JP5999233B2 - Liquid supply device and liquid ejection device - Google Patents

Description

  The present invention relates to a liquid ejecting apparatus.

  Conventionally, as a liquid ejecting apparatus, an ejecting head and a cartridge are arranged on a carriage that scans on a recording medium, and desired printing is performed by ejecting ink (liquid) supplied from the cartridge from the ejecting head (recording head) to the recording medium. Inkjet recording apparatuses that perform processing are known. As a method for connecting an ejection head and a cartridge in such an ink jet recording apparatus, an ink supply needle is used (for example, see Patent Document 1).

  By the way, instead of the cartridge mounted on the carriage, a connecting body connected to an external tank arranged outside the recording apparatus via a flexible supply path is mounted on the carriage, and the connecting body is ejected. A method of supplying ink from an external tank to the ejection head by connecting to the ink supply needle of the head is also conceivable.

JP 2002-200772 A

In the connection method via the ink supply needle as described above, it is necessary to dispose a filter for collecting foreign matters from the outside in the ink flow path in the ejection head. This filter requires a certain area in order to reduce the pressure loss generated in the filter by the passage of ink, and as a result, the widened ink path formed above the filter between the ink supply needle and the filter. It is necessary to perform maintenance work such as a suction operation for discharging the growing bubbles.
Normally, in an ink jet recording apparatus of a type in which a cartridge is mounted on a carriage, a maintenance operation (exchange cleaning) for discharging bubbles that have grown in the widened ink path is automatically performed at the timing when the cartridge is replaced.

However, when the connection body is mounted instead of the cartridge of this ink jet recording apparatus and the method of supplying ink from the external tank to the ejection head as described above is adopted, the connection body is not replaced once it is mounted. There arises a problem in that the cleaning failure is not automatically performed and the ejection failure due to the bubbles grown in the widened ink path is not recovered.
Therefore, good ink ejection characteristics can be obtained even when a connection body is mounted on the carriage instead of the cartridge mounted on the carriage and ink is supplied from the external tank to the ejection head. It is desired to provide new technologies that can be used.

  The present invention has been made in view of such circumstances, and is usually connected to an ink tank (external liquid container) disposed outside the recording apparatus instead of a cartridge (liquid container) to be mounted. A liquid ejecting apparatus capable of obtaining good ink ejecting characteristics even when a method is employed in which a sub-tank (connecting body) is mounted and ink is supplied from the ink tank (external liquid container) to the ejecting head. The purpose is to provide.

The liquid supply device of the present invention supplies the liquid contained in an external liquid container provided outside the liquid ejecting unit to the ejection head unit of the liquid ejecting unit that ejects the liquid onto the medium. The connection body includes: a connection body detachably attached to the ejection head portion; and a liquid path connected to the connection body so that the liquid in the external liquid container can be supplied to the connection body. Is a storage chamber that stores the liquid supplied through the liquid path, and has a communication hole to which one end side of the liquid path is connected, and a meniscus can be formed at the gas-liquid interface. is formed of a member, said a jet head state odor attached to the portion Te liquid absorbing body having a contact portion contactable with the filter provided in the ejection head portion, contactable with the liquid in the liquid storage chamber And said Wherein the morphism head liquid and having a liquid absorbing member is provided at a position lower than the liquid surface of the liquid storage chamber of the liquid as it is injected.

The liquid ejecting apparatus according to the aspect of the invention includes an ejecting head unit included in a liquid ejecting unit that ejects a liquid onto a medium, a connection body that is detachable from the ejecting head unit, and an external liquid that is provided outside the liquid ejecting unit. A liquid path connected to the connection body so that the liquid stored in a container can be supplied to the connection body, and the connection body stores the liquid supplied via the liquid path. a storage chamber for storing a reservoir having a communicating hole whose one end of the liquid path is connected, is formed of a member capable of forming a meniscus into the air-liquid interface, Te state odor attached to the ejection head part a liquid absorbing body having a contact portion contactable with the filter provided in the ejection head portion, said liquid when the liquid is ejected from the liquid storage chamber of the possible and the ejection head in contact with the liquid Storage chamber And having a liquid absorber provided on the lower the liquid level of the liquid position.
According to this configuration, good liquid ejection characteristics can be obtained even when a method for supplying liquid from the external liquid container to the ejection head is employed.

The storage chamber may include a flexible wall formed of a flexible film member, and a biasing member that biases the flexible wall in a direction in which the volume of the storage chamber increases.
In addition, the external liquid container holding unit is detachable from the external liquid container, and the position of the contact portion of the liquid absorber in the state where the connection body is mounted on the ejection head unit is as follows. It is good also as a structure higher than the position corresponded to the pressure head of the said liquid in the said external liquid container in the state with which the said external liquid container holding | maintenance part was mounted | worn.

  In addition, the external liquid container holding unit is detachable from the external liquid container, and the position of the contact portion of the liquid absorber in the state where the connection body is mounted on the ejection head unit is as follows. As a configuration higher than a position lower by a capillary force height of a meniscus formed in the contact portion than a position corresponding to a pressure head of the liquid in the external liquid container in a state of being mounted on the external liquid container holding portion. Good.

In addition, the external liquid container holding unit is detachable from the external liquid container, and the position of the contact portion of the liquid absorber in the state where the connection body is mounted on the ejection head unit is as follows. It is good also as a structure higher than the position lower by the capillary force height of the meniscus formed in the said contact part from the position of the said external liquid container upper surface in the state with which the said external liquid container holding | maintenance part was mounted | worn.
According to this configuration, when the connecting body is attached to and detached from the ejection head section, or when the connection body is not completely attached to the ejection head section, the gas-liquid interface at the contact portion of the liquid absorber with the filter due to an impact or the like Even if the meniscus formed in the device breaks, it is possible to prevent the liquid from leaking from the liquid absorber and contaminating the inside or the surroundings of the apparatus.

FIG. 1 is a diagram illustrating a schematic configuration of a printer according to a first embodiment. FIG. 3 is a diagram illustrating a configuration of an ink supply path in the head unit according to the first embodiment. FIG. 3 is a diagram illustrating a configuration of a recording head that is a main part of a head unit. FIG. 2 is a block diagram illustrating an electrical configuration of the printer. FIG. 6 is a diagram illustrating an example of conditions used when determining whether or not the printer according to the embodiment performs maintenance work. The flowchart which shows the determination step of a maintenance operation | work. FIG. 5 is a diagram illustrating a schematic configuration of a printer according to a second embodiment. FIG. 10 is a diagram illustrating a configuration of an ink supply path and an ink supply mechanism IS in a head unit according to a second embodiment.

(First embodiment)
Embodiments of the present invention will be described below with reference to the drawings. In each drawing, each member has a different scale so that each member has a size that can be recognized on the drawing. In the following embodiments, an ink jet printer (hereinafter referred to as a printer) according to a liquid ejecting apparatus will be described as an example.

FIG. 1 is a diagram illustrating a schematic configuration of a printer according to the first embodiment.
The printer (liquid ejecting apparatus) 1 has a head unit (carriage) 2 movably attached to a guide shaft 3 as shown in FIG.

  The head unit (carriage) 2 is connected to a timing belt 6 that is stretched between a driving pulley 4 and an idle pulley 5. The drive pulley 4 is joined to the rotation shaft of the drive motor 7. Therefore, the head unit (carriage) 2 moves in the width direction (main scanning direction) of the recording medium 8 when the drive motor 7 is driven.

  A paper feed roller 11 is disposed below the guide shaft 3 in parallel with the guide shaft 3. The paper feed roller 11 is rotated by the driving force from the paper feed motor 12 when the recording medium 8 is conveyed. Thus, the printing process is performed while the recording medium 8 is conveyed in the length direction (sub-scanning direction).

  A home position is set outside the recording area in the movement range of the head unit (carriage) 2, and the recording head (jetting head) 10 is positioned at this home position when waiting for a printing operation or the like.

  At this home position, a maintenance device (maintenance unit) 13 that performs maintenance processing on the recording head 10 is disposed. The maintenance device 13 includes a capping mechanism 14 that can seal the nozzle surface of the recording head 10 in a non-recording state.

  The capping mechanism 14 is for performing a suction process in which the periphery of the nozzle forming surface 10a is depressurized by coming into contact with the nozzle forming surface 10a on which the nozzle NZ is formed in the recording head 10, and ink is forcibly discharged from the nozzle NZ. It is. The maintenance device 13 has a wiping member 15 for wiping the nozzle forming surface 10a after the suction process in addition to the capping mechanism 14.

FIG. 2 is a diagram illustrating a configuration of an ink supply path in the head unit 2 according to the first embodiment. FIG. 3 is a diagram showing a configuration of the recording head 10 which is a main part of the head unit 2.
As shown in FIG. 2, the head unit (carriage) 2 includes a cartridge unit 9, a recording head 10, and an ink supply unit (liquid supply unit) 17 that supplies ink from the cartridge unit 9 side to the recording head 10 side. . The recording head 10 includes a head case 18, a flow path unit 19, and an actuator unit 20.

  The cartridge unit 9 includes a cartridge holder portion 27 and a plurality of ink cartridges (liquid containers) 26 mounted on the cartridge holder portion 27. A plurality of ink cartridges 26 are detachably attached to the cartridge holder portion 27. The ink cartridge 26 is mainly composed of an ink storage chamber 26a for storing ink liquid, that is, liquid ink (liquid). An ink absorber (liquid absorber) 28 is provided in the ink storage chamber 26a. The ink absorber (liquid absorber) 28 is in a state where ink has oozed out on the surface by contacting the ink accommodated in the ink storage chamber 26a. As the ink absorber (liquid absorber) 28, a member capable of forming a meniscus on the surface (gas-liquid interface) can be applied, and a porous member such as polyethylene or polypropylene foam resin or a nonwoven fabric can be used.

  Specifically, in the present embodiment, the ink cartridge 26 contains, for example, each color ink of yellow (Y), magenta (M), cyan (C), and black (K). Thus, it is possible to eject four colors of ink from the recording head 10 to the recording medium 8.

  The cartridge holder 27 is provided with a detection unit SW (not shown) that detects the attachment / detachment state of the ink cartridge 26. As the detection unit SW, various methods can be adopted as long as it is possible to detect whether or not the ink cartridge 26 is in the cartridge holder unit 27. For example, the contact point is located at a position corresponding to each ink cartridge 26 of the cartridge holder unit 27. The presence or absence of the ink cartridge 26 may be detected by arranging a switch or a reflective photosensor. In the case where a circuit board including a storage element storing information related to ink stored on the ink cartridge 26 side is provided, electrical contacts arranged at positions corresponding to the respective ink cartridges 26 of the cartridge holder portion 27 The presence or absence of the ink cartridge 26 may be detected based on whether information about ink is available via the connector or whether electrical connection is established.

  The ink supply unit 17 includes the ink absorber 28 provided in the ink cartridge 26 and a filter unit (filter) 31 provided in the ink introduction path 23 of the recording head 10. The filter unit 31 is composed of a mesh member through which ink can pass. As the filter part (filter) 31, a metal thin plate member in which small holes are formed or a metal wire rod that is laid is applicable. The ink introduction path 23 constitutes the ink flow path of the recording head 10 through which the ink supplied from the ink cartridge 26 side flows (see FIG. 3).

  The filter unit 31 is disposed at a position in contact with the ink absorber 28 when the ink cartridge 26 is attached to the cartridge holder unit 27. Specifically, the filter portion 31 is disposed at the inlet 23a of the ink introduction path 23, and the inlet 23a is a widened portion that is wider than other flow path portions. Note that the filter unit 31 also functions as a filter for collecting foreign matter or the like in the ink flow path of the recording head 10, so that it is not necessary to separately provide a filter and a widened portion necessary above the filter. .

  The filter unit 31 can communicate with the ink pack 26 a and the ink introduction path 23 by contacting the ink absorber 28 of the ink cartridge 26. As a result, ink can be supplied from the ink pack 26a to the recording head 10 via the ink introduction path 23, and ink can be ejected from the nozzle NZ (see FIG. 3) of the recording head 10.

  As shown in FIG. 3, the head case 18 is formed using a synthetic resin or the like. The head case 18 is formed in a box shape so as to have a hollow portion, for example. A flow path unit 19 is joined to the lower end surface of the head case 18. The actuator unit 20 is accommodated in a hollow portion 37 formed inside the head case 18.

A case channel 25 is provided inside the head case 18 so as to penetrate the height direction.
The upper end of the case flow path 25 communicates with the ink introduction path 23 via the packing 24. The lower end of the case flow path 25 communicates with the common ink chamber 44 in the flow path unit 19. For this reason, the ink introduced from the ink supply unit 17 is supplied to the common ink chamber 44 side through the ink introduction path 23 and the case flow path 25.

  The actuator unit 20 supplies, for example, a plurality of piezoelectric vibrators 38 arranged in a comb shape, a fixed plate 39 that holds the piezoelectric vibrator 38, and a drive signal from the control device 106 to the piezoelectric vibrator 38. And a flexible cable 40.

  The piezoelectric vibrator 38 is fixed so that the lower end portion in the figure protrudes from the lower end surface of the fixed plate 39. Thus, each piezoelectric vibrator 38 is mounted on the fixed plate 39 in a so-called cantilever state. The fixed plate 39 that supports each piezoelectric vibrator 38 is made of, for example, stainless steel having a thickness of about 1 mm. For example, a surface different from the surface on which the piezoelectric vibrator 38 is fixed is bonded to the inner wall surface of the case that defines the hollow portion 37.

  The flow path unit 19 includes a vibration plate 41, a flow path substrate 42 and a nozzle substrate 43. The diaphragm 41, the flow path substrate 42, and the nozzle substrate 43 are bonded in a stacked state. The flow path unit 19 constitutes a series of ink flow paths (liquid flow paths) from the common ink chamber 44 through the ink supply port 45 and the pressure chamber 46 to the nozzle NZ. The pressure chamber 46 is formed such that the direction perpendicular to the arrangement direction (nozzle row direction) of the nozzles NZ is the longitudinal direction.

  The common ink chamber 44 is connected to the case flow path 25. The common ink chamber 44 is a chamber into which ink is introduced from the ink introduction path 23 side. The common ink chamber 44 is connected to the ink supply port 45. The ink introduced into the common ink chamber 44 is distributed to each pressure chamber 46 through the ink supply port 45.

  The nozzle substrate 43 is disposed at the bottom of the flow path unit 19. A plurality of nozzles NZ are formed on the nozzle substrate 43 at a pitch (for example, 180 dpi) corresponding to the dot formation density of an image or the like formed on the recording medium 8. As the nozzle substrate 43, for example, a metal plate material such as stainless steel is used. The lower surface of the nozzle substrate 43 constitutes a nozzle forming surface 10a in which a plurality of nozzle openings are formed.

FIG. 4 is a block diagram illustrating an electrical configuration of the printer 1. The printer 1 includes a control device 106 that controls the operation of the entire printer 1.
Connected to the control device 106 are an input device 100 for inputting various information related to the operation of the printer 1, a storage device 101 storing various information related to the operation of the printer 1, and the like. A drive motor 7 for driving 10 is connected.
Further, the control device 106 applies a drive signal to the piezoelectric vibrator 38 via the drive signal generator 62 and performs control to eject a predetermined amount of ink from the nozzles NZ. The control device 106 controls the capping mechanism 14 and the like of the maintenance device 13.

  By the way, in the printer 1, when the ink in the ink storage chamber 26a runs out, the ink cartridge 26 is replaced. At this time, when the ink cartridge 26 is removed from the cartridge holder portion 27, the filter portion 31 provided at the inlet 23 a of the ink introduction path 23 that forms one of the ink supply portions 17 is exposed to the outside air. When the filter unit 31 is exposed to the outside air, the ink evaporates from the surface. In the ink supply unit 17 according to the present embodiment, the open area of the filter unit 31 is larger than the ink supply needle method employed in the conventional printer. For this reason, ink is likely to evaporate when the ink cartridge 26 is replaced.

  The evaporation of ink from the surface of the filter unit 31 means that the ink introduction path 23 and the internal flow path (the case flow path 25, the common ink chamber 44, the ink supply port 45, the pressure chamber 46, etc.) through which the ink introduction path 23 communicates. ) Means that the ink inside also evaporates. That is, the evaporation of ink from the surface of the filter unit 31 can be translated into the evaporation of the ink in the ink flow path between the filter unit 31 and the nozzle NZ.

  When the ink evaporates in this way, the pressure (internal pressure) in the recording head 10 (nozzle NZ) increases. When the internal pressure of the nozzle NZ exceeds the pressure resistance of the ink meniscus, the ink meniscus of the nozzle NZ is destroyed. When the meniscus is destroyed, it is necessary to perform maintenance work by the maintenance device 13 in order to recover the meniscus.

  On the other hand, when the internal pressure of the nozzle NZ does not exceed the pressure resistance of the ink meniscus, the ink meniscus is not destroyed, so that the maintenance work described above is not necessary. In other words, the printer 1 allows the ink to evaporate until the internal pressure of the nozzle NZ becomes a pressure that does not destroy the ink meniscus even when the ink is evaporated from the filter unit 31 when the ink cartridge 26 is replaced. In addition, maintenance work by the maintenance device 13 can be made unnecessary.

  The printer 1 according to the present embodiment performs the maintenance work by the maintenance device 13 when the ink evaporation amount in the filter unit 31 exceeds the evaporation amount that destroys the ink meniscus of the nozzle NZ as the ink cartridge 26 is replaced. It is supposed to be. According to this, the maintenance work can be appropriately executed when necessary, and the ink is not wasted by the maintenance.

  The printer 1 acquires information on the ink evaporation amount from the filter unit 31 based on the time when the ink cartridge 26 is removed, which is calculated based on the detection result of the attachment / detachment state of the ink cartridge 26 detected by the detection unit SW. . Conditions defining the relationship between the time when the ink cartridge 26 is removed and the amount of ink evaporation include, for example, the surface area of the filter unit 31, the volume of the ink flow path, the type of ink, external environmental conditions (temperature, humidity), and the like. It can be calculated by conducting experiments and simulations using parameters in advance.

  FIG. 5 shows an example of conditions used when the printer 1 according to this embodiment determines whether or not to perform maintenance work. In FIG. 5, the case where the cartridge removal time is less than 5 minutes means that the amount of ink evaporation has not reached the amount of evaporation that destroys the ink meniscus. In FIG. 5, the case where the cartridge removal time is 5 minutes or more and less than 30 minutes means that the ink evaporation amount exceeds the evaporation amount that destroys the ink meniscus. In FIG. 5, the case where the cartridge removal time is 30 minutes or more means that the ink evaporation amount exceeds the evaporation amount that destroys the ink meniscus, and that most of the ink in the ink flow path has evaporated. To do.

  The maintenance mode 1 uses the capping mechanism 14 and performs a suction operation with a weak suction force. In the maintenance mode 2, the capping mechanism 14 is used to perform chalk suction with a strong suction force.

  Based on such a configuration, the printer 1 can estimate the ink evaporation amount by measuring the time when the ink cartridge 26 is removed, and can grasp the state of the ink meniscus of the nozzle NZ. Therefore, the printer 1 can determine whether or not to perform the maintenance work by the maintenance device 13 and the type of the maintenance work.

Next, the operation of the printer 1 having the above configuration will be described. In the following description, the maintenance operation which is a characteristic part of the present application will be mainly described.
When a print start job command is input, the control device 106 drives the paper feed motor 12 and applies a voltage to the piezoelectric vibrator 38 via the drive signal generator 62 while conveying the recording medium 8. The recording head 10 is driven. As a result, the recording head 10 can perform a desired printing process by ejecting ink from the nozzles NZ to a predetermined position of the recording medium 8 conveyed immediately below by the paper feed motor 12.

  The printer 1 supplies ink from the ink cartridge 26 to the recording head 10 during the printing process. Accordingly, the printer 1 can continue the printing process by continuously ejecting ink onto the recording medium 8.

  When the printing process is continued, the ink in the ink pack 26a is finished. In this case, it is necessary to replace the ink cartridge 26. When the ink cartridge 26 is removed from the cartridge holder 27, the printer 1 performs a step of determining whether or not to perform maintenance work based on the ink evaporation amount calculated from the cartridge removal time as described above.

FIG. 6 is a flowchart showing a maintenance operation determination step.
As shown in FIG. 6, when the ink cartridge 26 is removed, the printer 1 measures the removal time of the cartridge. Then, based on the conditions shown in FIG. 5, data on the ink evaporation amount is acquired from the cartridge removal time (step S1).

  The printer 1 determines whether the ink evaporation amount is larger than a predetermined value from the acquired data regarding the ink evaporation amount (step S2). Specifically, in this embodiment, the printer 1 determines whether the removal of the ink cartridge 26 is less than 5 minutes.

  If the cartridge removal time is 5 minutes or longer, the printer 1 determines that the ink evaporation amount exceeds the evaporation amount that destroys the ink meniscus. Then, the printer 1 determines the maintenance mode (step S3). In the determination of the maintenance mode, the printer 1 determines that either the maintenance mode 1 or the maintenance mode 2 is selected.

  When maintenance mode 1 is selected (in the case of YES), the process proceeds to step S5. The printer 1 drives the maintenance device 13 based on the maintenance mode 1. In maintenance mode 1, the capping mechanism 14 is driven to seal the nozzle forming surface 10a of the recording head 10, and a suction operation is performed to depressurize the sealed space with a weak suction force. After performing the suction operation, the wiping member 15 wipes the nozzle forming surface 10a. In addition, you may perform a flushing process as needed.

  By executing the maintenance mode 1, the destroyed ink meniscus can be recovered satisfactorily. Therefore, the ink ejection characteristics of the recording head 10 can be restored by recovering the ink meniscus.

  When maintenance mode 2 is selected (in the case of YES), the process proceeds to step S5. The printer 1 drives the maintenance device 13 based on the maintenance mode 2. In maintenance mode 2, the capping mechanism 14 is driven to seal the nozzle forming surface 10a of the recording head 10, and a choke suction operation is performed to depressurize the sealed space with a strong suction force. By performing the choke suction operation, ink can be refilled from the ink cartridge 26 into the ink flow path which has been in a dry state. After performing the suction operation, the wiping member 15 wipes the nozzle forming surface 10a. In addition, you may perform a flushing process as needed.

  On the other hand, if the cartridge removal time is less than 5 minutes, the printer 1 determines that the ink meniscus has not been destroyed and does not perform the maintenance process (step S7). That is, the printer 1 does not drive the maintenance device 13.

  As described above, according to the present embodiment, since the maintenance work is performed only when the ink has evaporated to such an extent that the ink meniscus is destroyed, the maintenance can be performed efficiently without wasting ink. .

  Further, by managing only the time when the ink cartridge 26 is removed, information on the ink evaporation amount can be acquired. Accordingly, there is no need to separately provide a measurement unit for measuring the ink evaporation amount, so that the apparatus configuration of the printer 1 can be simplified and the cost can be reduced.

  The printer 1 can selectively execute the maintenance modes 1 and 2 by changing the suction force of the capping mechanism 14 according to the ink evaporation amount. Therefore, waste of ink can be eliminated by performing optimum maintenance according to the application.

(Second Embodiment)
Next, a second embodiment related to the printer (liquid ejecting apparatus) 101 will be described. The difference between the present embodiment and the first embodiment is the peripheral structure of the ink supply mechanism IS corresponding to the ink cartridge (liquid container) 26 of the first embodiment, and the other configurations are common. Therefore, only the peripheral configuration of the ink supply mechanism IS will be described below, and description of other configurations will be omitted or simplified. In addition, the same code | symbol is attached | subjected and demonstrated about the same structure and member as 1st Embodiment.

FIG. 7 is a diagram illustrating a schematic configuration of a printer according to the second embodiment.
The ink supply mechanism IS replaces the ink cartridge (liquid container) 26 of the first embodiment with an ink tank (external liquid container) 126 housed at a position different from the head unit (carriage) 2 from the recording head (external liquid container). Ink is supplied to the ejection head 10. The ink supply mechanism IS includes a tank holder portion (external liquid container holding portion) 127 and a plurality of sub tanks (connectors) 226 mounted on the cartridge holder portion 27 instead of the ink cartridge 26 of the first embodiment. Furthermore, in order to supply the ink in the ink tank (external liquid container) 126 attached to the tank holder 127 to the recording head (jet head) 10, the tank holder 127 and a plurality of sub tanks (connectors) 226 A flexible supply tube (liquid path) TB is connected.

FIG. 8 is a diagram illustrating the configuration of the ink supply path and the ink supply mechanism IS in the head unit according to the second embodiment.
A plurality of sub tanks (connectors) 226 are detachably attached to the cartridge holder portion 27. The sub tank 226 is mainly configured by an ink storage chamber 226a for storing ink liquid, that is, liquid ink (liquid). The ink storage chamber 226a is formed by, for example, adhering a flexible film member 226c in a liquid-tight manner to an opening provided in the case member 226b constituting the sub tank 226. In this case, the ink storage chamber 226a can be easily formed by heat welding if the material on the attachment surface side of the case member 226b and the film member 226c is made of the same material such as polyethylene or polypropylene. The film member 226c has an effect of absorbing pressure fluctuation applied to ink in the ink storage chamber 226a due to movement of the head unit (carriage) 2 or the like.

  An ink absorber (liquid absorber) 28 is provided in the ink storage chamber 226a. The ink absorber (liquid absorber) 28 is in a state where ink has oozed out on the surface by contacting the ink stored in the ink storage chamber 226a. As the ink absorber (liquid absorber) 28, a member capable of forming a meniscus on the surface (gas-liquid interface) can be applied, and a porous member such as polyethylene or polypropylene foam resin or a nonwoven fabric can be used. When the liquid used is an ink, if it is a porous member or non-woven fabric, the pressure of the meniscus formed on the surface (gas-liquid interface) is converted to a capillary force height of about 80 to 120 mm. Further, as the ink absorber (liquid absorber) 28, a filter-like member in which small holes are formed in a film-like member so that ink can pass can be adopted. In this case, the meniscus pressure resistance is increased to a high capillary force. When converted, it is about 500 mm.

  One end side of the supply tube (liquid path) TB is connected to the ink storage chamber 226a of the sub tank (connector) 226 through the communication hole 226d, and the other end side is a tank holder part (external liquid container holding part) 127. The ink in the ink tank (external liquid container) 126 connected to the ink connecting part 127d provided in the tank and attached to the tank holder part (external liquid container holding part) 127 is supplied to the recording head (jet head) 10. To do. In the case where there are a plurality of sub tanks (connectors) 226 or ink tanks (external liquid containers) 126, a plurality of supply tubes (liquid paths) TB are required corresponding to the number, but a multiple tube in which a plurality of liquid paths are formed. Can also be adopted.

  The ink tank (external liquid container) 126 is an open ink tank having an ink container 126a for storing ink and an air communication hole 126b for communicating the inside of the ink container 126a with the atmosphere above the ink container 126a. ing. The position of the ink liquid level (position corresponding to the pressure head of the liquid) h in the ink tank (external liquid container) 126 mounted on the tank holder (external liquid container holding part) 127 is the sub tank (connector). ) 226 is preferably set lower in the vertical direction than the position of the contact portion of the ink absorber (liquid absorber) 28 with the filter portion (filter) 31 in a state where the head unit (carriage) 2 is mounted.

  According to this configuration, when the sub tank (connector) 226 is attached to and detached from the head unit (carriage) 2 or when the sub tank (connector) 226 is not completely attached to the head unit (carriage) 2, Even if the meniscus formed at the gas-liquid interface of the contact portion with the filter portion (filter) 31 of the ink absorber (liquid absorber) 28 is broken, the ink leaks from the ink absorber (liquid absorber) 28 and the apparatus It is possible to prevent the inside and surroundings from being contaminated.

  Another form of the ink tank (external liquid container) 126 is an open tank form in which the ink container 126a is communicated with the atmosphere through an opening on the upper side of the communication pipe extending from the lower part of the ink container 126a. Things can be adopted. In this case, the position h corresponding to the pressure head of the ink (liquid) in the ink tank (external liquid container) 126 is the position of the opening on the upper side of the communication pipe. Moreover, the form (sealing system) which employ | adopted the pack formed with the flexible film member as the ink accommodating part 126a, and the form which adds ink to an ink accommodating part may be sufficient.

  Also in the printer 101 according to the second embodiment, since the detection unit SW (not shown) is provided in the same manner as the printer 1 according to the first embodiment, based on the detection result of the attachment / detachment state of the sub tank (connector) 226. When the ink evaporation amount in the filter unit 31 calculated in this way exceeds the evaporation amount that destroys the ink meniscus of the nozzle NZ, the maintenance work by the maintenance device 13 is performed.

  When the ink supply mechanism IS is adopted, the sub tank (connector) 226 is also used when the ink tank (external liquid container) 126 is replaced or when ink is added to the ink container of the ink tank (external liquid container) 126. It is basically unnecessary to replace or remove. For this reason, although the frequency with which the maintenance work by the maintenance device 13 described above is executed is reduced, the ink supply unit 17 is provided in the sub tank (connector) 226 as in the printer 1 according to the first embodiment. Since the ink absorber 28 and the filter part (filter) 31 provided in the ink introduction path 23 of the recording head 10 are configured, the growth of bubbles in the flow path can be reduced, and the recording head 10 can be improved. Liquid ejection characteristics can be obtained.

  Although the printer according to the first embodiment and the second embodiment has been described, the present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the gist of the invention. For example, in the above-described embodiment, the case where it is determined whether to perform the maintenance work based on the ink evaporation amount in the ink flow path between the filter unit 31 and the nozzle NZ is described as an example. The size of bubbles in the ink flow path between the filter unit 31 and the nozzle NZ calculated based on the detection result of the attachment / detachment state of the ink cartridge (liquid container) 26 or the sub tank (connector) 226 and the liquid from the recording head 10. It may be possible to determine whether or not the maintenance work can be performed by comparing the size of bubbles that cause the ejection characteristics to be poor.

  In addition, an open / close valve (pressure adjusting valve) may be provided in the ink storage chamber 226a of the sub tank (connector) 226 that opens from the state in which the communication hole 226d is closed when the pressure in the ink storage chamber 226a falls below a predetermined negative pressure. Good. For example, a compression spring is disposed in the ink storage chamber 226a so as to urge the flexible film member 226c in the direction in which the volume of the ink storage chamber 226a expands, and the ink storage chamber 226a has a predetermined negative pressure. This can be realized by opening the on-off valve in conjunction with the displacement of the film member 226c.

  In addition, the position of the ink level (position corresponding to the pressure head of the liquid) h in the ink tank (external liquid container) 126 mounted on the tank holder (external liquid container holding part) 127 is the sub tank ( The ink absorber (liquid absorber) 28 is located at the position of the contact portion of the ink absorber (liquid absorber) 28 with the filter portion (filter) 31 in a state where the connection body 226 is mounted on the head unit (carriage) 2. It may be set lower in the vertical direction than the position above the height of the capillary force of the meniscus formed at the gas-liquid interface of the contact portion with the filter portion (filter) 31.

  According to this configuration, when ink is replenished to the ink tank (external liquid container) 126, even if the sub tank (connector) 226 is not completely attached to the head unit (carriage) 2. Ink leaks from the ink absorber (liquid absorber) 28 by the capillary force of the meniscus formed at the gas-liquid interface at the contact portion of the ink absorber (liquid absorber) 28 with the filter portion (filter) 31. It is possible to prevent the inside and surroundings of the apparatus from being contaminated.

  Therefore, the sub tank (connector) 226 is connected to the head unit (carriage) 2 on the upper surface of the ink storage portion 126a in the ink tank (external liquid storage body) 126 attached to the tank holder portion (external liquid storage body holding portion) 127. The contact portion of the ink absorber (liquid absorber) 28 with the filter portion (filter) 31 at the position of the contact portion of the ink absorber (liquid absorber) 28 with the filter portion (filter) 31 in the state of being attached to the ink absorber. Even if it is set lower in the vertical direction than the position above the capillary force height of the meniscus formed at the gas-liquid interface, the same effect is obtained.

  In the present embodiment and the modification, the case where the liquid ejecting apparatuses are the printers 1 and 101 has been described as an example, but the present invention is not limited thereto. It may be an apparatus such as a copying machine or a facsimile.

  Further, as the liquid ejecting apparatus, a recording apparatus that ejects or discharges fluid other than ink may be employed. The present invention can be applied to various recording apparatuses including, for example, a recording head that discharges a minute amount of liquid droplets. The droplet means a state of the liquid ejected from the recording apparatus, and includes a liquid having a granular shape, a tear shape, or a thread shape. The liquid here may be any material that can be ejected by the recording 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 a liquid as one state of a substance, as well as a material in which particles of a functional material made of a solid such as a pigment or metal particles are dissolved, dispersed or mixed in a solvent. A typical example of the liquid is an ink (ultraviolet curable ink) as described in the above embodiment, but it may not be an ultraviolet curable ink as long as the viscosity is high. The recording medium includes, in addition to plastic films such as paper and vinyl chloride films, functional paper that is thin and thermally stretched, a substrate, a metal plate, and the like.

  DESCRIPTION OF SYMBOLS 1,101 ... Printer (liquid ejecting apparatus), 10 ... Recording head (ejection head), 13 ... Maintenance device (maintenance part), 14 ... Capping mechanism, 17 ... Ink supply part (liquid supply part), 26 ... Ink cartridge ( (Liquid container), 28 ... ink absorber (liquid absorber), 31 ... filter part (filter), NZ ... nozzle, 126 ... ink tank (external liquid container), 226 ... sub tank (connector).

Claims (6)

A liquid supply device that supplies the liquid contained in an external liquid container provided outside the liquid ejecting unit to an ejecting head unit of a liquid ejecting unit that ejects liquid onto a medium,
A connector that can be attached to and detached from the ejection head unit;
A liquid path connected to the connection body so that the liquid in the external liquid container can be supplied to the connection body;
With
The connection body is
A storage chamber for storing the liquid supplied via the liquid path, the storage chamber having a communication hole to which one end side of the liquid path is connected;
Is formed of a member capable of forming a meniscus into the air-liquid interface, the jetting heads state odor attached to the portion Te a liquid absorbing body having a contact portion contactable with the filter provided in the ejection head unit, the A liquid absorber that is in contact with the liquid in the liquid storage chamber and is provided at a position lower than the liquid level of the liquid in the liquid storage chamber when the liquid is ejected from the ejection head. A liquid supply device.   The storage chamber includes a flexible wall formed of a flexible film member, and a biasing member that biases the flexible wall in a direction in which the volume of the storage chamber increases. The liquid supply apparatus according to claim 1. An external liquid container holding portion to which the external liquid container can be attached and detached,
The position of the contact portion of the liquid absorber in a state where the connection body is mounted on the ejection head portion is, in the vertical direction, the position in the external liquid storage body in a state where the connection body is mounted on the external liquid storage body holding portion. The liquid ejecting apparatus according to claim 1, wherein the liquid ejecting apparatus is higher than a position corresponding to a pressure head of the liquid. An external liquid container holding portion to which the external liquid container can be attached and detached,
The position of the contact portion of the liquid absorber in a state where the connection body is mounted on the ejection head portion is, in the vertical direction, the position in the external liquid storage body in a state where the connection body is mounted on the external liquid storage body holding portion. 3. The liquid ejecting apparatus according to claim 1, wherein the liquid ejecting apparatus is higher than a position lower by a capillary force height of a meniscus formed at the contact portion than a position corresponding to a pressure head of the liquid. An external liquid container holding portion to which the external liquid container can be attached and detached,
The position of the contact portion of the liquid absorber in a state where the connection body is mounted on the ejection head portion is, in the vertical direction, the position of the upper surface of the external liquid storage body in a state where it is mounted on the external liquid storage body holding portion. The liquid ejecting apparatus according to claim 1, wherein the liquid ejecting apparatus is higher than a position lower than a position by a capillary force height of a meniscus formed at the contact portion. An ejection head unit included in a liquid ejection unit that ejects liquid onto a medium;
A connector that can be attached to and detached from the ejection head unit;
A liquid path connected to the connection body so that the liquid stored in an external liquid storage body provided outside the liquid ejecting unit can be supplied to the connection body;
With
The connection body is
A storage chamber for storing the liquid supplied via the liquid path, the storage chamber having a communication hole to which one end side of the liquid path is connected;
Is formed of a member capable of forming a meniscus into the air-liquid interface, the jetting heads state odor attached to the portion Te a liquid absorbing body having a contact portion contactable with the filter provided in the ejection head unit, the A liquid absorber that is in contact with the liquid in the liquid storage chamber and is provided at a position lower than the liquid level of the liquid in the liquid storage chamber when the liquid is ejected from the ejection head ;
A liquid ejecting apparatus comprising:

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