The present invention relates to a liquid supply device, which includes a liquid container that can be filled with a liquid such as ink, and a printing device, which performs printing using liquid supplied from the liquid supply device.
One example of a known printing device is an inkjet printer that ejects a liquid such as ink from a printing unit onto a medium to print an image or the like. In the prior art, one example of such a printer includes a liquid container such as a tank that can be filled with a liquid used for printing such as ink. The printer performs printing using the liquid that is supplied from the liquid container through a liquid supply tube (for example, refer to patent document 1).
Patent Document 1: JP-A-2014-54824
In the printer described above, the liquid container is filled with liquid by the user. Thus, it is desirable that the convenience of such a printer be further improved.
It is an object of the present invention to provide a liquid supply device and a printing device that improve convenience.
The means for achieving the object described above and the effects of such means will now be described.
A liquid supply device that achieves the above object includes a liquid container that includes a liquid containing chamber, which is capable of containing liquid, and a liquid inlet, which allows the liquid containing chamber to be filled with liquid. An external member covers at least a portion of the liquid container excluding a portion where the liquid inlet is located from an outer side. A seal member seals a gap between the external member and the liquid inlet. The liquid supply device is configured to allow the liquid to be supplied from the liquid container to a printing unit that performs printing on a medium using the liquid.
With this structure, situations are reduced in which liquid leaking from the liquid inlet enters and smears the inside of the external member, which covers the liquid container.
Preferably, in the liquid supply device, the seal member includes a recess that allows for collection of the liquid that leaks from a side of the liquid inlet on the seal member.
With this structure, when adding liquid, if liquid leaks from the liquid inlet onto the seal member, the leaked liquid is collected in the recess of the seal member. This avoids a situation in which the leaked liquid spreads in an unnecessary manner.
Preferably, in the liquid supply device, the external member includes a liquid container housing that covers the liquid container separately from a shell that accommodates the printing unit.
With this structure, the liquid supply device can easily be connected to the printing device for retrofitting.
Preferably, in the liquid supply device, the external member includes both of a shell, which covers the printing unit, and a liquid container housing, which covers the liquid container in cooperation with the shell.
With this structure, part of the shell accommodating the printing unit can be used as part of the external member.
Preferably, in the liquid supply device, the external member includes a liquid guide that guides the liquid in a direction that is directed away from the printing unit.
With this structure, even if liquid accidentally leaks onto the external member when adding the liquid, the liquid is guided away from the printing unit by the liquid guide. This reduces situations in which the leaked liquid smears the medium that has undergone printing.
Preferably, the liquid supply device includes a plug that closes the liquid inlet. The seal member is integrated with the plug.
With this structure, situations are reduced in which the plug becomes lost when removed from the liquid inlet.
Preferably, in the liquid supply device, the seal member is a first seal member. The liquid supply device further includes a second seal member that is separate from the first seal member. The liquid container includes a visual checking portion that allows a remaining amount of the liquid contained in the liquid containing chamber to be visible. The external member covering the liquid container includes an exposing portion that exposes the visual checking portion. The second seal member is arranged in the exposing portion to seal a gap between the visual checking portion and the external member.
With this structure, even if, for example, liquid enters the space between the liquid container and the external member when filling the liquid containing chamber with liquid, the second seal member reduces situations in which the liquid leaks out of the exposing portion.
Preferably, in the liquid supply device, the second seal member is integrated with a plug that closes the liquid inlet of the liquid container.
With this structure, the number of components can be reduced.
A printing device that achieves the above object includes a printing unit, which performs printing on a medium using liquid, and the liquid supply device.
With this structure, the same advantages as the liquid supply device can be obtained.
A first embodiment of an all-in-one machine including a printing device will now be described with reference to the drawings. The printing device in the present embodiment is configured by an inkjet printer that ejects ink, which is one example of a liquid, onto paper, which is one example of a medium, to perform printing. The printer is a so-called serial printer that performs printing by moving a liquid ejection head, which functions as a printing unit, in a main scanning direction, which intersects a paper transfer direction. In the description hereafter, the paper transfer direction will be referred to as “the front-rear direction.” The main scanning direction in which the printing unit moves will be referred to as “the lateral direction.” The vertical direction that conforms to the gravitational direction will be referred to as “the up-down direction.”
As shown in
The printing device 12 includes an operation panel 18, which is located on the upper front surface of the upper shell 17 at a generally middle portion in the lateral direction. The operation panel 18 is operated to perform various actions with the all-in-one machine 11. The operation panel 18 includes, for example, a power button 18a, a touch panel type LCD screen 18b, an operation button 18c, and the like. The operation panel 18 has a rectangular shape elongated sideward as viewed from the front. The upper end of the operation panel 18 is located upward from the upper surface of the upper shell 17 that extends from the operation panel 18 toward the rear of the printing device 12. Further, the upper end of the operation panel 18 overlaps part of the front surface of the image reading device 13.
The printing device 12 includes a rectangular paper ejection port 19 located in the front side of the lower shell 16 below the operation panel 18. Paper P that has undergone printing in the shell 15 of the printing device 12 is ejected out of the paper ejection port 19 toward the front. A paper ejection tray 20 (ejection portion), which has the form of a rectangular plate, extends below the paper ejection port 19 and projects toward the front in the paper ejection direction to support the paper P ejected from the paper ejection port 19. The front surface of the lower shell 16 includes a cassette socket 21, which has the form of a rectangular opening, below the paper ejection tray 20. A paper feed cassette 22 (medium setting portion), which holds a stack of paper P, is arranged in the cassette socket 21. The paper feed cassette 22 is freely inserted into and removed from the cassette socket 21 in the front-rear direction. The paper feed cassette 22 is sized so that when the paper feed cassette 22 is inserted into the cassette socket 21, the front end of the paper feed cassette 22 is located at substantially the same position in the front-rear direction as the front end of the paper ejection tray 20.
As shown in
A liquid supply unit 27 is accommodated in the shell 15 of the printing device 12 at the rear side of the lid 23, that is, near the front surface and one end (in this case, right end) of the printing device 12. The liquid supply unit 27 is sized so that the dimensions in the vertical direction and the lateral direction substantially conform to the dimensions of the lid 23 in the vertical direction and the lateral direction. The liquid supply unit 27 is a structure including a plurality of (four in the present embodiment) liquid containers 28 (28a to 28d) that can be handled integrally. As will be described later, ink can be added to the liquid containers 28a to 28d.
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A support base 43 is arranged in the lower shell 16 of the printing device 12 in front of the timing belt 40. The support base 43 has the form of a rectangular parallelepiped and is elongated in the lateral direction that is orthogonal to the front-rear direction, which conforms to the transfer direction of the paper P. When the paper P is transferred in the transfer direction during printing, the support base 43 supports the lower surface of the paper P. A porous ink absorbent 44 is exposed to the outside over a rectangular region elongated in the lateral direction from the surface of the support base 43 that faces the liquid ejection head 42. Two rails 45, which extend in the lateral direction, are arranged at the front and rear sides of the support base 43 to support the carriage 41 in a movable manner. Accordingly, when the motor is driven to rotate the drive pulley 39, drive force transmitted by the timing belt 40 to the coupling portion 41a moves the carriage 41 back and forth in the lateral direction along the front and rear rails 45.
A support frame 46, which is rectangular in a plan view, is arranged in the lower shell 16 of the printing device 12 at the front side of the front rail 45. A circuit board 47, which functions as a controller including a CPU or the like, is supported by the support frame 46. The electric connector 37, which is connected to the distal end of the cable 35, and a plurality of (only two shown in example of the present embodiment) connectors 48a and 48b are fixed to the circuit board 47. A vertical guide wall 49, which extends elongated in the lateral direction, is formed on a portion of the support frame 46 near the rear edge extending along the rear long side of the circuit board 47.
A slotted recess 49a is formed in the guide wall 49 at a substantially central portion in the lateral direction. A fastening member 51 is arranged on the rear surface of the guide wall 49 toward the right end from the slotted recess 49a at the side facing the carriage 41 to fasten intermediate portions of flexible liquid supply tubes 50, each having one end connected to the liquid supply unit 27. The portion of each liquid supply tube 50 located toward the other end from the fastening member 51 is bent back along the rear surface of the guide wall 49 and extended via a connection portion 41b, which is arranged on the front portion of the carriage 41 to connect the other end to a corresponding one of sub tanks 52 mounted on the carriage 41.
Each sub tank 52 temporarily holds ink supplied through the liquid supply tube 50 and supplies the liquid ejection head 42 with the ink. Instead of mounting the sub tanks 52 on the carriage 41, the liquid supply tubes 50 may be connected by an adapter (not shown) to the liquid ejection head 42. The number of the liquid supply tubes 50 (four in the present embodiment) is equal to the number of the liquid containers 28a to 28d (four in the present embodiment) of the liquid supply unit 27. However,
One end of a signal line 53 is connected to the liquid ejection head 42. The signal line 53 extends from the connection portion 41b of the carriage 41 and along the rear surface of the guide wall 49 at the side facing the carriage 41. Then, the signal line 53 passes through the slotted recess 49a and connects to the circuit board 47 via the connector 48a. Further, one end of a signal line 54 is connected to the liquid supply unit 27, and the other end of the signal line 54 is connected to the other connector 48b on the circuit board 47.
The liquid supply unit 27 of the printing device 12 will now be described. The liquid supply unit 27 functions as a liquid supply device that supplies ink to the liquid ejection head 42.
As shown in
The liquid containers 28a to 28d include the liquid container 28a that contains black ink, the liquid container 28b that contains cyan ink, the liquid container 28c that contains magenta ink, and the liquid container 28d that contains yellow ink. The four liquid containers 28a to 28d are set in the setting member 56 laid out next to one another in the lateral direction, which is the main scanning direction when the liquid ejection head 42 performs printing on the paper P, so that the liquid containers 28a to 28d are in a front surface attachment arrangement in which the longitudinal direction of the liquid containers 28a to 28d conforms to the front-rear direction that extends from the front surface of the shell 15 toward the rear. When the liquid container 28a, which contains black ink and has a larger volume than the other three liquid containers 28b to 28d, is attached inside the shell 15 of the printing device 12, the liquid container 28a is set to be located at the rightmost position in the lateral direction as shown in
As shown in
The liquid containers 28a to 28d are ink tanks having the form of substantially rectangular parallelepipeds. In a state laid out in the shell 15 by the setting member 56 or the like, the lateral direction of the liquid containers 28a to 28d that conforms to the layout direction is the thickness-wise direction of the liquid containers 28a to 28d, the height-wise direction of the liquid containers 28a to 28d that conforms to the vertical direction is a short side extending direction of the liquid containers 28a to 28d, and the front-rear direction of the shell 15 that conforms to the transfer direction of the paper P is a longitudinal direction of the liquid containers 28a to 28d. The inside of each of the liquid containers 28a to 28d defines a liquid containing chamber 59 that can contain ink. The liquid containers 28a to 28d each include a rectangular upper wall 60 that extends in the longitudinal direction. The upper wall 60 includes a liquid inlet 61 that allows the liquid containing chamber 59 to be filled with ink from the outside.
The liquid inlet 61 is funnel-shaped and includes a first opening 61a, which is one example of an inner end opening that opens in the liquid containing chamber 59, and a second opening 61b, which is an opening located at the opposite side and has a larger diameter than the first opening 61a. The first opening 61a, which is the inner end opening, is located near the front end of the upper wall 60 in each of the liquid containers 28a to 28d. In this regard, the upper wall 60 of each of the liquid containers 28a to 28d corresponds to an opening formation wall in which the inner end opening (first opening 61a) of the liquid inlet 61 is formed in each of the liquid containers 28a to 28d.
The liquid containers 28a to 28d each include a front wall 62 that is exposed to the front side when the lid 23 in the front surface of the shell 15 opens. The front wall 62 includes a visual checking portion 63 that is formed from a transparent resin or the like and allows for visual checking of the liquid level of the ink in the liquid containing chamber 59. Further, the liquid containers 28a to 28d each include a rear wall 64. The bottom portion of the rear wall 64 includes a liquid supply port 65 that supplies ink from the liquid containing chamber 59 to the outside. The flow passage formation member 55 is joined with the rear walls 64 of the liquid containers 28a to 28d and supplied with ink from the liquid supply ports 65.
As shown in
The setting member 56 is a rectangular case in a plan view and open at the upper side, front side, and rear side. The setting member 56 includes a bottom wall 56a, a right wall 56c, and a left wall 56d. The dimension of the setting member 56 between the opposing inner surfaces of the right wall 56c and the left wall 56d is slightly greater than the dimension of the four liquid containers 28a to 28d laid out in the lateral direction between the right surface of the liquid container 28a at the right end and the left surface of the liquid container 28d at the left end. Further, the dimension of the setting member 56 between the opposing inner surfaces of the right wall 56c and the left wall 56d is slightly greater than the width-wise dimension of the flow passage formation member 55 in the lateral direction. The thickness-wise direction of the flow passage formation member 55 conforms to the front-rear direction. The length of the setting member 56 in the front-rear direction (rearward direction) is longer than the sum of the length of the liquid container 28 in the front-rear direction (longitudinal direction) and the thickness of the flow passage formation member 55 in the front-rear direction by a length corresponding to the thickness of the flow passage formation member 55. Thus, as shown in
The opposing inner surfaces of the right wall 56c and the left wall 56d of the setting member 56 each include a guide groove 69. The left and right guide grooves 69 extend vertically from the upper end surfaces of the left and right walls 56c and 56d to substantially middle positions in the vertical direction. The guide grooves 69 have a width that is slightly greater than the diameter of the cylindrical projections 58 formed on the outer side surfaces of the liquid containers 28a and 28d. Thus, when setting the liquid containers 28a to 28d in the setting member 56, the projections 58, which project from the left and right ends of the liquid containers 28a to 28d that are laid out next to one another, are aligned with the guide grooves 69 of the setting member 56. In this state, the projections 58 are moved downward as sliding portions. This positions the liquid containers 28a to 28d in the front-rear, lateral, and vertical direction. In this regard, the projections 58 and the guide grooves 69 function as an aligning mechanism.
Further, the outer surfaces of the right wall 56c and the left wall 56d of the setting member 56 each include cylindrical projections 70 that project outward. More specifically, two cylindrical projections 70 project from the right wall 56c at two positions separated by a certain distance in the front-rear direction at substantially middle locations in the vertical direction, and one projection 70 located between the two projections 70 of the right wall 56c projects from the left wall 56d at a substantially middle location in the vertical direction. As shown in
The holding member 57 is a case that is rectangular in a plan view and has an open upper side and an open front side. Further, the holding member 57 includes a bottom wall 57a, a rear wall 57b, a right wall 57c, and a left wall 57d. The bottom wall 57a, the rear wall 57b, the right wall 57c, and the left wall 57d function as partition walls that partition the inner side of the holding member 57 from the outer side of the holding member 57. A square through hole 71 is formed in an upper left portion of the rear wall 57b. The liquid supply tube 50 and the signal line 54 are inserted through the through hole 71. In this case, an encapsulation member 72 as a sealing member (refer to
The opposing inner surfaces of the right wall 57c and the left wall 57d include vertical grooves 73 that function as guides and extend from the upper end surfaces of the two left and right walls 57c and 57d to substantially middle positions in the vertical direction. The right wall 57c includes two vertical grooves 73 that are separated by a certain distance in the front-rear direction. The left wall 57d includes one vertical groove 73 located between the two vertical grooves 73 of the right wall 57c. The lower ends of the three vertical grooves 73 are located at the same position in the vertical direction and lie along a horizontal plane. The lower end of each vertical groove 73 is configured to function as an engagement portion 74 that engages, from the lower side, another object moved in the corresponding vertical groove 73 from the upper side toward the lower side (in the present embodiment, corresponding projection 70 of setting member 56).
The dimension between the inner surfaces of the right wall 57c and the left wall 57d of the holding member 57 is slightly greater than the dimension between the outer surfaces of the right wall 56c and the left wall 56d of the setting member 56. The length of the holding member 57 in the front-rear direction (rearward direction) is greater than the length of the setting member 56 in the front-rear direction (rearward direction) by an amount corresponding to the thickness of the rear wall 57b of the holding member 57.
Thus, when the projections 70, which serve as sliding portions and project from the left and right walls 56c and 56d of the setting member 56, slide downward in a state aligned with the left and right vertical grooves 73 of the holding member 57, the liquid containers 28a to 28d are positioned relative to the holding member 57, which is fixed in the shell 15, by the setting member 56 in the front-rear, lateral and vertical directions. In this regard, the projections 70 and the vertical grooves 73 function as aligning mechanisms. In this manner, when the liquid containers 28 are coupled to the holding member 57 and the setting member 56 in the shell 15, the upper walls 60 extend in a direction (horizontal direction in present embodiment) intersecting the vertical direction. When a combination of one projection 70 and one vertical groove 73 forms a single aligning mechanism, there may be four or more aligning mechanisms. Some or all of the aligning mechanisms may perform aligning and positioning through another method such as screw fastening.
As shown in
In a state in which the liquid containers 28 are accommodated by the setting member 56 and the holding member 57 in the shell 15 near the front surface and the right end, the upper ends of the liquid inlets 61 are located in the open portions 32 of the upper shell 17. An annular seal member 76 is arranged between the upper end of the liquid inlet 61 of each liquid container 28 and the corresponding open portion 32 of the upper shell 17 to seal the gap between the liquid inlet 61 and the open portion 32. More specifically, if ink leaks out of the liquid inlet 61 when adding ink, the seal member 76 prevents the leaking ink from spreading on the upper wall 60 of the liquid container 28 and smearing the liquid container 28. As can be understood from the cross-sectional shape, the seal member 76 includes a recess 77 that is sunken so that leaking ink does not spread out.
The upper wall 60 of each liquid container 28 includes an atmospheric communication portion 78 located rearward from where the liquid inlet 61 is formed. The liquid containing chamber 59 is in communication with the atmosphere through the atmospheric communication portion 78. The atmospheric communication portion 78 is configured by, for example, a fine flow passage structure of meandering elongated grooves referred to as accordion-like grooves or a waterproof moisture permeable material that permits the passage of gas such as air and restricts the passage of liquid.
For example, as shown in
Accordingly, each liquid container 28 is filled with ink by adding ink through a liquid reception portion that includes the liquid inlet 61, which has an inner end opening (first opening 61a) that opens in the liquid containing chamber 59, and the open portion 32, which has an outer end opening at the opposite side. The liquid inlet 61 is normally closed by a plug 79, which is formed from rubber or the like and which is inserted from above into the open portion 32. When the image reading device 13 is located at the close position, the plug 79 is concealed and cannot be seen from the outer side. As shown in
The operation of the printing device 12 and the liquid supply unit 27 will now be described.
When arranging the liquid supply unit 27, which functions as a liquid supply device, in the shell 15 of the printing device 12, the holding member 57 is first fixed by screws to the lower shell 16 of the shell 15. More specifically, the holding member 57 is fixed to the lower shell 16 near the front surface and the right end. Further, the plurality of (four) liquid containers 28a to 28d and the flow passage formation member 55 are set in the setting member 56 outside the shell 15. The setting member 56, to which the liquid containers 28 and the flow passage formation member 55 have been set, is coupled to the holding member 57.
In this case, the engagement of the projections 70 with the vertical grooves 73 aligns the setting member 56 with the holding member 57. Further, the engagement of the projections 70 with the engagement portions 74, which are the lower ends of the vertical grooves 73, positions the projections 70 in the front-rear, lateral and vertical directions in a non-movable manner. This arranges and positions the plurality of (four) liquid containers 28 in the shell 15 near the front surface and the right end so that the liquid containers 28 are successively arranged in the lateral direction and so that the longitudinal direction of each liquid container 28 conforms to the front-rear direction. The pump is driven to supply ink from the liquid containers 28 to the liquid ejection head 42 through the liquid supply tubes 50. Ink may be supplied without the pump 68 by using the water head difference of the height of the liquid level of the ink in the liquid containing chamber 59 and the height of the nozzle surface of the liquid ejection head 42 in addition to the nozzle suction force.
Further, in this case, the opening width of the second opening 61b at the upper end of the liquid inlet 61 is larger than the width of the upper wall 60, which serves as an opening formation wall of the liquid container 28, in the lateral direction (one direction), which is the layout direction of the liquid containers 28. Thus, the liquid inlet 61 of adjacent liquid containers 28 may contact each other and form a gap between the adjacent liquid containers 28. However, in the present embodiment, the liquid inlets 61 of adjacent liquid containers 28 are alternately shifted and offset from each other. Thus, such a gap does not form between adjacent liquid containers 28. Further, the side surfaces of the liquid containers 28 are joined with one another. This allows for a compact stacking structure and allows for reduction in the space occupied by the entire device.
Referring to
When adding ink, the open portions 32 and the liquid inlets 61, which are in an offset layout, have a larger opening width than the width of the upper walls 60 of the liquid containers 28. This allows for easy alignment of the ink bottle 80, which serves as the liquid adding member. Further, when adding ink, the rising amount of the liquid level of the added ink in the liquid container 28 is visible through the visual checking portion 63. When the liquid level reaches the upper limit portion 63a in the visual checking portion 63, the user stops adding ink.
Further, when adding ink, if ink is spilt around the open portions 32 of the upper shell 17, which functions as an exterior member and covers the liquid containers 28 from above, the vertical surface 33 of the recess 29a that forms a step stops the spreading of ink to the wiring region 36 of the cable 35, the circuit board 47, and the electric connector 37. In this respect, the vertical surface 33 of the recess 29a in the upper shell 17 functions as a barrier that is capable of stopping the flow of ink (liquid).
In the present embodiment, the printing device 12 and the liquid supply unit 27, which serves as the liquid supply device, has the advantages described below.
(1) The liquid supply unit 27 is accommodated in the shell 15 and held in a state positioned by the holding member 57 of the shell 15. Thus, compared with when the liquid supply unit 27 is entirely arranged outside the shell 15, the area occupied by the entire device can be decreased. This allows liquid to be added to the liquid containers 28 in a stably held state. Further, the printing device 12 can be used when not much area is available. This improves the convenience.
(2) The liquid supply unit 27 is held in a fixed and positioned state. This allows ink to be stably added.
(3) The liquid supply unit 27, which can be handled in an integral manner including the liquid containers 28, is coupled to the holding member 57 of the shell 15 aligned by the projections 70 and the vertical grooves 73 that function as aligning mechanisms. This reduces situations in which the liquid containers 28 are displaced relative to the holding member 57.
(4) In a state in which the projections 70, which serve as sliding portions arranged on the liquid supply unit 27, are in contact with the vertical grooves 73, which serve as guides arranged on the holding member 57, the projections 70 are moved along the vertical grooves 73. This allows the liquid containers 28 to be easily coupled to the holding member 57.
(5) The liquid supply unit 27 is positioned relative to the holding member 57 at least at two points, namely, at one side of the liquid supply unit 27 with respect to the layout direction of the liquid containers 28 and the other side of the liquid supply unit 27 with respect to the layout direction of the liquid containers 28.
(6) The three engagement portions 74 lying along a plane extending along the layout direction of the liquid containers 28 restrict downward movement, which intersects the plain, of the liquid containers 28 set in the setting member 56. Thus, for example, when the horizontal direction is the layout direction, the liquid containers 28 are positioned on the plane that extends in the horizontal direction.
(7) In case ink leaks from the liquid containers 28 held in the holding member 57, the walls 57a to 57d, which function as partition walls of the holding member 57, stop the leaking ink so that the ink does not spread out of the holding member 57. This prevents ink from smearing locations other than the holding member 57 in the shell 15.
(8) Ink is supplied from the liquid containers 28 in the holding member 57 to the liquid ejection head 42, which is located outside the holding member 57, through the liquid supply tubes 50, which are inserted through the through hole 71 in the rear wall 57b. In case ink leaks out of the liquid containers 28, which are located in the holding member 57, the encapsulation member 72 prevents the leaking ink from flowing out of the holding member 57 through the through hole 71.
(9) The necessity for adding ink to the liquid containers 28 can be checked with the detection result of each remaining amount detector 75.
(10) The ink added from the liquid inlet 61 and held in each liquid container 28 can be supplied toward the liquid ejection head 42 by driving the pump 68.
(11) Each liquid container 28 includes the atmospheric communication portion 78. Thus, ink can be smoothly supplied from the liquid container 28 to the liquid ejection head 42.
(12) The liquid containers 28 are accommodated in the shell 15. This decreases the area occupied by the entire device compared to when the liquid containers 28 are located outside the shell 15. Further, the shell 15 includes the open portions 32 at positions corresponding to the liquid inlets 61 of the liquid containers 28. This allows ink to be added from the open portions 32 to the liquid inlet 61. Thus, ink can be easily added, and the printing device 12 can be used when not much area is available. This improves the convenience.
(13) In the shell 15, the open portions 32 that expose the accommodated liquid inlets 61 of the liquid containers 28 are separated from the wiring region 36 of the cable 35 in the upper surface of the shell 15 (upper shell 17). This avoids situations in which ink spilt from the liquid inlets 61 smears the cable 35.
(14) Even if ink is spilt around the open portions 32 when adding ink to the liquid inlets 61 of the liquid containers 28 through the open portions 32 of the shell 15, the vertical surface 33, which functions as a barrier, stops the flow of the spilt ink so that the ink does not flow to the electric connector 37. This avoids situations in which ink collects on the electric connector 37.
(15) In the liquid reception portion (open portion 32 and liquid inlet 61) of each liquid container 28, the size of the outer end opening (fourth opening 32b), which is located at the opposite side of the inner end opening (first opening 61a) that opens in the liquid containing chamber 59, is greater than or equal to the width of the opening formation wall (upper wall 60) of the liquid container 28, which includes the inner end opening, in one direction (e.g., layout direction of liquid containers 28 or direction of short side of upper wall 60, which is the opening formation wall including the inner end opening of the liquid container 28). This facilitates the alignment of, for example, the liquid adding member (ink bottle 80) with the outer end opening of the liquid reception portion. Accordingly, ink can easily be added, and the convenience is improved.
(16) The surface of the opening formation wall (upper wall 60), which includes the inner end opening (first opening 61a) of the liquid reception portion (open portion 32 and liquid inlet 61), is configured by an upwardly faced horizontal surface. Thus, the liquid reception portion (open portion 32 and liquid inlet 61) is set at a location where ink can easily be added.
(17) The liquid inlet 61 of each of the liquid containers 28, which are laid out next to one another in one direction, is offset from the liquid inlet 61 of the adjacent liquid container 28 in a direction intersecting the one direction. This decreases the occupied area in the layout direction of the liquid containers 28 and limits enlargement of the printing device 12 accordingly.
(18) The user can add ink while checking the liquid level that rises in the liquid containing chamber 59 with respect to the upper limit portion 63a in the visual checking portion 63 so that ink is not spilt out of the liquid inlet 61.
(19) The seal member 76 is arranged around the liquid inlet 61 to seal the gap formed with the open portion 32 in the upper shell 17. This reduces situations in which ink that leaks from the liquid inlet 61 enters and smears the inner side of the holding member 57, which also functions as an exterior member covering the liquid containers 28.
(20) When adding ink, if the ink leaks from the liquid inlet 61 onto the seal member 76, the leaked ink collects in the recess 77 of the seal member 76. This limits unnecessary spreading of the leaked ink.
A second embodiment of an all-in-one machine including a printing device will now be described with reference to the drawings. The second embodiment differs from the first embodiment only in how the liquid supply unit 27 is attached to the shell 15 and where the liquid inlets 61 are located. Otherwise the second embodiment is identical to the first embodiment. Thus, same reference numerals are given to those components that are the same as the corresponding components of the first embodiment. Such components will not be described in detail.
As shown in
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Ink is added to the embodiment of
The liquid supply unit 27, which includes the liquid containers 28 and the setting member 56, is held by the holding member 57, which covers the liquid containers 28 from the right side, the left side, and the bottom side of the liquid containers 28. The holding member 57 also functions as a protection member 57A that protects the liquid containers 28 from external impact outside the shell 15. The protection member 57A has a front surface and an upper surface that are open. Further, the holding member 57 is configured so that the visual checking portion 63 formed in each liquid container 28 is not covered when viewed from the front. The liquid inlet 61 of each liquid container 28 is exposed to the outside from the upper surface of the protection member 57A.
The operation of the printing device 12 and the liquid supply unit 27 (liquid supply device) in the second embodiment will now be described.
As shown in
The printing device 12 and the liquid supply unit 27, which serves as a liquid supply device, in the second embodiment have the advantages described below.
(21) The liquid containers 28 are partially accommodated in the shell 15. This decreases the area occupied by the entire device in comparison with when the liquid containers 28 are entirely located outside the shell 15. Thus, the printing device 12 can be used when not much area is available. This improves the convenience.
(22) The liquid inlet 61 is located at a portion of each liquid container 28 that projects out of the shell 15. Thus, the user can easily add liquid.
(23) The portion of each liquid container 28 projecting out of the shell 15 in the forward direction (projecting portion) is covered by the holding member 57 that also projects out of the shell 15 in the forward direction. More specifically, the holding member 57 functions as the protection member 57A that covers the liquid containers 28. The protection member 57A limits displacement of each liquid container 28 that would occur when an object strikes the projecting portion from the outer side.
(24) The protection member 57A, which protects the liquid containers 28, has an open upper surface. Thus, when ink becomes low in each liquid container 28, ink may be added from the liquid inlet 61, which is exposed to the outside through the upper surface of the protection member 57A, to continuously perform printing.
(25) The projection amount of the liquid supply unit 27 from the shell 15 in the forward direction is smaller than the projection amount of the paper ejection tray 20 and the paper feed cassette 22. This reduces situations in which an object strikes the liquid containers 28 from the outer side. As a result, displacement of each liquid container 28 is limited.
(26) In the liquid inlet 61, the opening width of the second opening 61b, which is located at the side opposite to the first opening 61a serving as the inner end opening, in the direction intersecting the layout direction of the liquid containers 28 is larger than the opening width of the second opening 61b in the layout direction. This allows for reduction in size in the layout direction of the liquid containers 28 and limits enlargement of the printing device 12.
The first embodiment and the second embodiment may be modified as described below.
In the printing device 12 of the first embodiment, the operation panel 18 may be extended toward the right to the front side of the hand insertion portion 29 so that the open portions 32 are located at the rear side of the operation panel 18 when viewing the shell 15 from the front side. This hides the open portions 32 with the operation panel 18 so that the open portions 32 cannot be seen from the front side of the printing device 12 and improves the aesthetic appeal of the printing device 12.
With the printing device 12 of the second embodiment, in the liquid inlet 61 of each liquid container 28, the opening width of the second opening 61b, which is located at the side opposite to the first opening 61a (inner end opening), in the layout direction of the liquid containers 28 may be larger than the opening width in the direction intersecting the layout direction. In this configuration, for example, if the liquid ejection head 42 is configured to perform printing on the paper P while moving in the main scanning direction and the liquid containers 28 are laid out next to one another in the scanning direction, the opening width of the second opening 61b in the liquid inlet 61 is large at the side opposite to the first opening 61a (inner end opening). Thus, liquid can be easily added from the liquid inlet 61.
For example, as shown in
For example, as shown in
For example, as shown in
In the printing device 12, the location of the liquid-adding open portions 32 formed in the shell 15 are not limited to the positions illustrated in the first embodiment and the second embodiment. For example, as shown in
Further, as shown in
In the cases of
The liquid containers 28 do not have to be attached to the shell 15 of the printing device 12 as illustrated in the first embodiment and the second embodiment. For example, as shown in
In this case, the outer end opening of the liquid reception portion (outer end opening of open portion formed in upper shell in the case of
Further, as shown in
The shape of the liquid containers 28 attached to the shell 15 of the printing device 12 is not limited to the form of substantially rectangular parallelepiped as illustrated in the first and second embodiments. For example, as shown in
As shown in
The open portions 32 formed in the upper shell 17 of the shell 15 of the printing device 12 expose the liquid inlets 61 to the outside as viewed from above. However, each open portion 32 does not necessarily have to expose a single liquid inlet 61. For example, as shown in
As shown in
As shown in
In the printing device 12, when projecting the holding member 57, which holds the liquid containers 28, out of the front side of the shell 15 to function as the protection member 57A, for example, as shown in
Further, the lid 23 shown in
In the printing device 12, for example, as shown in
If the liquid supply unit 27 (liquid supply device) shown in
In the liquid supply unit 27 (liquid supply device) shown in
In the above embodiments, as shown in
In the printing device 12, the opening width D2 of the second opening 61b, which is the outer opening of the liquid inlet 61 of the liquid container 28, in the lateral direction does not necessarily have to be greater than the width D3 of the upper wall 60 of the liquid container 28 in the lateral direction. For example, as shown in
In the first embodiment and the modified example of
As shown in
The liquid container 28 of the modified example shown in
As shown in
As shown in
As shown in
As shown in
As shown in
This modified example has the advantages described below.
(27) The band 102 reduces situations in which the plug 79 gets lost when the plug 79 is removed from the liquid inlet 61.
(28) For example, when filling the liquid containing chamber 59 with ink through the liquid inlet 61, the second seal member 103 reduces situations in which ink leaks out of the exposing portion 101 even if the ink flows into the space between the liquid container 28 and the liquid container housing 83. Further, situations are reduced in which ink flows into the space between the liquid container 28 and the liquid container housing 83 through the exposing portion 101.
(29) The integration of the plug 79 and the second seal member 103 reduces the number of components in the liquid supply unit 27.
As shown in
In the above embodiments, the projections 70 and the vertical grooves 73 that form the aligning mechanism may be configured so that the projections 70 are arranged on the holding member 57, and the vertical grooves 73 are arranged in the liquid containers 28.
In the above embodiment, the aligning mechanism does not have to be formed by the projections 70 and the vertical grooves 73 and may be, for example, a combination of a male thread and a female thread or a printed identification mark.
In the second embodiment, the projection amount of the liquid supply unit 27 from the front surface of the shell 15 may be greater than or less than the projection amount of the paper ejection tray 20.
In the second embodiment in which the liquid container 28 partially projects out of the shell 15, the liquid inlet 61 may be located inside the shell 15. In this case, preferably, the corresponding open portion 32 is located above the liquid inlet 61. This also increases the volume of the ink that can be held.
The liquid container 28 does not have to include the flow restriction 60a and the upper limit portion 63a. Further, the visual checking portion 63 may include a lower limit portion (not shown) that indicates a near end of the ink amount. Further, the visual checking portion 63 may include, for example, an index or the like that indicates a halfway amount.
In each of the above embodiments, the printing device 12 may be a dot impact printer or a laser printer as long as printing can be performed on a medium. The printing device 12 may be of a sole configuration having only a printing function and not be included in an all-in-one machine. Further, the printing device 12 is not limited to a serial printer and may be a line printer or a page printer.
In each of the above embodiment, the printing device 12 uses four colors of ink but may use only a single color of ink, two or three colors of ink, or five or more colors of ink. The number of the liquid containing chambers 59, the liquid supply tubes 50, and the like need only be in correspondence with the number of colors that are used.
The liquid containers 28 may be formed independently for each color of ink. Alternatively, the liquid containers 28 for multiple colors (may be all of the colors) may be formed integrally.
The medium is not limited to paper P and may be a resin film, metal foil, metal film, a composite film (laminate film) of resin and metal, fabric, nonwoven fabric, ceramic sheet, or the like.
In the above embodiments, the printing device 12 may be a liquid ejection device that ejects or discharges a liquid other than ink. A fine amount of liquid ejected from the liquid ejection device as a liquid droplet may be in a state that is particulate, tear-like, or shaped in a tailed manner. The liquid referred to here may be any material that can be ejected from the liquid ejection device. For example, the liquid may be a substance that is in a liquid phase state. Thus, the liquid may be a fluidal body such as a liquid body having low or high viscosity, a sol, gel water, other inorganic solvents, an organic solvent, a liquid solution, a liquefied resin, or a liquefied metal (metal melt). Further, the liquid is just not one state of a substance and includes particles of a functional material formed by a solid such as pigments or metal particles that are dissolved, dispersed, or mixed. Representative examples of liquid ink, such as that described in the above embodiments, include liquid crystal and the like. Ink includes typical water-based ink and oil-based ink and various liquid compositions such as gel ink and hot melt ink.
The above modified examples may be combined.
Number | Date | Country | Kind |
---|---|---|---|
2015-070368 | Mar 2015 | JP | national |
2015-210073 | Oct 2015 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2016/060036 | 3/29/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2016/158912 | 10/6/2016 | WO | A |
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Number | Date | Country |
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102248801 | Nov 2011 | CN |
2010-058429 | Mar 2010 | JP |
2014-054824 | Mar 2014 | JP |
Entry |
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International Preliminary Report on Patentability dated Oct. 3, 2017 in PCT/JP2016/060036 (5 pgs.). |
International Search Report dated Jun. 21, 2016 in PCT/JP2016/060036 with English-language translation (4 pgs.). |
Number | Date | Country | |
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20180072067 A1 | Mar 2018 | US |