ULTRAFINE BUBBLE GENERATING APPARATUS AND METHOD OF MANUFACTURING ELEMENT SUBSTRATE

Abstract

An ultrafine bubble generating apparatus generates thermal-ultrafine bubbles by bringing a liquid into film boiling while using a heater provided to a substrate. The ultrafine bubble generating apparatus includes a control unit which inputs energy to the heater such that a value of a ratio of energy to be inputted to the heater relative to energy with which the heater generates film boiling falls below 1.17 under a condition that the energy to be inputted to the heater is larger than the energy with which the heater generates film boiling.

Description

BACKGROUND OF THE INVENTION

Field of the Invention

The present invention relates to an ultrafine bubble generating apparatus that generates ultrafine bubbles with diameters below 1.0 μm, and to a method of manufacturing an element substrate.

Description of the Related Art

Recently, there have been developed techniques for applying the features of fine bubbles such as microbubbles in micrometer-size in diameter and nanobubbles in nanometer-size in diameter. Especially, the utility of ultrafine bubbles (hereinafter also referred to as “UFBs”) smaller than 1.0 μm in diameter have been confirmed in various fields.

Japanese Patent Laid-Open No. 2019-42732 (hereinafter referred to as Reference 1) discloses a technique for generating the UFBs by using film boiling associated with rapid heat generation. In Reference 1, the aforementioned method of generating the UFBs is referred to as thermal ultrafine bubble (T-UFB) generating method. In addition, the UFBs generated in accordance with the T-UFB generating method are referred to as T-UFBs.

According to the method of Reference 1, the T-UFBs are generated by applying energy produced from the film boiling to a dissolved gas in a liquid. Generation efficiency of the T-UFBs becomes higher as an amount of the original dissolved gas is larger. Accordingly, it is desirable to dissolve as much gas as possible in the liquid. However, the amount of dissolution of the gas depends on the temperature. In general, the amount of dissolution of the gas is decreased with an increase in temperature of the liquid, whereby T-UFB generation efficiency is reduced as a consequence. Since the method according to Reference 1 is designed to generate the T-UFBs by applying the energy produced from the film boiling, a temperature of a substrate provided with heaters is increased and the temperature of the liquid is increased accordingly.

SUMMARY OF THE INVENTION

An ultrafine bubble generating apparatus according to an aspect of the present invention provides an ultrafine bubble generating apparatus configured to generate ultrafine bubbles by bringing a liquid into film boiling while using a heater provided to a substrate. Here, the apparatus includes a control unit configured to input energy to the heater such that a value of a ratio of energy to be inputted to the heater relative to energy with which the heater generates film boiling falls below 1.17 under a condition that the energy to be inputted to the heater is larger than the energy with which the heater generates film boiling.

Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram illustrating an example of a UFB generating apparatus;

FIG. 2 is a schematic configuration diagram of a pre-processing unit;

FIGS. 3A and 3B are a schematic configuration diagram of a dissolving unit and a diagram for describing the dissolving states in a liquid;

FIG. 4 is a schematic configuration diagram of a T-UFB generating unit;

FIGS. 5A and 5B are diagrams for describing details of a heating element;

FIGS. 6A and 6B are diagrams for describing the states of film boiling on the heating element;

FIGS. 7A to 7D are diagrams illustrating the states of generation of UFBs caused by expansion of a film boiling bubble;

FIGS. 8A to 8C are diagrams illustrating the states of generation of UFBs caused by shrinkage of the film boiling bubble;

FIGS. 9A to 9C are diagrams illustrating the states of generation of UFBs caused by reheating of the liquid;

FIGS. 10A and 10B are diagrams illustrating the states of generation of UFBs caused by shock waves made by disappearance of the bubble generated by the film boiling;

FIGS. 11A to 11C are diagrams illustrating a configuration example of a post-processing unit;

FIG. 12 is a graph illustrating a relation between a set value representing a ratio and a maximum reaching temperature;

FIG. 13 is a graph illustrating a decomposition temperature of heat-resistant polyimide;

FIGS. 14A and 14B are plan views illustrating an example of an element substrate;

FIGS. 15A to 15G are diagrams for describing an example of manufacturing the element substrate; and

FIGS. 16A to 16F are diagrams for describing the example of manufacturing the element substrate.

DESCRIPTION OF THE EMBODIMENTS

<<Configuration of UFB Generating Apparatus>>

FIG. 1 is a diagram illustrating an example of an ultrafine bubble generating apparatus (UFB generating apparatus) applicable to the present invention. A UFB generating apparatus 1 of this embodiment includes a pre-processing unit 100, dissolving unit 200, a T-UFB generating unit 300, a post-processing unit 400, a collecting unit 500 and a control unit 600. The control unit 600 controls each operation of each unit. Each unit performs unique processing on a liquid W such as tap water supplied to the pre-processing unit 100 in the above order, and the thus-processed liquid W is collected as a T-UFB-containing liquid by the collecting unit 500. Functions and configurations of the units are described below. Although details are described later, UFBs generated by utilizing the film boiling caused by rapid heating are referred to as thermal-ultrafine bubbles (T-UFBs) in this specification.

FIG. 2 is a schematic configuration diagram of the pre-processing unit 100. The pre-processing unit 100 of this embodiment performs a degassing treatment on the supplied liquid W. The pre-processing unit 100 mainly includes a degassing container 101, a shower head 102, a depressurizing pump 103, a liquid introduction passage 104, a liquid circulation passage 105, and a liquid discharge passage 106. For example, the liquid W such as tap water is supplied to the degassing container 101 from the liquid introduction passage 104 through a valve 109. In this process, the shower head 102 provided in the degassing container 101 sprays a mist of the liquid W in the degassing container 101. The shower head 102 is for prompting the gasification of the liquid W; however, a centrifugal and the like may be used instead as the mechanism for producing the gasification prompt effect.

When a certain amount of the liquid W is reserved in the degassing container 101 and then the depressurizing pump 103 is activated with all the valves closed, already-gasified gas components are discharged, and gasification and discharge of gas components dissolved in the liquid W are also prompted. In this process, the internal pressure of the degassing container 101 may be depressurized to around several hundreds to thousands of Pa (1.0 Torr to 10.0 Torr) while checking a manometer 108. The gases to be removed by the pre-processing unit 100 includes nitrogen, oxygen, argon, carbon dioxide, and so on, for example.

The above-described degassing processing can be repeatedly performed on the same liquid W by utilizing the liquid circulation passage 105. Specifically, the shower head 102 is operated with the valve 109 of the liquid introduction passage 104 and a valve 110 of the liquid discharge passage 106 closed and a valve 107 of the liquid circulation passage 105 opened. This allows the liquid W reserved in the degassing container 101 and degassed once to be resprayed in the degassing container 101 from the shower head 102. In addition, with the depressurizing pump 103 operated, the gasification processing by the shower head 102 and the degassing processing by the depressurizing pump 103 are repeatedly performed on the same liquid W. Every time the above processing utilizing the liquid circulation passage 105 is performed repeatedly, it is possible to decrease the gas components contained in the liquid W in stages. Once the liquid W degassed to a desired purity is obtained, the liquid W is transferred to the dissolving unit 200 through the liquid discharge passage 106 with the valve 110 opened.

FIG. 2 illustrates the pre-processing 100 that depressurizes the gas part to gasify the solute; however, the method of degassing the solution is not limited thereto. For example, a heating and boiling method for boiling the liquid W to gasify the solute may be employed, or a film degassing method for increasing the interface between the liquid and the gas using hollow fibers. A SEPAREL series (produced by DIC Corporation) is commercially supplied as the degassing module using the hollow fibers. The SEPAREL series uses poly(4-methylpentene-1) (PMP) for the raw material of the hollow fibers and is used for removing air bubbles from ink and the like mainly supplied for a piezo head. In addition, two or more of an evacuating method, the heating and boiling method, and the film degassing method may be used together.

FIGS. 3A and 3B are a schematic configuration diagram of the dissolving unit 200 and a diagram for describing the dissolving states in the liquid. The dissolving unit 200 is a unit for dissolving a desired gas into the liquid W supplied from the pre-processing unit 100. The dissolving unit 200 of this embodiment mainly includes a dissolving container 201, a rotation shaft 203 provided with a rotation plate 202, a liquid introduction passage 204, a gas introduction passage 205, a liquid discharge passage 206, and a pressurizing pump 207.

The liquid W supplied from the pre-processing unit 100 is supplied and reserved into the dissolving container 201 through the liquid introduction passage 204. Meanwhile, a gas G is supplied to the dissolving container 201 through the gas introduction passage 205.

Once predetermined amounts of the liquid W and the gas G are reserved in the dissolving container 201, the pressurizing pump 207 is activated to increase the internal pressure of the dissolving container 201 to about 0.5 MPa. A safety valve 208 is arranged between the pressurizing pump 207 and the dissolving container 201. With the rotation plate 202 in the liquid rotated via the rotation shaft 203, the gas G supplied to the dissolving container 201 is transformed into air bubbles, and the contact area between the gas G and the liquid W is increased to prompt the dissolution into the liquid W. This operation is continued until the solubility of the gas G reaches almost the maximum saturation solubility. In this case, a unit for decreasing the temperature of the liquid may be provided to dissolve the gas as much as possible. When the gas is with low solubility, it is also possible to increase the internal pressure of the dissolving container 201 to 0.5 MPa or higher. In this case, the material and the like of the container need to be the optimum for safety sake.

Once the liquid Win which the components of the gas G are dissolved at a desired concentration is obtained, the liquid W is discharged through the liquid discharge passage 206 and supplied to the T-UFB generating unit 300. In this process, a back-pressure valve 209 adjusts the flow pressure of the liquid W to prevent excessive increase of the pressure during the supplying.

FIG. 3B is a diagram schematically illustrating the dissolving states of the gas G put in the dissolving container 201. An air bubble 2 containing the components of the gas G put in the liquid W is dissolved from a portion in contact with the liquid W. The air bubble 2 thus shrinks gradually, and a gas-dissolved liquid 3 then appears around the air bubble 2. Since the air bubble 2 is affected by the buoyancy, the air bubble 2 may be moved to a position away from the center of the gas-dissolved liquid 3 or be separated out from the gas-dissolved liquid 3 to become a residual air bubble 4. Specifically, in the liquid W to be supplied to the T-UFB generating unit 300 through the liquid discharge passage 206, there is a mix of the air bubbles 2 surrounded by the gas-dissolved liquids 3 and the air bubbles 2 and the gas-dissolved liquids 3 separated from each other.

The gas-dissolved liquid 3 in the drawings means “a region of the liquid W in which the dissolution concentration of the gas G mixed therein is relatively high.” In the gas components actually dissolved in the liquid W, the concentration of the gas components in the gas-dissolved liquid 3 is the highest at a portion surrounding the air bubble 2. In a case where the gas-dissolved liquid 3 is separated from the air bubble 2 the concentration of the gas components of the gas-dissolved liquid 3 is the highest at the center of the region, and the concentration is continuously decreased as away from the center. That is, although the region of the gas-dissolved liquid 3 is surrounded by a broken line in FIG. 3 for the sake of explanation, such a clear boundary does not actually exist. In addition, in the present discloser, a gas that cannot be dissolved completely may be accepted to exist in the form of an air bubble in the liquid.

FIG. 4 is a schematic configuration diagram of the T-UFB generating unit 300. The T-UFB generating unit 300 mainly includes a chamber 301, a liquid introduction passage 302, and a liquid discharge passage 303. The flow from the liquid introduction passage 302 to the liquid discharge passage 303 through the chamber 301 is formed by a not-illustrated flow pump. Various pumps including a diaphragm pump, a gear pump, and a screw pump may be employed as the flow pump. In in the liquid W introduced from the liquid introduction passage 302, the gas-dissolved liquid 3 of the gas G put by the dissolving unit 200 is mixed.

An element substrate 12 provided with a heating element 10 is arranged on a bottom section of the chamber 301. With a predetermined voltage pulse applied to the heating element 10, a bubble 13 generated by the film boiling (hereinafter, also referred to as a film boiling bubble 13) is generated in a region in contact with the heating element 10. Then, an ultrafine bubble (UFB) 11 containing the gas G is generated caused by expansion and shrinkage of the film boiling bubble 13. As a result, a UFB-containing liquid W containing many UFBs 11 is discharged from the liquid discharge passage 303.

FIGS. 5A and 5B are diagrams for illustrating a detailed configuration of the heating element 10. FIG. 5A illustrates a closeup view of the heating element 10, and FIG. 5B illustrates a cross-sectional view of a wider region of the element substrate 12 including the heating element 10.

As illustrated in FIG. 5A, in the element substrate 12 of this embodiment, a thermal oxide film 305 as a heat-accumulating layer and an interlaminar film 306 also serving as a heat-accumulating layer are laminated on a surface of a substrate 304 made of silicon (hereinafter also referred to as a silicon substrate 304). A SiO₂ film or a SiN film may be used as the interlaminar film 306. In this example, the heat-accumulating layer is formed from a two-layer structure including the thermal oxide film 305 and the interlaminar film 306. However, the heat-accumulating layer may be formed from a single layer. Alternatively, heat-resistant polyimide may be used as the heat-accumulating layer as will be described later. A resistive layer 307 is formed on a surface of the interlaminar film 306, and wiring 308 is formed on a portion of a surface of the resistive layer 307. Al-alloy wiring of Al, Al—Si, Al—Cu, or the like may be used as the wiring 308. A protective layer 309 made of a SiO₂ film or a Si₃N₄ film is formed on surfaces of the wiring 308, the resistive layer 307, and the interlaminar film 306.

A cavitation-resistant film 310 for protecting the protective layer 309 from chemical and physical impacts due to the heat evolved by the resistive layer 307 is formed on a portion and around the portion on the surface of the protective layer 309, the portion corresponding to a heat-acting portion 311 that eventually becomes the heating element 10. A region on the surface of the resistive layer 307 in which the wiring 308 is not formed is the heat-acting portion 311 in which the resistive layer 307 evolves heat. The heating portion of the resistive layer 307 on which the wiring 308 is not formed functions as the heating element (heater) 10. As described above, the layers in the element substrate 12 are sequentially formed on the surface of the silicon substrate 304 by a semiconductor production technique, and the heat-acting portion 311 is thus provided on the silicon substrate 304.

The configuration illustrated in the drawings is an example, and various other configurations are applicable. For example, a configuration in which the laminating order of the resistive layer 307 and the wiring 308 is opposite, and a configuration in which an electrode is connected to a lower surface of the resistive layer 307 (so-called a plug electrode configuration) are applicable. In other words, as described later, any configuration may be applied as long as the configuration allows the heat-acting portion 311 to heat the liquid for generating the film boiling in the liquid.

FIG. 5B is an example of a cross-sectional view of a region including a circuit connected to the wiring 308 in the element substrate 12. An N-type well region 322 and a P-type well region 323 are partially provided in a top layer of the silicon substrate 304, which is a P-type conductor. AP-MOS 320 is formed in the N-type well region 322 and an N-MOS 321 is formed in the P-type well region 323 by introduction and diffusion of impurities by the ion implantation and the like in the general MOS process.

The P-MOS 320 includes a source region 325 and a drain region 326 formed by partial introduction of N-type or P-type impurities in a top layer of the N-type well region 322, a gate wiring 335, and so on. The gate wiring 335 is deposited on a part of a top surface of the N-type well region 322 excluding the source region 325 and the drain region 326, with a gate insulation film 328 of several hundreds of A in thickness interposed between the gate wiring 335 and the top surface of the N-type well region 322.

The N-MOS 321 includes the source region 325 and the drain region 326 formed by partial introduction of N-type or P-type impurities in a top layer of the P-type well region 323, the gate wiring 335, and so on. The gate wiring 335 is deposited on a part of a top surface of the P-type well region 323 excluding the source region 325 and the drain region 326, with the gate insulation film 328 of several hundreds of Å in thickness interposed between the gate wiring 335 and the top surface of the P-type well region 323. The gate wiring 335 is made of polysilicon of 3000 Å to 5000 Å in thickness deposited by the CVD method. A C-MOS logic is constructed with the P-MOS 320 and the N-MOS 321.

In the P-type well region 323, an N-MOS transistor 330 for driving an electrothermal conversion element (heating resistance element) is formed on a portion different from the portion including the N-MOS 321. The N-MOS transistor 330 includes a source region 332 and a drain region 331 partially provided in the top layer of the P-type well region 323 by the steps of introduction and diffusion of impurities, a gate wiring 333, and so on. The gate wiring 333 is deposited on a part of the top surface of the P-type well region 323 excluding the source region 332 and the drain region 331, with the gate insulation film 328 interposed between the gate wiring 333 and the top surface of the P-type well region 323.

In this example, the N-MOS transistor 330 is used as the transistor for driving the electrothermal conversion element. However, the transistor for driving is not limited to the N-MOS transistor 330, and any transistor may be used as long as the transistor has a capability of driving multiple electrothermal conversion elements individually and can implement the above-described fine configuration. Although the electrothermal conversion element and the transistor for driving the electrothermal conversion element are formed on the same substrate in this example, those may be formed on different substrates separately.

An oxide film separation region 324 is formed by field oxidation of 5000 Å to 10000 Å in thickness between the elements, such as between the P-MOS 320 and the N-MOS 321 and between the N-MOS 321 and the N-MOS transistor 330. The oxide film separation region 324 separates the elements. A portion of the oxide film separation region 324 corresponding to the heat-acting portion 311 functions as a heat-accumulating layer 334, which is the first layer on the silicon substrate 304.

An interlayer insulation film 336 including a PSG film, a BPSG film, or the like of about 7000 Å in thickness is formed by the CVD method on each surface of the elements such as the P-MOS 320, the N-MOS 321, and the N-MOS transistor 330. After the interlayer insulation film 336 is made flat by heat treatment, an Al electrode 337 as a first wiring layer is formed in a contact hole penetrating through the interlayer insulation film 336 and the gate insulation film 328. On surfaces of the interlayer insulation film 336 and the Al electrode 337, an interlayer insulation film 338 including an SiO₂ film of 10000 Å to 15000 Å in thickness is formed by a plasma CVD method. On the surface of the interlayer insulation film 338, a resistive layer 307 including a TaSiN film of about 500 Å in thickness is formed by a co-sputter method on portions corresponding to the heat-acting portion 311 and the N-MOS transistor 330. The resistive layer 307 is electrically connected with the Al electrode 337 near the drain region 331 via a through-hole formed in the interlayer insulation film 338. On the surface of the resistive layer 307, the wiring 308 of Al as a second wiring layer for a wiring to each electrothermal conversion element is formed. The protective layer 309 on the surfaces of the wiring 308, the resistive layer 307, and the interlayer insulation film 338 includes an SiN film of 3000 Å in thickness formed by the plasma CVD method. The cavitation-resistant film 310 deposited on the surface of the protective layer 309 includes a thin film of about 2000 Å in thickness, which is at least one metal selected from the group consisting of Ta, Fe, Ni, Cr, Ge, Ru, Zr, Ir, and the like. Various materials other than the above-described TaSiN such as TaN_0.8, CrSiN, TaAl, WSiN, and the like can be applied as long as the material can generate the film boiling in the liquid.

FIGS. 6A and 6B are diagrams illustrating the states of the film boiling when a predetermined voltage pulse is applied to the heating element 10. In this case, the case of generating the film boiling under atmospheric pressure is described. In FIG. 6A, the horizontal axis represents time. The vertical axis in the lower graph represents a voltage applied to the heating element 10, and the vertical axis in the upper graph represents the volume and the internal pressure of the film boiling bubble 13 generated by the film boiling. On the other hand, FIG. 6B illustrates the states of the film boiling bubble 13 in association with timings 1 to 3 shown in FIG. 6A. Each of the states is described below in chronological order. The UFBs 11 generated by the film boiling as described later are mainly generated near a surface of the film boiling bubble 13. The states illustrated in FIG. 6B are the states where the UFBs 11 generated by the generating unit 300 are resupplied to the dissolving unit 200 through the circulation route, and the liquid containing the UFBs 11 is resupplied to the liquid passage of the generating unit 300, as illustrated in FIG. 1.

Before a voltage is applied to the heating element 10, the atmospheric pressure is substantially maintained in the chamber 301. Once a voltage is applied to the heating element 10, the film boiling is generated in the liquid in contact with the heating element 10, and a thus-generated air bubble (hereinafter, referred to as the film boiling bubble 13) is expanded by a high pressure acting from inside (timing 1). A bubbling pressure in this process is expected to be around 8 to 10 MPa, which is a value close to a saturation vapor pressure of water.

The time for applying a voltage (pulse width) is around 0.5 μsec to 10.0 μsec, and the film boiling bubble 13 is expanded by the inertia of the pressure obtained in timing 1 even after the voltage application. However, a negative pressure generated with the expansion is gradually increased inside the film boiling bubble 13, and the negative pressure acts in a direction to shrink the film boiling bubble 13. After a while, the volume of the film boiling bubble 13 becomes the maximum in timing 2 when the inertial force and the negative pressure are balanced, and thereafter the film boiling bubble 13 shrinks rapidly by the negative pressure.

In the disappearance of the film boiling bubble 13, the film boiling bubble 13 disappears not in the entire surface of the heating element 10 but in one or more extremely small regions. For this reason, on the heating element 10, further greater force than that in the bubbling in timing 1 is generated in the extremely small region in which the film boiling bubble 13 disappears (timing 3).

The generation, expansion, shrinkage, and disappearance of the film boiling bubble 13 as described above are repeated every time a voltage pulse is applied to the heating element 10, and new UFBs 11 are generated each time.

The states of generation of the UFBs 11 in each process of the generation, expansion, shrinkage, and disappearance of the film boiling bubble 13 are further described in detail with reference to FIGS. 7A to 10B.

FIGS. 7A to 7D are diagrams schematically illustrating the states of generation of the UFBs 11 caused by the generation and the expansion of the film boiling bubble 13. FIG. 7A illustrates the state before the application of a voltage pulse to the heating element 10. The liquid W in which the gas-dissolved liquids 3 are mixed flows inside the chamber 301.

FIG. 7B illustrates the state where a voltage is applied to the heating element 10, and the film boiling bubble 13 is evenly generated in almost all over the region of the heating element 10 in contact with the liquid W. When a voltage is applied, the surface temperature of the heating element 10 rapidly increases at a speed of 10° C./μsec. The film boiling occurs at a time point when the temperature reaches almost 300° C., and the film boiling bubble 13 is thus generated.

Thereafter, the surface temperature of the heating element 10 keeps increasing to around 450° C. during the pulse application, and the liquid around the film boiling bubble 13 is rapidly heated as well. Depending on the energy applied to the heating element 10, its surface temperature may be increased to a range from about 600° C. to 800° C. in some cases. In FIG. 7B, a region of the liquid that is located around the film boiling bubble 13 and is to be rapidly heated is indicated as a not-yet-bubbling high temperature region 14. The gas-dissolved liquid 3 within the not-yet-bubbling high temperature region 14 exceeds the thermal dissolution limit and is precipitated to become the UFB. The thus-precipitated air bubbles have diameters of around 10 nm to 100 nm and large gas-liquid interface energy. Thus, the air bubbles float independently in the liquid W without disappearing in a short time. In this embodiment, the air bubbles generated by the thermal action from the generation to the expansion of the film boiling bubble 13 are called first UFBs 11A.

FIG. 7C illustrates the state where the film boiling bubble 13 is expanded. Even after the voltage pulse application to the heating element 10, the film boiling bubble 13 continues expansion by the inertia of the force obtained from the generation thereof, and the not-yet-bubbling high temperature region 14 is also moved and spread by the inertia. Specifically, in the process of the expansion of the film boiling bubble 13, the gas-dissolved liquid 3 within the not-yet-bubbling high temperature region 14 is vaporized as a new air bubble and becomes the first UFB 11A.

FIG. 7D illustrates the state where the film boiling bubble 13 has the maximum volume. As the film boiling bubble 13 is expanded by the inertia, the negative pressure inside the film boiling bubble 13 is gradually increased along with the expansion, and the negative pressure acts to shrink the film boiling bubble 13. At a time point when the negative pressure and the inertial force are balanced, the volume of the film boiling bubble 13 becomes the maximum, and then the shrinkage is started.

In the shrinking stage of the film boiling bubble 13, there are UFBs generated by the processes illustrated in FIGS. 8A to 8C (second UFBs 11B) and UFBs generated by the processes illustrated in FIGS. 9A to 9C (third UFBs 11C). It is considered that these two processes are made simultaneously.

FIGS. 8A to 8C are diagrams illustrating the states of generation of the UFBs 11 caused by the shrinkage of the film boiling bubble 13. FIG. 8A illustrates the state where the film boiling bubble 13 starts shrinking. Although the film boiling bubble 13 starts shrinking, the surrounding liquid W still has the inertial force in the expansion direction. Because of this, the inertial force acting in the direction of going away from the heating element 10 and the force going toward the heating element 10 caused by the shrinkage of the film boiling bubble 13 act in a surrounding region extremely close to the film boiling bubble 13, and the region is depressurized. The region is indicated in the drawings as a not-yet-bubbling negative pressure region 15.

The gas-dissolved liquid 3 within the not-yet-bubbling negative pressure region 15 exceeds the pressure dissolution limit and is vaporized to become an air bubble. The thus-vaporized air bubbles have diameters of about 100 nm and thereafter float independently in the liquid W without disappearing in a short time. In this embodiment, the air bubbles vaporized by the pressure action during the shrinkage of the film boiling bubble 13 are called the second UFBs 11B.

FIG. 8B illustrates a process of the shrinkage of the film boiling bubble 13. The shrinking speed of the film boiling bubble 13 is accelerated by the negative pressure, and the not-yet-bubbling negative pressure region 15 is also moved along with the shrinkage of the film boiling bubble 13. Specifically, in the process of the shrinkage of the film boiling bubble 13, the gas-dissolved liquids 3 within a part over the not-yet-bubbling negative pressure region 15 are precipitated one after another and become the second UFBs 11B.

FIG. 8C illustrates the state immediately before the disappearance of the film boiling bubble 13. Although the moving speed of the surrounding liquid W is also increased by the accelerated shrinkage of the film boiling bubble 13, a pressure loss occurs due to a flow passage resistance in the chamber 301. As a result, the region occupied by the not-yet-bubbling negative pressure region 15 is further increased, and a number of the second UFBs 11B are generated.

FIGS. 9A to 9C are diagrams illustrating the states of generation of the UFBs by reheating of the liquid W during the shrinkage of the film boiling bubble 13. FIG. 9A illustrates the state where the surface of the heating element 10 is covered with the shrinking film boiling bubble 13.

FIG. 9B illustrates the state where the shrinkage of the film boiling bubble 13 has progressed, and a part of the surface of the heating element 10 comes in contact with the liquid W. In this state, there is heat left on the surface of the heating element 10, but the heat is not high enough to cause the film boiling even if the liquid W comes in contact with the surface. A region of the liquid to be heated by coming in contact with the surface of the heating element 10 is indicated in the drawings as a not-yet-bubbling reheated region 16. Although the film boiling is not made, the gas-dissolved liquid 3 within the not-yet-bubbling reheated region 16 exceeds the thermal dissolution limit and is vaporized. In this embodiment, the air bubbles generated by the reheating of the liquid W during the shrinkage of the film boiling bubble 13 are called the third UFBs 11C.

FIG. 9C illustrates the state where the shrinkage of the film boiling bubble 13 has further progressed. The smaller the film boiling bubble 13, the greater the region of the heating element 10 in contact with the liquid W, and the third UFBs 11C are generated until the film boiling bubble 13 disappears.

FIGS. 10A and 10B are diagrams illustrating the states of generation of the UFBs caused by an impact from the disappearance of the film boiling bubble 13 generated by the film boiling (that is, a type of cavitation). FIG. 10A illustrates the state immediately before the disappearance of the film boiling bubble 13. In this state, the film boiling bubble 13 shrinks rapidly by the internal negative pressure, and the not-yet-bubbling negative pressure region 15 surrounds the film boiling bubble 13.

FIG. 10B illustrates the state immediately after the film boiling bubble 13 disappears at a point P. When the film boiling bubble 13 disappears, acoustic waves ripple concentrically from the point P as a starting point due to the impact of the disappearance. The acoustic wave is a collective term of an elastic wave that is propagated through anything regardless of gas, liquid, and solid. In this embodiment, compression waves of the liquid W, which are a high pressure surface 17A and a low pressure surface 17B of the liquid W, are propagated alternately.

In this case, the gas-dissolved liquid 3 within the not-yet-bubbling negative pressure region 15 is resonated by the shock waves made by the disappearance of the film boiling bubble 13, and the gas-dissolved liquid 3 exceeds the pressure dissolution limit and the phase transition is made in timing when the low pressure surface 17B passes therethrough. Specifically, a number of air bubbles are vaporized in the not-yet-bubbling negative pressure region 15 simultaneously with the disappearance of the film boiling bubble 13. In this embodiment, the air bubbles generated by the shock waves made by the disappearance of the film boiling bubble 13 are called fourth UFBs 11D.

The fourth UFBs 11D generated by the shock waves made by the disappearance of the film boiling bubble 13 suddenly appear in an extremely short time (1 μS or less) in an extremely narrow thin film-shaped region. The diameter is sufficiently smaller than that of the first to third UFBs, and the gas-liquid interface energy is higher than that of the first to third UFBs. For this reason, it is considered that the fourth UFBs 11D have different characteristics from the first to third UFBs 11A to 11C and generate different effects.

Additionally, the fourth UFBs 11D are evenly generated in many parts of the region of the concentric sphere in which the shock waves are propagated, and the fourth UFBs 11D evenly exist in the chamber 301 from the generation thereof. Although many first to third UFBs already exist in the timing of the generation of the fourth UFBs 11D, the presence of the first to third UFBs does not affect the generation of the fourth UFBs 11D greatly. It is also considered that the first to third UFBs do not disappear due to the generation of the fourth UFBs 11D.

As described above, it is expected that the UFBs 11 are generated in the multiple stages from the generation to the disappearance of the film boiling bubble 13 by the heat generation of the heating element 10. The first UFBs 11A, the second UFBs 11B, and the third UFBs 11C are generated near the surface of the film boiling bubble generated by the film boiling. In this case, near means a region within about 20 μm from the surface of the film boiling bubble. The fourth UFBs 11D are generated in a region through which the shock waves are propagated when the air bubble disappears. Although the above example illustrates the stages to the disappearance of the film boiling bubble 13, the way of generating the UFBs is not limited thereto. For example, with the generated film boiling bubble 13 communicating with the atmospheric air before the bubble disappearance, the UFBs can be generated also if the film boiling bubble 13 does not reach the disappearance.

Next, remaining properties of the UFBs are described. The higher the temperature of the liquid, the lower the dissolution properties of the gas components, and the lower the temperature, the higher the dissolution properties of the gas components. In other words, the phase transition of the dissolved gas components is prompted and the generation of the UFBs becomes easier as the temperature of the liquid is higher. The temperature of the liquid and the solubility of the gas are in the inverse relationship, and the gas exceeding the saturation solubility is transformed into air bubbles and appeared in the liquid as the liquid temperature increases.

Therefore, when the temperature of the liquid rapidly increases from normal temperature, the dissolution properties are decreased without stopping, and the generation of the UFBs starts. The thermal dissolution properties are decreased as the temperature increases, and a number of the UFBs are generated.

Conversely, when the temperature of the liquid decreases from normal temperature, the dissolution properties of the gas are increased, and the generated UFBs are more likely to be liquefied. However, such temperature is sufficiently lower than normal temperature. Additionally, since the once generated UFBs have a high internal pressure and large gas-liquid interface energy even when the temperature of the liquid decreases, it is highly unlikely that there is exerted a sufficiently high pressure to break such a gas-liquid interface. In other words, the once generated UFBs do not disappear easily as long as the liquid is stored at normal temperature and normal pressure.

In this embodiment, the first UFBs 11A described with FIGS. 7A to 7C and the third UFBs 11C described with FIGS. 9A to 9C can be described as UFBs that are generated by utilizing such thermal dissolution properties of gas.

On the other hand, in the relationship between the pressure and the dissolution properties of liquid, the higher the pressure of the liquid, the higher the dissolution properties of the gas, and the lower the pressure, the lower the dissolution properties. In other words, the phase transition to the gas of the gas-dissolved liquid dissolved in the liquid is prompted and the generation of the UFBs becomes easier as the pressure of the liquid is lower. Once the pressure of the liquid becomes lower than normal pressure, the dissolution properties are decreased instantly, and the generation of the UFBs starts. The pressure dissolution properties are decreased as the pressure decreases, and a number of the UFBs are generated.

Conversely, when the pressure of the liquid increases to be higher than normal pressure, the dissolution properties of the gas are increased, and the generated UFBs are more likely to be liquefied. However, such pressure is sufficiently higher than the atmospheric pressure. Additionally, since the once generated UFBs have a high internal pressure and large gas-liquid interface energy even when the pressure of the liquid increases, it is highly unlikely that there is exerted a sufficiently high pressure to break such a gas-liquid interface. In other words, the once generated UFBs do not disappear easily as long as the liquid is stored at normal temperature and normal pressure.

In this embodiment, the second UFBs 11B described with FIGS. 8A to 8C and the fourth UFBs 11D described with FIGS. 10A to 10B can be described as UFBs that are generated by utilizing such pressure dissolution properties of gas.

Those first to fourth UFBs generated by different causes are described individually above; however, the above-described generation causes occur simultaneously with the event of the film boiling. Thus, at least two types of the first to the fourth UFBs may be generated at the same time, and these generation causes may cooperate to generate the UFBs. It should be noted that it is common for all the generation causes to be induced by the film boiling phenomenon. In this specification, the method of generating the UFBs by utilizing the film boiling caused by the rapid heating as described above is referred to as a thermal-ultrafine bubble (T-UFB) generating method. Additionally, the UFBs generated by the T-UFB generating method are referred to as T-UFBs, and the liquid containing the T-UFBs generated by the T-UFB generating method is referred to as a T-UFB-containing liquid.

Almost all the air bubbles generated by the T-UFB generating method are 1.0 μm or less, and milli-bubbles and microbubbles are unlikely to be generated. That is, the T-UFB generating method allows dominant and efficient generation of the UFBs. Additionally, the T-UFBs generated by the T-UFB generating method have larger gas-liquid interface energy than that of the UFBs generated by a conventional method, and the T-UFBs do not disappear easily as long as being stored at normal temperature and normal pressure. Moreover, even if new T-UFBs are generated by new film boiling, it is possible to prevent disappearance of the already generated T-UFBs due to the impact from the new generation. That is, it can be said that the number and the concentration of the T-UFBs contained in the T-UFB-containing liquid have the hysteresis properties depending on the number of times the film boiling is made in the T-UFB-containing liquid. In other words, it is possible to adjust the concentration of the T-UFBs contained in the T-UFB-containing liquid by controlling the number of the heating elements provided in the T-UFB generating unit 300 and the number of the voltage pulse application to the heating elements.

Reference to FIG. 1 is made again. Once the T-UFB-containing liquid W with a desired UFB concentration is generated in the T-UFB generating unit 300, the UFB-containing liquid W is supplied to the post-processing unit 400.

FIGS. 11A to 11C are diagrams illustrating configuration examples of the post-processing unit 400 of this embodiment. The post-processing unit 400 of this embodiment removes impurities in the UFB-containing liquid W in stages in the order from inorganic ions, organic substances, and insoluble solid substances.

FIG. 11A illustrates a first post-processing mechanism 410 that removes the inorganic ions. The first post-processing mechanism 410 includes an exchange container 411, cation exchange resins 412, a liquid introduction passage 413, a collecting pipe 414, and a liquid discharge passage 415. The exchange container 411 stores the cation exchange resins 412. The UFB-containing liquid W generated by the T-UFB generating unit 300 is injected to the exchange container 411 through the liquid introduction passage 413 and absorbed into the cation exchange resins 412 such that the cations as the impurities are removed. Such impurities include metal materials peeled off from the element substrate 12 of the T-UFB generating unit 300, such as SiO₂, SiN, SiC, Ta, Al₂O₃, Ta₂O₅, and Ir.

The cation exchange resins 412 are synthetic resins in which a functional group (ion exchange group) is introduced in a high polymer matrix having a three-dimensional network, and the appearance of the synthetic resins are spherical particles of around 0.4 to 0.7 mm. A general high polymer matrix is the styrene-divinylbenzene copolymer, and the functional group may be that of methacrylic acid series and acrylic acid series, for example. However, the above material is an example. As long as the material can remove desired inorganic ions effectively, the above material can be changed to various materials. The UFB-containing liquid W absorbed in the cation exchange resins 412 to remove the inorganic ions is collected by the collecting pipe 414 and transferred to the next step through the liquid discharge passage 415. In this process in the present embodiment, not all the inorganic ions contained in the UFB-containing liquid W supplied from the liquid introduction passage 413 need to be removed as long as at least a part of the inorganic ions are removed.

FIG. 11B illustrates a second post-processing mechanism 420 that removes the organic substances. The second post-processing mechanism 420 includes a storage container 421, a filtration filter 422, a vacuum pump 423, a valve 424, a liquid introduction passage 425, a liquid discharge passage 426, and an air suction passage 427. Inside of the storage container 421 is divided into upper and lower two regions by the filtration filter 422. The liquid introduction passage 425 is connected to the upper region of the upper and lower two regions, and the air suction passage 427 and the liquid discharge passage 426 are connected to the lower region thereof. Once the vacuum pump 423 is driven with the valve 424 closed, the air in the storage container 421 is discharged through the air suction passage 427 to make the pressure inside the storage container 421 negative pressure, and the UFB-containing liquid W is thereafter introduced from the liquid introduction passage 425. Then, the UFB-containing liquid W from which the impurities are removed by the filtration filter 422 is reserved into the storage container 421.

The impurities removed by the filtration filter 422 include organic materials that may be mixed at a tube or each unit, such as organic compounds including silicon, siloxane, and epoxy, for example. A filter film usable for the filtration filter 422 includes a filter of a sub-pm-mesh (a filter of 1 μm or smaller in mesh diameter) that can remove bacteria, and a filter of a nm-mesh that can remove virus. The filtration filter having such a fine opening diameter may remove air bubbles larger than the opening diameter of the filter. Particularly, there may be the case where the filter is clogged by the fine air bubbles adsorbed to the openings (mesh) of the filter, which may slowdown the filtering speed. However, as described above, most of the air bubbles generated by the T-UFB generating method described in the present embodiment of the invention are in the size of 1 μm or smaller in diameter, and milli-bubbles and microbubbles are not likely to be generated. That is, since the probability of generating milli-bubbles and microbubbles is extremely low, it is possible to suppress the slowdown in the filtering speed due to the adsorption of the air bubbles to the filter. For this reason, it is favorable to apply the filtration filter 422 provided with the filter of 1 μm or smaller in mesh diameter to the system having the T-UFB generating method.

Examples of the filtration applicable to this embodiment may be a so-called dead-end filtration and cross-flow filtration. In the dead-end filtration, the direction of the flow of the supplied liquid and the direction of the flow of the filtration liquid passing through the filter openings are the same, and specifically, the directions of the flows are made along with each other. In contrast, in the cross-flow filtration, the supplied liquid flows in a direction along a filter surface, and specifically, the direction of the flow of the supplied liquid and the direction of the flow of the filtration liquid passing through the filter openings are crossed with each other. It is preferable to apply the cross-flow filtration to suppress the adsorption of the air bubbles to the filter openings.

After a certain amount of the UFB-containing liquid W is reserved in the storage container 421, the vacuum pump 423 is stopped and the valve 424 is opened to transfer the T-UFB-containing liquid in the storage container 421 to the next step through the liquid discharge passage 426. Although the vacuum filtration method is employed as the method of removing the organic impurities herein, a gravity filtration method and a pressurized filtration can also be employed as the filtration method using a filter, for example.

FIG. 11C illustrates a third post-processing mechanism 430 that removes the insoluble solid substances. The third post-processing mechanism 430 includes a precipitation container 431, a liquid introduction passage 432, a valve 433, and a liquid discharge passage 434.

First, a predetermined amount of the UFB-containing liquid W is reserved into the precipitation container 431 through the liquid introduction passage 432 with the valve 433 closed, and leaving it for a while. Meanwhile, the solid substances in the UFB-containing liquid W are precipitated onto the bottom of the precipitation container 431 by gravity. Among the bubbles in the UFB-containing liquid, relatively large bubbles such as microbubbles are raised to the liquid surface by the buoyancy and also removed from the UFB-containing liquid. After a lapse of sufficient time, the valve 433 is opened, and the UFB-containing liquid W from which the solid substances and large bubbles are removed is transferred to the collecting unit 500 through the liquid discharge passage 434. The example of applying the three post-processing mechanisms in sequence is shown in this embodiment; however, it is not limited thereto, and the order of the three post-processing mechanisms may be changed, or at least one needed post-processing mechanism may be employed.

Reference to FIG. 1 is made again. The T-UFB-containing liquid W from which the impurities are removed by the post-processing unit 400 may be directly transferred to the collecting unit 500 or may be put back to the dissolving unit 200 again. In the latter case, the gas dissolution concentration of the T-UFB-containing liquid W that is decreased due to the generation of the T-UFBs can be compensated to the saturated state again by the dissolving unit 200. If new T-UFBs are generated by the T-UFB generating unit 300 after the compensation, it is possible to further increase the concentration of the UFBs contained in the T-UFB-containing liquid with the above-described properties. That is, it is possible to increase the concentration of the contained UFBs by the number of circulations through the dissolving unit 200, the T-UFB generating unit 300, and the post-processing unit 400, and it is possible to transfer the UFB-containing liquid W to the collecting unit 500 after a predetermined concentration of the contained UFBs is obtained. This embodiment shows a form in which the UFB-containing liquid processed by the post-processing unit 400 is put back to the dissolving unit 200 and circulated; however, it is not limited thereto, and the UFB-containing liquid after passing through the T-UFB generating unit may be put back again to the dissolving unit 200 before being supplied to the post-processing unit 400 such that the post-processing is performed by the post-processing unit 400 after the T-UFB concentration is increased through multiple times of circulation, for example.

The collecting unit 500 collects and preserves the UFB-containing liquid W transferred from the post-processing unit 400. The T-UFB-containing liquid collected by the collecting unit 500 is a UFB-containing liquid with high purity from which various impurities are removed.

In the collecting unit 500, the UFB-containing liquid W may be classified by the size of the T-UFBs by performing some stages of filtration processing. Since it is expected that the temperature of the T-UFB-containing liquid W obtained by the T-UFB method is higher than normal temperature, the collecting unit 500 may be provided with a cooling unit. The cooling unit may be provided to a part of the post-processing unit 400.

The schematic description of the UFB generating apparatus 1 is given above; however, it is needless to say that the illustrated multiple units can be changed, and not all of them need to be prepared. Depending on the type of the liquid W and the gas G to be used and the intended use of the T-UFB-containing liquid to be generated, a part of the above-described units may be omitted, or another unit other than the above-described units may be added.

For example, when the gas to be contained by the UFBs is the atmospheric air, the degassing unit as the pre-processing unit 100 and the dissolving unit 200 can be omitted. On the other hand, when multiple kinds of gases are desired to be contained by the UFBs, another dissolving unit 200 may be added.

The units for removing the impurities as described in FIGS. 11A to 11C may be provided upstream of the T-UFB generating unit 300 or may be provided both upstream and downstream thereof. When the liquid to be supplied to the UFB generating apparatus is tap water, rain water, contaminated water, or the like, there may be included organic and inorganic impurities in the liquid. If such a liquid W including the impurities is supplied to the T-UFB generating unit 300, there is a risk of deteriorating the heating element 10 and inducing the salting-out phenomenon. With the mechanisms as illustrated in FIGS. 11A to 11C provided upstream of the T-UFB generating unit 300, it is possible to remove the above-described impurities previously.

<<Liquid and Gas Usable For T-UFB-Containing Liquid>>

Now, the liquid W usable for generating the T-UFB-containing liquid is described. The liquid W usable in this embodiment is, for example, pure water, ion exchange water, distilled water, bioactive water, magnetic active water, lotion, tap water, sea water, river water, clean and sewage water, lake water, underground water, rain water, and so on. A mixed liquid containing the above liquid and the like is also usable. A mixed solvent containing water and soluble organic solvent can be also used. The soluble organic solvent to be used by being mixed with water is not particularly limited; however, the followings can be a specific example thereof. An alkyl alcohol group of the carbon number of 1 to 4 including methyl alcohol, ethyl alcohol, n-propyl alcohol, isopropyl alcohol, n-butyl alcohol, sec-butyl alcohol, and tert-butyl alcohol. An amide group including N-methyl-2-pyrrolidone, 2-pyrrolidone, 1,3-dimethyl-2-imidazolidinone, N,N-dimethylformamide, and N,N-dimethylacetamide. A keton group or a ketoalcohol group including acetone and diacetone alcohol. A cyclic ether group including tetrahydrofuran and dioxane. A glycol group including ethylene glycol, 1,2-propylene glycol, 1,3-propylene glycol, 1,2-butanediol, 1,3-butanediol, 1,4-butanediol, 1,5-pentanediol, 1,2-hexanediol, 1,6-hexanediol, 3-methyl-1,5-pentanediol, diethylene glycol, triethylene glycol, and thiodiglycol. A group of lower alkyl ether of polyhydric alcohol including ethylene glycol monomethyl ether, ethylene glycol monoethyl ether, ethylene glycol monobutyl ether, diethylene glycol monomethyl ether, diethylene glycol monoethyl ether, diethylene glycol monobutyl ether, triethylene glycol monomethyl ether, triethylene glycol monoethyl ether, and triethylene glycol monobutyl ether. A polyalkylene glycol group including polyethylene glycol and polypropylene glycol. A triol group including glycerin, 1,2,6-hexanetriol, and trimethylolpropane. These soluble organic solvents can be used individually, or two or more of them can be used together.

A gas component that can be introduced into the dissolving unit 200 is, for example, hydrogen, helium, oxygen, nitrogen, methane, fluorine, neon, carbon dioxide, ozone, argon, chlorine, ethane, propane, air, and so on. The gas component may be a mixed gas containing some of the above. Additionally, it is not necessary for the dissolving unit 200 to dissolve a substance in a gas state, and the dissolving unit 200 may fuse a liquid or a solid containing desired components into the liquid W. The dissolution in this case may be spontaneous dissolution, dissolution caused by pressure application, or dissolution caused by hydration, ionization, and chemical reaction due to electrolytic dissociation.

<<Effects of T-UFB Generating Method>>

Next, the characteristics and the effects of the above-described T-UFB generating method are described by comparing with a conventional UFB generating method. For example, in a conventional air bubble generating apparatus as represented by the Venturi method, a mechanical depressurizing structure such as a depressurizing nozzle is provided in a part of a flow passage. A liquid flows at a predetermined pressure to pass through the depressurizing structure, and air bubbles of various sizes are generated in a downstream region of the depressurizing structure.

In this case, among the generated air bubbles, since the relatively large bubbles such as milli-bubbles and microbubbles are affected by the buoyancy, such bubbles rise to the liquid surface and disappear. Even the UFBs that are not affected by the buoyancy may also disappear with the milli-bubbles and microbubbles since the gas-liquid interface energy of the UFBs is not very large. Additionally, even if the above-described depressurizing structures are arranged in series, and the same liquid flows through the depressurizing structures repeatedly, it is impossible to store for a long time the UFBs of the number corresponding to the number of repetitions. In other words, it has been difficult for the UFB-containing liquid generated by the conventional UFB generating method to maintain the concentration of the contained UFBs at a predetermined value for a long time.

In contrast, in the T-UFB generating method of this embodiment utilizing the film boiling, a rapid temperature change from normal temperature to about 300° C. and a rapid pressure change from normal pressure to around a several megapascal occur locally in a part extremely close to the heating element. The heating element is a rectangular shape having one side of around several tens to hundreds of μm. It is around 1/10 to 1/1000 of the size of a conventional UFB generating unit. Additionally, with the gas-dissolved liquid within the extremely thin film region of the film boiling bubble surface exceeding the thermal dissolution limit or the pressure dissolution limit instantaneously (in an extremely short time under microseconds), the phase transition occurs and the gas-dissolved liquid is precipitated as the UFBs. In this case, the relatively large bubbles such as milli-bubbles and microbubbles are hardly generated, and the liquid contains the UFBs of about 100 nm in diameter with extremely high purity. Moreover, since the T-UFBs generated in this way have sufficiently large gas-liquid interface energy, the T-UFBs are not broken easily under the normal environment and can be stored for a long time.

Particularly, the present discloser using the film boiling phenomenon that enables local formation of a gas interface in the liquid can form an interface in a part of the liquid close to the heating element without affecting the entire liquid region, and a region on which the thermal and pressure actions performed can be extremely local. As a result, it is possible to stably generate desired UFBs. With further more conditions for generating the UFBs applied to the generation liquid through the liquid circulation, it is possible to additionally generate new UFBs with small effects on the already-made UFBs. As a result, it is possible to produce a UFB liquid of a desired size and concentration relatively easily.

Moreover, since the T-UFB generating method has the above-described hysteresis properties, it is possible to increase the concentration to a desired concentration while keeping the high purity. In other words, according to the T-UFB generating method, it is possible to efficiently generate a long-time storable UFB-containing liquid with high purity and high concentration.

<<Specific Usage of T-UFB-Containing Liquid>>

In general, applications of the ultrafine bubble-containing liquids are distinguished by the type of the containing gas. Any type of gas can make the UFBs as long as an amount of around PPM to BPM of the gas can be dissolved in the liquid. For example, the ultrafine bubble-containing liquids can be applied to the following applications.

A UFB-containing liquid containing air can be preferably applied to cleansing in the industrial, agricultural and fishery, and medical scenes and the like, and to cultivation of plants and agricultural and fishery products.

A UFB-containing liquid containing ozone can be preferably applied to not only cleansing application in the industrial, agricultural and fishery, and medical scenes and the like, but to also applications intended to disinfection, sterilization, and decontamination, and environmental cleanup of drainage and contaminated soil, for example.

A UFB-containing liquid containing nitrogen can be preferably applied to not only cleansing application in the industrial, agricultural and fishery, and medical scenes and the like, but to also applications intended to disinfection, sterilization, and decontamination, and environmental cleanup of drainage and contaminated soil, for example.

A UFB-containing liquid containing oxygen can be preferably applied to cleansing application in the industrial, agricultural and fishery, and medical scenes and the like, and to cultivation of plants and agricultural and fishery products.

A UFB-containing liquid containing carbon dioxide can be preferably applied to not only cleansing application in the industrial, agricultural and fishery, and medical scenes and the like, but to also applications intended to disinfection, sterilization, and decontamination, for example.

A UFB-containing liquid containing perfluorocarbons as a medical gas can be preferably applied to ultrasonic diagnosis and treatment. As described above, the UFB-containing liquids can exert the effects in various fields of medical, chemical, dental, food, industrial, agricultural and fishery, and so on.

In each of the applications, the purity and the concentration of the UFBs contained in the UFB-containing liquid are important for quickly and reliably exert the effect of the UFB-containing liquid. In other words, unprecedented effects can be expected in various fields by utilizing the T-UFB generating method of this embodiment that enables generation of the UFB-containing liquid with high purity and desired concentration. Here is below a list of the applications in which the T-UFB generating method and the T-UFB-containing liquid are expected to be preferably applicable.

(A) Liquid Purification Application

With the T-UFB generating unit provided to a water clarification unit, enhancement of an effect of water clarification and an effect of purification of PH adjustment liquid is expected. The T-UFB generating unit may also be provided to a carbonated water server.

With the T-UFB generating unit provided to a humidifier, aroma diffuser, coffee maker, and the like, enhancement of a humidifying effect, a deodorant effect, and a scent spreading effect in a room is expected.

If the UFB-containing liquid in which an ozone gas is dissolved by the dissolving unit is generated and is used for dental treatment, burn treatment, and wound treatment using an endoscope, enhancement of a medical cleansing effect and an antiseptic effect is expected.

With the T-UFB generating unit provided to a water storage tank of a condominium, enhancement of a water clarification effect and chlorine removing effect of drinking water to be stored for a long time is expected.

If the T-UFB-containing liquid containing ozone or carbon dioxide is used for brewing process of Japanese sake, shochu, wine, and so on in which the high-temperature pasteurization processing cannot be performed, more efficient pasteurization processing than that with the conventional liquid is expected.

If the UFB-containing liquid is mixed into the ingredient in a production process of the foods for specified health use and the foods with functional claims, the pasteurization processing is possible, and thus it is possible to provide safe and functional foods without a loss of flavor.

With the T-UFB generating unit provided to a supplying route of sea water and fresh water for cultivation in a cultivation place of fishery products such as fish and pearl, prompting of spawning and growing of the fishery products is expected.

With the T-UFB generating unit provided in a purification process of water for food preservation, enhancement of the preservation state of the food is expected.

With the T-UFB generating unit provided in a bleaching unit for bleaching pool water or underground water, a higher bleaching effect is expected.

With the T-UFB-containing liquid used for repairing a crack of a concrete member, enhancement of the effect of crack repairment is expected.

With the T-UFBs contained in liquid fuel for a machine using liquid fuel (such as automobile, vessel, and airplane), enhancement of energy efficiency of the fuel is expected.

(B) Cleansing Application

Recently, the UFB-containing liquids have been receiving attention as cleansing water for removing soils and the like attached to clothing. If the T-UFB generating unit described in the above embodiment is provided to a washing machine, and the UFB-containing liquid with higher purity and better permeability than the conventional liquid is supplied to the washing tub, further enhancement of detergency is expected.

With the T-UFB generating unit provided to a bath shower and a bedpan washer, not only a cleansing effect on all kinds of animals including human body but also an effect of prompting contamination removal of a water stain and a mold on a bathroom and a bedpan are expected.

With the T-UFB generating unit provided to a window washer for automobiles, a high-pressure washer for cleansing wall members and the like, a car washer, a dishwasher, a food washer, and the like, further enhancement of the cleansing effects thereof is expected.

With the T-UFB-containing liquid used for cleansing and maintenance of parts produced in a factory including a burring step after pressing, enhancement of the cleansing effect is expected.

In production of semiconductor elements, if the T-UFB-containing liquid is used as polishing water for a wafer, enhancement of the polishing effect is expected. Additionally, if the T-UFB-containing liquid is used in a resist removal step, prompting of peeling of resist that is not peeled off easily is enhanced.

With the T-UFB generating unit is provided to machines for cleansing and decontaminating medical machines such as a medical robot, a dental treatment unit, an organ preservation container, and the like, enhancement of the cleansing effect and the decontamination effect of the machines is expected. The T-UFB generating unit is also applicable to treatment of animals.

(C) Pharmaceutical Application

If the T-UFB-containing liquid is contained in cosmetics and the like, permeation into subcutaneous cells is prompted, and additives that give bad effects to skin such as preservative and surfactant can be reduced greatly. As a result, it is possible to provide safer and more functional cosmetics.

If a high concentration nanobubble preparation containing the T-UFBs is used for contrasts for medical examination apparatuses such as a CT and an MRI, reflected light of X-rays and ultrasonic waves can be efficiently used. This makes it possible to capture a more detailed image that is usable for initial diagnosis of a cancer and the like.

If a high concentration nanobubble water containing the T-UFBs is used for a ultrasonic wave treatment machine called high-intensity focused ultrasound (HIFU), the irradiation power of ultrasonic waves can be reduced, and thus the treatment can be made more non-invasive. Particularly, it is possible to reduce the damage to normal tissues.

It is possible to create a nanobubble preparation by using high concentration nanobubbles containing the T-UFBs as a source, modifying a phospholipid forming a liposome in a negative electric charge region around the air bubble, and applying various medical substances (such as DNA and RNA) through the phospholipid.

If a drug containing high concentration nanobubble water made by the T-UFB generation is transferred into a dental canal for regenerative treatment of pulp and dentine, the drug enters deeply a dentinal tubule by the permeation effect of the nanobubble water, and the decontamination effect is prompted. This makes it possible to treat the infected root canal of the pulp safely in a short time.

<Suppression of Energy>

Next, an example for suppressing the energy to be inputted to the heating element (hereinafter simply referred to as the heater) will be described. In this embodiment, a description will be given by using a ratio between bubbling threshold energy used by the heater to bring a liquid into film boiling (hereinafter also referred to as bubbling) and inputted energy to be actually inputted to the heater. To be more precise, this embodiment will be described by using a ratio of the “inputted energy” relative to the “bubbling threshold energy”.

In order to suppress the heat generation of the element substrate 12 as much as possible, this embodiment defines an upper limit to a value indicating the ratio of the “inputted energy to be actually inputted to the heater” relative to the “bubbling threshold energy used by the heater to bring the liquid into bubbling”. This makes it possible to lower a maximum reaching temperature of the heater, to suppress an increase in temperature of the element substrate 12, and to improve generation efficiency of the T-UFBs. Moreover, by lowering the maximum reaching temperature of the heater 10, it is also possible to use a certain organic material as the heat-accumulating layer, which has not been usable from the viewpoint of heat resistance. As a consequence, it is possible to significantly reduce power consumption for bubbling, thereby improving a power saving performance and further reducing the heat generation of the element substrate 12 itself.

In the following, a structure of the element substrate 12 and a principle of the bubbling will be described to begin with. Then, a description will be given of a reason why the organic material can be used as mentioned above by suppressing the ratio of the “inputted energy to be actually inputted to the heater” relative to the “bubbling threshold energy used by the heater to bring the liquid into bubbling” and advantageous effects thereof. The following description will be given on the assumption that the heater 10 is located below the liquid W in terms of the direction of the gravity and the liquid W above the heater 10 is heated and brought into the film boiling. Moreover, the description will be given on the assumption that the heat-accumulating layer of the element substrate 12 is formed in a direction on an opposite side of a direction of presence of the liquid W relative to the heater 10 in terms of a stacking direction of the element substrate 12.

First, the structure of the element substrate 12 and the principle of the bubbling will be described. As mentioned earlier, the bubbles of the liquid W are generated by heating the heater 10. The film boiling (film bubbling) begins at a time point that a film on the uppermost layer of the element substrate 12 reaches some 300° C. by the heat from the heater 10. In this instance, the heat also diffuses in a direction of a layer below the heater 10 (an opposite direction to the direction of presence of the liquid W). In a case where no countermeasures are provided to the layer below the heater 10, a large amount of the heat diffuses below the heater 10 before the uppermost film in contact with the liquid W reaches 300° C., thus causing a deterioration in bubbling efficiency relative to inputted power.

In the element substrate 12 that generates the T-UFBs, the heat-accumulating layer having lower heat conductivity than that of the substrate is generally formed below the heater 10 in order to suppress the diffusion of the heat below the heater 10. To be more precise, a SiO₂ film is formed as the heat-accumulating layer. Here, it has been known that this SiO₂ heat-accumulating layer has a variable effect on the bubbling depending on its thickness. In a certain film configuration, the occurrence of heat dissipation in a downward direction is not negligible if the thickness of the SiO₂ film is equal to or below 2 μm and it is therefore necessary to increase the inputted power. Meanwhile, if the thickness of the SiO₂ film is equal to or above 4 μm, the amount of heat accumulated in SiO₂ is increased and the temperature of the element substrate 12 is increased as a consequence. Accordingly, the bubbling occurs even after applying the power for the bubbling. Otherwise, the accumulated heat may reduce the product life of the heater 10. This phenomenon means that the heat accumulated in the heat-accumulating layer may also adversely affect the bubbling. An ideal material for the heat-accumulating layer is a material that has very low heat conductivity as well as low heat capacity (in other words, low specific heat). If such a material is adaptable to the heat-accumulating layer, almost all the energy inputted to the heater 10 will be used for heating the upper layer side of the heater and the energy efficiency will be thus improved.

Next, a description will be given of a relation between a set value of the energy to be inputted to the heater and an increase in temperature of the heater 10 concerning the “bubbling threshold energy used by the heater to bring the liquid into bubbling”. The “bubbling threshold energy” is energy required for bubbling the liquid W (minimum energy required for bubbling) by heating with the heater 10. To be more precise, this is the energy calculated from the voltage and the current pulse width at the point of start of the bubbling as a consequence of gradually extending the pulse width of the inputted current at the constant voltage (see FIG. 6A). On the other hand, the “energy inputted to the heater” means the energy inputted directly to the heater 10. The bubbling is generated under such a condition that the “energy inputted to the heater” is larger than the “bubbling threshold energy”. For this reason, a ratio of the “energy inputted to the heater” relative to the “bubbling threshold energy” turns out to be a value equal to or above 1 in the case of causing the heater 10 to generate the bubbling.

FIG. 12 is a graph illustrating a relation between the “set value of the energy to be inputted to the heater” relative to the “bubbling threshold energy” and the maximum reaching temperature of the heater corresponding to the set value. In the case where the “energy inputted to the heater” is larger than the “bubbling threshold energy”, the heater 10 is further heated even after the bubbling depending on the aforementioned value (that is, depending on the set value of the ratio) and the heater 10 will eventually turn into a boil-dry state. FIG. 12 plots a result of simulation indicating how the maximum reaching temperature of the heater 10 is increased in response to the set value of the ratio. The horizontal axis of FIG. 12 indicates the ratio of the “energy inputted to the heater” relative to the “bubbling threshold energy”. The vertical axis of FIG. 12 indicates the maximum reaching temperature of the heater. As the value of the ratio is increased, the temperature of the heater is increased and the temperature reaches 450° C. in the case where the value of the ratio is equal to 1.17. This phenomenon means that the temperature of the layer below the heater 10 also reaches a value close to 450° C. in the case where the value of the ratio is equal to 1.17.

Here, SiO₂ is generally used as the material of the heat-accumulating layer in the element substrate 12 as mentioned above. In the case of using SiO₂, there is no problem in light of heat resistance even if the temperature reaches a value close to 700° C. at the time that the value of the ratio is equal to 1.69, for example.

Meanwhile, it has been known that a film having small heat conductivity in general, like an organic material such as a heat-resistant polyimide film, has heat conductivity which is about one-quarter as large as that of SiO₂. The heat conductivity is correlated with the distance. Accordingly, if the organic material like heat-resistant polyimide can be used as the heat-accumulating layer, it is possible to reduce the film thickness of the heat-accumulating layer one-quarter as large as that in the case of SiO₂. As a consequence, the energy to be inputted to the heater can be significantly reduced. Now, a specific description will be given below.

The heat conductivity of SiO₂ is assumed to be 1.38 W/m·K and the specific heat thereof is assumed to be 0.76 J/g·K, for example. Meanwhile, the heat conductivity of heat-resistant polyimide is assumed to be 0.29 W/m·K and the specific heat thereof is assumed to be 1.13 J/g·K. In the meantime, the film thickness of SiO₂ serving as the heat-accumulating layer is assumed to be 2 μm. In the case where heat-resistant polyimide substitutes for the heat-accumulating layer equivalent to that made of SiO₂, the film thickness required for heat-resistant polyimide becomes 0.29/1.38 times as large based on the relation of the heat conductivities therebetween. In other words, in the case where the film thickness of SiO₂ is 2 μm, the sufficient film thickness of heat-resistant polyimide turns out to be 0.29/1.38 times as large as 2 μm, or 0.42 μm to be more specific.

Meanwhile, the heater is assumed to be in a square shape with each side equal to 20 μm. In this case, the heat capacity to be accumulated in the heat-accumulating layer is derived from the area corresponding to the size of the heater, the thickness of the layer, and the specific heat. The specific gravity of SiO₂ is 2.2 g/cm³ and the specific gravity of heat-resistant polyimide is 1.47 g/cm³. The heat capacity is calculated by the mass (g)×the specific heat (J/g·K). Accordingly, the heat capacity of the SiO₂ heat-accumulating layer is calculated by the mass 1.76×10⁻²¹×the specific heat 0.76=1.33×10⁻²¹ J/K. Meanwhile, the heat capacity of the heat-resistant polyimide heat-accumulating layer is calculated by the mass 2.47×10⁻²²×the specific heat 1.13=0.279×10⁻²¹ J/K. A comparison between these two heat capacities turns out to be 0.279/1.33. That is to say, heat-resistant polyimide has the heat capacity which is about 20% as large as that of SiO₂ in this example. In other words, it turns out that heat-resistant polyimide only needs to accumulate about 20% as much heat as that by SiO₂ in light of suppressing dissipation of the heat in the downward direction of the heater 10. This means that the use of heat-resistant polyimide as the heat-accumulating layer successfully reduced a heat loss in the layer below the heater 10 by about 20% as compared to the case of the SiO₂ heat-accumulating layer. As a result of conducting simulations of this effect, the inputted energy was successfully reduced by about 30%. To be more precise, the simulations were conducted on the energy inputted for the bubbling with the heater using the heat conductivity and the specific heat corresponding to the SiO₂ heat-accumulating layer and on the energy inputted for the bubbling with the heater using the heat conductivity and the specific heat corresponding to the heat-resistant polyimide heat-accumulating layer, respectively. As a consequence, in the case of using the heat-resistant polyimide heat-accumulating layer, the inputted energy was successfully reduced by about 30% as compared to the case of using the SiO₂ heat-accumulating layer.

FIG. 13 is a graph illustrating a decomposition temperature of heat-resistant polyimide. Here, the heat resistance means a characteristic that the decomposition of the material is substantively suppressed under a conduction equal to or below a specific temperature. For example, polyimide has heat resistance at a temperature below 450° C. FIG. 13 indicates that decomposition of heat-resistant polyimide starts at a temperature equal to or above 450° C. This phenomenon means that the heat-resistant polyimide having low heat conductivity can be used as the heat-accumulating layer if the maximum reaching temperature of the heater can be controlled below 450° C. That is to say, the maximum reaching temperature of the heater is controlled below 450° C. by controlling the value of the ratio of the “energy inputted to the heater” relative to the “bubbling threshold energy”. To be more precise, the energy to be inputted to the heater 10 is controlled such that the ratio of the “energy inputted to the heater” relative to the “bubbling threshold energy” falls below 1.17.

In this way, the maximum reaching temperature of the heater can be controlled below 450° C., so that heat-resistant polyimide is usable as the heat-accumulating layer. The use of heat-resistant polyimide makes it possible to form the thin heat-accumulating layer. As a consequence, it is possible to reduce the heat capacity of the heat-accumulating layer and thus to realize energy saving. Moreover, generation of extra heat can be suppressed by realizing the energy saving. There is also a good effect on the product life of the heater by realizing the energy saving. Specifically, an oxidation rate of the cavitation-resistant film deposited on the heater is reduced by suppressing the maximum reaching temperature of the heater to a lower level. Accordingly, it is possible to suppress a deterioration of the cavitation-resistant film due to oxide film disruption, and thus to achieve the long product life of the heater.

This embodiment has described the example of using heat-resistant polyimide as the material of the heat-accumulating layer. However, other materials can achieve similar effects as long as such a material has the similar relation between the heat conductivity and the specific heat, like the heat conductivity below 0.3 W/m·K and the specific heat below 1.14 J/g·K, for example.

As described above, the energy inputted to the heater 10 is controlled in this embodiment such that the ratio of the “energy inputted to the heater” relative to the “bubbling threshold energy” falls below 1.17. Here, a supplementary explanation will be given of the concept of the ratio of the “energy inputted to the heater” relative to the “bubbling threshold energy”. The energy actually inputted to the heater varies depending on a difference (such as a variation) in resistance of wiring connected to the respective heaters in the case where the numerous heaters 10 are arranged on the element substrate 12. This energy also varies depending on environments of the element substrate 12 or a state of a surface to generate the bubbles. If there is a heater that receives the insufficient energy, the liquid is not bubbled on the heater. As a consequence, the bubbling efficiency of the UFBs is reduced.

In this regard, it is preferable to set the “energy inputted to the heater” such that every heater selected from the numerous heaters 10 mounted on the element substrate 12 and supposed to generate the bubbles at once by applying the voltage pulse thereto can generate the bubbles properly. In other words, the “energy inputted to the heater” is set in accordance with the “bubbling threshold energy” of the heater which is least likely to generate the bubbles among the group of the heaters supposed to generate the bubbles at once by applying the voltage pulse. The set value which is set as described above is set in such a way as to allow all the heaters to generate the bubbles, or to allow the heater that is least likely to generate the bubbles to stably generate the bubbles, for example, even in the case where environmental conditions vary. In the case of the constant voltage, for instance, the set value is set in such a way as to extend the pulse width more than the pulse width of the bubbling threshold. As a result, the value of the above-described ratio may vary between the heater that is most likely to generate the bubbles and the heater that is least likely to generate the bubbles among the group of heaters supposed to generate the bubbles at once by applying the voltage pulse.

Usually, the value of the ratio of the heater that is least likely to generate the bubbles is set equal to or above 1.06 in consideration of the aforementioned variation and other factors. In the meantime, the inputted energy set for the heater that is least likely to generate the bubbles is the same inputted energy to the heater that is most likely to generate the bubbles. For this reason, the excessive power may be supplied to the heater that is most likely to generate the bubbles due to the difference in wiring resistance and the like. If the wiring resistance is large, there may be a case where the heater with the ratio of the “energy inputted to the heater” relative to the “bubbling threshold energy” in excess of 1.69 may come into being. Such an increase in value of the ratio means an increase in amount of heat generation of the element substrate 12. Specifically, since the current continuously flows after generating the bubbles as described above, the liquid is depleted from the surface of the heater whereby the temperature thereof is increased without being cooled down. Eventually, the heater turns into a boil-dry state, thus leading to the increase in temperature of the element substrate 12. As illustrated in FIG. 12, the maximum reaching temperature of the heater becomes 700° C. or above in the case where the value of the ratio is 1.69. As a result, the entire element substrate 12 is heated and the liquid before the bubbling is heated as well, thereby reducing the generation efficiency of the UFBs.

For this reason, regarding the element substrate 12, it is preferable to suppress the difference (the variation) in wiring resistance connected to the multiple heaters supposed to generate the bubbles at once as much as possible, and to reduce the difference in bubbling threshold between the heater that is most likely to generate the bubbles and the heater that is least likely to generate the bubbles. This embodiment has described that the energy inputted to the heater 10 is preferably controlled such that the ratio of the “energy inputted to the heater” relative to the “bubbling threshold energy” falls below 1.17. This ratio is targeted for the heater that is most likely to generate the bubbles among the group of heaters supposed to be generate the bubbles at once by applying the voltage pulse. Instead, the ratio may be targeted for a portion of the heaters among the group of heaters supposed to be generate the bubbles at once by applying the voltage pulse. For example, the energy to be inputted to about 80% of the heaters among the group of heaters supposed to generate the bubbles at once by applying the voltage pulse may be set to fall below this predetermined ratio (1.17). In other words, the energy to be applied to another portion of the heaters among the heaters supposed to generate the bubbles at once may be set to a ratio above the predetermined ratio. In generating the T-UFBs, it is possible to generate the UFBs efficiently by causing all the heaters to generate the bubbles. Nevertheless, even if the maximum reaching temperature of a portion of the heaters becomes higher than the prescribed maximum reaching temperature of other heaters, it is still possible to generate the UFBs almost efficiently. Alternatively, the energy to be inputted to about 50% of the heaters among the group of heaters supposed to generate the bubbles at once by applying the voltage pulse may be set to fall below this predetermined ratio (1.17). In this case, the heater that is least likely to generate the bubbles may fail to generate the bubbles depending on its wiring resistance and other factors thereof. In generating the T-UFBs, it is possible to generate the UFBs efficiently by causing all the heaters to generate the bubbles. Nevertheless, even if a portion of the heaters do not generate the bubbles, it is still possible to generate the UFBs almost efficiently. As described above, the element substrate 12 may be configured such that a certain percentage of the heaters 10 therein have the value of the ratio falling below the predetermined value (1.17).

FIGS. 14A and 14B are plan views illustrating an example of the element substrate 12 of this embodiment. FIG. 14A illustrates an example of the entire element substrate 12 while FIG. 14B is an enlarged view of a portion in FIG. 14A. The multiple heaters 10, an electrode pad portion 352, and the wiring 308 (wiring patterns) to connect the heaters 10 to the electrode pad portion 352 are formed on the element substrate 12. In this example, the heaters 10 connected to a common wiring pattern out of the electrode pad portion 352 serve as the heaters that belong to the group of heaters supposed to generate the bubbles at once by applying the voltage pulse.

The following method may be used as a method of suppressing the aforementioned variation in ratio between the heater that is most likely to generate the bubbles and the heater that is least likely to generate the bubbles among the group of heaters supposed to generate the bubbles at once by applying the voltage pulse.

For example, as illustrated in FIG. 14B, there is a method of setting a width of a wiring pattern 308 to connect the heater 10 remote from the electrode pad portion 352 larger than a width of another wiring pattern 308 to connect the heater 10 close to the electrode pad portion 352. Meanwhile, the multiple heaters 10 may be provided with a common wiring pattern while reducing lengths of individual wiring patterns to be individually connected to the heaters 10. Here, a region of the common wiring pattern may be expanded by forming multiple wiring layers in the element substrate 12. In the meantime, a not-illustrated switch may be provided on the wiring patterns 308. Then, the current from the electrode pad portion 352 is fed to the corresponding heater 10 in the case where the switch is on, and the current from the electrode pad portion 352 is not fed to the corresponding heater 10 in the case where the switch is off. Moreover, the variation in energy inputted to the heaters 10 may be suppressed by driving the heaters 10 in a time-division manner. Other various methods may be applied in order to suppress the variation in energy.

<Manufacturing Method>

Next, a method of manufacturing the element substrate 12 as illustrated in FIGS. 14A and 14B will be described. To be more precise, a description will be given of a manufacturing method of manufacturing the element substrate 12 having the lower heat conductivity of the heat-accumulating layer than the case of the using SiO₂ by using heat-resistant polyimide as the material of the heat-accumulating layer.

FIGS. 15A to 16F are diagrams for describing an example of manufacturing the element substrate 12. Each of FIGS. 15A to 16F shows a cross-section of the element substrate 12. FIGS. 15A to 15G and FIG. 16A to 16E illustrate the manufacturing method in chronological order. FIG. 16F illustrates an example of the finished element substrate 12.

First, the silicon substrate 304 serving as a UFB generating substrate is prepared as illustrated in FIG. 15A. Next, as illustrated in FIG. 15B, U-Varnish S which is polyimide varnish manufactured by Ube Industries is coated on a surface of the silicon substrate 304 by spin coating, and a heat treatment is conducted at 350° C. for 30 minutes. Thus, the heat-accumulating layer 305 (the thermal oxide film) in a thickness of 0.42 μm is formed. In other words, the heat-accumulating layer 305 is formed by using heat-resistant polyimide. Although this example describes a case of forming the heat-accumulating layer 305 from a single layer, the heat-accumulating layer may be formed from two or more layers as illustrated in FIG. 5A. If the heat-accumulating layer is formed from two or more layers, only one of the layers needs to contain heat-resistant polyimide.

Next, as illustrated in FIG. 15C, the resistive layer 307 is formed in a thickness of 30 nm by using TaSiN as its material and in accordance with a sputtering method. Then, Al serving as the material of the wiring is continuously formed thereon in a thickness of 500 nm as the wiring 308. Next, the two materials of TaSiN and Al are formed into a predetermined shape by photolithography. To be more precise, a photosensitive resist 351 manufactured by Tokyo Ohka Kogyo is coated in a thickness of 2 μm by spin coating. Then, the resist is subjected to exposure with the i-line stepper FPA-3000 i5 manufactured by Canon while using a glass mask for achieving exposure in the predetermined shape. Then, the resist is developed and left in the shape of the wiring patterns 308 illustrated in FIGS. 14A and 14B. Subsequently, Al and TaSiN are etched simultaneously by reactive ion etching while using BCl₃ gas and Cl₂ gas. Thus, the wiring patterns 308 are formed.

Thereafter, the substrate is dipped in the resist remover 1112A manufactured by Rohm and Haas Electronic Materials so as to peel and remove the resist. Then, the photosensitive resist 351 manufactured by Tokyo Ohka Kogyo is coated again in a thickness of 2 μm by spin coating. Next, the resist is subjected to exposure with the i-line stepper FPA-3000 i5 while using a glass mask for achieving exposure in a predetermined shape. Then, the resist is developed and left in a predetermined shape as illustrated in FIG. 15E. Subsequently, only Al located above TaSiN is partially removed by wet etching using phosphoric acid. Thus, the heater 10 is formed as illustrated in FIG. 15F. Then, the substrate is dipped in the remover 1112A and the resist 351 is peeled and removed as illustrated in FIG. 15G.

Next, the protective layer and the cavitation-resistant film are formed in order to insulate the heater 10 and the wiring 308 from the liquid and to protect the heater 10 and the wiring 308 against the heat and impact associated with the bubbling. Specifically, as illustrated in FIG. 16A, the protective layer 309 is formed on the substrate of FIG. 15G. In this example, a silicon nitride (hereinafter referred to as SiN) film is formed in a thickness of 200 nm as the protective layer 309 in accordance with ALD film deposition, which is a method involving a lower deposition temperature of about 300° C. as compared to CVD while avoiding development of pin holes even in the case of a thin film. Subsequently, as illustrated in FIG. 16B, a metal Jr film is formed in a thickness of 200 nm as the cavitation-resistant film 310 by sputtering. Here, SiN serves as a protective film to establish electrical isolation from the liquid. Meanwhile, metal Ir has a function as the cavitation-resistant film that protects the heater against the heat generated at the heater portion, in particular, and impact attributable to the bubble generation and the bubble disappearance (that is, the cavitation).

The protective layer 309 and the cavitation-resistant film 310 are formed into a predetermined shape by photolithography. The photosensitive resist 351 manufactured by Tokyo Ohka Kogyo is coated again in a thickness of 2 μm by spin coating. Then, the resist is subjected to exposure with the i-line stepper FPA-3000 i5 while using a glass mask for achieving exposure in the predetermined shape. Then, the resist 351 is developed and left in a predetermined shape as illustrated in FIG. 16C. The metal Jr film is etched by reactive ion etching while using CF₄, and then SiN is continuously etched. In this way, the electrode pad portion 352 for establishing connection with external wiring is formed as illustrated in FIG. 16D. At the end, the substrate is dipped in the remover 1112A and the resist is peeled and removed to finish the UFB generating substrate (FIG. 16E). FIG. 16F is the diagram illustrating the entire substrate after this process, which depicts the electrode pad portions 352 and the heaters 10.

According to this disclosure, it is possible to improve UFB generation efficiency by suppressing an increase in temperature of a liquid in a case of generating T-UFBs.

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. 2019-198519, filed Oct. 31, 2019, which is hereby incorporated by reference wherein in its entirety.

Claims

1. An ultrafine bubble generating apparatus configured to generate ultrafine bubbles by bringing a liquid into film boiling while using a heater provided to a substrate, the apparatus comprising: a control unit configured to input energy to the heater such that a value of a ratio of energy to be inputted to the heater relative to energy with which the heater generates film boiling falls below 1.17 under a condition that the energy to be inputted to the heater is larger than the energy with which the heater generates film boiling.

2. The ultrafine bubble generating apparatus according to claim 1, wherein a plurality of the heaters are arranged on the substrate, andthe control unit controls the energy to be inputted to the plurality of the heaters such that the value of the ratio falls below 1.17 in at least a prescribed percentage of the plurality of the heaters.

3. The ultrafine bubble generating apparatus according to claim 1, wherein the substrate includes a heat-accumulating layer located in an opposite direction to a direction of presence of the liquid relative to the heater, andthe heat-accumulating layer is made of a heat-resistant organic material.

4. The ultrafine bubble generating apparatus according to claim 3, wherein a maximum reaching temperature that the heater reaches by the input of the energy is lower than a decomposition temperature of the heat-accumulating layer.

5. The ultrafine bubble generating apparatus according to claim 3, wherein a maximum reaching temperature that the heater reaches by the input of the energy is below 450° C.

6. The ultrafine bubble generating apparatus according to claim 3, wherein the heat-resistant organic material is a material having heat conductivity below 0.3 W/m·K.

7. The ultrafine bubble generating apparatus according to claim 3, wherein the heat-resistant organic material is a material having specific heat below 1.14 J/g·K.

8. The ultrafine bubble generating apparatus according to claim 3, wherein the heat-resistant organic material is heat-resistant polyimide.

9. An ultrafine bubble generating apparatus configured to generate ultrafine bubbles by bringing a liquid into film boiling while using a heater provided to a substrate, the substrate comprising: a heat-accumulating layer made of a heat-resistant organic material and located in an opposite direction to a direction of presence of the liquid relative to the heater.

10. The ultrafine bubble generating apparatus according to claim 9, further comprising: a control unit configured to input energy to the heater such that a maximum reaching temperature that the heater reaches by the input of the energy becomes lower than a decomposition temperature of the heat-accumulating layer.

11. The ultrafine bubble generating apparatus according to claim 9, further comprising: a control unit configured to input energy to the heater such that a maximum reaching temperature that the heater reaches by the input of the energy falls below 450° C.

12. The ultrafine bubble generating apparatus according to claim 9, wherein the heat-resistant organic material is a material having heat conductivity below 0.3 W/m·K.

13. The ultrafine bubble generating apparatus according to claim 9, wherein the heat-resistant organic material is a material having specific heat below 1.14 J/g·K.

14. The ultrafine bubble generating apparatus according to claim 9, wherein the heat-resistant organic material is heat-resistant polyimide.

15. An ultrafine bubble generating apparatus configured to generate ultrafine bubbles by bringing a liquid into film boiling while using a heater provided to a substrate, the substrate comprising: a heat-accumulating layer made of a material having heat conductivity below 0.3 W/m·K and specific heat below 1.14 J/g·K, and located in an opposite direction to a direction of presence of the liquid relative to the heater.

16. A method of manufacturing an element substrate used in an ultrafine bubble generating apparatus configured to generate ultrafine bubbles by bringing a liquid into film boiling while using a heater, the method comprising: preparing a substrateforming a heat-accumulating layer above the substrate in a stacking direction by using a heat-resistant material;forming the heater and a wiring pattern above the heat-accumulating layer in the stacking direction;forming a protective layer above the heater and the wiring pattern in the stacking direction; andforming a cavitation-resistant film above the protective layer in the stacking direction.