JP4315188B2 - Liquid ejector - Google Patents

Description

  The present invention relates to a liquid ejecting apparatus such as an ink jet printer.

  In general, ink jet printers (hereinafter referred to as “printers”) are widely known as liquid ejecting apparatuses that eject liquid onto a target. This printer supplies ink from an ink cartridge that contains ink to a recording head (liquid ejecting head) that ejects ink (liquid), and records the ink as a target from nozzles formed on the nozzle formation surface of the recording head. Printing is performed by spraying on paper. In such a printer, when an ink cartridge is disposed at a position away from the recording head, ink is supplied to the recording head side through a tube drawn from the ink cartridge into the printer. Yes.

  By the way, when changing the ink ejected from the nozzle of the recording head to another type of ink, first, the supply of ink from the ink cartridge that has been used until then is stopped, and from this state, Residual ink is discharged through the nozzles of the recording head. Then, after the inside of the tube is cleaned by discharging the residual ink, the other type of ink is supplied to the recording head side through the tube from an ink cartridge containing another type of ink.

  For this reason, when the type of ink ejected from the nozzles of the recording head is changed in this way, the ink before the change remaining in the tube must be sucked and discharged, resulting in increased waste of ink. There was a problem. Therefore, in order to cope with such a problem, conventionally, there has been proposed a printer provided with an ink switching device connected to each ink cartridge via a tube corresponding to each ink cartridge in the vicinity of the recording head (for example, Patent Document 1).

  In the printer of Patent Document 1, the type of ink supplied to the recording head can be switched between the first type ink (first liquid) and the second type ink (second liquid) in the switching device. It has become. That is, in the switching device, the downstream end of the first passage portion (first supply passage) that supplies the first type of ink and the downstream end of the second passage portion (second supply passage) that supplies the second type of ink. Are joined, and the joining point and the recording head are connected by a head side supply path for supplying ink to the recording head. Furthermore, in this switching device, a first diaphragm (first on-off valve) for opening and closing the first passage portion and a second diaphragm (second on-off valve) for opening and closing the second passage portion are provided, The supply state of the first type ink and the second type ink is switched by opening the other diaphragm and closing the other diaphragm.

That is, in this switching device, when supplying the first type of ink to the recording head, the first diaphragm of the first passage portion is opened and the second diaphragm of the second passage portion is closed. On the other hand, when supplying the second type of ink to the recording head, the second diaphragm of the second passage portion is opened and the first diaphragm of the first passage portion is closed.
JP 2006-175626 A

  By the way, in the printer of patent document 1, the two sliders are provided in the switching device, and these two sliders are respectively slid linearly to move the first pressing member (first actuator) and the second pressing member ( The first diaphragm and the second diaphragm are opened and closed by swinging the second actuator. For this reason, the printer of Patent Document 1 has a problem that a space for sliding the two sliders in the switching device must be secured, resulting in an increase in the size of the switching device and an increase in the size of the printer. .

  The present invention has been made paying attention to such problems existing in the prior art. An object of the invention is to provide a liquid ejecting apparatus capable of downsizing a switching device for changing the type of liquid supplied to the liquid ejecting head.

In order to achieve the above object, a liquid ejecting apparatus according to an aspect of the invention includes a liquid ejecting head that ejects a liquid, and a second type of liquid that is supplied to the liquid ejecting head, which is different from the first liquid and the first liquid. A liquid ejecting apparatus including a switching device that selectively switches between liquids, wherein the switching device includes a first supply path that supplies the first liquid and a second supply that supplies the second liquid. A head-side supply path that communicates between the liquid jet head and a junction point between downstream ends of the first supply path and the second supply path, and the second supply path in the first supply path The first on-off valve that opens and closes the first supply path upstream of the merging point and the second supply path is opened and closed upstream of the merging point of the first supply path in the second supply path. Second on-off valve, one rotary cam, and crossing each other A first actuator and a second actuator pivotally supported by a single shaft, and the cam is disposed between one end sides of the first actuator and the second actuator with the shaft as a boundary. The first on-off valve and the second on-off valve are disposed in sliding contact with the actuator, and the first actuator and the second on-off valve are disposed between the other ends of the first actuator and the second actuator with the shaft as a boundary. The first actuator and the second actuator are disposed so as to face the other end side of the second actuator, respectively, and the first actuator and the second actuator are swung in accordance with the rotational drive of the cam. as other with one of the two on-off valve is opened is closed, varying by applying a pressing force thereto first on-off valve and the second on-off valve Ru is.

In general, a rotary cam requires less space during driving than a direct-acting cam that slides linearly. In this respect, according to the present invention, the actuator that opens and closes the first on-off valve and the second on-off valve is swung in accordance with the rotational drive of the rotary cam, so the actuator is driven by the direct-acting cam. Less space is required than in the case. Accordingly, it is possible to reduce the size of the switching device for changing the type of liquid supplied to the liquid ejecting head.
Further, since both the first actuator and the second actuator are swung by the rotational drive of one rotary cam, the parts are compared with the case where the first actuator and the second actuator are swung by separate cams, respectively. It is possible to reduce the score.
In addition, since the first actuator and the second actuator are pivotally supported by one shaft, the parts are compared to the case where the first actuator and the second actuator are pivotally supported by separate shafts. It is possible to reduce the score.

In the liquid ejecting apparatus according to the aspect of the invention, the cam includes a first cam surface and a second cam surface that are sequentially engaged with one end sides of the first actuator and the second actuator as the cam rotates. The both actuators are disengaged in a direction in which one end side engages with the first cam surface and the other end side of the actuator separates from the corresponding on-off valve, while one end side engages with the second cam surface. By doing so, the other end side of the actuator is configured to be displaced in a direction in which a pressing force is applied to the corresponding on-off valve to perform the valve closing operation .

According to the present invention, when the cam is driven to rotate in one direction, the first actuator and the second actuator swing, so that one of the first on-off valve and the second on-off valve is closed. In addition, it is possible to switch alternately between a state in which the other is opened and a state in which one is opened and the other is closed.

In the liquid ejecting apparatus according to the aspect of the invention, a transmission member can slide between the first on-off valve and the second on-off valve in the first supply path and the second supply path communicating with each other via the junction. The transmission member transmits the closing force when the first on-off valve is closed by the first actuator to the second on-off valve as the opening force for opening the second on-off valve. as well as, the valve closing force at the time of closing the second on-off valve by the second actuator, you transmitted to the first on-off valve as opening force for opening the first on-off valve.

According to the invention, by Rukoto to oscillate the first actuator with the closing of the first on-off valve and opening the second on-off valve are performed simultaneously, by Rukoto to oscillate the second actuator second The closing of the on-off valve and the opening of the first on-off valve are performed simultaneously. Therefore, the type of liquid supplied to the liquid ejecting head can be quickly switched.

The liquid ejecting apparatus according to the aspect of the invention may be provided between the one end side of the first actuator and the other end side of the second actuator, and between the one end side of the second actuator and the other end side of the first actuator. The biasing members for biasing these in the direction of separating are interposed .

  According to this invention, a decrease in the sealing performance when the first actuator closes the first on-off valve is suppressed, and the sealing performance when the second actuator closes the second on-off valve. Is suppressed. Therefore, it is possible to improve the reliability when the first on-off valve and the second on-off valve are closed.

  Hereinafter, an embodiment in which the present invention is embodied in an ink jet printer and an ink cartridge mounted on the printer will be described with reference to the drawings. In the following description, “front-rear direction”, “left-right direction”, and “up-down direction” indicate the front-rear direction, left-right direction, and up-down direction indicated by arrows in FIG.

  As shown in FIG. 1, an ink jet printer 11 as a liquid ejecting apparatus includes a main body frame 12 having a rectangular shape in a plan view, and a platen 13 is disposed in the main body frame 12 along a left-right direction that is a main scanning direction. It is provided to extend. On the platen 13, a recording sheet (not shown) as a target is fed along a front-rear direction which is a sub-scanning direction by a paper feeding mechanism (not shown). A rod-shaped guide shaft 14 extending in parallel with the longitudinal direction (left-right direction) of the platen 13 is installed above the platen 13 in the main body frame 12.

  A carriage 15 is supported on the guide shaft 14 in a state where the carriage 15 can reciprocate in the axial direction (left-right direction) of the guide shaft 14. The carriage 15 is connected to a carriage motor 17 provided on the back surface of the main body frame 12 via an endless timing belt 16 stretched between a pair of pulleys 16 a provided on the inner surface of the rear wall of the main body frame 12. Yes. Accordingly, the carriage 15 is reciprocated along the guide shaft 14 by driving the carriage motor 17.

  As shown in FIGS. 1 and 2, a recording head 18 as a liquid ejecting head is mounted on the surface of the carriage 15 that faces the platen 13. On the carriage 15, a plurality (four in this embodiment) of valve units 19 a to 19 d for supplying ink as temporarily stored liquid to the recording head 18 are provided. A plurality (three in this embodiment) of nozzles 20a to 20c are formed on the lower surface of the recording head 18, and the recording paper (not shown) fed from the nozzles 20a to 20c onto the platen 13 is formed. Printing is performed by ejecting ink droplets.

  A cartridge holder 21 is provided at the right end in the main body frame 12, and a plurality (four in this embodiment) of ink cartridges 22 a to 22 d that contain different types of ink are respectively stored in the cartridge holder 21. It is attached detachably. The cartridge holder 21 is connected to the valve units 19a to 19d on the carriage 15 via ink supply tubes 24a to 24d, respectively. When the ink cartridges 22a to 22d are attached to the cartridge holder 21, the ink cartridges 22a to 22d communicate with the valve units 19a to 19d via the ink supply tubes 24a to 24d, respectively. .

  The ink cartridge 22a and the ink cartridge 22b contain photo black ink as the first liquid and mat black ink as the second liquid, respectively. Accordingly, photo black ink is temporarily stored in the valve unit 19a, and mat black ink is temporarily stored in the valve unit 19b.

  In this case, the photo black ink is suitable for printing when the recording paper is glossy paper, and the mat black ink is suitable for printing when the recording paper is matte paper. Therefore, between the valve units 19a and 19b on the carriage 15 and the recording head 18, the ink supplied from the both valve units 19a and 19b to the recording head 18 is either photo black ink or matte black ink. A switching device 25 is provided for switching between the two.

  That is, the switching device 25 switches the ink ejected from the nozzle 20a of the recording head 18 between the photo black ink and the matte black ink depending on whether the recording paper is a glossy paper or a matte paper, for example. It is possible. The switching device 25 includes a switching unit 25A that switches ink and a drive unit 25B that drives the switching unit 25A.

  A maintenance unit 26 for cleaning the recording head 18 and the like is disposed at a position near the right end in the main body frame 12 and at the home position of the carriage 15. The maintenance unit 26 includes a cap 27 for sealing the nozzles 20a to 20c of the recording head 18 and receiving ink ejected from the nozzles 20a to 20c by flushing.

Next, the configuration of the switching unit 25A constituting the switching device 25 will be described in detail.
As shown in FIGS. 3 to 5, the switching unit 25 </ b> A includes a main body 30 having a substantially symmetrical block shape, and is paired with a top surface of the main body 30 at a predetermined interval in the left-right direction. A first connection pipe 31 and a second connection pipe 32 are erected. The first connection pipe 31 is connected to the valve unit 19a, and the second connection pipe 32 is connected to the valve unit 19b. A bottomed cylindrical first valve body housing portion 33 opened on the left side is provided on the front side of the first connection pipe 31, and a bottomed cylindrical second opening opened on the right side on the front side of the second connection pipe 32. A valve body accommodating portion 34 is provided.

  The first valve body housing portion 33 and the second valve body housing portion 34 are connected via a connecting portion 35. A connecting path 36 that extends linearly in the left-right direction is formed in the connecting section 35, and the first valve body housing section 33 and the second valve body housing section 34 are centrally connected to each other via the connecting path 36. In communication with each other. That is, the connection path 36 is opened in the center part of the 1st valve body accommodating part 33 and the 2nd valve body accommodating part 34, respectively.

  Further, the main body 30 is formed with a first communication groove 37 that communicates the first connection pipe 31 and the first valve body housing portion 33. That is, the base end of the first communication groove 37 is connected to the first connection pipe 31, on the left surface of the main body 30, on the inner peripheral surface 33 a of the first valve body housing portion 33, and on the first valve body housing portion 33. The connection path 36 on the inner bottom surface 33b extends from the upper side to the front side through the inner bottom surface 33b, and the tip of the connection path 36 reaches the obliquely lower front side of the connection path 36 on the inner bottom surface 33b. An annular first protrusion 33 c is formed on the inner bottom surface 33 b of the first valve body housing portion 33 so as to surround the connection path 36.

  Similarly to the first communication groove 37, the main body 30 is formed with a second communication groove 38 that communicates the second connection pipe 32 and the second valve body housing portion 34. That is, the base end of the second communication groove 38 is connected to the second connecting pipe 32, the right side surface of the main body 30, the inner peripheral surface 34 a of the second valve body housing portion 34, and the second valve body housing portion 34. The connecting path 36 on the inner bottom face 34b extends from the upper side to the front side through the inner bottom face 34b, and the tip of the connecting path 36 reaches the obliquely lower front side of the connecting path 36 on the inner bottom face 34b. On the inner bottom surface 34 b of the second valve element housing portion 34, an annular second protrusion 34 c is formed so as to surround the connection path 36.

  As shown in FIGS. 5 and 6, the front end in the center of the connecting path 36 in the left-right direction is at the front end in the groove 40 formed in the connecting path 36 and on the upper surface of the connecting portion 35 and extending in the front-rear direction. A first through hole 39 communicating with the portion is formed. On the other hand, a second through hole 41 communicating with the recording head 18 (see FIG. 2) is formed at the rear end portion in the concave groove 40. A sealing member (not shown) that seals the upper end opening of the groove 40 is disposed on the upper surface of the connecting portion 35. In the present embodiment, the first through hole 39, the recessed groove 40, and the second through hole 41 constitute a head side supply path.

  As shown in FIG. 5, in the connection path 36, the left part from the center in the left-right direction is the first connection path 44, and the right part from the center in the left-right direction is the second connection path 45. Accordingly, the central portion of the connection path 36 is a junction point G between the first connection path 44 and the second connection path 45, and at the junction point G, the first connection path 44, the second connection path 45, and the The 1 through holes 39 communicate with each other.

  In the present embodiment, a first supply path is configured by the first communication groove 37 (see FIG. 4), the first valve body housing portion 33, and the first connection path 44, and the second communication groove 38, A second supply path is configured by the second valve body accommodating portion 34 and the second connection path 45. In addition, the enlarged diameter part 36a whose diameter is wider than a center part is provided in the both ends (the left end part of the 1st connection path 44, and the right end part of the 2nd connection path 45) of the connection path 36.

  As shown in FIG. 7, a substantially cylindrical transmission member 46 is accommodated in the first connection path 44 and the second connection path 45 so as to be slidable in the left-right direction. Here, as shown in FIG. 8, the transmission member 46 includes a columnar small-diameter portion 46a and a large-diameter portion 46b in which one end of the small-diameter portion 46a is larger in diameter than the small-diameter portion 46a. ing. The large-diameter portion 46b is formed with a notch 46c having the same diameter as the small-diameter portion 46a by the amount rotated about 90 degrees about the axial direction of the transmission member 46.

  3 and FIG. 7, one of the two transmission members 46 is inserted into the first connecting path 44 from the small diameter portion 46a side, and the other transmission member 46 is inserted into the small diameter portion 46a. The transmission member 46 is accommodated in the first connection path 44 and the second connection path 45 by being inserted into the second connection path 45 from the 46a side. In this case, the notches 46 c of both transmission members 46 face downward, and the large diameter portions 46 b of both transmission members 46 are respectively accommodated in the enlarged diameter portions 36 a of the connection path 36. Further, the end surfaces on the small diameter portion 46 a side of both transmission members 46 are in contact with each other at the center portion in the left-right direction of the connection path 36. The sum of the lengths of the two transmission members 46 in the longitudinal direction is slightly longer than the length of the connecting path 36 in the left-right direction.

  In the first valve body housing portion 33 and the second valve body housing portion 34, a disk-like first opening / closing valve 47 having flexibility and a second opening / closing valve 48 having the same configuration as the first opening / closing valve 47 are provided. Are loosely fitted. A circular first concave portion 47a and a second concave portion 48a are provided at the outer central portions of the first on-off valve 47 and the second on-off valve 48, respectively. A rigid disc-shaped first relay member 49 and second relay member 50 are loosely fitted in the first recess 47a and the second recess 48a, respectively.

  In this case, the first recess 47a and the second recess 48a have the same configuration, and the first relay member 49 and the second relay member 50 have the same configuration. A flexible film 51 (see FIG. 10) is attached to the left surface of the main body 30 so as to seal the opening of the first valve body housing portion 33 and the opening of the first communication groove 37. Similarly, The flexible film 51 is attached to the right surface of the main body 30 so as to seal the opening of the second valve body accommodating portion 34 and the opening of the second communication groove 38.

  As shown in FIGS. 7 and 10, the bottom wall of the first recess 47a in the first on-off valve 47 is a first film-like portion 47b, and the inner bottom surface 47c of the first recess 47a and the first relay member 49 are It is parallel to the right surface 49a. Moreover, the inner peripheral surface (inner side surface) of the first recess 47a is orthogonal to the inner bottom surface 47c and constitutes the first guide surface 47d.

  On the other hand, the bottom wall of the second recess 48a in the second on-off valve 48 is a second film-like portion 48b, and the inner bottom surface 48c of the second recess 48a and the left surface 50a of the second relay member 50 are parallel to each other. Yes. Further, the inner peripheral surface (inner side surface) of the second recess 48a is orthogonal to the inner bottom surface 48c and constitutes a second guide surface 48d.

Next, the configuration of the drive unit 25B constituting the switching device 25 will be described in detail.
As shown in FIG. 9, the drive unit 25 </ b> B includes a plate cam 71 as a rotary cam made of a non-circular plate material having a curved outer peripheral edge, and a first operating plate as a first actuator constituting the actuator. 73 and a second operation plate 72 as a second actuator constituting the actuator. A shaft 74 extends from the center of the plate cam 71 in a direction orthogonal to the plate cam 71, and a cam motor 75 is connected to the tip of the shaft 74. That is, the plate cam 71 is rotated (rotated) in the forward rotation direction or the reverse rotation direction (the direction indicated by the arrow in the drawing) around the shaft 74 by the drive of the cam motor 75.

  Further, on the outer peripheral edge of the plate cam 71, there are a first cam surface 71a and a second cam surface 71b with which the first operation plate 73 and the second operation plate 72 are sequentially engaged as the plate cam 71 rotates. Is formed. The first cam surface 71a is formed to have an arc shape whose radius is the distance from the shaft 74, which is the rotation center of the plate cam 71, while the second cam surface 71b has a distance from the shaft 74 of the first cam surface 71a. It is formed to have a substantially chordal shape that is shorter than the cam surface 71a.

  The first operating plate 73 and the second operating plate 72 have the same shape, and both of them have a substantially Z-shaped plate shape. The first operating plate 73 and the second operating plate 72 are superposed so as to cross each other at the center thereof, with only one of them turned upside down. The first operating plate 73 and the second operating plate 72 are pivotally supported by a single shaft 76 extending in a direction orthogonal to the first operating plate 73 and the second operating plate 72 so as to be swingable at the center portion where these intersect. That is, each of the first operating plate 73 and the second operating plate 72 is swung (driven) in the forward direction or the reverse direction about the shaft 76.

  The first operating plate 73 and the second operating plate 72 have one end side as the first driven portion 73a and the second driven portion 72a, respectively, with the shaft 76 as a boundary, and the other end side as the first pressing operating portion 73b and the second pressing portion, respectively. It is set as the operation part 72b. A plate cam 71 is disposed so as to be sandwiched between the first driven portion 73a and the second driven portion 72a. The first driven portion 73a and the second driven portion 72a have a shape in which the distal ends thereof are bent toward the plate cam 71, and the distal ends of the first driven portion 73a and the second driven portion 72a are outside the plate cam 71, respectively. It is in sliding contact with the peripheral edge, that is, the first cam surface 71a or the second cam surface 71b.

  A first coil spring 77 is interposed between the second driven portion 72a and the first pressing operation portion 73b as a valve closing force reduction suppressing means, and the second driven portion 72a and the first pressing operation portion are provided by the first coil spring 77. 73b is always urged away from the center. Similarly, a second coil spring 78 is interposed between the first driven portion 73a and the second pressing operation portion 72b as a valve closing force reduction suppressing means, and the second coil spring 78 and the first driven portion 73a. The second pressing operation portion 72b is always urged in a direction away from the second pressing operation portion 72b. Therefore, the tips of the first driven portion 73 a and the second driven portion 72 a are always pressed against the peripheral edge of the plate cam 71 by the urging forces of the second coil spring 78 and the first coil spring 77.

  A first convex portion 73c and a second convex portion 72c extending inward so as to face each other are provided at the distal end portions of the first pressing operation portion 73b and the second pressing operation portion 72b, respectively. A switching unit 25A is arranged between the first pressing operation portion 73b and the second pressing operation portion 72b, that is, between the first protrusion 73c and the second protrusion 72c. In this case, the switching unit 25A is configured so that the right surface of the second relay member 50 faces the tip surface of the second convex portion 72c, while the left surface of the first relay member 49 faces the tip surface of the first convex portion 73c. Has been placed.

  And by rotating the plate cam 71, the 2nd convex part 72c presses the 2nd relay member 50 toward the left side from the right side via the flexible film 51, or the 1st convex part 73c is flexible. The first operating plate 73 and the second operating plate 72 are swung so as to press the first relay member 49 from the left side to the right side through the conductive film 51. FIG. 9 shows a state where the second convex portion 72c presses the second relay member 50 from the right side to the left side through the flexible film 51.

Next, the operation of the switching device 25 will be described.
10 and 11 are cross-sectional views of the main body 30 when viewed from the lower side in the vicinity of the connecting portion 35 and the connecting portion 35.

  As shown in FIGS. 9 and 10, when the ink supplied to the recording head 18 is switched from the matte black ink to the photo black ink, the plate cam 71 is first rotated. 9, the first driven portion 73a of the first operating plate 73 engages with the first cam surface 71a of the plate cam 71, and the second driven portion 72a of the second operating plate 72 is the plate cam. 71 is engaged with the second cam surface 71b.

  Then, the second operating plate 72 presses the second relay member 50 from the right side to the left side via the flexible film 51 by the second convex portion 72c, and the first operating plate 73 presses the first convex portion 73c. It stops at a position separated from the first relay member 49 (a position at which the valve opening operation of the first on-off valve 47 is allowed). At this time, since the second operating plate 72 swings about the shaft 76, the second convex portion 72c presses the second relay member 50 while drawing an arcuate path instead of a straight line. For this reason, the pressing force from the second convex portion 72c is applied to the right surface of the second relay member 50 from a slightly oblique direction with respect to the left direction, but the second relay member 50 is guided by the second guide surface 48d. And move straight to the left.

  Then, the left surface 50a of the second relay member 50 comes into contact with the inner bottom surface 48c of the second recess 48a, and the second relay member 50 causes the second film-like portion 48b (second on-off valve 48) to move to the left. Displaced in the direction. Due to the displacement of the second film-like portion 48b, the second film-like portion 48b is brought into close contact with the second protrusion 34c and both the transmission members 46 are pressed leftward. When both the transmission members 46 are pressed in the left direction, the two transmission members 46 press the first on-off valve 47 in the left direction along with the pressing, and the first on-off valve 47 is pressed in the left direction. When the first on-off valve 47 is pressed in the left direction, the first on-off valve 47 and the first protrusion 33c are separated from each other.

  In this state, the first communication groove 37 and the first connection path 44 are in communication with each other through the first valve body housing portion 33, and the second connection groove 38 and the second connection path 45 are in non-communication. That is, the first on-off valve 47 is opened and the second on-off valve 48 is closed (the state shown in FIG. 10). That is, the pressing force from the second convex portion 72 c becomes a valve closing force for closing the second on-off valve 48, and the valve closing force for closing the second on-off valve 48 by the both transmission members 46 causes the first on-off valve 47 to close. This is transmitted to the first on-off valve 47 as a valve opening force for opening the valve. Therefore, the closing of the second on-off valve 48 and the opening of the first on-off valve 47 are performed simultaneously.

  Then, when mat black ink, which has been used last time, is ejected from the nozzle 20a of the recording head 18 into the cap 27 by flushing, the photo black ink passes through the first valve body accommodating portion 33 from the first communication groove 37. Into the first connecting path 44. In the flushing in this case, ink is selectively ejected only from the nozzles 20a. 10, the photo black ink that has flowed into the first connection path 44 flows into the first through hole 39, and the ink supplied to the recording head 18 is transferred from the mat black ink. Switch to photo black ink.

  Here, during the closing of the second on-off valve 48, the pressing force from the second convex portion 72c continues to act on the second on-off valve 48 as the closing force. When the time has elapsed, the second operating plate 72 may be deformed due to aging (creep), and the adhesion (sealability) of the second film-like portion 48b of the second on-off valve 48 to the second protrusion 34c may be reduced. In this regard, in the present embodiment, when the second on-off valve 48 is closed, the first operating plate 73 is stopped while the first on-off valve 47 and the first protrusion 33 c are separated from each other. The second coil spring 78 is contracted by the one driven portion 73a.

  For this reason, since the restoring force of the second coil spring 78 is increased by the amount contracted by the first driven portion 73a, the second convex portion 72c presses the second opening / closing valve 48 in the valve closing direction (valve closing force). ) Increases so that the second coil spring 78 urges the second pressing operation portion 72b in the direction in which the second operation plate 72 swings. Therefore, a decrease in the adhesion (sealability) of the second film-like portion 48b to the second protrusion 34c during the closing of the second on-off valve 48 is suppressed.

  On the other hand, as shown in FIGS. 9 and 11, when the ink supplied to the recording head 18 is switched from the photo black ink to the matte black ink, the plate cam 71 is first rotated. In contrast to the case shown in FIG. 9, the second driven portion 72 a of the second operating plate 72 engages with the first cam surface 71 a of the plate cam 71 and the first driven portion 73 a of the first operating plate 73. Is engaged with the second cam surface 71 b of the plate cam 71.

  Then, the first operating plate 73 presses the first relay member 49 from the left side toward the right side through the flexible film 51 by the first convex portion 73c, and the second operating plate 72 presses the second convex portion 72c. It stops at a position separated from the second relay member 50 (a position at which the valve opening operation of the second on-off valve 48 is allowed). At this time, since the first operating plate 73 swings about the shaft 76, the first convex portion 73c presses the first relay member 49 while drawing an arcuate path instead of a straight line. Therefore, the pressing force from the first convex portion 73c is applied to the left surface of the first relay member 49 from a slightly oblique direction with respect to the right direction, but the first relay member 49 is guided to the first guide surface 47d. And move straight to the right.

  Then, the right surface 49a of the first relay member 49 comes into contact with the inner bottom surface 47c of the first recess 47a, and the first relay member 49 causes the first film-like portion 47b (first on-off valve 47) to be in the valve closing direction. Displaced in the direction. Due to the displacement of the first film-like portion 47b, the first film-like portion 47b is brought into close contact with the first protrusion 33c and both the transmission members 46 are pressed rightward. When both transmission members 46 are pressed in the right direction, both transmission members 46 press the second on-off valve 48 in the right direction along with the pressing, and the second on-off valve 48 is pressed in the right direction. When the second on-off valve 48 is pressed rightward, the second on-off valve 48 and the second protrusion 34c are separated from each other.

  In this state, the second communication groove 38 and the second connection path 45 are in communication with each other through the second valve body housing portion 34, and the first communication groove 37 and the first connection path 44 are in non-communication. That is, the second on-off valve 48 is opened and the first on-off valve 47 is closed (the state shown in FIG. 10). That is, the pressing force from the first convex portion 73 c becomes a valve closing force for closing the first on-off valve 47, and the valve closing force for closing the first on-off valve 47 by the both transmission members 46 causes the second on-off valve 48 to close. This is transmitted to the second on-off valve 48 as a valve opening force for opening the valve. Therefore, the closing of the first on-off valve 47 and the opening of the second on-off valve 48 are performed simultaneously.

  Then, when the photo black ink, which was previously used, is ejected from the nozzle 20a of the recording head 18 into the cap 27 by flushing, the mat black ink passes through the second valve body accommodating portion 34 from the second communication groove 38. Into the second connecting path 45. In the flushing in this case, ink is selectively ejected only from the nozzles 20a. Then, as indicated by an arrow in FIG. 11, the matte black ink that has flowed into the second connection path 45 flows into the first through hole 39, and the ink supplied to the recording head 18 is removed from the photoblack ink. Switch to matte black ink.

  Here, while the first on-off valve 47 is closed, the pressing force from the first convex portion 73c continues to act on the first on-off valve 47 as the valve closing force. When the time has elapsed, the first operating plate 73 may be deformed due to aging (creep), and the adhesion (sealability) of the first film-like portion 47b of the first on-off valve 47 to the first protrusion 33c may be reduced. In this regard, in the present embodiment, when the first on-off valve 47 is closed, the second operation plate 72 is stopped while the second on-off valve 48 and the second protrusion 34c are separated from each other. The first coil spring 77 is contracted by the two driven portions 72a.

  For this reason, since the restoring force of the first coil spring 77 is increased by the amount contracted by the second driven portion 72a, the first convex portion 73c presses the first on-off valve 47 in the valve closing direction (valve closing force). ) Increases so that the first coil spring 77 urges the first pressing operation portion 73b in the direction in which the first operation plate 73 swings. Accordingly, a decrease in the adhesion (sealability) of the first film-like portion 47b to the first protrusion 33c during the closing of the first on-off valve 47 is suppressed.

  As described above, when the ink to be used is switched between the photo black ink and the matte black ink, the second film-like portion 48b (second on-off valve 48) is moved by the second convex portion 72c by swinging the second operation plate 72. ) In the valve closing direction or by swinging the first operating plate 73 to press the first film-like portion 47b (first on-off valve 47) in the valve closing direction by the first convex portion 73c. There is.

  In this case, both the first operating plate 73 and the second operating plate 72 that are arranged so as to cross each other are swung by the rotation of the single rotary plate cam 71, so that the plate cam 71 is linearly moved. Less space is required when driving the cam than when the cam is changed to a direct-acting cam that slides. For this reason, the drive unit 25B (switching device 25) can be downsized.

As described above, according to the embodiment described in detail, the following effects can be obtained.
(1) In general, a rotary cam requires less space during driving than a linear motion cam that slides linearly. In this regard, according to the present embodiment, the first operating plate 73 and the second operating plate 72 for opening and closing the first on-off valve 47 and the second on-off valve 48 are driven as the rotary plate cam 71 rotates. Therefore, the required space can be reduced as compared with the case where the first operating plate 73 and the second operating plate 72 are driven by the direct acting cam. Therefore, the switching device 25 for changing the type of ink supplied to the recording head 18 can be reduced in size, and the ink jet printer 11 can be reduced in size.

  (2) Since both the first operating plate 73 and the second operating plate 72 can be driven by the rotation of one rotary plate cam 71, the first operating plate 73 and the second operating plate 72 are separately provided. The number of parts can be reduced as compared with the case where each cam is driven.

  (3) With both transmission members 46, the closing force when the first opening / closing valve 47 is closed by pressing the first opening / closing valve 47 with the first convex portion 73c of the first operating plate 73 is opened to open the second opening / closing valve 48. The first on-off valve 47 is opened as the valve force is transmitted to the second on-off valve 48 as well as the closing force when the second on-off valve 48 is closed by the second convex portion 72c of the second operating plate 72. The valve opening force can be transmitted to the first on-off valve 47. Therefore, the first on-off valve 47 can be closed and the second on-off valve 48 can be simultaneously opened, and the second on-off valve 48 and the first on-off valve 47 can be simultaneously opened. be able to. Therefore, the type of ink supplied to the recording head 18 can be quickly switched between the photo black ink and the matte black ink.

  (4) Since the first operating plate 73 and the second operating plate 72 are pivotally supported by the single shaft 76, the first operating plate 73 and the second operating plate 72 are swung by separate shafts. The number of parts can be reduced as compared with the case of pivot support.

  (5) By rotating and driving the plate cam 71 in one direction, the first operating plate 73 and the second operating plate 72 swing, so that one of the first on-off valve 47 and the second on-off valve 48 Can be alternately switched between a state in which the valve is closed and the other is opened and a state in which one is opened and the other is closed.

  (6) While the second on-off valve 48 is closed, the second coil spring 78 is contracted by the first driven portion 73a. For this reason, since the restoring force of the second coil spring 78 is increased by the amount contracted by the first driven portion 73a, the second convex portion 72c presses the second opening / closing valve 48 in the valve closing direction (valve closing force). ) Increases so that the second coil spring 78 urges the second pressing operation portion 72b in the direction in which the second operation plate 72 swings. Accordingly, it is possible to suppress a decrease in the adhesion (sealability) of the second film-like portion 48b to the second protrusion 34c while the second opening / closing valve 48 is closed. On the other hand, while the first opening / closing valve 47 is closed, the first coil spring 77 is contracted by the second driven portion 72a. For this reason, since the restoring force of the first coil spring 77 is increased by the amount contracted by the second driven portion 72a, the first convex portion 73c presses the first on-off valve 47 in the valve closing direction (valve closing force). ) Increases so that the first coil spring 77 urges the first pressing operation portion 73b in the direction in which the first operation plate 73 swings. Therefore, it is possible to suppress a decrease in the adhesion (sealability) of the first film-like portion 47b to the first protrusion 33c while the first opening / closing valve 47 is closed.

Therefore, the reliability during closing of the first on-off valve 47 and the second on-off valve 48 can be improved.
(6) Since the ink switching between the mat black ink and the photo black ink is performed by flushing in which the ink is selectively ejected only from the nozzle 20a, the mat black ink and the photo black ink are switched when the ink is switched. It is possible to prevent the consumption of ink other than. Incidentally, when the ink is switched between the matte black ink and the photoblack ink by cleaning using the integral cap 27 that collectively covers all the nozzles 20a to 20c, the matte black ink and the photo black are used. Ink other than ink is wasted.

(Example of change)
In addition, you may change the said embodiment as follows.
As the valve closing force reduction suppressing means, a plate spring or a torsion spring may be used instead of the first coil spring 77 and the second coil spring 78. Alternatively, instead of the first coil spring 77 and the second coil spring 78, two sets of magnets that repel each other may be used as the valve closing force reduction suppression means. In this case, the repulsive force of each of the two sets of magnets urges the second driven portion 72a and the first pressing operation portion 73b to always move away from each other, and the first driven portion 73a and the second pressing operation portion. 72b is always biased in the direction of separating.

The first operating plate 73 and the second operating plate 72 may be pivotally supported by different shafts so as to be swingable.
-A rotary cam is not limited to the shape of the plate cam 71 of embodiment. That is, when the actuator is engaged, the rotary cam has a cam surface that imparts a swinging motion to the actuator in a direction that allows the opening / closing valve to open, and causes the actuator to close the opening / closing valve. Any shape may be used as long as a cam surface that imparts a swinging motion in the direction is formed.

-The two transmission members 46 may be formed integrally.
The first operating plate 73 and the second operating plate 72 may be driven by separate rotary plate cams 71, respectively.

  In the present embodiment, the switching device 25 switches the ink between the matte black ink and the photo black ink, but the ink is switched between the dark ink and the light color ink in the same color ink. You may make it perform. For example, the ink may be switched between cyan ink and light cyan ink, or between magenta ink and light magenta ink.

  The switching device 25 may be configured such that the first connection path 44 and the second connection path 45 are connected so as to form a V shape or a U shape. That is, the switching device 25 may be configured so that the connecting path 36 has a V shape or a U shape. In this case, the shape of the transmission member 46 needs to be changed as appropriate in accordance with the shape of the connecting path 36.

  In the above embodiment, an ink jet printer (printing apparatus including a fax machine, a copier, etc.) that ejects ink has been described as the liquid ejecting apparatus. However, a liquid ejecting apparatus that ejects another liquid may be used. For example, as a liquid ejecting apparatus for ejecting liquids such as electrode materials and color materials used in the manufacture of liquid crystal displays, EL displays, and surface-emitting displays, as a liquid ejecting apparatus for ejecting bioorganic materials used in biochip manufacturing, and as precision pipettes The sample injection device may be used.

FIG. 2 is a schematic plan view of the ink jet printer according to the embodiment. The front simplified view of the carriage of the printer. The disassembled perspective view of the switching unit of the printer. The principal part perspective view of the switching unit of the printer. The principal part expanded sectional view of the connection part of a switching unit. The top view of a switching unit. Sectional drawing of the principal part of a switching unit. The perspective view of a transmission member. Schematic which shows the positional relationship of a switching unit and a drive unit. The principal part expanded sectional view of the switching apparatus of the state which the 1st on-off valve opened and the 2nd on-off valve closed. The principal part expanded sectional view of the switching apparatus of the state which the 1st on-off valve closed and the 2nd on-off valve opened.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 ... Inkjet printer as a liquid ejecting device, 18 ... Recording head as a liquid ejecting head, 25 ... Switching device, 33 ... First valve body housing portion constituting the first supply passage, 34 ... Constructing the second supply passage Second valve body housing portion 37, first communication groove constituting the first supply path 38, second communication groove constituting the second supply path 39, first through hole constituting the head side supply path, 40: a concave groove constituting the head side supply path, 41: a second through hole constituting the head side supply path, 44 ... a first connection path constituting the first supply path, 45 ... a second constituting the second supply path. 2 connection paths, 46 ... transmission member, 47 ... first on-off valve, 48 ... second on-off valve, 71 ... plate cam as a rotary cam, 71a ... first cam surface, 71b ... second cam surface, 72 ... Second operating plate as a second actuator constituting the actuator, 73. First actuating plate as first actuator constituting actuator, 76 ... shaft, 77 ... first coil spring as valve closing force reduction suppressing means, 78 ... second coil spring as valve closing force reduction suppressing means, G ... confluence .

Claims (4)

A liquid comprising: a liquid ejecting head that ejects liquid; and a switching device that selectively switches a type of liquid supplied to the liquid ejecting head between a first liquid and a second liquid different from the first liquid. An injection device,
The switching device is
A first supply path for supplying the first liquid;
A second supply path for supplying the second liquid;
A head side supply path that communicates between a confluence of downstream ends of the first supply path and the second supply path and the liquid ejecting head;
A first on-off valve that opens and closes the first supply path on the upstream side of the junction with the second supply path in the first supply path;
A second on-off valve that opens and closes the second supply path upstream of a junction with the first supply path in the second supply path;
One rotary cam,
A first actuator and a second actuator pivotally supported by one shaft in a state of crossing each other;
With
The cam is disposed so as to be in sliding contact with both actuators between one end sides of the first actuator and the second actuator with the shaft as a boundary, and the first on-off valve and the second on-off valve are disposed on the shaft. Between the other end side of the first actuator and the second actuator with the boundary as the other end side of the first actuator and the second actuator, respectively,
The first actuator and the second actuator are oscillated as the cam is rotated, so that one of the first on-off valve and the second on-off valve is opened and the other is closed. as the valve, a liquid-jet apparatus characterized and Turkey the pressing force is displaced by applying to these first on-off valve and the second on-off valve. The cam is formed with a first cam surface and a second cam surface that are sequentially engaged with one end side of the first actuator and the second actuator as the cam rotates. By engaging one end side with the first cam surface, the other end side of the actuator is displaced away from the corresponding on-off valve, while by engaging one end side with the second cam surface, the other end of the actuator. The liquid ejecting apparatus according to claim 1, wherein the side is configured to be displaced in a direction in which a pressing force is applied to a corresponding opening / closing valve to perform a valve closing operation . A transmission member is slidably disposed between the first on-off valve and the second on-off valve in the first supply path and the second supply path that communicate with each other via the junction.
The transmission member transmits a valve closing force when the first actuator is closed by the first actuator to the second valve as an opening force for opening the second valve. claims the closing force at the time of closing the second on-off valve by a second actuator, characterized by the Turkey be transmitted to the first on-off valve as opening force for opening the first on-off valve the liquid ejecting apparatus according to 1 or claim 2. The one end side of the first actuator and the other end side of the second actuator, and the one end side of the second actuator and the other end side of the first actuator are attached in a direction to separate them. liquid ejecting apparatus as claimed in any one of claims 1 to 3, characterized in that the urging member for energizing is interposed, respectively.

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