1. Technical Field
The present invention relates to a container holder of a liquid consuming apparatus detachably mounted with a liquid container having a pressurizing chamber into which a pressurization fluid are introduced and a liquid containing chamber in which liquids are contained.
2. Related Art
Exemplary liquid consuming apparatuses capable of ejecting liquid droplets from a liquid ejecting head include an ink jet printing apparatus mounted with an ink jet printing head for an image printing, a device mounted with a color material ejecting head used to manufacture a color filter such as liquid crystal display, a device mounted with an electrode material (conductive paste) ejecting head used to form an electrode such as an organic EL display or a field emission display (FED), a device mounted with a living-body organic matter ejecting head used to manufacture a bio chip, a device mounted with a sample ejecting head which is a precise pipette, and the like.
In particular, since the ink jet printing apparatus causes relatively small noise and can also form small dots with a high density in a printing, the ink jet printing apparatus has been recently used for the many printings including a color printing. As a type of supplying a liquid to the ink jet printing apparatus, there is a so-called cartridge type in which the liquid is supplied from a liquid container storing the liquid to the liquid consuming apparatus. The cartridge type is configured so that the liquid container is simply attached to or detached from the liquid consuming apparatus in order for a user to exchange the liquid container when the liquid contained in the liquid container are completely consumed.
In this type of liquid container, a circuit board mounted with a memory element (IC) for storing information on a ink type, a amount of residual liquid or the like may be disposed on an outer surface thereof. In this case, an apparatus terminal of the liquid consuming apparatus connected to a contact point of the circuit board is disposed in a container holder of the liquid consuming apparatus mounted with the liquid container. When the liquid container including such a circuit board is mounted in the container holder, it is necessary to reliably connect the contact point of the circuit board to the apparatus terminal of the liquid consuming apparatus. That is, it is necessary to connect the apparatus terminal to the contact point of the circuit board so as to be conductive.
Some liquid containers and container holders include, for example, a container fixation structure for releasably regulating a movement of the liquid container in a pulling direction of the liquid container in cooperation with an apparatus fixation structure formed in the container holder as a mechanism for firmly fixing the liquid container on a predetermined position of the container holder.
The container fixation structure includes a guide groove for releasably regulating the movement of the liquid container in a position opposite a insertion direction of the liquid container in cooperation with a locking pin of the apparatus fixation structure disposed in the container mounting portion when the liquid container is mounted in the container mounting portion against an urging force in the direction opposite the insertion direction.
When the liquid container is fixed on the container holder, the liquid container is inserted into the container mounting portion, further pushed against the urging force in the direction opposite the insertion direction by a slider member and a pressing force is released, the locking pin of the apparatus fixation structure is moved to a lock position of the guide groove and the liquid container is fixed.
In addition, when the liquid container is detached from the container holder, the container is pushed into the container mounting portion so that the locking pin is moved to a non-lock position of the guide groove. Accordingly, when the pressing force is released, the container is urged so as to be taken out in the direction opposite the insertion direction by the slider member.
Patent Document 1: JP-A-2005-88575
The known liquid container disclosed in Patent Document 1 realizes a reliable connection between the contact point of the circuit board and the contact point of the liquid consuming apparatus by disposing the circuit board in the vicinity of the apparatus fixation structure. Specifically, when substantially flat rectangular parallelepiped liquid containers are arranged in a direction in which a pair of flat largest surfaces are perpendicular to a vertical surface and arranged so that the largest surfaces are not overlapped vertically (hereinafter, referred to as “a vertically positioned”), the circuit board is disposed on a side surface and the apparatus fixation structure is disposed on a lower surface close to the side surface. That is, the circuit board and the container fixation structure are disposed on two surfaces which are near the outer surface of the container and are perpendicular to each other.
Recently, however, as the number of the liquid containers increases in order to improve printing quality, the liquid containers have been configured so as to be arranged lengthwise with high density.
However, the circuit board and the container fixation structure are disposed on the outer surfaces of the container that intersect each other. Accordingly, for example, when the known liquid containers are lengthwise arranged, for example, in this structure, gaps are normally interposed between the adjacent liquid containers in order to dispose the apparatus fixation structure. For this reason, the containers cannot be arranged with the high density.
Alternatively, when the apparatus fixation structure is separately positioned, positioning precision of the contact point of the circuit board is deteriorated. Accordingly, since the apparatus terminal and the contact point of the circuit board are easily detached, good electrical connection may not be obtained.
The liquid container disclosed in Patent Document 1 is an airtight type liquid container. The airtight type liquid container is formed in a flexible bag and the like having an airtight structure and designed to prevent a liquid from deteriorating due to air contact. In this way, since good quality of stored ink can be maintained for a long time, the airtight type liquid container is appropriate for a large-scale liquid container.
However, when the pressurization fluid are introduced into the pressurizing chamber from the outside in order to pressurize the flexible bag which is a liquid containing chamber, a pair of parallel largest surfaces of the liquid container are mainly expanded and deformed.
As described above, the circuit board is disposed in the side surface of the liquid container. Accordingly, when the liquid container is expanded and deformed, a position in which the apparatus terminal comes in contact with the contact point of the circuit board may be deviated, thereby resulting in contact failure. Moreover, the expansion and deformation of the liquid container may induce deviation of fixation location between the slots of the container holder and the liquid containers.
As a result, load may be applied to an engagement portion of the apparatus fixation structure and the container fixation structure, a partition wall of each slot, and the like. Consequently, since the locking pin, the guide groove, and the partition wall of each slot may be deformed, a more robust fixation mechanism is necessary, and thus manufacture cost may increase.
An advantage of some aspects of the invention is to provide a container holder capable of liquid containers with high density without deteriorating electrical connection between the contact points of the apparatus terminal and the circuit board, a liquid consuming apparatus, and the liquid container. The advantage can be attained by at least one of the following aspects:
A first aspect of the invention provides a container holder of a liquid consuming apparatus to which substantially rectangular parallelepiped liquid containers can be detachably mounted, the liquid containers each having a front end surface with a substantially rectangular shape, a first side surface intersecting a first short side of the substantially rectangular shape, a second side surface intersecting a second short side of the substantially rectangular shape, a third side surface intersecting a first long side of the substantially rectangular shape, a fourth side surface intersecting a second long side of the substantially rectangular shape, a rear end surface opposed to the front end surface, a liquid containing chamber for containing a liquid, a pressurizing chamber for pressurizing the liquid containing chamber by introducing a pressurization fluid, and a liquid supply port for supplying the liquid to a liquid ejecting head, and each configured such that the third side surface and the fourth side surface are largest surfaces, the container holder comprising: a plurality of container mounting portions which can be mounted with a plurality of the liquid containers in parallel so as to oppose the largest surfaces to each other; a plurality of apparatus terminals, each terminal adapted to come in contact with an electrode of a circuit board disposed on the first side surface of each liquid container; a plurality of apparatus fixation structures, each apparatus fixation structure adapted to releasably regulate a movement of the liquid container in a direction opposite to an insertion direction thereof in cooperation with a container fixation structure disposed on the second side surface of each liquid container; a plurality of guide protrusions, each guide protrusion disposed along the insertion direction of the liquid container and having a shape corresponding to a shape of a notch formed along the insertion direction in a corner portion corresponding to a side in which at least two of the first to fourth side surfaces of each liquid container intersect each other; and a pair of support sidewalls opposed to largest surfaces each of which is not opposed to the largest surface of another liquid container, at both ends of the plurality of liquid containers mounted on the container mounting portions.
According to the container holder with the above-described configuration, when the liquid containers are mounted in the container mounting portions, a space formed by the notch is formed at least in one of an upper portion and a lower portion of the adjacent liquid containers. In addition, the guide protrusion is disposed in the space.
Each liquid container is guided in the insertion direction by the guide protrusion and positioned in the corresponding container mounting portion. That is, there is no partition wall for partitioning the container mounting portions between the adjacent liquid containers. Accordingly, it is not necessary for the plurality of the liquid containers to be spaced by the partition walls or the guide protrusions.
That is, the plurality of liquid containers can be accommodated more closely (with high density). As a result, it is possible to form the container holder with a small width size in a thickness direction of the liquid container and realize a compact size thereof.
In the container holder with the above-described configuration, when the pressurization fluid is introduced into the pressuring chamber of each liquid container, the pair of largest surfaces parallel with each other of the liquid containers are expanded and deformed. In addition, in the container holder with no partition wall, at least some largest surfaces of the adjacent liquid containers come in pressing contact with each other. Of the largest surfaces of the liquid containers in both ends, at least some largest surfaces which are not opposed to the largest surfaces of the other liquid containers come in contact with the support sidewalls of the container holder.
That is, when the pressurizing fluid is introduced into the liquid containers mounted in the container holder, the liquid containers become a locked state between the pair of support sidewalls by an expansion force of the liquid containers. The plurality of liquid containers of which the expansion deformation is regulated are fixed on the container mounting portions firmly and integrally.
Alternatively, when the pressurization in the pressurizing chamber is released and the expanded liquid containers return an original shape, the adjacent liquid containers do not come in pressing contact with each other any longer or the liquid containers do not come in pressing contact with the support sidewalls any longer. Accordingly, the liquid containers can be smoothly attached or detached.
In this way, according to the container holder with the above-described configuration, since the expansion and deformation of the liquid containers can be regulated at the time the liquid containers are pressurized. Accordingly, it is possible to prevent contact failure between the apparatus terminal and the contact point of the circuit board and also to prevent electrical connection thereof from deteriorating. Moreover, it is possible to reduce load applied to an engagement portion of the apparatus fixation structure and the container fixation structure. Moreover, since the plurality of liquid containers are fixed on the container mounting portions firmly and integrally by the expansion force of the liquid containers, it is not necessary to provide a partition wall for partitioning the container mounting portions in the container holder. As a result, it is possible to simplify the container holder and to reduce a size of the container holder.
The contact point of the electrode of the circuit board and the container fixation structure are disposed on the first side surface and the second side surface, respectively. Accordingly, it is not necessary to dispose the apparatus terminal and the apparatus fixation structure between the largest surfaces (the third or fourth side surface) of the adjacent liquid containers. As a result, it is possible to accommodate the plurality of liquid containers with high density.
That is, according to the container holder with the above-described configuration, it is possible to obtain the simplified and miniaturized container holder capable of receiving the plurality of liquid containers with the high density without deteriorating the electrical connection of the contact point between the apparatus terminal and the circuit board.
In the container holder with the above-described configuration, the guide protrusion may be disposed on a support board on which a plurality of the liquid containers can be arranged in parallel in a state where the largest surfaces of the liquid containers are directed in a direction parallel to a vertical surface.
According to the container holder with such a configuration, when the liquid containers are mounted in the container mounting portions, the guide protrusions are disposed in the lower portions between the adjacent liquid containers.
That is, when the liquid containers are attached to or detached from the container mounting portions, the lower portions of the liquid containers are guided. Accordingly, it is easy to attach or detach the liquid containers. Moreover, the liquid containers are more reliably positioned in the container mounting portions.
In the container holder with such a configuration, a second guide protrusion disposed opposite the guide protrusion disposed on the support board may protrude at least in the vicinity of an opening for attachment and detachment of each container mounting portion.
According to the container holder with such a configuration, when each liquid container is attached to or detached form the corresponding container mounting portion, the upper portion of each liquid container is guided by the second guide protrusion. As a result, it is further easy to attach or detach the liquid containers.
A second aspect of the invention provides a liquid consuming apparatus comprising: a liquid ejecting head for ejecting a liquid; a plurality of substantially rectangular parallelepiped liquid containers each liquid container having a front end surface with a substantially rectangular shape, a first side surface intersecting a first short side of the substantially rectangular shape, a second side surface intersecting a second short side of the substantially rectangular shape, a third side surface intersecting a first long side of the substantially rectangular shape, a fourth side surface intersecting a second long side of the substantially rectangular shape, a rear end surface opposed to the front end surface, a liquid containing chamber for containing the liquid, a pressurizing chamber for pressurizing the liquid containing chamber by introducing a pressurization fluid, and a liquid supply port for supplying the liquid to the liquid ejecting head, and each configured such that the third side surface and the fourth side surface are the largest surfaces; a pressurization fluid supply mechanism for introducing the pressurization fluid into the liquid containers; a liquid supply mechanism for supplying the liquid from the liquid containers to the liquid ejecting head; the container holder according to any one of claims 1 to 3 to which the liquid containers are detachably mounted, wherein the plurality of liquid containers each has: a circuit board with at least one electrode on the first side surface, a contact point of the electrode being electrically connected to an apparatus terminal; a container fixation structure releasably regulating a movement of the liquid container in a direction opposite to insertion direction in cooperation with an apparatus fixation structure on the second side surface; and a notch disposed along the insertion direction in a corner portion corresponding to a side in which at least two of the first to fourth side surfaces of each liquid container intersect each other.
According to the liquid consuming apparatus with the above-described configuration, the liquid consuming apparatus can be configured to be compact since using the simplified and miniaturized container holder capable of receiving the plurality of liquid containers with the high density without deteriorating the electrical connection of the contact point between the apparatus terminal and the circuit board
A third aspect of the invention is to provide a liquid container comprising: a front end surface with a substantially rectangular shape; a first side surface intersecting a first short side of the substantially rectangular shape; a second side surface intersecting a second short side of the substantially rectangular shape; a third side surface intersecting a first long side of the substantially rectangular shape; a fourth side surface intersecting a second long side of the substantially rectangular shape, the third side surface and the fourth side surface being largest surfaces; a rear end surface opposed to the front end surface, a liquid containing chamber for containing a liquid; a pressurizing chamber for pressurizing the liquid containing chamber by introducing a pressurization fluid; a liquid supply port for supplying the liquid to a liquid ejecting head; a circuit board with at least one electrode on the first side surface, a contact point of the electrode being electrically connected to a terminal of a liquid consuming apparatus; a container fixation structure for releasably regulating a movement of the liquid container in a direction opposite to an insertion direction in cooperation with an apparatus fixation structure of the liquid consuming apparatus on the second side surface; and a notch disposed along the insertion direction in a corner portion corresponding to a side in which at least two of the first to fourth side surfaces of the liquid container intersect each other.
According to the liquid container with the above-described configuration, it is possible to obtain the simplified and miniaturized container holder capable of accommodating the plurality of liquid containers with the high density without deteriorating the electrical connection of the contact point between the apparatus terminal and the circuit board. Moreover, the liquid consuming apparatus using the container holder having the above-described configuration can become compact.
In the liquid container with the above-described configuration, the pressurizing chamber of the liquid container may be partitioned by a bag receiving portion with one open surface and a sheet film sealing the open surface of the bag receiving portion, and the liquid containing chamber may be formed by a flexible bag having a liquid lead-out portion for leading out the stored liquid to the outside.
According to the liquid container with such a configuration, it is easy to configure an airtight structure of the pressurizing chamber and the liquid containing chamber. As a result, it is possible to reduce manufacturing cost.
In the liquid container with the above-described configuration, a pair of positioning holes may be formed in the front end surface, and a movement in a direction along the front end surface may be regulated by fitting the pair of positioning holes to a pair of positioning pins disposed in the liquid consuming apparatus.
According to each liquid container with such a configuration, when each liquid container is mounted in the corresponding container mounting portion, the pair of positioning pins are inserted into the pair of positioning holes disposed on the front end surface in the insertion direction of the liquid container. Afterward, as each liquid container is further inserted, each liquid container is moved on the basis of the positioning pins. When each liquid container is completely mounted, the positioning holes are fitted to the positioning pins, and thus a direction along the front end surface of the liquid container is determined. Accordingly, the movement of each liquid container in the direction along the front end surface in the insertion direction is regulated. That is, since each liquid container can be mounted in the container mounting portion with an exact inclination, it is easy to mount the liquid container. Moreover, even when each liquid container is mounted with an erroneous inclination, it is possible to prevent the apparatus terminal, the container fixation structure, or the apparatus fixation structure from being broken. Moreover, when each liquid container is mounted in the container mounting portion, it is possible to maintain good electrical connection between the circuit board and the apparatus terminal or good fixation state between the container fixation structure and the apparatus fixation structure.
In the liquid container with the above-described configuration, the pair of positioning holes, the circuit board, and the container fixation structure may be disposed substantially on the same vertical section.
According to each liquid container with such a configuration, when each liquid container is mounted in the container mounting portion and the one pair of positioning pins disposed on the container mounting portion are fitted to the one pair of positioning holes disposed on the front end surface of the liquid container, each liquid container is positioned in the direction (that is, which is parallel to the vertical section) along the front end surface of each liquid container. Accordingly, the contact point of the circuit board and apparatus terminal positioned on one side of the vertical section and the fixation structures positioned on the other side of the vertical section are positioned with the high density in an approach direction or a departing direction.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
a) is a perspective view illustrating a lever member 45 and a spring 44 shown from the side of the ink cartridges 100.
a) is a top view illustrating a front end surface 11 of each ink cartridge 100.
b) is a diagram illustrating the front end surface 11 when viewed from an arrow D.
Hereinafter, an exemplary embodiment of a liquid container, a container holder, and a liquid consuming apparatus will be described in detail with reference to the accompanying drawings.
In a rear upper portion of the platen 213 in the main body case 212, a guide shaft 214 with a bar shape is disposed along the primary scanning direction. A carriage 215 is movably supported in the guide shaft 214 along the guide shaft 214.
In a rear side surface of the inside of the main body case 212, a driving pulley 216 and a driven pulley 217 are rotatably supported in positions corresponding to both end portions of the guide shaft 214. A carriage motor 218 is connected to the driving pulley 216 and an endless timing belt 219 for supporting the carriage 215 is suspended between the pair of driving pulley 216 and the driven pulley 217. Accordingly, the carriage 215 is configured to reciprocate along the guide shaft 214 in the primary scanning direction by drive of the carriage motor 218.
A cartridge holder 200, which is a container holder with a box-like shape, is disposed in one end (right end in
Each ink cartridge 100 is configured to be connected to an upstream end of corresponding ink supply passages 223 when mounted in the cartridge holder 200. In addition, a downstream end of each ink supply passage 223 is connected to the upstream end of a corresponding valve unit 224 mounted in the carriage 215. Downstream sides of the valve units 224 are configured to be connected to a print head 225, which is a liquid ejecting head, disposed in the lower surface of the carriage 215. The ink supply passages 223 and the valve units 224 are a liquid supply mechanism for supplying liquids supplied from the ink cartridge 100 to the print head 225.
A home position HP which is an evacuation position of the print head 225 is disposed between the cartridge holder 200 and the platen 213. In addition, before a print start and the like, the print head 225 is in the home position HP and various maintenance operations such as a cleaning of the print head 225 are performed.
In the inside of the main body case 212, a pressurizing pump 226 is disposed in an upper side of the cartridge holder 200. The pressurizing pump 226, which is a supply source of pressurizing air (a pressurization fluid), is connected to the upstream end of pressurization air supply passages 227. The number of the pressurization air supply passages 227 divided from distributors 228 disposed on the downstream side of the pressurizing pump 226 is the same as that of the ink cartridge 100. The downstream end of each divided pressurization air supply passage 227 is connected to the corresponding ink cartridge 100. In addition, the pressurizing pump 226, the pressurization air supply passage 227, and the distributors 228 constitute the pressurization fluid supply mechanism for supplying the pressurization fluid to the ink cartridges 100. In this embodiment, as the pressurization fluid, air is used, but another gas different from air, liquids, or the like may be used.
As shown in
As shown in
As shown in
The board 241 is a support board for placing the ink cartridges 100 in parallel when the ink cartridges 100 are mounted in the cartridge holder 200. On the board 241, a plurality of guide rails 33, which are first guide protrusions, are disposed so as to be extended in line along front and rear directions. The guide rails 33 are disposed to guide the ink cartridges 100 when the ink cartridges 100 are attached to or detached from the holder 200. In the inside of the cartridge holder 200, the guide rails 33 partition five cartridge slots 7A to 7E. The cartridge slots 7A to 7E serve as a container mounting portion for separately receiving each ink cartridge 100 of each color.
The wall body 244 is a molded product with a D shape in a top view. The wall body 244 is mounted on the board 241 so as to be opened toward an opening frontward. A top plate 245 formed in a rectangular shape is mounted on the upper surface of the wall body 244.
The wall body 244 includes a rear surface (not shown). In addition, the wall body 244 includes a slider member 246 having surfaces 246b substantially parallel to the rear surface of the wall body 244. The slider member 246 is configured to be urged frontward, that is, in a direction opposite an insertion direction of the ink cartridges 100 by urging means (not shown). The surfaces 246b of the slider member 246 are formed of an inward end section of the cartridge slots 7A to 7E. When the ink cartridges 100 are not mounted into the cartridge slots 7A to 7E, the slider member 246 is positioned on a front side by a force of the urging means.
When the ink cartridges 100 are inserted into the cartridge slots 7a to 7E, the slider member 246 is pushed by the front end surfaces 11 (see
When the ink cartridges 100 are completely mounted into the cartridge slots 7A to 7E, the slider member 246 is stopped in a predetermined position. Even when the ink cartridges 100 are mounted into the cartridge slots 7A to 7E, the force of the urging means allows the slider member 246 to normally apply an urging force to the mounted ink cartridges 100 in the direction opposite the insertion direction. When the ink cartridges 100 are detached from the cartridge slots 7A to 7E, the ink cartridges 100 are applied by the urging force to be pushed frontward.
In the slider member 246, opening portions 246a for exposing each pair of positioning pins 247 disposed on the rear surface of the wall body 244, air communicating ports 248, ink supply pins 249, and identification members 251a to 251e frontward from the rear surface of the wall body 244 are provided.
On the rear surface of the wall body 244, that is, on an inward end surface of the respective cartridge slots 7A to 7E, the pairs of positioning pins 247, the air communicating ports 248, the ink supply pins 249, and the identification member 251a to 251e are disposed so as to be protrude frontward through the opening portions 246a of the slider member 246.
The pairs of positioning pins 247, the air communicating ports 248, the ink supply pins 249, the identification member 251a to 251e on the front surface of the slider member 246, which is the inward end surface of container mounting portions 1, function when the ink cartridges 100 are mounted in the cartridge slots 7A to 7E on the board 241.
One pair of positioning pins 247 are used to position each ink cartridge 100. The one pair of positioning pins 247 are disposed on the upper portion and the lower portion of the inward end surface of each of the cartridge slots 7A to 7E.
The air communicating ports 248, which is positioned between the one pair of positioning pins 247 vertically provided and inserted into the positioning holes 21 and 23 of each ink cartridge 100, is used to supply air to each ink cartridge 100. The air communicating port 248 is disposed on the lower portion of the inward end surface of each of the cartridge slots 7A to 7E. In addition, the air communicating port 248 is disposed substantially on an imaginary line connecting the one pair of positioning pins 247 to each other and on a position close to the positioning pin 247 in the lower portion.
The ink supply pin 249 is used to supply the ink from each ink cartridge 100 to the print head 225 (see
The identification members 251a to 251e are used to prevent the ink cartridges 100 from being erroneously mounted. The identification members 251a to 251e are disposed on the lower portion of the inward end surface of the cartridge slots 7A to 7E, respectively. In addition, the identification members 251a to 251e are disposed in the position between the one pair of positioning pins 247 and a position right above the air communicating ports 248. That is, the identification members 251a to 251e are disposed in the position between the upper positioning pin 247 and the air communicating port 248 and a position close to the air communicating port 248.
From the position right above the air communicating ports 248, front end portions of the plurality of identification members 251a to 251e (which are 5 members in this embodiment) are configured to protrude frontward through notches 246a formed so as to be cut from the lower portions of the slider member 246.
The identification members 251a to 251e each have a hollow-hole cylindrical shape of which the rear end surface, which is a base end, are opened and which extend in front and rear directions. An uneven fitting portion is formed in the front end of each of the identification member 251a to 251e. In addition, an identification portion 22 (see
Each of the uneven fitting portions of the identification members 251a to 251e is configured to be fitted only to the identification portion 22 of one type of the ink cartridge 100, but not to be fitted to the identification portions 22 of the other types of the ink cartridges 100. In this way, the ink jet printing apparatus according to this embodiment is configured to prevent the ink cartridges 100 from being erroneously mounted by combination of the identification portions 22 of the ink cartridges 100 and the uneven fitting portions of the identification members 251a to 251e.
As shown in
The guide protrusions 265 are disposed opposite the guide rails 33. Like the guide rails 33, the second guide protrusions 265 are used to guide the ink cartridges 100 when the ink cartridges 100 are attached to or detached from the cartridge slots 7A to 7E of the container holder 200.
When the ink cartridges 100 are mounted in the cartridge slots 7A to 7E, the apparatus terminals 250 come in contact with contact points 17a (see
The apparatus fixation structure 50 is provided on the lower side and inward side (rear side) of the cartridge slots 7A to 7E.
As shown in
The lever member 45 has a slim long lever main body 47 with elasticity, a shaft hole 36 disposed in a base end portion, and a substantial cylindrical locking pin 37 protruding on the upper surface (which is a surface of the ink cartridge 100) of the front end portion of the lever main body 47. There is a gap between a bottom surface 243 and board 241 of the wall body 244 and the lever member 45 is arranged by using the gap.
A protruding portion 242 is provided on the bottom surface 243 of the wall body 244. The shaft hole 36 of the lever member 45 is inserted into the protruding portion 242. The lever member 45 is axially supported so as to be rotatable on the protruding portion 242. That is, the protruding portion 242 functions as a rotation shaft of the lever member 45. The circumference of the protruding portion 242 is supported by a cap 38 and coil springs 60 accommodated in the groove of the cap 38. The coil springs 60 have a function of rotatably supporting the lever member 45 on the board 241 and a function of stabilizing the movement of the lever member 45 by urging the lever member 45 upward.
As shown in
The ink cartridge 100 includes a case 5 with a substantially flat rectangular parallelepiped shape as shown in
The case 5 is a chassis formed of a resin. The case 5 includes the bag receiving portion 3 with a substantial box shape of which the upper portion is opened and a detection unit receiving portion 4 positioned in the front surface of the bag receiving portion 3. The ink pack 20 and resin spacers 26 are accommodated in the bag receiving portion 3. The ink pack 20 is a flexible bag formed of an aluminum lamination multilayered film in which an aluminum layer is laminated on a resin film layer. The resin spacers 26 are mounted on the inclined portions of the front and rear of the ink pack 20. The liquid residual quantity detection unit 30 is accommodated in the detection unit receiving portion 4.
The opened surface of the bag receiving portion 3 is sealed by a sheet film 24 after receiving the ink pack 20 and the resin spacers 26. The pressurizing chamber is partitioned in the case 5 by the bag receiving portion 3 and the sheet film 24.
When the upper surface of the bag receiving portion 3 is covered with the sheet film 24 and the bag receiving portion 3 is sealed, the spacers 26 prevents the ink pack 20 from being shaken in the sealed case and also fill the empty spaces in the sealed case to improve pressurization efficiency when the bag receiving portion 3 is pressurized by pressurization air.
A resin cover 6 is mounted on the sheet film 24 sealing the opened surface of the bag receiving portion 3 and the detection unit receiving portion 4.
In this embodiment, there is provided five types of the ink cartridges 100. Different five-color ink is stored in the ink packs 20 of the five-type ink cartridges 100. The five-type ink cartridges 100 have the same configuration except for the ink types stored in the ink packs 20 and the detailed shape of the identification portions 22 described above.
As shown in
As shown in
The ink cartridges 100 are mounted in the cartridge slots 7A to 7E so that each first side surface 15 and each second side surface 25 face to the upper side and the down side, respectively. In addition, the plurality of ink cartridges 100 are placed in parallel on the board 241 in lines so that each third side surface 35a and each fourth side surface 35b are opposed in a direction parallel to the vertical surface. As shown in
As shown in
When the ink cartridges 100 are not mounted in the cartridge slots 7A to 7E, each ink supply port 7 is blocked by a valve or a sealing member. A pressure (static pressure) by which ink contained in the ink pack 20 is flown out from the ink supply port 7 is applied to the ink supply port 7. As an amount of ink contained in the ink pack 20 is larger, the static pressure increases. Accordingly, the static pressure (initial static pressure) is relatively high in a state where the ink is sufficiently filled. In addition, when the ink supply port 7 is opened in a state where the static pressure in the ink pack 20 is relatively high, the ink may flow out from the ink supply port 7.
However, if the ink supply port 7 is configured to be positioned above the center portion in the height direction (vertical direction) of the ink pack 20 according to this embodiment, the static pressure of the ink in the ink pack 20 becomes lower at a position in which the ink supply port 7 is disposed. Moreover, flow resistance caused by the flow passage 19 which connects the ink supply port 7 to the ink ejecting port 20a reduces the static pressure applied to the ink supply port 7. That is, according to this embodiment, even when the ink cartridges 100 are mounted in the cartridges slots 7A to 7E and the ink supply pins 249 are inserted into the ink supply ports 7, it is difficult for the ink to leak from the ink supply ports 7.
With reference to
When the ink cartridges 100 are mounted in the cartridge slots 7A to 7E, the ink supply pins 249 described above are inserted into the ink supply ports 7. The ink supply pins 249 are connected to the print head 225 through the ink supply passages 223 and the valve units 224.
When the ink cartridges 100 are mounted in the cartridge slots 7A to 7E, the air inflow ports 9 are inserted into the air communicating ports 248 described above. The air communicating ports 248 are connected to the pressurizing pump 226 through the pressurization air supply passage 227. The pressurizing pump 226 can pressurize the ink packs 20 by supplying pressurization air to the bag receiving portions 3 through the pressurization air supply passages 227, the air communicating ports 248, and the air inflow ports 9. By pressurizing each of the ink pack 20 in this way, the ink flowing out from the ink ejecting port 20a of each of the ink packs 20 is supplied to the print head 225 of the ink jet printing apparatus 211 through the ink supply port 7.
As shown in
When the ink cartridges 100 are mounted in the cartridge slots 7A to 7E, the front ends of the positioning pins 247 are fitted to the positioning holes 21 and 23. Afterward, when the ink cartridges 100 are further inward inserted into the cartridge slots 7A to 7E, the ink cartridges 100 are moved on the basis of the positioning pins 247.
When the ink cartridges 100 are mounted in the cartridge slots 7A to 7E, the positioning holes 21 and 23 are fitted to the one pair of positioning pins 247. At this time, since a direction of the front end surface 11 of each ink cartridge 100 is determined, the movement of the ink cartridges 100 in the direction along the front end surface 11 is regulated.
Moreover, as shown in
According to this embodiment, as shown in
That is, when the ink cartridges 100 are mounted in the cartridge slots 7A to 7E, the location precision of the ink cartridges 100 in the cartridge slots 7A to 7E is maintained by the positioning hole 21 in the upper portion. Relative location deviation of the positioning hole 23 and the positioning pin 247 (see
As shown in
A residual quantity detecting sensor (sensor using piezoelectric element) (not shown) is mounted in the liquid residual quantity detecting unit 30. The residual quantity detecting sensor is a sensor for detecting an amount of residual ink in each ink cartridge 100. At least one electrode electrically connected to the residual quantity detecting sensor is disposed on the circuit board 17.
As shown in
Moreover, since each of the circuit board 17 is disposed in the vicinity of the front end surface 11 and the positioning hole 23 in the upper portion for maintaining the location precision is disposed in the vicinity of the first side surface 15, the contact point 17a of the circuit board 17 and the contact point 250a of the apparatus terminal 250 are located with high precision.
When the ink cartridges 100 are mounted in the cartridge holder 200 of the ink jet printing apparatus 211 (see
As shown in
When the substantially flat rectangular parallelepiped ink cartridges 100 are accommodated lengthwise, that is, accommodated in parallel so that the first side surfaces 15 are faced upward and the second side surfaces 25 are faced downward, the ink cartridges 100 are arranged in parallel so that the first side surfaces 35a and the fourth side surfaces 35b are opposed to each other between the plurality of adjacent ink cartridges 100. In addition, between the adjacent ink cartridges 100, the chamfered surfaces 29a and 29b of the ink cartridges 100 form sectional triangular spaces 31a and 31b in a sectional view so as to be extended in the insertion direction of the ink cartridges 100.
As shown in
As shown in
In the configuration in which the sectional triangular guide rails 33 corresponding to the chamfered surfaces 29b are arranged along the insertion direction of the ink cartridges 100, when the plurality of substantially flat rectangular parallelepiped ink cartridges 100 are mounted in the cartridge holder 200 lengthwise in parallel, the substantially same sectional triangular guide rails 33 can be arranged in the sectional triangular spaces 31b formed in the lower portions between the adjacent ink cartridges 100 in the insertion direction of the ink cartridges 100.
The ink cartridges 100 are guided in the insertion direction by the guide rails 33 and located in the cartridge holder 200. Accordingly, partition walls for partitioning the cartridge slots 7A to 7E of the cartridge holder 200 between the adjacent ink cartridges 100 are not necessary.
When pressurization air is introduced into the bag receiving portions 3 and the ink packs 20 are pressured from the outside in order to supply the ink to ink jet printing apparatus 211, as shown as an imaginary line in
In this embodiment, there is no partition wall in the cartridge holder 200. Accordingly, when the pressurizing air is introduced into the bag receiving portions 3, the largest surfaces 35a and 35b of the adjacent cases 5 are expanded and deformed. In addition, parts of the largest surfaces 35a and 35b of the adjacent ink cartridges 100 come in contact with each other in the cartridge slots 7A to 7E with no partition wall. In addition, of the largest surfaces 35a and 35b of the ink cartridges 100 in both outer ends, as shown in
That is, when the pressurizing fluid is introduced into the ink cartridges 100 mounted in the cartridge slots 7A to 7E, as shown in
Alternatively, when the pressurization in the pressurizing chamber is released and the expanded ink cartridges 100 return to the original shape, the adjacent ink cartridges 100 do not come in pressing contact with each other any longer and the ink cartridges 100 and the support sidewalls 262 do not come in pressing contact with each other any longer.
In the second side surface 25, as shown in
As shown in
As shown in
Since an exit portion 57 is connected to an entrance portion 59, the guide groove 39 overall has a loop configuration. Since the groove depth of the exit portion 57 is shallower than that of the entrance portion 59 in a connection portion of the entrance portion 59 and the exit portion 57, an uneven portion 65 is formed in the connection portion. Each of the uneven portions 65 prevents the locking pin 37 from entering the exit portion 57 when the ink cartridges 100 are inserted into the cartridge slots 7A to 7E.
The apparatus fixation structure 50 is provided blow the container fixation structure 40. As described above, the apparatus fixation structure 50 includes The lever member 45 and the spring 44 shown in
The lever member 45 is urged in a fixed rotation direction by the spring 44. This direction is an arrow −R direction shown in
As shown in
Next, an operation of the locking pin 37 in the guide groove 39 at the time the ink cartridges 100 are attached or detached will be described with reference to
When the ink cartridges 100 are inserted into the cartridge slots 7A to 7E and the ink cartridges 100 are further pushed against the urging force of the slider member 244 (see
The locking pin 37 is urged toward the direction of the bottom surface of the guide groove 39 by elastically deforming the lever main body 47 (see
In addition, when the locking pin 37 collides with an interim stopping sidewall 61 and stops, the click sounds. The click allows a user to check the ink cartridges 100 are sufficiently inserted.
Next, when the pressing pressure of the user in the insertion direction is released, the ink cartridges 100 moves back a little in the pulling direction due to the urging force of the slider member 246 (see
In addition, when the locking pin 37 collides with an end stop sidewall 63 formed in the locking portion 49 and stops in the lock position, the clock sounds. The click allows the user to check the ink cartridges 100 are fixed on the cartridge slots 7A to 7E (see
When the ink cartridge 100 is attached or detached, the engagement of the locking pin 37 in the end stop sidewall 63 is released by pushing the locked ink cartridge 100 and the locking pin 37 is relatively moved to a non-lock position along the exit guide portion 55 by the urging force of the lever member 45 generated by the spring 44. At this time, the ink cartridge 100 is pushed frontward by the urging force of the slider member 246 (see
In addition, as shown in
Next, a positional relation between the apparatus terminal 250 and the locking pin 37 at the time each ink cartridge 100 is mounted, that is, the locking pin 37 is locked in the locking portion 49 will be described mainly with reference to
The apparatus terminal 250 includes the contact point 250a connected to the contact point 17a of the electrode of the circuit board 17 disposed in the first side surface 15 of each ink cartridge 100. The contact point 250a is connected to the contact point 17a in a position closer to the front end surface 11 of each ink cartridge 100 by a distance S than the position in which the locking pin 37 is locked in the locking portion 49.
In this embodiment, as described above, when the ink cartridges 100 are mounted in the cartridge slots 7A to 7E, as shown in
The ink cartridges 100 are guided in the insertion direction by the guide protrusions 33 and positioned in the cartridge slots 7A to 7E. That is, there is no partition wall for portioning the cartridge slots 7A to 7E between the adjacent ink cartridges 100.
Accordingly, it is not necessary for the plurality of ink cartridges 100 to be spaced by the partition walls or the guide protrusions 33. That is, it is possible to accommodate the plurality of ink cartridges 100 more closely (with high density). Accordingly, it is possible to form the compact cartridge holder of which a total reception size is smaller in a thickness direction of the container holder. Moreover, it is possible to allow the overall ink jet printing apparatus 211 to be compact.
According to this embodiment, as described above, when the ink cartridges 100 are pressurized, the expansion and deformation of the liquid containers are regulated. Accordingly, it is possible to prevent the apparatus terminal 250 and of the contact point 17a of the circuit board 17 from being deviated and prevent the electrical connection thereof from deteriorating. In addition, it is possible to reduce load applied to the engagement portion of the apparatus fixation structure 50 and the container fixation structure 40 describe below. In addition, since the plurality of ink cartridges 100 are fixed on the cartridge slots 7A to 7E firmly and integrally by their expansion force, it is not necessary to form the partition walls for partitioning the cartridge slots 7A to 7E in the container holder 200. As a result, it is possible to simplify the container holder 200 and decrease the size thereof.
Since the contact point 17a of the electrode of the circuit board 17 and the apparatus fixation structure 40 are disposed on the first side surface 15 and the second side surface 25 of each of the ink cartridge 100, it is not necessary to form the apparatus terminals 250 or the apparatus fixation structures 50 between the firth side surfaces 35a and the fourth side surfaces 35b of the adjacent cartridges 100. Accordingly, it is possible to accommodate the plurality of ink cartridges 100 with the high density.
That is, according to this embodiment, it is possible to accommodate the plurality of ink cartridges 100 with the high density without deteriorating the electrical connection between the apparatus terminal 250 and the contact point 17a of the circuit board 17.
According to this embodiment, as shown in
Accordingly, when the ink cartridges 100 are mounted in the cartridge slots 7A to 7E, the guide protrusions 33 are formed on the lower portions between the adjacent ink cartridges 100.
That is, when the ink cartridges 100 are attached to or detached from the cartridge slots 7A to 7E, the lower portions of the ink cartridges 100 are guided. Accordingly, it is easy to attach or detach the ink cartridges 100. Moreover, the ink cartridges 100 are more reliably positioned in the cartridges slots 7A to 7E.
As shown in
The shape of the sectional surface of each guide rail 33 or guide protrusion 265 (see
Each guide protrusion 265 (see
According to this embodiment, as shown in
According to this embodiment, as shown in
According to this embodiment, as shown in
According to this embodiment, as shown in
However, the case where the ink cartridges 100 are lengthwise arranged in parallel, in particular, the case where the first side surface 15 on which the circuit board 17 is formed and the apparatus terminal 250 are disposed on the upper side and the second side surface 25 on which the container fixation structure 40 is formed and the apparatus fixation structure 50 are disposed on the lower side is advantageous in that it is possible to prevent the circuit board 17 from electrically deteriorating due to leaked ink.
According to this embodiment, the circuit board 17, the positioning hole 21, and the ink supply port 7 are all integrated on the upper side. As described above, it is possible to improve position precision of the circuit board 17 and the apparatus terminal 250 and position precision of the ink supply port 17 and the ink supply pin 249 by arranging the circuit board 17, the positioning hole 21, and the ink supply port 7 more closely. In addition, since the ink supply port 7 is formed on the upper portion, the ink ejecting port 20a of the ink pack 20 can be formed on the lower side than the ink supply port 7. Accordingly, it is possible to reduce the initial static pressure. That is, like the this embodiment, when the first side surface 15 and the second side surface 25 are disposed on the upper portion and the lower portion, respectively, it is possible to improve the position precision of the circuit board 17 and the apparatus terminal 250 and the position precision of the ink supply port 17 and the ink supply pin 249. In addition, it is easy to realize the configuration in which the initial static pressure can be reduced.
According to this embodiment, as shown in
In particular, according to this embodiment, as shown in
The contact point 17a of the electrode of the circuit board 17 disposed on the first side surface 15 is firmly pressed to the apparatus terminal 250. However, since the contact point 17a can move more than the bottom surface of the guide groove 39 of the container fixation structure 40 by the locking pin 37, the contact point 17a move to the apparatus terminal 250. Accordingly, since the contact point 17a is configured to be more firmly pressed to the apparatus terminal 250, the electrode of the circuit board 17 and the apparatus terminal 250 more reliably are connected with each other.
This application claims priority from Japanese Patent Application Nos. 2006-300935 filed on Nov. 6, 2006 and 2007-240195 filed on Sep. 14, 2007, the entire disclosure of which are expressly incorporated by reference herein.
While this invention has been described in conjunction with the specific embodiments thereof, it is evident that many alternatives, modifications, and variations will be apparent to those skilled in the art. Accordingly, preferred embodiments of the invention as set forth herein are intended to be illustrative, not limiting. There are changes that may be made without departing from the spirit and scope of the invention.
Number | Date | Country | Kind |
---|---|---|---|
2006-300935 | Nov 2006 | JP | national |
2007-240195 | Sep 2007 | JP | national |