JP4844100B2 - Ink cartridge manufacturing method - Google Patents

Description

  The present invention relates to an ink cartridge, and more particularly, to an ink cartridge manufacturing method capable of suppressing damage to the internal structure of an ink reservoir due to the influence of vibration caused by ultrasonic vibration.

  2. Description of the Related Art Conventionally, there has been known an ink cartridge that has an internal space for storing ink and is detachably attached to an ink jet recording apparatus that performs recording by discharging ink stored in the internal space from a recording head. As this type of ink cartridge, there is also known a double-structured ink cartridge including an ink reservoir that forms an internal space and a case that encloses the ink reservoir.

  On the other hand, in this type of ink cartridge, from the viewpoint of weight, ink resistance, cost, etc., the constituent members constituting the ink cartridge are often made of resin, and when these constituent parts are fixed to each other, As disclosed in the following Patent Documents 1 and 2, ultrasonic welding is adopted in which the constituent members are vibrated by ultrasonic waves to weld the constituent members.

In addition, as a method for manufacturing the ink cartridge, it is preferable that the ink dispensing process of dispensing ink into the ink reservoir is performed at the end of the manufacturing process in order to prevent ink leakage in the manufacturing process. Therefore, in the above-described double-structured ink cartridge, an empty ink reservoir is accommodated in the case, the case containing the empty ink reservoir is ultrasonically welded, and then the ink reservoir is used. Ink was dispensed.
JP-A-9-11487 (20th paragraph, etc.) JP 2002-120383 (24th paragraph etc.)

  However, as described above, when ink is dispensed into the ink reservoir after ultrasonically welding the case containing the empty ink reservoir, the internal structure of the ink reservoir is affected by the vibration caused by the ultrasonic waves. There was a problem that could be damaged.

  The present invention has been made to solve the above-described problems, and provides an ink cartridge manufacturing method capable of suppressing damage to the internal structure of the ink reservoir due to the influence of vibration caused by ultrasonic waves. The purpose is that.

In order to achieve this object, an ink cartridge manufacturing method according to claim 1 comprises an ink reservoir having an internal space in which at least a portion of ink is stored, and a plurality of components that contain the ink reservoir. A first opening that communicates with the internal space, and communicates with the internal space with the internal space interposed between the first opening and the first opening. A first molding step of molding the ink reservoir including a frame member having a second opening, and a second molding step of molding a rotating member that rotates in the internal space as the ink decreases. of the frame member which is molded by the first molding step, a position opposed to said second opening and the first opening, to attach the rotating member which is molded by the second molding step And Chakukotei, thereby fixing the first film having flexibility to the periphery of the first opening so as to閉封the first opening facing the rotating member which is attached by its attachment step, An adhering step of adhering a flexible second film to a peripheral portion of the second opening so as to close the second opening facing the rotating member, and the first film and the second by the adhering step . An ink dispensing process for dispensing ink into the internal space of the ink reservoir in a state where the film is fixed facing the rotating member, and the ink is stored in the internal space by the ink dispensing process. An assembly step of assembling the plurality of components such that the ink reservoir in a state of being contained is accommodated in the case, and the ink reservoir is accommodated in the case by the assembly step The plurality And a welding step of welding by vibrating the formed parts together by ultrasonic.

The ink cartridge manufacturing method according to claim 2, wherein in the ink cartridge manufacturing method according to claim 1 , the first molding step includes a first rib that supports the first film from the inner space side. An ink reservoir is molded, and in the fixing step, the first film is fixed to a peripheral portion of the first opening, and the first film is fixed to the first rib.

Method of manufacturing an ink cartridge according to claim 3, wherein, in the manufacturing method of the ink cartridge according to claim 1 or 2, wherein in the first molding step, the first chamber and the second of said inner space of said first opening side The ink comprising: a partition plate partitioning into a second chamber on the two opening side; the first rib standing on the first opening side from the partition plate; and the second rib standing on the second opening side. The reservoir is molded, and in the fixing step, the second film is fixed to the peripheral edge of the second opening, and the second film is fixed to the second rib.

Method of manufacturing an ink cartridge according to claim 4, wherein, in the manufacturing method of the ink cartridge according to any one of claims 1 to 3, wherein the fixing step, and said second film and said first film of said frame member It adheres while sucking from the inside.

The ink cartridge manufacturing method according to claim 5 is the ink cartridge manufacturing method according to any one of claims 1 to 4 , wherein, in the first molding step, the ink in the ink storage chamber protrudes from a side surface of the frame member. An ink supply unit for supplying the ink to the ink jet recording apparatus, and an air introduction unit for introducing air into the ink storage chamber by projecting in the same direction as the ink supply unit from the side surface of the frame member from which the ink supply unit projects, A side surface of the frame member from which the air introduction part and the ink supply part protrude, and is the same as the direction in which the air introduction part and the ink supply part protrude from between the air introduction part and the ink supply part. Projecting in the direction and forming a passage in which the light blocking portion of the rotating member is displaceable and provided in the inkjet recording apparatus The ink container that includes a detected portion is molded of light emitted from the optical sensor is irradiated.

6. The ink cartridge manufacturing method according to claim 6, wherein in the ink cartridge manufacturing method according to claim 5 , the preparation step includes an ink supply part through-hole for projecting the ink supply part to the outside, and the air introduction part. A third molding step of molding the plurality of components such that an air introduction portion through hole that projects the outside and a detection window that exposes the detected portion to the outside are disposed on one surface of the case, In the assembling step, the ink supply part protrudes to the outside from the ink supply part through hole, the atmosphere introduction part protrudes to the outside from the atmosphere introduction through hole, and the detected part is exposed to the outside from the detection window. The plurality of component parts molded by the third molding process are assembled, and in the welding process, the plurality of component parts are mutually connected in a portion other than one surface of the case. It is wearing.
The method for manufacturing an ink cartridge according to claim 7 is the method for manufacturing an ink cartridge according to any one of claims 1 to 6 , wherein the first film and the second film are formed in the fixing step before the ink dispensing step. A first decompression step of decompressing the inside of the ink reservoir in a state where the ink is fixed, and after the ink is dispensed by the ink dispensing step into the ink reservoir decompressed by the first decompression step, A second decompression step for decompressing the inside of the ink reservoir again.

  According to the ink cartridge manufacturing method of the present invention, the ink reservoir is accommodated in the case after the ink is dispensed into the internal space, and thereafter, the plurality of components constituting the case are vibrated by ultrasonic waves. To be welded. Therefore, the vibration due to the ultrasonic waves is absorbed by the ink, and there is an effect that it is possible to suppress damage to the internal structure of the ink reservoir due to the influence of the vibration due to the ultrasonic waves.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. FIG. 1 is a perspective view illustrating an appearance of an ink cartridge 1 according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of the ink cartridge 1.

  As shown in FIG. 1, the ink cartridge 1 is attached to a case 200 that covers substantially the entire ink reservoir 100 (see FIG. 2) that stores ink, and when the ink cartridge 1 is transported. And a protector 300 that protects the ink reservoir 100. In the present embodiment, the ink reservoir 100, the case 200, and the protector 300 are made of a resin material and do not have a metal material, and therefore can be incinerated at the time of disposal. For example, examples of the resin material include nylon, polyethylene, and polypropylene.

  As shown in FIG. 2, the ink reservoir 100 includes a frame portion 110 that forms an ink reservoir chamber (or internal space) that stores ink, and an ink (ink jet recording apparatus 1000) that stores ink stored in the frame portion 110. (Refer to FIG. 29)), an ink supply unit 120 for supplying air, an air introduction unit 130 for introducing air into the frame unit 110, and a remaining amount of ink stored in the frame unit 110. The detection unit 140, the ink dispensing unit 150 for dispensing ink into the frame unit 110, and the frame unit 110 are welded to both surfaces (upper and lower surfaces in FIG. 2) to form an ink storage chamber. The film 160 is mainly provided. The description of the frame unit 110, the ink supply unit 120, the air introduction unit 130, the detection unit 140, the ink dispensing unit 150, the film 160, and the manufacturing process of the ink reservoir 100 will be described later.

  The case 200 includes two case members 210 and 220 that sandwich the ink reservoir 100 from above and below (upper and lower in FIG. 2). The first case member 210 is a member that covers the lower side of the ink reservoir 100 in FIG. The second case member 220 is a member that covers the upper side surface of the ink reservoir 100 in FIG. The first and second case members 210 and 220 are made of a resin material and are manufactured by injection molding.

  The first case member 210 is formed with two case notches 211 and 212 for exposing the ink supply part 120 and the air introduction part 130 to the outside of the case 200. The case notches 211 and 212 are formed in a substantially semicircular shape, the case notch 211 on the right front side in FIG. 2 is a notch corresponding to the ink supply unit 120, and the case notch 212 on the left side in FIG. It is a notch corresponding to the air introduction part 130. In addition, a case notch 213 cut into a rectangular shape is formed between the case notch 211 and the case notch 212, and this is a remaining ink detection sensor 1014 ( It is a notch for inserting (refer FIG. 29). A contact groove 211 a that contacts the ink supply unit 120 is formed on the inner surface of the first case member 210 that is connected to the case notch 211, and the inner surface that is connected to the case notch 212 of the first case member 210 is formed. A contact groove 212b that contacts the air introduction part 130 is formed on the side surface. By providing the contact grooves 212a and 212b, the ink reservoir 100 can be easily aligned with the first case member 210.

  Further, the first case member 210 is formed with two case protrusions 214a and 214b that protrude in the direction of the protector 300 (the left front side in FIG. 2) from the surface on which the case notches 211 to 213 are formed. The case projecting portions 214a and 214b are formed on both sides (the right front side end portion in FIG. 2 and the left side end portion in FIG. 2) of the first case member 210 so as to sandwich the case cutout portions 211 to 213, and the ink supply portion The 120 side (right front side in FIG. 2) is the case protrusion 214a, and the atmosphere introduction part 130 side (left port side in FIG. 2) is the case protrusion 214b. In addition, the case protrusion 214a extends from the portion connected to the side wall of the first case member 210 toward the tip (the protector 300 direction, the left front side in FIG. 2) in the case notch portions 211 to 213 (inside the first case member 210). The inclined surface 214a2 is inclined in the direction). When the ink cartridge 1 is mounted on the ink jet recording apparatus 1000 (see FIG. 29), the case protrusion 214a is mounted on the lower side. Accordingly, when the ink cartridge 1 is mounted, when the inclined surface 214a2 comes into contact with the lower portion of the ink jet recording apparatus 1000, the ink cartridge 1 is smoothly guided to a predetermined mounting position by the inclination.

  The case protrusion 214a is formed with a case protrusion 214a1 cut into a rectangular shape on the inner surface on the case notches 211 to 213 side. The case protrusion 214b is formed with a case protrusion notch 214b1 cut into a rectangular shape on the inner surface on the case notches 211 to 213 side. The case protruding cutouts 214a1 and 214b1 are provided to prevent the protector 300 from being naturally attached and detached when the protector 300 is attached to the case 200. Protrusions 330a1 and 330b1 of the protector 300 described later (See FIG. 3) is fitted.

  Further, the case protrusion 214b is formed with a case fitting groove 214b2 as a fitting portion into which a first protector fitting portion 320 (see FIG. 3) of the protector 300 described later is fitted. The case fitting groove 214b2 is formed from the tip of the case protrusion 214b (the end on the protector 300 side) to the side surface of the first case member 210.

  In addition, the first case member 210 projects in the direction of the second case member 220 in the vicinity of the side wall on the ink supply unit 120 side (right front side in FIG. 2), and positions the ink reservoir 100 enclosed in the case 200. The bar member 215a to be performed and the ink reservoir 100 protruding in the second case member 220 side (upward in FIG. 2) in the vicinity of the side wall on the atmosphere introduction part 130 side (on the port side in FIG. 2) and enclosed in the case 200 Bar members 215b and 215c for positioning are formed. Since the ink reservoir 100 is positioned by the three portions of the rod members 215a to 215c, it is possible to prevent the ink reservoir 100 from being attached in the wrong direction.

  Similarly to the first case member 210, the second case member 220 is formed with three case cutout portions 221 to 223, and is connected to the contact groove 221a connected to the case cutout portion 221 and the case cutout portion 222. A contact groove 222a is formed. In addition, case protrusions 224a and 224b are formed on both sides of the case notches 221 to 223, and the case protrusions 224a extend from the portion connected to the side surface of the second case member 220 toward the tip. An inclined surface 224a2 that inclines in the directions 221 to 223 is provided. The case protrusion 224a is formed with a case protrusion notch 224a1 (not shown), and the case protrusion 224b has a case protrusion notch 224b1 and a tip of the case protrusion 224b of the second case member 220. A case fitting groove 224b2 is formed over the side surface. The second case member 220 protrudes toward the first case member 210 (downward in FIG. 2) corresponding to the position where the rod members 215a to 215c of the first case member 210 are formed, and the rod members 215a to 215c. Fitting hole portions 225a to 225c (not shown) having holes to be fitted are provided.

  As described above, in the case 200, the first case member 210 and the second case member 220 are formed in substantially the same shape. When the ink reservoir 100 is sandwiched, the case notches 211 and 221 allow ink to be ejected. A substantially circular through hole that exposes a part of the supply part 120 to the outside is formed, and a substantially circular through hole that exposes a part of the air introduction part 130 to the outside is formed by the case notches 212 and 222. Through-holes into which the ink remaining amount detection sensor 1014 (see FIG. 29) can be inserted are formed on both sides of the detection unit 140 (upper and lower sides in FIG. 2) by the portions 213 and 223 and the side wall of the detection unit 140. Further, a through-hole into which the protruding portion 330a1 (see FIG. 3) of the protector 300 is loosely inserted is formed by the case protruding notches 214a1 and 224a1, and the protruding portion 330b1 (see FIG. 3) of the protector 300 is formed by the case protruding notches 214b1 and 224b1. Is formed, and a substantially rectangular parallelepiped fitting groove into which the first protector fitting portion 320 (see FIG. 3) of the protector 300 is fitted is formed by the case fitting grooves 214b2 and 224b2.

  Next, the outer shape of the case 200 will be described. The first and second case members 210 and 220 are formed in a concave shape on both side surfaces in a direction perpendicular to the longitudinal direction A (the direction connecting the starboard side of FIG. 2 and the left front side of FIG. 2, arrow A in FIG. 2). Steps are formed on the surfaces of the first and second case members 210 and 220. At the step portion, the first and second case members 210 and 220 are welded, and the ink reservoir 110 is fixed to the case 200. As for the stepped portion, the stepped portion on the ink supply unit 120 side (right front side in FIG. 2) is the first case welded portion 216, 226, and the stepped portion on the atmosphere introducing unit 130 side (left port side in FIG. 2) is the second case welded. Parts 217 and 227.

  In the following description, the longitudinal direction A of the first and second case members 210 and 220 means the longitudinal direction of the ink cartridge 1, the longitudinal direction of the ink reservoir 100, and the longitudinal direction of the case 200.

  Here, the first and second case welded portions 226 and 227 of the second case member 220 will be described. The first case welded portion 226 is connected to the same plane as the case protruding portion 224a, and on the opposite side of the case protruding portion 224a, a concave portion 226a formed in a concave shape in the inner direction of the second case member 220, When the ink cartridge 1 is removed from the ink jet recording apparatus 1000 (see FIG. 29), an engaging portion 226b that engages with the engaging member 1017 (see FIG. 29) is provided. The recess 226a is a region for securing a swing range when the engaging member 1017 swings. The case welded portion 227 has a locking portion 227a formed in a concave shape at a substantially intermediate position in the longitudinal direction A of the second case member 220. The locking portion 227a is attached to the ink jet recording apparatus 1000 (see FIG. 29). This is a portion for locking the ink cartridge 1 in the attached state.

  Although not described in detail, the first case member 210 also has a recess 216a (not shown) formed in the same shape as the recess 226a, the engagement portion 226b, and the locking portion 227a of the second case member 220. An engaging portion 216b (not shown) and a locking portion 217a are formed.

  Next, the protector 300 will be described with reference to FIGS. 2 and 3. FIG. 3 is a view showing the protector 300, FIG. 3 (a) is a top view of the protector 300 as viewed in IIIa of FIG. 2, and FIG. 3 (b) is IIIb-IIIb of FIG. 3 (a). It is sectional drawing of the protector 300 in a line. The protector 300 is a member that protects the ink supply unit 100, particularly the ink supply unit 120 and the air introduction unit 130, when the ink cartridge 1 is shipped. The protector 300 is made of a resin material and is manufactured by injection molding.

  As shown in FIG. 2, the protector 300 has a protector through-hole 310 formed at a location corresponding to the bottom surface of the air introduction part 130 (the port side of FIG. 2). This is because the valve opening portion 721a (see FIG. 22) for operating the atmospheric valve 720 protrudes outward from the atmospheric introduction portion 130, and the protector through-hole 310 is used to protect the valve opening portion 721a. Is formed.

  As shown in the top view of FIG. 3A, case fitting grooves 214b2 and 224b2 (see FIG. 2) are formed near the end of the protector 300 on the protector through hole 310 side (left side of FIG. 3A). A first protector fitting portion 320 to be fitted into the fitting groove is formed. Further, in the vicinity of the end on the side opposite to the side on which the first protector fitting portion 320 is formed (right side in FIG. 3A), through holes formed by case protruding notches 214a1 and 224a1 (see FIG. 2). And a second protector fitting portion 330a for fixing the protector 300 to the case 200 is formed. Between the first protector fitting portion 320 and the protector through hole 310, a case protruding notch 214b1 is formed. , 224b1 (see FIG. 2), a second protector fitting portion 330b is formed for fitting the protector 300 to the case 200.

  Further, the case notches 213 and 223 and the detection unit 140 (FIG. 2) are located at substantially intermediate positions in the longitudinal direction B (the left-right direction in FIG. 3A, the arrow C in FIG. Protector loose insertion portions 340a and 340b that are loosely inserted into the through holes formed by the side walls of the reference). The protector loosely inserted portions 340a and 340b are connected to both side walls (upper and lower side walls in FIG. 3A) formed in parallel to the longitudinal direction B, and above (in FIG. 3A, the front side of the page, in FIG. It protrudes toward the ink reservoir 100 side. A plurality of ribs are erected from the bottom surface of the protector 300 to maintain the strength of the protector 300.

  The first protector fitting portion 320 is arranged in parallel to the direction (vertical direction in FIG. 3A) perpendicular to the longitudinal direction B of the protector 300, and the protector standing wall 321 standing from the bottom wall of the protector 300, It consists of two protector standing walls 322 connected from the protector standing wall 321 to the side wall on the side opposite to the protector through-hole 310 (left side in FIG. 3A). As shown in FIG. 3B, the protector standing wall 322 includes an upper portion formed in parallel with the protector standing wall 321 from the upper end portion (the upper end portion in FIG. 3B) of the first protector fitting portion 320, and the first The protector fitting part 320 includes a lower part connected from a substantially intermediate position in the protruding direction (upward in FIG. 3B) to the side wall of the protector 300, and has a step.

  Therefore, when fitted in the fitting groove formed by the case fitting grooves 214b2 and 224b2 (see FIG. 2), the protector standing wall 321 and the upper part of the protector standing wall 322 are inserted into the fitting groove. When the first protector fitting portion 320 is inserted into the fitting groove, the first protector fitting portion 320 is inserted while being regulated by both end portions of the protector standing wall 321 orthogonal to the longitudinal direction B and the end portion of the protector standing wall 322 in the longitudinal direction B. The Here, if the first protector fitting part 320 is formed in substantially the same shape as the fitting groove formed by the case fitting grooves 214b2 and 224b2 (see FIG. 2), it takes time to mount the protector 300. If the first protector fitting portion 320 is extremely small with respect to the fitting groove, the protector 300 cannot be positioned in the mounting direction. However, insertion is performed by the protector standing walls 321 and 322 while being restricted by one surface (the plane of the protector standing wall 321) and four points (both ends of the protector standing wall 321 and two ends of the protector standing wall 322). In addition, it is possible to prevent erroneous mounting while improving the mountability of the protector 300.

  As shown in FIG. 3 (b), the second protector fitting portions 330a and 330b have protrusions 330a1 and 330b1 protruding in directions away from each other, and the tip portions of the second protector fitting portions 330a and 330b (FIG. 3B). ) Are formed at the upper end), and rod portions 330a2 and 330b2 formed in a substantially rod shape from the tip portion toward the bottom surface of the protector 300 (downward in FIG. 3 (b)). Further, the rod portions 330a2 and 330b2 have elasticity because the protector 300 is formed of a resin material, and the second protector fitting portions 330a and 330b are elastically deformed inward to attach / detach the protector 300. Is done.

  Next, the ink reservoir 100 will be described with reference to FIG. 4 is a view showing the ink reservoir 100, FIG. 4 (a) is a front view of the ink reservoir 100, and FIG. 4 (b) is a rear view of the ink reservoir 100. FIG. Note that the state of the ink reservoir 100 shown in FIG. 4 is a posture in which the ink cartridge 1 is attached to the ink jet recording apparatus 1000 (see FIG. 29). That is, the ink supply unit 120, the air introduction unit 130, and the detection unit 140 are positioned on the side surface, the ink supply unit 120 is positioned on the bottom side, and the air introduction unit 130 is positioned on the ceiling side.

  As described above, the ink reservoir 100 mainly includes the frame part 110, the ink supply part 120, the air introduction part 130, the detection part 140, the ink dispensing part 150, and the film 160. The ink reservoir 100 is configured as a substantially hexahedron having a flat shape. The pair of surfaces having the largest area of the hexahedron are surfaces that form the front side and the back side of the ink reservoir 100 shown in FIG. It is comprised by the approximately six surfaces with the side surface (side wall) located in. In addition, since the film 160 is welded to both the front side and the back side of the frame part 110, the thickness of the ink storage body 100 formed in a flat shape is made thinner than the case where both sides are closed by the side walls. Can do.

  First, the frame unit 110 will be described in detail. Moreover, the frame part 110 is comprised from the resin material, and is manufactured by injection molding.

  As shown in FIG. 4 (a), on the front side of the frame portion 110, there are an outer periphery weld portion 400a for welding the film 160 in the vicinity of the outer edge portion, and a plurality of inner peripheries provided on the inner side of the outer periphery weld portion 400a. Welded portions 411a to 417a are formed. The outer periphery welded portion 400a is a standing wall that defines the internal space of the frame portion 100 (the space on the first chamber 111a side). In addition, as shown in FIG. 4A, the blackened portions of the inner circumference welded portions (ribs or first ribs) 411a to 417a are welded portions (rib fixed portions or first rib fixed portions), The front end (blacked portion) of the outer periphery welded portion 400a is a welded portion (adhered portion) at the periphery of the first opening 112a. The film 160 is welded to the welded portion by ultrasonic welding.

  As shown in FIG. 4 (b), on the back side of the frame part 110, there are an outer periphery welded part 400b for welding the film 160 in the vicinity of the outer edge part, and a plurality of inner peripheries provided inside the outer periphery welded part 400b. Welded portions 411a to 417b are formed. The outer periphery welded portion 400 b is a standing wall that defines the internal space of the frame portion 100. The outer periphery welded portion 400b is a standing wall that defines the internal space of the frame portion 100 (the space on the second chamber 111b side). In addition, as shown in FIG. 4 (b), the blackened portions of the inner periphery welded portions (ribs or second ribs) 411b to 417b are welded portions (rib fixed portions or second rib fixed portions), The rear end (blacked portion) of the outer welded portion 400b is a welded portion (fixed portion) at the periphery of the opening. The film 160 is welded to the welded portion by ultrasonic welding.

  Further, the inner side of the outer periphery welded portions 400a and 400b is an ink storage chamber 111 in which ink is stored. The area on the front side shown in FIG. 4A is the first chamber 111 a of the ink storage chamber 111, and the area on the back side shown in FIG. 4B is the second chamber 111 b of the ink storage chamber 111. 4A is the first opening 112a of the frame part 110, and the outer periphery welding part 400b shown in FIG. 4B is the second opening 112b of the frame part 110. .

  The frame part 110 mainly communicates with the ink supply part 120, and supplies the ink stored in the ink storage chamber 111 to the outside. The supply path forming part 420 (see FIGS. 4A and 4B). And an atmosphere communication path forming section 430 (see FIG. 4A) that communicates with the atmosphere introduction section 130 and introduces the atmosphere into the ink storage chamber 111, and a substantially central portion of the frame section 110 (or the ink storage chamber 111). The connection forming portion 440 (see FIGS. 4A and 4B) that connects the vicinity of the air introduction portion 130 and the vicinity of the ink dispensing portion 150 and the ink dispensing portion 150 communicates with the ink. A dispensing path forming unit 450 (see FIG. 4B) for dispensing ink into the storage chamber 111 is provided. In the present embodiment, the ink storage chamber 111 (internal space) in the frame portion 110 is defined as an area including the supply passage formation portion 420, the atmosphere communication passage formation portion 430, the connection formation portion 440, and the branch flow passage formation portion 450. However, since the atmosphere communication path forming part 430 is an atmosphere path for introducing the atmosphere into the ink storage chamber 111, the area may be different from the ink storage chamber 111 (internal space) in the frame part 110.

  Further, at the outer edge of the frame part 110, there are two places, one at the bottom (the lower part of FIG. 4 (a) and the lower part of FIG. 4 (b)) and the upper part (the upper part of FIG. 4 (a) and the upper part of FIG. 4 (b)). Protrusions are formed, and through-holes 460a to 460c through which the rod members 215a to 215c (see FIG. 2) of the first case member 210 described above are inserted are formed in the protrusions.

  First, with reference to Fig.4 (a), the inner periphery welding parts 411a-417a are demonstrated. The inner circumference welded portions 411a to 417a are provided in the inner circumference welded portion 411a provided in the supply path forming portion 420, the inner circumference welded portion 412a provided in the atmosphere communication path forming portion 430, and the connection forming portion 440. It is comprised by the inner periphery welding part 413a-417a. Moreover, the inner periphery welding parts 411a-417a are located on the same virtual plane as the inner periphery welding part 400a, and can weld the film 160 on the same plane.

  The inner circumference welded portion 411a is provided in the supply path forming portion 420, and is configured by a standing wall that is inclined downward in a direction intersecting the longitudinal direction A of the frame portion 110 (see FIG. 2, FIG. 4 (a) left-right direction). Yes. The inner circumference welded portion 412a forms one side wall (standing wall) of an atmosphere connecting path 433, which will be described later, in the atmosphere communicating path forming portion 430, and the standing wall inclined downward in the direction intersecting the longitudinal direction A of the frame portion 110. It consists of The inner circumference welded portion 413 a is provided in the vicinity of the air introduction portion 130, and a standing wall that is inclined downward in a direction intersecting with the longitudinal direction A of the frame portion 110 and the longitudinal direction A of the frame portion 110 from the standing wall. It is comprised with the standing wall extended in the substantially orthogonal direction (FIG. 4 (a) up-down direction). The inner circumference welded portion 414a is formed in a substantially inverted U-shape, and a standing wall that is parallel to the longitudinal direction A of the frame portion 110 and a substantially perpendicular to the longitudinal direction A of the frame portion 110 from the standing wall. The standing wall extends in the direction, and the standing wall is inclined downward from the standing wall in a direction intersecting the longitudinal direction A of the frame portion 110. The inner circumference welded portion 415a includes a standing wall that is parallel to the longitudinal direction A of the frame portion 110, a standing wall that curves from the standing wall to the lower portion of the frame portion 110, and a longitudinal wall that extends from the standing wall to the longitudinal direction A of the frame portion 110. And standing walls that are inclined downward in the direction of crossing. The inner circumference welded portion 416 a is provided in the vicinity of the ink dispensing portion 150, and is constituted by a standing wall that is inclined downward in a direction intersecting the longitudinal direction A of the frame portion 110. The inner circumference welded portion 417 a is provided in the vicinity of the ink dispensing portion 150, and a standing wall extending in a direction substantially orthogonal to the longitudinal direction A of the frame portion 110, and from the standing wall in the longitudinal direction A of the frame portion 110. It is comprised with the standing wall inclined down in the direction which cross | intersects.

  That is, the inner circumferential welded portions 411a to 417a have at least some of the standing walls inclined downward with respect to the longitudinal direction A of the frame portion 110 or in a direction substantially orthogonal (that is, in the posture in which the ink cartridge 1 is mounted). It extends to the bottom of the chamber 111), and the end on the bottom (the lower side in FIG. 4A) is a free end. Therefore, even if a plurality of inner circumference welded portions 411a to 417a are provided inside the outer circumference welded portion 400a in order to suppress loosening of the film 160 when the film 160 is welded to the frame portion 110, the plurality of inner circumferences thereof It can reduce that the welding parts 411a-417a obstruct the flow of ink. Further, since the inner circumference welded portions 411a to 417a are arranged to be diffused inside the outer circumference welded portion 400a, it is possible to reduce the occurrence of slack in the film 160 and more efficiently reduce the hindrance to the ink flow. Can do.

  As shown in FIG. 4B, the inner circumference welded portions 411b to 417b are the inner circumference welded portions 411b and the inner circumference welded portions 413b to 417b, and the inner circumference welded portions 411a and the inner circumference welded portions 413a to 417a described above. It has substantially the same shape and is formed at a position corresponding to the inner circumference welded portion 411a and the inner circumference welded portions 413a to 417a, and only the inner circumference welded portion 412b is formed in a shape different from the inner circumference welded portion 412a. Moreover, the inner periphery welding parts 411b-417b are located on the same virtual plane as the inner periphery welding part 400b, and can weld the film 160 on the same plane.

  The inner circumference welded portion 412b is an inner circumference welded portion 412b1 configured by a standing wall extending in a direction substantially orthogonal to the longitudinal direction A of the frame portion 110 from the outer circumference welded portion 400b. Similarly, the inner circumference welded portion 412b is elongated from the outer circumference welded portion 400b. It is comprised by the inner periphery welding part 412b2 comprised by the standing wall extended in the direction substantially orthogonal to the direction A. As shown in FIG. This is because the atmosphere communication path forming part 430 is formed only on the front side of the frame part 110, and the occurrence of slack in the film 160 corresponding to the back side of the atmosphere communication path forming part 430 is suppressed. Therefore, inner circumference welded parts 412b1 and 412b2 are provided. In addition, since the inner periphery welded portions 411b to 417b are provided as free ends and diffused on the back side of the frame portion 110 similarly to the front side, the flow of ink is suppressed while suppressing the occurrence of slack in the film 160. Can be efficiently reduced.

  Further, by diffusing and providing the inner circumference welded portions 411a to 417a and 411b to 417b, for example, when the case 200 is formed from a soft resin material, the case is deformed to the ink reservoir 100 side. However, deformation of the case can be restricted by the inner circumference welded portions 411a to 417a and 411b to 417b. Therefore, damage to the case and damage to the film 160 can be reduced. Furthermore, since the outer periphery welded portions 400a and 400b and the inner periphery welded portions 411a to 417a and 411b to 417b are formed by standing walls erected on the front side or the back side, when the frame portion 110 is injection molded, Does not require extremely complicated molds. Therefore, the manufacturing cost of the ink cartridge 1 can be reduced.

  Next, the supply path forming unit 420 will be described with reference to FIG. FIG. 5 is a view showing the supply path forming section 420, and FIG. 5A is a view showing the outline of the supply path forming section 420 (a view on the back side of the frame section 110). FIG. 5B is a cross-sectional view of the supply path forming unit 420 taken along the line Vb-Vb in FIG. 5A, and FIG. 5C is a diagram illustrating a state in which the remaining amount of ink is reduced. FIG. 4D is a diagram illustrating a state in which the ink supply is completed.

  As shown in FIG. 5A, the supply path forming unit 420 includes a first supply communication hole 421 communicating with the ink supply unit 120 and a first supply communication hole 421 so as to surround the first supply communication hole 421. A supply partition wall 422 formed in a substantially triangular shape as viewed in the vertical direction, a second supply communication hole 423 formed by cutting a part of the supply partition wall 422, and the bottom of the ink cartridge 1 (lower part in FIG. 5A) A supply recess 424 formed in a concave shape (stepped shape) in a part of the outer periphery welded portion 400b), an arm holding portion 425 to which a sensor arm 470 (see FIG. 9) as a rotating member to be described later is attached, It mainly includes an inner circumference welded portion 411a provided in the direction from the arm holding portion 425 to the detecting portion 140 (see FIG. 4B). The space surrounded by the supply partition wall 422 is an ink supply chamber 426 that temporarily stores ink to be supplied to the ink supply unit 120, and the space formed by the supply recess 424 is a recess space 424a. The arm clamping unit 425 is formed in a substantially reverse C shape when viewed in the direction perpendicular to the plane of FIG. 5A, and a part of the side opposite to the ink supply unit 120 (left side in FIG. 5A) is opened. Yes.

  As shown in FIG. 5B, the supply partition 422 is formed to separate the inside of the frame part 110 (ink storage chamber 111) from the first supply communication hole 421 when the film 160 is attached. Yes. That is, the ink supply chamber 426 surrounded by the supply partition 422 communicates with the inside of the frame part 110 only through the second supply communication hole 423. Therefore, the ink stored in the frame part 110 is supplied from the second supply communication path 423 into the ink supply chamber 426, and then supplied from the first supply communication hole 421 to the ink supply part 120 (FIG. 5 ( c) Arrow C).

  Next, with reference to FIG. 5C and FIG. 5D, the ink flow path C that supplies ink inside the frame unit 110 to the ink supply unit 120 will be described. As shown in FIG. 5C, when the ink level I stored in the frame 110 is above the supply recess 424, it passes through the ink flow path indicated by the arrow C in FIG. Ink is supplied to the ink supply unit 120. In this case, since the recessed space 424a is filled with ink, the ink supply chamber 426 surrounded by the supply partition 422 is also filled with ink. That is, in the state of FIG. 5C, since the ink supply chamber 426 is filled with ink, even if the liquid level I of the ink falls below the first supply communication hole 421, the ink supply chamber 426 passes through the second supply communication hole 423. Thus, ink can be supplied to the ink supply unit 120. In the present embodiment, the ink supply unit 120 has a substantially cylindrical shape as shown in FIG. 2, and the check valve 670 (see FIG. 18) is inserted through the first supply communication hole 431. There is a limit in forming the formation position of the hole 431 in the bottom direction. In the configuration in which the supply partition wall 422 is not provided, when the ink level I drops from the first supply communication hole 431, the ink cannot be supplied, and the ink in the ink storage chamber 111 is used up. However, by providing the supply partition 422 and forming the second supply communication hole 433 in the bottom direction from the first supply communication hole 431, the ink can be supplied until the ink level I drops below the second supply communication hole 433. The ink can be used up.

  When ink is further supplied from the state of FIG. 5C and the ink liquid level I becomes lower than the supply recess 424 and lower than the second supply communication hole 423, the supply partition wall 422 is provided via the second supply communication hole 423. The air flows into the ink supply chamber 426 surrounded by, and as a result, no more ink can be supplied (state shown in FIG. 5D).

  As shown in FIG. 5D, the vertical side wall (bottom direction in FIG. 5B) of the bottom side wall (the lower side wall in FIG. 5D) of the frame part 110 and the second supply communication hole 423 is provided. The position is provided with a difference in distance t1. Here, if the second supply communication hole 423 is located above the side wall at the bottom of the frame portion 110, ink cannot be supplied any more when the ink level I reaches the second supply communication hole 423. The use up of becomes worse. Therefore, the supply recess 424 is provided, and the second supply communication hole 423 is configured to be positioned lower than the bottom side wall of the frame part 110 by a distance t1. Therefore, as shown in FIG. 5D, only a small amount of ink remains near the bottom of the supply recess 424 (a portion below the second supply communication hole 423). Since the supply recess 424 is formed at the bottom of the ink reservoir 100 (see FIG. 4), the ink in the ink storage chamber 111 flows into the supply recess 424. Therefore, by providing the supply recess 424, the ink in the ink storage chamber 111 can be used up.

  Further, the residue D remains in the ink remaining in the supply recess 424. This is because there is a difference in distance t2 between the second supply communication hole 423 and the bottom side wall (the side wall on the lower side of FIG. 5D) of the supply recess 424. As described above, when the ink level I drops from the second supply communication hole 423, ink cannot be supplied any more, so that the ink between the second supply communication hole 423 and the lower side wall of the supply recess 424 can be used. Is not supplied to the ink supply unit 120 and remains in the supply recess 424. Dust and plastic residue that remain in the frame portion 110 when the ink cartridge 1 is manufactured may remain in the ink, but the dust and plastic residue have a specific gravity greater than the specific gravity of the ink. It remains near the bottom in the frame 110. Therefore, as shown in FIG. 5D, the residue D remains in the ink remaining in the supply recess 424. If the waste D is supplied to the ink supply unit 120 and supplied to the ink jet recording apparatus 1000 (see FIG. 29), ink clogging may occur, and accurate printing cannot be performed. However, as described above, by providing the distance t2 between the second supply communication hole 423 and the bottom side wall of the supply recess 424, the residue D remains in the supply recess 424, thereby reducing the occurrence of ink clogging. can do.

  Next, the atmosphere communication path forming part 430 will be described with reference to FIG. 6 is a view showing the atmosphere communication path forming portion 430, FIG. 6 (a) is a perspective view schematically showing the atmosphere communication path forming portion 430, and FIG. 6 (b) is a view showing FIG. FIG. 6A is a diagram showing the atmosphere communication path forming portion 430 as viewed from the arrow VIb of FIG. 6A, and FIG. 6C is a diagram showing the atmosphere communication path forming portion 430 as viewed from the arrow VIc of FIG.

  As shown in FIG. 6A, the atmosphere communication path forming portion 430 is formed in a first atmosphere communication chamber 431 formed in a substantially rectangular parallelepiped communicating with the atmosphere introduction portion 130 and a substantially rectangular parallelepiped communicating with the ink storage chamber 111. An atmosphere connection path 433 that communicates the second atmosphere communication chamber 432, the first atmosphere communication chamber 431, and the second atmosphere communication chamber 432 on the first surface 437a side (the left front side in FIG. 6) to which the film 160 is welded. Is mainly equipped. The first atmosphere communication chamber 431, the second atmosphere communication chamber 432, and the atmosphere connection path 433 form a chamber and a passage, respectively, by welding the film 160 to the front side of FIG.

  A first atmosphere communication hole 434 that communicates with the atmosphere introduction unit 130 is formed on the second surface 437 b side of the first atmosphere communication chamber 431 facing the first surface 437 a side. The second atmosphere communication chamber 432 has a second atmosphere communication hole 435 that communicates with the first chamber 111 a of the ink storage chamber 111 on the first surface 437 a side, and communicates with the second chamber 111 b of the ink storage chamber 111. A third atmospheric communication hole 436 is formed on the second surface 437b side. The first atmosphere communication hole 434 is formed in the side wall surface 431a of the first atmosphere communication chamber 431 on the atmosphere introduction part 130 side (the port side in FIG. 6), and the communication port 433b 1 is formed on the side wall surface 432a on the atmosphere communication chamber 431 side (the port side in FIG. 6). As described above, one of the side walls of the atmosphere connection path 433 (the side wall on the lower side in FIG. 6A) is the inner circumference welded portion 412a.

  In the atmosphere connection path 433, communication ports 433a and 433b communicating with the first atmosphere communication chamber 431 and the second atmosphere communication chamber 432 are formed on the first surface 437a side, and the communication ports 433a and 433b are formed. The opening area is extremely smaller than the side wall areas of the first atmospheric communication chamber 431 and the second atmospheric communication chamber 432 (side walls where the communication ports 433a and 433b are formed). Providing a portion (atmospheric connection path 433) having an extremely small cross-sectional area of the passage through which the air is introduced (so-called labyrinth) increases the resistance to circulation when the air passes. Therefore, it is possible to reduce the evaporation of unnecessary ink through the atmosphere connection path 433.

  The atmosphere connection path 433 is inclined downward from the first atmosphere communication chamber 431 toward the second atmosphere communication chamber 432. When the atmosphere connection path 433 is inclined downward, the ink that has entered the atmosphere connection path 433 can be naturally returned to the ink storage chamber 111. Further, by reducing the cross-sectional area of the atmosphere connection path 433, it is possible to reduce the ink stored in the ink storage chamber 111 from entering the atmosphere connection path 433. Here, when ink enters the atmosphere connection path 433, a meniscus may be formed and the atmosphere may not be normally introduced. As described above, since the atmosphere connection path 433 is inclined downward, even if ink enters, the ink is returned to the ink storage chamber 111, so that formation of a meniscus can be reduced. Furthermore, since the atmosphere connection path 433 is formed by welding the film 160, at least one surface is a side wall that can be bent and deformed. Therefore, even if a meniscus is formed, the meniscus is easily broken by the film 160 being bent and deformed, so that the atmosphere can be normally introduced. In addition, since a part of surface of the 2nd atmospheric | air communication hole 435 is also formed of the film 160, it can reduce that a meniscus is formed in the 2nd atmospheric | air communication hole 435. FIG.

  The third atmosphere communication hole 436 is formed at the uppermost part of the second atmosphere communication chamber 432 when the ink cartridge 1 is attached to the ink jet recording apparatus 10000 (see FIG. 29) (the state shown in FIG. 6A). Has been. Therefore, even if a meniscus is formed in the second atmosphere communication hole 435 or ink is stored so as to close the second atmosphere communication hole 435, the atmosphere is stored in the ink through the third atmosphere communication hole 436. It can be reliably introduced into the chamber 111.

  Next, with reference to FIGS. 6B and 6C, a mechanism for preventing ink leakage from the atmosphere communication path forming portion 430 will be described. FIG. 6B shows a case where the ink cartridge 1 is placed so that the atmosphere connection path 433 is positioned on the lower side (the first chamber 111a side of the frame portion 110 is on the lower side and the first surface 437a is on the lower side). FIG. 6C shows a case where the ink cartridge 1 is placed so that the atmosphere connection path 433 is located on the upper side (the second chamber 111b side of the frame portion 110 is on the lower side and the second surface 437b is on the lower side). .

  As shown in FIG. 6B, when the ink cartridge 1 is placed so that the atmosphere connection path 433 is positioned on the lower side during the transportation of the ink cartridge 1, the ink stored in the ink storage chamber 111 is changed to the first. The air enters the first atmosphere communication chamber 431 through the two atmosphere communication chamber 432 and the atmosphere communication chamber 433. As described above, since the atmosphere connection path 433 communicates with the communication port 433b that is extremely smaller than the area of the side surface of the second atmosphere communication chamber 432, the ink in the ink storage chamber 111 passes through the atmosphere communication chamber 433. In some cases, the first atmosphere communication chamber 431 may not necessarily enter the street. In the state of FIG. 6B, since the ink level I has not reached the opening position of the first atmosphere communication hole 434, even if the ink cartridge 1 is placed so that the atmosphere connection path 433 is positioned on the lower side. Further, it is possible to reduce the outflow of ink from the atmosphere introduction unit 130 to the outside.

  As shown in FIG. 6C, when the ink cartridge 1 is placed so that the atmosphere connection path 433 is positioned on the upper side during the transportation of the ink cartridge 1, the ink stored in the ink storage chamber 111 is 2 Although flowing into the atmosphere communication chamber 432, the ink level I does not reach the opening position of the communication port 433 b of the atmosphere connection path 433. As a result, ink does not flow into the atmosphere connection path 433 from the communication port 433b, so that ink does not flow into the first atmosphere communication chamber 431. Therefore, even if the ink cartridge 1 is placed so that the atmosphere connection path 433 is positioned on the upper side, it is possible to reduce the outflow of ink from the atmosphere introduction unit 130 to the outside.

  As described above, the first atmosphere communication chamber 431, the second atmosphere communication chamber 432, and the atmosphere connection path 433 are configured as described above, and the opening position of the first atmosphere communication hole 434 and the opening position of the communication port 433b are defined as the atmosphere connection path. By providing it at a position that is symmetric with respect to 433, it is possible to reduce the leakage of ink from the atmosphere introduction unit 130. Furthermore, by reducing the cross-sectional area of the atmosphere connection path 433, it is possible to reduce ink evaporation and to reduce ink from flowing into the first atmosphere communication chamber 431.

  Here, returning to FIG. 4, the connection forming portion 440 will be described. The connection forming unit 440 connects the vicinity of the air introduction unit 130 and the vicinity of the ink dispensing unit 150 in the ink storage chamber 111 and is formed at a substantially central position in the ink storage chamber 111. Therefore, since the connection formation part 440 connects two places where the frame part 110 opposes, it is also a reinforcement member which maintains the intensity | strength of the frame part 110. FIG. Moreover, the connection formation part 440 is also a partition plate which partitions off so that the 1st opening 112a side and the 2nd opening 112b side may become a substantially equivalent space area | region.

  The connection forming part 440 is connected to the atmosphere side connection part 441 provided on the atmosphere introduction part 130 side (the left side in FIG. 4 (a) or the right side in FIG. 4 (b)) with the inner circumference welded parts 415a and 415b as a boundary. It is comprised with the dispensing connection part 442 provided in the injection part 150 side (FIG. 4 (a) right side or FIG. 4 (b) left side). The atmosphere-side connecting portion 441 includes inner-surface welded portions 413a, 413b, 414a, and 414b from the atmosphere-side connecting portion 441 on the first and second openings 112a and 112b sides (FIG. Side and heel side or FIG. 4 (b) vertical direction front side and heel side of the paper surface. In addition, the dispensing side connecting portion 442 has inner circumferential welded portions 416a, 416b, 417a, and 417b extending from the dispensing side connecting portion 442 to the first and second openings 112a and 112b side (FIG. 4A). It is erected on the front side and the heel side in the vertical direction or on the front side and the heel side in the vertical direction of FIG. 4B.

  The atmosphere-side connecting portion 441 is formed with a first connecting communication hole 443 that communicates between the first chamber 111a and the second chamber 111b, and the dispensing-side connecting portion 442 has the first chamber 111a. The second to fourth connection communication holes 444 to 446 are formed to connect the first chamber 111b and the second chamber 111b. Here, if the connection communication holes 443 to 446 are not formed in the connection forming portion 440, the first chamber 111a and the second chamber 111b do not communicate with each other at the substantially central portion of the ink storage chamber 111. There may be a slight difference in the amount of ink from the second chamber 111b. If there is a difference in the amount of ink between the first chamber 111a and the second chamber 111b, a difference occurs in the air pressure in the ink storage chamber 111, which causes a problem that ink cannot be supplied smoothly (or accurately). However, by forming the connection communication holes 443 to 446 by diffusing into the connection formation portion 440, the ink amount in the first chamber 111a and the second chamber 111b can be made substantially equal, and the ink can be smoothly (or Accurately) can be supplied.

  A portion surrounded by the atmosphere side connecting portion 441, the dispensing side connecting portion 442, and the atmosphere communication path forming portion 430 is a first storage chamber opening 113 that communicates the first chamber 111a and the second chamber 111b. A portion surrounded by the atmosphere side connecting portion 441, the dispensing side connecting portion 442, and the supply path forming portion 420 is a second storage chamber opening 114 that communicates the first chamber 111a and the second chamber 111b. That is, the first chamber 111a and the second chamber 111b communicate with each other in a portion that introduces the atmosphere into the ink storage chamber 111 and a portion that supplies the ink stored in the ink storage chamber 111 to the outside. Therefore, introduction of air and ink supply can be performed in a stable space.

  The connection forming portion 440 is formed with connection ribs 418a and 418b that connect the plurality of inner circumference welded portions 411a to 417a and the inner circumference welded portions 411b to 417b. Although not shown in the drawing, the connecting ribs 418a and 418b are formed in a thin wall with standing walls lower than the inner circumference welded portions 411a to 417a and the inner circumference welded portions 411b to 417b. Further, the connecting ribs 418 a and 418 b are formed at the edge of the connection forming portion 440. Therefore, since the connection ribs 418a and 418b connect the inner circumference welded portions 411a to 417a and 411b to 417b and are formed at the edge of the connection forming portion 440, the strength of the connection forming portion 440 can be maintained. Further, since the connecting ribs 418a and 418b are formed in a thin shape and are formed with standing walls lower than the inner circumference welded portions 417a to 417a and 411b to 417b, it is possible to reduce the obstruction of ink circulation. Can do.

  Next, the dispensing path forming unit 450 will be described with reference to FIG. FIG. 7 is a diagram showing the dispensing channel forming unit 450, FIG. 7A is a diagram showing an outline of the dispensing channel forming unit 450, and FIG. 7B is a diagram illustrating FIG. It is sectional drawing of the dispensing path formation part 450 in the VIIb-VIIb line | wire of). The dispensing path forming unit 450 is positioned at the top of the ink storage chamber 111 in a posture in which ink is dispensed, and the dispensed ink is directed toward the ink supply unit 120 and the air introduction unit 130. To flow down.

  As shown in the drawing, the dispensing channel forming unit 450 includes a dispensing cylinder part 451 formed in a substantially cylindrical shape into which an ink dispensing plug 520 (see FIG. 10) described later is press-fitted, and the dispensing cylinder part 451. A first dispensing communication hole 452 that communicates with the inside of the ink storage chamber 111 and a dispensing wall that stands from the outer surface of the dispensing cylinder 451 and partitions the first dispensing communication hole 452 with respect to the ink storage chamber 111. It mainly includes a partition wall 453 and a second dispensing communication hole 454 that becomes an opening portion of the dispensing partition wall 453. Further, the opened portion of the dispensing tube portion 451 is an opening 451a formed on the outer end surface of the frame portion 110, and the surface corresponding to the opening 451a is the bottom portion 451b of the dispensing tube portion 451. The range defined by the dispensing partition 453 and the film 160 is the dispensing partition channel 453a.

  The dispensing partition wall 453 is a part of the inner circumference welded portion where the film 160 is welded, and the dispensing path and the second dispensing communication hole 454 are formed in a state where the film 160 is welded. In addition, the dispensing partition 453 is located on the same virtual plane of the outer peripheral welded portion 400b as the other inner peripheral welded portions 411b to 417b.

  As will be described later, when ink is dispensed into the ink storage chamber 111, the second dispensing communication hole 454 is positioned above and the first dispensing communication hole 452 is positioned below. Dispensing is performed (posture in FIG. 7A). Further, the ink passes in the order of the dispensing cylinder portion 451 of the dispensing formation portion 450, the first dispensing communication hole 452, the dispensing partition channel 453a surrounded by the dispensing partition 453, and the second dispensing communication hole 454. The ink is dispensed until the ink level I reaches FIG. 7 (a). In addition, the dispensing partition wall 453 is formed substantially linearly from the first dispensing communication hole 452 to the second dispensing communication hole 454. Therefore, the ink is dispensed smoothly without resistance.

  If ink is dispensed to fill the ink storage chamber 111, the volume of the ink expands and the film 160 is damaged or deformed depending on the environment in which the ink cartridge 1 is placed. If the film 160 is damaged, the ink leaks, and if the film 160 is deformed, the volume in the ink storage chamber 111 changes and stable ink supply cannot be performed. Therefore, in order to prevent the damage and deformation of the film 160, the ink is not dispensed until the ink storage chamber 111 is full.

  In this embodiment, the pressure in the ink storage chamber 111 after the ink is dispensed is set lower than the atmospheric pressure. Therefore, a decompression process may be performed after the atmosphere in the ink storage chamber 111 is sucked from the dispensing path forming unit 450 and decompressed. This is performed to reduce the atmosphere in the ink storage chamber 111 in order to maintain the degree of deaeration of the ink, and to reduce the generation of bubbles in the ink. The degassing of the ink is to keep the viscosity of the ink substantially constant, and the generation of bubbles in the ink causes the ink to be discharged when the bubbles are supplied to the inkjet recording apparatus 1000 (see FIG. 29). This is because the pressure is not transmitted to the ejection port (not shown) and the ink cannot be ejected accurately.

  In addition, when the post-depressurization step is performed, if the atmosphere in the ink storage chamber 111 is sucked from the dispensing path forming unit 450, an accurate ink amount is not obtained even though an appropriate amount of ink is dispensed. If the amount of ink decreases, it will cause a loss to the user of the ink cartridge 1, which is not preferable. Therefore, the first dispensing communication hole 452 is surrounded by a substantially U-shaped dispensing partition wall 453, and the second dispensing communication hole 454 is located above the ink level I (or the first dispensing communication hole 452) (FIG. 7 ( Even if the inside of the ink storage chamber 111 is depressurized, there is a distance between the ink liquid level I and the second dispensing communication hole 454, so that the ink in the ink storage chamber 111 is separated. Extraction to the outside through the channel formation portion 450 can be reduced.

  Here, the structure in the vicinity of the detection unit 140 will be described with reference to FIG. FIG. 8 is a diagram showing the vicinity of the detection unit 140, FIG. 8A is a diagram showing an outline of the vicinity of the detection unit 140, and FIG. 8B is a diagram of FIG. FIG. 8C is a cross-sectional view of the detection unit 140 along the line VIIIb, and FIG. 8C is a cross-sectional view of the vicinity of the detection unit 140 along the line VIIIc-VIIIc of FIG.

  As shown in FIG. 8A, the detection unit 140 protrudes outward (right side in FIG. 8A) from the frame unit 110. The detection unit 140 includes an inner packet part 141 that includes a tip of the sensor arm 470 (see FIG. 9) so as to be sandwiched between a pair of wall surfaces and forms a passage through which the sensor arm 470 can be displaced, and the inner packet part 141. An arm support part 142 that supports the sensor arm 470 from below, and is connected to the arm support part 142 in the vicinity of the detection part 140, extends in the direction of the supply path forming part 420, and extends from the inner wall of the frame part 110. A standing wall 143 is provided.

  As shown in FIG. 8B, the inner wall (a pair of wall surfaces) of the inner packet part 141 and the arm support portion are formed from the first gap t3 between the inner wall (a pair of wall surfaces) of the inner packet part 141 and the outer wall of the sensor arm 470. The thickness of the arm support portion 142 is formed so that the second gap t4 between the outer wall 142 and the outer wall 142 becomes narrower. Here, when the ink stored in the detection unit 140 decreases, the ink level I decreases as the ink decreases, and when the ink level I decreases from the detection unit 140, the ink in the detection unit 140 decreases. Although the first gap t3 between the sensor arm 470 and the inner packet part 141 is very small, ink remains in the detection unit 140 due to the surface tension of the ink, and the sensor arm 470 is normal due to the surface tension of the ink. May not rotate. Therefore, by forming the arm support part 142 so that the first gap t3> the second gap t4, the arm support part 142 and the inner packet part 141 are obtained from the surface tension of the ink generated between the sensor arm 470 and the inner packet part 141. The surface tension of the ink generated between the two becomes stronger. Therefore, the ink remaining in the inner packet part 141 is attracted between the arm support part 142 and the inner packet part 141, so that the ink remaining between the sensor arm 470 and the inner packet part 141 can be reduced, and the sensor arm 470. It can suppress that the behavior of is inhibited. Accordingly, since the sensor arm 470 behaves normally, the remaining amount of ink can be accurately detected.

  Further, as shown in FIG. 8A, the bottom wall 141a of the lower part (lower side of FIG. 8A) of the inner packet part 141 is inclined downward toward the ink storage chamber 111. The bottom surface formed by the bottom wall 141a is also inclined downward. Therefore, the ink drawn between the inner packet part 141 and the arm support part 142 flows down in the direction of the ink storage chamber 111 (or the supply path forming part 420). Further, as shown in the cross-sectional view of FIG. 8B, the connecting portion (edge) between the bottom wall 141a of the inner packet part 141 and the arm support part 142 is formed in a cross-sectional view (substantially right angle). The capillary force at the connecting portion between the inner packet part 141 and the arm support part 142 becomes stronger, and the ink is easily guided to the ink storage chamber 111 (or the supply path forming part 420). That is, the connecting portion between the inner packet part 141 and the arm support part 142 becomes a liquid guiding (guide) path for guiding ink. Therefore, the ink remaining in the inner packet part 141 can be efficiently flowed down.

  Further, as shown in FIG. 8A, the standing wall 143 connected to the arm support portion 141 is formed on an inclined surface 143 a that is inclined downward from the arm support portion 141 toward the supply path forming portion 420. The inclined surface 143a constitutes a part of the inner wall of the frame portion 110. Further, as shown in the cross-sectional view of FIG. 8C, the connecting portion between the standing wall 143 and the inner wall of the frame portion 110 is formed in a cross sectional view (substantially right angle), and the thickness of the arm support portion 141 is substantially the same. It is formed equally. Therefore, the standing wall 143 is inclined downward in the direction of the supply path forming portion 420, and the connecting portion with the inner wall of the frame portion 110 is formed at a substantially right angle. Therefore, the supply path forming portion is efficiently used by the inclination and the capillary force. Ink can be directed in the 420 direction. That is, the connecting portion between the standing wall 143 and the inner wall of the frame portion 110 serves as a liquid guiding (guide) path for guiding ink. Since the arm support portion 142 and the standing wall 143 have substantially the same thickness, the standing wall 143 is formed continuously from the arm support portion 142. Therefore, there is no resistance in guiding the ink to the supply path forming unit 420, and the ink can be guided efficiently.

  When the sensor arm 470 is rotated upward, the sensor arm 470 comes into contact with the ceiling surface formed by the ceiling wall 141b facing the bottom wall 141a of the detection unit 140, and the rotation of the sensor arm 470 is restricted. Is done. Therefore, since the sensor arm 470 can be prevented from jumping out from the inner packet part 140, the behavior of the sensor arm 470 becomes accurate, and the remaining amount of ink can be detected accurately.

  Here, the sensor arm 470 will be described with reference to FIG. 9 is a view showing the sensor arm 470, FIG. 9A is a view showing the front side of the sensor arm 470, and FIG. 9B is a view taken along the arrow IXb in FIG. 9A. It is the figure which showed the sensor arm 470 in. The sensor arm 470 is a member for detecting the remaining amount of ink in the ink storage chamber 111. The sensor arm 470 is made of a resin material (for example, polypropylene) and is manufactured by injection molding.

  The sensor arm 470 is a rotating member that rotates in accordance with the remaining amount of ink in the ink storage chamber 111, and a remaining ink detection sensor 1014 that detects the remaining amount of ink stored in the ink storage chamber 111 (FIG. 29). The detection unit is detected by (see). The sensor arm 470 includes a balance portion 471 formed of a material having a specific gravity smaller than the specific gravity of the ink, an attachment portion 472 that is swingably attached to the frame portion 110, and the attachment portion 472 to the balance portion 471. It mainly includes an arm portion 473 that extends in the vertical direction (upward in FIG. 9A) and further inclines upward and blocks the detectable range of the ink remaining amount detection sensor 1014. The attachment portion 472 serves as a connecting portion that connects the balance portion 471 and the arm portion 473.

  The attachment portion 472 is formed with a substantially cylindrical attachment shaft 472a attached to the arm holding portion 425 (see FIG. 4) of the frame portion 110. The attachment shaft 472a is formed to have a diameter smaller than the inner diameter of the arm holding portion 425 and a diameter larger than the length of the opening of the arm holding portion 425. Therefore, when the sensor arm 470 rotates, the sensor arm 470 can be operated with less resistance and the sensor arm 470 can be prevented from being detached from the arm holding portion 425.

  The arm portion 473 includes a vertical arm portion 473a extending in a substantially vertical direction (upward in FIG. 9A) with respect to the balance portion 471, an inclined arm portion 473b inclined upward from the vertical arm portion 473a, and an ink remaining amount detection sensor. 1014 (see FIG. 29) and a shielding arm portion 473c as a light shielding portion that shields the detectable range.

  As shown in FIG. 9B, the arm portion 473 is formed extremely thin with respect to the balance portion 471 and the attachment portion 472. This is because when the arm portion 473 is formed thick, the detection portion 140 is enlarged, and as a result, the resistance force when the ink cartridge 1 becomes larger or the sensor arm 470 rotates is increased. The remaining ink level may not be detected. Further, as the thickness of the detection unit 140 increases, the detection range of the ink remaining amount detection sensor 1014 is increased accordingly, and therefore an expensive and high-performance ink remaining amount detection sensor is required. Therefore, the arm portion 473 is formed thin in order to prevent the ink cartridge 1 from becoming large-scale and accurately detect the remaining amount of ink. The vertical arm portion 473a and the inclined arm portion 473b are formed with ribs 473d to maintain strength.

  Further, the shielding arm portion 473c has substantially hemispherical arm protrusions 473e1 and 473e2 at the upper and lower portions (the upper end portion and the lower end portion in FIG. 8A) of the portion accommodated in the detection portion 140. The arm protrusions 473e1 and 473e2 reduce the situation where the shield arm 473c is brought into close contact with the inner wall of the detection unit 140 due to the surface tension of the ink and cannot be rotated. That is, since the arm protrusions 473e1 and 373e2 are formed in a hemispherical shape, only the tip of the arm protrusions 473e1 and 473e2 is in contact with the inner wall of the detection unit 140, thereby reducing the influence of the surface tension of the ink. .

  Since the balance portion 471 is made of a resin material having a specific gravity smaller than the specific gravity of the ink, when the ink level I drops as the ink remaining amount decreases, the balance 471 decreases as the liquid level I drops. The part 471 moves toward the bottom of the frame part 110 (downward in FIGS. 4A and 4B). When the balance portion 471 moves in the bottom direction, the arm portion 473 moves upward using the mounting portion 472 as a support shaft of the rotation shaft, and the ink is out of the detectable range of the ink remaining amount detection sensor 1014. Can be detected.

  In addition, in some conventional balance portions, the balance portion is hollowed in order to float the balance portion on the ink liquid surface I, but with this configuration, processing (or molding) of the balance portion becomes difficult. On the other hand, in this embodiment, the material of the sensor arm 470 is made of a material having a specific gravity smaller than the specific gravity of the ink, so that a processing step is not required and a complicated mold need not be manufactured. Therefore, the manufacturing cost of the sensor arm 470 can be reduced.

  Next, the component configuration of the ink reservoir 100 will be described with reference to FIG. FIG. 10 is an exploded front view of the ink reservoir 100.

  As shown in FIG. 10, the ink reservoir 100 is mainly disassembled into four parts. The four parts are a frame part 110, an ink supply mechanism 500 constituting the ink supply part 120, an air introduction mechanism 510 constituting the air introduction part 130, and a dispensing cylinder part 451 of the ink dispensing part 150 (FIG. 7). Reference) and an ink dispensing plug 520 that is press-fitted into the inside. The ink dispensing plug 520 is made of an elastic member such as pulch rubber. Once the ink dispensing plug 520 is press-fitted into the dispensing cylinder 451, it cannot be easily removed. It is configured to be blocked.

  Further, the frame portion 110 is formed in a substantially cylindrical shape in which a part of the ink supply mechanism 500 is inserted into a substantially cylindrical shape and a part of the air introduction mechanism 510 is inserted. An air introduction body 117 is formed. Further, the ink supply body 116 has protrusions 116 a and 116 b (protrusion parts 116 b not shown) protruding in the outer peripheral direction of the ink supply body 116 in order to fix the ink supply mechanism 500. They are arranged symmetrically around the center (arranged on the front side and the heel side in the vertical direction in FIG. 10). Similarly, the air introduction body 117 has protrusions 117 a and 117 b (projection part 117 b not shown) protruding in the outer peripheral direction of the air introduction body 117 in order to fix the air introduction mechanism 510. They are arranged symmetrically about the axis (arranged on the front side and the heel side in the vertical direction in FIG. 10). The protrusions 116 a, 116 b, 117 a, 117 b have an end surface on the ink storage chamber 111 side protruding in a direction perpendicular to the outer peripheral surface of the ink supply body 116 or the outer peripheral surface of the air introduction body 117, and the protruding tip From the surface to the outer peripheral surface of the ink supply body 116 or the outer peripheral surface of the air introduction body 117. That is, when the ink supply mechanism 500 and the air introduction mechanism 510 are attached to the ink supply body 116 and the air introduction body 117, the ink supply mechanism 500 and the air introduction mechanism 510 can be prevented from being easily detached.

  Next, components of the ink supply mechanism 500 and the air introduction mechanism 510 will be described with reference to FIGS. 11 is an exploded view of the ink supply mechanism 500 and the atmosphere introduction mechanism 510, FIG. 11A is an exploded view of the ink supply mechanism 500, and FIG. 11B is an exploded view of the atmosphere introduction mechanism 510. FIG.

  As shown in FIG. 11A, in the ink supply mechanism 500, a supply cap 600 attached to the ink supply body 116 and an ink extraction tube 1015 (see FIG. 29) of the ink jet recording apparatus 1000 (see FIG. 29) are inserted. A supply joint 610 made of an elastic resin material such as rubber, a supply valve 620 that closes the ink flow path when the supply joint 610 contacts the bottom wall, and the supply valve 620 A first supply spring 630 housed in a resinous elastic material and a uniaxial direction that covers the open surface of the supply valve 620 and is the moving direction of the supply valve 620 pressed by the ink extraction pipe 1015 (FIG. 11 ( a) Supply slider 640 operable in the direction of arrow H1, hereinafter referred to as “direction of axis O1 of ink supply mechanism 500”, and its supply A second supply spring 650 housed in the rider 640 and formed of the same material and shape as the first supply spring 630; a valve seat 660 that contacts the second supply spring 650 and receives the check valve 670; A cover 680 is provided between the valve seat 660 and the check valve 670. The supply valve 620, the first supply spring 630, the supply slider 640, and the second supply spring 650 serve as the supply valve member 501 that actually operates.

  As shown in FIG. 11B, the air introduction mechanism 510 includes an air cap 700 attached to the air introduction body 117, an air joint 710 made of a resin material having elasticity such as rubber, and the air. When the joint 710 contacts the bottom wall, the ink flow path is blocked, and when the ink cartridge 1 is mounted on the inkjet recording apparatus 1000 (see FIG. 29), it contacts the mounting surface of the inkjet recording apparatus 1000. An atmospheric valve 720 that opens an atmospheric flow path (passage), a first atmospheric spring 730 that is housed in the atmospheric valve 720 and made of a resinous elastic material, and covers and opens the open surface of the atmospheric valve 720. 1-axis direction (FIG. 11 (b) arrow O2 direction, hereinafter referred to as “the direction of the axis O2 of the atmospheric supply mechanism 510” An operable air slider 740 "and also referred to), and a second atmosphere spring 750 which is formed in the same shape as the first air spring 730 is housed within the air slider 740 in the same material. The atmospheric valve 720, the first atmospheric spring 730, the atmospheric slider 740, and the second atmospheric spring 750 are the atmospheric valve members 511 that actually operate.

  Hereinafter, with reference to FIGS. 12 to 22, a supply cap 600, a supply joint 610, a supply valve 620, first and second supply springs 630 and 650, a supply slider 640, a valve seat 660, a check valve 670, and a cover 680, atmospheric cap 700, atmospheric joint 710, atmospheric valve 720, first and second atmospheric springs 730 and 750, and atmospheric slider 740 will be described.

  FIG. 12 is a view showing the supply cap 600, FIG. 12 (a) is a view showing a side surface of the supply cap 600, and FIG. 12 (b) is a view in the direction of arrow XIIb in FIG. 12 (a). FIG. 12C is a diagram illustrating a side surface of the supply cap 600, FIG. 12C is a diagram illustrating a plane of the supply cap 600, and FIG. 12D is a diagram illustrating a bottom surface of the supply cap 600; FIG. 12E is a cross-sectional view of the supply cap 600 taken along the line XIIe-XIIe in FIG.

  As shown in FIG. 12A, the supply cap 600 is formed in a two-stage shape when viewed from the side (FIG. 12A as viewed in the direction perpendicular to the paper surface), and the upper portion of FIG. The lower portion of FIG. 12B is an ink storage space for preventing ink dripping to the outside of the ink cartridge 1. An ink reservoir 602.

  The supply fixing portion 601 is formed from the connecting portion of the ink reservoir 602 to the vicinity of the upper portion (near the upper end portion in FIG. 12A), and the supply cap 600 is fixed to the ink supply body 116 (see FIG. 10). In this case, engagement holes 603a and 603b (see FIG. 12B for the engagement holes 601b) that engage with the protrusions 116a and 116b (see FIG. 10) of the ink supply body 116 are formed.

  As shown in FIG. 12B, the supply fixing portion 601 is formed on a straight line substantially orthogonal to the straight line connecting the engagement holes 603a and 603b (substantially about the axis O1 of the ink supply mechanism 500). (Position moved 90 degrees), supply cap cutouts 604a and 604b (supply cap cutout 604b are shown in FIG. c)) is formed.

  As shown in the front view of FIG. 12C and the bottom view of FIG. 12D, an ink extraction tube 1015 (see FIG. 29), which will be described later, is inserted into the approximate center position of the ink reservoir 602 of the supply cap 600. An insertion hole 605 is formed. As shown in FIG. 12C, the circle from the insertion hole 605 to the one outer circle is a first upper wall 606a that forms the upper end surface of the ink reservoir 602, and the first upper wall 606a is From the outer circle to be formed to one outer circle is an inclined wall 606b that forms an inclined surface that is inclined downward toward the bottom surface of the ink reservoir 602, and one outer side from the outer circle that forms the inclined wall 606b. The lower wall 606c that forms the lower end surface of the ink storage portion 602 is formed up to the circle, and the lower end surface of the supply fixing portion 601 is formed from the outer circle that forms the lower wall 606c to the one outer circle. The second upper wall 606d forms the upper end surface of the ink reservoir 602, and the portion connecting the lower wall 606c and the second upper wall 606d is the outer peripheral wall 606e that forms the outer peripheral surface of the ink reservoir 602. . The inclined wall 606b becomes a cylindrical portion inside the ink reservoir 602, and the outer peripheral wall 606e connected to the inclined wall 606b by the lower wall 606c is an inclined wall 606b (inner cylindrical portion). It becomes the outer cylindrical part which surrounds.

  In FIG. 12D, since the inclined wall 606b is inclined downward, the insertion port of the ink extraction tube 1015 is formed in a tapered shape as shown in the sectional view of FIG. Therefore, when the ink extraction tube 1015 is inserted, the ink extraction tube 1015 is smoothly inserted because the ink extraction tube 1015 is guided while being guided by the tapered inclined surface. Therefore, the inner peripheral surface on the axis O1 side of the inclined wall 606b becomes an insertion path into which the ink extraction tube 1015 (see FIG. 29) is inserted. In addition, an ink storage in which ink can be stored (stored) during a range t5 shown in FIGS. 12C and 12E (that is, a space formed by the inclined wall 606b, the lower wall 606c, and the outer peripheral wall 606e). Part 607.

  When the supply cap 600 is attached to the ink supply body 116 (see FIG. 10), since the protrusions 116a and 116b of the ink supply body 116 protrude in the outer peripheral direction, the diameter of the supply cap 600 increases in the outer peripheral direction. Installation is performed while. Since the supply cap notches 604a and 604b are formed, the diameter of the supply cap 600 is increased in the direction in which the engaging portions 603a and 603b are separated from each other. Therefore, when attaching the supply cap 600, it can carry out without applying a strong pressure, Therefore The mounting efficiency can be improved, reducing the damage of the supply cap 600. FIG.

  13 is a view showing the supply joint 610, FIG. 13 (a) is a view showing a side surface of the supply joint 610, and FIG. 13 (b) is a view showing a plane of the supply joint 610. FIG. 13C is a view showing the bottom surface of the supply joint 610, and FIG. 13D is a cross-sectional view of the supply joint 610 along the line XIIId-XIIId in FIG. 13B.

  As shown in FIG. 13A, the supply joint 610 is formed in three stages in a side view (see FIG. 13A in a direction perpendicular to the paper surface). The portion shown in the lowermost step (the lower side in FIG. 13A) is in contact with the second upper wall 605d of the ink reservoir 602 of the supply cap 600 (see FIG. 12) and the inner peripheral surface of the supply fixing portion 601. A joint outer peripheral portion 611 that is a contact portion and forms the outer peripheral portion of the supply joint 610. The joint outer peripheral portion 611 is a portion that is sandwiched between the second upper wall 606 d of the supply cap 600 and the outer end surface of the ink supply body 116 when the supply cap 600 is fixed to the ink supply body 116. . The portion shown in the upper part of the joint outer peripheral portion 611 is a joint inner peripheral portion 612 that is press-fitted into the ink supply body 116 (see FIG. 10) and forms the inner peripheral portion of the supply joint 610. FIG. 13A shows the upper part of the joint inner periphery 612. Furthermore, the part shown in the upper stage of the joint inner peripheral part 612 is a joint contact part 613 that contacts the supply valve 620 (see FIG. 14). The supply joint 610 is made of an elastic material such as resin rubber. As shown in FIG. 13B, the shaft center of the supply joint 610 is located on the shaft center O1 of the ink supply mechanism 500, and the joint contact portion 613, from the shaft center O1 toward the outer peripheral direction. The joint inner periphery 612 and the joint outer periphery 611 are formed in this order.

  As shown in FIG. 13D, a joint contact portion 613 protrudes from the upper surface 612a of the joint inner peripheral portion 612 (the surface on the side in contact with the supply valve 620). The joint abutting portion 613 is formed to be thinner toward the tip end portion 613a (the upper end portion in FIG. 13D), and the tip end portion 613a abuts against the bottom surface of the supply valve 620 to block the ink flow path. To do. Further, the joint inner peripheral portion 612 is formed on the joint protrusion 614 protruding from the inner peripheral surface toward the axis O1 and the bottom surface 612b of the joint inner peripheral portion 612 (lower side in FIG. 13 (d)). An opening 612c serving as an insertion port for the ink extraction tube 1015 (see FIG. 29) and a step-like insertion passage 612d formed between the opening 612c and the joint projection 614 are formed. As shown in FIG.13 (c), the step-shaped part of the insertion path 612d is formed in the outer peripheral direction from the axial center O1 at substantially equal intervals. The inner peripheral surface 614a of the joint protrusion 614 is provided in parallel to the direction of the axis O1 of the ink supply mechanism 500, and the step surface 614b is provided in a direction orthogonal to the direction of the axis O1. .

  Further, as shown in FIG. 13D, the supply joint 610 penetrates from the bottom surface 612b of the joint inner peripheral portion 612 to the tip portion 613a of the joint contact portion 613 (from the upper side to the lower side in FIG. 13D). An ink flow path 615 is formed. The ink flow path 615 includes an opening 612c formed in the bottom surface 612b, a stepped flow path 615a defined by a step-shaped insertion path 612d connected to the opening 612c, and a joint protrusion connected to the insertion path 612d. The protrusion channel 615b defined by the inner peripheral surface 614a of the portion 614, the step surface 614b provided continuously with the inner peripheral surface 614a of the joint protrusion 614, and the joint contact portion 613 provided continuously with the step surface 614b. It is comprised from the contact part flow path 615c demarcated by the internal peripheral surface 613b.

  The staircase portion channel 615a has a lower half formed in a step shape in the direction of the axis O1, and an upper half formed in a taper shape toward the protruding portion channel 615b. Further, the staircase channel 615a is formed in a staircase shape whose diameter gradually decreases from the opening 612c toward the connecting portion with the inner peripheral surface 614a of the joint projection 614. Since the lower part of the staircase channel 615a is formed in a staircase shape, even if a small amount of ink flows through the ink channel 615 when the ink extraction tube 1015 (see FIG. 29) is pulled out, The ink can be held by the capillary force by the corners, and the ink dripping out of the supply joint 610 can be reduced. In the present embodiment, since the supply cap 600 includes the ink reservoir 602, the stepped portion of the lower half of the staircase channel 615a may be tapered.

  The protrusion channel 615b is a channel having the minimum inner diameter of the ink channel 615, and is formed in a substantially hollow cylindrical shape. The inner diameter of the protrusion channel 615b is slightly smaller than the diameter of the ink extraction tube 1015 (see FIG. 29). The contact part flow path 615c is formed in a substantially hollow cylindrical shape having an inner diameter larger than that of the protrusion part flow path 615b, and the inner diameter is sufficiently larger than the diameter of the ink extraction tube 1015. Then, the step surface 614b is formed at the boundary between the protruding portion flow path 615b and the abutting portion flow path 615c, so that the inner diameter in the direction of the axis O1 from the protruding portion flow path 615b to the contacting portion flow path 615c rapidly increases. It has changed. Accordingly, as shown in FIG. 13 (d), the joint contact portion 613 has a structure that is notched in a staggered shape by the inner peripheral surface 613b and the stepped surface 614b. A tip end portion 613a of the joint contact portion 613 is positioned around the periphery.

  The ink extraction tube 1015 inserted from the opening 612c is guided by the upper portion of the staircase channel 615a formed in a tapered shape and is inserted into the protrusion channel 615b. At this time, since the inner diameter of the projection channel 615b is slightly smaller than the diameter of the ink extraction tube 1015, the ink extraction tube 1015 is elastically applied to the inner peripheral surface 614a of the joint projection 614 that forms the projection channel 615b. It is press-fitted so as to closely contact and push the protruding portion flow path 615b. That is, the joint protrusion 614 acts to seal the periphery of the ink extraction tube 1015 press-fitted into the protrusion flow path 615b. Note that when the area of the portion of the supply joint 610 that elastically adheres to the outer periphery of the ink extraction tube 1015 increases, the resistance when the ink cartridge 1 is attached to the ink jet recording apparatus 1000 (see FIG. 29) increases, and smoothness is achieved. It becomes impossible to install. However, in this embodiment, since the joint protrusion 614 is provided and contacts the ink extraction tube 1015 only on the inner peripheral surface 614a, the contact surface with the ink extraction tube 1015 can be reduced, and ink jet recording is performed. Attachment to the apparatus 1000 can be performed smoothly. Note that the ink extraction pipe 1015 is inserted into the ink flow path 615, so the flow path through which the ink actually flows is inside the ink extraction pipe 1015. Further, by forming the contact portion flow path 615c in a spot shape, it is possible to reduce the displacement of the supply joint 610 in the direction of the axis O1 when the ink extraction tube 1015 is inserted.

  FIG. 14 is a view showing the supply valve 620, FIG. 14 (a) is a view showing a side surface of the supply valve 620, and FIG. 14 (b) is a view as viewed from an arrow XIVb in FIG. FIG. 14C is a diagram illustrating a side surface of the supply valve 620, FIG. 14C is a diagram illustrating a plane of the supply valve 620, and FIG. 14D is a diagram illustrating a bottom surface of the supply valve 620. FIG. 14E is a cross-sectional view of the supply valve 620 taken along the line XIVe-XIVe in FIG.

  As shown in FIG. 14A, the supply valve 620 includes a valve bottom wall 621 that forms the bottom surface (lower side surface of FIG. 14A) of the supply valve 620, and an ink supply mechanism 500 (see FIG. 14) from the valve bottom wall 621. 10) and an outer peripheral wall 622 of the valve standing along the direction of the axis O1.

  The valve outer peripheral wall 622 is formed with a pair of valve guide grooves 623 into which the slider loose insertion portion 643 of the supply slider 640 (see FIG. 16) is loosely inserted. As shown in FIG. 14C, the pair of valve guide grooves 623 are formed symmetrically with respect to the direction of the axis O <b> 1 of the ink supply mechanism 500. Further, as shown in FIG. 14A, the valve outer peripheral wall 622 is formed with a valve protruding wall 624 that protrudes from the upper portion of the valve outer peripheral wall 622 in the direction opposite to the valve bottom wall 621 in the axial center O1 direction. The valve guide groove 623 is formed from the tip of the valve protruding wall 624 to the vicinity of the lower portion of the valve outer peripheral wall 622. Therefore, by ensuring the long distance of the valve guide groove 623, it is possible to reduce the slider loose insertion portion 643 from being detached from the valve guide groove 623.

  The valve outer peripheral wall 622 is connected to a pair of valve restricting portions 625 that project in the opposite direction of the valve bottom wall 621 and restrict the operation of the supply slider 640. Each of the valve restricting portions 625 includes a valve hook portion 626 that protrudes from its tip (tip of the upper portion in FIG. 14A) toward the axis O <b> 1 and engages with the supply slider 640.

  Further, the valve outer peripheral wall 622 is formed with a valve protrusion 622 a that protrudes in a semicircular shape in the outer peripheral direction and is formed from the upper part to the lower part of the valve outer peripheral wall 622. The valve protrusion 622a is provided to smoothly operate the supply valve 620 when the supply valve 620 is inserted into the ink supply body 116 (see FIG. 10). Without the valve protrusion 622a, the inner peripheral surface of the ink supply body 116 and the valve outer peripheral wall 622 may come into contact with each other. Therefore, the contact area with the ink supply body 116 becomes large, and the resistance during operation increases. End up. Therefore, by providing the valve protrusion 622a protruding in a semicircular shape, the operation of the supply valve 620 in the ink supply body 116 becomes smooth.

  Further, the valve restricting portion 625 and the valve protruding wall 624 are formed to extend upward from the valve outer peripheral wall 622. As a result, it is possible to prevent the supply slider 640 from shifting in a direction perpendicular to the direction of the axis O1. Further, since the operation of the supply slider 640 in the direction of the axis O1 is restricted by the valve restricting portion 625, the first supply spring 630 can be securely stored and operated.

  As shown in FIG. 14C, the valve bottom wall 621 corresponds to the valve guide groove 623 and the valve restricting portion 625 when viewed in the direction of the axis O1 of the ink supply mechanism 500 (the direction perpendicular to the paper surface of FIG. 14C). The four ink flow paths 627 communicating with the valve bottom wall 621 in the vertical direction (FIG. 13C, the direction perpendicular to the paper surface) are formed. The valve bottom wall 621 protrudes upward from the bottom surface (FIG. 14 (c), the front side in the direction perpendicular to the paper surface), and is a valve receiving portion 628 that is a base that receives the spring upper portion 632 of the first supply spring 630 (see FIG. 15). It has. The valve receiving portion 628 is composed of two plate-like members arranged substantially in parallel on the valve bottom wall 621. Further, as shown in FIG. 14 (e), the height of the valve receiving portion 628 in the direction of the axis O 1 is extremely low with respect to the valve outer peripheral wall 622. The valve receiver 628 is provided to prevent the first supply spring 630 from coming into contact with the valve bottom wall 621 when the first supply spring 630 is disposed in the space inside the valve outer peripheral wall 622. This is because if the first supply spring 630 comes into contact with the valve bottom wall 621, the ink flow path is blocked and the ink does not flow. Therefore, the valve receiving portion 628 is provided to secure the ink flow path, and the first supply spring 630 does not have to abut against the valve bottom wall 621. Thus, the size of the ink supply mechanism 500 in the direction of the axis O1 is prevented from increasing.

  A valve inner peripheral wall 629 formed in a substantially arc shape covering the outer peripheral surface of the spring upper part 632 of the first supply spring 630 is provided outside the valve receiving portion 628 and inside the ink flow path 627. The valve inner peripheral wall 629 is provided to restrict the movement of the first supply spring 630 in the direction orthogonal to the axis O1 and the movement of the first supply spring 630 in the direction orthogonal to the axis O1. By restricting, the first supply spring 630 is accurately bent in the direction of the axis O1.

  15 is a view showing the first supply spring 630, FIG. 15A is a view showing a side surface of the first supply spring 630, and FIG. 15B is a view showing the first supply spring 630. FIG. 15C is a diagram illustrating a bottom surface of the first supply spring 630, and FIG. 15D is a first supply along the XVd-XVd line in FIG. 15B. 4 is a cross-sectional view of a spring 630. FIG.

  The first supply spring 630 is formed on the substantially reverse bowl side (or substantially hollow conical shape), and has a ring-shaped spring bottom 631 that forms the bottom surface (end of the larger diameter) of the first supply spring 630; A ring-shaped spring top 632 that is formed to have a diameter smaller than the diameter of the spring bottom 631 and forms the top (smaller end) of the upper surface of the first supply spring 630, and the spring top 632 and the spring bottom 631 and the direction of the axis O1 of the ink supply mechanism 500 (the direction of movement of the supply valve 620 pressed against the ink extraction tube 1015 (see FIG. 29)), the first supply spring 630 and the second supply spring 630. And a spring flexible portion 633 that is bent and deformed when a load of the supply spring 650 (which is also the biasing direction of the supply spring 650) is applied. . The spring upper portion 632 is in contact with the valve receiving portion 628 of the supply valve 620 (see FIG. 14) and serves as a pressing portion that presses the supply valve 620 in the direction of the supply joint 610 (see FIG. 13). Since the diameter of the spring bottom 631 is larger than the diameter of the spring top 632, the spring bottom 631 serves as a base when the spring flexible portion 633 is elastically deformed.

  As shown in FIG. 15 (d), the first supply spring 630 communicated with the spring top 632 from the tip (FIG. 15 (d) right end surface) to the bottom surface of the spring bottom 631 (FIG. 15 (d) left end surface). An ink flow path 634 is formed. The ink flow path 634 includes an upper flow path 634 a defined by the inner peripheral surface of the spring upper part 632, a flexible part flow path 634 b defined by the inner peripheral surface of the spring flexible part 633, and an inner part of the spring bottom 631. The bottom channel 634c is defined by the peripheral surface. The opening area of the ink flow path 634 gradually increases from the tip of the spring top 632 toward the bottom of the spring bottom 631 as shown in FIG. As shown in FIGS. 15B and 15C, the upper flow path 634a of the spring upper portion 632 is formed in a circular shape when viewed in the direction perpendicular to the paper surface.

  Note that the cross-sectional shape of the upper flow path 634a of the spring upper portion 632 may be formed in a substantially rectangular shape. If the opening of the upper flow path 634a is formed in a substantially square shape, the influence of bubbles contained in the ink can be reduced. Here, since the bubbles contained in the ink are spheres, and the flow path is blocked by bubbles that grow larger than the inner diameter of the upper flow path 634a, the ink flow path (passage) disappears and the ink is normally discharged. It cannot be fed into the ink jet recording apparatus 1000 (see FIG. 29). As a result, the quality of printing by the ink jet recording apparatus 1000 is degraded. However, by forming the opening of the upper flow path 634a in a substantially square shape, even if bubbles that have grown large on the opening surface of the upper flow path 634a stop, the four corners are not blocked, so the ink flow path is blocked. It is possible to prevent the printing quality from deteriorating. Furthermore, the opening surface of the upper flow path 634a is not limited to a quadrangle, and may be formed in a polygonal shape such as a hexagon or a star shape. It is good also as what forms in a diameter.

  As shown in FIG. 15D, the spring upper portion 632 is formed in a relatively thick cylindrical shape extending in the direction of the axis O1, and the direction of the axis O1 (the biasing direction of the first supply spring 630). ) And the vertical cross-sectional shape are uniform. Similarly, the spring bottom 631 is also formed in a relatively thick cylindrical shape extending in the direction of the axis O1, and the cross-sectional shape perpendicular to the direction of the axis O1 is uniform.

  Further, as shown in FIG. 15D, the spring flexible portion 633 is formed in a substantially inverted bowl shape (or substantially conical shape) that is curved (or inclined) at a predetermined angle with respect to the direction of the axis O1. As a result, the strength against the load in the direction of the axis O <b> 1 is weaker than that of the spring bottom 631 and the spring top 632. In addition, since the thickness of the spring flexible portion 633 is thinner than that of the spring bottom 631 and the spring upper portion 632, the strength is also weakened by this. Therefore, when the first supply spring 630 is elastically deformed, the spring flexible portion 633 is bent and deformed.

  The second supply spring 650 is formed in the same shape as the first supply spring 630, and the configuration of the second supply spring 650 includes a spring bottom 651, a spring top 652, a spring flexible part 653, and an ink flow path 654. (Upper channel 654a, flexible channel 654b, and bottom channel 654c). Further, the first atmospheric spring 730 and the second supply spring 750 are also formed in the same shape as the first supply spring 630, and have spring bottom portions 731 and 751, spring top portions 732 and 752, and spring flexible portions 733 and 753, respectively. And ink flow paths 734 and 754 (upper flow paths 734a and 754a, flexible flow paths 734b and 754b, and bottom flow paths 734c and 754c).

  FIG. 16 is a view showing the supply slider 640, FIG. 16 (a) is a view showing a side surface of the supply slider 640, and FIG. 16 (b) is a view as viewed from an arrow XVIb of FIG. 16 (a). FIG. 16C is a diagram illustrating a side surface of the supply slider 640, FIG. 16C is a diagram illustrating a plane of the supply slider 640, and FIG. 16D is a diagram illustrating a bottom surface of the supply slider 640, FIG. 16E is a cross-sectional view of the supply slider 640 along the line XVIe-XVIe in FIG.

  The supply slider 640 is made of a resin material having a hardness higher than that of the first supply spring 630 (see FIG. 15) and the second supply spring 650. The slider outer peripheral wall 641 that forms the outer periphery of the supply slider 640, and the slider The slider protruding walls 642a and 642b protrude from the outer peripheral wall 641 in the direction of the axis O1 of the ink supply mechanism 500, respectively, and extend from the slider outer peripheral wall 641 to the upper end of the slider protruding wall 642a (the upper end surface in FIG. 16A). , A pair of slider loosely inserted portions 643 that are loosely inserted into the valve guide groove 623 (see FIG. 14) of the supply valve 620, and the bottoms of the first and second supply springs 630 and 650 formed inside the slider outer peripheral wall 641. First and second supply springs 630 and 650 are disposed on both sides in contact with 631 and 651. A slider pedestal portion 644, is formed at the center position of the slider pedestal portion 644, and a slider through hole 645 for communicating the upper and lower slider pedestal portion 644 mainly includes.

  The inner diameter of the slider outer peripheral wall 641 is formed substantially equal to the outer diameter of the spring bottoms 631 and 651 of the first and second supply springs 630 and 650, and the slider protruding walls 642a and 642b are pivoted from the slider outer peripheral wall 641. Since the first and second supply springs 630 and 650 are disposed, the first and second springs 630 and 650 are perpendicular to the axis O1 when the first and second supply springs 630 and 650 are disposed. Movement is restricted. Therefore, the first and second springs 630 and 650 are reliably elastically deformed in the direction of the axis O1.

  The slider loose insertion portion 643 is formed so as to extend in the direction of the axis O1 of the supply slider 640 (it is formed across the slider outer peripheral wall 641 and the slider protrusion 642), so that the valve guide groove 623 ( 14), the supply slider 640 can be smoothly moved in the direction of the axis O1 and can be prevented from being displaced in a direction orthogonal to the direction of the axis O1.

  17 is a view showing the valve seat 660, FIG. 17 (a) is a view showing a side surface of the valve seat 660, and FIG. 17 (b) is a view showing a plane of the valve seat 660. FIG. 17 (c) is a view showing the bottom surface of the valve seat 660, and FIG. 17 (d) is a cross-sectional view of the valve seat 660 along the line XVIId-XVIId in FIG. 17 (b).

  As shown in FIG. 17A, the valve seat 660 forms the bottom surface of the valve seat 660, and contacts the spring top 632 of the second supply spring 650, and the valve seat bottom 661. And a valve seat receiving portion 662 arranged on the upper surface (upper side in FIG. 17A). The valve seat receiving portion 662 includes a valve seat inclined surface 662a that is inclined downward toward the center of the valve seat 660, and a check valve 670 described later is received by the valve seat inclined surface 662a.

  As shown in FIG. 17B, six valve seat receiving portions 662 are formed at predetermined equal intervals in the circumferential direction of the valve seat 660. Further, of the six valve seat receiving portions 662, three valve seat receiving portions 662 are formed with first valve seat through holes 662b penetrating the front and back of the valve seat 660. The first valve seat through hole 662b is formed in a portion other than the valve seat inclined surface 662a of the valve seat receiving portion 662 (horizontal portion of the valve seat receiving portion 662). Therefore, since the first valve seat through-hole 662b is formed in a portion different from the portion that receives the check valve 670, it is possible to prevent the ink flow path from being blocked.

  A second valve seat through hole 663 that penetrates the valve seat bottom 661 is formed between the valve seat receiving portions 662 of the valve seat 660. In FIG. 17B, the second valve seat through-hole 663 is 6 symmetrically with respect to a center line (center line Q shown in FIG. 17) passing through the axis O1 of the ink supply mechanism 500 (see FIG. 10). Individually formed. The second valve seat through hole 663 serves as an ink flow path through which ink flows.

  As shown in FIG. 17C, a concave valve seat communication groove 664 that communicates with each second valve seat through hole 663 is formed on the bottom surface of the valve seat bottom portion 661. The valve seat communication groove 664 communicates the second valve seat through-holes 663 substantially linearly on the bottom surface of the valve seat bottom portion 661. Accordingly, the valve seat bottom 661 is formed with three valve seat communication grooves 664 that intersect at the axis O1. A pair of valve seat protrusions 665 protruding from the bottom surface are formed on the bottom surface of the valve seat bottom 661. The valve seat protrusion 665 houses a spring upper portion 652 of the second supply spring, and comes into contact with the outer peripheral surface of the spring upper portion 652 of the second spring 650 so as to be orthogonal to the axis O1 of the second supply spring 650. Movement in the direction is restricted.

  As shown in FIG. 17D, a gap is formed in the direction of the axis O1 between the valve seat inclined surface 662a of the valve seat receiving portion 662 and the second valve seat through hole 663. Therefore, even when the check valve 670 is supported by the valve seat inclined surface 662a, an ink flow path is secured. Even when the end surface of the spring upper portion 632 of the second supply spring 650 is in contact with the bottom surface of the second valve seat through-hole 663, the second valve seat through-hole 663 is an imaginary circumference of the valve seat protrusion 665. Since it is located outside the phantom line R in FIG. 17 (c), an ink flow path is secured by the valve seat communication groove 664. In addition, since the valve seat communication groove 664 communicates with all the second valve seat through holes 663, the ink flow path is ensured even if there is the second valve seat through hole 663 surrounded by the valve seat protrusion 665. Secured.

  18 is a view showing the check valve 670, FIG. 18 (a) is a view showing a side surface of the check valve 670, and FIG. 18 (b) is a plan view of the check valve 670. 18C is a view showing the bottom surface of the check valve 670, and FIG. 18C is a cross-sectional view of the check valve 670 along the line XVIIId-XVIIId in FIG. It is.

  The check valve 670 is formed in a substantially umbrella shape in a side view (viewed in the vertical direction in FIG. 18A), and includes an umbrella portion 671 and a shaft portion 672. The umbrella portion 671 closes the ink flow path by contacting the cover 680 (see FIG. 19), and is connected to the shaft portion 672 as shown in FIGS. 18 (b) and 18 (d). A connecting portion 671a and a blade portion 671b extending from the connecting portion 671a in the outer peripheral direction substantially uniformly and formed in a thin shape are provided. Therefore, when contacting the cover 680, the thin blade 671b is in close contact with the cover 680 while being elastically deformed, so that the ink flow path between the cover 680 and the check valve 670 is reliably connected. Can be blocked.

  Further, as shown in FIG. 18A, the lower surface of the umbrella portion 671 is curved and is supported by the valve seat receiving portion 662 (see FIG. 17) of the valve seat 660. Therefore, the umbrella portion 671 is provided. Is supported by the valve seat receiving portion 662 of the valve seat 660, the ink flow path is opened, and when the umbrella portion 671 of the check valve 670 is in contact with the cover 680, the ink flow The road is blocked.

  The shaft portion 672 is a portion that is inserted into a second cover communication hole 684 (see FIG. 19) of a cover 680 described later. The shaft portion 672 has a spherical portion 672a formed in a substantially spherical shape, located in the vicinity of the cover 680 when attached to the cover 680. The ball portion 672a is formed to have a diameter larger than the diameter of the second cover communication hole 684 of the cover 680. After the check valve 670 (see FIG. 17) is once attached to the cover 680, the check valve 670 falls off. Is preventing. Therefore, it is possible to reduce the loss of the check valve 670 when the ink cartridge 1 is manufactured, and it is possible to improve workability.

  19 is a view showing the cover 680, FIG. 19 (a) is a view showing a side surface of the cover 680, and FIG. 19 (b) is a view showing a plane of the cover 680. 19 (c) is a view showing the bottom surface of the cover 680, and FIG. 19 (d) is a cross-sectional view of the cover 680 along the line XIXd-XIXd in FIG. 19 (b).

  The cover 680 is formed in a substantially cylindrical shape having an open bottom surface (the valve seat 660 (see FIG. 17) side). The cover 680 includes a cover outer peripheral wall 681 that forms the outer periphery of the cover 680 and a cover upper portion 682 that forms the upper surface of the cover 680 (upper side in FIG. 19A), and the lower surface is open. In the cover 680, the valve seat 660 is fitted into the opening on the lower surface (the lower side in FIG. 19A), and the check valve 670 is accommodated between the valve seat 660 and the cover 680. That is, a space for accommodating the check valve 670 is formed by the cover 680 and the valve seat 660.

  As shown in FIG. 19B or 19C, the cover upper portion 682 is formed with six first cover through holes 683 penetrating the front and back of the cover 680 in the circumferential direction with respect to the axis O1. ing. The first cover through hole 683 becomes a flow path through which ink flows, and the umbrella portion 671 (see FIG. 17) of the check valve 670 contacts the cover upper portion 682, thereby closing the first cover through hole 683, The ink flow path is blocked.

  Further, a second cover through hole 684 through which the shaft portion 672 of the check valve 670 is inserted is formed at the center of the cover upper portion 682 (a position passing through the axis O1 of the ink supply mechanism 500). The shaft portion 672 of the check valve 670 is inserted into the second cover through hole 684, and the check valve 670 is assembled. Even if the check valve 670 is inserted in the second cover through-hole 684, an ink flow path is formed on a part of the inner peripheral surface thereof. However, when the umbrella portion 671 of the check valve 670 comes into contact with the cover upper portion 682, the entire first cover through-hole 683 is closed, so that the ink flow path of the second cover through-hole 684 formed in the center is also at the same time. Blocked.

  20 is a view showing the atmospheric cap 700, FIG. 20 (a) is a view showing a side surface of the atmospheric cap 700, and FIG. 20 (b) is an arrow XXb view of FIG. 20 (a). FIG. 20C is a diagram illustrating a side surface of the atmospheric cap 700, FIG. 20C is a diagram illustrating a plane of the atmospheric cap 700, and FIG. 20D is a diagram illustrating a bottom surface of the atmospheric cap 700; FIG. 20E is a cross-sectional view of the atmospheric cap 700 taken along line XXe-XXe in FIG.

  As shown in FIG. 20A, the atmospheric cap 700 forms a side wall of the atmospheric cap 700 and is fixed to the atmospheric introduction body 117 (see FIG. 10). And an atmospheric cap bottom wall 702 forming a bottom wall 700. The air adhering portion 701 is formed from the lower portion (lower side of FIG. 20A) to the vicinity of the upper portion (near the upper end portion of FIG. 20A), and the air cap 700 is introduced into the air. When fixed to the body 117, engagement holes 703a and 703b (see FIG. 12B for the engagement holes 703b) that are engaged with the projections 117a and 117b of the air introduction body 117 described above are formed. .

  As shown in FIG. 20B, the atmosphere fixing portion 701 is formed at a position moved approximately 90 degrees with respect to the axis O2 of the atmosphere introduction mechanism 510 from the position where the engagement holes 703a and 703b are formed. Atmospheric cap notches 704a and 704b (atmospheric cap notch 704b is not shown) cut from the upper end of the atmosphere adhering portion 701 to the vicinity of the lower portion are formed.

  As shown in the plan view of FIG. 20 (c) and the bottom view of FIG. 20 (d), a joint skirt portion 714 (see FIG. 21) of the atmospheric joint 710, which will be described later, is provided at a substantially central position of the atmospheric cap bottom wall 702. And an atmospheric cap insertion hole 705 through which the valve opening 721a (see FIG. 22) of the atmospheric valve 720 is inserted. Note that an atmospheric joint 710 (see FIG. 21) is stored in contact with the inner surface of the atmospheric cap bottom wall 702 and the inner peripheral surface of the atmospheric fixing portion 701.

  When the atmospheric cap 700 is attached to the atmospheric introduction body 117, the projections 117a and 117b of the atmospheric introduction body 117 project in the outer circumferential direction as in the case of the supply cap 600. It is attached while expanding the diameter. Therefore, when attaching the atmospheric cap 700, it can be performed without applying a strong pressure, and the mounting efficiency can be improved while reducing the damage of the atmospheric cap 700.

  FIG. 21 is a view showing the atmosphere joint 710, FIG. 21A is a view showing a side surface of the atmosphere joint 710, and FIG. 21B is a view showing a plane of the atmosphere joint 710. FIG. 21 (c) is a view showing the bottom surface of the atmospheric joint 710, and FIG. 21 (d) is a cross-sectional view of the atmospheric joint 710 along the line XXId-XXId in FIG. 21 (b).

  As shown in FIG. 21A, the air joint 710 is formed in four stages in a side view (see FIG. 21A in a direction perpendicular to the paper surface). The portion shown in the second row from the lower side (the lower side in FIG. 21A) is a portion that abuts on the inner peripheral surface of the atmospheric fixing portion 701 (see FIG. 20) of the atmospheric cap 700 and the atmospheric cap bottom wall 702. It is a joint outer peripheral portion 711 that forms the outer peripheral portion of the atmospheric joint 710. The portion shown in the upper stage of the joint outer peripheral portion 711 is a joint inner peripheral portion 712 that is disposed inside the atmospheric introduction body 117 (see FIG. 10) and forms the inner peripheral portion of the atmospheric joint 710, FIG. 21A shows the upper part of the joint inner periphery 712. Further, the upper portion of the joint inner peripheral portion 712 is a joint contact portion 713 that contacts the atmospheric valve 720. The lowermost portion is a member that covers the outer surface of the valve opening 721a (see FIG. 22) of the atmospheric valve 720 and is exposed outward from the atmospheric cap 700, and is a thin joint. A skirt portion 714 is provided.

  As shown in FIG. 21 (b), the joint outer peripheral portion 711, joint inner peripheral portion 712, joint contact portion 713, and joint skirt portion 714 have the same axial center as the axial center O2 direction of the air introduction mechanism 510. Is located. Further, since the air joint 710 is made of an elastic material such as resin rubber, the joint skirt portion 714 formed in a thin shape is used when the ink cartridge 1 is mounted on the ink jet recording apparatus 1000 (see FIG. 29). Is elastically deformed in contact with the end face on the ink jet recording apparatus 1000 side.

  As shown in FIG. 21D, a joint contact portion 713 protrudes from the upper surface 712a of the joint inner peripheral portion 712 (the surface on the side in contact with the atmospheric valve 720). The joint abutting portion 713 is formed to be thinner toward the tip end portion 713a (upper end portion in FIG. 21 (d)), and the tip end portion 713a abuts against the bottom surface of the atmosphere valve 720 to block the atmosphere introduction path. To do. Further, as shown in FIG. 21 (d), the atmosphere joint 710 has a joint that penetrates from the bottom surface of the joint inner peripheral portion 712 to the tip end portion 713a of the joint contact portion 713 (FIG. 21 (d) from the upper side to the lower side). A passage 715 is formed, and the valve opening portion 721 a of the atmospheric valve 720 is inserted through the joint passage 715.

  22 is a view showing the atmospheric valve 720, FIG. 22 (a) is a view showing a side surface of the atmospheric valve 720, and FIG. 22 (b) is a view showing a bottom surface of the atmospheric valve 720. is there. The air valve 720 protrudes from the bottom surface of the valve bottom wall 721 with respect to the supply valve 620, and has a valve opening portion 721a that contacts the ink jet recording apparatus 1000 (see FIG. 29) side and opens the air introduction path. This is an added configuration. Therefore, the valve bottom wall 721, the valve outer peripheral wall 722, the valve protrusion 722a, the valve guide groove 723, the valve protrusion wall 724, the valve restricting portion 725, the valve hook portion 726, the air introduction passage 727 (the portion corresponding to the ink passage 627) ), Detailed description of the valve receiving portion 728 and the valve inner peripheral wall 729 is omitted. In addition, the illustration of the portion that cannot be visually recognized by the side view (FIG. 22A) and the bottom view (FIG. 22B) of the atmospheric valve 720 is also omitted.

  The atmospheric valve 720 includes a valve opening 721 a that protrudes from the bottom surface of the valve bottom wall 721. The valve opening portion 721a is located on the axis O2 of the atmosphere introduction mechanism 510 and is formed in a substantially rod shape. Further, the valve opening portion 721a is formed with a substantially semicircular convex portion 721b protruding in the outer peripheral direction from the lower portion (lower end surface in FIG. 22) to the valve bottom wall 721 on the outer peripheral surface thereof. This valve opening portion 721a passes through the joint passage 715 (see FIG. 21) of the above-described atmospheric joint 710, and is further partially exposed to the outside of the atmospheric cap 700 (see FIG. 20). When the ink cartridge 1 is mounted on the ink jet recording apparatus 1000 (see FIG. 29), the valve opening portion 721a comes into contact with the end surface of the ink jet recording apparatus 1000, and the joint contact portion 713 (tip portion 713a) of the atmospheric joint 710. Is released and an air introduction path is formed.

  When the ink cartridge 1 is mounted on the ink jet recording apparatus 1000 and the valve opening portion 721a operates, the joint skirt portion 714 of the atmospheric joint 710 is also in contact with the end face of the ink jet recording apparatus 1000 and elastically deforms, and the air introduction path And communication with the outside of the joint skirt portion 714 is blocked. Therefore, the air introduced from the inkjet recording apparatus 1000 side can be smoothly introduced. Further, even if the joint skirt portion 714 is elastically deformed toward the axis O2 and comes into contact with the valve opening portion 721a, the air introduction path can be secured by the convex portion 721b of the valve opening portion 721a. Therefore, it is possible to prevent the atmosphere introduction path from being blocked and the atmosphere from being introduced into the ink storage chamber 111 (see FIG. 4).

  Next, a state where the ink supply mechanism 500 and the air introduction mechanism 510 are assembled to the ink supply body 116 and the air introduction body 117 will be described with reference to FIG. FIG. 23 is a partial cross-sectional view showing a state where the ink supply mechanism 500 and the air introduction mechanism 510 are assembled to the ink supply body 116 and the air introduction body 117.

  As shown in FIG. 23, the ink supply mechanism 500 is inserted into and attached to the inner peripheral surface 800 of the ink supply body 116, and the atmospheric introduction mechanism 510 is inserted into the inner peripheral surface 810 of the atmospheric introduction body 117. Has been attached.

  First, the ink supply mechanism 500 attached to the ink supply body 116 will be described. On the inner peripheral surface 800 of the ink supply body 116, a protruding wall 801 protruding inward of the inner peripheral surface 800 is formed on the first supply communication hole 421 side of the supply path forming portion 420. It is formed in a staircase shape that can accommodate the cover 680. The cover 680 is inserted so as to abut on the stepped surface 801 a formed in a step shape of the protruding wall 801, and the position of the ink supply mechanism 500 on the first supply communication hole 421 side is determined.

  The shaft portion 672 of the check valve 670 is inserted into the second cover through-hole 684 of the cover 680, and the valve seat 660 is disposed so as to accommodate the check valve 670 in the cover 680. A second supply spring 650 is disposed on the bottom surface side (left side in FIG. 23) of the valve seat 660, and a supply slider 640 is disposed so as to accommodate the second supply spring 650. A first supply spring 630 is accommodated on the opposite side of the supply slider 640 to the second supply spring 650, and the first supply spring 630 is disposed between the supply slider 640 and the supply valve 620. A supply joint 610 is disposed so as to contact the bottom surface of the supply valve 620, and the supply cap 600 is fixed to the outside of the ink supply body 116 so as to contact the bottom surface of the supply joint 610. Since the supply cap 600 is engaged and fixed to the protrusions 116 a and 116 b of the ink supply body 116, the position outside the ink supply mechanism 500 is determined. Accordingly, the ink supply mechanism 500 is positioned in the direction of the axis O1 by the supply cap 600 and the step surface 801a of the inner peripheral surface 800 of the ink supply body 116.

  In addition, the inner diameter 800 of the inner peripheral surface 800 of the ink supply body 116 is formed to be slightly larger than the outer diameter of the supply valve 620, and the operation of the supply valve 620 in the direction of the axis O1 is smoothly performed inside the ink supply body 116. It is configured to be As described above, the four valve protrusions 622a are formed on the outer peripheral surface of the supply valve 620 so that the contact area with the inner peripheral surface 800 is reduced. Therefore, even if the supply valve 620 operates in an oblique direction with respect to the axis O1 and comes into contact with the inner peripheral surface 800, it is possible to prevent the supply valve 620 from becoming inoperable. Since a gap is formed between the supply valve 620 and the inner peripheral surface 800, an ink flow path that passes through the inside of the ink supply mechanism 500 and an ink flow path that passes through the outside of the supply valve 620 are formed. . Therefore, the inner peripheral surface 800 of the ink supply body 116 is a space that forms an ink flow path chamber.

  As described above, the slider pedestal portion 644 is sandwiched between the first supply spring 630 and the spring bottom 631 of the second spring member. Further, on the contact side of the spring pedestal 644 with the spring bottom 631 of the second supply spring 650, the supply valve 620 is engaged by the two valve hook portions 626, and movement in the direction of the axis O1 is restricted. . The space formed between the supply valve 620 and the supply slider 640 is shorter than the length of the first supply spring 630 in the axial center O1 direction. Therefore, the first supply spring 630 is attached to the ink supply body 116. Already bent and deformed.

  Next, the air introduction mechanism 510 attached to the air introduction body 117 will be described. The inner peripheral surface 810 of the air introduction body 117 is provided with a protrusion 811 protruding in the direction of the air introduction mechanism 510 (the left direction in FIG. 23) on the end surface of the air introduction path forming portion 430 on the first air communication chamber 431 side. Yes. The protrusion 811 is composed of a pair of plate-like members and abuts against the end surface of the spring upper portion 752 of the second atmospheric spring 750. Therefore, an atmosphere introduction path is formed between the protrusion 811 and the spring upper portion 752 of the second atmosphere spring 750. Further, when the second atmospheric spring 750 comes into contact with the protruding portion 811, the position of the atmospheric introduction mechanism 510 on the first atmospheric communication hole 434 side is determined.

  As in the ink supply mechanism 500 side, the atmospheric air introduction mechanism 510 has an atmospheric slider 740 disposed so as to accommodate the second atmospheric spring 750, and the atmospheric slider 740 has a first atmospheric spring on the opposite side of the first atmospheric spring 750. An atmospheric spring 730 is accommodated, and a first atmospheric spring 730 is disposed between the atmospheric slider 740 and the atmospheric valve 720. An atmospheric joint 710 is disposed so as to contact the bottom surface of the atmospheric valve 720, and the atmospheric cap 700 is fixed to the outside of the atmospheric introduction body 117 so as to contact the bottom surface on the outer peripheral side of the joint skirt portion 714 of the atmospheric joint 710. Is done. Since the atmospheric cap 700 is engaged and fixed with the protrusions 117a and 117b of the atmospheric introduction body 117, the position outside the atmospheric introduction mechanism 510 is determined. Therefore, the atmosphere introduction mechanism 510 is positioned in the axial center O2 direction by the atmosphere cap 700 and the protrusion 811 of the inner peripheral surface 810 of the atmosphere introduction body 117.

  Since the space formed between the atmospheric valve 720 and the atmospheric slider 740 is shorter than the length of the first atmospheric spring 730 in the axial center O2 direction, the first atmospheric spring 730 is similar to the ink supply mechanism 500. In the state where it is assembled to the air introduction body 117, it has already been bent and deformed.

  Next, the manufacturing process of the ink cartridge 1 will be described with reference to FIGS. FIG. 24 is a diagram illustrating a manufacturing process before the film 160 is welded. FIG. 25 is a diagram for explaining a welding process of the film 160, FIG. 25 (a) is a diagram for explaining a welding surface of the film 160 to the frame portion 110, and FIG. It is a figure explaining the welding process welded to the flame | frame part. FIG. 26 is a diagram for explaining a manufacturing process performed after the film 160 is welded, and FIG. 26A is a diagram for explaining an attachment process for attaching the ink supply mechanism 500 and the air introduction mechanism 510 to the frame portion 110. FIG. 26B is a diagram for explaining the decompression step, and FIG. 26C is a diagram for explaining the ink dispensing step. FIG. 27 is a diagram for explaining a process for assembling the case 200, FIG. 27 (a) is a diagram for explaining a process for holding the case 200 between the frame portions 110, and FIG. It is a figure explaining the welding process which welds. FIG. 28 is a diagram for explaining a manufacturing process performed before shipment of the ink cartridge 1, FIG. 28 (a) is a diagram for explaining a process for attaching the protector 300, and FIG. 28 (b) is a diagram for explaining the ink cartridge. It is a figure explaining the process of packaging 1 with the packaging bag 930. FIG.

  As shown in FIG. 24, in manufacturing the ink cartridge 1, first, the sensor arm 470 is attached to the frame portion 110. In addition, the frame part 110 and the sensor arm 470 are each molded by injection molding in the previous process (molding process). That is, the first molding process (preparation process) for injection molding the frame part 110 and the second molding process (preparation process) for injection molding of the sensor arm 470 are respectively performed in advance.

  The sensor arm 470 has an attachment shaft 472a provided in the attachment portion 472 of the sensor arm 470 attached to an arm clamping portion 425 provided in the vicinity of the supply path forming portion 420 of the frame portion 110 (attachment process of the sensor arm 470). , Preparation process). The arm clamping portion 425 is open on the side opposite to the ink supply body 116 side (upper side in FIG. 24). In other words, the opening of the arm holding portion 425 opens toward the second storage chamber opening 114 side. Therefore, since the sensor arm 470 can be attached in a range where the first chamber 111a and the second chamber 111b communicate with each other, there is little interference and the sensor arm 470 can be attached efficiently. The sensor arm 470 is attached so that the shielding arm portion 473c of the arm portion 473 is housed inside the detection portion 140.

  When the attachment of the sensor arm 470 is completed, the ink dispensing plug 520 is then press-fitted into the dispensing cylinder 451 of the ink dispensing unit 150 (press-fitting process and preparation process of the ink dispensing plug 520). The ink dispensing plug 520 is press-fitted so that the outer end surface 520a of the ink dispensing plug 520 is substantially flush with the outer surface of the frame part 110, and is press-fitted to a position where it abuts against the bottom 451b of the dispensing cylinder part 451. do not do. As described above, this is because the first dispensing communication hole 452 of the dispensing channel forming portion 450 is formed on the side surface of the dispensing tube portion 451, and the ink dispensing plug 520 is connected to the dispensing tube portion 451. This is because the first dispensing communication hole 452 is blocked when the press-fitting is carried out up to the soot, and the ink cannot be dispensed.

  As shown in FIG. 25A, when the sensor arm 470 and the ink dispensing plug 520 are attached, the film 160 is then welded (the fixing process of the film 160). The film 160 is welded to the frame portion 110 so as to cover the openings on both sides of the first opening 112a and the second opening 112b. That is, the film 160 is attached to the frame portion by two fixing steps including a first fixing step (preparation step) for welding the film 160 to the first opening 112a and a second fixing step for welding the film 160 to the second opening 112b. It is welded to both sides of 110.

  Further, as shown in FIG. 25B, the film 160 is cut to be larger than the outer shape of the frame part 110 and is installed so as to cover the frame part 110. At this time, the film 160 is disposed on the first opening 112a and the second opening 112b by sucking the film 160 from the frame part 110 side with a suction device (not shown). Thereafter, an ultrasonic welding surface 900 of an ultrasonic mounting device (not shown) is installed so as to cover the outer peripheral portions (outer peripheral welding portions 400a and 400b) of the first and second openings 112a and 112b from above the film 160, and the film 160 is welded to the frame part 110. In addition, as for the welding to each welding part of the film 160, the part (outer periphery welding part 400a, 400b and inner periphery welding part 411a-417a, 411b-417b) of FIG.

  Since a plurality of inner peripheral welded portions 411a to 417a and 411b to 417b are diffused and formed on the inner peripheral side of the outer peripheral welded portions 400a and 400b, the frame portion 110 is super-corresponding to all the welded portions. When sonic welding is performed, the structure of the ultrasonic welding surface 900 becomes complicated, and the manufacturing cost increases. However, in this embodiment, since the ultrasonic welding surface 900 of the ultrasonic welding apparatus is configured to cover all the welding parts (the outer circumferential welding part and the inner circumferential welding part), the manufacturing cost of the welding process of the film 160 is reduced. It is possible to reduce the increase.

  The film 160 is a two-layer film (hereinafter referred to as “nylon polyethylene”) made of a nylon film and a polyethylene film, and the side in contact with the frame portion 110 is a polyethylene film layer. Yes. This nylon polyethylene completely blocks the liquid but has a low gas barrier property. Therefore, it is slightly between the ink storage chamber 111 substantially sealed by the film 160 and a packaging bag 930 (see FIG. 28B) described later. Gas can be moved back and forth. Therefore, since the gas present in the ink in the ink storage chamber 111 can gradually move through the film 160 to the space formed between the inclusion body 930 and the case 200, bubbles are generated in the ink. Can be reduced. Accordingly, it is possible to prevent the deterioration of the printing quality due to the bubbles in the ink. The film 160 may be made of any material as long as it can maintain strength and has a low gas barrier property. Examples thereof include a film in which a nylon film and a polypropylene film are formed in two layers, and a film formed by mixing nylon and polyethylene or nylon and polypropylene.

  The frame part 110 is made of nylon resin and is made of the same material as the film on the frame part 110 side of the film 160. By configuring the film 160 and the frame part 110 with the same material, both the film 160 and the welded part can be melted and reliably welded during ultrasonic welding. In this embodiment, the film 160 has a two-layer structure. A nylon film is superior in strength to a polyethylene film, but has a high melting point but is inferior in terms of welding workability. Therefore, the film 160 has a two-layer structure made of nylon and polyethylene, so that the strength is ensured, and the polyethylene layer is used as a welding layer with the frame portion 110 to enable welding at a low heating temperature. The sex is secured. In addition, since the nylon layer does not melt during the welding operation, the change in the thickness of the film near the welded portion is reduced, and the strength of the film near the welded portion can be maintained.

  As shown in FIG. 26A, when the film 160 is completely welded, the ink supply mechanism 500 and the air introduction mechanism 510 are then attached to the frame portion 110. The ink supply mechanism 500 is attached to the ink supply body 116 (attachment process and preparation process of the ink supply mechanism 500), and the air introduction mechanism 510 is attached to the air introduction body 117 (attachment process and preparation process of the air introduction mechanism 500). In attaching the ink supply mechanism 500 (attachment process), first, the cover 680, the check valve 670, and the valve seat 660 are integrated into the ink supply body 116 (position where the step surface 801a comes into contact). At this time, the check valve 670 is attached so that the tip of the check valve 670 protrudes into the space surrounded by the supply partition 422 through the first supply communication hole 421 (see FIG. 23). Thereafter, the supply joint 600, the supply valve 620, the first supply spring 630, the supply slider 640, and the second supply spring 650 are integrated into the inner peripheral surface 800 of the ink supply body 116 in the supply cap 600. At the same time, the supply cap 600 is fixed to the outer peripheral surface of the ink supply body 116. At this time, the supply cap 600 is pressed toward the ink supply body 116, and the engagement holes 603 a and 603 b of the supply cap 600 are engaged with the protrusions 116 a and 116 b of the ink supply body 116. In the supply joint 610, the joint inner peripheral portion 612 is press-fitted into the inner peripheral surface 800 of the ink supply body 116, and the joint outer peripheral portion 611 is sandwiched between the ink supply body 116 and the supply cap 600. When the attachment of the supply cap 600 to the ink supply body 116 is finished, the attachment of the ink supply mechanism 500 is finished, and the ink supply unit 120 is configured.

  Further, the attachment (attachment process) of the atmosphere introduction mechanism 510 to the atmosphere introduction body 117 is similar to the attachment of the ink supply mechanism 500 to the ink supply body 116, the atmosphere joint 710, the atmosphere valve 720, and the first one. The air spring 730, the air slider 740, and the second air spring 750 are integrated into the inner peripheral surface 810 of the air introduction body 117, and the air cap 700 is fixed to the outer peripheral surface of the air introduction body 117. It is done by doing. At this time, the atmospheric cap 700 is pressed toward the atmospheric introduction body 117, and the fitting holes 703 a and 703 b of the atmospheric cap 700 are fitted into the protrusions 117 a and 117 b of the atmospheric introduction body 117. In the atmosphere joint 710, the joint inner periphery 712 is press-fitted into the inner periphery 810 of the atmosphere introduction body 117, and the joint outer periphery 711 is sandwiched between the atmosphere introduction body 117 and the atmosphere cap 700. When the attachment of the atmosphere cap 700 to the atmosphere introduction body 117 is finished, the attachment of the atmosphere introduction mechanism 510 is finished, and the atmosphere introduction unit 130 is configured.

  As shown in FIG. 26B, when the ink supply mechanism 500 and the air introduction mechanism 510 are attached to the ink supply body 116 and the air introduction body 117 (each attachment process), the frame portion 110 (ink storage chamber 111) is completed. A depressurization step for depressurizing the inside is performed. In this embodiment, the decompression in the frame part 110 is performed from the ink supply part 120 side. To reduce the pressure in the frame portion 110, first, the suction pipe 911 of the pressure reducing device 910 is inserted through the supply joint 610 of the ink supply mechanism 500 to press the supply valve 620, thereby opening the ink flow path. Thereafter, the suction pump (P1) 912 is driven to suck the air in the frame part 110. When the atmospheric pressure in the frame unit 110 is sucked by the decompression device 910 and reaches a predetermined pressure (at least lower than atmospheric pressure), the suction pump 912 is stopped and the suction pipe 911 is removed from the ink supply unit 120. When the suction tube 911 is removed from the ink supply unit 120, the supply valve 620 contacts the joint contact portion 613 of the supply joint 610 by the elastic force of the first and second supply springs 630 and 650, and the ink flow. Since the path is blocked, the decompressed state is maintained.

  As shown in FIG. 26 (c), when the decompression in the frame part 110 is completed by the decompression process, the ink dispensing needle 920 is inserted into the ink dispensing plug 520, and the ink is put into the frame part 110 (ink reservoir chamber 111). Dispensing (ink dispensing process). Since the inside of the ink storage chamber 111 is depressurized, the ink is vigorously dispensed into the ink storage chamber 111, and when a predetermined amount of ink is dispensed, the dispensing needle 920 is pulled out and the ink dispensing step. Ends. It becomes the atmospheric pressure p1 (first pressure) in the ink storage chamber 111 after the ink is dispensed. In addition, the predetermined amount of ink is an amount in which the ink liquid level I is below the second atmospheric communication hole 435 and the third atmospheric communication hole 436 of the atmospheric communication path forming portion 430, as shown in FIG. is there. Therefore, when ink is dispensed, ink can be prevented from entering the atmosphere connection path 433. The reason why ink is not dispensed in the ink storage chamber 111 without a gap is to prevent the film 160 from being damaged or deformed as described above. In addition, the ink space shown in FIG. 26C below which the ink is stored is below the ink level I, and the space above the ink level I and the space including the atmosphere communication path forming portion 430 are formed. Although it is an atmosphere communication space (decompression space), the shape and size of the ink space and the atmosphere communication space change depending on the state where the ink cartridge 1 is placed and the ink remaining amount.

  Since the ink is dispensed in a state where the inside of the ink storage chamber 111 is decompressed by the decompression device 910, the pressure in the ink storage chamber 111 is reduced even after the ink dispensing is completed ( Atmospheric pressure p1). Therefore, there are cases where a post-depressurization step is not required. If the post-depressurization process is not performed, the manufacturing process can be simplified. However, since the air pressure p1 in the ink storage chamber 111 after the ink has been dispensed is not necessarily within the predetermined range, the air pressure p1 in order to make the air pressure within the predetermined range (at the atmospheric pressure within the predetermined range). In order to confirm that this is the case, in this embodiment, a post-depressurization step is performed.

  Here, although not shown, a post-depressurization step performed after the completion of the ink dispensing will be described. The post-depressurization step is performed using the ink dispensing needle 920 inserted into the ink dispensing plug 520. That is, the ink dispensing needle 920 is connected to a supply device (not shown) for supplying ink and a decompression device (not shown) for sucking the atmosphere in the frame portion 110 to reduce the pressure. When the dispensing of is completed, the flow path is switched and decompression by the decompression device is started. The pressure p3 (third pressure) in the ink storage chamber 111 after the post-depressurization is performed is lower than the pressure p1 in the ink storage chamber 111 after the ink is dispensed. Note that a pressure reducing needle (not shown) for post-depressurization may be provided separately from the ink dispensing needle 920, and after the ink dispensing needle 920 has been pulled out, the pressure reducing needle may be inserted to perform pressure reduction.

  Further, as shown in FIG. 7, the dispensing channel forming portion 450 has an opening position of the second dispensing communication hole 454 located above the ink liquid level I (above FIG. 7A). Even if the pressure is reduced afterward by the pressure reducing device, the ink is not sucked to the outside through the dispensing path. Therefore, the amount of ink once dispensed does not change by subsequent decompression, and a predetermined amount of ink can be reliably dispensed.

  Although not shown, when the ink dispensing (or post-depressurization) is finished, the ink dispensing plug 520 is press-fitted until it comes into contact with the bottom 451b (the end surface on the ink storage chamber 111 side) of the dispensing cylinder 451. Therefore, after the ink dispensing plug 520 is press-fitted to the bottom 451b of the dispensing cylinder 451, the first dispensing communication hole 452 is blocked by the outer peripheral surface of the ink dispensing plug 520. Even if it does, the ink is not dispensed. That is, in the manufacturing process of the ink cartridge 1, it is possible to prevent the dispensing process from being performed twice and to prevent the generation of defective products.

  As shown in FIG. 27A, when the ink dispensing (or post-depressurization) is completed, the manufacture of the ink reservoir 110 is completed, and then the case 200 is assembled (the assembly process of the case 200). The case 200 (first and second case members 210 and 220) is molded by injection molding and manufactured in advance (third molding step).

  As described above, the cover 200 is assembled to the ink reservoir 110 in the first case in the three through holes 460a to 460c (see FIG. 4 for the through holes 460b and 460c) formed in the outer peripheral portion of the frame portion 100. The bar members 215 a to 215 c of the member 210 are inserted, and the ink reservoir 110 is assembled to the first case member 210. At this time, the ink supply unit 120 (supply cap 600) and the atmosphere introduction unit 130 (atmosphere cap 700) are fitted into the case notches 211 and 212, respectively, and the outer wall of the ink supply unit 120 (at the contact grooves 211a and 212a). The outer peripheral surface of the supply cap 600 and the outer wall of the atmospheric introduction unit 130 (the outer peripheral surface of the atmospheric cap 700) abut. Thereafter, the second case member 220 is attached so that the case fitting holes 225 a to 225 c (not shown) of the second case member 220 are fitted to the rod members 215 a to 215 c of the first case member 210. At this time, the ink supply part 120 (supply cap 600) and the atmosphere introduction part 130 (atmosphere cap 700) are fitted in the case notches 221 and 222 of the second case member 220, respectively, and ink is supplied to the contact grooves 221a and 222a. The outer wall of the portion 120 (the outer peripheral surface of the supply cap 600) and the outer wall of the atmospheric introduction unit 130 (the outer peripheral surface of the atmospheric cap 700) abut.

  As shown in FIG. 27B, after the assembly (assembly process) of the first and second cases 210 and 220 is completed, the first and second case members 210 and 220 are welded together (welding process of the case 200). . The first and second case members 210 and 220 are welded by welding the first case welded portion 216 of the first case member 210 and the first case welded portion 226 of the second case member 220 together with the first case member. The second case welded portion 217 of 210 and the second case welded portion 227 of the second case member 220 are welded (the hatched portion in FIG. 27B is welded). In this embodiment, the case 200 is welded by welding the entire first and second case welded parts 226 and 227, but several parts may be welded partially. That is, as long as the case 200 is not peeled off during conveyance or is welded so as not to be easily peeled off by human action, the welding range and welding method may be any range or method.

  In the present embodiment, the first and second case members 210 and 220 are assembled after the ink is dispensed into the ink reservoir 100, and then the first and second case members 210 and 220 are welded. Vibration caused by sonic welding is absorbed by the ink. Therefore, vibration for welding the case 200 is transmitted, so that the welded part of the frame part 110 and the film 160 are damaged or the film 160 is peeled off. In addition, in the case where the welded portions of the first and second case members 210 and 220 are partially performed, vibrations due to ultrasonic welding are reduced, so that damage to each component and peeling of the film 160 can be further reduced. Can do.

  As shown in FIG. 27B, the case protrusions 214a and 224a (the case protrusion 214a is not shown) and the case protrusions 214b and 224b (the case protrusion 214b are not shown) are inks. Projecting outward from the supply unit 120 and the air introduction unit 130. Therefore, even when the ink cartridge 1 is dropped when the ink cartridge 1 is mounted on the ink jet recording apparatus 1, the case protrusions 214a, 214b, 224a, 224b collide with the ground, so the ink supply unit 120 and the air introduction unit It is possible to prevent 130 from being damaged. Furthermore, since it is possible to prevent the air introduction path from being opened and the ink supply path from being opened, it is possible to prevent ink from leaking out.

  As shown in FIG. 28A, when the welding process of the case 200 is completed, the protector 300 is attached to the case 200 (attachment process of the protector 300). Since the protector 300 is removed when the ink cartridge 1 is attached to the ink jet recording apparatus 1000 (see FIG. 29), the protector 300 is configured to be detachable. As described above, the through holes formed by the case protruding notches 214a and 224a (see FIG. 2) of the first and second case members 210 and 220, and the case protruding notches of the first and second case members 210 and 220, respectively. The projections 330a1 and 330b1 of the protector 300 are fitted into the through holes formed by the portions 214b and 224b, so that the protector 300 is attached to the case 200. In addition, the 2nd protector fitting part 330a, 330b of the protector 300 can perform attachment or detachment of the protector 300 easily by elastically deforming in the direction away from each other.

  As shown in FIG. 28B, when the protector 300 is attached (attachment process), the ink cartridge 1 is accommodated in the packaging bag 930 in order to ship the ink cartridge 1 (accommodation process). Thereafter, the inside of the packaging bag 930 is decompressed by the decompression device 940 (packaging space decompression process of the packaging bag 930). The packaging bag 930 is a bag body in which one end side (the end portion on the left front side in FIG. 28 (b)) is opened. In the packaging process, the ink cartridge 1 is included and the opening 931 is left and the other opened. Ultrasonic weld the part. The suction pipe 941 of the decompression device 940 is inserted through the opening 931 and the suction pump (P2) 942 is driven, so that the atmosphere in the packaging bag 930 is sucked and decompressed. The pressure of the packaging bag 930 due to the reduced pressure is lower than the atmospheric pressure, but is lower than the reduced pressure p3 (or the pressure p1 if the post-depressurization step is not performed) in the ink storage chamber 111 (first pressure). 2). When the decompression by the decompression device 940 is finished, the suction tube 941 is pulled out, the opening 931 is welded, and the ink cartridge 1 can be shipped. The relationship between the pressures p1 to p3 is p2 <p3 <p1.

  The film 160 of the ink cartridge 1 can be bent and deformed in the direction of the packaging bag 930 by setting the pressure in the packaging bag 930 to a pressure lower than the pressure in the ink storage chamber 111 by the packaging space decompression step. If the air pressure in the packaging bag 930 is higher than the air pressure in the ink storage chamber 111, the film 160 becomes hard and hardened in a state where the ink storage chamber 111 is depressurized when the ink cartridge 1 is left unused for a long period of time. Or may be damaged. If the film 160 hardens, the shape of the ink storage chamber 116 changes and the air pressure becomes non-uniform, so that accurate ink supply cannot be performed. Further, when the film 160 is damaged, the ink in the ink storage chamber 111 flows out of the ink cartridge 1. However, in this embodiment, the pressure in the packaging bag 930 is reduced so as to be lower than the pressure in the ink storage chamber 111, so that the film 160 can be deformed (recoverable) in the direction of the packaging bag 930. Therefore, even when the film 160 is not used for a long period of time, it is possible to reduce the problem that the film 160 is hardened and ink cannot be supplied accurately, and damage to the film 160 can be prevented.

  Further, in this embodiment, the ink cartridge 1 is packaged with the packaging bag 930 and decompressed with the protector 300 attached to the case 200, so that the direct air introduction part 130 ( And no contact with the ink supply unit 120). Since the valve opening part 721a protrudes outside the atmosphere introduction part 130, when the packaging bag 930 directly contacts the valve opening part 721a, the valve opening part 721a may be operated to open the atmosphere introduction path. When the air introduction path is opened, ink in the ink storage chamber 111 leaks out. In addition, the air introduction unit 130 and the ink supply unit 120 may be damaged as the packaging bag 930 is deformed. However, in this embodiment, since it is attached to the protector 300 and the case 200, it is possible to prevent damage to the atmosphere introduction unit 130 and the ink supply unit 120 and to prevent the atmosphere introduction path from being opened.

  As described above, the ink cartridge 1 is manufactured by dispensing ink into the ink storage chamber 111 of the frame portion 110 and then welding the ink storage body 100 with the case 200 covered. Some conventional ink cartridges dispense ink from outside the case after the case is placed on the ink reservoir. In this conventional ink cartridge, it is necessary to prepare a frame and a case according to the amount of ink stored and the ink color. However, in this embodiment, since the case 200 is covered after the ink is dispensed into the ink storage chamber 111 of the ink storage body 100, the ink storage body 100 can be made into a common component. That is, even when the case shapes are different, the ink reservoir 100 can be used in common. As a result, the manufacturing cost of the ink cartridge 1 can be reduced.

  In addition, since the ink dispensing unit 150 (ink dispensing plug 520) is not visible from the outside by the case 200 and is completely concealed in the ink cartridge 1, the user accidentally removes the ink dispensing plug 520, It is possible to prevent problems such as scattering ink outside.

  Next, a method for attaching and detaching the ink cartridge 1 to the ink jet recording apparatus 1000 will be described with reference to FIGS. FIG. 29 is a diagram illustrating a method of mounting the ink cartridge 1 to the ink jet recording apparatus 1000. FIG. 30 is a diagram illustrating a method for detaching the ink cartridge 1 from the ink jet recording apparatus 1000. 29 and 30 show the inkjet recording apparatus 1000 side in a sectional view and the ink cartridge 1 in a side view for convenience of explanation.

  When attaching the ink cartridge 1 to the ink jet recording apparatus 1000, first, the packaging bag 930 is broken, and the ink cartridge 1 is taken out from the packaging bag 930. Then, it is performed with the protector 300 removed from the case 200.

  First, the mounting portion of the ink cartridge 1 of the ink jet recording apparatus 1000 will be described.

  As shown in FIG. 29A, the mounting portion 1010 on the ink jet recording apparatus 1000 side protrudes from the mounting portion 1010 of the ink cartridge 1 in a substantially vertical direction (left direction in FIG. 29), and the locking portions 217a and 227b of the case 200. The support rod 1011 that locks and the first case welded portions 216 and 226 of the case 200 are supported from below, and the support portion 1012 that is formed in a concave shape according to the shape of the first case welded portions 216 and 226. And. The locking rod 1011 has a convex portion 1011a that protrudes toward the support portion 1012 and is formed in substantially the same shape as the locking portions 217a and 227a.

  An ink remaining amount detection sensor 1014 is disposed on the mounting surface 1013 of the ink cartridge 1 of the mounting unit 1010. The ink remaining amount detection sensor 1014 is formed in a substantially U-shape, and one open end of the U-shape is a light emitting unit 1014a that emits light, and the other end receives light. Part 1014b (not shown). The light emitting portion 1014a and the light receiving portion 1014b are attached so as to protrude from the mounting surface 1013 so as to be inserted through the through holes formed by the case cutout portions 213 and 223 and the detection portion 140, respectively. The remaining ink detection sensor 1014 does not output a signal to a control board (not shown) provided in the inkjet recording apparatus 1000 when the light receiving unit 1014b receives the light emitted from the light emitting unit 1014a. (Or output) When the light emitted from the light emitting unit 1014a is blocked and the light receiving unit 1014b cannot receive light, a signal is output (or not output) to the control board.

  In addition, an ink extraction tube 1015 is provided on the side corresponding to the ink supply part 120 of the contact surface 1013 (lower side in FIG. 29A), while corresponding to the air introduction part 130 of the contact surface 1013. On the side (upper side in FIG. 29A), the contact surface 1013 is formed as a flat surface. An ink flow path 1013a is connected to the ink extraction tube 1015, and ink is supplied to an ejection port (not shown) through the ink flow path 1013a. An air introduction path 1013b is formed on the contact surface 1013 on the air introduction portion 130 side, and the air is introduced into the ink cartridge 1 (ink storage chamber 111) through the air introduction path 1013b.

  Further, on both sides of the contact surface 1013 (on both side ends of the contact surface 1013 between the locking rod 1011 and the support portion 1012 in FIG. 29A), the case protrusions 214a and 224a of the case 200 and the case The protrusions 214b and 224b are loosely inserted, and recesses 1016a and 1016b corresponding to the outer shapes of the case protrusions 214a and 224a and the case protrusions 214b and 224b are formed. Further, the recess 1016b is formed with a fitting rod 1016b1 which is inserted and fitted into a fitting groove formed by the case fitting grooves 214b2 and 224b2 of the case 200. When the ink cartridge 1 is mounted, the fitting rod 1016b1 is inserted into the fitting groove formed by the case fitting grooves 214b2 and 224b2. That is, the shape of the case protrusion formed by the case protrusions 214a and 224a of the case 200 and the case protrusion formed by the case protrusions 214b and 224b are different, and the recesses 1016a and 1016b of the ink jet recording apparatus 1000 are different. Since the shapes are different from each other, when the ink cartridge 1 is mounted upside down, the fitting rod 1016b1 becomes an obstacle and the ink cartridge 1 cannot be mounted. Accordingly, it is possible to prevent the ink cartridge 1 from being erroneously mounted, and thus it is possible to prevent the ink supply unit 120 and the air introduction unit 130 from being damaged, and the ink remaining amount detection sensor 1014 and the ink extraction tube 1015 from being damaged.

  Further, the mounting portion 1010 enters the recesses 216a and 226a of the case 200 at the front end side of the support portion 1012 (the left side in FIG. 29A, the end portion on the ink cartridge 1 side) and the engaging portions 216b and 226b. An engaging member 1017 that engages and rotates is provided. The engagement member 1017 includes an engagement end portion 1017a that engages with the engagement portions 216b and 226b of the case 200, a shaft support portion 1017b that is connected to the engagement end portion 1017a and supports the engagement member 1017, and a shaft support portion. 1017b and a covering portion 1017c that covers the opposite side of the surface of the case 200 that faces the mounting portion 1010. The shaft support portion 1017b is formed with a convex portion 1017d protruding in the outer peripheral direction from the shaft center of the support member of the engaging member 1017, and the convex portion 1017d is a concave portion formed in the mounting portion 1010 of the ink jet recording apparatus 1010. By engaging with 1018, the engaging member 1017 is fixed.

  As shown in FIG. 29A, when the ink cartridge 1 (with the protector 300 removed) is attached to the ink jet recording apparatus 1000, the ink cartridge 1 is placed below the ink supply unit 120 and the air introduction unit 130 is placed below. Install it so that it faces up. This is because the ink in the ink cartridge 1 (ink storage chamber 111) cannot be used efficiently unless the ink supply unit 120 is positioned below.

  In addition, the ink cartridge 1 is in the order of the ink supply unit 120, the detection unit 140, and the air introduction unit 130 from the bottom to the top in a state where the ink cartridge 1 is mounted on the ink jet recording apparatus 1000. 120, a detection unit 140 and an air introduction unit 130 are formed on one end face. Accordingly, since the ink supply 120, the detection unit 140, and the air introduction unit 130 are concentrated on one end surface, the ink remaining amount detection sensor 1014 and the ink extraction tube 1015 (ink ink required for the inkjet recording apparatus 1000 side) are provided. The flow path 1013a) and the air introduction path 1013b can be provided on one side. Therefore, the ink cartridge 1 and the ink jet recording apparatus 1000 can be reduced in size.

  Further, since the ink supply unit 120, the detection unit 140, and the air introduction unit 130 are provided in this order from the bottom to the top, it is possible to improve the use of ink. This is because the atmosphere introduction unit 130 introduces the atmosphere into the ink storage chamber 111, and therefore, the atmosphere in the ink storage chamber 111 is formed on the side where there is the atmosphere (a space different from the ink storage space). It needs to be formed on the top. If the detection unit 140 is disposed below the ink supply unit 120, the ink below the ink supply unit 120 is not supplied, and the ink is used up accordingly. Therefore, in this embodiment, the sensor arm 470 is provided and the ink remaining amount is detected by the arm detection method, so that the ink supply unit 120, the detection unit 140, and the air introduction unit 130 are formed from the bottom to the top. It can be. As a result, the ink can be used up.

  The ink cartridge 1 is inserted so that the case protruding portions 214a and 224a (first case welded portions 216 and 226) of the case 200 are in contact with the support portion 1012, and the first case welded portions 216 and 226 are inserted into the support portion 1012. This is done by pressing to slide up. That is, the ink cartridge 1 is slid in the direction of arrow E as shown in FIG. As described above, since the inclined surfaces 214a2 and 224a2 are formed on the case protrusions 214a and 224a, the ink cartridge 1 can be smoothly inserted onto the support portion 1012 by the inclined surfaces 214a2 and 224a2. it can.

  As shown in FIG. 29B, when the ink cartridge 1 is pushed in the direction of the mounting portion 1010 (leftward in FIG. 29B), the locking rod 1011 is pushed by the second case welding portions 217 and 227. , Elastic deformation in a direction away from the support portion 1012. Further, the engagement end portion 1017a of the engagement member 1017 enters the recesses 216a and 226a of the case 200, and then comes into contact with the engagement portions 216b and 226b. Further, when the ink cartridge 1 is pushed in, the engaging member 1017 rotates upward (in the direction of arrow F in FIG. 29B).

  As shown in FIG. 29 (c), when the ink cartridge 1 is further pushed in from the state of FIG. 29 (b) (or when the user rotates the engaging member 1017 in the direction of arrow F in FIG. 29 (b)). The convex portion 1011a of the locking rod 1011 is fitted and engaged with the locking portions 217a and 227a of the case 200, and the ink cartridge 1 is fixed. Further, in the engaging member 1017, the convex portion 1017d is engaged with the concave portion 1018, and the ink cartridge 1 is also fixed by the engaging member 1017. Therefore, the ink cartridge 1 is prevented from being easily detached due to printing vibration or the like in the state where the ink cartridge 1 is mounted on the mounting unit 1010.

  Further, since the ink cartridge 1 is restricted from moving in the vertical direction by the locking rod 1011 and the support portion 1012, the ink cartridge 1 is inserted obliquely, and the remaining ink detection sensor 1014 and the ink extraction tube 1015 are damaged. Can be prevented.

  Further, when the ink cartridge 1 is attached to the attachment portion 1010, the ink extraction tube 1015 is inserted into the ink supply portion 120 so that ink can be supplied, and the valve opening portion 721a of the air introduction portion 130 is brought into contact with the contact surface. The ink remaining amount detection sensor 1014 is inserted into the through-hole formed by the case notches 213 and 223 and the detection unit 140 so that the ink remaining amount can be detected. However, a detailed description will be given later.

  When the ink cartridge 1 is attached to the attachment portion 1010, the ink remaining amount detection sensor 1014 is inserted into the through hole formed by the case cutout portions 213 and 223 and the detection portion 140, so that the remaining ink amount is detected. The light emitting unit 1014 a and the light receiving unit 1014 b of the sensor 1014 are located in the case 200. Accordingly, it is possible to reduce the damage of the ink remaining amount detection sensor 1014 and reduce the occurrence of erroneous detection due to dust or dust adhering to the light emitting unit 1014a and the light receiving unit 1014b.

  Next, a method for detaching the ink cartridge 1 from the ink jet recording apparatus 1000 will be described with reference to FIG.

  As shown in FIG. 30A, when the ink cartridge 1 is detached from the ink jet recording apparatus 1000, the engaging member 1017 is rotated in the arrow S direction. When the engaging member 1017 is rotated in the direction of arrow S in FIG. 20A, the engaging end portion 1017 a comes into contact with the engaging portions 216 b and 226 b of the case 200.

  As shown in FIG. 30B, when the engagement member 1017 is further rotated in the direction of arrow T (to the state shown in FIG. 30B), the ink cartridge 1 is pulled away from the contact surface 1013. Accordingly, the convex portion 1011 a of the locking rod 1011 is detached from the locking portions 217 a and 227 a of the case 200, and the locking rod 1011 is elastically deformed in the direction away from the support portion 1012. In this state, the fixing of the ink cartridge 1 at the mounting portion 1010 is released, so that the user can easily pull out the ink cartridge 1 in the direction of the arrow U and detach it easily (the state shown in FIG. 30C). ).

  Here, the operations of the ink supply mechanism 500 and the air introduction mechanism 510 when the ink cartridge 1 is mounted on the ink jet recording apparatus 1000 will be described with reference to FIG. FIG. 31 is a diagram illustrating a state where the ink cartridge 1 is mounted on the ink jet recording apparatus 1000. FIG. 31 is a diagram for explaining the operation of the ink supply mechanism 500 and the air introduction mechanism 510, and therefore, the case 200, the locking rod 1011 of the ink jet recording apparatus 1000, the support portion 1012, and the like are omitted. It is shown.

  As shown in FIG. 31, when the ink cartridge 1 is mounted on the ink jet recording apparatus 1000, the light emitting unit 1014 a and the light receiving unit 1014 b (not shown) of the ink remaining amount detection sensor 1014 are arranged at positions that sandwich the detection unit 140. The Since the detection unit 140 is made of a translucent or transparent resin material, light emitted from the light emitting unit 1014a of the ink remaining amount detection sensor 1014 passes through the detection unit 140, and the light receiving unit 1014b receives the light. be able to. As described above, since the shielding arm portion 473c of the sensor arm 470 is disposed in the inner packet portion 141 of the detection unit 140, the remaining amount of ink can be detected by the operation of the sensor arm 470. The operation of the sensor arm 470 will be described later.

  When the ink cartridge 1 is mounted on the ink jet recording apparatus 1000, the ink supply mechanism 500 includes a space surrounded by the inclined wall 606d of the supply cap 600, the insertion hole 605 of the supply cap 600, and the ink flow path 615 of the supply joint 600. The ink extraction tube 1015 is inserted in order, the tip of the ink extraction tube 1015 comes into contact with the valve bottom wall 621 of the supply valve 620, and the supply valve 620 is pushed. As a result, the supply valve 620 is separated from the joint contact portion 613 of the supply joint 610 to form an ink flow path. The ink extraction tube 1015 communicates with an ejection port (not shown) of the inkjet recording apparatus 1000 via an ink flow path 1013a. In addition, a notch 1015a for securing an ink flow path is formed at the tip of the ink extraction tube 1015. Even if the tip of the ink extraction tube 1015 contacts the valve bottom wall 621 of the supply valve 620, the notch An ink flow path is secured by 1015a.

  Here, the operation of the ink supply mechanism 500 when the supply valve 620 is pushed by the ink extraction tube 1015 will be described. As described above, the first flexible spring 630 housed in the supply valve 620 (and the supply slider 640) has the spring flexible portion 633 slightly bent. On the other hand, the spring flexible portion 653 of the second supply spring 650 disposed on the opposite side of the supply slider 640 from the first supply spring 630 is not bent. This is to determine the order in which the first and second supply springs 630 and 650 are bent. That is, since the first supply spring 630 in which the spring flexible portion 633 is bent is easier to bend than the second supply spring 650, when the ink extraction tube 1015 is inserted, the first supply spring 630 is bent first. Thereafter, the second supply spring 650 is bent.

  Here, the height of the ink supply mechanism 500 in the direction of the axis O1 has a dimensional error at the time of production for each component. However, since the supply slider 640 is in contact with the valve hook portion 626 of the valve member 610, at least the dimensional error of the first supply spring 630 is irrelevant. Therefore, the dimensional error of the ink supply mechanism 500 is reduced, and the expansion / contraction operation of the ink supply mechanism 500 is stabilized.

  Further, the inner diameter of the valve outer peripheral wall 622 of the supply valve 620 and the outer diameter of the slider outer peripheral wall 641 of the supply slider 640 are formed to be substantially equal. Therefore, when the supply slider 640 moves in the direction of the axis O1 of the ink supply mechanism 500, it is possible to prevent the shift in the movement direction. Further, the inner diameter of the slider outer peripheral wall 641 and the outer diameters of the spring bottom portions 631 and 651 of the first and second supply springs 630 and 650 are formed to be substantially equal. Therefore, when the first and second spring members 630 and 650 are disposed on the slider pedestal portion 644 of the supply slider 640, the displacement of the first and second spring members 630 and 650 in the direction perpendicular to the axis O1 (the vertical direction in FIG. 31) is reduced. Can do. Further, the outer shape of the outer peripheral wall 622 of the supply valve 620 is slightly smaller than the inner diameter of the ink supply body 116, but a valve protrusion 622 a is formed outward from the outer peripheral wall 622 of the supply valve 620. Therefore, it is possible to prevent a shift in the moving direction when the supply valve 620 operates in the direction of the axis O1. Accordingly, the expansion / contraction operation of the ink supply mechanism 500 in the direction of the axis O1 is stabilized.

  Further, when the valve bottom wall 621 of the supply valve 620 is pushed by the ink extraction pipe 1015 and moves in the direction of the valve seat 660 (rightward in FIG. 31), the first supply spring 630 is compressed along with this movement. When the ink extraction tube 1015 is inserted, the supply valve 620 moves in the direction of the valve seat 660 and the supply slider 640 moves in the direction of the valve seat 660 (the first supply spring 630 and the second supply). The second supply spring 650 is flexibly deformed by moving in the direction opposite to the biasing direction of the spring 650. This state is the state shown in FIG.

  When the ink cartridge 1 is attached to the attachment portion 1010 of the ink jet recording apparatus 1000, the first and second supply springs 630 and 650 are also elastically deformed to form the ink flow path K indicated by the arrow K. The ink flow path K includes an ink storage chamber 111 (see FIG. 4), a second supply communication hole 423, a first supply communication hole 421, a first cover through hole 683 (and second cover through hole 684) of the cover 680, a valve. The first valve seat through hole 662b and the second valve seat through hole 663 of the seat 660, the valve seat communication groove 664 of the valve seat 660, the ink flow path 654 of the second supply spring 650, the slider through hole 645 of the supply slider 640, the first 1 ink flow path 634 of the supply spring member 630, a flow path formed between the first spring member 930 and the valve receiving portion 628, an ink flow path 627 of the supply valve 620, a notch 1015a of the ink extraction tube 1015, an ink extraction It is a flow path that passes through the inside of the tube 1015 in order. This channel is the main channel through which most of the ink flows. The space between the valve outer peripheral wall 622 of the supply valve 620 and the inner peripheral surface of the ink supply body 116 also serves as an ink flow path.

  Here, the operation of the supply joint 610 when the ink extraction tube 1015 is inserted into the supply joint 610 will be described. When the ink extraction tube 1015 is press-fitted into the protrusion channel 615b through the staircase channel 615a, the joint protrusion 614 has an ink extraction tube due to friction between the inner peripheral surface 614a and the outer peripheral surface of the ink extraction tube 1015. It is dragged by 1015 and displaced in the insertion direction (left side in FIG. 31) of the ink extraction tube 1015 (displaced in the contact portion flow path 615c). At this time, since the joint contact portion 613 has a structure that is notched in a countersink shape, the displacement of the joint projection portion 614 in the insertion direction of the ink extraction tube 1015 is directly at the tip of the joint contact portion 613. It is not transmitted to 613a. That is, the tip 613 a of the joint contact portion 613 is hardly displaced in the insertion direction, and the tip 613 a of the joint contact portion 613 is slightly displaced in the direction away from the ink extraction tube 1015. Therefore, the shape change of the supply joint 610 accompanying the insertion of the ink extraction tube 1015 is a shape change that displaces the joint contact portion 613 in a direction away from each other. If the joint contact portion 613 has a shape having a gentle slope from the inner peripheral surface 614a of the joint projection 614 toward the tip 613a of the joint contact portion 613, the ink extraction tube 1015 is inserted. The joint protrusion 614 is deformed so as to be displaced in the insertion direction of the ink extraction tube 1015, and the deformation of the joint protrusion 614 is directly transmitted to the joint contact part 613, so that the joint contact part 613 is inserted in the insertion direction together with the joint protrusion 614. Will be displaced. As a result, since the insertion stroke of the ink extraction tube 1015 for forming the ink flow path between the supply valve 620 and the joint contact portion 613 becomes long, the ink extraction tube 1015 must be formed long. In addition, when the ink extraction tube 1015 is long, it is liable to be damaged due to contact with other members, and the length of the ink supply mechanism 500 in the direction of the axis O1 becomes long and the scale becomes large. However, in this embodiment, the joint contact portion 613 is displaced in a direction substantially perpendicular to the insertion direction of the ink extraction tube 1015, so that it is not necessary to lengthen the stroke for forming the ink flow path. Therefore, the ink extraction tube 1015 can be prevented from coming into contact with other members to reduce breakage, and the scale of the ink supply mechanism 500 can be reduced.

  When the ink cartridge 1 is detached from the ink jet recording apparatus 1000, the ink extraction tube 1015 is removed, and the valve bottom wall 621 of the supply valve 620 comes into contact with the joint contact portion 613 of the supply joint 610. The flow path K is closed. At this time, the second supply spring 650 is in a fully extended state, and the first supply spring 630 is returned to the state of being bent and deformed. When the ink cartridge 1 is detached from the ink jet recording apparatus 1000, the ink extraction pipe 1015 is removed and the ink joint 1 is moved to the vicinity of the ink flow path 615 (the contact flow path 615 c and the protrusion flow path 615 b). Some ink flows in the direction of the supply cap 600 (left side in FIG. 31) and flows out to the staircase portion flow path 615a. However, since the amount of ink flowing out to the staircase channel 615a is very small, the ink can be held by the capillary force of the staircase portion of the staircase channel 615a, and the outflow to the outside of the ink cartridge 1 can be reduced. Furthermore, even if the ink flows out of the staircase channel 615a, the ink storage portion 602 of the supply cap 600 has an opening wider than the opening 612c of the staircase channel 615a. Flows into the portion 607. Therefore, it is possible to reliably prevent the ink from flowing out of the ink cartridge 1.

  Next, the atmosphere introduction mechanism 510 side will be described. When the ink cartridge 1 is mounted on the ink jet recording apparatus 1000, the air introduction mechanism 510 is configured such that the valve opening portion 721a of the air valve 720 exposed to the outside from the air cap 700 comes into contact with the mounting surface 1013 of the mounting portion 1010. Press 720. As a result, the atmospheric valve 720 is separated from the joint contact portion 713 of the atmospheric joint 710, and the atmospheric introduction path L indicated by the arrow L shown in the drawing is formed. Further, when the valve opening portion 721a of the atmospheric valve 720 contacts and is pressed against the mounting surface 1013, the joint skirt portion 714 of the atmospheric joint 710 contacts the mounting surface 1013, and the joint skirt portion 714 has an enlarged diameter (or reduced diameter). To bend and deform. As a result, it closely contacts the mounting surface 1013 and shields the outside and inside of the joint skirt portion 714. An air passage 1013b serving as a passage for introducing air is formed in the mounting surface 1013 that is inside the joint skirt portion 714, and air is introduced into the ink storage chamber 111 through the air passage 1013b.

  The operation of the atmospheric introduction mechanism 510 when the atmospheric valve 720 is pushed will be described. As described above, in the first atmospheric spring 730 housed in the atmospheric valve 720 (and the atmospheric slider 740), the spring flexible portion 733 is slightly bent, while the spring flexible portion 753 of the second atmospheric spring 750 is bent. There is no deflection. Therefore, the order in which the first and second atmospheric springs 730 and 750 are bent is also determined.

  Further, the inner diameter of the valve outer peripheral wall 722 of the atmospheric valve 720 and the outer diameter of the slider outer peripheral wall 741 of the atmospheric slider 740 are formed substantially equal. Therefore, when the atmospheric slider 740 operates in the direction of the axis O2 of the atmospheric introduction mechanism 510, it is possible to prevent the movement direction from being shifted. Further, the inner diameter of the slider outer peripheral wall 741 and the outer diameters of the spring bottom portions 731 and 751 of the first and second atmospheric spring members 730 and 750 are formed to be substantially equal. Therefore, it is possible to reduce the first and second atmospheric springs 730 and 750 from being displaced in a direction perpendicular to the axis O2 (up and down direction in FIG. 31) in a state where the first and second atmospheric springs 730 and 750 are disposed on the slider base portion 744 of the atmospheric slider 740. Can do. In addition, the outer shape of the outer peripheral wall 722 of the atmospheric valve 720 is slightly smaller than the inner diameter of the atmospheric introduction body 117, but a valve protrusion 722 a is formed outward from the outer peripheral wall 722 of the atmospheric valve 720. Therefore, it is possible to prevent a shift in the moving direction when the atmospheric valve 720 operates in the direction of the axis O2. Accordingly, the expansion / contraction operation in the direction of the axis O2 of the atmosphere introduction climate 510 is stabilized.

  Further, when the atmospheric valve 720 is pushed by the valve opening portion 721a and moves in the direction of the protrusion 811 (right side in FIG. 31), the first atmospheric spring 730 is flexibly deformed so as to be compressed along with this movement, Furthermore, when the atmospheric valve 720 is pushed, the atmospheric slider 740 moves in the direction of the protrusion 811 and the second atmospheric spring 750 is flexibly deformed. This state is the state shown in FIG.

  When the ink cartridge 1 is attached to the attachment portion 1010 of the ink jet recording apparatus 1000, the first and second atmospheric springs 730 and 750 are also elastically deformed, and an atmospheric introduction path L indicated by an arrow L is formed. The atmosphere introduction path L includes a joint passage 715 of the atmosphere joint 710, an ink flow path 727 of the atmosphere valve 720, a flow path formed between the first atmosphere spring 730 and the valve receiver 728, and ink of the first atmosphere spring 730. A flow path 734, a slider through-hole 745 of the atmospheric slider 740, an ink flow path 754 of the second atmospheric spring 750, a flow path formed between the spring upper portion 752 of the second atmospheric spring 750 and the protrusion 811, the first atmosphere The flow path passes through the communication holes 434 in order. This channel is the main channel through which most of the air flows. Further, the space between the outer peripheral wall 722 of the atmospheric valve 720 and the inner peripheral surface 810 of the atmospheric introduction body 117 also serves as an atmospheric introduction path. Thereafter, as shown in FIG. 6, the first atmosphere communication chamber 431, the communication port 433a, the atmosphere connection path 433, the communication port 433b, the second atmosphere communication chamber 432, the second atmosphere communication hole 435, and the third atmosphere communication hole 436. The air is introduced into the ink storage chamber 111. When the atmosphere introduction path L is opened, the atmosphere is introduced so that the inside of the ink storage chamber 111 is at atmospheric pressure.

  As described above, the ink flow path K and the air introduction path L are formed when the ink cartridge 1 is mounted on the ink jet recording apparatus 1000. The ink supply mechanism 500 and the air introduction mechanism 510 operate smoothly and without deviation with respect to the axial centers O1 and O2. Therefore, it is possible to reliably supply the ink and introduce the air while facilitating the mounting of the ink cartridge 1.

  Next, with reference to FIG. 32, a method for detecting the remaining amount of ink in the ink storage chamber 111 will be described. FIG. 32 is a diagram showing the operation of the sensor arm 470 corresponding to the ink remaining amount in the ink storage chamber 111, and FIG. 32 (a) shows a state where the ink remaining amount is present, and FIG. ) Indicates a state where there is no ink remaining.

  As shown in FIG. 32A, a state where a large amount of ink is stored in the ink storage chamber 111 (a state where a large amount of ink is stored at least from the lower end portions of the inner circumference welded portions 415a, 415b, 416a, 416b). Then, since the balance portion 471 of the sensor arm 470 is made of a resin material having a specific gravity smaller than the specific gravity of the ink, it floats in the ink. That is, it does not contact the lower inner surface 118 of the frame part 110. As a result, the shielding arm portion 473c of the sensor arm 470 blocks between the light emitting unit 1014a and the light emitting unit 1014b of the ink remaining amount detection sensor 1014. This state is a state with ink, and the presence of ink is determined by a control board (not shown) of the inkjet recording apparatus 1000.

  When the ink in the ink storage chamber 111 decreases through the ink flow path K, the ink liquid level I decreases as the ink decreases. When the ink in the ink storage chamber 111 is almost exhausted and does not exist on the lower inner surface 118 of the frame portion 110, the balance portion 471 of the sensor arm 470 contacts the lower inner surface 118. As a result, with the mounting shaft 472a of the mounting portion 472 as a fulcrum, the shielding arm portion 473c of the sensor arm 470 operates upward, and the space between the light emitting portion 1014a and the light receiving portion 1014b of the ink remaining amount detection sensor 1014 is opened. Light passes between the light emitting unit 1014a and the light receiving unit 1014b. This state is an ink-free state, and the ink-jet recording apparatus 1000 determines whether there is no ink on a control board (not shown).

  When it is determined that there is no ink, an ink-free lamp is turned on or a voice is used to inform the user that there is no ink in order to suggest that the user is out of ink. Note that a counter provided on the control board may be used to store the number of times ink is ejected, and a soft counter that virtually determines the absence of ink may be used in combination to detect the ink remaining amount.

  As shown in FIG. 32A, the sensor arm 470 is attached to the arm holding portion 425 and in the ink-filled state, the upper end surface (upper end surface in FIG. 32) of the shielding arm portion 473c is the ink liquid. It is located approximately parallel to the surface. In this state, when the liquid level of the ink falls and becomes the same position as the upper end face of the shielding arm 473c, a force for holding the shielding arm 473c is applied by the surface tension of the ink. If the surface tension of the ink holds the shielding arm 473c more than the buoyancy of the balance portion 473a, the sensor arm 470 will not operate normally. Therefore, in this embodiment, the upper end surface of the shielding arm 473c outside the detection unit 140 is provided with an angle so as to be inclined downward, and the portion of the shielding arm 473c that is substantially parallel to the ink surface is reduced. . Therefore, the force that the surface tension of the ink acts on the shielding arm 473c can be reduced, and the sensor arm 470 can be operated normally.

  A modification of this embodiment will be described below. In the above embodiment, the supply valve 620 and the atmospheric valve 720 are attached in the direction of the supply joint 610 and the atmospheric joint 710 by the elastic force of the first and second supply springs 630 and 650 and the first and second atmospheric springs 730 and 750. The ink flow path K and the air introduction path L were closed by force. On the other hand, the supply valve and the atmospheric valve may be urged in the direction of the supply joint and the atmospheric joint by the elastic force of the coil spring member made of a metal material or a resin material to close the ink flow path and the atmospheric introduction path. good. Further, if a coil spring having at least a part formed in a conical shape is used, the ink supply mechanism and the air introduction mechanism can be reduced in scale. In addition, the first supply spring 630, the second supply spring 650, the first atmospheric spring 730, and the second atmospheric spring 750 are in direct contact with each other without the supply slider 640 and the atmospheric slider 740, and the supply valve and The atmospheric valve may be configured to have a simple structure including only the bottom plate. With this configuration, the structure of the ink supply mechanism and the air introduction mechanism is simplified, so that the manufacturing cost can be reduced. Further, the first supply (atmosphere) spring and the second supply (atmosphere) spring may be integrally connected. Further, the supply valve 620 and the atmospheric valve 720 are not provided with the valve hook portions 626 and 726, but the supply (atmosphere) slider 640 (740) and the first and second supply (atmosphere) springs 630 and 650 (730 and 750). And the supply (atmosphere) slider and the first and second supply (atmosphere) springs that are integrally connected to each other may be configured to be freely operable.

  In addition, the check valve 670 includes the umbrella portion 671 and the shaft portion 672, but may include only the umbrella portion 671. Since the check valve 670 is for preventing the backflow of ink, it is sufficient that the check valve 670 can be configured to shield the communication between the first cover through-hole 683 and the second cover through-hole 684 of the cover 680. Further, the cover 680 may be configured such that the second cover through hole 684 is not formed.

  In the above embodiment, the joint protrusion 614 and the joint contact portion 613 of the supply joint 610 are formed in a countersink shape. However, a groove portion is formed on the outer periphery of the joint contact portion of the supply joint. It may be formed. Since the displacement of the joint protrusion is absorbed by the groove, it is possible to reduce the displacement of the joint abutting portion in the insertion direction as the ink extraction tube 1015 is inserted. Furthermore, if the inner diameter of the joint contact portion is formed larger than the inner diameter of the joint projection portion, it is possible to reduce the displacement of the joint projection portion from being transmitted to the joint contact portion.

  Further, in the above embodiment, the film 160 is welded to both sides of the first opening 112a and the second opening 112b of the frame part 110, but one opening is closed by the side wall, and the film 160 is attached only to the other opening. You may comprise so that it may weld. In this case, if the side of the second opening 112b is closed by the side wall and the film 160 is welded to the first opening 112a, the side wall of the atmosphere connection path 433 is formed by the film 160, so that a meniscus is formed in the atmosphere connection path 433. The formation can be reduced. Further, when the second opening 112b side is closed with a side wall, the side wall serves as a support plate, and the strength of the frame portion is maintained, so that there is no connection formation portion (partition plate) for connecting the ink storage chambers. It may be configured.

  Moreover, in the said Example, although the film 160 welded to the flame | frame part 110 shall be comprised with the nylon layer by the flame | frame part 110 side, it is good also as what gives a water-repellent coating to the nylon layer. With this configuration, the formation of a meniscus in the atmosphere connection path 433 can be further reduced.

  Further, in the above embodiment, the atmosphere communication path forming portion 430 is configured to be inclined downward from the first atmosphere communication chamber 431 toward the second atmosphere communication chamber 432, but one surface of the atmosphere connection path 433 is the film 160. Therefore, the formation of a meniscus in the atmosphere connection path 433 can be reduced. Therefore, the atmosphere communication path forming unit 430 is not necessarily configured to be inclined downward, and may be configured to be horizontal in the mounting posture of the ink cartridge 1.

  In the above embodiment, all the welding steps are performed by ultrasonic welding. However, in the case where the bonding can be performed with an adhesive, the bonding may be performed using an adhesive. It may be used and welded. For example, since welding of the case 200 is not required if the first and second case members 210 and 220 are not peeled off, the case 200 can be bonded with an adhesive.

  The ink cartridge, ink reservoir, ink cartridge package, ink cartridge package manufacturing method, and ink cartridge manufacturing method according to the present invention will be described below.

  An ink cartridge comprising an ink reservoir having an internal space for storing ink, and a case containing the ink reservoir, wherein the ink reservoir is attached to an ink jet recording apparatus that performs recording by discharging the ink. A frame member having an opening communicating with the internal space, and a film that is fixed to an opening peripheral edge of the opening and seals the opening, and the frame member includes a rib that supports the film from the internal space side. An ink cartridge A1 is provided.

  In the ink cartridge A1, the film is fixed to the rib.

  In the ink cartridge A2, the fixing of the film and the rib is performed by melting at least one of the film and the rib and joining each other.

  In the ink cartridge A2 or A3, the fixing portion of the rib fixed to the film is located on the same virtual plane as the fixing portion at the opening peripheral edge of the opening fixed to the film. Ink cartridge A4.

  In any one of the ink cartridges A1 to A4, the rib is configured to regulate the displacement when a part of the case that is opposed to the opening is displaced toward the opening. Characteristic ink cartridge A5.

  In any one of the ink cartridges A1 to A5, in the posture attached to the ink jet recording apparatus, the rib is formed to be inclined downward and the downward inclined end portion is formed as a free end, and the ink that flows by gravity. The ink cartridge A6 is characterized in that it can be guided toward the bottom side of the internal space.

  The ink cartridge A7 according to any one of the ink cartridges A1 to A6, wherein a plurality of the ribs are dispersedly arranged in an opening region of the frame member.

  In any one of the ink cartridges A1 to A7, the frame member includes an outer frame portion that defines the opening, and a support plate that extends substantially parallel to the opening surface of the opening from the outer frame portion, and the rib An ink cartridge A8 which is erected on the support plate.

  An ink reservoir A9 that is used in any of the ink cartridges A1 to A8.

  An ink cartridge comprising an ink reservoir having an internal space for storing ink, and a case containing the ink reservoir, wherein the ink reservoir is attached to an ink jet recording apparatus that performs recording by discharging the ink. A frame member having a first opening and a second opening communicating with the internal space, and a film fixed to the periphery of each opening of the first opening and the second opening and closing the first opening and the second opening, respectively. The frame member includes a partition plate that partitions the internal space into a first chamber on the first opening side and a second chamber on the second opening side, and is erected from the partition plate from the first opening side. An ink cartridge comprising: a first rib that supports the film; and a second rib that is erected from the partition plate and supports the film from the second opening side. B1.

  In the ink cartridge B1, the film is fixed to the first rib and the second rib, respectively.

  In the ink cartridge B2, the film is fixed to the first rib and the second rib by melting at least one of the film and the first rib and the second rib to join each other. An ink cartridge B3.

  In the ink cartridge B2 or B3, the fixing portion of the first rib fixed to the film is located on the first virtual plane together with the fixing portion at the opening periphery of the first opening fixed to the film, The ink cartridge B4, wherein the fixing portion of the second rib fixed to the film is located on the second imaginary plane together with the fixing portion at the opening periphery of the second opening fixed to the film.

  The ink cartridge B5, wherein the first virtual plane and the second virtual plane are parallel to each other in the ink cartridge B4.

  In any of the ink cartridges B1 to B5, when a part of the case that is opposed to the first opening and the second opening is displaced toward the first opening and the second opening, the displacements are changed. An ink cartridge B6, wherein the first rib and the second rib are respectively restricted.

  In any one of the ink cartridges B1 to B6, the first rib and the second rib are formed so as to be inclined downward and the downward inclined end portion is formed as a free end in the posture mounted on the ink jet recording apparatus. The ink cartridge B7 is configured to be able to guide the ink flowing by gravity toward the bottom side of the first chamber and the second chamber.

  The ink cartridge B8 according to any one of the ink cartridges B1 to B7, wherein a plurality of the first ribs and the second ribs are dispersedly arranged in the opening region of the frame member.

  The ink cartridge B9 according to any one of the ink cartridges B1 to B8, wherein the partition plate includes a communication path that communicates the first chamber and the second chamber.

  The ink cartridge B9 includes a rotation member that is pivotally supported in the internal space and rotates as the ink decreases, and the rotation member is disposed in the communication path. Ink cartridge B10.

  In the ink cartridge B10, the rotating member includes a substantially cylindrical shaft-shaped portion, and the partition plate includes a holding portion that rotatably holds the shaft-shaped portion of the rotating member, and the holding portion. Is formed in a substantially C-shaped cross section with the side facing the communication path open, and the shaft-shaped portion of the rotating member is inserted and held in the holding portion of the partition plate, whereby the rotating member is An ink cartridge B11 which is rotatably supported by the partition plate.

  In any one of the ink cartridges B1 to B11, the frame member includes an auxiliary wall portion erected from the partition plate, and the auxiliary wall portion has a lower erection height than the rib. Characteristic ink cartridge B12.

  In the ink cartridge B12, the auxiliary wall portion is configured to be thinner than the rib.

  In the ink cartridge B12 or B13, the auxiliary wall portion is erected from the partition plate at an end edge portion of the partition plate adjacent to the communication path.

  In any of the ink cartridges B12 to B14, when there are a plurality of the ribs, the auxiliary wall portion connects the plurality of ribs to the ink cartridge B15.

  In any one of the ink cartridges B1 to B15, the frame member includes an outer frame portion that defines the first opening and the second opening, and the partition plate is between the opening surfaces of the first opening and the second opening. An ink cartridge B16 formed so as to extend from the outer frame portion in a space.

  An ink reservoir B17 that is used in any one of the ink cartridges B1 to B16.

  An ink cartridge including an ink storage body having an internal space for storing ink, and mounted on an ink jet recording apparatus that performs recording by discharging the ink, wherein the ink storage body includes an ink injection member into which a plug member can be press-fitted. An injection portion having a flow path; and a communication portion that communicates the ink injection flow path of the injection portion to the internal space, the communication portion including a first hole that communicates with the ink injection flow path of the injection portion; A second hole communicating with the internal space; a connection flow path connecting the first hole and the second hole and communicating the ink injection flow path and the internal space; The second hole is positioned above the first hole when the ink reservoir takes an ink injection posture, which is a posture at the time of ink injection operation for injecting ink into the internal space through a path. When That ink cartridge C1.

  In the ink cartridge C1, the ink reservoir includes a frame member having an opening and a film fixed to the opening periphery of the opening, and the opening of the frame member is sealed with the film, whereby the frame member The internal space is formed between the film and the film, and the communication portion includes a wall portion standing in the internal space, and the film is fixed to the wall portion, The ink cartridge C2 is characterized in that the connection channel is formed between a wall portion and the film.

  In the ink cartridge C2, the wall portion is erected from the outer surface of the injection portion.

  In the ink cartridge C2 or C3, the fixed portion of the wall portion fixed to the film is located on the same virtual plane as the fixed portion at the opening peripheral edge of the opening fixed to the film. An ink cartridge C4.

  In any one of the ink cartridges C1 to C4, the second hole of the communication portion is located on the opening side of the ink injection channel that is the start end side of the plug member in the press-fitting direction, and the first hole of the communication portion. Is located on the bottom side of the ink injection channel, which is the end side in the press-fitting direction of the plug member.

  The ink cartridge C6 according to any one of the ink cartridges C2 to C5, wherein the connection flow path of the communication portion extends linearly.

  The ink cartridge C7 according to any one of the ink cartridges C1 to C6, wherein the communication portion is positioned at an uppermost position of the internal space in the ink injection posture.

  In any one of the ink cartridges C1 to C7, the ink reservoir is configured as a substantially flat hexahedron, and the injection portion is formed from a side surface that is connected to a pair of surfaces having the largest area of the substantially hexahedron. An ink cartridge C8, which is disposed inside the ink reservoir so as to press-fit the plug member.

  In any one of the ink cartridges C9 to C10, the ink injection operation includes injecting ink into the internal space through the ink injection flow path, and further sucking the internal space through the ink injection flow path to decompress the internal space. An ink cartridge C9, which is characterized by

  In the ink cartridge C9, the ink injection operation is to suck the internal space and decompress the internal space before injecting ink into the internal space.

  An ink storage body having an internal space for storing ink; and an air introduction section for introducing air into the internal space of the ink storage body, wherein the ink storage body includes a first surface and a second surface facing each other, and these The air introduction portion is disposed on the side surface of the ink reservoir and performs recording by ejecting the ink. In the ink cartridge mounted on the ink jet recording apparatus, the ink reservoir includes an atmosphere communication path that guides the atmosphere from the atmosphere introduction section to the internal space, and the atmosphere communication path communicates with the atmosphere introduction section. A first communication chamber, a second communication chamber communicating with the internal space, and a connection path connecting the second communication chamber and the first communication chamber, wherein the first communication chamber and the second communication chamber are: Bottom on the first side Is formed as a space in which the ceiling surface is located on the second surface side, and the first hole for communicating the first communication chamber and the air introduction portion is located at a position away from the bottom surface of the first communication chamber. The ink cartridge D1 is characterized in that the ink cartridge D1 is disposed, and a second hole for communicating the connection path and the second communication chamber is disposed at a position separated from a ceiling surface of the second communication chamber.

  In the ink cartridge D1, when the first surface is placed as a placement surface, the first hole is located above the second hole, and the second surface is placed as a placement surface. In this case, the ink cartridge D2 is configured such that the second hole is positioned above the first hole.

  In the ink cartridge D1 or D2, the ink cartridge D3 is characterized in that the first hole is opened at a side wall surface of the first communication chamber and is in contact with a ceiling surface of the first communication chamber.

  The ink cartridge according to any one of the ink cartridges D1 to D3, wherein the second hole is opened at a side wall surface of the second communication chamber and is in contact with a bottom surface of the second communication chamber. D4.

  In any one of the ink cartridges D1 to D4, the second communication chamber is formed with at least two holes, a third hole and a fourth hole, for communicating the second communication chamber and the internal space. Characteristic ink cartridge D5.

  The ink cartridge D5 includes a partition plate that partitions the internal space into a first chamber and a second chamber, and the ceiling surface of the second communication chamber is configured to also serve as the partition plate, and the third hole is the An ink cartridge D6 having an opening in a side wall surface of the second communication chamber, and the fourth hole being opened in a ceiling surface of the second communication chamber.

  In the ink cartridge D6, the ink cartridge D7 is characterized in that the fourth hole is opened at a corner portion of the ceiling surface that is located farthest from the second hole.

  In the ink cartridge D6, the fourth hole is located in the uppermost position in the second communication chamber in the mounting posture to the ink jet recording apparatus.

  In any one of the ink cartridges D5 to D8, the opening area of the second hole is smaller than the opening areas of the third hole and the fourth hole.

  The ink cartridge D10 according to any one of the ink cartridges D5 to D9, wherein a flow path cross-sectional area of the connection path is smaller than an opening area of the third hole and the fourth hole.

  The ink cartridge D11 according to any one of the ink cartridges D1 to D10, wherein an opening area of the second hole is smaller than an opening area of the first hole.

  The ink cartridge D12 according to any one of the ink cartridges D1 to D11, wherein a flow path cross-sectional area of the connection path is smaller than an opening area of the first hole.

  In any one of the ink cartridges D1 to D12, the ink reservoir includes a frame member having an opening communicating with the internal space, and a film that is fixed to an opening peripheral edge of the opening and seals the opening. An ink cartridge D13, wherein a ceiling surface of a path and a side wall surface of the connection path are formed by the frame member, and a bottom surface of the connection path is formed by the film.

  In the ink cartridge D13, a ceiling surface of the first communication chamber and a side wall surface of the first communication chamber are formed by the frame member, and a bottom surface of the first communication chamber is formed by the film. Ink cartridge D14.

  In the ink cartridge D13 or D14, the ceiling surface of the second communication chamber and the side wall surface of the second communication chamber are formed by the frame member, and the bottom surface of the second communication chamber is formed by the film. An ink cartridge D15.

  In the ink cartridge D14 or D15, the third hole is disposed at a position where the third hole is opened on the side wall surface of the second communication chamber and in contact with the bottom surface of the second communication chamber, and a part of the opening periphery of the third hole is formed. An ink cartridge D16 formed of the film.

  In any one of the ink cartridges D1 to D16, in the mounting posture to the ink jet recording apparatus, the air communication path is disposed above the internal space, and from the communication side with the air introduction portion, The ink cartridge D17 is configured such that the atmosphere communication path is inclined downward toward the communication side.

  The ink cartridge D18 according to any one of the ink cartridges D13 to D16, wherein the film has a water-repellent finish at least at a portion forming a bottom surface of the atmosphere communication path.

  An ink storage body having an internal space for storing ink and an air communication path for introducing air to the internal space; and an air introduction section that is disposed on a side surface of the ink storage body and introduces air to the air communication path, In the ink cartridge attached to the ink jet recording apparatus that performs recording by discharging the ink, the atmosphere communication path is disposed above the internal space and the air introduction section is mounted in the ink jet recording apparatus. The ink cartridge E1 is configured such that the atmosphere communication path is inclined downward from the communication side to the communication side with the internal space.

  In the ink cartridge E1, the ink reservoir includes a frame member having an opening that communicates with the internal space, and a film that is fixed to an opening peripheral edge of the opening and seals the opening. An ink cartridge E2 having a surface formed of the film.

  An ink storage body having an internal space for storing ink and an air communication path for introducing air to the internal space; and an air introduction section that is disposed on a side surface of the ink storage body and introduces air to the air communication path, In an ink cartridge mounted on an ink jet recording apparatus that performs recording by discharging ink, the ink reservoir is fixed to a frame member having an opening communicating with the internal space and an opening periphery of the opening. An ink cartridge E3, wherein one surface of the atmosphere communication path is formed of the film.

  In the ink cartridge E3, in the mounting posture to the ink jet recording apparatus, the atmosphere communication path is disposed above the internal space, and as it goes from the communication side with the atmosphere introduction unit toward the communication side with the internal space. The ink cartridge E4 is configured so that the atmosphere communication path is inclined downward.

  The ink cartridge E5 according to any one of the ink cartridges E2 to E4, wherein the film is subjected to water repellent processing at least at a portion forming the one surface of the atmosphere communication path.

  In any one of the ink cartridges E1 to E5, the ink reservoir has a first surface and a second surface that face each other, and a side surface that connects the peripheral edges of the first surface and the second surface to each other. In addition, the atmosphere introduction part is disposed on the side surface of the ink reservoir, and the atmosphere communication path is communicated with the first communication chamber communicating with the atmosphere introduction part and the second space communicating with the internal space. And a communication path connecting the second communication chamber and the first communication chamber. The first communication chamber and the second communication chamber have a bottom surface on the first surface side and the first communication chamber. Formed as a space where the ceiling surface is located on the second surface side, the first hole for communicating the first communication chamber and the air introduction portion is disposed at a position spaced from the bottom surface of the first communication chamber, and A second hole for communicating the connection path with the second communication chamber; Ink cartridge E6, characterized in that it is arranged at a position away from the ceiling surface of serial second communication chamber.

  In the ink cartridge E6, when the first surface is placed as a placement surface, the first hole is located above the second hole, and the second surface is placed as a placement surface. In this case, the ink cartridge E7 is configured such that the second hole is positioned above the first hole.

  In the ink cartridge E6 or E7, the ink cartridge E8 is characterized in that the first hole is opened at a side wall surface of the first communication chamber and is in contact with a ceiling surface of the first communication chamber.

  In any one of the ink cartridges E6 to E8, the second hole is disposed at a position where the second hole is opened in a side wall surface of the second communication chamber and is in contact with a bottom surface of the second communication chamber. E9.

  In any one of the ink cartridges E6 to E9, the second communication chamber is formed with at least two holes, a third hole and a fourth hole, which connect the second communication chamber and the internal space. Characteristic ink cartridge E10.

  The ink cartridge E10 includes a partition plate that partitions the internal space into a first chamber and a second chamber, and is configured such that a ceiling surface of the second communication chamber also serves as the partition plate, and the third hole is the The ink cartridge E11 is opened in a side wall surface of the second communication chamber, and the fourth hole is opened in a ceiling surface of the second communication chamber.

  In the ink cartridge E10, the ink cartridge E12 is characterized in that the fourth hole is opened in a corner portion of the ceiling surface that is positioned farthest from the second hole.

  In the ink cartridge E10, the fourth hole is located at the uppermost position in the second communication chamber in the mounting posture of the ink jet recording apparatus.

  The ink cartridge E14 according to any one of the ink cartridges E10 to E13, wherein the opening area of the second hole is smaller than the opening areas of the third hole and the fourth hole.

  The ink cartridge E15 according to any one of the ink cartridges E10 to E14, wherein a flow path cross-sectional area of the connection path is smaller than an opening area of the third hole and the fourth hole.

  The ink cartridge E16 according to any one of the ink cartridges E6 to E15, wherein an opening area of the second hole is smaller than an opening area of the first hole.

  Ink cartridge E17, wherein in any one of ink cartridges E1 to E16, the cross-sectional area of the connection path is smaller than the opening area of the first hole.

  In any one of the ink cartridges E6 to E17, the ceiling surface of the first communication chamber and the side wall surface of the first communication chamber are formed by the frame member, and the bottom surface of the first communication chamber is formed by the film. An ink cartridge E18.

  In any one of the ink cartridges E6 to E18, the ceiling surface of the second communication chamber and the side wall surface of the second communication chamber are formed by the frame member, and the bottom surface of the second communication chamber is formed by the film. An ink cartridge E19.

  In the ink cartridge E10, the third hole is disposed at a position where the third hole is opened in the side wall surface of the second communication chamber and in contact with the bottom surface of the second communication chamber, and a part of the opening periphery of the third hole is the film. An ink cartridge E20, which is formed by:

  An ink cartridge including an ink storage body having an internal space for storing ink and attached to an ink jet recording apparatus that performs recording by discharging the ink, and is disposed on a side surface of the ink storage body and stored in the internal space. An ink supply hole for supplying the ink to the ink jet recording apparatus, an ink supply chamber which is formed by dividing the internal space by a partition wall and communicating with the ink supply hole; An ink communication hole that communicates with the space and opens in the partition wall, and the ink communication hole is positioned below the ink supply hole when mounted on the inkjet recording apparatus. Ink cartridge F1.

  In the ink cartridge F1, the ink communication hole is configured to be spaced apart from the bottom surface of the internal space by a predetermined distance in a posture in which the ink communication hole is mounted on the ink jet recording apparatus. .

  The ink cartridge F1 or F2 includes a recessed portion formed by recessing a part of a wall portion serving as a bottom surface of the internal space in a posture attached to the ink jet recording apparatus, and the recessed portion is the An ink cartridge F3, which is located below the ink communication hole.

  In the ink cartridge F3, the ink communication hole is configured so that the ink communication hole is located in a space formed by the recessed portion.

  In the ink cartridge F1 or F2, the wall portion that becomes the bottom surface of the internal space in the posture attached to the ink jet recording apparatus is formed as a stepped step portion, and the lowest step among the step portions is the ink. An ink cartridge F5 configured to be positioned below the communication hole.

  In the ink cartridge F5, the ink communication hole is configured so that the ink communication hole is located in a space formed by the lowermost step in the stepped portion.

  In the ink cartridge F5 or F7, the side surface of the ink reservoir in which the ink supply unit is disposed is a portion that connects the peripheral edges of the first surface and the second surface of the ink reservoir facing each other, The width dimension of the space formed by the recessed portion or the space formed by the lowermost step among the stepped portions is at least smaller than the facing distance between the first surface and the second surface. An ink cartridge F7.

  The ink cartridge F8 according to any one of the ink cartridges F1 to F7, wherein the ink supply chamber is formed in a tapered shape in which a cross-sectional area decreases as the distance from the ink supply hole increases.

  In any one of the ink cartridges F1 to F8, the partition wall is connected to a wall portion serving as a bottom surface of the internal space in a posture attached to the ink jet recording apparatus, and is formed to be inclined upward from the wall portion. An ink cartridge F9.

  In the ink cartridge F9, the ink communication hole is formed in the partition wall that is inclined upward from the wall portion.

  One of the ink cartridges F5 to F10 includes a rotating member that is pivotally supported in the internal space and rotates as the ink decreases, and a part of the rotating member is the stepped step portion. The ink cartridge F11 is configured to be positioned in a space formed by a step portion adjacent to the lowermost step.

  In any one of the ink cartridges F1 to F11, the ink stored in the internal space is disposed on the side surface of the ink storage body and attached to the ink jet recording apparatus. An ink cartridge F12 including an ink supply unit that supplies the recording apparatus.

  An ink storage body that forms an ink storage chamber for storing ink; and a rotation member that is rotatably provided in the ink storage chamber and rotates as the ink decreases. The ink reservoir includes a passage in which the light blocking member is displaceable by a pair of wall surfaces substantially parallel to the rotating surface of the rotating member, and ink jet recording. In the ink cartridge provided with the detected portion that is irradiated with light from the outside when attached to the apparatus, the detected portion is located below the light blocking portion, the light blocking portion and the pair of wall surfaces. An ink cartridge G1 having a pair of second gaps continuous with the pair of first gaps formed between the first gap and the second gap being narrower than the first gap.

  In the ink cartridge G1, the detected portion includes a first standing wall that is located between the pair of wall surfaces, extends substantially parallel to the rotation surface, and is thicker than the light blocking portion. The ink gap G2 is formed between the pair of wall surfaces and the first standing wall.

  In the ink cartridge G2, the detected portion includes a bottom surface that connects the lower ends of the pair of wall surfaces and on which the first standing wall is erected, and the bottom surface is lowered toward the lower side on the ink storage chamber side. The ink cartridge G3 is configured to be inclined.

  In the ink cartridge G3, an ink cartridge G4 is characterized in that an edge portion where the first standing wall and the bottom surface intersect with each other is formed in an angular shape in cross section.

  In the ink cartridge G2 or G3, an ink supply unit that is provided in the ink storage body below the bottom surface of the detection unit and supplies ink in the ink storage chamber to the ink jet recording apparatus, the ink supply unit, and the detection target And a second standing wall that extends from the inner surface of the ink reservoir that connects the bottom surface of the section and extends from a position continuous with the first standing wall toward the ink supply section. Ink cartridge G5.

  In the ink cartridge G5, the ink cartridge G6 is characterized in that an edge portion where the second standing wall and the inner surface of the ink storage body intersect is formed in an angular shape in cross section.

  In the ink cartridge G5 or G6, the inner surface of the ink storage body standing on the second standing wall includes an inclined surface that is inclined downward from the detected portion side toward the ink supply portion side. Ink cartridge G7 to be used.

  In any one of the ink cartridges G1 to G7, the rotating member is pivotally supported by connecting the light blocking portion, a balance portion located on the opposite side of the light detecting portion, and the balance portion and the light blocking portion. An ink cartridge G8, wherein at least the balance portion of the rotating member is made of a material having a specific gravity smaller than the specific gravity of the ink.

  In the ink cartridge G8, the balance portion is made of polypropylene, and the ink cartridge G9.

  In the ink cartridges G3 to G9, the detected portion includes a ceiling surface that is arranged to face the bottom surface and is connected to the upper edge portions of the pair of wall surfaces, and the ceiling surface has the light blocking portion on the ceiling surface. An ink cartridge G10, which is disposed at a contact position.

  An ink storage body that forms an ink storage chamber for storing ink; and a rotation member that is rotatably provided in the ink storage chamber and rotates as the ink decreases. The ink reservoir includes a passage in which the light blocking member is displaceable by a pair of wall surfaces substantially parallel to the rotating surface of the rotating member, and ink jet recording. In the ink cartridge provided with the detected portion that is irradiated with light from the outside when attached to the apparatus, the detected portion is located below the light blocking portion, the light blocking portion and the pair of wall surfaces. A pair of liquid guide paths that are respectively continuous with the pair of first gaps formed between the two, and the pair of liquid guide paths draws ink remaining in the first gap by capillary action. Ink cartridge G11 to be a butterfly.

  An ink cartridge that includes an ink storage body having an internal space in which ink is stored in a part thereof and is detachably attached to the ink jet recording apparatus, and a flexible and gas-blocking packaging bag that contains the ink cartridge The ink reservoir includes a frame member having a first opening communicating with the internal space, and a flexible member that is fixed to a peripheral portion of the first opening and closes the first opening. And a first film having gas permeability, and a decompression space that is a space other than the space in which ink is stored in the internal space and is decompressed to a first pressure lower than atmospheric pressure, and the packaging bag The ink cartridge package H1 is characterized in that the inside thereof is depressurized to a second pressure lower than the first pressure.

  In the ink cartridge package H1, the frame member includes a first rib that supports the first film from the inner space side.

  The ink cartridge package H3, wherein the first film is fixed to the first rib.

  In the ink cartridge package H2 or H3, the ink reservoir is fixed to a second opening that opens on the opposite side of the frame member from the first opening and communicates with the internal space, and a peripheral edge of the second opening. A second film having flexibility and gas permeability that closes the second opening, and a partition plate that partitions the internal space into a first chamber on the first opening side and a second chamber on the second opening side The partition plate is provided with the first rib for supporting the first film on the first opening side, and the second rib for supporting the second film on the second opening side. An ink cartridge package H4, wherein

  In the ink cartridge package H4, the second film is fixed to the second rib, and the ink cartridge package H5.

  In any one of the ink cartridge packaging bodies H1 to H5, the internal space includes an ink space in which ink is stored at least in part, and an air communication space that communicates the ink space with the outside. An ink cartridge package H6 including the atmosphere communication space.

  An ink cartridge that includes an ink storage body having an internal space in which ink is stored in a part thereof and is detachably attached to the ink jet recording apparatus, and a flexible and gas-blocking packaging bag that contains the ink cartridge In the method of manufacturing an ink cartridge package comprising: a frame member having a first opening communicating with the internal space; and a flexible and gas permeable member that is fixed to a peripheral edge portion of the first opening and seals the first opening. A preparatory step for preparing the ink reservoir including the first film having the property, and the internal space of the ink reservoir prepared by the preparatory step is reduced in advance to a pressure lower than the atmospheric pressure, An ink dispensing process for dispensing ink so that a decompressed space reduced to a first pressure lower than atmospheric pressure remains in the internal space, and the ink dispensing process Therefore, a housing step for housing the ink cartridge filled with ink in the packaging bag, and a second lower than the first pressure in the packaging bag in which the ink cartridge is housed by the housing step. And a packaging space decompression step of decompressing the pressure to the pressure of the ink cartridge packaging body manufacturing method H7.

  In the ink cartridge package manufacturing method H7, the ink dispensing step includes a post-decompression step of depressurizing the decompression space to a third pressure lower than the first pressure and higher than the second pressure. A method H8 for producing an ink cartridge package characterized by comprising:

  In the manufacturing method H7 or H8 of the ink cartridge package, the preparation step includes a molding step of molding the ink reservoir including the frame member and a first rib that supports the first film from the inner space side. And a first adhering step of adhering the first film to the peripheral edge portion of the first opening and the first rib so as to close the first opening of the frame member molded by the molding step. A method H9 for producing an ink cartridge package characterized by comprising:

  In the ink cartridge package manufacturing method H9, in the molding step, the ink reservoir including the second opening that is opened on the opposite side to the first opening of the frame member and communicates with the internal space is molded. In the preparing step, a second film having flexibility and gas permeability is fixed to a peripheral portion of the second opening so as to close the second opening of the frame member formed by the forming step. An ink cartridge package manufacturing method H10, comprising a fixing step.

  In the ink cartridge package manufacturing method H10, in the molding step, a partition plate that partitions the internal space into a first chamber on the first opening side and a second chamber on the second opening side, and the partition plate The ink reservoir including the first rib standing on the first opening side and the second rib standing on the second opening side is molded, and the second adhering step is performed at a peripheral edge of the second opening. The method for manufacturing an ink cartridge package H11, wherein the first film is fixed to the portion, and the second rib and the second film are fixed to each other.

  An ink cartridge having an ink storage body having an ink storage chamber for storing ink and an ink supply path communicating with the ink storage chamber and detachably attached to the ink jet recording apparatus, wherein the ink outlet side of the ink supply path The ink extraction member inserted into the first insertion path is formed with a hollow ink extraction member for extracting the ink that is mounted on the ink jet recording apparatus and is extracted. An elastic member having elasticity for closely contacting the ink, and provided in the ink supply path closer to the ink storage chamber than the elastic member, and comes into contact with the elastic member in a state of being detached from the ink jet recording apparatus. 1 The insertion path is closed, and the ink reservoir is brought into contact with an end of the ink extraction member in a state of being mounted on the ink jet recording apparatus. A valve member that allows ink supply to the ink extraction member, and a cap that prevents the elastic member from coming off from the side opposite to the ink storage chamber side, and the cap includes the first insertion path. And a second insertion path into which the ink extraction member is inserted prior to the first insertion path, and a second insertion path therein, and the first of the second insertion paths. An inner cylindrical portion having an opening diameter at the end on the insertion path side smaller than an opening diameter on the side of the first insertion path where the ink extraction member is inserted, and a first outer side surrounding the inner cylindrical section A connecting portion that connects the tubular portion, the first outer tubular portion and the inner tubular portion on the side where the ink extraction member is inserted, the connecting portion, the first outer tubular portion, and the inner portion; The first insertion path and the inner side are formed by being surrounded by a cylindrical portion Ink cartridge I1, characterized in that it comprises an ink reservoir for storing ink flowing down from between the end of the Jo portion.

  In the ink cartridge I1, the cap is formed at an end portion on the first insertion path side of the first outer cylindrical portion, and a flange portion that comes into contact with a surface of the elastic member on which the ink extraction member is inserted; An ink cartridge I2 comprising a second outer cylindrical portion extending from the periphery of the flange portion to the ink storage chamber side along the outer peripheral surface of the elastic member.

  In the ink cartridge I2, the ink reservoir has a cylindrical ink supply part in which the ink supply path is formed, and a protrusion protruding outward is provided on the outer peripheral surface of the ink supply part. The second outer cylindrical portion includes the elastic member and the ink supply portion and extends toward the ink storage chamber, and a fitting portion into which the protrusion is fitted is formed. Ink cartridge I3.

  In the ink cartridge I2 or I3, the second outer cylindrical portion is formed with a notch extending from the end on the ink storage chamber side toward the flange portion.

  In any one of the ink cartridges I1 to I4, at least a part of the first insertion path is formed in a tapered shape in a sectional view that is reduced in diameter in a direction in which the ink extraction member is inserted. Ink cartridge I5.

  In any one of the ink cartridges I1 to I4, at least a part of the first insertion path is formed in a tapered shape and a step shape in a sectional view that is reduced in diameter in a direction in which the ink extraction member is inserted. An ink cartridge I6.

  In any one of the ink cartridges I1 to I6, at least a part of the second insertion path is formed in a tapered shape in a sectional view that is reduced in diameter in a direction in which the ink extraction member is inserted. Ink cartridge I7.

  In any one of the ink cartridges I3 to I7, the elastic member is press-fitted into a space surrounded by an end portion of the ink supply portion opposite to the ink storage chamber, the second outer cylindrical portion, and the flange portion. An ink cartridge I8, comprising: a first press-fit portion that is pressed, and a second press-fit portion that protrudes from the first press-fit portion toward the first insertion path and is press-fitted into the first insertion path.

  An ink cartridge having an ink storage chamber for storing ink therein and having a side surface extending in a substantially vertical direction when mounted on an ink jet recording apparatus, and is detachably mounted on the ink jet recording apparatus. The side surface includes an ink supply unit that supplies the ink stored in the ink storage chamber to the ink jet recording apparatus, an air introduction unit that introduces air into the ink storage chamber, and ink in the ink storage chamber. In order to detect the remaining amount, a detected portion irradiated with light emitted from an optical sensor provided in the ink jet recording apparatus is disposed, and the air introduction portion is located above the ink supply portion. And the detected portion is located above the ink supply portion and below the air introduction portion. Ink cartridge J1.

  In the ink cartridge J1, the ink storage chamber is provided with a rotation member having a light blocking portion that rotates as the ink decreases and is displaced by the rotation. A passage where the light blocking member is displaceably formed is formed by a part of a wall surface defining the storage chamber, and the position of the light blocking portion is detected by the optical sensor. The ink cartridge J2 is characterized in that the remaining amount of ink is detected.

  In the ink cartridge J2, the rotation member is provided with the light blocking member on one end side and a balance portion on the other end side, and rotates about the pivot between the light blocking portion and the balance portion. When the entire balance portion is located in the ink, the balance portion is displaced upward due to a buoyancy greater than gravity, and when the ink is reduced and part of the balance is exposed from the ink surface, the buoyancy is increased. An ink cartridge J3 that decreases and displaces downward.

  In the ink cartridge J3, a passage formed inside the air introduction portion, and a pressing member that is attached to the inside of the passage and is pressed from the ink jet recording apparatus side in a state where the ink cartridge is attached to the ink jet recording apparatus. A valve that allows the ink storage chamber to communicate with the outside when the pressing member is pressed, and blocks the communication between the ink storage chamber and the outside when the ink cartridge is detached from the ink jet recording apparatus. And an ink cartridge J4.

  In any one of the ink cartridges J1 to J4, the ink supply part and the detected part protrude from the side surface, and the detected part is located on the side of the side of the protruding side of the ink supply part and the air introduction part. The ink cartridge J5 is provided in the ink cartridge.

  The ink cartridge J5 includes an ink reservoir that forms the ink reservoir, and a case that encloses the ink reservoir and defines the side surface, the ink supply unit, the air introduction unit, and the detected unit Is formed so as to protrude from the ink reservoir, and the case exposes the ink supply part through-hole for projecting the ink supply part to the outside, the air introduction part through-hole, and the detected part to the outside. And an ink cartridge J6 having a detection window.

  In the ink cartridge J6, the case includes a protruding portion that protrudes outside the ink supply portion and the air introduction portion from both sides of the ink supply portion, the detected portion, and the air introduction portion. Ink cartridge J7 characterized by the above.

  In the ink cartridge J7, one of the protrusions includes a fitted portion that is fitted into a fitting portion that is disposed in a mounting portion of the inkjet recording apparatus.

  In the ink cartridge J8, the fitting portion is a guide bar extending along a direction in which the ink cartridge is attached to the attachment portion of the inkjet recording apparatus, and the guide rod is inserted into the fitted portion. Ink cartridge J9, characterized in that it is a guide groove extending in the direction of the ink.

  A method of manufacturing an ink cartridge comprising an ink reservoir having an internal space in which ink is stored at least in part, and a case made of a plurality of components that enclose the ink reservoir, and detachably attached to an ink jet recording apparatus And an ink dispensing process for dispensing ink into the internal space, and the ink reservoir in a state where the ink is stored in the internal space by the ink dispensing process is accommodated in the case. An assembly step of assembling the plurality of component parts, and welding in which the plurality of component parts are vibrated by ultrasonic waves while the ink reservoir is housed in the case by the assembly step. An ink cartridge manufacturing method K1.

  In the ink cartridge manufacturing method K1, before the ink dispensing step, a frame member having a first opening that communicates with the internal space, and a flexible member that is fixed to the periphery of the first opening and closes the first opening. 2. A preparatory step of preparing the ink reservoir including a first film having a property and a first rib for supporting the first film from the inner space side is provided. Ink cartridge manufacturing method K2.

  In the ink cartridge manufacturing method K2, the preparation step includes a first molding step of molding the ink reservoir including the frame member and a first rib that supports the first film from the inner space side; A first adhering step of adhering the first film to a peripheral portion of the first opening and the first rib so as to close the first opening of the frame member molded by the first molding step; An ink cartridge manufacturing method K3, wherein:

  In the ink cartridge manufacturing method K3, in the first molding step, the ink reservoir including a second opening that is opened on a side opposite to the first opening of the frame member and communicates with the internal space is molded. A second fixing step of fixing a second film having flexibility and gas permeability to a peripheral portion of the second opening so as to close the second opening of the frame member molded by the first molding step; An ink cartridge manufacturing method K4, comprising:

  In the ink cartridge manufacturing method K4, in the first molding step, the inner space is divided into a first chamber on the first opening side and a second chamber on the second opening side, and the partition plate The ink reservoir including the first rib standing on the first opening side and the second rib standing on the second opening side is molded, and the second adhering step is performed at a peripheral edge of the second opening. The method of manufacturing an ink cartridge K5, wherein the second film is fixed to the portion and the second film is fixed to the second rib.

  In the ink cartridge manufacturing methods K3 to K5, the preparatory step is a second molding step of molding a rotating member that rotates the internal space as the ink decreases and has a light blocking portion that is displaced by the rotation. In the first molding step, a light path provided in the frame member is formed so as to displace the light blocking member, and light emitted from an optical sensor provided in the ink jet recording apparatus is irradiated. The ink storage body including a detected portion is molded, and the preparation step includes an attachment step of attaching a rotating member formed by the second molding step to the frame member. Ink cartridge manufacturing method K6.

  In the ink cartridge manufacturing method K6, in the first molding step, an ink supply unit that protrudes from a side surface of the frame member and supplies ink in the ink storage chamber to the ink jet recording apparatus, and the ink supply unit protrudes from the ink supply unit. An air introduction part that protrudes from the side surface of the frame member in the same direction as the ink supply part and introduces air into the ink storage chamber, and a side surface of the frame member from which the air introduction part and the ink supply part protrude. The ink reservoir including the detected portion protruding in the same direction as the air introduction portion and the ink supply portion protrude from between the air introduction portion and the ink supply portion is molded. An ink cartridge manufacturing method K7.

  In the ink cartridge manufacturing method K7, the preparation step includes: an ink supply part through-hole for projecting the ink supply part to the outside; an air introduction part through-hole for projecting the atmosphere introduction part to the outside; and the detected part. A third molding step of molding the plurality of components such that a detection window to be exposed to the outside is disposed on one surface of the case; and in the assembly step, the ink supply unit is inserted into the ink supply unit through-hole. The plurality of components molded by the third molding step are assembled so that the projecting portion protrudes outside, the atmosphere introducing portion projects outside from the atmosphere introducing through hole, and the detected portion is exposed to the outside from the detection window. In the welding step, the plurality of component parts are welded to each other in a portion other than one surface of the case.

  An ink cartridge that includes an ink storage chamber that stores ink therein and that is mounted on an ink jet recording apparatus that performs recording by discharging ink stored in the ink storage chamber. An ink supply unit that protrudes and supplies ink in the ink storage chamber to the ink jet recording apparatus, and protrudes outward from the one surface of the case in the same direction as the ink supply unit, and introduces air into the ink storage chamber And a pair of protrusions that are connected to the case and protrude outwardly from the ink supply part and the air introduction part in the same direction as the ink supply part and the air introduction part protrude. And the pair of protrusions are disposed on both sides of the ink supply unit and the air introduction unit, respectively. Cartridges L1.

  In the ink cartridge L1, the ink cartridge L2 is characterized in that one of the protrusions includes a fitted portion that is fitted into a fitting portion that is disposed in a mounting portion of the inkjet recording apparatus.

  In the ink cartridge L2, the fitting portion is a guide rod extending along a direction in which the ink cartridge is attached to the attachment portion of the inkjet recording apparatus, and the guide rod is inserted into the fitting portion. An ink cartridge L3, which is a guide groove extending in the direction of the ink.

  In any one of the ink cartridges L1 to L3, the case is formed in a substantially box shape including the one surface, and the pair of protrusions are arranged in a direction in which the ink supply unit and the air introduction unit are arranged. Protruding portions that are disposed at both ends of the one surface across the supply portion and the air introduction portion and that are positioned below in the state of being attached to the ink jet recording apparatus among the pair of protruding portions are: An ink cartridge L4, comprising an inclined surface extending upward continuously from the bottom surface of another case.

  In any one of the ink cartridges L1 to L4, the ink storage chamber is formed and includes an ink storage body included in the case. The ink supply unit and the air introduction unit are formed from the ink storage body. The case is formed so as to protrude outward, and the case has an ink supply part through-hole through which the ink supply part protrudes to the outside and an air introduction part through which the air introduction part protrudes to the outside. An ink cartridge L5, wherein a hole is formed.

  In the ink cartridge L5, a part of the ink reservoir is protruded from the space between the ink supply part and the air introduction part in the same direction as the direction in which the ink supply part or the air introduction part protrudes. A detection portion that is irradiated with light emitted from an optical sensor provided in the ink jet recording apparatus, and the one surface of the case has a detection opening at a position corresponding to the detection portion. An ink cartridge L6, wherein a window is formed.

  In the ink cartridge L6, a rotation member having a light blocking portion that rotates as the ink decreases and is displaced by the rotation is provided in the ink storage chamber. A passage in which the light blocking portion is displaceably formed is formed by a part of a wall surface defining the storage chamber, and the position of the light blocking portion is detected by the optical sensor, whereby the ink storage chamber The ink cartridge L7 is characterized in that the remaining amount of ink is detected.

FIG. 2 is a perspective view showing the appearance of the ink cartridge of the present invention. FIG. 3 is an exploded perspective view of an ink cartridge. It is the figure which showed the protector, (a) is a top view of the protector in the IIIa view of FIG. 2, (b) is sectional drawing of the protector in the IIIb-IIIb line | wire of FIG. 3 (a). It is the figure which showed the ink storage body, (a) is a front view of an ink storage body, (b) is a rear view of an ink storage body. It is the figure which showed the supply path formation part, (a) is the figure (figure on the back side of a frame part) which showed the outline of the supply path formation part, (b) is Vb of Fig.5 (a). FIG. 4C is a cross-sectional view of a supply path forming portion taken along the line −Vb. FIG. 4C is a diagram illustrating a state in which the remaining amount of ink is reduced, and FIG. is there. It is the figure which showed the atmosphere communication path formation part, (a) is the perspective view which showed the outline of the atmosphere communication path formation part, (b) is the atmosphere communication path in the arrow VIb view of Fig.6 (a). It is the figure which showed the formation part, (c) is the figure which showed the atmosphere communication path formation part in the arrow VIc view of Fig.6 (a). It is the figure which showed the dispensing path formation part, (a) is the figure which showed the outline of the dispensing path formation part, (b) is the dispensing path in the VIIb-VIIb line | wire of Fig.7 (a). It is sectional drawing of a formation part. It is the figure which showed the detection part vicinity, (a) is the figure which showed the outline of the detection part vicinity, (b) is sectional drawing of the detection part in the VIIIb-VIIIb line | wire of Fig.8 (a). (C) is sectional drawing of the detection part vicinity in the VIIIc-VIIIc line | wire of Fig.8 (a). It is the figure which showed the sensor arm, (a) is the figure which showed the front side of the sensor arm, (b) is the figure which showed the sensor arm in the arrow G view of Fig.9 (a). It is the front view which decomposed | disassembled the ink storage body. FIG. 2 is an exploded view of an ink supply mechanism and an air introduction mechanism, (a) is an exploded view of the ink supply mechanism, and (b) is an exploded view of the air introduction mechanism. It is the figure which showed the supply cap, (a) is the figure which showed the side surface of a supply cap, (b) is the figure which showed the side surface of the supply cap in the arrow XIIb view of Fig.12 (a). (C) is the figure which showed the plane of the supply cap, (d) is the figure which showed the bottom face of the supply cap, (e) is the supply in the VIIe-XIIe line | wire of FIG.12 (c). It is sectional drawing of a cap. It is the figure which showed the supply joint, (a) is the figure which showed the side surface of the supply joint, (b) is the figure which showed the plane of the supply joint, (c) is the bottom face of a supply joint (D) is sectional drawing of the supply joint in the XIIId-XIIId line | wire of FIG.13 (b). It is the figure which showed the supply valve, (a) is the figure which showed the side surface of the supply valve, (b) is the figure which showed the side surface of the supply valve in the arrow XIVb view of Fig.14 (a). (C) is a diagram showing a plane of the supply valve, (d) is a diagram showing a bottom surface of the supply valve, and (e) is a line XIVe-XIVe in FIG. 14 (c). It is sectional drawing of a supply valve. It is the figure which showed the 1st supply spring, (a) is the figure which showed the side surface of the 1st supply spring, (b) is the figure which showed the plane of the 1st supply spring, (c) FIG. 16 is a view showing a bottom surface of the first supply spring, and FIG. 15D is a cross-sectional view of the first supply spring taken along line XVd-XVd in FIG. It is the figure which showed the supply slider, (a) is the figure which showed the side surface of the supply slider, (b) is the figure which showed the side surface of the supply slider in the arrow XVIb view of Fig.16 (a). (C) is the figure which showed the plane of the supply slider, (d) is the figure which showed the bottom face of the supply slider, (e) is the supply in the XVIe-XVIe line | wire of FIG.16 (c). It is sectional drawing of a slider. It is the figure which showed the valve seat, (a) is the figure which showed the side surface of the valve seat, (b) is the figure which showed the plane of the valve seat, (c) is the bottom face of the valve seat. (D) is sectional drawing of the valve seat in the XVIId-XVIId line | wire of FIG.17 (b). It is the figure which showed the non-return valve, (a) is the figure which showed the side surface of the non-return valve, (b) is the figure which showed the plane of the non-return valve, (c) It is the figure which showed the bottom face of the stop valve, (c) is sectional drawing of the non-return valve in the XVIIId-XVIIId line | wire of Fig.18 (a). It is the figure which showed the cover, (a) is the figure which showed the side of the cover, (b) is the figure which showed the plane of the cover, (c) was the figure which showed the bottom face of the cover FIG. 19D is a cross-sectional view of the cover taken along line XIXd-XIXd in FIG. It is the figure which showed the atmospheric cap, (a) is the figure which showed the side of the atmospheric cap, (b) is the figure which showed the side of the atmospheric cap in the arrow XXb view of Fig.20 (a). (C) is the figure which showed the plane of the atmosphere cap, (d) is the figure which showed the bottom face of the atmosphere cap, (e) is the atmosphere in the XXe-XXe line | wire of FIG.20 (c). It is sectional drawing of a cap. It is the figure which showed the atmospheric joint, (a) is the figure which showed the side surface of the atmospheric joint, (b) is the figure which showed the plane of the atmospheric joint, (c) is the bottom face of the atmospheric joint (D) is sectional drawing of the air | atmosphere joint in the XXId-XXId line | wire of FIG.21 (b). It is the figure which showed the atmospheric valve, (a) is the figure which showed the side surface of the atmospheric valve, (b) is the figure which showed the bottom face of the atmospheric valve. FIG. 5 is a partial cross-sectional view illustrating a state in which an ink supply mechanism and an air introduction mechanism are assembled to the ink supply body and the air introduction body. It is a figure explaining the manufacturing process before a film is welded. It is a figure explaining the welding process of a film, (a) is a figure explaining the welding surface to the frame part of a film, (b) is a figure explaining the welding process which welds a film to a frame part. is there. It is a figure explaining the manufacturing process performed after welding of a film, (a) is a figure explaining the attachment process which attaches an ink supply mechanism and an air introduction mechanism to a flame | frame part, (b) demonstrates a pressure reduction process. (C) is a figure explaining the ink dispensing process. It is a figure explaining the assembly | attachment process of a case, (a) is a figure explaining the process of clamping a frame part, (b) is a figure explaining the welding process which welds a case. It is a figure explaining the manufacturing process performed before shipment of an ink cartridge, (a) is a figure explaining the process of attaching a protective cap, (b) explains the process of packaging an ink cartridge with a package. It is a figure to do. FIG. 4 is a diagram illustrating a method for mounting an ink cartridge on an ink jet recording apparatus. FIG. 3 is a diagram illustrating a method for detaching an ink cartridge from an ink jet recording apparatus. FIG. 3 is a diagram illustrating a state where an ink cartridge is mounted on an ink jet recording apparatus. It is the figure which showed the operation | movement of the sensor arm corresponding to the ink remaining amount in an ink storage chamber, (a) has shown the state with ink remaining, (b) has shown the state without ink remaining. ing.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Ink cartridge, 100 Ink storage body, 110 Frame part (a frame member, a part of ink storage body), 111 Ink storage chamber (internal space), 111a 1st chamber, 111b 2nd chamber, 112a 1st opening (opening of an opening Part, opening region), 112b Second opening (part of opening, opening region), 113 First storage chamber opening (communication path connecting the first chamber and the second chamber), 114 Second storage chamber opening ( (Communication path connecting the first chamber and the second chamber), 116 ink supply body, 116a, 116b projection (projection), 117 air introduction body, 117a, 117b projection, 120 ink supply section (one of the ink reservoirs) Part), 130 air introduction part (part of ink reservoir), 140 detector (part of ink reservoir, part to be detected), 141 inner part (a pair of wall surfaces substantially parallel to the rotation surface of the light blocking part) The 141a bottom wall (wall forming the bottom surface of the detected part), 141b ceiling wall (wall forming the ceiling surface of the detected part), 142 arm support part (first standing wall of the detected part), 143 standing wall (Second standing wall continuous with the first standing wall of the detected part), 143a inclined surface (a part of the frame part 110), 150 ink dispensing part (a part of the ink reservoir), 160 film (one of the ink reservoirs) Part, first film (film welded to the first opening side), second film (film welded to the second opening side)), 200 case, 210 first case member (part of the case), 211 case Notch (part of case ink supply part through hole), 212 Case notch (case air introduction part through hole), 213 Case notch (case detection window part), 211a, 212a Groove, 214 a, 214b Case protrusion (part of case protrusion), 214a1, 214b1 Case protrusion notch, 214a2 inclined surface, 214b2 Case fitting groove (case fitting part, part of guide groove) 215a to 215c bar member, 216 first case welded portion, 216a recessed portion, 216b engaging portion, 217 second case welded portion, 217a locking portion, 220 second case member (part of case), 221 case notch (Part of the ink supply part through hole of the case), 222 Case cutout part (part of the air introduction part through hole of the case), 223 Case cutout part (part of the detection window of the case), 224a, 224b Case protrusion (Part of the protruding part of the case) 224a1, 224b1 Case protruding notch part, 224a2 Inclined surface, 224b2 Case fitting groove (of the fitting part of the case Part, part of guide groove), 225a to 225c fitting hole part, 226 first case welded part, 226a concave part, 226b engaging part, 227 second case welded part, 227a locking part, 300 protector, 310 through protector Hole, 320 1st protector fitting part, 321, 322 Protector standing wall, 330a, 330b 2nd protector fitting part, 330a1, 330b1 Projection part, 330a2, 330b2 Shaft part, 340a, 340b Protector loose insertion part, 400a, 400b Welding part (outer frame part, opening peripheral edge), 411a to 417a Inner circumferential welding part (rib supporting the film, first rib supporting the first film), 411b to 417b Inner circumferential welding part (rib supporting the film, Second rib for supporting the second film), 418a, 418b connecting rib (auxiliary wall portion) , 420 Supply path forming portion, 421 First supply communication hole (ink supply hole), 422 Supply partition wall (partition wall), 423 Second supply communication hole (ink communication hole), 424 Supply recess (concave contact), 424a Space (space formed by the concave contact portion), 425 Arm holding portion (holding portion), 426 Ink supply chamber, 430 Atmospheric communication passage forming portion (atmospheric communication passage), 431 First atmospheric communication chamber (communication with atmospheric introduction portion) First communication chamber), 431a side wall surface, 432 second atmospheric communication chamber (second communication chamber communicating with the internal space), 432a side wall surface, 433 atmospheric connection path (connection path), 433a communication port, 433b communication port ( 434 First atmosphere communication hole (first hole for communicating the first communication chamber and the atmosphere introduction portion), 435 Second atmosphere communication hole (second communication) Room and interior space 436a third air communication hole (fourth hole for communicating the second communication chamber and the internal space), 437a first surface (the bottom surface of the first communication chamber, the bottom surface of the second communication chamber, Bottom surface of atmosphere communication path, one surface of atmosphere communication path), 437b second surface, 440 connection forming part (partition plate, support plate), 441 atmosphere side connection part (part of partition plate), 442 dispensing side connection Part (part of the partition plate), 443 to 446 connection communication hole (communication path connecting the first chamber and the second chamber), 450 dispensing path forming part (injection part), 451 dispensing cylinder part (ink injection) Flow path), 451a opening (opening of ink injection flow path), 451b bottom (bottom of ink injection flow path), 452 first dispensing communication hole (first hole, part of communication section), 453 dispensing partition wall ( Wall part, part of communication part), 453a dispensing partition channel (connection channel, part of communication part), 454 Dispensing communication hole (second hole, part of communication part), 460a to 460c through hole, 470 sensor arm (rotating member), 471 balance part (part of rotating member), 472 mounting part (rotating member) Connecting part, part of connecting part), 472a mounting shaft (shaft upper part), 473 arm part (light blocking part of rotating member, part of connecting part), 473a vertical arm part (part of light blocking part, Part of connecting part), 473b Inclined arm part (part of light blocking part), 473c Shielding arm part (part of light blocking part), 473d Rib (part of light blocking part), 473e1, 473e2 Arm protrusion , 500 Ink supply mechanism, 501 Supply valve member (valve member), 510 Atmospheric introduction mechanism, 511 Atmospheric valve member, 520 Ink dispensing plug, 520a Outer end surface, 600 Supply cap (cap), 601 Supply fixing portion (second Outer cylindrical part), 602 Ink storage part, 603a, 603b Engagement hole (fitting part of second outer cylindrical part), 604a, 604b Supply cap notch part (notch part of second outer cylindrical part), 605 Insertion hole (part of second insertion path), 606a first upper wall, 606b inclined wall (part of second insertion path, inner cylindrical part), 606c lower wall (connecting part), 606d second upper wall ( Flange portion), 606e outer peripheral wall (first outer cylindrical portion), 607 ink storage portion, 610 supply joint (elastic member), 611 joint outer peripheral portion (first press-fit portion), 612 joint inner peripheral portion (second press-fit portion) ), 612a top surface, 612b bottom surface, 612c opening, 612d insertion passage, 613 joint abutting portion, 613a tip, 613b inner peripheral surface, 614 joint protrusion, 614a inner peripheral surface, 614 Step surface, 615 Ink channel (first insertion path into which ink extraction member is inserted), 615a Step channel (a part of first insertion path), 615b Protrusion channel (a part of first insertion path) , 615c Contact portion flow path (part of the first insertion path), 620 Supply valve (part of the valve member), 621 Valve bottom wall, 622 Valve outer peripheral wall, 622a Valve protrusion, 623 Valve guide groove, 624 Valve Protruding wall, 625 Valve regulating portion, 626 Valve hook portion, 627 Ink flow path, 628 Valve receiving portion, 629 Valve inner peripheral wall, 630 First supply spring (part of valve member), 631 Spring bottom portion, 632 Spring upper portion, 633 Spring flexible part, 634 Ink flow path, 634a Upper flow path, 634b Flexible flow path, 634c Bottom flow path, 640 Supply slider (valve member) 641) Slider outer peripheral wall, 642a, 642b Slider protruding wall, 643 Loose insertion part, 644 Slider base part, 645 Slider through hole, 650 Second supply spring (part of valve member), 651 Spring bottom part, 652 Spring Upper part, 653 Spring flexible part, 654 Ink flow path, 654a Upper flow path, 654b Flexible part flow path, 654c Bottom flow path, 660 Valve seat, 661 Valve seat bottom part, 662 Valve seat receiving part, 662a Valve seat inclined surface , 662b First valve seat through hole, 663 Second valve seat through hole, 664 Valve seat communication groove, 665 Valve seat protrusion, 670 Check valve, 671 Umbrella part, 671a Connection part, 671b Blade part, 672 Shaft part, 672a Sphere, 680 cover, 681 cover outer peripheral wall, 682 cover upper part, 683 1st cover through hole, 684 1st Cover through hole, 700 Atmospheric cap, 701 Atmospheric adhering portion, 702 Atmospheric cap bottom, 703a, 703b Engagement hole, 704a, 704b Atmospheric cap notch, 705 Atmospheric cap insertion hole, 710 Atmospheric joint, 711 Joint outer peripheral portion, 712 Joint Inner peripheral portion, 712a upper surface, 713 joint protrusion, 713a tip, 714 joint skirt portion, 715 joint passage, 720 atmospheric valve (valve member forming an atmospheric introduction path), 721 valve bottom wall, 721a valve opening portion (atmosphere) 721b Protruding part, 722 Valve outer peripheral wall, 722a Valve protruding part, 723 Valve guide groove, 724 Valve protruding wall, 725 Valve restricting part, 726 Valve hook part, 727 Ink flow path, 728 valve Receiving part, 729 valve inner peripheral wall, 730 first atmospheric spring, 731 spring bottom, 732 spring upper part, 733 spring flexible part, 734 ink flow path, 734a upper flow path, 734b flexible part flow path, 734c bottom flow path, 740 Atmospheric slider, 741 Slider outer peripheral wall, 742a, 742b Slider protruding wall, 743 Loose insertion part, 744 Slider base part, 745 Slider through hole, 750 Second atmospheric spring, 751 Spring bottom part, 752 Spring upper part, 753 Spring flexible part , 754 Ink channel, 754a Top channel, 754b Flexible channel, 754c Bottom channel, 800 Inner surface of ink supply body (ink supply channel), 810 Inner surface of air introduction body, 900 Ultrasonic welding Surface, 910 pressure reducing device, 911 suction pipe, 912 suction Pump, 920 Ink dispensing needle, 930 packaging bag, 931 opening, 940 decompression device, 941 suction tube, 942 suction pump, 1000 inkjet recording device, 1010 mounting portion, 1011 locking rod, 1011a convex portion, 1012 support portion, 1013 Mounting surface, 1013a ink flow path, 1013b air introduction path, 1014 ink remaining amount detection sensor (optical sensor), 1014a light emitting part (part of optical sensor), 1014b light receiving part (part of optical sensor), 1015 Ink extraction tube (ink extraction member), 1015a Notch (part of ink extraction member), 1016a, 1016b recess, 1016b1 fitting rod (guide rod, fitting portion), 1017 engagement member, 1017a engagement end portion, 1017b Axial support part, 1017c stomach part, 1017d convex part, 1018 Concave part, A longitudinal direction of the first and second case members, longitudinal direction of the case, longitudinal direction of the ink reservoir, longitudinal direction of the frame part 110, longitudinal direction of the B protector, C ink flow path, D residue, E ink cartridge Sliding direction, F engaging member moving direction, I ink liquid level, K ink flow path, L atmosphere introduction path, O1 axis direction of ink supply mechanism, O2 axis direction of atmosphere introduction mechanism, P1, P2 suction Center line of pump, Q valve seat, virtual outer circumference of R valve seat protrusion, rotation direction of S engagement member, rotation direction of T engagement member, removal direction of U ink cartridge, p1 after ink dispensing process The pressure in the ink storage chamber (first pressure), the pressure in the ink storage chamber after the p2 post-decompression step (second pressure), the pressure in the packaging bag after the p3 packaging space depressurization step (third pressure), t1 Second supply chain Distance between the through hole and the lower side wall of the frame part, t2 Distance between the second supply communication hole and the lower side wall of the supply recess, t3 First gap, t4 Second gap, t5 Range for storing ink in the ink storage part

Claims (7)

A method of manufacturing an ink cartridge comprising an ink reservoir having an internal space in which ink is stored at least in part, and a case made of a plurality of components that enclose the ink reservoir, and detachably attached to an ink jet recording apparatus In
The ink reservoir including a frame member having a first opening communicating with the internal space and a second opening communicating with the internal space between the first opening and the first opening is molded. 1 molding process,
A second molding step of molding a rotating member that rotates in the internal space as the ink decreases;
An attaching step of attaching a rotating member formed by the second forming step to a position facing the first opening and the second opening among the frame members formed by the first forming step; ,
A first flexible film is fixed to the peripheral edge of the first opening so as to close the first opening facing the rotating member attached by the attaching step , and the rotating member An adhering step of adhering a flexible second film to the peripheral edge of the second opening so as to close the opposing second opening ;
An ink dispensing process by the fixing step and the first film and the second film dispensing ink into the inner space of the ink container in a state of being fixed so as to face the rotating member,
An assembly step of assembling the plurality of components so that the ink reservoir in a state where ink is stored in the internal space by the ink dispensing step is housed in the case;
An ink cartridge comprising: a welding step of welding the plurality of component parts with ultrasonic waves while the ink reservoir is housed in the case by the assembling step. Manufacturing method. In the first molding step, the ink reservoir including a first rib that supports the first film from the inner space side is molded,
2. The method of manufacturing an ink cartridge according to claim 1, wherein in the fixing step, the first film is fixed to a peripheral portion of the first opening, and the first film is fixed to the first rib. . In the first molding step, a partition plate that partitions the internal space into a first chamber on the first opening side and a second chamber on the second opening side, and the partition plate is erected on the first opening side. The ink reservoir including the first rib and the second rib standing on the second opening side is molded;
3. The ink cartridge according to claim 1, wherein, in the fixing step, the second film is fixed to a peripheral portion of the second opening, and the second film is fixed to the second rib. Production method. The fixing step, an ink cartridge manufacturing method according to any one of claims 1 to 3, characterized in that fixing with suction and the second film and the first film from the inside of the frame member. In the first molding step, an ink supply unit that protrudes from a side surface of the frame member and supplies ink in the ink storage chamber to the inkjet recording apparatus, and the ink supply from the side surface of the frame member from which the ink supply unit protrudes An air introduction portion that protrudes in the same direction as the portion and introduces air into the ink storage chamber, and a side surface of the frame member from which the air introduction portion and the ink supply portion protrude, wherein the air introduction portion and the ink supply A passage projecting in the same direction as the air introduction part and the ink supply part project from between the part and a light blocking part of the rotating member is formed so as to be displaceable, and provided in the ink jet recording apparatus 2. The ink storage body comprising a detected portion irradiated with light emitted from the optical sensor thus formed is molded. Ink cartridge manufacturing method according to 4 either. An ink supply part through-hole for projecting the ink supply part to the outside, an air introduction part through-hole for projecting the atmosphere introduction part to the outside, and a detection window for exposing the detected part to the outside are provided on one surface of the case. A third molding step of molding the plurality of component parts to be disposed;
In the assembling step, the ink supply part protrudes to the outside from the ink supply part through hole, the atmosphere introduction part protrudes to the outside from the atmosphere introduction through hole, and the detected part is exposed to the outside from the detection window. The plurality of components molded by the third molding step are assembled,
6. The ink cartridge manufacturing method according to claim 5 , wherein, in the welding step, the plurality of component parts are welded to each other in a portion other than one surface of the case. Before the ink dispensing step, a first depressurization step of depressurizing the inside of the ink reservoir in a state where the first film and the second film are fixed in the fixing step;
A second depressurizing step for depressurizing the interior of the ink reservoir again after the ink is dispensed by the ink dispensing step into the ink reservoir depressurized by the first depressurizing step. ink cartridge manufacturing method according to any one of claims 1 to 6, characterized.

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