DE102014224324A1 - liquid cartridge - Google Patents

Abstract

A liquid cartridge has a movable member, and the movable member has a detecting portion and a float. The liquid cartridge also has a restriction member, and the restriction member has an operation portion and a restriction portion. When the operating portion is at a first position, the limiting portion is configured to be in contact with the movable member such that movement of the float is limited within a limited range. When the operating portion is at a second position, the limiting portion is configured to disengage the movable member such that the float is positioned in a free area that is above the limited area.

Description

The present invention relates to a liquid cartridge.

A known ink jet recording apparatus is configured to record an image on a recording medium by ejecting ink stored in an ink tank from nozzles. The viscosity of the ink stored in the ink container may change over time. A known ink jet recording apparatus as disclosed in the patent publication JP 09 277560 A is configured to estimate the viscosity of the ink stored in an ink tank and to perform optimized preliminary ejection based on the estimation result. Specifically, the ink jet recording apparatus is configured to estimate the viscosity of the ink based on an elapsed time after the ink tank is mounted on the ink jet recording apparatus and an amount of the ink remaining in the ink tank. Nonetheless, this known ink jet recording apparatus does not estimate the viscosity by directly measuring a physical quantity obtained when a movable member moves in the ink. In addition, this known ink jet recording apparatus can not estimate the viscosity of the ink stored in an ink tank which has not been mounted on the ink jet recording apparatus and has not been used.

Therefore, a need exists for a liquid cartridge that overcomes these and other deficiencies of the prior art. A technical advantage of the present invention is that the viscosity of a liquid stored in a liquid cartridge can be estimated by an even more direct measurement.

According to one aspect of the present invention, a liquid cartridge includes: a first outer side; a second outer side opposite the first outer side; a liquid chamber positioned between the first outside and the second outside and configured to store a liquid therein, the liquid having a first specific gravity; a liquid supply section positioned at the first outside and configured to supply the liquid from an interior of the liquid chamber to an outside of the liquid chamber; a movable member positioned in the liquid chamber, the movable member having a detecting portion and a float, the float having a second specific gravity smaller than the first specific gravity; and a restriction member having an operation portion and a restriction portion, wherein the operation portion is operable from the outside of the liquid chamber and is movable between a first position and a second position, the second position being closer to the second outside than the first position. The restricting portion is movable with movement of the operating portion from the first position to the second position. When the operating portion is at the first position, the restricting portion is configured to contact the movable member in the liquid chamber and limit movement of the movable member, the float in the liquid being submerged in the liquid chamber within a limited range , When the operating portion is at the second position, the restricting portion is configured to disengage the movable member so that the float is positioned in a free area that is above the limited range.

With this configuration, when the operating portion is moved from the first position to the second position, the movable member is released and moves as the float moves within the liquid. Since the movable element moves against viscosity resistances and inertial resistances caused by the liquid in the liquid chamber, the speed of the detection section depends on the viscosity of the liquid in the liquid chamber. By measuring a physical quantity, on the basis of which the speed of the detection section can be specified, the viscosity of the fluid stored in the fluid chamber can be estimated.

According to another aspect of the present invention, a liquid cartridge comprises: a liquid chamber configured to store a liquid therein, the liquid having a first specific gravity; a liquid supply section configured to supply the liquid from an inside of the liquid chamber to an outside of the liquid chamber; and a movable member positioned in the liquid chamber, the movable member having a detecting portion and a float, the float having a second specific gravity smaller than the first specific gravity; and a gas bag filled with gas. The gas bag is configured to change state from a bulge to a contracted state. When the gas bag is in the bulge condition, the gas bag in the fluid chamber is bulged and in contact with the movable member in the fluid chamber and limits movement of the movable member the float in the liquid is submerged in the liquid chamber within a limited range. When the gas bag is in the contracted state, the gas bag is configured to disengage the movable member such that the float is positioned in a free area that is above the limited area. When the gas bag is in the contracted state, a gas amount in the gas bag is smaller than a gas amount in the gas bag when the gas bag is in the bulged state.

With this configuration, when the gas bag changes its state from the bulge state to the contracted state, the movable element is released and moves as the float moves within the fluid. As the movable member moves against viscosity resistances and inertial resistances caused by the liquid in the liquid chamber, the velocity of the detection portion depends on the viscosity of the liquid in the liquid chamber. By measuring a physical quantity, on the basis of which the speed of the detection section can be specified, the viscosity of the fluid stored in the fluid chamber can be estimated.

Other objects, features and advantages will become apparent to those skilled in the art from the following detailed description of the invention and the accompanying drawings.

For a better understanding of the present invention and the needs of it as well as its objects, features and advantages, reference is now made to the ensuing description taken in conjunction with the accompanying drawings.

1 FIG. 12 is a schematic cross-sectional view of a printer having a cartridge mounting portion and an ink cartridge according to an embodiment of the present invention. FIG.

2 FIG. 12 is a perspective view of the cartridge mounting portion, which is partially cut away, showing an end surface of the cartridge mounting portion. FIG.

3A shows a perspective view of the ink cartridge in which a film is welded to a frame.

3B shows an exploded perspective view of the ink cartridge in which the film is removed from the frame.

4 shows a functional block diagram of the printer.

5A FIG. 12 shows a cross-sectional view of the ink cartridge and the cartridge mounting portion during insertion of the ink cartridge into the cartridge mounting portion. FIG.

5B Fig. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion when the mounting of the ink cartridge to the cartridge mounting portion is completed and the upper end of a movable member is in a detection position.

5C Fig. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion when mounting the ink cartridge to the cartridge mounting portion is completed and the lower end of the movable member is at the detection position.

6A Fig. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion when the movable member is at the upper end of a moving path.

6B Fig. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion when the ink cartridge is in a near-empty state.

6C Fig. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion when the ink cartridge is in an empty state.

7 FIG. 12 is a flowchart of a process performed by a controller when a cover of the cartridge mounting portion is opened and a sensor outputs a high level signal. FIG.

8th FIG. 12 is a flowchart of a process performed by the control device when the processes of FIG 7 are completed and the cover of the cartridge mounting portion is closed.

9 shows a cross-sectional view of an ink cartridge according to a first modified embodiment.

10A FIG. 12 is a cross-sectional view of an ink cartridge and a cartridge mounting portion according to a second modified embodiment during insertion of the ink cartridge into the cartridge mounting portion. FIG.

10B FIG. 16 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the second modified embodiment when mounting the Ink cartridge is completed on the cartridge mounting portion.

11A FIG. 10 is a cross-sectional view of an ink cartridge according to a third modified embodiment before the ink cartridge is mounted to the cartridge mounting portion. FIG.

11B FIG. 12 is a cross-sectional view of the ink cartridge and a cartridge mounting portion according to the third modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion is completed. FIG.

12A FIG. 12 is a cross-sectional view of an ink cartridge and a cartridge mounting portion according to a fourth modified embodiment when a light transmitting portion is at a detection position. FIG.

12B FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the fourth modified embodiment when a light-blocking portion is at the detection position. FIG.

13A FIG. 12 is a cross-sectional view of an ink cartridge and a cartridge mounting portion according to a fifth modified embodiment during insertion of the ink cartridge into the cartridge mounting portion. FIG.

13B FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the fifth modified embodiment when mounting the ink cartridge to the cartridge mounting portion is completed and the lower end of a movable member is at a detection position. FIG.

13C FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the fifth modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion is completed and the upper end of the movable member is at the detection position.

14A FIG. 12 is a cross-sectional view of an ink cartridge and a cartridge mounting portion according to a sixth modified embodiment during insertion of the ink cartridge into the cartridge mounting portion. FIG.

14B FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the sixth modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion is completed. FIG.

15A FIG. 12 is a cross-sectional view of an ink cartridge and a cartridge mounting portion according to a seventh modified embodiment during insertion of the ink cartridge into the cartridge mounting portion. FIG.

15B FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the seventh modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion is completed and a detection portion is at a detection position. FIG.

15C FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the seventh modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion is completed and the detection portion has passed the detection position.

16A FIG. 12 shows a cross-sectional view of an ink cartridge and a cartridge mounting portion according to an eighth modified embodiment during insertion of the ink cartridge into the cartridge mounting portion. FIG.

16B 12 shows a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the eighth modified embodiment when mounting of the ink cartridge to the cartridge mounting portion is completed and is a movable member at the upper end of a moving path.

16C FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the eighth modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion is completed and the movable member is at the lower end of the movement path.

17A shows a cross-sectional view of a sub-tank according to a ninth modified embodiment, before an electric current is fed into an electromagnet.

17B FIG. 12 is a cross-sectional view of the subtank according to the ninth modified embodiment after an electric current is supplied to the electromagnet. FIG.

18A FIG. 12 is a cross-sectional view of an ink cartridge and a cartridge mounting portion according to a tenth modified one. FIG Embodiment, before a rack engages with a pinion.

18B FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the tenth modified embodiment after the rack is engaged with the pinion. FIG.

19A FIG. 12 is a cross-sectional view of an ink cartridge and a cartridge mounting portion according to an eleventh alternate embodiment during insertion of the ink cartridge into the cartridge mounting portion. FIG.

19B FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the eleventh modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion is completed. FIG.

20A FIG. 12 shows a cross-sectional view of an ink cartridge and a cartridge mounting portion according to a twelfth modified embodiment during insertion of the ink cartridge into the cartridge mounting portion. FIG.

20B FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the twelfth modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion is completed. FIG.

Embodiments of the present invention and their features and advantages will be described with reference to FIGS 1 to 20B understandable, wherein the same reference numerals are used for the same or corresponding parts in the various drawings.

[Printer 10 ]

With reference to the 1 is a liquid consuming device, such as a printer 10 , an ink jet printer configured to record an image on a sheet of recording paper by selectively ejecting ink drops onto the sheet of the recording paper. The printer 10 has a liquid consumption section such as a recording head 21 , an ink supply device 100 and an ink tube 20 holding the recording head 21 with the ink supply device 100 combines. The ink supply device 100 has a cartridge mounting section 110 , The cartridge mounting section 110 is configured to mount a liquid container or a liquid cartridge such as an ink cartridge 30 to enable it. The cartridge mounting section 110 has an opening 112 , and the interior of the cartridge mounting section 110 lies through the opening 112 to the outside of the cartridge mounting section 110 free. The ink cartridge 30 is configured to be in the cartridge mounting section 110 through the opening 112 in an insertion direction 56 inserted and removed from the cartridge mounting section 110 through the opening 112 in a withdrawal direction 55 to be taken.

The ink cartridge 30 is configured to store ink through the printer 10 is consumed. The ink cartridge 30 and the recording head 21 are through the ink tube 20 in fluid communication when mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed. The recording head 21 has a side tank 28 , The secondary tank 28 is configured to pass through the ink tube 20 from the ink cartridge 30 temporarily store supplied ink. The recording head 21 has nozzles 29 and is configured to that of the sub tank 28 supplied ink through the nozzles 29 optionally eject. In particular, the recording head has 21 a head control plate 21A and piezoelectric actuators 29A according to the nozzles 29 , and the head control plate 21A is configured to selectively apply an electrical drive voltage to the piezoelectric actuators 29A applied. This will cause the ink to get out of the nozzles 29 pushed out.

The printer 10 has a paper transfer tray 15 , a paper feed roller 23 , a feed roller pair 25 , a printing plate 26 , an outlet roller pair 27 and an outlet tray 16 , A feed path 24 is from the paper feed tray 15 to the outlet tray 16 over the feed roller pair 25 , the pressure plate 26 and the outlet roller pair 27 educated. The paper feed roller 23 is configured to hold a sheet of the recording paper from the paper feed tray 15 to the feed path 24 to promote. The feed roller pair 25 is configured to hold the sheet of recording paper from the paper feed tray 15 is promoted on the printing plate 26 advance. The recording head 21 is configured to selectively eject ink onto the sheet of recording paper, via the printing plate 26 occurs. Accordingly, an image is recorded on the sheet of the recording paper. The sheet of recording paper passing over the printing plate 26 is entered through the outlet roller pair 27 to the paper discharge tray 16 omitted at the most downstream side of the feed path 24 is arranged.

[ink supply 100 ]

With reference to the 1 has the printer 10 the ink supply device 100 , The ink supply device 100 is configured to send ink to the recording head 21 supply. The ink supply device 100 has the cartridge mounting section 110 on which the ink cartridge 30 can be mounted. The cartridge mounting section 110 has a mount 101 , an elongated object such as a hollow tube 102 , a detector such as a sensor 103 and a mounting detector such as a mounting sensor 107 , In the 1 is the mounting of the ink cartridge 30 on the cartridge mounting portion 110 completed. With reference to the 2 is the cartridge mounting section 110 configured to have four ink cartridges 30 to record the ink in cyan, magenta, yellow and black respectively. Four hollow tubes 102 , four sensors 103 and four mounting sensors 107 are on the cartridge mounting section 110 according to the four ink cartridges 30 intended.

The mount 101 of the cartridge mounting section 110 has the opening 112 passing through a side of the mount 101 is trained. The mount 101 has an end face opposite the opening 112 , With reference to the 1 and 2 the hollow tube extends 102 from the end face of the enclosure 101 in the removal direction 55 , The hollow tube 102 is at the end face of the mount 101 and at a position corresponding to an ink supply section 60 (described later) of the ink cartridge 30 positioned. The hollow tube 102 is a plastic tube in which a fluid path is formed. The hollow tube 102 has a proximal end and a distal end. The hollow tube 102 has an opening through one side at the distal end of the hollow tube 102 is formed, and the ink tube 20 is with one side at a proximal end of the hollow tube 102 connected. If the hollow tube 102 in the ink feed section 60 the ink cartridge 30 can be inserted, ink that is in the ink cartridge 30 is stored in the ink tube 20 through the hollow tube 102 stream.

The printer 10 has a cover (not shown) configured to open the opening 112 of the cartridge mounting section 110 Optionally cover or the opening 112 Optionally, do not cover, leaving the opening 112 to the outside of the printer 10 is free. The cover 10 is through the mount 101 or through an outer enclosure of the printer 10 supported so that the cover can be selectively opened and closed. When the cover is open, the opening is located 112 to the outside of the printer 10 free. When the cover is opened, a user can use the ink cartridge 30 in the cartridge mounting section 110 through the opening 112 insert and he can use the ink cartridge 30 from the cartridge mounting section 110 through the opening 112 remove. When the cover is closed, the opening is 112 covered, and the ink cartridge 30 can not into the cartridge mounting section 110 inserted or removed from it.

When this description describes that the ink cartridge 30 to the cartridge mounting section 110 is mounted, it means that at least a portion of the ink cartridge 30 in the cartridge mounting section 110 is positioned, and that he is in particular in the enclosure 101 is positioned. Therefore, an ink cartridge 30 Inserting into the cartridge mounting section 110 is also an example of an ink cartridge 30 attached to the cartridge mounting section 110 is mounted. On the other hand, when it is described that the mounting of the ink cartridge 30 on the cartridge mounting portion 110 is complete, it means that the ink cartridge 30 in such a state is that the printer 10 can record a picture. If, for example, the ink cartridge 30 is in such a state, at least one ink supply from the ink cartridge 30 to the recording head 21 possible, and it is preferable that the ink cartridge 30 locked so that the movement of the ink cartridge 30 relative to the cartridge mounting portion 110 is limited or that the ink cartridge 30 in the cartridge mounting section 110 is positioned with the cover closed.

[Sensor 103 ]

With reference to the 2 is the sensor 103 over the hollow tube 102 positioned and extends from the end surface of the enclosure 101 in the removal direction 55 , The sensor 103 has a light emitting portion such as a light emitting diode 104 and a light receiving portion, such as a phototransistor 105 in a width direction 51 are aligned. The light-emitting section 104 and the light-receiving portion 105 lie in the width direction 51 opposite each other. The light-emitting section 104 is configured to transmit light such as visible light, infrared light, and / or UV light to the light-receiving portion 105 to send out, and the light receiving section 105 is configured to pass through the light-emitting section 104 to record emitted light. That through the light-emitting section 104 emitted light can through the in the ink cartridge 30 pass stored ink. When assembling the ink cartridge 30 on the cartridge mounting portion 110 is completed, is the ink cartridge 30 between the light emitting section 104 and the light-receiving portion 105 positioned. In other words, the light-emitting portion 104 and the light-receiving portion 105 provided so that they are with the ink cartridge positioned therebetween 30 face each other when mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed.

A detection position is a position inside the ink cartridge 30 that intersects an imaginary line that extends between the light-emitting section 104 and the light-receiving portion 105 extends when mounting the ink cartridge 30 on the cartridge mounting portion 100 is completed. In other words, the detection position intersects an optical path extending between the light-emitting portion 104 and the light-receiving portion 105 extends. In other words, the sensor 103 positioned so that it is opposite to the detection position. In this embodiment, the sensor 103 positioned so that it's the ink cartridge 30 when mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed. In another embodiment, the sensor is 103 positioned so that it's the ink cartridge 30 opposite when the ink cartridge 30 in the cartridge mounting section 110 is inserted. The sensor 103 namely, it is positioned to be the one on the cartridge mounting portion 110 mounted ink cartridge 30 is opposite, and the detection position intersects the optical path extending between the light-emitting portion 104 and the light-receiving portion 105 extends when the ink cartridge 30 on the cartridge mounting portion 110 is mounted.

The sensor 103 is configured to output different detection signals based on the intensity of the light passing through the light-receiving portion 105 is recorded. The sensor 103 is configured to output a low-level signal, that is, a signal whose level is smaller than a predetermined threshold when the intensity of the light-receiving portion 105 received light is less than a predetermined strength. The sensor 103 is configured to output a high level signal, that is, a signal whose level is greater than or equal to the predetermined threshold when the intensity of the light receiving section 105 received light is greater than or equal to the predetermined strength.

[Assembly sensor 107 ]

With reference to the 1 and 2 is the mounting sensor 107 at a mounting detection position in an insertion path of the ink cartridge 30 in the cartridge mounting section 110 positioned. The ink cartridge 30 moves in the insertion path when the ink cartridge 30 in the cartridge mounting section 110 is inserted. In this embodiment, the mounting sensor 107 at the end face of the enclosure 101 positioned. The mounting sensor 107 is configured to provide various detection signals based on the presence or absence of the ink cartridge 30 at the assembly detection position. In this embodiment, the mounting sensor 107 positioned so that the ink cartridge 30 is positioned at the mounting detection position when mounting the ink cartridge 30 on the cartridge mounting portion 100 is completed. In this embodiment, the mounting sensor 107 a mechanical sensor configured to emit a signal indicating that the ink cartridge is 30 on the cartridge mounting portion 100 is mounted when the mechanical sensor through a front wall 40 (described later) of the ink cartridge 30 is pressed. Nonetheless, the mounting sensor is 107 not limited to the mechanical sensor, but may be an optical sensor such as a combination of a light emitting diode and a phototransistor, a magnetic sensor such as a Hall effect sensor, an electrical sensor or any other known sensor.

[Ink cartridge 30 ]

With reference to the 3A and 3B has the ink cartridge 30 a frame 31 in which a liquid chamber such as an ink chamber 36 is formed, a Flüssigkeitszuführabschnitt such as an ink feed section 30 that is different from the frame 31 extends. The ink cartridge 30 is configured to be in the ink chamber 36 stored ink to the outside of the ink cartridge 30 over the ink feed section 60 supply. The ink cartridge 30 is configured to be in the cartridge mounting section 110 in an insertion / removal direction 50 inserted and removed therefrom while the ink cartridge 30 is in an upright position, as in the 3A is shown, wherein an upper side of the ink cartridge 30 directed upward and a lower side of the ink cartridge 30 directed downwards. In this embodiment, the insertion / removal direction extends 50 in a horizontal direction. The insertion direction 56 is an example of the insertion / removal direction 50 , The removal direction 55 is an example of the insertion / removal direction 50 , The insertion direction 56 and the removal direction 55 are opposite directions. In another embodiment, the insertion / removal direction needs to be 50 does not extend exactly in a horizontal direction, but may extend in a direction intersecting a horizontal direction and the vertical direction.

The frame 31 has a substantially rectangular parallelepiped shape, and its dimension in a width direction (left / right direction) 51 is each smaller than its dimension in a height direction (top / bottom direction) 52 and its dimension in a depth direction (forward / backward direction) 53 , The width direction 51 , the height direction 52 and the depth direction 53 are perpendicular to each other. The width direction 51 extends in a horizontal direction. The depth direction 53 extends in a horizontal direction. The height direction 52 extends in the vertical direction. The insertion / removal direction 50 is parallel to the depth direction 53 , The frame 31 has a front wall 40 , a back wall 41 , an upper wall 39 , a lower wall 42 and a right wall 38 , The front wall 40 and the back wall 41 overlap at least partially when viewed in the depth direction 53 , The upper wall 39 and the bottom wall 42 overlap at least partially when viewed in the height direction 52 , The right wall 38 is on one side of the frame 31 in the width direction 51 positioned. In this embodiment, the right wall is 38 on the right side of the frame 31 positioned when the frame 31 from the side of the front wall 40 is looked at. If the ink cartridge 30 in the cartridge mounting section 110 is inserted is the front wall 40 on the front side of the ink cartridge 30 positioned, and the rear wall 41 is at the back of the ink cartridge 30 positioned. If the ink cartridge 30 in the cartridge mounting section 110 is inserted is the front wall 40 in the insertion direction 56 oriented, and the back wall 41 is in the removal direction 55 oriented. The back wall 41 is from the front wall 40 in the removal direction 55 positioned at a distance. The frame 31 has a front outside, a back outside, an upper outside, a lower outside and a right outside. The front wall 40 has the front outside, the back wall 41 has the back outside, the top wall 39 has the top outside, the bottom wall 42 has the lower outside and the right wall 38 has the right outside.

The upper wall 39 is with the top of the front wall 40 , the upper end of the back wall 41 and the top of the right wall 38 connected. The bottom wall 42 is with the lower end of the front wall 40 , the lower end of the rear wall 41 and the bottom of the right wall 38 connected. The right wall 38 is with the right end of the front wall 40 , the right end of the back wall 41 , the right end of the upper wall 39 and the right end of the lower wall 42 connected. The other side of the frame 31 in the width direction 51 is open. In this embodiment, the left side of the frame 31 open, on the left side of the frame 32 is positioned when the frame 31 from the side of the front wall 40 is looked at. The frame 31 has a partition 43 extending from the inner surface of the right wall 38 in the width direction 51 to the left side of the frame 31 extends. The partition 43 extends in the height direction 52 , The partition 43 is from the front wall 40 positioned at a distance. The partition 43 extends substantially parallel to the front wall 40 , Every wall of the frame 31 allows light to pass therethrough, that of the light-emitting portion 104 of the sensor 103 is sent out.

The ink cartridge 30 has a left wall 37 with the left side of the frame 31 in the width direction 51 connected is. In this embodiment, the left wall is 37 a film 44 , The film 44 and the frame 31 have about the same outer contour when viewed in the width direction 51 , The film 44 is at the left end of the front wall 40 , the left end of the back wall 41 , the left end of the upper wall 39 , the left end of the lower wall 42 and the left end of the partition 43 welded by means of heat. This makes it possible for the ink in the ink chamber 36 to save that by the front wall 40 , the back wall 41 , the upper wall 39 , the bottom wall 42 , the right wall 38 and the left wall 37 (the movie 44 ) is defined. The left wall 37 (the film 44 ) allows the light to pass therethrough, that of the light-emitting portion 104 of the sensor 103 is sent out. The ink cartridge 30 may have a cover that the film 44 covering from the outside. In such a case, the cover also allows the light to pass therethrough, that of the light-emitting portion 104 of the sensor 103 is sent out.

With reference to the 1 . 3A and 3B the ink feed section extends 60 from the front outside of the front wall 40 in the insertion direction 56 , In this embodiment, the ink supply section has 60 a cylindrical shape. The ink feed section 60 has a proximal end on the front wall 40 and a distal end opposite the proximal end. The ink feed section 60 has a liquid supply port such as an ink supply port 61 formed at the distal end. The ink feed section 60 has an interior, and the interior can match the outside of the ink cartridge 30 through the ink supply port 61 be in fluid communication. The interior of the ink feed section 60 is with the interior of the frame 31 ie with the ink chamber 36 , on the side of the proximal end in fluid communication. The ink chamber 36 can with the outside of the ink cartridge 30 through the ink feed section 60 be in fluid communication. Before the ink cartridge 30 to the cartridge mounting section 110 is mounted, the ink supply port 61 by an operating section 82 (described later) closed. When it is described in this specification that the ink supply port 61 on the front wall 40 is provided, this means at least that the Tintenzuführöffnung 61 the front wall 40 penetrates, or that the ink feed opening 61 at the distal end of the ink supply section 60 is provided, extending from the front wall 40 in the insertion direction 56 extends, or that the ink feed opening 61 is provided at a distal end of a projection extending from the front wall 40 in the removal direction 55 extends.

The ink cartridge 30 also has a movable element 70 , a limiting element 80 and a biasing member such as a coil spring 49 in the frame 31 ie in the ink chamber 36 , The ink cartridge 30 Also has an air introduction portion (not shown) for introducing air into the ink chamber 36 ,

[Movable element 70 ]

The movable element 70 has a detection section and a float. In this specification, when it is described that a movable member has a detecting portion and a float, it means at least that the movable member has the detecting portion and the float as portions of the movable member, or that the movable member includes the detecting portion and the float as a whole having movable element. In this embodiment, the movable element 70 , the detecting section and the float one and the same element. The movable element (float, detection section) 70 has a specific gravity smaller than the specific gravity of the ink chamber 36 stored ink. When the movable element (float, detection section) 70 from a limiting section 81 (described later), the movable member (float, detection portion) moves 70 due to the buoyancy of the movable element (float, detection section) 70 acts in a free area within the ink chamber 36 up. In particular, the movable element (float, detection section) 70 configured to move into a room through the right wall 38 , the front wall 40 , the partition 43 and the movie 44 is defined. The partition 42 is an example of a guide wall configured to control the movement of the movable member (float, detection section) 70 respectively. The room is an example of a movement path and an example of the free area. The detection position described above is in the movement path and in the free area. The movable element (float, detection section) 70 has a recessed section 71 on its wall surface, in the removal direction 55 is directed.

The movable element (float, detection section) 70 has a light-blocking section. In this embodiment, the movable member (float, detection portion) has 70 the whole light-blocking section. That is, the movable element 70 The detecting portion, the float and the light-blocking portion are one and the same element. The movable element (float, detection section, light-blocking section) 70 is configured to block the light coming from the light emitting section 104 of the sensor 103 is sent out. When the movable member (float, detection portion, light-blocking portion) 70 at the detection position and the light coming from the light-emitting portion 104 of the sensor 103 is emitted, one side of the movable member (float, detection portion, light-blocking portion) 70 in one direction (the width direction) 51 perpendicular to the insertion / removal direction 50 In particular, a quantity (strength) of the light coming from the other side of the movable member (float, detection portion, light-blocking portion) is reached. 70 comes and the light-receiving section 105 of the sensor 103 reaches less than a predetermined amount (strength), such as zero. The blocking of the light is completely effected by the movable element (float, detection section, light-blocking section) 70 , which prevents the light from being there in the width direction 51 perpendicular to the insertion / removal direction 50 passes through the movable member (float, detection portion, light-blocking portion) 70 that absorbs a part of the amount of light by the movable member (float, detection portion, light-blocking portion) 70 that deflects the light by the movable element (float, detection section, light-blocking section) 70 that totally reflects light, or another phenomenon. For example, the movable member (float, detection portion, light-blocking portion) 70 out of an opaque Plastic containing a pigment, or it is made of a transparent or semi-transparent plastic, but has a prism-like shape that is configured to deflect light, or it has a reflection film such as an aluminum film on its surface. On the other hand, when the movable member (float, detection portion, light-blocking portion) 70 is not at the detection position and the light coming from the light emitting section 104 of the sensor 103 is sent out, one side of the ink cartridge 30 in the width direction 51 perpendicular to the insertion / removal direction 50 reached, is a lot (strength) of the light coming from the other side of the ink cartridge 30 comes and the light-receiving section 105 of the sensor 103 reached, greater than or equal to the predetermined amount (strength). As a result, the amount (strength) of the light that hangs the light-receiving section 105 of the sensor 103 achieved, depending on whether the movable element (float, detection section, light blocking section) 70 is at the detection position or not.

[Limiting element 80 ]

With reference to the 3A . 3B and 5A to 5C has the delimiter 80 a limiting section 81 , an operating section 82 and a connection section 83 that with the delimiting section 81 and the operation section 82 connected is.

The operating section 82 extends from a front end of the connecting portion 83 down, which is in the depth direction 53 extends. The operating section 82 has a front surface that is in the insertion direction 56 is directed, and the front surface of the actuating portion 82 lies the ink supply port 61 of the ink feed section 60 in the depth direction 53 across from. The operating section 82 is between a first position in the 5A is shown, and a second position movable in the 5B is shown. The second position is closer to the rear outside of the rear wall 41 as the first position. When the operation section 82 is at the first position, the operating portion 82 in contact with a wall that houses the ink supply port 61 surrounds, and thereby the ink supply port 61 closed. When the operation section 82 at the second position, the operating portion is 82 Positioned spaced from the wall, the ink feed opening 61 surrounds, and thereby is the ink supply port 61 open. The operating section 82 is from the outside of the ink cartridge 30 actuated. In this embodiment, the operating portion 82 through the hollow tube 102 over the ink supply port 61 actuated. If the hollow tube 102 in the ink feed section 60 through the ink supply port 61 is inserted pushes the hollow tube 102 the operating section 82 from the first position to the second position in the withdrawal direction 55 ,

The boundary element 81 extends from a rear end of the connecting portion 83 up. The boundary section 81 has a front surface that is in the insertion direction 56 is directed, and a projection 84 extending from the front surface in the insertion direction 56 extends. When the operation section 82 is in the first position, is the lead 84 with the recessed section 71 the movable element (float, detection section, light-blocking section) 70 engaged such that the movement of the movable member (float, detection portion, light-blocking portion) 70 is limited within a limited range. In this embodiment, the projection has 84 a wedge shape, and the recessed portion 71 has a corresponding shape. Nonetheless, the forms of projection are 84 and the recessed section 71 not limited to the wedge shape. The movable element (float, detection section, light-blocking section) 70 can through the limiting section 81 be completely immobilized. In such a case, the limited range is zero. The movable element (float, detection section, light-blocking section) 70 Within the limited range, something can move to that extent due to the dimensional errors of the projection 84 and the recessed section 71 is allowed. The movable element (float, detection section, light-blocking section) 70 can move within the limited range as long as the movable element (float, detection section, light-blocking section) 70 the acquisition position is not reached. When the movable member (float, detection portion, light-blocking portion) 70 in the limited area, the movable element (float, detection section, light-blocking section) is 70 immersed in the ink.

If the actuating section 82 at the second position is the projection 84 from the recessed section 71 positioned at a distance, and thereby releases the limiting section 81 the movable element (float, detection section, light-blocking section) 70 such that the movable member (float, detection portion, light-blocking portion) 70 is positioned in the free area that is above the limited area. In another embodiment, the limiting section 81 not completely spaced from the movable element (float, detection section, light-blocking section) 70 be positioned when the operating section 82 at the second position, but can continue with the movable member (float, detection portion, light-blocking portion) 70 be in contact as long as the movable member (float, detection portion, light-blocking portion) 70 is resolved and can move in the free area.

The coil spring 49 has a first end with one in the insertion direction 56 directed surface of the frame 31 in the ink chamber 36 in contact, and a second end connected to a rear surface of the operating portion 82 is in contact, in the removal direction 55 is directed. The coil spring 49 is configured to the operating portion 82 in the insertion direction 56 to bias in the first position. The coil spring 49 is an example of a biasing member, and it may be replaced by a leaf spring, a plastic spring, etc.

[Controller 130 ]

With reference to the 4 has the printer 10 a control device 130 , The control device 130 has a CPU 131 , a ROM 132 , a ram 133 , an EEPROM 134 as well as an ASIC 135 that have an internal bus 137 connected to each other. The ROM 132 saves programs for the CPU 131 to different printers of the printer 10 to control. The RAM 133 is used as a storage area for temporarily storing data and signals for the CPU 131 used to run them while running the programs and as a workspace for data processing. The EEPROM 134 stores settings and flags that are held even after the power is turned off. A chip can be the CPU 131 , the ROM 132 , the RAM 133 , the EEPROM 134 and the ASIC 135 or a chip can be a part of the CPU 131 , the ROM 132 , the ram 133 , the EEPROM 134 and the ASIC 135 and another chip may be the other parts of the CPU 131 , the ROM 132 , the ram 133 , the EEPROM 134 and the ASIC 135 exhibit.

The control device 130 is configured to the paper feed roller 23 , the feed roller pair 25 and the outlet roller pair 27 by driving a motor (not shown). The control device 130 is configured to the recording head 21 for ejecting ink from the nozzles 29 to control. In particular, the control device 130 configured to provide control signals indicative of the values of the electrical drive voltages applied to the piezoelectric actuators 29A to be applied to the head control plate 21A to send. The head control plate 21A is configured to apply the electrical drive voltages to the piezoelectric actuators 29A based on the control signals applied by the control device 130 be absorbed, so that the ink from the nozzles 29 is ejected. The printer 10 also has a display device 109 , and the control device 130 is configured to the display device 109 to display information about the printer 10 and the ink cartridge 30 or control diverse messages.

The printer 10 also has a temperature sensor 106 and a cover sensor 108 , and the control device 130 is configured to that of the sensor 103 output detected signals from the temperature sensor 106 emitted signals from the mounting sensor 107 output detection signals and those of the cover sensor 108 recorded signals. The temperature sensor 106 is configured to emit signals based on the temperature. Where the temperature sensor 106 detecting a temperature is not limited to a specific position. The temperature sensor 103 can in the cartridge mounting section 110 be positioned, or it may be on an outer surface of the printer 10 be positioned. The cover sensor 108 is configured to emit various signals based on whether the cover for the opening 112 of the cartridge mounting section 110 is open or closed.

The ink cartridge 30 gets into the cartridge mounting section 110 inserted when the cover of the cartridge mounting section 110 is open. With reference to the 5A is the operating section 82 at the first position when the ink cartridge 30 in the cartridge mounting section 110 is inserted. Therefore, the movement of the movable member (float, detection portion, light-blocking portion) becomes 70 through the limiting section 81 limited, and the ink supply port 61 of the ink feed section 60 is through the operating section 82 closed. The sensor 103 gives the high level signal to the controller 130 from.

If the ink cartridge 30 further into the cartridge mounting section 110 is inserted with reference to the 5B the hollow tube 102 in the ink feed section 60 through the ink supply port 61 inserted and pushes the operating section 82 in the removal direction 55 against the biasing force of the coil spring 49 such that the actuating portion 82 moved from the first position to the second position. As a result, the movable member (float, detection portion, light-blocking portion) becomes 70 solved, and the ink supply port 61 will be opened. When assembling the ink cartridge 30 on the cartridge mounting portion 110 is completed, pushes the front wall 40 of the ink cartridge 30 the mounting sensor 107 , When this occurs, the mounting sensor gives 107 a detection signal indicating the presence of the ink cartridge 30 indicates at the assembly detection position. The ink cartridge 30 can by a locking mechanism (not shown) in the cartridge mounting portion 110 be locked so they are in the removal direction 55 not moved when mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed.

The movable element (float, detection section, light-blocking section) 70 that of the boundary section 81 is dissolved moves in the movement path or in the free area between the front wall 40 and the partition 43 up. When the upper end of the movable member (float, detection portion, light blocking portion) 70 reaches the detection position, as in the 5B is shown changes from the sensor 103 output detection signal from the high level signal to the low level signal. With reference to the 5C moves the movable element (float, detection section, light-blocking section) 70 consequently, further up. When the lower end of the movable member (float, detection portion, light-blocking portion) 70 As the detection position passes, that changes from the sensor 103 output detection signal from the low level signal to the high level signal. With reference to the 6A stops the movable element (float, detection section, light blocking section) 70 the movement when the movable member (float, detection portion, light-blocking portion) 70 In contact with a surface which is the ink chamber 36 defines, for example, the inner surface of the upper wall 39 , Alternatively, the movable member stops (float, detection portion, light-blocking portion) 70 the movement when a portion of the movable member (float, detection portion, light-blocking portion) 70 breaks the ink level and is exposed by the ink level.

When a user thinks that mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed, the user closes the cover of the cartridge mounting portion 110 to the opening 112 cover. Even if mounting the ink cartridge 30 on the cartridge mounting portion 110 is not completed, the closed cover comes with the ink cartridge 30 in contact and pushes them in the insertion direction 56 to mounting the ink cartridge 30 on the cartridge mounting portion 110 complete.

[Processes by the control device 130 be performed]

The control device 130 is configured to process the 7 perform when the control device 130 the signal from the coverage sensor 108 indicating that the cover of the cartridge mounting portion 110 is open and when it receives the high signal from the sensor 103 receives. In other words, the processes of 7 started when the cover of the cartridge mounting section 110 is open to the ink cartridge 30 to eliminate in an empty state.

The control device 130 resets a determination completion flag, that is, it sets the determination completion flag to "OFF" at step S1. The determination completion flag indicates whether a determination of a transitional time (described later at a step S9) has been performed. The determination completion flag is set to "ON" when the determination of the transitional time has been made, and it is set to "OFF" when the determination of the transitional time has not been made. The determination flag becomes for each ink cartridge 30 set. The control device 130 stores the determination completion flag in the EEPROM 134 ,

Subsequently, the control device starts 130 a measurement of the transition time at a step S3, if that from the sensor 103 output detected signal from the high level signal to the low level signal changes (step S2: Yes). If that from the sensor 103 When the detected detection signal has not changed from the high level signal to the low level signal (step S2: No), the control device performs 130 the process of step S13 (described later). For example, the situation in which this is the same as the sensor 103 does not change from the high level signal to the low level signal (step S2: No), a situation in which a new ink cartridge 30 not on the cartridge mounting portion 110 was mounted.

Subsequently, the control device determines 130 at a step S4, whether the elapsed time after the start of the measurement of the transitional time by the control device 130 has exceeded a predetermined maximum time. If the elapsed time has exceeded the maximum time (step S4: Yes), the controller performs 130 the process in step S6 (described later). If the elapsed time has not exceeded the maximum time (step S4: No), the controller determines 130 at step S5, whether that is from the sensor 103 output detection signal from the low level signal to the high level signal has changed. If that from the sensor 103 When the detected detection signal has not changed from the low level signal to the high level signal (step S5: No), the controller performs 103 Review the process in step S4. If that from the sensor 103 When the detected detection signal has changed from the low level signal to the high level signal (step S5: Yes), the controller determines 103 the transitional period. The transitional period is a period of time after a change in that of the sensor 103 outputted detection signal from the high level signal to the low level signal (step S2: Yes) until a change of the from the sensor 103 outputted detection signal from the low level signal to the high level signal (step S5: Yes).

In other words, the control device measures 130 the transition time after the output of the low level signal as an example of a first detection signal to the output of the high level signal as an example of a second detection signal. In other words, the control device measures 130 the length of time during which the sensor 103 the low level signal is output. In other words, the control device measures 130 the time required for the movable element (float, detection section, light-blocking section) 70 is required, from the in the 5B shown position to that in the 5C to move shown position. If the elapsed time has exceeded the maximum time (step S4: Yes), the controller considers 130 the maximum time as the transitional period.

The situation in which the elapsed time has exceeded the maximum time (step S4: Yes) corresponds to a situation in which the movable element (float, detection section, light-blocking section) 70 very slowly from the one in the 5B shown position to that in the 5C moved position or the movement stops. One reason for the slow movement of the movable element (float, detection section, light-blocking section) 70 that may be that viscosity in the ink chamber 36 stored ink, or it may be that the movable element (float, detection section, light-blocking section) 70 in the ink chamber 36 stuck.

Subsequently, sets the control device 130 returns an error flag, ie it sets the error flag to "OFF" in a step S7. The error flag is set to "ON" when the transition time is not within a threshold range (step S9: No). The error flag becomes for each ink cartridge 30 set. The control device 130 stores the error flag in the EEPROM 134 ,

Subsequently, the control device determines 130 at a step S8, the threshold range based on that from the temperature sensor 106 emitted signal. The threshold range is used with the transition time to estimate the viscosity of the ink chamber 36 compared to stored ink. If that from the temperature sensor 106 output signal indicates that the temperature is relatively high, puts the control device 130 at least either the upper limit or the lower limit of the threshold range lower fixed. In other words, the control device sets 130 at least either the upper limit or the lower limit of the threshold range higher, if that of the temperature sensor 106 emitted signal indicates that the temperature is relatively low.

Subsequently, the controller compares 130 at step S9, the transition time determined at step S6 coincides with the threshold value range determined at step S8, and determines whether or not the transitional time is within the threshold range. If the transition time is below the lower limit, it is estimated that the viscosity of the ink is too low. If the transition time is over the upper limit, it is estimated that the viscosity of the ink is too high. If the transitional time is out of the threshold range (step S9: No), the controller sets 130 at a step S10, the error flag is "ON". If the transitional time is within the threshold range (step S9: Yes), the controller skips 130 the processing of step S10.

Subsequently, sets the control device 130 at a step S11, the determination completion flag is "ON", and it resets a near-empty flag at a step S12, that is, sets the near-empty flag to "OFF". The near empty flag is set to "ON" when it is determined that the ink cartridge 30 is in a nearly empty state (step S25: Yes). The near-empty flag is used for every ink cartridge 30 set. The control device 130 stores the near-empty flag in the EEPROM 134 ,

Subsequently, the control device determines 130 at a step S13, whether the cover sensor 108 or not, the signal indicating that the cover of the cartridge mounting portion 110 closed is. If it is determined that the cover is opened (step S13: No), the control device repeats 130 the process of step S2 and the processes following step S2. If it is determined that the cover is closed (step S13: Yes), the controller determines 130 at step S14, whether or not a predetermined period of time has elapsed after being determined has been that the cover is closed in step S13.

If the predetermined time period has elapsed (step S14: Yes), the control device closes 130 the processes of 7 from. If the predetermined time period has not elapsed (step S14: No), the control device repeats 130 the process of step S2 and the processes following step S2. If the control device 130 determines that the cover of the cartridge mounting portion 110 is open (step S13: No) when the control device 130 repeats the process of step S2 and the processes following step S2 clears the control device 130 the time count that was started when it was determined that the cover was closed (step S13: Yes).

When assembling the ink cartridge 30 on the cartridge mounting portion 110 is completed and the cover is closed, the recording head 21 perform the image recording. When the recording head 21 As ink ejects and images are recorded, the amount of ink in the ink chamber decreases 36 , When the amount of ink in the ink chamber 36 decreases, the ink level in the ink chamber lowers 36 from. When a portion of the movable member (float, detection portion, light-blocking portion) 70 is free from the ink level and the ink level lowers, the movable member (float, detection portion, light blocking portion) moves 70 in the motion path or the free area of the in the 6A shown position down. When the lower end of the movable member (float, detection portion, light-blocking portion) 70 the in the 6B When the detected detection position is reached, it changes from the sensor 103 output detection signal from the high level signal to the low level signal. When the upper end of the movable member (float, detection portion, light-blocking portion) 70 the in the 6C If the detection position shown happens, that changes from the sensor 103 output detection signal from the low level signal to the high level signal.

After completing the processes of 7 leads the control device 130 the processes of 8th repeated in a predetermined time interval when the control device 130 from the cover sensor 108 receives the signal indicating that the cover of the cartridge mounting portion 110 closed is.

The control device 130 determines in step S21 whether the mounting sensor 107 emits the signal indicating that the ink cartridge 30 is at the mounting position. If the mounting sensor 107 does not emit the signal indicating that the ink cartridge 30 at the mounting position (step S21: No) notifies the control device 130 a user at step S30 that the ink cartridge 30 is not mounted, and she completes the processes of 8th from. How to notify a user is not limited to a specific way, but the control device 130 can the display device 109 to display a message, or it may be a speaker (not shown) of the printer 10 to sound an audio message.

If the mounting sensor 107 emits the signal indicating that the ink cartridge 30 at the mounting position (step S21: Yes), the controller determines 130 at step S22, if the determination completion flag is set to "ON". If the determination completion flag is set to "OFF" (step S22: No), the controller performs 130 the process of step S31. If the determination completion flag is set to "ON" (step S22: Yes), the controller performs 130 the process of step S23.

The control device 130 asks a user at a step S31 whether he or she is using the ink cartridge 30 has exchanged. How to ask a user is not limited to a specific way, but the control device 130 can the display device 109 to cause a message to be displayed, or it may cause a speaker (not shown) to sound an audio message. The control device 130 then waits for a signal from an input interface (not shown) of the printer 10 should come. For example, the input interface is an interface in which a user commands to the printer 10 can be given by pressing their keys. If the control device 130 from the input interface receives a signal indicating that the ink cartridge 30 has been exchanged (step S31: Yes), the controller performs 130 the process of step S32 through.

If the control device 130 from the input interface receives a signal indicating that the ink cartridge 30 was not replaced (S31: No), puts the control device 130 at a step S33, the determination completion flag is "ON", and then it performs the process of the step S23. The control device 130 determines at step S23 whether the error flag is set to "ON". If the error flag is set to "ON" (step S23: Yes), the controller performs 130 the process of the step 32 by.

The control device 130 informs a user about the ink cartridge 30 at step S32, and then it completes the process of 8th from. If the control device 130 from the input interface receives the signal indicating that the ink cartridge 30 has been exchanged (step S31: Yes), the control device 130 at step S32 notify the user that the replacement of the ink cartridge 30 was not recognized. If the control device 130 determines that the error flag is set to "ON" (step S23: Yes), the control device may 130 tell a user that the ink is in the ink chamber 36 is deteriorated, or that the replacement of the ink cartridge 30 is required. How to notify a user is not limited to a specific way, but the control device 130 can the display device 109 to display a message, or it may be a speaker (not shown) of the printer 10 to sound an audio message.

If the error flag is set to "OFF" (step S23: No), the controller performs 130 the process of step S24 through. The control device 130 determines at step S24 whether the near-empty flag is set to "ON". If the near-empty flag is set to "OFF" (step S24: No), the controller determines 130 at a step S25, if the sensor 103 the low level signal is output.

If the sensor 103 outputs the high level signal (step S25: No), the controller performs 130 the process of step S28. If the sensor 103 outputs the low-level signal (step S25: Yes) sets the controller 130 at a. Step S26 sets the near empty flag to "ON", and then notifies a user at a step S27 that the ink cartridge 30 in the nearly empty state, that is, the amount of ink in the ink chamber 36 is low, ie it is less than a threshold. The situation in which the sensor 103 outputs the low-level signal at step S25 may be a situation where the movable element (float, detection section, light-blocking section) 70 at the in the 6B is shown detection position. How to notify a user is not limited to a specific way, but the control device 130 can the display device 109 to display a message, or it may be a speaker (not shown) of the printer 10 to sound an audio message. Subsequently, the control device controls 130 the process of step S28.

The control device 130 determines at step S28 whether to record an image recording command. If the control device 130 does not receive the image recording command (step S28: No), closes the control device 130 the processes of 8th from. If the control device 130 takes the image recording command (step S28: Yes), controls the control device 130 the recording head 21 , the paper feed roller 23 , the feed roller pair 25 , the outlet roller pair 27 , etc., directly or indirectly, to record an image on a sheet of the recording paper in step S29, and then it completes the processes of 8th from. The control device 130 For example, an image may be recorded on a sheet of the recording paper when the process of step S29 is performed once, or the control device 130 can record images according to all the image data that the controller 130 when the process of step S29 is performed once.

If the near-empty flag is set to "ON" (step S24: Yes), the controller determines 130 at a step S34, if the sensor 130 the high level signal is output. If the sensor 103 outputs the low-level signal (step S34: No), the controller performs 130 the process of step S27. If the sensor 103 outputs the high level signal (step S34: Yes) notifies the controller 130 a user at a step S35 that the ink cartridge 30 is in the empty state, that is, the amount of ink in the ink chamber 36 is zero or near zero, and then it completes the processing of 8th from. The situation in which the sensor 103 outputs the high level signal at step S34 may be a situation in which the movable element (float, detection portion, light blocking portion) 70 at the in the 6C shown position. How to notify a user is not limited to a specific way, but the control device 130 can the display device 109 to display a message, or it may be a speaker (not shown) of the printer 10 to sound an audio message.

If the error flag is set to "ON" (step S23: Yes), the controller performs 130 the processing of the step S29, that is, the image recording process, not by. In other words, the control device skips 130 the step S29, thereby limiting the ink consumption by the recording head 21 ,

[Advantages]

If according to the embodiment described above, the operating portion 82 is moved from the first position to the second position, the movable member (float, detection portion, light-blocking portion) moves 70 inside the ink. The movable element (float, detection section, light-blocking section) 70 moves up against viscosity resistances and inertial resistances caused by the ink, which differs from that when it floats on the ink level or moves down when the ink level lowers. As a result, the speed of the upward movement of the movable member (float, detection portion, light-blocking portion) depends. 70 of the viscosity of the ink in the ink chamber 36 from. By measuring the transition time for the movable element (float, detection section, light-blocking section) 70 is required to pass the detection position, the viscosity of the ink in the ink chamber 36 For example, it can be estimated whether the viscosity of the ink is within a certain range or not. Namely, since the distance from the position of the movable member (float, detection portion, light-blocking portion) 70 in the 5B is shown to the position of the movable member (float, detection portion, light-blocking portion) 70 in the 5C is shown, is a predetermined constant distance between two points, the speed of the movable member (float, detection portion, light blocking portion) 70 by specifying the time required for the movable member (float, detection portion, light-blocking portion) 70 it is necessary to move between the two points. The transition time is an example of a physical quantity, due to which the speed of the movable element (float, detection section, light-blocking section) 70 can be specified.

Nonetheless, the example of the physical quantity is not limited to the transition time. Another example of the physical quantity may be a distance of the movable member (float, detection portion, light blocking portion) 70 over which it moves during a predetermined period of time.

According to the embodiment described above, the viscosity of the ink can be estimated at a time when mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed. Therefore, the deterioration degree of the ink can be estimated by calculating the transitional time even when the ink cartridge 30 not to the printer 10 was mounted and was not used in a long time. In addition, if a variety of ink cartridges 30 storing inks of different viscosities for mounting on the same cartridge mounting section 110 is configured, it is possible to determine which ink cartridge 30 is mounted by calculating the transitional time.

According to the embodiment described above, the control device limits 130 the function of the recording head 29 ie it skips step S29 if the transition time is outside the threshold range (step S9: No). Therefore, a difficulty in the recording head 21 be prevented, which could be caused by an unusual viscosity of the ink. Nevertheless, it is not always necessary to skip step S29. If the error flag is set to "ON" in another embodiment (step S23: Yes), the process of step S32 may be performed to provide the user with the information about the ink cartridge 30 notifies, but the control device 130 can let the user decide whether to record the image. In such a case, by the control device 130 performed processes of those of 7 and 8th but their description is omitted here.

In addition, in another embodiment, if the error flag is set to "ON" (step S23: Yes), steps S24 to S29 need not be skipped, but the controller 130 can the head control plate 21A so control that on the piezoelectric actuators 29A applied electric drive voltages are set in step S29. More specifically, the control device outputs 130 different control signals to the head control plate 21A such that the on the piezoelectric actuators 29A applied electric drive voltages are set for the amounts of ink, the so from the nozzles 29 that they are the same amounts when the transition time is within the threshold range and when the transition time is outside the threshold range. Namely, when the transition time is below the lower limit of the threshold range (it is estimated that the viscosity of the ink is too low), the driving electric voltages are made smaller than those of the driving electric voltages when the transition time is within the threshold range. If the transition time is above the upper limit of the threshold range (it is estimated that the viscosity of the ink is too high), the driving electric voltages are made larger than those of the driving electric voltages when the transition time is within the threshold range. If in this case many ink cartridges 30 storing inks of different viscosities are configured to be on the same cartridge mounting portion 110 to assemble, it is possible the piezoelectric actuators 29A to drive with appropriate voltages according to the types of ink. The actuators do not have to be on the piezoelectric actuators 29A they may be thermal actuators, the ink from the nozzles 29 by applying heat to the ink and thereby creating bubbles in the ink.

In addition to controlling the head control plate 21A such that on the piezoelectric actuators 29A applied electrical drive voltages can be adjusted, the control device 130 control a rinse operation in which the ink forcibly from the nozzles 29 of the recording head 21 is omitted. For example, if the control device 130 determines that the error flag is set to "ON" (step S23: Yes), the control device may 130 control the purging operation so that the ink is discharged, whereby a pressure is applied to it, which is greater than when the control device 130 determines that the error flag is set to "OFF" (step S23: No). When the ink is out of the nozzles 29 of the recording head 21 is discharged by a suction pump, the control device 130 More specifically, to control the suction pump so that the suction pump sucks the ink, and the suction pressure is larger when the error flag is set to "ON". By this control, air bubbles or compressed ink in the recording head 21 can be reliably discharged by the suction operation even when the viscosity of the ink is high, and the ink can reliably discharge from the ink tube 20 to the recording head 21 be supplied.

In the embodiment described above, both the upper limit and the lower limit of the threshold range are specified. Nevertheless, in another embodiment at least either the upper limit or the lower limit of the threshold range is specified.

According to the embodiment described above, the movable member (float, detection portion, light-blocking portion) moves 70 to the ink level by the upward lift acting thereon, and it moves down when the ink is in the ink chamber 36 is consumed and the ink level lowers. When the movable member (float, detection portion, light-blocking portion) 70 moved down and reached the detection position again, the nearly empty state and the empty state can be determined. Nevertheless, the process of determining the near-empty state and the empty state (steps S12, S24 through S27, S34, and S35) is not always required, and it may be dependent on the processes of 7 and 8th be eliminated.

The viscosity of the ink changes as the ambient temperature changes. When the temperature is high, the viscosity is low. When the temperature is low, the viscosity is high. The control device 130 can the head control plate 21A so control that on the piezoelectric actuators 29A applied electrical drive voltages can be adjusted on the basis of temperature. More specifically, the control device outputs 130 Control signals to the head control plate 21A such that low electrical drive voltages on the piezoelectric actuators 29A be applied when the temperature is high. When the temperature is low, the controller gives 130 Control signals to the head control plate 21A such that high electrical drive voltages on the piezoelectric actuators 29A be applied. There is an optimum threshold range of the viscosity of the ink corresponding to those on the piezoelectric actuators 29A applied electrical drive voltages, which are determined by the temperature. In other words, it is preferable to set the threshold range of the viscosity of the ink based on the temperature. Therefore, the control device determines 130 According to the embodiment described above, the threshold value range based on the temperature at the step S8. How to determine the threshold range is not limited to a specific way, but the control device 130 may select a single appropriate threshold range based on the temperature of many threshold ranges included in the ROM 132 or may calculate the upper limit and / or the lower limit of the threshold range as a function of the temperature value. Nevertheless, the step S8 for determining the threshold range based on the temperature may be eliminated, and a fixed threshold range may be used at the step S9 when, for example, the piezoelectric actuators 29A applied electrical drive voltages can not be adjusted on the basis of temperature.

According to the embodiment described above, the sensor 103 an optical sensor, but the sensor 103 is not limited to an optical sensor. The sensor 103 may be a magnetic sensor, such as a Hall effect sensor, configured to emit different signals based on a magnetic flux density detected by the sensing section 70 is generated, which may have a magnet. In addition, the sensor can 103 be any other known sensor.

According to the embodiment described above, the control device stores 130 the determination completion flag, the error flag, and the near-empty flag in the EEPROM 134 but the control device 130 may store one or all of the flags in a memory of an IC chip (not shown) attached to the ink cartridge 30 is mounted. According to the embodiment described above, the control device 130 the CPU 131 and the ASIC 135 but the control device 130 must be the ASIC 135 not have, and the CPU 131 can all processes 7 and 8th perform by reading a program stored in the ROM 132 is stored. In contrast, the control device needs 130 the CPU 131 not have, and it can only hardware such as the ASIC 135 or have an FPGA. In addition, the control device 130 many CPU's 131 and / many ASIC's 135 exhibit.

According to the embodiment described above, the operating portion 82 through the hollow tube 102 moves the operating section 82 contacts and pushes, but like the operating section 82 to move is not limited to this. For example, the ink cartridge 30 in another embodiment, having a valve configured to receive the ink supply port 61 optionally open and close. The valve and the limiting element 80 can be different and separate elements. The valve can pass through the hollow tube 102 be moved, which contacts the valve and pushes. The operating section 82 Can be moved by an element extending from the hollow tube 102 differentiates and the operating section 82 contacted and pressed.

In addition, the operation section 82 in another embodiment, outside the ink cartridge 30 so that when the ink cartridge 30 on the cartridge mounting portion 110 is mounted, the extended portion of the actuating portion 82 with the end face of the mount 101 of the cartridge mounting section 110 comes in contact, and thereby moves the operating portion 82 from the first position to the second position. Nonetheless, in such a case, a user may have the extended portion of the operation portion 82 accidentally touching, and the movable element 70 can be solved in an unwanted time. Therefore, it is preferable (but not limiting) that the operating section 82 inside the ink cartridge 30 is positioned, for example, that he is within the frame 31 is positioned.

According to the above-described embodiment, the movement of the movable member (float, detection portion, light-blocking portion) becomes 70 through the engagement between the projection 84 of the delimiting section 81 and the recessed section 71 the movable element (float, detection section, light-blocking section) 70 limited, but like the movement of the movable element (float, detection section, light blocking section) 70 to limit is not limited thereto.

<First Modified Embodiment>

With reference to the 9 becomes an ink cartridge 30 described according to a first modified embodiment. The descriptions of those parts common to the above-described embodiment and the first modified embodiment may be omitted, but the parts of the first modified embodiment which are different from the parts of the above-described embodiment will be described. Similarly, the descriptions of those parts common to the above-described embodiment, the first modified embodiment and the later-described further modified embodiments may be omitted once they are described. In addition, the parts of the above-described embodiment, the first modified embodiment and the later-described further modified embodiments may be arbitrarily combined as long as the technical object of the invention is achieved.

In the ink cartridge 30 According to the first modified embodiment, the movable member (float, detection portion, light-blocking portion) 70 with the limiting section 81 connected when the operation section 82 initially positioned at the first position. When the operating section 82 moved from the first position to the second position, the connecting portion between the movable member (float, detection portion, light-blocking portion) 70 and the limiting section 81 destroyed. When the operation section 82 at the second position, therefore, the movable member (float, detection portion, light-blocking portion) becomes 70 from the limiting section 81 decoupled. Like the movable element (float, detection section, light-blocking section) 70 with the limiting section 81 is not limited in a specific way, but the movable member (float, detection portion, light-blocking portion) 70 can at the boundary section 81 be joined with an adhesive, or the movable element (float, Detection section, light blocking section) 70 and the delimiter 80 can be cast in one piece. Preferably, the strength of the connection portion is between the movable member (float, detection portion, light-blocking portion) 70 and the limiting section 81 strong enough that it will not be destroyed by vibrations or shocks to the ink cartridge 30 then picks up when it is transported, but which is weak enough to allow the assembly of the ink cartridge 30 on the cartridge mounting portion 110 not difficult.

In the above-described embodiment and the first modified embodiment, the transitional time after reaching the detection position is determined by the upper end of the movable member (float, detection portion, light-blocking portion). 70 until the passing of the detection position by the lower end of the movable member (float, detection portion, light-blocking portion) 70 measured. The position and speed of the movable member (float, detection portion, light-blocking portion) 70 can directly after the detachment of the movable element (float, detection section, light-blocking section) 70 be unstable. According to the above-described embodiment and the first modified embodiment, the transition time is measured after the position and the speed of the movable member (float, detection portion, light-blocking portion) 70 stabilized. Therefore, the viscosity of the ink can be estimated more accurately. However, how to measure the transition time is not limited to the manner described in the above-described embodiment and the first modified embodiment, but the transition time may be between the detachment of the movable member (float, detection portion, light-blocking portion). 70 and the reaching of the detection position by the movable member (float, detection portion, light-blocking portion) 70 be measured.

<Second Modified Embodiment>

With reference to the 10A and 10B become an ink cartridge 30 and a cartridge mounting section 110 described according to a second modified embodiment. The control device 130 determines that the movable member (float, detection portion, light-blocking portion) 70 from the limiting section 81 is solved when the mounting sensor 107 the signal emits that the ink cartridge 30 is at the mounting position. In other words, the control device determines 130 in that the movable element (float, detection section, light-blocking section) 70 from the limiting section 81 is solved at a time when that of the mounting sensor 107 delivered detection signal from the signal indicating that the ink cartridge 30 is not at the mounting position, changes to the signal indicating that the ink cartridge 30 is at the mounting position.

The timing at which the movable member (float, detection portion, light-blocking portion) 70 from the limiting section 81 is solved, and the time at which the mounting sensor 107 the signal emits that the ink cartridge 30 is at the mounting position, are equal or close to each other. Therefore, the latter date is assumed to be the first date. The control device 130 measures as the transitional period a time after the detachment of the movable element (float, detection section, light-blocking section) 70 from the limiting section 81 until the sensor outputs the low level signal 103 ,

In this second modified embodiment, the control device determines 130 more precisely, whether that is from the mounting sensor 107 delivered detection signal from the signal indicating that the ink cartridge 30 is not at the mounting position, changes to the signal indicating that the ink cartridge 30 at the mounting position, at step S2 in the flowchart of FIG 7 , In addition, the control device determines 130 at step S5 in the flowchart of FIG 7 whether that is from the sensor 103 output detected signal from the high level signal to the low level signal.

The control device 130 namely measures a time that is required for the movable element (float, detection section, light-blocking section) 70 is required, from the in the 10A shown position to that in the 10B to move shown position. Since the assumption described above is made over time, the controller measures 130 more specifically, a time necessary for the movable member (float, detection portion, light-blocking portion) 70 is required from a position when the ink cartridge 30 reached the mounting position, to move to the position in the 10B is shown. The control device 130 measures a time necessary for the movable element (float, detection section, light-blocking section) 70 it is necessary to move between two points in the path of movement.

In the embodiment described above, the first modified embodiment and the second modified Embodiment is the hollow tube 102 uses the delimiter 80 for releasing the movable member (float, detection portion, light-blocking portion) 70 to induce. Nonetheless, the hollow tube is 102 just an example of what the release of the movable element (float, detection section, light-blocking section) 70 causes.

<Third Modified Embodiment>

With reference to the 11A and 11B become an ink cartridge 30 and a cartridge mounting section 110 described according to a third modified embodiment.

The ink cartridge 30 has a gas bag 85 standing in the front wall 40 is positioned. The gas bag 85 penetrates through the front wall 40 in the depth direction 53 , The gas bag 85 is filled with gas and in the ink chamber 36 bulged. The condition of the gas bag 85 is referred to as a bulge. The gas bag 85 in the bulged state, the upper end of the movable member (float, detection portion, light-blocking portion) contacts 70 and thereby acts as a restriction member that controls the movement of the movable member (float, detection portion, light-blocking portion) 70 limited. The boundary section 81 and the connecting section 83 are with the ink cartridge 30 omitted according to the third modified embodiment, and the operating portion 82 is replaced by a valve configured to the ink supply port 61 optionally open and close. The coil spring 49 is configured to bias the valve so that the valve is the ink supply port 61 closes.

The cartridge mounting section 110 according to the third modified embodiment has a gas extraction tube 113 extending from the end face in the removal direction 55 extends. The gas extraction tube 113 is positioned to the gas bag 85 opposite. If the ink cartridge 30 on the cartridge mounting portion 110 is mounted, penetrates the gas extraction tube 113 through the gas bag 85 and the top end of the extraction tube 113 reaches the inside of the gas bag 85 , When this occurs, the gas inside the gas bag 85 through the gas extraction tube 113 left out, and the gas bag 85 contracts. The condition of the gas bag 85 is referred to as a contracted state. Therefore, the amount of gas in the gas bag 85 if the gas bag 85 in the contracted state is less than the gas amount in the gas bag 85 if the gas bag 85 in the bulge is. The gas bag 85 in the contracted state with the movable member (float, detection portion, light-blocking portion) 70 not in contact and releases the movable element (float, detection section, light blocking section) 70 ,

When the gas extraction tube 113 through the gas bag 85 penetrates, this is not limited to when the ink cartridge 30 on the cartridge mounting portion 110 is mounted. In another embodiment, the time when the ink cartridge needs to be 30 on the cartridge mounting portion 110 is mounted, and the time is not equal when the movable member (float, detection portion, light-blocking portion) 70 is solved. For example, in another embodiment, the gas extraction tube 113 withdrawn from the end face, and the control device 130 may drive a motor (not shown) to the gas extraction tube 113 from the end face into the gas bag 85 to move after mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed. In another embodiment, the gas bag 85 not in the front wall 40 it can be positioned but it can be in another wall of the frame 31 be positioned.

<Fourth Modified Embodiment>

With reference to the 12A and 12B become an ink cartridge 30 and a cartridge mounting section 110 described according to a fourth modified embodiment. The ink cartridge 30 According to the fourth modified embodiment has a movable member 70A instead of the movable element (float, detection section, light blocking section) 70 , In this fourth modified embodiment, the movable member has 70A a detecting section and a float, and the movable element 70A That is, the detecting portion and the float are one and the same element similar to the above-described embodiment. The movable element (float, detection section) 70A Also has a light-blocking portion similar to the above-described embodiment, but also has a light-transmitting portion. In particular, the light blocking portion has many light blocking portions, and the light transmitting portion has at least one light transmitting portion. The many light blocking portions and the at least one light transmitting portion are in the moving direction of the movable member (float, detection portion) 70A alternately positioned. In this fourth modified embodiment, the direction of movement is the height direction 52 , In other words, everyone is at least a light transmitting portion between two of the many light blocking portions in the moving direction of the movable member (float, detection portion) 70A positioned. In this fourth modified embodiment, the light-transmitting portion is a slit formed between the light-blocking portions. The slot is through the movable element (float, detection section) 70A formed in the direction in which the light-emitting portion 104 and the light-receiving portion 105 are aligned, ie in the width direction 51 , The slot allows the light coming from the light emitting section 104 is sent out, in the width direction 51 to go through there.

With reference to the 12A When the slot is at the detection position, the sensor outputs 103 the high level signal. With reference to the 12B When the light-blocking portion is at the detection position, the sensor outputs 103 the low level signal off. Different types of ink cartridges 30 have different dimensions of the slots in the direction of movement (the height direction 52 ), different numbers of slots, different dimensions of the light-blocking portions in the moving direction (the height direction 52 ) and / or different numbers of light-blocking sections. For example, an ink cartridge 30 have a single slot, and another ink cartridge 30 can have two slots. Additionally or alternatively, an ink cartridge 30 have a longer slot, and another ink cartridge 30 can have a shorter slot. Therefore, the sensor gives 103 different patterns of the detection signals or different combinations of the detection signals depending on what types of ink cartridges 30 on the cartridge mounting portion 110 are mounted. The control device 130 determines a type of ink cartridge 30 based on a pattern or a combination of the detection signals provided by the sensor 103 delivered when the movable element (float, detection section) 70A the entry position happens. The light transmitting section need not be limited to a slot. For example, in another embodiment, the light transmitting portion may be a transparent, synthetic plastic.

<Fifth Modified Embodiment>

With reference to the 13A to 13C become an ink cartridge 30 and a cartridge mounting section 110 described according to a fifth modified embodiment. The ink cartridge 30 according to the fifth modified embodiment has a movable element 70B instead of the movable element (float, detection section, light blocking section) 70 , The movable element 70B has a detection section and an anchor. When it is described in this specification that a movable member has a detecting portion and an armature, it means at least that the movable member has the detecting portion and the armature as portions of the movable member, or that the movable member includes the detecting portion and the armature has whole movable element. In this fifth modified embodiment, the movable member 70B , the detection section and the anchor one and the same element. The movable element (armature, detection section) 70B has a specific gravity that is greater than the specific gravity of the ink chamber 36 stored ink. When the movable element (armature, detection section) 70B from the limiting section 81 is released, the movable element moves (armature, detection section) 70B due to the movable element (armature, detection section) 70B acting gravity in a free area within the ink chamber 36 downward. The movable element (armature, detection section) 70B has a light-blocking section. In this fifth modified embodiment, the movable member (armature, detection portion) has 70B the light-blocking portion as a whole. The movable element 70B Namely, the detecting portion, the armature and the light blocking portion are one and the same element. The movable element (Anchor, detection section, light-blocking section) 70B is configured to that of the light emitting portion 104 of the sensor 103 emitted light similar to block in the embodiment described above. The movable element (armature, detection section, light-blocking section) 70B has the recessed section 71 on its wall surface, in the removal direction 55 is directed, similar to the embodiment described above.

In this fifth modified embodiment, the limiting element 80 a limiting section 81A instead of the boundary section 81 , The boundary section 81A has a longer dimension in the height direction 52 as the limiting section 81 , The boundary section 81A extends to a position adjacent to the top wall 39 , When the operation section 82 is in the first position, is the lead 84 with the recessed section 71 the movable element (armature, detection section, light blocking section) 70B engaged such that movement of the movable member (armature, detection portion, light-blocking portion) 70B is limited within a limited range. The movable element (armature, detection section, light-blocking section) 70B can through the limiting section 81 be completely immobilized. In such a case, the limited range is zero. The movable element (armature, detection section, light-blocking section) 70B can easily move within the limited range to that extent due to the dimensional errors of the projection 84 and the recessed section 71 is allowed. The movable element (armature, detection section, light-blocking section) 70B can move within the limited range as long as the movable element (anchor, detection section, light-blocking section) 70B the acquisition position is not reached. The limited area is positioned above the detection position.

When the operation section 82 at the second position is the projection 84 from the recessed section 71 positioned at a distance, and thereby releases the limiting section 81A the movable element (anchor, detection section, light-blocking section) 70B such that the movable element (armature, detection section, light-blocking section) 70B is positioned in the free area that is below the limited area. The detection position is in the free area.

With reference to the 13A to 13C if the hollow tube 102 in the ink feed section 60 through the ink supply port 61 is inserted and the operating section 82 in the removal direction 55 against the biasing force of the coil spring 49 presses, the operating section moves 82 from the first position to the second position. As a result, the movable member (armature, detection portion, light-blocking portion) becomes 70B solved. The movable element (armature, detection section, light-blocking section) 70B that of the boundary section 81A dissolved, moves down in the free area. When the lower end of the movable member (armature, detection portion, light blocking portion) 70B reaches the detection position, as in the 13B is shown changes from the sensor 103 output detection signal from the high level signal to the low level signal. With reference to the 13C consequently moves the movable element (armature, detection section, light-blocking section) 70B further down. When the upper end of the movable member (armature, detection portion, light-blocking portion) 70B As the detection position passes, that changes from the sensor 103 output detection signal from the low level signal to the high level signal.

Similar to the first modified embodiment, the movable member (armature, detection portion, light-blocking portion) 70B with the limiting section 81A be connected when the operating section 82 initially positioned at the first position. When the operating section 82 moved from the first position to the second position, the connecting portion between the movable member (armature, detection portion, light-blocking portion) 70B be destroyed. When the operation section 82 at the second position, therefore, the movable member (armature, detection portion, light-blocking portion) can 70B from the limiting section 81A be decoupled.

<Sixth modified embodiment>

With reference to the 14A to 14B become an ink cartridge 30 and a cartridge mounting section 110 described according to a sixth modified embodiment. The ink cartridge 30 According to this sixth modified embodiment has a movable member 70C , The movable element 70C has a detection section, an armature, and a light-blocking section. The movable element 70C That is, the detecting portion, the armature, and the light-blocking portion are one and the same member as in the fifth modified example.

In this sixth modified embodiment, the limiting element 80 a limiting section 81B instead of the boundary section 81 and a connection section 83A instead of the connection section 83 , The connecting section 83A has a longer dimension in the depth direction 53 as the connecting section 83 , The connecting section 83A extends to a position closer to the back wall 41 as on the front wall 40 is. The boundary section 81B has a first section that is in the height direction 52 from the rear end of the connecting portion 83A extends upwards, and a second section, which extends in the depth direction 53 from the upper end of the first section of the restricting section 81B extends forward. The second section of the boundary section 81B has a small projection that extends from its front end upwards.

In this sixth modified embodiment, the frame 31 a boundary wall 45 extending from the inside of the right wall 38 to the movie 44 in the width direction 51 extends. The frame 31 also has a guide wall 46 extending from the inside of the right wall 38 to the movie 44 in the width direction 51 extends. The upper surface of the guide wall 46 is a guide surface 47 which extends forwards and downwards.

The movable element (armature, detection section, light-blocking section) 70C has a round outline in a cross section along the insertion / removal direction 50 and the vertical direction. For example, the movable member (armature, detection portion, light-blocking portion) 70C have a spherical shape, a round cylindrical shape or a round, cylindrical tubular shape.

With reference to the 14A when the operation section 82 at the first position, the movable member (armature, detection portion, light-blocking portion) is 70C at the second portion of the limiting section 81B positioned such that movement of the movable member (armature, detection portion, light-blocking portion) 70C within a limited area between the boundary wall 45 and the small protrusion extending from the front end of the second portion of the restricting portion 81B extends upwards.

With reference to the 14B when the operation section 82 from the first position to the second position through the hollow tube 102 is moved, the limiting section moves 81B in the removal direction 55 relative to the frame 31 but the movable element (anchor, detection section, light-blocking section) 70C can not be in the removal direction 55 relative to the frame 31 move as the boundary wall 45 with the movable element (armature, detection section, light-blocking section) 70C is in contact. Therefore, the movable member climbs (anchor, detection portion, light-blocking portion) 70C over the small projection of the second section of the limiting section 81B , and consequently rolls on the guide surface 47 in a free area below the limited area. As a result, the movable member reaches (anchor, detection portion, light-blocking portion) 70C the entry position. Transition time between detachment of the movable member (armature, detection portion, light-blocking portion) 70C and the delivery of the low level signal by the sensor 103 is measured similarly to the second modified embodiment.

<Seventh Modified Embodiment>

With reference to the 15A to 15C become an ink cartridge 30 and a cartridge mounting section 110 described according to a seventh modified embodiment. The ink cartridge 30 has an air connection section 65 which is configured to the ink chamber 36 with the atmosphere outside the ink cartridge 30 to bring into fluid communication. The air connection section 65 is above the ink feed section 60 and the sensor 103 positioned, and it extends from the front outside of the front wall 40 of the frame 31 in the insertion direction 56 , For example, the air connection section 65 have a cylindrical shape. The air connection section 65 has a proximal end on the front wall 40 and a distal end opposite the proximal end. The air connection section 65 has an air connection opening 66 formed at the distal end. The air connection section 65 has an interior, and the interior can match the outside of the ink cartridge 30 through the air connection opening 66 be in fluid communication. The interior of the air connection section 65 is with the interior of the frame 31 ie with the ink chamber 36 , on the side of the proximal end in fluid communication. The ink chamber 36 can with the outside of the ink cartridge 30 through the air connection section 65 be in fluid communication. If in this description is described that the air connection opening 66 on the front wall 40 is provided, this means at least that the air connection opening 66 the front wall 40 penetrates, or that the air connection opening 66 at the distal end of the air connection section 65 is provided, extending from the front wall 40 in the insertion direction 56 extends, or that the air connection opening 66 is provided at a distal end of a projection extending from the front wall 40 in the removal direction 55 extends.

In this seventh modified embodiment, the ink cartridge 30 a movable element 70D instead of the movable element 70 , The movable element 70D has a detection section 73 and a swimmer 72 , In this seventh modified embodiment, the movable member has 70D the detection section 73 at a first end of the movable member 70D and the swimmer 72 at a second end of the movable member 70D , The detection section 73 is closer to the front wall 40 as the swimmer 72 positioned. The swimmer 72 has a specific gravity that is lower than the specific gravity of the ink chamber 36 stored ink, similar to the embodiment described above. The ink cartridge 30 has a shaft 74 that extends from the inside of the right wall 38 to the movie 44 in the width direction 51 extends. The movable element 70D is through the shaft 74 at a position between the detection section 73 and the swimmer 72 pivotally supported. The movable element 70D is configured to pivot about a pivot axis such as the shaft 74 clockwise and counterclockwise according to 15A to 15C to pan. Of the detecting section 73 has the recessed section 71 on its wall surface, in the removal direction 55 is directed, similar to the embodiment described above.

The detection section 73 has a light-blocking portion similar to the above-described embodiment configured to be that of the light-emitting portion 104 of the sensor 103 block out emitted light.

The ink cartridge 30 has a boundary element 90 , and the limiting element 90 has a boundary section 91 , an operating section 92 and a connection section 93 that with the delimiting section 91 and the operation section 92 connected is. The operating section 92 extends from a front end of the connecting portion 93 upwards, which is in the depth direction 53 extends. The operating section 92 has a front surface that is in the insertion direction 56 is directed, and the front surface of the actuating portion 92 is the air connection opening 99 of the air connection section 65 in the depth direction 53 across from. The operating section 92 is between a first position in the 15A is shown, and a second position movable in the 15B is shown. The second position is closer to the rear outside of the rear wall 41 as the first position. When the operation section 92 is at the first position, the operating portion 92 in contact with a wall connecting the air connection 66 surrounds, and thereby the air connection opening 66 closed. When the operation section 92 at the second position, the operating portion is 92 Positioned spaced from the wall, the air connection opening 66 surrounds, and thereby the air connection opening 66 open. The operating section 92 can from the outside of the ink cartridge 30 be operated. In this seventh modified embodiment, the operating portion 92 through an elongated object such as a staff 114 through the air connection opening 66 actuated. If the rod 114 in the air connection section 65 through the air connection opening 66 is inserted, the rod pushes 114 the operating section 92 from the first position to the second position in the withdrawal direction 55 ,

The boundary section 91 extends from a rear end of the connecting portion 93 downward. The boundary section 91 has a front surface that is in the insertion direction 56 is directed, and a projection 94 extending from the front surface in the insertion direction 56 extends. When the operation section 92 is in the first position, is the lead 94 with the recessed section 71 of the detection section (light-blocking section) 73 so engaged that the movement of the float 72 is limited within a limited range. When the swimmer 72 in the limited area is the float 72 immersed in the ink.

When the operation section 92 at the second position is the projection 94 from the recessed section 71 positioned at a distance, and thereby releases the limiting section 91 the movable element 70D such that the float 72 is positioned in a free area that is above the limited area.

The ink cartridge 30 also has a coil spring 48 , The coil spring 48 has a first end with one in the insertion direction 56 directed surface of the frame 31 in the ink chamber 36 in contact, and a second end connected to a rear surface of the operating portion 92 is in contact, in the removal direction 55 is directed. The coil spring 48 is configured to the operating portion 92 in the insertion direction 56 to bias in the first position. The coil spring 48 is an example of a biasing member, and it may be replaced by a leaf spring, a plastic spring, etc.

In this seventh modified embodiment, the limiting portion 81 and the connecting section 83 omitted, and the operating section 82 is replaced by a valve configured to the ink supply port 61 optionally open and close. The coil spring 49 is configured to bias the valve so that the valve is the ink supply port 61 similar to the third modified embodiment.

In this seventh modified embodiment, the cartridge mounting portion has 110 the staff 114 extending from the end face of the mount 101 in the removal direction 55 extends. The rod 114 is at a position corresponding to the air connection portion 65 positioned. While inserting the ink cartridge 30 in the cartridge mounting section 110 the rod enters 114 in the air connection section 65 through the air connection opening 66 and pushes the operating section 92 in the removal direction 55 from the first position to the second position. When this occurs, the movable element becomes 70D solved, and the ink chamber 36 is brought into fluid communication with the atmosphere.

When the movable element 70D is released, the movable element pivots 70D around the shaft 74 clockwise from that in the 15A shown position to that in the 15C shown position over in the 15B shown position. In particular, the float moves 72 in the free area up, and the detection section (light-blocking section) 73 moves down. After this occurs, the ink level lowers, as in the ink chamber 36 stored ink is consumed, and the movable element 70D pivots around the shaft 74 in a counterclockwise direction in the 15C shown position to that in the 15A shown position (nonetheless, the limiting section 91 with the recessed section 71 not in contact) over in the 15B shown position. In particular, the float moves 72 in the free area after lowering the ink level down, and the detecting portion (light-blocking portion) 73 moves up.

The control device 130 leads the processes of 7 through when the movable element 70D around the shaft 74 clockwise from that in the 15A shown position to that in the 15C shown position over in the 15B shown position pivots. The control device 130 leads the processes of 8th through when the movable element around the shaft 74 in a counterclockwise direction in the 15C shown position to that in the 15A shown position (nonetheless, the limiting section 91 with the recessed section 71 not in contact) over in the 15B shown position pivots.

<Eighth Modified Embodiment>

With reference to the 16A to 16C become an ink cartridge 30 and a cartridge mounting section 110 described according to an eighth modified embodiment. The difference between the eighth modified embodiment and the above-described embodiment is that the ink cartridge 30 from this eighth modified embodiment, the movable element 70B of the fifth modified embodiment instead of the movable element 70 and that it also has a biasing member such as a coil spring 86 having, between the connecting portion 83 and the movable element 70B is arranged. With reference to the 16A when the movement of the movable member (armature, detection portion, light-blocking portion) 70B through the limiting section 81 is limited within a limited range, the coil spring biases 86 the movable element (anchor, detection section, light-blocking section) 70B upwards. With reference to the 163 when the movable member (armature, detection portion, light-blocking portion) 70B is released, the movable member (armature, detection portion, light-blocking portion) 70B by the biasing force of the coil spring 86 set in motion and move up in an open area that is above the limited area, it passes the detection position. With reference to the 16C moves the movable element (armature, detection section, light-blocking section) 70B subsequently in the free area due to its own weight down and returns to the detection position. In this eighth modified embodiment, the control device 130 Transient time after passing the detection position by the movable member (armature, detection portion, light-blocking portion) 70B until the return of the movable element (armature, detection section, light-blocking section) 70B measure to the detection position. In other words, the control device measures 130 a time necessary for the movable element (armature, detection section, light-blocking section) 70B is required to be between two positions in the moving path of the movable member (armature, detection portion, light-blocking portion) 70B to move, but the two points are the same point.

<Ninth Modified Embodiment>

With reference to the 17A and 17B becomes a liquid container such as a sub tank 28 described according to a ninth modified embodiment. The secondary tank 28 According to the ninth modified embodiment, a liquid chamber such as an ink chamber 120 , an ink introduction port 121 an ink supply port such as an ink supply port 122 , an air connection opening 123 , a movable element 125 , a detection section 124 , a sensor 126 , a magnetic material such as a metal plate 127 and ink level sensors 128 . 129 , The ink introduction port 121 is with the cartridge mounting section 110 through the ink tube 20 connected. The ink supply port 122 is with the recording head 21 through an ink tube (not shown).

The secondary tank 28 is configured to receive ink passing through the ink introduction port 121 passes, and the ink in the ink chamber 120 save. The secondary tank 28 is configured to be in the ink chamber 120 stored ink to the recording head 21 through the ink supply port 122 supply. The air connection opening 123 is configured to the ink chamber 120 with the atmosphere outside the sub-tank 28 to bring into fluid communication. The ink level sensors 128 . 129 are configured to control the position of the ink level in the ink chamber 120 to capture stored ink.

The movable element 125 is in the ink chamber 120 positioned. The detection section 124 has a magnet, preferably a permanent magnet 124A , The detection section 124 is an anchor with a specific gravity that is greater than the specific gravity of the ink chamber 120 stored ink. The movable element 125 has a first end and a second end, and the detection section 124 is at the first end of the movable element 125 intended. The second end of the movable element 125 is through the side tank 28 in the ink chamber 120 pivotally supported. The movable element 125 is configured to rotate the second end clockwise and counterclockwise according to the 17A and 17B to pan.

The sensor 126 is at a position opposite to the moving path of the detecting portion 124 intended. The sensor 126 has the same structure as the sensor 103 , The metal plate 127 is in an outside wall of the side tank 28 , The metal plate 127 is adjacent to the movement path of the detection section 124 positioned. More precisely, the metal plate 127 in the outside wall of the side tank 28 embedded, and the sensor 126 is over the metal plate 127 positioned. The printer 10 has an electromagnet 140 and a power supply circuit 130A that is configured to the electromagnet 140 to supply an electric current. The electromagnet 140 is outside the secondary tank 28 at a position adjacent to the metal plate 127 positioned. The power supply circuit 130A is configured to be controlled by the control device 130 is controlled, and it is configured by the electromagnet 140 optionally to supply an electric current, so that the electromagnet 140 generates a magnetic field.

With reference to the 17A if the electric current is not to the electromagnet 140 is supplied, is the movement of the detection section 124 within a limited range by an attraction force between the permanent magnet 124A and the metal plate 127 limited. When an electric current to the electromagnet 140 from the power supply circuit 130A is supplied, the electromagnet generated 140 a repulsive force between the permanent magnet 124A and the metal plate 127 , wherein the repulsive force is greater than the attraction. When this occurs, the detection section becomes 124 with reference to the 17B initiated by the repulsive force and moves upwards in an open area that is above the limited range. When the detection section 124 moved upward, the movable element pivots 124 around the second end of the movable element 125 , Subsequently, the detection section reaches 124 the entry position.

When the supply of electric current to the electromagnet 140 is stopped, the detecting section moves 124 down, and the movement of the detection section 124 is limited again within the limited range. At the secondary tank 28 According to this ninth modified embodiment, the transition time for estimating the viscosity of the ink can be measured several times if necessary. The control device 130 According to this ninth modified embodiment, a time after the supply of the electric current to the electromagnet 140 until the sensor outputs the low level signal 126 to measure as the transitional period. The structure of this ninth modified embodiment can not only apply to the subtank 28 but also on the ink cartridge 30 ,

In the embodiment described above and the first to ninth modified embodiments, the ink cartridge becomes 30 manually to the cartridge mounting section 110 assembled. Like the ink cartridge 30 to the cartridge mounting section 110 nevertheless, is not limited to manual mounting. An automatic loading mechanism can be used for the cartridge mounting section 110 be provided as described below as an example.

<Tenth Modified Embodiment>

With reference to the 18A and 18B become an ink cartridge 30 and a cartridge mounting section 110 described according to a tenth modified embodiment. The ink cartridge 30 has a rack 42A on the outside of the lower wall 42 , The cartridge mounting section 110 has a pinion 115 Configured with the rack 42A to engage, a drive gear 116 that with the pinion 115 engaged, and a coil spring 117 , One end of the spiral spring 117 is with the drive gear 116 in contact, and the coil spring 117 is configured to drive a drive gear 116 applied.

Before the ink cartridge 30 to the cartridge mounting section 110 is mounted, the coil spring 117 locked in a state in which the coil spring 117 tightly wrapped, as in the 18A is shown, so that in the coil spring 117 an energy is stored. If the ink cartridge 30 in the cartridge mounting section 110 inserted by a user, the rack gets 42A with the pinion 115 in contact and turn this. When the pinion 115 turns, the drive gear rotates 116 , and this turns the coil spring 117 unlocked. When the coil spring 117 unlocked, loosens the winding of the coil spring 117 , and the coil spring 117 brings the driving force to the drive gear 116 on. When the driving force on the drive gear 116 is applied, the drive gear rotates 116 , and the pinion 115 turns. When the pinion 115 turns, the rack moves 42A in the insertion direction 56 to the end surface of the enclosure 101 of the cartridge mounting section 110 , As a result, the ink cartridge moves 30 in the insertion direction 56 to the end surface of the enclosure 101 of the cartridge mounting section 110 ie the user needs the ink cartridge 30 no longer insert, and mounting the ink cartridge 30 on the cartridge mounting portion 110 is finished, like this in the 18B is shown. In other words, the mounting of the ink cartridge becomes 30 to the cartridge mounting section 110 automatically effected.

After the in the ink cartridge 30 stored ink is used up, the user pulls the ink cartridge 30 in the removal direction 55 When a user wishes, the ink cartridge 30 from the cartridge mounting section 110 refer to. If the ink cartridge 30 in the removal direction 55 is moved, the pinion rotate 115 and the drive gear 116 each in a direction opposite to that direction in which the pinion 115 and the drive gear 116 each turn when the ink cartridge 30 in the insertion direction 56 emotional. As a result, the coil spring 117 again tightly wrapped. Subsequently, the tight winding of the coil spring 117 locked, at a time when the rack 42A from the pinion 115 separates.

According to this tenth modified embodiment, the user needs the ink cartridge 30 only insert at a position where the rack is 42A and the pinion 115 are engaged. Thereafter, the ink cartridge 30 automatically in the insertion direction 56 moves, and finally, the mounting of the ink cartridge 30 on the cartridge mounting portion 110 completed. Therefore, there is a reduced probability that the sensor 103 the movable element (float, detection section, light-blocking section) 70 can not detect, even if the movable element (float, detection section, light-blocking section) 70 is solved. The measurement of the transitional period can be carried out even more safely.

<Eleventh modified embodiment>

With reference to the 19A and 19B become an ink cartridge 30 and a cartridge mounting section 110 described according to an eleventh modified embodiment. The difference between this eleventh modified embodiment and the above-described embodiment is that the ink cartridge 30 of the eleventh modified embodiment, a movable element 70E instead of the movable element 70 and the sensor 103 in this eleventh modified embodiment extends from the ceiling of the enclosure 101 ,

The movable element 70E has a detection section 173 and an anchor 172 , The movable element 70E has the detection section 173 at a first end of the movable member 70E and the anchor 172 at a second end of the movable member 70E , The detection section 173 is closer to the front wall 40 as the anchor 172 positioned. The anchor 172 has a specific gravity that is greater than the specific gravity of the ink chamber 36 stored ink, similar to the fifth modified embodiment described above. The ink cartridge 30 has a shaft 174 that extends from the inside of the right wall 38 to the movie 44 in the width direction 51 extends. The movable element 70E is through the shaft 174 at a position between the detection section 173 and the anchor 172 pivotally supported. The movable element 70E is configured to pivot about a pivot axis such as the shaft 174 in the counterclockwise direction according to 19A and 19B to pan. The detection section 173 has the recessed section 71 on its wall surface, in the removal direction 55 is directed, similar to the embodiment described above.

The detection section 173 has a light-blocking portion similar to the above-described embodiment configured to be that of the light-emitting portion 104 of the sensor 103 block out emitted light.

When the operation section 82 is in the first position, is the lead 84 with the recessed section 71 of the detection section (light-blocking section) 173 engaged in such a way that the movement of the anchor 172 is limited within a limited range. When the operation section 82 at the second position is the projection 84 from the recessed section 71 positioned at a distance, thereby releasing the limiting element 81 the movable element 70E such that the anchor 172 is positioned in a free area that is below the limited area.

When the movable element 70E is released, the movable element pivots 70E around the shaft 174 in a counterclockwise direction in the 19A shown position to that in the 19B shown position. In particular, the anchor moves 172 in the free area down, and the detection section (light-blocking section) 173 moves up. Finally, the anchor arrives 172 with the lower surface of the ink chamber 36 in contact, and the detection section (light blocking section) 173 reaches the detection position, and the movable element 70E stops the movement.

In this eleventh embodiment, the control device determines 130 whether that is from the mounting sensor 107 delivered detection signal from that signal indicating that the ink cartridge 30 is not at the mounting position, changes to that signal indicating that the ink cartridge 30 at the mounting position, at step S2 in the flowchart of FIG 7 , In addition, the control device determines 130 at a step S5 in the flowchart of FIG 7 whether that is from the sensor 103 outputted detection signal from the high level signal to the low level signal changes, similar to the above-described second embodiment. The control device 130 That is, it measures a time for the movable element 70E is required, from the in the 19A shown position to that in the 19B to move shown position.

In this eleventh modified embodiment, the initial position of the ink level is in the ink chamber 36 under the sensor 103 that is, under the detection position, and the ink may have a dye such as a pigment blocking light. Since the ink level does not reach the detection position, the ink does not affect the detection of the detection portion (light-blocking portion) 173 even if the ink has such a dye.

<Twelfth Modified Embodiment>

With reference to the 20A and 20B become an ink cartridge 30 and a cartridge mounting section 110 described according to a twelfth modified embodiment. The difference between this twelfth modified embodiment and the above-described embodiment is that the ink cartridge 30 from this twelfth modified embodiment, a movable element 70F instead of the movable element 70 and that it is a delimiter 280 instead of the delimiter 80 having. In addition, the sensor extends 103 from the ceiling of the mount 101 in this twelfth modified embodiment, similar to the eleventh modified embodiment described above. In addition, the ink cartridge has 30 from this twelfth modified embodiment, a pair of guide walls 243 . 244 instead of the partition 43 ,

The movable element 70F has a detection section 273 and a swimmer 272 , The detection section 273 extends from the upper end of the float 272 , The swimmer 272 has a specific gravity smaller than the specific gravity of the ink chamber 36 stored ink, similar to the embodiment described above. The detection section 273 has a light-blocking portion similar to the above-described embodiment configured to be that of the light-emitting portion 104 of the sensor 103 block out emitted light. The swimmer 272 has a recessed portion on its wall surface in the direction of insertion 56 is directed.

The boundary element 280 has an operating section 282 , an axial section 283 , a rising section 285 , a connecting section 287 and a restriction section 281 , The operating section 282 and the axial section 283 are a first single-level element, and the rising section 285 , the connection section 287 and the limiting section 281 are a second one-piece element that is separate from the first one-piece element.

The operating section 282 extends from a front end of the axial section 283 down, which is in the depth direction 53 extends. The operating section 282 has a front surface that is in the insertion direction 56 is directed, and the front surface of the actuating portion 282 lies the ink supply port 61 in the depth direction 53 across from. The operating section 282 is between a first position in the 20A is shown, and a second position movable in the 20B is shown. The second position is closer to the rear outside of the rear wall 41 as the first position. When the operation section 282 is at the first position, the operating portion 282 in contact with a wall that houses the ink supply port 61 surrounds, and thereby the ink supply port 61 closed. When the operation section 282 at the second position, the operating portion is 282 Positioned spaced from the wall, the ink feed opening 61 surrounds, and thereby is the ink supply port 61 open. The operating section 282 is from the outside of the ink cartridge 30 actuated. In this twelfth modified embodiment, the operating portion 282 through the hollow tube 102 through the ink supply port 61 actuated. If the hollow tube 102 in the ink supply section 60 through the ink supply port 61 is inserted pushes the hollow tube 102 the operating section 282 from the first position to the second position in the withdrawal direction 55 ,

When the operation section 282 is at the first position is a rear end of the axial section 283 with a front surface of the rising portion 285 in contact, in the insertion direction 56 is directed. The connecting section 287 extends from the rising portion 285 forward and up, and the limiting section 289 is at one end of the connection section 287 opposite the rising section 285 positioned. The boundary section 2891 has a rear surface that is in the removal direction 55 is directed, and a projection extending from the rear surface in the removal direction 55 extends. The connecting section 287 is configured to be one between the rising section 285 and the limiting section 281 positioned pivot axis clockwise and counterclockwise according to the 20A and 20B to be panned.

When the operation section 282 is at the first position is the projection of the limiting section 281 with the recessed section of the float 272 of the movable element 70F so engaged that the movement of the float 272 is limited within a limited range. When the swimmer 272 in the limited area is the float 282 immersed in the ink.

When the operating section 82 moving from the first position to the second position, the axial section moves 283 in the removal direction 55 and press the rising section 285 up. The axial section 283 then slides under the rising section 285 , When this occurs, the connecting section pivots 287 about the pivot axis in the clockwise direction according to the 20A , and the projection of the limiting section 281 moves out of the recessed section of the float 272 out.

When the operation section 282 at the second position, the delimiting section releases 81 hence the movable element 70F such that the float 272 is positioned in a free area that is above the limited area.

The guide walls 243 . 244 each extend from the inner surface of the right wall 38 in the width direction 51 to the left side of the frame 31 , Every guide wall 243 . 244 extends in the height direction 52 , The guide walls 243 . 244 extend substantially parallel to each other. The right wall 38 , the guide walls 243 . 244 and the movie 44 define a space in it, and the space is an example of the free area.

The coil spring 49 has a first end with one in the insertion direction 56 directed surface of the frame 31 in the ink chamber 36 is in contact, and a second end, with one in the removal direction 55 directed rear surface of the actuating portion 282 is in contact. The coil spring 49 is configured to the operating portion 282 in the insertion direction 56 to bias in the first position.

When the movable element 70F is released, the movable element moves 70F from in the 20A shown position to that in the 20B shown position upwards. In particular, the movable element moves 70F in a free area between the guide walls 243 . 244 up. Finally, the detection section (light-blocking section) reaches 273 the detection position, and the movable element 70F stops the movement. When the movable element 70F the movement stops, is the detection section (light-blocking section) 273 with the inner surface of the upper wall 39 in contact, and / or a section of the float 272 is free from the ink level.

In this twelfth embodiment, the control device determines 130 at a step S2 in the flowchart of FIG 7 whether that is from the mounting sensor 107 delivered detection signal from that signal indicating that the ink cartridge 30 is not at the mounting position, changes to that signal indicating that the ink cartridge 30 is at the mounting position. In addition, the control device determines 130 at a step S5 in the flowchart of FIG 7 whether that is from the sensor 103 outputted detection signal from the high level signal to the low level signal changes, similar to the above-described second modified embodiment. The control device 130 That is, it measures a time for the movable element 70F is required, from the in the 20A shown position to that in the 20B to move shown position.

In this twelfth modified embodiment, the initial position of the ink level is in the ink chamber 36 under the sensor 103 ie, under the detection position, and the ink can a dye such as a pigment blocking light, similar to the eleventh modified embodiment described above.

In the above-described embodiment and the first to twelfth modified embodiments, the ink is an example of the liquid. Nonetheless, the liquid is not limited to ink. For example, the liquid may be a pretreatment liquid that is ejected onto the sheet of paper before the ink is ejected upon printing.

As described above, the parts of the above-described embodiment and the first to twelfth modified embodiments can be arbitrarily combined as long as the object of the invention is achieved. For example, the operation section 92 of the above-described seventh modified embodiment by the operating portion 82 of the embodiment described above are exchanged.

While the invention has been described in conjunction with various exemplary structures and illustrative embodiments, it will be understood by those skilled in the art that other modifications and variations of the structures and embodiments described above may be made without departing from the scope of the invention. Other structures and embodiments will become apparent to those skilled in the art in light of the description or practice of the invention disclosed herein. It is intended that the specification and examples described are merely illustrative, and that the scope of the invention is defined by the appended claims.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 09277560 A [0002]

Claims (14)

Liquid cartridge ( 30 ) with: a first outer side ( 40 ); a second outer side ( 41 ) opposite the first outer side ( 40 ); a liquid chamber ( 36 ), which between the first outer side ( 40 ) and the second outer side ( 41 ) and configured to store a liquid therein, the liquid having a first specific gravity; a liquid supply section ( 60 ) positioned on the first outside and configured to supply the liquid from an interior of the liquid chamber to an outside of the liquid chamber; a movable element ( 70 ) positioned in the liquid chamber, the movable element ( 70 ) a detection section ( 70 ) and a float ( 70 ), whereby the float ( 70 ) has a second specific gravity smaller than the first specific gravity; and a delimiter ( 80 ) having an operating section ( 82 ) and a limiting section ( 81 ) Has; the operating section ( 82 ) is operable from the outside of the liquid chamber and is movable between a first position and a second position, wherein the second position is closer to the second outside ( 41 ) is considered the first position; the limiting section ( 81 ) with the movement of the actuating section ( 82 ) is movable from the first position to the second position; wherein when the operating section ( 82 ) is at the first position, the limiting section ( 81 ) is configured with the movable element ( 70 ) in the liquid chamber and a movement of the movable element ( 70 ), whereby the float ( 70 ) is immersed in the liquid in the liquid chamber within a limited range; and wherein, when the actuation section ( 82 ) is at the second position, the limiting section ( 81 ) is configured to move the movable element ( 70 ) in such a way that the float ( 70 ) is positioned in a free area that is above the limited area. A liquid cartridge according to claim 1, wherein the liquid in the liquid chamber has a liquid level, the float ( 70 ) is configured to move down in the free area when a portion of the float ( 70 ) is exposed from the liquid level and the liquid level lowers. A liquid cartridge according to claim 1 or 2, wherein when the operation section ( 82 ) is at the second position, the limiting section ( 81 ) of the movable element ( 70 ) is positioned at a distance. A liquid cartridge according to claim 1, 2 or 3, wherein the liquid supply section ( 60 ) a liquid feed opening ( 61 ), wherein when the operating section ( 82 ) at the first position, the operating portion ( 82 ) to configure the liquid feed port ( 61 ), and wherein when the actuation section ( 82 ) at the second position, the operating portion ( 82 ) to configure the liquid feed port ( 61 ), wherein the liquid cartridge optionally further comprises a biasing element ( 49 ), which is configured to control the operating section (10) 82 ) in the first position. Liquid cartridge according to one of the preceding claims, wherein the detection section ( 70 ) and the float ( 70 ) are the same element. Liquid cartridge according to one of the preceding claims, further comprising a guide wall ( 43 ), which is positioned within the liquid chamber, and wherein the guide wall ( 43 ) is configured to control the movement of the float ( 70 ) in the open area. A liquid cartridge according to any one of the preceding claims, wherein, when the operation portion is at the first position, the restriction portion (12) 81 ) with the movable element ( 70 ) connected is ( 9 ), and when the operation portion is at the second position, the restriction portion (FIG. 81 ) of the movable element ( 70 ) decoupled. A liquid cartridge according to claim 1, 2, 3 or 4, wherein the movable element ( 70D ) is configured to pivot about a pivot axis ( 74 ) to pivot in the liquid chamber. The liquid cartridge of claim 1, wherein the actuation portion is configured to be moved from the first position to the second position by an elongated object that is inserted into the fluid cartridge, and wherein the fluid cartridge is optionally configured to be mounted to a cartridge mounting portion becoming the elongate object, and wherein the elongate object is optionally a hollow tube configured to be inserted into the liquid supply portion such that the liquid flows through the hollow tube. A liquid cartridge according to any one of the preceding claims, wherein the detection portion has a light-blocking portion. A liquid cartridge according to claim 10, wherein said detection section (12) 70A ) has a light transmitting portion and the light blocking portion has a first portion and a second portion, wherein, when the float moves in the free area, the detection portion moves along a moving direction, the light transmitting portion between the first portion of the light blocking portion and the second portion of the light-blocking portion is positioned in the direction of movement. Liquid cartridge according to one of the preceding claims, wherein the liquid cartridge ( 30 ) is configured to be attached to a cartridge mounting portion ( 110 ) which has a light-emitting section ( 104 ) and a light-receiving section ( 105 ), and the detection section ( 70 ) is configured to intersect an optical path extending between the light emitting portion (FIG. 104 ) and the light-receiving portion ( 105 ) when the liquid cartridge ( 30 ) on the cartridge mounting portion (FIG. 110 ) and the float ( 70 ) is in the free area. Liquid cartridge according to one of the preceding claims, wherein the liquid cartridge ( 30 ) is configured to be inserted into a cartridge mounting section ( 110 ) in an insertion direction, wherein the operation portion is configured to move from the first position to the second position in a direction opposite to the insertion direction. Liquid cartridge ( 30 ) with: a liquid chamber ( 36 ) configured to store a liquid therein, the liquid having a first specific gravity; a liquid supply section ( 60 ) configured to supply the liquid from an interior of the liquid chamber to an outside of the liquid chamber; a movable element ( 70 ) positioned in the liquid chamber, the movable element ( 70 ) has a detecting portion and a float, the float having a second specific gravity smaller than the first specific gravity; and a gas bag filled with gas ( 85 ), wherein the gas bag is configured to change its state from a bulged state to a contracted state; wherein, when the gas bag is in the bulged state, the gas bag is bulged into the fluid chamber and is in contact with the movable member in the fluid chamber and limits movement of the movable member, the float in the fluid in the fluid chamber within a limited range wherein, when the gas bag is in the contracted state, the gas bag is configured to disengage the movable member such that the float is positioned in a free area overlying the limited area; and wherein a gas amount in the gas bag when the gas bag is in the contracted state is smaller than a gas amount in the gas bag when the gas bag is in the bulged state.

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