JP2005254701A - Inkjet cartridge and inkjet recording device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an inexpensive inkjet cartridge that performs accurately a recovery action to maintain an ink discharge performance with high reliability. <P>SOLUTION: The arrangement direction of a plurality of nozzles 202 (202a to 202f) and the arrangement direction of a plurality of ink tanks 203 (203a to 203f) are intersected each other. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an ink jet cartridge, an ink jet recording head, an ink tank, and an ink jet recording apparatus used in various recording fields.

  In recent years, an ink jet recording apparatus using an ink jet cartridge has been widely used in various recording fields. The ink jet cartridge has a configuration in which an ink jet recording head portion capable of ejecting ink and an ink tank portion for supplying ink ejected from the ink jet recording head portion are combined. With the widespread use of such ink jet cartridges, there is a need for higher image quality of recorded images. As ink jet cartridges, ink jet cartridges using dark ink and light ink, and four color inks of black, cyan, magenta, and yellow are used. In addition, the development of ink jet cartridges using inks such as orange and green is underway. Thus, the type of ink used in an ink jet cartridge tends to increase.

  FIG. 1 is a diagram for explaining a conventional inkjet cartridge 101. 1A is a schematic perspective view of the inkjet cartridge 101, FIG. 1B is a schematic cross-sectional view (cross-sectional view of black ink) taken along line XX in FIG. 1A, and FIG. These are schematic sectional drawings in alignment with the YY line of FIG.1 (b).

  The ink jet cartridge 101 includes six nozzle groups 102 (102a to 102f) and six ink tanks 103 (103a to 103f). Each of the nozzle groups 102a to 102f is formed by a plurality of nozzles capable of ejecting ink, and the ejection ports 100A forming the nozzles are arranged in a line along the left-right direction in FIG. Nozzle group 102a is for black ink ejection, nozzle group 102b is for light cyan ink ejection, nozzle group 102c is for light magenta ink ejection, nozzle group 102d is for cyan ink ejection, nozzle group 102e is for magenta ink ejection, nozzle group 102f Are for discharging yellow ink, and the ink discharged from each is the corresponding ink tank 103a for black ink, ink tank 103b for light cyan ink, ink tank 103c for light magenta ink, ink tank 103d for cyan ink. The ink tank 103e for magenta ink and the ink tank 103f for yellow ink are supplied.

  The nozzle groups 102a and 102b are formed on the chip 104a, the nozzle groups 102c and 102d are formed on the chip 104b, and the nozzle groups 102e and 102f are formed on the chip 104c. These chips 104 (104 a to 104 c) are connected to the base substrate 105. In the base substrate 105, ink chambers 109 (109a to 109f) communicating with the nozzle groups 102 (102a to 102f) are formed. The ink flow path 108 (108a to 108f) between the ink chamber 109 (109a to 109f) and the ink tank 103 (103a to 103f) is formed by the lower ink flow path substrate 106 and the upper ink flow path substrate 107. Has been.

  In the inkjet cartridge 101 shown in FIG. 1, the direction in which the nozzle group 102 is arranged and the direction in which the ink tank 103 are arranged are both the left-right direction in FIG. Therefore, the six nozzle groups 102 (102a to 102f) are densely arranged in a relatively small range in the left-right direction in FIG. 1C, whereas the six ink tanks 103 (103a to 103f) are arranged. Since these are relatively large, they are arranged over a relatively large range in the left-right direction in FIG. As a result, the ink flow paths 108a and 108f between the nozzle groups 102a and 102f located at both ends and the corresponding ink tanks 103a and 103f are longer than the other ink flow paths 108b to 108e.

  However, in such a conventional ink jet cartridge 101, the ink flow paths 108a and 108f communicating with the nozzle groups 102a and 102f located at both ends are longer than the other ink flow paths. There was a risk of causing the following problems.

  Here, the recovery operation is an operation for maintaining a good discharge state of ink from the discharge port 100A. An example of such a recovery operation is a suction recovery operation. In this suction recovery operation, negative pressure is applied to the outside of the discharge ports 100A of the nozzle groups 102a to 102f, and ink that does not contribute to image recording is sucked and discharged from the discharge ports 100A to the outside together with the ink. The bubbles mixed in are discharged.

  When such a suction recovery operation is performed on the ink jet cartridge 101, the flow resistance of the relatively long ink flow paths 108a and 108f is larger than that of the other ink flow paths 108b to 108e. Ink discharge performance (bubble removal performance) from the nozzle groups 102a and 102f communicating with the paths 108a and 108f is worse than that of the other nozzle groups 102b to 102e. If the suction recovery operation is similarly performed on the ejection ports 100A of the nozzle groups 102a to 102f, ink is sucked and discharged more than necessary from the nozzle groups 102b to 102e having relatively good ink discharge performance. As a result, the ink may be consumed wastefully. Further, since the ink flow path is bent as shown in FIG. 1C, the number of parts for forming the ink flow path is increased, which may increase the price of the ink jet cartridge.

  Such a problem is the same when the recovery operation other than the suction recovery operation is performed on the inkjet cartridge 101. As another recovery operation, there can be mentioned a pressure discharge operation in which the ink is pressurized and discharged from the discharge port. Even when such a pressure discharge operation is performed, since the flow resistance of the relatively long ink channels 108a and 108f is larger than that of the other ink channels 108b to 108e, the ink channels 108a and 108f The ink discharge performance (bubble removal performance) from the communicating nozzle groups 102a and 102f is worse than the other nozzle groups 102b to 102e. Therefore, there is a possibility of causing the same problem as when the suction recovery operation is performed.

  Further, such a problem is not limited to the form of the ink jet cartridge 101 in which the ink jet recording head portion and the ink tank portion are integrally coupled, but also the ink jet recording head and the ink tank that can be separated from each other. The same applies to the case where they are configured and combined for use.

  An object of the present invention is to provide an ink jet cartridge, an ink jet recording head, an ink tank, a recovery operation for maintaining the ink ejection performance with high reliability and an appropriate cost reduction. And providing an ink jet recording apparatus.

  The inkjet cartridge of the present invention includes an inkjet cartridge in which a plurality of nozzle groups each including a plurality of nozzles capable of ejecting ink are arranged, and a plurality of ink containing portions that contain ink to be supplied to the plurality of nozzle groups are arranged. The arrangement direction of the plurality of nozzle groups intersects with the arrangement direction of the plurality of ink storage portions.

  An ink jet recording head of the present invention is an ink jet recording head in which a plurality of nozzle groups composed of a plurality of nozzles capable of ejecting ink are arranged, and is combined with an ink tank in which a plurality of ink containing portions for containing ink are arranged. In some cases, the arrangement direction of the plurality of nozzle groups intersects with the arrangement direction of the plurality of ink storage portions.

  The ink tank of the present invention is an ink tank in which a plurality of ink storage portions for storing ink are arranged, and is combined with an ink jet recording head in which a plurality of nozzle groups each including a plurality of nozzles capable of ejecting ink are arranged. In addition, the arrangement direction of the plurality of ink storage portions intersects the arrangement direction of the plurality of nozzle groups.

  The ink jet recording apparatus of the present invention repeats the recording scan in the main scanning direction using the ink jet cartridge and the transport operation of the recording medium in the sub scanning direction intersecting with the main scanning direction. In the ink jet recording apparatus for recording an image, the ink jet cartridge of the present invention can be mounted as the ink jet cartridge.

  The ink jet recording apparatus of the present invention repeats the recording scan in the main scanning direction using the ink jet recording head and the transport operation of the recording medium in the sub scanning direction intersecting with the main scanning direction. In an ink jet recording apparatus for recording an image on a medium, the ink jet recording head of the present invention can be mounted as the ink jet recording head.

  The ink jet recording apparatus of the present invention repeats the recording scan in the main scanning direction using the ink jet recording head and the transport operation of the recording medium in the sub scanning direction intersecting with the main scanning direction. In an ink jet recording apparatus for recording an image on a medium, the ink tank of the present invention can be mounted so as to be coupled with the ink jet recording head.

  According to the present invention, an ink supply path between each of the plurality of nozzle groups and the plurality of ink storage portions is obtained by intersecting the arrangement direction of the plurality of nozzle groups and the alignment direction of the plurality of ink storage portions. Can be formed in a similar form. As a result, when a recovery operation is performed to discharge ink that does not contribute to image recording from the nozzle and maintain the ink ejection performance, it can be performed accurately with high reliability. Price and size can be reduced.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
(First embodiment)
FIG. 2 is a view for explaining the ink jet cartridge 201 according to the first embodiment of the present invention. 2A is a schematic perspective view of the ink jet cartridge 201, FIG. 2B is a schematic cross-sectional view taken along line XX of FIG. 2A, and FIG. 2C is a diagram of FIG. FIG.

  The ink jet cartridge 201 includes six nozzle groups 202 (202a to 202f) and six ink tanks 203 (203a to 203f). Each of the nozzle groups 202a to 202f is formed by a plurality of nozzles capable of ejecting ink, and the ejection ports 200A forming the nozzles are arranged in a line along the left-right direction in FIG. The nozzle group 202a is for discharging black ink, the nozzle group 202b is for discharging light cyan ink, the nozzle group 202c is for discharging light magenta ink, the nozzle group 202d is for discharging cyan ink, the nozzle group 202e is for discharging magenta ink, and the nozzle group 202f Are for discharging yellow ink, and the ink discharged from each is the corresponding ink tank 203a for black ink, ink tank 203b for light cyan ink, ink tank 203c for light magenta ink, ink tank 203d for cyan ink. , Magenta ink tank 203e and yellow ink tank 203f.

  The nozzle groups 202a and 202b are formed on the chip 204a, the nozzle groups 202c and 202d are formed on the chip 204b, and the nozzle groups 202e and 202f are formed on the chip 204c. These chips 204 (204a to 204c) are connected to the base substrate 205. In the base substrate 205, ink chambers 208 (208a to 208f) communicating with the nozzle groups 202 (202a to 202f) are formed. Ink flow paths 207 (207a to 207f) between the ink chambers 208 (208a to 208f) and the ink tanks 203 (203a to 203f) are formed by the ink flow path substrate 206.

  The chip 204 is formed with a plurality of liquid paths that communicate between each of the ejection openings 200A and the ink chamber 208, and the ink in the ink chamber 208 is ejected from the ejection opening 200A through the liquid path. . The liquid path is provided with ejection energy generating means for generating energy for ejecting ink. As the discharge energy generating means, an electrothermal converter (heater), a piezoelectric element, or the like can be used. When an electrothermal transducer is used, the ink can be foamed by the thermal energy generated by the electrothermal transducer, and the ink can be ejected from the ejection port using the foaming energy.

  In the inkjet cartridge 201, the direction in which the nozzle group 202 is arranged is the left-right direction in FIG. 2C, and the direction in which the ink tanks 203 as a plurality of ink storage units are arranged is in FIG. Left and right direction. Thus, the arrangement direction of the nozzle group 202 and the arrangement direction of the ink tank 203 are directions that intersect with each other (in this example, orthogonal directions). In this example, the surface on which the nozzle group 202 is arranged and the surface on which the ink tank 203 is arranged extend in the left-right direction in FIGS. 2A and 2B and are parallel to each other. ing.

  FIG. 3 is an explanatory diagram of the relationship between the arrangement direction of the nozzle group 202 and the arrangement direction of the ink tank 103. FIG. 3 is a schematic view in which only the nozzle group 202 and the ink tank 203 are extracted from the ink jet cartridge 201 and viewed from the direction of arrow III in FIG.

  3, the nozzle group 202 is arranged in the left-right direction in the figure, and the ink tank 203 is arranged in the up-down direction in the figure. The ink supply port 203a-1 of the ink tank 203a is formed at a position intersecting with the corresponding nozzle group 202a, and as shown in FIGS. 2B and 2C, the nozzles are passed through the ink flow path 207a and the ink chamber 208a. It communicates with the group 202a. Similarly, the ink supply ports 203b-1 to 203f-1 of the ink tanks 203b to 203f are formed at positions intersecting with the corresponding nozzle groups 202b to 202f, respectively, and the ink flow paths 207b to 207f and the ink chambers 208b to 208f. The nozzle groups 202b to 203f are communicated through 208f. Therefore, the ink supply ports 203a to 203f are shifted in the arrangement direction of the nozzle groups 202 (202a to 202f) (left and right direction in FIG. 3) as shown in FIG.

  In FIG. 3, the portion where the nozzle group 202 and the ink tank 203 intersect is defined by the nozzle group 202 and the ink tank 203 in a direction opposite to the surface where the nozzle group 202 is arranged and the surface where the ink tank 203 is arranged. This corresponds to the intersection of projected images when projected onto a predetermined virtual plane. Therefore, the ink flow path 207 is located on the intersection of the nozzle group 202 and the ink tank 203 corresponding to each other on such a virtual plane.

  Ink supply ports 203a-1 to 203f-1 of the ink tank 203 are located immediately above the ink chambers 208 (208a to 208f) in FIGS. 2B and 2C, and communicate with each other. Each of 207 (207a to 207f) has a uniform length extending linearly in the vertical direction in FIG.

  In this example, the ink chamber 208 is directed from the ink flow path 207 toward the nozzle group 202 in FIG. 2B in order to supply the ink introduced from the corresponding ink flow path 207 to all of the nozzle groups 202. It is formed in a substantially triangular cross section. Since the positions of the ink flow paths 207 (207a to 207f) correspond to the positions of the ink supply ports 203a-1 to 203f-1 of the ink tank 203, the substantially triangular cross-sectional shape of the ink chamber 208 (208a to 208f) is The position varies depending on the positions of the ink supply ports 203a-1 to 203f-1. For example, since the ink supply port 203d-1 and the ink flow path 207d are located on the right side in FIG. 2B with respect to the ink supply port 203a-1 and the ink flow path 207a, the ink flow path 207d and the nozzle group. The ink chamber 208d located between the ink chamber 202d and the ink chamber 208d has a cross-sectional shape as shown by a dotted line in FIG. Further, the ink flow path 207 and the ink chamber 208 are shaped to reduce the ink flow resistance. For example, the ink flow path 207a located on the left side of FIG. 2B has a shape in which the corner on the lower left side in the figure is closed and smoothly guides the ink into the ink chamber 208a.

  Since the length of the ink flow path 207 (207a to 207f) corresponding to each ink color is uniform, the flow resistance of each ink flow path 207 is uniformized. As a result, a recovery operation for maintaining a good discharge state of ink from the discharge port 200A can be accurately performed with high reliability. As a recovery operation, a negative pressure is applied to the outside of the ejection openings 200A of the nozzle groups 202a to 202f, and ink that does not contribute to image recording is sucked and discharged from each ejection opening 200A, and mixed with the ink into the nozzles. It is possible to perform a suction recovery operation for discharging the foams and the like.

  When such a suction recovery operation is performed, since the flow resistances of the ink flow paths 207 (207a to 207f) are equal, the ink discharge performance (bubble removal performance) from the nozzle group 202 (202a to 202f) is high. Make uniform. When the suction recovery operation is similarly performed on the ejection ports 200A of such nozzle groups 202 (202a to 202f), all the nozzle groups 202 (202a to 202f) having uniform ink discharge performance are used. The minimum necessary ink can be sucked and discharged. In addition, variation in the amount of ink discharged from each nozzle group 202 (202a to 202f) by the suction recovery operation (recovered ink amount) can be suppressed to a small value. As a result, it is possible to avoid the inconvenience in the above-described conventional example of FIG. 1, that is, wasteful consumption of ink that occurs when the ink discharge performance in each nozzle group is not uniform.

  Such an effect is the same when a recovery operation other than the suction recovery operation is performed as the recovery operation. As another recovery operation, there is a pressure recovery operation in which ink is pressurized and discharged from the ejection port. Even when such a pressure discharge operation is performed, the minimum necessary ink is sucked and discharged from all the nozzle groups 202 (202a to 202f) with uniform ink discharge performance, and the variation in the recovered ink amount is suppressed to a small level. Thus, wasteful consumption of ink can be avoided.

  Further, as described above, the ink flow paths 207 (207a to 207f) are located at the intersections of the nozzle groups 202 (202a to 202f) and the ink tanks 203 (203a to 203f) as shown in FIG. 2 (b), extending in the vertical direction in (c). Therefore, when the ink flow path substrate 206 is injection-molded with a resin material, the mold drawing direction can be set to the vertical direction in FIGS. 2B and 2C. Therefore, the ink flow path 207 (207a to 207f) can be formed by the ink flow path substrate 206 as one component. As a result, the number of parts can be reduced and the price of the ink jet cartridge 201 can be reduced compared to the case where the ink flow path is formed by a plurality of parts as in the conventional example of FIG.

  Further, as will be described later, the ink cartridge 201 of this example can be used by being mounted on a carriage in a serial scan type ink jet recording apparatus. In the ink jet recording apparatus, when the main scanning direction in which the carriage moves and the sub-scanning direction in which the recording medium is conveyed are orthogonal to each other, the arrangement direction of the nozzle group 202 is set as a main scanning direction indicated by an arrow A described later. Accordingly, the arrangement direction of the ink tanks 203 becomes a sub-scanning direction of an arrow B described later. As described above, when the arrangement direction of the ink tanks 203 is the sub-scanning direction B orthogonal to the carriage movement direction (main scanning direction A), the ink in the ink tank 203 is easily stirred during the carriage movement scanning. . When pigment ink is used as the ink in the ink tank 203, the ink density in the ink tank 203 changes due to the sedimentation of the pigment, resulting in variations in the density of the recorded image, or ink ejection becomes unstable. There is a fear. However, as in the case of this example, the ink in the ink tank 203 is agitated by carriage movement scanning, so that such a problem can be prevented.

(Second Embodiment)
FIG. 4 is a view for explaining an ink jet cartridge 401 according to the second embodiment of the present invention. 4A is a schematic perspective view of the inkjet cartridge 401, FIG. 4B is a schematic cross-sectional view taken along line XX of FIG. 4A, and FIG. 4C is FIG. 4B. FIG.

  The ink jet cartridge 401 includes six nozzle groups 402 (402a to 402f) and a liquid storage container 410, and six liquid storage chambers 409 (409a to 409f) are formed in the liquid storage container 410. Each of the nozzle groups 402a to 402f is formed by a plurality of nozzles that can eject ink, and the ejection ports 400A that form the nozzles are arranged in a line along the left-right direction in FIG. The nozzle group 402a is for discharging black ink, the nozzle group 402b is for discharging light cyan ink, the nozzle group 402c is for discharging light magenta ink, the nozzle group 402d is for discharging cyan ink, the nozzle group 402e is for discharging magenta ink, and the nozzle group 402f Are for yellow ink discharge, and the ink discharged from each is the liquid storage chamber 409a for black ink, the liquid storage chamber 409b for light cyan ink, the liquid storage chamber 409c for light magenta ink, and the ink for cyan ink. Supplied from the liquid storage chamber 409d, the magenta ink liquid storage chamber 409e, and the yellow ink liquid storage chamber 409f.

  The nozzle groups 402a and 402b are formed on the chip 404a, the nozzle groups 402c and 402d are formed on the chip 404b, and the nozzle groups 402e and 402f are formed on the chip 404c. These chips 404 (404a to 404c) are connected to the base substrate 405. In the base substrate 405, ink chambers 408 (408a to 408f) communicating with the nozzle groups 402 (402a to 402f) are formed. Ink flow paths 407 (407a to 407f) between the ink chambers 408 (408a to 408f) and the liquid storage chambers 409 (409a to 409f) are formed by the ink flow path substrate 406.

  In this inkjet cartridge 401, the direction in which the nozzle group 204 is arranged is the left-right direction in FIG. 4C, and the direction in which the liquid storage chambers 409 as a plurality of ink storage units are arranged is shown in FIG. It is the left and right direction inside. Thus, the arrangement direction of the nozzle group 402 and the arrangement direction of the liquid storage chamber 409 are directions that intersect each other (in the present example, orthogonal directions).

  FIG. 5 is an explanatory diagram of the relationship between the arrangement direction of the nozzle group 402 and the arrangement direction of the liquid storage chamber 409. FIG. 5 is a schematic view in which only the nozzle group 402 and the liquid storage chamber 409 are extracted from the ink jet cartridge 401 and viewed from the direction of arrow V in FIG.

  In FIG. 5, the nozzle group 402 is arranged in the left-right direction in the figure, and the liquid storage chamber 409 is arranged in the up-down direction in the figure. The ink supply port 409a-1 of the liquid storage chamber 409a is formed at a position intersecting with the corresponding nozzle group 402a, and passes through the ink flow path 407a and the ink chamber 408a as shown in FIGS. It communicates with the nozzle group 402a. Similarly, the ink supply ports 409b-1 to 509f-1 of the liquid storage chambers 409b to 409f are formed at positions intersecting with the corresponding nozzle groups 402b to 402f, respectively, and the ink flow paths 407b to 407f and the ink chamber 408b are formed. The nozzle groups 402b to 403f communicate with each other through ˜408f. Accordingly, the ink supply ports 409a to 409f are shifted from each other in the arrangement direction of the nozzle groups 402 (402a to 402f) (left and right direction in FIG. 5) as shown in FIG.

  The ink supply ports 409a-1 to 409f-1 of the liquid storage chamber 409 are located immediately above the ink chambers 408 (408a to 408f) in FIGS. 4B and 4C, and the ink flow communicates therebetween. The paths 407 (407a to 407f) all have a uniform length extending linearly in the vertical direction in FIG.

  In this example, the ink chamber 408 moves from the ink channel 407 toward the nozzle group 402 in FIG. 4B in order to supply the ink introduced from the corresponding ink channel 407 to all of the nozzle groups 402. It is formed in a substantially triangular cross section. Since the position of the ink flow path 407 (407a to 407f) corresponds to the position of the ink supply ports 409a-1 to 409f-1 of the liquid storage chamber 409, the substantially triangular cross-sectional shape of the ink chamber 408 (408a to 408f) is The ink supply ports 409a-1 to 409f-1 differ depending on the positions. For example, since the ink supply port 409d-1 and the ink flow path 407d are located on the right side in FIG. 4B with respect to the ink supply port 409a-1 and the ink flow path 407a, the ink flow path 407d and the nozzle group An ink chamber 408d located between the ink chamber 402d and the ink chamber 408d has a cross-sectional shape as indicated by a dotted line in FIG. Further, the ink flow path 407 and the ink chamber 408 are shaped to reduce the ink flow resistance. For example, the ink flow path 407a located on the left side of FIG. 4B is shaped to smoothly guide the ink into the ink chamber 408a by closing the lower left corner in the figure.

  Since the length of the ink flow path 407 (407a to 407f) corresponding to each ink color is uniform, the flow resistance of each ink flow path 407 is made uniform. As a result, the recovery operation for maintaining a good ink discharge state from the discharge port 400A can be accurately performed with high reliability. As the recovery operation, negative pressure is applied to the outside of the ejection port 400A of the nozzle groups 402a to 402f, and ink that does not contribute to image recording is sucked and discharged from each ejection port 400A, and mixed into the nozzle together with the ink. It is possible to perform a suction recovery operation for discharging the foams and the like.

  When such a suction recovery operation is performed, since the flow resistance of the ink flow path 407 (407a to 407f) is equal, the dischargeability of the ink from the nozzle group 402 (402a to 402f) (foaming ability) is reduced. Make uniform. When the suction recovery operation is similarly performed on the discharge ports 400A of the nozzle groups 402 (402a to 402f), all the nozzle groups 402 (402a to 402f) having uniform ink discharge performance are used. The minimum necessary ink can be sucked and discharged. In addition, variation in the amount of ink discharged from each nozzle group 402 (402a to 404f) by the suction recovery operation (recovered ink amount) is suppressed to a small value. As a result, it is possible to avoid the inconvenience in the above-described conventional example of FIG. 1, that is, wasteful consumption of ink that occurs when the ink discharge performance in each nozzle group is not uniform.

  Such an effect is the same when a recovery operation other than the suction recovery operation is performed as the recovery operation. As another recovery operation, there is a pressure recovery operation in which ink is pressurized and discharged from the ejection port. Even when such a pressure discharge operation is performed, the minimum necessary ink is sucked and discharged from all the nozzle groups 402 (402a to 402f) with uniform ink discharge properties, and the variation in the recovered ink amount is suppressed to be small. Thus, wasteful consumption of ink can be avoided.

  Further, as described above, the ink flow path 407 (407a to 407f) is located at a portion where the nozzle group 402 (402a to 402f) and the liquid storage chamber 409 (409a to 409f) intersect as shown in FIG. It extends in the vertical direction in FIGS. 4 (b) and 4 (c). Therefore, when the ink flow path substrate 406 is injection-molded with a resin material, the mold drawing direction can be set in the vertical direction in FIGS. 4B and 4C. Therefore, the ink flow path 407 (407a to 407f) can be formed by the ink flow path substrate 406 as one component. As a result, the number of parts can be reduced and the price of the ink jet cartridge 401 can be reduced compared to the case where the ink flow path is formed by a plurality of parts as in the conventional example of FIG.

  Further, as will be described later, the ink cartridge 401 of this example can be mounted on a carriage in a serial scan type ink jet recording apparatus. In the ink jet recording apparatus, when the main scanning direction in which the carriage moves and the sub-scanning direction in which the recording medium is conveyed are orthogonal to each other, the arrangement direction of the nozzle group 402 is set as the main scanning direction indicated by the arrow A, The arrangement direction of the liquid storage chambers 409 is the sub-scanning direction of the arrow B. As described above, when the arrangement direction of the liquid storage chambers 409 is the sub-scanning direction B orthogonal to the carriage movement direction (main scanning direction A), the ink in the liquid storage chamber 409 is agitated during the carriage movement scanning. It becomes easy. When pigment ink is used as the ink in the liquid storage chamber 409, the ink density in the liquid storage chamber 409 changes due to the sedimentation of the pigment, resulting in variations in the density of the recorded image, or the ink ejection being unstable. There is a risk of becoming. However, as in the case of this example, the ink in the liquid storage chamber 409 is agitated by moving scanning of the carriage, so that such a problem can be prevented.

(Third embodiment)
FIG. 6 is a view for explaining an ink jet cartridge 501 in the third embodiment of the present invention. 6A is a schematic perspective view of the ink jet cartridge 501, FIG. 5B is a schematic cross-sectional view taken along line XX of FIG. 6A, and FIG. 6C is a diagram of FIG. FIG.

  The ink jet cartridge 501 has eight nozzle groups 502 (502a to 502h) and four ink tanks 503 (503a to 503d). Each of the nozzle groups 502a to 502h is formed by a plurality of nozzles capable of ejecting ink, and the ejection ports 500A forming the nozzles are arranged in a line along the left-right direction in FIG. The nozzle groups 502a and 502h are for discharging black ink, the nozzle groups 502b and 502g are for discharging cyan ink, the nozzle groups 502c and 502f are for discharging magenta ink, and the nozzle groups 502d and 502e are for discharging yellow ink. The ink is supplied from the corresponding ink tank 503a for black ink, ink tank 503b for cyan ink, ink tank 503c for magenta ink, and ink tank 503d for yellow ink.

  The nozzle groups 502a, 502b, 502c, and 502d for discharging black, cyan, magenta, and yellow ink are arranged from left to right in FIG. 6C, and on the contrary, black, cyan, magenta , Yellow ink discharge nozzle groups 502h, 502g, 502f, and 502e are arranged from the right side to the left side in FIG. The arrangement of such nozzle groups 502 is for bidirectional recording of high-quality images in a serial scan type inkjet recording apparatus, as will be described later.

  The nozzle group 502 (502a to 502h) is formed on the chip 504, and the chip 504 is connected to the base substrate 505. In the base substrate 505, ink chambers 508 (508a to 508h) communicating with the nozzle groups 502 (502a to 502h) are formed. Ink flow paths 507 (507a to 507h) between the ink chambers 508 (508a to 208h) and the ink tanks 503 (503a to 503d) are formed by the ink flow path substrate 506.

  In this inkjet cartridge 501, the direction in which the nozzle group 502 is arranged is the left-right direction in FIG. 6C, and the direction in which the ink tank 503 is arranged is the left-right direction in FIG. 6B. Thus, the arrangement direction of the nozzle group 502 and the arrangement direction of the ink tank 503 are directions that intersect with each other (in this example, orthogonal directions).

  FIG. 7 is an explanatory diagram of the relationship between the arrangement direction of the nozzle group 502 and the arrangement direction of the ink tank 503. FIG. 7 is a schematic view in which only the nozzle group 502 and the ink tank 503 are extracted from the ink jet cartridge 501 and viewed from the direction of arrow VII in FIG. 6C.

  In FIG. 7, the nozzle group 502 is arranged in the left-right direction in the figure, and the ink tank 503 is arranged in the up-down direction in the figure. The ink supply port 503a-1 of the ink tank 503a is an ink supply port 503b-1 of the ink tank 503b, the ink supply port 503c-1 of the ink tank 503c, and the ink supply port 503d-1 of the ink tank 503d is a nozzle group, respectively. It is formed at a position that intersects 502 (502a to 502h).

  Ink flow paths 507a and 507h are formed at the intersections (including the intersections Pa-1 and Pa-2) of the ink supply port 503a-1 and the nozzle groups 502a and 502h of the ink tank 503a. Black ink is supplied from the ink tank 503a to the nozzle groups 502a and 502h through the ink flow paths 507a and 507h and the ink chambers 508a and 508h (see FIG. 6B). In addition, ink flow paths 507b and 507g are formed at intersections between the ink supply port 50b-1 of the ink tank 503b and the nozzle groups 502b and 502g (including the intersections Pb-1 and Pb-2). Cyan ink is supplied from the ink tank 503b to the nozzle groups 502b and 502g through the ink flow paths 507b and 507g and the ink chambers 508b and 508g (see FIG. 6B). In addition, ink flow paths 507c and 507f are formed at intersections (including the intersections Pc-1 and Pc-2) of the ink supply port 50c-1 and the nozzle groups 502c and 502f of the ink tank 503c. Magenta ink is supplied from the ink tank 503c to the nozzle groups 502c and 502f through the ink flow paths 507c and 507f and the ink chambers 508c and 508f (see FIG. 6B). In addition, ink flow paths 507d and 507e are formed at the intersections between the ink supply port 50d-1 of the ink tank 503d and the nozzle groups 502d and 502e (including the intersections Pd-1 and Pd-2). Yellow ink is supplied from the ink tank 503d to the nozzle groups 502d and 502e through the ink flow paths 507d and 507e and the ink chambers 508d and 508e (see FIG. 6B).

  The ink supply ports 503a-1 to 503d-1 of the ink tank 503 are located immediately above the ink chambers 508 (508a to 508h) in FIGS. 6B and 6C and communicate with each other. Each of 507 (507a to 507h) has a uniform length extending linearly in the vertical direction in FIG.

  In the case of this example, the ink chamber 508 is directed from the ink channel 507 toward the nozzle group 502 in FIG. 6B in order to supply the ink introduced from the corresponding ink channel 507 to all of the nozzle groups 502. It is formed in a substantially triangular cross section. The positions of the ink flow paths 507 (507a to 507h) are intersection points Pa (Pa-1, Pa-2), Pb (Pb-1, Pb-2), Pc (Pc-1, Pc-2), Pd (Pd). -1 and Pd-2), the substantially triangular cross-sectional shape of the ink chambers 508 (508a to 508h) varies depending on the positions of the intersections Pa, Pb, Pc, and Pd. For example, since the ink supply port 503c-1 and the ink flow path 507c are located to the right of the ink supply port 503a-1 and the ink flow path 507a in FIG. 6B, the ink flow path 507c and the nozzle group The ink chamber 508c positioned between the ink chamber 502c and the ink chamber 508c has a cross-sectional shape as indicated by a dotted line in FIG. Further, the ink flow path 507 and the ink chamber 508 are shaped to reduce the ink flow resistance. For example, the ink flow path 507a located on the left side of FIG. 6B has a shape in which the corner on the lower left side in the figure is closed and smoothly guides the ink into the ink chamber 508a.

  Since the length of the ink flow path 507 (507a to 207h) corresponding to each ink color is uniform, the flow resistance of each ink flow path 507 is uniformized. As a result, the recovery operation for maintaining a good discharge state of ink from the discharge port 500A can be accurately performed with high reliability. As the recovery operation, negative pressure is applied to the outside of the ejection ports 500A of the nozzle groups 502a to 502h, and ink that does not contribute to image recording is sucked and discharged from the ejection ports 500A to the outside together with the ink. It is possible to perform a suction recovery operation for discharging the foams and the like.

  When such a suction recovery operation is performed, since the flow resistance of the ink flow path 507 (507a to 507h) is equal, the ink dischargeability (bubble removal property) from the nozzle group 502 (502a to 502h) is high. Make uniform. When the suction recovery operation is similarly performed on the discharge ports 500A of the nozzle groups 502 (502a to 502h), all the nozzle groups 502 (502a to 502h) having uniform ink discharge performance are used. The minimum necessary ink can be sucked and discharged. In addition, variation in the amount of ink discharged from each nozzle group 502 (502a to 502h) by the suction recovery operation (recovered ink amount) is suppressed to be small. As a result, it is possible to avoid the inconvenience in the above-described conventional example of FIG. 1, that is, wasteful consumption of ink that occurs when the ink discharge performance in each nozzle group is not uniform.

  Such an effect is the same when a recovery operation other than the suction recovery operation is performed as the recovery operation. As another recovery operation, there is a pressure recovery operation in which ink is pressurized and discharged from the ejection port. Even when such a pressure discharge operation is performed, the minimum necessary ink is sucked and discharged from all nozzle groups 502 (502a to 502h) with uniform ink discharge properties, and the variation in the amount of recovered ink is kept small. Thus, wasteful consumption of ink can be avoided.

  Further, as described above, the ink flow path 507 (507a to 507h) is located at a portion intersecting the nozzle group 502 (502a to 502h) and the ink tank 503 (503a to 503d) as shown in FIG. 6 (b), extending in the vertical direction in (c). Therefore, when the ink flow path substrate 506 is injection-molded with a resin material, the mold drawing direction can be set in the vertical direction in FIGS. 6B and 6C. Accordingly, the ink flow path 507 (507a to 507h) can be formed by the ink flow path substrate 506 as one component. As a result, the number of parts can be reduced and the price of the ink jet cartridge 501 can be reduced compared to the case where the ink flow path is formed by a plurality of parts as in the conventional example of FIG.

  Further, as will be described later, the ink cartridge 501 of the present example can be used by being mounted on a carriage in a serial scan type ink jet recording apparatus. In the ink jet recording apparatus, when the main scanning direction in which the carriage moves and the sub-scanning direction in which the recording medium is conveyed are orthogonal to each other, the arrangement direction of the nozzle group 500A is set as the main scanning direction of the arrow A, The arrangement direction of the ink tanks 503 is the sub-scanning direction of the arrow B. As described above, when the arrangement direction of the ink tanks 503 is set to the sub-scanning direction B orthogonal to the carriage movement direction (main scanning direction A), the ink in the ink tank 503 is easily stirred during the carriage movement scanning. . When pigment ink is used as the ink in the ink tank 503, the ink density in the ink tank 503 changes due to the sedimentation of the pigment, resulting in variations in the density of the recorded image or unstable ink ejection. There is a fear. However, as in the case of this example, the ink in the ink tank 503 is agitated by the movement scanning of the carriage, so that such a problem can be prevented.

  The black, cyan, magenta, and yellow ink ejection nozzle groups 502a, 502b, 502c, and 502d, and the black, cyan, magenta, and yellow ink ejection nozzle groups 502h, 502g, 502f, and 502e are main scans indicated by arrows A. Since they are arranged in a contrasting direction, a high-quality image can be bidirectionally recorded in a serial scan type ink jet recording apparatus. That is, when the carriage moves in one of the forward direction and the backward direction, an image is recorded using the nozzle groups 502a, 502b, 502c, and 502d, and when the carriage moves in the other direction, the nozzle groups 502h, 502g, 502f, By recording an image using 502e, it is possible to record a high-quality image at a high speed by using the same ink ejection order during the forward and backward recording scans.

(Fourth embodiment)
FIG. 8 is a schematic perspective view for explaining an ink jet cartridge 701 according to a fourth embodiment of the present invention.

  The ink jet cartridge 701 includes a nozzle group 702 including a plurality of discharge ports and a liquid storage container 710. As the nozzle group 702, four nozzle groups 702a to 702d for discharging black ink, cyan ink, magenta ink, and yellow ink are provided. In the liquid storage container 710, four liquid storage chambers 709 (709a to 709d) for black ink, cyan ink, magenta ink, and yellow ink are formed. The arrangement direction of the nozzle group 702 and the arrangement direction of the liquid storage chamber 709 intersect with each other (in the present example, orthogonal) in the same manner as in the above-described embodiment.

  The chip 704 on which the nozzle group 702 is formed is connected to the base substrate 705. An ink flow path between the nozzle group 702 (702a to 702d) and the liquid storage chamber 709 (709a to 709d) in the base substrate 705 is formed by the ink flow path substrate 708. Each ink flow path has the same length as in the above-described embodiment.

  The liquid storage chamber 709 (709a to 709d) is provided with a liquid supply port 711 (711a to 711d). By connecting the liquid supply port 711 to a main tank (not shown), the ink supplied from the main tank can be refilled into the liquid storage chamber 709.

  FIG. 9 is an explanatory diagram of a serial scan type ink jet recording apparatus using the ink jet cartridge 701 of this example, and is a schematic projection view of the ink jet recording apparatus as viewed from above. A carriage 811 on which the ink jet cartridge 701 can be mounted is guided by a lead shaft 813 so as to be reciprocally movable in the main scanning direction indicated by an arrow A. The ink jet cartridge 701 ejects ink based on image data while moving in the main scanning direction together with the carriage 811. Reference numeral 812 (812a to 812d) is a joint portion connected to a main tank (not shown), and when refilling ink (pit-in supply) into the liquid storage chamber 709 (709a to 709d), the corresponding liquid supply port 711 (711a). To 711d). That is, the inkjet cartridge 701 moves to the right pit-in position in FIG. 9 together with the carriage 811, and the liquid supply ports 711 (711a to 711d) are connected to the corresponding joint portions 812 (812a to 812d). The pit-in position is set outside the normal recording operation range of the ink jet cartridge 701. The connection direction of the liquid supply port 711 and the joint portion 812 is the same arrow A direction as the scanning direction (main scanning direction) of the inkjet cartridge 701, and the inkjet cartridge 701 is used as a power source for connecting them. A power source is used to move the vehicle.

  The arrangement direction of the nozzle group 702 is the main scanning direction indicated by the arrow A, and the arrangement direction of the liquid storage chamber 709 is the sub-scanning direction indicated by the arrow B. The sub-scanning direction and the main scanning direction intersect each other (in this example, orthogonal). Since the liquid storage chamber 709 is arranged in the sub-scanning direction and the liquid supply port 711 and the joint portion 812 are opposed to each other in the main scanning direction, the liquid supply port is utilized by using the scanning power of the ink jet cartridge 701 as described above. 711 and the joint portion 812 can be connected. Therefore, in the pit-in supply system that supplies ink by connecting the liquid storage chamber 709 and the main tank, it is not necessary to newly provide an operation unit for operating the joint unit 812, and it is necessary when configuring the operation unit. Therefore, it is possible to reduce the size of the ink jet recording apparatus without using parts such as a motor. In addition, the degree of freedom of the layout of the joint portion 812 in such pit-in supply is increased, which is extremely advantageous for simplifying and downsizing the joint portion in an ink jet recording apparatus such as a small printer or a large format plotter.

  Also in this example, since the arrangement direction of the nozzle group 702 and the arrangement direction of the liquid storage chamber 709 are orthogonal to each other as in the embodiment described above, each ink color from the nozzle group 702 to the liquid storage chamber 709 is used. The length of each ink flow path can be made uniform. Therefore, the amount of ink discharged that does not contribute to image recording in the recovery operation (such as suction recovery operation) performed when the flow resistance of each ink flow path is made uniform and bubbles or the like are mixed into the ink ejection port Variation in (recovery amount) can be reduced.

  Similarly to the above-described embodiment, when the ink flow path substrate is molded from a resin material, the mold can be slid up and down, and the ink flow path can be formed by one component. . The ink jet cartridge 701 is mounted on the carriage 811 of the ink jet recording apparatus, and the arrangement direction of the nozzle group 702 is a main scanning direction, and the arrangement direction of the liquid storage chamber 709 is a sub scanning direction. The ink in 709 is easily stirred when the carriage 811 is scanned. When pigment ink is used as the ink in the liquid storage chamber 709, the pigment settles and the ink density changes, so that there is a possibility that the recording density varies and the ink ejection becomes unstable. In this example, occurrence of such a problem can be avoided.

  Further, in this example, in the inkjet cartridge that performs pit-in supply by making the arrangement direction of the nozzle group and the arrangement direction of the liquid storage chamber orthogonal, the configuration of the joint portion is simplified and miniaturized, and the inkjet recording apparatus Downsizing can be realized.

(Configuration example of recording device)
FIG. 10 is a perspective view for explaining a schematic configuration of a recording apparatus to which the present invention is applicable. The recording apparatus 50 of this example is a serial scanning type recording apparatus, and a carriage 53 is guided by guide shafts 51 and 52 so as to be movable in the main scanning direction of an arrow A. The carriage 53 is reciprocated in the main scanning direction by a driving force transmission mechanism such as a carriage motor and a belt for transmitting the driving force. The carriage 53 is mounted with the same ink jet cartridge 54 as in the above-described embodiment. The paper P as the recording medium is inserted from the insertion port 55 provided at the front end of the apparatus, and then the transport direction is reversed, and then the transport is performed in the sub-scanning direction indicated by the arrow B by the feed roller 56. The recording apparatus 50 performs sub-scanning of the paper P by a distance corresponding to the recording width and the recording operation of ejecting ink toward the print area of the paper P on the platen 57 while moving the inkjet cartridge 54 in the main scanning direction. Images are sequentially recorded on the paper P by repeating the transport operation for transporting in the direction.

  A recovery system unit (recovery processing means) 58 is provided at the left end in FIG. 10 in the movement region of the carriage 53 so as to face the ink discharge port formation surface of the ink jet cartridge 54 mounted on the carriage 53. The recovery system unit 58 includes a cap capable of capping the ink discharge port and a suction pump capable of introducing a negative pressure into the cap. The negative pressure is introduced into the cap covering the ink discharge port. As a result, the ink is sucked and discharged from the ink discharge port, and a suction recovery operation is performed in order to maintain a good ink discharge state. Further, a recovery operation (also referred to as “discharge recovery operation”) can be performed to maintain a good ink discharge state by discharging ink that does not contribute to the image from the ink discharge port toward the inside of the cap.

(Other embodiments)
The present invention is a form of an ink jet cartridge as described above, that is, a form of an ink jet cartridge in which a portion of an ink jet recording head in which a plurality of nozzle groups are arranged and a portion in which a plurality of ink containing portions are arranged are integrally formed. However, the present invention can also be applied to a case where these portions are separately configured in an ink jet recording head and an ink tank that can be coupled and separated.

  That is, the present invention can also be applied to an ink jet recording head or an ink tank that can be coupled and separated from each other. In that case, when an ink jet recording head in which a plurality of nozzle groups are arranged and an ink tank in which a plurality of ink containing portions are arranged are connected, the arrangement direction of the nozzle groups and the arranging direction of the ink containing portions are determined. What is necessary is just to become the relationship which mutually crosses. In this case, the length of the ink flow path between each ink storage portion and each nozzle group can be made uniform as in the above-described embodiment. That is, the present invention includes an ink jet recording head or an ink tank that can be connected so that the arrangement direction of the plurality of nozzle groups and the arrangement direction of the plurality of ink storage portions intersect each other. In this case, the ink jet recording head and the ink tank may be coupled directly or indirectly. Furthermore, the present invention includes an ink jet recording apparatus in which the ink jet recording head and the ink tank can be mounted so that the arrangement direction of the plurality of nozzle groups and the arrangement direction of the plurality of ink storage portions intersect each other. . The inkjet recording apparatus is not limited to the serial scan type as described above, and is a so-called full-line type inkjet recording that uses a long inkjet recording head that extends over the entire recording width of the recording medium. It may be a device.

(A) is a perspective view of a conventional inkjet cartridge, (b) is a sectional view taken along line XX in (a), and (c) is a sectional view taken along line YY in (b). . (A) is a perspective view of the ink jet cartridge according to the first embodiment of the present invention, (b) is a cross-sectional view taken along line XX of (a), and (c) is a view taken along arrow Y in (b). FIG. FIG. 3 is a view taken in the direction of arrow III in FIG. 2C for explaining the positional relationship between the nozzle group and the ink tank in the ink jet cartridge in FIG. (A) is a perspective view of the inkjet cartridge of the 2nd Embodiment of this invention, (b) is sectional drawing in alignment with the XX line of (a), (c) is Y arrow view of (b). FIG. FIG. 5 is a V arrow view of FIG. 4C for explaining the positional relationship between the nozzle group and the liquid storage chamber in the inkjet cartridge of FIG. (A) is a perspective view of an ink jet cartridge according to a third embodiment of the present invention, (b) is a cross-sectional view taken along line XX of (a), and (c) is a view taken along arrow Y in (b). FIG. FIG. 7 is a view taken along arrow VII in FIG. 6C for explaining the positional relationship between the nozzle group and the ink tank in the inkjet cartridge in FIG. It is a perspective view of the inkjet cartridge of the 4th Embodiment of this invention. It is a schematic block diagram of the inkjet recording head carrying the inkjet cartridge of FIG. 1 is a schematic perspective view of an ink jet recording apparatus to which the present invention can be applied.

Explanation of symbols

201, 401, 501, 701 Inkjet cartridge 202, 402, 502, 702 Nozzle group 203, 503 Ink tank 409, 709 Liquid storage chamber 204, 404, 504, 704 Chip 205, 405, 505, 705 Base substrate 206, 406, 506, 706 Ink channel substrate 711 Liquid supply port 812 Joint part

Claims (22)

In an inkjet cartridge in which a plurality of nozzle groups each composed of a plurality of nozzles capable of ejecting ink are arranged, and a plurality of ink containing portions for containing ink to be supplied to the plurality of nozzle groups are arranged.
An ink jet cartridge, wherein an arrangement direction of the plurality of nozzle groups intersects with an arrangement direction of the plurality of ink storage portions.   An ink flow path having substantially the same length for supplying the ink in the ink storage unit to the nozzle group is provided between the plurality of nozzle groups and the corresponding ones of the plurality of ink storage units. The inkjet cartridge according to claim 1, wherein   The inkjet cartridge according to claim 1, wherein a surface on which the plurality of nozzle groups are arranged and a surface on which the plurality of ink storage portions are arranged are parallel to each other. An ink flow path for supplying ink in the ink containing portion to the nozzle group is provided between the nozzle group and the ink containing portion corresponding to each other,
On a predetermined virtual surface on which the plurality of nozzle groups and the plurality of ink storage portions are projected from a facing direction of a surface on which the plurality of nozzle groups are arranged and a surface on which the plurality of ink storage portions are arranged. 4. The ink jet cartridge according to claim 1, wherein the ink flow path is located at an intersecting portion of the nozzle group corresponding to each other and a projected image of the ink containing portion.   The said some ink accommodating part is a form of a some ink tank, or a form of the some liquid storage chamber formed in the liquid storage container, The any one of Claim 1 to 4 characterized by the above-mentioned. Inkjet cartridge.   The inkjet cartridge according to claim 1, wherein an arrangement direction of the plurality of nozzle groups and an arrangement direction of the plurality of ink storage portions are substantially orthogonal to each other. An ink jet recording apparatus for recording an image on the recording medium by repeating a recording scan in the main scanning direction using an ink jet cartridge and a transport operation of the recording medium in a sub scanning direction intersecting the main scanning direction. It can be attached to,
When mounted on the ink jet recording apparatus, the arrangement direction of the plurality of nozzle groups is substantially along the main scanning direction, and the arrangement direction of the plurality of ink storage portions is substantially along the sub-scanning direction. An ink jet cartridge according to any one of claims 1 to 6.   8. The ink supply system according to claim 1, further comprising a supply port connectable to an external ink supply system, wherein ink can be supplied from the ink supply system into the ink container through the supply port. Inkjet cartridge. An ink jet recording apparatus for recording an image on the recording medium by repeating a recording scan in the main scanning direction using an ink jet cartridge and a transport operation of the recording medium in a sub scanning direction intersecting the main scanning direction. It can be attached to,
The ink jet cartridge according to claim 8, wherein when the ink jet recording apparatus is mounted, a connection direction between the supply port and the ink supply system is substantially along the main scanning direction.   The ink jet cartridge according to claim 9, wherein the supply port is connected to the ink supply system by a moving force for recording and scanning the ink jet cartridge in the main scanning direction. An inkjet recording head in which a plurality of nozzle groups each composed of a plurality of nozzles capable of ejecting ink are arranged,
An ink jet recording head characterized in that an arrangement direction of the plurality of nozzle groups intersects with an arrangement direction of the plurality of ink containing portions when coupled to an ink tank in which a plurality of ink containing portions for containing ink are arranged. .   When combined with the ink tank, substantially the same length for supplying the ink in the ink containing portion to the nozzle group between the plurality of nozzle groups and the corresponding ones of the plurality of ink containing portions, respectively. An ink jet recording head according to claim 11, wherein an ink flow path is formed. Inkjet recording for recording an image on the recording medium by repeating the recording scanning in the main scanning direction using the inkjet recording head and the conveying operation of the recording medium in the sub-scanning direction intersecting the main scanning direction It can be attached to the device,
When the ink jet recording apparatus is mounted so as to be coupled to the ink tank, the arrangement direction of the plurality of nozzle groups is substantially along the main scanning direction, and the arrangement direction of the plurality of ink storage portions is the sub-scanning. The ink jet recording head according to claim 11, wherein the ink jet recording head is substantially along a direction. An ink tank in which a plurality of ink storage portions for storing ink are arranged,
The arrangement direction of the plurality of ink storage portions intersects the arrangement direction of the plurality of nozzle groups when combined with an inkjet recording head in which a plurality of nozzle groups each composed of a plurality of nozzles capable of ejecting ink are combined. Ink tank.   Substantially the same for supplying the ink in the ink container to the nozzle group between the corresponding ones of the plurality of nozzle groups and the plurality of ink containers when coupled to the ink jet recording head. The ink tank according to claim 14, wherein an ink channel having a length is formed. Inkjet recording for recording an image on the recording medium by repeating the recording scanning in the main scanning direction using the inkjet recording head and the conveying operation of the recording medium in the sub-scanning direction intersecting the main scanning direction It can be attached to the device,
When mounted on the inkjet recording apparatus so as to be coupled to the inkjet recording head, the arrangement direction of the plurality of nozzle groups is substantially along the main scanning direction, and the arrangement direction of the plurality of ink containing portions is the sub-direction. The ink tank according to claim 14, wherein the ink tank is substantially along a scanning direction.   17. The ink supply device according to claim 14, further comprising a supply port connectable to an external ink supply system, wherein ink can be supplied from the ink supply system into the ink storage portion through the supply port. Ink tank. Inkjet recording for recording an image on the recording medium by repeating the recording scanning in the main scanning direction using the inkjet recording head and the conveying operation of the recording medium in the sub-scanning direction intersecting the main scanning direction It can be attached to the device,
18. The connection direction between the supply port and the ink supply system is substantially along the main scanning direction when the ink jet recording apparatus is mounted so as to be coupled to the ink jet recording head. Ink tank.   19. The ink tank according to claim 18, wherein the supply port is connected to the ink supply system by a moving force for recording and scanning the ink jet recording head in the main scanning direction. An ink jet recording apparatus for recording an image on the recording medium by repeating a recording scan in the main scanning direction using an ink jet cartridge and a transport operation of the recording medium in a sub scanning direction intersecting the main scanning direction. In
11. An ink jet recording apparatus, wherein the ink jet cartridge according to claim 1 can be mounted as the ink jet cartridge. Inkjet recording for recording an image on the recording medium by repeating the recording scanning in the main scanning direction using the inkjet recording head and the conveying operation of the recording medium in the sub-scanning direction intersecting the main scanning direction In the device
An ink jet recording apparatus, wherein the ink jet recording head according to claim 11 can be mounted as the ink jet recording head. Inkjet recording for recording an image on the recording medium by repeating the recording scanning in the main scanning direction using the inkjet recording head and the conveying operation of the recording medium in the sub-scanning direction intersecting the main scanning direction In the device
An ink jet recording apparatus, wherein the ink tank according to any one of claims 14 to 19 can be mounted so as to be coupled to the ink jet recording head.

Images