JP5282841B2 - Liquid container - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid container and its manufacturing method capable of keeping a degassing effect by sucking the gas in a liquid containing chamber to a degassing chamber side by a pressure difference even after it is unsealed from a decompression package. <P>SOLUTION: The liquid container includes a case 10 in which at least one liquid containing chamber 370, 390, 430 communicated with the outer air is formed and includes an opening sealing film which seals an opening surface of the case 10. The liquid container is packaged in the decompression package until it is used by a consumer and opened upon usage. In the liquid container, sealed space which is disposed adjacent to the at least one liquid containing chamber 370, 390, 430, is not filled with liquid, and is not communicated with the outer air even after unsealing of the decompression package serves as decompression space, thus at least one degassing chamber 501 which sucks the gas in the at least one liquid containing chamber 370, 390, 430 by the pressure difference is provided. <P>COPYRIGHT: (C)2009,JPO&amp;INPIT

Description

The present invention relates to a liquid that is stored in the liquid storage chamber to the liquid container supplies the liquid consuming apparatus.

  As an example of the liquid container and the liquid consuming apparatus, for example, an ink cartridge storing ink liquid and an ink jet recording apparatus in which the ink cartridge is replaceably mounted can be cited.

  This ink cartridge is usually an ink storage chamber filled with ink in a case that is detachably mounted on a cartridge mounting portion of an ink jet recording apparatus, and ink stored in the ink storage chamber. An ink supply port for supplying to the apparatus. When the ink cartridge is mounted on the cartridge mounting portion of the recording apparatus, the ink supply needle mounted on the cartridge mounting portion is inserted and connected to the ink supply port, so that the stored ink can be supplied to the printer.

  By the way, with such an ink cartridge, bubbles may be generated in the stored ink due to temperature change during long-term storage, vibration during transportation, etc., and these bubbles are generated when the ink cartridge is mounted on the recording apparatus. In addition, the ink supply characteristics are deteriorated, resulting in a decrease in print quality.

  Therefore, the relatively small on-carriage type ink cartridge mounted on the carriage for scanning the print head, in particular, immediately reduces the pressure around the container in order to suppress the generation of bubbles inside the ink cartridge. It is known to provide a vacuum package that seals the space.

  Furthermore, in consideration of long-term storage, etc., in order to maintain the effect of decompression in the decompression package for a longer period, a recess is formed on the outer surface of the upper cover of the case having the ink containing chamber, In this case, a technique has been proposed in which a recess is used as a deaeration chamber that communicates with the inside of the decompression package and accumulates a negative pressure for deaeration (for example, see Patent Document 1).

  Alternatively, a spacer member for forming a space communicating with the outside air is stored from an opening of an ink storage chamber in which a porous member that sucks ink is disposed, and the spacer member has the same reduced pressure atmosphere as the reduced pressure package. A cartridge has been proposed (Patent Document 2).

  Here, the small on-carriage type ink cartridge has a rigid ink storage chamber with a resin case, and the ink storage chamber is opened to the atmosphere. In contrast, a large off-carriage type ink cartridge contains ink in an ink pack that can be deformed by pressure or suction. And the thing which ensured the decompression space formed with the gas-permeable material in this ink pack, and was able to deaerate the air dissolved in the ink is proposed (patent document 3).

  Note that the ink cartridge was used up to the preset threshold so that the stored ink was completely used up and the recording head of the recording apparatus was not emptied. Sometimes, there is an ink remaining amount sensor that outputs a predetermined electric signal (for example, Patent Document 4).

JP 2000-33709 A JP 2005-67076 A Japanese Patent Laid-Open No. 2005-169851 JP 2001-146019 A

  In each of the techniques disclosed in Patent Documents 1, 2, and 4, a part of the ink cartridge is used as a deaeration chamber by communicating a part of the ink cartridge with the decompression package.

  However, the function of the deaeration chamber is exhibited only while the ink cartridge is housed in the decompression package, and after the ink cartridge is removed from the decompression package, it does not function as the deaeration chamber.

  This is because the on-carriage type ink cartridge has an ink storage chamber open to the atmosphere, and the deaeration chamber released from the decompression package is also open to the atmosphere, so the deaeration chamber and the ink storage chamber have the same atmospheric pressure. Because it becomes. If it does so, the deaeration effect | action using the differential pressure | voltage between two rooms will not arise.

  The technique of Patent Document 3 is directed to an off-carriage type large-capacity container, and a deaeration chamber is directly arranged in a deformable ink pack in this type of container that is not packaged under reduced pressure. Therefore, it is difficult to apply the technique of Patent Document 4 to a small-capacity on-carriage type ink cartridge.

Therefore, an object of the present invention is particularly suitable for a small-capacity on-carriage type ink cartridge or the like, and after opening from the decompression package, the gas in the liquid storage chamber is sucked into the deaeration chamber side by the differential pressure. An object of the present invention is to provide a liquid storage container capable of continuing the deaeration effect.

One aspect of the present invention is a liquid storage container sealed in a decompression space, the liquid storage chamber, a deaeration chamber having a volume larger than the volume of the liquid storage chamber, the liquid storage chamber, and the deaeration chamber And a partition wall having a property of allowing gas to pass therethrough .

According to one aspect of the present invention, when the volume of the deaeration chamber is larger than the volume of the liquid storage chamber, the deaeration effect can be improved.

One aspect of the present invention further includes an air opening hole connected to the liquid storage container and a cavity for a liquid remaining amount sensor, and when the liquid in the liquid storage chamber is exhausted, the liquid is placed in the cavity. It is characterized in that the air introduced into the accommodation chamber enters.

According to one embodiment of the present invention, it is possible to prevent erroneous detection of the liquid remaining amount sensor due to remaining bubbles.

One embodiment of the present invention is characterized in that the deaeration chamber is adjacent to a first flow path for supplying liquid from the liquid storage chamber to the cavity.

According to one aspect of the present invention, bubbles in the liquid remaining amount sensor can be eliminated more reliably, and erroneous detection of the liquid remaining amount sensor due to remaining bubbles can be prevented.

One embodiment of the present invention further includes an air chamber, and the volume of the deaeration chamber is larger than the volume of the air chamber.

According to one aspect of the present invention, in a liquid container provided with an air chamber, the remaining amount of air increases by the volume of the chamber, so that the deaeration performance for preventing the generation of bubbles is further increased. However, since the volume of the deaeration chamber is set larger than that of the air chamber, the bubbles can be more reliably eliminated.

In one embodiment of the present invention, the deaeration chamber is provided adjacent to the liquid storage chamber and the air chamber.

According to one aspect of the present invention, since the liquid storage chamber, the air chamber, and the deaeration chamber are adjacent to each other, the deaeration efficiency can be increased, and thereby, the bubbles in the liquid remaining amount sensor can be more reliably removed. The liquid remaining amount sensor can be prevented from being erroneously detected due to the bubbles remaining.

In one mode of the present invention, it further includes a liquid supply port, and a second flow path that communicates the liquid supply port and the liquid supply chamber, and the deaeration chamber is adjacent to the second flow path. Features.

According to one aspect of the present invention, bubbles in the middle of the second flow path can be captured by the deaeration chamber.

In one aspect of the present invention , the trap further includes a trap channel formed by a vertical direction conversion unit that converts the liquid flow in the vertical direction and a horizontal direction conversion unit that converts the liquid flow in the horizontal direction. The flow path is formed with a space for collecting bubbles.

According to one aspect of the present invention, when the ink passes through the bubble trap channel, the bubbles are separated from the ink and captured in the space where the bubbles are collected.

FIG. 3 is an external perspective view of the ink cartridge according to the first embodiment. FIG. 2 is an external perspective view of the ink cartridge according to the first embodiment when viewed from an angle different from that in FIG. FIG. 3 is an exploded perspective view of the ink cartridge according to the first embodiment. FIG. 4 is an exploded perspective view of the ink cartridge according to the first embodiment viewed from an angle different from that in FIG. 3. FIG. 3 is a diagram illustrating a state where the ink cartridge according to the first embodiment is attached to the ink jet recording apparatus. FIG. 3 is a cross-sectional view illustrating a state immediately before the ink cartridge according to the first embodiment is attached to the carriage. FIG. 3 is a cross-sectional view illustrating a state immediately after the ink cartridge according to the first embodiment is attached to the carriage. FIG. 3 is a front view of the ink cartridge according to the first embodiment. FIG. 3 is a rear view of the ink cartridge according to the first embodiment. (A) is the simplified schematic diagram of FIG. 8, (b) is the simplified schematic diagram of FIG. AA sectional drawing of FIG. The conceptual diagram of the flow-path structure shown in FIG. The front view of the ink cartridge of 2nd Embodiment. The front view of the ink cartridge of 3rd Embodiment. The rear view of the ink cartridge shown in FIG. The front view of the ink cartridge of 4th Embodiment. It is a top view of the bubble trap flow path shown in FIG. It is sectional drawing which follows the BB line of FIG. FIG. 10 is a schematic perspective view of a part of an ink cartridge according to a fifth embodiment. FIG. 20 is a partial cross-sectional view of the ink cartridge shown in FIG. 19. FIG. 21 is a cross-sectional view of a deaeration chamber that is further different from those of FIGS. 19 and 20.

  Next, an embodiment of the present invention will be described. The present embodiment described below does not unduly limit the contents of the present invention described in the claims, and all the configurations described in the present embodiment are indispensable as means for solving the present invention. Not always.

(First embodiment)
In the following embodiments, as an example of the liquid container, an ink cartridge mounted on an ink jet recording apparatus (printer) that is an example of a liquid ejecting apparatus will be described.

(Outline of ink cartridge)
FIG. 1 is an external perspective view of an ink cartridge as a first embodiment of a liquid container according to the present invention. FIG. 2 is an external perspective view of the ink cartridge according to the present embodiment as viewed from the opposite angle to FIG. It is. FIG. 3 is an exploded perspective view of the ink cartridge of the present embodiment, and FIG. 4 is an exploded perspective view of the ink cartridge of the present embodiment as viewed from the opposite angle to FIG. FIG. 5 is a view showing a state in which the ink cartridge of the present embodiment is attached to the carriage, FIG. 6 is a cross-sectional view showing a state immediately before attachment to the carriage, and FIG. 7 is a cross-sectional view showing a state immediately after attachment to the carriage. It is.

  As shown in FIGS. 1 and 2, the ink cartridge 1 according to the present embodiment is a liquid storage container that has a substantially rectangular parallelepiped shape and stores and stores ink in an ink storage chamber provided therein. The ink cartridge 1 is mounted on a carriage 200 of an ink jet recording apparatus as an example of a liquid consuming apparatus, and supplies ink to the ink jet recording apparatus (see FIG. 5).

  The appearance characteristics of the ink cartridge 1 will be described. As shown in FIGS. 1 and 2, the ink cartridge 1 has a flat upper surface 1a and is connected to an ink jet recording apparatus on a bottom surface 1b facing the upper surface 1a. An ink supply port 50 for supplying ink is provided. In addition, an air opening hole 100 (see FIG. 4) for introducing air into the ink cartridge 1 is opened on the bottom surface 1b. In other words, the ink cartridge 1 is an air release type ink cartridge that introduces air from the air release hole 100 while supplying ink from the ink supply port 50.

  In the present embodiment, as shown in FIG. 6, the air opening hole 100 includes a substantially cylindrical concave portion 101 opened on the bottom surface 1 b from the bottom surface side to the top surface side, and a small hole 102 opened on the inner peripheral surface of the concave portion 101. And have. The small hole 102 communicates with an air release channel which will be described later, and the air is introduced into the most upstream ink storage chamber 370 described later through the small hole 102.

  The concave portion 101 of the air opening hole 100 is configured to have a depth so as to receive the protrusion 230 formed on the carriage 200. The protrusion 230 is a forgetting to peel-off protrusion for preventing forgetting to peel off the sealing film 90 as a closing means for closing the air opening hole 100 in an airtight manner. That is, since the protrusion 230 is not inserted into the atmosphere opening hole 100 in a state where the sealing film 90 is attached, the ink cartridge 1 cannot be attached to the carriage 200. This prevents the user from attaching the ink cartridge 1 to the carriage 200 while the sealing film 90 is stuck on the air opening hole 100, and ensures that the sealing film 90 is attached when the ink cartridge 1 is attached. Can be prompted to remove.

  Further, as shown in FIG. 1, an erroneous insertion prevention protrusion for preventing the ink cartridge 1 from being mounted at an incorrect position on the narrow side surface 1 c adjacent to one short side of the upper surface 1 a of the ink cartridge 1. 22 is formed. As shown in FIG. 5, a concave and convex portion 220 corresponding to the erroneous insertion preventing projection 22 is formed on the carriage 200 side serving as a receiver, and the ink cartridge 1 is used only when the erroneous insertion preventing projection 22 and the concave and convex portion 220 do not interfere with each other. Mounted on the carriage 200. The erroneous insertion prevention protrusion 22 has a different shape for each type of ink, and the unevenness 220 on the carriage 200 side serving as a receiver also has a shape corresponding to the corresponding ink type. Therefore, as shown in FIG. 5, even when the carriage 200 can mount a plurality of ink cartridges, the ink cartridge is not mounted at an incorrect position.

  Further, as shown in FIG. 2, an engagement lever 11 is provided on the narrow side surface 1 d that faces the narrow side surface 1 c of the ink cartridge 1. The engaging lever 11 is formed with a protrusion 11a that engages with a recess 210 (see FIG. 5) formed in the carriage 200 when mounted on the carriage 200. The protrusion 11a and the recess 210 are bent while the engaging lever 11 is bent. Is engaged and the ink cartridge 1 is positioned and fixed with respect to the carriage 200.

  A circuit board 34 is provided below the engagement lever 11. A plurality of electrode terminals 34 a are formed on the circuit board 34, and when these electrode terminals 34 a come into contact with electrode members (not shown) provided on the carriage 200, the ink cartridge 1 is electrically inkjet. Connected to a recording device. The circuit board 34 is provided with a data rewritable nonvolatile memory (not shown), and stores various information related to the ink cartridge 1, ink use information of the ink jet recording apparatus, and the like. Further, a liquid remaining amount sensor (sensor unit) 31 (refer to FIG. 3 or FIG. 4) for detecting the ink remaining amount in the ink cartridge 1 using residual vibration is provided on the back side of the circuit board 34. ing. In the following description, the liquid remaining amount sensor 31 and the circuit board 34 are collectively referred to as an ink end sensor 30.

  As shown in FIG. 1, a label 60a indicating the contents of the ink cartridge is attached to the upper surface 1a of the ink cartridge 1. The label 60a is formed by sticking the end portion of the outer surface film 60 covering the wide side surface 1f to the upper surface 1a.

  As shown in FIGS. 1 and 2, the wide side surfaces 1 e and 1 f adjacent to the two long sides of the upper surface 1 a of the ink cartridge 1 have a flat surface shape. In the following description, for the sake of convenience, the wide side 1e side will be described as the front side, the wide side 1f side as the back side, the narrow side 1c side as the right side, and the narrow side 1d side as the left side.

  Next, each part constituting the ink cartridge 1 will be described with reference to FIGS. 3 and 4.

  The ink cartridge 1 includes a case 10 and a lid member 20 that covers the front side of the case 10.

  Ribs 10 a having various shapes are formed on the front side of the case 10. These ribs 10a serve as partition walls, and a plurality of ink storage chambers (liquid storage chambers) filled with ink, a deaeration chamber that is not filled with ink and serves as a decompression space, and an air release channel 150 described later. An air chamber or the like located in the middle of the case 10 is partitioned in the case 10.

  An opening sealing film 80 that covers the front side of the case 10 is provided between the case 10 and the lid member 20, and the upper surfaces of the ribs, recesses, and grooves are closed by the opening sealing film 80. Flow paths, ink storage chambers, deaeration chambers, and air chambers are formed.

  Further, on the back side of the case 10, a differential pressure valve housing chamber 40 a serving as a recess for housing the differential pressure valve 40 and a gas-liquid separation chamber 70 a serving as a recess constituting the gas-liquid separation filter 70 are formed.

  A valve member 41, a spring 42, and a spring seat 43 are housed in the differential pressure valve housing chamber 40a to constitute the differential pressure valve 40. The differential pressure valve 40 is disposed between the ink supply port 50 on the downstream side and the ink storage chamber on the upstream side, and the ink supplied to the ink supply port 50 by decompressing the downstream side with respect to the upstream side. Is configured to be a negative pressure.

  A gas-liquid separation film 71 is attached to the upper surface of the gas-liquid separation chamber 70a along a peripheral wall 70b surrounding the outer periphery provided in the vicinity of the center of the gas-liquid separation chamber 70a. The gas-liquid separation membrane 71 is a material that allows gas to pass through and blocks liquid from passing through, and constitutes a gas-liquid separation filter 70 as a whole. The gas-liquid separation filter 70 is provided in an air release channel 150 (see FIG. 10B) connecting the air release hole 100 and the ink storage chamber, and the ink in the ink storage chamber passes through the air release channel 150. This is to prevent backflow and outflow from the air opening hole 100.

  In addition to the differential pressure valve storage chamber 40a and the gas-liquid separation chamber 70a, a plurality of grooves 10b are carved on the back side of the case 10. These grooves 10b are covered with the outer surface film 60 in the state in which the differential pressure valve 40 and the gas-liquid separation filter 70 are configured, so that the openings of the grooves 10b are closed, and the air release channels 150 and the inks are formed. A flow path is formed.

  On the right side surface of the case 10, as shown in FIG. 4, a sensor chamber 30 a is formed as a recess that houses each member constituting the ink end sensor 30. The sensor chamber 30a accommodates a remaining liquid sensor 31 and a compression spring 32 that presses and fixes the remaining liquid sensor 31 against the inner wall surface of the sensor chamber 30a. The opening of the sensor chamber 30 a is covered with a cover member 33, and the circuit board 34 is fixed on the outer surface 33 a of the cover member 33. The sensing member of the remaining liquid sensor 31 is connected to the circuit board 34.

  The liquid remaining amount sensor 31 includes a cavity that forms a part of an ink flow path between the ink storage chamber and the ink supply port 50, a diaphragm that forms a part of the wall surface of the cavity, and a vibration plate on the diaphragm. A piezoelectric element (piezoelectric actuator) for applying vibration is provided, and the presence or absence of ink in the ink flow path is detected from residual vibration when vibration is applied to the diaphragm. The remaining liquid sensor 31 detects the presence or absence of ink in the case 10 by detecting differences in residual vibration (free vibration) characteristics such as amplitude and frequency between ink and gas.

  Specifically, when the ink in the ink storage chamber in the case 10 is exhausted and the air introduced into the ink storage chamber enters the cavity of the liquid remaining amount sensor 31 through the ink flow path, the residual at that time This is detected from vibration (free vibration) characteristics, such as changes in amplitude and frequency, and an electrical signal indicating the ink end is output.

  On the bottom side of the case 10, in addition to the ink supply port 50 and the air opening hole 100 described above, as shown in FIG. 4, air is sucked out from the inside of the ink cartridge 1 through the evacuation means when ink is injected. A decompression hole 110 for decompressing the interior, a recess 95 a constituting an ink flow path from the ink storage chamber to the ink supply port 50, and a buffer chamber 30 b provided below the ink end sensor 30 are formed.

  The ink supply port 50, the air opening hole 100, the decompression hole 110, the concave portion 95a, and the buffer chamber 30b are all opened by the sealing films 35, 54, 90, 98, and 95 immediately after the ink cartridge is manufactured. It is in a sealed state. Among these, the sealing film 90 that seals the air opening hole 100 is peeled off by the user before the ink cartridge is mounted on the ink jet recording apparatus and put into use. As a result, the atmosphere opening hole 100 is exposed to the outside, and the ink storage chamber inside the ink cartridge 1 communicates with the outside air via the atmosphere opening flow path 150.

  Further, as shown in FIGS. 6 and 7, the sealing film 35 attached to the outer surface of the ink supply port 50 is broken by the ink supply needle 240 on the ink jet recording apparatus side when mounted on the ink jet recording apparatus. It is configured to be.

  As shown in FIGS. 6 and 7, inside the ink supply port 50, an annular seal member 51 that is pressed against the outer surface of the ink supply needle 240 when attached, and a seal member 51 when not attached to the printer. And a spring seat 52 that closes the ink supply port 50, and a compression spring 53 that urges the spring seat 52 in the contact direction of the seal member 51.

  6 and 7, when the ink supply needle 240 is inserted into the ink supply port 50, the inner periphery of the seal member 51 and the outer periphery of the ink supply needle 240 are sealed, and the ink supply port 50 and the ink supply are sealed. The gap between the needle 240 is sealed in a liquid-tight manner. Further, the tip of the ink supply needle 51 abuts on the spring seat 52, pushes the spring seat 52 upward, and the seal between the spring seat 52 and the seal member 51 is released, so that the ink supply port 50 moves to the ink supply needle 240. Ink can be supplied.

  Next, the internal structure of the ink cartridge 1 of the present embodiment will be described with reference to FIGS.

  8 is a view of the case 10 of the ink cartridge 1 of the present embodiment as viewed from the front side, and FIG. 9 is a view of the case 10 of the ink cartridge 1 of the present embodiment as viewed from the back side. 8A is a simplified schematic diagram of FIG. 8, FIG. 10B is a simplified schematic diagram of FIG. 9, and FIG. 11 is a cross-sectional view taken along line AA of FIG. FIG. 12 is a conceptual diagram of the flow channel structure formed in the case 10.

  In the ink cartridge 1 of the present embodiment, an upper ink storage chamber 370, a lower ink storage chamber 390, and a buffer chamber 430, which are divided into two upper and lower parts, serve as main ink storage chambers filled with ink. It is formed on the front side. In addition, an air release channel 150 (see FIG. 10B) that introduces the atmosphere into the upper ink storage chamber 370 that is the most upstream ink storage chamber according to the amount of ink consumed is provided on the back side of the case 10. Is formed.

  The ink storage chambers 370 and 390 and the buffer chamber 430 are divided by the rib 10a. The ink storage chambers 370 and 390 and the buffer chamber 430 communicate with ink flow paths 380 and 420 formed on the back side of the case 10 through through holes that penetrate the case 10 in the thickness direction. The ink can move between the ink storage chambers via the ink flow paths 380 and 420.

  Hereinafter, an ink flow path from the upper ink storage chamber 370, which is the main ink storage chamber, to the ink supply port 50 will be described with reference to FIGS.

  The upper ink storage chamber 370 is the most upstream ink storage chamber in the case 10 and is formed on the front side of the case 10 as shown in FIG. The upper ink storage chamber 370 is an ink storage area that occupies about half of the ink storage chamber, and is formed in a portion above approximately half of the case 10. A through-hole 371 communicating with the ink flow path 380 is opened below the upper ink storage chamber 370. The through hole 371 is formed in the vicinity of the position closest to the bottom surface side of the rib 10a forming the upper ink storage chamber 370. Even if the amount of ink in the upper ink storage chamber 370 decreases, it is lower than the liquid level. It is comprised so that it may be located in.

  As shown in FIG. 9, the ink flow path 380 is formed on the back side of the case 10 and configured to guide the ink from above to the lower ink storage chamber 390 below.

  The lower ink storage chamber 390 is an ink storage chamber into which the ink stored in the upper ink storage chamber 370 is introduced. As shown in FIG. 8, about half of the ink storage chamber formed on the front side of the case 10 is formed. This is an ink storage area that occupies, and is formed in a lower part from approximately half of the case 10. A through-hole 391 communicating with the ink flow path 380 is opened below the lower ink storage chamber 390. The through hole 391 is formed in the vicinity of the position closest to the bottom surface side of the rib 10 a forming the lower ink storage chamber 390.

  The lower ink storage chamber 390 communicates with the upstream ink end sensor communication channel 400 through a through hole (not shown). The upstream side ink end sensor communication channel 400 is formed with a three-dimensional maze channel, which captures bubbles and the like flowing before the ink end and flows downstream. Is configured to not. The details of the upstream ink end sensor communication channel 400 will be described in another embodiment.

  The upstream ink end sensor communication channel 400 communicates with the downstream ink end sensor communication channel 410 through a through hole (not shown), and the ink remains in the liquid state via the downstream ink end sensor communication channel 410. It is guided to the quantity sensor 31.

  The ink guided to the remaining liquid sensor 31 passes through a cavity (flow path) in the remaining liquid sensor 31 and is guided to an ink flow path 420 formed on the back side of the case 10. The ink flow path 420 is formed so as to guide the ink obliquely upward from the liquid remaining amount sensor 31 and is connected to a through hole 431 communicating with the buffer chamber 430. As a result, the ink that has left the liquid remaining amount sensor 31 is guided to the buffer chamber 430 through the ink flow path 420.

  The buffer chamber 430 is a small chamber defined by the rib 10 a between the upper ink storage chamber 370 and the lower ink storage chamber 390, and is formed as an ink storage space immediately before the differential pressure valve 40. The buffer chamber 430 is formed to face the back side of the differential pressure valve 40, and ink flows into the differential pressure valve 40 through the through hole 432.

  The ink that has flowed into the differential pressure valve 40 is guided to the downstream side by the differential pressure valve 40 and is guided to the outlet channel 450 through the through hole 451. The outlet channel 450 communicates with the ink supply port 50, and ink is supplied to the ink jet recording apparatus side via the ink supply needle 240 inserted into the ink supply port 50.

  Next, the atmosphere opening flow path 150 from the atmosphere opening hole 100 to the upper ink storage chamber 370 will be described with reference to FIGS.

  When the ink in the ink cartridge 1 is consumed and the pressure in the ink cartridge 1 decreases, the atmosphere (air) flows from the atmosphere opening hole 100 into the upper ink storage chamber 370 by the amount of the stored ink.

  A small hole 102 provided in the atmosphere opening hole 100 communicates with one end of a serpentine 310 formed on the back side of the case 10 (see FIG. 10). The serpentine path 310 is a meandering path formed so as to increase the distance from the atmosphere opening hole 100 to the upper ink storage chamber 370 and suppress the evaporation of moisture in the ink. The other end of the serpentine 310 is connected to the gas-liquid separation filter 70.

  A through-hole 322 is formed in the bottom surface of the gas-liquid separation chamber 70a constituting the gas-liquid separation filter 70, and communicates with a space 320 formed on the front side of the case 10 through the through-hole 322 ( (See FIG. 9). In the gas-liquid separation filter 70, a gas-liquid separation film 71 (see FIG. 4) is disposed between the through hole 322 and the other end of the serpentine 310. The gas-liquid separation membrane 71 is formed by knitting a fiber material having high water and oil repellency into a mesh shape.

  As shown in FIG. 8, the space 320 is formed on the upper right side of the upper ink chamber as viewed from the front side of the case 10. In the space 320, a through hole 321 opens above the through hole 322. The space 320 communicates with an upper connection channel 330 (see FIG. 9) formed on the back side through the through hole 321.

  As shown in FIGS. 9 and 10 (a), the upper connecting flow path 330 passes through the uppermost side of the ink cartridge 1, that is, the uppermost portion in the direction of gravity in a state where the ink cartridge 1 is attached. Further, when viewed from the back side, the flow path portion 333 extending rightward from the through hole 321 along the long side and the folded portion 335 near the short side are folded back and pass through the upper surface side of the ink cartridge 1 from the flow path portion 333. And a flow path portion 337 extending to the through hole 341 formed in the vicinity of the through hole 321. The through hole 341 communicates with an ink trap chamber 340 formed on the front side.

  Here, when the upper connecting flow path 330 is viewed from the back side, the flow path portion 337 extending from the folded portion 335 to the through hole 341 has a position 336 where the through hole 341 is formed, and the cartridge thickness direction from the position 336. A concave portion 332 that is deeply dug in position is provided, and a plurality of ribs 331 are formed so as to delimit the concave portion 332. Further, the flow path portion 333 extending from the through hole 321 to the folded portion 335 is formed to be shallower than the flow path portion 337 extending from the folded portion 335 to the through hole 341.

  In the present embodiment, since the upper connection channel 330 is formed at the uppermost portion in the direction of gravity, basically, the ink does not move to the atmosphere opening hole 100 side beyond the upper connection channel 330. It is configured. In addition, the upper connecting flow path 330 has a width that is wide enough to prevent backflow of ink due to capillarity or the like, and the flow path portion 337 has a recess 332 so that the backflowed ink is captured. It is structured easily.

  The ink trap chamber 340 shown in FIGS. 8 and 10A is a rectangular parallelepiped space formed at the upper right corner of the case 10 when viewed from the front side. As shown in FIG. 10A, the through-hole 341 opens in the vicinity of the upper left rear corner of the ink trap chamber 340. Further, a notch portion 342 in which a part of the rib 10a serving as a partition is notched is formed at the right lower front corner of the ink trap chamber 340, and the communication buffer chamber is formed through the notch portion 342. 350 is communicated. Here, the ink trap chamber 340 and the communication buffer chamber 350 are air chambers in which the volume in the middle of the air release flow path 150 is expanded, and even if the ink flows backward from the upper ink storage chamber 370 for some reason, this ink trap. The ink is retained in the chamber 340 and the communication buffer chamber 350 so that no more ink flows into the atmosphere opening hole 100 side.

  As shown in FIGS. 8 and 10A, the communication buffer chamber 350 is a space formed below the ink trap chamber 340. The bottom surface 352 of the connection buffer chamber 350 is provided with a decompression hole 110 for releasing air when ink is injected. In addition, a through hole 351 is opened on the thickness direction side in the vicinity of the bottom surface 352 and at the lowest position in the gravitational direction when the ink jet recording apparatus is mounted, and is formed on the back side through the through hole 351. The communication channel 360 communicates.

  The communication flow path 360 shown in FIG. 10A extends to the center upper side as viewed from the back side, and communicates with the upper ink storage chamber 370 through a through hole 372 opened near the bottom surface of the upper ink storage chamber 370. doing. That is, the atmosphere opening channel 100 to the communication channel 360 constitute the atmosphere opening channel 150 of the present embodiment.

(Deaeration room)
In the case of the ink cartridge 1 of the present embodiment, as shown in FIG. 8, the ink storage chambers (upper ink storage chambers 370 and 390, the buffer chamber 430) and the air chamber are disposed on the front side of the case 10. (Ink trap chamber 340, communication buffer chamber 350) and ink flow path (upstream ink end sensor communication flow path 400, downstream ink end sensor communication flow path 410) A deaeration chamber 501 is defined.

  As shown in FIG. 8, the deaeration chamber 501 is a hatched area near the left side on the front side of the case 10, and is adjacent to the upper ink storage chamber 370, the lower ink storage chamber 390, and the buffer chamber 430. Yes. The deaeration chamber 501 and the upper ink storage chamber 370 are partitioned by a partition wall 10a1, the deaeration chamber 501 and the lower ink storage chamber 390 are partitioned by a partition wall 10a2, and the deaeration chamber 501 and the buffer chamber 430 are partitioned by a partition wall. It is partitioned by 10a3.

  The deaeration chamber 501 is sealed with an opening sealing film 80 in a state where the case 10 is placed in a reduced-pressure atmosphere, thereby forming a sealed space that does not communicate with the outside air and a reduced-pressure space.

  In the ink cartridge 1 described above, even if a minute bubble remains in the cavity of the liquid remaining amount sensor 31 in the ink filling process in a factory or the like, the ink cartridge 1 is then packaged in a reduced pressure package and then the ink is filled. Bubbles in the cavity of the liquid remaining amount sensor 31 are dissolved in the liquid and disappear by the action of the degassing negative pressure for degassing the inside of the cartridge 1.

  Further, the negative pressure for deaeration during decompression package packaging is accumulated in the deaeration chamber 501 of the case 10, and the deaeration chamber 501 is used as a decompression space between the time after the decompression package packaging and the opening, Even after opening, it contributes to dissolution and disappearance of bubbles in the case 10.

  That is, since the negative pressure for deaeration during decompression package packaging is accumulated in the deaeration chamber 501 of the case 10, the upper ink storage chamber 370, the lower ink storage chamber 390 and the buffer chamber 430, which are atmospheric pressure, are stored. The pressure in the deaeration chamber 501 adjacent through the partition walls 10a1, 10a2, 10a3 is low. Due to this differential pressure, the gas in the upper ink storage chamber 370, the lower ink storage chamber 390, and the buffer chamber 430 passes through the partition walls 10a1, 10a2, 10a3 of the case 10 made of, for example, a polyolefin-based material having gas permeability. It passes through and is sucked to the deaeration chamber 501 side having a differential pressure. This deaeration action is performed as long as the inside of the deaeration chamber 501 is depressurized, that is, in the state after opening, in addition to the time after the decompression package packaging until the opening. This is because the deaeration chamber 501 is a sealed space after being sealed with the opening sealing film 80 and can maintain a reduced pressure atmosphere. The outer wall ribs 10a excluding the partition walls 10a1, 10a2, and 10a3 that form the three sides of the deaeration chamber 501 also have gas permeability. For this reason, it is considered that the degree of decompression of the deaeration chamber 501 gradually decreases after opening. However, if the deaeration chamber 501 is communicated with the outside air and compared with the one that ensures the deaeration action only when packaging the decompression package. The deaeration action can be continued for a longer time, and the deaeration action can be exhibited even when the ink cartridge 1 is used.

  Accordingly, it is possible to provide the ink cartridge 1 that can eliminate the bubbles in the remaining liquid sensor 31 more reliably and prevent erroneous detection of the remaining liquid sensor 31 due to remaining bubbles.

  In this embodiment, the formation of the deaeration chamber 501 can be realized only by molding the case 10 and sealing the case 10 with the opening sealing film 80. That is, as compared with the conventional case, the operation of sealing the case 10 with the opening sealing film 80 only needs to be performed in a reduced-pressure atmosphere.

  In addition, the installation position of the deaeration chamber which concerns on this invention, the volume of the deaeration chamber, and the number of installations are not restricted to the said embodiment. For example, various ink car cartridges having the same outer size as the ink cartridge 1 described in the first embodiment and only the ink capacity are changed, and the ink capacity is adjusted by changing the volume or number of deaeration chambers. It can also be created. In the following embodiment, the volume and number of deaeration chambers are changed.

(Second Embodiment)
FIG. 13 is a front view of a case 10 </ b> A of an ink cartridge that is a second embodiment of a liquid container having a deaeration chamber according to the present invention.

  In the case 10A of the second embodiment, the areas of the upper ink storage chamber 370 and the lower ink storage chamber 390 in the case 10 of the first embodiment are narrowed, and these ink storage chambers 370, 390 and the right side of the container are arranged. Two deaeration chambers 511 and 512 are newly added between the air chambers (ink trap chamber 340 and communication buffer chamber 350) equipped on the surface side.

  In the case of the case 10A of the second embodiment, the configuration other than the addition of the deaeration chambers 511 and 512 is the same as the case 10 of the first embodiment, and the common configuration is the first. The same reference numerals as those in the embodiment are given, and the description is omitted.

  The two deaeration chambers 511 and 512 are provided side by side. The upper deaeration chamber 511 is equipped so as to be sandwiched between the upper ink storage chamber 370 and the ink trap chamber 340 by shortening the area of the upper ink storage chamber 370. A wall portion between the deaeration chamber 511 and the upper ink chamber 370, which is an object to be mainly deaerated, is referred to as a partition wall 10a4.

  Further, the lower deaeration chamber 512 is equipped so as to be sandwiched between the lower ink storage chamber 390 and the communication buffer chamber 350 by shortening the lower ink storage chamber 390. A wall portion between the deaeration chamber 512 and the lower ink chamber 390, which is an object to be mainly deaerated, is referred to as a partition wall 10a5. The gas in the upper ink storage chamber 370, the lower ink storage chamber 390, and the buffer chamber 430 is taken into the degassing chambers 511 and 512 through the partition walls 10a4 and 10a5.

  The above two deaeration chambers 511 and 512 are not filled with ink as in the case of the deaeration chamber 501 of the first embodiment, and are added between the time after the ink cartridge is decompressed and packaged. Even after opening, the deaeration action is possible as a deaeration chamber in which the negative pressure for deaeration is accumulated.

  In the case of the present embodiment, by adding the deaeration chambers 511 and 512, the deaeration chambers are provided in a distributed manner at a plurality of locations in the case 10A. As a result, since the upper ink storage chamber 370 is adjacent to the two degassing chambers 501 and 511 and the lower ink storage chamber 390 is also adjacent to the two degassing chambers 501 and 512, the degassing efficiency is improved.

  Further, the added deaeration chambers 511 and 512 are provided so as to be adjacent to the ink storage chambers 370 and 390 and the chambers 340 and 350 which are air chambers. The total volume of the deaeration chambers 501, 511, and 512 is set to be larger than the sum of the volumes of the ink trap chamber 340 and the communication buffer chamber 350 that are air chambers.

  In the ink cartridge of the second embodiment described above, the depressurization action due to the degassing negative pressure accumulated in the deaeration chambers 501, 511, 512 is exhibited at a plurality of locations in the case 10A. In the wider range on the case 10, the pressure reducing action effective for the disappearance of the bubbles can be ensured more evenly. Further, the pressure reducing action works from more than one direction at the locations where the bubbles are generated. The bubbles can be eliminated more efficiently than the ink cartridge of the embodiment.

  In addition, in an ink cartridge having an air chamber such as the ink trap chamber 340 and the communication buffer chamber 350, the remaining amount of air in the case is increased by the volume of these chambers 340 and 350, so that generation of bubbles is prevented. However, since the sum of the volumes of the deaeration chambers 501, 511, and 512 is set larger than that of the ink trap chamber 340 and the communication buffer chamber 350, which are air chambers, a high deaeration performance is required. The air performance can be easily maintained, and the air bubbles in the liquid remaining amount sensor 31 can be more reliably eliminated by ensuring sufficient deaeration performance.

  Further, in the ink cartridge of the present embodiment, the ink storage chambers 370 and 390, the ink trap chamber 340 and the communication buffer chamber 350 which are air chambers, and the deaeration chambers 511 and 512 are adjacent to each other over a wide area through the partition walls. Therefore, the deaeration efficiency in the case 10A can be increased, and thereby the bubbles in the liquid remaining amount sensor 31 can be more reliably eliminated, and the liquid remaining amount sensor caused by the remaining bubbles. 31 erroneous detection can be prevented.

(Third embodiment)
FIG. 14 is a front view of a case 10B of an ink cartridge as a third embodiment of a liquid container having a deaeration chamber according to the present invention, and FIG. 15 is a rear view thereof.

  In the case 10B of the third embodiment, the area of the lower ink storage chamber 390 in the case 10A of the second embodiment is further narrowed, and a new space is formed between the buffer chamber 430 and the lower ink storage chamber 390. A deaeration chamber 521 is added. A wall portion where the deaeration chamber 521 is partitioned from the lower ink storage chamber 390 is referred to as a partition wall 10a6, and a wall portion where the deaeration chamber 521 is partitioned from the buffer chamber 430 is referred to as a partition wall 10a7. The gas in the ink storage chamber 390 and the buffer chamber 430 is taken into the deaeration chamber 521 through the partition walls 10a6 and 10a7.

  In the case of the case 10B of the third embodiment, the configuration other than the addition of the deaeration chamber 521 is common to the case 10A of the second embodiment, and the common configuration is the same as that of the second embodiment. The same numbers as those of the forms are attached, and the description is omitted.

  The deaeration chamber 521 is adjacent to the lower ink storage chamber 390 adjacent to the cavity of the liquid remaining amount sensor 31 and the upstream ink end sensor communication channel 400 and the downstream ink end sensor communication channel 410 communicating therewith.

  This deaeration chamber 521 is also not filled with ink as in the other deaeration chambers, and accumulates the negative pressure for deaeration in addition to after the decompression package packaging of the ink cartridge until the opening, and also after the opening. It becomes a deaeration chamber.

  In the case of the present embodiment, by adding the deaeration chambers 521, the sum of the volumes of the respective deaeration chambers is the sum of the volumes as the ink storage chambers (that is, the upper ink storage chamber 370, the lower ink storage chamber 390, and the buffer chamber). The sum of the volume with 430) is larger.

  As in the third embodiment, when the total volume of the deaeration chambers is larger than the total volume of the ink storage chambers, the deaeration chambers 501, 511, 512, and 521 are used for deaeration. After the negative pressure accumulation amount is increased and the decompression package is opened, the deaeration chambers 501, 511, 512, and 521 are maintained in a higher decompression environment even after opening, and the effect of extinguishing bubbles by decompression Can be maintained for a longer period of time, the long-term storage stability of the ink cartridge packaged in a reduced pressure package can be further improved, and the deaeration effect after opening can also be improved. In particular, since the deaeration chamber 521 is disposed adjacent to the liquid storage area close to the cavity of the liquid remaining amount sensor 31, the bubbles remaining in the cavity of the liquid remaining amount sensor can be surely eliminated.

  In addition, the addition of the deaeration chamber 521 results in a structure in which more deaeration chambers are dispersedly arranged on the case, and the effect of the deaeration chambers being distributed and distributed (equalizing the pressure reducing action over the entire area of the cartridge). Is further improved.

(Fourth embodiment)
FIG. 16 is a front view of a case 10 </ b> C of an ink cartridge which is a fourth embodiment of a liquid container having a deaeration chamber according to the present invention.

  The case 10C of the fourth embodiment expands the area of the deaeration chamber 521 in the case 10B of the third embodiment to further reduce the lower ink storage chamber 390, and in addition, the upper ink storage chamber 370. The deaeration chamber 531 is newly added between the buffer chamber 430 and the buffer chamber 430. The partition wall 10a6 in which the deaeration chamber 521 is partitioned from the lower ink storage chamber 390 is extended, the wall portion in which the deaeration chamber 531 is partitioned from the upper ink storage chamber 370 is referred to as the partition wall 10a8, and the deaeration chamber 531 is the buffer. A wall section partitioned from the chamber 430 is referred to as a partition wall 10a9. The gas in the upper ink storage chamber 370 and the buffer chamber 430 is taken into the degassing chamber 531 side through the partition walls 10a8 and 10a9.

  In the case of the case 10C of the fourth embodiment, the configuration other than the enlargement of the deaeration chamber 521 and the addition of the deaeration chamber 531 is the same as the case 10B of the third embodiment, and the common configuration Are denoted by the same reference numerals as those in the third embodiment, and description thereof is omitted.

  As with the other deaeration chambers, the added deaeration chamber 531 is not filled with ink, and after the decompression package of the ink cartridge is packaged until it is opened, the negative pressure for deaeration is also applied after the opening. It becomes the deaeration chamber which accumulated pressure.

  In the case of the present embodiment, due to the expansion of the deaeration chamber 521 and the addition of the deaeration chamber 531, the total volume of each deaeration chamber is the sum of the volumes as ink storage chambers (that is, the upper ink storage chamber 370 and The sum of the volumes of the lower ink storage chamber 390 and the buffer chamber 430 is larger.

  Here, as a result of enlarging the deaeration chamber 521, the deaeration chamber 521 is adjacent to the upstream ink end sensor flow path 400 via the partition wall 10a6. A bubble trap means 600 shown in FIGS. 17 and 18 is arranged in the upstream ink end sensor flow path 400.

  Therefore, the gas (bubbles) separated from the ink by the bubble trap means 600 can be sucked to the deaeration chamber 521 side via the partition wall 10a6 without stopping at the upstream ink end sensor flow path 400. . Therefore, in the bubble trap means 600, it is possible to prevent the bubble trapping space from being saturated and the bubble trap function from being deteriorated.

  As described above, the upstream ink end sensor flow path 400 in which the bubble trap means 600 is provided traps bubbles immediately upstream of the cavity of the liquid remaining amount sensor 31, so that the liquid remaining amount is high even though the ink remaining amount is large. It is possible to prevent a situation where bubbles are mixed into the cavity of the quantity sensor 31 and the ink end is erroneously detected.

  FIG. 17 shows a bubble trap channel 610 provided in the bubble trap means 600. As shown in FIG. 17, the bubble trap channel 610 has a substantially rectangular parallelepiped shape that fits in the bottom of the case 3 as an overall schematic structure. As shown in FIG. 17, the bubble trap channel 610 has an inlet 612 through which ink flows from the lower ink storage chamber 390 formed at the approximate center of the upper surface, and discharges ink to the outer surface located on the sensor side. An outlet 614 is formed.

  As shown in FIGS. 17 and 18, the bubble trap channel 610 includes a plurality of vertical direction conversion units 621 a to 621 g that change the direction of the ink flow in the reverse direction, and about 90 degrees in the horizontal direction. A plurality of horizontal direction conversion portions 623a to 623f that change the direction are combined to form a complicated flow path structure with many bent portions.

  The bubble trap channel 610 has a standard channel cross-sectional position C (which is the position of the channel before and after the channel cross-section is adopted at the outlet end of the bubble trap channel 610 at several points in the middle of the channel. Bubble collection spaces 624a to 624c are formed that extend vertically upward from FIG. 18).

  In the case of the illustrated example, among the bubble collection spaces 624a to 624c, the bubble collection space 624c located on the most downstream side is set to the largest volume.

  Furthermore, in the bubble trap channel 610 of the present embodiment, a dead-end bubble collection space 625 is formed in the middle of the channel.

  Thus, when passing through the bubble trap channel 610 provided upstream from the detection position by the ink end sensor 30, it is separated from the ink and trapped in the bubble collection spaces 624a to 624c and 625. The captured bubbles pass through the partition wall 10a6 shown in FIG. 16, and move from the bubble trap channel 610 to the deaeration chamber 521 side. For this reason, bubbles do not flow into the cavity of the ink end sensor 30, and erroneous detection of the ink end is prevented.

(Fifth embodiment)
This 5th Embodiment shows the modification of the deaeration chamber demonstrated in the 1st-4th embodiment.

  19 and 20 are a schematic perspective view and a cross-sectional view in which the fifth embodiment is applied to, for example, the deaeration chamber 501 in the first embodiment. 19 and 20, at least one ink chamber (liquid storage chamber) 390 and at least one deaeration chamber 501 are partitioned by partition walls 10a2 and 10a3, and at least one deaeration chamber 501 is formed as an opening sealing film. It is sealed with a deaeration chamber forming film 700 different from 80. In the fifth embodiment, the opening sealing film 80 is used to seal the opening of the case 10 as in the first to fourth embodiments. In addition, before the deaeration chamber 501 is sealed with the deaeration chamber forming film 700, the inside of the case 10 including the deaeration chamber 501 is in a reduced pressure state. On the other hand, when the opening of the case 10 is sealed with the opening sealing film 80, the inside of the case 10 does not necessarily need to be in a reduced pressure state. Since the sealing process by the opening sealing film 80 can also be performed under atmospheric pressure, workability is improved. However, you may implement both the sealing process by the deaeration chamber formation film 700 and the opening sealing film 80 by making the inside of the case 10 into a pressure-reduced state.

  Here, the rising height of at least a part of the partition wall 10a2 is lower than the rising height of the outer wall 10a and the other partition walls 10a1 and 10a3. That is, both end positions A and B of the partition wall 10a2 are the same height as the outer wall 10a or the partition wall 10a3, but become lower toward the center from both ends, and the lowest rising height at the intermediate point C.

  When the deaeration chamber 501 is sealed with the deaeration chamber forming film 700, the ink chamber 390 defined by the low partition wall 10a2 is expanded to above the deaeration chamber forming film 700 as shown in FIG. That is, the deaeration chamber forming film 700 functions as a partition wall. Therefore, if a material having good air permeability (gas permeability) is used as the degassing chamber forming film 700, the bubbles in the ink chamber 390 are changed through the degassing chamber forming film 700 as indicated by arrows in FIG. It can be captured in the deaeration chamber 501 by pressure. For this reason, the deaeration chamber forming film 700 can be selected from a material different from the material of the opening sealing film 80 and the material of the partition walls 10a1 to 10a3 (that is, the material of the case 10). You can choose.

  FIG. 21 shows another example in which a deaeration chamber 720 provided in the ink chamber 710 is sealed with a deaeration chamber forming film 730. In this case, the rising height from the bottom surface 740 of the partition walls 722 and 724 for partitioning the deaeration chamber 720 from the ink chamber 710 is lower than the wall portions 712 and 714 for partitioning the ink chamber 710. The ink chamber 710 is sealed with the opening sealing film 80, while the deaeration chamber 720 is sealed with the deaeration chamber forming film 730. Even in this case, the same operation and effect as the embodiment of FIGS. 20 and 21 can be obtained.

  In particular, as in the fifth embodiment, when the deaeration chamber forming films 700 and 730 that function as partition walls have air permeability (gas permeability), the deaeration chambers 501 and 720 are replaced with the ink chambers 390 and 710, respectively. The partition walls 10 a 2, 10 a 3, 722 and 724 for partitioning are not necessarily formed integrally with the case 10. For example, the outer wall 10a (the outer wall of the case 10) which is another part of the deaeration chamber 501 is deposited with a material that does not have gas permeability, for example, metal or metal, in order to maintain the deaeration function. You may form with a film, glass, etc.

  Although the present embodiment has been described in detail as described above, those skilled in the art can easily understand that many modifications can be made without departing from the novel matters and effects of the present invention. Accordingly, all such modifications are intended to be included in the scope of the present invention. For example, a term described at least once together with a different term having a broader meaning or the same meaning in the specification or the drawings can be replaced with the different term in any part of the specification or the drawings.

  For example, in the present invention, the deaeration chamber is not limited to the injection molding of the case 10 and the case 10 is sealed with the opening sealing film 80 or the deaeration chamber forming film 700 under reduced pressure to form the deaeration chamber. . A decompression space chamber sealed with a material having shape retention formed separately from the case 10 may be accommodated in a room partitioned into the case 10 for the deaeration chamber.

  Moreover, in embodiment mentioned above, the partition walls 10a1-10a9 are formed thinner than the other rib 10a, and the gas permeability per unit area is made higher than the other rib 10a, and the gas supplementary effect is heightened. Also good.

  In particular, in the third and fourth embodiments, the deaeration chamber 521 is adjacent to the most downstream flow path 421 (see FIG. 10A) that allows the liquid supply port 50 and the buffer chamber 430 to communicate with each other. Yes. Alternatively, the deaeration chamber 521 is adjacent to a flow path 420 connected to the downstream ink end sensor communication flow path that functions as an intermediate flow path for communicating the lower ink storage chamber 390 and the buffer chamber 430. Therefore, bubbles in the middle of the most downstream flow path 421 and the intermediate flow path 420 can be captured in the deaeration chamber 521.

  In the above embodiment, the example in which the ink cartridge is mounted on the carriage to which the head is attached has been described. However, the ink cartridge of the present invention is not limited to that mounted on the carriage of the liquid consuming device. The liquid container of the present invention may be attached at a location different from the carriage to which the head is attached. For example, a liquid consuming device is known in which a container mounting portion is provided at a location different from the carriage of the liquid consuming device, and a flow path for supplying ink to the carriage is formed therefrom. The ink cartridge of the present invention can also be applied to such a liquid consuming apparatus. In the above embodiment, an example of a liquid consuming device in which liquid is ejected while the carriage reciprocates is shown. However, the liquid container of the present invention is also applicable to a liquid consuming device in which the carriage is fixed. Is possible.

  The liquid consuming device includes a container mounting portion on which a liquid storage container is detachably mounted, and various devices in which the liquid stored in the liquid storage container is supplied to the device are applicable. For example, an apparatus having a color material ejecting head used for manufacturing a color filter such as a liquid crystal display, an apparatus having an electrode material (conductive paste) ejecting head used for forming an electrode such as an organic EL display and a surface emitting display (FED), Examples thereof include an apparatus equipped with a bio-organic matter ejecting head used for biochip manufacturing, an apparatus equipped with a sample ejecting head as a precision pipette, and the like.

  Furthermore, the appearance of the case, the configuration of the flow path, and the like can be freely changed without departing from the spirit of the present invention.

1 ink cartridge (liquid container), 10 cases,
10a1-10a9,722,724, partition wall, 20 lid member,
30 ink end sensor, 31 liquid remaining amount sensor, 40 differential pressure valve,
50 ink supply port (liquid supply port), 70 gas-liquid separation filter,
80 opening sealing film, 90 sealing film (blocking means), 100 air opening hole,
150 open air flow path, 220 carriage, 330 upper connection flow path,
340 ink trap chamber (air chamber), 350 linked buffer chamber (air chamber),
370 Upper ink storage chamber (liquid storage chamber), 380 Ink channel (liquid channel),
390 Lower ink storage chamber (liquid storage chamber),
400 upstream ink end sensor communication channel (liquid channel),
410 downstream side ink end sensor communication channel (liquid channel),
420 ink flow path (liquid flow path), 430 buffer chamber (liquid storage chamber),
501, 511, 512, 521, 531, 720, a deaeration chamber,
700, 730 Degassing chamber forming film, 710 Ink chamber (liquid storage chamber)

Claims (7)

A liquid container sealed in a decompression space,
A liquid storage chamber;
Volume of the closed space by the partition wall is vacuum partitioned with the liquid storage chamber, and the size have degassing chamber than the volume of the previous SL liquid chamber,
With
Before Symbol partition Ri wall, that having a property of transmitting the gas,
Liquid container. The liquid container according to claim 1,
further,
An air opening hole connected to the liquid container;
A cavity for the liquid level sensor;
With
When the liquid in the liquid storage chamber is exhausted, the air guided into the liquid storage chamber enters the cavity.
Liquid container. The liquid container according to claim 2,
The deaeration chamber is adjacent to a first flow path for supplying liquid from the liquid storage chamber to the cavity.
Liquid container. The liquid container according to any one of claims 1 to 3,
further,
With an air chamber,
The volume of the deaeration chamber is larger than the volume of the air chamber,
Liquid container. The liquid container according to claim 4,
The deaeration chamber is provided adjacent to the liquid storage chamber and the air chamber.
Liquid container. The liquid container according to any one of claims 1 to 5,
further,
A liquid supply port;
A second flow path for communicating the liquid supply port with the liquid storage chamber;
With
The deaeration chamber is adjacent to the second flow path;
Liquid container. The liquid container according to any one of claims 1 to 6,
further,
A trap channel formed by a vertical direction conversion unit that converts the flow of the liquid in a vertical direction and a horizontal direction conversion unit that converts the flow of the liquid in a horizontal direction;
With
In the trap channel, a space for collecting bubbles is formed,
Liquid container.