This application claims priority to Japanese Patent Application No. 2012-026451 filed on Feb. 9, 2012. The entire disclosure of Japanese Patent Application No. 2012-026451 is hereby incorporated herein by reference.
1. Technical Field
The present invention relates to a liquid ejection device for ejecting a liquid on an ejection medium that is supported by suction on a medium support unit.
2. Related Art
From the past, inkjet printers (hereafter referred to simply as “printers”) have been put to practical use as liquid ejection devices for ejecting ink as a liquid from a liquid ejection head onto paper (ejection medium) in a sheet form supported on a medium support unit, and forming an image containing text or graphics. Among this type of printer, there is a printer that performs so-called “borderless printing” which ejects ink from the liquid ejection head on the entire surface of the paper to form an image.
With a printer that performs this kind of “borderless printing,” for example as disclosed in Japanese Laid-Open Patent Application Publication No. 2011-189538, at a medium support unit, ink discarding grooves that accept ink discarded away from the paper end parts ejected from the liquid ejection head are provided at positions according to the width direction end parts that is orthogonal to the transport direction of the supported paper. Also, a plurality of recesses in which are formed suction holes which operate a suction force for suctioning the paper to the medium support unit are provided between the ink discarding grooves. Then, of the recesses provided on the medium support unit, the ink discarding grooves are provided in communication with adjacent recesses in the paper width direction. Therefore, the paper is supported on the medium support unit by being suctioned and adsorbed to both the recesses on which the suction force acts directly and the ink discarding grooves on which the suction force acts indirectly via the recesses.
However, as disclosed in the above mentioned publication, at the medium support unit, while the ink discarding grooves are formed with a large width dimension to be able to reliably accept ink, the recesses in which the suction holes are formed has the width dimension formed to be small to suppress bending (cockling) due to direct action by the suction force on the paper. As a result, with the conventional medium support unit, the recesses are formed with a width dimension formed to be smaller than the width dimension of the ink discarding grooves. By the recesses and the ink discarding grooves being formed in this way, the paper is suctioned on the medium support surface so that it is in a state for which bending deformation (cockling volume) is suppressed.
However, when paper of different width dimensions is supported on a printer, in addition to a wide ink discarding groove provided according to the end part of a wide paper with a large width dimension, also provided is a narrow width ink discarding groove provided according to the end part of a narrow width paper with a small width dimension. As a result, when this narrow width ink discarding groove is covered by a wide width paper, it is positioned further to the inside than the width direction end part of the wide width paper.
In such a case, with wide width paper support by suction on the medium support unit, though the bending deformation of the paper that occurs in the width direction is smaller at the positions corresponding to the recesses, it can easily become bigger at positions corresponding to the narrow width ink discarding grooves. Also, for example when the paper is swollen due to adhesion of ink ejected from the liquid ejection head during printing, though the bending deformation in the width direction of the paper that accompanies this swelling is also smaller at the recesses, it easily becomes larger at the narrow width ink discarding grooves. Therefore, with the suctioned paper, the bending is concentrated at the larger width ink discarding grooves, and greater bending of the paper occurs more easily at the ink discarding grooves than at the recesses. Because of that, the paper supported on the medium support unit has little bending at the recesses, so the impact displacement volume is small, and the bending at the ink discarding grooves is great, so the impact displacement volume is great. As a result, for example, there is the problem that localized color unevenness occurs in images printed on the paper.
The present invention was created considering the circumstances noted above, and an object is to provide a liquid ejection device for which the bending that occurs in the width direction orthogonal to the transport direction of the ejection medium that is supported by suction on the medium support unit is made uniform.
A liquid ejection device according to one aspect includes a transport unit, a medium support unit and a liquid ejection head. The transport unit is configured and arranged to transport an ejection medium. The medium support unit is arranged on a downstream side of the transport unit with respect to a transport direction of the ejection medium, and having a medium support surface on which the ejection medium is supported by suction using negative pressure when the transport unit transports the ejection medium. The liquid ejection head is configured and arranged to eject liquid on the ejection medium supported on the medium support unit. The medium support unit includes a plurality of first recesses and a plurality of second recesses arranged on the medium support surface along a width direction orthogonal to the transport direction. The first recesses and the second recesses are configured and arranged to be imparted with the negative pressure. A width dimension of an opening of each of the first recesses in the width direction is larger on the downstream side than on an upstream side with respect to the transport direction. A width dimension of an opening of each of the second recesses in the width direction is smaller than the width dimension of the opening of each of the first recesses in the width direction on the downstream side with respect to the transport direction. The second recesses are configured and arranged to accept the liquid ejected toward the ejection medium from the liquid ejection head.
With this arrangement, with the ejection medium that is supported by suction on the upstream side of the transport direction on the medium support surface, as it is transported to the downstream side of the transport direction on the medium support surface, the bending deformation that occurs at the second recess is absorbed by the bending deformation that occurs at the downstream side of the transport direction within the first recess for which the width dimension of the opening is greater than that of the second recess. Therefore, with the ejection medium that is supported by suction on the medium support surface, the bending that occurs in the width direction orthogonal to the transport direction is made uniform.
With the liquid ejection device of the above described aspect, each of the first recesses preferably includes a rib extending from an upstream side edge of the first recess toward the downstream side with respect to the transport direction, and a width dimension between one of edges of the opening of each of the first recesses in the width direction and the rib is preferably smaller than the width dimension of the opening of each of the second recesses.
With this arrangement, at the upstream side of the transport direction of the medium support surface at which suction of the ejection medium is started, it is possible to suppress bending deformation of the ejection medium at the first recesses that occurs in the width direction orthogonal to the transport direction by using the ribs. As a result, at the first recesses, since it is supported on the medium support surface suctioned in a state with bending deformation suppressed, the ejection medium is supported at a suitable position on the medium support surface.
With the liquid ejection device of the above described aspect, an upstream side edge of the opening of each of the second recesses with respect to the transport direction is preferably positioned on the upstream side than an upstream side edge of the opening of each of the first recesses with respect to the transport direction.
With this arrangement, the liquid ejected from the liquid ejection head can be accepted with high reliability at the second recesses. Therefore, soiling of the medium support surface by the liquid is suppressed.
With the liquid ejection device of the above described aspect, the second recesses are arranged at positions respectively corresponding to end parts of the ejection medium in the width direction.
With this arrangement, it is possible to accept the liquid, which is ejected from the liquid ejection head at a position sticking out further than the end parts of the ejection medium, by the second recesses. Therefore, soiling of the medium support surface by liquid is suppressed.
With the liquid ejection device of the above described aspect, at least one of the first recesses includes a suction hole in communication with a negative pressure generating unit that generates the negative pressure.
With this arrangement, negative pressure is imparted to the first recess via the suction hole provided in the first recess, so it is possible to reliably generate bending deformation on the ejection medium at the first recess.
Referring now to the attached drawings which form a part of this original disclosure:
Following, as an embodiment with the present invention in a specific example, we will describe an inkjet printer (hereafter referred to simply as “printer”) as an example of a liquid ejection device, equipped with a liquid ejection head for ejecting liquid, for forming (printing) an image or the like containing text or graphics by ejecting liquid on paper (roll paper) as an ejection medium, while referring to the drawings.
As shown in
The paper supply unit 13 has the paper RP equipped so as to be able to rotate with a roll shaft 13a at the center on the side opposite to the paper ejection unit 14, and supplies the paper RP into the main unit case 12. Inside the main unit case 12 is provided a transport path 16 equipped with a guide member 16a or the like by which the end part of the paper RP is guided. The end part of the paper RP which is supplied unwound from its rolled state as the roll shaft 13a is rotated is transported along this transport path 16, and in the transport path 16, is fed between a pair of rollers consisting of a paper feed roller 17a provided at the back end of the transport direction and a paper pressing roller 17b which is driven by the rotation of this paper feed roller 17a. While being sandwiched by the paper feed roller 17a driven by a drive source (motor, not illustrated) and the paper pressing roller 17b, the paper RP is transported to the liquid ejection unit 15 side which is positioned at the transport direction downstream side. Therefore, with this embodiment, the paper feed roller 17a and the paper pressing roller 17b function as a transport unit.
The liquid ejection unit 15 is equipped with a carriage 18 on the upper side (antigravity direction side) of the transported paper RP. The carriage 18 is supported on a guide shaft (not illustrated) that is erected within the main unit case 12 in a state extending in a roughly horizontal direction along the width direction of the paper RP orthogonal to the transport direction (direction between the paper front side and back side in
Also, the printer 11 is equipped with a medium support unit 20 that sandwiches the transported paper RP and supports the paper RP from the lower side (gravity direction side) at a position facing the liquid ejection head 19. The medium support unit 20 is equipped with a roughly rectangular shaped surface for which the main scan direction X is the long direction on the top surface facing opposite the liquid ejection head 19, and the paper RP is supported by suction on this top surface by negative pressure given to the medium support unit 20.
Specifically, the medium support unit 20 is equipped on its top surface with a roughly plate shaped support surface forming member 21 formed as a medium support surface SM supporting the paper RP transported in the transport direction Y (white outline arrow direction in the drawing), and a support unit frame member 22 joined and fixed to the bottom surface side which is the side opposite to the medium support surface SM. Then, an interior space is formed by the joined support surface forming member 21 and the support unit frame member 22, and this interior space functions as a negative pressure chamber 21s to which negative pressure is given in order to suction the paper RP to the medium support surface SM.
Also, with this embodiment, a negative pressure generating unit 23 connected so as to be in communication with the negative pressure chamber 21s, consisting of a suction chamber 23a for suctioning air from the negative pressure chamber 21s and a rotating fan 23b, is provided on the bottom side of the medium support unit 20. Therefore, the negative pressure generated at the negative pressure generating unit 23 by the air (atmosphere) rotated by the rotating fan 23b flowing as shown by the double-dot-dash line arrow K in the drawing is given to the negative pressure chamber 21s.
Then, on the front surface of the paper RP supported by suction on the medium support unit 20 (the top surface in
Also, inside the main unit case 12, further to the transport direction Y downstream side than the medium support unit 20 (support surface forming member 21), are equipped a guide plate 26 and intermediate roller pair 27 for transporting the paper RP from the medium support unit 20 side to the paper ejection unit 14 side. Further equipped is a paper ejection roller pair 28 for ejecting paper RP from the paper ejection port to the paper ejection tray 12a. Provided as necessary between the intermediate roller pair 27 and the paper ejection roller pair 28 are a cutter for cutting the paper RP after image formation to a cut paper CP of a designated length, and further to the transport direction Y downstream side than the cutter, a drying device for drying ink by blowing warm air (drying air) on the printed surface of the cut paper CP, and the like.
Furthermore, with the printer 11, for example in cases such as when exchanging the paper RP with a different paper RP of a different width dimension, reversing the roll shaft 13a and returning the paper RP from the liquid ejection unit 15 to the direction opposite to the transport direction Y are performed. At that time, a release mechanism 25 for releasing such that the paper pressing roller 17a is separated from the paper feed roller 17a is equipped using a gear train or the like.
Now then, with the printer 11 of this embodiment, the constitution is such that when the paper RP transported on the medium support unit 20 is suctioned to the medium support surface SM, the bending deformation that occurs with the paper RP is made to be uniform. We will describe this constitution while referring to
As shown in
On the medium support surface SM, a plurality of first recesses Hm (m=1 to 31) and second recesses Fn (n=0 to 8), which are respectively formed with designated volume depressions downward so as to be open at the medium support surface SM and also to be separated from the supported paper RP, are provided aligned in the width direction orthogonal to the transport direction Y of the paper RP (hereafter also simply called “width direction”). Specifically, with this embodiment, as shown in
Then, among these nine second recesses Fn, between two second recesses Fn aligned with a gap open, a designated number of first recesses Hm are provided in parallel at almost the same pitch. For example, fifteen first recesses Hm from first recess H1 to first recess H15 are provided in parallel between the second recess F0 and the second recess F1. With this embodiment, due to manufacturing reasons and the like, the support surface forming member 21 having the medium support surface SM is constituted by three partitioned members. Of course, it is also possible to constitute this with one member that is not partitioned.
Suction holes 32 in communication with the negative pressure chamber 21s are provided on all the first recesses Hm provided on the medium support surface SM, and each first recess Hm is in communication via the suction holes 32 with the negative pressure generating unit 23 which generates negative pressure. Also, each of the second recesses Fn is in communication with the adjacent first recess Hm on the inside of the paper RP among each of the first recesses Hm covered by the paper RP, via the groove part 31 formed lowered by a designated volume from the medium support surface SM, and the negative pressure of the negative pressure chamber 21s given to the first recess Hm is given via this groove part 31. Therefore, the paper RP is suctioned by the first recesses Hm and the second recesses Fn including the end parts. Also, so as to have stable suction of the paper RP to the medium support surface SM even at the surface area at which first recesses Hm and second recesses Fn are not provided, the suction holes 33 in communication with the negative pressure chamber 21s are provided at suitable locations (e.g. positions aligned along the suction holes 32 and the transport direction Y).
Next, we will describe the first recesses Hm and the second recesses Fn while referring to
As shown in
With this embodiment, four second recesses Fn (F0, F1, F2, F3) are all formed depressed in roughly the same manner from the medium support surface SM, and at least the width dimension B of the width direction has the same roughly rectangular shaped openings at the medium support surface SM. In contrast to this, all of the first recesses Hm are similarly formed with roughly the same depression from the medium support surface SM, and at the medium support surface SM, for all the first recesses Hm, the width dimension A of the opening has a larger rectangular opening shape than the width dimension B of the opening of the second recesses Fn. The opening of the first recesses Hm is formed with approximately equal length as the ejection area of the ink ejected from the liquid ejection head 19 in the transport direction Y. The opening of the second recesses Fn is formed at a length that is a broader area than the ejection area of the ink in the transport direction Y to be able to reliably accept the ink ejected from the liquid ejection head 19. In addition, the first recesses Hm and the second recesses Fn have the depressed part at the transport direction downstream side edge of the respective openings formed as a sloped surface so that the paper RP is transported smoothly without catching on something.
Furthermore, with this embodiment, ribs 35 are provided extending from the transport direction Y upstream side edge at the opening of the first recess Hm toward the transport direction Y downstream side. With the ribs 35, the upstream side of the transport direction Y at the first recess Hm has the dimension between both edges in the width direction at the opening of the first recesses Hm and the rib 35 formed to be smaller than the width dimension of the opening of the second recesses Fn. Said another way, between the second recesses Fn provided with a gap open on the medium support surface SM, the first recesses Hm are provided with the opening width dimension larger than the second recesses Fn, and set to an item count for which the width dimensions Aa and Ab between the rib 35 provided on the transport direction Y upstream side at that opening and both edges of the opening will be less than the second recesses Fn.
Incidentally, with this embodiment, as shown in
Also, as shown in
In this way, the width dimension of the width direction of the opening of the first recesses Hm is formed as a larger dimension than the width dimension of the width direction of the opening of the second recesses Fn. Then, with this embodiment, depending on the number of items set between all the second recesses Fn provided on the medium support surface SM, the first recesses Hm are formed with the width dimension A of the opening having a value between approximately 13.5 to 15.4 millimeters.
The end part of the width direction of the paper RP supported on the medium support unit 20 is suctioned at the medium support surface SM such that at the opening of width dimension 12 millimeters of the corresponding second recess Fn, it is at a position separated by approximately 4.5 millimeters from the edge of the opening positioned inside the paper RP. Also, so as to reliably accept ink ejected from the liquid ejection head 19, the second recesses Fn are formed with long openings for which the opening edge has respectively designated dimensions (here, approximately 3 to 6 millimeters) in both the upstream side and the downstream side directions of the transport direction in relation to the openings of the first recesses Hm.
Also, as shown in
For the other second recess Fn provided corresponding to the end part in the width direction of the paper RP, similarly, these are in communication via the adjacent first recess Hm and the groove part 31 inside the covered paper RP, and furthermore, the end part of the paper RP given the negative pressure of the negative pressure chamber 21s from the first recess Hm via this groove part 31 is suctioned. On the suction hole 32 provided on the first recess Hm in communication via the groove part 31 with the second recess Fn, a wall part 32a is formed that suppresses the inflow of floating ink that has become mist around that hole.
Next, we will describe the action by the medium support unit 20 of this embodiment for which the first recesses Hm and the second recesses Fn are formed in this way on the medium support surface SM on the transported paper RP while referring to
As shown in
Also, with the prior art medium support unit 20, at the opening of the first recesses Hm, a rib 35 of a designated width is provided extending from the edge of the opening of the transport direction Y upstream side toward the transport direction Y downstream side. With this rib 35, at the transport direction Y upstream side of the opening of the first recesses Hm, the respective width dimensions between both edges of the first recesses Hm and the ribs 35 positioned in the width direction are smaller than the width dimension A of the transport direction Y downstream side at the opening of the first recesses Hm.
Therefore, in a state with the paper RP3 suctioned to the upstream side of the first recesses Hm for which transport has started on the medium support surface SM (the state shown by code number P1 in
In a state for which the paper RP3 is transported further to the downstream side from this state, and the paper RP3 is suctioned at the transport direction Y downstream side of the opening of the first recesses Hm (the state shown by code number P2 in
In contrast to this, as shown in
Therefore, the paper RP3 starts being transported on the medium support surface SM, and in the state for which the paper RP is suctioned at the transport direction Y upstream side at the opening of the first recesses Hm (the state shown by code number P1 in
From this state, the paper RP3 is further transported to the transport direction Y downstream side, and in a state for which the paper RP3 is suctioned at the transport direction Y downstream side of the opening of the first recesses Hm (the state shown by code number P2 in
The bending at the second recesses Fn having openings with a small width dimension when the paper RP3 is swollen due to impacted ink is suppressed more than the bending of the first recesses Hm having openings with a large width dimension, so the bending deformation TB of the second recesses Fn due to suction becoming even larger due to swelling is suppressed. Therefore, together with the deformation due to this swelling, the bending deformation TB that occurs with the second recesses Fn is absorbed by the bending deformation TA of the first recesses Hm that occurs due to suction.
With the embodiment noted above, it is possible to obtain effects such as the following.
(1) With the paper RP supported by suction at the transport direction Y upstream side on the medium support surface SM, the bending deformation that occurs at the second recesses Fn is absorbed by the bending deformation that occurs at the transport direction downstream side within the first recesses Hm for which the opening width dimension is larger than that of the second recesses Fn as it is transported to the transport direction Y downstream side on the medium support surface SM. Therefore, with the paper RP supported by suction on the medium support surface SM, the bending that occurs in the width direction is made uniform. As a result, the impact displacement volume on the second recesses Fn and the first recesses Hm of the ink ejected from the liquid ejection head 19 is suppressed. Also, the occurrence of large bending deformation on the paper RP is suppressed, so suppression is done such that there is no contact with the liquid ejection head 19.
(2) At the transport direction Y upstream side of the medium support surface SM for which suction of the paper RP has started, it is possible to suppress bending deformation of the paper RP that occurs in the width direction at the first recesses Hm using the ribs 35. As a result, at the first recesses Hm, because the paper RP is supported on the medium support surface SM by suction in a state with the bending deformation suppressed, it is supported at a suitable position in relation to the medium support surface SM.
(3) The transport direction Y upstream side edge at the openings of the second recesses Fn is positioned further to the transport direction Y upstream side than the transport direction Y upstream side edge at the openings of the first recesses Hm, so it is possible to accept the ink ejected from the liquid ejection head 19 with high reliability at the second recesses Fn. Therefore, soiling by the ink of the medium support surface SM is suppressed.
(4) The second recesses Fn are arranged at positions corresponding to the width direction end parts of the paper RP, so it is possible to accept ink ejected from the liquid ejection head 19 positioned sticking out further than the end parts of the paper RP at the second recesses Fn. Therefore, soiling by ink of the medium support surface SM is suppressed.
(5) The first recesses Hm are equipped with suction holes 32 in communication with the negative pressure generating unit 23 that generates negative pressure, so negative pressure is given to the first recesses Hm via the suction holes 32 provided in the first recesses Hm. Therefore, it is possible to have bending deformation occur reliably on the paper RP at the first recesses Hm.
The embodiment noted above can be modified as noted below.
With the embodiment noted above, the shape of the first recesses Hm is not limited to the shape shown in
Alternatively, as shown in
With the embodiment noted above, the first recesses Hm do not absolutely have to be equipped with suction holes 32 in communication with the negative pressure generating unit 23 for generating negative pressure. For example, the same as with the second recesses Fn, with a portion of the first recesses Hm, it is also possible to be in communication with the suction holes 32 provided on another first recess Hm using a groove part 31 formed on the adjacent other first recesses Hm and the medium support surface SM.
With the embodiment noted above, it is also possible to not necessarily have the second recesses Fn arranged at positions corresponding to the width direction end parts orthogonal to the transport direction Y of the paper RP. For example, when ink is ejected on the medium support surface SM regardless of whether it is borderless printing, it is sufficient to form the second recesses Fn at positions at which this ink is ejected on the medium support surface SM.
With the embodiment noted above, the transport direction Y upstream side edge of the openings of the second recesses Fn does not absolutely have to be positioned to the transport direction Y upstream side from the transport direction Y upstream side edge of the openings of the first recesses Hm. For example, these can also be at the same position. Specifically, it is sufficient to be a position for which it is possible to accept the ink ejected from the liquid ejection head 19.
With the embodiment noted above, it is also possible for the second recesses Fn to be equipped with an absorptive material that absorbs ejected ink. By doing this, it is possible for the ink ejected from the liquid ejection head 19 to be accepted reliably at the second recesses Fn. Therefore, soiling by ink of the medium support surface SM is suppressed at a high ratio, so for example, soiling of the transported paper RP covering the second recesses Fn is suppressed.
With the embodiment noted above, the ejection medium is not limited to being paper (roll paper), and can also be a sheet type member which uses a material such as a metal plate, resin plate, fabric or the like. As long as it is a member for which it is possible to form an image or the like using the liquid ejected from the liquid ejection head 19, it can be used as the ejection medium.
With the embodiment noted above, with the liquid ejection head 19, the liquid storage container in which the ejected liquid is housed can be an on-carriage type which is placed on the carriage 18, or the liquid storage container can also be an off-carriage type which is not placed on the carriage 18. Alternatively, this is not limited to being a serial type printer for which the carriage 18 moves in the main scan direction X, but can also be a line head type printer for which it is possible to do maximum width range printing of the paper RP even with the liquid ejection head 19 remaining fixed.
With the embodiment noted above, the liquid ejection device was put into specific form as the printer 11 for ejecting ink as the liquid, but it is also possible to make it into a specific form as a liquid ejection device that ejects or discharges a liquid other than ink. Various types of liquid ejection device equipped with a liquid ejection head or the like for discharging tiny volume droplets can be appropriated for this. Droplets means the state of liquid discharged from the aforementioned liquid ejection device, and includes granular shapes, tear shapes, and threadlike shapes with a tail. Also, what is called liquid here is sufficient as long as it is a material that can be ejected by the liquid ejection device. For example, it is sufficient as long as it is an item in a state when the property is liquid phase, and includes not only liquid bodies with high or low viscosity, fluid bodies such as sol, gel water, other inorganic solvents, organic solvents, solutions, liquid resin, liquid metal (metal melt), or a liquid as one state of a substance, but also includes items such as items for which particles of functional materials consisting of a solid such as a pigment, metal particle or the like is dissolved, dispersed, or blended in a solvent. Also, as a representative example of a liquid, we can list the ink or liquid crystal or the like such as those described with the embodiment noted above. Here, ink includes typical water based inks, oil based inks, as well as various liquid compositions such as gel ink, hot melt ink and the like. As a specific example of the liquid ejection device, for example, there are liquid ejection devices which eject liquid including materials such as electrode materials or coloring materials or the like in a dispersed or dissolved form used in manufacturing items such as liquid crystal displays, EL (electro luminescence) displays, surface light emitting displays, color filters and the like. Alternatively, it is also possible to be a liquid ejection device for ejecting bioorganic material used for biochip manufacturing, a liquid ejection device for ejecting a liquid that will be a sample used for a precision pipette, a textile printing device, a micro dispenser or the like. Furthermore, it is also possible to use a liquid ejection device for ejecting lubricating oil with a pinpoint on precision machines such as watches, cameras or the like, a liquid ejection device for ejecting a transparent resin liquid such a ultraviolet curing resin or the like for forming a miniature hemispheric lens (optical lens) used for optical communication elements or the like on a substrate, or a liquid ejection device for ejecting an acid or alkaline or the like etching fluid for etching a substrate or the like. Then, it is possible to apply the present invention to any one type of liquid ejection device among these.
In understanding the scope of the present invention, the term “comprising” and its derivatives, as used herein, are intended to be open ended terms that specify the presence of the stated features, elements, components, groups, integers, and/or steps, but do not exclude the presence of other unstated features, elements, components, groups, integers and/or steps. The foregoing also applies to words having similar meanings such as the terms, “including”, “having” and their derivatives. Also, the terms “part,” “section,” “portion,” “member” or “element” when used in the singular can have the dual meaning of a single part or a plurality of parts. Finally, terms of degree such as “substantially”, “about” and “approximately” as used herein mean a reasonable amount of deviation of the modified term such that the end result is not significantly changed. For example, these terms can be construed as including a deviation of at least ±5% of the modified term if this deviation would not negate the meaning of the word it modifies.
While only selected embodiments have been chosen to illustrate the present invention, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made herein without departing from the scope of the invention as defined in the appended claims. Furthermore, the foregoing descriptions of the embodiments according to the present invention are provided for illustration only, and not for the purpose of limiting the invention as defined by the appended claims and their equivalents.
Number | Date | Country | Kind |
---|---|---|---|
2012-026451 | Feb 2012 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
6270215 | Miyasaka et al. | Aug 2001 | B1 |
6927841 | Hinojosa et al. | Aug 2005 | B2 |
7144106 | Ishii et al. | Dec 2006 | B2 |
7322690 | Ishii et al. | Jan 2008 | B2 |
7887179 | Toyoshima | Feb 2011 | B2 |
8287119 | Yamaguchi et al. | Oct 2012 | B2 |
20070291096 | Toyoshima | Dec 2007 | A1 |
20110074872 | Ozaki et al. | Mar 2011 | A1 |
20110221843 | Ozaki | Sep 2011 | A1 |
Number | Date | Country |
---|---|---|
06-015902 | Jan 1994 | JP |
08-156351 | Jun 1996 | JP |
11-208045 | Aug 1999 | JP |
2001-347691 | Dec 2001 | JP |
2001-347710 | Dec 2001 | JP |
2002-120420 | Apr 2002 | JP |
2003-118180 | Apr 2003 | JP |
2003-118181 | Apr 2003 | JP |
2003-118182 | Apr 2003 | JP |
2003-246524 | Sep 2003 | JP |
2005-219434 | Aug 2005 | JP |
2006-181939 | Jul 2006 | JP |
2006-192836 | Jul 2006 | JP |
2006-231612 | Sep 2006 | JP |
2007-098936 | Apr 2007 | JP |
2007-152737 | Jun 2007 | JP |
2007-260913 | Oct 2007 | JP |
2007-331255 | Dec 2007 | JP |
2009-067015 | Apr 2009 | JP |
2009-119778 | Jun 2009 | JP |
2010-000694 | Jan 2010 | JP |
2010-137399 | Jun 2010 | JP |
2010-269456 | Dec 2010 | JP |
2010-269609 | Dec 2010 | JP |
2011-046110 | Mar 2011 | JP |
2011-088424 | May 2011 | JP |
2011-189538 | Sep 2011 | JP |
Entry |
---|
The extended European Search Report for European Application No. 13154360.5 mailed May 3, 2013. |
Number | Date | Country | |
---|---|---|---|
20130208065 A1 | Aug 2013 | US |