1. Field of the Invention
The present invention relates to an inkjet printing apparatus that ejects ink to perform a printing operation and an inkjet printing head used for the printing apparatus.
2. Description of the Related Art
Conventionally, the inkjet printing apparatus achieves a reduced running cost for color images and also can have a smaller size. Thus, the inkjet printing apparatus has been widely used for computer-related output devices and has been commercialized.
In recent years, in order to realize the printing of high-definition images with a higher speed, a printing head having a wider printing width (or an ejection opening array having a longer length) also has been desired. Specifically, a printing head having a length of 4 inches to 13 inches also has been required.
The printing head having a longer length and a higher speed as described above causes an increased energy inputted to the printing head to consequently cause an increased temperature rise of the printing head during a printing operation. This consequently requires measures for preventing factors deteriorating the printing reliability (e.g., fluctuation in the ejection amount for the respective pages, unstable ejection at a high temperature, a deteriorated continuous printing operation).
Conventionally, the printing head has been cooled by methods such as air cooling from the outside of the printing head or a cooling pipe attached to the printing head.
In the conventional method, the completed printing head is externally attached with a heat pipe or a radiation member. Thus, a disadvantage has been caused where a printing element substrate as a heat source cannot be provided in the close vicinity of the heat pipe. The externally-attached heat pipe also causes a limited area at which the heat pipe contacts with the printing head, thus causing a poor heat transfer efficiency between the printing head and the heat pipe. Some conditions for executing the printing operation may provide, even in the conventional configuration, sufficient cooling and soaking effects. However, the conventional configuration is disadvantageous when the printing head having a longer length and a higher density is used to continuously perform a printing operation for a longer time. This is due to that the conventional configuration cannot provide a heat transfer efficiency enough to suppress a defective printing due to an uneven temperature distribution and a temperature rise in the printing head due to the long-time printing.
In view of the disadvantages of the conventional technique as described above, it is an objective of the present invention to provide an inkjet printing head that has a high printing reliability even when a printing head having a long length and a higher density is used to perform a high-speed printing operation.
In one aspect of the present invention, an inkjet printing head,. including a plurality of ejection openings for ejecting ink, comprises:
The present invention can suppress the temperature rise of the inkjet printing head and an uneven temperature distribution in the inkjet printing head due to a printing operation with a higher speed and an arrangement of ejection openings with a higher density to prevent the fluctuation in the ejection amount and an ejection failure due to a temperature rise. At the same time, a higher speed and a higher image quality can be both established and the reliability during a continuous printing operation can be remarkably improved.
Further features of the present invention will become apparent from the following description of exemplary embodiments (with reference to the attached drawings).
Embodiments of the present invention will be described with reference to the drawings.
An inkjet the printing head H1000 shown in
As shown in the exploded perspective view of
The ink supply opening H1101 uses the crystal orientation of the Si substrate H1108 to perform an anisotropic etching. The Si substrate H1108 has thereon the eject opening plate H1110 in which an ink flow path H1104 corresponding to an electric heat conversion element H1102, an ejection opening H1105, and a foaming room H1107 are formed by a photolithography technique. The ejection opening H1105 is provided so as to be opposed to the electric heat conversion element H1102 and allows ink supplied from the ink supply opening H1101 to be ejected by bubbles generated by the electric heat conversion element H1102.
The support plate H1200 is formed by alumina (Al2O3) material to have a thickness of 0.5 to 10 mm, for example. The material of the support plate is not limited to alumina and also may be made of other materials that have the same linear expansion coefficient as that of the material of the printing element substrate H1100 and that have a thermal conductivity equal to or higher than thermal conductivity of the material of the printing element substrate H1100. The support plate H1200 may be made, for example, of silicon (Si), aluminum nitride (AlN), zirconia, silicon nitride (Si3N4), silicon carbide (SiC), molybdenum (Mo), or tungsten (W).
The support plate H1200 includes an ink supply opening H1201 (the first ink supply opening) for supplying ink to the printing element substrate H1100. The support plate H1200 is structured so that the ink supply opening H1101 of the printing element substrate H1100 (the second ink supply opening) corresponds to the ink supply opening H1201 of the support plate H1200. The printing element substrate H1100 is fixedly adhered to the support plate H1200 with a high position accuracy. The support plate H1200 has a direction X reference H1204, a direction Y reference H1205, and a direction Z reference H1206 functioning as a positioning reference.
As shown in
At ends of the ejection opening groups of the respective printing element substrates, superposed regions (L) are provided at ends of ejection opening groups of ends of neighboring printing element substrates in the staggered pattern and along the printing direction to prevent a gap between printing regions of the respective printing element substrates from being caused. For example, an ejection opening group H1106a and an ejection opening group H1106b have superposed regions H1109a and H1109b.
The electric wiring substrate H1300 functions to apply an electric signal for ejecting ink to the printing element substrate H1100 and has an opening section to which the printing element substrate H1100 is provided. A plate H1400 is fixedly adhered to the back face. The electric wiring substrate H1300 has an electrode terminal H1302 corresponding to the electrode H1103 of the printing element substrate H1100 and an external signal input terminal H1301 that is positioned at the end of the wiring and that receives an electric signal from the main body of the printing apparatus.
The electric wiring substrate H1300 is electrically connected to the printing element substrate H1100 by a connection method of, for example, using a wire bonding technique to electrically connect the electrode H1103 of the printing element substrate H1100 to the electrode terminal H1302 of the electric wiring substrate H1300 via a metal wire H1303 (not shown). The electric wiring substrate H1300 is made of a flexible wiring substrate having a wiring having a double structure for example and the top layer is covered by a polyimide film.
The plate H1400 is made of a stainless steel plate having a thickness of 0.5 to 1 mm, for example. The material of the plate is not limited to stainless steel. The plate also may be made of material that has ink resistance and that has a favorable planarity. The plate H1400 has the printing element substrate H1100 fixedly adhered to a support plate H1200 and an opening section through which the printing element substrate is provided and is fixedly adhered to the support plate.
A groove section formed by an opening section H1402 of the plate and the side face of the printing element substrate H1100 is filled with the first sealant H1304 to seal an electric mount section of the electric wiring substrate H1300. An electrode H1103 of the printing element substrate is sealed by the second sealant H1305 to protect an electric connection part from corrosion due to ink and an external impact. The ink supply opening H1201 at the back face of the support plate H1200 is fixedly adhered with a filter member H1600 for removing foreign matter mixed in ink.
The ink supply member H1500 is formed by resin molding for example and includes a common liquid room H1501 and a direction Z reference face H1502. The direction Z reference face H1502 positions and fixes the printing element unit and functions as a reference Z of the printing head H1000.
As shown in
The external signal input terminal H1301 of the printing element unit H1001 is positioned and fixed to the back face of the ink supply member H1500, for example. The inkjet printing apparatus M4000 according to an illustrative embodiment of the present invention includes, as shown in
These printing heads H1000 are controlled by a not-shown driving circuit to subject a printing medium to a printing operation. The printing apparatus of
Next, the inkjet printing head of the present invention is structured so that a plurality of printing element substrates having ejection opening arrays consisting of a plurality of ejection openings for ejecting ink are arranged on the support plate along the direction of the ejection opening arrays. The inkjet printing head described in the following respective embodiments has a configuration in which the support plate includes therein a heat pipe.
(First Embodiment)
When only the heat pipe H2000 is provided, the printing head of the entire support plate H1200 can be soaked. Some conditions for executing a printing operation may not require the cooling of the support plate H1200. Thus, this may be effective for a printing operation that is not performed with a high speed but that requires a high definition.
When a continuous high speed printing is carried out, a cooling function also must be provided. Thus, as shown in
By the configuration as described above, the heat pipe H2000 can be provided in the vicinity of the printing element substrate as a heat source, thus reducing the temperature tolerance in the printing head.
The configuration in which the heat pipe coupled to a cooling member such as a heat sink also can suppress the temperature rise of the printing head.
(Second Embodiment)
The groove in which the heat pipe is stored and the shape of the used heat pipe have the same structures as those of the above-described first embodiment. By filling the gap between the passage H2001, as a storage space and the heat pipe H2000 by silicon adhesive agent, the heat pipe H2000 is fixed to the support plate H1200. In this embodiment, the flow path H2002-2 has a cross section having a width of 3 mm and a depth of 2 mm. The cooling liquid is flowed in a flow rate from about 20 ml/min to about 100 ml/min. This flow rate may be an appropriate flow rate depending on the conditions for carrying out a printing operation and the specification of the printing head.
The heat pipe H2000 may be a commercially-available heat pipe. The heat pipe H2000 may have any shape so long as the shape can allow the heat pipe H2000 to contact with the support plate H1200 in a sufficient contact area. In view of the processibility of the groove and the structure of the printing head, the heat pipe is preferably formed to have a flat shape. The gap between the heat pipe H2000 and the support plate H1200 may be filled by material that has a high thermal conductivity and that is stable. Such material may be silicon-base adhesive agent.
The support plate H1200 is preferably made of material that has ink resistance and that has a high heat conduction including ceramic material, carbon graphite material or the like. Among ceramic materials, alumina in particular is relatively low-cost and rigid and thus is optimal for a long printing head for which the disadvantageous warpage or wavinesss of the printing head is easily caused. An alumina substrate obtained by layering and burning green sheets is preferred because the alumina substrate can be manufactured with a low cost for the complicated structure as in the present invention. Thus, the heat pipe can be provided without using adhesive agent as an insulating member and thus is more preferred from the viewpoint of the cooling and soaking of the printing head.
The heat pipe H2000 and the cooling flow path H2004 in the support plate H1200 are preferably provided to be close to the printing element substrate H1100 as a heat source as much as possible. It is necessary that the temperature distribution of the support plate H1200 partially increased due to the temperature rise of the printing element substrate H1100 is soaked by the heat pipe H2000 with a high heat transfer efficiency and can be cooled by cooling liquid. Thus, such a configuration is preferred in which the heat pipe H2000 is close to the printing element substrate H1100 in the support plate H1200 as much as possible and a partition layer is sandwiched therebetween to form a cooling flow path.
The configuration as described above can reduce the temperature tolerance in the printing head and can suppress a temperature rise. Thus, even when the electric heat conversion elements H1102 are arranged with a high density to perform a printing operation with a high speed, a partially-uneven concentration or an ejection failure can be reduced and a high-quality image can be printed with a high speed.
When compared with the cooling by the heat sink as in the first embodiment, the configuration as in this embodiment using both of the heat pipe and the cooling flow path can provide a higher cooling efficiency and thus is optimal.
The cooling medium preferably used in the present invention may be water, ink, air, and nitrogen gas, for example. The circulation of a medium having an adjusted temperature in particular can realize easy management and control of the temperature. When the cooling flow path is divided into a plurality of paths, the temperature of the printing head can be finely controlled by the direction along which the cooling liquid is flowed or the number of used flow paths.
The temperature rise (ΔT) changes depending on the heat transport amount of a heat pipe, the shape of a cooling groove, the flow rate of cooling water, or a temperature. Thus, optimal conditions are provided by the specification such as the arrangement of electric heat conversion elements of the used inkjet printing head or the ejection amount.
(Third Embodiment)
(Fourth Embodiment)
(Fifth Embodiment)
The support plate H1200 is composed of two members that are mutually adhered by adhesive agent. At the opposite side of a face of the first support plate H1200-1 on which the printing element substrate is provided, three grooves are formed independently. By adhering the second support plate H1200-2 to the first support plate H1200-1, the passage H2001, as a storage space is formed in which the heat pipe H2000 is provided. The groove for storing the heat pipe has a cross section having a width of 4.2 mm and a depth of 2.2 mm. A flat heat pipe having a cross-sectional shape of a width of 4 mm and a thickness of 2 mm was fixed by silicon adhesive agent to the bottom face and the side face of the groove H2001, as a storage space in which the heat pipe H2000 is provided. Specifically, the cross-sectional area of the heat pipe in the direction along which a plurality of printing element substrates are arranged is smaller than the cross-sectional area of a passage in which the heat pipe is provided.
At the lower face of the second support plate H1200-2, a position opposed to the groove H2001 has three grooves H2002-5 formed independently along the direction of the ejection opening arrays (i.e., the direction along which the electric heat conversion element H1102 is arranged). This groove also has a cross section having a width of 4.2 mm and a depth of 2.2 mm. At the lower side of the passage H2003 formed of the groove H2001 and the groove H2002-5, the heat pipe H2000 is provided as described above.
On the other hand, the heat pipe H2000 is provided in a position close to the printing element substrate H1100 in the passage H2003 formed of the groove H2001 and the groove H2002-5. The passage H2003 has a space of a height slightly higher than 2 mm in the upper side of the heat pipe H2000. Through this space, cooling liquid such as water can be flowed, for example. Specifically, the space that is in the passage H2003 formed by the two grooves H2001 and H2002-5 and that does not include therein the heat pipe H2000 functions as a cooling liquid flow path (cooling flow path) H2004. In other words, the printing element substrate H1100, the passage H2003, and the cooling flow path H2004 are provided in the listed order in a thickness direction of the support plate. In this manner, the heat pipe H2000 and the cooling flow path H2004 are provided in the support plate H1100 along the direction of the ejection opening array (the direction along which the electric heat conversion element H1102 is arranged).
The cooling liquid flow rate is about 20 ml/min to 100 ml/min. An optimal flow rate may be selected depending on the condition for carrying out a printing operation or the specification of the printing head. The configuration as shown in
In this embodiment, the heat pipe is directly cooled by cooling liquid. Thus, a higher cooling effect can be achieved when compared with the configuration in which the heat pipe and the cooling flow path are provided independently.
(Sixth Embodiment)
As shown in
(Seventh Embodiment)
As shown in
(Eighth Embodiment)
By the cross section of the flow path H2002-8 having the concave shape, the surface area can be increased to provide a higher cooling effect in a limited space.
(Ninth Embodiment)
In this embodiment, the heat pipe is directly cooled by cooling liquid. Thus, a higher cooling effect can be provided when compared with the eighth embodiment.
When printing liquid is used as a cooling medium, only a single tank can be used unlike methods using other media. Thus, the printing apparatus can have a smaller size.
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 Nos. 2007-309698, filed Nov. 30, 2007, 2007-311415, filed Nov. 30, 2007, 2007-309700, filed Nov. 30, 2007 and 2008-283334, filed Nov. 4, 2008 which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | Kind |
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2007-309698 | Nov 2007 | JP | national |
2007-309700 | Nov 2007 | JP | national |
2007-311415 | Nov 2007 | JP | national |
2008-283334 | Nov 2008 | JP | national |
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Notification of Reasons for Refusal dated Dec. 4, 2012, in Japanese Application No. 2008-283334. |
Number | Date | Country | |
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20090141063 A1 | Jun 2009 | US |