DE102014224328A1 - Liquid consumption device - Google Patents

Abstract

A liquid consuming device has a liquid cartridge, a detector and a control device. The liquid cartridge has a first liquid chamber and a second liquid chamber. The detector is configured to emit a detection signal based on an amount of fluid that has flowed from the first fluid chamber to the second fluid chamber. The controller is configured to measure a physical quantity based on the detection signal output from the detector, whereby a flow rate of the liquid flowing from the first liquid chamber to the second liquid chamber can be specified, and configured to determine whether the physical size is within a threshold range.

Description

The present invention relates to a liquid consuming device.

A known ink jet recording apparatus is configured to record an image on a recording medium by ejecting an 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 an ink stored in an ink tank and to perform optimized preliminary ejection based on the estimation result. More specifically, the ink jet recording apparatus is configured to estimate the viscosity of the ink on the basis of an elapsed time after the ink tank is mounted on the ink jet recording apparatus and an amount of 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 ink moves in the ink tank. 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 consuming device that overcomes these and other deficiencies of the prior art. A technical advantage of the present invention is that the viscosity of the 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-consuming apparatus comprises: a liquid cartridge having: a liquid chamber configured to store a liquid therein; a second liquid chamber configured to store the liquid therein; and a liquid supply port configured to supply the liquid from the first liquid chamber and the second liquid chamber to an outside of the liquid cartridge; a cartridge mounting portion configured to receive the fluid cartridge; a liquid consumption portion configured to consume the liquid supplied through the liquid supply port from the liquid cartridge mounted on the cartridge mounting portion; means such as a connector for fluidly communicating the first fluid chamber and the second fluid chamber with each other; a detector configured to output a detection signal based on an amount of liquid that has flowed from the first liquid chamber to the second liquid chamber; and a controller configured to: measure a physical quantity based on the detection signal output from the detector, whereby a flow rate of the liquid flowing from the first liquid chamber to the second liquid chamber can be specified; and determine if the physical quantity is within a threshold range.

With this configuration, when the connector fluidly communicates the first fluid chamber with the second fluid chamber, the fluid moves from the first fluid chamber to the second fluid chamber through the communication port. The flow rate of the liquid moving from the first liquid chamber to the second liquid chamber varies depending on the viscosity of the liquid in the liquid chamber. By measuring a physical quantity, by which the flow rate of the liquid can be specified, the viscosity of the liquid stored in the liquid 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, the needs thereof and their 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 including 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 shows 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. FIG.

5C 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 ink level of a second ink chamber reaches a detection position.

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

7 FIG. 12 shows a flowchart of a process performed by the controller when the processes of FIG 6 are completed and the cover of the cartridge mounting portion is closed.

8A FIG. 12 is a cross-sectional view of an ink cartridge and a cartridge mounting portion according to a first modified embodiment during insertion of the ink cartridge into the cartridge mounting portion. FIG.

8B FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the first modified embodiment when the mounting of the ink cartridge on the cartridge mounting portion has just been completed. FIG.

8C 12 shows a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the first modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion is completed and the ink level of a second ink chamber reaches a detection position.

9 shows an exploded perspective view of an ink cartridge according to a second modified embodiment.

10 FIG. 12 is a perspective view of a cartridge mounting portion, which is partially cut away, showing an end surface of the cartridge mounting portion according to the second modified embodiment. FIG.

11A FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the second modified embodiment during insertion of the ink cartridge into the cartridge mounting portion. FIG.

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

11C 12 shows a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the second modified embodiment when mounting the ink cartridge to the cartridge mounting portion is completed and the ink level of a first ink chamber falls below a detection position.

12 shows an exploded perspective view of an ink cartridge according to a third modified embodiment.

13A FIG. 12 is a cross-sectional view of the ink cartridge and a cartridge mounting portion according to the third 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 third modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion has just been completed. FIG.

13C FIG. 12 is a cross-sectional view of the ink cartridge and the cartridge mounting portion according to the third modified embodiment when the mounting of the ink cartridge to the cartridge mounting portion is completed and the ink level of a first ink chamber falls below a detection position.

14A shows a cross-sectional view of an ink cartridge according to a fourth modified embodiment, in which a valve element is at a closed position and a movable member is at a blocking position.

14B FIG. 12 is a cross-sectional view of the ink cartridge according to the fourth modified embodiment, in which the valve element is in an open position and the movable member is at a connecting position. FIG.

15A shows a cross-sectional view of an ink cartridge according to a fifth modified embodiment, wherein a pointed member is at a rest position.

15B Fig. 12 is a cross-sectional view of the ink cartridge according to the fifth modified embodiment, in which the pointed member is at a crushing position.

16A FIG. 12 is a fragmentary perspective view of an ink cartridge according to a sixth modified embodiment, in which the ink cartridge is cut along a plane parallel to the width direction. FIG 51 and the height direction 52 and an ink level of a second ink chamber does not reach a detection position.

16B FIG. 12 is a perspective, fragmentary view of the ink cartridge according to the sixth modified embodiment, in which the ink cartridge is cut along a plane parallel to the width direction. FIG 51 and the height direction 52 is, and the ink level of the second chamber reaches a detection position.

17A FIG. 12 is a perspective, fragmentary view of an ink cartridge according to a seventh modified embodiment, in which the ink cartridge is cut along a plane parallel to the width direction. FIG 51 and the height direction 52 and an ink level of a second ink chamber does not reach a detection position.

17B FIG. 12 is a perspective, fragmentary view of the ink cartridge according to the seventh modified embodiment, in which the ink cartridge is cut along a plane parallel to the width direction. FIG 51 and the height direction 52 is, and the ink level of the second chamber reaches a detection position.

Embodiments of the present invention, as well as its features and advantages, may be understood with reference to FIGS 1 to 17B with the same reference numerals being 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 on the sheet of 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 temporarily store ink passing through the ink tube 20 from the ink cartridge 30 is supplied. The recording head 21 has nozzles 29 and is configured to selectively ink through the nozzles 29 to be ejected from the sub tank 28 is supplied. More specifically, 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 printing 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 to 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 , a mounting detector such as a mounting sensor 107 and a staff 114 , 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 store the corresponding inks in cyan, magenta, yellow and black. Four hollow tubes 102 , four sensors 103 , four mounting sensors 107 and four bars 114 are on the cartridge mounting section 110 according to the four ink cartridges 30 intended.

[Hollow tube 102 ]

The mount 101 of the cartridge mounting section 110 has the opening 112 passing through a side of the mount 101 is formed through. 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 of 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 is inserted in the ink cartridge 30 stored ink 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 and the opening 112 optionally not to cover such that the opening 112 to the outside of the printer 10 is free. The cover 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 on the cartridge mounting portion 110 is mounted, it means that at least a portion of the ink cartridge 30 in the cartridge mounting section 110 is positioned, and more precisely 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 the ink supply from the ink cartridge 30 to the recording head 21 possible, and preferably the ink cartridge 30 locked so that the movement of the ink cartridge 30 relative to the cartridge mounting portion 110 is limited or 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. The sensor 103 has a light emitting section 104 and a light receiving section 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 emit light, such as visible light, infrared light and / or UV light, to the light-receiving portion 105 , and the light-receiving section 105 is configured to receive the light from the light emitting portion 104 is sent out. 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 as to be positioned with the ink cartridge positioned therebetween 30 face each other when mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed.

In this embodiment, a detection position is a position within 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 to the cartridge mounting section 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 so that it is the ink cartridge 30 located in the cartridge mounting portion 110 is mounted, 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 various detection signals based on the intensity of the light received from the light-receiving portion 105 is recorded. The sensor 103 is configured to output a low level signal, ie a signal whose level is less than a predetermined threshold, when the intensity of the light passing through the light receiving portion 105 is less than a predetermined strength. The sensor 103 is configured to output a high level signal, ie a signal whose level is greater than or equal to the predetermined threshold, when the intensity of the light transmitted through the light receiving section 105 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. If the mounting sensor 107 through a front wall 40 (described later) of the ink cartridge 30 is not pressed, gives the mounting sensor 107 a low level signal indicating that the ink cartridge 30 not at the assembly detection position. If the mounting sensor 107 through the front wall 40 the ink cartridge 30 is pressed, gives the mounting sensor 107 a high level signal indicating that the ink cartridge 30 at the assembly detection position. The mounting sensor 107 is not limited to the mechanical sensor, but it may be an optical sensor, an electrical sensor, or any other known sensor.

[Rod 114 ]

With reference to the 1 and 2 is the staff 114 over the hollow tube 102 positioned and extends from the end surface of the enclosure 101 in the removal direction 55 , The rod 114 is at the end face of the mount 101 positioned and at a position corresponding to an air connection opening 65 (described later) the ink cartridge 30 , If the rod 114 through the air connection opening 65 is inserted, the inside of the ink cartridge 30 with the atmosphere outside the ink cartridge 30 placed in a fluid connection.

[Ink cartridge 30 ]

With reference to the 3A and 3B has the ink cartridge 30 a frame 31 having a liquid chamber formed therein, such as an ink chamber 36 and a liquid supply portion such as an ink supply portion 60 that is different from the frame 31 extends. The ink cartridge 30 is configured to be one in the ink chamber 36 stored ink to the outside of the ink cartridge 30 through 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 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 a 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 45 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 45 has a first wall 45A that are in the height direction 52 extends, and a second wall 45B that are in the depth direction 53 extends. The first wall 45A extends substantially parallel to the front wall 40 , and the second wall 45B extends substantially parallel to the upper wall 39 , The first wall 45A is from the front wall 40 in the depth direction 53 positioned at a distance. The first wall 45A has an upper end and a lower end that connects to the lower wall 42 connected is. The second wall 45B is from the upper wall 39 in the height direction 52 positioned at a distance. The second wall 45B is with the top of the first wall 45A connected at one end, and she is with the front wall 40 connected at the other end. 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 almost 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 45 welded by 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 covering 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.

In this embodiment, the one in the ink chamber blocks 36 stored ink the light emitted by the light-emitting section 104 of the sensor 103 is sent out. When a body of the ink is at the detection position and that of the light-emitting portion 104 of the sensor 103 emitted light one side of the body of the ink in one direction (the width direction 51 ) perpendicular to the insertion / withdrawal direction 50 is reached, is a lot (strength) of the light that comes from the other side of the body of the ink 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 caused by the body of the ink, which completely prevents the light in the width direction 51 perpendicular to the insertion / removal direction 50 There passes through the body of the ink, which absorbs a certain amount of light, through the body of the ink that scatters the light, or through some other phenomenon. On the other hand, if the body of the ink is not at the detection position and that of the light-emitting portion 104 of the sensor 103 emitted light 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 reaches, whether the body of the ink is at the detection position or not.

[ink supply 60 ]

With reference to the 1 . 3A and 3B the ink feed section extends 60 from the front outside 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 supply port 61 extends in the depth direction 53 , 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, is the ink supply port 61 through a crushing wall, such as a film 61A closed (see 5A ). The hollow tube 102 is configured to the movie 61A to penetrate and break when the ink cartridge 30 to the cartridge mounting section 110 is mounted. The film 61A has elasticity and can be, for example, a rubber film. If the hollow tube 102 through the movie 61A is inserted, is the movie 61A with the outer surface of the hollow tube 102 in close contact. If the hollow tube 102 in the ink feed section 60 the ink cartridge 30 may be inserted in the ink cartridge 30 stored ink in the ink tube 20 through the hollow tube 102 stream. If the hollow tube 102 of the movie 61A can be eliminated, an opening in the film 61A By penetrating the hollow tube 102 is formed by the elasticity of the film 61A getting 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.

[Atmospheric communication port 65 ]

With reference to the 1 . 3A and 3B has the ink cartridge 30 an air connection opening 65 passing through the front wall 40 of the frame 31 is trained. The air connection opening 65 is configured to the ink chamber 36 with the atmosphere outside the ink chamber 30 to bring into fluid communication. The air connection opening 65 is above the ink feed section 60 positioned and extends through the front wall 40 of the frame 31 in the depth direction 53 , The air connection opening 65 is also over the second wall 45B the partition 45 positioned. In addition, the air connection opening 65 at a position corresponding to the rod 114 of the cartridge mounting section 110 , Before the ink cartridge 30 to the cartridge mounting section 110 is mounted, is the air connection opening 65 through a crushing wall, such as a film 65A closed (see 5A ). The rod 114 is configured to the movie 65A to penetrate and break when the ink cartridge 30 to the cartridge mounting section 110 is mounted. If the rod 114 through the movie 65A and the air connection opening 65 is inserted, the ink chamber 36 and more specifically, the first ink chamber 36A with the atmosphere outside the ink cartridge 30 through the air connection opening 65 placed in a fluid connection.

If in this description is described that the air connection opening 65 on the front wall 40 is provided, this means at least that the air connection opening 65 the front wall 40 penetrates, or that the air connection opening 65 is provided at a distal end of a projection extending from the front wall 40 in the insertion direction 56 extends, or that the air connection opening 65 is provided at a distal end of a projection extending from the front wall 40 in the removal direction 55 extends.

[Ink chamber 36 ]

With reference to the 1 and 3B is the ink chamber 36 in a first ink chamber 36A and a second ink chamber 36B partitioned. In this embodiment, the first ink chamber 36A from the front wall 40 positioned further than the first wall 45A , In other words, the first wall is 45A between the first ink chamber 36A and the front wall 40 positioned. In addition, the second ink chamber 36B closer to the front wall 40 positioned as the first wall 45A , In other words, the second ink chamber 36B between the first wall 45A and the front wall 40 positioned. The first ink chamber 36A and the second ink chamber 36B are in the insertion / removal direction 50 aligned and grasp the first wall 45A in between.

The first wall 45A has a connection opening 45C which is formed therethrough. The connection opening 45C extends in the depth direction 53 , In other words, the connection opening 45C on a straight line through the ink supply port 61 passes through and in the depth direction 53 (the removal direction 55 ). The diameter of the connection opening 45C is larger than the outer diameter of the hollow tube 102 , The connection opening 45C is in a lower half of the ink cartridge 30 positioned. A section of the first ink chamber 36A and a portion of the second ink chamber 36B are in an upper half of the ink chamber 30 positioned. Therefore, the portion of the first ink chamber 36A and the portion of the second ink chamber 36B over the connection opening 45C positioned. The ink cartridge 30 has a valve mechanism 70 , and the connection opening 45C is through the valve mechanism 70 optionally open and closed. When the connection opening 45C open, are the first ink chamber 36A and the second ink chamber 36B brought in such fluid communication that the ink from the first ink chamber 36A to the second ink chamber 36B through the connection opening 45C can flow.

The valve mechanism 70 has a movable element 71 and a biasing member such as a coil spring 72 , The movable element 71 has a cylindrical shape with a diameter that is larger than the diameter of the connection opening 45C , The movable element 71 is in the first ink chamber 36A arranged, that of the connection opening 45C in the depth direction 53 (the insertion direction 56 ) is opposite. The movable element 71 and the ink supply port 61 are in the depth direction 53 aligned. The movable element 71 is movable between a blocking position and a connecting position. When the movable element 71 at the blocking position is the movable element 71 with a section of the first wall 45A in contact with the connection opening 45C surrounds, and thereby the connection opening 45C closed. When the movable element 71 at the connection position is the movable element 71 from the section of the first wall 45A positioned at a distance from the connecting opening 45C surrounds, and thereby the connection opening 45C open. In this embodiment, the connection position is closer to the rear outside of the rear wall 41 as the blocking position. The coil spring 72 has a first end with that one in the insertion direction 56 directed surface of the frame 31 in the first ink chamber 36A is in contact, and a second end, with one in the removal direction 55 directed rear surface of the movable element 71 is in contact. The coil spring 72 is configured to be the movable element 71 in the insertion direction 56 to bias in the blocking position. The coil spring 72 is an example of a biasing member, and it may be replaced by a leaf spring, a plastic spring, etc.

Before the ink cartridge 30 to the cartridge mounting section 110 is mounted, ie, when the movable element 71 initially at the blocking position, stores the first ink chamber 36A a first initial amount of ink therein, and the second ink chamber 36B stores a second initial amount of ink therein. The second initial amount of ink may be zero, that is, the second ink chamber 36B does not have to store ink in it. The first initial amount of ink in the first ink chamber 36A has a first initial ink level, and the second initial amount of ink in the second ink chamber 36B has a second initial ink level when the second initial ink amount is not zero. The first initial ink level is positioned above the second initial ink level. The second ink chamber 36B has a space to fill with ink when the connection opening 45C is open. In this embodiment, the second initial amount is zero.

The second wall 45B has an opening 45D which is formed therethrough. The ink cartridge 30 has an air permeable film 75 standing at the second wall 45B is appropriate. The breathable film 75 covers the opening 45D from. The breathable film 75 allows air to pass through, but blocks the passage of a liquid. Therefore, the air between the first ink chamber 36A and the second ink chamber 36B through the opening 45D flow, but the flow of ink between the first ink chamber 36A and the second ink chamber 36B is through the opening 45D by means of the air-permeable film 75 blocked. The opening 45D and the breathable film 75 are above the first initial ink level in the first ink chamber 36A positioned. The breathable film 75 is a porous film, and is made of polytetrafluoroethylene, polychlorotrifluoroethylene, tetrafluoroethylene-hexafluoropropylene copolymer, tetrafluoroethylene-perfluoroalkylvinylether copolymer, tetrafluoroethylene-ethylene copolymer, or other known material.

[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 and an ASIC 135 that have an internal bus 137 connected to each other. The ROM 132 saves programs for the CPU 131 to control various operations of the printer 10 , The RAM 133 is used as a memory area for temporarily storing data and signals to be used by the CPU 131 when running the programs, and as a workspace for data processing. The EEPROM 134 stores settings and flags that can be held even after the power is turned off. A single chip can be the CPU 131 , the ROM 132 , the RAM 133 , the EEPROM 134 and the ASIC 135 or a single chip may be part of the CPU 131 , the ROM 132 , the ram 133 , the EEPROM 134 and the ASIC 135 and another chip can take the rest 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. More specifically, the control device 130 configured to the head control panel 21A To transmit control signals indicative of the values of the electrical drive voltages applied to the piezoelectric actuators 29A are to raise. 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 taken in such a way 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 to control a variety of 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 receive signals based on a temperature leave. 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. If the ink cartridge 30 in the cartridge mounting section 110 is inserted with reference to the 5A the ink supply port 61 through the movie 61A closed, and the connection opening 45C is through the movable element 71 closed, which is positioned in the blocking position. The sensor 103 gives the high level signal to the controller 130 off, and the mounting sensor 107 gives the low level signal to the controller 130 from.

If the ink cartridge 30 further into the cartridge mounting section 110 is inserted, penetrates and breaks the hollow tube 102 the movie 61A with reference to the 5B , and she enters the ink feed section 60 one. Then the hollow tube enters 102 through the connection opening 45C and pushes the movable element 71 in the removal direction 55 from the blocking position to the connecting position against the biasing force of the coil spring 72 , The rod 114 penetrates and breaks the film 65A , When this occurs, the ink flows out of the first ink chamber 36A into the hollow tube 102 through the opening on the side of the distal end of the hollow tube 102 is trained. In addition, the ink flows out of the first ink chamber 36A in the second ink chamber 36B through the gap between the connection opening 45C and the hollow tube 102 , Air enters the first ink chamber 36A and the second ink chamber 36B through the air connection opening 65 and the opening 45D ,

When assembling the ink cartridge 30 on the cartridge mounting portion 110 is completed, pushes the front wall 40 the ink cartridge 30 the mounting sensor 107 , When this occurs, the mounting sensor gives 107 the high level signal to the controller 130 from. Even if a flow of ink into the second ink chamber 36B from the first ink chamber 36A was started, the ink level in the second ink chamber 36B the height of the sensor 103 not reached, that is, it has not reached the detection position at a time immediately after the mounting of the ink cartridge 30 on the cartridge mounting portion 110 is completed. In a state of affairs in the 5B is shown, the sensor gives 103 therefore the high level signal to the controller 130 from. The ink level in the first ink chamber 36A moves down, and the ink level in the second ink chamber 36B moves up when the ink from the first ink chamber 36A to the second ink chamber 36B emotional. When the ink level in the second ink chamber 36B reaches the detection position, the sensor gives 103 with reference to the 5C the low level signal to the controller 130 from. In other words, the sensor gives 103 the detection signal based on an amount of ink from the first ink chamber 36A to the second ink chamber 36B has flowed. Finally, the height of the ink level in the first ink chamber 36A and the height of the ink level in the second ink chamber 36B equal.

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, is the closed cover 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 6 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 the low level signal from the mounting sensor 107 receives. In other words, the process of the 6 started when the cover of the cartridge mounting section 110 is open and the ink cartridge 30 eliminated.

The control device 130 Start measuring a transitional time at a step S2 when that of the mounting sensor 107 output detected signal from the low level signal to the high level signal changes (step S1: Yes). If that from the mounting sensor 107 When the detected detection signal does not change from the low level signal to the high level signal (step S1: No), the controller performs 130 the process of step S10 (described later). For example, the situation in which that of the mounting sensor 107 emitted detection signal is not from the low level signal to the high level Signal changes (step S1: No), a situation in which a new ink cartridge 30 not to the cartridge mounting section 110 was mounted.

Subsequently, the control device determines 130 at a step S3, 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 S3: Yes), the controller performs 130 the process of step S5 by (described later). If the elapsed time has not exceeded the maximum time (step S3: No), the controller determines 130 at step S4, whether that from the sensor 103 output signal changed from the high level signal to the low level signal. 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 S4: No), the controller performs 103 the process of step S3 again. If that from the sensor 103 When the detected detection signal has changed from the high level signal to the low level signal (step S4: Yes), the controller determines 103 the transitional time at step S5.

The transitional time is a period of time after a change in that of the mounting sensor 107 outputted detection signal from the low level signal to the high level signal (step S1: Yes) until a change of the from the sensor 103 outputted detection signal from the high level signal to the low level signal (step S4: Yes). In other words, the transitional time is a time necessary for the ink level in the second ink chamber 36B it is necessary to move between two points. In this embodiment, the transitional time is a time necessary for the ink level in the second ink chamber 46B is required to move from the zero-elevation point to the point corresponding to the detection position. In other words, the control device measures 130 the transitional period following the delivery of the high level signal from the mounting sensor 107 until delivery of the low level signal from the sensor 103 , If the elapsed time has exceeded the maximum time (step S3: Yes), the controller considers 103 the maximum time as the transitional period.

The situation where the elapsed time has exceeded the maximum time (step S3: Yes) corresponds to a situation in which the ink is very slowly discharged from the first ink chamber 36A to the second ink chamber 36B through the connection opening 45C flows, or in which they are not from the first ink chamber 36A to the second ink chamber 36B flows. One reason for the slow movement of the ink may be that the viscosity in the ink chamber 36 stored ink was high.

The timing at which the connection opening 45C is opened so that the first ink chamber 36A and the second ink chamber 36B through the connection opening 45C be brought into fluid communication, and the time at which the output signal from the mounting sensor 107 from the low level signal to the high level signal are equal or close to each other. Therefore, the latter date is assumed to be the first date. The control device 130 Measures a time for the ink level in the second ink chamber as the transition time 36B is required after changing the from the mounting sensor 107 to the output of the detection signal from the low level signal to the high level signal until reaching the detection position by the ink level. This transition time is assumed to be the time necessary for the ink level in the second ink chamber 46B is required to move from the zero-elevation point to the point corresponding to the detection position.

Subsequently, sets the control device 130 at a step S6 an error flag back, ie it sets the error flag to "OFF". The error flag is set to "ON" when the transition time is not within a threshold range (step S8: 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 the threshold range based on that of the temperature sensor 106 output signal in a step S7. The threshold range is compared to the transition time to the viscosity of the ink chamber 36 to estimate 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 the transition time determined at step S5 is the threshold range determined at step S7, and it determines at step S8 whether or not the transition time is within the threshold range. If the transitional time is below the lower limit, it is estimated that the viscosity of the ink is too low. If the transition time is above the upper limit, it is estimated that the viscosity of the ink is too high. If the transitional time is outside the threshold range (step S8: No), the controller sets 130 at a step S9, the error flag to "ON". If the transition time is within the threshold range (step S8: Yes), the controller skips 130 the process of step S9.

Subsequently, determine the control device 130 at step S10, if 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 open (step S10: No), the control device repeats 130 the process of step S1 and the processes following step S1. If it is determined that the cover is closed (step S10: Yes), the controller determines 130 at step S11, whether or not a predetermined time period has elapsed after it is determined at step S10 that the cover is closed.

If the predetermined time period has elapsed (step S11: Yes), the control device closes 130 the processes of 6 from. If the predetermined time has not elapsed (step S11: No), the control device repeats 130 the process of step S1 and the processes following step S1. If the control device 130 determines that the cover of the cartridge mounting portion 110 is open (step S10: No) when the control device 130 repeats the process of step S1 and the processes following step S1 clears the control device 130 the time count that was started when it was determined that the cover was closed (step S10: Yes).

After completing the processes of 6 leads the control device 130 the processes of 7 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 the high level signal is output. If the mounting sensor 107 outputs the low-level signal (step S21: No), informs the controller 130 a user in step S25 that the ink cartridge 30 is not mounted, and she completes the processes of 7 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 outputs the high level signal (step S21: Yes), the controller determines 130 at step S22, if the error flag is set to "ON". If the error flag is set to "ON" (step S22: Yes), the controller performs 130 the process of step S26. The control device 130 informs a user about the ink cartridge 30 at step S26, and then it completes the process of 7 from. The control device 130 can 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 S22: No), the controller determines 130 at step S23, if it takes an image recording command. If the control device 130 does not receive the image recording command (step S23: No), closes the control device 130 the processes of 7 from. If the control device 130 takes the image recording command (step S23: Yes), controls the control device 130 at a step S24 directly or indirectly the recording head 21 , the paper feed roller 23 , the feed roller pair 25 , the outlet roller pair 27 , etc., to record an image on a sheet of the recording paper. The control device 130 For example, an image may be recorded on a single sheet of the recording paper when the process of step S24 is performed once, or the control device 130 can record images according to all the image data that the controller 130 when it performs the process of step S24 once.

If the error flag is set to "ON" (step S22: Yes), the controller performs 130 the process of step S24, ie the image recording process, not through. In other words, the control device skips 130 Step S24, and thereby the ink consumption by the recording head 21 limited.

According to the processes of 6 if an ink cartridge 30 with a sufficient amount of ink stored therein from the cartridge mounting portion 110 is removed and then again on the cartridge mounting portion 110 is mounted, the error flag is set to "ON". This is because the ink is no longer from the first ink chamber 36A to the second ink chamber 36B is moved when the ink cartridge 30 on the cartridge mounting portion 110 is reassembled. In this situation, the image recording process of step S24 is skipped even if the ink cartridge 30 has a sufficient amount of ink. In another embodiment, the control device 130 Therefore, ask a user if he or she has the ink cartridge 30 has exchanged after step S22. 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 can then wait for a signal from an input interface (not shown) from the printer 10 comes. For example, the input interface is an interface to which a user commands the printer 10 can give by pressing buttons on it. If the control device 130 from the input interface receives a signal indicating that the ink cartridge 30 has not been replaced, the control device 130 does not perform the process in step S26, and performs the process in step S24. In such a case, by the control device 130 performed processes of those of 6 and 7 but their description is omitted here.

[Advantages]

According to the embodiment described above, the flow rate of the ink extending from the first ink chamber changes 36A to the second ink chamber 36B moves, depending on the viscosity of the ink. By measuring the transient time required for the ink level in the second ink chamber 36B is necessary after opening the connection opening 45C can move until the ink level reaches 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.

The amount (volume) of the second ink chamber 36B Namely, the stored ink is constant while the ink level in the second ink chamber 36B moved between the two points. (As described above, the two points are the zero-height point and the point corresponding to the detection position.) Therefore, the flow rate of the ink, that is, an amount (volume) of the ink passing through the communication port 45C can be specified by measuring the transition time in which the ink level in the second ink chamber 36B moved between the two points. 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 for a long time. In addition, if a variety of ink cartridges 30 storing inks of different viscosities is configured to be on the same cartridge mounting portion 110 To be mounted, it is possible to determine which ink cartridge 30 is mounted by calculating the transitional time.

In the embodiment described above, the ink level becomes in the second ink chamber 36B through the sensor 103 detected. In another embodiment, the ink level in the first ink chamber 36A through the sensor 103 be recorded. In such a case, the sensor is 103 below the first initial ink level of the first initial amount of ink in the first ink chamber 36A positioned before the connection opening 45C is opened. The control device 103 measures as the transition time a time after a change in the detection signal of the mounting sensor 107 from the low level signal to the high level signal to a change in the detection signal of the sensor 103 from the low level signal to the high level signal.

In the embodiment described above, the control device starts 130 the measurement of the transitional time at a time when mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed, ie the detection signal from the mounting sensor 107 changes from the low level signal to the high level signal. Nonetheless, the timing at which the control device 103 the measurement of the transitional period starts, but is not limited to, and may be any arbitrary time. For example, the timing may be a certain time after the mounting of the ink cartridge 30 on the cartridge mounting portion 110 is completed, or a specific time just before mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed.

In the embodiment described above, the time after the opening of the connection opening becomes 45C until reaching the detection position by the ink level measured as the transition time. Nevertheless, the transitional period is not limited to this. For example, the cartridge mounting portion 110 a first optical sensor and a second optical sensor, in the height direction 52 are positioned spaced apart, and the first and the second optical sensor are the second ink chamber 36B the ink cartridge 30 opposite to the cartridge mounting portion 110 is mounted. The control device 130 may be a time after reaching the first optical sensor by the ink level in the second ink chamber as the transitional time 36B until reaching the second optical sensor by the ink level. In other words, the transitional time is a time necessary for the ink level in the second ink chamber 36B it is necessary to move between two points.

The transition time is an example of a physical quantity that can be used to specify the throughput rate of the ink. Nonetheless, the example of the physical quantity is not limited to the transition time. For example, a rotator in the first ink chamber 36A or the second ink chamber 36B be arranged. The rotator is configured to move in accordance with the movement of the ink from the first ink chamber 36A to the second ink chamber 36B to turn. The cartridge mounting section 110 may include a detector configured to detect the rotation of the rotator. The control device 130 For example, as the transition time, it may measure the number of revolutions of the rotator within a predetermined time, or it may measure a time required for the rotator to turn by a predetermined number.

In the embodiment described above, the pressure in the first ink chamber 36A and the pressure in the second ink chamber 36B that is, they become the atmospheric pressure through the air communication port 65 and the connection opening 45C , Therefore, the flow rate of the ink extending from the first ink chamber 36A to the second ink chamber 36B moved, not by a pressure differential between the pressure in the first ink chamber 36A and the pressure in the second ink chamber 36B affected. Like the first ink chamber 36A and the second ink chamber 36B is to be associated with the atmosphere is not limited to the manner described in the embodiment described above. In addition, the first ink chamber 36A and the second ink chamber 36B not necessarily be brought into contact with the atmosphere.

According to the embodiment described above, the control device limits 130 the function of the recording head 29 that is, it skips step S24 if the transition time is outside the threshold range (step S8: 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 S24. In another embodiment, the process of step S26 may be performed, in which the information about the ink cartridge is provided to a user 30 to be notified if the error flag is set to "ON" (step S22: Yes), but the control device 130 can let the user decide whether to record an image. In such a case, by the control device 130 performed processes of those of 6 and 7 but their description is omitted here.

In addition, in another embodiment, steps S23 and S24 need not be skipped if the error flag is set to "ON" (step S22: Yes), 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 S24. More specifically, the control device outputs 130 Signals to the head control plate 21A such that the on the piezoelectric actuators 29A applied electrical drive voltages are adjusted for those quantities of ink coming from the nozzles 29 are ejected to be the same amount 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 driving electric voltages when the transition time is within the threshold range. If the transition time is above the upper threshold of the threshold range (it is assumed that the viscosity of the ink is too high), the electrical drive voltages will be made larger than those electrical drive voltages where the transition time is within the threshold range. If in this case a variety of ink cartridges 30 storing inks of different viscosities is configured to be on the same cartridge mounting portion 110 It is possible to mount the piezoelectric actuators 29A to drive with appropriate voltages according to the types of ink. The actuators are not on the piezoelectric actuators 29A limited, but they can be thermal actuators, the ink from the nozzles 29 By applying heat to the ink, bubbles are generated 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 set, 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 S22: Yes), the control device may 130 control the purging operation so that the ink is discharged, wherein an even higher pressure is applied to them than when the control device 130 determines that the error flag is set to "OFF" (step S22: 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 with a larger suction pressure if the error flag is set to "ON". By this control, air bubbles or thickened ink in the recording head 21 by the flushing operation, even when the viscosity of the ink is high, and the ink can be discharged from the ink tube 20 reliably 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.

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. When the temperature is high, the controller gives 130 more precisely, 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 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 range based on the temperature at step S7. How to determine the threshold range is not limited to a specific way, but the control device 130 may select an appropriate threshold range based on the temperature of many threshold ranges included in the ROM 132 or may calculate the upper limit or lower limit of the threshold range as a function of the temperature value. Nevertheless, the step S7 for determining the threshold range based on the temperature may be eliminated, and at a step S8, a fixed threshold range may be used, for example, when applied to the piezoelectric actuators 29A applied electrical drive voltages can not be adjusted on the basis of temperature.

Like the connection opening 45C , the ink supply port 61 and the air connection opening 65 to be opened and closed is not limited to the manner described in the embodiment described above. For example, the connection opening 65 be closed by a breakable wall, and the hollow tube 102 may penetrate and break the frangible wall such that the first ink chamber 36A and the second ink chamber 36B be brought into fluid communication. The ink supply port 61 and the air connection opening 65 can each be controlled by a valve mechanism such as the valve mechanism 70 getting closed. The air connection opening 65 may be closed by an air-permeable film such that the ink chamber 36 associated with the atmosphere before the ink cartridge 30 to the cartridge mounting section 110 is mounted.

According to the embodiment described above, the control device stores 130 the error flag into the EEPROM 134 but the control device 130 may store the error flag into 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 6 and 7 perform by reading out a program stored in the ROM 132 is stored. In contrast, the control device needs 130 the CPU 131 not and it can only be hardware for example like the ASIC 135 or have an FPGA. In addition, the control device 130 many CPU's 131 and / or many ASIC's 135 exhibit.

With reference to the 8A to 17B A first to seventh modified embodiment will be described. Descriptions of those parts between the above-described embodiment and the first to may be omitted in the seventh modified embodiment, but the parts of the first modified embodiment, which are different from the parts of the other embodiments will be described. In addition, the parts of the above-described embodiment and the first to seventh modified embodiments may be arbitrarily combined as long as the object of the invention is achieved.

<First Modified Embodiment>

With reference to the 8A to 8C become an ink cartridge 30 and a cartridge mounting section 110 described according to the first modified embodiment. The partition 45 the ink cartridge 30 according to this first modified embodiment extends substantially parallel to the front wall 40 and the back wall 41 and she is with the upper wall 39 and the bottom wall 42 connected. The air connection opening 65 the ink cartridge 30 According to this first modified embodiment is configured to the second ink chamber 46B with the atmosphere outside the ink cartridge 30 to bring into fluid communication. The movable element 71 the ink cartridge 30 According to this first modified embodiment is in the second ink chamber 36B positions and closes the connection opening 45C from the side of the second ink chamber 36B , Before the ink cartridge 30 to the cartridge mounting section 110 is mounted, the pressure in the first ink chamber 36A maintained at a first pressure which is greater than the atmospheric pressure, and the pressure in the second ink chamber 36B is maintained at a second pressure that is greater than the first pressure.

With reference to the 8A is the movable element 71 on a section of the partition 45 in contact with the connection opening 45C due to the pressure differential between the pressures in the first ink chamber 36A and the second ink chamber 36B , and thereby becomes the connection opening 45C closed. In other words, the movable element 71 at the blocking position. With reference to the 8B when the rod 114 the movie 65A Penetrates and breaks and thereby the air connection opening 65 is opened, the second ink chamber 36B with the atmosphere through the air connection opening 65 connected. As a result, the movable element moves 71 from the partition 45 away to the connection opening 45C to open. In other words, the movable element moves 71 to the connection position. Ink flows out of the first ink chamber 36A to the second ink chamber 36B through the connection opening 45C , With reference to the 8C when the ink level in the second ink chamber 36B reaches the detection position, the sensor gives 103 the low level signal to the controller 130 from. Part of the ink in the second ink chamber 36B flows into the ink tube 20 through the hollow tube 102 ,

According to this first modified embodiment, the connection opening 45C passing through the dividing wall 45 is formed through the pressure differential between the pressure in the first ink chamber 36A and the pressure in the second ink chamber 36B opened and closed. Therefore, the number of parts of the ink cartridge 30 be reduced. In another embodiment, the pressure in the first ink chamber 36A greater than the pressure in the second ink chamber 36B before the ink cartridge 30 to the cartridge mounting section 110 is mounted, and the movable element 71 can be in the first ink chamber 36A be positioned and the connection opening 45C from the side of the first ink chamber 36A shut down.

<Second Modified Embodiment>

With reference to the 9 and 11C become an ink cartridge 30 and a cartridge mounting section 110 described according to the second modified embodiment. With reference to the 9 extends the partition 45 essentially parallel to the top wall 39 and the bottom wall 42 and she is with the front wall 40 and the back wall 41 connected. The partition 45 partitioned the ink chamber 36 in the first ink chamber 36A and the second ink chamber 36B in terms of height direction 52 , The first ink chamber 36A and the second ink chamber 36B are in the height direction 52 aligned, taking the dividing wall 45 between them. The second ink chamber 36B is further from the upper wall 39 positioned as the first ink chamber 36A , Before the ink cartridge 30 to the cartridge mounting section 110 is mounted, stores the first ink chamber 36A therein a first initial amount of ink, and the second ink chamber 36B stores therein a second initial amount of ink. In this second modified embodiment, the second initial ink amount is zero, that is, the second ink chamber 36B does not store ink in it. The ink feed section 60 is on the front wall 40 provided at a position with the second ink chamber 36B in the depth direction 53 is aligned. The air connection opening 65 is on the front wall 40 provided at a position with the first ink chamber 36A in the depth direction 54 is aligned.

With reference to the 9 has the front wall 40 the ink cartridge 30 according to this second modified embodiment, a first opening 40A and a second opening 40B passing through it in the depth direction 53 are formed. The first opening 40A is with the first ink chamber 36A in the insertion direction 56 aligned, and therefore the first opening 40A the first ink chamber 36A with the outside of the ink cartridge 30 bring in a fluid connection. The second opening 40B is with the second ink chamber 36B in the insertion direction 56 aligned, and therefore the second opening 40B the second ink chamber 36B with the outside of the ink chamber 30 bring in a fluid connection. With reference to the 11A becomes the first opening 40A through a breakable wall such as a movie 40C closed, and the second opening 40B is through a breakable wall like a movie 40D closed.

With reference to the 10 has the cartridge mounting section 110 According to this second modified embodiment, a hollow tube 115 , The hollow tube 115 is at the end face of the mount 101 over the hollow tube 102 intended. The hollow tube 115 has a U-shape with a first end 115A and a second end 115B , The first end 115A extends from the end face of the enclosure 101 in the removal direction 55 at a position corresponding to the first opening 40A the ink cartridge 30 , The second opening 115B extends from the end face of the enclosure 101 in the removal direction 55 at a position corresponding to the second opening 40B the ink cartridge 30 , The interior of the hollow tube 115 opens to the outside at the first end 115A and the second end 115B ,

With reference to the 11B if the ink cartridge 30 on the cartridge mounting portion 110 is mounted, penetrates and breaks the first end 115A the movie 40C and then enters the first ink chamber 36A through the first opening 40A one. The film 40C has elasticity, and it can be a rubber film, for example. If the first end 115A through the movie 40C is inserted, the film arrives 40C with the outer surface of the first end 115A in a close contact. If the ink cartridge 30 on the cartridge mounting portion 110 is mounted, penetrates and breaks the second end 115B similarly the movie 40D and then enters the second ink chamber 36B through the second opening 40B one. The film 40D has elasticity, and it can be, for example, a rubber film. If the second end 115B through the movie 40D is inserted, the film arrives 40D with the outer surface of the second end 115B in a close contact. As a result, the first ink chamber become 36A and the second ink chamber 36B over the hollow tube 115 brought into fluid communication with each other. The in the first ink chamber 36A stored ink flows into the second ink chamber 36B through the hollow tube 115 , and the ink flows out of the second ink chamber 36B into the hollow tube 102 through the ink feed section 60 , If the hollow tube 115 of the movie 40C and 40D is eliminated, the openings in the film 40C and 40D By penetrating the hollow tube 115 were formed by the elasticity of the film 40C and 40D getting closed.

The sensor 103 of the cartridge mounting section 110 According to this second modified embodiment, it is positioned to be the first ink chamber 36A the ink cartridge 30 which is mounted on the cartridge mounting portion. With reference to the 11A and 11b is the sensor 103 more specifically, under the first initial ink level in the first ink chamber 36A positioned before the first ink chamber 36A with the second ink chamber 36B is brought into fluid communication. With reference to the 11C is the sensor 103 above the ink level in the first ink chamber 36A positioned when the second ink chamber 36B filled with ink.

If the ink cartridge 30 on the cartridge mounting portion 110 is mounted and the sensor 103 the first ink chamber 36A is opposite, that changes from the sensor 103 output detection signal from the high level signal to the low level signal. When the ink level in the first ink chamber 36A below the detection position, subsequently changes from the sensor 103 output detection signal from the low level signal to the high level signal. The control device 103 measures as the transitional period a time after a change of the sensor 103 outputted detection signal from the high level signal to the low level signal to a change of the from the sensor 104 outputted detection signal from the low level signal to the high level signal.

The timing at which the first ink chamber 36A and the second ink chamber 36B through the hollow tube 115 be brought into fluid communication with each other, and the time at which the sensor 103 When the detected detection signal changes from the high level signal to the low level signal, they are equal to or close to each other. Therefore, the latter date is assumed to be the first date. Therefore, the by the control device 103 measured transition time as a time after bringing the first ink chamber 36A and the second ink chamber 36B in fluid communication through the hollow tube 115 up to a change of the from the sensor 103 output detected signal from the low level signal to the high level signal.

According to this second modified embodiment, there is no need for a path in the ink cartridge 30 provide to the first ink chamber 36A with the second ink chamber 36B to bring into fluid communication, and the structure of the ink cartridge 30 can be simplified. It is preferable to the first opening 40A near the partition 45 to position, for example, at a lower portion of the first ink chamber 36A , and it is preferable to the second opening 40B above the ink feed section 60 to position. As a result, the ink can be consumed efficiently.

In another embodiment, the first opening 40A and the second opening 40B each by a valve mechanism similar to the valve mechanism instead of the films 40C and 40D getting closed. If the ink cartridge 30 on the cartridge mounting portion 110 is mounted, press the first end 115A and the second end 115B the hollow tube 115 each of the movable member of the valve mechanism against the biasing force of the biasing member to the first opening 40A and the second opening 40B to open.

Even if in this second modified embodiment of the mounting sensor 107 can be eliminated, the cartridge mounting section 110 the mounting sensor 107 exhibit. In such a case, the control device 103 as the transitional period, a time after a change of the from the mounting sensor 107 outputted detection signal from the low level signal to the high level signal to a change of the from the sensor 103 output detected signal from the low level signal to the high level signal.

In the 9 and 11A to 11C There is no structure that is pictured to the second ink chamber 36B into fluid communication with the atmosphere. Air in the second ink chamber 36B allowed in the hollow tube 102 stream. Additionally or alternatively, the ink cartridge 30 have a path to the second ink chamber 36B into fluid communication with the atmosphere.

<Third Modified Embodiment>

With reference to the 12 and 13C become an ink cartridge 30 and a cartridge mounting section 110 described according to the third modified embodiment. With reference to the 12 extends the partition 45 essentially parallel to the top wall 39 and the bottom wall 42 and she is with the front wall 40 and the back wall 41 connected. The partition 45 partitioned the ink chamber 36 in the first ink chamber 36A and the second ink chamber 36B in terms of height direction 52 , The first ink chamber 36A and the second ink chamber 36B are in the height direction 52 aligned, taking the dividing wall 45 between them. The second ink chamber 36B is further from the upper wall 39 positioned as the first ink chamber 36A , Before the ink cartridge 30 to the cartridge mounting section 110 is mounted, stores the first ink chamber 36A a first initial amount of ink therein, and the second ink chamber 36B stores a second initial amount of ink therein. In this second modified embodiment, the second initial ink amount is zero, that is, the second ink chamber 36B does not store ink in it. The ink feed section 60 is on the front wall 40 provided at a position with the second ink chamber 36B in the depth direction 53 is aligned. The air connection opening 65 is on the front wall 40 provided at a position with the first ink chamber 36A in the depth direction 53 is aligned.

The connection opening 45C the ink cartridge 30 according to this third modified embodiment extends through the partition wall 45 in the height direction 52 , The connection opening 45C is through a lock 80 closed. The closure 80 consists of a material that can be destroyed by ultrasound irradiation. For example, the shutter 80 a metal film or plastic, and its thickness, ie the dimension in the height direction 52 , may be smaller than the thickness of the partition 45 , If the shutter 80 is irradiated with ultrasonic waves, cavitation occurs around the shutter 80 on, and thereby becomes the shutter 80 destroyed.

With reference to the 13A to 13C has the cartridge mounting section 110 an ultrasonic irradiation device 116 facing the ink cartridge 30 positioned on the cartridge mounting portion 110 is mounted. When the ultrasonic irradiation device 116 a destruction signal from the control device 130 receives, irradiates the ultrasonic irradiation device 116 the lock 80 with ultrasonic waves. When this occurs, the shutter becomes 80 destroyed, and the first ink chamber 36A and the second ink chamber 36B be through the connection opening 45C placed in a fluid connection. When the ink level in the first ink chamber 36A below the detection position, subsequently changes from the sensor 103 output detection signal from the low level signal to the high level signal. The control device 130 measures as the transitional time a time after the discharge of the destruction signal by the control device 130 to the ultrasonic irradiation device 116 up to a change of the from the sensor 103 outputted detection signal from the low level signal to the high level signal.

The timing at which the first ink chamber 36A and the second ink chamber 36B through the connection opening 45C be brought into fluid communication with each other, and the timing at which the control device 130 the destruction signal to the ultrasonic irradiation device 116 give, are the same or are close to each other. Therefore, the latter date is assumed to be the first date. Therefore, the by the control device 130 measured transition time as a time after bringing the first ink chamber 36A and the second ink chamber 36B in a fluid connection through the connection opening 45C up to a change of the from the sensor 103 output detected signal from the low level signal to the high level signal.

According to this third modified embodiment, the measurement of the transitional time is started when the control device 130 the destruction signal to the ultrasonic irradiation device 116 so that the transitional period can be measured more accurately. The material of the closure 80 is not limited to that configured to be destroyed by ultrasonic irradiation. For example, the shutter 80 Made of a material that can be destroyed by heat. In such a case, the material of the closure has 80 a melting point less than the melting point of the material of the frame 31 , For example, the frame exists 31 polyethylene terephthalate (PET), and the closure 80 consists of polypropylene (PP). The ultrasound irradiation device 160 is replaced by a heater.

In the third modified embodiment, the first ink chamber 36A and the second ink chamber 36B brought into fluid communication after mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed. In the embodiment described above, the first modified embodiment and the second modified embodiment, on the other hand, the first ink chamber 36A and the second ink chamber 36B brought into fluid communication when or just before mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed. The timing at which the first ink chamber 36A and the second ink chamber 36B be brought into fluid communication is not limited to a specific time.

<Fourth Modified Embodiment>

With reference to the 14A and 14B becomes an ink cartridge 30 described according to the fourth modified embodiment. The front wall 40 the ink cartridge 30 has an opening 400 in the depth direction 53 is formed therethrough. The opening 400 is closer to the top of the front wall 40 as at the lower end of the front wall 40 positioned. The ink cartridge 30 has an air permeable film 400A , which is at the front outside of the front wall 40 attached to the opening 400 cover. The second ink chamber 36B is with the atmosphere outside the ink cartridge 30 through the opening 400 and the breathable film 400A in an air connection.

The upper wall 39 the ink cartridge 30 has an opening 390 in the height direction 52 is formed therethrough. The ink cartridge 30 has an air permeable film 390A which is at the upper outside of the upper wall 39 attached to the opening 390 cover. The first ink chamber 36A is with the atmosphere outside the ink cartridge 30 through the opening 390 and the breathable film 390A in an air connection.

The ink cartridge 30 has a valve element 710 that is between one in the 14A shown closed position and one in the 14B shown opened position in the depth direction 53 is movable. When the valve element 710 is at the closed position, is the valve element 710 in contact with a wall that houses the ink supply port 61 surrounds, and thereby is the ink supply port 61 closed. When the valve element 710 in the open position, is the valve element 710 Positioned spaced from the wall, the ink feed opening 61 surrounds, and thereby is the ink supply port 61 open. The ink cartridge 30 has a connection section 711 that extends from the valve element 710 to the movable element 71 in the depth direction 53 extends, and the movable element 71 is with the valve element 710 through the connecting section 711 connected. The coil spring 72 clamps the movable element 71 in the blocking position, and it also biases the valve element 710 in the closed position over the connecting portion 711 like this in the 14A is shown.

With reference to the 14B if the hollow tube 102 through the ink supply port 61 is inserted, is the hollow tube 102 with the valve element 710 and pushes it, and it also pushes the movable element 71 over the connecting section 711 , When this occurs, the valve element moves 710 to the open Position, and at the same time moves the movable element 71 to the connection position. Ink flows out of the first ink chamber 36A in the second ink chamber 36B through the connection opening 45C , and she flows into the hollow tube 102 ,

In this embodiment, the second initial amount of ink is in the second ink chamber 36B not zero, before the ink cartridge 30 with reference to the 14A to the cartridge mounting section 110 is mounted, ie, when the movable element 71 at the blocking position, and the first initial ink level of the first initial ink amount in the first ink chamber 36A is above the second initial ink level of the second initial ink amount in the second ink chamber 36B positioned. Nonetheless, in another embodiment, the second initial amount of ink may be zero. The ink level in the first ink chamber 36A moves down, and the ink level in the second ink chamber 36B moves up when the ink is out of the first ink chamber 36A to the second ink chamber 36B emotional. Finally, the height of the ink level in the first ink chamber 36A and the height of the ink level in the second ink chamber 36B same as this in the 14B is shown.

<Fifth Modified Embodiment>

With reference to the 15A and 15B becomes an ink cartridge 30 described according to a fifth modified embodiment. The ink cartridge 30 According to this fifth modified embodiment, it is similar to the ink cartridge 30 according to the fourth modified embodiment, but it does not have the movable element 71 and the coil spring 72 ,

The ink cartridge 30 has a breakable wall like a movie 740 which is mounted on the wall which connects the connection 45C surrounds to the connection opening 45C close. The ink supply port 61 extends in the depth direction 53 , and the ink supply port 61 and the movie 740 are in the depth direction 53 aligned. The ink cartridge 30 has a biasing element such as a coil spring 730 that is between the wall, which is the connection opening 45C surrounds, and the valve element 710 is positioned. The coil spring 730 clamps the valve element 710 in the closed position in front.

The ink cartridge 30 has a sharp element 720 extending from the valve element 710 to the movie 740 extends. The pointed element 720 is between one in the 15A shown rest position and one in the 15B shown breaking position movable. When the pointed element 720 Moves from the rest position to the breaking position, penetrates and breaks the pointed element 720 the movie 740 so as to open the connection opening 45C to open. When the valve element 710 is at the closed position, the pointed element is at the rest position. When the valve element 710 at the open position, the pointed element is at the breaking position.

With reference to the 15B if the hollow tube 102 through the ink supply port 61 is inserted, is the hollow tube 102 with the valve element 710 and the pointed element 720 in contact and presses this. When this occurs, the valve element moves 710 to the open position, and at the same time the pointed element moves to the breaking position. Ink flows out of the first ink chamber 36A in the second ink chamber 36B through the connection opening 45C , and she flows into the hollow tube 102 ,

The ink cartridge 30 must the valve element 710 and the pointed element 720 not have. In such a case, the ink cartridge 30 the movie 61A to the ink supply port 61 to close as in the embodiment described above. If the hollow tube 102 through the movie 61A and the ink supply port 61 is inserted, penetrates and breaks the hollow tube 102 the movie 740 so as to open the connection opening 45C to open.

<Sixth modified embodiment>

With reference to the 16A and 16B becomes an ink cartridge 30 described according to a sixth modified embodiment. The ink cartridge 30 According to this sixth modified embodiment is similar to the ink cartridge 30 according to the fourth modified embodiment or the ink cartridge 30 according to the fifth modified embodiment, but it has a reflection element 800 that over a section of the upper wall 39 is positioned, which is the second ink chamber 36B Are defined.

The reflection element 800 has a first reflection surface 801 and a second reflection surface 802 , each in the depth direction 53 extend. The first reflection surface 801 and the second reflection surface 802 each have an aluminum film formed thereon by sputtering or non-electrolytic coating. If the ink cartridge 30 on the cartridge mounting portion 110 is mounted, is the reflection element 800 between the light emitting section 104 and the light-receiving portion 105 positioned. The first reflection surface 801 is regarding the width direction 51 and the height direction 52 inclined so that light coming from the light-emitting section 104 is sent out and in the width direction 52 migrates, at the first reflection surface 801 down and to the section of the upper wall 39 which reflects the second ink chamber 36B Are defined. The second reflection surface 802 is in the width direction 51 and the height direction 52 inclined so that light coming from the section of the upper wall 39 migrates the second ink chamber 36B defined on the second reflection surface 802 in the width direction 51 to the light-receiving portion 105 is reflected. The first reflection surface 801 and the second reflection surface 802 are symmetric with respect to a plane parallel to the height direction 52 and the depth direction 53 is. The first reflection surface 801 and the second reflection surface 802 are arranged in a V-shape.

The section of the upper wall 39 , the second ink chamber 36B is defined, consists of a material that allows the passage of light there, such as polypropylene plastic, acrylic plastic, polycarbonate plastic, glass, etc. In other words, the section of the upper wall 39 , the second ink chamber 36B defined, translucent. The section of the upper wall 39 , the second ink chamber 36B defined, has a first inclined surface 39A and a second inclined surface 39B , The first inclined surface 39A and the second inclined surface 39B extend in the depth direction 53 and are in the width direction 51 and the height direction 52 inclined. The first inclined surface 39A and the second inclined surface 39B are symmetric with respect to a plane parallel to the height direction 52 and the depth direction 53 is. The first inclined surface 39A and the second inclined surface 39B are arranged in a V-shape. The upper outer surface of the section of the upper wall 39 , the second ink chamber 36B defined extends in the width direction 51 and the depth direction 53 ,

The first inclined surface 39A and the second inclined surface 39B each have a first reflectance R1 for light passing through the top wall 39 when passing with the ink in the second ink chamber 36B are not in contact, and they each have a second reflectance R2 for light passing through the top wall 39 when passing with the ink in the second ink chamber 36B are in contact. The first reflectance R1 and the second reflectance R2 are different. Because the difference between the refractive index of air and the refractive index of the upper wall 39 is relatively large when the first inclined surface 39A and the second inclined surface 39B not in contact with ink, but with air in the second ink chamber 36B In contact, the light is for the most part at the first inclined surface 39A and the second inclined surface 39B reflected. In other words, the first reflectance R1 is relatively large. On the other hand, there is the difference between the refractive index of the ink and the refractive index of the upper wall 39 is relatively small when the first inclined surface 39A and the second inclined surface 39B are in contact with the ink, the light for the most part passes through the first inclined surface 39A and the second inclined surface 39B therethrough. In other words, the second reflectance R2 is relatively low.

With reference to the 16A , right after mounting the ink cartridge 30 on the cartridge mounting portion 110 is completed, the ink has the first inclined surface 39A and the second inclined surface 39B not reached. Light coming from the light-emitting section 104 is sent out, wandering in the width direction 51 to the first reflection surface 801 , The light is at the first reflection surface 801 reflects and moves in the height direction 52 downward. The light then enters the upper wall 39 and moves to the first inclined surface 39A , The light will then be on the first inclined surface 39A reflected because the first inclined surface 39A with the ink is not in contact. The light then travels in the width direction 51 to the second inclined surface 39B , The light then becomes at the second inclined surface 39B reflects because the second inclined surface is not in contact with the ink. The light then moves in the height direction 52 up and coming out of the top wall 39 , The light then becomes at the second reflection surface 802 reflects and wanders in the width direction 51 to the light-receiving portion 105 , The light-receiving section 105 picks up the light, and the sensor 103 returns the high level signal. The path of light is in the 16A represented by arrows.

With reference to the 16B when the ink is from the first ink chamber 36A to the second ink chamber 36B moves, the ink level moves in the second ink chamber 36B upwards and gets to the first inclined surface 39A and the second inclined surface 39B in contact. Light coming from the light-emitting section 104 is sent out, wandering in the width direction 51 to the first reflection surface 801 , The light is at the first reflection surface 801 reflects and moves in the height direction 52 downward. The light then enters the upper wall 39 and moves to the first inclined surface 39A , The light then passes for the most part through the first inclined surface 39A in the second ink chamber 36B because the first inclined surface 39A is in contact with the ink. Little or no light reaches the light-receiving section 105 , The sensor 103 returns the low level signal. The path of light is in the 16B represented by arrows. In this sixth modified embodiment, the position at which the first inclined surface 39A and the second inclined surface 39B are located, a collection item.

In this sixth modified embodiment, the difference in the refractive index determines whether or not light is reflected. Therefore, the ink does not have to block the light, but it can allow the light to pass therethrough.

<Seventh Modified Embodiment>

With reference to the 17A and 17B becomes an ink cartridge 30 described according to a seventh modified embodiment. The ink cartridge 30 According to this seventh modified embodiment is similar to the ink cartridge 30 according to the sixth modified embodiment, but it may be a photoconductive member 900 instead of the reflection element 800 exhibit.

The light-conducting element 900 is configured to direct the light to the portion of the top wall 39 to guide the second ink chamber 36B Are defined. The light-conducting element 900 has a first photoconductive plate 901 and a second photoconductive plate 902 , each in the depth direction 53 extend. The first photoconductive plate 901 and the second photoconductive plate 902 are each made of a material that allows light to pass therethrough, such as polypropylene plastic, acrylic plastic, polycarbonate plastic, glass, etc. When the ink cartridge 30 on the cartridge mounting portion 110 is mounted, is the light-conducting element 900 between the light emitting section 104 and the light-receiving portion 105 positioned. The first photoconductive plate 901 and the second photoconductive plate 902 are in the width direction 51 and the height direction 52 inclined. The first photoconductive plate 901 and the second photoconductive plate 902 are symmetric with respect to a plane parallel to the height direction 52 and the depth direction 53 , The first photoconductive plate 901 and the second photoconductive plate 902 are arranged in a V-shape. The lower ends of the first photoconductive plate 901 and the second photoconductive plate 902 are with the upper outer surface of the section of the upper wall 39 connected to the second ink chamber 36B Are defined. Preferably, the first photoconductive plate 901 and the second photoconductive plate 902 integral with the upper wall 39 educated.

The section of the upper wall 39 , the second ink chamber 36B defined, has an inner surface 39C that of the second ink chamber 36B opposite. The inner surface 39C extends in the width direction 51 and the depth direction 53 , The inner surface 39C has the first reflectance R1 for light passing through the top wall 39 when passing with the ink in the second ink chamber 36B is not in contact, and it has the second reflectance R2 for the light passing through the top wall 39 passing through there when they are with the ink in the second ink chamber 36B in contact, similar to the first inclined surface 39A and the second inclined surface 39B in the sixth modified embodiment.

Immediately after mounting the ink cartridge 30 on the cartridge mounting portion 110 completed, the ink has reference to the 17A the inner surface 39C not reached. Light coming from the light-emitting section 104 is sent out, wandering in the width direction 51 and enters the first photoconductive plate 901 from the upper end of the first photoconductive plate 901 one. The light then travels in the photoconductive plate 901 sloping down to the top wall 39 , The light then enters the upper wall 39 and wanders to the inner surface 39C , The light is then on the inner surface 39C reflected, because the inner surface 39C with the ink is not in contact. The light then moves to the top wall 39 and in the second photoconductive plate 902 diagonally upwards. The light then comes from the second photoconductive plate 902 from the upper end of the photoconductive plate 902 and moves in the width direction 51 to the light-receiving portion 105 , The light-receiving section 105 picks up the light, and the sensor 103 returns the high level signal. The path of light is in the 17A represented by arrows.

With reference to the 17B when the ink is out of the first ink chamber 36A to the second ink chamber 36B moves, the ink level moves in the second ink chamber 36B upwards and gets to the inner surface 39C in contact. Light passing through the light-emitting section 104 is sent out, wandering in the width direction 51 and enters the first photoconductive plate 901 from the upper end of the first photoconductive plate 901 one. The light then travels in the photoconductive plate 901 sloping down to the top wall 39 , The light then enters the upper wall 39 and wanders to the inner surface 39C , The light then for the most part passes through the inner surface 39C through into the second ink chamber 36B because the inner surface 39C is in contact with the ink. Little or no light reaches the light-receiving section 105 , The sensor 103 returns the low level signal. The path of light is in the 17B represented by arrows. In this seventh modified embodiment, the position at which the inner surface 39C is located, a detection position.

In the embodiment described above and the first to seventh modified embodiment, 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.

In the above-described embodiment and the first to seventh 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 may be attached to the cartridge mounting portion 110 be provided. In the automatic loading mechanism, for example, a user needs the ink cartridge 30 only halfway into the cartridge mounting section 110 insert. 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 movement of the ink level can not detect, even if the first ink chamber 36A and the second ink chamber 36B be brought into fluid communication with each other.

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 changes and modifications of the structures and embodiments described above can be made without departing from the scope of the invention. Other structures and embodiments will become apparent to those skilled in the art upon consideration of the specification 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 (15)

Liquid consumption device comprising: a liquid cartridge ( 30 ), comprising: a first liquid chamber ( 36A ) configured to store a liquid therein; a second liquid chamber ( 36B ) configured to store the liquid therein; and a liquid feed opening ( 60 ) configured to remove the liquid from the first liquid chamber ( 36A ) and the second fluid chamber ( 36B ) to an outside of the liquid cartridge; a cartridge mounting section ( 110 ) configured to charge the liquid cartridge ( 30 ) take up; a liquid consumption section ( 21 ) configured to consume the liquid passing through the liquid feed port ( 60 ) from the liquid cartridge ( 30 ) supplied to the cartridge mounting portion (FIG. 110 ) is mounted; a connector configured to receive the first fluid chamber ( 36A ) with the second liquid chamber ( 36B ) to bring into fluid communication; a detector ( 103 ) configured to emit a detection signal based on an amount of liquid discharged from the first fluid chamber ( 36A ) to the second liquid chamber ( 36B ) has flown; and a control device ( 130 ) configured to: based on that of the detector ( 103 ) to measure a physical quantity, on the basis of which a throughput rate of the liquid can be specified, which from the first liquid chamber ( 36A ) to the second liquid chamber ( 36B ) flows; and determine if the physical quantity is within a threshold range. A liquid consuming device according to claim 1, wherein the control device ( 130 ) is configured to measure, as the physical quantity, a transitional time in which a liquid level in the first liquid chamber or the second liquid chamber moves between two points. A liquid consuming device according to claim 1, wherein the detector ( 103 ) is configured to emit the detection signal when a liquid level in the first liquid chamber ( 36A ) falls below a detection position or when a liquid level in the second liquid chamber ( 36B ) reaches the detection position, wherein the control device ( 130 ) is configured as the physical quantity a transitional time after bringing the first liquid chamber ( 36A ) and the second fluid chamber ( 36B ) into a liquid connection through the connecting element until the delivery of the detection signal by the detector ( 130 ) to eat. A fluid power device according to claim 3, further comprising a mounting detector ( 107 ) at a mounting detection position in an insertion path of the liquid cartridge (FIG. 30 ) in the mounting section ( 110 ) and configured to generate a mounting detection signal based on presence or absence of the liquid cartridge ( 30 ) at the assembly detection position, the control device ( 130 ) is configured as the transition time a time after the delivery of the assembly detection signal indicating that the liquid cartridge ( 30 ) at the assembly detection position, by the mounting detector ( 107 ) until the detection signal is output by the detector ( 130 ) to eat. A liquid consuming device according to claim 4, wherein the liquid cartridge ( 30 ) is configured to be inserted into the cartridge mounting portion (FIG. 110 ) is inserted in an insertion direction and removed from the cartridge mounting portion (FIG. 110 ) in a withdrawal direction opposite to the insertion direction, the liquid cartridge ( 30 ) further includes a front wall ( 40 ) which is oriented in the insertion direction when the liquid cartridge ( 30 ) in the cartridge mounting portion (FIG. 110 ) and a rear wall ( 41 ), which is oriented in the withdrawal direction, when the liquid cartridge ( 30 ) from the cartridge mounting section ( 110 ), wherein the first liquid chamber ( 36A ) and the second liquid chamber ( 36B ) between the front wall ( 40 ) and the rear wall ( 41 ) are positioned, wherein the liquid feed opening ( 60 ) on the front wall ( 40 ) is provided, wherein the liquid cartridge ( 30 ) further comprises a partition wall ( 45 ) between the first liquid chamber ( 36A ) and the second fluid chamber ( 36B ) is positioned. A liquid consumption device according to claim 5, wherein the partition wall ( 45 ) between the first liquid chamber ( 36A ) and the second fluid chamber ( 36B ) is positioned in the insertion direction, and the partition ( 45 ) a connection opening ( 45C ) which is formed therethrough in the insertion direction, wherein the connection opening ( 45C ) is located on a straight line passing through the liquid feed opening ( 60 ) and extends in the withdrawal direction, the first liquid chamber ( 36A ) further from the front wall ( 40 ) as the partition wall ( 45 ), and the second liquid chamber ( 36B ) closer to the front wall ( 40 ) is positioned as the partition wall. A liquid consuming device according to claim 6, wherein the liquid cartridge ( 30 ) further comprises a movable element ( 71 ), which in the second fluid chamber ( 36B ), and the movable element ( 71 ) is movable between a blocking position and a connecting position, wherein when the movable element ( 71 ) at the blocking position, the movable element ( 71 ) is configured to direct a flow of the liquid from the first liquid chamber ( 36A ) to the second liquid chamber ( 36B ) through the connection opening, and when the movable element ( 71 ) at the connection position, the liquid from the first liquid chamber ( 36A ) to the second liquid chamber ( 36B ), the liquid cartridge ( 30 ) a biasing element ( 72 ) configured to move the movable member (10) 71 ) in the blocking position in the insertion direction, wherein the connecting element is a hollow tube ( 102 ) mounted on the cartridge mounting portion (FIG. 110 ) and configured to pass through the liquid feed port ( 60 ), wherein when the hollow tube ( 102 ) through the liquid feed opening ( 60 ), the hollow tube is the movable element ( 71 ) from the blocking position to the connecting position against a biasing force of the biasing member (FIG. 72 ) presses. A liquid consuming device according to claim 6, wherein the liquid cartridge further comprises a breakable wall (10). 740 ) having the connection opening ( 45C ), wherein the connecting element is a hollow tube ( 102 ) mounted on the cartridge mounting portion (FIG. 110 ) and configured to pass through the liquid feed port ( 60 ), wherein when the hollow tube ( 102 ) through the liquid feed opening ( 60 ), the hollow tube the breakable wall ( 740 ) breaks. A liquid consumption device according to claim 5, wherein the partition wall ( 45 ) between the first liquid chamber ( 36A ) and the second fluid chamber ( 36B ) is positioned in a direction intersecting the insertion direction, the front wall ( 40 ) a first opening ( 40A ) and a second opening ( 40B ), which are formed therethrough, wherein the first opening ( 40A ) with the first liquid chamber ( 36A ) is aligned in the insertion direction and the second opening ( 40B ) with the second liquid chamber ( 36B ) is aligned in the insertion direction, wherein the liquid cartridge ( 30 ) further comprises a first closing element ( 40C ), which is the first opening ( 40A ), and a second closing element ( 40D ) having the second opening ( 40B ), wherein the connecting element is a hollow tube ( 115 ) mounted on the cartridge mounting portion (FIG. 110 ), wherein the hollow tube ( 115 ) a first end ( 115A ) and a second end ( 115B ), wherein when the liquid cartridge ( 30 ) on the cartridge mounting portion (FIG. 110 ), the first end ( 115A ) closing the first opening ( 40A ) by the first closing element ( 40C ) and the second end ( 115B ) closing the second opening ( 40B ) by the second closing element ( 40D ), so that the first fluid chamber ( 36A ) with the second liquid chamber ( 36B ) through the hollow tube ( 115 ), wherein the liquid consumption device optionally further comprises a second hollow tube ( 102 ) mounted on the cartridge mounting portion (FIG. 110 ) and is configured to enter the liquid feed port ( 60 ), the liquid feed opening ( 60 ) under the first opening ( 40A ) and the second opening ( 40B ) is positioned. A liquid consumption device according to claim 5, wherein the partition wall ( 45 ) a connection opening ( 45C ) formed therethrough, the front wall (FIG. 40 ) an air connection opening ( 65 ), which is formed therethrough, and wherein the second liquid chamber ( 36B ) with the outside of the liquid cartridge ( 30 ) can be brought into an air connection, wherein a pressure in the first liquid chamber ( 36A ) is a first pressure and a pressure in the second fluid chamber ( 36B ) is a second pressure which is greater than the first pressure, wherein the liquid cartridge ( 30 ) a movable element ( 71 ), which is connected to a portion of the partition ( 45 ) connecting the connection opening ( 45C ), due to a pressure differential between the first pressure and the second pressure comes into contact, wherein the connecting element is a rod ( 114 ) configured to communicate with the air connection port ( 65 ) to open. A liquid consumption device according to claim 3, wherein the detector ( 103 ) a light-emitting section ( 104 ) and a light-receiving section ( 105 ), which face each other, whereby the detection position of the liquid cartridge ( 30 ) attached to the cartridge mounting portion (FIG. 110 ), and wherein the detector ( 103 ) is configured to emit the detection signal when the light-receiving portion (16) 105 ) Receives light from the light emitting portion ( 104 ), wherein in the first liquid chamber ( 36A ) or the second fluid chamber ( 36B ) stored liquid is suitable to block the light. A liquid consuming device according to claim 3, wherein the liquid cartridge ( 30 ) further comprises a partition wall ( 45 ) between the first liquid chamber ( 36A ) and the second Liquid chamber ( 36B ), and wherein the partition wall has a connection opening ( 45C ), which is formed therethrough, wherein the liquid cartridge further comprises a closure ( 80 ) having the connection opening ( 45C ), wherein the connecting element is configured to close the closure ( 80 ) when it receives a destructive signal from the control device ( 130 ), wherein the control device ( 130 ) is configured as the transitional time a time after the discharge of the destruction signal from the control device ( 130 ) to the connector until the detector outputs the detection signal ( 103 ) and wherein the connector is optionally configured to either 80 ) to destroy by heat or the closure ( 80 ) by ultrasonic waves. Fluid consumption device according to one of the preceding claims, wherein the liquid cartridge ( 30 ) further comprises a partition wall disposed between the first fluid chamber ( 36A ) and the second fluid chamber ( 36B ), and wherein the partition wall has an opening formed therethrough, wherein the liquid cartridge ( 30 ) further comprises an air-permeable film attached to the partition to cover the opening of the partition, the opening of the partition being positioned above a liquid level in the first liquid chamber. A liquid consumption device according to any one of the preceding claims, wherein the liquid cartridge further comprises a wall ( 39 ), the first liquid chamber ( 36A ) and where the wall ( 39 ) an opening ( 390 ) formed therethrough to the first fluid chamber ( 36A ) with the outside of the liquid cartridge in an air connection. Fluid consumption device according to one of the preceding claims, wherein the control device ( 130 ) is configured for at least one of the following: when the fluid power device further comprises a temperature detector ( 106 configured to emit a signal based on a temperature, it is for determining the threshold range based on the temperature detected by the temperature detector (FIG. 106 ) signal emitted; for communicating information about the liquid cartridge ( 30 ), when the control device ( 130 ) determines that the physical quantity is not within the threshold range; for limiting the fluid consumption by the fluid consumption section ( 21 ), when the control device ( 130 ) determines that the physical quantity is not within the threshold range; and if the liquid consumption section ( 21 ) a nozzle ( 29 ) and an actuator ( 29A ) configured to direct the liquid through the nozzle (10) 29 ) when discharging an electric drive voltage, it is for controlling the liquid consumption section (FIG. 21 ) configured such that the on the actuator ( 29A ) are set for applied amounts of liquid discharged from the nozzle ( 29 ) are ejected so that they are the same amount when the control device ( 130 ) determines that the transitional time is within the threshold range, and when the control device ( 130 ) determines that the transitional time is not within the threshold range.

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