This application is based on and claims priority under 35 USC 119 from Japanese Patent Application No. 2008-322133 filed Dec. 18, 2008.
1. Technical Field
The present invention relates to a liquid droplet ejecting head and a liquid droplet ejecting apparatus and particularly to a liquid droplet ejecting head and a liquid droplet ejecting apparatus that eject a high-viscosity liquid as a liquid droplet.
2. Related Art
Water-based inkjet printers that are known as liquid droplet ejecting apparatus and are currently commercially available use dye-based liquids and pigment-based inks with a viscosity generally around 5 cps or 10 (or slightly larger than 10) cps at most. For reasons such as preventing liquid-bleeding when the liquid lands on a medium, increasing optical color density, suppressing expansion of the medium resulting from water content reduction and drying the medium in a short amount of time, and/or increasing the degree of freedom when totally designing such a high-quality liquid, it is known that printing performance can be improved by increasing ink viscosity.
In the ejection of the high-viscosity liquid, it is easy for problems to occur, in comparison to a low-viscosity liquid, such as the stability of the ejected liquid falls and variations in the ejected liquid droplets per nozzle increase. Particularly in a case where, counter to excessive flow path resistance of the high-viscosity liquid, back pressure is applied in order to supply the liquid to the vicinity of the nozzle, it becomes even more difficult to maintain a uniform meniscus (problem of dripping from the nozzle may also arise), and the above-described problems are promoted.
A liquid droplet ejecting head of an aspect of the present invention includes: a nozzle that ejects a liquid droplet; a liquid flow path member at which a liquid flow path that supplies a liquid toward the nozzle is formed; a back pressure generating unit that applies back pressure to the liquid in the liquid flow path toward the nozzle; a beam member joined together with the liquid flow path member or including the liquid flow path member, that deforms so as to become concave in a liquid droplet ejection direction, thereafter undergoes buckling reverse deformation so as to become convex in the liquid droplet ejection direction, and applies inertia to the liquid in the vicinity of the nozzle in the ejection direction, to cause the liquid in the vicinity of the nozzle to be ejected from the nozzle as a liquid droplet; an opening that is disposed on an opposite side of the liquid flow path member to a side in the ejection direction and is communicated with the external atmosphere; a suction path whose suction opening is directed toward the vicinity of the nozzle; and a negative pressure generating unit that generates negative pressure in the suction path.
Exemplary embodiments of the invention will be described in detail with reference to the following figures, wherein:
In
The liquid droplet ejecting head 10 shown in
Further, in the left side portion of the liquid droplet ejecting head 10 with respect to the nozzle 16 in
The flow path member 12 is capable of flexure in a liquid droplet ejection direction (upward in
At this time, the liquid L, to which back pressure has been applied by a back pressure generating component 200, is supplied to the liquid flow path 13 from the liquid pool 24 disposed in one rotary encoder 20A, is fed from a longitudinal direction end to the vicinity of the nozzle 16, and is ejected from the nozzle 16 as liquid droplets 2.
Moreover, as shown in
As shown in
In the right side portion of the liquid droplet ejecting head 10 with respect to the nozzle 16 in
The support members 18 are pressed from both sides in positions that are offset from rotation centers of the rotary encoders 20 (hereinafter, “rotary encoder 20A and rotary encoder 20B” will be merely recited as “rotary encoders 20”), or force is applied in a bend direction to the support members 18, such that the flow path member 12 that is joined to the beam member 14 is made flexure in the ink liquid ejection direction or in the opposite direction. The support members 18 may have a rod-like structure that is long in the front-to-back direction of the page surface of
Further, in the case of a liquid droplet ejecting head that jets the liquid droplets 2 collectively from the plural nozzles 16, it is not necessary for the suction path 42 to be disposed for each nozzle 16; for example, one suction path 42 may be formed with respect to two nozzles 16 (liquid flow paths 13). It is not necessary for the liquid flow path 13 and the suction path 42 to have the same shape, and the suction path 42 may have a larger (fatter, wider, higher) cross section than that of the liquid flow path 13.
<Buckling Reverse Ejection>
In
In a case where the liquid droplet ejecting head 10 is controlled so as to not eject the liquid droplet 2, first, as shown in (A) in
Next, as shown in (B) in
Further, when the rotary encoders 20 continue to be forwardly rotated in the ejection direction as shown in (C) and (D) in
On the other hand, in a case where the liquid droplet ejecting head 10 is controlled so as to eject the liquid droplet 2, first, as shown in (A) in
Next, as shown in (B) in
Moreover, when the rotary encoders 20 are forwardly rotated in the direction of the arrows shown in (C) in
When this change approaches the center from both end sides, the flow path member 12 (or the beam member 14) undergoes a steep buckling reverse at a certain point and abruptly deforms convex in the liquid droplet ejection direction (upward in the drawing) as shown in
Because the nozzle 16 is disposed in the substantial center of the flow path member 12 in the length direction of the flow path member 12, the liquid L that is supplied through the inside of the flow path member 12 and reaches the nozzle 16 is ejected as the liquid droplet 2 from the nozzle 16 in accompaniment with the convex deformation of the flow path member 12 in the ejection direction resulting from this buckling reverse.
Moreover, after the flexure amount reaches a maximum in
In
Further, a liquid flow path 13 is disposed at the support member 18B side in a flow path member 12 that is disposed on the beam member 14, a liquid L is fed toward a nozzle 16 that is disposed in the vicinity of the longitudinal direction center, and the liquid L is ejected from the nozzle 16.
As shown in (A) in
Moreover, as shown in (B) in
In
The liquid L is fed, in a state where back pressure is applied, through the inside of the liquid flow path 13 formed by the flow path member 12, so the liquid L is always supplied to the liquid pool 100 that is formed in the vicinity of the opening 16. At this time, the liquid pool 10 temporarily holds the liquid L, which is supplied in a larger quantity than the liquid quantity that is lost by ejection, so as to not become supply-deficient, and the surplus portion of the liquid L is sucked out and discharged by the suction path 113 to which negative pressure is applied. Thus, the liquid L in the pool 100 forms a free surface, shear resistance of the liquid L that obstructs inertia ejection of the liquid droplets 2 is suppressed, and the liquid droplet ejecting head is given a configuration where, in comparison to a structure where the opposite side in the ejection direction (back side of the nozzle) is tightly closed, it is difficult to be obstructed for ejection even when the liquid L has a high viscosity.
As shown in
The flow path member 40 is disposed on the opposite side of the beam member 14 in the ejection direction (the back side of the beam member 14), and the blowing path 44 is formed between the flow path member 40 and the beam member 14. The blowing path 44 is communicated with the blowing component such that air that has been pressurized is fed through the blowing path 44 as indicated by arrow 43.
A filter 48 is disposed as a filtering component inside the blowing path 44 and filters the air that is fed through the blowing path 44. Moreover, a humidifying component 46 such as a sponge that is capable of holding a liquid is disposed inside the blowing path 44 and humidifies the air that is fed through the blowing path 44 with solvent component of the liquid L. Some of the air that has been fed as indicated by arrow 43 proceeds toward the suction path 113 as indicated by arrow 45 in the liquid pool 100 and is sucked out and removed together with the surplus liquid L as indicated by arrow 41.
By configuring the liquid droplet ejecting head 10 in this manner, the liquid droplet ejecting head 10 has a configuration where, in comparison to a configuration where the liquid pool 100 merely opens to the atmosphere, there is little incorporation of dirt and foreign matter because air that has been filtered by the filter 48 is fed to the liquid pool 100 and it is difficult for the liquid L in the vicinity of the nozzle 16 to dry because air that has been humidified by solvent is fed.
In
The place where an opening 116 is disposed and which had been open to the atmosphere in the first exemplary embodiment is sealed by a flexible thin film 102 of a polyimide or epoxy resin with a thickness of about 5 μm, for example, such that the liquid L in a liquid pool 100 that has been formed is prevented from contacting the outside air.
That is, the opening 116 is disposed in a beam member 14 on the opposite side of the nozzle 16 in the ejection direction to form the liquid pool 100, and the opposite side of the liquid pool 100 in the ejection direction is sealed by the thin film 102, so that when the liquid L is fed, in a state where back pressure is applied, through the inside of a liquid flow path 13 formed by a flow path member 12, the thin film 102 expands as shown in
The liquid L is always supplied to the liquid pool 100, so the liquid pool 100 that the expanded thin film 102 seals temporarily holds the liquid L, which is supplied in a larger quantity than the liquid quantity that is lost by ejection, and the surplus portion of the liquid L is sucked out and removed by a suction path 113 to which negative pressure is applied. Thus, in the liquid pool 100, a surface is formed by the flexible thin film 102, and shear resistance of the liquid L that obstructs inertia ejection of a liquid droplet 2 is suppressed.
The liquid droplet ejecting head 11 has a structure where, at the time of ejection of the liquid droplet 2, as shown in
<Manufacturing Process>
In
As shown in
Next, as shown in
Moreover, the piezo elements 30 on which the signal electrodes 32 have been formed beforehand are joined in a region up to half in the longitudinal direction at the ejection back surface. A supply port 25 through which the liquid is supplied from an unillustrated liquid feed pump is connected to the liquid pool 24 disposed inside the support member 18, and the liquid droplet ejecting head 10 is formed.
In
As shown in
A flow path member 40 is disposed on the opposite side of the beam member 14 in the ejection direction (the back side of the beam member 14), and a blowing path 44 is formed between the flow path member 40 and the beam member 14. The blowing path 44 is communicated with the blowing component such that air that has been pressurized is fed through the blowing path 44 as indicated by arrow 43.
A filter 48 is disposed as the filtering component inside the blowing path 44 and filters the air that is fed through the blowing path 44. Moreover, a humidifying component 46 such as a sponge that is capable of holding a liquid is disposed inside the blowing path 44 and humidifies the air that is fed through the blowing path 44 with solvent component of the liquid L.
The liquid flow path 13 becomes a suction path 113 after passing the nozzle 16 and is communicated with the suction component such that negative pressure is applied thereto. Some of the air that has been fed as indicated by arrow 43 proceeds toward the suction path 113 as indicated by arrow 45A in a liquid pool 100 and is sucked out and removed together with the surplus liquid L as indicated by arrow 41.
On the other hand, some of the air does not proceed from the liquid pool 100 toward the suction path 113 but is returned back to the blowing component through an air circulation path as indicated by arrow 45B. Moreover, the air is fed from the blowing component to the blowing path 44 and is again sent to the liquid pool 100 as indicated by arrow 43. By configuring the liquid droplet ejecting head 110 in this manner, the liquid droplet ejecting head 110 has a configuration where, in comparison to a configuration where the liquid pool 100 merely opens to the atmosphere, there is little incorporation of dirt and foreign matter because air that has been filtered by the filter 48 is always fed. Further, drying of the liquid in the vicinity of the nozzle 16 can be suppressed.
In
As shown in
A flow path member 40A is disposed on the opposite side of the beam member 14 in the ejection direction (the back side of the beam member 14), and a blowing path 44A is formed between the flow path member 40A and the beam member 14. The blowing path 44A is communicated with the blowing component such that air that has been pressurized is fed through the blowing path 44A as indicated by arrow 43A.
A filter 48A is disposed as the filtering component inside the blowing path 44A and filters the air that is fed through the blowing path 44A. Moreover, a humidifying component 46A such as a sponge that is capable of holding a liquid is disposed inside the blowing path 44A and humidifies the air that is fed through the blowing path 44A with solvent component of the liquid L.
The liquid flow path 13 becomes the suction path 113 after passing the nozzle 16 and is communicated with the suction component such that negative pressure is applied thereto. Air that has been fed as indicated by arrow 43A proceeds toward the suction path 113 as indicated by arrow 45 in a liquid pool 100 and is sucked out and removed together with the surplus liquid L as indicated by arrow 41A.
Further, a flow path member 40B is disposed on the ejection direction side of the beam member 14 (the front side of the beam member 14), and a blowing path 44B is formed between the flow path member 40B and the beam member 14. The blowing path 44B is also communicated with the blowing component such that air that has been pressurized is fed through the blowing path 44B as indicated by arrow 43B.
Moreover, a suction path 42B is formed between the flow path member 40B and the flow path member 12 on the downstream side of the nozzle 16 in the blowing direction, and the suction path 42B sucks out air that has been fed thereto. This suction path 42B is communicated with the negative pressure generating component (a suction pump or the like) such that negative pressure is applied thereto, so the suction path 42B sucks out and removes air and the liquid L that has spilled over in the ejection direction in the vicinity of the nozzle 16, as indicated by arrow 41B.
An opening 416 that is larger than the nozzle 16 as seen from the ejection direction is disposed in the flow path member 40B and does not obstruct the ejection of the liquid droplet 2 from the nozzle 16. Moreover, a filter 48B is also disposed as the filtering component inside the blowing path 44B and filters the air that is fed through the blowing path 44B. Moreover, a humidifying component 46B such as a sponge that is capable of holding a liquid is also disposed inside the blowing path 44B and humidifies the air that is fed through the blowing path 44B with solvent component of the liquid L.
By configuring the liquid droplet ejecting head 111 in this manner, the liquid droplet ejecting head 111 has a configuration where, in comparison to a configuration where the liquid pool 100 merely opens to the atmosphere, there is little incorporation of dust and foreign matter because air that has been filtered by the filter 48A is always fed, and, drying of the liquid in the vicinity of the nozzle 16 can be suppressed. Moreover, it is difficult for the liquid L to adhere in the vicinity of the nozzle 16.
In
The liquid droplet ejecting head 112 pertaining to the fifth exemplary embodiment of the invention has a structure where, as shown in
The suction path 42C is communicated with a suction component such that negative pressure is applied thereto. The suction path 42C opens in the vicinity of the liquid pool 100 that is formed on the opposite side of the nozzle 16 in the ejection direction, and the suction path 42C sucks out and removes the surplus liquid L. By configuring the liquid droplet ejecting head 112 in this manner, the liquid L can be supplied from both end sides of the liquid flow path 13 toward the nozzle 16. Further, in this configuration, when the liquid L is supplied only from one end side of the liquid flow path 13 toward the nozzle 16, the suction path 42C can be disposed on the ejection surface side (front side) and on the opposite side of the ejection surface (back side), which is superior in terms of the dischargeability of the surplus liquid L in comparison to each of the preceding exemplary embodiments.
<Opening Position>
In
In a case where the opening size of the nozzle 16 is 50 μm, when a size d1 of the opening 116 is equal to or less than 100 μm, as shown in
In a case where the opening diameter of the nozzle 16 is 25 μm, when suction is not performed and the liquid L is capillary-supplied without back pressure being applied thereto, there are no problems in terms of ejectability only in a case where, as shown in
In a case where back pressure is applied to the liquid L and suction is performed by the suction path 113, when the size of the opening 116 is equal to or less than 100 μm, as shown in
When the size of the opening 116 is about 150 μm, as shown in
Thus, the charts in
As shown in
<Other>
The present invention is not limited to the preceding exemplary embodiments. For example, in each of the preceding exemplary embodiments, there has been exemplified a configuration where the suction path 113 and the blowing path 44 are disposed for each of the nozzles 16, but the present invention is not limited to this and may also be configured such that the suction path 113 and the blowing path 44 are disposed for each plurality (e.g., two or four) of the nozzles 16. At this time, as long as the nozzles 16 are disposed evenly with respect to the suction path 113 and the blowing path 44, it is easy for the liquid film to be made uniform.
Further, the liquid droplet ejecting head in the exemplary embodiments has been described by way of an inkjet recording head, but the liquid droplet ejecting head is not invariably limited to recording characters and images on recording paper using ink. That is, the recording medium is not limited to paper, and the liquid that is ejected is also not limited to ink. For example, it is possible to apply the present invention to all liquid droplet jetting apparatus that are used for industrial purposes, such as apparatus that eject a liquid onto polymer film or glass to create color filters for displays or apparatus that eject liquid-solder onto a substrate to form bumps for mounting parts.
Number | Date | Country | Kind |
---|---|---|---|
2008-322133 | Dec 2008 | JP | national |