1. Technical Field
The present invention relates to a liquid container suitable for detecting an amount of remaining liquid (ink) in a liquid consuming apparatus such as an inkjet printing apparatus and a method of manufacturing the liquid container.
2. Related Art
As a representative example of a liquid consuming apparatus, there is an inkjet printing apparatus having an inkjet print head for printing an image. Other liquid ejecting apparatuses may include an apparatus having a coloring material ejecting head used for manufacturing a color filter and the like of a liquid crystal display, an apparatus having an electrode material (conductive paste) ejecting head used for forming electrodes of an organic EL display, a field emission display (FED), and the like, an apparatus having a biological organic material ejecting head used for manufacturing a bio chip, and an apparatus having a sample ejecting head as a precise pipette.
In the inkjet printing apparatus as the representative example of the liquid consuming apparatus, an inkjet print head having a pressure generator pressurizing a pressure generating chamber and nozzle orifices ejecting the pressurized ink as ink droplets is mounted on a carriage. By endlessly supplying the ink in an ink container to the print head through a flow channel, a printing operation can be continuously performed. The ink container is constructed as a detachable cartridge that can be replaced by a user when the ink is completely consumed.
There is a method of managing ink consumption by integrating the number of ink droplets emitted from the print head or the amount of ink sucked in maintenance by software or a method of managing when the ink is actually consumed by a predetermined amount by attaching a liquid level detecting electrode to the ink cartridge, as a method of managing the ink consumption of an ink cartridge.
However, the method of managing the ink consumption by integrating the number of ejected ink droplets or the amount of ink by software causes the following problem. The head may eject ink droplets with non-uniformity in weight. The non-uniformity in weight of the ink droplets does not affect the image quality but the ink with a margin is filled in the ink cartridge in consideration of accumulation of errors in ink consumption due to the non-uniformity. Accordingly, there is a problem that the ink corresponding to the margin remains in some apparatuses.
On the other hand, in the method of managing when the ink is consumed by the use of an electrode, since the actual amount of remaining ink can be detected, it is possible to manage the amount of remaining ink with high reliability. However, since the detection of the ink level depends on the conductivity of the ink, the kinds of ink detectable are limited, thereby complicating the sealing structure of the electrode. Since precious metals with excellent conductivity and anti-corrosion are usually used as the material of the electrode, the cost for manufacturing the ink cartridge is enhanced. Since two electrodes should be necessarily formed, the number of manufacturing processes increases, thereby increasing the manufacturing cost.
Therefore, to solve the above-mentioned problems, a piezoelectric device (herein, referred to as a sensor unit) is disclosed in JP-A-2001-146030. The sensor unit monitors the amount of ink remaining in the ink cartridge by the use of the resonance frequency of a residual vibration signal resulting from the residual vibration (free vibration) of a vibrating plate after forcible vibration when the ink remains and does not remain in a sensor cavity opposed to the vibrating plate having a piezoelectric element formed thereon.
In FIG. 8 of JP-A-2006-248201, plural vertical-direction changing portions changing the flow of ink in vertical directions are shown. The space above the vertical-direction changing portions serves as a bubble trapping space.
In FIGS. 9 and 14 of JP-A-2006-315302, a structure supporting a sensor base at three positions of a partition wall and both main case walls thereof is shown. In JP-A-2001-328277, a barrier wall is disposed in the liquid opposed to the sensor, whereby bubbles hardly enter the sensor cavity even when the bubbles are formed in the liquid level in the tank.
Techniques of securing a bypass channel of a liquid by not welding a part of a film covering an opening of a liquid passage and then closing the bypass channel of the liquid by welding the part of the film are disclosed in JP-A-2005-022257 and JP-A-2004-306466.
The technique disclosed in JP-A-2006-248201 employs a specific gravity separation method of trapping bubbles having small specific gravity in the upside by the use of a labyrinth channel on the basis of a difference in specific gravity between the liquid and the bubbles.
Here, as shown in FIG. 8 of JP-A-2006-248201, the ink is introduced from the lower position of the bubble trapping space and the ink is discharged from the lower position of the bubble trapping space. In this case, as described later, when the ink consumption rate is great due to a continuous printing operation and thus the ink flow rate is great, the bubbles in the bubble trapping space are sucked into the ink and discharged along with the ink in the vicinity of the ink end. Then, bubbles are formed in the buffer chamber in the just upstream side of the sensor cavity and the bubbles are detected by the sensor, thereby falsely detecting the ink end.
In the technique disclosed in JP-A-2006-315302, the vibration of the piezoelectric element is absorbed by the main case coming in contact with the sensor base at three positions, thereby making it difficult to satisfactorily guarantee the vibration being detectable by the piezoelectric element. Since the sensor base is positioned in an opening formed in the main case, bubbles may stay in minute gaps around the sensor base at the time of injecting the ink, thereby causing false detection of the ink end. This problem is not prevented even by the use of the barrier wall shown in JP-A-2001-328277. This is because the barrier wall hinders the flow of ink at the time of initially injecting the ink to easily generate bubbles around the sensor base.
An advantage of some aspects of the invention is that it provides a liquid container that can prevent formation of bubbles in the immediate upstream of a sensor cavity even when the amount of remaining ink decreases, thereby enhancing the liquid detection precision.
Another advantage of some aspects of the invention is that it provides a liquid container that can reduce the false detection by employing a structure for enhancing the amplitude at the time of detecting the liquid and a structure for suppressing bubbles from staying around the sensor base at the time of introducing the liquid.
Another advantage of some aspects of the invention is that it provides a method of manufacturing a liquid container that can deliver bubbles to satisfactorily fill the liquid container with the liquid even when the bubbles are easily gathered due to its structure at the time of filling the liquid container with the liquid.
According to an aspect of the invention, there is provided a liquid container including: a case in which a flow channel of a liquid is exposed from an opening; a sensor base, disposed in the opening of the case to face the flow channel; a sensor chip, including: a piezoelectric element, mounted on a surface opposite to a surface of the sensor base which faces the flow channel; and a sensor cavity, disposed opposite to the piezoelectric element and adapted to receive the liquid as a detection target; a film, adapted to hold the sensor base in the opening and sealing the opening; a partition wall, partitioning the flow channel in the case into an upstream buffer chamber and a downstream buffer chamber; and a bubble trapping section, disposed upstream of the upstream buffer chamber. The bubble trapping section includes: a bubble trapping chamber, adapted to trap bubbles upside by allowing the liquid level to be lowered with reduction in an amount of remaining liquid at a time of consuming the liquid; an inlet, communicating at a vertical upper position of the bubble trapping chamber to introduce the liquid at the time of consuming the liquid; and an outlet, communicating at a vertical lower position of the bubble trapping chamber to discharge the liquid at the time of consuming the liquid.
According to an aspect of the invention, there is also provided a method of manufacturing a liquid container having a tank chamber, first and second communication holes communicating with the tank chamber, and a flow channel communicating with the first communication hole, the method including: welding a film to one surface of the liquid container in which openings communicating with the tank chamber and the flow channel, respectively, are formed; filing the tank chamber with a liquid from the second communication hole disposed in a vertical upper portion of the tank chamber; and delivering bubbles, which are gathered in the vertical upper portion of the tank chamber at a time of filling the tank chamber with the liquid, from the tank chamber to the flow channel through a bypass channel extending from an opening of the tank chamber to an opening of the flow channel through a non-welded portion of the film.
The present disclosure relates to the subject matter contained in Japanese patent application Nos. 2007-269355 filed on Oct. 16, 2007, 2008-75006 filed on Mar. 24, 2008 and 2008-75549 filed on Mar. 24, 2008, which are expressly incorporated herein by reference in its entirety.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
Hereinafter, exemplary embodiments of the invention will be described in detail. The following embodiments do not excessively limit the scope of the invention described in the appended claims and all elements described in the embodiments are not essential to the solving means of the invention.
Ink Cartridge
An ink cartridge (liquid container) to which a liquid detecting device according to an embodiment of the invention is attached will be described now with reference to the accompanying drawings.
An inkjet print head 12 is mounted on a side of the carriage 1 facing a printing sheet 6. An ink cartridge 100 supplying ink (water ink or oil ink) to the print head 12 is demountably mounted on a holder (not shown) disposed in the upper portion of the carriage 1.
A cap member 13 is disposed at a home position (in the right side in
In the vicinity of a printing area in the cap member 13, a wiping unit 11 having an elastic plate of rubber is disposed to reciprocate in the horizontal direction about the moving trace of the print head 12. The wiping unit 11 wipes out the nozzle formation surface of the print head 12 as needed when the carriage 1 reciprocates with respect to the cap member 13.
The ink cartridge 100 includes a film 104 covering the rear surface of the main case 102, a cover member 106 covering the film 104 and the bottom surface of the main case 102, and a film 108 covering the surface and the top surface of the main case 102.
The main case 102 is partitioned by ribs or walls complexly. The main case 102 includes an ink channel section having an ink containing area and an ink delivery channel, an ink-side passage allowing the ink containing area to communicate with the atmospheric air, and an atmospheric communication portion having an atmospheric air valve receiving chamber and an atmospheric air-side passage, detailed description of which are omitted (for example, see JP-A-2007-15408).
The ink delivery channel of the ink channel section finally communicates with an ink supply section 110 and the ink in the ink cartridge 100 is sucked up from the ink supply section 110 for supply by the negative pressure.
An ink supply needle (not shown) of the holder disposed in the carriage 1 is inserted into the ink supply section 110. The ink supply section 110 includes a supply valve 112 that is pressed by the ink supply needle and slides to open its valve, a sealing member 114 formed of an elastic material such as elastomer, which is fitted to the surrounding of the ink supply needle, and an urging member 116 formed of a coil spring to urge the sealing member 114 to the supply valve 112. Theses elements are assembled by fitting the urging member 116, inserting the sealing member 114 to the ink supply section 110, and finally pushing the supply valve 112.
A lever 120 engaging with the holder disposed in the carriage 1 is disposed on one side surface of the main case 102. An opening 130 opened at a position corresponding to the upstream of the ink supply section 110 and the end of the ink delivery channel is formed at a position on one side surface of the main case 102, for example, at a position below the lever 120. A welding rib 132 is formed in the circumferential edge of the opening 130. A partition rib 136 partitions the ink delivery channel 134 facing the opening 130 into an upstream buffer chamber 134a and a downstream buffer chamber 134b (the reference numerals are omitted in
Ink Detector
An ink detector 200 employing the liquid detector according to this embodiment, which is formed by the main case 102, the ink delivery channel 134, and the partition rib 136, will be described now with reference to
In
In
Upstream Channel Structure of Ink Detector
Before describing in detail the ink detector, the channel structure upstream of the ink delivery channel 134 in the ink detector will be described with reference to
The bubble trapping section 280 includes a bubble trapping chamber (tank chamber) 282 trapping the bubbles in the upper portion thereof with the lowering of the liquid level LH1 due to the decrease in the amount of remaining ink at the time of consuming the ink, an inlet 284 introducing the ink at a vertical upper position of the bubble trapping chamber 282 at the time of consuming the ink, and an outlet 286 discharging the ink at a vertical lower position of the bubble trapping chamber 282 at the time of consuming the ink.
In this embodiment, the bubble trapping chamber 282 employs the specific gravity separation method of separating the ink and the bubbles by the use of a difference in specific gravity between the ink and the bubbles. The specific gravity separation method is known in a system for continuously supplying a liquid. This embodiment employs a structure for not mixing the bubbles into the ink, particularly, even when the amount of remaining ink decreases.
The bubble trapping chamber 282 traps the bubbles in the upper portion thereof with the lowering of the liquid level LH1 due to the decrease in the amount of remaining liquid. The bubble trapping employs the specific gravity separation method without any change and is not different from that of the bubble trapping chamber used to endlessly supply the liquid.
In the course of trapping the bubbles when the amount of remaining ink decreases, the inlet 284 is located in the vertical upper portion of the bubble trapping chamber 282. Then, the bubbles initially generated from the inlet 284, but when the lower end of the bubble group does not reach the outlet 284, no meniscus is formed in the inlet 284, thereby stopping the generation of the bubbles. At the same time, the bubbles gathered in the upper portion are broken and merged to form a gas space, the liquid level of which is LH1. Then, in the bubble trapping chamber 282, the mixture of the bubbles into the liquid is prevented. When the outlet 286 of the bubble trapping chamber 282 is located at the vertical lower position, only the liquid not containing the bubbles is discharged and thus the bubbles are not mixed in the communication channel 290 and the delivery channel 134 of the ink detector 200 downstream therefrom. Accordingly, the false detection is prevented at the time of detecting the ink end by detecting the bubbles.
However, in the comparative example, particularly, when the amount of ink consumption per unit time is great, the ink in the bubble trapping chamber 500 is replaced with the bubbles and thus a lot of bubbles may remain in the upstream portion therefrom when the bubbles reach the ink detector 200. When time elapses in this state, the bubbles are finally broken and disappear, but the ink forming the bubbles may serve as the remaining ink and may enter the ink detector 200 at the time of consuming the ink, where the remaining ink may be detected later. In addition, the bubbles 506 in the bubble trapping chamber 500 are involved in the flow of ink and the bubbles are delivered to the delivery channel 134 of the ink detector 200 through the communication channel 510 downstream therefrom. Then, as described later, the bubbles enter the sensor cavity, thereby causing the false detection of the ink end.
Accordingly, in this embodiment shown in
In this embodiment, the bubble trapping chamber 282 may be connected directly to the delivery channel 134, but the communication channel 290 may be disposed downstream of the bubble trapping chamber 282. The communication channel 290 includes a supply hole 292 communicating with the outlet 286 of the bubble trapping chamber 282 at the time of consuming the ink and guides the ink introduced from the vertical lower position to the vertical upper portion. Then, the communication channel 290 introducing the ink from the outlet 294 located at the vertical upper position of the delivery channel 134 (upstream buffer chamber 134a) is further provided.
Accordingly, in the vicinity of the ink end after the ink in the bubble trapping chamber 282 is consumed, as shown in
In this embodiment, a liquid containing chamber (tank chamber) 260 disposed upstream of the bubble trapping chamber 282 to contain the ink is opened to the atmospheric air as described above. Then, the space above the meniscus formed in the bubble trapping chamber 282 can be filled with the atmospheric air instead of the consumed ink.
In this embodiment, a detour channel 270 bent in a labyrinth shape is disposed between the bubble trapping chamber 282 and the liquid containing chamber (tank chamber) 260. The detour channel 270 can also trap the bubbles.
In this embodiment, the ink cartridge may be disposed at the time of filling the ink container so that the bubble trapping chamber 282 has a posture vertically reverse to that at the time of consuming the ink. That is, at the time of filling the ink container, the bubble trapping chamber is vertically reverse and the ink is introduced from the outlet 286 located at the vertical upper position. Therefore, the bypass channel 288 opened at the time of filling the ink container to allow the bubble trapping chamber 282 to communicate with the detour channel 270 can be disposed vertically above the bubble trapping chamber 282 at the time of filling the ink container. The bypass channel 288 can deliver the bubbles gathered in the upper portion of the bubble trapping chamber 282 to the detour channel 270 at the time of filling the ink container. Accordingly, it is possible to prevent the bubbles from being mixed into the liquid in the bubble trapping chamber 282. Since the gathering of the bubbles in the bubble trapping chamber 282 can be prevented, the bubble trapping chamber 282 can be filled with the ink. Accordingly, it is possible to prevent the false detection of the ink end due to the mixture of the bubbles even when a lot of ink remains in the bubble trapping chamber 282 of the ink detector 200. The bypass channel 288 is closed at the time of consuming the ink.
Details of Ink Detector
Details of the ink detector 200 will be described now with reference to
As shown in
In
Specifically, as shown in
In the vibration cavity forming base 300, the cavity 222 having a cylindrical space shape for receiving the medium (ink) as the detection target is opened in the first surface 300a and the bottom surface 222a of the cavity 222 can be made to vibrate by the vibrating plate 224. In other words, the portion actually vibrating in the vibrating plate 224 is defined in outline by the cavity 222. Electrode terminals 228 and 228 are formed on both sides of the second surface 300b of the vibration cavity forming base 300.
A lower electrode 310 is formed on the second surface 300b of the vibration cavity forming base 300 and the lower electrode 310 is connected to one electrode terminal 228.
A piezoelectric layer 312 is stacked on the lower electrode 310 and an upper electrode 314 is stacked on the piezoelectric layer 312. The upper electrode 314 is connected to an assistant electrode 320 insulated from the lower electrode 310. The assistant electrode 320 is connected to the other electrode terminal 228.
The piezoelectric element 226 performs the function of determining the ink end on the basis of the difference in electrical characteristics (such as frequency) due to the existence of the ink in the sensor cavity 222. The piezoelectric layer may be formed of piezoelectric zirconate titanate (PZT), piezoelectric lead zirconate titanate (PLZT), or a lead-free piezoelectric film not containing lead.
The sensor chip 220 is fixed monolithically to the sensor base 210 by an adhesive layer 216 by placing the bottom of the chip body on the top center portion of the sensor base 210, and the space between the sensor base 210 and the sensor chip 220 are sealed by the adhesive layer 216.
Detection of Amount of Remaining Ink
As shown in
The upstream buffer chamber 134a communicates with the sensor cavity 222 of the sensor chip 220 through the first hole 212 of the sensor base 210. Accordingly, the ink in the upstream buffer chamber 134a is guided to the sensor cavity 222 through the first hole 212 with the supply of the ink. Here, the vibration of the vibrating plate 224 made to vibrate by the piezoelectric element 226 is transmitted to the ink and the existence of the ink is detected on the basis of the frequency of the residual vibration waveform. In the end point where air enters the sensor cavity 222 in addition to the ink, the attenuation of the residual vibration waveform is great and the residual vibration waveform becomes a frequency higher than that of the case where the ink is filled full. By detecting the state, the ink end can be detected.
Specifically, when a voltage is applied to the piezoelectric element 226, the vibrating plate 224 is deformed with the deformation of the piezoelectric element 226. When the application of the voltage is stopped after the piezoelectric element 226 is forcibly deformed, the bending vibration remains in the vibrating plate 224 for a moment. The residual vibration is free vibration of the vibrating plate 224 and the medium in the sensor cavity 222. Accordingly, by setting the voltage applied to the piezoelectric element 226 to a pulse waveform or a rectangular waveform, the resonance state of the vibrating plate 224 and the medium after the application of the voltage can be easily obtained.
The residual vibration is the vibration of the vibrating plate 224 and accompanies the deformation of the piezoelectric element 226. Accordingly, the piezoelectric element 226 generates a back electromotive force with the residual vibration.
As shown in
Since the resonance frequency can be specified by the use of the back electromotive force detected as described above, the existence of the ink in the ink cartridge 100 can be detected on the basis of the resonance frequency. The semiconductor memory stores identification information such as the kind of the ink cartridge 100, information on the color of the ink contained in the ink cartridge 100, and information on the amount of remaining ink.
The ink staying in the sensor cavity 222 is guided to the downstream buffer chamber 134b through the second hole 214 of the sensor base 210 with the additional supply of the ink. The ink is supplied along the ink delivery channel 134 through the ink outlet 135b, and is finally discharged from the ink cartridge 100 through the ink supply section 110 (see
Method and Structure for Supporting Sensor Base
When it is intended to fit the sensor base 210, the sensor chip 220, and the film 202 to the opening 130, the following two processes are required. That is, a first process of disposing the metal sensor base 210 mounted with the sensor chip 220 in the opening 130 of the main case 102 having the flow channel 134 formed therein to face the flow channel 134 and a second process of welding the film 202 to the rib 132 around the opening 130 to allow the sensor base 210 to be supported by the main case 102 with the film 202 interposed therebetween are necessary. With the first process and the second process, the sensor cavity 222 formed in the sensor chip 220 communicates with the upstream buffer chamber 134a through the first hole 212 formed in the sensor base 210 and communicates with the downstream buffer chamber 134b through the second hole 214 formed in the sensor base 210, thereby forming the detection path of the liquid as described above.
In this embodiment, in the first process before welding the film 202, the sensor base 210 is supported by only the partition wall 136 (supporting function using the partition wall). Before the film 202 is welded to the welding rib 132 around the opening 130, the sensor base 210 should be temporarily positioned at a predetermined position of the opening 130. After the sensor base 210 is supported by the film 202 in the second process, the sensor base 210 can come in contact with only the partition wall 136 in the depth direction of the opening 130 (upstream and downstream partitioning function using the partition wall). Since the sensor base 210 is supported by the film 202, the sensor base 210 does not always be in contact with the partition wall 136 but the upstream and downstream partitioning function of the partition wall 136 is always necessary.
Here, as shown in
In order to partition the ink delivery channel 134 into the upstream buffer chamber 134a and the downstream buffer chamber 134b, the partition wall 136 should come in contact with the sensor base 210 or the gap between the sensor base 210 and the partition wall 136 is small so as not to allow the bubbles to pass through the gap. In other words, the flow resistance of the gap should be greater than the flow resistance of the first hole 212, thereby not permitting the passage of the bubbles. This is the inherent function of the partition wall 136.
On the other hand, the partition wall 136 is contacted and supported by the sensor base 210 at the time of fitting the sensor base 210 (first process), thereby preventing the sensor base 210 from falling into the opening 130. That is, in the first process, the partition wall 136 has the function of temporarily supporting the sensor base 210.
After the film 202 is welded to the welding rib 132 around the opening 130 and the sensor base 210 and the sensor chip 220 are attached to the opening 130, the sensor base 210 comes in contact with only the partition wall 136, except for the sensor chip 220 and the film 202. That is, the sensor base 210 can come in contact with only the partition wall 136 in the depth direction of the opening 130.
Accordingly, it is possible to detect the residual vibration waveform by the use of the piezoelectric element 226. In this embodiment, the main case 102 of the ink detector 200 is a part of the main case of the ink cartridge 100 and has a great capacity. In general, the main case 102 is formed of a flexible resin material such as polypropylene and thus the absorption of vibration thereof increases with the increase in capacity.
Here, when the piezoelectric element 226 vibrates, the sensor base 210 mounted with the sensor chip 220 also vibrates in addition to the vibrating plate 224. When the contact area between the sensor base 210 and the main case 102 is great, the vibration of the sensor base 102 is absorbed by the main case 102. In this case, the amplitude of the residual vibration waveform is not enough to detect the residual vibration waveform by the use of the piezoelectric element 226.
In this embodiment, since the sensor base 210 is supported by only the film 202 and the partition wall 136, the vibration wave absorbed by the main case 102 is minimized and thus the amplitude enough to detect the residual vibration by the use of the piezoelectric element 226 is guaranteed.
Although this embodiment has been described in detail, it should be understood by those skilled in the art that the embodiment can be modified in various forms without departing from the idea and advantages of the invention. Therefore, the following modified examples should be included in the scope of the invention. For example, in the specification or drawings, a term described at least once along with another term having broader meaning or equivalent meaning can be replaced with the another term in any place of the specification or drawings.
As shown in
In order to enhance the stability of the attachment of the sensor base 210, the configuration shown in
In the embodiment shown in
However, regarding the assistant support rib 138, since the sensor base 210 is substantially parallel to the channel wall 102a after the sensor base 210 is assembled as shown in
After the sensor base 210 is assembled, the assistant support rib 138 can prevent the sensor base 210 from being excessively inclined even in the abnormal state where falling impact force acts. Accordingly, it is possible to prevent the sensor base 210 supported by the film 202 from being excessively inclined to tear down the film 202.
The position of the partition wall 136 is not limited to the channel wall 102a. For example, as shown in
Structure for Preventing False Detection
A structure for preventing the false detection due to the bubbles will be described now with reference to
Here, a slight gap D1 is formed between the inner wall of the opening 102A and four sides of the sensor base 210. By setting a margin in design to reduce the gap D1, the sensor base 210 is positioned in the opening 102A.
A problem of the structure shown in
Since the film 202 is formed of, for example, polypropylene (PP) and thus has the gas transmitting property, the bubbles grow in a great size by attracting the gas for a long time. The grown bubbles depart from the gap D1 due to the vibration of the piezoelectric element 226 (see
A structure for improving this problem is schematically shown in
At this time, as shown in
On the other hand, in the area other than four positioning portions 410, 411, 412, and 413, a gap D2 sufficiently greater than the gap D1 based on the design margin is formed between the wall portion of the opening 402 and four sides of the sensor base 210. The gap D2 forms a part of the flow channel 134 formed by the upstream buffer chamber 134a or the downstream buffer chamber 134b shown in
That is, at the time of injecting the ink, the ink is introduced into the sensor cavity 222 through the first hole 212 of the sensor base 210 as indicated by the solid line in
In this way, the gap D2 is filled with the ink and thus the bubbles do not remain. Accordingly, it is possible to prevent the false detection of the ink end.
When it is intended for the ink to easily flow in the gap D2, it is preferable that the inlet 135a of the upstream buffer chamber 134a is located at a position not opposed to the first hole 212 of the sensor base 210 and the outlet 135b of the downstream buffer chamber 134b is located at a position not opposed to the second hole 214 of the sensor base 210. Accordingly, as described above, since the wall exists in the traveling direction of the ink introduced or discharged, the ink is diffused and easily flows in the gap D2.
Here, two positioning portions 410 and 412 of four positioning portions exist in an extension line of the partition wall 136 (see
A more specific example of the example shown in
As shown in
As shown in
By setting the design margin on the gap D1 (omitted in
In the area other than four positioning portions 410, 411, 412, and 413, the gap D2 sufficiently greater than the gap based on the design margin is formed between the wall portion of the opening 402 and four sides of the sensor base 210. The gap D2 forms a part of the flow channel 134 formed by the upstream buffer chamber 134a and the downstream buffer chamber 134b partitioned by the partition wall 136.
As described above, the ink is filled in the main case 400 in a state where the main case is almost in vacuum. At this time, the gap D2 communicating with the upstream buffer chamber 134a or the downstream buffer chamber 134b can form the flow channel of the ink. Accordingly, when the ink is fully filled in the upstream buffer chamber 134a or the downstream buffer chamber 134b, the gap D2 is filled with the ink and thus bubbles do not remain in the gap D2. Accordingly, it is possible to prevent the false detection of the ink end.
Two opposed positioning portions 410 and 412 of four positioning portions exist in the extension line of the partition wall 136 (see
In the example shown in
In the example shown in
The ink introduced from the inlet 135a travels straightly and flows in the gap D2. Preferably, the ink is guided by the partitioning wall 134a1 to flow in the gap D2. Similarly, the ink discharged from the second hole 216 of the sensor base 210 is diffused by the downstream buffer chamber 134b to flow in the gap D2. Preferably, the ink is guided by the partition wall 134b1 to flow in the gap D2.
Details of Bypass Channel
The details of the bypass channel 288 for removing the bubbles described with reference to
In
Here,
At the time of filling the ink cartridge, the ink is introduced into the bubble trapping chamber 282 from the outlet 286 disposed in the vertical upper portion of the bubble trapping chamber 282. At this time, the ink is discharged to the detour channel 270 from the inlet 284 disposed in the vertical lower portion of the bubble trapping chamber 282. That is, at the time of filling the ink cartridge, the vertical position is reverse to that at the time of consuming (using) the ink, and the inlet 284 serves as the outlet and the outlet 286 serves as the inlet. That is, the functions are also reversed. Hereinafter, in order to avoid the confusion in title and function at the time of consuming (using) the ink and at the time of filling the ink cartridge, the inlet 284 and the outlet 286 are referred to as a first communication hole 284 and a second communication hole 286, respectively.
In the posture shown in
However, at the time of filling the ink cartridge when the positional relation is reversed and the inlet and the outlet are also reversed, the positional relation of the first and second communication holes 284 and 286 relative to the bubble trapping chamber 282 is not desirable. The second communication hole 286 shown in
Therefore, a bypass channel 288 for pulling out the bubbles is provided. The bypass channel 288 is similar to that of JP-A-2005-022257 and JP-A-2004-306466 in that a part of the film 104 is not welded, but is different from that of JP-A-2005-022257 and JP-A-2004-306466 in installation position and usage or object.
As shown in
The bypass channel 288 may be formed by one or more grooves depressed from the sealing surface 600 by a predetermined depth. When the grooves are not welded to the film 104, a gap is guaranteed between the bottom of the groove and the film 104.
Method of Manufacturing Liquid Container
A method of manufacturing the ink cartridge 100 (liquid container) including the case body having the structure shown in
Then, the posture at the time of consuming the ink (see
At the time of filling the ink cartridge, the bubbles gathered in the vertical upper portion of the bubble trapping chamber 282 is delivered from the bubble trapping chamber 282 to the detour channel 270 through the bypass channel 288 extending from the opening of the bubble trapping chamber 282 to the opening of the detour channel 270 through the non-welded portions of the film 104. The bubbles are discharged to the outside from an end opening opened to the atmospheric air. When the air is discharged from the opening downstream of the detour channel 270 for depressurization, the bubbles are forcibly discharged from the ink cartridge 100.
After finishing the ink filling process, the non-welded portions of the film 104 are welded to close the bypass channel 288. The bypass channel 288 is necessary only at the time of filling the ink cartridge, but not necessary at the time of consuming the ink.
The method of manufacturing the liquid container is not limited to the ink cartridge 100 shown in
Specific examples of the liquid consuming apparatuses may include an apparatus having a coloring material ejecting head used for manufacturing a color filter of a liquid crystal display and the like, an apparatus having an electrode material (conductive paste) ejecting head used for forming electrodes of an organic EL display, a field emission display (FED), and the like, an apparatus having a biological organic material ejecting head used for manufacturing a bio chip, an apparatus having a sample ejecting head as a precise pipette, and a printing apparatus or a micro dispenser.
The liquid container according to the embodiment of the invention is not limited to the on-carriage type ink cartridge, but may be a sub tank not mounted on the carriage or an off-carriage type ink cartridge.
In the above-mentioned embodiments, the case body of the liquid detector is also used as the case body of the liquid container and the sealing rubber or spring described in JP-A-2006-248201 is excluded, but the invention is not limited to the configuration. The liquid detector can be configured as a unit independent of the case body of the liquid container. In this case, the sealing rubber or spring may not be excluded, but it can contribute to suppressing the absorption of vibration in the unit case in minimum and guaranteeing the amplitude of the detected waveform greatly, even when the unit case increases in size.
In the above-mentioned embodiment, the liquid ejecting apparatus may be embodied in a so-called full-line type (line head type) printer in which the whole shape of the print head 19 corresponds to the length in the width direction (lateral direction) of a printing sheet (not shown) in the direction intersecting the transport direction (longitudinal direction) of the printing sheet (not shown).
In the above-mentioned embodiment, the liquid ejecting apparatus is embodied in the inkjet printer 11, but not limited to the inkjet printer. The invention may be embodied in a liquid ejecting apparatus spraying or ejecting a liquid (including a liquid material in which functional material particles are dispersed or mixed in a liquid and a fluid material such as gel) other than the ink. Examples thereof include a liquid material ejecting apparatus ejecting a liquid material including in a dispersed or dissolved type a material such as electrode material or coloring material (pixel material) used for manufacturing a liquid crystal display, an electroluminescence (EL) display, or a surface emission display, a liquid ejecting apparatus ejecting a biological organic material used for manufacturing a bio chip, and a liquid ejecting apparatus ejecting a liquid as a sample in a precise pipette. Examples thereof can also include a liquid ejecting apparatus ejecting lubricant to a precise machine such as a watch or camera with a pin point, a liquid ejecting apparatus ejecting transparent resin liquid such as UV-curable resin to a substrate to form minute semi-spherical lenses (optical lenses) used in optical communication devices, a liquid ejecting apparatus ejecting etchant such as acid or alkali to etch a substrate and the like, and a fluid material ejecting apparatus ejecting a fluid material such as gel (for example, physical gel). The invention can be applied to at least one kind of the above-mentioned liquid ejecting apparatuses. In this specification, the “liquid” does not include a liquid containing only gas, and examples of the liquid include a liquid material and a fluid material, in addition to inorganic solvent, organic solvent, solution, liquid-phase resin, and liquid-phase metal (metal solution).
The above-mentioned manufacturing method may be applied to a liquid container having a tank chamber containing a liquid, not the liquid container in which the bubble trapping chamber 282 is filled with the liquid. That is, the invention is not limited to trapping the bubbles at the time of consuming the liquid as described above. There may be a need for removing the bubbles staying at the time of filling the liquid container and filling the tank chamber with the liquid without trapping the bubbles.
In other words, in the method of manufacturing a liquid container according to the embodiment of the invention, the posture for use and the posture for filling may not be necessarily reverse. In some applications, there may be a need for a structure not requiring the consumption of liquid or for allowing the first and second communication holes 284 and 286 in the tank chamber to have the same positional relation as described above for the reason other than the bubble trapping. The detour channel 270 is not essential, but a flow channel connected to the first communication hole 284 may be used.
For example, there may be a liquid container as a kind of buffer in which a liquid always flows in one direction at the time of filling and consuming. In this case, since the bubbles should be removed from the tank chamber instead of the bubble trapping chamber 282, it is not necessary to close the bypass channel 288 after filling the liquid container.
Number | Date | Country | Kind |
---|---|---|---|
2007-269355 | Oct 2007 | JP | national |
2008-075006 | Mar 2008 | JP | national |
2008-075549 | Mar 2008 | JP | national |