The present invention relates to a liquid ejecting apparatus such as an ink jet printer, for example.
In the related art, as an example of the liquid ejecting apparatus, there has been an ink jet printer which performs printing by ejecting ink (liquid) supplied from an ink tank to a recording medium from a recording head (liquid ejecting head). In addition, in such a printer, there has been a printer provided with a sub-tank (liquid chamber) which expands and contracts on an ink supply path (liquid supply path) supplies ink to the recording head from the ink tank (liquid accommodating unit), and which detects a residual quantity of ink in the ink tank according to a swelling state of the sub-tank (for example, JP-A-2005-96152).
Meanwhile, such a printer is provided with an ink supply valve which opens or closes the ink supply path on the upstream side from the sub-tank. For this reason, the ink supply path becomes complicated.
Such a problem is not limited to an ink jet printer provided with an ink supply path, and is generally common to a liquid ejecting apparatus provided with a liquid supply path.
An advantage of some aspects of the invention is to provide a liquid ejecting apparatus in which it is possible to prevent a configuration of a liquid supply path from becoming complicated.
Hereinafter, means of the invention and operation effects thereof will be described.
According to an aspect of the invention, there is provided a liquid ejecting apparatus which includes a liquid ejecting head which ejects liquid from nozzles, a liquid supply path which includes a liquid chamber partly formed by a flexible member, and supplies the liquid to the liquid ejecting head, and a flow path unit which includes a displacement detecting unit which detects a displacement of the flexible member, and the liquid chamber, in which the flexible member closes the liquid supply path by being displaced in a direction in which a volume of the liquid chamber is reduced due to a decrease in the liquid in the liquid chamber.
According to the configuration, since the liquid supply path is closed by the flexible member which is a detecting target of the displacement detecting unit, and configures a part of the liquid chamber, it is possible to prevent a configuration of the liquid supply path from being complicated, compared to a case in which a configuration for closing the liquid supply path is separately provided.
In the liquid ejecting apparatus, it is preferable that the flow path unit further include a guided portion which is connected to the flexible member and displaced along with the flexible member, and a guide portion which guides the guided portion in a displacing direction of the flexible member.
According to the configuration, since the guided portion connected to the flexible member is guided in a displacing direction of the flexible member by the guide portion, it is possible to make a displacement of the flexible member stable. Accordingly, it is possible to stably close the liquid supply path using the flexible member.
In the liquid ejecting apparatus, it is preferable that the guided portion be provided in a shaft shape so as to protrude on the liquid chamber side from the flexible member, the guide portion be configured so that the guided portion is inserted into the guide portion, the flexible member have an annular closing portion at a position surrounding the guided portion, and the closing portion close the liquid supply path when the flexible member is displaced in a direction of reducing a volume of the liquid chamber, and comes into contact with the liquid supply path.
According to the configuration, the closing portion included in the flexible member closes the liquid supply path at a position of surrounding the guided portion. That is, since it is possible to determine a position for closing the liquid supply path, closing of the liquid supply path can be stably performed.
It is preferable that the liquid ejecting apparatus further include a suctioning unit which suctions the liquid from the liquid ejecting head, and the flow path unit further include a liquid sending unit which sends the liquid to the liquid ejecting head from a liquid accommodating unit on the upstream side from the liquid chamber, and the flexible member close the liquid supply path when the liquid is suctioned by the suctioning unit in a state in which the liquid sending unit is set to a non-driving state.
According to the configuration, it is possible to perform cleaning of the liquid ejecting head using the suctioning unit which suctions liquid from the liquid ejecting head. In addition, since it is possible to close the liquid supply path using the suctioning, it is possible to suppress an increase in the number of components compared to a case of separately providing a mechanism for closing the liquid supply path.
In the liquid ejecting apparatus, it is preferable that the flexible member open the liquid supply path when the liquid sending unit is driven in a state in which the liquid is suctioned by the suctioning unit, and the liquid supply path is closed.
According to the configuration, when liquid is suctioned by the suctioning unit, and the liquid supply path is closed, a negative pressure in the liquid supply path increases. In addition, when the liquid supply path is opened by driving the liquid sending unit in this state, liquid can be caused to flow with great force.
In the liquid ejecting apparatus, it is preferable that the flow path unit further include a connection portion which is connected to the liquid accommodating unit which accommodates the liquid supplied to the liquid ejecting head, and an engaging portion which is engaged with the liquid accommodating unit, and the connection portion and the engaging portion are respectively provided with respect to a plurality of liquid accommodating units.
According to the configuration, since the flow path unit includes the connection portion and the engaging portion, it is possible to make a structure of a mounting unit on which the liquid accommodating unit is mounted simple. For this reason, it is possible to cause a color of liquid to be accommodated, a quantity of liquid to be accommodated, or the like, to easily correspond to a liquid accommodating unit of a different type.
In the liquid ejecting apparatus, it is preferable that the flow path unit further include a substrate connection portion which is electrically connected to a circuit board of the liquid accommodating unit which accommodates the liquid supplied to the liquid ejecting head, and the substrate connection portion are respectively provided with respect to the plurality of liquid accommodating units.
According to the configuration, since the flow path unit includes the substrate connection portion which is connected to the circuit board of the liquid accommodating unit, it is possible to make a structure of the mounting unit on which the liquid accommodating unit is mounted simple. For this reason, it is possible to cause a color of liquid to be accommodated, a quantity of liquid to be accommodated, or the like, to easily correspond to a liquid accommodating unit of a different type.
The invention will be described with reference to the accompanying drawings, wherein like numbers reference like elements.
Hereinafter, one embodiment of a liquid ejecting apparatus will be described with reference to drawings. The liquid ejecting apparatus is an ink jet printer which performs recording (printing) by ejecting ink as an example of liquid to a medium such as a sheet, for example.
As illustrated in
One or a plurality of (four in embodiment) containers 13 can be mounted on the mounting unit 14 in the embodiment. A liquid accommodating body 20 can be detachably mounted in these containers 13. In addition, in the embodiment, a liquid accommodating unit 21 is formed of the container 13, and the liquid accommodating body 20 mounted in the container 13.
The liquid accommodating bodies 20 accommodate liquid of different types (for example, ink of different color such as black, cyan, magenta, yellow), respectively. In addition, the container 13 is detachably mounted on the mounting unit 14 even in a state of a single body which does not hold the liquid accommodating body 20, and is a constituent element provided in the liquid ejecting apparatus 11.
In the embodiment, a direction intersecting (orthogonal, preferably) a movement path of the container 13 when being mounted on the mounting unit 14 is a width direction, and a direction in which the movement path extends is a depth direction. The width direction and the depth direction substantially go along a horizontal plane. In drawings, a direction of gravity is denoted by a Z axis by assuming that the exterior body 12 is placed on the horizontal plane, and a movement direction of the container 13 when being mounted on the mounting unit 14 is denoted by a Y axis. There is a case in which the movement direction is also written as a mounting direction on the mounting unit 14 or an inserting direction to an accommodating space, and a direction opposite to the movement direction is written as an extracting direction. In addition, the width direction is denoted by an X axis which is orthogonal to the Z axis and the Y axis. That is, the width direction, the direction of gravity, and the mounting direction intersect (orthogonal, preferably) each other, and become directions in a case of writing lengths of a width, a height, and a depth, respectively.
As illustrated in
As illustrated in
A flow path unit 33 including a connection portion 32 formed in a hollow pin shape is provided on the depth side of the accommodating space formed by the frame body 31. When the liquid accommodating unit 21 is mounted on the mounting unit 14, a supply port 34 (refer to
As illustrated in
The transport unit 24 includes a medium support unit 36 which supports the medium S. The transport unit 24 transports the medium S accommodated in the medium accommodating unit 23, by taking out the medium from the medium accommodating unit 23 sheet by sheet, and dispose the medium on the medium support unit 36.
The recording unit 25 is provided with a liquid ejecting head 38 which ejects liquid from the nozzle 37, and a carriage 39 which holds the liquid ejecting head 38. A guide shaft 40 which extends in the width direction is installed inside the exterior body 12. The carriage 39 reciprocates in the width direction along the guide shaft 40, and printing is performed when the liquid ejecting head 38 ejects liquid to the medium S on the medium support unit 36 in the middle of reciprocating of the carriage.
The liquid supply flow path 27 is a flow path for supplying liquid to the liquid ejecting head 38 from the liquid accommodating unit 21, and at least one (four in embodiment) liquid supply path is provided in each type of liquid (color in embodiment). That is, liquid supplied to the liquid ejecting head 38 is accommodated in the liquid accommodating unit 21.
It is preferable that the liquid supply flow path 27 include a flow path on upstream side 41, a flow path on downstream side 42, and a connection flow path 43 which connects the flow path on upstream side 41 and the flow path on downstream side 42. In addition, the flow path on upstream side 41 includes the flow path unit 33 and a flexible supply tube 44.
As illustrated in
As illustrated in
The cap 49 forms a closed spatial area between the cap and a lower face side to which the nozzle 37 of the liquid ejecting head 38 opens in a surrounding manner, by coming into contact with the liquid ejecting head 38 so as to surround an opening of the nozzle 37, by moving in a lifting manner. In addition, suctioning cleaning in which liquid in the liquid ejecting head 38 is discharged through the nozzle 37 is performed, by causing a negative pressure in the closed spatial area by driving the suctioning unit 51 in this state. That is, the suctioning unit 51 suctions liquid from the liquid ejecting head 38.
Subsequently, an external configuration of the flow path unit 33 will be described in detail.
As illustrated in
In addition, the first connecting mechanism 53F is provided with a substrate connection portion 56 which is disposed upward vertically, compared to the connection portion 32, and protrudes in the extracting direction. The substrate connection portion 56 is connected to the control unit 29 through electric wiring 57 such as a flat cable. It is preferable that a higher end of the substrate connection portion 56 protrudes in an extracting direction compared to a lower end, and is disposed so as to face downward diagonally. In addition, it is preferable that a pair of guiding protrusion portions 56a which protrudes in the width direction, and extends along a mounting direction is disposed on both sides of the substrate connection portion 56 in the width direction.
It is preferable that the second connecting mechanism 53S be provided with a block 58 for preventing an erroneous insertion which protrudes in the extracting direction on the vertically higher side of the connection portion 32. The block 58 is formed in an uneven shape which is disposed by facing downward, and the uneven shape is different in each flow path unit 33.
The flow path unit 33 is provided with a pair of positioning protrusion portions 59a and 59b, an extrusion mechanism 60 which is disposed so as to surround the connection portion 32, and a liquid receiving portion 61 which protrudes in the extracting direction on the lower side of the connection portion 32. The pair of positioning protrusion portions 59a and 59b are aligned in the width direction by interposing the connection portion 32 therebetween so as to be included in the first connecting mechanism 53F and the second connecting mechanism 53S, respectively. The positioning protrusion portions 59a and 59b can be set to a bar-shaped protrusion portion which protrudes in the extracting direction by being in parallel to each other, for example. It is preferable that a protruding length of the positioning protrusion portions 59a and 59b in the extracting direction be longer than a protruding length of the connection portion 32 in the extracting direction.
The extrusion mechanism 60 is provided with a frame member 60a which surrounds a base end portion of the connection portion 32, an extrusion portion 60b which protrudes in an extracting direction from the frame member 60a, and an urging portion 60c which urges the liquid accommodating unit 21 in the extracting direction through the extrusion portion 60b. The urging portion 60c can be set to a coil spring which is interposed between the frame member 60a and the extrusion portion 60b, for example.
Subsequently, the liquid accommodating unit 21 mounted on the mounting unit 14 will be described.
As illustrated in
The liquid accommodating unit 21 is provided with a connection structure 63 at a tip end portion when setting a side which goes forward when being mounted on the mounting unit 14 (refer to
The first connection structure 63F is provided with a circuit board 64 which is disposed vertically upward compared to the supply port 34. The circuit board 64 includes a storage unit which stores various information (for example, type of liquid accommodating body 20, accommodating quantity of liquid, or the like) related to the liquid accommodating body 20. In addition, the circuit board 64 includes a connecting terminal which is electrically connected to the substrate connection portion 56 included in the flow path unit 33.
It is preferable that the circuit board 64 is disposed in a recessed portion 64a which is provided in a form of being opened to a higher part and in a mounting direction, in a posture of facing upward, diagonally. In addition, it is preferable that a guiding recessed portion 64g which extends in a mounting direction be disposed on both sides of the circuit board 64 in the width direction.
It is preferable that the second connection structure 63S be provided with an identification portion 65 for preventing an erroneous insertion which is disposed vertically upward compared to the supply port 34. The identification portion 65 has an uneven portion formed in a shape of being fitted to the block 58 (refer to
The connection structure 63 is provided with a pair of positioning holes 66a and 66b, and an urge receiving portion 67 which receives an urging force of the urging portion 60c (refer to
Subsequently, a connection of the connection structure 63 provided in the liquid accommodating unit 21 to the flow path unit 33 will be described.
As illustrated in
When the positioning protrusion portions 59a and 59b are engaged with the positioning holes 66a and 66b, and the liquid accommodating unit 21 proceeds to the depth side thereafter, the urge receiving portion 67 receives an urging force of the urging portion 60c by being in contact with the extrusion portion 60b, and the supply port 34 of the liquid accommodating unit 21 is connected to the connection portion 32. In this manner, it is preferable that the positioning protrusion portions 59a and 59b position the liquid accommodating unit 21 before the connection portion 32 is connected to the supply port 34.
In a case in which the liquid accommodating unit 21 is inserted into a correct position, the identification portion 65 is appropriately fitted to the block 58 of the flow path unit 33. In contrast to this, the identification portion 65 is not fitted to the block 58 in a case in which the liquid accommodating unit 21 is going to be mounted on a wrong position, it is not possible for the liquid accommodating unit 21 to further proceed to the depth side, and it is possible to prevent an erroneous mounting.
When the liquid accommodating unit 21 proceeds in the mounting direction, the substrate connection portion 56 enters inside the recessed portion 64a of the liquid accommodating unit 21, a position of the substrate connection portion 56 is adjusted when the guiding recessed portion 64g is guided by the guiding protrusion portion 56a, and the substrate connection portion comes into contact with the circuit board 64. In this manner, the circuit board 64 is electrically connected to the substrate connection portion 56, and an exchange of information is performed between the circuit board 64 and the control unit 29. In this manner, it is preferable to dispose the first positioning hole 66a as a standard of positioning on the side of the first connection structure 63F including the circuit board 64, between the first connection structure 63F and the second connection structure 63S.
When the supply port 34 of the liquid accommodating unit 21 is connected to the connection portion 32 so as to be able to supply liquid, and the circuit board 64 is electrically connected to the substrate connection portion 56 by being in contact therewith, a connection of the connection structure 63 to the flow path unit 33 is completed.
Subsequently, a structure for attaching or detaching of the liquid accommodating unit 21 with respect to the mounting unit 14 will be described.
As illustrated in
The engaging groove 68 can be set to a heart shaped cam groove which includes a first inclined groove 68a which extends toward the extracting direction from a tip end on a bottom face, a locking groove 68b which extends in the width direction from a terminal end of the first inclined groove 68a, and a second inclined groove 68c which extends from a terminal end of the locking groove 68b toward a starting end of the first inclined groove 68a. In addition, when the container 13 or the liquid accommodating unit 21 gets close to a terminal end of a movement path at a time of being mounted on the mounting unit 14, the engaging portion 55 which protrudes at a tip end of the arm 54 is engaged with the engaging groove 68.
Here, the first inclined groove 68a, the locking groove 68b, and the second inclined groove 68c are inclined so that the grooves become shallow from a starting end toward a terminal end, respectively, and there is a level difference in each intersecting portion. For this reason, when the liquid accommodating unit 21 moves along the mounting direction after the engaging portion 55 is engaged with a starting end of the first inclined groove 68a, the engaging portion 55 is engaged with the first inclined groove 68a, the locking groove 68b, and the second inclined groove 68c in this order along the inclination, and there is no case in which the engaging portion 55 returns to the first inclined groove 68a from the locking groove 68b, or returns to the locking groove 68b from the second inclined groove 68c.
A portion of the locking groove 68b between a starting end and a terminal end is formed in a shape which is bent toward a tip end side, and the locking groove includes an engaging wall portion 68d which is located on the depth side in the mounting direction of the engaging portion 55, and is engaged with the engaging portion 55 at the bent portion. In addition, when the engaging portion 55 is engaged with the engaging wall portion 68d, a movement of the liquid accommodating unit 21 in the extracting direction is regulated while receiving an urging force of the urging portion 60c, and a state of the liquid accommodating unit mounted on the mounting unit 14 is maintained.
When the liquid accommodating unit 21 is engaged with the engaging portion 55, mounting of the liquid accommodating unit 21 on the mounting unit 14 is completed. In addition, since an engaging target of the engaging portion 55 is the container 13, it is also possible to mount the container 13 on the mounting unit 14 even in a case of a single body, not only the liquid accommodating unit 21.
Meanwhile, when the liquid accommodating unit 21 inserted into the accommodating space is pushed in the mounting direction by a user, and the engaging portion 55 relatively moves along the first inclined groove 68a by being engaged with the engaging groove 68, the liquid accommodating unit 21 receives an urging force of the urging portion 60c. For this reason, the liquid accommodating unit 21 slightly moves in the extracting direction using the urging force of the urging portion 60c between proceeding of the engaging portion 55 from the first inclined groove 68a to the locking groove 68b and engaging with the engaging wall portion 68d.
By setting so that there is a touching sound (clicking sound) when the engaging portion 55 comes into contact with the engaging wall portion 68d, or the like, at a terminal end of a movement path in the extracting direction, it is possible to give a user a sense or a feeling (clicking feeling) that mounting on the liquid accommodating unit 21 is completed. In this manner, it is possible to suppress an occurrence of a mounting failure which is caused by an incomplete insertion, or the like, of the liquid accommodating unit 21.
When the liquid accommodating unit 21 is pushed in the mounting direction by a user at a time in which the engaging portion 55 is engaged with the engaging wall portion 68d, the engaging portion 55 proceeds to the second inclined groove 68c along the inclination of the locking groove 68b, moves toward a terminal end of the second inclined groove 68c due to an urging force of the urging portion 60c while going along the inclination of the second inclined groove 68c, subsequently, and the engaging portion is disengaged from the engaging groove 68. Then, the liquid accommodating unit 21 moves in the extracting direction due to an urging force of the urging portion 60c, and a base end portion of the liquid accommodating unit 21 goes out of the frame body 31 and the exterior body 12 from the insertion port 31a. At this time, the supply port 34 is separated from the connection portion 32, the circuit board 64 is separated from the substrate connection portion 56, and mounting of the liquid accommodating unit 21 on the mounting unit 14 is released.
In addition, as illustrated in
In addition, it is preferable to provide three or more (four in embodiment) leg portions 13b which horizontally hold a posture of the container 13 at the base portion of the container 13. In this manner, it is possible to appropriately connect the liquid accommodating unit 21 and the connection portion 32, since the liquid accommodating unit 21 can be positioned in the vertical direction. In addition, it is possible to appropriately maintain the connection between the liquid accommodating unit 21 and the connection portion 32, since a posture of the liquid accommodating unit 21 can be correctly held.
Subsequently, an internal structure of the flow path unit 33 will be described.
As illustrated in
The one-way valve on suctioning side 70 and the liquid sending unit 71 communicate with each other through a first flow path 27a, and the liquid sending unit 71 and the one-way valve on ejecting side 72 communicate with each other through a second flow path 27b. In addition, the one-way valve on ejecting side 72 and the buffer 73 communicate with each other through a third flow path 27c, and the buffer 73 and the supply tube 44 communicate with each other through a fourth flow path 27d (refer to
Subsequently, a configuration and an operation of the liquid sending unit 71 will be described.
As illustrated in
As illustrated in
As illustrated in
In addition, as illustrated in
Subsequently, a configuration and an operation of the one-way valve on suctioning side 70 will be described.
As illustrated in
The one-way valve on suctioning side 70 is provided with a valve chamber on suctioning side 85 which is formed by being surrounded with the recessed portion on suctioning side 78b and the fixing member on suctioning side 83. The valve chamber on suctioning side 85 is partitioned into a portion on the upstream side and a portion on the downstream side using the valve on suctioning side 82, in which a downstream end of the connection portion 32 is connected to the portion on the upstream side, and an upstream end of the first flow path 27a is connected to the portion on the downstream side.
A through-hole 82a is formed at a center portion of the valve on suctioning side 82, and an annular protrusion portion 82b is formed at a position surrounding the through-hole 82a so as to face an inner bottom face of the recessed portion on suctioning side 78b. For this reason, the portion on the upstream side and the portion on the downstream side of the valve chamber on suctioning side 85 can communicate through the through-hole 82a.
As illustrated in
As illustrated in
Meanwhile, as illustrated in
Subsequently, a configuration and an operation of the one-way valve on ejecting side 72 will be described.
As illustrated in
As illustrated in
As illustrated in
Subsequently, a configuration and an operation of the buffer 73 will be described.
As illustrated in
The buffer 73 is provided with a displacing member 94 which is connected to the flexible member 92, and is displaced along with the flexible member 92, a fixing member 95 which fixes the flexible member 92 by being in contact with an outer edge portion of the flexible member 92, and a first urging member 96 as a coil spring, or the like, for example, which is disposed between the displacing member 94 and the fixing member 95.
The displacing member 94 is provided on an outer face on a side opposite to an inner face which configures the liquid chamber 93 of the flexible member 92. In addition, the first urging member 96 urges the flexible member 92 in a direction in which a volume of the liquid chamber 93 is reduced, by urging the displacing member 94.
The displacing member 94 is provided with a first guided portion 94a which protrudes inside the liquid chamber 93 along a displacing direction A, and a second guided portion 94b which protrudes on a side opposite to the liquid chamber 93. In addition, a first guide portion 78e which guides the first guided portion 94a in the displacing direction A of the flexible member 92 is formed in flow path forming member 78. A second guide portion 95a which guides the second guided portion 94b in the displacing direction A is formed in the fixing member 95. That is, the flow path unit 33 includes the guide portions 78e and 95a, and the guided portions 94a and 94b, and the guided portions 94a and 94b are connected to the flexible member 92, and are displaced along with the flexible member 92.
The first guided portion 94a is provided in a shaft shape so as to protrude on the liquid chamber 93 side from approximately a center position of the flexible member 92 which is formed in an approximately disc shape. In addition, the first guide portion 78e is formed in a hole shape in the recessed portion for buffer 78d, and is configured so that the first guided portion 94a is inserted thereto.
It is preferable that the first guided portion 94a be set to a bar-shaped column including one or a plurality of recessions which extend so as to go along the displacing direction A, for example, and a part of the fourth flow path 27d is configured due to an interval between the circular hole-shaped first guide portion 78e and the first guided portion 94a. In addition, the flexible member 92 includes a closing portion 92a which protrudes in an annular shape at a position surrounding the first guided portion 94a.
It is preferable that the first guided portion 94a be set to a length obtained when the first guided portion 94a is engaged with the first guide portion 78e, in a case in which the flexible member 92 is located at the most distant position from the first guide portion 78e, and the liquid chamber 93 has the largest volume. In addition, as illustrated in
As illustrated in
As illustrated in
As illustrated in
Subsequently, in the liquid ejecting apparatus 11 which is configured as described above, particularly, an operation of the buffer 73 included in the flow path unit 33 will be described. In addition, the liquid sending unit 71 is a unit which alternately performs a suctioning operation and an ejecting operation, continuously.
As illustrated in
When liquid is ejected from the liquid ejecting head 38, and is consumed, liquid in the liquid chamber 93 flows out to the fourth flow path 27d. Since the liquid supply flow path 27 includes the liquid chamber 93 of which a volume is variable, liquid can be supplied to the liquid ejecting head 38 while the liquid sending unit 71 performs a suctioning operation. In addition, when the liquid sending unit 71 performs an ejecting operation, a quantity of liquid which flows out is supplied to the liquid chamber 93 from the liquid sending unit 71, and the liquid chamber 93 is maintained at a state of communicating with the fourth flow path 27d.
Meanwhile, when a residual quantity of liquid accommodated in the liquid accommodating unit 21 enters an end state in which liquid is reduced to a quantity which is not sufficient for performing printing, liquid is not supplied from the liquid accommodating unit 21. Then, a volume of the liquid chamber 93 is reduced by a quantity of liquid which flows out to the fourth flow path 27d.
That is, as illustrated in
Subsequently, an operation in a case in which suctioning cleaning of the liquid ejecting head 38 is performed by the maintenance unit 26 will be described. The supply mechanism 28 is maintained at a non-driving state in which the pressure changing chamber 75 is opened to atmosphere. That is, a non-driving state of the liquid sending unit 71 is a state in which a suctioning operation is not performed. For this reason, the liquid sending unit 71 in the non-driving state performs an ejecting operation until the diaphragm 77 comes into contact with the recessed portion for sending liquid 78a in a case of being located at a position separated from the recessed portion for sending liquid 78a, and stops the operation after the diaphragm 77 comes into contact with the recessed portion for sending liquid 78a.
Meanwhile, when the suctioning unit 51 is driven in a state in which the cap 49 comes into contact with the liquid ejecting head 38, liquid is discharged from the nozzle 37, and liquid in the liquid chamber 93 flows out to the fourth flow path 27d. In addition, a quantity of liquid which flows out is supplied to the liquid chamber 93 from the liquid sending unit 71.
As illustrated in
In addition, negative pressures in the liquid supply flow path 27 on the downstream side of the fourth flow path 27d, and in the liquid ejecting head 38 are increased when suctioning, using the suctioning unit 51 is continued in a state in which the liquid supply flow path 27 is closed by the flexible member 92. The buffer 73 is maintained at a state of closing the liquid supply flow path 27, since the one-way valve on ejecting side 72 is opened when the liquid sending unit 71 performs a suctioning operation in this state. In addition, when the liquid sending unit 71 sends liquid therefrom, by performing an ejecting operation after a suctioning operation, liquid flows into the liquid chamber 93 of the buffer 73 through the third flow path 27c, and the flexible member 92 is displaced in a direction of increasing the volume of the liquid chamber 93. That is, the flexible member 92 opens the liquid supply flow path 27 when the liquid sending unit 71 is driven in a state in which liquid is suctioned by the suctioning unit 51, and closes the liquid supply flow path 27.
In this manner, a closed state of the liquid supply flow path 27 is relieved, and bubbles, thickened liquid, or the like, which remains inside the liquid ejecting head 38 is discharged with great force through the nozzle 37 along with liquid send from the liquid sending unit 71. That is, so-called chock cleaning is performed, using the maintenance unit 26 and the buffer 73.
According to the above-described embodiment, it is possible to obtain the following effects.
(1) Since the liquid supply flow path 27 is closed, using the flexible member 92 as a detecting target of the displacement detecting unit 99, and which configures a part of the liquid chamber 93, it is possible to prevent a configuration of the liquid supply flow path 27 from being complicated, compared to a case of providing a configuration for closing the liquid supply flow path 27 separately.
(2) Since the guided portions 94a and 94b which are connected to the flexible member 92 are guided by the guide portions 78e and 95a in the displacing direction A of the flexible member 92, it is possible to make a displacement of the flexible member 92 stable. Accordingly, it is possible to stably close the liquid supply flow path 27 using the flexible member 92.
(3) The closing portion 92a included in the flexible member 92 closes the liquid supply flow path 27 at a position of surrounding the first guide portion 94a. That is, since it is possible to determine a position of closing the liquid supply flow path 27, it is possible to stably perform closing of the liquid supply flow path 27.
(4) It is possible to perform cleaning of the liquid ejecting head 38 using the suctioning unit 51 which suctions liquid from the liquid ejecting head 38. In addition, since it is possible to close the liquid supply flow path 27 using the suctioning, an increase in the number of components can be suppressed, compared to a case of separately providing a mechanism for closing the liquid supply flow path 27.
(5) When liquid is suctioned by the suctioning unit 51, and the liquid supply flow path 27 is closed, a negative pressure in the liquid supply flow path 27 increases. In addition, when opening the liquid supply flow path 27 by driving the liquid sending unit 71 in this state, it is possible to make liquid flow with great force.
(6) Since the flow path unit 33 includes the connection portion 32 and the engaging portion 55, it is possible to make a structure of the mounting unit 14 on which the liquid accommodating unit 21 is mounted simple. For this reason, it is possible to easily make a color of liquid which is accommodated, a quantity of liquid to be accommodated, or the like, correspond to a liquid accommodating unit 21 of a different type.
(7) Since the flow path unit 33 includes the substrate connection portion 56 connected to the circuit board 64 which is included in the liquid accommodating unit 21, it is possible to make a structure of the mounting unit 14 on which the liquid accommodating unit 21 is mounted simple. For this reason, it is possible to make a color of liquid which is accommodated, a quantity of liquid to be accommodated, or the like, correspond to a liquid accommodating unit 21 of a different type.
(8) Since bubbles in the liquid chamber 93 are discharged along with liquid when performing chock cleaning, bubbles in the liquid chamber 93 are reduced, and it is possible to improve detection accuracy of the displacement detecting unit 99. Accordingly, it is possible to improve accuracy when detecting a residual quantity in a case in which a residual quantity of liquid accommodated in the liquid accommodating unit 21 is detected, using a displacement of the flexible member 92.
The above-described embodiment can be changed like the following modification example. In addition, the above-described embodiment and the following example may be arbitrarily combined.
As illustrated in
When the pressure changing mechanism 46 is driven, each pressure changing chamber 75 enters a negative pressure state, and each liquid sending unit 71 performs a suctioning operation. Then, the one-way valve on suctioning side 70 of the first flow path unit 33F is opened, and liquid is suctioned from the liquid accommodating unit 21. Meanwhile, in the second flow path unit 33S, liquid flows into the valve chamber on suctioning side 85 through the connecting member 102, and liquid flows into the liquid sending chamber 76 while maintaining the one-way valve on suctioning side 70 at a closed state. In addition, when each liquid sending unit 71 performs an ejecting operation, liquid is supplied to the liquid ejecting head 38 through the one-way valve on ejecting side 72 and the buffer 73, from each liquid sending chamber 76 of the first flow path unit 33F and the second flow path unit 33S.
For example, in a liquid ejecting apparatus which performs printing of a single color using a single color (for example, black), a consumption speed of liquid of one color becomes high compared to a liquid ejecting apparatus which performs color printing using a plurality of colors. In this point, a speed of supplying liquid to the liquid ejecting head 38 is increased, and it is possible to suppress a decrease in throughput, by supplying liquid of one type to the liquid ejecting head 38 using a plurality of flow path units 33 in this manner.
The flow path unit 33 may not include the substrate connection portion 56. For example, the substrate connection portion 56 may be provided in the mounting unit 14. In addition, the liquid accommodating unit 21 may not include the circuit board 64.
The flow path unit 33 may not include the connection portion 32. For example, the connection portion 32 may be provided in the mounting unit 14. In addition, the connection portion 32 and the flow path unit 33 may be connected.
The flow path unit 33 may not include the engaging portion 55. For example, the engaging portion 55 may be provided in the mounting unit 14. In addition, a configuration of the engaging portion 55 may be arbitrarily changed. For example, the engaging portion 55 is set to an elastic member like a plate spring which has elasticity, and may be engaged with the liquid accommodating unit 21 in a case in which the liquid accommodating unit 21 is mounted on the mounting unit 14.
The liquid ejecting apparatus 11 may not be provided with the suctioning unit 51. In addition, the liquid sending unit 71 may send liquid to the liquid ejecting head 38 by pressurizing the liquid accommodated in the liquid accommodating unit 21. For example, pressurizing cleaning in which liquid is supplied from the liquid sending unit 71, and the liquid is discharged from the liquid ejecting head 38 may be performed.
In the suctioning cleaning performed by the maintenance unit 26, a suctioning operation and an ejecting operation may be performed, by driving the liquid sending unit 71 after stopping suctioning, using the suctioning unit 51. In addition, a configuration may be adopted, in which the suctioning unit 51 is caused to suction liquid in a state in which the pressure changing chamber 75 is set to a negative pressure state by driving the supply mechanism 28.
The flow path unit 33 may have a configuration in which the first guide portion 78e and the first guided portion 94a, and second guide portion 95a and the second guided portion 94b are not provided, and may have a configuration of being provided with any one thereof. In addition, the guide portions 78e and 95a may be arbitrarily changed when it is possible to guide the guided portions 94a and 94b in the displacing direction A. For example, a guided portion which is guided with respect to a rail-shaped guide portion may be provided in the flexible member 92.
The closing portion 92a may be provided at a position different from a position of surrounding the first guided portion 94a. The closing portion 92a may not protrude from the flexible member 92. In addition, a configuration may be adopted, in which an annular protrusion portion is formed at a position surrounding the first guide portion 78e of the recessed portion 78d for buffer, and the liquid supply flow path 27 is closed by causing the flexible member 92 to come into contact with the annular protrusion portion.
A configuration in which, in the liquid accommodating unit 21, the container 13 and the liquid accommodating body 20 are integrally formed, and the liquid accommodating unit is a cartridge which is exchanged when accommodated liquid is consumed may be adopted.
Liquid ejected from a liquid ejecting unit is not limited to ink, and may be a liquid body obtained by dispersing or mixing particles of a functional material in liquid, for example. For example, a configuration may be adopted, in which a liquid body including a material such as an electrode material which is used when manufacturing a liquid crystal display, an electroluminescence (EL) display, and a surface light emission display, or a coloring material (pixel material) in a form of dispersion or dissolution is ejected, and recording is performed.
The medium S is not limited to a sheet, may be a plastic film, a thin plate material, or the like, and may be cloth which is used in a textile printing apparatus, or the like. The medium S may be a cut sheet which is cut into a predetermined size, may be a roll-shaped medium which is wound in a cylindrical shape, for example, may be a cloth in an arbitrary shape, or the like, such as T-shirts, and may be a three-dimensional object formed in an arbitrary shape such as tableware, or stationery.
The entire disclosure of Japanese Patent Application No. 2016-167224, filed Aug. 29, 2016 is expressly incorporated by reference herein.
Number | Date | Country | Kind |
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2016-167224 | Aug 2016 | JP | national |
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2005-096152 | Apr 2005 | JP |
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20180056652 A1 | Mar 2018 | US |