JP2004209665A - Liquid feeding mechanism, liquid discharging head cartridge, liquid discharging device, liquid supply method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To automatically supply a necessary amount of liquid by a simple arrangement. <P>SOLUTION: There are set a liquid chamber 55 where the liquid 4 is filled, an inflow channel 56 for flowing the liquid 4 into the liquid chamber 55, an outflow channel 57 for flowing the liquid 4 out of the liquid channel 55, a valve 59 for opening and closing the outflow channel 57, a coil spring 60 for urging the valve 59 in a direction to shut the outflow channel 57, an outside air communication part 58 which communicates with the outflow channel 57 and also communicates with the outside air, and a diaphragm 63 which separates between the outside air communication part 58 and the outflow channel 57 and is coupled to the valve 59. When the pressure in the outflow channel 57 decreases, the diaphragm 63 is elastically displaced to the outflow channel 57 side, and at the same time, the valve 59 opens the outflow channel 57 against the urging of the coil spring 60 by the pressing of the diaphragm 63. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a liquid discharge device that discharges a liquid, a liquid discharge head cartridge that discharges a liquid stored in a storage portion of such a liquid discharge device, and a storage portion of such a liquid discharge head cartridge to a head portion. The present invention relates to a liquid supply mechanism for supplying liquid and liquid, and a liquid supply method for supplying liquid from one side to the other side.
[0002]
[Prior art]
As a liquid discharge device that discharges liquid, for example, there is an ink jet type printer device. This ink jet type printer device supplies ink contained in an ink tank to a head chip of a print head, and discharges ink from minute ink discharge holes provided in the head chip, thereby forming an object such as a recording paper. Print on the object. Such an ink jet type printer device is widely used in general because it has advantages such as low running cost, easy downsizing, and easy colorization of a printed image.
[0003]
Further, recently, a so-called line type printer device has been proposed in which a plurality of ink ejection holes of a head chip are arranged in a substantially linear manner with a length corresponding to the width of recording paper or the like. On the other hand, a conventional printer device that performs printing while reciprocating a print head in the width direction of recording paper or the like is called a serial type.
[0004]
In this serial type printer device, it is difficult to increase the size of the ink tank because it is necessary to move the print head with the ink tank mounted. On the other hand, in a line-type printer device, since it is not necessary to move the print head chip, the size of the ink tank can be increased, and the printing speed can be increased.
[0005]
Specifically, as shown in FIG. 16, the print head 200 included in the line-type printer device includes a connecting portion 203 to which an ink tank 202 containing the ink 201 is connected, a head chip 204 that discharges the ink 201, An ink supply mechanism 205 that supplies the ink 201 from the ink tank 202 connected to the connecting portion 203 to the head chip 204 is provided.
[0006]
The ink tank 202 includes an ink storage unit 206 that stores the ink 201, an ink supply unit 207 that is connected to the connection unit 203 and supplies the ink 201 from the ink storage unit 206 to the ink supply mechanism 205, An external communication hole 208 for taking in air into the inside 206 and an air introduction pipe 209 for introducing air taken from the outside communication hole 208 into the ink containing section 206 are provided.
[0007]
Among these, the ink containing section 206 forms a space for containing the ink 201 with a highly airtight material. The ink supply unit 207 is a nozzle that communicates with the ink storage unit 206, and is provided to extend downward from the center of the lower surface of the ink storage unit 206. Then, the tip of the nozzle is connected to the connecting portion 203. When the ink 201 flows into the ink supply mechanism 205 from the ink supply unit 207 via the connection unit 203, the external communication hole 208 supplies air corresponding to the reduced amount of the ink 201 in the ink storage unit 206. It is provided at the center of the upper surface of the ink storage unit 206 so as to be taken into the ink storage unit 206 from outside. The air introduction pipe 209 is provided to extend downward from the external communication hole 208 to the inside of the ink storage unit 206. In the middle of the air introduction pipe 209, an ink storage section is provided as a space for storing the ink 201 so that the ink 201 flowing backward from the ink storage section 206 does not suddenly flow out of the external communication hole 208 to the outside. 210 are provided.
[0008]
The connecting portion 203 to which the ink tank 202 is connected is provided with a seal member 211 such as an O-ring in order to prevent the ink 201 from leaking from between the connected ink supply portion 207. .
[0009]
The head chip 204 has a base 212 in which a plurality of ink ejection holes 204a for ejecting the ink 201 are provided in a substantially linear manner with a length corresponding to the width of a recording paper or the like, and corresponds to each ejection hole 204a of the base 211. In addition, it has an ink pressurizing chamber for pressurizing the ink 201 and a heating resistor (both not shown) for heating the ink 201 supplied to the ink pressurizing chamber. The head chip 204 generates bubbles in the ink 201 by the heating resistor heating the ink 201 supplied to the ink pressurizing chamber, and the ink 201 pressurized in the ink pressurizing chamber by the bubbles is generated. The droplet 201a is ejected from the ink ejection hole 204a.
[0010]
The ink supply mechanism 205 includes an ink chamber 213 filled with ink, an ink inflow path 214 through which the ink 201 flows from the ink supply unit 207 of the ink tank 202 to the ink chamber 213 via the connection unit 203, and an ink chamber. An ink outflow path 215 through which the ink 201 flows out from the head 213 to the head chip 204, a valve 216 that opens and closes the ink inflow path 214, and a coil spring 217 that urges the valve 216 in a direction in which the ink inflow path 214 is closed. Have.
[0011]
The ink chamber 213 forms a substantially rectangular parallelepiped space, and the space between the upper surface of the ink chamber 213 and the connecting part 203 of the ink tank 202 to which the ink supply part 207 is connected is described. The ink inflow path 214 communicates with the lower surface of the ink chamber 213 and the head chip 204 through the ink outflow path 215. The valve 216 is formed of a substantially hemispherical member, and is disposed in the ink chamber 213 with the spherical surface facing the ink inflow path 214. The coil spring 217 is arranged in a compressed state in the ink chamber 213 with one end attached to the plane side of the valve 216 and the other end attached to the lower surface of the ink chamber 213. Therefore, the valve 216 is biased by the coil spring 217 so that the spherical surface side closes the ink inflow path 214 in a steady state.
[0012]
In the print head 200 configured as described above, when the ink 201 is ejected from the ink ejection holes 204a of the head chip 204, a negative pressure is generated in the ink pressurizing chamber of the head chip 204, and the ink inside the ink chamber 213 201 is fed into the ink pressurizing chamber of the head chip 204 through the ink outflow path 215.
[0013]
At this time, in the ink supply mechanism 205, the pressure in the ink chamber 213 is reduced by supplying the ink 201 in the ink chamber 213 to the head chip 204 side. When the pressure in the ink chamber 213 becomes lower than the pressure in the ink inflow path 214, a suction force for drawing the ink 201 from the ink inflow path 214 into the ink chamber 213 is generated, and the valve 216 is driven by a coil spring. The ink inflow path 214 is opened against the urging of 217. Thus, the ink 201 flows from the ink inflow path 214 into the ink chamber 213.
[0014]
On the other hand, in the print head 200, when the ink 201 is supplied to the ink pressurizing chamber of the head chip 204, the negative pressure in the ink pressurizing chamber disappears. Accordingly, in the ink supply mechanism 205, the suction force for drawing the ink 201 from the ink inflow path 214 into the ink chamber 213 disappears, and the valve 216 is urged by the coil spring 217 to close the ink inflow path 214 again.
[0015]
On the other hand, in the ink tank 202, when the ink 201 flows from the ink inflow path 214 into the ink chamber 213, the ink 201 is supplied from the ink supply unit 207 to the ink supply mechanism 205 via the connection unit 203. In the ink tank 202, the amount of the ink 201 in the ink storage unit 206 decreases, and air corresponding to the reduced ink 201 is introduced into the ink storage unit 206 from the external communication hole 208 through the air introduction pipe 209. . This air is sent to the upper part in the ink storage unit 206. As a result, the pressure in the ink storage unit 206 returns to a state before the ink 201 is discharged from the ink discharge holes 204a of the head chip 204, and the supply of the ink 201 from the ink supply unit 207 to the ink supply mechanism 205 is stopped. Is done.
[0016]
[Patent Document 1]
JP-A-6-40043 (page 4-5, FIG. 2)
[Patent Document 2]
JP-A-7-60984 (pages 6-10, FIG. 11)
[0017]
[Problems to be solved by the invention]
By the way, in the printer device including the above-described print head 200, when the ink 201 evaporates from the ejection holes 204a of the head chip 204 due to drying and the ink 201 is not supplied, during printing, the ink is discharged from the ink ejection holes 204a into the flow path. The air is entrapped, and the ink 201 is not ejected, and there is a problem that an image is missing only in that portion.
[0018]
For this reason, in the ink supply mechanism 205 described above, the valve 216 is opened by the negative pressure generated by the evaporation of the ink 201 from the ink ejection hole 204a of the head chip 204, and the ink 201 is supplied to the head chip 204a side. Thus, it is necessary to adjust the urging force in the direction in which the valve 216 by the coil spring 217 closes the ink inflow path 214.
[0019]
However, when the biasing force of the coil spring 217 is adjusted so that the valve 216 is opened by the negative pressure generated by the evaporation of the ink 201, the valve 216 is easily opened by a weak external force such as vibration. As a result, ink leaks from the ink ejection holes 204a of the head chip 204.
[0020]
For this reason, in the ink supply mechanism 205, it is necessary to increase the urging force of the coil spring 217 in the direction in which the valve 216 closes the ink inflow path 214 to some extent in consideration of the ink leakage, thereby preventing the above-described image omission. It was very difficult.
[0021]
In the above-described print head 200, it is conceivable to provide a cap at the ink ejection holes 204a of the head chip 204 in order to prevent the ink 201 from evaporating due to drying. It is difficult to completely seal 204a with a simple configuration, and in this case, it is necessary to supply the ink 201 according to the required amount of drying.
[0022]
Further, in the above-described ink supply mechanism 205, since the valve 216 provided in the ink chamber 213 closes the ink inflow path 214 side, when the pressure on the ink tank 202 side increases, the valve 216 operates as a coil spring. In some cases, the ink inflow path 214 is opened against the urging of the ink 217, and ink leakage may occur from the ink ejection holes 204a of the head chip 204.
[0023]
Conventionally, in order to prevent such ink leakage, for example, the inside of a supply path to which ink is supplied by a sponge or the like is maintained at a negative pressure, and ink is supplied to the head chip according to a predetermined negative pressure. (For example, see Patent Documents 1 and 2). However, when a sponge or the like is arranged in the supply path, the amount of ink that can be accommodated inside is naturally limited.
[0024]
In the case where a large amount of ink 201 needs to be supplied from the ink tank 202 to the head chip 204 as in the above-described line-type printer device and the ink-jet printer device for large-size paper, the above-described ink supply device is used. The mechanism 205 has a problem that the supply of the ink 201 cannot keep up.
[0025]
Therefore, the present invention has been proposed in view of such a conventional situation, and a head unit that discharges a liquid from a storage unit that automatically stores a necessary amount of liquid by a simple configuration is provided. It is an object of the present invention to provide a liquid supply mechanism capable of appropriately supplying the liquid.
[0026]
In addition, the present invention includes a liquid discharge head cartridge capable of appropriately discharging liquid while preventing liquid leakage by providing such a liquid supply mechanism, and also includes such a liquid discharge head cartridge. It is an object to provide a liquid ejection device.
[0027]
Another object of the present invention is to provide a liquid supply method capable of automatically and appropriately supplying a necessary amount of liquid from one side to the other side.
[0028]
[Means for Solving the Problems]
In order to achieve this object, a liquid supply mechanism according to the present invention supplies liquid from a storage section of a liquid discharge head cartridge that discharges liquid stored in a storage section from a discharge hole of a head section to the head section. A liquid chamber filled with liquid, an inflow path through which the liquid flows from the storage section to the liquid chamber, an outflow path through which the liquid flows out from the liquid chamber to the head section, and a liquid chamber. A valve that opens and closes the outflow passage, a first elastic member that urges the valve in a direction to close the outflow passage, an outside air communication portion that is in communication with the outflow passage, and that is in communication with the outside air, and an outside air communication portion. And a second elastic member connected to the valve while isolating between the valve and the outflow passage. Then, a negative pressure is generated on the head portion side, and the pressure in the outflow passage decreases, so that the pressure in the outflow passage becomes lower than the atmospheric pressure on the outside air communication portion side. The elastic member is elastically displaced to the outflow path side, and the valve opens the outflow path by pressing the valve in a direction in which the outflow path is opened against the bias of the first elastic member. .
[0029]
Further, a liquid ejection head cartridge according to the present invention ejects a liquid accommodated in an accommodation section of a liquid ejection apparatus that ejects a liquid, and includes a head section provided with an ejection hole for ejecting the liquid; And a liquid supply mechanism for supplying liquid from the head to the head unit. The liquid supply mechanism includes a liquid chamber filled with the liquid, an inflow path through which the liquid flows from the storage section to the liquid chamber, an outflow path through which the liquid flows out from the liquid chamber to the head section, and a liquid chamber. A valve that opens and closes the outflow passage, a first elastic member that urges the valve in a direction to close the outflow passage, an outside air communication portion that is in communication with the outflow passage, and that is in communication with the outside air, and an outside air communication portion. And a second elastic member connected to the valve while isolating between the valve and the outflow passage. In this liquid supply mechanism, a negative pressure is generated on the head portion side, and the pressure in the outflow passage decreases, so that the pressure in the outflow passage becomes lower than the atmospheric pressure on the outside air communication portion side. The second elastic member is elastically displaced toward the outflow path in response to the pressure, and the valve is pressed in the direction in which the outflow path is opened against the bias of the first elastic member, whereby the valve opens the outflow path. It is characterized by doing.
[0030]
In addition, a liquid discharge apparatus according to the present invention includes a liquid discharge head cartridge that discharges liquid stored in a storage section, and an apparatus main body to which the liquid discharge head cartridge is attached. The liquid ejection head cartridge has a head unit provided with ejection holes for ejecting liquid, and a liquid supply mechanism for supplying liquid from the storage unit to the head unit. The liquid supply mechanism includes a liquid chamber filled with the liquid, an inflow path through which the liquid flows from the storage section to the liquid chamber, an outflow path through which the liquid flows out from the liquid chamber to the head section, and a liquid chamber. A valve that opens and closes the outflow passage, a first elastic member that urges the valve in a direction to close the outflow passage, an outside air communication portion that is in communication with the outflow passage, and that is in communication with the outside air, and an outside air communication portion. And a second elastic member connected to the valve while isolating between the valve and the outflow passage. In this liquid supply mechanism, a negative pressure is generated on the head portion side, and the pressure in the outflow passage decreases, so that the pressure in the outflow passage becomes lower than the atmospheric pressure on the outside air communication portion side. The second elastic member is elastically displaced toward the outflow path in response to the pressure, and the valve is pressed in the direction in which the outflow path is opened against the bias of the first elastic member, whereby the valve opens the outflow path. It is characterized by doing.
[0031]
Further, the liquid supply method according to the present invention is a method for supplying a liquid from one side to the other side, and a liquid chamber filled with the liquid and a liquid flowing from one side into the liquid chamber. An inflow path, an outflow path through which liquid flows out from the liquid chamber to the other side, a valve provided in the liquid chamber to open and close the outflow path, and biases the valve in a direction to close the outflow path. A first elastic member, an outside air communicating portion communicating with the outflow passage and communicating with the outside air, and a second elastic member separating the outside air communicating portion and the outflow passage and connected to the valve. By this, when a negative pressure is generated on the other side, the pressure in the outflow passage is reduced, so that the pressure in the outflow passage is lower than the atmospheric pressure on the outside air communication portion side, and according to this pressure difference, The second elastic member is elastically displaced to the outflow path side, and the outflow path is pressed against the valve by the bias of the first elastic member. By pressing in the release direction, the valve opens the outflow path, and from the one side to the other side due to the generation of suction force that draws the liquid from the liquid chamber to the outflow path due to the pressure drop in the outflow path And supplying a liquid.
[0032]
As described above, in the present invention, a negative pressure is generated on the head portion side (the other side) and the pressure in the outflow passage is reduced, so that the pressure in the outflow passage is lower than the atmospheric pressure on the outside air communication portion side. In response to the pressure difference, the second elastic member is elastically displaced toward the outflow path side, and the valve is pressed in the direction in which the outflow path is opened against the bias of the first elastic member, A valve opens the outlet. Then, by the generation of a suction force that draws the liquid from the liquid chamber to the outflow path due to the pressure drop in the outflow path, the liquid is supplied from the storage section on one side to the head section on the other side.
[0033]
On the other hand, when the liquid is supplied from the storage section to the head section and the pressure in the outflow path returns to a steady state, the pressure difference between the pressure in this outflow path and the atmospheric pressure on the outside air communication section side disappears, The second elastic member elastically displaced toward the outside air communication portion returns to the state before deformation, and closes the outflow path again while the valve is urged by the first elastic member. As a result, the supply of the liquid from the storage section on one side to the head section on the other side is stopped.
[0034]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a liquid supply mechanism, a liquid discharge head cartridge, a liquid discharge device, and a liquid supply method to which the present invention is applied will be described in detail with reference to the drawings.
[0035]
As shown in FIG. 1, a liquid ejection apparatus to which the present invention is applied is an ink jet printer apparatus 1 that ejects ink as a liquid and prints images, characters, and the like on a target recording sheet. The printer device 1 is a so-called line type printer device in which a plurality of ink ejection holes are provided in a substantially straight line in accordance with the printing width of recording paper.
[0036]
The printer device 1 includes an ink jet print head cartridge (hereinafter, referred to as a head cartridge) 2 for discharging ink, and a printer main body 3 which is an apparatus main body to which the head cartridge 2 is attached.
[0037]
The head cartridge 2 is detachable from the printer main body 3. Further, an ink tank 11, which is a storage section for storing ink described later, is detachable from the head cartridge 2. That is, in the printer 1, the head cartridge 2 and the ink tank 11 are handled as consumables, and can be easily replaced.
[0038]
As shown in FIGS. 2 and 3, the head cartridge 2 is a liquid ejection head cartridge to which the present invention is applied, and has a cartridge main body 31 in which an ink tank 11 that is a container containing the ink 4 is mounted. The conductive ink contained in the ink tank 11 is finely divided into particles by, for example, an electrothermal conversion method or an electromechanical conversion method and ejected, and ink droplets are sprayed on a recording medium such as recording paper.
[0039]
As shown in FIG. 3, the ink tank 11 is formed by, for example, injection-molding a resin material or the like, and has a substantially rectangular shape having substantially the same size as the width of the recording paper used in the longitudinal direction. And is detachable from the cartridge body 31.
[0040]
Specifically, the ink tank 11 includes an ink storage unit 12 that stores the ink 4, an ink supply unit 13 that supplies the ink 4 from the ink storage unit 12 to the cartridge body 31, and air from the outside into the ink storage unit 12. An external communication hole 14 for taking in air, an air introduction pipe 15 for introducing air taken in from the external communication hole 14 into the ink container 12, and the ink 4 is temporarily supplied between the external communication hole 14 and the air introduction pipe 15. An ink storage section 16 for storing the ink, a seal 17 for preventing ink from leaking from the external communication hole 14 to the outside, a locking projection 18 and an engagement step 19 for fixing the ink tank 11 to the cartridge main body 31, A terminal unit 20 for detecting the remaining amount of the ink 4 in the tank 11 and an identification protrusion 21 for identifying the ink tank 11 are provided.
[0041]
The ink storage section 12 forms a space for storing the ink 4 using a highly airtight material. The ink storage section 12 is formed in a substantially rectangular shape, and is formed such that the dimension in the longitudinal direction is substantially the same as the dimension in the width direction of the recording paper to be used, ie, the dimension in the direction orthogonal to the recording paper feed direction. I have. The ink container 12 is formed such that the inner surface in contact with the ink has a smaller surface roughness than the outer surface, so that minute foreign substances such as dust do not remain when cleaning the inside.
[0042]
The ink supply unit 13 is provided at a substantially central portion below the ink storage unit 12. The ink supply unit 13 is a substantially convex nozzle that communicates with the ink storage unit 12, and the tip of the nozzle is fitted to a connection supply unit 37 described later to connect the ink tank 11 to the cartridge main body 31. Is done. Note that the bottom surface of the ink storage unit 12 is formed so that the center where the ink supply unit 13 is provided is the deepest, and the stored ink concentrates on the ink supply unit 13.
[0043]
When the ink tank 11 is mounted on the mounting part 32, the connection supply part 37 provided on the mounting part 32 of the ink head cartridge 2 is smoothly connected to the ink supply port 13b provided at the end of the ink supply part 13. It is formed so as to increase in diameter while being linear or curved toward the distal end portion so as to fit into.
[0044]
Specifically, as shown in FIGS. 4 and 5, the ink supply unit 13 includes a bottom surface 13a of the ink tank 11, a supply port 13b for supplying the ink 4, a valve 13c for opening and closing the supply port 13b, and a valve 13c. And a switching pin 13e for opening and closing the valve 13c. As shown in FIG. 4, before the ink tank 11 is mounted on the cartridge body 31, the ink supply section 13 is biased in a direction in which the valve 13c closes the supply port 13d by the biasing force of the coil spring 13d. The mouth 13d is closed. When the ink tank 11 is mounted on the cartridge main body 31, the ink supply section 13 pushes up and down the open / close pin 13e by an upper portion of a connection supply section 37 of the cartridge main body 31, which will be described later, as shown in FIG. The valve 13c is pushed up against the urging force of 13d to open the supply port 13b. As a result, the ink supply unit 13 of the ink tank 11 is mounted on the connection supply unit 37, and the ink storage unit 12 communicates with an ink reservoir 51 described later, so that the ink 4 can be supplied.
[0045]
In addition, as shown in FIGS. 2 and 3, when the ink tank 11 is pulled out from the connection supply unit 37, the ink supply unit 13 closes the supply port 13b by the operation opposite to the above-described operation. . This prevents the ink 4 in the ink container 12 from leaking even when the tip of the ink supply unit 13 faces downward immediately before the ink tank 11 is mounted on the cartridge main body 31. . Further, when the ink tank 11 is pulled out from the cartridge body 31, the valve 13c immediately closes the supply port 13b, so that the ink 4 can be prevented from leaking from the tip of the ink supply unit 13.
[0046]
The external communication hole 14 is a vent that takes in air from outside the ink tank 11 into the ink container 12. The external communication hole 14 corresponds to a decrease in the amount of the ink 4 in the ink storage unit 12 when the ink 4 flows into the cartridge main body 31 from the ink storage unit 12 when the ink tank 11 is mounted on the cartridge main body 31. It is provided on the outer peripheral surface of the ink tank 11 or the like in order to take the minute air into the ink tank 11 from outside.
[0047]
The air introduction pipe 15 communicates the ink container 12 with the external communication hole 14, and introduces the air taken in from the external communication hole 14 into the ink container 12. Thus, in the ink tank 11, even when the ink 4 is supplied to the cartridge main body 31 when the ink container 11 is attached to the cartridge main body 31 and the inside of the ink containing section 12 is depressurized due to the decrease of the ink 4, air is introduced. Since the air is introduced into the ink storage section 12 by the tube 15, the internal pressure is maintained in an equilibrium state, so that the ink 4 can be appropriately supplied to the cartridge main body 31.
[0048]
The ink storage section 16 is provided between the external communication hole 14 and the air introduction pipe 15. When the ink 4 leaks out of the air introduction pipe 15 communicating with the ink storage section 12, the ink storage section 16 suddenly flows to the outside. The ink 4 is temporarily stored so as not to exist.
[0049]
Specifically, the ink tank 11 is in a state where there is no ink 4 in the ink storage unit 16 at normal temperature and normal pressure. However, in the ink tank 11, when a decrease in the external pressure or a rise in the external temperature occurs, the air in the ink storage section 12 expands, and the expanded air transfers the ink 4 from the ink storage section 12 through the air introduction pipe 15. And is pushed out to the ink storage unit 16. At this time, in the ink tank 11, the ink 4 pushed out from the ink storage unit 12 is stored in the ink storage unit 16, so that it is possible to prevent the ink 4 from leaking out of the external communication hole 14.
[0050]
The ink storage section 16 is formed in a substantially rhombus shape with the longer diagonal line being the longitudinal direction of the ink storage section 12, and the air introduction pipe 15 is provided at the top located at the lowermost side of the ink storage section 12, and the ink storage section 16 is provided. The ink that has entered from the position 12 can be returned to the ink storage unit 12 again. Further, the air introduction pipe 15 is provided so as to be located above the ink supply unit 13 so that the ink in the ink storage unit 16 can be efficiently supplied to the ink supply unit even when the remaining amount of ink in the ink storage unit 12 becomes small. 13 can be supplied.
[0051]
The seal 17 is a member that prevents the ink 4 from leaking to the outside of the ink tank 11 even when the ink 4 flows backward to the external communication hole 14 at the time of shipping or the like. In use, the seal 17 is peeled from the ink container 12 so as to open the external communication hole 14. Of course, since the external communication hole 14 is provided on the upper surface of the ink containing section 12, the ink does not leak outside from the external communication hole 14 during use.
[0052]
The locking projection 18 is a projection provided on one side surface of the ink tank 11 in the longitudinal direction, and is engaged with an engagement hole 34 a formed in a later-described latch lever 34 of the cartridge body 31. The locking projection 18 is formed as a plane whose upper surface is substantially perpendicular to the side surface of the ink container 12, and whose lower surface is formed to be inclined from the side surface toward the upper surface.
[0053]
The engagement step 19 is provided on the upper surface of the ink tank 11 on the side opposite to the side on which the locking projection 18 is provided, and has an inclined surface 19 a contacting one end with the upper surface of the ink tank 11; And a flat surface 19b parallel to the upper surface. The ink tank 11 is provided with the engagement step 19 so that the height of the side surface provided with the flat surface 19 b is lower than the height of the side surface provided with the locking projection 18. This step is engaged with an engagement piece 33 of the cartridge body 31 which will be described later. The engagement step portion 19 is provided on the side surface on the insertion end side when inserted into the mounting portion 32 of the head cartridge 2, and engages with the engaging piece 33 on the mounting portion 32 side to mount the ink tank 11. It serves as a rotation fulcrum when mounted on the part 32.
[0054]
As shown in FIG. 6, the terminal portion 20 is an electrode terminal arranged in the height direction on the side surface of the ink tank 11 on which the engaging step portion 19 is provided. From the ink tank 11. The terminal section 20 is connected to an ink remaining amount detecting section 36 of the cartridge body 31 which will be described later. That is, here, a pair of terminals facing the inside of the ink container 12 are provided in three stages in the height direction. The resistance of the pair of terminals facing the inside of the ink container 12 is small when the terminal is immersed in the ink inside the ink container 12 because the ink has conductivity. On the other hand, when the amount of ink in the ink storage unit 12 decreases and the pair of terminals facing the inside of the ink storage unit 12 are exposed to air, the resistance value increases.
[0055]
In such a terminal section 20, when the ink in the ink containing section 12 is full, the resistance between the terminals in all stages becomes small. Then, as the ink is used, the resistance value between the terminals sequentially changes from the top to the bottom. Here, the remaining amount of ink in the ink storage unit 12 can be detected by the ink remaining amount detecting unit 36 detecting that the resistance value of each stage increases. The number of terminals 20 provided in the height direction of the ink storage unit 12 is not limited to three, but may be two. If more accurate remaining amount detection is to be performed, this number of terminals is required. Should be further increased.
[0056]
Since the terminal portion 20 is drawn out from the inside of the ink tank 11, it is fixed with an adhesive so that the ink 4 inside does not leak. At this time, the terminal section 20 has an internal pressure of, for example, 150 mmH. ₂ It is designed so that the ink 4 does not leak if it is O or less.
[0057]
The identification projection 21 is a projection for identifying the type of the ink tank 11, and is inserted into an identification recess 43 of the cartridge main body 31, which will be described later.
[0058]
Here, specific types of the ink tank 11 include, for example, ink tanks 11y, 11m, 11c, and 11k corresponding to four colors of yellow, cyan, magenta, and black, as shown in FIG. By mounting all of these ink tanks 11y, 11m, 11c, and 11k on the cartridge main body 31, the head cartridge 2 is adapted for color printing. Here, since the ink tank 11 usually consumes the largest amount of black ink during printing, it is assumed that the ink tank 11k has a larger capacity of the ink storage unit 12 than the other ink tanks 11y, 11m, and 11c. Have been. Since all of the ink tanks 11y, 11m, 11c, and 11k are mounted on the cartridge main body 31, there is a possibility that the mounting positions may be mistaken when mounting the ink tanks 11 on the cartridge main body 31.
[0059]
Therefore, the identification protrusion 21 is provided in the ink tanks 11y, 11m, 11c, and 11k in accordance with the identification recess 43 described later of the cartridge main body 31 in order to mount each ink tank 11 at a predetermined position without fail as described above. The positions of the protrusions are different in each case.
[0060]
When manufacturing the ink tanks 11y, 11m, 11c, and 11k, the identification protrusions 21 are formed so as to have a plurality of protrusions at the same position, and then each of the ink tanks 11y, 11m, 11c, and 11k. It is preferable to cut off the protrusions at different positions. By forming the identification protrusions 21 in this manner, the same process can be performed up to the process of cutting out the protrusions described above without manufacturing the ink tanks 11y, 11m, 11c, and 11k all in separate processes. Manufacturing efficiency can be improved.
[0061]
The ink tank 11 configured as described above includes the ink tanks 11y, 11m, 11c, and 11k corresponding to the respective colors as described above. Each of the ink tanks 11 is mounted on the cartridge main body 31 constituting the head cartridge 2, and the ink 4 is stored in the cartridge main body 2. 31 side.
[0062]
As shown in FIGS. 2 and 3, the cartridge main body 31 to which the ink tank 11 is mounted includes a mounting portion 32 to which the ink tank 11 is mounted, an engagement piece 33 and a latch lever 34 for fixing the ink tank 11, An urging member 35 for urging the ink tank 11, an ink remaining amount detecting unit 36 for detecting the remaining amount of ink in the ink tank 11, and a connection supply unit 37 connected to the ink supply unit 13 and supplied with the ink 4. An ink detector 38 for detecting the presence or absence of the ink 4 in the connection supply unit 37; a handle 40 for removing the cartridge body 31 from the printer body 3; and a head chip 41 serving as a head for discharging ink. And a head cap 42 for protecting the head chip 41.
[0063]
The mounting portion 32 to which the ink tank 11 is mounted has a substantially concave shape so that the ink tank 11 is mounted. Here, four ink tanks 11 are housed in parallel. Since the ink tank 11 is accommodated in the mounting portion 32, the mounting portion 32 is provided to be long in the print width direction, similarly to the ink tank 11. The cartridge body 31 can mount the ink tank 11 by housing the ink tank 11 in the mounting portion 32.
[0064]
As shown in FIG. 7, the mounting section 32 includes a mounting section 32y for mounting the yellow ink tank 11y, a mounting section 32m for mounting the magenta ink tank 11m, and a cyan ink tank 11c. And a mounting portion 32k to which the black ink tank 11k is mounted. The mounting portions 32y, 32m, 32c, and 32k are partitioned by a partition wall 32a so as to be adjacent to each other.
[0065]
As described above, the black ink tank 11k has a large inner volume of the ink 4, so that the width in the vertical direction with respect to the longitudinal direction is provided wider than the other ink tanks 11y, 11m, and 11c. The width of the mounting portion 32k is also wider than the other mounting portions 32y, 32m, and 32c.
[0066]
As shown in FIG. 3, the engagement piece 33 provided at the opening end of the mounting portion 32 is provided at one longitudinal edge of the mounting portion 32 and engages with the engagement step portion 19 of the ink tank 11. . Specifically, the engagement piece 33 is engaged with the engagement step 19 of the ink tank 11. The ink tank 11 is inserted obliquely into the mounting portion 32 with the engagement step portion 19 side as an insertion end, and the engagement position between the engagement step portion 19 and the engagement piece 33 is used as a rotation fulcrum. The side on which the engaging step portion 19 is not provided can be mounted on the mounting portion 32 so as to rotate toward the mounting portion 32. Thereby, the ink tank 11 can be easily mounted on the mounting section 32.
[0067]
As shown in FIG. 3, the latch lever 34 is provided on a side surface opposite to the engagement piece 33 of the mounting portion 32, that is, on a side surface at the other end in the longitudinal direction, and has a substantially rectangular engagement hole 34a. have. The latch lever 34 is formed such that its base end is integrally provided on the bottom side of the side surface of the other end in the longitudinal direction that constitutes the mounting portion 32, and its distal end side is elastically displaced in a direction approaching or separating from this side surface. An engagement hole 33a is formed on the distal end side. The latch lever 34 is elastically displaced at the same time when the ink tank 11 is mounted on the mounting portion 32, and an urging force acts so that the engagement hole 34 a engages with the locking projection 18 of the ink tank 11, and the To prevent the ink tank 11 mounted on the mounting portion 32 from dropping off from the mounting portion 32.
[0068]
When the ink tank 11 is removed, the latch lever 34 is elastically displaced, whereby the engagement state between the engagement hole 34a and the locking projection 18 is released, and the ink tank 11 can be removed.
[0069]
The urging member 35 is provided on the bottom surface on the side surface corresponding to the engagement step 19 of the ink tank 11, and urges the ink tank 11 in a detaching direction. The urging member 35 is, for example, a leaf spring that is elastically displaceable in a direction in which the ink tank 11 is removed. The biasing member 35 bends the leaf spring, presses the bottom surface of the ink tank 11 at the top formed by bending, and removes the ink tank 11 mounted on the mounting portion 32 from the mounting portion 32. It is urged in the direction. Accordingly, the urging member 35 presses the bottom surface of the ink tank 11 in a direction in which the ink tank 11 is detached when the ink tank 11 is detached from the mounting portion 32 by elastically displacing the latch lever 34. Can be facilitated.
[0070]
As shown in FIG. 8, the ink remaining amount detection unit 36 includes a pair of three conductive members 36a, 36b, and 36c for detecting the remaining amount of the ink 4 in the ink tank 11 stepwise. The detection section is connected to a conductor plate 36d connected to a control circuit (not shown), and is provided in the mounting sections 32y, 32m, 32c, and 32k of the ink tanks 11y, 11m, 11c, and 11k for the respective colors.
[0071]
When the ink tank 11 is mounted on the head cartridge 2, the ink remaining amount detection unit 36 contacts and is electrically connected to the terminal units 20 arranged side by side in the height direction of the side surface inside the ink tank 11. When the ink tank 11 is installed, the ink remaining amount detection unit 36 is pressed by an elastic body (not shown) that urges the ink tank 11 side. The terminal portion 20 is securely brought into contact with the terminal portion 20 so as to be electrically connected thereto.
[0072]
Such an ink remaining amount detecting unit 36 detects the remaining amount of the ink 4 in the ink tank 11 by detecting the electric resistance value between the pair of members 36a, 36b, 36c. More specifically, in the ink remaining amount detecting unit 36, since the ink 4 in the ink tank 11 has conductivity, the electric power between the pair of members 36a, 36b, 36c depends on the remaining amount of the ink 4 in the ink tank 11. The resistance values are different. That is, in the ink remaining amount detecting unit 36, the detected electric resistance value decreases if the ink 4 is present in the ink tank 11, and the detected electric resistance value increases if the ink 4 is absent because the air is an insulating substance. I try to detect that.
[0073]
When the ink tank 11 is mounted on the cartridge body 31, the engaging surface 19 of the ink tank 11 is engaged with the engagement piece 33, and the ink tank 11 is rotated so that the engagement piece 33 becomes a fulcrum. Then, the locking projection 18 is engaged with the engagement hole 34 a of the latch lever 34. At this time, when the urging member 35 urges the ink tank 11 in the removing direction, the ink tank 11 is fixed to the cartridge main body 31.
[0074]
In the cartridge body 31, when the ink tank 11 is mounted, a connection supply section 37 is provided at a portion corresponding to the ink supply section 13 of the ink tank 11 as a connection section connected to the ink supply section 13. The connection supply portion 37 is formed so as to protrude from a hole 13f provided in a part of the bottom surface portion from above a head chip 41 provided on a bottom surface portion in the mounting portion 32 of the cartridge body 31, and has a convex shape. It is a convex ink supply adjusting unit that engages with the ink supply port 13b, and forms an ink supply path to the head chip 41 of the inkjet print head.
[0075]
In the connection supply unit 37, a tip (not shown) may also serve as the opening / closing pin 13e of the ink supply unit 13. In this case, when the ink tank 11 is mounted on the cartridge body 31, the tip is The unit pushes up the valve 13c of the ink supply unit 13 described above to enable the supply of the ink 4. As described above, the connection supply unit 37 can supply an appropriate amount of the ink 4 from the ink tank 11 to the head chip 41.
[0076]
Specifically, as shown in FIG. 9, the connection supply unit 37 includes an ink storage unit 51 that stores the ink 4 supplied from the ink tank 11 and a seal that seals the ink supply unit 13 connected to the connection supply unit 37. It has a member 52, a filter 53 for removing impurities in the ink 4, and an ink supply mechanism 54 for supplying the ink 4 from the ink tank 11 side to the head chip 41 side.
[0077]
The ink reservoir 51 is a space that is connected to the ink supply unit 13 and stores the ink 4 supplied from the ink tank 11.
[0078]
The seal member 52 is a seal member provided at the upper end of the ink reservoir 51. When the ink supply unit 13 of the ink tank 11 is connected to the ink reservoir 51 of the connection supply unit 37, the ink 4 leaks to the outside. This is a sealing member that seals the space between the ink reservoir 51 and the ink supply unit 13 so as not to cause the problem.
[0079]
The filter 53 is a filter for removing dirt such as dust and dirt mixed into the ink 4 when the ink tank 11 is attached or detached. The filter 53 is provided below the ink detectors 38 and 39.
[0080]
As shown in FIGS. 10 and 11, the ink supply mechanism 54 is a liquid supply mechanism to which the present invention is applied. The ink chamber 55 is filled with the ink 4, and the ink 4 is supplied from the ink reservoir 51 to the ink chamber 55. The ink inflow path 56 into which the ink flows, the ink outflow path 57 through which the ink 4 flows out from the ink chamber 55 to the head chip 41, and the outside air communication portion 58 which communicates with the ink outflow path 57 and communicates with the outside air. A valve 59 provided in the ink chamber 55 to open and close the ink outflow path 57; a coil spring 60 as a first elastic member for urging the valve 59 in a direction to close the ink outflow path 57; A negative elasticity adjusting screw 61, which is an adjusting means for adjusting the force, is isolated from the ink outflow passage 57 and the outside air communication portion 58, and is connected to the second elastic portion via a valve 59 and a valve shaft 62. And a diaphragm 63 is.
[0081]
The ink chamber 55 is a liquid chamber that forms a space having a substantially rectangular parallelepiped shape. An ink inflow path 56 allows communication between one side surface of the ink chamber 55 and the ink storage section 51 described above. The ink flow path 57 communicates between the lower surface of the ink chamber 55 and the ink flow path 106 of the head chip 41.
[0082]
The ink inflow path 56 is provided to extend downward from the ink reservoir 51, and extends in the horizontal direction from the middle thereof so as to communicate with one side surface of the ink chamber 55.
[0083]
The ink outflow passage 57 is provided extending downward from the lower surface of the ink chamber 55 so as to communicate with the outside air communication portion 58, and extends horizontally from a position communicating with the outside air communication portion 58. It is provided so as to extend downward so as to be communicated with the ink flow path portion 106 of the head chip 41 from the middle thereof. In addition, a flow path 57a that is opened and closed by a valve 59 while penetrating the valve shaft 62 is provided between the ink chamber 55 of the ink outflow path 57 and the outside air communication portion 58.
[0084]
The outside air communication part 58 is located below the flow path 57a to form a substantially cylindrical space, and an outside air communication hole 58a for communicating with outside air is provided on a lower surface part. A holding portion 64 for holding an outer peripheral portion of a diaphragm 63 described later is provided on an inner side surface of the outside air communication portion 58.
[0085]
The valve 59 is formed of a substantially columnar member as a whole, and has a shape in which the distal end portion 59a is tapered so that the distal end portion 59a is fitted into the flow path 57a of the ink outflow path 57 described above. are doing. In the center of the valve 59, a fitting hole 59b into which one end of a valve shaft 62 described later is fitted is formed. The material of the valve 59 is not limited to a particular type, but it is preferable to use an elastic body having a high blocking property, for example, rubber or elastomer. In addition, in order to prevent sticking due to contact with the flow path 57a, it is preferable to provide minute irregularities on the surface of the valve 59 so as not to cause liquid leakage, or to apply and coat a film for preventing adhesion. .
[0086]
The coil spring 60 is a compression coil spring that urges the valve 59 in a direction to close the ink outflow path 57 by its elastic force, and has one end connected to the upper surface of the valve 59 and the other end connected to a negative pressure adjusting screw 61 described later. Is connected to the front end. The coil spring 60 is provided in the ink chamber 57 in a compressed state between the valve 59 and the negative pressure adjusting screw 61. Accordingly, the valve 59 is urged by the coil spring 60 to close the flow path 57a of the ink inflow path 57 in a steady state.
[0087]
The negative pressure adjusting screw 61 adjusts the amount of screwing from the upper surface of the ink chamber 55 from the outside, so that the distal end presses the coil spring 60 and changes the compression state of the coil spring 60, so that the valve by the coil spring 60 is changed. 59 adjusts the urging force in the direction in which the flow path 57a of the ink outflow path 57 is closed. That is, according to the negative pressure adjusting screw 61, it is possible to adjust the negative pressure necessary for opening and closing the valve 59. Specifically, the valve 59 by the coil spring 60 closes the ink outflow path 57 so that the valve 59 is opened by the negative pressure generated by the evaporation of the ink 4 from the nozzle 104a of the head chip 41 described later. Adjust the bias.
[0088]
The valve shaft 62 is a connecting member that connects the valve 59 and the diaphragm 63. One end of the valve shaft 62 is fitted in a fitting hole 59b of the valve 59, and the other end is fitted in a fitting hole 63b of the diaphragm 63 described later. It is attached in the state that was done. On the other end of the valve shaft 62, a stopper 62a for restricting the movement of the valve 59 in the opening direction is provided so as to protrude.
[0089]
The diaphragm 63 has an elastic member such as rubber formed in a substantially disk shape as a whole, and has an elastic displacement portion 63a bulged concentrically toward the ink outflow path 57 between the center portion and the outer peripheral portion. are doing. In the center of the diaphragm 63, a fitting hole 63b into which the other end of the valve shaft 62 is fitted is formed. In addition, a thick portion 63c that is held by the holding portion 64 of the outside air communication portion 58 is provided on an outer peripheral portion of the diaphragm 63.
[0090]
The other end of the valve shaft 62 is fitted into the fitting hole 63b, and the diaphragm 63 is held in a state where the thick portion 63c is sandwiched by the holding portion 64 of the outside air communication portion 58. The ink outflow passage 57 and the outside air communication portion 58 are isolated. As a result, the ink outflow path 27 side is closed, and one main surface of the diaphragm 63 faces the ink 4 in the ink outflow path 57, and the other main surface side faces the outside air of the outside air communication portion 58.
[0091]
Further, the diaphragm 63 is elastically displaceable toward the outflow path 57 while preventing ink leakage due to deformation of the central portion and the outer peripheral portion by elastically displacing the elastic displacement portion 63. Further, in conjunction with the elastic displacement of the diaphragm 63, the valve 59 can be pressed via the valve shaft 62 in the direction in which the flow path 57a of the ink outflow path 57 is opened against the bias of the coil spring 60. It has become.
[0092]
In the ink supply mechanism 54 configured as described above, when the ink 4 is ejected from the nozzle 104a of the head chip 41 described later, a negative pressure is generated on the head chip 41 side, and the pressure in the ink outflow path 57 is reduced. descend. As a result, the pressure in the ink outflow passage 57 becomes lower than the atmospheric pressure on the outside air communication portion 58 side, and the diaphragm 63 is elastically displaced toward the ink outflow passage 57 in accordance with this pressure difference. Against the bias of the coil spring 60 in the direction in which the flow path 57a of the ink outflow path 57 is opened. Thus, the valve 59 opens the flow path 57a of the ink outflow path 57. The ink 4 flows from the ink inflow path 56 into the ink chamber 55 due to the suction force that draws the ink 4 from the ink chamber 55 to the ink outflow path 57 due to the pressure drop in the ink outflow path 57 described above. Then, the ink 4 flows out of the ink chamber 55 to the ink outflow path 57. Thus, the ink 4 can be supplied from the ink storage section 12 of the ink tank 11 on one side to the head chip 4 on the other side.
[0093]
On the other hand, when the ink 4 is supplied from the ink storage section 12 of the ink tank 11 to the head chip 4 and the pressure in the ink outflow path 57 returns to a steady state, the pressure in the ink outflow path 57 and the outside air communication section 58 When the pressure difference from the atmospheric pressure on the side disappears, the diaphragm 63 elastically displaced toward the outside air communication portion 58 returns to the state before deformation due to the restoring force, and the valve 59 is again urged by the coil spring 60 while being urged by the coil spring 60. The flow path 57a of the outflow path 57 is closed. Thus, the supply of the ink 4 from the ink storage unit 12 of the ink tank 11 on one side to the head chip 4 on the other side is stopped.
[0094]
As described above, the ink supply mechanism 54 repeats the above-described ink 4 supply operation when the negative pressure on the head chip 4 side increases each time the ink 4 is ejected.
[0095]
On the other hand, in the ink tank 11, when the ink 4 in the ink storage section 12 is supplied to the ink chamber 55, the ink 4 in the ink storage section 12 is reduced. Get inside 11. The air that has entered the ink tank 11 is sent above the ink tank 11. As a result, the state returns to a state before the ink 4 is ejected from the nozzle 104a to be described later, and the state becomes an equilibrium state. At this time, an equilibrium state is established in a state where the ink 4 hardly exists in the air introduction pipe 15.
[0096]
The ink detection units 38 and 39 are a pair of conductive linear members that detect the presence or absence of the ink 4 in the connection supply unit 37. The ink detection units 38 and 39 are disposed such that the tips face the connection supply unit 37. I have. The ink detectors 38 and 39 are provided on the side surface of the ink reservoir 51 of the connection supply unit 37 so as to penetrate from the inside of the connection supply unit 37 to the outside, and are connected to the head chip 41, respectively.
[0097]
The ink detection units 38 and 39 are provided above the filter 53 in the connection supply unit 37. This is to prevent the negative pressure of the ink 4 on the head chip 41 side from increasing when the amount of the ink 4 becomes equal to or less than the filter 53, thereby preventing the device from malfunctioning. The ink detectors 38 and 39 detect the ink 4 on the ink tank 11 side with respect to the filter 53, thereby preventing the ink 4 from disappearing from the filter 53 on the head chip 41 side.
[0098]
Further, the ink detecting units 38 and 39 can detect the remaining amount of the ink 4 in the ink tank 11 in more detail by using the ink detecting unit 38 and the ink remaining amount detecting unit 36 in combination. Specifically, in the ink detectors 38 and 39, since the ink 4 has conductivity, the electric resistance between the two differs depending on the presence or absence of the ink 4 in the connection supply unit 37. That is, in the ink detection units 38 and 39, the detected electric resistance value decreases if the ink 4 is present in the connection supply unit 37, and if the ink 4 is absent, the detected electric resistance value is large because air is an insulating substance. Become.
[0099]
As described above, the ink detectors 38 and 39 can detect the presence or absence of the ink 4 in the connection supply unit 37 even when there is no remaining amount of the ink 4 in the ink tank 11. The remaining amount of the ink 4 can be detected more accurately.
[0100]
The handle portion 40 facilitates removal of the cartridge body 31 when the cartridge body 31 needs to be replaced due to wear or the like, or when the ink jet printer device 1 is repaired.
[0101]
As shown in FIG. 12, the head chip 41 includes a circuit board 101 serving as a base, a heating resistor 102 for heating the ink 4, a film 103 for preventing the ink 4 from leaking, as shown in FIG. A nozzle sheet 104 provided with a large number of nozzles 104a, which are ink ejection holes from which the ink 4 is ejected, an ink pressurizing chamber 105 surrounded by these, and an ink pressurizing chamber 105 for supplying the ink 4; And an ink flow path section 106 for supplying ink.
[0102]
The circuit board 101 is made of a semiconductor substrate such as silicon. A heating resistor 102 is formed on one main surface 101a of the circuit board 101. The heating resistor 102 and a control circuit (not shown) on the circuit board 101 are connected to each other. It is connected. The control circuit includes a logic IC (Integrated Circuit), a driver transistor, and the like.
[0103]
The heating resistor 102 generates heat by electric power supplied from the control circuit, and heats the ink 4 in the ink pressurizing chamber 105 to increase the internal pressure. The heated ink is discharged from a nozzle 104a provided on a nozzle sheet 104 described later.
[0104]
The film 103 is laminated on one main surface 101a of the circuit board 101. The film 103 is made of, for example, an exposure-curable dry film resist. After being laminated on substantially the entire main surface 101a of the circuit board 101, an unnecessary portion is removed by a photolithography process to form a predetermined shape. . Thus, the film 103 is formed so as to surround the periphery of each heating resistor 102 in a substantially concave shape. A portion surrounding the heating resistor 102 by the film 103 forms a part of the ink pressurizing chamber 105.
[0105]
The nozzle sheet 104 is a sheet-like member on which nozzles 104 a for discharging the ink 4 are formed, and is stacked on the film 103 on the side opposite to the circuit board 101. The nozzle 104 a is a hole opened in a circular shape in the nozzle sheet 104, and is arranged so as to be located below each heating resistor 102. The nozzle sheet 104 forms a part of the ink pressurizing chamber 105.
[0106]
The ink pressurizing chamber 105 is a space surrounded by the circuit board 101, the heating resistor 102, the film 103, and the nozzle sheet 104. The ink 4 supplied from the ink flow path 106 is heated by the heating resistor 102. Increase internal pressure.
[0107]
The ink flow path section 106 is connected to the ink outflow path 57 of the ink supply mechanism 54 described above, and forms a flow path for feeding the ink 4 supplied by the ink supply mechanism 54 to each of the ink pressurizing chambers 105. .
[0108]
In the head chip 41 configured as described above, as shown in FIG. 9, for example, the ink flow path portions 106 corresponding to the yellow, magenta, cyan, and black ink tanks 11, respectively, extend in the width direction of the recording paper. As shown in FIG. 13, the nozzles 104a are arranged substantially linearly in the printing width direction in correspondence with the ink flow path portions 106 to which the inks 4 of the respective colors are supplied.
[0109]
Specifically, connection supply units 37 corresponding to the respective colors are provided immediately below the yellow, magenta, cyan, and black ink tanks 11y, 11m, 11c, and 11k. Since the portion 106 is provided over the printing width of recording paper or the like, the head chip 41 has the nozzles 104a of the respective colors provided along the ink flow path portion 106 on the ejection surface 41a.
[0110]
In the head chip 41, the nozzles 104a of the respective colors are arranged substantially on a straight line. However, a predetermined number of nozzles 104a are provided as a set, and the set of the nozzles 104a is provided so as to be arranged back and forth in the printing direction.
[0111]
The principle of such a head chip 41 discharging the ink droplet i will be described.
[0112]
First, a current pulse is applied to the heating resistor 102 selected by a command from a control circuit (not shown) for a short time, for example, about 1 to 3 microseconds, so that the heating resistor 102 is rapidly heated. As a result, as shown in FIG. 14, an ink bubble B is generated at a portion in contact with the heating resistor 102, and as shown in FIG. Ink 4 is displaced. As a result, an ink droplet i having the same volume as the displaced ink 4 at the portion in contact with the nozzle 104a is ejected from the nozzle 104a and landed on an object such as recording paper.
[0113]
When the ink droplet i is ejected, the same amount of ink 4 as the amount ejected into the ink pressurizing chamber 105 from which the ink droplet i has been ejected is immediately replenished from the ink flow path portion 106, as shown in FIG. Then, return to the original state. The ink 4 is supplied from the ink tank 11 through the ink supply mechanism 54 of the connection supply unit 37.
[0114]
Before the ink 4 is ejected from the nozzle 104a, that is, before ink bubbles are generated in the ink pressurizing chamber 105, the ink liquid level inside the air introduction pipe 15 of the ink tank 11 and outside the air introduction pipe 15 are the same. When this happens, the ink 4 is in an equilibrium state.
[0115]
Here, the electrothermal conversion method in which the head chip 41 heats the ink 4 by the heating resistor 102 has been described. However, a head chip using an electromechanical conversion element such as a piezoelectric element that mechanically pushes the ink 4 by a piezoelectric element is used. It may be.
[0116]
The head cap 42 is a cover provided to protect the head chip 41, and is opened and closed by a cover opening and closing mechanism of the printer main body 3 when discharging the ink 4. As shown in FIG. 2, the head cap 42 has a groove 71 provided in the opening and closing direction, and a cleaning roller 72 provided in the longitudinal direction and absorbing excess ink attached to the ejection surface 41 a of the head chip 41. I have.
[0117]
The head cap 42 is opened and closed along the groove 71 during the opening and closing operation. At this time, the cleaning roller 72 rotates while abutting on the ejection surface 41 a of the head chip 41, thereby absorbing excess ink 4. Then, the ejection surface 41a of the head chip 41 is cleaned. As the cleaning roller 72, for example, a member having high water absorption is used. Further, the head cap 42 prevents the ink 4 in the head chip 41 from drying.
[0118]
As shown in FIG. 1, the printer main body 3 includes a head cartridge mounting portion 81 in which the head cartridge 2 is mounted, a head cartridge attaching / detaching mechanism 82 for attaching / detaching the head cartridge 2, and a head cap opening / closing mechanism for opening / closing the head cap. 83, a paper feeding / discharging mechanism 84 for feeding / discharging recording paper, etc., a paper feed port 85 for supplying recording paper, etc., to the paper feeding / discharging mechanism 84, And a paper port 86.
[0119]
The head cartridge mounting portion 81 is a concave portion in which the head cartridge 2 is mounted, and the head cartridge 2 can be attached and detached by the head cartridge attaching / detaching mechanism 82.
[0120]
The head cartridge attachment / detachment mechanism 82 is a mechanism for attaching / detaching the head cartridge 2 to / from the head cartridge attachment unit 81, and is configured to fix and open the head cartridge 2 by, for example, a lever or the like.
[0121]
The head cap opening / closing mechanism 83 has a drive unit that opens and closes the head cap 42 of the head cartridge 2 so that the head cap 42 is opened when printing is performed so that the chip head 41 is exposed to recording paper or the like. When the printing is completed, the head cap 42 is closed to protect the chip head 41.
[0122]
The paper supply / discharge mechanism 84 has a drive unit that transports recording paper and the like, transports the recording paper and the like supplied from the supply port 85 to the chip head 41 of the head cartridge 2, and records the ink 4 ejected. Paper and the like are conveyed to the paper discharge unit 85 and output outside the apparatus. The paper supply port 85 is an opening for supplying recording paper and the like to the paper supply / discharge mechanism 84, and can stack a plurality of recording papers on a tray 85a or the like and stock them. The recording paper or the like from which the ink 4 has been discharged is conveyed by the paper supply and discharge mechanism 84 and discharged from the paper discharge port 86. This is the opening to be output.
[0123]
By the way, in the above-described printer device 1, since the valve 59 is opened by generating a negative pressure on the head chip 41 side of the head cartridge 2, the ink 4 is discharged from the nozzle 104a of the head chip 41 and the liquid is discharged. When the amount decreases or when the amount of liquid decreases due to the evaporation of the ink 4 from the nozzles 104a of the head chip 41, the valve 59 is opened and closed according to the negative pressure corresponding to the reduced amount of liquid. The ink 4 can be appropriately supplied from the ink storage section 12 of the ink tank 11 on the side to the head chip 4 on the other side.
[0124]
Further, in the printer device 1, when a negative pressure is generated on the head chip 4 side, the pressure in the ink outflow path 57 connected to the head chip 4 side and the large pressure on the outside air communication section 58 side connected to the outside air are increased. The diaphragm 63 is elastically displaced toward the ink outflow path 57 in accordance with the pressure difference from the atmospheric pressure, and the pressure of the diaphragm 63 causes the valve 59 to open the ink outflow path 57 against the bias of the coil spring 60. For example, it is possible to follow a sudden pressure change generated on the head chip 41 side from when the ink 4 is ejected from the nozzle 104a of the head chip 41 to when the valve 59 opens the ink outflow path 57. is there. Accordingly, it is possible to prevent the air from being sucked from the nozzles 104 a of the head chip 41 and mixed into the ink 4. In particular, in the case of the line type printer device 1 in which the head chip 4 ejects a large amount of ink, the ink 4 is transferred from the ink storage section 12 of the ink tank 11 on one side to the head chip 41 on the other side. Can be supplied appropriately and in large quantities.
[0125]
Further, in the printer 1, even when the pressure in the ink storage section 12 of the ink tank 11 is increased, the valve 59 provided in the ink chamber 55 closes the ink outflow path 57 side. The valve 59 does not open the flow path 57a of the ink outflow path 57 due to the increase in the pressure in the ink inflow path 56 and the ink chamber 55 communicated with the ink storage section 12, and ink leakage from the nozzle 104a of the head chip 41 is prevented. It is possible to prevent it from occurring.
[0126]
In the printer device 1 described above, the head cartridge 2 provided with the head chip 41 and the like is detachable from the printer main body 3. However, the present invention is not limited to this. A configuration provided integrally with the printer main body 3 may be used. Further, in the head cartridge 2, the ink tank 11 is detachable from the cartridge main body 31. However, the present invention is not limited to this, and the ink tank 11 is provided integrally with the cartridge main body 31. There may be.
[0127]
Further, the liquid supply method to which the present invention is applied is not limited to the method applied to the ink supply mechanism 54 that supplies the ink 4 from the ink tank 11 to the head chip 41, and the liquid is supplied from one side to the other side. Is widely applicable in supplying. Further, the present invention is not limited to the one applied to the above-described printer device 1 but can be widely applied to other liquid ejection devices and liquid ejection head cartridges that eject liquid. For example, the present invention can be applied to a liquid ejection device that ejects DNA or the like in a liquid, a liquid ejection device that ejects a liquid containing conductive particles for forming a wiring pattern of a printed wiring board, and the like.
[0128]
【The invention's effect】
As described above in detail, according to the present invention, since the valve is opened by the negative pressure generated on the head portion side (the other side), the liquid is discharged from the discharge hole of the head portion and the liquid amount is reduced. When the liquid volume is reduced or when the liquid volume evaporates from the discharge hole of the head portion and the liquid volume is reduced, the valve is opened and closed according to the negative pressure corresponding to the reduced liquid volume, and the housing portion on one side is opened. It is possible to appropriately supply the liquid to the other side, ie, the head portion.
[0129]
Further, according to the present invention, when a negative pressure is generated on the head portion side (the other side), the pressure in the outflow passage communicated with the head portion and the atmospheric pressure on the outside air communication portion side communicated with the outside air are provided. The second elastic member is elastically displaced toward the outflow path in accordance with the pressure difference between the first elastic member and the second elastic member, and the valve opens the outflow path against the urging of the first elastic member due to the pressing of the second elastic member. Therefore, for example, it is possible to follow a sudden pressure change occurring on the head portion side (the other side) from when the liquid is discharged from the discharge hole of the head portion until the valve opens the outflow passage. It is. Thereby, it is possible to prevent the air from being sucked from the ejection holes of the head portion and being mixed into the liquid, and particularly when the head portion ejects a large amount of liquid, It is possible to supply an appropriate and large amount of liquid to the other side, the head section.
[0130]
Further, according to the present invention, even when the pressure in the storage section on one side increases, the valve provided in the liquid chamber closes the outflow path side, so that the inflow path communicated with the storage section. In addition, the valve does not open the outflow path due to the increase in the pressure in the liquid chamber, and it is possible to prevent the liquid from leaking from the discharge hole of the head portion on the other side.
[Brief description of the drawings]
FIG. 1 is a perspective view illustrating a configuration of a printer device suitable for the present invention.
FIG. 2 is a perspective view illustrating a configuration of a head cartridge provided in the printer device.
FIG. 3 is a cross-sectional view illustrating a configuration of a head cartridge included in the printer device.
FIG. 4 is a schematic diagram for explaining a state in which a supply port of a supply unit of an ink tank mounted on a head cartridge is closed.
FIG. 5 is a schematic diagram for explaining a state in which a supply port of a supply unit of an ink tank mounted on the head cartridge is opened.
FIG. 6 is a schematic diagram for explaining a terminal portion of an ink tank mounted on a head cartridge.
FIG. 7 is a plan view illustrating the configuration of a head cartridge.
FIG. 8 is a plan view illustrating a configuration of an ink remaining amount detection unit in the head cartridge.
FIG. 9 is a schematic diagram for explaining a configuration of an ink tank and a head cartridge.
FIG. 10 is a diagram for explaining an ink supply mechanism of the head cartridge, and is a cross-sectional view showing a state where a valve is closed.
FIG. 11 is a view for explaining an ink supply mechanism of the head cartridge, and is a cross-sectional view showing a state where a valve is opened.
FIG. 12 is a cross-sectional view illustrating a head chip of a head cartridge.
FIG. 13 is a plan view illustrating a head chip of the head cartridge.
FIG. 14 is a cross-sectional view illustrating a state in which bubbles are generated in the head chip of the head cartridge.
FIG. 15 is a cross-sectional view illustrating a state in which ink droplets are ejected by generated bubbles in a head chip of the head cartridge.
FIG. 16 is a schematic diagram for explaining a conventional print head.
[Explanation of symbols]
1 printer device (liquid ejection device), 2 head cartridge (liquid ejection head cartridge), 3 printer body, 4 ink (liquid), 11 ink tank, 12 ink storage section, 13 ink supply section, 13a bottom face, 13b supply port, 13c valve, 13d coil spring, 13e opening / closing pin, 14 external communication hole, 15 air introduction pipe, 16 ink reservoir, 17 seal, 18 locking projection, 19 locking surface, 19a slope, 19b flat surface, 20 terminal, Reference Signs List 21 identification protruding part, 31 cartridge main body, 32 mounting part, 33 claw part, 34 latch lever, 34a hole part, 35 urging member, 36 ink remaining amount detecting part, 37 connection supply part, 38, 39 ink detecting part, 40 Handle part, 41 head chip (head part), 42 head cap, 43 identification concave part, 51 ink reservoir part, 52 seal member 53 filter, 54 ink supply mechanism (liquid supply mechanism), 55 ink chamber (liquid chamber), 56 ink inflow path, 57 ink outflow path, 58 outside air communication section, 59 valve, 60 coil spring (first elastic member), 61 Negative pressure adjusting screw (adjusting means), 62 valve shaft, 63 diaphragm (second elastic member), 71 groove, 72 cleaning roller, 81 head cartridge mounting section, 82 head cartridge attaching / detaching mechanism, 83 head cap opening / closing mechanism, 84 supply Paper discharge mechanism, 85 paper feed port, 86 paper discharge port, 101 circuit board, 101a one main surface, 102 heating resistor, 103 film, 104 nozzle sheet, 104a nozzle (ejection hole), 105 ink pressurizing chamber, 106 ink Channel section

Claims (24)

A liquid supply mechanism for supplying the liquid from the storage section to the head section of the liquid discharge head cartridge that discharges the liquid stored in the storage section from the discharge hole of the head section,
A liquid chamber filled with the liquid,
An inflow passage through which the liquid flows from the storage section to the liquid chamber,
An outflow passage through which the liquid flows out from the liquid chamber to the head portion,
A valve provided in the liquid chamber to open and close the outflow passage;
A first elastic member for urging the valve in a direction in which the outflow passage is closed;
An outside air communication part that is communicated with the outflow passage and is communicated with outside air;
A second elastic member connected to the valve while isolating the outside air communication portion from the outflow passage;
A negative pressure is generated on the head portion side, and the pressure in the outflow passage is reduced, so that the pressure in the outflow passage is lower than the atmospheric pressure on the outside air communication portion side. When the second elastic member is elastically displaced toward the outflow path and presses the valve in a direction in which the outflow path is opened against the bias of the first elastic member, the valve is moved out of the outflow path. A liquid supply mechanism for opening a passage. 2. The liquid supply mechanism according to claim 1, wherein the first elastic member is a coil spring, and the second elastic member is a diaphragm. 2. The liquid supply mechanism according to claim 1, further comprising an adjusting unit that adjusts an urging force in a direction in which the valve formed by the first elastic member closes the outflow path. The first elastic member is a coil spring provided in a compressed state between the valve and the adjusting unit,
The adjusting means adjusts the urging force of the first elastic member in the direction in which the valve closes the outflow path by pressing the coil spring and changing the compression state of the coil spring. The liquid supply mechanism according to claim 3. The adjusting means may be arranged so that the valve by the first elastic member closes the outflow path so that the valve is opened by a negative pressure generated by evaporating the liquid from the ejection hole of the head portion. The liquid supply mechanism according to claim 3, wherein the urging force is adjusted. A liquid ejection head cartridge that ejects a liquid stored in an accommodation section of a liquid ejection device that ejects a liquid,
A head portion provided with a discharge hole for discharging the liquid,
A liquid supply mechanism for supplying the liquid from the storage section to the head section,
The liquid supply mechanism includes a liquid chamber filled with the liquid, an inflow passage through which the liquid flows from the storage section to the liquid chamber, and a liquid outflow from the liquid chamber to the head section. An outflow path, a valve provided in the liquid chamber for opening and closing the outflow path, a first elastic member for urging the valve in a direction in which the outflow path is closed, and communicating with the outflow path. An external air communication portion that is in communication with the external air, and a second elastic member that is connected to the valve while isolating between the external air communication portion and the outflow passage;
A negative pressure is generated on the head portion side, and the pressure in the outflow passage is reduced, so that the pressure in the outflow passage is lower than the atmospheric pressure on the outside air communication portion side. When the second elastic member is elastically displaced toward the outflow path and presses the valve in a direction in which the outflow path is opened against the bias of the first elastic member, the valve is moved out of the outflow path. A liquid discharge head cartridge that opens a passage. 7. The liquid ejection head cartridge according to claim 6, wherein the first elastic member is a coil spring, and the second elastic member is a diaphragm. 7. The liquid ejection head cartridge according to claim 6, wherein the liquid supply mechanism includes an adjusting unit that adjusts a biasing force of the first elastic member in a direction in which the valve closes the outflow path. The first elastic member is a coil spring provided in a compressed state between the valve and the adjusting unit,
The adjusting means adjusts the urging force of the first elastic member in the direction in which the valve closes the outflow path by pressing the coil spring and changing the compression state of the coil spring. A liquid ejection head cartridge according to claim 8. The adjusting means may be arranged so that the valve by the first elastic member closes the outflow path so that the valve is opened by a negative pressure generated by evaporating the liquid from the ejection hole of the head portion. 9. The liquid ejection head cartridge according to claim 8, wherein the urging force is adjusted. 7. The liquid ejection head cartridge according to claim 6, further comprising a connecting portion for connecting the housing portion and the inflow path, wherein the housing portion is detachable from the connecting portion. 7. The liquid ejection head cartridge according to claim 6, wherein the housing portion and the inflow path are provided integrally. 7. The liquid ejection head cartridge according to claim 6, wherein the liquid ejection head cartridge is detachable from the liquid ejection device. The head section includes a base provided with a plurality of the discharge holes arranged in the width direction, a pressurizing chamber for pressurizing a liquid supplied from the outflow passage corresponding to each discharge hole of the base, A heating resistor for heating the liquid supplied to the chamber,
Air bubbles are generated in the liquid by the heating element heating the liquid supplied to the pressurizing chamber, and the liquid pressurized in the pressurizing chamber by the air bubbles is discharged from the discharge holes. 7. The liquid ejection head cartridge according to claim 6, wherein: A liquid ejection head cartridge for ejecting liquid stored in the storage section,
An apparatus main body to which the liquid ejection head cartridge is attached,
The liquid ejection head cartridge has a head portion provided with ejection holes for ejecting the liquid, and a liquid supply mechanism for supplying the liquid from the storage portion to the head portion,
The liquid supply mechanism includes a liquid chamber filled with the liquid, an inflow passage through which the liquid flows from the storage section to the liquid chamber, and a liquid outflow from the liquid chamber to the head section. An outflow path, a valve provided in the liquid chamber for opening and closing the outflow path, a first elastic member for urging the valve in a direction in which the outflow path is closed, and communicating with the outflow path. An external air communication portion that is in communication with the external air, and a second elastic member that is connected to the valve while isolating between the external air communication portion and the outflow passage;
A negative pressure is generated on the head portion side, and the pressure in the outflow passage is reduced, so that the pressure in the outflow passage is lower than the atmospheric pressure on the outside air communication portion side. When the second elastic member is elastically displaced toward the outflow path and presses the valve in a direction in which the outflow path is opened against the bias of the first elastic member, the valve is moved out of the outflow path. A liquid discharge device characterized by opening a path. The liquid ejection apparatus according to claim 15, wherein the first elastic member is a coil spring, and the second elastic member is a diaphragm. 16. The liquid ejection apparatus according to claim 15, wherein the liquid supply mechanism has an adjusting unit that adjusts a biasing force of the first elastic member in a direction in which the valve closes the outflow path. The first elastic member is a coil spring provided in a compressed state between the valve and the adjusting unit,
The adjusting means adjusts the urging force of the first elastic member in the direction in which the valve closes the outflow path by pressing the coil spring and changing the compression state of the coil spring. The liquid ejection device according to claim 17. The adjusting means may be arranged so that the valve by the first elastic member closes the outflow path so that the valve is opened by a negative pressure generated by evaporating the liquid from the ejection hole of the head portion. The liquid ejection device according to claim 17, wherein the urging force is adjusted. 16. The liquid ejection head cartridge according to claim 15, wherein the liquid ejecting head cartridge has a connecting portion connecting the housing portion and the inflow path, and the housing portion is detachable from the connecting portion. Liquid ejection device. 16. The liquid discharging apparatus according to claim 15, wherein the housing portion and the inflow path are provided integrally with the liquid discharging head cartridge. The liquid ejecting apparatus according to claim 15, wherein the liquid ejecting head cartridge is detachable from the apparatus main body. The head section includes a base provided with a plurality of the discharge holes arranged in the width direction, a pressurizing chamber for pressurizing a liquid supplied from the outflow passage corresponding to each discharge hole of the base, A heating resistor for heating the liquid supplied to the chamber,
Air bubbles are generated in the liquid by the heating element heating the liquid supplied to the pressurizing chamber, and the liquid pressurized in the pressurizing chamber by the air bubbles is discharged from the discharge holes. The liquid ejection device according to claim 15, wherein A liquid supply method for supplying liquid from one side to another side,
A liquid chamber filled with the liquid, an inflow path through which the liquid flows from the one side to the liquid chamber, and an outflow path through which the liquid flows out from the liquid chamber to the other side, A valve provided in the liquid chamber for opening and closing the outflow passage, a first elastic member for urging the valve in a direction in which the outflow passage is closed, and being communicated with the outflow passage and with outside air; By providing a second elastic member connected to the valve while isolating the outside air communication portion from the outside air communication portion and the outflow passage.
When a negative pressure is generated on the other side, the pressure in the outflow path decreases due to a decrease in the pressure in the outflow path, and the pressure in the outflow path decreases below the atmospheric pressure on the outside air communication portion side. The second elastic member is elastically displaced toward the outflow path, and the valve is pressed in a direction in which the outflow path is opened against the bias of the first elastic member, whereby the valve is opened. The liquid is supplied from the one side to the other side by opening the outflow path and generating a suction force that draws the liquid from the liquid chamber to the outflow path due to a pressure drop in the outflow path. A liquid supply method characterized by the above-mentioned.

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