the image formed by each of the dot groups is the same as the image stored as the print data, except for the density of the ink dots. The printer 10 according to the present preferred embodiment overlaps “sparse” images on top of each other to eventually obtain a high-density image. The method of assigning ink dots to each of the dot groups is not limited to the above-described method. For example, the mask provided in each of the data setters 120a to 120c need not be a random mask, but may be a mask that uses any kind of statistical technique.
After ink dots have been assigned to each of the dot groups as described above, printing on the recording medium 5 is performed. The following describes a print process that is performed in the case shown in
As described above, the printer 10 according to the present preferred embodiment is configured or programmed so as to perform high-density printing through the three-time overprinting that is continuously carried out. For that purpose, each of the ink heads 40, 50, 60, and 70 according to the present preferred embodiment preferably includes three partial nozzle arrays Na, Nb, and Nc, each of which has an equal number (five herein) of nozzles. In addition, the data setter 120 according to the present preferred embodiment is able to set a desired print coverage (or a desired decimation rate) for the mask. As a result, it is possible to control drying conditions for ink by way of the print coverage as described above. More specifically, by setting a print coverage such as to enable the ink to dry sufficiently by the time the next ink ejection is performed, it is possible to prevent ink feathering resulting from the overlapping of ink. As a result, it is possible to produce a high-quality image.
The high-density printing may be carried out by a multi-pass technique. For example, in the case of multi-pass printing in which an image is completed with 4 passes, a set of 4 passes corresponds to 1 scanning in single-pass printing. In that case, at the time point illustrated in
In the foregoing preferred embodiment, the operation panel screen is illustrated as having a design as shown in
For example, a preferred embodiment of automatically setting print coverages may be as follows. Assume that the operator sets the cumulative print coverage to about 120% via an input operation. Then, the data setter 120 according to this preferred embodiment allocates, for example, about 70% to the first print coverage, about 25% to the second print coverage, and about 25% to the third print coverage. That is, the print coverage for each of the dot groups that are formed later than the second dot group is set lower than the print coverage for the first dot group. In many cases, a dot group that is formed relatively later is overlapped on the locations where ink dots have already been formed. When the number of the ink dots in such an ink dot group that is formed relatively later is set smaller, problems associated with the overlapping of ink dots, such as ink feathering, may be alleviated.
Another preferred embodiment of automatically setting print coverages may be, for example, as follows. As in the above-described example, it is assumed that the operator sets the cumulative print coverage to about 120% by way of an input operation. Then, the data setter 120 according to the other preferred embodiment allocates, for example, about 60% to the first print coverage, about 20% to the second print coverage, and about 40% to the third print coverage, for example. That is, the print coverage for the second dot group is set lower than the print coverage for the first dot group. At the same time, the print coverage for each of the dot groups that are formed later than the third dot group is set lower than the print coverage for the first dot group and higher than the print coverage for the second dot group. When the amount of ink of the second dot group, which is ejected over the ink dots of the first dot group, is set lower to eliminate the problem such as feathering at that time point, the print coverage for each of the dot groups formed later than the third dot group may be set relatively freely. For this reason, the print coverage for each of the dot groups that are formed later than the third dot group is set higher than the print coverage for the second dot group.
Alternatively, it is possible that the print coverage for each of the dot groups may be set so that a high print coverage and a low print coverage are alternately assigned to the dot groups repeatedly. When the print coverage for each of the dot groups is set in this manner, high-density printing may be proceeded while ink is allowed to dry appropriately every two print layers.
A second preferred embodiment of the present invention allows the operator to specify the number of nozzle arrays allocated per ink head through an operation on the operation panel screen. In other words, a printer 10 according to the second preferred embodiment does not have a fixed number of nozzle arrays, and the operator sets the number of nozzle arrays and the print coverage for each of the nozzle arrays each time. In the second preferred embodiment, preferably at most five nozzle arrays are able to be set per each one ink head. It should be noted that the number, at most five, is merely illustrative, and the number of the nozzle arrays that can be set per one ink head is not limited to five. Note that the printer 10 according to the second preferred embodiment is preferably the same as that according to the first preferred embodiment, except for the just-described configuration. In the following description of the second preferred embodiment, the same elements as in the first preferred embodiment are designated by the same reference numerals and will not be further elaborated upon. The same applies to the later-described third preferred embodiment.
In
With the printer 10 according to the second preferred embodiment as well, the process of high-density printing is similar to that in the first preferred embodiment. Under the conditions shown in
The printer 10 according to the present preferred embodiment allows more freedom in controlling on the drying of ink in high-density printing. Therefore, adjustment for obtaining desired print quality may be carried out more easily. As a result, higher print quality is achieved.
A third preferred embodiment of the present invention allows an independent print coverage to be set for each of a plurality of ink heads. A printer 10 according to the present preferred embodiment allows each one of the ink heads to have a first print coverage to an m-th print coverage independent of the print coverages of the other ones of the ink heads.
As illustrated in
A data input interface 130 according to the present preferred embodiment is also configured or programmed in a like manner. The data input interface 130 includes a first head data input interface 131, a second head data input interface 132, a third head data input interface 133, and a fourth head data input interface 134. The first head data input interface 131 includes a first data input interface 131a, a second data input interface 131b, and a third data input interface 131c. The second head data input interface 132 includes a first data input interface 132a, a second data input interface 132b, and a third data input interface 132c. The third head data input interface 133 includes a first data input interface 133a, a second data input interface 133b, and a third data input interface 133c. The fourth head data input interface 134 includes a first data input interface 134a, a second data input interface 134b, and a third data input interface 134c.
In addition, at the top end of the condition table Tb, the input boxes Bx for the first print coverage (first dot group) are lined up horizontally. Directly below the input boxes Bx for the first print coverage, the input boxes Bx for the second print coverage are lined up. Further, directly below the input boxes Bx for the second print coverage, the input boxes Bx for the third print coverage are lined up.
When the operator inputs print coverages in the condition table Tb, the condition table Tb is read as a matrix. For example, an input box Bx that is the third one from the left and the second one from the top of the condition table Tb accepts an input of the second print coverage for the third ink head 60 (which ejects yellow ink herein). This input box Bx corresponds to the second data input interface 133b of the third head data input interface 133.
As illustrated in
As described above, the printer 10 according to the present preferred embodiment makes it possible to set different print coverages for different ink colors independently, and accordingly increases freedom in controlling drying conditions of ink. The printer 10 according to the present preferred embodiment is effective when, for example, it uses an ink that is more difficult to dry in comparison with other inks. Moreover, the printer 10 according to the present preferred embodiment is able to print an image with a different color balance from the color balance of the image data. For example, when the recording medium 5 is colored paper, a problem may arise that the color tone of the actual printed image results in a different one from that of the image data. In such a circumstance, the printer 10 according to the present preferred embodiment makes it possible to adjust color tones taking the printed results into consideration.
The present preferred embodiment is one in which the above-described features are added to the first present preferred embodiment. However, it is also possible that the above-described features may be added to the second preferred embodiment. This further increases freedom in control operations.
Hereinabove, preferred embodiments of the present invention have been described. It should be noted, however, that the foregoing preferred embodiments are merely exemplary and the present invention may be embodied in various other forms.
For example, although the controller 100 preferably is configured or programmed to include the data input interface 130 in the foregoing preferred embodiments, a preferred embodiment that does not include the data input interface 130 is also possible. When this is the case, it is possible that the print coverages for the dot groups may be fixed, automatically calculated, or contained in the image data in advance, for example.
In the foregoing preferred embodiments, each of the nozzle arrays preferably is divided into a plurality of partial nozzle arrays allocated along the sub-scanning direction X, and the ink dots of different dot groups are formed by the inks ejected from the nozzles of the plurality of partial nozzle arrays. However, the method of ejecting ink is not limited to the above-described manner. For example, each of the nozzle arrays may not be divided into partial nozzle arrays, but only the ink ejection may be divided into a plurality of times.
In the foregoing preferred embodiments, the dot groups preferably are complementary to each other, and in the end, all the ink dots are formed at least one time. For example, the “second dot group” is extracted preferentially from the ink dots that have not been extracted as the “first dot group”. However, it is possible that not all of the ink dots need to be formed at least one time. For example, when the “first dot group” is randomly extracted from the entire ink dot aggregate at a print coverage of about 90% and the “second dot group” is also randomly extracted from the entire ink dot aggregate at a print coverage of about 90%, about 1% of the ink dots remain unprinted in terms of probability. Nevertheless, the technology disclosed herein may be implemented in such a preferred embodiment.
In the foregoing preferred embodiments, a plurality of colors of inks are preferably ejected from different ink heads, but this is not always the case. It is possible that a single ink head may include a plurality of nozzle arrays so that the single ink head can eject a plurality of colors of inks. The “ink head” disclosed herein also includes such an ink head.
In the foregoing preferred embodiments, the drying device that dries the ink on the recording medium 5 preferably is the heater 35 disposed below the platen 12. However, the drying device is not limited thereto. The drying device may also include, for example, a remote heating system such as an infrared irradiation device or a halogen heater. Moreover, even when the drying device is a heater, the heater is not limited to one that heats the platen 12. Furthermore, the drying device may also be provided with a pre-heater and/or a post-heater.
In the foregoing preferred embodiments, the inkjet system that ejects ink preferably is a piezo-electric system. However, the inkjet system of the printers according to preferred embodiments of the present invention may be selected from various types of inkjet systems, including various continuous inkjet systems such as binary deflection inkjet system and a continuous deflection inkjet system, and various on-demand inkjet systems such as a thermal inkjet system. The inkjet system is not limited to any particular inkjet system.
In the foregoing preferred embodiments, the carriage 25 preferably moves along the main scanning direction Y and the recording medium 5 moves along the sub-scanning direction X, but this is not necessarily required to practice the present invention. The movements of the carriage 25 and the recording medium 5 are relative, so either one of them may move along the main scanning direction Y or along the sub-scanning direction X. For example, it is possible that the recording medium 5 may be placed immovably while the carriage 25 may be allowed to move both along the main scanning direction Y and the sub-scanning direction X. Alternatively, it is possible that both the carriage 25 and the recording medium 5 may be allowed to move both along the main scanning direction Y and the sub-scanning direction X.
Furthermore, the technology disclosed herein may be applied to various types of inkjet printers. In addition to the so-called roll-to-roll inkjet printers as shown in the foregoing preferred embodiments, in which a rolled recording medium 5 is delivered, the technology may also be applied to flat-bed inkjet printers, for example, in a similar manner. Moreover, the printer 10 is not limited to a printer that is to be used alone as an independent printer, but may be a printer that is combined with another apparatus. For example, the printer 10 may be incorporated in another apparatus.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
The terms and expressions used herein are for description only and are not to be interpreted in a limited sense. These terms and expressions should be recognized as not excluding any equivalents to the elements shown and described herein and as allowing any modification encompassed in the scope of the claims. The present invention may be embodied in many various forms. This disclosure should be regarded as providing preferred embodiments of the principles of the present invention. These preferred embodiments are provided with the understanding that they are not intended to limit the present invention to the preferred embodiments described in the specification and/or shown in the drawings. The present invention encompasses any of preferred embodiments including equivalent elements, modifications, deletions, combinations, improvements and/or alterations which can be recognized by a person of ordinary skill in the art based on the disclosure. The elements of each claim should be interpreted broadly based on the terms used in the claim, and should not be limited to any of the preferred embodiments described in this specification or referred to during the prosecution of the present application.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
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