This disclosure relates to a liquid ejection head, a liquid ejection module, and a method of manufacturing a liquid ejection head.
Japanese Patent Laid-Open No. H06-305143 discloses a liquid ejection unit configured to bring a liquid serving as an ejection medium and a liquid serving as a bubbling medium into contact with each other at an interface, and to eject the ejection medium along with growth of a bubble generated in the bubbling medium as a consequence of imparting thermal energy. Japanese Patent Laid-Open No. H06-305143 also discloses formation of a flow by applying a pressure to one or both of the ejection medium and the bubbling medium.
However, Japanese Patent Laid-Open No. H06-305143 lacks a detailed description of a configuration of a confluence unit for the two types of liquids. Accordingly, depending on the shape of an inflow portion for a liquid to flow into a liquid flow passage inclusive of a pressure chamber, an interface may be formed across which the bubbling medium and the ejection medium flow side by side in a width direction (horizontal direction) orthogonal to a direction of flow of the liquids in the liquid flow passage. In this case, there is a risk of unstable ejection of the liquid serving as the ejection medium because the liquid serving as the ejection medium may fail to come into contact with an ejection port.
In view of the above circumstances, this disclosure aims to stabilize ejection of a liquid serving as an ejection medium by causing a liquid serving as a bubbling medium and the liquid serving as the ejection medium to flow while being arranged in a height direction in a pressure chamber, the height direction being a direction of ejection of the liquid serving as the ejection medium from an ejection port.
A liquid ejection head according to an aspect of this disclosure includes a substrate including a pressure generating element configured to apply pressure to a first liquid, a member provided with an ejection port configured to eject a second liquid, a pressure chamber including the ejection port and the pressure generating element, and a liquid flow passage which is formed by using the substrate and the member stacked on the substrate, includes the pressure chamber, and extends at least in a direction of flow of the first liquid and the second liquid. The substrate includes a first inflow port located on an upstream side of the pressure chamber in the direction of flow of the liquids in the liquid flow passage and configured to allow the first liquid to flow into the liquid flow passage, a second inflow port located on the upstream side of the first inflow port and configured to allow the second liquid to flow into the liquid flow passage, and a lateral wall extending in a direction of extension of the liquid flow passage, at least part of the lateral wall being located above the first inflow port. In the pressure chamber, the first liquid flows in contact with the pressure generating element and the second liquid flows closer to the ejection port than the first liquid does.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Now, liquid ejection heads and liquid ejection apparatuses according to embodiments of this disclosure will be described below with reference to the drawings.
(Configuration of Liquid Ejection Head)
Given the liquid ejection head 1 formed by the multiple arrangement of the liquid ejection modules 100 in a longitudinal direction as described above, even if a certain one of the ejection elements causes an ejection failure, only the liquid ejection module involved in the ejection failure needs to be replaced. Thus, it is possible to improve a yield of the liquid ejection heads 1 during a manufacturing process thereof, and to reduce costs for replacing the head.
(Configuration of Liquid Ejection Apparatus)
A liquid circulation unit 504 is a unit configured to circulate and supply the liquid to the liquid ejection head 1 and to conduct flow rate control of the liquid in the liquid ejection head 1. The liquid circulation unit 504 includes a sub-tank to store the liquid, a flow passage for circulating the liquid between the sub-tank and the liquid ejection head 1, pumps, a valve mechanism, and so forth. Hence, under the instruction of the CPU 500, the liquid circulation unit 504 controls the pumps and the valve mechanism such that the liquid flows in the liquid ejection head 1 at a predetermined flow rate.
(Configuration of Element Board)
Pressure generating elements 12 (not shown in
The multiple liquid flow passages 13 which extend in the y direction and are connected to the ejection ports 11, respectively, are formed in the orifice plate 14. Meanwhile, the liquid flow passages 13 arranged in the x direction are connected to a first common supply flow passage 23, a first common collection flow passage 24, a second common supply flow passage 28, and a second common collection flow passage 29 in common. Flows of liquids in the first common supply flow passage 23, the first common collection flow passage 24, the second common supply flow passage 28, and the second common collection flow passage 29 are controlled by the liquid circulation unit 504 described with reference to in
(Configurations of Liquid Flow Passage and Pressure Chamber)
The substrate 15 corresponding to a bottom portion of the liquid flow passage 13 includes a second inflow port 21, a first inflow port 20, a first outflow port 25, and a second outflow port 26, which are formed in this order in the y direction. Moreover, the pressure chamber 18 including the ejection port 11 and the pressure generating element 12 is located substantially at the center between the first inflow port 20 and the first outflow port 25 in the liquid flow passage 13. The second inflow port 21 is connected to the second common supply flow passage 28, the first inflow port 20 is connected to the first common supply flow passage 23, the first outflow port 25 is connected to the first common collection flow passage 24, and the second outflow port 26 is connected to the second common collection flow passage 29, respectively (see
Under the above-described configuration, a first liquid 31 supplied from the first common supply flow passage 23 to the liquid flow passage 13 through the first inflow port 20 flows in the y direction (a direction indicated with arrows), then passes through the pressure chamber 18 and is collected by the first common collection flow passage 24 through the first outflow port 25. Meanwhile, a second liquid 32 supplied from the second common supply flow passage 28 to the liquid flow passage 13 through the second inflow port 21 flows in the y direction (the direction indicated with arrows), then passes through the pressure chamber 18 and is collected by the second common collection flow passage 29 through the second outflow port 26. In other words, both of the first liquid and the second liquid flow in the y direction in a section of the liquid flow passage 13 between the first inflow port 20 and the first outflow port 25. In the pressure chamber 18, the pressure generating element 12 is in contact with the first liquid 31 while the second liquid 32 exposed to the atmosphere forms a meniscus in the vicinity of the ejection port 11. The first liquid 31 and the second liquid 32 flow in the pressure chamber 18 such that the pressure generating element 12, the first liquid 31, the second liquid 32, and the ejection port 11 are arranged in this order. Specifically, assuming that the pressure generating element 12 is located on a lower side and the ejection port 11 is located on an upper side, the second liquid 32 flows above the first liquid 31. Moreover, the first liquid 31 is pressurized by the pressure generating element 12 located below and at least the second liquid 32 is ejected upward from the bottom. Note that this up-down direction corresponds to a height direction of the pressure chamber 18 and of the liquid flow passage 13.
In this embodiment, flow rates of the first liquid 31 and of the second liquid 32 are adjusted in accordance with physical properties of the first liquid 31 and the second liquid 32 such that the first liquid 31 and the second liquid 32 flow in contact with each other in the pressure chamber as shown in
In the case of the parallel flows, it is preferable to keep an interface between the first liquid 31 and the second liquid 32 from being disturbed, or in other words, to establish a state of laminar flows inside the pressure chamber 18 with the flows of the first liquid 31 and the second liquid 32. Specifically, in the case of an attempt to control an ejection performance so as to maintain a predetermined amount of ejection, for instance, it is preferable to drive the pressure generating element in a state where the interface is stable. Nevertheless, this embodiment is not limited only to this configuration. Even if the interface between the two liquids in the pressure chamber 18 gets unstable a little, the pressure generating element 12 may still be driven in a state where at least the first liquid flows mainly on the pressure generating element 12 side and the second liquid flows mainly on the ejection port 11 side. The following description will be mainly focused on the example where the flows in the pressure chamber are in the state of parallel flows and in the state of laminar flows.
(Conditions to Form Parallel Flows in Concurrence with Laminar Flows)
Conditions to form laminar flows of liquids in a tube will be described to begin with. The Reynolds number Re to represent a ratio between viscous force and interfacial tension has been generally known as a flow evaluation index.
Now, a density of a liquid is defined as ρ, a flow velocity thereof is defined as u, a representative length thereof is defined as d, and a viscosity is defined as η. In this case, the Reynolds number Re can be expressed by the following (formula 1):
Re=ρud/η (formula 1).
Here, it is known that the laminar flows are more likely to be formed as the Reynolds number Re becomes smaller. To be more precise, it is known that flows inside a circular tube are formed into laminar flows in the case where the Reynolds number Re is smaller than some 2200 and the flows inside the circular tube become turbulent flows in the case where the Reynolds number Re is larger than some 2200, for example.
In the case where the flows are formed into the laminar flows, flow lines become parallel to a traveling direction of the flows without crossing each other. Accordingly, in the case where the two liquids in contact constitute the laminar flows, the liquids can form the parallel flows with the stable interface between the two liquids. Here, in view of a general inkjet printing head, a height H [μm] of the flow passage (the height of the pressure chamber) in the vicinity of the ejection port in the liquid flow passage (the pressure chamber) is in a range from about 10 to 100 μm. In this regard, in the case where water (density ρ=1.0×103 kg/m3, viscosity η=1.0 cP) is fed to the liquid flow passage of the inkjet printing head at a flow velocity of 100 mm/s, the Reynolds number Re turns out to be Re=ρud/η≈0.1˜1.0<<2200. As a consequence, the laminar flows can be deemed to be formed therein.
Here, even if the liquid flow passage 13 and the pressure chamber 18 have rectangular cross-sections as shown in
(Theoretical Conditions to Form Parallel Flows in State of Laminar Flows)
Next, conditions to form the parallel flows with the stable interface between the two types of liquids in the liquid flow passage 13 and the pressure chamber 18 will be described with reference to
Here, as for boundary conditions in the liquid flow passage 13 and the pressure chamber 18, velocities of the liquids on wall surfaces of the liquid flow passage 13 and the pressure chamber 18 are assumed to be zero. Moreover, velocities and shear stresses of the first liquid 31 and the second liquid 32 at the liquid-liquid interface are assumed to have continuity. Based on the assumption, if the first liquid 31 and the second liquid 32 form two-layered and parallel steady flows, then a quartic equation as defined in the following (formula 2) holds true in a section of the parallel flows:
(η1−η2)(η1Q1+η2Q2)h14+2η1H{η2(3Q1+Q2)−2η1Q1}h13+3η1H2{2η1Q1−η2(3Q1+Q2)}h12+4η1Q1H3(η2−η1)h1+η12Q1H4=0 (formula 2).
In the (formula 2), η1 represents the viscosity of the first liquid 31, η2 represents the viscosity of the second liquid 32, Q1 represents the flow rate of the first liquid 31, and Q2 represents the flow rate of the second liquid 32, respectively. In other words, the first liquid and the second liquid flow so as to establish a positional relationship in accordance with the flow rates and the viscosities of the respective liquids within such ranges to satisfy the above-mentioned quartic equation (formula 2), thereby forming the parallel flows with the stable interface. In this embodiment, it is preferable to form the parallel flows of the first liquid and the second liquid in the liquid flow passage 13 or at least in the pressure chamber 18. In the case where the parallel flows are formed as mentioned above, the first liquid and the second liquid are only involved in mixture due to molecular diffusion on the liquid-liquid interface therebetween, and the liquids flow in parallel in the y direction virtually without causing any mixture. Note that the flows of the liquids do not always have to establish the state of laminar flows in a certain region in the pressure chamber 18. In this context, at least the flows of the liquids in a region above the pressure generating element preferably establish the state of laminar flows.
Even in the case of using immiscible solvents such as oil and water as the first liquid and the second liquid, for example, the stable parallel flows are formed regardless of the immiscibility as long as the (formula 2) is satisfied. Meanwhile, even in the case of oil and water, if the interface is disturbed due to a state of slight turbulence of the flows in the pressure chamber, it is preferable that at least the first liquid flows mainly above the pressure generating element and the second liquid flows mainly in the ejection port.
Here, as for the water phase thickness ratio hr=h1/(h1+h2), the parallel flows of the first liquid and the second liquid are presumably formed in the liquid flow passage (the pressure chamber) as long as 0<hr<1 (condition 1) is satisfied. However, as described later, the first liquid is caused to function mainly as the bubbling medium while the second liquid is caused to function mainly as the ejection medium so as to stabilize a ratio between the first liquid end and the second liquid contained in ejected droplets to a desired value. In consideration of this situation, the water phase thickness ratio hr is preferably set equal to or below 0.8 (condition 2) or more preferably set equal to or below 0.5 (condition 3).
Note that status A, status B, and status C shown in
Status A) the water phase thickness ratio hr=0.50 in a case where the viscosity ratio ηr=1 and the flow rate ratio Qr=1;
Status B) the water phase thickness ratio hr=0.39 in a case where the viscosity ratio ηr=10 and the flow rate ratio Qr=1; and
Status C) the water phase thickness ratio hr=0.12 in a case where the viscosity ratio ηr=10 and the flow rate ratio Qr=10.
(Flows at Liquid-Liquid Interface During Ejection)
As the first liquid and the second liquid flow severally, a liquid level (the liquid-liquid interface) is formed at a position corresponding to the viscosity ratio ηr and the flow rate ratio Qr therebetween (corresponding to the water phase thickness ratio hr). If the liquids are successfully ejected from the ejection port 11 while maintaining the position of the interface, then it is possible to achieve a stable ejection operation. The following are two possible configurations for achieving the stable ejection operation:
Configuration 1: a configuration to eject the liquids in a state where the first liquid and the second liquid are flowing; and
Configuration 2: a configuration to eject the liquids in a state where the first liquid and the second liquid are at rest.
The configuration 1 makes it possible to eject the liquids stably while maintaining the given position of the interface. This is due to a reason that an ejection velocity (several meters per second to more than ten meters per second) of a droplet in general is faster than flow velocities (several millimeters per second to several meters per second) of the first liquid and the second liquid, and the ejection of the liquids is affected little even if the first liquid and the second liquid are kept flowing during the ejection operation.
In the meantime, the status 2 also makes it possible to eject the liquids stably while maintaining the given position of the interface. This is due to a reason that the first liquid and the second liquid are not mixed immediately due to a diffusion effect on the liquids on the interface, and an unmixed state of the liquids is maintained for a very short period of time. During a period of several tens of microseconds at a general inkjet driving frequency in a case where a low-molecular material in water has a typical diffusion coefficient of D=10−9 m2/s, the liquids are diffused in a distance of only 0.2 to 0.3 μm. Accordingly, the interface is maintained in the state where the flows of the liquids are stopped to rest immediately before ejecting the liquids. Thus, it is possible to eject the liquid while maintaining the position of the interface therebetween.
However, the configuration 1 is preferable because this configuration can reduce adverse effects of mixture of the first and second liquids due to the diffusion of the liquids on the interface and because it is not necessary to conduct advanced control for flowing and stopping the liquids.
(Ejection Modes of Liquids)
A percentage of the first liquid contained in droplets ejected from the ejection port (ejected droplets) can be changed by adjusting the position of the interface (corresponding to the water phase thickness ratio hr). Such ejection modes of the liquids can be broadly categorized into two modes depending on types of the ejected droplets:
Mode 1: a mode of ejecting only the second liquid; and
Mode 2: a mode of ejecting the second liquid inclusive of the first liquid.
The mode 1 is effective, for example, in a case of using a liquid ejection head of a thermal type that employs an electrothermal converter (a heater) as the pressure generating element 12, or in other words, in a case of using a liquid ejection head that utilizes a bubbling phenomenon that depends heavily on properties of a liquid. This liquid ejection head is prone to destabilize bubbling of the liquid due to a scorched portion of the liquid developed on a surface of the heater. The liquid ejection head also has a difficulty in ejecting some types of liquids such as non-aqueous inks. However, if a bubbling agent that is suitable for bubble generation and is less likely to develop scorch on the surface of the heater is used as the first liquid and any of functional agents having a variety of functions is used as the second liquid by adopting the mode 1, it is possible to eject the liquid such as a non-aqueous ink while suppressing the development of the scorch on the surface of the heater.
The mode 2 is effective for ejecting a liquid such as a high solid content ink not only in the case of using the liquid ejection head of the thermal type but also in a case of using a liquid ejection head that employs a piezoelectric element as the pressure generating element 12. To be more precise, the mode 2 is effective in the case of ejecting a high-density pigment ink having a large content of a pigment being a coloring material onto a printing medium. In general, by increasing the density of the pigment in the pigment ink, it is possible to improve chromogenic properties of an image printed on a printing medium such as plain paper by use of the high-density pigment ink. Moreover, by adding a resin emulsion (resin EM) to the high-density pigment ink, it is possible to improve abrasion resistance and the like of a printed image owing to the resin EM formed into a film. However, an increase in solid component such as the pigment and the resin EM tends to develop agglomeration at a close interparticle distance, thus causing deterioration in dispersibility. Accordingly, it is difficult to disperse each of the pigment and the resin EM into the ink at a high density. The pigment is especially harder to disperse than the resin EM. For this reason, the pigment and the resin EM have heretofore been dispersed by reducing the amount of one of them. To be more precise, the pigment and the resin EM have been dispersed by setting ratios of the pigment and the resin EM contained in the ink, for example, to 4 wt % and 15 wt % or to 8 wt % and 4 wt %, respectively.
However, by adopting the above-described mode 2, it is possible to use the high-density resin EM ink as the first liquid and to use the high-density pigment ink as the second liquid. In this way, each of the pigment ink and the resin EM ink can be ejected at a high density. As a consequence, it is possible to deposit the high-density pigment ink and the high-density resin EM ink on the printing medium, thereby printing a high-quality image that can be hardly achievable with a single ink, or in other words, an image with good chromogenic properties, excellent abrasion resistance, and the like. Specifically, the use of the mode 2 makes it possible to deposit the high-density pigment at a density in a range from 8 to 12 wt % and the high-density resin EM at a density in a range from 15 to 20 wt %, for example, on the printing medium, respectively.
(Configuration of Confluence Unit on Inflow Side)
A length of the first inflow port 20 in a direction (hereinafter referred to as a width direction) orthogonal to a direction of flow of the liquids in the pressure chamber 18 (a direction of arrows in
In the meantime, the second liquid 32 is in a state of velocity distribution u2 on an upstream side of the first inflow port 20 in the liquid flow passage 13 in the direction of flow of the liquids. The second liquid 32 having the velocity distribution u2 joins the first liquid 31 having velocity distribution u1. The first liquid 31 in the liquid flow passage 13 is less likely to flow between each wall surface 141 of the liquid flow passage 13 and the first inflow port 20. Hence, the second liquid 32 flows between each wall surface 141 and the first inflow port 20. For this reason, the second liquid 32 flows in such a way as to sandwich the first liquid 31. Accordingly, it is more likely that the liquid-liquid interface is formed in such a way as to arrange the first liquid 31 and the second liquid 32 in the horizontal direction (the width direction) in the liquid flow passage 13.
The second liquid 32 and the first liquid 31 flow to the pressure chamber 18 while maintaining the state in which the liquid-liquid interface is formed in such a way as to arrange the first liquid 31 and the second liquid 32 in the horizontal direction (the width direction) of the liquid flow passage 13. In other words, the first liquid 31 and the second liquid 32 do not form parallel flows that are stacked in the height direction of the liquid flow passage 13.
In the case where the liquid-liquid interface is formed as shown in
In this embodiment, a lateral wall (a wall) 51 is provided in such a way as to be opposed to the first inflow port 20. A length in the width direction of the lateral wall 51 of this embodiment is equal to the length W in the width direction of the liquid flow passage. The equality mentioned here does not always have to be strictly equal. The lengths may be deemed equal as long as the lengths are substantially the same after taking into account a manufacturing error and other allowable differences. The lateral wall 51 extends in a direction of extension of the liquid flow passage and at least part of the lateral wall is located above the first inflow port. A basic function of the lateral wall 51 is to separate the flows of the liquids in the liquid flow passage 13 into a flow that flows on an upper flow passage 132 out of the flow passage between the lateral wall 51 and the orifice plate 14 and into a flow that flows on a lower flow passage 131 out of the flow passage between the lateral wall 51 and the substrate 15. The liquids flowing on the upper flow passage 132 and the lower flow passage 131 join together at an end portion on a downstream side of the lateral wall 51 in the direction of flow of the liquids. The liquids flowing on the upper flow passage 132 and the lower flow passage 131 form parallel flows stacked in the height direction of the liquid flow passage 13 thanks to the presence of the lateral wall 51. For this reason, even in the case where the first liquid 31 and the second liquid 32 join together at the end portion of on the downstream side of the lateral wall 51 in the direction of flow of the liquids, the liquid-liquid interface is stably formed such that the first liquid 31 and the second liquid 32 are arranged in the height direction of the liquid flow passage 13 (the vertical direction). As a consequence, the first liquid 31 and the second liquid 32 can also flow in the pressure chamber 18 while maintaining the interface as shown in
(Concerning Liquids Flowing on Upper Flow Passage and Lower Flow Passage)
Now, some examples of this embodiment will be described involving various states of the liquids flowing on the upper flow passage 132 and the lower flow passage 131.
Accordingly, a flow of the first liquid 31 can also be created in a region between the first inflow port 20 and each wall surface 141 of the liquid flow passage 13 by adjusting the flow rate of the first liquid 31 or the second liquid 32. In other words, in this embodiment, it is possible to fill the lower flow passage 131 with the first liquid 31 by adjusting the flow rate of the first liquid 31. As a consequence, the second liquid 32 is more likely to flow on the upper flow passage 132. In this case, the first liquid 31 flows along the lower flow passage 131 while the second liquid 32 flows along the upper flow passage 132, and the first liquid 31 and the second liquid 32 join together at the end portion on the downstream side of the lateral wall 51.
Next, a description will be given of two more examples in which only the second liquid 32 flows on the upper flow passage 132 whereas the second liquid 32 as well as the first liquid 31 flow on the lower flow passage 131 because of a low flow rate of the first liquid 31 or a high flow rate of the second liquid 32.
Lastly, a description will be given of another example of this embodiment in which the first liquid 31 flows on the upper flow passage 132 in addition to the second liquid 32 thereon due to a high flow rate of the first liquid 31 whereas only the first liquid 31 flows on the lower flow passage 131.
As described above, the presence of the lateral wall 51 makes the first liquid 31 flow while spreading in the width direction of the liquid flow passage such that the first liquid 31 is located above the heater. Thus, it is more likely that the liquid-liquid interface is formed such that the first liquid 31 and the second liquid 32 flow in the z direction in the liquid flow passage 13 while being stacked on each other. Even in a case where any of flow rates and physical properties of the first liquid 31 and the second liquid 32 is changed, the lateral wall 51 can create the liquid-liquid interface such that the first liquid 31 flows in contact with the pressure generating element 12 and that the second liquid 32 is present in the vicinity of the ejection port 11. As a consequence, it is possible to stably generate a bubble of the first liquid 31 with the pressure generating element 12 and to eject the second liquid 32.
(Length of Lateral Wall)
In order to cause the second liquid 32 to flow on the upper flow passage 132 and to cause the first liquid 31 to flow on the lower flow passage 131, it is preferable to set the second clearance C2 on the downstream side of the lateral wall 51 to C2≥0.
In the case where the second clearance on the downstream side of the lateral wall 51 satisfies C2<0, then there is a region where the lateral wall 51 is not provided at a position opposed to the first inflow port 20. In the region without the lateral wall 51 at the position opposed to the first inflow port 20, the first liquid 31 discharged from the first inflow port 20 directly joins the second liquid 32 without colliding against the lateral wall 51, and then flows in the liquid flow passage 13 as with the aforementioned comparative example. The effect of the lateral wall 51 is therefore diminished. As a consequence, a liquid-liquid interface that renders an arrangement of the first liquid 31 and the second liquid 32 in the width direction (the x direction) of the liquid flow passage 13 is apt to be formed as with the comparative example of
In the case where the first clearance C1 of the lateral wall 51 satisfies C1<0, the first liquid 31 discharged from the first inflow port 20 is more likely to flow on the upper flow passage 132 as compared to the case of C1>0 in
As described above, even in the case where the first clearance C1 of the lateral wall 51 satisfies C1<0, it is still possible to cause the first liquid 31 to flow in contact with the pressure generating element 12 in the pressure chamber 18 and to form the liquid-liquid interface such that the second liquid 32 is present in the vicinity of the ejection port 11. As a consequence, it is possible to stably generate a bubble of the first liquid 31 with the pressure generating element 12 and to eject the second liquid 32. However, it is more likely that the first liquid 31 is included in the liquid to be ejected from the ejection port 11 in the case where the first clearance C1 of the lateral wall 51 satisfies C1<0 as compared to the case where the first clearance C1 satisfies C1≥0.
(Width of Lateral Wall)
As described above, according to this embodiment, it is possible to stably form the liquid-liquid interface such that the first liquid 31 and the second liquid 32 flow side by side in the height direction (the z direction) in the pressure chamber 18. Accordingly, the first liquid 31 comes into contact with the pressure generating element 12 while the second liquid 32 is present on the ejection port side. Thus, it is possible to eject the second liquid 32 by generating a bubble of the first liquid 31 with the pressure generating element 12.
Here, any of the first liquid and the second liquid flowing in the pressure chamber 18 may be circulated between the pressure chamber 18 and an outside unit. If the circulation is not conducted, a large amount of any of the first liquid and the second liquid having formed the parallel flows in the liquid flow passage 13 and the pressure chamber 18 but having not been ejected would come into being. Accordingly, the circulation of the first liquid and the second liquid with the outside units makes it possible to use the liquids that have not been ejected for the purpose of forming the parallel flows again.
(Specific Examples of First Liquid and Second Liquid)
According to the configuration of the embodiment described above, the main functions required in the first liquid and the second liquid are clarified. Specifically, the first liquid may typically be the bubbling medium for developing the film boiling while the second liquid may typically be the ejection medium to be ejected to the atmosphere. The configuration of this embodiment can improve the degree of freedom of components to be contained in the first liquid and the second liquid as compared to the related art. Now, the bubbling medium (the first liquid) and the ejection medium (the second liquid) in this configuration will be described below in detail based on specific examples.
For instance, the bubbling medium (the first liquid) of this embodiment is required to have a high critical pressure to enable development of the film boiling in the media upon heat generation of the electrothermal converter and a rapid growth of the bubble thus generated, or in other words, to enable efficient transformation of thermal energy into bubbling energy. Water is suitable for such a medium in particular. Water has the high boiling point (100° C.) and the high surface tension (58.85 dyne/cm at 100° C.) despite its small molecular weight of 18, and therefore has a high critical pressure of about 22 MPa. In other words, water also exhibits an extremely large bubbling pressure at the time of film boiling. In general, an inkjet printing apparatus adopting the mode of ejecting an ink by use of the film boiling favorably uses an ink prepared by causing water to contain a coloring material such as a dye and a pigment.
Nevertheless, the bubbling medium is not limited to water. Any other substances may function as the bubbling medium as long as such a substance has the critical pressure equal to or above 2 MPa (or preferably equal to or above 5 MPa). Examples of the bubbling medium other than water include methyl alcohol and ethyl alcohol. It is also possible to use a mixture of any of these liquids with water. Meanwhile, it is also possible to use a medium prepared by adding the aforementioned coloring material such as a dye and a pigment, an additive, and the like to water.
On the other hand, the physical properties to enable the film boiling as in the case of the bubbling medium is not required in the ejection medium (the second liquid) of this embodiment, for example. In the meantime, adhesion of a scorched material onto the electrothermal converter (the heater) may deteriorate the bubbling efficiency due to damage on flatness of a heater surface or deterioration in heat conductivity. Nonetheless, the ejection medium does not come into contact directly with the heater and therefore does not bring about any scorched component on the heater. In other words, the ejection medium of this embodiment is exempted from the physical conditions required for developing the film boiling and for avoiding the scorch as the relevant conditions required in a conventional ink for a thermal head, whereby the degree of freedom of the components is improved. As a consequence, the ejection medium can more actively contain components suitable for applications after the ejection.
For example, the pigment that has heretofore been unused because it was easily scorched on the heater may be more actively contained in the ejection medium in this embodiment. In the meantime, a liquid other than an aqueous ink, which has an extremely low critical pressure, can also be used as the ejection medium in this embodiment. Moreover, it is also possible to use various inks having special functions which can hardly be handled by the conventional thermal head, such as an ultraviolet curable ink, an electrically conductive ink, an electron-beam (EB) curable ink, a magnetic ink, and a solid ink, can also be used as the ejection media. In the meantime, the liquid ejection head of this embodiment can also be used in various applications other than image formation by using any of blood, cells in culture, and the like as the ejection media. The liquid ejection head is also adaptable to other applications including biochip fabrication, electronic circuit printing, and so forth. Since there are no restrictions regarding the second liquid, the second liquid may adopt the same liquid as one of those cited as the examples of the first liquid. For instance, even if both of the two liquids are inks each containing a large amount of water, it is still possible to use one of the inks as the first liquid and the other ink as the second liquid depending on situations such as a mode of usage.
This embodiment describes another mode of the liquid ejection head 1 in which the first liquid 31 and the second liquid 32 flow in the pressure chamber 18 while being stacked on each other in the height direction (the vertical direction). This embodiment will be described while being mainly focused on different features from those of the first embodiment. In this context, the features not specifically mentioned in this embodiment should be regarded the same as those in the first embodiment.
(Relation Between Water Phase Thickness and Confluence Wall)
As shown in
Moreover, the confluence wall 41 is provided with a projection 43 (a lateral wall) that projects downstream in the direction of flow of the liquids. The confluence wall 41 and the projection 43 are integrally formed and the projection 43 is formed to be opposed to the first inflow port 20. Since the confluence wall 41 is disposed on the upstream side of the first inflow port 20, the confluence wall 41 blocks the second liquid 32 from flowing into the lower flow passage 131. Accordingly, a large flow of the first liquid 31 as compared to the case of not installing the confluence wall 41 is created between the first inflow port 20 and each of the wall surfaces of the liquid flow passage 13 located on the right and left sides in the direction of flows in the liquid flow passage 13. As a consequence, the first liquid 31 flows on the lower flow passage 131 and the second liquid 32 flows on the upper flow passage 132 thanks to the confluence wall 41. Here, as shown in
(Relation Between Water Phase Thickness and Projecting Amount of Projection)
The state of the clearance C3 equal to or above 0 (C3≥0) representing a configuration to entirely cover the first inflow port 20 is preferable from the viewpoint of forming the liquid-liquid interface such that the first liquid 31 and the second liquid 32 flow in the pressure chamber 18 while being stacked on each other in the vertical direction. In the case where the clearance C3 of the projection 43 is negative (C3<0) as shown in
The water phase thickness hr is constant in the case where the viscosity ratio and the flow rate ratio are constant. Accordingly, the thickness h1 of the phase of the first liquid 31 maintains a constant thickness as long as the length in the height direction of the liquid flow passage 13 is the same. For this reason, the thicknesses h1 of the phase of the first liquid 31 in the pressure chamber 18 are the same among the configurations of the projection 43 in
In the case where a printing medium having functions necessary for print formation is used for the second liquid 32 and water serving as the bubbling medium is used for the first liquid 31 so as to enable stable ejection of the second liquid 32, the second liquid 32 has a larger viscosity than that of the first liquid 31. It is preferable to increase the supply of the second liquid 32 in this case. As the confluence wall height b becomes larger, the length in the height direction of the upper flow passage 132 located above the confluence wall 41 becomes smaller. Hence, the flow rate of the second liquid 32 flowing on the upper flow passage 132 is limited in this case. Accordingly, a configuration with a small confluence wall height b is preferred in the case of using the printing medium having the functions necessary for print formation for the second liquid 32 and using water serving as the bubbling medium for the first liquid 31.
As described above, this embodiment can also form the liquid-liquid interface such that the first liquid 31 and the second liquid 32 flow in the pressure chamber 18 while being arranged in the height direction (the vertical direction). Accordingly, the first liquid 31 comes into contact with the pressure generating element 12 and the second liquid 32 is present on the ejection port side. As a consequence, it is possible to generate a bubble of the first liquid 31 with the pressure generating element 12 and thus to eject the second liquid 32.
(First Manufacturing Method)
As shown in
Next, as shown in
Next, as shown in
Next, as shown in
Next, a second covering layer 170 is deposited as shown in
Next, as shown in
Next, the first pattern 110, the second pattern 140, and the unexposed portion 122 of the first covering layer 120 are removed as shown in
As described above, according to this manufacturing method, the unexposed portion 122 of the first covering layer 120 is not developed at the time of deposition of the first covering layer 120. Thus, the second pattern 140 can be deposited on the unexposed portion 122 of the first covering layer 120. In this way, the second pattern 140 can be deposited flatly while preventing the second pattern 140 from sagging. Moreover, the second covering layer 170 that constitutes part of the orifice plate can be deposited on the flatly deposited second pattern 140. Accordingly, it is possible to suppress the development of a height difference on the orifice plate and to reduce the thickness distribution thereof. As a consequence, it is possible to manufacture the element board for the inkjet printing head with reduced height differences among the ejection ports.
Meanwhile, the second liquid 32 flows in the liquid flow passage 13 while being in contact with the orifice plate. In this way, the second liquid 32 can flow in the liquid flow passage 13 as a laminar flow thanks to the orifice plate without a height difference. In this regard, it is also effective to manufacture the orifice plate without a height difference in order for the first liquid 31 and the second liquid 32 to form the parallel flows in the state of laminar flows.
(Second Manufacturing Method)
After the second pattern 140 is formed, a second covering layer 160 is formed as shown in
Next, as shown in
As described above, according to this manufacturing method, the material having the higher sensitivity of the unexposed portion than that of the material for forming the first covering layer 120 is used as the material for forming the second covering layer 160. As a consequence, it is possible to further suppress the adverse effect on the unexposed portion 122 of the first covering layer 120, which is associated with the light exposure process on the second covering layer 160, as compared to the first manufacturing method.
A liquid ejection head was manufactured in accordance with the following process. This example represents a manufacturing example based on the first manufacturing method. First, a heat-generating resistor serving as the energy generation element was formed on a silicon substrate having the diameter of ϕ200 mm. Then, the first inflow port, the second inflow port, the first outflow port, and the second outflow port were formed in the silicon substrate. Next, the first pattern was formed on the substrate by applying a positive resist ODUR-1010A manufactured by Tokyo Ohka Kogyo Co., Ltd., then subjecting the photoresist to light exposure of a flow passage pattern with an exposure machine, and then forming the pattern by conducting the development. Moreover, a cationic polymerization epoxy resin solution was spin-coated as the first covering layer on the substrate provided with the flow passage pattern. Thus, an epoxy resin layer was formed.
Thereafter, the epoxy resin layer serving as the first covering layer was subjected to light exposure, and then the positive resist ODUR-1010A manufactured by Tokyo Ohka Kogyo Co., Ltd. was deposited as the second pattern on the epoxy resin layer without conducting the development of the unexposed portion. The deposition was conducted by means of dry film lamination. Next, an epoxy resin layer which is the same as the epoxy resin layer serving as the first covering layer was deposited as the second covering layer. After conducting the light exposure and the development, the unexposed portions of all the layers, the first pattern, and the second pattern were removed.
The surfaces of the resin layers on the substrate and surfaces of partition walls were flat. Hence, the element board for the liquid ejection head with small thickness distribution on the orifice plate was successfully manufactured. Moreover, the liquid ejection head was successfully manufactured by cutting, mounting, and assembling this liquid ejection head wafer.
A liquid ejection head was manufactured in accordance with the following process. This example represents a manufacturing example based on the second manufacturing method. The process to deposit the first pattern and the first covering layer was the same as that in the first example. Thereafter, the epoxy resin layer serving as the first covering layer was subjected to light exposure, and then the positive resist ODUR-1010A manufactured by Tokyo Ohka Kogyo Co., Ltd. was deposited as the second pattern on the epoxy resin layer without conducting the development of the unexposed portion. The deposition was conducted by means of dry film lamination. Next, an epoxy resin layer which has higher sensitivity than that of the epoxy resin layer constituting the first covering layer was deposited as the second covering layer. After conducting the light exposure and the development, the unexposed portions of all the layers, the first pattern, and the second pattern were removed.
The surfaces of the resin layers on the substrate and surfaces of partition walls were flat. Hence, the element board for the liquid ejection head with small thickness distribution on the orifice plate was successfully manufactured. Moreover, the liquid ejection head was successfully manufactured by cutting, mounting, and assembling this liquid ejection head wafer.
Next, as reference examples, a description will be given of examples in which the second pattern was formed after conducting the development of the unexposed portion of the first covering layer.
A liquid ejection head was manufactured in accordance with a reference example shown in
As shown in
As shown in
As shown in
As shown in
The portion corresponding to the ejection port 11 was subjected to light exposure and development as shown in
A liquid ejection head was manufactured in accordance with the following process. The process to deposit the first pattern and the first covering layer was the same as that in the first example. Thereafter, the epoxy resin layer serving as the first covering layer was subjected to light exposure and the unexposed portion thereof was developed. Then, the positive resist ODUR-1010A manufactured by Tokyo Ohka Kogyo Co., Ltd. was formed into a dry film and deposited as the second pattern on the epoxy resin layer. An attempt was made by means of dry film tenting in order to reduce a height difference on the epoxy resin layer serving as the first covering layer, which was developed as a consequence of patterning. However, a tenting region was large and the dry film sagged as a consequence. Next, an epoxy resin layer was deposited as the second covering layer. After conducting the light exposure and the development, the first pattern and the second pattern were removed. The surfaces of the resin layers on the substrate were not flat, and wafer for the head with small thickness distribution on the orifice plate was not successfully manufactured.
This embodiment also uses the liquid ejection head 1 and the liquid ejection apparatus shown in
As with the above-described embodiments, the first liquid 31 and the second liquid 32 flow from the first inflow port 20 and the second inflow port 21 into the liquid flow passage 13, then flow in the y direction through the pressure chamber 18, and then flow out of the first outflow port 25 and the second outflow port 26. The third liquid 33 that flows in through the third inflow port 22 is introduced into the liquid flow passage 13, then flows in the liquid flow passage 13 in the y direction, then passes through the pressure chamber 18, and flows out of the third outflow port 27 and is collected. As a consequence, in the liquid flow passage 13, the first liquid 31, the second liquid 32, and the third liquid 33 flow together in the y direction between the first inflow port 20 and the first outflow port 25. In this instance, inside the pressure chamber 18, the first liquid 31 is in contact with the inner surface of the pressure chamber 18 where the pressure generating element 12 is located. Meanwhile, the second liquid 32 forms the meniscus at the ejection port 11 while the third liquid 33 flows between the first liquid 31 and the second liquid 32.
In this embodiment as well, a lateral wall 511 is provided at a position opposed to the first inflow port 20 as with the above-described first embodiment. Moreover, in this embodiment, a lateral wall 512 is provided at a position opposed to the third inflow port 22. These lateral walls 511 and 512 have the same function as that of the lateral wall 51 of the above-described first embodiment.
The above-described embodiments are based on the structure in which the length L in the width direction of the first inflow port 20 is smaller than the length W in the width direction of the liquid flow passage 13 (L<W). However, there are also a mode in which the length L in the width direction of the first inflow port 20 is equal to the length W in the width direction of the liquid flow passage 13 (L=W), and a mode in which the length L in the width direction of the first inflow port 20 is larger than the length W in the width direction of the liquid flow passage 13 (L>W). In these modes as well, provision of the lateral wall 51 or the confluence wall 41 is effective for forming the liquid-liquid surface such that the first liquid 31 and the second liquid 32 flow in the pressure chamber 18 while being stacked on each other in the vertical direction.
The liquid ejection head and the liquid ejection apparatus including the liquid ejection head according to this disclosure are not limited only to the inkjet printing head and the inkjet printing apparatus configured to eject an ink. The liquid ejection head, the liquid ejection apparatus, and the liquid ejection method of this disclosure are applicable to various apparatuses including a printer, a copier, a facsimile machine equipped with a telecommunication system, and a word processor including a printer unit, and to other industrial printing apparatuses that are integrally combined with various processing apparatuses. In particular, since various liquids can be used as the second liquid, the liquid ejection head, the liquid ejection apparatus, and the liquid ejection method are also adaptable to other applications including biochip fabrication, electronic circuit printing, and so forth.
According to this disclosure, it is possible to stabilize ejection of a liquid serving as an ejection medium by causing a bubbling medium and the ejection medium to flow while being arranged in the height direction in the pressure chamber.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2019-027393 filed Feb. 19, 2019, and No. 2019-105340 filed Jun. 5, 2019, which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | Kind |
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JP2019-027393 | Feb 2019 | JP | national |
JP2019-105340 | Jun 2019 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
8235505 | Xie | Aug 2012 | B2 |
8685763 | Takahashi | Apr 2014 | B2 |
10538087 | Nakagawa et al. | Jan 2020 | B2 |
20090133256 | Okano | May 2009 | A1 |
20190009554 | Nakagawa | Jan 2019 | A1 |
20190023016 | Nakagawa et al. | Jan 2019 | A1 |
20200039210 | Nakagawa et al. | Feb 2020 | A1 |
20200039218 | Nakagawa et al. | Feb 2020 | A1 |
20200039219 | Nakagawa et al. | Feb 2020 | A1 |
20200039223 | Nakagawa et al. | Feb 2020 | A1 |
Number | Date | Country |
---|---|---|
0 737 580 | Oct 1996 | EP |
0 819 532 | Jan 1998 | EP |
05-169663 | Jul 1993 | JP |
06-305143 | Nov 1994 | JP |
2009004318 | Jan 2009 | WO |
Entry |
---|
Extended European Search Report dated Jun. 23, 2020, in European Patent Application No. 20158225.1. |
U.S. Appl. No. 16/682,120, filed Nov. 13, 2019, Yoshiyuki Nakagawa Kazuhiro Yamada Takuro Yamazaki Toru Nakakubo Ryo Kasai. |
U.S. Appl. No. 16/789,800, filed Feb. 13, 2020, Yoshiyuki Nakagawa Akiko Hammura. |
Number | Date | Country | |
---|---|---|---|
20200262201 A1 | Aug 2020 | US |