The present invention relates to a liquid container, a liquid container unit, a liquid ejection system, a liquid ejection apparatus and the like.
An inkjet printer has conventionally been known as one example of a liquid ejection apparatus. The inkjet printer ejects ink as one example of a liquid from an ejection head onto a printing medium such as printing paper, so as to implement printing on the printing medium. A known configuration of the inkjet printer causes ink stored in a tank as one example of a liquid container to be supplied to the ejection head. This tank is provided with an ink inlet port. The user is allowed to refill ink from the ink inlet port into the tank (see, for example, JP 2012-51309A). In the description below, the configuration that the liquid container such as tank is added to the liquid ejection apparatus such as inkjet printer may be called liquid ejection system.
The tank described in JP 2012-51309A has a translucent tank main body. This configuration enables the user to visually check the amount of ink contained in the tank from outside. The tank has an upper limit line provided in part of wall portions constituting the tank main body. This configuration enables the user to pour ink from an inlet port into the tank, while visually checking the amount of ink contained in the tank via the wall portion with the upper limit line. The wall portion with the upper limit line is called visual recognition portion. When the liquid level of ink contained in the tank reaches the upper limit line, the user can recognize that the amount of ink in the tank reaches its upper limit. In the tank described in JP 2012-51309A, however, the visual recognition portion is located near to the inlet port. When ink is poured from the inlet port into the tank, the poured ink may thus adhere to the visual recognition portion inside of the tank. This deteriorates the visibility of the visual recognition portion and makes it difficult for the user to recognize the amount of ink contained in the tank. Accordingly, the conventional liquid container has difficulty in recognizing the amount of the liquid.
In order to solve at least part of the problems described above, the invention may be implemented by the following aspects or embodiments.
According to one aspect of the invention, a liquid container includes a liquid container portion and a liquid inlet portion. The liquid container portion is configured to contain a liquid. The liquid inlet portion is connected with the liquid container portion and allows the liquid to be poured into the liquid container portion. The liquid container portion includes a bottom wall, a liquid inlet portion-forming wall that is located above the bottom wall and at which the liquid inlet portion is arranged, a visual recognition wall that extends in a direction intersecting with the bottom wall and the liquid inlet portion-forming wall and through which the liquid in the liquid container portion is visible from outside, an opposite wall opposite to the visual recognition wall, and a partition wall. At least a part of the partition wall is located between an opening and the visual recognition wall, and the opening is an intersecting part at which the liquid inlet portion intersects with the liquid inlet portion-forming wall.
According to the aspect of the invention, the partition wall includes a first partition wall that is located between the visual recognition wall and the opposite wall and extends in a direction from the liquid inlet portion-forming wall toward the bottom wall, and a second partition wall that is located between the liquid inlet portion-forming wall and the bottom wall and extends in a direction from the visual recognition wall toward the opposite wall. A part of the second partition wall is located below the opening in a vertical direction.
According to the aspect of the invention, the second partition wall is inclined to be closer to the bottom wall as approaching from the visual recognition wall toward the opposite wall.
According to the aspect of the invention, the partition wall has a cylindrical structure that extends from the intersecting part toward the bottom wall.
According to the aspect of the invention, a lower limit mark that indicates a lower limit of a liquid amount in the liquid container portion is disposed on the visual recognition wall.
According to the aspect of the invention, an upper limit mark that indicates an upper limit of a liquid amount in the liquid container portion is disposed on the visual recognition wall.
According to the aspect of the invention, only an area of a part of the visual recognition wall has liquid repellency.
According to the aspect of the invention, only an area of a part of the visual recognition wall has liquid repellency, and the area includes the lower limit mark.
According to the aspect of the invention, only an area of a part of the visual recognition wall has liquid repellency, and the area includes the upper limit mark.
According to another aspect of the invention, a printer includes the liquid container according to the above aspect of the invention, and a liquid ejection head. The liquid container is contained in a case of the printer, and the case has a window portion that faces the visual recognition wall of the liquid container portion.
The following describes a liquid ejection system including an inkjet printer (hereinafter called printer) as one example of the liquid ejection apparatus according to one aspect with reference to the drawings. The respective drawings may employ different scales to show the respective configurations and members in recognizable sizes.
As shown in
XYZ axes as coordinate axes that are orthogonal to one another are shown in
A mechanism unit 10 (shown in
The printer 3 is provided with a paper ejection portion 11. In the printer 3, the printing medium P is discharged from the paper ejection portion 11. In the printer 3, a surface where the paper ejection portion 11 is located is a front surface 13. The printer 3 also has an operation panel 17 on a top surface 15 intersecting with the front surface 13. The operation panel 17 includes a power button 18A and other operation buttons 18B. The tank unit 5 is provided on a side surface 19 of the first casing 6 intersecting with the front surface 13 and the top surface 15. The second casing 7 has windows 21. The windows 21 are provided on a side surface 27 of the second casing 7 intersecting with its front surface 23 and top surface 25. The windows 21 have optical transparency. The four tanks 9 described above are provided at positions overlapping the windows 21. This enables the operator using the liquid ejection system 1 to visually check the four tanks 9 via the windows 21. According to this aspect, the windows 21 are provided as openings formed in the second casing 7. The operator can visually check the four tanks 9 via the windows 21 that are the openings. The windows 21 are, however, not limited to the openings but may be made of a material having optical transparency.
According to this aspect, at least part of an area of each tank 9 facing the window 21 has optical transparency. The ink contained in the tank 9 is visible through this area of each tank 9 having optical transparency. Accordingly, this enables the operator to visually recognize the four tanks 9 via the windows 21 and thereby visually check the amounts of inks in the respective tanks 9. In other words, at least part of the area of the tank 9 facing the window 9 serves as the visual recognition portion from which the amount of ink is visible. Each tank 9 has an upper limit mark 28 indicating an upper limit of ink amount and a lower limit mark 29 indicating a lower limit of ink amount, in the area facing the window 21. The operator recognizes the amount of ink remaining in each tank 9 using the upper limit mark 28 and the lower limit mark 29 as indications. The first casing 6 and the second casing 7 are provided as separate members. According to this aspect, the second casing 7 is thus separable from the first casing 6 as shown in
The tank unit 5 has a support frame 32. The four tanks 9 are supported by the support frame 32. The support frame 32 is provided as a separate member from the first casing 6. According to this aspect, the support frame 32 is thus separable from the first casing 6 as shown in
A s shown in
The printer 3 also has a medium feeding mechanism (not shown) and a head carrying mechanism (not shown). The medium feeding mechanism drives a feed roller 51 with the power from a motor (not shown), so as to feed the printing medium P along the Y-axis direction. The head carrying mechanism transmits the power from a motor 53 via a timing belt 55 to the carriage 45, so as to carry the carriage 45 along the X-axis direction. The print head 47 is mounted on the carriage 45. The print head 47 is thus movable in the X-axis direction via the carriage 45 by the head carrying mechanism. The print head 47 is supported on the carriage 45 in the state that the print head 47 faces the printing medium P. The medium feeding mechanism and the head carrying mechanism cause ink to be ejected from the print head 47 while changing the position of the print head 47 relative to the printing medium P, so as to implement printing on the printing medium P.
The following describes some embodiments of the tanks 9. In the description below, for the purpose of discrimination of the tanks 9 of respective embodiments, different alphabets are added in different embodiments as suffixes to the signs as appropriate.
The following describes a tank 9A according to Embodiment 1. As shown in
As shown in
In the plan view of the first wall 81 from the sheet member 63-side, the air chamber 68 is surrounded by the fifth wall 85, the sixth wall 86, the seventh wall 87 and the eighth wall 88. The first wall 81 of the container portion 65 is identical with the first wall 81 of the air chamber 68. In other words, the container portion 65 and the air chamber 68 share the first wall 81 according to this embodiment. The fourth wall 84, the fifth wall 85, the second wall 82 and the third wall 83 respectively intersect with the first wall 81 as shown in
The fourth wall 84, the fifth wall 85, the second wall 82 and the third wall 83 are protruded in the −Y-axis direction from the first wall 81. A recess 91 is accordingly formed by the first wall 81 as main wall and the fourth wall 84, the fifth wall 85, the second wall 82 and the third wall 83 extended in the −Y-axis direction from the main wall. The recess 91 is formed to be concave in the +Y-axis direction. The recess 91 is open in the −Y-axis direction, i.e., toward the sheet member 63 (shown in
As shown in
The sixth wall 86, the seventh wall 87 and the eighth wall 88 are protruded in the −Y-axis direction from the first wall 81. A recess 99 is accordingly formed by the first wall 81 as main wall and the fifth wall 85, the sixth wall 86, the seventh wall 87 and the eighth wall 88 extended in the −Y-axis direction from the main wall. The recess 99 is formed to be concave in the +Y-axis direction. The recess 99 is open in the −Y-axis direction, i.e., toward the sheet member 63 (shown in
The second wall 82 and the sixth wall 86 form a step. The second wall 82 is located on the third wall 83-side of the sixth wall 86, i.e., on the +X-axis direction side of the sixth wall 86. The third wall 83 and the seventh wall 87 also form a step. The seventh wall 87 is located on the second wall 82-side of the third wall 83, i.e., on the −X-axis direction side of the third wall 83. In the plan view of the first wall 81 from the sheet member 63-side, an ink inlet portion 101 is placed between the third wall 83 and the seventh wall 87. The ink inlet portion 101 is provided on the fifth wall 85.
As shown in
As shown in
The ninth wall 111 is located between the third wall 83 and the second wall 82 and is arranged to face the third wall 83 across the eleventh wall 113. The tenth wall 112 is located between the first wall 81 and the sheet member 63 (shown in
As shown in
As shown in
As shown in
As shown in
The ink inlet portion 101 is provided on the fifth wall 85. As shown in
The above configuration causes the ink inlet portion 101 to be surrounded by the seventh wall 87, the extended portion 105, the third wall 83 and the first wall 81. In other words, the ink inlet portion 101 is provided in the area of the fifth wall 85 surrounded by the seventh wall 87, the extended portion 105, the third wall 83 and the first wall 81. The recess 131 serves as an ink receiving portion. The ink receiving portion is configured to receive, for example, ink overflowing from the ink inlet portion 101 and ink dripping down in the course of pouring of ink. Accordingly, the recess 131 has the function of ink receiving portion to receive ink.
As shown in
As shown in
The cutout 129 is provided on the second partition wall 125B. As shown in
As shown in
In the tank 9A, as shown in
With progress in printing by means of the print head 47, the ink 141 contained in the container portion 65 is fed toward the print head 47. Accordingly, the internal pressure of the container portion 65 decreases to be lower than the atmospheric pressure with progress in printing by means of the print head 47. As the internal pressure of the container portion 65 becomes lower than the atmospheric pressure, the air in the air chamber 68 flows through the communicating path 73 into the container portion 65. This is likely to maintain the internal pressure of the container portion 65 at the atmospheric pressure. The above configuration causes the ink 141 contained in the tank 9 to be supplied to the print head 47. When the remaining amount of the ink 141 is decreased with consumption of the ink 141 contained in the container portion 65 of the tank 9, the operator is allowed to refill the container portion 65 with ink newly supplied from the ink inlet portion 101.
As described above, the partition wall 125 is provided in the container portion 65. Accordingly, the ink poured from the ink inlet portion 101 into the container portion 65 is guided by the partition wall 125 in a direction to be away from the third wall 83, i.e., in a direction from the third wall 83-side toward the second wall 82-side. This makes the ink poured from the ink inlet portion 101 into the container portion 65 unlikely to be directly poured on the third wall 83. This accordingly maintains the high optical transparency of the third wall 83 during pouring of ink from the ink inlet portion 101 into the container portion 65. As a result, this enables the liquid level of ink contained in the container portion 65 to be accurately reflected on the third wall 83 when ink is poured from the ink inlet portion 101 into the container portion 65. Accordingly this enables the liquid level of ink contained in the container portion 65 to be accurately recognized when ink is poured from the ink inlet portion 101 into the container portion 65.
The first partition wall 125A of the partition wall 125 is located on the third wall 83-side of the opening 132 that is the intersecting part of the ink inlet portion 101 and the fifth wall 85 as shown in
In Embodiment 1, the container portion 65 corresponds to the liquid container portion; the ink inlet portion 101 corresponds to the liquid inlet portion, the fifth wall 85 corresponds to the first wall portion; the third wall 83 corresponds to the second wall portion; the fourth wall 84 corresponds to the bottom wall; the first wall 81 corresponds to the third wall portion; and the sheet member 63 corresponds to the fourth wall portion.
In the tank 9A, a clearance is formed at the position of the cutout 128 between the fifth wall 85 and at least part of the partition wall 125. This configuration makes the air trapped in a space surrounded by the fifth wall 85, the third wall 83, the first wall 81 and the sheet member 63 likely to be released through the clearance between the fifth wall 85 and at least part of the partition wall 125 during pouring of ink from the ink inlet portion 101 into the container portion 65. Accordingly, the liquid level of ink in the space surrounded by the fifth wall 85, the third wall 83, the first wall 81 and the sheet member 63 is likely to adequately rise during pouring of ink from the ink inlet portion 101 into the container portion 65. This configuration enables the liquid level of ink contained in the container portion 65 to be accurately recognized during pouring of ink from the ink inlet portion 101 into the container portion 65. As a result, this enables the amount of ink contained in the container portion 65 to be accurately recognized.
In the tank 9A, a clearance is formed at the position of the cutout 129 between the sheet member 63 and at least part of the partition wall 125. This configuration makes the air trapped in the space surrounded by the fifth wall 85, the third wall 83, the first wall 81 and the sheet member 63 likely to be released through the clearance between the sheet member 63 and at least part of the partition wall 125 during pouring of ink from the ink inlet portion 101 into the container portion 65. Accordingly, the liquid level of ink in the space surrounded by the fifth wall 85, the third wall 83, the first wall 81 and the sheet member 63 is likely to adequately rise during pouring of ink from the ink inlet portion 101 into the container portion 65. This configuration enables the liquid level of ink contained in the container portion 65 to be accurately recognized during pouring of ink from the ink inlet portion 101 into the container portion 65. As a result, this enables the amount of ink contained in the container portion 65 to be accurately recognized.
In the tank 9A, as shown in
In the tank 9A, as shown in
The positions at which the cutout 128 and the cutout 129 are formed are not limited to the end on the sheet member 63-side. The cutout 128 and the cutout 129 may be provided on the first wall 81-side. The cutout 128 may be provided at any position that enables the air trapped between the third wall 83 and the partition wall 125 to be moved to the ink inlet portion 101 via the cutout 128 during pouring of ink from the ink inlet portion 101.
The partition wall 125 is not limited to the configuration that is divided into the first partition wall 125A and the second partition wall 125B but may have any configuration that allows the partition wall 125 to interfere with the flow of ink from the ink inlet portion 101 toward the third wall 83 when ink is poured from the ink inlet portion 101 into the container portion 65. The partition wall 125 may be configured, for example, to have only the first partition wall 125A.
The following describes a tank 9B according to Embodiment 2. The tank 9B has a similar configuration to that of the tank 9A of Embodiment 1, except the partition wall 125 of the tank 9A of Embodiment 1. The like components of the tank 9B to those of the tank 9A are expressed by the like signs to those of Embodiment 1 and are not specifically described here. As shown in
The casing 61B is provided with a partition wall 151 placed in the container portion 65. The partition wall 151 is continuous with the ink inlet portion 101 and is formed in a cylindrical shape. As shown in
The tank 9B employs the configuration that the side wall 133 is continuous with the partition wall 151. The configuration of the partition wall 151 is, however, not limited to this configuration. For example, the partition wall 151 may be configured to surround the opening 132 from the outer side of the opening 132. In this modified configuration, a step is formed between the side wall 133 and the partition wall 151.
In the tank 9A of Embodiment 2, the cylindrical partition wall 151 is likely to suppress the splash of ink from the ink inlet portion 101 toward the third wall 83 when ink is poured from the ink inlet portion 101 into the container portion 65. This reduces the likelihood that ink adheres to the third wall 83. This accordingly maintains the high optical transparency of the third wall 83 during pouring of ink from the ink inlet portion 101 into the container portion 65. As a result, this enables the liquid level of ink contained in the container portion 65 to be accurately reflected on the third wall 83 when ink is poured from the ink inlet portion 101 into the container portion 65. Accordingly this enables the liquid level of ink contained in the container portion 65 to be accurately recognized when ink is poured from the ink inlet portion 101 into the container portion 65.
In Embodiment 2, the container portion 65 corresponds to the liquid container portion; the ink inlet portion 101 corresponds to the liquid inlet portion, the fifth wall 85 corresponds to the first wall portion; the third wall 83 corresponds to the second wall portion; the fourth wall 84 corresponds to the bottom wall; the first wall 81 corresponds to the third wall portion; and the sheet member 63 corresponds to the fourth wall portion. In the first aspect, the tank unit 5 corresponds to the liquid container unit.
In Embodiment 1 and Embodiment 2 described above, the third wall 83 inside of the container portion 65 may be configured to have enhanced liquid repellency against ink. The third wall 83 of this configuration is likely to repel the ink even in the case that the splashed ink adheres to the third wall 83 during pouring of ink from the ink inlet portion 101 into the container portion 65. This accordingly maintains the higher optical transparency of the third wall 83 during pouring of ink from the ink inlet portion 101 into the container portion 65. As a result, this enables the liquid level of ink contained in the container portion 65 to be more accurately reflected on the third wall 83 when ink is poured from the ink inlet portion 101 into the container portion 65. Accordingly this enables the liquid level of ink contained in the container portion 65 to be more accurately recognized when ink is poured from the ink inlet portion 101 into the container portion 65.
One method employed to achieve the configuration of enhancing the liquid repellency against ink may be, for example, that the casing 61A or the casing 61B is made of a material having liquid repellency against ink. Another method employed to achieve the configuration of enhancing the liquid repellency against ink may be, for example, that a material having liquid repellency against ink (hereinafter called liquid repellent material) is applied on the third wall 83 inside of the container portion 65. An example of the liquid repellent material may be a paint containing a fluororesin or a fluorine compound. The area in which the liquid repellent material is applied may be the entire area of the third wall 83 or part of the third wall 83.
A method employed to apply the liquid repellent material on only part of the third wall 83 may apply the liquid repellent material on a partial area 155 in the width of the third wall 83 along the Y axis as shown in
Another method employed to apply the liquid repellent material on only part of the third wall 83 may apply the liquid repellent material on partial areas 157 in the height of the third wall 83 along the Z axis as shown in
In the configuration that the liquid repellent material is applied on only the partial areas 157 in the height of the third wall 83 along the Z axis, the plurality of areas 157 may have equal height dimensions H1 or may have different height dimensions H1 along the Z axis as shown in
In the configuration that the liquid repellent material is applied on only the partial areas 157 in the height of the third wall 83 along the Z axis, the liquid repellent material may be applied on an area 157A including the upper limit mark 28 and an area 157B including the lower limit mark 29 as shown in
In the first aspect, the plurality of tanks 9 are not placed inside of the first casing 6 arrange to cover the mechanism unit 10. In other words, the first aspect employs the configuration that the plurality of tanks 9 are placed outside of the first casing 6. According to another configuration, the plurality of tanks 9 may be placed inside of the first casing 6. The following describes a multifunction printer as one example of the liquid ejection system according to a second aspect, with regard to the configuration that the plurality of tanks 9 are placed inside of a casing.
A multifunction printer 500 of this aspect includes a printer 503 and a scanner unit 505 as shown in
The scanner unit 505 is flatbed type having an imaging element (not shown) such as an image sensor, a platen and a cover. The scanner unit 505 is capable of reading an image or the like recorded on a medium such as paper via the imaging element in the form of image data. The scanner unit 505 accordingly serves as a reader of the image or the like. As shown in
The printer 503 performs printing on a printing medium P such as printing paper with ink as one example of liquid. As shown in
The printer 503 also has an operation panel 512. The operation panel 512 is provided with a power button 513 and other operation buttons 514. The operator who operates the printer 503 faces the operation panel 512 to operate the power button 513 and the operation buttons 514. A front surface of the printer 503 is a surface where the operation panel 512 is provided. The casing 507 has a window 515 provided on the front surface of the printer 503. The window 515 has optical transparency. The four tanks 9 described above are placed at a position overlapping the window 515. This configuration enables the operator to visually check the four tanks 9 through the window 515.
In the printer 503, a region of each of the tank 9 facing the window 515 has optical transparency. Ink contained in the tank 9 is visible through the region of each tank 9 having optical transparency. This enables the operator to observe the four tanks 9 through the window 515 and thereby visually check the amounts of inks contained in the respective tanks 9. In the printer 503, the window 515 is provided on the front surface of the printer 503. This configuration enables the operator facing the operation panel 512 to visually recognize the respective tanks 9 through the window 515. This accordingly enables the operator to check the remaining amounts of inks in the respective tanks 9 while operating the printer 503.
As shown in
In the respective aspects and embodiments described above, the liquid ejection apparatus may be a liquid ejection apparatus that sprays, ejects or applies and thereby consumes a liquid other than ink. The liquid ejected in the form of very small amounts of droplets from the liquid ejection apparatus may be in a granular shape, a teardrop shape or a tapered threadlike shape. The liquid herein may be any material consumed in the liquid ejection apparatus. The liquid may be any material in the liquid phase and may include liquid-state materials of high viscosity or low viscosity, sols, aqueous gels and other liquid-state materials including inorganic solvents, organic solvents, solutions, liquid resins and liquid metals (metal melts). The liquid is not limited to the liquid state as one of the three states of matter but includes solutions, dispersions and mixtures of the functional solid material particles, such as pigment particles or metal particles, solved in, dispersed in or mixed with a solvent. Typical examples of the liquid include liquid crystal, in addition to ink described in the above aspects and embodiments. The ink herein includes general water-based inks and oil-based inks, as well as various liquid compositions, such as gel inks and hot-melt inks. A concrete example of the liquid ejection apparatus may be a liquid ejection apparatus that ejects a liquid in the form of a dispersion or a solution containing a material such as an electrode material or a color material used for production of liquid crystal displays, EL (electroluminescent) displays, surface emission displays and color filters. The liquid ejection apparatus may also be a liquid ejection apparatus that ejects a bioorganic material used for manufacturing biochips, a liquid ejection apparatus that is used as a precision pipette and ejects a liquid as a sample, a printing apparatus or a microdispenser. Additionally, the liquid ejection apparatus may be a liquid ejection apparatus for pinpoint ejection of lubricating oil on precision machines such as machines and cameras or a liquid ejection apparatus that ejects a transparent resin solution of, for example, an ultraviolet curable resin, onto a substrate to manufacture a hemispherical microlens (optical lens) used for optical communication elements and the like. As another example, the liquid ejection apparatus may be a liquid ejection apparatus that ejects an acidic or alkaline etching solution to etch a substrate or the like.
According to one aspect of the embodiment, the liquid container comprises a liquid container portion that is configured to contain a liquid; and a liquid inlet portion that is connected with the liquid container portion and is configured to pour the liquid into the liquid container portion. The liquid container portion includes a first wall portion that is arranged to intersect with the liquid inlet portion; a second wall portion that has optical transparency and is arranged to intersect with the first wall portion; and a partition wall that is located between the second wall portion and an intersecting part at which the liquid inlet portion intersects with the first wall portion.
In the liquid container of this aspect, the partition wall interferes with the flow of the liquid from the liquid inlet portion toward the second wall portion when the liquid is poured from the liquid inlet portion into the liquid container portion. This configuration reduces the likelihood that the liquid adheres to the second wall portion even when the liquid is splashed from the liquid inlet portion toward the second wall portion. This facilitates the amount of the liquid contained in the liquid container to be recognized via the second wall portion.
In the liquid container of the above aspect, the liquid container portion may include a bottom wall that is located below the first wall portion in a state that the liquid container portion contains the liquid, and the partition wall may be extended in a direction from the first wall portion toward the bottom wall.
This aspect facilitates the wide area of the second wall portion to be blocked from the liquid inlet portion and thus makes the partition wall likely to interfere with the flow of the liquid from the liquid inlet portion toward the second wall portion.
In the liquid container of the above aspect, the liquid container portion may include a third wall portion that is arranged to intersect with the first wall portion and the second wall portion; and a fourth wall portion that is arranged to intersect with the first wall portion and the second wall portion. The partition wall may be a projection that is protruded from the third wall portion, and a clearance may be formed between at least part of the partition wall and the first wall portion.
This aspect makes the air trapped in a space surrounded by the first wall portion, the second wall portion, the partition wall, the third wall portion and the fourth wall portion likely to be released through the clearance between the partition wall and the first wall portion during pouring of the liquid from the liquid inlet portion into the liquid container portion. Accordingly, the liquid level in the space surrounded by the first wall portion, the second wall portion, the partition wall, the third wall portion and the fourth wall portion is likely to adequately rise according to the amount of the liquid poured form the liquid inlet portion. Accordingly this enables the amount of the liquid contained in the liquid container portion to be recognized accurately.
In the liquid container of the above aspect, the liquid container portion may include a third wall portion that is arranged to intersect with the first wall portion and the second wall portion; and a fourth wall portion that is arranged to intersect with the first wall portion and the second wall portion. The partition wall may be a projection that is protruded from the third wall portion, and a clearance may be formed between at least part of the partition wall and the fourth wall portion.
This aspect makes the air trapped in a space surrounded by the first wall portion, the second wall portion, the partition wall, the third wall portion and the fourth wall portion likely to be released through the clearance between the partition wall and the fourth wall portion during pouring of the liquid from the liquid inlet portion into the liquid container portion. Accordingly, the liquid level in the space surrounded by the first wall portion, the second wall portion, the partition wall, the third wall portion and the fourth wall portion is likely to adequately rise according to the amount of the liquid poured form the liquid inlet portion. Accordingly this enables the amount of the liquid contained in the liquid container portion to be recognized accurately.
In the liquid container of the above aspect, a distance between one end of the partition wall on the intersecting part-side and the second wall portion may be less than a distance between the other end of the partition wall on an opposite side to the intersecting part side and the second wall portion.
In this aspect, the partition wall is arranged to be away from the second wall portion in a direction from one end on the intersecting part side to the other end. This configuration makes the liquid poured from the liquid inlet port likely to be away from the second wall portion and thereby reduces the likelihood that the liquid adheres to the second wall portion.
In the liquid container of the above aspect, at least part of the partition wall may be located vertically below the intersecting part in a state that the liquid is poured through the liquid inlet portion.
In this aspect, the partition wall serves to reduce the impact of liquid dripping when the liquid poured from the liquid inlet portion drips down in the vertical direction from the intersecting part. This accordingly reduces the splash of the dripping liquid. As a result, this further reduces the likelihood that the liquid adheres to the second wall portion.
In the liquid container of the above aspect, the partition wall may have a cylindrical structure, and the cylindrical structure may be extended from the intersecting part.
In this aspect, the cylindrical structure is likely to suppress the liquid from being splashed toward the second wall portion when the liquid is poured into the liquid container. As a result, this further reduces the likelihood that the liquid adheres to the second wall portion.
In the liquid container of the above aspect, a material having liquid repellency against the liquid may be applied on an inner wall of the second wall portion.
In this aspect, even when the liquid adheres to the second wall portion, the second wall portion is likely to repel the liquid. This is likely to maintain the visibility through the second wall portion and thereby further facilitates the amount of the liquid contained in the liquid container to be recognized via the second wall portion.
A liquid container unit comprises a cover, a support structure, and the liquid container according to any one of the above aspects 1 to 8 that is located between the cover and the support structure.
In the liquid container unit having the liquid container located between the cover and the support structure, this aspect facilitates the amount of the liquid contained in the liquid container to be recognized.
A liquid ejection system comprises the liquid container unit of the above aspect; a liquid ejection apparatus having a liquid ejection head; and a tube that is arranged to supply the liquid from the liquid container of the liquid container unit to the liquid ejection head. The liquid container unit is fixed to outer periphery of the liquid ejection apparatus.
In the liquid ejection system including the liquid container unit, the liquid ejection apparatus and the tube, this aspect facilitates the amount of the liquid contained in the liquid container to be recognized.
A liquid ejection apparatus comprises a cover; a support structure; the liquid container of any one of the above aspects that is located between the cover and the support structure; a liquid ejection head that is provided between the cover and the support structure; and a tube that is provided between the cover and the support structure and is arranged to supply the liquid from the liquid container to the liquid ejection head.
In the liquid ejection apparatus including the liquid container, the liquid ejection head and the tube, this aspect facilitates the amount of the liquid contained in the liquid container to be recognized.
Number | Date | Country | Kind |
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2014-003960 | Jan 2014 | JP | national |
This application is a continuation application of U.S. patent application Ser. No. 14/779,035, filed on Sep. 22, 2015. This application claims priority to Japanese Patent Application No. 2014-003960 filed on Jan. 14, 2014. The entire disclosures of U.S. patent application Ser. No. 14/779,035 and Japanese Patent Application No. 2014-003960 are hereby incorporated herein by reference.
Number | Date | Country | |
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Parent | 14779035 | Sep 2015 | US |
Child | 15409727 | US |