The present invention relates to a liquid ejection head and an inkjet printing apparatus.
In some liquid ejection heads for a full line type inkjet printing apparatus, printing element substrates are arrayed in a width direction of a print medium to elongate heads and improve manufacturing yields. U.S. Pat. No. 7,758,142 discloses that power and an ejection signal are supplied to each of printing element substrates arrayed in a line from an electrical substrate via a flexible circuit.
In a configuration of arraying electrical substrates and connecting printing element substrates to the electrical substrates via flexible circuits as disclosed in U.S. Pat. No. 7,758,142, the longer the flexible circuits, the higher the probability of a voltage drop. Further, an increase in printing speed of the liquid ejection head may result in a bigger voltage drop.
The present invention has been accomplished in order to solve the problem described above. Thus, an object of the present invention is to provide a liquid ejection head capable of voltage drop suppression and high-speed ejection operation.
According to a first aspect of the present invention, there is provided a liquid ejecting head comprising: a plurality of element substrates including a first element substrate and a second element substrate on which elements configured to eject liquid are arrayed; a plurality of electrical substrates including a first electrical substrate configured to supply power and an ejection signal to the first element substrate and a second electrical substrate configured to supply power and an ejection signal to the second element substrate; and a plurality of flexible circuits including a first flexible circuit electrically connecting the first element substrate to the first electrical substrate and a second flexible circuit electrically connecting the second element substrate to the second electrical substrate, wherein in each of the flexible circuits, a width Wa on a side connected to the electrical substrate is smaller than the width of another area.
According to a second aspect of the present invention, there is provided an inkjet printing apparatus to print an image on a print medium by ejecting ink based on an ejection signal by the use of an inkjet printing head, the inkjet printing head comprising: a plurality of element substrates including a first element substrate and a second element substrate on which elements configured to eject ink are arrayed; a plurality of electrical substrates including a first electrical substrate configured to supply power and an ejection signal to the first element substrate and a second electrical substrate configured to supply power and an ejection signal to the second element substrate; and a plurality of flexible circuits including a first flexible circuit electrically connecting the first element substrate to the first electrical substrate and a second flexible circuit electrically connecting the second element substrate to the second electrical substrate, wherein in each of the flexible circuits, a width Wa on a side connected to the electrical substrate is smaller than the width of another area.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
The circulation pump P1 guides ink that is flowed out from liquid supply units 4 through liquid connection portions 111 to the buffer tank 1003. Providing the circulation pump P1 can reduce the influence of a pressure head of the buffer tank 1003 on the liquid ejection head 3, with the result that the buffer tank 1003 can be laid out with a high degree of freedom in the inkjet printing apparatus 1000. It should be noted that the above advantageous result can be achieved if the circulation pump P1 is replaced with, for example, a water head tank disposed to have a predetermined water head difference with respect to negative pressure control units 230. The circulation pumps P2 and P3 supply ink stored in the buffer tank 1003 to the liquid supply units 4 through the liquid connection portions 111.
The liquid supply units 4 pass ink supplied from the liquid connection portions 111 through filters 221 to remove foreign matter and then supply the ink to a liquid ejection unit 300. On the other hand, ink collected from the liquid ejection unit 300 flows into the negative pressure control units 230 of the liquid supply units 4.
The negative pressure control units 230 include a negative pressure control unit H that causes ink to flow out at high fluid pressure and a negative pressure control unit L that causes ink to flow out at low fluid pressure. The negative pressure control units H and L are connected to a common supply flow path 621 and a common collection flow path 622 in the liquid ejection unit 300 located upstream of the negative pressure control units, respectively. The negative pressure control units 230 function as so-called back pressure regulators to regulate the fluid pressure in the common supply flow path 621 and the common collection flow path 622 within a certain range regardless of ink consumption by ejection operation of the liquid ejection unit 300.
Besides the common supply flow path 621 through which ink flows at high pressure from the negative pressure control unit H and the common collection flow path 622 through which ink flows at low pressure from the negative pressure control unit L, the liquid ejection unit 300 is equipped with printing element substrates 10 which are arrayed in the Y direction and each of which comprises printing elements. Each printing element substrate 10 is connected to an individual supply flow path 521 connected to the common supply flow path 621 and an individual collection flow path 522 connected to the common collection flow path 622. An ink flow is produced by a difference in fluid pressure between the common supply flow path 621 and the common collection flow path 622. More specifically, ink flows into the printing element substrate 10 from the common supply flow path 621 having high pressure through the individual supply flow paths 521 and the ink then flows out from the printing element substrate 10 to the common collection flow path 622 through the individual collection flow paths 522. When each printing element substrate 10 performs ejection operation, circulating ink is partly consumed by the ejection and the rest of the ink is discharged into the liquid supply units 4 through the individual collection flow paths 522 and the common collection flow path 622.
In the liquid ejection head 3 using the circulation supply circuit described above, heat generated in ejection operation is dissipated by circulating liquid, which reduces the possibility of an ejection failure due to heat accumulation. Further, since thickened ink and foreign matter are less prone to stay, the ejection state of all nozzles can be stable. Furthermore, in a configuration of providing the negative pressure control unit H and the negative pressure control unit L at respective ends of the liquid ejection head 3 like the present embodiment, the flow direction in the common supply flow path 621 (right to left) and the flow direction in the common collection flow path 622 (left to right), which are parallel to each other with the printing element substrates 10 interposed therebetween, are opposed to each other. Accordingly, heat exchange is promoted between the common supply flow path 621 and the common collection flow path 622 through each printing element substrate 10, thereby equalizing the temperatures of the printing element substrates 10. As a result, variations in the amount of ejection due to a temperature difference are suppressed and density unevenness is reduced.
On the other hand, ejection data and power for ejection operation are input to signal input terminals 91 and power supply terminals 92 respectively on electrical substrates 90, on which electrical wirings are laid out for various purposes, and supplied to the printing element substrates 10 via flexible circuits 40 (not shown in
One end of the electrical substrate support 82 is an electrical substrate fixing portion 82a protruding in the X direction and the other end is an electrical substrate fixing portion 82b protruding in the −X direction. The liquid ejection unit support 81 is fastened to the side surface of each fixing portion with screws. Since the two liquid ejection unit supports 81 are fixed to the electrical substrate support 82 symmetrically with respect to a point, the stiffness of the electrical substrate support 82 is improved and the liquid ejection head is prevented from being deformed.
At this time, screw holes in the electrical substrate fixing portion 82b are movable holes elongated in the Y direction, which maintains a state of connection between the electrical substrate support 82 and the second flow path member 60 even in the case of displacement caused by a difference in coefficient of linear expansion between them. Further, when liquid ejection heads 3 are arranged in parallel as shown in
Although the drawings show a method of elongating the screw holes of the liquid ejection unit support 81b as an example to expand a movable area, elongated screw holes may be provided in the liquid ejection unit support 81a or both of the liquid ejection unit supports 81a and 81b. Further, the electrical substrate support 82 and the liquid ejection unit supports 81a and 81b may be fastened by shoulder screws or other than screws.
The stiffness of the liquid ejection head 3 as a whole is ensured mainly by the second flow path member 60 having the shape of a flat plate. Accordingly, the material for the second flow path member 60 should preferably have sufficient resistance to corrosion by liquid and high mechanical strength. For example, it is preferable to use SUS, Ti, and alumina. On the other hand, the first flow path members 50 are formed by arraying flat plates, which are smaller than the second flow path member 60 and correspond to the ejection modules 200, that is, the printing element substrates 10, in the Y direction to have a length corresponding to the length of the second flow path member 60.
The surface of the second flow path member 60 (
The surface of each first flow path member 50 (
Ink moving in the common supply flow path 621 of the second flow path member 60 in the Y direction flows into the individual communication port 53 of the first flow path member 50 through the communication port 61 and then moves in the X direction in the individual flow path 51. Then, the ink is supplied to the printing element substrate 10 through the liquid supply port 31. Ink not consumed in the printing element substrate 10 is collected into the common collection flow path 622 of the second flow path member 60 through a liquid supply port 31, individual flow path 51, individual communication port 53, and communication port 61, which are different from those described above. Such an ink path for collection can be recognized in another cross section in
As shown in
On respective sides of the ejection port array in the X direction, the liquid supply path 18 connected to the common supply flow path 621 to supply ink to the pressure chamber 23 and the liquid collection path 19 connected to the common collection flow path 622 to collect ink from the pressure chamber 23 extend in the Y direction. Supply ports 17a and collection ports 17b communicating with the pressure chambers 23 are formed in the liquid supply path 18 and the liquid collection path 19, respectively. Ink stored in the pressure chambers 23 is circulated between the pressure chambers 23 and the outside.
In the configuration described above, ink flows in the printing element substrate 10 in the order of the openings 21, liquid supply paths 18, supply ports 17a, pressure chambers 23, collection ports 17b, liquid collection paths 19, and openings 21. In a case where the energy generating element 15 is driven while ink flows through the pressure chambers 23, the ink is partly ejected from the ejection port 13. Ink stably flows through the pressure chambers 23 regardless of ejection frequency. Therefore, even if thickened ink, bubbles, foreign matter, and the like are mixed with the ink, they are guided (discharged) to the liquid collection paths 19 without staying in a particular position.
In the liquid ejection head of the present embodiment, 20 nozzles included in different nozzle arrays can sequentially print dots of the same pixel line on a print medium conveyed in the X direction. That is, the frequency of printing of dots can be increased by 20 times as compared with a liquid ejection head having only one nozzle array. Further, even if an ejection failure occurs in any of the 20 nozzles which print the same pixel line, the other nozzles can perform ejection operation to compensate for the failure.
As shown in
In the configuration described above, even if two printing element substrates 10 are somewhat misaligned and connected when manufacturing a liquid ejection head, an image in a position corresponding to the connection portion can be printed by cooperation between ejection ports included in the overlapping area. Therefore, a black stripe or white patch caused by the misalignment can be inconspicuous in an image printed on paper.
The wiring structure including the energy generating elements 15 (heaters), wirings 303 for supplying power thereto, pads 302 and the like is patterned on the substrate 301 having the supply ports 17a and collection ports 17b shown in
In each of the two flexible circuits 40, a first terminal 41 on the opposite side of the printing element substrate 10 is electrically connected to a connection terminal 93 of the electrical substrate 90. The support member 30 has the liquid supply ports 31 to be connected to the individual flow paths 51 of the first flow path member 50. The support member 30 serves as a support of the printing element substrate 10 as well as a flow path member located between the printing element substrate 10 and the first flow path member 50. Accordingly, it is preferable that the support member 30 has a high degree of flatness and can be connected to the printing element substrate 10 with sufficiently high reliability. For example, alumina and a resin material are suitable for the support member 30.
At this time, since each printing element substrate 10 has the shape of a parallelogram, opposing terminals 16 are shifted from each other in the Y direction as shown in
In the present embodiment, since the number (36) of arrayed printing element substrates 10 is a multiple of the number (4) of electrical substrates arrayed on one side of the printing element substrates 10, all the eight electrical substrates 90 each connected to the same number (9) of flexible circuits 40 can have an identical shape. Further, all the printing element substrates 10 and all the flexible circuits 40 forming the ejection modules 200 are also identical in shape. Accordingly, an elongated liquid ejection head 3 can be manufactured by producing a number of printing element substrates 10, flexible circuits 40, and electrical substrates 90, conducting electrical inspection individually, performing electrical inspection for products individually, and combining only qualified products as shown in
In the present embodiment, each flexible circuit 40 does not have a uniform width in the Y direction. More specifically, a width Wa near a first terminal 41 connected to an electrical substrate 90 is smaller than a width Wb of a central area. Further, a width Wc near a second terminal 42 connected to a printing element substrate 10 is larger than the width Wa near the first terminal 41 and smaller than the width Wb of the central area. In short, Wa<Wc<Wb. A length La of the area near the first terminal 41 and having the width Wa is smaller than a length Lb of the central area having the width Wb. That is, La<Lb.
An area for connection where no wiring can be laid out must be provided between two adjacent electrical substrates 90. Further, although the sealant 400 is applied to each of the first terminals 41 and second terminals 42 after wire bonding, the second terminals 42 should preferably be arranged at sufficient intervals d to avoid interference therebetween. Consequently, the width of the electrical substrate 90 is designed to exceed the total width of the first terminals 41 of the nine flexible circuits 40, the nine flexible circuits 40 being arranged at the intervals d and connected to the electrical substrate 90.
On the other hand, in the flexible circuits 40 which connect the electrical substrates 90 to the printing element substrates 10 and through which a current flows for high-speed driving of 10 printing element arrays, it is necessary to minimize a voltage drop in paths, that is, to minimize electrical resistance. In particular, when two flow paths, the liquid supply path 18 and the liquid collection path 19, are provided for each nozzle array 14 like the ink circulation type liquid ejection head of the present embodiment, a width in the X direction is large as shown in
Incidentally, wirings inside the flexible circuit 40 should preferably have a multilayer structure. This is because the multilayer structure can gather wirings for power supply, substantially increase the cross-sectional area of wirings, and substantially reduce electrical resistance. It is also effective in reducing a voltage drop to provide a capacitor in wirings for power supply. The capacitor can lessen a sharp voltage drop even if ejection frequency increases and a large current momentarily flows.
The liquid ejection head 3 has a symmetric structure with respect to the electrical substrate support 82. The electrical substrate support 82 is located in the center immediately above the printing element substrate 10 so as to be orthogonal to the plane of the printing element substrate 10. The electrical substrate support 82 supports the electrical substrates 90 in parallel on both sides. In the X direction, the electrical substrate support 82 and the electrical substrates 90 are located within the second flow path member 60 which ensures the stiffness of the entire liquid ejection head 3 as a whole.
The two flexible circuits 40 connected to the respective sides of the printing element substrate 10 are provided along the outer perimeter of the second flow path member 60 and connected to the respective electrical substrates 90. To be more specific, each flexible circuit 40 is bent 90° from the lower surface of the second flow path member 60 along the corner, extended upward along the side wall of the second flow path member 60, bent again toward the upper surface along the corner, further bent in a direction away from the second flow path member 60, and then connected to the electrical substrate 90. All of these members are protected by the shields 132.
In the layout described above, even if electrical components mounted on the electrical substrates 90 somewhat protrude, the protruding components can be prevented from protruding from the width area (X direction area) of the second flow path member 60 as much as possible, thereby reducing the width of the entire liquid ejection head 3 to the width of the printing element substrate 10. At this time, the electrical substrate support 82 should not necessarily be orthogonal to the plane of the printing element substrate 10 immediately above the plane. The advantageous result of reducing the width of the liquid ejection head 3 can be produced as long as the electrical substrates 90 are arrayed in two lines along a plane included in an area in a normal direction of a plane on which the printing element substrates 10 are arrayed.
In the above description,
It should be noted that if the width Wc near the second terminal 42 is smaller than the width Wb, interference between adjacent printing element substrates 10 during and after assembly can be reduced in the same manner as the electrical substrates 90. In addition to this, the printing element substrates require smaller areas for connection than those required for the electrical substrates. In view of the above, it is preferable that Wa<Wc<Wb in order to minimize electrical resistance while ensuring requisite minimum connection areas.
As described above, in each of the flexible circuits 40 of the ejection modules 200 of the present embodiment, the width Wa near the terminal connected to the electrical substrate 90 is smaller than the widths of the other areas. This makes it possible to reduce a voltage drop and manufacture an elongated printing head capable of high-speed printing at low cost.
In the embodiment described above, the printing element substrates 10 having the shape of a parallelogram are arrayed in a line in the Y direction, one electrical substrate 90 is provided on each side of nine printing element substrates 10, and one printing element substrate 10 is connected to two flexible circuits 40. However, the present invention is not limited to this configuration.
In contrast,
In any of the configurations described above, a voltage drop from the electrical substrates 90 to the printing element substrates 10 can be suppressed by using the flexible circuits 40 each having a central area of a width Wb larger than a width Wa near the first terminal 41 connected to the electrical substrate 90 like the embodiment described above. As a consequence, an elongated printing head capable of high-speed printing can be manufactured at low cost.
In the above embodiments, the liquid ejection head using a heater as the energy generating element 15 has been described. However, the energy generating element 15 of the present invention is not limited to this. For example, a piezoelectric element having a volume expanded by applying a voltage or the like can be used as an energy generating element.
Further, liquid ejected from the liquid ejection head 3 should not necessarily be circulated in the configuration shown in
In any case, the advantageous result of the present invention can be achieved as long as liquid ejection modules are arranged in parallel in a liquid ejection head and each of printing element substrates are connected to electrical substrates via flexible circuits. That is, a liquid ejection head capable of high-speed printing can be realized by suppressing a voltage drop by adjusting the widths of a flexible circuit such that a width near a terminal connected to an electrical substrate is smaller than the widths of the other areas.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions
This application claims the benefit of Japanese Patent Application No. 2017-084679 filed Apr. 21, 2017, which is hereby incorporated by reference wherein in its entirety.
Number | Date | Country | Kind |
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2017-084679 | Apr 2017 | JP | national |