The present invention relates to a tank used in a liquid ejection device.
Various types of liquid ejection devices that eject liquid, such as ink, have been proposed. Such a liquid ejection device includes a liquid ejection head, a tank containing liquid, and a tube connecting the liquid ejection head to the tank and supplying the liquid from the tank to the liquid ejection head. As an example, WO/2014/115506 discloses a printer used as a liquid ejection device included in a multifunctional apparatus. A tank provided for the printer disclosed in WO/2014/115506 has an ink supply port in the bottom at an end part closer to a print head. This ink supply port is connected, via a supply tube, to a relay unit mounted on a carriage. Then, ink in the tank is supplied to the print head via the supply tube and the relay unit.
When the printer disclosed in WO/2014/115506 is in a normal usage state, the tank is positioned below the print head in the vertical direction. Here, suppose that this state is changed and the tank is positioned above the print head in the vertical direction. In this case, the meniscus of the print head is damaged under an impact, for example, and ink leaks from the print head or the relay unit. In addition, ink in the tank leaks from the print head through the supply tube. These circumstances where the tank is positioned above the print head in the vertical direction in this way can take place when, for example, the top face is confused with the side face and the printer is laid on its side by mistake when transported in a container box, such as a cardboard box. As another example, the tank is positioned above the print head when, after taken out of the container box, the top face is confused with the side face and the printer is placed on its side by mistake.
Such circumstances commonly occur, not only to printers, but also to liquid ejection devices that discharge any liquid. In view of this, a technology of reducing leakage of liquid in the tank from the liquid ejection head is desired.
An advantage of some aspects of the invention is to solve at least a part of the stated problem and the invention can be implemented as follows.
1. According to an aspect of the invention, a tank is provided which is mounted on a liquid ejection device to supply liquid to a liquid ejection head included in the liquid ejection device. The tank includes: a liquid chamber containing the liquid; an air introduction inlet introducing air into the liquid chamber; a liquid inlet configured to inject the liquid into the liquid chamber; a liquid outlet from which the liquid in the liquid chamber flows out; a liquid communication path causing the liquid from the liquid outlet to pass through the liquid communication path; a liquid supply port configured to supply the liquid in the liquid communication path to the liquid ejection head; a filter removing foreign matter from the liquid; and an exterior wall forming the liquid chamber and including: an upper wall positioned higher in an in-use state in which the liquid is ejected from the liquid ejection head; a bottom wall positioned lower in the in-use state; a first side wall crossing each of the upper wall and the bottom wall; and a second side wall crossing each of the upper wall and the bottom wall and positioned farther away from the liquid ejection head than the first side wall is in the in-use state. The liquid communication path has: a first liquid communication path provided on an outer surface side of the bottom wall; and a second liquid communication path provided on an outer surface side of the first side wall and communicating with the first liquid communication path. Each of the liquid outlet and the filter is positioned at an end part of the first liquid communication path near the second side wall. The liquid supply port is positioned in the liquid communication path near the upper wall.
With the configuration of the tank according to the above aspect, the liquid outlet is positioned at the end part of the first liquid communication path near the second side wall, that is, at the end part near the second side wall located away from the liquid ejection head than the first side wall in the in-use state. Thus, when circumstances cause the tank to be above the liquid ejection head, the liquid outlet is located near the second side wall which is in the upper part of the tank. This configuration can prevent the liquid in the liquid chamber from flowing out of the liquid outlet and thus prevent leakage of the ink in the tank from the liquid ejection head in the liquid ejection device. In addition, suppose that when ink is injected from the liquid inlet, foreign matter enters the ink in the liquid chamber. In this case, the filter provided for the first liquid communication path can prevent the liquid communication path and the liquid ejection head from being clogged with this foreign matter.
2. With the configuration of the tank according to the above aspect, when the liquid chamber is filled with the liquid up to a highest level of a predetermined capacity range and the first side wall is positioned lower in a vertical direction, the liquid outlet may be positioned above a fluid level of the liquid. With this configuration of the tank in the above aspect, when the liquid chamber is filled with the liquid up to the highest fluid level of the predetermined capacity range and the first side wall is positioned lower in the vertical direction, the liquid outlet is positioned above the fluid level of the liquid. Thus, in this state, the liquid in the liquid chamber is more reliably prevented from flowing out of the liquid outlet.
3. With the configuration of the tank according to the above aspect, the liquid chamber may have an opening enclosed by the exterior wall. Moreover, the first liquid communication path may have a first groove provided on the outer surface side of the bottom wall. Furthermore, the second liquid communication path may have a second groove provided on the outer surface side of the first side wall. The tank may further include a film covering the opening, the first groove, and the second groove. With this configuration of the tank in the above aspect, one side of the liquid chamber, one side of the first liquid communication path, and one side of the second liquid communication path can be formed to share one and the same film. This configuration can reduce the manufacturing cost and time of the tank. Furthermore, the exterior wall, which is included in the liquid chamber, is a part of the wall forming the liquid communication path. Thus, as compared with the case where the exterior wall and the liquid communication path are formed separately, the tank can be reduced in size and manufactured in a shorter time as well.
4. With the configuration of the tank according to the above aspect, the liquid chamber may have an air release hole that communicates with the air introducing inlet. The air release hole may be positioned above a fluid level of the liquid when the liquid chamber is filled with the liquid up to a highest level of a predetermined capacity range and the first side wall is positioned lower in a vertical direction. With this configuration of the tank in the above aspect, when the liquid chamber is filled with the liquid up to the highest fluid level of the predetermined capacity range and the first side wall is positioned lower in the vertical direction, the air release hole is positioned above the fluid level of the liquid. Thus, in this state, the liquid in the liquid chamber is more reliably prevented from flowing into the air release hole and flowing out of the air introducing inlet.
The invention can be implemented through various aspects. For example, the invention can be implemented by a liquid ejection device including the tank and the liquid ejection head according to any one of the above aspects. Moreover, the invention can be implemented by a method of manufacturing a tank or a method of manufacturing a liquid ejection device, for example.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
The scanner unit 51 is a so-called flatbed scanner and includes an imaging element (not shown), a platen, and a cover. For example, the imaging element may be an image sensor. The scanner unit 51 images letters or images recorded on a medium, such as a sheet of paper, using the imaging element and reads the letters or images as image data. The scanner unit 51 has a rotation axis along the X axis direction at an end part in the −Y direction, and is configured to be rotatable about the rotation axis. A surface of the platen (not shown) of the scanner unit 51 on the side near the printer 11 (i.e., the surface in the −Z direction) covers a housing 15 and also functions as a cover of the printer 11.
The printer 11 includes: the housing 15; four tanks 100K, 100C, 100M, and 100Y; a carriage 21; four relay units 20K, 20C, 20M, and 20Y; a print head 22; a tube 30; an operation panel 13; and a paper discharge port 14.
The housing 15 is an outer shell of the printer 11. The housing 15 houses the four tanks 100K, 100C, 100M, and 100Y, the carriage 21, the four relay units 20K, 20C, 20M, and 20Y, the print head 22, and the tube 30. In the embodiment, the four tanks 100K, 100C, 100M, and 100Y may also be referred to collectively as the “tanks 100” or individually as the “tank 100”. Similarly, the four relay units 20K, 20C, 20M, and 20Y may also be referred to collectively as the “relay units 20” or individually as the “relay unit 20”. Note that
In addition to the four tanks 100 and so forth described above, the housing 15 further houses a controller (not shown), a carrying mechanism (not shown), and a transport mechanism (not shown). The controller controls the ink ejection timing, the amount of ejection, and the transport amount of printing paper. The carrying mechanism causes the carriage 21 to reciprocate back and forth (perform scanning). The transport mechanism transports printing paper. The housing 15 is provided with a tank holder 17. In the in-use state, the tank holder 17 is positioned on the front side in the multifunctional apparatus 10 (in the +Y direction) and protrudes in the +Y direction as compared with the other parts of the housing 15. The tank holder 17 holds the four tanks 100 aligned along the X axis direction. The tank container 17 has an opening in the top. This opening is covered by a cover 16 to be openable and closable. The cover 16 is rotatable in the same direction in which the scanner unit 51 is rotatable. As described later, each of the tanks 100 is configured to be refillable with ink. A user can turn the cover 16 to expose the tanks 100 and then refill a desired one of the tanks 100 with ink.
Each of the tanks 100 contains a different color of ink. To be more specific, the tank 100K contains black ink. Moreover, the tank 100C contains cyan ink, the tank 100M contains magenta ink, and the tank 100Y contains yellow ink. The tank 100K is connected to the relay unit 20K via the tube 30 and supplies black ink to the relay unit 20K. The tank 100C is connected to the relay unit 20C via the tube 30 and supplies cyan ink to the relay unit 20C. The tank 100M is connected to the relay unit 20M via the tube 30 and supplies magenta ink to the relay unit 20M. The tank 100Y is connected to the relay unit 20Y via the tube 30 and supplies yellow ink to the relay unit 20Y. The detailed configuration of the tank 100 is described later. The tube 30 includes a total of four tubes each of which is made of a flexible material, such as synthetic rubber.
The carriage 21 is reciprocatable back and forth along the X axis direction inside the housing 15. The four relay units 20 and the print head 22 are mounted on the carriage 21. The carrying mechanism (not shown) causes the carriage 21 to reciprocate back and forth along the X axis direction. Thus, the scanning direction of the carriage 21 and the print head 22 is parallel to the X axis direction. In the embodiment, the carriage 21 and the print head 22 perform scanning on the rear side (in the −Y direction) with respect to the tanks 100 as shown in
The print head 22 is positioned to be able to eject ink in the vertically downward direction, below the carriage 21 in the vertical direction. The print head 22 has a number of nozzles (not shown). While the carriage 21 is reciprocating back and forth, ink is ejected from the print head 22 to form, for example, an image onto a medium, such as printing paper. The printing paper on which the image, for example, is formed is discharged from the paper discharge port 14. The print head 22 corresponds to a subordinate concept of the liquid ejection head described in SUMMARY above.
The relay units 20 are aligned in the carriage 21 along the X axis direction. Each of the relay units 20 is connected to the corresponding one of the tanks 100 via the tube 30. Moreover, each of the relay units 20 is connected to the print head 22. Each of the relay units 20 temporarily retain the ink supplied from the corresponding one of the tanks 100 and supplies the ink to the print head 22 in accordance with ink ejection from the print head 22.
The operation panel 13 is positioned on the front side in the multifunctional apparatus 10 (in the +Y direction) in the in-use state. The operation panel 13 has a power button and other operation buttons. The user of the multifunctional apparatus 10 can operate the various operation buttons, facing the operation panel 13.
As shown in
The case 101 is made of synthetic resin, such as nylon or polypropylene. The case 101 includes a liquid inlet 150, an air introduction inlet 160, and a liquid supply port 140. As shown in
The liquid chamber 110 contains ink. As shown in
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The liquid inlet 150 is used for injecting ink into the liquid chamber 110. As shown in
The air introduction inlet 160 is used for introducing air into the liquid chamber 110. As shown in
As shown in
The liquid supply port 140 corresponds to an outlet of ink flowing from the tank 100 to the outside. The liquid supply port 140 is inserted into the tube 30 and supplies ink of the liquid chamber 110 to the tube 30. As shown in
The liquid communication path 130 allows the ink from the liquid outlet 120 to pass through the liquid communication path 130. As shown in
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In the tipped-over state shown in
In this tipped-over state, a fluid level FL2 of the ink in the liquid chamber 110 is above the print head 22 in the vertical direction. In this state, even when the meniscus of the print head 22 is damaged, the ink in the liquid chamber 110 is prevented from flowing out of the print head 22. This is because the liquid outlet 120 is positioned in an upper part of the tank 100 in the vertical direction and, in this state, the ink in the liquid chamber 110 does not flow out of the liquid outlet 120. According to the embodiment in particular, when the liquid chamber 110 is filled with the liquid up to the highest fluid level FL1 of the predetermined capacity range and the first side wall 111 is positioned lower in the vertical direction, the liquid outlet 120 is positioned above the fluid level of ink (the fluid level FL2). Thus, in this tipped-over state, the ink is more reliably prevented from flowing out of the liquid outlet 120.
Moreover, in the tipped-over state shown in
It should be noted that, in the tipped-over state, the filter 170 hardly receives the fluid pressure of ink and also causes the channel resistance to increase as compared with the case where the filter 170 is not provided. Thus, this configuration can further prevent the ink from flowing into the liquid communication path 130 and make the menisci of the nozzles of the print head 22 harder to damage.
With the configuration of the tank 100 according to the embodiment described thus far, the liquid outlet 120 is positioned at an end part of the first liquid communication path 131 near the second side wall 112, that is, at the end part near the second side wall 112 located away from the print head 22 than the first side wall 111 in the in-use state. Thus, when circumstances cause the tank 100 to be above the print head 22, the liquid outlet 120 is located near the second side wall 112 which is in the upper part of the tank 100. This configuration can prevent the liquid in the liquid chamber 110 from flowing out of the liquid outlet 120 and thus prevent leakage of the ink in the tank 100 from the print head 22 in the printer 11. In addition, suppose that when ink is injected from the liquid inlet 150, foreign matter enters the ink in the liquid chamber 110. In this case, the filter 170 provided for the first liquid communication path 131 can prevent the liquid communication path 130 and the print head 22 from being clogged with this foreign matter.
Furthermore, in the state where the liquid chamber 110 is filled with ink up to the highest fluid level FL1 of the predetermined capacity range and the first side wall 111 is positioned lower in the vertical direction, the liquid outlet 120 is positioned above the fluid level of ink (the fluid level FL2). This configuration can reliably prevent the ink in the liquid chamber 110 from flowing out of the liquid outlet 120.
Moreover, one side of the liquid chamber 110, one side of the first liquid communication path 131, and one side of the second liquid communication path 132 can be formed to share one and the same film (i.e., the first sheet member 102). This configuration can reduce the manufacturing cost and time of the tank 100. Furthermore, the exterior wall 119, which is included in the liquid chamber 110, is a part of the wall forming the liquid communication path 130. Thus, as compared with the case where the exterior wall 119 and the liquid communication path 130 are formed separately, the tank 100 can be reduced in size and manufactured in a shorter time as well.
Moreover, the filter 170 is disposed to contact with the liquid outlet 120 (the protrusion 124). Thus, as compared with the case where the filter 170 is disposed at a different position of the liquid communication path 130, this configuration can simplify the structure and reduce the manufacturing cost and size of the tank 100.
Although the tank 100 is positioned on the front side to be more forward (in the +Y direction) than the print head 22 in the in-use state in the above embodiment, the invention is not limited to this. For example, the tank 100 may be positioned to be more backward (in the −Y direction) than the print head 22. Moreover, the tank 100 may be positioned more to the side in the +X direction than the print head 22, or more to the side in the +Z direction than the print head 22. With each of these configurations, the second side wall 112 is positioned farther away from the print head 22 than the first side wall 111 is in the in-use state. Thus, when the print head 22 is located below the tank 100 in the tipped-over state, the ink in the liquid chamber 110 can be prevented from leaking from the print head 22.
In the above embodiment, when the liquid chamber 110 is filled with ink up to the highest fluid level FL1 of the predetermined capacity range and the first side wall 111 is positioned lower in the vertical direction, the liquid outlet 120 is positioned above the fluid level of ink (the fluid level FL2). However, the invention is not limited to this. In the above state, the liquid outlet 120 may be positioned below the fluid level of ink. Even with this configuration, the liquid outlet 120 is positioned at the end part of the first liquid communication path 131 near the second side wall 112, that is, at the end part near the second side wall 112 located away from the print head 22 than the first side wall 111 in the in-use state. Thus, as compared with a configuration where the liquid outlet 120 is positioned at an end part near the first side wall 111, leakage of the ink in the liquid chamber 110 from the print head 22 can be prevented. Similarly, when the liquid chamber 110 is filled with ink up to the highest fluid level FL1 of the predetermined capacity range and the first side wall 111 is positioned lower in the vertical direction, the air release hole 163 may be positioned below the fluid level of ink.
In the above embodiment, the bottom wall 114 in the −Z direction is a part of the wall forming the first liquid communication path 131, and the first side wall 111 in the −Y direction is a part of the wall forming the second liquid communication path 132. However, the invention is not limited to this. The bottom wall 114 and the first liquid communication path 131 may be formed separately. Similarly, the first side wall 111 and the second liquid communication path 132 may be formed separately.
In the above embodiment, the filter 170 is provided outside the liquid chamber 110. However, the filter 170 may be provided inside the liquid chamber 110.
In the above embodiment, the liquid supply port 140 is positioned at the end part in the upper part (near the upper wall 113) of the second liquid communication path 132. However, the invention is not limited to this. The liquid supply port 140 may be positioned in the upper part other than the end part of the second liquid communication path 132. Alternatively, the liquid supply port 140 may be positioned in a center part of the second liquid communication path 132 in the Z axis direction, or in a lower part of the second liquid communication path 132.
The invention is not limited to the tank used in an inkjet printer, and applicable to a tank used in any liquid ejection device that ejects a different kind of liquid other than ink. For example, the invention is applicable to tanks used in various liquid ejection devices as follows.
1. Image recording device, such as facsimile
2. Color material ejection device used for manufacturing color filter for image display device, such as liquid crystal display
3. Electrode ejection device used for forming electrode of organic EL (Electro Luminescence) display and surface-emitting display (FED: Field Emission Display)
4. Liquid ejection device that discharges liquid containing bioorganic substance used in biochip manufacturing
5. Specimen ejection device as precision pipette
6. Lubricant ejection device
7. Liquid resin ejection device
8. Liquid ejection device that ejects lubricant to precision instrument, such as watch and camera, with pinpoint accuracy
9. Liquid ejection device that ejects transparent liquid resin, such as ultraviolet curable liquid resin, to form, for example, micro hemispherical lens (optical lens) used for element, such as optical communication element
10. Liquid ejection device that ejects acid or alkaline etching liquid to etch, for example, substrate
11. Other liquid ejection device provided with liquid ejection head that discharges micro droplet in any amount
It should be noted that the term “droplet” refers to liquid that is ejected from a liquid ejection device and that examples of the “droplet” include granular, tear-like, and stringy liquids. Moreover, the “liquid” may be any material that can be ejected by a liquid ejection device. For example, the “liquid” may be any material in which substance is in the liquid phase. Thus, examples of the “liquid” include high- and low-viscosity materials in the fluid state, sol, gel water, and other materials in the fluid state, such as inorganic solvent, organic solvent, solution, liquid resin, and liquid metal (metallic melt). Furthermore, examples of the “liquid” includes not only liquid of substance in one phase, but also melted, dispersed, and mixed materials in which particles of functional material made of solid matter, such as pigment and metal metallic particles, are melted, dispersed, and mixed into solvent. Typical examples of the liquid include ink and liquid crystal as described in the above embodiments. Here, examples of ink include typical water-based and oil-based ink and various kinds of liquid composition, such as gel ink and hot melt ink.
The invention is not limited to the above-described embodiments and thus can be implemented in various configurations without departing from the spirit of the invention. For example, technical features in the embodiments that correspond to technical features in the aspects described in SUMMARY above can be replaced and combined as necessary to solve some or all of the above-described problems or achieve some or all of the above-described advantageous effects. Moreover, technical features not described as being essential in the specification can be omitted as necessary.
This application claims the benefit of foreign priority to Japanese Patent Application No. JP2017-237834, filed Dec. 12, 2017, which is incorporated by reference in its entirety.
Number | Date | Country | Kind |
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2017-237834 | Dec 2017 | JP | national |