JP2000039346A - Area flowmeter and liquid reservoir tank - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid adhering of stain in liquid to the inner surface of flowmeter and the like. SOLUTION: The inner wall surface of a tapered pipe 1 is coated with a photocatalytic layer 11 containing anatase type titanium oxide as a kind of photocatalytic material. By coating with this kind of photocatalytic layer 11, the inner surface of the tapered pipe 1 becomes to have photocatalytic material. Furthermore, the photocatalytic layer is also formed on the surface of a float 2. By irradiating a float type flowmeter by the light from a light source LS such as fluorescence light, chemical fluorescent light or black light or the sun light, condensate water from the condenser is let pass through the float type flowmeter, stain such as iron oxide and the like mixed in the condensate does not adhere to the inner wall of the tapered pipe 1 and so the tapered pipe 1 maintains transparent state for a long period.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an area type flow meter and a liquid storage tank, and more specifically, to an area type flow meter interposed in a liquid flow path and a liquid provided in a liquid flow path, for example. Related to storage tanks. The present invention particularly relates to an area-type flowmeter and a liquid storage tank to which dirt in a liquid hardly adheres and which can remove dirt by irradiating light such as visible light or ultraviolet light even if the dirt once adheres. .

[0002]

2. Description of the Related Art In a boiler, a power plant, a pure water production apparatus, a chemical plant and the like, not only tap water but also lake water, raw water, boiler water, cooling water, etc. Fresh water such as well water and river water, and seawater are used. In a power plant, steam from a power generation turbine is returned to water by a condenser, and this water is supplied to a boiler as resupply water. For measuring the flow rates of fresh water, seawater, and resupply water, area flow meters represented by float flow meters have been widely used because of their simple structure and robustness.

[0003] However, the freshwater and seawater contain various contaminants such as dust, bacteria, fungi, and iron oxide. Further, iron oxide from the water pipe of the boiler and other pipes is mixed in the return water. Therefore, when the float type flow meter is used for a long period of time, dirt derived from impurities in the fresh water and seawater, and red-brown precipitates derived from iron oxide mixed in the resupply water are float-type in a short time. Deposits inside the flow meter. Therefore, in a float type flow meter of a type in which the flow rate is measured by visually observing the float in the glass tube, there is a problem that the float becomes invisible within a short time due to the dirt. Even in a float type flow meter that detects the position by, for example, magnetic means, the distance between the float and the inner wall of the metal tube is disturbed due to contamination of the float, and as a result, the position of the float is detected. However, there has been a problem in that the accuracy of measurement decreases, and the flow area of the liquid sample decreases, and the measurement accuracy decreases.

In a continuous water quality analyzer for continuously monitoring the pH and the like of boiler water, it is necessary to supply sample water such as the boiler water at a constant supply pressure. Therefore, in the continuous water quality analyzer and the like, a pipe is branched from a sample water introduction pipe for introducing the sample water, a liquid storage tank such as a head vessel is provided at one end of the pipe, and a fixed head is provided for the sample water. Have given. In the head vessel, a transparent window is formed on at least a part of the side surface so that the presence or absence of sample water can be visually checked from the outside.

However, when the head vessel is used for a long time, dirt such as dust, bacteria, fungi, and iron oxide in the sample water may be contaminated on the entire inner wall surface including the inside of the window as in the case of the float type flow meter. Therefore, there is a problem that the inside of the head vessel cannot be seen from the outside.

Conventionally, the float type flow meter and the head vessel have been frequently disassembled and washed to remove dirt.

However, when disassembling and cleaning the float type flow meter and head vessel, it is necessary to close the flow path in which the float type flow meter and head vessel are mounted. It was also necessary to stop the continuous water quality analyzer and the like that had been used. Further, disassembling and cleaning the float type flow meter and the head vessel are troublesome, and there is a possibility that breakage may occur during disassembly or reassembly.

Therefore, it is necessary to prevent the contamination contained in the liquid such as the sample water from adhering to the area type liquid flow meter such as the float type flow meter and the inner wall of the liquid storage tank such as the head vessel. It has been desired that at least the dirt hardly adheres.

An object of the present invention is to provide an area flow meter and a liquid storage tank in which dirt in a liquid is less likely to adhere to an inner wall.

[0010]

Means for Solving the Problems The area type flow meter aiming at solving the above problems is as follows. An area type flow meter comprising a photocatalytic material contained in a liquid contact surface in contact with a liquid and promoting decomposition of an organic substance by light irradiation, and a light source for irradiating the photocatalytic material with light. , 2. The liquid contact surface in the area type flowmeter includes a liquid introduction part for introducing liquid from below, a liquid derivation part for deriving liquid upward, and a float that moves up and down in the liquid inside, and extends in the vertical direction. 2. the inner wall surface of the transparent portion of the tapered tube, which can be seen through the float from outside; The liquid contact surface in the area type flow meter is a taper pipe extending vertically with a liquid introduction part for introducing liquid downward and a liquid derivation part for extracting liquid upward.
3. the outer surface of the float that moves up and down in the liquid; A liquid storage tank comprising at least a part of a transparent side wall, a liquid introduction flow path and a liquid discharge flow path, wherein the inner wall surface of the side wall contains a photocatalytic material.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Example of the Area Type Flow Meter of the Present Invention A float type flow meter which is an example of the area type flow meter according to the present invention will be described below.

FIG. 1 shows a longitudinal section of the float type flow meter.

In the float type flow meter shown in FIG. 1, a glass tapered pipe 1 extending in the vertical direction and having an inner diameter increasing upward, and a float 2 moving up and down inside the tapered pipe 1 are shown. A sample introduction unit 3 attached to the lower end of the tapered tube 1; and a sample lead-out unit 4 attached to the upper end of the tapered tube 1. A sample water introduction channel 31 is formed inside the sample water introduction section 3, and the sample water outlet section 4 is formed.
Is formed with a sample water outlet channel 41.

At one end of the sample water introduction channel 31, a sample water introduction line A for introducing sample water to the float type flow meter is provided.
Is connected to a lower end of the tapered tube 1 at the other end of the sample water introduction flow path 31. On the other hand, the upper end of the tapered tube 1 is connected to one end of the sample water outlet channel 41, and the sample water flowing out of the float flow meter flows to the other end of the sample water outlet channel 41. The sample water outlet pipe B is connected. The arrows in FIG. 1 indicate the directions in which the sample water flows in the sample water introduction pipe A, the float type flow meter, and the sample water outlet pipe B.

As shown in FIG. 1, the inner wall surface of the tapered tube 1 is covered with a photocatalytic layer 11 containing anatase type titanium oxide, which is a kind of photocatalytic material. By covering with such a photocatalyst layer 11, the inner wall surface of the tapered tube 1 has a photocatalytic material.

The photocatalyst layer 11 is formed, for example, by applying silica sol to the inner wall surface of the tapered tube 1 and baking it at a temperature of about 1000 ° C. to form a thin layer of silicon dioxide. It can be formed by applying an organic titanium compound and finally thermally decomposing the organic titanium compound at a temperature of about 500 ° C.

Further, a photocatalytic layer is also formed on the surface of the float 2. In the float 2, the photocatalyst layer is formed by coating the surface with a coating material in which fine particles of anatase-type titanium oxide whose surface is covered with a layer of porous calcium phosphate are dispersed.

In the float type flow meter shown in FIG. 1, the inner wall surface of the tapered tube 1 corresponds to the liquid contact surface in the area type flow meter of the present invention.

While irradiating the float type flow meter with light from a light source LS such as a fluorescent lamp, a chemical fluorescent lamp, or a black light, or sunlight, for example, returning water supplied from a condenser to the float type flow meter. When circulated in the tapered pipe 1, dirt such as iron oxide mixed in the resupply water does not adhere to the inner wall of the tapered pipe 1, and the tapered pipe 1 maintains a transparent state for a long period of time.

When the float type flow meter is exposed to light from the light source LS or sunlight after using the float type flow meter for a long time, the dirt attached to the inner wall of the tapered tube 1 in the float type flow meter is reduced. Is stripped and removed by the flow of water inside the tapered tube 1.

It is not always clear what effect the above action in the float type flow meter has due to the anatase type titanium oxide contained in the photocatalytic layer. However, titanium oxide is activated when irradiated with light such as ultraviolet light, and when water comes into contact with the activated titanium oxide, the water is oxidized by the titanium oxide to generate hydroxy radicals. It is known that dissolved oxygen present in water is reduced by the activated titanium oxide to become a superoxide anion. Therefore, even in the sample water flowing through the float type flow meter, it is considered that the anatase type titanium oxide in the photocatalyst layer generates the hydroxyl radical and the superoxide anion, and the dirt is oxidatively decomposed by these active species. Can be Further, when the photocatalyst layer is irradiated with ultraviolet light, the surface of the photocatalyst layer becomes superhydrophilic by the action of anatase type titanium oxide contained in the photocatalyst layer, whereby dirt on the photocatalyst layer surface is easily removed by water flow. It is also considered that they come off. 2. Example of Liquid Storage Tank Hereinafter, a head vessel, which is an example of the liquid storage tank according to the present invention, will be described with reference to FIG.

The head vessel shown in FIG. 2 is a continuous water quality analyzer for continuously analyzing the water quality of boiler water at a power plant or the like. A fixed head is provided to the boiler water and introduced into the water quality continuous analyzer. This is the head vessel used for

The head vessel has a substantially cylindrical shape or a rectangular parallelepiped shape as a whole, and has a transparent cylindrical side wall portion 5 extending in the vertical direction, and a disk-shaped portion mounted on the lower end of the side wall portion 5. It has a bottom plate 6 and a disk-shaped top plate 7 mounted on the upper end of the side wall portion 5. The bottom plate 6 and the top plate 7
Are formed at the center portion thereof with a protruding portion 61 and a protruding portion 71 protruding toward the center portion of the side wall portion 5, respectively. In the bottom plate 6, the protrusion 61 is fitted to the lower end of the side wall 5, and in the top plate 7, the protrusion 71 is fitted in the side wall 5.
Is fitted at the upper end.

In the vicinity of the peripheral edge of the bottom plate 6, a head pipe 62 branched from a sample water introduction pipe C for introducing sample water into the continuous water quality analyzer 8 penetrates. At a position on the bottom plate 6 opposite to the head pipe 62 with the central portion interposed therebetween, excess sample water is drained to the outside as a drain to keep the storage height of the sample water inside the head vessel constant. The drain discharge pipe 63 penetrates. The upper end of the drain discharge pipe 63 is cut obliquely upward at a certain angle with respect to the axis. In FIG. 2, the arrow indicates the direction in which drain is discharged from the drain discharge pipe 63.

The side wall 5 is formed of a transparent hard polyvinyl chloride resin or the like, and the inner wall surface of the side wall 5 is covered with a photocatalyst layer 51 containing anatase type titanium oxide, which is a kind of photocatalytic material. I have. The photocatalyst layer 51
For example, a mixed solution of silica sol and trimethoxymethylsilane is applied to the inner wall surface of the side wall 5 and cured at a temperature lower than the softening point of the hard polyvinyl chloride resin. It can be formed by applying a mixed solution of silica sol and trimethoxysilane and curing by heating. Alternatively, by attaching the side of the polyester film having the anatase type titanium oxide layer formed on one surface thereof, on which the titanium oxide layer is not formed, to the inner wall surface of the side wall portion 5,
The photocatalyst layer 51 can be formed.

In the head vessel shown in FIG.
The side wall portion 5 corresponds to a side wall in the liquid storage tank of the present invention, and the head pipe 62 corresponds to a liquid introduction flow path and a liquid discharge flow path in the liquid storage tank of the present invention.

In a state where the head vessel is exposed to the light from the light source LS described with reference to the float type flow meter or the sunlight, the water supplied from the condenser to the continuous water quality analyzer provided with the head vessel, for example, from a condenser. Circulates, iron oxides and the like mixed in the resupply water are removed from the side wall 5 of the head vessel.
The side walls 5 remain transparent for a long period of time because they do not adhere to the inner wall.

When resupply water is allowed to flow through the head vessel for a long time without being exposed to the light from the light source or sunlight, iron oxide mixed in the resupply water adheres to the inner wall of the side wall 5. A reddish-brown stain layer is formed, but when light or sunlight from the light source is applied to the head vessel, the side wall 5
The dirt adhering to the inner wall of the head vessel is peeled off by the flow of water inside the head vessel, and is discharged from the drain discharge pipe 63 together with the drain.

The effect of the head vessel is as follows.
It is considered that both are based on the same photocatalytic action of titanium oxide as described in the example of the float type flow meter.

3. General Description The components of the area flow meter and the liquid storage tank of the present invention will be described below.

3.1 Area type flow meter The type of liquid that can be used by the area type flow meter of the present invention is not particularly limited. For example, resupply water collected through a condenser from a steam turbine in a power plant or the like, And cooling water in a condenser or the like. Other examples include raw water and cooling water in various plants, raw water in a water purification device, a pure water production device, and the like.

As the area type flow meter of the present invention, for example,
A float type flow meter including a tapered pipe extending in the vertical direction and a float that moves up and down according to the flow rate of the liquid flowing inside the tapered pipe can be given. In the float type flow meter, a tapered pipe formed so as to expand upward is usually used as the tapered pipe. Examples of the material of the tapered pipe include acrylic resin, polycarbonate resin, polysulfone resin, polyethersulfone resin, poly (4-methylpentene-1) resin, hard polyvinyl chloride resin, poly (cyclohexadiene) resin, and poly (cyclohexane). Transparent synthetic resins such as resins, transparent materials such as various glasses such as silica glass, soda glass, and borosilicate glass, and non-magnetic metal materials such as stainless steel, aluminum alloy, pure titanium, titanium alloy, and copper alloy. Can be mentioned.

Of the float type flowmeters, in a flowmeter of a type in which the position of the float is visually detected, a taper tube formed of the transparent material can be used. When the tapered tube is formed of an opaque material, a transparent window through which the float can be observed may be provided, and the transparent window may be fitted with a transparent material. Then, the inner surface of the transparent material may be a liquid contact surface.

On the other hand, a float type flow meter in which a magnet is buried inside the float and the magnetism from the magnet is detected by magnetic detecting means such as a Hall element, a magnetoresistive element and a coil to detect the position of the float. In such cases, a tapered tube formed of the nonmagnetic metal material can be used.

In the float type flow meter, a liquid introduction portion having a liquid introduction passage for introducing a liquid into the tapered tube is provided at the lower end of the tapered tube, and the liquid outlet flow from which the liquid is led out from the tapered tube. A liquid outlet having a passage formed therein may be provided at an upper end of the tapered tube.

The sample introduction part 3 and the sample derivation part 4 in the float type flow meter shown in FIG. 1 correspond to the liquid introduction part and the liquid derivation part, respectively.

As the material of the liquid introduction part and the liquid discharge part, for example, stainless steel, pure titanium, titanium alloy,
And various metal materials such as copper alloys such as nickel silver, bronze, aluminum bronze, and beryllium bronze, various synthetic resins, and ceramics. Among the above materials, in terms of corrosion resistance, strength, and ease of processing, stainless steel,
Pure titanium, titanium alloys, copper alloys, and various synthetic resins are preferred.

In the area type flow meter of the present invention, a photocatalyst layer containing a photocatalytic material is provided on a surface in contact with the liquid.

In the float type flow meter which is an example of the area type flow meter of the present invention, the inner wall surface of the tapered pipe can be mentioned as the liquid contact surface. In the float type flow meter, the liquid contact surface may include an inner wall surface of the liquid introduction channel and an inner wall surface of the liquid outlet channel. In the float type flow meter, a photocatalyst layer may be formed only on the inner wall surface of the tapered tube, and the inner wall surface of the tapered tube, the inner wall surface of the liquid introduction channel, and the inner wall surface of the liquid outlet channel. May be provided with a photocatalyst layer.

The photocatalytic material that can be used in the photocatalyst layer includes a photoactive material in which the lower end of the conduction band is more negative than the hydrogen generation potential and the upper end of the valence band is more positive than the oxygen generation potential, that is, a photoactive material. Any material that can decompose water and generate hydrogen and oxygen when exposed to visible light or ultraviolet light in the presence of water can be used. Examples of such a photocatalytic material include titanium oxide such as rutile-type titanium oxide and anatase-type titanium oxide, strontium titanate, and potassium niobate. As the photocatalytic material, titanium oxide is preferable in terms of price, performance, and stability to light, and anatase-type titanium oxide is particularly preferable in terms of high efficiency as an optical semiconductor.

The method of forming the photocatalyst layer on the inner wall surface of the tapered tube is not particularly limited, and an appropriate method can be adopted according to the material of the tapered tube.

For example, in the case of a taper tube made of a transparent synthetic resin, an undercoating agent containing a silica sol and an organic silane compound selected from various alkoxyoxysilanes, alkoxyalkylsilanes, alkylsilanes and the like is applied to the inner wall surface. Then, drying and baking are performed at a temperature of about 60 to 100 ° C. to form a protective layer. Then, a sol of a photocatalytic material such as titanium oxide or an organic titanium compound such as tetraalkoxy titanium or tetraalkyl titanium is used. A method of forming a photoactive layer by applying a top coat agent containing the precursor compound of the photocatalytic material to be performed and the organic silane compound, followed by drying and baking can be employed. Further, the surface of the fine particles of the photocatalytic material may be covered with a thin protective layer such as calcium phosphate to stabilize the fine particles, and the fine particles dispersed in a clear paint may be directly applied to the inner wall of the tapered tube. Further, a method of attaching a plastic film having the photocatalytic material layer formed on one surface thereof to a liquid by an appropriate method may be employed.

In a tapered tube made of a non-magnetic metal material such as stainless steel, a method in which the inner wall surface is coated with a coating material in which fine particles of the photocatalytic material stabilized by appropriate means are dispersed, and A method of attaching a plastic film on which a layer of a photocatalytic material is formed by an appropriate method can be given. In the case of pure titanium and titanium alloy among the non-magnetic metal materials, a photoactive titanium oxide layer is formed on the inner wall surface of the tapered tube by oxidizing the inner wall surface of the tapered tube by an appropriate method. It is also possible.

In a taper tube made of silica glass, a method in which a sol of a photocatalytic material is applied to the inner wall surface, dried, and baked at a temperature of 400 ° C. or more can be employed. on the other hand,
In a glass containing sodium such as soda glass, a silicon dioxide layer is first formed on the inner wall surface by an appropriate method so that sodium or the like is not diffused into the layer of the photocatalytic material and the photocatalytic property is not lost. Then, a sol of a photocatalytic material is applied on the silicon dioxide layer,
A method of performing baking at a temperature of about 0 ° C. can be used.

When the photocatalyst layer is formed on the inner wall surface of the liquid introduction channel and the inner wall surface of the liquid outlet channel in addition to the inner wall surface of the tapered tube, the liquid inlet portion and the liquid outlet portion are formed of a metal material. , Or an appropriate method can be adopted depending on whether it is made of a synthetic resin. As a method for forming the photocatalyst layer, the method described for the tapered tube can be used.

The light source used to irradiate the area type flow meter of the present invention includes an artificial light source capable of generating light in the range of visible light to ultraviolet light, and sunlight. Examples of the artificial light source include a fluorescent lamp, a chemical fluorescent lamp, a mercury lamp, an ultraviolet lamp, and a black light. In an area flow meter having a tapered tube formed of a transparent material, the light from the light source can irradiate the tapered tube from outside. On the other hand, in a tapered tube formed of an opaque material such as a non-magnetic metal material, light from the light source is introduced into the tapered tube by an appropriate means such as a mirror and an optical fiber, and the light is applied to the inner wall surface. The photocatalyst layer can be irradiated. Further, the liquid introduction section and the liquid lead-out section may be formed of a transparent material, and light from the light source may be introduced into the tapered tube through the liquid introduction section and the liquid lead-out section. Further, an ultraviolet light emitting element may be provided between the inner wall surface of the tapered tube and the photocatalyst layer, and the photocatalyst layer may be irradiated with ultraviolet light from the ultraviolet light emitting element.

3.2 Liquid Storage Tank The liquid storage tank of the present invention is a storage tank provided in a liquid flow path. Specifically, the liquid storage tank is interposed in the liquid flow path and stores the liquid flowing through the flow path. Examples thereof include a temporary storage tank having a function of temporarily storing the liquid and a head vessel that gives a fixed head to a liquid introduced into a continuous analyzer such as a water quality monitoring device.

The liquid storage tank of the present invention has at least a partly transparent side wall, a liquid introduction flow path, and a liquid discharge flow path. Examples of the introduction channel include a channel having a function of introducing a liquid into a liquid storage tank.Specifically, when the liquid storage tank is a temporary storage tank, the temporary storage tank is provided. Introductory pipelines can be mentioned,
In the case where the liquid storage tank is a head vessel, a head pipe branching from the sample introduction pipe of the continuous analyzer and leading to the head vessel may be mentioned. Examples of the outlet channel include a channel for extracting a liquid from a storage tank, and examples thereof include an outlet pipe in the temporary storage tank and a head pipe in the head vessel. Note that, in the head vessel, the introduction channel and the exit channel may be the same channel.

More specifically, as the liquid storage tank, a columnar container having transparent side walls and a rectangular parallelepiped having transparent side walls, such as the head vessel shown in FIG. Container and the like.

Examples of the side wall include a side wall formed of a transparent material such as a transparent resin and various kinds of glass similar to those described for the tapered tube in the area type flow meter.

In the liquid storage tank of the present invention, a photocatalytic layer is provided on at least the inner wall surface of the side wall. The photocatalyst layer can be provided not only on the inner wall surface of the side wall but also on the adjacent ceiling surface and floor surface.

As the photocatalytic material used for the photocatalytic layer, the same photocatalytic material as described in the area type flow meter can be used. Also, the method of forming the photocatalyst layer can be appropriately selected according to the material of the side wall, and specifically, the method described for the area flow meter can be used.

The light source used to irradiate the liquid storage tank is the same as in the case of the area flow meter.

[0054]

In the area type flow meter and the liquid storage tank provided by the present invention, when visible light or ultraviolet light is irradiated, the dirt contained in the liquid does not adhere to the liquid contact surface, and Even if the liquid surface is dirty,
The dirt easily falls off due to the flow of the liquid flowing inside. Therefore, in the area type flow meter and the liquid storage tank provided by the present invention, there is no need to disassemble and clean. Further, even when the disassembly and cleaning are performed periodically, the interval between the disassembly and cleaning can be greatly extended.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of a float type flow meter which is an example of an area type flow meter provided by the present invention.

FIG. 2 is a longitudinal sectional view of a head vessel which is an example of a liquid storage tank provided by the present invention.

[Brief description of reference numerals]

DESCRIPTION OF SYMBOLS 1 ... Taper tube, 11 ... Photocatalyst layer; 2 ... Floater; 3 ... Sample introduction part, 31 ... Sample water introduction flow path;
4 ··· Sample outlet section, 41 ··· Sample water outlet channel;
..Side walls, 51 photocatalyst layers; 6 bottom plates, 61
... Projection, 62 ... Head piping, 63 ... Drain piping; 7 ... Top plate, 71 ... Projection; 8 ... Continuous water quality analyzer; A ... Sample water introduction flow Channel B: sample water outlet channel, C: sample water introduction channel, LS: light source.

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Masahiko Kurashina 2-16-2 Noguchicho, Higashimurayama-shi, Tokyo Nikkiso Co., Ltd. Higashimurayama Works F-term (reference) 2F030 CA07 CC01 CF03 CH05 4G069 AA02 AA08 AA11 BA02B BA04B BA22B BA48A BB14B BC09B CA01 CA11 CD10 DA05 EA07 EC22Y FA01 FB23 FB29 FB30 FB33 FB34

Claims (4)

[Claims] 1. An area characterized by comprising a photocatalytic material contained in a liquid contact surface in contact with a liquid and promoting decomposition of an organic substance by light irradiation, and a light source for irradiating the photocatalytic material with light. Flow meter. 2. The liquid-contacting surface according to claim 1, wherein the liquid-contacting surface includes a liquid introducing portion for introducing a liquid from below, a liquid extracting portion for extracting the liquid upward, and a float that moves up and down in the internal liquid.
2. The area type flowmeter according to claim 1, wherein the flowmeter is an inner wall surface of a transparent portion of the tapered tube extending in a vertical direction, which can be seen through the float from outside. 3. A liquid contact surface according to claim 1, wherein the liquid contact surface is provided in a vertically extending tapered tube having a liquid introduction portion for introducing the liquid from below and a liquid outlet portion for extracting the liquid upward. 2. The area type flowmeter according to claim 1, wherein the float is an outer surface of the float that moves up and down. 4. A liquid characterized by comprising at least a part of a transparent side wall, a liquid introduction flow path and a liquid discharge flow path, wherein the inner wall surface of the side wall contains a photocatalytic material. Storage tank.