JP6036973B2 - Liquid ejector - Google Patents

Description

  The present invention relates to a liquid ejecting apparatus, and more particularly to a configuration of a liquid flow path for supplying a liquid to a liquid ejecting head.

  In general, inkjet printers are widely known as a type of liquid ejecting apparatus that ejects liquid onto a medium. This printer performs printing by ejecting ink (liquid) supplied from an ink cartridge (liquid supply source) to a medium (for example, paper) from an ejection nozzle formed in a liquid ejection head. In such a printer, pigment ink may be used in recent years in order to realize high-quality printing.

  The pigment ink has a problem that, as time passes, pigment particles settle in the ink solvent, and the density of the pigment ink is biased to change its color. In particular, when the liquid flow path from the ink cartridge to the liquid ejecting head is long, the pigment particles tend to settle in the liquid flow path. Accordingly, even if the ink stirred from the ink cartridge is supplied to the liquid flow path, the color tone of the pigment ink is not corrected unless the deviation in the concentration of the pigment ink is suppressed in the liquid flow path between the ink cartridge and the liquid ejecting head. It becomes difficult to suppress changes in

  Therefore, for example, Patent Document 1 proposes a technique for stirring ink in a liquid flow path. This technology uses a tube pump that rotates while a roller crushes a flexible tube to cause pressure fluctuations in a circulation flow path that forms part of the liquid flow path, thereby causing ink flow in the liquid flow path. This is a technique for causing ink to stir.

Japanese Unexamined Patent Publication No. 2011-255543

  By the way, in the printer, a check valve is usually provided between the liquid supply source and the circulation flow path so that the ink does not flow backward from the liquid flow path side to the liquid supply source side. For this reason, when the ink in the circulation channel is caused to flow using the pressure fluctuation repeatedly generated by the tube pump as disclosed in Patent Document 1, when the pressure inside the circulation channel is reduced due to the pressure fluctuation, Then, a phenomenon occurs in which the ink flows from the liquid supply source side into the circulation channel through the check valve.

  Therefore, when the tube pump is driven for a long time, the ink flowing from the liquid container into the circulation channel gradually increases in the circulation channel due to the repeatedly generated decompression state, and the pressure of the ink in the circulation channel increases. It will be. As a result, when the circulation channel (liquid channel) is formed by connecting a plurality of tubes, the connection between the tubes may be disconnected or the tubes may be ruptured.

  Such a situation is not limited to an ink jet printer, but is a liquid ejecting device that supplies liquid to an ejecting mechanism from a liquid supply source side through a liquid channel provided with a check valve, and ejects the liquid through the ejecting mechanism. The devices are generally common.

  The present invention has been made in view of the above circumstances, and a main object thereof is to realize a liquid ejecting apparatus that can suppress an increase in pressure in a circulation flow path accompanying a pump operation.

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 liquid, and a first liquid that is supplied from the upstream side that is the liquid supply source side to the liquid ejecting head that is downstream. A downstream connection in which one end is connected to the upstream connecting portion of the first liquid passage and the other end is on the liquid ejecting head side from the upstream connecting portion of the first liquid passage. A first connection channel that forms an annular channel that is connected to the first liquid channel and the liquid flows between the first liquid channel and a second connection stream that is connected to both ends of the annular channel. A flow pump provided in the channel, the second connection flow channel, and capable of flowing the liquid in the annular flow channel by operation; and a liquid provided to store the liquid in the annular flow channel A storage portion that responds to pressure fluctuations in the annular flow path and A liquid storage part which the product is changed, the備Ru.

According to this configuration, it is possible to suppress the pressure change of the liquid that pulsates in the annular flow path during the operation of the flow pump.

In the liquid ejecting apparatus according to the aspect of the invention, the flow pump operates in a direction in which the liquid in the annular flow path flows from the liquid ejecting head side to the liquid supply source side in the first liquid flow path.

According to this configuration, the liquid can be reliably returned to the upstream side, which is the liquid supply source side, by the flow pump, so that an increase in the pressure of the liquid in the annular channel can be suppressed with a high probability.

In the liquid ejecting apparatus according to the aspect of the invention, the liquid in the first connection flow path may flow from the upstream connection portion into the first liquid flow path and flow toward the liquid supply source side. A check valve is further provided to allow and prevent the liquid in the annular flow path from flowing toward the liquid supply source in the first liquid flow path .

According to this configuration, the liquid can be reliably returned to the upstream side, which is the liquid supply source side, via the first connection flow path, so that the increase in the pressure of the liquid in the annular flow path is suppressed with a high probability. Can do.

In the liquid ejecting apparatus according to the aspect of the invention, the flow pump may be a diaphragm pump having a diaphragm.

According to this configuration, the liquid can flow in the annular flow path.

1 is a schematic configuration diagram of a printer that is an embodiment of a liquid ejecting apparatus according to the invention. FIG. The schematic diagram which shows the structure of the liquid flow path in which the circulation flow path and the return flow path were provided in the printer of this embodiment. FIG. 5 is a schematic diagram showing the ink circulation operation in a circulation channel not provided with a return channel, where (a) shows a state in which ink circulates in the circulation channel by pressurization by a tube pump, and (b) shows a tube. The figure which shows the state into which an ink flows in in a circulation flow path by pressure reduction by a pump. FIG. 5 is a schematic diagram showing the circulation operation of ink in a circulation channel provided with a return channel, where (a) shows a state in which ink circulates in the circulation channel by pressurization by a tube pump, and (b) shows a tube pump. The figure which shows the state into which an ink flows in in a circulation flow path by pressure reduction by. (A) is a graph showing the difference in pressure variation of the ink in the circulation flow path depending on the presence or absence of the return flow path, and (b) is a comparison table showing the difference in the ink flow mode depending on the presence or absence of the return flow path as a ratio. The schematic diagram which shows the modification of the liquid flow path provided with two or more return flow paths. FIG. 3 is a schematic diagram illustrating an example of a liquid channel in which a liquid storage unit is provided in a channel region of ink.

  Hereinafter, an embodiment in which a liquid ejecting apparatus according to the present invention is embodied in an ink jet printer (hereinafter also abbreviated as “printer”) will be described with reference to the drawings. The printer of this embodiment forms an image including characters and figures by ejecting liquid supplied from a liquid supply source from a liquid ejecting head to a medium conveyed in one direction.

  As shown in FIG. 1, a sheet S which is an example of a medium along the longitudinal direction X is formed in a lower portion on the gravity direction side in a frame 12 having a substantially rectangular box shape in a printer 11 as an example of a liquid ejecting apparatus. A support member 13 is extended to support the image during image formation, that is, during printing. Then, a paper feed mechanism (not shown) is driven based on the drive of a paper feed motor (not shown) provided in the lower part of the rear of the frame 12 in the direction opposite to the conveyance direction Y of the paper S. The mechanism is transported on the support member 13 in the short direction (front direction) of the support member 13.

  The cartridge holder 14 disposed on one end side in the longitudinal direction X of the frame 12 (right end side when viewed from the front side in the transport direction Y in this embodiment) stores liquid as an example of liquid. A plurality (four in this case) of ink cartridges 15 as an example of a body are detachably mounted as liquid supply sources. In the present embodiment, each ink cartridge 15 contains different colors of ink and is mounted on the cartridge holder 14. Each ink cartridge 15 contains pigment ink.

  A guide shaft 19 extending along the longitudinal direction X is installed in the frame 12, and a carriage 20 is slidably supported on the guide shaft 19. The carriage 20 is fixed to a part of an endless timing belt 17 that is rotationally driven by a carriage motor 16 provided on the upstream side (rear side) in the conveyance direction of the frame 12. Accordingly, the carriage 20 is reciprocated along the guide shaft 19 with the longitudinal direction X as the scanning direction by driving the timing belt 17 by driving the carriage motor 16. Further, the carriage 20 is provided with a liquid ejecting head 21 provided with a plurality of ejecting nozzles (not shown) for ejecting ink on the lower surface side, and the ink is supplied to the liquid ejecting head 21 corresponding to each ink cartridge 15. A plurality (four in this case) of valve units 25 for controlling the supply are mounted.

  One end side (in the present embodiment, the right end side as viewed in the conveyance direction) in the movement range along the scanning direction of the carriage 20 in the frame 12 is a non-medium ejection area other than the medium ejection area, and the home position HP is in this area. Is provided. A maintenance device 22 for performing various maintenance processes on the liquid ejecting head 21 is disposed at the home position HP.

  The maintenance device 22 raises a cap (not shown) from below to come into contact with the liquid jet head 21 moved to the home position HP, and the closed space formed by the contact is brought into a negative pressure state by a suction pump (not shown). Thus, ink is sucked from the ejection nozzle. Alternatively, ink is forcibly ejected from the ejection nozzle of the liquid ejection head 21 that has moved to the home position HP, and the ejected ink is received. By doing so, the maintenance device 22 discharges, for example, thickened ink from the ejection nozzle, and performs maintenance for stabilizing the ejection operation of the ink from the ejection nozzle.

  In the present embodiment, an ink supply tube having one end connected to the ink cartridge 15 serving as a liquid supply source and the other end connected to the liquid ejecting head 21 via a valve unit 25 located on the downstream side of the ink cartridge 15. 31 is provided as a first liquid flow path. Accordingly, the ink is supplied from each ink cartridge 15 to the liquid ejecting head 21 by each ink supply tube 31.

  The valve unit 25 is a so-called self-sealing valve that opens when ink is ejected from the ejection nozzle and the ink pressure drops and supplies ink from the upstream side to the liquid ejection head 21 (ejection nozzle). A functioning pressure control valve 24 is provided. The ink supply tube 31 is connected to the upstream side of the pressure control valve 24.

  Further, the ink supply tube 31 is provided with a check valve 23 provided with an on-off valve 23 a on the upstream side of the pressure control valve 24. The on-off valve 23a opens when the ink flows from the upstream ink cartridge 15 side to the downstream pressure control valve 24 side, while the on-off valve 23a opens from the downstream pressure control valve 24 side to the upstream ink cartridge 15 side. When ink is going to flow toward the head, the valve is closed to block the flow.

  Further, although illustrated as a block in FIG. 1, the ink supply tube 31 is provided with a second liquid channel whose both ends are connected to the ink supply tube 31. A circulation flow path JF is formed with the supply tube 31. Further, a return flow path KF is formed by a third liquid flow path connected to one end of the circulation flow path JF and the other end to the ink supply tube 31.

  The circulation flow path JF and the return flow path KF will be described with reference to FIG. In the present embodiment, each circulation channel JF and return channel KF have the same configuration for each ink cartridge 15. Therefore, here, as a representative, one circulation flow path JF and return flow path KF will be described. For this reason, in FIG. 2, one circulation flow path JF and the return flow path KF are schematically illustrated including other components. Further, in FIG. 2, each component constituting the circulation flow path JF and the return flow path KF is illustrated as a continuous member, but in reality, it is formed by a plurality of members connected to each other.

  As shown in FIG. 2, the circulation flow path JF includes an ink circulation tube 32 as a second liquid flow path whose both ends are connected to the ink supply tube 31 by connection portions C1 and C2. Ink is circulated between the tube 32 and the ink supply tube 31. The ink circulation tube 32 is provided with a tube pump 40 as a circulation pump that performs a pump operation for causing ink to flow in one direction in the circulation flow path JF.

  The tube pump 40 is configured so that a flexible tube (here, a part of the ink circulation tube 32) is unidirectionally rotated by a drive source in a curved portion 32R formed in an arc shape. The roller 42 is squeezed by a roller 42 that is movably provided on the rotating body 41 as it rotates. The roller 42 rotates (revolves) while maintaining this crushing state, thereby pushing the ink in the rotation direction, thereby causing the ink to flow in one direction in the circulation flow path JF. That is, when the roller 42 rotates in the direction indicated by the arrow R in FIG. 2 and enters the bending portion 32R, the roller 42 moves along the guide hole 43 away from the rotation center of the rotating body 41 and moves to the ink circulation tube 32. Crush. By this crushing, the ink in the ink circulation tube 32 is in a pressurized state. The roller 42 rotates (revolves) along the curved portion 32 </ b> R together with the rotating body 41 while crushing the ink circulation tube 32, so that the ink in the ink circulation tube 32 is pressurized and the rotation direction of the roller 42. To flow in one direction in the circulation channel JF.

  Thereafter, when the roller 42 rotates (revolves) and leaves the curved portion 32 </ b> R of the ink circulation tube 32, the ink circulation tube 32 causes the guide hole 43 to be pressed by the reaction force that resists crushing of the roller 42 that has been crushed. And move toward the center of rotation. As a result, since the collapsed tube shape of the ink circulation tube 32 quickly returns to the original tube shape, the ink in the ink circulation tube 32 is decompressed by the return of the tube shape. As described above, the tube pump 40 is a circulation pump that causes pressure fluctuation (pulsation) between the pressurized state and the decompressed state for the ink in the ink circulation tube 32 during operation.

  The return flow path KF has a third liquid flow connected at one end of the flow path portion of the ink circulation tube 32 located on one side of the tube pump 40 by which the ink flows through the pump operation. An ink return tube 33 is provided as a path. Further, when ink flows from the check valve 23 side to the downstream connection portion C1 side between the check valve 23 and the connection portion C1 in the ink supply tube 31, the valve is opened and the connection portion C1 side to the upstream side. When the ink flows to the check valve 23 side, a check valve 27 provided with an open / close valve 27a is provided. The other end of the ink return tube 33 is located on the upstream side of the ink cartridge 15 with respect to the check valve 27 and on the downstream side of the check valve 23 with respect to the flow path portion of the ink supply tube 31. Are connected by a connecting portion C4. As a result, the return flow path KF causes the ink return tube 33 to return ink from the circulation flow path JF to the ink cartridge 15 (upstream side) as the liquid supply source rather than the check valve 27.

  Next, the ink stirring action in the printer 11 of the present embodiment in which the circulation flow path JF and the return flow path KF are provided with respect to the ink supply tube 31 will be described. Before that, in order to facilitate understanding of the stirring action of the present embodiment, the ink stirring action in the printer 11 provided with only the circulation flow path JF without the return flow path KF as a comparative example is shown in FIG. ) And (b) will be described first.

  As shown in FIG. 3A, in the tube pump 40, when the roller 42 enters the curved portion 32R of the ink circulation tube 32 and rotates while crushing the ink circulation tube 32, the roller 42 is pushed out of the curved portion 32R. The ink is pressurized in the ink circulation tube 32 and flows in the direction indicated by the solid line arrow Fa in the figure. As a result, between the connecting portions C1 and C2 in the ink supply tube 31 constituting the circulation flow path JF with the ink circulation tube 32, the flow direction of the ink flowing when supplying ink to the liquid ejecting head 21 is opposite. Ink flows in the direction, that is, from the downstream side toward the upstream side.

  At this time, the pressure of the ink on the downstream side of the check valve 23 is increased by the ink flowing through the ink supply tube 31 from the downstream side to the upstream side by the operation of the tube pump 40. Therefore, as shown by the white arrow Fp in the drawing. Pressure to the check valve 23 side is generated. For this reason, the on-off valve 23a is closed to prevent ink from flowing from the ink cartridge 15 side to the circulation flow path JF side. Further, since the flow path is closed to the liquid ejecting head 21 side by the pressure control valve 24, the ink does not flow to the liquid ejecting head 21 side even if the ink pressure rises in the ink supply tube 31. .

  Next, as shown in FIG. 3B, when the roller 42 further rotates (revolves) in the tube pump 40 and separates from the curved portion 32 </ b> R of the ink circulation tube 32, the ink circulation tube that has been crushed by the roller 42. By returning 32 to the original tube shape, the ink is decompressed in the curved portion 32R. For this reason, ink flows in the direction from the connecting portion C2 toward the curved portion 32R as indicated by the broken line arrow Fb in the figure in the circulation flow path JF. At this time, the ink flowing from the connecting portion C1 along the ink circulation tube 32 toward the curved portion 32R is maintained in the substantially same direction although the flow velocity is changed.

  As a result, also in the ink supply tube 31, as in the ink circulation tube 32, an ink flow from the connection portion C <b> 1 to the connection portion C <b> 2 occurs as shown by a broken line arrow Fb in the drawing, The pressure downstream of the check valve 23 is reduced in order to draw the ink to be drawn. As a result, as indicated by a broken line arrow Fs in the figure, ink flows from the ink cartridge 15 to the circulation flow path JF via the check valve 23. On the other hand, since the ink flow path is closed by the pressure control valve 24 from the liquid ejecting head 21 side, even if the ink pressure in the ink supply tube 31 drops and the pressure is reduced, the ink is ejected from the liquid ejecting head 21 side. Does not flow (backflow). As a result, a predetermined amount of ink flows from the ink cartridge 15 to the downstream side via the check valve 23, and the ink flow path between the check valve 23 and the pressure control valve 24, that is, the ink supply tube 31 and the circulation flow. Accumulated in Road JF.

  Therefore, when the tube pump 40 is operated and the ink is continuously stirred, the ink cartridge 15 passes through the check valve 23 every time the pressure variation of the ink accompanying the operation of the tube pump 40 occurs. A phenomenon in which a predetermined amount of ink flows downstream is caused. That is, the ink circulation flow state shown in FIG. 3A and the ink inflow state from the ink cartridge 15 side shown in FIG. 3B repeatedly occur. Therefore, in the ink flow path between the check valve 23 and the pressure control valve 24, the ink flowing from the ink cartridge 15 side is gradually accumulated and increased, and the pressure of the ink in the circulation flow path JF increases. It will follow. As a result, as described above, for example, when the circulation flow path JF is formed by connecting a plurality of flow path members, the connection between the flow path members is disconnected or the flow path member itself is ruptured. Will end up.

  Therefore, in the present embodiment, by providing the return flow path KF in addition to the circulation flow path JF, an increase in the pressure of the ink in the circulation flow path JF that occurs during the ink stirring operation is suppressed. Hereinafter, the ink stirring action in the printer 11 of the present embodiment will be described with reference to FIGS.

  As shown in FIG. 4A, in the tube pump 40, in the operation state of the pump in which the roller 42 rotates while crushing the curved portion 32R of the ink circulation tube 32, as shown by the solid line arrow Fa in the drawing, the curved portion 32R. The ink that has been pressurized and pushed out from the ink flows in the circulation flow path JF in one direction and circulates and flows. That is, the ink flowing through the ink circulation tube 32 flows toward the connection portion C <b> 2 and flows into the downstream side of the ink supply tube 31.

  At this time, a part of the ink flowing through the ink circulation tube 32 flows from the connection portion C3 to the ink return tube 33. For this reason, the amount of ink flowing in the ink supply tube 31 from the downstream connection portion C2 toward the upstream connection portion C1 flows to the ink return tube 33 at the connection portion C3 and is pushed out at the curved portion 32R. The amount of ink that flows to the ink return tube 33 is less than the amount of ink that is discharged.

  A portion of the ink that has flowed from the ink circulation tube 32 into the ink return tube 33 via the connection portion C3 flows to the connection portion C4 side as indicated by the solid line arrow Fk in the drawing, and is downstream of the check valve 23. And flows into the flow path portion of the ink supply tube 31 positioned upstream of the check valve 27. As a result, in the ink supply tube 31, the ink pressure on the upstream side of the check valve 27 is increased by the ink flowing from the ink return tube 33 through the connection portion C <b> 4. On the other hand, on the downstream side of the check valve 27, the ink pressure increases due to the ink flowing through the ink supply tube 31 from the downstream side toward the upstream side. Accordingly, the check valve 27 increases the ink pressure on both the upstream side and the downstream side.

  At this time, when the pressure of the ink on the upstream side of the check valve 27 is larger than the pressure of the ink on the downstream side, the on-off valve 27a is opened as shown by a two-dot chain line in FIG. Thus, ink flows from the connection portion C4 side toward the connection portion C1 side, and flows into the circulation flow path JF. This ink flow raises the pressure of the ink downstream of the check valve 27 and merges with the ink flowing from the downstream side with respect to the connection portion C1 in the ink supply tube 31, and from the connection portion C1 to the ink circulation tube. 32 flows toward the curved portion 32R. When the pressure on the downstream side and the pressure on the upstream side of the check valve 27 are substantially the same or the pressure on the downstream side is large, the on-off valve 27a of the check valve 27 is closed as shown by the solid line in the figure. Then, the flow of ink from the connection portion C4 side toward the connection portion C1 side is stopped.

  As a result, the ink stays in a pressurized state in the ink return tube 33 and the ink supply tube 31 between the check valve 23 and the check valve 27. Therefore, in the circulation flow path JF between the ink circulation tube 32 and the ink supply tube 31, the ink does not flow from the ink return tube 33 through the check valve 27, and a certain amount is obtained by the operation of the tube pump 40. Ink circulates.

  In this way, in a state where the ink circulates through the circulation flow path JF in a constant amount, the ink located on the connection portion C4 side, which is the downstream side of the check valve 23, is pushed out by the tube pump 40 via the ink feedback tube 33. The pressurized state is maintained by the ink. For this reason, the on-off valve 23a is pressurized as shown by the white arrow Fp in the figure, the check valve 23 is closed, and the ink flow between the check valve 23 and the pressure control valve 24 from the ink cartridge 15 side. The inflow of ink into the path, that is, the inflow of ink into the return flow path KF and the circulation flow path JF is substantially prevented.

  Next, as shown in FIG. 4B, in the state where the roller 42 further rotates in the tube pump 40 and is detached from the curved portion 32 </ b> R of the ink circulation tube 32, the ink circulation tube 32 that has been crushed by the roller 42. The ink is decompressed by returning to the original shape. For this reason, in the circulation flow path JF, the ink flows in the direction from the connecting portion C2 and the connecting portion C3 toward the curved portion 32R as indicated by the broken line arrow Fb in the drawing. Note that the ink flowing from the connecting portion C1 side toward the curved portion 32R along the ink circulation tube 32 is maintained in the same direction although the flow velocity is changed.

  As a result, as in the comparative example, in the ink supply tube 31, an ink flow from the connection portion C <b> 1 side to the connection portion C <b> 2 side occurs, and this ink flow also draws ink downstream from the check valve 27. Therefore, the pressure on the downstream side of the check valve 27 is reduced (decompressed) to open the on-off valve 27a.

  At this time, in the present embodiment, unlike the comparative example, in the ink return tube 33, as shown by the arrow Fr in the figure, the connection in which the pressure is reduced from the connection portion C4 side where the ink is maintained in the pressure state. Ink flows toward the portion C3. Therefore, in the ink supply tube 31, since the ink flows from the ink return tube 33 to the ink circulation tube 32 through the connection portion C3, the amount of ink flowing from the connection portion C1 side to the connection portion C2 side is the comparative example. It is suppressed to a small amount compared to. As a result, the amount of ink flowing into the circulation channel from the connection portion C4 via the check valve 27 is similarly suppressed as compared with the comparative example.

  Further, in the present embodiment, the ink flowing to the connection portion C1 side via the connection portion C3 or the check valve 27 is the ink feedback tube 33 and the ink supply tube 31 between the check valve 23 and the check valve 27. In this case, the ink is returned from the circulation flow path JF side and retained in a pressurized state. For this reason, the ink pressure drop (negative pressure) on the downstream side of the check valve 23 is suppressed as compared with the comparative example. As a result, the on-off valve 23a is opened as shown by a two-dot chain line in the drawing, and flows from the ink cartridge 15 side to the connecting portion C4 side through the check valve 23 as shown by a broken line arrow Fs in the drawing. The inflow amount of ink is suppressed to be smaller than that of the comparative example. The ink that has flowed from the ink cartridge 15 side to the connection portion C4 side is included in the ink that has been returned from the circulation flow path JF side and retained in a pressurized state, and passes through the check valve 27 to reach the circulation flow path JF. In some cases.

  In the present embodiment, the ink stirring operation is continuously performed, so that the roller 42 shown in FIG. 4A enters the curved portion 32R of the ink circulation tube 32 and the state shown in FIG. The operation state in which the illustrated roller 42 is detached from the curved portion 32R of the ink circulation tube 32 is repeated. Each time these operating states are repeated, the amount of ink flowing from the ink cartridge 15 into the return flow path KF (circulation flow path JF) via the check valve 23 is suppressed as compared with the comparative example. As a result, an increase in ink pressure in the circulation flow path JF is suppressed, and an increase amount of ink accumulated from the ink cartridge 15 via the check valve 23 into the return flow path KF (circulation flow path JF) is accumulated. However, it is suppressed compared with the comparative example which is not provided with the return flow path KF.

An example of the result of this suppression action will be described with reference to FIGS. 5 (a) and 5 (b).
As shown in FIG. 5A, the pressure of the ink in the circulation flow path JF on the outlet side of the tube pump 40 where the ink is pushed out by the operation of the tube pump 40 is provided with a feedback flow path indicated by a broken line in the figure. Compared with the value in the comparative example which is not, the value in this embodiment in which the return flow path shown by the solid line in the figure is provided is reduced to half or less. In addition, the residual pressure in the circulation flow path JF at the time when the ink stirring operation is completed is considerably smaller in the present embodiment than in the comparative example.

  The ink pressure (negative pressure) downstream of the check valve 23 and upstream of the check valve 27 (ink cartridge 15 side) is not provided with the feedback flow path KF indicated by the broken line in the figure. Compared with the value in the comparative example, the value in the present embodiment in which the return flow path KF indicated by the solid line in the drawing is provided is considerably smaller particularly at the time of starting the ink stirring operation. From this, it can be seen that the ink flowing from the ink cartridge 15 through the check valve 23 is suppressed by providing the return flow path KF.

  Incidentally, FIG. 5B shows a table comparing the results of the ink stirring operation according to the present embodiment with the comparative example being 100%. As shown in FIG. 5B, in this embodiment, compared with the comparative example, the pressure on the outlet side of the tube pump 40 is 44%, the maximum negative pressure on the ink cartridge 15 side is 36%, and the ink cartridge The amount of inflow ink from 15 is suppressed to 22.5%.

According to the embodiment described above, the following effects can be obtained.
(1) Even when the ink flows into the circulation flow path JF from the upstream side, which is the ink cartridge 15 side, via the check valve 27 during the operation of the tube pump 40, the ink that flows in at that time remains in the ink feedback tube 33. Thus, the ink containing the ink returned from the circulation flow path JF to the upstream side of the check valve 27 is obtained. Therefore, compared to the case where there is no ink return tube 33, an increase in ink in the circulation flow path JF is suppressed, and an increase in the pressure of ink in the circulation flow path JF can be suppressed.

  (2) Since the ink return tube 33 is connected to a flow path portion that is unidirectional with respect to the tube pump 40 in the ink circulation tube 32, the ink that is pressurized and flows in one direction by the tube pump 40. Thus, the ink can be reliably returned to the upstream side, which is the ink cartridge 15 side, via the ink return tube 33. Therefore, an increase in the pressure of the ink in the circulation channel JF can be suppressed with a high probability.

The above embodiment may be changed to another embodiment as described below.
In the above embodiment, the return flow path KF is further provided with an ink flow path (fourth liquid flow path) for returning ink from the circulation flow path JF to the ink cartridge 15 side in addition to the ink return tube 33. Also good. This modification will be described with reference to FIG.

  As shown in FIG. 6, in this modification, when the check valve 27 is the first check valve, the ink supply tube 31 is connected to the other end of the ink flow path of the ink return tube 33. A check valve 28 as a second check valve is provided on the upstream side which is the ink cartridge 15 side further than the connection portion C4 which is a part. One end is connected to the ink return tube 33 by the connection portion C5, and the other end is located upstream of the check valve 28 in the ink supply tube 31 on the ink cartridge 15 side and downstream of the check valve 23. An ink return sub-tube 34 is provided as a fourth liquid flow path connected to the path portion by the connection portion C6.

  As described above, by providing the ink feedback sub-tube 34, a part of the ink that is pressurized and pushed out of the curved portion 32 </ b> R by the operation of the tube pump 40 and flows through the ink circulation tube 32 is connected to the connection portion. The ink flows from C3 to the ink return tube 33 and the ink return subtube 34. For this reason, the amount of ink flowing in the ink supply tube 31 from the downstream connecting portion C2 toward the upstream connecting portion C1 is further smaller than the amount of ink flowing in the embodiment. Therefore, the amount of ink flowing from the upstream side of the check valve 27 to the downstream circulation flow path JF via the check valve 27 increases.

  At this time, in the present modification, ink in a pressurized state flows from the ink feedback tube 33 into the circulation flow path JF and pressurizes from the ink feedback subtube 34 via the check valve 28 as in the above embodiment. The ink in a state flows into the downstream connection portion C4 side. Therefore, the ink flowing into the circulation flow path JF via the check valve 27 can be ink returned from the circulation flow path JF side to the upstream side of the check valve 27 by the return flow path KF.

  Further, the ink flowing from the ink circulation tube 32 to the ink return tube 33 via the connection portion C3 and the ink flowing from the ink circulation tube 32 to the ink feedback subtube 34 via the connection portion C5 are the respective ink flow paths. In a pressurized state. Accordingly, when the pressure of the ink drops from the upstream side downstream of the check valve 27 due to the pressure reduction of the ink generated next in the curved portion 32R, the ink circulates from the upstream side of the check valve 27 via the check valve 27. Ink flows into the flow path JF.

  In this case, in this modification, in addition to the pressurized ink that has flowed from the ink return tube 33 through the connection portion C4 to the upstream side of the check valve 27, the upstream side of the check valve 28, that is, the connection portion. Also from the C6 side, the pressurized ink that has flowed in from the ink return subtube 34 flows through the check valve 28. As a result, the amount of ink flowing from the ink cartridge 15 to the connection portion C6 side, that is, the return flow path KF side through the check valve 23 is suppressed to be small.

According to this modification, in addition to the effects (1) and (2) of the above embodiment, the following effects can be obtained.
(3) Since the ink return subtube 34 is further provided, even if the ink flowing into the circulation flow path JF from the upstream side via the check valve 27 increases, the ink flowing back from the circulation flow path JF side is returned to the ink flow. In addition to the tube 33, the ink can be returned to the upstream side of the check valve 27 by the ink return subtube 34. Therefore, an increase in ink in the circulation flow path JF can be suppressed.

  In this modification, the ink return sub-tube 34 is supplied with ink between the connecting portions C1 and C2 in the circulation flow path JF as shown by a two-dot chain line in FIG. It is good also as the ink return subtube 34A connected with the connection part C7 with respect to the flow-path part of the tube 31. FIG.

  In the above embodiment, one end of the ink return tube 33 is connected to the outlet side of the tube pump 40 in the ink circulation tube 32 by the connecting portion C3. However, the present invention is not limited to this. One end of the ink return tube 33 may be connected to the inlet side of the tube pump 40 in the ink circulation tube 32, that is, the connection portion C1 side. Alternatively, as indicated by a broken line in FIG. 6, one end of the ink return tube 33 is connected to the flow path portion of the ink supply tube 31 between the connection sections C1 and C2 in the circulation flow path JF by the connection section C7. The ink return tube 33A may be used.

Furthermore, when the third liquid flow path is the ink return tube 33A, the fourth liquid flow path may be the ink return subtube 34 in the above modification.
In the above embodiment, at least the ink supply tube 31 and the ink circulation tube 32 between the check valve 23 and the pressure control valve 24 are temporarily stored in a state where the ink is pressurized. The liquid storage part 50 to be performed may be provided. This modification will be described with reference to FIG.

  As shown in FIG. 7, in the present modification, a liquid reservoir 50 that stores ink in a pressurized state is provided in a flow path portion between the check valve 27 and the connection portion C <b> 1 in the ink supply tube 31. Yes. The liquid storage section 50 includes a container body 51 formed with a communication section 55 that communicates the ink supply tube 31 and the ink flow path, and a displacement plate 53 that is displaced so as to change the volume in the container body 51. have. In this modification, the displacement plate 53 is formed of a flat plate member, and moves away from the communication portion 55 side with the ink circulation tube 32 while closely contacting the periphery of the inner wall 51a of the container body 51. The internal volume of the container body 51 is increased, and the amount of ink that can be stored in the liquid storage unit 50 is increased.

  Further, the displacement plate 53 is urged so as to move in a direction in which the internal volume is changed to be small by a pressurizing unit 54 formed of, for example, a coil spring. Therefore, when the displacement plate 53 moves against the urging force of the pressurizing unit 54, the liquid can be temporarily stored in the liquid storage unit 50 while being pressurized by the pressurizing unit 54. Increase fluid volume. In this modification, the inner wall 51a of the container body 51 is formed with a protrusion 52 that protrudes in a bowl shape toward the center so as to engage with the displacement plate 53 when viewed from above. However, the state in which the movement of the pressurizing unit 54 in the urging direction is restricted by the protrusion 52 is a state in which the amount of liquid stored in the liquid storage unit 50 is zero.

  In this displacement, the displacement plate 53 is pressurized in the direction opposite to the direction in which the internal volume is increased by the pressure unit 54, and thus is displaced in a state where the ink is pressurized. In other words, the pressurizing force of the pressurizing unit 54 in the liquid storage unit 50 is set to a pressure lower than the pressurizing force generated in the tube pump 40. Accordingly, although explanation is omitted here, a change in pressure (pulsation) of the ink in the circulation flow path JF generated in accordance with the operation of the tube pump 40 in the ink agitation operation causes the ink to flow into the liquid reservoir 50. It is suppressed by causing ink to flow out of the liquid storage section 50. That is, when the displacement plate 53 is displaced in the liquid storage unit 50, the ink flowing through the ink supply tube 31 is caused to flow in and out, and the pressure fluctuation is suppressed.

According to this modification, in addition to the effects (1) and (2) of the above embodiment, the following effects can be obtained.
(4) Since the liquid storage section 50 that temporarily stores the ink in a pressurized state is provided, the ink flowing from the ink cartridge 15 side to the circulation flow path JF side via the check valve 23 Even if it increases, since the increased ink is temporarily stored in the liquid storage part 50, the pressure change of the ink pulsating in the circulation flow path JF can be suppressed.

  In the above modification, the liquid storage unit 50 may be formed of a diaphragm in which the periphery of the displacement plate 53 is hermetically fixed. In this case, the diaphragm may be directly pressurized using air as a medium as the pressurizing unit 54 or may be pressurized via a pressure plate.

  In the above embodiment, the tube pump 40 may cause the ink to flow in the circulation flow path JF in the same direction as the flow direction of the ink flowing through the ink supply tube 31 when supplying the ink to the liquid ejecting head 21. Good.

  In the above embodiment, the circulation pump is not necessarily limited to the tube pump 40. For example, a diaphragm pump using a diaphragm and two check valves may be a circulation pump. Also in the diaphragm pump, when the diaphragm reciprocates (vibrates), the ink pulsates, so that the ink flowing in the diaphragm pump pulsates. This pulsation causes ink pressure fluctuations in the circulation flow path JF as in the tube pump.

  In the above embodiment, the number of ink cartridges 15 is not limited to four, and may be more or less than four. In the printer 11, the liquid ejecting head 21 may not necessarily move in the scanning direction but may eject ink onto the paper S at a fixed position.

  In the above embodiment, the liquid ejecting apparatus is embodied in the ink jet printer 11, but may be embodied in a liquid ejecting apparatus that ejects or discharges liquid other than ink. The present invention can be used for various liquid ejecting apparatuses including a liquid ejecting head that ejects a minute amount of liquid droplets. In addition, a droplet means the state of the liquid discharged from the said liquid ejecting apparatus, and shall also include what pulls a tail in granular shape, tear shape, and thread shape. The liquid here may be any material that can be ejected by the liquid ejecting apparatus. For example, it may be in a state in which the substance is in a liquid phase, such as a liquid with high or low viscosity, sol, gel water, other inorganic solvents, organic solvents, solutions, liquid resins, liquid metals (metal melts ) And liquids as one state of the substance, as well as particles in which functional material particles made of solid materials such as pigments and metal particles are dissolved, dispersed or mixed in a solvent. Further, representative examples of the liquid include ink and liquid crystal as described in the above embodiment. Here, the ink includes general water-based inks and oil-based inks, and various liquid compositions such as gel inks and hot melt inks. As a specific example of the liquid ejecting apparatus, for example, a liquid containing a material such as an electrode material or a color material used for manufacturing a liquid crystal display, an EL (electroluminescence) display, a surface emitting display, or a color filter in a dispersed or dissolved form. There is a liquid ejecting apparatus for ejecting. Alternatively, it may be a liquid ejecting apparatus that ejects a bio-organic material used for biochip manufacturing, a liquid ejecting apparatus that ejects a liquid that is used as a precision pipette and a sample, a printing apparatus, a micro dispenser, or the like. In addition, transparent resin liquids such as UV curable resin to form liquid injection devices that pinpoint lubricant oil onto precision machines such as watches and cameras, and micro hemispherical lenses (optical lenses) used in optical communication elements. A liquid ejecting apparatus that ejects a liquid onto the substrate or a liquid ejecting apparatus that ejects an etching solution such as an acid or an alkali to etch the substrate may be employed. The present invention can be applied to any one of these liquid ejecting apparatuses.

  DESCRIPTION OF SYMBOLS 11 ... Printer as an example of a liquid ejecting apparatus, 21 ... Liquid ejecting head, 23 ... Check valve, 24 ... Pressure control valve, 27 ... Check valve (first check valve), 28 ... Check valve (first 2 check valve), 24 ... pressure control valve, 40 ... tube pump as circulation pump, 50 ... liquid reservoir, JF ... circulation flow path, KF ... return flow path.

Claims (4)

  A liquid ejecting head for ejecting liquid;
  A first liquid flow path for supplying the liquid to the liquid jet head on the downstream side from the upstream side serving as the liquid supply source side;
  One end is connected to the upstream connection part of the first liquid flow path, and the other end is connected to the downstream connection part that is closer to the liquid jet head than the upstream connection part of the first liquid flow path, A first connection channel that forms an annular channel through which the liquid flows with the first liquid channel;
  A second connection flow path having both ends connected to the annular flow path;
  A flow pump provided in the second connection flow path and capable of flowing the liquid in the annular flow path by operating;
  A liquid storage section provided in the annular flow path so as to be able to store the liquid, and a liquid storage section in which an internal volume of the liquid storage section changes in response to pressure fluctuation in the annular flow path;
A liquid ejecting apparatus comprising:   The liquid ejecting apparatus according to claim 1,
  The flow pump operates in a direction in which the liquid in the annular flow path flows from the liquid ejecting head side to the liquid supply source side in the first liquid flow path. The liquid ejecting apparatus described.   The liquid ejecting apparatus according to claim 1 or 2,
  The liquid in the first connection channel is allowed to flow from the upstream connection portion into the first liquid channel and flow toward the liquid supply source side, and in the annular channel A liquid ejecting apparatus comprising: a check valve that prevents the liquid from flowing in the first liquid flow path toward the liquid supply source side.   The liquid ejecting apparatus according to any one of claims 1 to 3,
  The liquid ejecting apparatus according to claim 1, wherein the flow pump is a diaphragm pump having a diaphragm.

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