JP2013059981A - Liquid ejecting apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To eject the ink to the sub tank to exhaust the ink in the head.SOLUTION: The liquid ejecting apparatus includes: a head that ejects liquid; a main tank that stores and exchanges the liquid; a sub tank that is positioned between the head and the main tank; a flow-in channel that enables the liquid to flow from the main tank to the sub tank; a flow-out channel that enables the liquid to flow from the sub tank to the head; an introducing channel that enables the liquid to flow from the head to the sub tank; an air communicating channel that is connected to middle of the flow-out channel and enables the flow-out channel to communicate with the air; and a pump that is arranged in middle of the flow-in channel, is driven when the flow-out channel is communicated with the air, enables the liquid in the head to be ejected to the sub tank, and supplies the air to the head.

Description

  The present invention relates to a liquid ejecting apparatus having a main tank, a sub tank, and a head.

2. Description of the Related Art Conventionally, as described in, for example, Patent Document 1, there is known a liquid ejecting apparatus that temporarily supplies ink from a main tank to a sub tank, supplies ink from the sub tank to the head, and ejects ink from the head. It was.
Further, as described in Patent Document 2, a liquid ejecting apparatus that causes ink to flow further from a head to a sub tank is also known.

JP 2001-199084 A JP-A-10-337884

In the liquid ejecting apparatus described in Patent Document 2, the sub tank ink is allowed to flow from the head, but is not allowed to flow to the sub tank so that the ink in the head disappears. For example, when the head is removed, if ink remains in the head, there arises a problem that the ink drips from the removed head.
An object of the present application is to discharge the ink into the sub tank so that the ink in the head runs out.

The liquid ejecting apparatus of the present invention includes a head that ejects liquid, a main tank that stores and replaces the liquid, a sub-tank positioned between the head and the main tank, and the liquid from the main tank to the sub-tank. An inflow passage through which the liquid flows from the sub tank to the head, an introduction passage through which the liquid flows from the head to the sub tank, and the outflow passage. An air communication path capable of communicating with the atmosphere and an air communication path that is provided in the middle of the introduction path, is driven in a state where the outflow channel is in communication with the atmosphere, and discharges the liquid in the head to the sub tank. And a pump for supplying air into the head.
In the state where the outflow passage where the liquid flows from the sub tank to the head communicates with the atmosphere, by driving a pump provided in the middle of the introduction passage where the liquid flows from the head to the sub tank, the air is supplied into the head, The liquid in the head can be reliably discharged to the sub tank.

This liquid ejecting apparatus prohibits the flow of the liquid from the sub tank when the pump is driven between the connection portion of the atmospheric communication path and the outflow channel in the outflow channel and the sub tank. Has an outflow valve.
By prohibiting the flow of the liquid from the sub tank by the outflow valve, it is possible to prevent the liquid from being supplied to the head and to discharge the ink in the head.

In this liquid ejecting apparatus, when the pump starts to be driven, the liquid is stored in the sub tank.
The liquid can be discharged to the sub tank even from the state where the liquid is stored in the sub tank.

In the liquid ejecting apparatus, the sub tank includes a part of the sub tank, the liquid, and a space portion inside the sub tank, and the volume of the space portion is from the head to the sub tank. It is larger than the volume of the liquid to be discharged.
Since the volume of the subtank space is larger than the volume of the liquid discharged to the subtank, the subtank is not filled with liquid and overflows.

In the liquid ejecting apparatus, the sub tank includes a supply control valve that controls the inflow of the liquid from the main tank according to a height of a liquid level in the sub tank. The liquid is stored.
Although the sub tank has a supply control valve, since the liquid is discharged into the sub tank from the state where the liquid is in the sub tank, the liquid level is lowered to prevent the liquid from being supplied from the main tank.

In the liquid ejecting apparatus, the atmosphere communication path includes an atmosphere valve that allows or prohibits the atmosphere from communicating with the outflow passage.
The atmosphere valve can easily allow and prohibit communication with the atmosphere.

In this liquid ejecting apparatus, the atmosphere communication path and the outflow channel are tubes, and the atmosphere valve prohibits communication of the atmosphere by crushing the tube.
By crushing the tube, communication with the atmosphere can be easily prohibited.

In the liquid ejecting apparatus, the outflow valve inhibits the flow of the liquid from the sub tank by crushing the tube.
By crushing the tube, liquid flow can be easily prohibited.

In this liquid ejecting apparatus, one end of the tube of the atmosphere communication path communicates with the outflow channel, and the other end communicates with the atmosphere.
Easy air communication.

In this liquid ejecting apparatus, the other end of the tube of the atmospheric communication path has a gas permeable portion through which air passes and liquid does not pass.
By providing the gas permeable portion, the liquid is prevented from leaking from the atmosphere communication path.

The liquid ejecting apparatus includes a plurality of the atmosphere communication paths, and the atmosphere valve prohibits the atmosphere communication of the plurality of atmosphere communication paths at the same time.
By prohibiting a plurality of air communication at the same time, it can be processed in a short time.

The liquid ejecting apparatus includes a plurality of outflow passages, and the outflow valve simultaneously inhibits the flow of the liquid from the sub tank.
By prohibiting the flow of a plurality of liquids at the same time, processing can be performed in a short time.

In the liquid ejecting apparatus, the pump is a tube pump.
A pump can be easily formed.

In the liquid ejecting apparatus, the pump is a diaphragm pump.
A pump can be easily formed.

FIG. 2 is a front view of the printer according to the first embodiment. FIG. 3 is a detailed view according to the first embodiment. FIG. 3 is a detailed view according to the first embodiment. FIG. 9 is a front view of a printer showing a first modification. FIG. 9 is a plan view of a printer showing a second modification.

  Hereinafter, an embodiment embodied in an ink jet printer (hereinafter referred to as a printer) which is an example of a liquid ejecting apparatus of the invention will be described with reference to the drawings. In the following drawings, the scale of each layer and each member is different from the actual scale so that each layer and each member can be recognized. 1 and 5, the vertical direction indicates the vertical direction, the longitudinal direction indicates the medium conveyance direction as the front, the reverse direction to the conveyance direction is the rear direction, and the left and right directions are perpendicular to the vertical direction and the longitudinal direction. . Here, each figure gives priority to legibility, and the positional relationship between the top, bottom, left and right is not necessarily accurate except for the sub tank 10. If the positional relationship is different from the description, the description shall be correct.

(Embodiment 1)
FIG. 1 is a front view showing an outline when the printer of this embodiment is viewed from the front. As shown in FIG. 1, ink as a liquid is ejected from a head 1 onto paper 3 as a medium supported by a platen 2 from below and conveyed. The paper 3 is conveyed forward, and ink is ejected downward from the head 1 to form images and characters on the paper 3. The head 1 is a line head that is larger than the width of the paper 3 in the left-right direction. A mechanism for transporting the paper 3 is omitted.

  Four main tanks 6 for storing ink are exchangeably mounted on the printer. The main tank 6 contains four inks of black Bk, magenta M, cyan C, and yellow Y in different main tanks 6. Although four inks are used in the present application, the number of inks may be 5 or more, or 3 or less. Two or more inks of the same color may be present. The main tank 6 and the sub tank 10 are arranged at the same height in the vertical direction along the left-right direction. That is, they are arranged in a direction intersecting with the conveyance direction of the paper 3.

  One end of the inflow channel 8 is connected to each main tank 6. The other end of the inflow channel 8 is connected to the sub tank 10. Ink flows from the main tank 6 side to the sub tank 10 via the inflow channel 8 for each color. In FIG. 1, one line indicating the inflow channel 8 indicates a tube. The arrow at the other end of the inflow channel 8 indicates the direction of ink flow.

  One end of the outflow channel 20 is further connected to the sub tank 10. The other end of the outflow channel 20 is connected to the head 1. Ink flows from the sub tank 10 to the head 1 through the outflow channel 20. That is, the sub tank 10, the head 1, and the outflow channel 20 are in communication. Further, the sub tank 10 is disposed between the head 1 and the main tank 6. In FIG. 1, one line indicating the outflow channel 20 indicates a tube. The arrow at the other end of the outflow channel 20 indicates the direction of ink flow. An outflow valve 22 is disposed in the middle of the outflow passage 20. The outflow valve 22 inhibits the flow of ink from the sub tank 10 by crushing the tube, and allows the flow of ink from the sub tank by not crushing the tube. The outflow valve 22 may crush four tubes simultaneously. The mechanism for crushing the tube is omitted.

  The head 1 and the sub tank 10 are further connected by an introduction channel 21. A pump 25 is arranged in the middle of the introduction flow path 21. The ink flows from the head 1 toward the sub tank 10 by the pump 25. In FIG. 1, one line indicating the introduction channel 21 indicates a tube. An arrow at the end of the introduction channel 21 indicates the direction of ink flow. As an example of the pump 25, a tube pump that rotates while crushing the tube is used. The tube pump rotates while crushing four tubes simultaneously. Another example is a diaphragm pump.

  In the outflow channel 20, an air communication path 30 capable of communicating the outflow channel 20 to the atmosphere is connected between the outflow valve 22 and the head 1. One end of the atmosphere communication passage 30 is connected to the outflow passage 20 and the other end is communicated with the atmosphere. In the middle of the atmosphere communication passage 30, an atmosphere valve 31 that allows or prohibits communication of the outflow passage 20 with the atmosphere is provided. In FIG. 1, a single line indicating the atmosphere communication path 30 indicates a tube. The atmospheric valve 31 prohibits communication with the atmosphere by crushing the tube, and allows communication with the atmosphere by not crushing the tube. The outflow valve 22 and the atmospheric valve 31 may be permitted or prohibited by using the same member and simultaneously crushing the tubes.

  As shown in FIG. 1, the sub tank 10 is arranged at a position below the head 1. The sub tank 10 communicates with the atmosphere as will be described later. Since the sub tank 10 communicating with the head 1 is positioned below the head 1, the ink in the head 1 is in a negative pressure state smaller than atmospheric pressure. By making the pressure inside the head 1 negative, the ejected ink droplets can be accurately controlled. When ink is consumed by the head 1, the ink flows from the sub tank 10 to the head 1 through the outflow channel 20. At this time, the outflow valve 22 does not crush the tube of the outflow passage 20 and allows the ink to flow from the sub tank 10. Further, the atmospheric valve 31 crushes the tube of the atmospheric communication path 30 and prohibits the outflow channel 20 from communicating with the atmosphere. Since the ink flows naturally from the sub tank 10 to the head 1, the outflow channel 20 is not provided with a pump for flowing ink.

  The main tank 6 is disposed at a position above the sub tank 10. The ink in the main tank 6 flows into the sub tank 10 through the inflow channel 8 due to the pressure due to the water head difference. Since ink flows due to the water head pressure, there is no pressurizing mechanism for the main tank 6 or a pump in the middle of the inflow channel 8. A supply control valve 23 to be described later is provided in the sub tank 10. The supply control valve 23 allows or prohibits the flow of ink from the main tank 6 to the sub tank 10 in accordance with the amount of ink in the sub tank 10.

  The pump 25 is driven when discharging ink from the head 1. For example, the case where the head 1 is removed from the printer or the case where the ink is not ejected from the head 1 for a long time to prevent the ink from drying or settling in the head 1 is assumed. At this time, the outflow valve 22 crushes the tube of the outflow passage 20 to inhibit the ink from flowing from the sub tank 10, and the atmospheric valve 31 does not crush the tube of the atmosphere communication passage 30 so that the outflow passage 20 is in the atmosphere. The pump 25 is driven in a state in which the pump 25 is communicated. Then, since air is taken in from the front end of the atmosphere communication path 30, the atmosphere is supplied to the head-side outflow channel 20, the head 1, and the introduction channel 21 from the connection portion with the atmosphere communication path 30, thereby Is replaced with air, and the ink is discharged to the sub tank 10. The pump 25 includes the pump 25 only in the introduction channel 21 among the inflow channel 8, the introduction channel 21, and the outflow channel 20.

2 and 3 show the main tank 6, the sub tank 10, the head 1, and each flow path for one color. As shown in FIG. 1, the main tank 6, the sub tank 10, the inflow channel 8, the outflow channel 20, the introduction channel 21, and the atmosphere communication channel 30 have one for each color, and the head 1 has four colors. One. However, the head 1 has a nozzle and a flow path for ejecting ink for each color. A unit including the main tank 6, the inflow channel 8, the sub tank 10, and the outflow channel 20 as a set is referred to as a supply unit that is a group of members that supply ink to the head 1. In the present application, a plurality of (four) supply units are provided, and each supply unit is connected to the head 1.
The shapes of the main tank 6 and the sub tank 10 are the same for each color. The tube used for each flow path may have the same length depending on each color, or the length may be changed depending on the position of a member to be connected. The sub tank 10 is preferably formed of a transparent member so that the stored ink and internal members can be visually recognized.

  In FIG. 2, the main tank 6 has a flexible ink container 7 for containing ink. One end of an inflow channel 8 is connected to the main tank 6. The inflow channel 8 has an inflow valve 9 in the middle. The inflow valve 9 allows the ink flow from the main tank 6 without crushing the tube of the inflow passage 8 when the main tank 6 is mounted. When the main tank 6 is not attached, the inflow valve 9 inhibits the movement of the ink in the inflow channel 8 by crushing the tube of the inflow channel 8. The other end of the inflow channel 8 is connected to the inflow connection portion 11 of the sub tank 10. Thereby, the main tank 6, the sub tank 10, and the inflow channel 8 communicate with each other.

The sub tank 10 has a hollow, substantially rectangular parallelepiped shape, and has an opening that is open on the upper side. The opening is covered with a lid 26. The lid portion 26 has a flat plate shape, and has a groove 27 on one surface side, and has a hole penetrating from the groove 27 on the other surface side. The groove 27 of the lid part 26 is covered with a sealing part 28. The sealing portion 28 has an air communication hole 29. The sub tank 10 communicates with the atmosphere through the hole of the lid portion 26, the groove 27, and the atmosphere communication hole 29.
The sub tank 10 has an inflow connection portion 11 to which the inflow channel 8 is connected. The inflow connecting portion 11 is a protrusion that protrudes outward from the sub tank 10 and has a through hole that communicates the inside and the outside of the sub tank 10. Of the through holes, ink flows into the sub tank 10 from the inlet 12 located on the inner side of the sub tank 10. The ink that has flowed in is stored in the sub tank 10. The main tank 6 and the inlet 12 are connected by an inflow channel 8.

  A float member 35 that is rotatably supported around a fulcrum 36 inside the sub tank 10 is disposed. The float member 35 is a member that floats against ink.

  The sub tank 10 has a supply control valve 23 that rotates around a fulcrum in the sub tank 10. The supply control valve 23 has an annular seal portion. When the supply control valve 23 is urged by the urging spring 24, the seal portion comes into close contact with the periphery of the inflow port 12. In this way, the ink is prohibited from flowing into the sub tank 10 from the inlet 12. Since the main tank 6 is located above the sub tank 10, ink naturally flows from the main tank 6 to the sub tank 10 due to a water head difference. When the flow of ink to the sub tank 10 always continues, the inside of the sub tank 10 is filled with ink, and the ink overflows from the air communication hole 29. This is prevented by stopping the flow of ink into the sub tank 10 by the supply control valve 23.

When the ink is consumed by the head 1 and the ink stored in the sub tank 10 is reduced, and the ink level is lowered, the float member 35 rotates downward about the fulcrum 36. Further, when the ink is reduced, the float member 35 comes into contact with the lever portion of the supply control valve 23 to rotate the supply control valve 23 against the urging force of the urging spring 24 as shown in FIG. When the supply control valve 23 rotates and the seal portion releases the close contact state around the inlet 12, ink flows from the inlet 12.
In this way, the position of the float member 35 changes according to the amount of ink in the sub tank 10 and the height of the liquid level, and the supply control valve 23 allows the ink to pass from the inlet 12 according to the position. Do or ban. That is, the supply control valve 23 controls the flow of ink from the main tank 6 into the sub tank 10. Further, the ink flows in by the movement of the supply control valve 23 and is stored in the sub tank 10.

  The sub tank 10 has an outflow connection portion 13 to which the outflow channel 20 is connected. The outflow connection portion 13 is a protrusion that protrudes outward from the sub tank 10 and has a through hole that communicates the inside and the outside of the sub tank 10. Ink flows out from the outlet 14 located on the inner side of the sub tank 10 in the through hole.

The outflow channel 20 is connected to the supply port 1 b of the head 1. Accordingly, the sub tank 10 and the head 1 are connected via the outflow channel 20. Ink flows out from the outlet 14 of the sub tank 10 toward the head side. The head 1 and the outlet 14 are also connected by the outlet channel 20. An outflow valve 22 is provided in the middle of the outflow channel 20.
The outflow channel 20 is connected to the atmosphere communication path 30 between the outflow valve 22 and the head 1. In other words, the outflow valve 22 is disposed between the connection portion of the outflow passage 20 with the air communication path 30 and the outflow port 14. In FIG. 2, the outflow channel 20 and the atmosphere communication path 30 are integrated. However, the connection may be made using a joint or the like. The atmosphere communication path 30 has a gas permeable portion 32 on the side opposite to the outflow channel 20. The gas permeable portion 32 is a member having a plurality of minute holes through which gas passes but liquid does not pass. This prevents ink from leaking out of the gas permeable portion 32. In addition, in FIG. 2, although the gas permeation | transmission part 32 side of the atmospheric | air communication hole 29 has faced downward, it may face in any direction not only this. Further, the gas permeable portion 32 may be omitted. In this case, since the distal end of the tube is open, the distal end of the tube is preferably directed upward. This makes it difficult for ink to leak.

  The head 1 ejects the ink supplied from the supply port 1b from the nozzle 1a. The head 1 has a discharge port 1c. An introduction channel 21 is connected to the discharge port 1c.

The sub tank 10 has an introduction connecting portion 15 to which the introduction flow path 21 is connected. The introduction connecting portion 15 is a projection that protrudes outward from the sub tank 10 and has a through hole that communicates the inside and the outside of the sub tank 10. Of these through holes, ink is introduced from the inlet 16 on the inner side of the sub tank 10. The head 1 and the introduction port 16 are connected by an introduction channel 21.
A pump 25 is provided in the middle of the introduction flow path 21. By driving the pump 25, the ink flows in the introduction flow path 21 from the head 1 side toward the inside of the sub tank 10.

  Here, the pump 25 is driven with the outflow valve 22 in a state that allows the ink flow from the sub tank 10 and the atmospheric valve 31 in a state in which the outflow passage 20 is prohibited from communicating with the atmosphere. At this time, since the ink flows in the order of the sub tank 10, the outflow channel 20, the head 1, the introduction channel 21, and the sub tank 10, it circulates. As a result, the ink components stored in the sub tank 10 are prevented from settling and a difference in ink density is prevented, or the ink in the head 1 is evaporated and the viscosity of the ink is increased. Or

  Further, the pump 25 is driven with the outflow valve 22 in a state for prohibiting the flow of ink from the sub tank 10 and the atmospheric valve 31 in a state for permitting the outflow passage 20 to communicate with the atmosphere. In this case, the atmosphere is taken in from the gas transmission part 32 of the atmosphere communication passage 30. For this reason, the ink in the outflow passage 20 from the connecting portion of the outflow passage 20 to the atmosphere communication passage 30 to the head 1, the ink in the head 1, and the atmosphere in which the ink in the introduction passage 21 is taken in is replaced. The ink is discharged to the sub tank 10. In the present application, “discharge ink to the sub-tank 10” means a state in which the ink is replaced by air, that is, a state in which the ink flows out.

As shown in FIG. 2, in the state where ink is stored in the sub tank 10, the sub tank 10 has a float member 35 and a supply control valve 23 which are members constituting the sub tank, and a space 19 in a portion excluding the ink.
When the pump 25 is driven and ink is discharged to the sub tank 10, the volume of the space 19 is larger than the volume of the discharged ink. Accordingly, even when ink is discharged into the sub tank 10 in a state where the liquid is stored in the sub tank 10 when the pump 25 starts to be driven, the ink does not leak out from the atmosphere communication hole 29.
When the pump 25 is driven and the ink is discharged to the sub tank 10, if all the ink in the introduction flow path 21 is discharged, then the air flows into the sub tank 10. Since the air that has flowed into the sub tank 10 flows out from the air communication hole 29, it does not accumulate in the sub tank 10.

  The sub tank 10 does not have a wall or the like protruding from the bottom. The inside of the sub tank 10 is not partitioned by this wall.

  Here, the atmosphere communication hole 29 communicates with the inside of the sub tank 10 through the groove 27. The groove 27 is a small groove having a width of 1 to 2 mm and a depth of 1 to 2 mm, so that the sub tank 10 communicates with the atmosphere while preventing the ink stored in the sub tank 10 from evaporating. Although the state of the shape of the groove 27 viewed from above is not shown, it may be a straight line or a serpentine shape that is curved to increase the distance.

When air is discharged into the sub tank 10, for example, in FIG. 2, since the inlet 16 is located below the liquid level, the air passes through the ink. This may generate bubbles. Therefore, among the introduction port 16, the inflow port 12, and the outflow port 14, the introduction port 16 is arranged at the uppermost position, that is, the highest position in the vertical direction. In the two positional relationships, the inlet 16 is at a higher position in the vertical direction than the inlet 12, and the inlet 16 is at a higher position in the vertical direction than the outlet 14. Thereby, even if air is discharged into the sub-tank 10, the distance passing through the ink is shortened, and the possibility of bubbles is reduced.
Although ink flows in from the inlet 12, the possibility that air flows in is low. Therefore, there is no problem even if the inlet 12 is located at a position lower than the inlet 16 in the vertical direction. The position of the outlet 14 is preferably the lowest position in the vertical direction among the outlet 14, the inlet 16, and the inlet 12. Since the outlet 14 is the lowest, the ink in the sub tank 10 is most easily consumed.

2 and 3, the outlet 14, the inlet 16, and the inlet 12 are all provided on the side surface of the main body 18 of the sub tank 10. However, the present invention is not limited to this, and may be provided on the bottom side as long as the above-described height relationship is observed.
In FIG. 2, a cap 4 that can contact the head is disposed below the head 1 so as to surround the nozzle 1 a. The cap 4 abuts against the head 1 when the head 1 is not ejecting ink onto the paper 3 and prevents the ink from evaporating from the nozzle 1a.

  As described above, in the present application, the main tank 6, the inflow passage 8, the sub tank 10, the outflow passage 20, and the introduction passage 21 as shown in FIG. 2 are provided for each color. Here, when the inflow channel 8, the outflow channel 20, and the introduction channel 21 are formed as one tube for each color, they are complicated and disturbed as shown by the line shown in FIG. 1. For example, it is conceivable that a tube is inserted into a different sub tank 10 by mistake during assembly. Conventionally, the main tank 6 to be replaced by a user has been pasted with a color indicating sticker so as not to be inserted erroneously. However, such a device has not been devised for the sub tank 10 and the tubes of the respective flow paths.

Therefore, in the present application, the sub-tank 10, the inflow channel 8, the outflow channel 20, and the introduction channel 21 are formed in a color similar to the color of the ink flowing and stored therein. That is, the sub-tank 10, the inflow channel 8, the outflow channel 20, and the introduction channel 21 are members of four types of colors, black, magenta, cyan, and yellow. However. The sub tank 10 is made of hard resin, and the tube is made of flexible rubber or elastomer. It is difficult to match these colors with the ink colors. In the present application, a similar color is a color that can be visually identified as the same color during assembly. For example, even if the sub-tank 10 and the tube through which magenta flows are red, the colors are close to magenta, so that they can be distinguished from similar colors.
This may be visually identifiable as a color different from the other colors. In the present application, black, magenta, cyan, and yellow inks are used. Depending on the resin, rubber, etc., these colors may be difficult or difficult to identify. Therefore, it may be made colorless or white instead of the color similar to the ink. Originally, ink is not contained in the sub tank 10 or the tube at the time of assembly. Therefore, it is not necessary to match the color of the sub tank 10 or the tube with the color of the ink. In the same supply unit, if the colors of the sub tank 10 and each tube are similar colors, the similar colors can be connected. What is necessary is just to understand the difference with another supply unit between different supply units.

  Moreover, it becomes an element which identifies the length of a tube. For example, a short tube cannot be connected to a long channel between the main tank 6 and the sub tank 10. For this reason, even if the inflow channel 8 is not colored, it can be identified and connected if only the sub tank 10 is colored. In the present application, at least the sub tank 10 only needs to be colored. The sub tank 10 has a lid portion 26 and a main body portion 18. At this time, both the lid portion 26 and the main body portion 18 may be colored, or either one may be used. If the lid 26 is colored, it can be identified when viewed from above. If the main body portion 18 is colored, it can be identified when the tube is connected to the inflow connection portion 11, the outflow connection portion 13, and the introduction connection portion 15.

In addition, as shown in FIG. 1, the length of the tube of the outflow channel 20 from the sub tank 10 to the head 1 differs depending on the color. For this reason, the outflow channel 20 does not have to be colored. However, if the outflow passage 20 is colored in the same color as the sub tank 10, the connection can be made without looking at the length. The introduction channel 21 is the same, and the introduction channel 21 may or may not have a color similar to that of the sub tank 10. Although not shown, when the outflow channel 20 is divided through the connection member in the middle, it is desirable that the connection member has the same color as the outflow channel 20.
Even if the length of the tube is the same, the main tank 6 usually has a display for identifying each color. Therefore, even if the sub tank 10 is colored and the inflow channel 8 is not colored, It is possible to connect the main tank 6 and the sub tank 10 of similar colors.

  Note that the present invention is not limited to the above-described embodiment, and various modifications and improvements can be added to the above-described embodiment. A modification will be described below.

(Modification 1)
FIG. 4 is a front view of the printer according to the first modification.
The difference between the first modification and the first embodiment is the height of the sub tank 10. Other than that, the configuration is the same as that of the first embodiment, and therefore, different points will be described and redundant description will be omitted.

  In the first modification, the four sub tanks 10 have different heights in the vertical direction. As shown in FIG. 4, black is the lowest, magenta and cyan are the same height, and yellow is the highest. As described above, the pressure inside the head 1 is negative due to the water head difference between the head 1 and the sub tank 10. Ink flows from the sub tank 10 to the head 1 by ejecting and consuming ink from the head 1. When ink flows in the outflow channel 20, the channel resistance (dynamic pressure) varies depending on the length of the outflow channel 20. The longer the length of the outflow channel 20, the greater the channel resistance. If the flow path resistance increases, it becomes difficult for ink to flow through the outflow flow path 20, and the ejection of ink from the head 1 cannot be accurately controlled. In FIG. 4, the distance of the outflow passage 20 from the yellow sub-tank 10 to the head 1 is the longest, and is the order of cyan, magenta, and black.

In the first modification, the sub tank 10 having the long outflow channel 20 is arranged at a position higher than the sub tank having the short outflow channel. In this way, the magnitude of the flow path resistance does not change, but the ink can flow more easily by reducing the water head difference between the head 1 and the sub tank 10 and increasing the negative pressure.
In FIG. 4, three kinds of heights of black, magenta, cyan, and yellow are made different. However, the heights of all four types of sub-tanks 10 may be changed, or the heights may be changed in two types, for example, black and magenta, and cyan and yellow.
Here, each sub tank 10 has the same shape. Therefore, changing the height of the sub-tank 10 also changes the height of the lid portion 26, the float member 35, the inlet 12 and the outlet 14.

(Modification 2)
FIG. 5 is a plan view of a printer according to the second modification.
The differences between the modified example 2 and the first embodiment are the height of the sub tank 10 and the position in the front-rear and left-right directions. Other than that, the configuration is the same as that of the first embodiment, and therefore, different points will be described and redundant description will be omitted. Modification 2 has the same problems, technical ideas, and effects as Modification 1.

  In FIG. 1, the sub tank 10 is located below the paper 3 and is disposed along the left-right direction. Moreover, although not shown in figure, it exists in the same position in the front-back direction. In the second modification, as shown in FIG. 5, the sub tanks 10 are arranged on both sides of the conveyed paper 3 indicated by the broken line. Specifically, a magenta sub-tank 10 is disposed on the left front side, black on the left rear side, yellow on the right front side, and cyan on the right rear side. In other words, magenta and black, and yellow and cyan are arranged along the transport direction of the paper 3 (shown in FIG. 5).

  In the case of the sub tank 10 having such an arrangement, the length of the outflow passage 20 is longer in the sub tank 10 arranged on the front side than in the sub tank 10 arranged on the rear side. For this reason, the front sub-tank 10 is positioned higher than the rear sub-tank 10 in the vertical direction. In other words, among the plurality of sub tanks 10 arranged along the transport direction, the sub tank 10 arranged on the side away from the head 1 is arranged at a higher position in the vertical direction than the sub tank 10 close to the head 1. The

Further, the length of the outflow passage 20 is longer in the right sub-tank 10 than in the left sub-tank 10 of the paper 3. Therefore, the sub tank 10 on the right side of the paper 3 is arranged at a higher position in the vertical direction than the sub tank 10 on the left side of the paper 3. This is because the supply port 1b of the head 1 is on the right side. In other words, among the sub-tanks 10 arranged on both sides of the paper 3, the sub-tank 10 on the side farther from the supply port 1b of the head 1 is perpendicular to the sub-tank 10 on the side farther from the supply port 1b of the head 1 in the vertical direction. It is placed at a high position.
Even in this case, the difference in flow path resistance due to the difference in the length of the outflow flow path 20 is absorbed by the head difference between the head 1 and the sub tank 10 to facilitate ink flow.

In addition, in the case of FIG. 5, it is good also considering the color of the subtank 10 as two types, a front side and a rear side. Since the length of the outflow channel 20 is clearly different because the paper 3 is divided into the left and right, it is sufficient that the difference between the sub tanks 10 can be identified before and after. That is, two of the plurality of sub tanks 10 are formed of members of different colors.
Further, the magenta sub-tank 10 may be arranged on the right side as a further modification from FIG. In this case, it is sufficient that the three subtanks 10 of magenta, yellow, and cyan have distinguishable colors. That is, three of the plurality of sub tanks 10 are formed of members of different colors.

The present invention is not limited to the above-described embodiments and modifications as an ink jet printer, and various changes can be made without departing from the scope of the claims.
In each embodiment, the inflow channel 8, the outflow channel 20, the introduction channel 21, and the atmosphere communication channel 30 are described as one tube, but are not particularly limited to one. A plurality of tubes may be connected in series using a connecting member (joint) in the middle.
In each embodiment, the inflow connection portion 11, the outflow connection portion 13, and the introduction connection portion 15 provided in the sub tank 10 are protrusions protruding from the sub tank, and the inflow passage 8, the outflow passage 20, and the introduction passage 21 are formed. It fits into each protrusion. However, in the present application, it is only necessary that the sub tank and each flow path can be connected, and how to connect them is arbitrary.

In each embodiment, the outflow channel 20 is connected to the left side of the head 1, and the introduction channel 21 is connected to the right side of the head 1. However, in the present application, how the head 1 is connected to the outflow passage 20 and the introduction passage 21 is arbitrary. Various connections are possible depending on the flow path in the head 1, and if the ink can be ejected from the nozzle 1 a, there is no problem in the position and orientation of the connection.
In each embodiment, the head 1 is a single line head that is common to all four colors. However, a head may be provided for each color, or a plurality of heads may be arranged in a staggered manner to form a line head. Good. In that case, it is desirable to connect the flow paths of the heads.
1 and 4, the color order of the main tank 6 and the color order of the sub tank 10 are different, but the same color order may be used. The order of the colors of the main tank 6 and the sub tank 10 is arbitrary. The same applies to FIG.

In the above embodiment, an ink jet printer is employed, but a liquid ejecting apparatus that ejects or ejects liquid other than ink may be employed. 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.
Further, the liquid here may be a material that can be ejected by the liquid ejecting head. 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 solvent, organic solvent, solution, liquid resin, liquid metal (metal melt) ) And liquids as one state of the substance, as well as those obtained by dissolving, dispersing or mixing particles of a functional material made of solid materials such as pigments and metal particles in a solvent.

  In addition, typical examples of the liquid include ink and liquid crystal as described in the above embodiments. Here, the ink includes general water-based inks and oil-based inks, and various liquid compositions such as gel inks and hot-melt inks.

  Specific examples of other liquid ejecting apparatuses include, for example, materials such as electrode materials and color materials used in the manufacture of liquid crystal displays, EL (electroluminescence) displays, surface-emitting displays, and color filters in a dispersed or dissolved form. It may be a liquid ejecting apparatus that ejects liquid, a liquid ejecting apparatus that ejects biological organic materials used in biochip manufacturing, a liquid ejecting apparatus that ejects liquid as a sample used as a precision pipette, a textile printing apparatus, a microdispenser, etc. . 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 injection devices.

  DESCRIPTION OF SYMBOLS 1 ... Head, 3 ... Paper (medium), 6 ... Main tank, 8 ... Inflow flow path, 10 ... Sub tank, 11 ... Inflow connection part, 12 ... Inflow port, 13 ... Outflow connection part, 14 ... Outlet port, 15 ... Introduction connection part, 16 ... introduction port, 18 ... main body part, 19 ... space part, 20 ... outflow channel, 21 ... introduction channel, 22 ... outflow valve, 23 ... supply control valve, 25 ... pump, 26 ... lid part , 27 ... groove, 30 ... atmospheric communication path, 31 ... atmospheric valve, 32 ... gas permeable part, 35 ... float member.

Claims (14)

A head for ejecting liquid;
A main tank for storing and replacing the liquid;
A sub tank located between the head and the main tank;
An inflow channel through which the liquid flows from the main tank to the sub tank;
An outflow passage through which the liquid flows from the sub tank to the head;
An introduction channel through which the liquid flows from the head to the sub tank;
An atmospheric communication path connected in the middle of the outflow channel and capable of communicating the outflow channel to the atmosphere;
A pump that is provided in the middle of the introduction path, is driven in a state where the outflow passage is communicated with the atmosphere, discharges the liquid in the head to the sub tank, and supplies the atmosphere into the head;
A liquid ejecting apparatus.   An outflow valve that prohibits the flow of the liquid from the sub tank when the pump is driven, between the connection portion of the atmospheric communication path and the outflow channel in the outflow channel and the sub tank. The liquid ejecting apparatus according to 1.   The liquid ejecting apparatus according to claim 2, wherein when the pump starts to be driven, the liquid is stored in the sub tank. The sub tank includes a part of the sub tank, the liquid, and a space portion inside the sub tank.
The liquid ejecting apparatus according to claim 3, wherein a volume of the space portion is larger than a volume of the liquid discharged from the head to the sub tank.   The sub tank has a supply control valve that controls the inflow of the liquid from the main tank according to the height of the liquid level in the sub tank, and the liquid is stored in the sub tank by the supply control valve. The liquid ejecting apparatus according to claim 4.   The liquid ejecting apparatus according to claim 5, wherein the atmosphere communication path includes an atmosphere valve that allows or prohibits communication of the atmosphere with respect to the outflow channel. The atmosphere communication path and the outflow channel are tubes,
The liquid ejecting apparatus according to claim 6, wherein the atmosphere valve prohibits communication of the atmosphere by crushing the tube.   8. The liquid ejecting apparatus according to claim 7, wherein the outflow valve inhibits the flow of the liquid from the sub tank by crushing the tube.   The liquid ejecting apparatus according to claim 8, wherein a tube of the atmosphere communication path has one end communicating with the outflow channel and the other end communicating with the atmosphere.   The liquid ejecting apparatus according to claim 9, wherein the other end of the tube of the atmosphere communication path has a gas permeable portion through which air passes but liquid does not pass.   The liquid ejecting apparatus according to claim 10, further comprising: a plurality of the atmosphere communication paths, wherein the atmosphere valve simultaneously prohibits the atmosphere communication of the plurality of atmosphere communication paths.   The liquid ejecting apparatus according to claim 11, wherein the liquid ejecting apparatus includes a plurality of the outflow passages, and the outflow valve simultaneously prohibits the flow of the liquid from the sub tank.   The liquid ejecting apparatus according to claim 10, wherein the pump is a tube pump.   The liquid ejecting apparatus according to claim 10, wherein the pump is a diaphragm pump.

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