This application claims priority to Japanese Patent Application No. 2012-191474 filed on Aug. 31, 2012, and Japanese Patent Application No. 2012-213719 filed on Sep. 27, 2012. The entire disclosures of Japanese Patent Application Nos. 2012-191474 and 2012-213719 are hereby incorporated herein by reference.
1. Technical Field
The present invention relates to a liquid container manufacturing method, a liquid container, and the like.
2. Related Art
In the related art, a technique is known of using an ink cartridge (alternatively referred to as simply a “cartridge”) as a technique for supplying ink to a printer, which is an exemplary liquid-jet apparatus. When a cartridge is manufactured, ink is injected into the internal portion of the cartridge. The cartridge is attached to a printer, and ink inside the cartridge flows through a supply opening to the printer. In the related art, when ink is consumed until little or no ink remains in a cartridge, the cartridge is replaced with a new cartridge. Alternatively, after a cartridge is used up, it may be recycled by again injecting ink into the cartridge. The related art cartridge may include a detection member (e.g., a piezoelectric element or a prism, also referred to as a first member) that can be used to detect the ink residual state (i.e., whether or not ink remains or how much ink remains). (Refer to, for example, JP-A-2010-5958.).
Incidentally, in order to increase the amount of ink in a cartridge, it is conceivable to increase the capacity of a container portion that contains ink in the cartridge. An exemplary method of increasing the capacity of the container portion is to increase the area of the container portion in directions that, with respect to the orientation in which the cartridge is used, intersect the vertical direction. This can avoid an increase in the size of the cartridge in the vertical direction. However, when the area of the container portion is increased in directions that intersect the vertical direction, the detection precision in detecting the ink residual amount tends to decrease. The reason for this is that, even though the residual amount of ink is the same, the height of the ink surface in a larger-volume cartridge will be lower than in a smaller-volume cartridge.
In order to address this problem, it is conceivable to partition off a small chamber having a volume smaller than that of the container portion, and to provide a detection member in the small chamber. With such a small chamber, even when little ink remains it easier to keep the liquid surface high in the small chamber. Thus, a decrease in the detection precision in detecting the ink residual amount can be avoided. As a method of injecting ink into the thus configured cartridge, a method in which ink is injected at a location other than the small chamber may be employed. However, when using the method in which ink is injected from a location other than the small chamber, it is difficult to distribute a sufficient amount of ink to the small chamber. As a result, there is a problem in that the detection precision in detecting the ink residual amount tends to drop. This sort of problem occurs not only in a cartridge that internally contains ink, but also in other liquid containers that contain liquid other than ink.
An advantage of some aspects of the invention can be achieved in the following modes or application examples.
Application Example 1 is directed to a method of manufacturing a liquid container as follows. The liquid container includes a casing provided with a container portion containing liquid, a supply opening through which the liquid inside the container portion is supplied to the outside, and a detection member for detecting an amount of the liquid inside the container portion. The container portion in the casing is divided into a first container chamber containing the liquid, a second container chamber provided downstream of the first container chamber with respect to a flow of the liquid from the container portion toward the supply opening, and in communication with the first container chamber, a third container chamber provided downstream of the second container chamber and in communication with the second container chamber, and a fourth container chamber provided downstream of the third container chamber and in communication with the third container chamber. The fourth container chamber is provided inside the third container chamber and is partitioned by a first sheet member from the third container chamber. The detection member is provided inside the fourth container chamber. In this liquid container, an injection opening in communication with the container portion is formed at the fourth container chamber or on the side downstream of the fourth container chamber, and liquid is injected from the injection opening.
According to this application example, the liquid is injected into the container portion from an injection opening that is formed at the fourth container chamber provided with the detection member or on the side downstream of the fourth container chamber. Thus, the injected liquid is easily introduced into the fourth container chamber. Thus, a decrease in the precision in detecting the amount of liquid can be more readily avoided.
Application Example 2 is directed to the method of manufacturing a liquid container as follows. The injection opening is formed at the fourth container chamber.
According to this application example, the liquid can be directly injected into the fourth container chamber. Thus, the injected liquid is easily introduced into the fourth container chamber.
Application Example 3 is directed to the method of manufacturing a liquid container as follows. In the casing, a channel from the third container chamber to the fourth container chamber includes a first outer wall channel that is provided on a second outer wall of the casing, and the first outer wall channel is sealed by a third sheet member from the outside of the casing. Furthermore, the injection opening is formed from the second outer wall side through a region of the third sheet member in which the third sheet member overlaps a communication opening that is open from the first outer wall channel toward an internal space of the fourth container chamber.
According to this application example, the liquid can be directly injected into the fourth container chamber. Thus, the injected liquid is easily introduced into the fourth container chamber.
Application Example 4 is directed to the method of manufacturing a liquid container as follows. A first outer wall of the casing is provided with an opening portion that is open from the outside of the casing toward an internal space of the fourth container chamber. The detection member is light-transmissive and projects from the opening portion into the fourth container chamber in a state in which the detection member covers the opening portion from the outside of the casing. Furthermore, the injection opening is formed at the detection member.
According to this application example, the liquid can be directly injected into the fourth container chamber. Thus, the injected liquid is easily introduced into the fourth container chamber.
Application Example 5 is directed to the method of manufacturing a liquid container as follows. A first outer wall of the casing is provided with an opening portion that is open from the outside of the casing toward an internal space of the fourth container chamber. The detection member is light-transmissive and projects from the opening portion into the fourth container chamber in a state in which the detection member covers the opening portion from the outside of the casing. The injection opening is formed by detaching the detection member from the casing, thereby exposing the opening portion, and the liquid is injected from the opening portion functioning as the injection opening.
According to this application example, the liquid can be directly injected into the fourth container chamber. Thus, the injected liquid is easily introduced into the fourth container chamber.
Application Example 6 is directed to the method of manufacturing a liquid container as follows. In the casing, a valve that allows the liquid to flow from the fourth container chamber toward the supply opening and that blocks flow of the liquid from the supply opening toward the fourth container chamber is provided between the fourth container chamber and the supply opening. Furthermore, the injection opening is formed at a channel from the fourth container chamber to the valve.
According to this application example, the liquid can be injected from the channel downstream of the fourth container chamber. Thus, the liquid flows through the channel downstream of the fourth container chamber and reaches the fourth container chamber. If air bubbles are mixed in with the injected liquid, the air bubbles are more readily caught in the channel while the liquid is flowing through the channel. Accordingly, mixing of air bubbles in the ink in the fourth container chamber can be more readily avoided. As a result, attachment of air bubbles to the detection member can be more readily suppressed, and, thus, it is easier to avoid a decrease in the precision in detecting the amount of liquid.
Application Example 7 is directed to the method of manufacturing a liquid container as follows. The channel from the fourth container chamber to the valve includes a second outer wall channel that is provided on a second outer wall of the casing, and the second outer wall channel is sealed by a third sheet member from the outside of the casing. Furthermore, the injection opening is formed through the third sheet member in the second outer wall channel.
According to this application example, the injection opening is formed through the third sheet member. Thus, formation of the injection opening through the casing can be avoided.
Application Example 8 is directed to the method of manufacturing a liquid container as follows. A first outer wall of the casing is provided with an opening portion that is open from the outside of the casing toward an internal space of the fourth container chamber. The detection member is light-transmissive and projects from the opening portion into the fourth container chamber in a state in which the detection member covers the opening portion from the outside of the casing. The channel from the fourth container chamber to the valve includes a third outer wall channel that is provided on the first outer wall of the casing, and the third outer wall channel is sealed from the outside of the casing by a second sheet member that is light-transmissive. Furthermore, the injection opening is formed through the second sheet member in the third outer wall channel.
According to this application example, the liquid can be injected from the first outer wall side provided with the light-transmissive detection member, through the third outer wall channel, into the container portion. Accordingly, the state of the liquid being injected can be seen through the detection member when the liquid is injected.
Application Example 9 is directed to the method of manufacturing a liquid container as follows. The channel from the fourth container chamber to the valve is provided with a bent portion, and at least part of a channel from the bent portion to the valve overlaps the valve. Furthermore, the injection opening is formed at a location in which the channel from the bent portion to the valve overlaps the valve.
According to this application example, at least part of the liquid injected from the injection opening flows through the bent portion and reaches the fourth container chamber. If air bubbles are mixed in with the injected liquid, the air bubbles are more readily caught in the bent portion while the liquid is flowing through the bent portion. Accordingly, it is easier to avoid mixing of air bubbles in the ink in the fourth container chamber.
Application Example 10 is directed to a liquid container manufactured using the above-described method of manufacturing a liquid container.
According to the liquid container of this application example is manufactured using a manufacturing method that can easily introduce the injected liquid into the fourth container chamber. Thus, with this liquid container, a decrease in the precision in detecting the amount of liquid can be more readily avoided.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
Hereinafter, using a liquid-jet system as an example, embodiments will be described with reference to the drawings. Note that, in the drawings, the constituent components and members may be shown in different scales, so that each constituent component is large enough to be recognized.
Configuration of the Liquid-Jet System
As shown in
The holder 3 is provided with a print head (not shown) for ejecting ink, at a side thereof opposing the printing paper PA. The cartridges 10 are detachably mounted in the holder 3. Each cartridge 10 contains a different colored ink, such as cyan, magenta, and yellow. Ink contained in the cartridges 10 is supplied to the print head of the holder 3, and is ejected onto the printing paper PA.
The first motor 5 drives the holder 3 in the main-scanning direction. The second motor 7 transports the printing paper PA in the sub-scanning direction. The control unit 9 controls the overall operation of the printer 1. The detecting device 15 is provided in the printer 1, and optically detects the residual amount of ink in the cartridges 10. In this embodiment, as a method of detecting the ink residual amount, a method is employed in which the detecting device 15 detects whether or not the residual amount of ink in the cartridges 10 becomes lower than a predetermined amount.
The control unit 9 controls the first motor 5, the second motor 7, and the print head to print based on print data that has been received from a computer 17 or the like, connected via the predetermined interface 13. The control unit 9 determines the ink residual state (i.e., how much ink remains or whether or not ink remains) in the cartridges 10, based on a result received from the detecting device 15. The operation portion 12 is connected to the control unit 9, and accepts various operations from a user.
Configuration of the Cartridges
The cartridges 10 are each substantially in the shape of a rectangular parallelepiped, as shown in
The outer surface (outer shell) of the cartridge 10 includes six faces 11. Hereinafter, when identifying each of the six faces 11, the six faces 11 are respectively referred to as a bottom face 11a, a top face 11b, a front face 11c, a rear face 11d, a right face 11e, and a left face 11f. The six faces 11 can be considered also as an outer shell member forming the outer shell of the cartridge 10. Each face 11 is planar. The term “planar” here encompasses a face whose entire area is completely flat, and faces that are partially uneven. That is to say, a face may be partially uneven to some extent. The external appearance of each face 11 is substantially rectangular in plan view. The outer surface (exterior surface) of the cartridge 10 includes a film 21 forming part of the left face 11f, a casing 23, a cover 25, and a cover 27 forming the right face 11e.
The bottom face 11a is a general concept that encompasses a wall forming the bottom wall of the cartridge 10, with respect to the mounted orientation of the cartridge 10, and may also be referred to as a “bottom face wall portion (bottom wall)”. The top face 11b is a general concept that encompasses a wall forming the top wall of the cartridge 10, with respect to the mounted orientation of the cartridge 10, and may also be referred to as a “top face wall portion (top wall)”. The front face 11c is a general concept that encompasses a wall forming the front face wall of the cartridge 10 with respect to the mounted orientation of the cartridge 10, and may also be referred to as a “front face wall portion (front face wall)”. The rear face 11d is a general concept that encompasses a wall forming the rear face wall with respect to the mounted orientation of the cartridge 10, and may also be referred to as a “rear face wall portion (rear face wall)”. The right face 11e is a concept that encompasses a wall forming the right wall with respect to the mounted orientation of the cartridge 10, and may also be referred to as a “right face wall portion (right face wall)”. The left face 11f is a general concept that encompasses a wall forming the left wall with respect to the mounted orientation of the cartridge 10, and may also be referred to as a “left face wall portion (left face wall)”. Note that a “wall portion” or a “wall” need not be configured from a single wall, but may be configured from a plurality of walls. For example, the bottom face wall portion (the bottom face 11a) is the wall positioned on the negative direction side of the Z axis from the internal space of the cartridge 10, with respect to the mounted orientation of the cartridge 10. In other words, as shown in
The bottom face 11a and the top face 11b oppose each other, and are separated from each other, in the Z axis direction. The front face 11c and the rear face 11d oppose each other, and are separated from each other, in the X axis direction. The right face 11e and the left face 11f oppose each other, and are separated from each other, in the Y axis direction. The length (the size in the X axis direction) is the largest dimension of the cartridge 10, followed by the width (the size in the Y axis direction) and the height (the size in the Z axis direction) in this order. Note that the relationship in size between the length, the width, and the height of the cartridge 10 can be freely changed. For example, the descending order in size may be the height, the length, and then the width. Alternatively, the height, the length, and the width may be the same size.
As shown in
The bottom face 11a is provided with the detection member 29. In this embodiment, the detection member 29 is provided at a position that is closer to the rear face 11d than to the front face 11c. In other words, the detection member 29 is provided closer to the rear face 11d than is the position at which the supply portion 31 is provided on the bottom face 11a. The detection member 29 is used in the process to detect the liquid residual state in the cartridge 10 by the detecting device 15. The detection member 29 is transparent, and covers from the outside an opening portion (described later) in the bottom face 11a of the casing 23. The opening portion in the bottom face 11a of the casing 23 is in communication with a container portion (described later) that contains ink. In this embodiment, the container chamber can be seen through the detection member 29. Note that the detection member 29 may be translucent.
As shown in
As shown in
Note that the directions of the cartridge 10 can be prescribed as below using the XYZ axes, which are coordinate axes orthogonal to each other. The direction in which the bottom face 11a and the top face 11b oppose each other matches the Z axis direction. In the Z axis direction, the direction from the bottom face 11a to the top face 11b is the positive direction of the Z axis. In the Z axis direction, the direction from the top face 11b to the bottom face 11a is the negative direction of the Z axis. Also, the direction in which the front face 11c and the rear face 11d oppose each other matches the X axis direction. In the X axis direction, the direction from the rear face 11d to the front face 11c is the positive direction of the X axis. In the X axis direction, the direction from the front face 11c to the rear face 11d is the negative direction of the X axis. Also, the direction in which the right face 11e and the left face 11f oppose each other matches the Y axis direction. In the Y axis direction, the direction from the left face 11f to the right face 11e is the positive direction of the Y axis. In the Y axis direction, the direction from the right face 11e to the left face 11f is the negative direction of the Y axis.
The directions of the cartridge 10 can be prescribed as below using the XYZ axes, which are coordinate axes orthogonal to each other. The direction in which the supply portion 31 extends from the bottom face 11a matches the Z axis direction. In the Z axis direction, the direction from the upstream to the downstream in the fluid flow is the negative direction of the Z axis. In the Z axis direction, the direction from the downstream to the upstream in the fluid flow is the positive direction of the Z axis. Also, it can be said that the movement direction of the cartridge 10 when being attached to or detached from the holder 3 matches the Z axis direction. In the Z axis direction, the movement direction of the cartridge 10 when being attached to the holder 3 is the negative direction of the Z axis. In the Z axis direction, the movement direction of the cartridge 10 when being detached from the holder 3 is the positive direction of the Z axis. Also, the direction that the cartridge 10 mounted on the holder 3 moves in the main-scanning direction under the drive of the first motor 5 (
As shown in
Hereinafter, the casing 23 will be described. The casing 23 has five walls 71 as shown in
The first wall 71a and the third wall 71c oppose each other, and are separated from each other, in the Z axis direction. The fourth wall 71d and the fifth wall 71e oppose each other, and are separated from each other, in the X axis direction. The second wall 71b intersects the first wall 71a, the third wall 71c, the fourth wall 71d, and the fifth wall 71e. Also, the first wall 71a intersects the fourth wall 71d and the fifth wall 71e. Also, the third wall 71c intersects the fourth wall 71d and the fifth wall 71e. Accordingly, the casing 23 is formed in the shape of a recessed box whose bottom corresponds to the second wall 71b. The back faces of the walls 71 form inner walls 73 of the casing 23, which is in the shape of a recessed box. The casing 23 has five inner walls 73 respectively corresponding to the five walls 71. Hereinafter, when identifying each of the five inner walls 73, the five inner walls 73 are respectively referred to as a first inner wall 73a, a second inner wall 73b, a third inner wall 73c, a fourth inner wall 73d, and a fifth inner wall 73e. The first inner wall 73a corresponds to the first wall 71a. In a similar manner, the second inner wall 73b corresponds to the second wall 71b, the third inner wall 73c corresponds to the third wall 71c, the fourth inner wall 73d corresponds to the fourth wall 71d, and the fifth inner wall 73e corresponds to the fifth wall 71e.
A plurality of partition plates 75 are provided inside the casing 23. The internal space of the casing 23 is partitioned by the plurality of partition plates 75 into a plurality of chambers. In this embodiment, three partition plates 75 are provided inside the casing 23, and the internal space of the casing 23 is partitioned by the three partition plates 75 into five chambers. Hereinafter, when identifying each of the three partition plates 75, the three partition plates 75 are respectively referred to as a first partition plate 75a, a second partition plate 75b, and a third partition plate 75c. The first partition plate 75a extends in the Z axis direction from the third inner wall 73c to the first inner wall 73a (the back face of the first wall 71a). The second partition plate 75b extends in the X axis direction from the fourth inner wall 73d (the back face of the fourth wall 71d) to the fifth inner wall 73e. The first partition plate 75a and the second partition plate 75b intersect each other. The third partition plate 75c is positioned between the first partition plate 75a and the fifth inner wall 73e, and is provided in the Z axis direction connecting the third inner wall 73c and the second partition plate 75b.
Of the five chambers partitioned by the three partition plates 75, three chambers sandwiched between the first partition plate 75a and the fifth inner wall 73e function as a container portion 81 that contains ink. Meanwhile, two chambers sandwiched between the first partition plate 75a and the fourth inner wall 73d (the back face of the fourth wall 71d) function as an atmospheric introduction portion 83 that introduces atmospheric air. The atmospheric introduction portion 83 includes a first atmospheric chamber 84a and a second atmospheric chamber 84b. The container portion 81 includes a first container chamber 85, a second container chamber 87, and a third container chamber 89. A bank 91 is provided inside the third container chamber 89. The bank 91 is provided in a loop shape on the second inner wall 73b, and projects from the second inner wall 73b. The region surrounded by the bank 91 is partitioned from the third container chamber 89 as a fourth container chamber 93. That is to say, the third container chamber 89 internally includes the fourth container chamber 93.
The end portions of the three partition plates 75 on the side opposite the second inner wall 73b, and the end portions of the four walls 71 excluding the second wall 71b on the side opposite the second inner wall 73b, all have the same height in the Y axis direction. The film 65 shown in
The end portion of the bank 91 on the side opposite from the second inner wall 73b is positioned closer to the second inner wall 73b than are any of the end portions of the three partition plates 75 on the side opposite from the second inner wall 73b. That is to say, the height in the Y axis direction of the bank 91 is lower than the height in the Y axis direction of each of the three partition plates 75. Thus, the fourth container chamber 93 surrounded by the bank 91 is included inside the third container chamber 89. As shown in
As shown in
As shown in
The valve unit 51 includes a valve body 111, a spring 113, and a spring washer 115. The valve unit 51 opens and closes a channel by the valve body 111 deforming under a pressure difference in the channel between upstream and downstream of the valve body 111, in the direction of flow of fluid from the atmospheric opening port 45 to the supply opening 33. The spring 113 biases the valve body 111 in a direction that presses the valve body 111 against the valve hole 106. Operation of the valve body 111 adjusts the pressure on the side downstream of the valve chamber 101 (alternately referred to as a “valve downstream side”) to be lower than the pressure on the side upstream from the valve chamber 101 (alternately referred to as a “valve upstream side”), so that the valve downstream side has a negative pressure with respect to atmospheric pressure as a reference. When the cartridge 10 is attached to the printer 1 and ink at the valve downstream side is consumed, the absolute value of the negative pressure at the valve downstream side increases, and the valve body 111 deforms away from the valve hole 106. At this time, ink inside the valve chamber 101 is supplied to the side downstream of the valve chamber 101, and the negative pressure on the valve downstream side returns to a predetermined range. As a result, the valve body 111 deforms under the force of the spring 113 to cover the valve hole 106. Also, atmospheric air (air) is introduced through the atmospheric opening port 45 into the container portion 81 as ink inside the container portion 81 is consumed.
The supply portion unit 53 is provided inside the supply portion 31. The supply portion unit 53 includes a seal member 117, a spring washer 119, and a spring 121. While the liquid supply needle of the printer 1 is in the supply portion 31, the seal member 117 seals any gaps between the inner wall of the supply portion 31 and the outer wall of the liquid supply needle. When the cartridge 10 is not mounted in the holder 3, the spring washer 119 is in contact with the seal member 117, and blocks the channel inside the supply portion 31. The spring 121 biases the spring washer 119 in a direction in which the spring washer 119 is brought into contact with the seal member 117. When the liquid supply needle is inserted into the supply portion 31, the liquid supply needle lifts the spring washer 119 in the positive direction of the Z axis, a gap is formed between the spring washer 119 and the seal member 117, and ink is supplied through this gap to the liquid supply needle.
As shown in
The prism portion 127 projects into the fourth container chamber 93, and functions as a detection member that the detecting device 15 of the printer 1 uses for optically detecting whether or not ink is present. The prism portion 127 is, for example, a light-transmissive member that is made of a synthetic resin such as polypropylene. The detection member 29 including the prism portion 127 may be made of a material that is not transparent, as long as it is light-transmissive to an appropriate extent. In situations where no optical detection is performed, the detection member 29 need not be light-transmissive. Furthermore, if no optical detection is performed, an opaque member or coating may be applied to the surface of the prism portion 127. Whether or not ink is present in the fourth container chamber 93 is detected, for example, as follows. The detecting device 15 that is provided at the printer 1 is provided with an optical sensor having a light-emitting element and a light-receiving element. The light-emitting element emits light toward the prism portion 127 of the detection member 29. When ink is present around the prism portion 127, light is transmitted through the prism portion 127, and enters the fourth container chamber 93. On the other hand, when ink is not present around the prism portion 127, light emitted from the light-emitting element is reflected from two reflecting faces of the prism portion 127, and impinges on the light-receiving element. The printer 1 determines whether or not ink is present in the fourth container chamber 93, based on whether or not light impinges on the light-receiving element.
As described above, the fourth container chamber 93 is provided inside the third container chamber 89. The volume of the fourth container chamber 93 is smaller than that of the third container chamber 89. The bottom area of the third container chamber 89 in directions that intersect the vertical direction is larger than that of the fourth container chamber 93. The prism portion 127 projects into the fourth container chamber 93, which has a volume smaller than that of the third container chamber 89. That is to say, this embodiment employs a configuration that detects the ink residual amount by detecting the amount of ink in the fourth container chamber 93 via the prism portion 127, which is provided inside the fourth container chamber 93.
Note that it is also possible to detect whether or not ink is present (detect the ink residual amount), using a configuration in which the fourth container chamber 93 is omitted, and the prism portion 127 is provided inside the third container chamber 89, for example. With this configuration, the ink residual amount is detected by detecting the amount of ink in the third container chamber 89. However, with this configuration, the detection precision in detecting the ink residual amount tends to be lower than that in the above-described embodiment. The reason for this is that, even though the height of the ink surface, which is used to detect the ink residual amount, varies by the same amount, the variation in the absolute amount of ink is greater when the area of the container portion is greater in directions that intersect the vertical direction.
In order to address this problem, this embodiment employs a configuration in which the fourth container chamber 93, which has a volume smaller than that of the third container chamber 89, is portioned inside the third container chamber 89, and the prism portion 127 is provided inside the fourth container chamber 93. Accordingly, even when the height of the ink surface, which is used to detect the ink residual amount, varies, the variation in the absolute amount of ink can be reduced. As a result, a decrease in the detection precision in detecting the ink residual amount can be avoided.
As described above, the film 61 shown in
As shown in
As shown in
Hereinafter, the channel from the atmospheric opening port 45 to the supply opening 33 will be described. For facilitating understanding, first, the channel from the atmospheric opening port 45 to the supply opening 33 will be conceptually described. Note that direction of fluid flow from the atmospheric opening port 45 to the supply opening 33 is considered as a fluid flow direction. The terms “upstream” or “downstream” are used based on this fluid flow direction. As shown in
The atmospheric opening port 45 and the separation chamber 103 are in communication with each other via a first internal channel 141 and a meandering channel 143. The first internal channel 141 is provided downstream of the atmospheric opening port 45. The atmospheric opening port 45 is in communication with the first internal channel 141. The meandering channel 143 is provided downstream from the first internal channel 141. The first internal channel 141 and the meandering channel 143 are in communication with each other through a communication opening 145. The meandering channel 143 and the separation chamber 103 are in communication with each other through a communication opening 147. The meandering channel 143 is configured to be long and meandering such that the length of the channel from the atmospheric opening port 45 to the first container chamber 85 is long. Accordingly, evaporation of liquid components of ink inside the container portion 81 can be suppressed. The filter 55 is disposed inside the separation chamber 103 so as to partition the channel. Even if ink flows backward from the first container chamber 85 upstream, the filter 55 can restrict flow of ink to the upstream side of the filter 55.
The separation chamber 103 and the first atmospheric chamber 84a are in communication with each other through an upper face channel 149 and a first surface channel 151. The upper face channel 149 is provided downstream from the separation chamber 103. The separation chamber 103 is in communication with the upper face channel 149 through a communication opening 153. The first surface channel 151 is provided downstream from the upper face channel 149. The upper face channel 149 and the first surface channel 151 are in communication with each other through a communication opening 155. The first surface channel 151 and the first atmospheric chamber 84a are in communication with each other through a communication opening 157.
The first atmospheric chamber 84a and the second atmospheric chamber 84b are in communication with each other through a second surface channel 159. The second surface channel 159 is provided downstream from the first atmospheric chamber 84a. The first atmospheric chamber 84a is in communication with the second surface channel 159 through a communication opening 161. The second surface channel 159 and the second atmospheric chamber 84b are in communication with each other through a communication opening 163.
If atmospheric air inside the container portion 81 expands due to a temperature increase or the like, and ink inside the container portion 81 flows backward to upstream from the first container chamber 85, the first atmospheric chamber 84a and the second atmospheric chamber 84b catch (trap) the backward flowing ink. Accordingly, the ink that flowed backward to upstream from the first container chamber 85 can be prevented from leaking from the atmospheric opening port 45. In this embodiment, of the plurality of atmospheric chambers, the second atmospheric chamber 84b, which is closer to the first container chamber 85 than the first atmospheric chamber 84a, has a volume larger than that of the first atmospheric chamber 84a. Accordingly, even if ink flows backward, the ink can be trapped further downstream (i.e., farther from the atmospheric opening port 45).
The second atmospheric chamber 84b and the first container chamber 85 are in communication with each other through a second internal channel 165, a third surface channel 167, and a third internal channel 169. The second internal channel 165 is provided downstream from the second atmospheric chamber 84b. The second atmospheric chamber 84b is in communication with the second internal channel 165 through a communication opening 171. The third surface channel 167 is provided downstream from the second internal channel 165. The second internal channel 165 and the third surface channel 167 are in communication with each other through a communication opening 173. The third internal channel 169 is provided downstream through the third surface channel 167. The third surface channel 167 and the third internal channel 169 are in communication with each other through a communication opening 175. The third internal channel 169 and the first container chamber 85 are in communication with each other through a communication opening 177.
In this embodiment, atmospheric air (air) that enters into the channel 100 through the atmospheric opening port 45 can flow to the first container chamber 85 and further downstream from the first container chamber 85, through the channel from the atmospheric opening port 45 to the third internal channel 169.
The first container chamber 85 and the second container chamber 87 are in communication with each other through a fourth surface channel 179. The fourth surface channel 179 is provided downstream from the first container chamber 85. The first container chamber 85 is in communication with the fourth surface channel 179 through a communication opening 181. The fourth surface channel 179 and the second container chamber 87 are in communication with each other through a communication opening 183.
The second container chamber 87 and the third container chamber 89 are in communication with each other through a fifth surface channel 185. The fifth surface channel 185 is provided downstream from the second container chamber 87. The second container chamber 87 is in communication with the fifth surface channel 185 through a communication opening 187. The fifth surface channel 185 and the third container chamber 89 are in communication with each other through a communication opening 189.
The third container chamber 89 and the fourth container chamber 93 are in communication with each other through a first lower face channel 191, a fourth internal channel 193, and a sixth surface channel 195. The first lower face channel 191 is provided downstream from the third container chamber 89. The third container chamber 89 is in communication with the first lower face channel 191 through a communication opening 197. The fourth internal channel 193 is provided downstream from the first lower face channel 191. The first lower face channel 191 and the fourth internal channel 193 are in communication with each other through a communication opening 199. The sixth surface channel 195 is provided downstream from the fourth internal channel 193. The fourth internal channel 193 and the sixth surface channel 195 are in communication with each other through a communication opening 201. The sixth surface channel 195 and the fourth container chamber 93 are in communication with each other through a communication opening 203.
The fourth container chamber 93 and the valve chamber 101 are in communication with each other through a seventh surface channel 205, a second lower face channel 207, and a first intra-casing channel 209. The seventh surface channel 205 is provided downstream from the fourth container chamber 93. The fourth container chamber 93 is in communication with the seventh surface channel 205 through a communication opening 211. The second lower face channel 207 is provided downstream from the seventh surface channel 205. The seventh surface channel 205 and the second lower face channel 207 are in communication with each other through a communication opening 213. The first intra-casing channel 209 is provided downstream from the second lower face channel 207. The second lower face channel 207 and the first intra-casing channel 209 are in communication with each other through a communication opening 215. The first intra-casing channel 209 and the valve chamber 101 are in communication with each other through a communication opening 217.
The valve chamber 101 and the supply opening 33 are in communication with each other through a second intra-casing channel 219, a third lower face channel 221, an eighth surface channel 223, and a supply path 225. The second intra-casing channel 219 is provided downstream from the valve chamber 101. The valve chamber 101 is in communication through the valve hole 106 with the second intra-casing channel 219. The third lower face channel 221 is provided downstream from the second intra-casing channel 219. The second intra-casing channel 219 and the third lower face channel 221 are in communication with each other through a communication opening 227. The eighth surface channel 223 is provided downstream from the third lower face channel 221. The third lower face channel 221 and the eighth surface channel 223 are in communication with each other through a communication opening 229. The supply path 225 is provided downstream from the eighth surface channel 223. The eighth surface channel 223 and the supply path 225 are in communication with each other through communication openings 231. Furthermore, the supply opening 33 is provided downstream from the supply path 225.
Next, the above-described channel 100 will be described with reference to the configuration of the casing 23.
As shown in
The meandering channel 143 is provided in the second wall 71b, and is configured by the groove 105 that is connected to the communication opening 145. The meandering channel 143 is in communication with the separation chamber 103 through the communication opening 147. In
As shown in
The communication opening 171 opens into the second atmospheric chamber 84b. As shown in
The communication opening 181 opens into the first container chamber 85. As shown in
The communication opening 187 opens into the second container chamber 87. As shown in
The communication opening 197 opens into the third container chamber 89. As shown in
The groove 105 that is connected to the communication opening 201 is the sixth surface channel 195, and in communication with the communication opening 203. The communication opening 203 is opened in the second wall 71b. As shown in
As shown in
When the cartridge 10 is manufactured, it is filled with ink to, for example, a liquid level ML1, which is a level of a liquid surface indicated by the broken line in
Method of Manufacturing the Cartridge
Hereinafter, a method of manufacturing the cartridge 10 will be described. In this embodiment, a method of manufacturing the cartridge 10 will be described wherein a cartridge 10 in which ink has been consumed until the ink residual amount reached a predetermined value or less, is again filled with ink (refill processing). Note that the method of manufacturing the cartridge 10 described below can be used also as a method of manufacturing the cartridge 10 by filling ink into an as yet unfilled, unused cartridge 10.
As shown in
The information update step S3 is a step of rewriting the information about ink consumption amount stored in the memory provided on the circuit board 40 of the cartridge 10, into a value indicating a sufficient amount of ink for printing. When ink is used until the residual amount of ink in the cartridge 10 reaches a predetermined value or less, information indicating a residual amount of ink that is at or below the predetermined value may be stored in the memory. In this case, even after the cartridge is refilled, the printer 1 may determine the cartridge 10 is empty, and may not commence normal printing operations. In this embodiment, in the information update step S3, the ink consumption amount information in the memory is updated to a value indicating an amount of ink that enables printing, that is, indicating that ink is contained in an amount that is more than the predetermined value. Accordingly, when the cartridge 10 is attached to the printer 1, the printer 1 commences normal printing operations. Note that the step S3 may be omitted.
When injecting ink in the injection step S2, for example, an injection system 1100 shown in
As shown in
As described above, the injection opening 250 can be formed by opening a hole through a wall that forms the channel 100. Once the injection opening 250 is formed, ink can be injected into the cartridge 10 through the injection opening 250. The injection opening 250 can be easily formed by opening a hole through, of the walls that form the channel 100, the film 21, the film 57, the film 61, the label 59, and the like.
In the tube attachment step S12, the tube 1110 is attached to the injection opening 250. Note that, if the tube 1110 is used to pierce the wall, the injection opening formation step S11 and the tube attachment step S12 are simultaneously performed.
In the atmospheric air suction step S13, the vacuum apparatus 1300 attached to the atmospheric opening port 45 sucks atmospheric air from inside the cartridge 10 through the atmospheric opening port 45. At this time, first the valve 1160 (
In the injection step S14 shown in
In the injection opening sealing step S15, the injection opening 250 is sealed. The injection opening 250 can be sealed, for example, with a film, an elastic member such as rubber and the like. Accordingly, the possibility that ink contained inside the cartridge 10 flows through the injection opening 250 to the outside can be reduced.
In the suction step S16, the suction apparatus 1400 shown in
In the sealing step S17, the atmospheric opening port 45 is sealed with the film 47, and the supply opening 33 is sealed with the film 35. Accordingly, the injection step S2 ends.
The cartridge 10 can be manufactured using this procedure. This embodiment employs a method in which ink is injected into the container portion 81 through the injection opening 250, which is formed in the channel 100 at a position that is in or downstream from the fourth container chamber 93, and that is also upstream from the valve hole 106. According to this method, the injected ink is easily introduced into the fourth container chamber 93. As a result, a decrease in the precision in detecting the amount of ink can be more readily avoided. Note that, in this embodiment, ink is injected into the container portion 81 from the injection opening 250 formed at the fourth container chamber 93, which is where the detection member 29 is provided, and, thus, ink can be directly injected into the fourth container chamber 93. Thus, the injected ink is easily introduced into the fourth container chamber 93. Accordingly, a decrease in the precision in detecting the amount of ink can be more readily avoided.
Furthermore, the location at which the injection opening 250 is formed is not limited to the fourth container chamber 93. The injection opening 250 may be formed, for example, through the film 21 at a location in which the film 21 overlaps the communication opening 203. The communication opening 203 is opened in the second wall 71b. Furthermore, the communication opening 203 also opens into the fourth container chamber 93. Thus, if the injection opening 250 is formed through the film 21 at a location in which the film 21 overlaps the communication opening 203, ink can be directly injected into the fourth container chamber 93.
Furthermore, the injection opening 250 may be formed, for example, at the detection member 29. The detection member 29 covers, from the outside of the casing 23, the opening portion 123 opened in the casing 23. Thus, if the injection opening 250 is formed at the detection member 29, the injection opening 250 opens into the internal space of the fourth container chamber 93. Thus, ink can be directly injected into the fourth container chamber 93 through the injection opening 250 formed at the detection member 29.
As a method of forming the injection opening 250, for example, a method may be employed in which the opening portion 123 opened in the casing 23 is used as the injection opening 250. According to this method, the detection member 29 is detached from the casing 23 and the opening portion 123 is exposed, and, thus, the opening portion 123 is used as the injection opening 250. Thus, ink can be directly injected into the fourth container chamber 93 through the opening portion 123 functioning as the injection opening 250.
The injection opening 250 may be formed, for example, between the fourth container chamber 93 and the valve chamber 101. In this case, ink can be injected from a channel downstream from the fourth container chamber 93, and, thus, the ink flows through the channel downstream from the fourth container chamber 93 and reaches the fourth container chamber 93. If air bubbles are mixed in with the injected ink, the air bubbles are more readily caught in the channel while the ink is flowing through the channel. Accordingly, air mixing in of bubbles in the fourth container chamber 93 can be more readily avoided. As a result, clinging of air bubbles to the detection member 29 can be more readily suppressed, and, thus, it is easier to avoid a decrease in the precision in detecting the amount of ink.
The injection opening 250 may be formed, for example, at the seventh surface channel 205. The seventh surface channel 205 is positioned downstream from the fourth container chamber 93. Ink can be injected from a channel downstream from the fourth container chamber 93, and, thus, the ink flows through the channel downstream from the fourth container chamber 93 and reaches the fourth container chamber 93. If air bubbles are mixed in with the injected ink, the air bubbles are more readily caught in the channel while the ink is flowing through the channel. Accordingly, mixing in of air bubbles in the fourth container chamber 93 can be more readily avoided. As a result, clinging of air bubbles to the detection member 29 can be more readily suppressed, and, thus, it is easier to avoid a decrease in the precision in detecting the amount of ink.
If the injection opening 250 is formed at the seventh surface channel 205, and a method is employed in which the injection opening 250 is formed through the film 21, then formation of the injection opening 250 through the casing 23 can be avoided.
The injection opening 250 may be formed, for example, at the second lower face channel 207. In this case, a method may be employed in which the injection opening 250 is formed through the film 57. In this embodiment, the film 57 is light-transmissive. If ink is injected from the second lower face channel 207 through an injection opening 250 formed through the film 57, the state of the ink being injected can be seen through the detection member 29 when the ink is injected.
Furthermore, the injection opening 250 may be formed, for example, at the first intra-casing channel 209. As shown in
Note that, in this embodiment, the optical member having the prism portion 127 is used as the detection member 29. However, the detection member 29 is not limited thereto, and various members may be used as long as they are members used to detect the ink residual state in the cartridge 10. As the detection member 29, for example, a piezoelectric element and the like also may be used.
In the foregoing embodiment, the film 61 corresponds to a first sheet member, the film 57 corresponds to a second sheet member, and the film 21 corresponds to a third sheet member. Furthermore, the first wall 71a corresponds to a first outer wall, and the second wall 71b corresponds to a second outer wall. Furthermore, the sixth surface channel 195 corresponds to a first outer wall channel, the seventh surface channel 205 corresponds to a second outer wall channel, the second lower face channel 207 corresponds to a third outer wall channel, and the bent portion 253 corresponds to a bent portion.
As described above, according to this embodiment, mixing of air bubbles in the fourth container chamber 93 at the time of ink injection can be more readily avoided. If air bubbles are mixed in with the ink in the fourth container chamber 93, the air bubbles in the fourth container chamber 93 may reach the print head. If the air bubbles reach the print head, the ink ejection performance of the print head may be lowered. That is to say, if air bubbles are mixed in with the ink in the fourth container chamber 93, a problem occurs in which the ink ejection performance may be lowered.
If ink is injected into the container portion 81 into or downstream from the fourth container chamber 93, air bubbles are more likely to mix in the ink downstream from the fourth container chamber 93. However, the supply opening 33 is provided downstream from the fourth container chamber 93. Thus, for example, when the cartridge 10 is attached to the printer 1, air bubbles mixed in with the ink downstream from the fourth container chamber 93 can be more readily discharged from the supply opening 33 in an initial stage, by the ink suction operation and the like.
On the other hand, if ink is injected into the container portion 81 from the side upstream from the fourth container chamber 93, air bubbles are more likely to mix in with ink upstream from the fourth container chamber 93. Air bubbles that have mixed in the ink upstream from the fourth container chamber 93 cannot be easily discharged in an initial stage. Thus, air bubbles that have been mixed in the ink upstream from the fourth container chamber 93 may flow through the fourth container chamber 93 and reach the print head during printing. Accordingly, it is preferable that ink is injected into the container portion 81 from the fourth container chamber 93 or the side downstream from the fourth container chamber 93 also for the purpose of avoiding air bubbles reaching the print head during printing.
The fourth container chamber 93 is partitioned off by the film 61 inside the third container chamber 89. That is to say, the film 61 is disposed inside the third container chamber 89. Thus, if the injection opening 250 is formed upstream from the fourth container chamber 93, the possibility that the film 61 will be damaged increases. This possibility increases particularly when ink is injected from the film 65 side. It is difficult to repair the damaged film 61. Thus, also in order to avoid damage to the film 61, it is preferable that ink is injected into the container portion 81 from the fourth container chamber 93 or downstream from the fourth container chamber 93.
In the printer 1 in this embodiment, when little or no ink remains in the cartridge 10, the cartridge is replaced by a new cartridge 10 having a sufficient residual amount. However, the mode of the printer 1 is not limited to this. The printer 1 may be embodied in another mode in which ink is supplied to the print head from tanks having an ink capacity larger than that of the cartridges 10. As shown in
Ink in the tanks 2100 is supplied through the tubes 2300 to the relay units 2200. The ink supplied to the relay units 2200 is further supplied to the print head (not shown) that is provided at the holder 3. That is to say, the relay units 2200 have a function of relaying ink inside the tanks 2100 to the print head. Then, when little or no ink remains in the tanks 2100, a user can refill the tanks 2100 with ink. The tanks 2100 are provided with injection openings (not shown). The user can refill the tanks 2100 with ink through these injection openings.
Note that a mode of the printer 2000 may be such that, as shown in
As shown in
The invention can be applied not only to ink-jet printers and ink cartridges thereof, but also to any liquid-jet apparatuses that consume liquid other than ink, and liquid containers that are used for these liquid-jet apparatuses. For example, the invention can be applied to liquid containers that are used for the various liquid-jet apparatuses described below:
(1) image recording apparatuses such as facsimile apparatuses, (2) coloring material-jet apparatuses used to manufacture color filters for image displays, such as liquid crystal displays, (3) electrode material-jet apparatuses used to form electrodes for organic electro luminescence (EL) displays, field emission displays (FEDs), or the like, (4) liquid-jet apparatuses that form a jet of liquid including bioorganic materials used to manufacture biochips, (5) sample-jet apparatuses used as precision pipettes, (6) lubricating oil-jet apparatuses, (7) resin liquid-jet apparatuses, (8) liquid-jet apparatuses that form a jet of lubricating oil for pinpoint application onto precision machines such as watches or cameras, (9) liquid-jet apparatuses that form a jet of transparent resin liquid such as ultraviolet curing resin liquid onto a substrate in order to form minute hemispherical lenses (optical lenses) used for optical communications devices or the like, (10) liquid-jet apparatuses that form a jet of acidic or alkaline etching liquid in order to perform etching on a substrate or the like, and (11) liquid-jet apparatuses that include a liquid consumption head for ejecting a slight amount of any other droplet.
Note that the “droplet” refers to a state of liquid that is ejected from a liquid-jet apparatus, and examples thereof include a spherical shape, a tear shape, and a shape having a thread-like trailing end. Furthermore, the “liquid” in this case may be any material that can be used in a liquid-jet apparatus. For example, the “liquid” may be any material that is in a liquid phase, and examples thereof also include materials in a liquid state having high or low viscosity, sol, gel water, and other materials in a liquid state such as inorganic solvent, organic solvent, solution, liquid resin, liquid metal (metallic melt), and the like. Furthermore, examples of the “liquid” include not only liquid, as one state of materials, but also materials in which are dissolved, dispersed, or mixed in solvent, particles of functional material made of a solid, such as pigments or metal particles. This sort of “liquid” also may be referred to as a “liquid state material”. Typical examples of the liquid or the liquid state material include ink, liquid crystal, and the like as described in the foregoing embodiments. Incidentally, it is assumed that examples of the ink include various liquid state compositions such as commonly used water-based ink, oil-based ink, gel ink, and hot melt ink.
Number | Date | Country | Kind |
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2012-191474 | Aug 2012 | JP | national |
2012-213719 | Sep 2012 | JP | national |
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20140061200 A1 | Mar 2014 | US |