JP5126187B2 - Liquid container - Google Patents

Description

  The present invention relates to a method for injecting liquid into a liquid storage container that is detachably attached to a liquid consumption apparatus and supplies liquid stored in a liquid storage chamber to the liquid consumption apparatus, and a liquid storage container manufactured by liquid injection About.

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

  The ink cartridge is normally detachably mounted on a cartridge mounting portion of an ink jet recording apparatus, and an ink storage chamber in which ink (liquid) is filled, and a liquid stored in the ink storage chamber is transferred to the ink jet recording apparatus. An ink supply hole for supplying the ink to the ink supply path, an ink guiding path communicating with the ink storage chamber and the ink supply hole, and an atmosphere for introducing air into the ink storage chamber from the outside as the ink in the ink storage chamber is consumed. The ink supply needle mounted on the cartridge mounting portion is inserted and connected to the ink supply hole when the cartridge is mounted on the cartridge mounting portion of the recording apparatus. Can be supplied to the recording head of the ink jet recording apparatus.

  The recording head in the ink jet recording apparatus controls the ejection of ink droplets using heat and vibration, and when the ink cartridge runs out of ink and the ink ejection operation occurs without ink being supplied, It will break down. Therefore, in the ink jet recording apparatus, it is necessary to monitor the remaining amount of ink in the ink cartridge so that the recording head does not run idle.

  In view of this background, the remaining amount of ink stored in the ink storage chamber does not cause the ink stored in the ink cartridge to be used up completely until the recording head of the recording apparatus is emptied. An ink cartridge having a liquid remaining amount sensor that outputs a predetermined electrical signal when consumed up to a preset threshold value has been developed (for example, Patent Document 1).

JP 2001-146030 A

By the way, since the ink cartridge is a container formed with a high precision composed of a large number of parts, if the ink is exhausted, discarding it as it is is a waste of useful resources, which is a large economic loss. End up.
Therefore, it is desired to regenerate a used ink cartridge by refilling it with ink.

However, conventional ink cartridges incorporate an ink filling process in the middle of the assembly process, and the same ink filling method cannot often be used after the completion of the ink cartridge assembly.
Therefore, it is necessary to develop a reproduction method that realizes ink filling without using an ink filling method for assembling a new ink cartridge.

However, recent ink cartridges have a check valve that adjusts the ink pressure supplied to the ink supply hole and prevents the backflow from the ink supply hole side in the ink guide path that connects the ink storage chamber and the ink supply hole. A high-performance differential pressure valve is provided, or a liquid remaining amount sensor for detecting the remaining amount of ink is provided. Furthermore, in order to maintain the quality of the stored ink for a long period of time, the structure of the ink storage chamber and the atmosphere communication path is complicated.
Therefore, if the ink cartridge is carelessly processed for ink injection, the original function may be caused by air leaking into a portion other than the ink storage chamber when ink is injected, or air bubbles mixed during ink filling. There is a possibility that it may be damaged and cause a reproduction failure.
In addition, the processing performed on the ink cartridge for ink injection is complicated, and if the recycling cost exceeds the manufacturing cost of a new ink cartridge due to an increase in processing cost, the significance of the regeneration is reduced.

  Therefore, the present invention requires less processing into the liquid container when injecting the liquid into the liquid container, and can inject the liquid without impairing various functions of the liquid container. The purpose is to manufacture the container at low cost.

The solution of the above-mentioned problem of the present invention is a liquid storage chamber for storing a liquid,
A liquid supply hole connectable to the liquid consumption device;
A liquid guide path for guiding the liquid stored in the liquid storage chamber to the liquid supply hole;
An atmosphere communication path for communicating the liquid storage chamber with the atmosphere;
A liquid remaining amount sensor that is provided in the middle of the liquid guiding path and outputs a different signal according to the liquid remaining amount in the liquid storage chamber;
With
And at least three or more liquid storage chambers,
These liquid storage chambers include a descent-type connection in which a pair of liquid storage chambers are connected so that the liquid flow direction in the liquid guide passage is a downward flow from top to bottom, and the liquid guide passage Are connected in series so as to alternately repeat the ascending connection in which a pair of liquid storage chambers are connected so that the flow direction of the liquid at the top is an upward flow from the bottom to the top, and is attached to and detached from the liquid consuming device. A method of injecting liquid into a possible liquid container,
Forming an inlet communicating with the liquid storage chamber in the atmosphere communication path;
Injecting a predetermined amount of liquid from the injection port;
And a step of sealing the inlet after the liquid injection.

According to the above configuration, the processing to be performed on the liquid container for liquid injection includes opening the injection port for injecting the liquid and sealing the injection port after the liquid injection. Easy processing. Therefore, the processing cost is low and it does not take time and effort.
If the position where the inlet is provided is the most upstream liquid storage chamber, the liquid can be smoothly supplied to all of the plurality of liquid storage chambers equipped in the liquid storage container and the liquid guide path connecting the liquid storage chambers to each other. Can be injected. Therefore, in the liquid storage container into which the liquid has been injected, the flow path structure bent up and down in a zigzag manner is restored between the liquid guide path that connects the liquid storage chambers with each other in a descending manner and the liquid guide path that connects with each other ascending. Even if bubbles are generated in the liquid storage chamber, the liquid remaining in the descending liquid guiding path serves as a protective wall that stops the bubbles. Therefore, it is difficult for the bubbles that have entered the liquid guiding path to travel downstream.
In addition to the zigzag flow path that connects the liquid storage chambers to each other, the upper space of each downstream liquid storage chamber functions effectively as a trap space for the incoming air bubbles, and the bubbles move downstream. To prevent.

Furthermore, the solution of the above-mentioned problem of the present invention is to provide a liquid storage chamber for storing a liquid;
A liquid supply hole connectable to the liquid consumption device;
A liquid guide path for guiding the liquid stored in the liquid storage chamber to the liquid supply hole;
An atmosphere communication path for communicating the liquid storage chamber with the atmosphere;
A liquid remaining amount sensor that is provided in the middle of the liquid guiding path and outputs a different signal according to the liquid remaining amount in the liquid storage chamber;
With
And at least three or more liquid storage chambers,
These liquid storage chambers include a descent-type connection in which a pair of liquid storage chambers are connected so that the liquid flow direction in the liquid guide passage is a downward flow from top to bottom, and the liquid guide passage Are connected in series so as to alternately repeat the ascending connection in which a pair of liquid storage chambers are connected so that the flow direction of the liquid at the top is an upward flow from the bottom to the top, and is attached to and detached from the liquid consuming device. For possible liquid containers,
This is achieved by a liquid storage container in which an injection port communicating with the liquid storage chamber is formed in the atmosphere communication path, a predetermined amount of liquid is injected from the injection port, and the injection port is sealed after liquid injection.

According to the above configuration, even if bubbles enter the liquid guide path communicating with the liquid supply unit from the liquid storage chamber, the liquid storage chamber can be used for a zigzag liquid guide path or a liquid storage chamber that communicates with each other. While there is a remaining amount of liquid, it is difficult for bubbles that have entered the liquid guide path to travel downstream. Therefore, it is possible to inject the liquid without deteriorating various functions of the liquid storage container due to the entry of bubbles.
In addition, since the cost required for regeneration is low and the liquid container can be provided at low cost, the operation cost of the liquid consuming apparatus is also reduced.

Moreover, the solution of the above-mentioned problem of the present invention is to provide a liquid storage chamber for storing a liquid,
A liquid supply hole connectable to the liquid consumption device;
A liquid guide path for guiding the liquid stored in the liquid storage chamber to the liquid supply hole;
An atmosphere communication path for communicating the liquid storage chamber with the atmosphere;
With
And at least three or more liquid storage chambers,
These liquid storage chambers include a descent-type connection in which a pair of liquid storage chambers are connected so that the liquid flow direction in the liquid guide passage is a downward flow from top to bottom, and the liquid guide passage A liquid storage container that is connected so as to have an ascending connection in which a pair of liquid storage chambers are connected to each other so that the flow direction of the liquid is an upward flow from the bottom to the top. A method for injecting liquid,
Forming an inlet communicating with the liquid storage chamber in the atmosphere communication path;
Injecting a predetermined amount of liquid from the injection port;
And a step of sealing the inlet after the liquid injection.

According to the above configuration, the processing to be performed on the liquid container for liquid injection includes opening the injection port for injecting the liquid and sealing the injection port after the liquid injection. Easy processing. Therefore, the processing cost is low and it does not take time and effort.
If the position where the inlet is provided is the most upstream liquid storage chamber, the liquid can be smoothly supplied to all of the plurality of liquid storage chambers equipped in the liquid storage container and the liquid guide path connecting the liquid storage chambers to each other. Can be injected. Therefore, in the liquid storage container into which the liquid has been injected, the channel structure bent up and down is restored by the liquid guide path that connects the liquid storage chambers to each other in a descending manner and the liquid guide path that connects the ascending types. Even if bubbles are generated in the storage chamber, the liquid remaining in the descending liquid guiding path serves as a protective wall that stops the bubbles from proceeding. Therefore, it is difficult for the bubbles that have entered the liquid guiding path to travel downstream.
Moreover, in addition to the bent flow path connecting the liquid storage chambers, the upper space of each downstream liquid storage chamber functions effectively as a trap space for the incoming air bubbles, preventing the bubbles from moving downstream. To do.

In the liquid injection method having the above-described configuration, it is preferable that a plurality of combinations having the descending connection and the ascending connection are provided.
According to the liquid injection method having such a configuration, the flow path structure bent up and down in a zigzag manner is restored by the liquid guide path connecting the plurality of sets of liquid storage chambers to each other in a descending manner and the liquid guide path connecting ascending. The bubbles that have entered the liquid guiding path are less likely to travel downstream.

  Further, in the liquid injection method configured as described above, a liquid remaining amount sensor that outputs a different signal according to the liquid remaining amount in the liquid storage chamber is provided downstream of the descending connection and the ascending connection in the liquid guiding path. It is desirable that

  According to the liquid injection method having such a configuration, even if bubbles enter the liquid guide path communicated with the liquid remaining amount sensor from the liquid storage chamber, the zigzag liquid guide path that connects the liquid storage chambers to each other, The liquid storage chamber can prevent bubbles that have entered the liquid guiding path from reaching the detection position by the liquid remaining amount sensor, and are discarded without being used up due to erroneous detection of the liquid remaining amount sensor due to the entry of bubbles. The problem of increased liquid volume can be avoided.

Moreover, the solution of the above-mentioned problem of the present invention is to provide a liquid storage chamber for storing a liquid,
A liquid supply hole connectable to the liquid consumption device;
A liquid guide path for guiding the liquid stored in the liquid storage chamber to the liquid supply hole;
An atmosphere communication passage for communicating the liquid storage chamber with the atmosphere,
And at least three or more liquid storage chambers,
These liquid storage chambers include a descent-type connection in which a pair of liquid storage chambers are connected so that the liquid flow direction in the liquid guide passage is a downward flow from top to bottom, and the liquid guide passage A liquid storage container that is connected so as to have an ascending connection in which a pair of liquid storage chambers are connected to each other so that the flow direction of the liquid is an upward flow from the bottom to the top. for,
This is achieved by a liquid storage container in which an injection port communicating with the liquid storage chamber is formed in the atmosphere communication path, a predetermined amount of liquid is injected from the injection port, and the injection port is sealed after liquid injection.

According to the above configuration, even if bubbles enter the liquid guide path communicating with the liquid supply unit from the liquid storage chamber, the liquid storage chamber can be used for a zigzag liquid guide path or a liquid storage chamber that communicates with each other. While there is a remaining amount of liquid, it is difficult for bubbles that have entered the liquid guide path to travel downstream. Therefore, it is possible to inject the liquid without deteriorating various functions of the liquid storage container due to the entry of bubbles.
In addition, since the cost required for regeneration is low and the liquid container can be provided at low cost, the operation cost of the liquid consuming apparatus is also reduced.

In the liquid container having the above-described configuration, it is preferable that a plurality of combinations having the descending connection and the ascending connection are provided.
According to the liquid storage container having such a configuration, the flow path structure bent in a zigzag manner in the up and down direction is restored by the liquid guide path connecting the plurality of sets of liquid storage chambers to each other in a descending manner and the liquid guide path connecting the ascending manner. The bubbles that have entered the liquid guiding path are less likely to travel downstream.

  Further, in the liquid container having the above-described configuration, a liquid remaining amount sensor that outputs a different signal according to the liquid remaining amount in the liquid storage chamber is provided downstream of the descending connection and the ascending connection in the liquid guiding path. It is desirable that

  According to the liquid container having such a configuration, it is possible to output a predetermined signal when the remaining amount of the liquid stored in the liquid storage chamber is consumed up to a preset threshold value. In addition, even if a bubble enters the liquid guide path that communicates with the liquid remaining amount sensor from the liquid storage chamber, it enters the liquid guide path by the zigzag liquid guide path or the liquid storage chamber that communicates with each other. Can be prevented from reaching the detection position by the liquid remaining amount sensor, and it is possible to avoid the problem that the amount of liquid discarded without being used up due to erroneous detection of the liquid remaining amount sensor due to the bubble entering increases. .

  In the liquid container having the above-described configuration, it is desirable that the air communication path be provided with an air chamber for preventing liquid leakage from the liquid storage chamber. Thus, even when the liquid flows out from the liquid storage chamber to the atmosphere side, it can be reliably trapped in the air chamber and the occurrence of liquid leakage can be suppressed. Further, since the liquid trapped in the air chamber is configured to flow into the liquid storage chamber as the liquid is consumed, the liquid stored inside can be used without waste.

In the liquid container having the above-described configuration, it is preferable that at least a part of the atmosphere communication path passes through the uppermost portion in the gravity direction of the liquid container.
According to the liquid container having such a configuration, even when the liquid flows backward, it is difficult to reach the atmosphere opening hole of the container body beyond the uppermost portion in the direction of gravity. Accordingly, liquid leakage can be suppressed.

In the liquid container having the above-described configuration, it is desirable that a gas-liquid separation filter that allows gas to pass therethrough and blocks the liquid from passing through is preferably provided in the atmosphere communication path.
According to the liquid container having such a configuration, even if the liquid flows out into the atmosphere communication path, the gas-liquid separation filter is provided in the atmosphere communication path. Do not leak to the atmosphere opening hole side. Therefore, ink leakage from the air opening hole can be further suppressed.

Moreover, it is desirable that the liquid container having the above-described configuration is packed in a decompression pack that is sealed under reduced pressure so that the internal atmospheric pressure is equal to or lower than atmospheric pressure.
According to the liquid container having such a configuration, the air pressure inside the liquid container is kept below a specified value by the negative pressure suction force of the decompression pack before use, and a liquid with little dissolved air can be supplied.

FIG. 2 is an external perspective view of an ink cartridge as a liquid container regenerated by the method for regenerating a liquid container according to the present invention. FIG. 2 is an external perspective view of the ink cartridge of FIG. 1 viewed from an angle opposite to that of FIG. 1. FIG. 2 is an exploded perspective view of the ink cartridge of FIG. 1. FIG. 4 is an exploded perspective view of the ink cartridge of FIG. 3 viewed from an angle opposite to that of FIG. 3. FIG. 2 is a diagram illustrating a state where the ink cartridge of FIG. 1 is attached to the carriage of the ink jet recording apparatus. FIG. 2 is a cross-sectional view showing a state immediately before the ink cartridge of FIG. 1 is attached to a carriage. FIG. 2 is a cross-sectional view illustrating a state immediately after the ink cartridge of FIG. 1 is attached to a carriage. FIG. 2 is a front view of a cartridge main body of the ink cartridge of FIG. 1. FIG. 2 is a view of a cartridge main body of the ink cartridge of FIG. 1 viewed from the back side. (A) is the simplified schematic diagram of FIG. 8, (b) is the simplified schematic diagram of FIG. It is AA sectional drawing of FIG. FIG. 9 is an enlarged perspective view of a part of the flow path structure in the cartridge main body shown in FIG. 8. It is a block diagram which shows the structure of the ink reinjection apparatus which enforces the injection method of the liquid container which concerns on this invention. In the structure of the ink cartridge shown in FIG. 10 (b), it is an explanatory view of a portion where ink can be injected by the liquid injection method according to the present invention.

Hereinafter, a liquid injection method according to the present invention and a preferred embodiment of a liquid container will be described in detail with reference to the drawings.
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.

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

  As shown in FIGS. 1 and 2, the ink cartridge 1 according to the present invention 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 hole 50 for supplying ink is provided. An air opening hole 100 for introducing air into the ink cartridge 1 is opened on the bottom surface 1b. That is, the ink cartridge 1 is an air release type ink cartridge that supplies ink from the ink supply hole 50 while introducing air from the air release hole 100.

  As shown in FIG. 6, the air opening hole 100 of the ink cartridge 1 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 atmosphere communication path described later, and the atmosphere is introduced into the most upstream ink storage chamber 370 described later via 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, thereby ensuring that the ink cartridge 1 is sealed when the ink cartridge 1 is attached. The film 90 can be prompted to peel off.

  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 preventing protrusion 22 has a different shape for each type of ink I, and the unevenness 220 on the carriage 200 side serving as a receiver also has a shape corresponding to the corresponding type of ink I. 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 formed in the carriage 200 when mounted on the carriage 200, and the protrusion 11a and the recess 210 engage while the engaging lever 11 is bent. As a result, the position of the ink cartridge 1 is 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 rewritable nonvolatile memory, and stores various information about the ink cartridge 1, ink use information of the ink jet recording apparatus, and the like. In addition, an ink remaining amount sensor (liquid remaining amount sensor) 31 (see FIG. 3 or FIG. 4) that outputs a different signal according to the ink remaining amount in the ink cartridge 1 is provided on the back side of the circuit board 34. ing. In the following description, the ink 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 cartridge main body 10 that is a container main body, and a lid member 20 that covers the front side of the cartridge main body 10.

The cartridge body 10 is formed with ribs 10a having various shapes on the front side thereof, and these ribs 10a partition to form a plurality of ink storage chambers (liquid storage chambers) filled with ink I. An unfilled chamber that is not filled with ink, an air chamber located in the middle of an air communication path 150 described later, and the like are partitioned in the interior.
A film 80 that covers the front side of the cartridge body 10 is provided between the cartridge body 10 and the lid member 20, and the upper surfaces of the ribs, recesses, and grooves are closed by the film 80, and a plurality of flow paths and An ink storage chamber, an unfilled chamber, and an air chamber are formed.

  Further, on the back side of the cartridge body 10, a differential pressure valve housing chamber 40 a as a recess for housing the differential pressure valve 40 and a gas-liquid separation chamber 70 a 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 hole 50 on the downstream side and the ink storage chamber on the upstream side, and is attached to a valve closing state that blocks the flow of ink from the ink storage chamber side to the ink supply hole 50 side. It is energized. With the ink supply from the ink supply hole 50 to the printer side, the differential pressure between the ink supply hole 50 side and the ink storage chamber side of the differential pressure valve 40 becomes a certain level or more, so that the differential pressure valve 40 changes from the closed state to the open state. The ink I is supplied to the ink supply hole 50 and a negative pressure is applied to the ink I supplied from the ink supply hole 50.

  A gas-liquid separation film 71 is attached to the upper surface of the gas-liquid separation chamber 70a along a bank 70b surrounding an 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 the atmosphere communication path 150 that connects the atmosphere opening hole 100 and the ink storage chamber so that the ink I in the ink storage chamber does not flow out of the atmosphere opening hole 100 through the atmosphere communication path 150. It is for making.

  In addition to the differential pressure valve housing chamber 40a and the gas-liquid separation chamber 70a, a plurality of grooves 10b are formed on the back side of the cartridge body 10. These grooves 10b are covered with the outer surface film 60 in the state where 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 communication paths 150 and the ink guides are formed. A path is formed.

  As shown in FIG. 4, a sensor chamber 30 a is formed on the right side surface of the cartridge body 10 as a recess for housing each member constituting the ink end sensor 30. Housed in the sensor chamber 30a are a remaining ink sensor 31 and a compression spring 32 that presses and fixes the remaining ink 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 ink sensor 31 is connected to the circuit board 34.

The ink remaining amount sensor 31 includes a cavity that forms part of an ink guide path between the ink storage chamber and the ink supply hole 50, a diaphragm that forms 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 residual vibration when the vibration is applied to the diaphragm is output as a signal to the ink jet recording apparatus. From the signal output from the ink remaining amount sensor 31, the remaining liquid amount detecting unit of the ink jet recording apparatus determines the amplitude, frequency, etc. of residual vibration between the ink I and the gas (bubble B mixed in the ink). By detecting the difference, the presence or absence of ink I in the cartridge body 10 is detected.
Specifically, the liquid remaining amount detection unit of the ink jet recording apparatus uses the ink I in the ink containing chamber in the cartridge body 10 to be exhausted or reduced to a predetermined amount, and the air introduced into the ink containing chamber is used as an ink guide path. When the ink enters the cavity of the ink remaining amount sensor 31, the ink in the ink storage chamber in the cartridge body 10 is changed based on the signal from the ink remaining amount sensor 31 based on the change in the amplitude and frequency of the residual vibration at that time. It is detected that I is exhausted or reduced to a predetermined amount, and an electric signal indicating ink end or ink near end is output.

  In addition to the ink supply hole 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 the ink is injected on the bottom surface side of the cartridge body 10. Are formed in the pressure reducing hole 110, the recess 95 a constituting the ink guiding path from the ink storage chamber to the ink supply hole 50, and the buffer chamber 30 b provided below the ink end sensor 30.

  The ink supply hole 50, the air opening hole 100, the decompression hole 110, the recess 95a, and the buffer chamber 30b are all opened by the sealing films 54, 90, 98, 95, and 35 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 communication path 150.

  Further, as shown in FIGS. 6 and 7, the sealing film 35 attached to the outer surface of the ink supply hole 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 hole 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 that is not attached to the printer. A spring seat 52 that closes the ink supply hole 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 hole 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 hole 50 and the ink supply are supplied. The gap between the needle 240 is sealed in a liquid-tight manner. Further, the tip of the ink supply needle 51 comes into contact with 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 needle 50 passes through the ink supply needle 240. Ink I can be supplied.

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

  FIG. 8 is a view of the cartridge body 10 of the ink cartridge 1 as viewed from the front side, FIG. 9 is a view of the cartridge body 10 of the ink cartridge 1 as viewed from the back side, and FIG. FIG. 10B is a simplified schematic diagram, FIG. 10B is a simplified schematic diagram, and FIG. 11 is a cross-sectional view taken along line AA in FIG. FIG. 12 is a partially enlarged perspective view of the flow path shown in FIG.

In the ink cartridge 1 described above, the main ink containing chamber filled with the ink I is sandwiched between the upper and lower ink containing chambers 370 and 390 divided into the upper and lower parts, and the upper and lower ink containing chambers. Three ink storage chambers with the buffer chamber 430 positioned in this manner are formed on the front side of the cartridge body 10.
Further, an air communication path 150 is formed on the back side of the cartridge body 10 to introduce air into the upper ink storage chamber 370 that is the most upstream ink storage chamber according to the amount of ink I consumed.

The ink storage chambers 370 and 390 and the buffer chamber 430 are divided by the rib 10a. Each of these ink storage chambers is formed with recesses 374, 394, and 434 having a shape recessed downward in a part of the rib 10a that extends in the horizontal direction and serves as the bottom wall of the storage chamber.
The depression 374 is a depression of a part of the bottom wall 375 formed by the rib 10 a of the upper ink storage chamber 370. The dent 394 is bulged in the cartridge thickness direction by the bottom wall 395 and the bulging portion of the wall surface by the rib 10a of the lower ink containing chamber 390. The depression 434 is obtained by depression of a part of the bottom wall 435 of the buffer chamber 430 10a.

In addition, ink discharge ports 371, 311, and 432 communicating with the ink guide path 380, the upstream ink end sensor liquid guide path 400, and the ink guide path 440 are provided at or near the bottoms of the recesses 374, 394, and 434. ing.
The ink discharge ports 371 and 432 are through holes that penetrate the wall surface of each ink storage chamber in the thickness direction of the cartridge body 10. The ink discharge port 312 is an outlet of a cavity (flow path) in the ink remaining amount sensor 31.

  One end of the ink guide path 380 communicates with the ink discharge port 371 of the upper ink storage chamber 370 and the other end communicates with the ink inlet 391 provided in the lower ink storage chamber 390. The liquid guide path guides the ink to the lower ink storage chamber 390. The ink guide path 380 is provided so as to extend vertically downward from the ink discharge port 371 of the upper ink storage chamber 370, and the flow direction of the liquid in the liquid guide path is a downward flow from top to bottom. A pair of ink storage chambers 370 and 390 are connected to each other by a descending connection.

  One end of the ink guide path 420 communicates with the ink discharge port 312 of the cavity in the ink remaining amount sensor 31, and the other end communicates with the ink inlet 431 provided in the buffer chamber 430. The ink in the lower ink storage chamber 390 is guided to the buffer chamber 430 through the sensor liquid guiding path 400. The ink guide path 420 is provided so as to extend obliquely upward from the ink discharge port 312 of the cavity in the liquid flow sensor 31, and the flow direction of the liquid in the liquid guide path is an upward flow from the bottom to the top. The pair of ink storage chambers 390 and 430 are connected to each other by the ascending connection.

  That is, in the cartridge main body 10 of the illustrated example, the three ink storage chambers 370, 390, 430 are connected to each other so as to have a descending type connection and an ascending type connection.

  The ink guide path 440 is an ink flow path that guides ink from the ink discharge port 432 of the buffer chamber 430 to the differential pressure valve 40.

  The ink inlets 372, 391, and 431 of the ink storage chambers are provided in the vicinity of the bottom walls 375, 395, and 435 of the ink storage chambers.

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

  The upper ink storage chamber 370 is the most upstream (uppermost) ink storage chamber in the cartridge main body 10 and is formed on the front side of the cartridge main body 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 cartridge body 10. An ink discharge port 371 communicating with the ink guide path 380 is opened in the recess 374 in the bottom wall of the upper ink storage chamber 370. The ink discharge port 371 is located at a position lower than the rib 10a which is the bottom wall of the upper ink storage chamber 370, and even if the ink level in the upper ink storage chamber 370 drops to the bottom wall, Stable ink derivation is continued at a position below the liquid level.

  As shown in FIG. 9, the ink guide path 380 is formed on the back side of the cartridge body 10 and guides ink from below to the lower ink storage chamber 390.

  The lower ink storage chamber 390 is an ink storage chamber into which the ink I stored in the upper ink storage chamber 370 is introduced. As shown in FIG. 8, the lower ink storage chamber 390 is about the ink storage chamber formed on the front side of the cartridge body 10. This is an ink containing area that occupies half of the area, and is formed in the lower half of the cartridge body 10. In the vicinity of the rib 10 a serving as the bottom wall of the lower ink storage chamber 390, an ink inlet 391 that communicates with the ink guide path 380 is a communication channel disposed below the bottom wall 395 of the lower ink storage chamber 390. Ink I from the upper ink storage chamber 370 flows through the communication channel.

  The lower ink storage chamber 390 communicates with the upstream ink end sensor liquid guiding path 400 through an ink discharge port 311 penetrating the bottom wall 395. The upstream side ink end sensor liquid guiding path 400 is formed with a three-dimensional maze flow path, which captures bubbles and the like flowing before the ink end and flows downstream. Is configured to not.

  The upstream side ink end sensor liquid guiding path 400 communicates with the downstream side ink end sensor liquid guiding path 410 via a through hole (not shown), and the ink I passes through the downstream side ink end sensor liquid guiding path 410. It is guided to the remaining amount sensor 31.

  The ink guided to the remaining ink sensor 31 passes through a cavity (flow path) in the remaining ink sensor 31 and is guided to the back side of the cartridge body 10 from the ink discharge port 312 which is the exit of the cavity. Guided to path 420. The ink guiding path 420 is formed so as to guide ink obliquely upward from the ink remaining amount sensor 31, and is connected to an ink inlet 431 that communicates with the buffer chamber 430. As a result, the ink that has left the ink remaining amount sensor 31 is guided to the buffer chamber 430 through the ink guide 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 the ink I is supplied to the differential pressure valve 40 via an ink guide path 440 that communicates with an ink discharge port 432 formed in a recess 434 of the buffer chamber 430. Flows in.

  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 hole 50, and the ink I is supplied to the ink jet recording apparatus side via the ink supply needle 240 inserted into the ink supply hole 50.

  Next, the atmosphere communication 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 I 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 I.

  A small hole 102 provided in the atmosphere opening hole 100 communicates with one end of a serpentine passage 310 formed on the back side of the cartridge body 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 cartridge body 10 through the through-hole 322. . In the gas-liquid separation filter 70, the gas-liquid separation film 71 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.

  The space 320 is formed on the upper right side of the upper ink chamber when viewed from the front side of the cartridge body 10. In the space 320, a through hole 321 opens above the through hole 322. The space 320 communicates with the upper connection channel 330 formed on the back side through the through hole 321.

  The upper connecting flow path 330 has a long side from the through hole 321 when viewed from the back side so as to pass through the uppermost side of the ink cartridge 1, that is, the uppermost part in the direction of gravity in a state where the ink cartridge 1 is attached. And a through-hole 341 formed in the vicinity of the through-hole 321 through the upper surface side of the ink cartridge 1 with respect to the flow-path portion 333 by folding back at a folded-back portion 335 near the short side. And a flow path portion 337 extending to the end. 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 from the position 336. A concave portion 332 having a deeper directional position is provided, and a plurality of ribs 331 are formed so as to divide 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.

  Further, in the ink cartridge 1, since the upper connecting flow path 330 is formed at the uppermost part in the direction of gravity, the ink I basically passes through the upper connecting flow path 330 and is on the atmosphere opening hole 100 side. It is configured not to move to. Further, the upper connecting flow path 330 has a width large enough to prevent the backflow of the ink I due to a capillary phenomenon or the like, and a recessed portion 332 is formed in the flow path portion 337, so that the backflowed ink is captured. Constructed easily.

  The ink trap chamber 340 is a rectangular parallelepiped space formed at the upper right corner of the cartridge body 10 when viewed from the front side. As shown in FIG. 12, the through hole 341 opens near the upper left rear corner of the ink trap chamber 340 when viewed from the front side. 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 atmosphere communication path 150 is expanded, and even if the ink I flows backward from the upper ink storage chamber 370 for some reason, this ink trap. Ink is retained in the chamber 340 and the communication buffer chamber 350 so that it does not flow into the atmosphere opening hole 100 as much as possible. Specific roles of the ink trap chamber 340 and the communication buffer chamber 350 will be described later.

  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 liquid guide path 360 is communicated.

  The liquid guide path 360 extends upward in the center as viewed from the back side, and communicates with the upper ink storage chamber 370 through a through hole 372 that opens near the bottom surface of the upper ink storage chamber 370. That is, the atmosphere communication path 150 of the ink cartridge 1 is configured from the atmosphere opening hole 100 to the liquid guide path 360. The liquid guiding path 360 forms a meniscus and is formed to be thin enough to prevent backflow of the ink I.

  Further, in the case of the ink cartridge 1, as shown in FIG. 8, the above-described ink storage chambers (upper ink storage chambers 370 and 390, buffer chamber 430) and air chamber ( In addition to the ink trap chamber 340 and the communication buffer chamber 350) and the ink guide path (upstream ink end sensor liquid guide path 400, downstream ink end sensor liquid guide path 410), there is an unfilled chamber 501 that is not filled with ink I. It is defined.

The unfilled chamber 501 is a hatched region near the left side on the front side of the cartridge body 10 and is defined so as to be sandwiched between the upper ink storage chamber 370 and the lower ink storage chamber 390.
The unfilled chamber 501 is provided with an air opening hole 502 penetrating to the back side in the upper left corner of the inner region, and communicates with the outside air through the air opening hole 502.
The unfilled chamber 501 is a deaeration chamber in which a negative pressure for deaeration is accumulated when the ink cartridge 1 is packed in a decompression pack.

  Even in the ink cartridge 1 described above, for example, the ink cartridges 370, 390, 390, 390, 390, 390, 390, 390, 390, 390, 390, 390, 390, 390. When the ink liquid level in 430 is shaken, in an ink storage chamber with a small amount of remaining ink, an air layer contacts the ink discharge port in the storage chamber, and a bubble B enters the ink guide path communicating with the ink discharge port. Sometimes.

However, according to the configuration of the ink cartridge 1 described above, the three ink storage chambers 370, 390, and 430 are connected to each other so as to have the descending type connection and the ascending type connection. The liquid guiding path is a flow path bent vertically, and the ink I remaining in the descending liquid guiding path serves as a protective wall that stops the progress of the bubbles. For this reason, it is difficult for the bubble B that has entered the ink guide path to travel downstream.
Further, the ink guide path that becomes the ascending connection functions as a descending connection when the ink cartridge 1 removed from the carriage 200 is upside down to prevent the bubbles from moving downstream. To do. In other words, even when the ink cartridge 1 is turned upside down, the action of preventing the bubbles from moving to the downstream side can be obtained by the descending connection.

  Further, the upper ink storage chambers 390 and 430 connected in the second and subsequent stages function as trap spaces for capturing bubbles flowing in from the upstream upper ink storage chamber 370. For example, the ink cartridge 1 is in a laid state. Thus, when the flow path extending in the vertical direction extends in the horizontal direction, the drop-type connection between the ink storage chambers cannot exert a sufficient effect for preventing the movement of the bubbles. However, even in such a case, the upper space of each of the ink storage chambers 390 and 430 functions effectively as a trap space for the bubble that has flowed in, and the ink I remaining in the ink storage chamber 390 and 430 flows downstream of the bubble. It functions as a protective wall that prevents movement and reliably prevents the bubbles from moving downstream.

  Further, even if the bubble B enters the ink guide path 380 from the upper ink storage chamber 370, the remaining amount of ink that can be used in the ink guide path 380 or the ink storage chamber 390 bent downward to communicate with each other. For a while, it is possible to prevent the bubble B that has entered the ink guiding path from reaching the detection position by the ink remaining amount sensor 31, and it is not used up due to erroneous detection of the ink remaining amount sensor 31 due to the entry of the bubble. The problem of increasing the amount of ink discarded can be avoided.

  In the ink cartridge 1 described above, three ink storage chambers are defined in one cartridge body. However, the number of ink storage chambers provided in the cartridge body is an arbitrary number of three or more. As the number of ink storage chambers increases, the bubble traps are multiplexed, and the performance of preventing the bubbles from moving downstream is improved. In particular, as the number of ink storage chambers, descending connections, and ascending connections upstream of the remaining liquid sensor increases, it is possible to reliably prevent bubbles from reaching the detection position by the remaining liquid sensor.

  Next, an embodiment of a method for injecting ink into the used ink cartridge 1 when the ink I in the ink cartridge 1 described above is exhausted or reduced to a predetermined amount is shown in FIG. This will be described with reference to FIGS.

First, the configuration of the ink re-injection apparatus used in the regeneration method of the present embodiment will be described.
As shown in FIG. 13, the ink re-injection apparatus 600 includes an ink injection unit 610 connected to an injection port 601 opened in the cartridge main body 10 by punching, and a vacuum suction connected to the ink supply hole 50 of the cartridge main body 10. And means 620.

  The ink injection unit 610 includes an ink tank 611 that stores ink to be filled, a pump 613 that pumps the ink in the ink tank 611 to the flow path 612 connected to the injection port 601, and the pump 613 and the injection port 601. And a valve 614 that opens and closes the flow path 612.

  The vacuum suction unit 620 includes a vacuum pump 621 that generates a negative pressure necessary for vacuum suction, a liquid guide path 622 that applies the negative pressure generated by the vacuum pump 621 to the ink supply hole 50, and a midway of the liquid guide path 622. The ink trap 623 that captures and collects the ink flowing into the liquid guiding path 622 from the cartridge body 10 side by vacuum suction and protects the vacuum pump 621 from ink mist, and the ink trap 623 and ink supply A valve 624 that opens and closes the liquid guide path 622 with the hole 50 is provided.

  In the present embodiment, in consideration of the structure and function of the ink cartridge 1, the position where the inlet 601 communicating with the upper ink storage chamber 370 is formed in the atmosphere communication path 150 forms a part of the atmosphere communication path 150. The vicinity of the position facing the through hole 372 located at the downstream end of the liquid guide path 360.

  The injection port 601 facing the through hole 372 is formed by making a hole in the outer surface film 60 covering the back side of the cartridge body 10 so as to coincide with the through hole 372. For example, when the front end of the channel 612 inserted into the inlet 601 is pressed against the through-hole 372, the tip of the channel 612 is tightly adhered to the container wall surface around the through-hole 372, and the channel 612 and the through-hole 372 are in close contact. And a seal ring or the like is provided.

  The injection port 601 on the cartridge body 10 may be in a form that directly communicates with the uppermost upper ink storage chamber 370, and the installation position of the injection port 601 need not be limited to the position opposite to the through hole 372. Absent. For example, when the injection port 601 is formed from the back side of the cartridge body 10, as shown in FIG. 14, corresponding to the region of the upper ink storage chamber 370, the serpentine 310 and the ink guide path provided on the back side. An appropriate position P2 that does not interfere with 380 can be set as the equipment position of the inlet 601.

  In the injection method in the present embodiment, first, an injection port forming step of opening the injection port 601 in the cartridge main body 10 so as to communicate with the upper ink storage chamber 370, ink remaining inside the ink supply hole 50, and residual ink A vacuum suction process for sucking and removing gas by the vacuum suction means 620, a liquid filling process for injecting a predetermined amount of ink from the injection port 601 by the ink injection means 610, and a seal for sealing the injection port 601 after the liquid filling process is completed. By performing the stopping process in order, the used ink cartridge 1 is revived as a reusable reusable ink cartridge (recycled liquid container).

  Specifically, the sealing step is a treatment step in which the inlet 601 is sealed or sealed with a sealing film or tape, or airtightly closed with a stopper or the like.

  In the method for regenerating the ink cartridge 1 according to the present embodiment described above, the processing performed on the ink cartridge 1 for injecting the ink I is performed by injecting ink so as to communicate with the uppermost ink storage chamber 370 in the uppermost stream. Opening the injection port 601 for performing the process and sealing the injection port 601 after the ink I is filled are both simple processes. Therefore, the processing cost is low and it does not take time and effort.

  The reproduction method of the present embodiment includes a vacuum suction process for sucking and removing ink and residual gas remaining inside from the ink supply hole 50, so that liquid filling is performed to inject a predetermined amount of ink from the inlet 601. In the process, each ink guide path 380, 420, 440 and each ink storage chamber of the cartridge body 10 are managed in a reduced pressure environment, and the injected ink is not only supplied to the ink storage chambers 370, 390, 430, but also the ink supply holes 50. It is possible to efficiently fill every corner of all the ink guide paths leading to.

Also, air bubbles mixed during the filling of the ink I are removed to the outside from the ink supply hole 50 by vacuum suction, or the inflowed bubbles are dissolved and extinguished in the liquid by the reduced pressure environment in the container formed by vacuum suction. be able to.
Therefore, the bubbles B mixed during the injection of the ink I do not float in the ink storage chamber or the ink guide path or remain attached to the flow path wall surface. For example, in the vicinity of the detection part of the liquid remaining amount sensor. There is no inconvenience that the liquid remaining amount sensor does not operate normally due to the bubbles B remaining.

Further, since the position where the injection port 601 is provided is the uppermost upper ink storage chamber 370, all of the plurality of ink storage chambers provided in the cartridge body 10 and the liquid guide path connecting the ink storage chambers to each other are provided. Ink can be injected smoothly.
Therefore, in the regenerated ink cartridge 1 into which ink has been injected, the ink guide path 380 that is a liquid guide path that connects the ink storage chambers in a descending manner and the ink guide path 420 that is a fluid guide path that connects the ink storage chambers are bent up and down. Thus, even if the bubble B is generated in the upstream ink storage chamber 370, the ink I remaining in the descending liquid guiding path serves as a protective wall that stops the movement of the bubbles downstream. For this reason, it is difficult for the bubbles B that have entered the ink guide path 380 to travel downstream.
Further, in addition to the vertically bent flow path connecting the ink storage chambers, the upper space of each of the downstream ink storage chambers 390 and 430 functions effectively as a trap space for the bubble that has flowed in. Stop moving to.

That is, the bubble trap function in the liquid guiding paths 380 and 420 between the ink storage chambers and the bubble trap function in the downstream ink storage chambers 390 and 430 are restored as in the case of the new manufacture of the ink cartridge 1.
Accordingly, as in the case of the newly manufactured ink cartridge 1, it is possible to suppress the bubble B that has entered the ink guide path from the ink storage chamber from reaching the detection position by the ink remaining amount sensor 31. It is possible to avoid the problem that the amount of ink discarded without being used up due to erroneous detection of the liquid remaining amount sensor due to the entry increases.

  That is, according to the method for regenerating the ink cartridge 1 in the present embodiment, when the ink is injected into the used ink cartridge 1, the processing of the ink cartridge 1 can be reduced, and various types of ink cartridge 1 can be used. Ink can be injected without impairing the function, and the recycled ink cartridge 1 can be manufactured at low cost.

  If a regenerated ink cartridge regenerated by such a regenerating method is provided, the product life as a container of the ink cartridge is extended, which can contribute to resource saving and prevention of environmental pollution. In addition, since the cost required for reproduction is low and can be provided at a low cost, it contributes to a reduction in the operating cost of the ink jet recording apparatus.

  In the ink cartridge 1 of the above-described embodiment, the ink guide path 420 that connects the pair of ink storage chambers with the ascending connection is the upstream ink end sensor liquid guide path 400 and the downstream ink end sensor liquid guide path 410. The lower ink storage chamber 390 and the buffer chamber 430 are connected to each other, and the lower ink storage chamber 390 and the buffer chamber 430 are not directly connected by the ink guide path 420. Of course, the liquid storage container of the present invention is not limited to such a configuration, and a pair of liquid storage chambers may be connected in series to alternately repeat a descending connection and an ascending connection. Needless to say.

  Further, in the ink cartridge 1 of the above embodiment, the ink guide path 420 is set to the ascending type connection after the descending type ink guiding path 380, and then the outlet channel 450 is set after the rising type connection ink guiding path 440. It is a descent type connection, and is a configuration in which a plurality of combinations having a descent type connection and an ascending type connection (the order of descent and ascending does not matter) are provided. Here, when the liquid storage container of the present invention includes four or more liquid storage chambers, it is sufficient that these liquid storage chambers have at least one descending connection and ascending connection. As a matter of course, the other liquid storage chambers can be connected to each other appropriately by other connection forms such as a drop-type connection or a rise-type connection, or a horizontal connection in which the liquid flow direction is a horizontal flow.

Furthermore, the liquid container produced according to the present invention is not limited to the ink cartridge shown in the above embodiment. Further, the liquid consuming apparatus provided with the container mounting portion to which the liquid container manufactured according to the present invention is mounted is not limited to the ink jet recording apparatus shown in the above embodiment.
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.

  1: ink cartridge (liquid container), 10: cartridge body (container body), 11: engagement lever, 20: lid member, 30: ink end sensor, 31: ink remaining amount sensor (liquid remaining amount sensor), 40 : Differential pressure valve, 50: ink supply hole (liquid supply hole), 70: gas-liquid separation filter, 80: film, 90: sealing film (blocking means), 100: atmosphere opening hole, 150: atmosphere communication path, 220: Carriage, 330: upper connection flow path, 340: ink trap chamber (air chamber), 350: connection buffer chamber (air chamber), 370: upper ink storage chamber (liquid storage chamber), 371, 432: ink discharge port (liquid 374, 394, 434: depression, 375, 395, 435: bottom wall of liquid storage chamber, 380: ink guide path (liquid guide path), 390: lower ink storage chamber ( Body accommodating chamber), 391, 431: ink inlet (liquid inlet), 400: upstream ink end sensor liquid guiding path (liquid guiding path), 410: downstream ink end sensor liquid guiding path (liquid guiding path), 420: ink guide path (liquid guide path), 430: buffer chamber (liquid storage chamber), 501, 511, 512, 521: unfilled chamber (deaeration chamber), 600: ink re-injection device, 601: injection port, 610: Ink injection means, 620: Vacuum suction means.

Claims (2)

  In a liquid storage container mounted on a liquid consumption device,
  A liquid storage chamber for storing a liquid, the liquid storage chamber including a first liquid storage chamber, a second liquid storage chamber, and a third liquid storage chamber;
  A remaining liquid sensor for detecting that the remaining amount of liquid in the liquid storage chamber has decreased to a predetermined amount; and
  A first liquid guiding path that connects the first liquid storage chamber and the second liquid storage chamber located downstream thereof, and the liquid flow direction in a state in which the liquid storage container is mounted on the liquid consumption device A first liquid guiding path that is a descending flow from top to bottom;
  A second liquid guiding path for communicating the second liquid storage chamber and the third liquid storage chamber located downstream thereof via the liquid remaining amount sensor, wherein the liquid storage container is attached to the liquid consuming device; A second liquid guiding path in which the liquid flow direction is an upward flow from the bottom to the top,
  An atmosphere communication path for communicating the liquid storage chamber with the atmosphere;
With
  A liquid storage container formed by injecting a liquid from an injection port formed in the atmosphere communication path and communicating with the liquid storage chamber, and then sealing the injection port with a sealing member.   In a liquid storage container mounted on a liquid consumption device,
  1st liquid induction | guidance | derivation which is at least 3 or more liquid storage chambers which store a liquid, Comprising: The said liquid storage container is mounted | worn with the said liquid consumption apparatus, and the flow direction of a liquid becomes a downward flow from the top to the bottom A liquid storage chamber including a pair of liquid storage chambers connected by a path and a pair of liquid storage chambers connected by a second liquid guide path in which the flow direction of the liquid is an upward flow from the bottom to the top;
  An atmosphere communication path for communicating the liquid storage chamber with the atmosphere;
With
  A liquid storage container formed by injecting a liquid from an injection port formed in the atmosphere communication path and communicating with the liquid storage chamber, and then sealing the injection port with a sealing member.

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