JP2014046625A - Liquid storage container - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid storage container that even when a foreign substance gets mixed in with liquid or a foreign substance is generated from an inlet, can reduce the risk that the foreign substance is extruded from an outlet for liquid and appropriately extrude the liquid.SOLUTION: The liquid storage container comprises: a first ink chamber 151 having an inlet for injecting ink to be supplied to a printer consuming the ink; and a second ink chamber 152 which is separated by a division wall 150 crossing with the opposite surface 153 opposing to a ceiling surface 137b with an inlet formed thereon from the first ink chamber 151 and communicated with the first ink chamber 151 via a wall communication port 155. In the second ink chamber 152 is formed an outlet for extruding liquid into the printer. The wall communication port 155 is formed at a position twisted toward the inlet and away from the opposite surface 153. The area of the wall communication port 155 is smaller than the area of the division wall 150 and the capacity of the first ink chamber 151 is smaller than the capacity of the second ink chamber 152.

Description

  The present invention relates to a liquid container that contains a liquid to be supplied to a liquid consuming apparatus.

  2. Description of the Related Art Conventionally, an ink jet printer that performs printing (recording) by ejecting ink (liquid) from a liquid ejecting head onto a target such as paper is known as a type of liquid consuming device. In such a printer, in order to continuously and stably supply ink to the liquid ejecting head when performing printing that consumes a relatively large amount of ink, the ink storage capacity is from a relatively large liquid storage container. A configuration for supplying ink to a liquid ejecting head has been proposed.

  For example, in the printer described in Patent Document 1, the liquid container is provided separately from the printer, and is configured to be detachable from the side surface of the printer. When ink is injected into the liquid storage container, the liquid storage container is removed from the side surface of the printer to expose the ink injection port, thereby enabling ink injection.

JP 2012-51307 A

  By the way, in a liquid container having an injection port, foreign matter (for example, dust or dust) is mixed from the injection port to obstruct the flow of ink, or the ink is dried at the gas-liquid interface. Sometimes it becomes. For this reason, when foreign matter is mixed in or generated, there is a possibility that problems may occur in the supply of ink to the liquid ejecting head and the ejection of ink onto the target (for example, paper).

Such a problem is not limited to the liquid storage container provided in the ink jet printer, but is generally common in liquid storage containers into which liquid can be injected.
The present invention has been made in view of such circumstances, and its purpose is to reduce the possibility that foreign matter is led out from the liquid outlet even when foreign matter is mixed in from the injection port or when foreign matter is generated inside. An object of the present invention is to provide a liquid container that can lead out the liquid satisfactorily.

Hereinafter, means for solving the above-described problems and the effects thereof will be described.
A liquid storage container that solves the above problems includes a first liquid storage chamber in which an injection port capable of injecting the liquid to be supplied to a liquid consumption device that consumes liquid is formed, and an injection port formation surface in which the injection port is formed A second liquid storage chamber that is partitioned from the first liquid storage chamber by a partition wall that intersects the facing surface facing the first liquid storage chamber and that communicates with the first liquid storage chamber through a communication opening. Is formed with a lead-out port through which the liquid is led out to the liquid consuming device, and the communication opening is formed at a position twisted with respect to the injection port and away from the facing surface, The area of the communication opening is smaller than the area of the partition wall, and the volume of the first liquid storage chamber is smaller than the volume of the second liquid storage chamber.

  According to this configuration, the communication opening is located at a position twisted with respect to the injection port and away from the facing surface. Therefore, the liquid injected from the injection port flows into the second liquid storage chamber via the communication opening, whereas the foreign matter mixed from the injection port and the foreign matter generated in the first liquid storage chamber are compared with the liquid. Difficult to pass through the communication opening. In other words, since the foreign matter can be easily retained in the first liquid storage chamber, the liquid in which the contamination of the foreign matter is suppressed flows into the second liquid storage chamber. Therefore, even when foreign matter is mixed from the inlet or when foreign matter is generated inside, the liquid can be favorably led out while reducing the possibility that the foreign matter is led out from the outlet.

In the liquid container, it is preferable that a concave portion recessed in the gravitational direction in a posture state during use is formed on the facing surface.
According to this configuration, since the concave portion recessed in the gravitational direction is formed on the facing surface, even when the foreign matter staying in the first liquid storage chamber settles with time, the foreign matter can be accumulated in the concave portion. . That is, when the liquid is injected from the injection port with foreign matter accumulated in the recess, the foreign matter accumulated from the recess can be prevented from rising outside the recess.

  In the liquid container, it is preferable that at least a part of the concave portion is formed at a position shifted from the inlet in a direction intersecting the direction of gravity in the posture state at the time of use.

  According to this configuration, mixed or generated foreign matter can be deposited in the recess. And since the recessed part is provided in the direction which cross | intersects a gravitational direction, the position from the injection hole is shifted, Therefore When a liquid is inject | poured from an injection hole, the rising of the foreign material deposited on the recessed part can be suppressed more.

  The liquid container further includes a liquid channel connecting a channel opening formed on a bottom surface of the second liquid storage chamber and the outlet port, and the distance between the channel opening and the partition wall is the opposite It is preferable that the distance is shorter than the distance between the surface and the communication opening.

  According to this configuration, the flow path opening can be formed at a position close to the partition wall by making the distance between the flow path opening and the partition wall smaller than the distance between the facing surface and the communication opening. Therefore, it is possible to reduce the possibility that foreign matter that has passed through the communication opening together with the liquid from the first liquid storage chamber side to the second liquid storage chamber side settles into the flow channel opening and enters the liquid flow channel.

  In the liquid storage container, the second liquid storage chamber further includes a flange provided to cover the flow path opening at a position in an antigravity direction with respect to the flow path opening in a posture state during use. Is preferred.

  According to this configuration, even when foreign matter enters the second liquid storage chamber or when foreign matter is generated in the second liquid storage chamber, the foreign matter that has settled in the second liquid storage chamber can be deposited on the buttocks. . Therefore, it is possible to further suppress foreign matter from being mixed into the liquid led out to the liquid channel from the channel opening located on the gravity direction side of the collar.

  In the liquid container, it is preferable that at least a part of the flange portion is formed along a direction intersecting the gravity direction and the horizontal direction in a posture state at the time of use.

  According to this configuration, since the eaves portion extends along a direction intersecting the gravity direction and the horizontal direction, the foreign matter accumulated in the eaves portion is reduced as the liquid stored in the second liquid storage chamber decreases. Can be collected in the direction.

  The liquid container includes a valve body that is displaceable between a valve opening position that opens the liquid flow path and a valve closing position that closes the liquid flow path, and the remaining amount of the liquid in the second liquid storage chamber It is preferable to further include a float valve having a float member that floats and displaces the valve body in accordance with the change, and the flange portion is provided on the antigravity direction side of the float valve in the posture state at the time of use. .

  A float valve that displaces a valve element using a float member that floats with a change in the remaining amount of liquid may malfunction due to the weight of the accumulated foreign matter, for example, when foreign matter accumulates on the float member. In this respect, according to this configuration, foreign matter can be deposited on the flange provided on the anti-gravity direction side of the float valve, so that the foreign matter that has settled in the second liquid storage chamber is deposited on the float member. Can be suppressed.

  In the liquid container, the flange portion includes a first flange portion and a second flange portion, and the first flange portion and the second flange portion are based on an axis along the direction of gravity passing through the float member. The distance between the upper end of the first collar part and the upper end of the second collar part in the posture state during use is the distance between the lower end of the first collar part and the lower end of the second collar part. Shorter is preferred.

  According to this configuration, even if the foreign matter accumulated on the collar moves and falls from the collar as the remaining amount of the liquid stored in the second liquid storage chamber changes, the float valve is avoided. Foreign matter can be dropped.

It is preferable that the liquid container further includes a filter between the flow path opening and the float valve in the liquid flow path.
According to this configuration, it is possible to flow the liquid led out from the channel opening to the float valve side after passing through the filter. That is, for example, among the foreign matters mixed in the liquid in the first liquid storage chamber from the inlet, the relatively large foreign matter stays in the first liquid storage chamber and accumulates in the buttocks in the second liquid storage chamber. Therefore, since the foreign matter mixed into the ink led out from the flow path opening to the liquid flow path is relatively small, even if it enters from the flow path opening, compared to the case where a large foreign object has entered, The clogging of the liquid channel is suppressed. Furthermore, foreign substances mixed in the liquid led out from the outlet can be further reduced by passing the liquid through a filter provided in the liquid channel.

In the liquid container, the area of the communication opening is preferably smaller than the area of the inlet.
According to this configuration, since the area of the communication opening is smaller than the area of the injection port, the possibility that the foreign material enters the second liquid storage chamber through the communication opening when a large foreign object is mixed from the injection port is reduced. can do.

FIG. 3 is a perspective view of the printer to which the liquid container according to the embodiment is fixed. The perspective view which shows the state with which the liquid storage container was mounted | worn by the mounting part. The perspective view which shows a liquid container in the state from which the slider was isolate | separated. The disassembled perspective view which shows the structure of the connection part with which a liquid storage container is provided. Sectional drawing which shows the structure of the connection part with which a liquid storage container is provided. (A) is a disassembled perspective view which shows the structure of a slider, (b) is a perspective view which shows the back surface side of a slider. (A) is a disassembled perspective view which shows the structure of a chip holder, (b) is a perspective view of the chip holder in which the recording chip was mounted. (A) is a perspective view which shows the structure of an opening / closing cover, (b) is sectional drawing which shows the state in which the opening / closing cover was attached to the slider, (c) is the elements on larger scale which show the structure of an engaging part. It is a figure which shows the liquid container in the state where the opening / closing cover is located in the open position, wherein (a) is a perspective view showing a state in which the inlet is covered with a covering, and (b) is a cover from the inlet. The perspective view which shows the state which removed. The top view of a liquid container. It is a figure which shows the cross-section of a liquid container, Comprising: AA sectional view taken on the line in FIG. It is a figure which shows the cross-section of a liquid container, Comprising: (a) is BB arrow sectional drawing in FIG. 10, (b) is CC sectional view taken on the line in FIG. The disassembled perspective view of a liquid container. The side view of the container case to which the film was adhere | attached. The enlarged view of D part in FIG. The enlarged view of the container case to which the film was adhere | attached. The enlarged view of the container case to which the film was adhere | attached. The fragmentary sectional view of a container case. The fragmentary sectional view of a container case. (A) is the EE arrow directional cross-sectional view in FIG. 19, (b) is the FF arrow directional cross-sectional view in FIG. The bottom view of a container case. The disassembled perspective view which shows a part of container case and each structural member of a float valve. FIG. 10 is an explanatory diagram of the operation of the slider in the liquid storage container attached to the holder. (A) is a perspective view showing the chip holder and the communication unit before engagement, (b) is a side view showing a partial cross-sectional view of the engagement state between the chip holder and the communication unit, and (c) is after engagement. The side view which shows a chip holder and a communication part. The perspective view which shows the positional relationship of the liquid storage container and liquid storage source at the time of inject | pouring ink. The partial cross section side view which shows the positional relationship of the liquid storage container and liquid storage source at the time of inject | pouring ink. The top view which shows the rotation range centering on the fixing | fixed part of the coating | coated member with which a liquid storage container is provided. FIG. 6 is a partial cross-sectional view illustrating a state of a float valve when the remaining amount of ink approaches a threshold remaining amount. FIG. 6 is a partial cross-sectional view illustrating a state of a float valve when the remaining amount of ink becomes less than a threshold remaining amount.

  Hereinafter, an embodiment of an ink jet printer (hereinafter also referred to as “printer”) that is an example of a liquid container and a liquid consuming device that consumes liquid supplied from the liquid container will be described with reference to the drawings. To do.

  As shown in FIG. 1, the printer 11 of the present embodiment includes a leg portion 13 with a wheel 12 attached to the lower end, and a substantially rectangular parallelepiped apparatus main body 14 assembled on the leg portion 13. In the present embodiment, the direction along the direction of gravity is defined as the vertical direction Z, and the longitudinal direction of the apparatus main body 14 intersecting with the vertical direction Z (orthogonal in the present embodiment) is defined as the horizontal direction X. Also, a direction that intersects (orthogonal in the present embodiment) both the vertical direction Z and the horizontal direction X is defined as the front-rear direction Y.

  As shown in FIG. 1, a feeding portion 15 that protrudes upward is provided at the rear portion of the apparatus main body 14. In the feeding unit 15, a roll paper R on which a paper S as a long medium is wound in a cylindrical shape is loaded. In the housing portion 16 constituting the exterior of the apparatus main body 14, an insertion port 17 for introducing the paper S fed from the feeding portion 15 into the housing portion 16 is formed at a position on the front side of the feeding portion 15. Has been.

  On the other hand, a discharge port 18 for discharging the paper S to the outside of the housing unit 16 is formed on the front side of the apparatus main body 14. Note that a medium transport mechanism (not shown) that transports the sheet S fed from the feeding unit 15 from the insertion port 17 side to the discharge port 18 side is accommodated in the housing unit 16. A medium receiving unit 19 that receives the paper S discharged from the discharge port 18 is provided at a position below the discharge port 18 on the front side of the apparatus main body 14.

  In addition, an operation panel 20 for performing a setting operation and an input operation is provided on one end side (the right end side in FIG. 1) that is outside the conveyance path of the sheet S in the left-right direction X in the upper part of the apparatus main body 14. Yes. Furthermore, a liquid container 21 that can store ink, which is an example of a liquid, is fixed to one end side (the right end side in FIG. 1) that is outside the conveyance path of the sheet S in the left-right direction X in the lower portion of the apparatus main body 14. Has been.

  A plurality (four in this embodiment) of liquid storage containers 21 are provided corresponding to the type and color of ink. The liquid storage unit 22 is configured by arranging the plurality of liquid storage containers 21 so as to be arranged in the left-right direction X. The liquid storage unit 22 has a portion exposed to the front side (outside side) of the apparatus main body 14 in a state where the liquid storage containers 21 are fixed to the apparatus main body 14. The liquid storage unit 22 is covered with a frame member 23 having a substantially U-shaped cross section fixed to the apparatus main body 14 side on both sides in the left-right direction X and the lower side in the up-down direction Z of the exposed portion.

  In addition, a carriage 25 on which the liquid ejecting head 24 is mounted is accommodated in the casing 16 so as to be capable of reciprocating in the left-right direction X, which is the main scanning direction. Note that a liquid supply mechanism (not shown) for supplying the ink stored in the liquid storage container 21 toward the liquid ejecting head 24 is stored in the housing unit 16. Then, recording (printing) is performed by ejecting ink droplets from the liquid ejecting head 24 onto the paper S transported by the medium transport mechanism, and ink in the liquid container 21 is consumed through ejection of such ink droplets. The

  Next, the mounting part 31 for mounting the liquid container 21 in a fixed state with respect to the apparatus main body 14 and the liquid container 21 fixed to the apparatus main body 14 via the mounting part 31 will be described. In FIG. 2, only one supply unit 32 that is a part of a liquid supply mechanism that supplies ink from each liquid storage container 21 to the liquid ejecting head 24 side is illustrated in order to avoid complication of the drawing. In addition, the liquid container 21 corresponding to the one supply part 32 shown in the figure is shown in a state before being attached to the attachment part 31 as indicated by a two-dot chain line and a white arrow. Further, in FIG. 3, the liquid container 33 constituting the liquid container 21 and the slider 34 as an example of the sub holding member are illustrated in a separated state.

  As shown in FIG. 2, the printer 11 is provided with a mounting portion 31 having an upper frame 35 and a lower frame 36 that are arranged at a predetermined interval in the vertical direction (vertical direction Z). In addition, a supply unit 32 that is a part of the liquid supply mechanism is attached to the mounting unit 31 corresponding to each liquid container 21. In FIG. 2, the upper frame 35 is illustrated in a state in which a part thereof is removed by being broken in the left-right direction X.

  The liquid container 21 is fixed to the printer 11 so as not to move in a state where one end side in the longitudinal direction (the right end side in FIG. 2) is positioned in the mounting portion 31. The ink ejected from the liquid container 21 while being fixed to the printer 11 is supplied to the liquid ejecting head 24 by the supply unit 32 attached to one end side of each liquid container 21 in the mounting unit 31. Supplied to each side. Therefore, in this embodiment, the state in which the liquid storage container 21 is mounted on the mounting portion 31 of the printer 11 and fixed so as not to move with respect to the printer 11 is the posture state when the liquid storage container 21 is used.

  As shown in FIGS. 2 and 3, the liquid storage container 21 of the present embodiment has a liquid storage body 33 that stores ink and an upper side that is the antigravity direction in the vertical direction with respect to the liquid storage body 33. And a slider 34 disposed in an overlapping manner.

  The liquid container 33 has a direction that is orthogonal to the longitudinal direction of the apparatus body 14 in the substantially horizontal direction as a longitudinal direction (front-rear direction Y), and a constant width in the lateral direction (lateral direction X) that is orthogonal to the substantially horizontal direction. It has a rectangular parallelepiped shape having a substantially L shape in side view. That is, the liquid container 33 has a first container body 37 that has a substantially square side shape when viewed from the short side direction (left-right direction X), and a front-rear direction on the rear side of the first container body 37. Y has a second accommodating body portion 38 having a substantially rectangular shape. Further, on the upper surface 39 of the liquid container 33, flat surface portions 41 and 42 continuously extending without a step in the longitudinal direction (front-rear direction Y) are formed at both ends in the short direction, and along the flat surface portions 41 and 42. The slider 34 is slidable. On the other hand, the lower surface 40 of the liquid container 33 has a shape in which the first container part 37 has a stepped surface that is lower than the second container part 38 in the longitudinal direction (front-rear direction Y).

  In the present embodiment, a fixed portion 37a (see FIGS. 13, 14, and 20) provided on the lower surface of the first container portion 37 is provided on a fixing portion (not shown) provided on the apparatus main body 14 side. On the other hand, the liquid container 21 is fixed to the printer 11 so as not to move by being screwed with a screw 37b (see FIG. 20). In the liquid container 33 fixed by screwing, the second container part 38 is almost entirely the second part located in the apparatus main body 14, while the first container part 37 is the printer 11. It becomes the 1st site | part exposed ahead of the apparatus main body 14 by being located outside the apparatus main body 14 of this.

  Further, the second container 38 has a casing member (the container case shown in FIG. 13) that forms the liquid container 33 on the rear end side opposite to the first container 37 in the longitudinal direction. 130), and is provided with a connection portion 43 that is formed as a separate member and attached to the second housing portion 38 so as to be relatively movable. In this connection portion 43, an ink flow path for guiding the ink stored in the liquid container 33 to the ink supply needle 44 provided in the supply portion 32 attached to the mounting portion 31 side, and the ink provided in the supply portion 32 are also provided. A transmission mechanism for transmitting the presence / absence of ink in the liquid container 33 to the remaining amount detection rod 45 is formed.

  Here, with reference to FIG. 4 and FIG. 5, the structure of the connection part 43 in which this ink flow path and the transmission mechanism were formed is demonstrated. 4 and 5, constituent members related to the supply needle 44 and the remaining amount detection rod 45 among the constituent members of the supply unit 32 are illustrated, and the other members are omitted as appropriate.

  As shown in FIGS. 4 and 5, the connection portion 43 provided in the second housing body portion 38 has a bottomed substantially box-shaped housing that is open on one side, and the bottom wall portion contains the liquid. An end face 46 on the supply part 32 side in the second container part 38 of the body 33 is configured. A needle insertion hole 47 into which the supply needle 44 of the supply part 32 is inserted is formed on the end surface 46 of the connection part 43, and a remaining amount detection is provided at a position adjacent to the needle insertion hole 47. A rod insertion hole 48 into which the rod 45 is inserted is formed. Further, the connection portion 43 has a projection portion 49 having a substantially cylindrical surface on the lower surface side.

  In the housing of the connection portion 43, a mounted member 50 having a substantially flat plate shape having a predetermined thickness in a direction in which the supply needle 44 is inserted into the needle insertion hole 47 is provided. The attached member 50 has a substantially cylindrical outflow port 52 into which the supply needle 44 is inserted through the needle insertion hole 47 on one end surface 51 on the supply portion 32 side in the thickness direction. A cylindrical liquid chamber 53 is formed. The attached member 50 is formed with an outflow passage 55 that allows the liquid chamber 53 and the outflow port 52 to communicate with each other, as indicated by a thick solid arrow in FIG.

  Since the supply needle 44 is inserted into the outflow port 52 through the needle insertion hole 47, the spring 56, the valve member 57, and the packing 58 that suppress the outflow of the ink supplied from the liquid container 33 side. An on-off valve 59 is provided. In addition, a seal 60 that covers the opening of the outlet 52 is provided so as to prevent ink from flowing out before the supply needle 44 is inserted.

  A flexible film 61 is welded to the liquid chamber 53 so as to cover the opening of the liquid chamber 53. Therefore, the volume of the liquid chamber 53 changes as the film 61 is deformed in accordance with a change in internal pressure. In the liquid chamber 53, a spring 62 that biases the film 61 toward the outside of the liquid chamber 53 is provided. A pressure receiving plate 63 that transmits the urging force of the spring 62 to the film 61 is inserted between the spring 62 and the film 61.

  A moving member 64 is attached to the outer surface of the liquid chamber 53 in the attached member 50. The moving member 64 is configured to be rotatable about a predetermined rotation fulcrum extending in a horizontal direction (left-right direction X) orthogonal to the longitudinal direction (front-rear direction Y) of the liquid container 33. The film 61 constituting a part of the inner surface is in contact with the liquid chamber 53 from the outside.

  On the other hand, a substantially cylindrical inflow port 65 is formed in the attached member 50 so as to protrude in the thickness direction of the attached member 50 on the other end face 50 a in the thickness direction. Corresponding to the inflow port 65, a substantially cylindrical outlet (outlet port) 69 into which the inlet 65 is inserted is provided on the liquid container 33 (second container part 38) side. Yes. By inserting the inflow port 65 into the outlet 69, the inside of the liquid container 33 (second container part 38) communicates with the liquid chamber 53. The outlet 69 is provided with a packing 70 that prevents the ink stored in the liquid container 33 from leaking and flowing out, and the inlet 65 has the liquid container 33 (second container 38). A seal 71 that covers the opening of the outlet port 69 is welded and provided so that the ink does not flow out of the liquid container 33 before being inserted into the container.

  Further, the attached member 50 has a liquid container 33 (second container part 38) so that, for example, the insertion of the supply needle 44 into the outlet 52 and the contact of the remaining amount detection rod 45 with the moving member 64 are stabilized. ) Is urged toward the mounting portion 31 in the connection portion 43 by a compression spring 72 inserted between them.

Here, the transmission mechanism will be described with reference to FIG.
As shown in FIG. 5, in the connection portion 43, the film 61 in the liquid chamber 53 is configured to be pushed out by the spring 62 so as to increase the volume of the liquid chamber 53 via the pressure receiving plate 63. Therefore, as the volume of the liquid chamber 53 increases, the ink in the liquid container 33 flows into the liquid chamber 53 through the inflow port 65. On the other hand, the ink in the liquid chamber 53 flows out from the liquid chamber 53 through the outflow passage 55 when the supply portion 32 sucks the ink from the outlet 52 toward the supply needle 44. At this time, in this embodiment, since the inner diameter of the outflow passage 55 is set larger than the inner diameter of the inlet 65, the amount of ink flowing out from the liquid chamber 53 catches up with the amount of ink flowing into the liquid chamber 53. First, the inside of the liquid chamber 53 becomes negative pressure. Therefore, the film 61 is deformed so as to be drawn into the liquid chamber 53 against the urging force of the spring 62. Incidentally, FIG. 5 illustrates a state in which the film 61 is drawn into the liquid chamber 53.

  The negative pressure generated in the liquid chamber 53 is gradually eliminated by the ink in the liquid container 33 flowing into the liquid chamber 53 through the inflow port 65. Then, the film 61 is pushed out of the liquid chamber 53 again by the force of the spring 62, and the volume of the liquid chamber 53 is restored. Therefore, after a predetermined time has elapsed after the supply of ink to the liquid ejecting head 24 is stopped in the supply unit 32, the original state before the start of ink supply to the liquid ejecting head 24 is restored. Further, when the ink is supplied again from the supply unit 32 to the liquid ejecting head 24 side, the pressure in the liquid chamber 53 becomes negative, and the film 61 is drawn into the liquid chamber 53. On the other hand, when the ink in the liquid container 33 is consumed and disappears, the ink does not flow into the liquid chamber 53 even if the pressure in the liquid chamber 53 is negative. That is, the negative pressure in the liquid chamber 53 is not eliminated even after a predetermined time has elapsed after the supply of ink by the supply unit 32 is stopped, and the state in which the film 61 is drawn into the liquid chamber 53 is maintained. Is done.

  A spring (not shown) for urging the remaining amount detecting rod 45 so as to press the remaining amount detecting rod 45 against the moving member 64 is attached. Further, the other end portion 45 b of the remaining amount detection rod 45 opposite to the one end portion 45 a that contacts the moving member 64 is a detection target portion by the concave sensor 68. The sensor 68 is a transmissive photosensor, and a light receiving unit and a light emitting unit (not shown) are provided to face each other. The presence or absence of ink in the liquid container 33 is detected by a detection signal output from the sensor 68.

  That is, when the ink in the liquid container 33 runs out, the ink does not flow from the liquid container 33 into the liquid chamber 53, so that the film 61 is maintained in a deformed state in a direction that reduces the volume of the liquid chamber 53. . Accordingly, when the moving member 64 is pressed by the one end portion 45a of the remaining amount detection rod 45 urged by a spring (not shown), the moving member 64 rotates about the rotation fulcrum, and the remaining amount detection rod. When 45 moves to the liquid container 33 side, the other end 45b of the remaining amount detection rod 45 is inserted between the light emitting portion and the light receiving portion of the sensor 68. Therefore, the sensor 68 detects that the ink in the liquid container 33 has run out based on the fact that the light is maintained in the blocked state.

Next, returning to FIGS. 2 and 3, the slider 34 will be described.
As shown in FIG. 3, in the first portion of the liquid container 33 located outside the printer 11, an injection port (injection port portion) that injects ink into the liquid container 33 on the upper surface 39 of the liquid container 33. 73 is provided. In the present embodiment, the first container part 37 corresponds to the first part, and the injection port 73 is provided in the first container part 37. The inlet 73 located outside the printer 11 can be covered with the slider 34 so that it is not exposed except when ink is injected.

  That is, the slider 34 has a substantially rectangular shape having a longitudinal direction, and has an outer shape that substantially overlaps the upper surface 39 of the liquid container 33. When the slider 34 is disposed in a state where one end side of the slider 34 is substantially overlapped with the upper surface 39 of the liquid container 33 by being inserted into the mounting portion 31, the ink supplied to the liquid container 33 is poured. The upper portion of the inlet 73 is configured to be covered with an openable / closable open / close cover 74. Specifically, the slider 34 is provided with an opening / closing cover 74 that is displaced at a longitudinal end portion between a position where the inlet 73 is covered and a position where the inlet 73 is opened. In the following description, “insertion direction” refers to the “insertion direction” of the slider 34 with respect to the mounting portion 31 unless otherwise specified.

  In the present embodiment, the opening / closing cover 74 is along the short direction of the liquid container 33 at a position closer to the second container part 38 (second part) than the inlet 73 in a state of covering the inlet 73. The slider 34 is rotatably supported so that the extending axis is the center of rotation. Therefore, as shown by a two-dot chain line in FIG. 3, when opening the injection port 73, the user lifts the front side of the opening / closing cover 74 that is the front end side in the longitudinal direction of the slider 34 to raise the second container part. It can be rotated about 180 degrees to the printer 11 side which is the 38 side.

  As a result, the opening / closing cover 74 is changed from the covering state of the injection port 73 shown by the solid line in FIG. 3 to the open state of the injection port 73 as shown by the two-dot chain line in FIG. It can be displaced so as to be positioned on the side. In the present embodiment, the injection port 73 is provided in the vicinity of the front end of the first container portion 37 of the liquid container 33, and the length in the front-rear direction Y required for the opening / closing cover 74 to cover the injection port 73. However, it is set as the structure which does not become long.

  In addition, the slider 34 has a recording chip 75 as an example of a storage unit that records related information regarding the ink injected from the injection port 73 into the liquid container 33 at the end 34 a in the insertion direction to the mounting unit 31. A chip holder 76 as an example of a storage unit holding member that can be mounted is attached. When the slider 34 is inserted into the mounting portion 31 so as to overlap the upper surface 39 of the liquid container 33, the recording chip 75 attached to the chip holder 76 is provided on the mounting portion 31 side of the printer 11. The communication unit 77 can be engaged. Due to the engagement with the communication unit 77, the recording chip 75 placed on the chip holder 76 comes into contact with and electrically connected to the electrical terminal 78 provided in the communication unit 77. As a result, the relationship information recorded on the recording chip 75 is transmitted to the printer 11 side.

  In the printer 11 according to the present embodiment, the slider 34 is attached to the mounting unit 31 together with the connection unit 43 when the slider 34 is inserted into the mounting unit 31 of the printer 11 so as to overlap the upper surface 39 of the liquid container 33. The pair of leaf springs 79 are positioned in the printer 11.

  That is, as shown in FIG. 2, in the vertical direction, leaf springs 79 having slanted shapes whose intervals are narrowed toward the insertion direction are fixed to the upper frame 35 and the lower frame 36 by screws. Then, the leaf spring 79 of the upper frame 35 abuts against the protruding portion 80 provided on the chip holder 76 provided in the slider 34 in a biased state, while the leaf spring 79 of the lower frame 36 is provided on the connection portion 43. It comes into contact with the projected portion 49 (see FIG. 5) in the biased state. As a result, the slider 34 (chip holder 76) and the connecting portion 43 are positioned by the pair of leaf springs 79 in the vertical direction Z.

  Further, the slider 34 inserted in a state of overlapping with the liquid container 33 and the second container part 38 of the liquid container 33 are both positioned in the mounting part 31. That is, as shown in FIG. 2, a guide groove (not shown) is inserted into the upper frame 35 of the mounting portion 31 while a protruding strip portion 82 extending along the longitudinal direction on the upper surface side of the slider 34 is slidably contacted. ) Is provided on the lower surface. Further, the lower frame 36 of the mounting portion 31 has a guide groove 84 that engages with a protruding strip portion 83 (see FIGS. 5 and 23) that extends along the longitudinal direction on the lower surface side of the liquid container 33. Is provided. Therefore, the slider 34 and the second container body 38 are positioned in the short direction by the engagement between the respective protrusions and the guide grooves. As a result, the slider 34 (and the chip holder 76 attached to the slider 34) and the connecting portion 43 provided in the second container 38 are each positioned in the short direction.

  Now, in the liquid container 21 of the present embodiment, the chip holder 76 and the opening / closing cover 74 provided in the slider 34 are detachably attached to the slider 34. The slider 34 is configured to be slidable with respect to the upper surface 39 of the liquid container 33 with these attached. In other words, the slider 34 is configured to be able to be inserted into and removed from the mounting portion 31 in a state where the liquid container 33 is fixed to the printer 11.

Further, the configuration of the slider 34 will be described in detail with reference to FIGS. 6 (a) and 6 (b).
As shown in FIG. 6A, the slider 34 includes a holder mounting portion that includes a substantially U-shaped opening 85 that is notched on the back side in the insertion direction at the end portion 34 a on the back side in the insertion direction to the mounting portion 31. 86 is formed. The chip holder 76 can be inserted into and removed from the opening 85 in the direction in which the slider 34 is inserted, that is, in the direction intersecting the sliding direction. In this embodiment, from the upper side opposite to the liquid container 33 with respect to the slider 34, the hook-shaped portion 87 provided on the upper side of the chip holder 76 forms a substantially C-shape that forms the opening 85 of the holder mounting portion 86. It is inserted into the opening 85 and attached so as to contact the upper surface 88 of the shape. Further, the chip holder 76 is extracted upward from the holder mounting portion 86 and removed from the slider 34.

  On the other hand, a rotary shaft 89 is formed on the slider 34 at an end 34 b on the near side in the insertion direction to the mounting portion 31, and a bearing portion 90 formed on the opening / closing cover 74 is fitted into the rotary shaft 89. The opening / closing cover 74 is attached to the slider 34 so as to be rotatable (swingable).

  The slider 34 according to the present embodiment, to which the chip holder 76 and the opening / closing cover 74 are attached in this manner, is overlaid on the liquid container 33, and on the upper surface 39 of the liquid container 33, The liquid container 33 is slidable along the longitudinal direction (front-rear direction Y) while being in contact with both end portions in the width direction which is the left-right direction X).

  Specifically, as shown in FIG. 6B, a linear rib extending in the longitudinal direction at both side ends in the width direction intersecting the longitudinal direction on the lower surface side of the slider 34 overlapping the upper surface 39 of the liquid container 33. The side wall portions 91 and 92 are respectively formed. On the other hand, at both side ends in the width direction intersecting with the longitudinal direction on the upper surface 39 of the liquid container 33, linear flats extending along the longitudinal direction as contact surfaces with which the side wall portions 91 and 92 abut each other. Surface portions 41 and 42 are formed. Accordingly, the side wall portions 91 and 92 formed on the slider 34 can move (slide) along the longitudinal direction while contacting the flat surface portions 41 and 42 formed on the upper surface 39 of the liquid container 33.

  That is, as shown in FIGS. 2 and 3, the upper surface 39 of the liquid container 33 is formed with a plurality of convex portions 93 adjacent to the inside of the flat surface portions 41 and 42 along the longitudinal direction. . Therefore, the slider 34 is stably moved along the longitudinal direction (front-rear direction Y) with respect to the liquid container 33 by restricting the movement in the width direction (left-right direction X) by the plurality of convex portions 93. Move (slide).

  By the way, the printer 11 according to the present embodiment can be slid up and down on the upper side of the liquid container 21 fixed to the printer 11 with the second container 38 positioned in the mounting unit 31. A provided slide knob 94 is provided. When the slide knob 94 provided on the printer 11 is displaced from the upper side to the lower side, the slide knob 94 is engaged with the concave portion 95 provided on the upper surface of the slider 34, and the slider 34 is removed from the mounting portion 31 along the longitudinal direction. Movement (sliding) in the exit direction is restricted. Therefore, when the user moves the slide knob 94 from below to above, the engagement with the concave portion 95 is released, and the slider 34 can be removed from the mounting portion 31. In this state, when the user slides the slider 34 with respect to the liquid container 33, the slider 34 can be inserted into and removed from the mounting portion 31. In the present embodiment, the slider 34 is formed with a finger hook portion 96 that protrudes along the short direction on the upper surface side of the slider 34, and the finger hook portion 96 facilitates insertion and removal of the slider 34 by the user. ing.

  Furthermore, in this embodiment, the recording chip 75 placed on the chip holder 76 is placed so as to be replaceable. This configuration will be described with reference to FIGS. 7 (a) and 7 (b). 7A and 7B, the chip holder 76 is illustrated in a state where it is detached from the slider 34.

  As shown in FIG. 7A, the chip holder 76 is composed of a plurality of walls. The chip holder 76 is provided with a recess 97 that is open on both the inner side and the upper side in the insertion direction of the slider 34 with respect to the mounting portion 31 in a state assembled to the slider 34. 98 is provided. A cylindrical boss 99 is formed on the lower end side of the inclined surface 98, and a plate-like rib 100 whose longitudinal direction is the insertion direction with respect to the mounting portion 31 is formed on the upper end side of the inclined surface 98. . Any or all of the inclined surface 98, the cylindrical boss 99, and the rib 100 are referred to as a support portion.

  On the other hand, in the present embodiment, the recording chip 75 placed on the chip holder 76 has a substantially rectangular shape, and a plurality of (here, nine) electrodes 75a are provided on the surface thereof with the insertion direction as the longitudinal direction. . In the recording chip 75, a round hole 101 is formed at one end which is front and rear in the insertion direction of the plurality of electrodes 75a, and a slit 102 is formed at the other end. Then, the boss 99 provided in the chip holder 76 is inserted into the round hole 101 formed in the recording chip 75, and the chip holder is inserted into the slit 102 provided in the recording chip 75 along with the insertion. The rib 100 provided in 76 is inserted. As a result, the recording chip 75 is placed on the inclined surface 98 of the chip holder 76 in an inclined state with respect to the horizontal direction. Further, regardless of the posture (arbitrary posture) of the chip holder 76, the recording chip 75 is attached to the chip holder 76 so that the wall protrudes in the direction of gravity from the recording chip 75. It is supported. An identification seal 104 (identification label) for identifying the recording chip 75 placed thereon is affixed to at least a part of the upper surface 103 of the chip holder 76 of the present embodiment. The identification seal 104 has the same color as the liquid stored in the liquid storage container 21 corresponding to the chip holder 76 or the liquid stored in the liquid injection source 126 described later.

  As shown in FIG. 7B, when the recording chip 75 is placed on the chip holder 76, the rotation of the recording chip 75 around the boss 99 in the inclined surface 98 is restricted by the rib 100. The In addition, a slight gap is provided between the round hole 101 and the boss 99 and between the slit 102 and the rib 100, and the placed recording chip 75 can be removed from the chip holder 76. The

  Although only one of the chip holders 76 is shown in FIGS. 7A and 7B, the recess 97 is formed on both sides in the left-right direction X intersecting the insertion direction with respect to the mounting portion 31. The side wall 105 is provided with a groove-shaped portion 107 extending in the insertion direction and having a chamfered portion 106 formed at an end in the insertion direction. Further, a projecting portion 80 that comes into contact with the leaf spring 79 provided on the upper frame 35 is formed on the upper surface 103 of the chip holder 76.

  Next, the configuration of the opening / closing cover 74 will be described with reference to FIGS. 8 (a), (b), and (c). In the present embodiment, the open / close cover 74 is detachably attached to the slider 34, and at the closed position of the inlet 73, a load is applied to the rotation around the rotation shaft 89 and the rotation is suppressed. .

  As shown in FIG. 8A, the opening / closing cover 74 has two bearing portions 90 having a substantially semi-cylindrical shape that engages with shaft end portions 108 on both sides of the rotation shaft 89 provided on the slider 34, and the rotation shaft. A contact portion 109 is formed in contact with the substantially central portion in the axial direction of 89 from a direction opposite to the bearing portion 90. The contact portion 109 is substantially J-shaped when viewed from the short side provided with two flexible plate-like portions that are formed to protrude from the inner surface (back surface 74 a) side facing the inlet 73 in the opening / closing cover 74. Is provided at the hook-shaped tip. When the two bearing portions 90 are engaged with the shaft end portion 108 of the rotating shaft 89, the contact portion 109 is once displaced by the rotating shaft 89 along with the bending displacement of the hook portion 110, and then the bearing portion. In a state where 90 is engaged with the shaft end portion 108 of the rotating shaft 89, the bending displacement is returned to engage with the rotating shaft 89 in a substantially abutting state. Thus, the opening / closing cover 74 is pivotally supported with respect to the rotating shaft 89.

  Further, the slider 34 is provided with extending portions 111 extending in the longitudinal direction at the side wall portions 91 and 92 on both sides in the short direction. A groove 112 is formed in the extended portion 111 along the vertical direction. On the other hand, in the cover side wall portions 91 a and 92 a constituting part of the side wall portions 91 and 92 of the slider 34 in the open / close cover 74, the groove portion 112 is in a state where the open / close cover 74 attached to the liquid container 33 covers the inlet 73. At a position corresponding to, a ridge 113 that can be engaged with the groove 112 is formed.

  That is, as shown in FIGS. 8B and 8C, the opening / closing cover 74 is configured such that the bearing portion 90 and the contact portion 109 are engaged with the rotating shaft 89 of the slider 34. Incorporated into. When the built-in open / close cover 74 is in a closed position that covers the inlet 73, the protruding strips 113 formed on the cover side walls 91a and 92a overlap the groove 112 as viewed in the short direction, and the groove The engaged state is entered with respect to 112. Therefore, as shown by a two-dot chain line in FIG. 8B, when the opening / closing cover 74 rotates about the rotation shaft 89 and is displaced to the opening position of the injection port 73, the opening / closing cover 74 rotates. Create a load. In this respect, the groove portion 112 of the slider 34 functions as an example of an engaging portion that engages with the opening / closing cover 74 and suppresses displacement from the closed position to the open position.

Next, the peripheral configuration of the inlet 73 in the liquid container 21 will be described.
As shown in FIG. 9A, a liquid receiving surface 116 as an example of a liquid receiving portion extending along a direction intersecting the vertical direction Z is formed on the front side portion of the upper surface 39 of the liquid container 33. . The liquid receiving surface 116 has a substantially rectangular shape in plan view, and the width dimension in the left-right direction X is slightly smaller than the width dimension in the left-right direction X of the liquid container 33.

  Further, a peripheral wall portion 117 projects from the upper surface 39 of the liquid container 33 in an upward direction (antigravity direction) intersecting the liquid receiving surface 116 so as to surround the liquid receiving surface 116. In the front wall portion of the peripheral wall portion 117, a notch groove 118 that is recessed downward from the other portions of the peripheral wall portion 117 is formed at the approximate center in the left-right direction X. That is, in the present embodiment, the notch groove 118 that is an example of the recess is formed in the peripheral wall portion 117 that is an example of the peripheral position of the injection port 73. On the other hand, a pair of reinforcing ribs 119 extending rearward while intersecting the wall portion is formed on the rear wall portion of the peripheral wall portion 117.

  Further, a covering member 121 having a covering body 120 that has a substantially cylindrical shape and can cover or open the injection port 73 (see FIG. 9B) is placed on the liquid receiving surface 116. Yes. The cover 120 is formed with a knob portion 122 having a substantially cylindrical shape protruding upward from the upper side surface thereof. The knob portion 122 is a part that is gripped when the user removes the covering 120 from the inlet 73 or conversely covers the inlet 73 with the covering 120.

  Further, the covering member 121 has a fixing portion for fixing the covering member 121 to the liquid receiving surface 116 on the rear side opposite to the front side provided with the covering body 120 in the state shown in FIG. 123. The fixing portion 123 is fixed to a fixing hole 124 (see FIG. 10) formed in the liquid receiving surface 116 so as to be rotatable about the axis of the fixing hole 124 and to be undetachable from the liquid receiving surface 116. Yes. Therefore, the covering member 121 is rotatable with respect to the liquid receiving surface 116 with the fixing portion 123 as the rotation center, but is not easily detached from the liquid receiving surface 116. However, the covering member 121 can be replaced with a new covering member 121 including the fixing portion 123.

  In addition, the covering member 121 is fixed on the covering member 120 while being bent a plurality of times (three times in the left-right direction X in the present embodiment) in a direction intersecting the up-down direction Z while being placed on the liquid receiving surface 116. A connecting part 125 that connects the parts 123 is provided. The connecting portion 125 has a rectangular cross-sectional shape in the extending direction, and is longer in the direction along the liquid receiving surface 116 than the length in the direction (vertical direction Z) intersecting the liquid receiving surface 116 in the rectangular cross-sectional shape. That is longer. For this reason, when the connecting portion 125 is placed on the liquid receiving surface 116, the contact area with the liquid receiving surface 116 is increased, and the connecting portion 125 is stably placed on the liquid receiving surface 116.

  Further, the covering body 120, the connecting portion 125, and the fixing portion 123 constituting the covering member 121 are formed of an elastomer such as rubber or resin, and can be elastically deformed. Accordingly, in the state shown in FIG. 9A, the covering body 120 is elastically deformed and fitted into the inlet 73 so that no gap is formed between the covering 120 and the inlet 73. Is covered.

  As shown in FIG. 9A, the cover 120 removed from the injection port 73 can be placed on the back surface 74 a (an example of the bottom surface) of the opening / closing cover 74 in the open position. . Moreover, since the area of the back surface 74a of the opening / closing cover 74 is larger than the projected area when the covering 120 is projected in the direction along the vertical direction Z, the covering 120 can be placed more stably. It is possible.

  Furthermore, the back surface 74a of the opening / closing cover 74 is a surface inclined downward toward the front where the inlet 73 is located in a state where the opening / closing cover 74 is located at the open position (the state shown in FIG. 9A). Yes. In addition, the cover side walls 91a and 92a are directed upward at both side ends of the back surface 74a of the open / close cover 74 located at the open position. Therefore, the cover side wall portions 91a and 92a prevent the ink from leaking out from the opening / closing cover 74 when the cover 120 having the ink attached thereto is placed on the back surface 74a of the opening / closing cover 74 located at the open position. It functions also as an example of the shielding part to suppress.

  FIG. 9B shows the liquid container 21 in a state where the covering 120 is removed from the inlet 73 and the covering 120 is placed on the back surface 74 a of the opening / closing cover 74. As shown in FIG. 9B, when the injection port 73 formed in a part of the liquid receiving surface 116 is exposed, the user can enter the inside of the liquid container 33 through the injection port 73 (the first (first)). Ink can be injected into the ink chamber 151 (see FIG. 14). In addition, the opening edge 73a serving as the upper end edge of the injection port 73 is chamfered to form an oblique shape, and the ink easily flows into the injection port 73 when the ink is injected.

  Further, as shown in FIG. 9B, the length of the connecting portion 125 of the covering member 121 is long enough to allow the covering 120 to be placed on the back surface 74a of the opening / closing cover 74 in the state of being in the open position. It is said. In the state shown in FIG. 9B, the connecting portion 125 is slightly extended, while the covering 120 is placed on the back surface 74 a of the opening / closing cover 74 and the hook portion 110 of the opening / closing cover 74. Is in contact with.

  As shown in FIG. 10, a fixing hole 124 into which the fixing portion 123 of the covering member 121 is inserted and fixed is provided in the vicinity of the wall portion on the rear side (right side in FIG. 10) of the peripheral wall portion 117 on the liquid receiving surface 116. An opening is formed in a direction crossing the receiving surface 116. The fixing hole 124 is provided so that the center position of the fixing hole 124 in the left-right direction X substantially coincides with the center position of the injection port 73 in the left-right direction X. The fixing hole 124 is formed on the liquid receiving surface 116 in the same manner as the injection port 73, but does not communicate with the first ink chamber 151.

  As shown in FIG. 11, the liquid receiving surface 116 is formed so as to incline downward (in the direction of gravity) toward the injection port 73 in the front-rear direction Y. Accordingly, the vicinity of the fixing hole 124 that is located away from the injection port 73 is the highest position on the liquid receiving surface 116. That is, since the fixing portion 123 of the covering member 121 fixed to the fixing hole 124 is located at a position higher than the periphery of the injection port 73 on the liquid receiving surface 116, when injecting ink into the injection port 73, etc. Even if the ink flows on the liquid receiving surface 116, the ink hardly adheres.

  Further, as shown in FIG. 12A, the liquid receiving surface 116 is formed so as to be inclined downward toward the injection port 73 also in the left-right direction X. Furthermore, as shown in FIG. 12B, the liquid receiving surface 116 is formed so as to incline downward toward the center in the left-right direction X at a position near the fixing hole 124 away from the injection port 73. .

Next, the internal configuration of the liquid container 33 will be described.
As shown in FIG. 13, the liquid container 33 includes a container case 130 that is substantially L-shaped in a side view when viewed from the left-right direction X, and a float valve 131 that is a type of valve mechanism that is housed in the container case 130. A film 133 that is bonded (for example, heat-sealed) to the case opening 132 of the housing case 130, and a resin cover 134 that covers the case opening 132 over the film 133. The housing case 130 is integrally molded so that the right side surface is opened, and the locking portion 130a for locking the claw portion 134a formed on the cover 134 is formed outside the case opening portion 132 forming an annular shape. Is formed.

  As shown in FIG. 14, when the film 133 is bonded to the case opening 132 of the container case 130, the space enclosed by the container case 130 and the film 133 has an air chamber 136 that communicates with the atmosphere, and ink. Functions as an ink chamber 137 as an example of a liquid storage chamber for storing liquid and a discharge channel 138 as an example of a liquid channel. The outlet channel 138 has one end communicating with the ink chamber 137 and the other end side leading to the liquid ejection head 24 (the printer 11 side) through the outlet 69 (see FIG. 69) for the ink contained in the ink chamber 137. 4 and 5) are formed.

Next, the air chamber 136 and the configuration for taking air into the air chamber 136 will be described.
As shown in FIG. 10, an atmosphere communication hole 140 that communicates with the atmosphere and a positioning protrusion 141 that extends along the left-right direction X are formed on the upper surface 39 of the container case 130 where the inlet 73 is formed. Yes. Further, between the reinforcing rib 119 and the positioning protrusion 141 described above, at least one (two in this embodiment) serpentine grooves 142 and 143 formed meandering, and serpentine grooves 142 and 143 are provided. A meandering convex portion 144 surrounding the periphery is formed.

  As shown in FIGS. 10 and 15, the upper surface 39 of the housing case 130 is bonded (for example, heat welded) to the air passage forming film 147 that covers the snake grooves 142 and 143 and forms the air passages 145 and 146. The That is, when the air passage forming film 147 is bonded to the meandering convex portion 144 in a state where the air passage forming film 147 is positioned on the reinforcing rib 119 and the positioning protrusion 141, the first air passage is formed by the first serpentine groove 142 and the air passage forming film 147. 145 is formed. Further, a second air passage 146 is formed by the second serpentine groove 143 and the air passage forming film 147.

  As shown in FIGS. 10 and 11, the air communication hole 140 communicates with the first air chamber 136a. One end 142a of the first snake groove 142 communicates with the first air chamber 136a, while the other end 142b communicates with the second air chamber 136b. Furthermore, one end 143a of the second snake groove 143 communicates with the second air chamber 136b, while the other end 143b communicates with the third air chamber 136c.

  As shown in FIG. 16, an air intake 148 is formed in the third air chamber 136c, and the third air chamber 136c and the ink chamber 137 communicate with each other through the air intake 148. Therefore, for example, when the ink stored in the ink chamber 137 is led out and the pressure in the ink chamber 137 decreases, the outside air taken in from the atmosphere communication hole 140 becomes the first air chamber 136a, the first air passage 145, the second air. The ink is introduced into the ink chamber 137 through the chamber 136b, the second air passage 146, and the third air chamber 136c.

Next, the ink chamber 137 will be described.
As shown in FIG. 14, the shape of the ink chamber 137 is similar to the shape of the liquid container 33 in that the height dimension in the vertical direction Z on the front side is larger than the height dimension in the vertical direction Z on the rear side. Further, the ink chamber 137 includes a first ink chamber 151 as an example of a first liquid storage chamber by a partition wall 150 that intersects a ceiling surface 137b as an example of an injection port formation surface on which the injection port 73 in the ink chamber 137 is formed. And a second ink chamber 152 as an example of the second liquid storage chamber.

  The partition wall 150 is provided so as to extend along the vertical direction Z, and also intersects with a facing surface (bottom surface) 153 facing the ceiling surface 137b. Further, the width of the partition wall 150 in the left-right direction X is substantially equal to the width from the left side wall 130 b of the housing case 130 to the case opening 132. Further, the partition wall 150 is orthogonal to the side wall 130b of the housing case 130 at a position closer to the front side where the height in the vertical direction Z is large in the ink chamber 137, and from the side wall 130b to the case opening 132 side (in FIG. 14). The container case 130 is integrally formed so as to protrude toward the front side. Therefore, the height of the second ink chamber 152 in the vertical direction Z on the first ink chamber 151 side is substantially equal to the height of the first ink chamber 151 in the vertical direction Z, and further on the rear side away from the first ink chamber 151. It is larger than the height in the vertical direction Z. The volume of the first ink chamber 151 is smaller than the volume of the second ink chamber 152.

  Specifically, as shown in FIG. 11, the partition wall 150 has a front wall surface 137 a in the first ink chamber 151 around the injection virtual line M extending along the vertical direction Z through the center of the opening of the injection port 73. Are formed so as to be substantially line symmetrical. That is, the inlet 73 is formed on the ceiling surface 137 b of the first ink chamber 151 on the front side of the partition wall 150.

  In addition, as shown in FIG. 17, in the first ink chamber 151, a concave portion 154 that is recessed in the gravitational direction so as to be away from the injection port 73 is located near the partition wall 150 of the facing surface 153. The position is shifted in the direction intersecting with. That is, the recess 154 is provided in the left-right direction X at a position shifted from the injection virtual line M in the front-rear direction Y.

  As shown in FIGS. 14 and 17, when the film 133 is bonded to the partition wall 150, a portion formed as a recess from the bonding surface 150a toward the side wall 130b is a wall communication opening (wall communication opening) as an example of the communication opening. ) And a wall ventilation opening (wall ventilation opening) 156 as an example of a ventilation opening. That is, the first ink chamber 151 and the second ink chamber 152 communicate with each other through the wall communication opening 155 and the wall ventilation opening 156. The wall ventilation opening 156 is formed at the upper end of the partition wall 150 so as to be in contact with the ceiling surface 137b, and is located above the wall communication opening 155.

  On the other hand, the wall communication opening 155 is located on the opposite surface 153 side lower than the wall ventilation opening 156 and is formed at a position away from the recess 154 upward. Further, the wall communication opening 155 has a lower surface 155a positioned on the lower side in the wall communication opening 155 formed substantially horizontally and substantially perpendicular to the left flange surface 155b. The upper surface 155c located on the side) is non-orthogonal to the flange surface 155b. That is, the upper surface 155c is inclined in a direction intersecting the horizontal direction, and is separated from the lower surface 155a as it is separated from the flange surface 155b. Further, the wall communication opening 155 passes through the center of the opening of the wall communication opening 155 and is orthogonal to the opening cross section (extending along the front-rear direction Y in this embodiment), and the communication port axis N is not parallel to the injection virtual line M. It will be a relationship that does not make a difference. That is, the wall communication opening 155 is formed at a twisted position with respect to the injection port 73.

  Furthermore, the area of the wall communication opening 155 corresponds to the area of the recessed portion of the partition wall 150, and is smaller than the area of the partition wall 150 and smaller than the area of the injection port 73. Further, the area of the wall ventilation opening 156 is smaller than the area of the wall communication opening 155.

  As shown in FIG. 14, the second ink chamber 152 has at least one (9 in this embodiment) intersecting rib portions 157a to 157i that intersect with the ceiling surface 137b and extend in the vertical direction Z. , With a gap in the front-rear direction Y. Further, in the second ink chamber 152, at least one (four in this embodiment) laterally inclined rib portions 158a to 158d intersecting the vertical direction Z and the front-back direction (horizontal direction) Y are provided. Is formed. These intersecting rib portions 157a to 157i and transverse oblique rib portions 158a to 158d are orthogonal to the side wall 130b of the housing case 130 and face the case opening 132 side (front side in FIG. 14) from the side wall 130b. The container case 130 is integrally molded so as to protrude.

  The intersecting rib portions 157 a to 157 i have a width in the left-right direction X that is substantially equal to the width from the side wall 130 b of the housing case 130 to the case opening 132. Further, in the intersecting rib portions 157a to 157i, a part of the upper end in contact with the ceiling surface 137b is formed to be recessed toward the side wall 130b. Therefore, when the film 133 is bonded to the bonding surfaces (right end surfaces) of the intersecting rib portions 157a to 157i, the recessed portion functions as a rib ventilation opening (rib ventilation opening) 160 as an example of a ventilation opening. The area of the rib ventilation opening 160 is larger than the area of the wall ventilation opening 156, and the size of the rib ventilation opening 160 in the vertical direction Z is larger than the size of the wall ventilation opening 156 in the vertical direction Z. That is, the lower opening end of the wall ventilation opening 156 is located closer to the ceiling surface 137 b than the lower opening end of the rib ventilation opening 160. Therefore, the wall ventilation opening 156 is formed closer to the ceiling surface 137 b than the rib ventilation opening 160.

  The first intersecting rib portion 157a closest to the partition wall 150 and the second intersecting rib portion 157b closest to the partition wall 150 have a gap with the bottom surface 152a at the front position where the size in the vertical direction Z is large in the second ink chamber 152. Is formed. Therefore, when the film 133 is bonded to the bonding surface between the first intersecting rib portion 157a and the second intersecting rib portion 157b, ink can pass through the lower ends of the first intersecting rib portion 157a and the second intersecting rib portion 157b. It functions as a rib communication opening (rib communication opening) 161 as an example of the communication opening. The bottom surface 152 a of the second ink chamber 152 is a surface located below the vertical direction Z in the second ink chamber 152, and is partially bent and inclined according to the shape of the second ink chamber 152. Yes. And the float valve 131 is accommodated between the 1st cross rib part 157a and the 2nd cross rib part 157b, and the bottom face 152a.

  The third intersecting rib portion 157 c to the ninth intersecting rib portion 157 i are formed at a position behind the second ink chamber 152. Furthermore, in the third intersecting rib portion 157c to the ninth intersecting rib portion 157i, a part of the lower end is formed to be recessed toward the side wall 130b. Therefore, when the film 133 is bonded to the bonding surface (right end surface) of the third intersecting rib portion 157c to the ninth intersecting rib portion 157i, the side wall 130b side at the lower end of the third intersecting rib portion 157c to the ninth intersecting rib portion 157i. The recessed portion functions as a rib communication opening 161 as an example of a communication opening through which ink can pass. That is, in the second ink chamber 152, the spaces separated by the intersecting rib portions 157a to 157i communicate with each other through the rib communication opening 161 and the rib ventilation opening 160 formed on the ceiling surface 137b side from the rib communication opening 161. To do.

  As shown in FIGS. 13 and 14, the first laterally inclined rib portion 158a at the highest position is formed to be a downward slope from the intersection of the partition wall 150 and the ceiling surface 137b toward the rear. . Further, the second oblique rib portion 158b at the second highest position descends more slowly than the first oblique rib portion 158a from the lower position to the rear of the partition wall 150 than the first oblique rib portion 158a. It is formed to be a slope. That is, the first laterally inclined rib portion 158a and the second laterally inclined rib portion 158b are formed so as to intersect with the partition wall 150 and intersect with the front-rear direction Y. The first laterally inclined rib portion 158a and the second laterally inclined rib portion 158b have a width in the left-right direction X that is smaller than the width of the partition wall 150 and the intersecting rib portions 157a to 157i. Therefore, when the film 133 is bonded to the case opening 132, a gap is formed between the first transverse oblique rib portion 158a and the second transverse oblique rib portion 158b and the film 133. Therefore, the space divided by the first laterally inclined rib portion 158a and the second laterally inclined rib portion 158b communicates with each other through the gap.

  Further, on the bottom surface 152a side of the second laterally inclined rib portion 158b and on the upper side of the float valve 131, as an example of the third laterally inclined rib portion 158c and an example of the second flange portion, The fourth laterally inclined rib portion 158d is formed. The third oblique rib portion 158c is formed between the partition wall 150 and the first intersecting rib portion 157a, and the fourth oblique rib portion 158d is formed on the rear side of the second intersecting rib portion 157b. Has been. The third oblique rib portion 158c and the fourth oblique rib portion 158d are symmetrical with respect to an axis (not shown) along the direction of gravity passing through the center of the float valve 131, and from the center of the float valve 131. It forms so that it may become a downward slope each to an edge part. That is, the distance between the upper end of the third horizontal oblique rib portion 158c and the upper end of the fourth horizontal oblique rib portion 158d is shorter than the distance between the lower end of the third horizontal oblique rib portion 158c and the lower end of the fourth horizontal oblique rib portion 158d.

  The third laterally inclined rib portion 158c and the fourth laterally inclined rib portion 158d have substantially the same width in the left-right direction X as the width of the partition wall 150. Furthermore, both ends of the third laterally inclined rib portion 158c and the fourth laterally inclined rib portion 158d are recessed toward the side wall 130b. Therefore, when the film 133 is adhered to the adhesion surface (right end surface) of the third laterally inclined rib portion 158c and the fourth laterally inclined rib portion 158d, the recessed portion formed on the side wall 130b side is a rib through which ink can pass. It functions as the communication opening 161. Accordingly, the space divided by the third laterally inclined rib portion 158c and the fourth laterally inclined rib portion 158d communicates with each other through the rib communication opening 161.

  As shown in FIGS. 17 and 18, the bottom surface 152 a of the second ink chamber 152 is formed with a flow path opening (flow path opening) 162 communicating with the outlet flow path 138. That is, the laterally inclined rib portions 158a to 158d are located above the flow path opening 162 and the float valve 131, and are provided so as to cover the flow path opening 162 and the float valve 131 from above. The distance L1 between the flow path opening 162 and the partition wall 150 in the front-rear direction Y is shorter than the distance L2 between the facing surface 153 and the wall communication opening 155 in the vertical direction Z. The distance L2 in the present embodiment corresponds to the distance between the upper end of the recess 154 formed in the facing surface 153 and the lower end of the wall communication opening 155. That is, the flow path opening 162 is formed at a position near the partition wall 150 on the bottom surface 152 a of the second ink chamber 152.

Next, the outlet channel 138 will be described.
As shown in FIG. 14, the outlet channel 138 is formed on the lower side of the second ink chamber 152 along the bottom surface 152 a of the second ink chamber 152. The lead-out flow path 138 is formed so as to be bent in accordance with the shape of the liquid container 33, and the bent flow path section 163 that allows the ink to flow while changing the direction in which the ink flows (hereinafter referred to as “flow direction”). Have Furthermore, the outlet channel 138 includes a connecting channel portion 164 that connects the channel opening 162 and the bent channel portion 163, and an inclined channel portion 165 that connects the bent channel portion 163 and the outlet port 69.

  As shown in FIGS. 18 and 19, the connecting channel portion 164 includes a substantially rectangular filter 166 in a bottom view from the lower side. That is, the connection channel portion 164 is divided by the filter 166 into a first connection channel portion 164 a on the channel opening 162 side and a second connection channel portion 164 b on the float valve 131 side with respect to the filter 166. Furthermore, the connection flow path part 164 includes a third connection flow path part 164 c that is closer to the outlet 69 than the float valve 131 and is connected to the bending flow path part 163.

  As shown in FIGS. 20A and 20B, the cross-sectional area of the bent flow passage portion 163 is larger than the cross-sectional area of the third connection flow passage portion 164c. Note that the width of the outlet channel 138 in the left-right direction X is substantially equal across the flow direction. Therefore, in the direction perpendicular to the flow direction of the bent flow passage portion 163 (the first vertical flow passage portion 163a in FIG. 20B) and also to the left-right direction X (the front-rear direction Y in the first vertical flow passage portion 163a). The width L3 is wider than the width L4 in the direction (vertical direction Z) that is orthogonal to the flow direction of the third connection channel portion 164c and is also orthogonal to the left-right direction X. Furthermore, the cross-sectional area of the inclined channel portion 165 is substantially equal to the cross-sectional area of the bent channel portion 163. Therefore, the width L5 (see FIG. 14) in the direction orthogonal to the flow direction of the inclined channel portion 165 and also orthogonal to the left-right direction X is wider than the width L4 of the third connection channel portion 164c.

  As shown in FIGS. 18 and 21, a substantially rectangular step portion 167 that is recessed upward on the ink chamber 137 side is formed on the lower surface 40 of the container case 130 that has a large height in the vertical direction Z. Has been. Further, first to third flow path forming recesses 168 a to 168 c are formed in the stepped portion 167 so as to be recessed toward the ink chamber 137. The other end side of the through hole 162 a that is formed to penetrate the bottom surface 152 a of the second ink chamber 152 and has one end serving as the channel opening 162 opens in the first channel forming recess 168 a. Further, the first flow path forming concave portion 168a is formed in a stepped manner so that the inner side of the substantially rectangular annular convex portion 169 is deeper than the outer side in a bottom view where the filter 166 is bonded. Furthermore, the flow path convex part 170 is formed in the periphery of the 1st-3rd flow path formation recessed part 168a-168c. That is, the through hole 162 a and the annular convex portion 169 are surrounded by the flow path convex portion 170.

  Therefore, the filter 166 is adhered to the annular convex portion 169, and the flow path forming film 171 is adhered (for example, heat welding) to the flow path convex portion 170, whereby the connection flow path portion 164 is formed. That is, when the flow path forming film 171 is bonded to the flow path convex portion 170, the first flow path forming concave portion 168a functions as the first connection flow path portion 164a and the second connection flow path portion 164b. The second flow path forming recess 168b functions as the second connection flow path part 164b. Furthermore, the third flow path forming recess 168c functions as a third connection flow path part 164c. Then, a substantially rectangular plate-shaped protective member 172 that protects the flow path forming film 171 is attached to the stepped portion 167.

  As shown in FIG. 14, the bent flow path portion 163 includes at least one (two in this embodiment) vertical flow path portions 163 a and 163 b extending in the vertical direction Z, and the vertical flow path portions 163 a and 163 b. A plurality of (four in this embodiment) bent portions 173a to 173d formed at both ends and a transverse flow path portion 163c extending along the front-rear direction Y are provided.

  That is, the 1st bending part 173a is located in the lowest side, and connects the rear end of the 3rd connection flow path part 164c, and the lower end of the 1st vertical flow path part 163a. The second bent portion 173b is located above the first bent portion 173a and connects the upper end of the first vertical flow path portion 163a and the front end of the horizontal flow path portion 163c. The third bent portion 173c connects the rear end of the horizontal flow path portion 163c and the lower end of the second vertical flow path portion 163b. The fourth bent portion 173d connects the upper end of the second vertical flow path portion 163b and the front end of the inclined flow path portion 165. Therefore, the bent channel portion 163 is different from the inclined channel portion 165 in the flow direction in which the ink flows, and is bent with respect to the inclined channel portion 165.

  The inclined channel portion 165 is positioned such that the rear end portion on the outlet port 69 side is located above (in the antigravity direction) with respect to the front end portion on the channel opening 162 side continuous with the fourth bent portion 173d. In addition, it is formed so as to extend along a direction intersecting with the front-rear direction (horizontal direction) Y. In other words, the inclined channel portion 165 becomes a continuous ascending slope from the channel opening 162 side toward the outlet port 69 side. The inclined channel portion 165 communicates with the outlet 69 by bending the rear end side upward.

  The outlet channel 138 is positioned on the gravity direction side of the second ink chamber 152 and extends along the bottom surface 152a. Therefore, the bottom surface 152a of the second ink chamber 152 corresponding to the connecting flow path portion 164 and the horizontal flow path portion 163c is substantially horizontal, whereas the portion corresponding to the inclined flow path portion 165 is the second ink chamber 152. The bottom surface 152a is a downward slope toward the channel opening 162 side.

Next, the float valve 131 will be described.
As shown in FIG. 22, the float valve 131 includes a float member 181 disposed in the ink chamber 137, a valve body 182 disposed below the float member 181, and a regulating member disposed above the float member 181. A regulation case 183 as an example, and a coil spring 184 as an example of an urging member disposed between the float member 181 and the regulation case 183. In FIG. 22, in order to simplify the structure for mounting the float valve 131 in the ink chamber 137, a part of the container case 130 in which the ink chamber 137 is formed constitutes the float valve 131. These are shown together with the constituent members.

Hereinafter, each component of the float valve 131 will be described.
First, the float member 181 includes a rectangular frame 185 that is partitioned into a plurality of (four in this embodiment) space areas on the inner side. A thin film member 186 made of, for example, a transparent film is bonded to the openings 185 a on both the left and right sides along the front-rear direction Y in the frame 185. Therefore, a plurality of (four in this embodiment) sealed gas chambers 187 are formed inside the thin film member 186 by closing the opening 185 a of the frame 185 with the thin film member 186 in the float member 181. Is done. Therefore, the float member 181 can float in the vertical direction Z with a change in the remaining amount of ink in the ink chamber 137 due to the buoyancy generated by these gas chambers 187.

  On the other hand, convex portions 188 projecting in the front-rear direction Y are formed on the lower portions of the front and rear side surfaces along the left-right direction X where the opening 185 a is not formed in the frame 185. Further, a pressing portion 189 having a substantially cylindrical shape protrudes vertically downward from the center position of the lower surface of the frame 185. In addition, a rod-like portion 190 that is coaxial with the pressing portion 189 on the lower surface protrudes from the center position of the upper surface of the frame 185 so as to extend vertically upward.

  Further, on the upper surface of the frame body 185, around the rod-shaped portion 190, a plate-shaped portion 191 having a cross shape in a plan view from above with the rod-shaped portion 190 as a center is projected from the upper surface of the frame body 185. Is formed to be approximately half of the protruding length of the rod-shaped portion 190. The size of the cross-sectional shape of the plate-like portion 191 is larger than the outer diameter of the coil spring 184. A spring seat 191a for placing and supporting the coil spring 184 is cut out in a rectangular shape at the leading edge in the radial direction from the rod-shaped portion 190 at the upper end of the plate-shaped portion 191 having a cross-shaped cross section. Is formed.

  Next, the valve body 182 is a substantially disk-shaped diaphragm valve made of a flexible elastomer or the like, and includes a second connecting channel portion 164b and a third connecting channel portion 164c in the outlet channel 138. It is disposed above a valve port 192 (see FIG. 19 and the like) formed in the bottom surface 152a of the second ink chamber 152 so as to be positioned at the boundary. That is, an annular mounting seat 193 surrounding the valve port 192 is formed on the bottom surface 152a of the second ink chamber 152, and an annular mounting tool 194 is similarly locked to the mounting seat 193 from above. The valve body 182 is disposed above the valve port 192 in a state of being sandwiched between the mounting seat 193 and the mounting tool 194.

  Further, on the inner side of the mounting seat 193, when the previously described coil spring 184 is a first biasing member having a first biasing force, the coil spring functions as a second biasing member having a second biasing force. 195 is arranged so as to always contact the valve body 182 from below. The valve spring 195 is always urged by the coil spring 195 toward the valve opening position (the position shown in FIGS. 19 and 28) that opens upward from the valve port 192 and opens the outlet flow path 138.

  Regarding the force relationship between the first biasing force of the coil spring 184 and the second biasing force of the coil spring 195, the first biasing force of the coil spring 184 is greater than the second biasing force of the coil spring 195. Based on this assumption, the following force relationship is set.

  That is, when the remaining amount of ink in the ink chamber 137 is less than a threshold remaining amount that is a preset remaining amount as shown in FIG. 29, for example, the float that floats in the remaining ink at that time The sum of the buoyancy of the member 181 and the second biasing force of the coil spring 195 is set to be smaller than the first biasing force of the coil spring 184. On the other hand, when the remaining amount of ink in the ink chamber 137 exceeds the threshold remaining amount as shown in FIGS. 19 and 28, for example, the buoyancy of the float member 181 floating in the remaining ink at that time And the second biasing force of the coil spring 195 are set to be equal to or greater than the first biasing force of the coil spring 184.

  Next, the regulation case 183 is formed to have a quadrangular annular wall portion 196 into which the float member 181 can be inserted and removed in the vertical direction Z, and an upper wall portion 197 that closes the upper opening of the annular wall portion 196. It has a box shape with an open bottom. That is, the annular wall portion 196 is formed in an annular shape that can surround the floating region in the vertical direction Z of the float member 181 with a gap between the float member 181 and the side surface of the float member 181.

  A cylindrical portion 198 whose upper opening is closed is formed at the center position of the upper wall portion 197 so as to communicate with the internal space of the annular wall portion 196 via the lower opening of the cylindrical portion 198. An insertion hole 198 a is formed in the upper wall portion of the cylindrical portion 198 so as to allow the rod-shaped portion 190 protruding upward from the upper surface of the float member 181 to pass therethrough. In addition, the upper wall portion of the cylindrical portion 198 has a spring seat 191a formed in a plate-like portion 191 on the float member 181 side in a cross-sectional shape when viewed from above centered on the insertion hole 198a. Spring seats (not shown) facing in the direction Z are formed to bulge downward.

  Further, the annular wall portion 196 of the regulation case 183 serves as a facing portion that faces the thin film member 186 of the float member 181 in a state where the left and right side walls 196a along the front-rear direction Y are assembled with the constituent members of the float valve 131. A rectangular notch 199 extending along the up-down direction Z in which the float member 181 floats is formed at a substantially center in the front-rear direction Y of each of the left and right side walls 196a. Has been. The notch 199 has a width dimension in the front-rear direction Y larger than an outer diameter dimension of the cylindrical part 198 of the upper wall part 197, and a height dimension in the vertical direction Z is the vertical direction of the frame 185 in the float member 181. It is formed in a shape larger than the height dimension of Z.

  Further, from the lower ends of the front and rear side walls 196b along the left-right direction X in the annular wall 196 of the regulation case 183, strip-shaped flanges 200 having a predetermined width in the front-rear direction Y are horizontally directed toward the front and rear, respectively. Is formed to protrude. Then, the float member 181 extends from a position that is approximately the center in the left-right direction X of the flange 200 and a position that is approximately the center in the front-rear direction Y to a position slightly below the center in the up-down direction Z of each side wall 196b. A guide slot 201 that can be inserted through the convex portion 188 on the side is formed along the vertical direction Z. Further, the restriction case 183 includes a portion extending from each of the two left and right long sides of the upper wall portion 197 to the upper end portions of the left and right side walls 196a of the annular wall portion 196, and four corners of the upper end portion of the annular wall portion 196. Through holes 202 that allow the ink to flow by connecting the inside and the outside of the regulation case 183 are formed in the respective parts.

  Next, the coil spring 184 is disposed between the float member 181 and the restriction case 183 so as to be contractible in the vertical direction Z. That is, the coil spring 184 is placed on the spring seat 191 a formed at the upper end of the plate-shaped portion 191 around the rod-shaped portion 190 by inserting the rod-shaped portion 190 of the float member 181 from below into the coil spring 184. Is done. Then, when the float member 181 inserts the rod-shaped portion 190 into the insertion hole 198a of the cylindrical portion 198 with respect to the regulation case 183 from the state, the frame body 185 is inserted into the annular wall portion 196 from below. The upper end of 184 contacts a spring seat (not shown) formed to bulge downward from the upper wall of the cylindrical portion 198 of the restriction case 183.

  Then, the regulation case 183 into which the float member 181 is inserted is maintained in the second ink in the ink chamber 137 while maintaining the state where the float member 181 is pushed into the regulation case 183 so that the coil spring 184 further contracts from that state. The float valve 131 is housed in the housing case 130 by being attached to the bottom surface 152 a of the chamber 152.

Next, a mounting structure of the float valve 131 in the housing case 130 will be described.
As shown in FIG. 22, on the bottom surface 152 a of the second ink chamber 152 in the container case 130, the two front and rear sides sandwiching the mounting seat 193 of the valve body 182 with a distance corresponding to the dimension in the front-rear direction Y of the restriction case 183. A locking rail portion 203 having an inverted L-shaped cross section is formed at the position so that the front and rear flange portions 200 of the regulation case 183 can be slid and inserted along the left-right direction X. Further, the container is provided with the flange 200 inserted in the locking rail portion 203 at two positions before and after the locking rail portion 203 and the mounting seat 193 and on the back side of the housing case 130. A positioning portion 204 is formed that can come into contact with the rear side wall 196a of the left and right side walls 196a along the front-rear direction Y of the regulation case 183 that is slid toward the back side of the case 130.

  Further, in the bottom surface 152 a of the second ink chamber 152, there is a restriction case 183 in which the rear side wall 196 a is in contact with the positioning unit 204 at two positions on the near side corresponding to the rear positioning unit 204 in the left-right direction X. A protrusion 205 that can be locked from the front side, which is the opening side of the housing case 130, is formed at the lower end of the side wall 196 a on the front side. The projecting portion 205 is an elastically deformable structure that extends obliquely upward on the back side of the housing case 130, and the regulation case 183 slides to the back side by inserting the collar portion 200 into the locking rail portion 203. In this case, the lower end edge of each side wall 196a is provided in an oblique posture so as to be able to get over while sliding from the near side to the far side. Then, after the front side wall 196a gets over, the regulation case 183 is elastically restored to the original oblique posture and locked to the front side surface of the side wall 196a, whereby the regulation case 183 is moved from the back side of the housing case 130 to the front side. I try not to escape.

Next, the operation of the liquid container 21 of the present embodiment will be described. In FIGS. 24A, 24B, and 24C, the slider 34 and the liquid container 33 are omitted.
As shown in FIG. 23, when the slide knob 94 is displaced upward in the liquid storage container 21 in which the portion of the second storage body portion 38 is positioned in the mounting portion 31 and is immovably fixed to the printer 11, the slide The knob 94 is disengaged from the concave portion 95 of the slider 34. Then, the user can extract the slider 34 from the printer 11 (the mounting portion 31) by sliding the slider 34 in the direction opposite to the insertion direction along the longitudinal direction.

  By this extraction, the slider 34 is located in the printer 11, that is, in the second container part 38 including the connection part 43 in the upper surface 39 of the liquid container 33 (second part). ) Moves outside the printer 11. In the present embodiment, as shown by a two-dot chain line in FIG. 23, the slider 34 has a chip holder 76 attached to the end 34 a on the back side in the insertion direction of the slider 34. It moves to a position where it can be removed from the holder mounting portion 86. Accordingly, in the upper surface 39 of the liquid container 33, the part of the slider 34 that overlaps the part (second part) located in the printer 11 in the second container part 38 including the connection part 43 is located in the printer 11 and the printer 11. It functions as a moving part that moves between the outside and the outside.

  As a result, the user removes the chip holder 76 that has moved out of the printer 11 by removing it from the slider 34 (holder mounting portion 86). For example, when there is a recording chip 75 already placed on the chip holder 76, related information (for example, the hue and saturation of the ink) related to the ink injected from the injection port 73 to the liquid container 33. , Brightness, ink viscosity, ink solute type, etc.) are replaced with a recording chip 75 on which recording is performed. The user then inserts and attaches the chip holder 76 on which the replaced recording chip 75 is placed into the slider 34 (holder attachment portion 86), and then attaches the slider 34 along the upper surface 39 of the liquid container 33 to the printer. 11 (mounting portion 31).

  With the insertion of the slider 34, the chip holder 76 is placed in contact with the electrical terminal 78 of the communication unit 77 provided in the supply unit 32 so as to be electrically connected to the recording chip 75 placed inclined with respect to the insertion direction. The related information recorded on the recording chip 75 is transmitted to the printer 11 side. During this connection, the recording chip 75 is positioned with respect to the electrical terminal 78. In a state where the relationship information recorded on the recording chip 75 is transmitted (read) to the printer 11 side, the chip holder 76 is located inside the printer 11 and a part (first portion) of the slider 34 is Located outside the printer 11. In other words, the recording chip 75 and the chip holder 76 are located at a position that cannot be touched by the user when the related information recorded on the recording chip 75 is read by the printer 11.

  That is, as shown in FIG. 24A, the communication unit 77 provided in the supply unit 32 includes a terminal unit 114 including an electrical terminal 78 that contacts a plurality of electrodes 75a formed on the recording chip 75, and a short circuit. On both sides in the hand direction, projecting portions 115 that protrude in the short direction and extend in the insertion direction are provided. The terminal portion 114 engages with a concave portion (engagement portion) 97 of the chip holder 76, and the projecting shape portion 115 engages with the groove shape portion 107 of the chip holder 76. The concave portion 97 is a wall surface constituting the chip holder 76 and is formed on the surface on the recording chip 75 side.

  At this time, as shown in FIG. 24 (b), the chip holder 76 is moved by a leaf spring 79 fixed to the upper frame 35 so as not to be separated from the slider 34 when the slider 34 is inserted into the mounting portion 31. The protruding portion 80 moves toward the communication unit 77 while being pressed downward. In this movement, the chip holder 76 is engaged with the protruding portion 115 of the communication portion 77 guided by the chamfered portion 106 and inserted into the groove shape portion 107, and the chip holder 76 is positioned with respect to the communication portion 77. The In this respect, the groove shape portion 107 of the chip holder 76 functions as an example of a positioning shape portion that is positioned in the printer 11.

  As a result, as shown in FIGS. 24A and 24C, the recording chip 75 placed on the chip holder 76 is positioned with respect to the terminal portion 114 of the communication unit 77 and provided in the terminal unit 114. The plurality of electrical terminals 78 are appropriately in contact with a plurality (here, nine) of electrodes 75 a of the recording chip 75. At the time of this contact, the electrode 75a of the recording chip 75 is in an oblique state with the tip in the insertion direction, so that the electrical terminal 78 contacts while rubbing the surface of the electrode 75a.

Next, an operation related to ink injection in the liquid container 21 will be described.
When injecting ink into the liquid container 33, the opening / closing cover 74 is displaced to the open position as shown in FIG. 9 (a), and the back surface of the opening / closing cover 74 is shown in FIG. 9 (b). The covering 120 is placed on 74a to expose the injection port 73.

  At this time, after the user removes the covering 120 from the inlet 73, the user rotates the covering member 121 by an arbitrary angle (180 degrees in this embodiment) with respect to the liquid receiving surface 116 around the fixing portion 123. Then, the covering 120 is placed on the back surface 74 a of the opening / closing cover 74. In the state shown in FIG. 9B, the back surface 74 a of the opening / closing cover 74 is positioned higher in the vertical direction Z than the liquid receiving surface 116, so the covering 120 is placed on the back surface 74 a of the opening / closing cover 74. In the placed state, the connecting portion 125 is slightly extended. Then, the restoring force accompanying the elastic deformation (extension) of the connecting portion 125 acts the cover 120 forward from the opening / closing cover 74. In this respect, in the present embodiment, since the covering body 120 is in contact with the hook portion 110 of the opening / closing cover 74, the covering body 120 is prevented from falling from the opening / closing cover 74. Further, since the back surface 74a of the opening / closing cover 74 located at the open position is in a state where the side where the hook part 110 is formed is lowest, for example, the covering 120 to which ink is attached is mounted on the back surface 74a of the opening / closing cover 74. Even if it is placed, the ink is prevented from spreading over the entire surface of the open / close cover 74 (particularly in the rear surface area).

  Then, as shown in FIGS. 25 and 26, ink is injected into the liquid container 33 from the liquid injection source 126 which welds the edge portion 128 such as a superimposed film and forms the spout 127. When injecting ink, the edge portion 128 in the vicinity of the spout 127 of the liquid injection source 126 is inserted into the notch groove 118 formed in the peripheral wall portion 117 of the liquid container 33 to be in contact with the liquid injection source 126. The source 126 is positioned with respect to the liquid container 33. Then, as shown in FIG. 26, the liquid injection source 126 is tilted so that the pouring spout 127 of the liquid injection source 126 faces downward with the point where the liquid injection source 126 and the liquid container 33 abut on the center of tilting. The ink in the liquid injection source 126 is injected into the first ink chamber 151 through the injection port 73 of the liquid container 33.

  At this time, if the user vigorously tilts the liquid injection source 126, the ink flowing out from the spout 127 of the liquid injection source 126 deviates from the injection port 73 and is poured around the injection port 73 on the liquid receiving surface 116. May end up. Even in such a case, the peripheral wall portion 117 surrounding the liquid receiving surface 116 blocks the ink poured into the liquid receiving surface 116, thereby preventing the ink from flowing out from the liquid receiving surface 116. Since the liquid receiving surface 116 is inclined downward toward the injection port 73 in the left-right direction X and the front-rear direction Y, the ink adhering to the liquid reception surface 116 is guided to the injection port 73 along the inclination. Is done.

  When the ink injection is finished, the injection port 73 of the liquid container 33 is covered with the covering body 120 placed on the back surface 74a of the opening / closing cover 74 as shown in FIG. 9A, and as shown in FIG. The opening / closing cover 74 is displaced to the closed position, and the injection operation is completed.

  In addition, as shown in FIG. 27, in a state where a plurality of liquid storage containers 21 are juxtaposed and used, it is poured from the fixing portion 123 (fixing hole 124) of the covering member 121 in one liquid storage container 21 (for example, the left end). The distance L6 to the inlet 73 is shorter than the distance L7 from the fixing portion 123 in one liquid storage container 21 to the injection port 73 in the other liquid storage container 21 arranged in parallel with the one liquid storage container 21. ing. In this way, as shown in FIG. 27, the covering body 120 of the covering member 121 provided corresponding to the liquid container 33 located at the left end is arranged in parallel with the fixing portion 123 as the rotation center. Even if it is directed to the 33 inlets 73 (shown by a two-dot chain line in FIG. 27), the covering 120 cannot cover the inlet 73. The distances L6 and L7 indicate distances connecting the center positions of the fixing portion 123 (fixing hole 124) and the injection port 73 in plan view as shown in FIG.

Next, the operation in the liquid container 33 when ink is injected from the injection port 73 will be described.
As shown in FIG. 14, when ink is injected from the injection port 73, the liquid level of the first ink chamber 151 rises and ink flows into the second ink chamber 152 through the wall communication opening 155. . The concave portion 154 formed in the first ink chamber 151 is formed with a position shifted in the front-rear direction Y with respect to the injection port 73, so that even if foreign matter is accumulated in the concave portion 154, the foreign matter rises. Is suppressed.

  The first ink chamber 151 and the second ink chamber 152 communicate with each other through the wall ventilation opening 156. Therefore, since the pressures in the first ink chamber 151 and the second ink chamber 152 are substantially the same, the ink levels in the first ink chamber 151 and the second ink chamber 152 are substantially the same in the vertical direction Z. To rise.

  Since the third laterally inclined rib portion 158c and the fourth laterally inclined rib portion 158d are formed with rib communication openings 161 at both ends, the ink passes through the rib communication openings 161, and the ink level is changed to the third horizontal oblique rib portion 158d. The rib portion 158c and the fourth laterally inclined rib portion 158d are located at substantially the same position on both sides. Further, the ink passes through a gap formed between the first horizontal oblique rib portion 158a, the second horizontal oblique rib portion 158b, and the film 133, and the ink level is changed to the first horizontal oblique rib portion 158a and the second horizontal oblique rib portion 158a. It moves to a position above the laterally inclined rib portion 158b. When the ink level further rises, the ink spreads up the inclined bottom surface 152a, and the ink level rises as the ink passes through the rib communication openings 161 of the fourth to ninth intersecting rib portions 157d to 157i. To do.

  Further, rib ventilation openings 160 are formed in the intersecting rib portions 157a to 157i, respectively. Therefore, the pressures in the spaces on both sides of the intersecting rib portions 157a to 157i in the second ink chamber 152 are substantially the same. Therefore, the liquid level of the ink in the second ink chamber 152 also rises so as to be substantially the same height in the vertical direction Z.

  By the way, in the liquid container 33 having the injection port 73, foreign matter such as dust or dust enters from the injection port 73, and the foreign matter itself accumulates or the ink dries at the gas-liquid interface. Sometimes it becomes. In the first ink chamber 151, foreign matter accumulates on the facing surface 153 and the recess 154. Since the wall communication opening 155 is formed away from the recess 154, the entry of foreign matter is suppressed as compared with the inflow of ink into the second ink chamber 152. That is, among foreign matters that have entered through the injection port 73, foreign matters that are particularly large in size or large in weight tend to stay in the first ink chamber 151.

  In the second ink chamber 152, as time passes, foreign matter accumulates on the laterally inclined rib portions 158a to 158d in the front region, and foreign matter accumulates on the bottom surface 152a in the rear region. The laterally inclined rib portions 158a to 158d and the bottom surface 152a on which foreign matter accumulates are inclined so as to intersect the front-rear direction Y. Therefore, when the ink is led out from the outlet 69 and the liquid level of the ink decreases, Foreign matter accumulated along with the movement of the surface moves in one direction (downward direction).

  Furthermore, when ink is injected from the injection port 73, bubbles may enter as the ink is injected. When the bubbles enter the second ink chamber 152 or the dissolved gas becomes bubbles in the second ink chamber 152, the bubbles move upward and reach the laterally inclined rib portions 158a to 158d. In this respect, in the present embodiment, since the horizontal oblique rib portions 158a to 158d intersect with the front-rear direction Y, the bubbles move along the inclined horizontal oblique rib portions 158a to 158d and are guided to the liquid surface. Is done.

  Further, the ink in the second ink chamber 152 flows through the outlet channel 138 from the channel opening 162 and is led out from the outlet 69. That is, first, foreign matter and bubbles are captured by the filter 166 from the ink drawn out from the flow path opening 162. Thereafter, the ink flows to the bent channel portion 163 via the second connection channel portion 164b and the third connection channel portion 164c.

  In addition, since the flow direction of ink changes in the bent flow path part 163, the gas melt | dissolved in the ink tends to grow into a bubble. In that respect, according to this configuration, since the cross-sectional area of the bent flow passage portion 163 is larger than the cross-sectional area of the third connection flow passage portion 164c, the generated bubbles are inclined to the inclined flow passage portion 165 side as the ink flows. Move to. Further, the inclined channel portion 165 has a cross-sectional area larger than the cross-sectional area of the third connection channel portion 164c, and is an upward slope toward the outlet port 69 side. For this reason, the bubbles generated in the bent channel portion 163 move to the outlet port 69 side through the inclined channel portion 165 and are led out together with the ink from the outlet port 69.

Next, the operation of the float valve 131 will be described.
In the state shown in FIG. 19, the ink level line IL in the ink chamber 137 is substantially above the threshold remaining amount line EL, that is, the ink remaining amount in the ink chamber 137 is equal to the liquid ejecting head 24. This indicates that the ink is ejected onto the paper S and is in a state necessary and sufficient to continue printing. For this reason, in the state shown in FIG. 19, the sum of the second urging force of the coil spring 195 and the buoyancy of the float member 181 is greater than or equal to the first urging force of the coil spring 184, so the float member 181 The valve body 182 is not brought into contact with the valve port 192 by being pushed downward by one urging force.

  That is, in this case, as shown in FIG. 19, the sum of the buoyancy generated by each gas chamber 187 of the float member 181 is superior to the first urging force of the coil spring 184, and the float member 181 It is in a floating state at a position away from 182 upward. On the other hand, since the valve body 182 is not pressed downward from the coil spring 184 via the float member 181, only the second upward biasing force from the coil spring 195 is received, and the valve port 192 It is located at the valve opening position that opens upward and opens the outlet flow path 138.

  Then, by continuing printing from the state shown in FIG. 19, the remaining amount of ink in the ink chamber 137 gradually decreases, and when the ink level line IL approaches the threshold remaining amount line EL, FIG. As shown, the sum of the buoyancy of the float member 181 and the second urging force of the coil spring 195 and the first urging force of the coil spring 184 are balanced with each other. Therefore, the float member 181 is pressed downward by the first urging force of the coil spring 184, and the pressing portion 189 on the lower surface thereof is in contact with the valve body 182 at the valve opening position from above. At this time, the float member 181 contacts the valve body 182 from above, but the valve body 182 has not yet been displaced toward the lower valve closing position.

  When the printing is further continued from the state shown in FIG. 28, the remaining amount of ink in the ink chamber 137 further decreases, and the ink level line IL becomes lower than the threshold remaining amount line EL. 29, the sum of the buoyancy of the float member 181 and the second urging force of the coil spring 195 is smaller than the first urging force of the coil spring 184. Therefore, the float member 181 is further pressed downward by the first biasing force of the coil spring 184, and presses the valve body 182 at the valve opening position downward by the pressing portion 189 on the lower surface thereof. As a result, the valve body 182 is displaced to the valve closing position where the valve port 192 is closed.

  Then, since the valve port 192 is closed, the outlet channel 138 is closed, so that ink does not flow downstream from the valve port 192. For this reason, as a result of the ink no longer flowing into the liquid chamber 53 disposed on the downstream side of the outlet flow path 138, the remaining amount detection rod 45 moves and the light between the light emitting portion and the light receiving portion of the sensor 68 is transmitted. Since the blocked state is maintained, the sensor 68 detects that the remaining amount of ink is less than the remaining threshold amount. In response to the detection result, when ink is newly injected into the ink chamber 137 from the injection port 73, the ink level line IL in the ink chamber 137 is again above the threshold remaining amount line EL. Therefore, the float member 181 is floated so that the buoyancy is greater than the first urging force of the coil spring 184 and away from the valve body 182.

  At this time, the valve body 182 in the closed position that is pressed downward by the pressing portion 189 of the float member 181 biased downward by the first biasing force of the coil spring 184 to close the valve port 192 is closed. When the state of the position is long, it may become stuck to the valve port 192 even after the pressure from above by the float member 181 is eliminated. In this regard, in the case of the present embodiment, the second biasing force of the coil spring 195 biases the valve body 182 in the valve closing position toward the upper valve opening position. Even if it sticks temporarily, it peels off from the valve port 192, and it cancels | releases such a sticking state.

  In addition, if ink is vigorously injected into the ink chamber 137 from the injection port 73, the inflow pressure of ink into the ink chamber 137 at the time of injection may increase. Therefore, the thin film member 186 that closes the opening 185a of the frame body 185 in the float valve 131 and forms the gas chamber 187 may be damaged if directly received such strong inflow pressure. In this regard, in the case of the present embodiment, the float valve 131 is disposed in the second ink chamber 152 that is partitioned by the partition wall 150 from the first ink chamber 151 in which the injection port 73 is formed. Therefore, it is avoided that the ink injected from the injection port 73 directly falls on the float valve 131 from above.

  In addition, even when the ink flows from the first ink chamber 151 side to the second ink chamber 152 side through the wall communication opening 155 formed in the partition wall 150, the float in the float valve 131 is caused by the inflow pressure. The thin film member 186 of the member 181 may be damaged. In this regard, in the present embodiment, the thin film member 186 is in the front-rear direction so as to be in a non-opposing state with respect to the front-rear direction Y, which is the direction of ink flow into the second ink chamber 152 via the wall communication opening 155. The float member 181 is disposed in the second ink chamber 152 so as to be in a state along Y. Therefore, the inflow pressure of the ink flowing into the second ink chamber 152 from the wall communication opening 155 acts on the thin film member 186 of the float member 181 so as to flow in the front-rear direction Y along the film surface.

  Incidentally, the thin film member 186 in the float member 181 is partially damaged due to deterioration over time, and some of the plural (four in this embodiment) gas chambers 187 may lose the sealed structure. obtain. In such a case, since the buoyancy of the entire float member 181 is reduced, the valve function of the float valve 131 may be hindered. However, in this embodiment, even when there is only one gas chamber 187, the sum of the buoyancy generated by the one gas chamber 187 and the second urging force of the coil spring 195 indicates that the remaining amount of ink is the threshold remaining. When the amount is greater than or equal to the amount, it is set to be greater than or equal to the first urging force of the coil spring 184. Therefore, even when the gas chamber 187 becomes one, the float valve 131 exhibits a valve function without any trouble.

  Further, when the float member 181 floats in the vertical direction Z in accordance with the change in the remaining amount of ink in the ink chamber 137, the float member 181 is inserted into the insertion hole 198 a of the cylindrical portion 198 in the front-rear direction Y. And the alignment in the left-right direction X is performed. And since the convex part 188 protruded from the front and back both sides | surfaces of the frame 185 is inserted in the guide long hole 201 of the control case 183, it is controlled that the float member 181 rotates centering | focusing on the rod-shaped part 190. FIG. Further, the float member 181 in a state where the coil spring 184 is placed is restricted from floating to a position higher than the valve opening position of the valve body 182 by the upper wall of the cylindrical portion 198 in the restriction case 183.

  Further, when the float member 181 floats in the front-rear direction Y and the left-right direction X in the ink chamber 137, for example, the thin film member 186 may come into surface contact with the opposing side wall 196a of the regulation case 183, thereby forming a cross-shaped plate shape. The portion 191 and the inner surface of the cylindrical portion 198 are regulated by contacting each other in the horizontal direction. That is, in the state where the rod-shaped portion 190 is inserted through the insertion hole 198a of the cylindrical portion 198, the float member 181 has a larger distance between the radial leading edge of the plate-shaped portion 191 and the inner side surface of the cylindrical portion 198. It is set to be smaller than the distance between the thin film member 186 and the inner surfaces of the left and right side walls 196a of the regulation case 183. Accordingly, the float member 181 is restricted from being in surface contact with both side walls 196 a of the restriction case 183 facing the thin film member 186 in the restriction case 183. In this respect, the plate-like portion 191 functions as an example of a regulating contact portion that regulates surface contact between opposing surfaces of the regulating case 183 and the float member 181 that are opposed to each other in the horizontal direction.

  In this case, a rectangular notch 199 is formed on the side wall 196a of the restricting case 183 and the thin film member 186 of the float member 181 facing each other in the left-right direction X toward the side wall 196a of the restricting case 183. Therefore, it is also suppressed that the thin film member 186 slides on the inner surface of the side wall 196a of the regulation case 183 and is damaged.

  In particular, when the float member 181 floats upward in the regulation case 183, the ink in the regulation case 183 may be pressed from below by the float member 181 to increase the ink pressure. In this respect, in this embodiment, such an increase in ink pressure allows ink to flow out from the through holes 202 and the cutout portions 199 formed at a plurality of locations of the regulation case 183, so that the ink pressure does not decrease. Increase in necessity is suppressed.

According to the above embodiment, the following effects can be obtained.
(1) Since the liquid container 21 is formed in the first part (first container part 37) where the injection port 73 is located outside the printer 11 in the liquid container 33, the liquid container 33 is connected to the printer 11. Ink can be injected in a fixed state. Therefore, it is possible to suppress damage during the ink injection operation and spilling of the liquid remaining inside. Further, when the fixed state is released by the second portion (second container portion 38) located in the printer 11 in the liquid container 33, the liquid container 33 is not dropped and is held by the printer 11. The probability that

  (2) The liquid container 21 uses a slider 34 that slides the recording chip 75 that records the information related to the ink injected into the liquid container 33 fixed so as not to move with respect to the liquid container 33. Thus, it can be moved from outside the printer 11 into the printer 11. For this reason, when the recording chip is designed to come into contact with, for example, the electrical terminals 78 provided in the liquid consuming device when the recording chip is moved into the liquid consuming device, the liquid container 33 can be used. It becomes possible to correctly transmit the relationship information of the injected ink to the printer 11. Further, after the recording chip 75 is placed outside the printer 11 with respect to the chip holder 76 provided at the moving part of the slider 34, the placed recording chip 75 is easily moved into the printer 11 by sliding the slider 34. It becomes possible to insert.

(3) Since the inlet 73 is covered by the slider 34, entry of foreign matter into the inlet 73 can be suppressed without providing a separate lid for the inlet 73.
(4) In the state where the slider 34 covers the injection port 73, the injection port 73 can be covered or exposed by the displacement of the provided opening / closing cover 74 without sliding the slider.

  (5) In a state where the open / close cover 74 is displaced from the closed position to the open position, the open / close cover 74 is positioned on the printer 11 side with respect to the inlet 73. Therefore, it is possible to prevent the opening / closing cover 74 from interfering with the operation when ink is injected into the injection port 73.

(6) Since the opening / closing cover 74 can be stably maintained at the closed position, it is possible to prevent the opening / closing cover 74 from being inadvertently opened and the injection port 73 from being exposed.
(7) Since the chip holder 76 is positioned in the printer 11 in a direction crossing the moving direction of the moving part, the recording chip 75 placed on the chip holder 76 is also accurately positioned in the printer 11. Therefore, for example, since the electrical terminal 78 provided in the printer 11 contacts the recording chip 75 in a state in which the positional deviation is suppressed, the transmission of the related information recorded on the recording chip 75 to the printer 11 is highly likely. Done.

  (8) Since the movement of the slider 34 in the sliding direction is suppressed, the chip holder 76 is accurately positioned in the printer 11 with respect to the sliding direction of the slider 34. Further, since the recording chip 75 placed on the chip holder 76 is inclined with respect to the sliding direction of the slider 34, for example, the electrical terminal 78 provided in the printer 11 is placed on the recording chip 75 (electrode 75a). It moves while rubbing and is electrically connected. Therefore, the reliability of electrical conduction is increased.

  (9) When the user injects ink into the first ink chamber 151 (ink chamber 137) of the liquid container 33 through the injection port 73, the user may hang the ink around the injection port 73, The ink can be received by the liquid receiving surface 116. Since the liquid receiving surface 116 is inclined downward (in the direction of gravity) toward the injection port 73, the ink received on the liquid reception surface 116 is guided to the injection port 73 along the inclined liquid reception surface 116. The Therefore, even when ink is dripped around the injection port 73 when the ink is injected into the injection port 73 of the liquid storage container 21, the ink travels from the periphery of the injection port 73 to the outer surface of the liquid storage container 21. It is possible to prevent the surroundings from becoming dirty.

  (10) The peripheral wall portion 117 surrounding the liquid receiving surface 116 prevents the ink from overflowing to the outside of the liquid receiving surface 116 when ink is injected into the first ink chamber 151 of the liquid container 33. be able to.

  (11) When the user injects ink from the liquid injection source 126 into the first ink chamber 151 via the injection port 73, the user brings the liquid injection source 126 into contact with the cutout groove 118 of the peripheral wall portion 117. The liquid injection source 126 can be positioned. Accordingly, the user can stably inject ink when injecting ink from the liquid injection source 126 into the first ink chamber 151.

  (12) The covering 120 that covers the injection port 73 is fixed to the liquid container 33 via the connecting portion 125 and the fixing portion 123. For this reason, when the covering 120 is removed from the inlet 73, the possibility of losing the covering 120 can be reduced. In addition, by covering the injection port 73 with the covering body 120, it is possible to prevent ink from evaporating from the first ink chamber 151 and foreign matters from being mixed into the first ink chamber 151.

  (13) When the ink is injected, the cover 120 can be placed on the back surface 74a of the open / close cover 74 located at the open position. According to this, when the user injects ink into the first ink chamber 151, for example, by holding the covering body 120 in one hand, it is possible to prevent the ink from being injected while the one hand is blocked. be able to.

  (14) When the cover 120 is placed on the opening / closing cover 74 located at the open position, even if ink adheres to the covering 120, the ink leaks out of the opening / closing cover 74. It can be suppressed by the shielding part.

  (15) The cover 120 can be placed so as to be within the surface area of the back surface 74a of the open / close cover 74 located at the open position. Further, even if ink is attached to the placed cover 120, the back surface 74a of the opening / closing cover 74 is inclined downward (in the direction of gravity) toward the injection port 73, so that the ink covers the entire area of the back surface 74a. Can be suppressed.

  (16) Since the connecting portion 125 of the covering member is bent, it can be placed on the liquid receiving surface 116 with good storability. In addition, when ink is attached to the cover 120 when the cover 120 is removed from the injection port 73 as compared with the case where the link 125 is formed linearly, the ink is connected to the link 125 can be made difficult to transmit.

  (17) Since the fixing portion 123 is fixed at a position higher than the injection port 73 on the liquid receiving surface 116, the ink flowing on the liquid receiving surface 116 is covered when the ink is injected into the liquid container 33. It is possible to make it difficult to adhere to the fixing portion 123 of the member 121. According to this, for example, it is possible to prevent the fixed state of the fixing unit 123 from being affected by the ink adhering to the fixing unit 123 and solidifying.

  (18) When a user tries to inject a plurality of types of ink into a plurality of liquid storage containers 21 (ink chambers 137), the covering 120 provided corresponding to one liquid storage container 21 is It is possible to suppress covering the injection port 73 of another liquid storage container 21 provided in parallel with the liquid storage container 21. According to this, the covering body 120 provided corresponding to one liquid container 21 covers the inlet 73 of the other liquid container 21, so that the ink chamber 137 of the other liquid container 21 is covered. It is possible to prevent ink from entering through the covering body 120 from being mixed therein.

  (19) The wall communication opening 155 is located at a position twisted with respect to the inlet 73 and away from the facing surface 153. Therefore, ink injected from the injection port 73 flows into the second ink chamber 152 through the wall communication opening 155, whereas foreign matter mixed in from the injection port 73 is generated in the first ink chamber 151. Foreign matter is less likely to pass through the wall communication opening 155 than ink. That is, foreign matter can be easily retained in the first ink chamber 151, so that the ink in which foreign matter is suppressed flows into the second ink chamber 152. Therefore, even when foreign matter is mixed from the injection port 73 or when foreign matter is generated inside, the ink can be favorably derived while reducing the possibility that the mixed foreign matter is led out from the outlet port 69.

  (20) Since the concave portion 154 in which the facing surface 153 is recessed in the direction of gravity is formed, even if the foreign matter staying in the first ink chamber 151 settles with time, the foreign matter can be accumulated in the concave portion 154. . That is, when ink is injected from the injection port 73 with foreign matter accumulated in the recess 154, it is possible to suppress the foreign matter accumulated from the recess 154 from flying out of the recess 154.

  (21) Foreign matter that is mixed or generated can be deposited in the recess 154. Since the concave portion 154 is provided with a position shifted from the injection port 73 in the direction intersecting the gravity direction, the rise of the foreign matter accumulated in the concave portion 154 when ink is injected from the injection port 73 is further suppressed. be able to.

  (22) By making the distance L1 between the flow path opening 162 and the partition wall 150 smaller than the distance L2 between the upper end of the recess 154 and the lower end of the wall communication opening 155, the flow path opening 162 is positioned closer to the partition wall 150. Can be formed. Therefore, it is possible to reduce the possibility that foreign matters that have passed through the wall communication opening 155 together with ink from the first ink chamber 151 side to the second ink chamber 152 side settle into the flow channel opening 162 and enter the outlet flow channel 138.

  (23) Even when foreign matter enters the second ink chamber 152 or when foreign matter is generated in the second ink chamber 152, the foreign matter settled in the second ink chamber 152 is accumulated in the laterally inclined rib portions 158a to 158d. Can be made. Therefore, it is possible to further suppress foreign matters from being mixed into the ink led out from the flow path opening 162 located on the gravity direction side of the laterally inclined rib portions 158a to 158d to the outlet flow path 138.

  (24) Since the laterally inclined rib portions 158a to 158d extend along the direction intersecting the vertical direction Z and the longitudinal direction Y, the laterally inclined rib portions accompany the decrease in the ink stored in the second ink chamber 152. Foreign matter deposited on 158a to 158d can be collected in one direction.

  (25) The float valve 131 that displaces the valve body 182 using the float member 181 that floats with a change in the remaining amount of ink may malfunction due to the weight of the accumulated foreign matter, for example, when foreign matter accumulates on the float member 181. is there. In this respect, foreign matters can be deposited on the laterally inclined rib portions 158a to 158d provided on the anti-gravity direction side of the float valve 131, so that the foreign matter settled in the second ink chamber 152 is deposited on the float member 181. Can be suppressed.

  (26) The foreign matter accumulated in the third laterally inclined rib portion 158c and the fourth laterally inclined rib portion 158d moves as the remaining amount of ink stored in the second ink chamber 152 changes, and the third laterally inclined rib portion 158c moves. And even if it falls from the 4th horizontal oblique rib part 158d, a foreign material can be dropped so that the float valve 131 may be avoided.

  (27) The ink led out from the flow path opening 162 can pass through the filter 166 and then flow toward the float valve 131 side. That is, for example, among the foreign matters mixed into the ink in the first ink chamber 151 from the injection port 73, the relatively large foreign matter stays in the first ink chamber 151, and the horizontal oblique rib portion in the second ink chamber 152. Deposits at 158a-158d. Therefore, the foreign matter mixed in the ink led out from the flow passage opening 162 is relatively small in size, so even if the foreign matter enters from the flow passage opening 162, compared to the case where a large foreign matter enters. Thus, clogging of the outlet channel 138 is suppressed. Furthermore, foreign matters mixed in the ink led out from the outlet 69 can be further reduced by passing the ink through the filter 166 provided in the outlet channel 138.

  (28) Since the area of the wall communication opening 155 is smaller than the area of the injection port 73, the foreign material enters the second ink chamber 152 through the wall communication opening 155 when a large foreign material enters from the injection port 73. The fear can be reduced.

  (29) Bubbles in the ink tend to stay in the bent portion in the outlet flow path 138. In that regard, the bubbles located in the bent flow channel portion 163 are guided to the outlet 69 side through the inclined flow channel portion 165. Therefore, for example, since the bubbles staying in the bent flow path portion 163 can be increased and the discharge flow path 138 can be blocked, the ink can be discharged while reducing the influence of the bubbles.

(30) Bubbles that have already occurred can be captured in advance by passing the filter 166 before the ink flows to the bent flow path portion 163 where the bubbles tend to stay.
(31) Since the bubbles generated in the ink chamber 137 move upward in the direction of gravity, the possibility that the bubbles enter the outlet channel 138 from the channel opening 162 is reduced by opening the channel opening 162 on the bottom surface 152a. be able to.

  (32) The ink chamber 137 can be reinforced by forming the laterally inclined rib portions 158a to 158d. Further, since the laterally inclined rib portions 158a to 158d extend along the direction intersecting the horizontal direction, when bubbles are generated in the ink stored in the ink chamber 137, the bubbles are aligned along the laterally inclined rib portions 158a to 158d. Can be moved. That is, it is possible to reduce the possibility that bubbles are trapped in the laterally inclined rib portions 158a to 158d.

  (33) The bottom surface 152 a of the ink chamber 137 can be inclined along the inclined channel portion 165. That is, since the inclined flow path portion 165 is formed so that the flow path opening 162 side is lowered, the ink in the ink chamber 137 can be collected on the flow path opening 162 side.

(34) Since the cross-sectional area of the inclined channel portion 165 is large, the possibility that the inclined channel portion 165 is blocked by bubbles generated in the bent channel portion 163 can be reduced.
(35) Even when bubbles are generated in the wall communication opening 155, the upper surface 155c on the antigravity direction side is inclined, so that the possibility of bubbles remaining in the wall communication opening 155 can be reduced.

  (36) The wall vent opening 156 formed in the partition wall 150 can reduce the pressure difference between the first ink chamber 151 and the second ink chamber 152. Further, the wall ventilation opening 156 formed in the partition wall 150 is formed closer to the ceiling surface 137b than the rib ventilation opening 160 formed in the intersecting rib portions 157a to 157i, so that the ink in the second ink chamber 152 is discharged. The possibility of entering the first ink chamber 151 from the wall ventilation opening 156 can be reduced.

(37) By forming the positioning ridge 141, the displacement of the air passage forming film 147 can be suppressed and the ridges 142 and 143 can be easily bonded.
(38) The filter 166 can be easily replaced by attaching the filter 166 to the first flow path forming recess 168a formed on the lower surface 40 of the housing case 130.

  (39) The float valve 131 disposed in the second ink chamber 152 of the liquid container 33 is configured such that the thin film member 186 that closes the opening 185 a of the gas chamber 187 is injected from the injection port 73 to the second ink chamber 152. It does not directly receive the inflow pressure of the ink flowing in. That is, the inflow pressure of ink acts on the thin film member 186 along the film surface. Therefore, even when ink is vigorously injected into the first ink chamber 151 of the ink chamber 137 from the outside through the injection port 73, the inflow pressure of the ink passes through the first ink chamber 151 and the second ink chamber. The strong action in the direction of pressing the thin film member 186 against the thin film member 186 of the float member 181 in 152 can be suppressed. Therefore, an appropriate valve operation can be maintained without the float valve 131 disposed inside being damaged by the inflow pressure of ink injected from the outside.

  (40) Since the float valve 131 is arranged in the second ink chamber 152 partitioned by the partition wall 150 from the first ink chamber 151 in which the injection port 73 is formed, the float valve 131 is injected from the outside through the injection port 73. In addition, it is possible to avoid the ink falling directly on the float valve 131, and in this respect, the possibility of damage to the float valve 131 can be further reduced.

  (41) Even if one gas chamber 187 out of a plurality (four as an example) is broken due to damage or the like, the total volume of the remaining gas chambers 187 is desired in the float member 181. If the volume of the gas chamber 187 is designed so as to generate buoyancy, the function of the float valve 131 can be maintained well.

  (42) In particular, the remaining amount of ink remains in the threshold value by injecting ink through the injection port 73 from the state where the remaining amount of ink is less than the remaining threshold value and the valve element 182 is in the closed position for a long period of time. When the amount exceeds the amount, the valve body 182 can be prevented from sticking to the valve closing position, and the valve body 182 can be quickly displaced from the valve closing position to the valve opening position.

  (43) When the float member 181 floats in the vertical direction Z while suppressing the inflow pressure of the ink flowing into the second ink chamber 152 from directly reaching the float member 181 by the annular wall portion 196 of the restriction case 183. Further, it is possible to reduce the possibility of generating a movement resistance by sliding in a surface contact state with respect to the annular wall portion 196 of the regulation case 183.

(44) When the float member 181 floats in the vertical direction, the possibility that the thin film member 186 slides on the annular wall portion 196 of the restriction case 183 and is damaged can be reduced.
(45) When the float member 181 floats in the vertical direction Z, the ink is allowed to flow between the inside and the outside of the annular wall portion 196 of the restriction case 183 via the through hole 202. A smooth floating state of the float member 181 according to the remaining amount change can be ensured.

  (46) Since the opposing surfaces of the regulation case 183 and the float member 181 facing each other in the horizontal direction, that is, the thin film member 186 and the side wall 196a can be reduced by the surface tension of the ink, the float valve 131 can be reduced. Therefore, it is possible to maintain the proper valve operation well.

  (47) Since the valve body 182 can be displaced between the valve opening position and the valve closing position by simply pressing the float member 181 against the valve body 182 with a small stroke, the float valve 131 can be made compact. Can contribute.

The above embodiment may be changed to another embodiment as described below.
In the above embodiment, the chip holder 76 may be inserted into the slider 34 by being inserted into the slider 34 from a direction along the sliding direction of the slider 34 with respect to the liquid container 33, that is, a direction along the longitudinal direction. . Further, the recording chip 75 attached to the chip holder 76 is not necessarily inclined with respect to the sliding direction of the slider 34 but is placed on the chip holder 76 in a state parallel to or perpendicular to the sliding direction, for example. May be.

  In the above embodiment, the groove shape portion 107 as an example of the positioning shape portion that is positioned in the printer 11 does not necessarily have to be provided in the chip holder 76 when the moving portion of the slider 34 moves into the printer 11. . For example, when the slider 34 is inserted into the mounting unit 31 in a state of being positioned with respect to the communication unit 77, the positioning shape unit is not necessary.

  In the above embodiment, the engaging portion (groove portion 112) with the opening / closing cover 74 is not necessarily provided on the slider 34. For example, when the bearing portion 90 of the opening / closing cover 74 is configured to be engaged with the rotary shaft 89 of the slider 34 in an interference fit state, a rotational load is obtained by the interference fit, and thus the engagement portion is unnecessary. .

  In the above embodiment, the opening / closing cover 74 does not necessarily have to be configured to rotate about the axis extending along the short direction of the liquid container 33 as the rotation center. For example, a configuration may be adopted in which the slider 34 is translated in the longitudinal direction and displaced from the closed position to the open position.

  In the embodiment described above, the opening / closing cover 74 is not necessarily provided in the slider 34 provided in a state of covering the injection port 73. In this case, the ink injection port 73 may be exposed by removing the slider 34 from the printer 11 (mounting portion 31).

  In the above embodiment, the injection port 73 is not necessarily provided on the upper surface 39 on the anti-gravity direction side in the liquid container 33. For example, you may provide in the side surface located in the horizontal direction side. Further, the slider 34 does not necessarily have to be provided so as to cover the injection port 73. In such a case, the inlet 73 may be covered with a member different from the slider 34.

  In the above embodiment, the chip holder 76 is not necessarily limited to the configuration that is attached to the holder attaching portion 86 of the slider 34. For example, the chip holder 76 may be formed integrally with a part of the slider 34.

  In the above embodiment, the medium is not limited to the paper S, and may be a plate-like member made of a metal plate, a resin plate, a cloth, or the like. That is, any member that can be recorded (printed) by the liquid ejected by the liquid ejecting head 24 can be used as the medium.

  In the above embodiment, the liquid consuming device is not limited to the serial type printer 11 in which the liquid ejecting head 24 moves reciprocally with the carriage 25, and can perform printing in the maximum paper width range even when the liquid ejecting head 24 is fixed. A simple line head type printer may be used.

In the above embodiment, the covering member 121 only needs to include at least the covering body 120.
In the above embodiment, an absorbing material capable of absorbing ink may be disposed on the back surface 74 a of the opening / closing cover 74.

  In the above-described embodiment, the connecting portion 125 may not have a shape that is bent a plurality of times on the liquid receiving surface 116. For example, the connecting portion 125 may be formed in an L shape in plan view by bending only once at a part of the connecting portion 125. The connecting portion 125 may be formed of a metal chain or the like and placed on the liquid receiving surface 116.

  In the above embodiment, the back surface 74a of the opening / closing cover 74 does not have to be a downwardly inclined surface toward the inlet 73 when the opening / closing cover 74 is located at the open position. In this case, it is desirable that the above-described ink absorbing material is disposed on a portion of the back surface 74a of the opening / closing cover 74 where the covering 120 is placed.

In the above embodiment, the covering 120 of the covering member 121 may not be placed on the back surface 74 a of the opening / closing cover 74.
In the above embodiment, the notch groove 118 may be provided at a peripheral position of the inlet 73 excluding the peripheral wall portion 117. For example, it may be formed at the opening edge 73 a of the inlet 73. Moreover, you may provide the convex part which protrudes upwards from the surrounding wall part 117 instead of the notch groove 118 as a recessed part. In this case, it is desirable to provide two convex portions so that the liquid injection source 126 can be positioned from both sides.

  In the above embodiment, the area of the wall communication opening 155 may be the same as the area of the injection port 73. Further, the area of the wall communication opening 155 may be larger than the area of the injection port 73.

  In the above embodiment, the filter 166 may not be provided. Further, the filter 166 may be provided so as to cover the flow path opening 162 in the second ink chamber 152.

In the above embodiment, the float valve 131 may not be provided.
-In the said embodiment, it is good also as a structure which does not provide the horizontal oblique rib part 158a-158d. Further, the laterally inclined rib portions 158a to 158d may be individually provided, and any of the laterally inclined rib portions 158a to 158d can be arbitrarily selected. For example, only one of the laterally inclined rib portions 158a to 158d may be provided. Further, for example, any two laterally inclined rib parts such as the third laterally inclined rib part 158c and the fourth laterally inclined rib part 158d, or any one of the first to third laterally inclined rib parts 158a to 158c. It is good also as a structure which provides three horizontal oblique rib parts.

  In the above embodiment, the laterally inclined rib portions 158a to 158d may not only extend along one direction but may be partially bent or curved. That is, for example, the laterally inclined rib portions 158a to 158d may have a portion extending along the gravity direction and a portion intersecting the gravity direction.

  In the above embodiment, the third horizontal oblique rib portion 158c and the fourth horizontal oblique rib portion 158d do not have to be line symmetrical. That is, for example, the third laterally inclined rib portion 158c and the fourth laterally inclined rib portion 158d may be formed so as to be shifted in the vertical direction Z by one. In addition, the axis that is the reference for line symmetry of the third laterally inclined rib portion 158c and the fourth laterally inclined rib portion 158d may pass through the float valve 131 at any position as long as it is along the direction of gravity. The third laterally inclined rib portion 158c and the fourth laterally inclined rib portion 158d may be partially symmetrical with respect to the axis.

  In the above embodiment, the laterally inclined rib portions 158a to 158d may be formed so as to extend along the front-rear direction Y. Further, the laterally inclined rib portions 158a to 158d may be formed so as to extend in a direction intersecting with the left-right direction X.

In the above embodiment, the laterally inclined rib portions 158a to 158d may be provided with their positions shifted in the vertical direction Z from the flow path opening 162.
In the above embodiment, the channel opening 162 may be formed at a position other than the bottom surface 152a. For example, a channel opening may be formed in the side wall 130b. Further, the flow path opening 162 may be formed at a position away from the partition wall 150. That is, the distance L1 may be longer than the distance L2.

  In the above embodiment, the concavity 153 may not be provided with the recess 154. Moreover, you may form the recessed part 154 so that it may dent toward the direction which cross | intersects a gravitational direction. Further, the recess 154 may be formed so as to coincide with the injection virtual line M. That is, the recess 154 may be formed at a position on the gravity direction side of the inlet 73. The concave portion 154 and the injection port 73 have different shapes in top view, and the size of the concave portion 154 is larger than the injection port 73 in the left-right direction X. Therefore, even if the recess 154 is formed at the position on the gravity direction side of the injection port 73, a part of the recess 154 is positioned at a position shifted from the injection port 73 in the direction intersecting the gravity direction. Therefore, the recess 154 may be formed smaller than the injection port 73 in top view, and the injection port 73 and the recess 154 may be formed in the same shape.

In the above embodiment, the liquid container 21 may be configured without the slider 34. In other words, the liquid storage container 21 may be configured with only the liquid storage body 33.
In the above embodiment, the partition wall 150 may be provided so as to intersect with the vertical direction Z.

-In above-mentioned embodiment, the container case 130 is good also as a structure which is not provided with the cross rib part 157a-157i.
In the above embodiment, the upper surface 155c of the wall communication opening 155 may be formed along the horizontal direction.

  In the above embodiment, the cross-sectional area of the inclined channel portion 165 may be the same size as the cross-sectional area of the connection channel portion 164. Further, the cross-sectional area of the inclined channel portion 165 may be larger than the cross-sectional area of the bent channel portion 163. In addition, the cross-sectional area of the inclined channel portion 165 may be smaller than the cross-sectional area of the connection channel portion 164 and the cross-sectional area of the bent channel portion 163.

  In the above embodiment, the inclined channel portion 165 may be provided at a position deviated from the lower position in the gravity direction of the ink chamber 137. That is, for example, the inclined channel portion 165 may be provided adjacent to the ink chamber 137 through the side wall 130b.

  In the above embodiment, the valve body 182 that is fixed to the bottom surface 152a of the second ink chamber 152 is omitted, and the valve port 192 is closed when the pressing portion 189 that protrudes vertically downward from the lower surface of the float member 181 moves downward. You may make it fulfill | perform the function as a possible valve body.

  In the above embodiment, the cross-sectional shape of the plate-like portion 191 that functions as an example of the restriction contact portion of the float member 181 with respect to the restriction case 183 may be other than a cross shape. In short, if the distance between the portion constituting the restricting contact portion and the inner surface of the cylindrical portion 198 is smaller than the distance between the thin film member 186 and the inner surface of the annular wall portion 196, the shape thereof is used. Can be arbitrarily changed.

  In the above embodiment, the shape of the through hole 202 in the restriction case 183 is not limited to a rectangular shape, and may be a round shape, a triangular shape, or a notch shape. In short, the shape can be arbitrarily changed as long as it allows the ink to flow when the float member 181 floats.

  In the above embodiment, the notch 199 formed in the side wall 196a along the front-rear direction Y of the restriction case 183 may be omitted. Alternatively, the notch 199 may be formed on the side wall 196b along the left-right direction X. Also in this case, the notch portion 199 can fulfill the function of reducing the possibility that the float member 181 slides when floating, in addition to allowing the inside and outside of the restriction case 183 to communicate and allowing the ink to flow.

In the above embodiment, the coil spring 195 having the second urging force that urges the valve body 182 toward the upper valve opening position may be omitted.
In the above embodiment, the float member 181 may have at least one gas chamber 187. That is, the number of gas chambers 187 is not necessarily limited to four, and may be at least one such as two, three, and five.

  In the above embodiment, the partition wall 150 that partitions the ink chamber 137 into the first ink chamber 151 and the second ink chamber 152 may be omitted. That is, there may be a configuration in which the liquid container 33 has only one ink chamber 137 and the float valve 131 is disposed in the one ink chamber 137.

  In the above embodiment, the shape of the regulation case 183 is not limited to the box shape, and an annular shape that surrounds the float member 181 so as to protect the float member 181 against the inflow pressure of the ink flowing into the second ink chamber 152. If it has the wall part 196, the shape can be changed arbitrarily.

  In the above embodiment, the restriction member may be a frame shape instead of a box shape like the restriction case 183. In short, when the float member 181 floats upward as the ink level rises, the float member 181 has a structure that abuts and regulates so that the upward floating stops at a position lower than the ceiling of the ink chamber 137. If there is, the shape can be arbitrarily changed.

  In the above embodiment, the thin film member 186 that forms the gas chamber 187 by closing the opening 185a of the float member 181 may be a thin resin sheet or plate, for example, in addition to the film.

  In the above embodiment, the posture of the liquid storage container 21 when used is not limited to the state in which the liquid storage container 21 is mounted on the mounting portion 31 of the printer 11 and is immovably fixed to the printer 11. The usage form connected so that a liquid can be supplied with a tube in the state mounted in the side of 11 may be sufficient.

In the above embodiment, the liquid container and the liquid injection source have been described, but both can be expressed as a liquid container.
In the above embodiment, the liquid consuming device may be a liquid ejecting device that ejects or ejects liquid other than ink. Note that the state of the liquid ejected as a minute amount of liquid droplets from the liquid ejecting apparatus includes a granular shape, a tear shape, and a thread-like shape. The liquid here may be any material that can be ejected from the liquid ejecting apparatus. For example, it may be in a state in which the substance is in a liquid phase, such as a liquid with high or low viscosity, sol, gel water, other inorganic solvents, organic solvents, solutions, liquid resins, liquid metals (metal melts ). Further, not only a liquid as one state of a substance but also a substance in which particles of a functional material made of a solid such as a pigment or a metal particle are dissolved, dispersed or mixed in a solvent is included. Typical examples of the liquid include ink and liquid crystal as described in the above embodiment. Here, the ink includes general water-based inks and oil-based inks, and various liquid compositions such as gel inks and hot melt inks. As a specific example of the liquid ejecting apparatus, for example, a liquid containing a material such as an electrode material or a color material used for manufacturing a liquid crystal display, an EL (electroluminescence) display, a surface emitting display, or a color filter in a dispersed or dissolved form. There is a liquid ejecting apparatus for ejecting the liquid. Further, it may be a liquid ejecting apparatus that ejects a bio-organic matter used for biochip manufacturing, a liquid ejecting apparatus that ejects liquid as a sample that is used as a precision pipette, a printing apparatus, a micro dispenser, or the like. In addition, transparent resin liquids such as UV curable resin to form liquid injection devices that pinpoint lubricant oil onto precision machines such as watches and cameras, and micro hemispherical lenses (optical lenses) used in optical communication elements. May be a liquid ejecting apparatus that ejects the liquid onto the substrate. Further, it may be a liquid ejecting apparatus that ejects an etching solution such as acid or alkali in order to etch a substrate or the like.

  DESCRIPTION OF SYMBOLS 11 ... Printer (an example of a liquid consumption apparatus), 21 ... Liquid container, 33 ... Liquid container, 34 ... Slider (an example of a sub-holding member), 37 ... 1st container part (an example of 1st site | part), 38 2nd container part (example of second part), 39 ... upper surface, 69 ... lead-out port, 73 ... injection port, 74 ... open / close cover, 74a ... back surface (example of bottom surface), 75 ... recording chip (of storage part) (Example), 76 ... Chip holder (an example of a storage unit holding member), 77 ... Communication unit, 91a, 92a ... Cover side wall (an example of a shielding unit), 95 ... Recess, 97 ... Recess, 116 ... Liquid receiving surface (Liquid) Example of receiving part), 117 ... peripheral wall part (example of peripheral position), 118 ... notch groove (example of recess), 121 ... covering member, 120 ... covering body, 123 ... fixing part, 125 ... connecting part, 126 ... Liquid injection source, 131 ... float valve, 137 ... ink chamber ( Example of body storage chamber) 137b ... Ceiling surface (example of injection port forming surface), 138 ... Derivation channel (example of liquid channel), 150 ... Partition wall, 151 ... First ink chamber (first liquid storage chamber) ,..., 152... Second ink chamber (an example of a second liquid storage chamber), 152 a... Bottom surface, 153. ... wall ventilation openings (ventilation openings), 157a to 157i ... intersecting rib parts, 158a to 158d ... horizontal oblique rib parts (an example of flanges), 160 ... rib ventilation openings (an example of ventilation openings), 162 ... flow path openings, 163: Bent channel portion, 164: Connection channel portion, 165: Inclined channel portion, 160 ... Rib communication opening (an example of communication opening), 166 ... Filter, 181 ... Float member, 182 ... Valve body, 183 ... Restriction Case (example of regulating member) 184 ... Coil spring (an example of an urging member and a first urging member), 185a ... an opening, 186 ... a thin film member, 187 ... a gas chamber, 191 ... a plate-like part (an example of a regulating contact part), 195 ... a coil Spring (an example of a second urging member), 196: annular wall portion, 199 ... notch, 202 ... through hole, L1, L2 ... distance, L6, L7 ... distance, X ... left-right direction, Y ... front-back direction, Z: Vertical direction.

Claims (10)

A first liquid storage chamber formed with an inlet capable of injecting the liquid to be supplied to a liquid consuming device that consumes the liquid;
A second liquid container that is partitioned from the first liquid storage chamber by a partition wall that intersects an opposing surface that faces the injection port forming surface on which the injection port is formed and that communicates with the first liquid storage chamber through a communication opening. A room and
The second liquid storage chamber is formed with a lead-out port for leading the liquid to the liquid consuming device,
The communication opening is formed at a position twisted with respect to the inlet and away from the facing surface,
The area of the communication opening is smaller than the area of the partition wall,
The volume of the first liquid storage chamber is smaller than the volume of the second liquid storage chamber. The liquid container according to claim 1, wherein a concave portion recessed in a gravitational direction in a posture state during use is formed on the facing surface. The liquid container according to claim 2, wherein at least a part of the concave portion is formed at a position shifted from the injection port in a direction intersecting with a gravitational direction in a posture state during use. A liquid flow path connecting the flow path opening formed on the bottom surface of the second liquid storage chamber and the outlet port;
The liquid container according to any one of claims 1 to 3, wherein a distance between the flow path opening and the partition wall is shorter than a distance between the facing surface and the communication opening. . The said 2nd liquid storage chamber is further equipped with the collar part provided so that it may cover the said flow-path opening on the position of an antigravity direction rather than the said flow-path opening in the attitude | position state at the time of use. 5. The liquid container according to 4. The liquid container according to claim 5, wherein at least a part of the flange portion is formed along a direction intersecting the gravitational direction and the horizontal direction in a posture state during use. . A valve body that is displaceable between a valve opening position for opening the liquid flow path and a valve closing position for closing the liquid flow path;
And a float member that floats and displaces the valve body in accordance with a change in the remaining amount of the liquid in the second liquid storage chamber,
The liquid container according to claim 5, wherein the flange portion is provided on the antigravity direction side of the float valve in a posture state during use. The collar part is composed of a first collar part and a second collar part,
The first collar part and the second collar part are arranged symmetrically with respect to an axis along the direction of gravity passing through the float member,
The distance between the upper end of the first collar part and the upper end of the second collar part in the posture state during use is shorter than the distance between the lower end of the first collar part and the lower end of the second collar part. The liquid container according to claim 7. The liquid container according to claim 7 or 8, further comprising a filter between the channel opening and the float valve in the liquid channel. 10. The liquid container according to claim 1, wherein an area of the communication opening is smaller than an area of the injection port.