JPH09267089A - Water purifying device and purifying method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water purifying device and a purifying method for producing purified water with safety and tastiness. SOLUTION: In the water purifying device provided with a first filter 2 for producing first purified water by at least filtering the residues remaining in underground water or city water, and a second filter 5 provided in the downstream of the first filter 2 for producing second purified water by at least filtering an organic compound remaining in the first purified water, the water purifying device is constituted such that mixed purified water is produced by feeding the first purified water via a water feed quantity adjusting valve 3 and mixing it with the second purified water.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to groundwater such as well water and river water, and sediment remaining in tap water specified by the Water Supply Act.
The present invention relates to a water purification device that filters organic compounds, bacteria and the like, and more particularly to a water purification device that can adjust the residual amount of minerals (calcium, magnesium, iron, manganese, etc.).

[0002]

2. Description of the Related Art As a conventional water purifying apparatus, sediment such as mud, rust, water stain, etc. is filtered from ground water or tap water supplied from a water supply pipe by a sediment filter, and then chlorine, chloramine, etc. It is known that organic compounds, bacteria and the like are filtered by absorption of activated carbon, and if necessary, trihalomethane, dioxin and the like are filtered by a filter having extremely small pores such as a reverse osmosis membrane filter.

The above-mentioned conventional water purifiers work well in achieving the purpose of removing contaminants, for example, for drinking water in ordinary households, steam engines and nuclear reactors. We provide us with highly pure water (pure water) for industrial use. Especially in the former case, it plays an important role in maintaining our health. The tap water supplied to ordinary households is chlorinated by the water quality of the water source and water purification process strictly controlled by the water supply companies such as municipalities, and is generally said to be "safe water". There is.

However, environmental damages caused by various factors in recent years have changed the water veins of groundwater, resulting in changes in water quality and mixing of groundwater with industrial wastewater and domestic wastewater.
The safety of water sources is questioned. Foreign matter such as oil and sand when constructing a water pipe mixes with ground water or tap water, making it unsuitable for drinking, or rusting on the inside of the water pipe due to long-term use, which peels off ground water or tap water. It may be cloudy. Further, algae generated in the rooftop tank of an apartment or a building may contaminate groundwater or tap water. In order to prevent such impurities (contaminants) from entering our body, the water purification device described above is necessary.

By the way, a water quality inspection conducted by the Hiroshima Environmental Insurance Association in November 1995 using a water purification device manufactured and sold by Jim John Flower Co., Ltd. (Meguro-ku, Tokyo) I got good results. The raw water that was the subject of the water quality inspection was groundwater collected in Saijo Town, Hiba District, Hiroshima Prefecture.

First, among the contaminants contained in raw water, focusing on manganese, fluorine, calcium and magnesium, the numerical values shown in Table 1 were shown. The water quality standards shown in Table 1 are those specified by the Water Supply Act. According to this, the contents of calcium and magnesium satisfy the water quality standard, but the contents of manganese and fluorine exceed the water quality standard. Therefore, this raw water is not suitable for drinking water.

[0007]

[Table 1]

On the other hand, when looking at the purified water obtained by filtering the raw water using the water purifier, not only calcium and magnesium but also manganese and fluorine came to satisfy the water quality standard as shown in Table 1. In other words, raw water, which was not suitable for drinking as it was, became "safe water" by the function of the water purifier.

As described above, "safe water" could be produced by using the water purifier. However, "safe water" is not all "delicious water." It is very desirable to reduce the content of manganese and fluorine, which are harmful to the human body, but if the content of calcium and magnesium, which are essential to "delicious water", is reduced, It's safe but bad water. "

For example, according to "Delicious Water Requirements" published by the Ministry of Health and Welfare in 1985, it is said that the suitable amount of calcium, magnesium, etc. contained in delicious water is 10 to 100 milligrams per liter of water. There is. Similar numbers are also shown in the 1993 version of the Water Supply Maintenance Guidelines issued by the Japan Water Works Association.

Returning to Table 1, the amount of calcium and magnesium contained in the purified water is 1.4 mg per liter of purified water. This is far from the "delicious water requirements" mentioned above, and it cannot be said that the water is delicious. Whether or not water is delicious, that is, whether or not it has deliciousness, is probably subjective, and its taste varies depending on the individual, but drinking water should have not only safety but also deliciousness. It can be said that it is a thing.

[0012]

The problem to be solved by the present invention is to improve the water purifying apparatus while maintaining the advantages of the conventional water purifying apparatus, and to satisfy a certain water quality standard (safety) while maintaining the deliciousness. It is to provide a water purification device and a water purification method for providing the purified water provided.

[0013]

In order to provide such a water purifying apparatus and a water purifying method, the inventor has sought to improve the conventional water purifying apparatus and water purifying method while continuing trial and error.
As a result, if purified water with a small amount of calcium etc. obtained by filtering with a filter is added within a range that satisfies the prescribed water quality standards, purified water with safety and deliciousness will be obtained. I realized that I could get it. The present invention has been made from such a viewpoint. Next, the specific configuration will be described.

The water purifying apparatus according to the invention described in claim 1 is, like the water purifying apparatuses up to now, a first filter for at least filtering the precipitates remaining in the ground water or tap water to produce the first purified water. And a second filter provided downstream of the first filter for producing at least the second purified water by filtering at least the organic compound remaining in the first purified water, and if necessary, these It has a device other than. The feature of this water purification device is that the first water purification is
It is configured such that mixed water is produced by sending water through the water feed amount adjusting valve and mixing with the second purified water.

With this structure, the first purified water containing a relatively large amount of calcium (minerals) but having the precipitate removed is mixed with the second purified water obtained by removing the organic compounds from the first purified water. As a result, the amount of calcium and the like contained in the second purified water is increased, so that the mixed purified water having safety and deliciousness can be produced. The first purified water may contain an organic compound, so that the organic compound may be mixed in the mixed purified water, but the amount of the mixed organic compound may satisfy the safety standard. The amount (mixed amount) of the first purified water is adjusted by opening or closing the water feed amount adjusting valve.

In the present specification, "groundwater" refers to all water other than tap water such as well water and river water. Similarly, "at least" means, for example, with respect to the first filter, it means that the first filter has at least the ability to filter the precipitate, and so on. It is meant that any substance other than the precipitate may have a capability of filtering the contaminant. Therefore, the "first filter" may be any as long as it can filter at least sediments such as mud, rust and scale.
There is no restriction on the material or shape. Similarly, "second
The "filter of" may be any filter as long as it can filter at least organic compounds such as chlorine and chloramine. As such a filter, for example, a carbon filter that filters by adsorption of activated carbon can be used.

Further, the "water feed rate adjusting valve" in the present specification may be any valve as long as its opening degree can be adjusted continuously or stepwise. The one provided with a check valve for preventing the backflow of the purified water to be sent is preferable.

The water purifying apparatus according to the invention described in claim 2 is, in addition to the features of the invention described in claim 1, provided with an ozone supply device for ozone treatment of the mixed water or an ultraviolet irradiation device for ultraviolet treatment. It is characterized by that.

By subjecting the mixed purified water to the ozone treatment as described above, a large amount of oxygen is melted into the mixed purified water, so that the mouth of the mixed purified water becomes mild. That is, the water is delicious and highly delicious. This is because ozone (O ₃ ) released into water is immediately decomposed into stable oxygen molecules (O ₂ ) and dissolves in water due to its unstable property. Furthermore, the high sterilizing power of ozone can further enhance the safety of the mixed purified water, and can also keep the tank for storing the purified water, the water pipe, the waste water facility, etc. clean. The ozone treatment method is performed by injecting ozone supplied by an ozone supply device into the mixed purified water.
On the other hand, by treating the mixed purified water with ultraviolet rays, it is possible to obtain the mixed purified water with higher safety without deteriorating the taste due to the sterilizing effect of ultraviolet rays. The ultraviolet treatment is performed by directly or indirectly irradiating the mixed purified water with ultraviolet rays.

The water purifying apparatus according to the third aspect of the present invention is the first aspect of the present invention in which the precipitate remaining in ground water or tap water is filtered.
A first filter for producing purified water, and a second filter provided downstream of the first filter for producing second purified water by filtering organic compounds remaining in the first purified water. A third filter for filtering a contaminant remaining in the second purified water by a reverse osmosis phenomenon to produce a third purified water,
And other devices as required.
The feature of this water purification device is that the first purified water or the second purified water is supplied through a water supply amount adjusting valve attached to a water supply pipe and mixed with the third purified water to make a mixed purified water. It is configured in.

A major difference between this water purifier and the water purifier according to claim 1 is that the former has a third filter which the latter does not have. A third purified water is produced by the third filter, and the third purified water is mixed with the first purified water or the second purified water to produce a mixed purified water having both safety and deliciousness. By providing the third filter, it is possible to filter water stepwise according to the nature and type of the contaminant, as compared with the water purifier according to claim 1. As a result, you can choose the purified water to mix according to the quality of the raw water. That is, for example, if there is no safety problem if only the precipitate is removed, the first purified water may be mixed with the third purified water, and if the organic compound content is too high, the second purified water may be mixed.
All you have to do is mix the purified water. Furthermore, the filter can be replaced efficiently. That is, when the amount of precipitates is relatively large, the first filter is the most dirty, and when the amount of organic compounds is large, the second filter is the most dirty. Therefore, in the former case, only the first filter and in the latter case only the second filter may be replaced with new ones, and the other filters may be replaced as needed.

The "third filter" in this specification means a filter for filtering contaminants by the reverse osmosis phenomenon, as is clear from the claims.
A typical example is a reverse osmosis membrane. Here, "reverse osmosis" means that the solution and the solvent are separated by an osmosis membrane (semi-permeable membrane),
This is a phenomenon in which, when a pressure higher than the osmotic pressure of the solution is applied to the solution side, the solvent molecules in the solution move to the solvent side through the osmotic membrane, contrary to normal penetration. In short, when pressure is applied to a thick liquid, the thick liquid is concentrated, and on the other side is pure liquid (water).
Refers to the phenomenon in which The pores of the osmotic membrane are generally less than 0.
Since the size is about 0001 micron, filtration with a reverse osmosis membrane makes it possible to separate all contaminants other than organic molecules and gas molecules from the liquid. The interpretation of other words is the same as that explained above.

A water purifying apparatus according to a fourth aspect of the present invention is characterized in that, in addition to the features of the third aspect, a pressurizing means for pressurizing the first purified water or the second purified water is provided. And

By providing the pressurizing means in this way,
An appropriate pressure can be applied to the first purified water or the second purified water, that is, the purified water before the filtration by the reverse osmosis phenomenon.
As a result, the reverse osmosis phenomenon can be efficiently generated, and thus a large amount of third purified water (mixed purified water) can be obtained within the same time. If the ground water or tap water has sufficient pressure, this pressurizing means may be omitted. As the “pressurizing means”, any means can be used as long as it can apply pressure to the second purified water, and as such means, for example, an electric pressure pump.

The water purifying apparatus according to the invention described in claim 4 is, in addition to the features of the invention described in claim 2 or 3, an ozone supply device for ozone treatment of the mixed water or an ultraviolet irradiation device for ultraviolet treatment. Is provided.

The function and effect obtained by providing such an ozone supply device or an ultraviolet irradiation device are the same as those in claim 2 described above.

The water purifying apparatus according to a sixth aspect of the present invention is, in addition to the features of any one of the third to fifth aspects, provided with a detection means for detecting the quality of the mixed purified water. It is configured to adjust the opening degree of the water feed rate adjusting valve based on the above.

By providing such characteristics, the water quality of the mixed purified water can be always kept constant. That is, since the first purified water or the second purified water containing a small amount of contaminants is mixed into the third purified water from which contaminants have been removed, the water quality standard may not be satisfied if the amount of the latter is too large. . On the other hand, if the amount is too small, it is not possible to obtain delicious mixed water. Therefore, the water quality standard of the mixed purified water is set in advance, and while checking the water quality of the mixed purified water, the water quantity adjusting valve is opened and closed to keep the mixed purified water quality constant at all times. The opening / closing method may be performed by microcomputer control, or may be opened / closed by an operator based on the detection result. The "detection means" in the present specification may be any as long as it can detect the water quality of the mixed purified water, and as such, for example, a conductivity meter for measuring the conductivity of the liquid. is there.

In the method for purifying groundwater or tap water according to the invention described in claim 7, the first purified water is prepared by filtering the sediment remaining in the groundwater or tap water with a sediment filter at least. Reverse osmosis of a step, a second step in which the organic compound remaining in the first purified water is at least filtered by activated carbon adsorption of a carbon filter to make a second purified water, and a contaminant remaining in the second purified water. A third step of making a third purified water by filtering at least by a reverse osmosis phenomenon with a membrane filter,
A fourth step of producing the mixed purified water by feeding the first purified water or the second purified water through a water feed amount adjusting valve to mix the third purified water, and ozone treatment or ultraviolet rays of the mixed purified water. It consists of the fifth step of processing.

By using this water purification method, ground water or tap water can be purified water having both safety and taste. The interpretation of each wording described in this claim is the same as that described so far.

[0031]

BEST MODE FOR CARRYING OUT THE INVENTION Next, an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a schematic view showing a water purification apparatus according to the present invention, FIG. 2 is an ozone treatment apparatus, and FIG. 3 is an ultraviolet irradiation apparatus. Note that the embodiment of the present invention includes the parts according to claims 1 and 2 and the parts according to claim 3 and subsequent parts, but since both parts overlap in most parts, they will be described together. The difference between the two is that the third filter is not provided in the former, while the third filter is provided in the latter. Here, what is claimed in claim 3 and below is simply the present embodiment,
Claims 1 and 2 will be referred to as modifications of the present embodiment, and these will be described.

First, the present embodiment (claims 3 and below) will be described. Reference numeral 1 shown in FIG. 1 is a water supply valve for supplying ground water or tap water (hereinafter, abbreviated as “tap water etc.”) to the first filter 2. The first filter 2 is generally a sedimentation filter (sediment filter).
It is also called a filter) and mainly filters sediments such as mud, rust, and scale mixed in groundwater or tap water through holes of about 0.5 micron. The first filter may be replaced once every about 6 months in order to maintain high filtration efficiency, although it varies depending on the properties and amount of ground water or tap water used, the material of the filter, and the like.

The ground water, tap water, etc. filtered by the first filter 2 (referred to as "first purified water") have almost no turbidity as compared with those before filtration because the precipitates have been removed. . The first purified water is sent to the second filter 5 via the water shutoff valve 3 and the pressurizing pump (pressurizing means) 4.

The water shutoff valve 3 is for shutting off the water supply line so that when the purified water in the water storage tank 9 (described later) is full, no further purified water is sent downstream.
That is, when the water storage tank 9 is full, the pressure due to this is sensed by the pressure sensing switch 15, and the water shutoff valve 3 is activated in response to the sensing signal. This prevents the water storage tank 9 and other devices and the water supply line from bursting or being damaged. In this embodiment, the first filter 2 and the second filter 5
Although the water shutoff valve 3 is provided between the two, it is not limited to this. The location of the water will be decided after considering the pressure and amount of purified water. For example, it may be provided between the pressurizing pump 4 and the second filter 5 or between the second filter 5 and the third filter 6.

The pressurizing pump 4 is for pressurizing the first purified water so as to send the pressurized purified water to the second filter 5 (third filter 6) arranged downstream of the water supply line. That is, in particular, the third filter 6 is for filtering the contaminants by utilizing the reverse osmosis phenomenon described above. Therefore, for efficient filtration, purified water before filtration (second purified water). Must have moderate pressure. This is the function of the pressure pump 4. The pressurizing pump 4 in the present embodiment is provided between the second filter 4 and the third filter 6 so that the second filter 5 also works efficiently. It may be provided between the second filter 5 and the third filter 6 depending on the circumstances.

However, if the tap water or the like supplied from the water supply valve 1 itself has a constant pressure (for example, about 2.8 to 8 kg), and if this pressure causes each filter to operate efficiently, it is added. The pressure pump 4 may be omitted.
Further, for the time being, the pressurizing pump 4 is provided, and when the ground water or the tap water (purified water) has a certain pressure, it is not operated, and when it has a certain pressure or less, it is operated. You may allow it.

Next, the second filter 5 will be described. In the present embodiment, a carbon filter is used as the second filter 5. The carbon filter 4 absorbs chlorine from the first purified water by activated carbon adsorption.
The organic compounds such as chloramine and chloramine are mainly filtered. The purified water filtered by the second filter 5 is referred to as "second purified water" in the present specification. The carbon filter 5 may be replaced every 6 months as in the case of the sediment filter.

Next, the third filter 6 will be described. A reverse osmosis membrane is used for the third filter 6. This has pores of about 0.0001 micron and filters the second purified water by utilizing the reverse osmosis phenomenon described above. That is, since the second purified water is in a state of being pressurized by the pressure pump 4 (or originally having a pressure), a reverse osmosis phenomenon occurs here, and as a result, contaminants such as trihalomethane and dioxin ( Almost all contaminants can be removed. The purified water filtered by the third filter 6 is referred to as "third purified water" in the present specification. The third purified water is temporarily stored in the water storage tank 9 and then sent to the water outflow line 17.

When the flow controller (overflow water control device) 7 detects the second purified water that cannot be completely filtered (overflowed) by the third filter 6, the wastewater pipe is opened. Discharge from 8. The impurities filtered by the third filter 6 are discharged together with this wastewater.
By doing so, the third filter 6 can be used for a long time without lowering the filtration efficiency. The reverse osmosis membrane 6 may be replaced about once every two years.

Next, a method for preparing mixed purified water will be described. The mixed purified water is produced by sending the third purified water produced by the above-described method to the mixing chamber 10 through the water discharge line 17 and mixing the first purified water or the second purified water therein. Both of the purified water are agitated and mixed by the pressure of each discharged into the mixing chamber 10. The first purified water is guided to the mixing chamber 10 via the water supply line 11 as shown in FIG. Note that reference numeral 12 is a check valve for preventing purified water in the mixing chamber 10 from flowing backward, and reference numeral 13 is a water amount adjusting valve for adjusting the mixing amount of the first purified water. The mixing amount is adjusted by opening or closing the water amount adjusting valve 13 based on the result of water quality detection performed by the conductivity meter (detection means) 15 provided in the water outflow line 17. This will be described later again.

Next, the sterilization chamber 2 located downstream of the water tap 18
Send mixed water to 0 and sterilize it. This is because the mixed first purified water (second purified water) contains bacteria so that the bacteria in the mixed purified water are killed and the safety of the mixed purified water is further enhanced. As a result of the experiment conducted by the inventor, it was found that the mixed purified water should be treated with ozone or treated with ultraviolet light in order to sterilize it without impairing the taste. Which processing method is used depends on the user's selection. You may make it use both processes together.

As shown in FIG. 2, the ozone treatment is performed by injecting ozone produced by the ozone supply device 14 into the sterilization chamber 20. The ozone supply device 14 is composed of an ozone supply device body 14a and a supply nozzle 14b. Although there are various methods of generating ozone, in the present embodiment, the ozone supply device main body 13a generates ozone by the silent discharge method and discharges it into the purified water through the supply nozzle 14b. ing. Supply nozzle 14
In b, there are many fine holes, and ozone passing through these holes becomes fine bubbles. This was done so that the ozone could quickly dissolve into the mixed water.

The ultraviolet treatment is carried out by using an ultraviolet irradiator 23 for irradiating the mixed purified water with ultraviolet rays. As shown in FIG. 3, the ultraviolet irradiation device 23 has a UV pipe (sterilization chamber) 20 with one end closed, a lid 24 fixed to the other end of the UV pipe 20, and one end fixed to the lid 24. Transparent glass tube 26 and U enclosed in this glass tube 26
It is almost made up of a V germicidal lamp 25. UV irradiation
This is performed by allowing the mixed purified water to pass through the UV pipe 20 and turning on the UV germicidal lamp 25 therein. The inner surface of the UV pipe 20 may be mirror-processed so as to reflect ultraviolet rays and irradiate as much ultraviolet rays as possible.

Here, the relationship between the conductivity meter 15 and the water amount adjusting valve 12 described above will be described. The water amount adjusting valve 12 in the present embodiment is configured to open and close under the control of the microcomputer, and the amount (ratio) of the first purified water contained in the mixed purified water is adjusted by controlling the opening and closing. There is. The control is performed according to the content of calcium or the like contained in the mixed purified water detected by the conductivity meter 15, and when the conductivity is low, the amount of calcium or the like is large. Open,
On the contrary, if it is expensive, it will be closed.

In the present embodiment, the mixed purified water is made by mixing the first purified water with the third purified water, but the nature of ground water or tap water, the taste of the mixed purified water, etc. are changed. Therefore, instead of the first purified water, the second purified water may be used by using the water supply line 19 shown by a virtual line, or both may be used together. In any case, the third purified water from which most of the contaminants have been removed is replaced by the first purified water (second
It is possible to obtain a mixed purified water containing a desired amount of minerals such as calcium.

In order to facilitate understanding of this, a simple numerical value will be used for explanation. First, 1 gram of calcium remaining in 1 liter of the third purified water and 1 liter of 1 liter of the first purified water
Assume 0 grams each. By mixing these, 2 liters of mixed purified water containing 11 grams of calcium can be obtained. That is, mixed purified water containing 5.5 g (half 11 g) of calcium per liter can be obtained. In this example, the mixing ratio of both purified water is set to 1: 1, but this mixing ratio may be changed according to the amount of calcium contained in each purified water and the taste of the mixed purified water. Needless to say, in such a case, the water quality standard of the mixed purified water must be satisfied (highly safe).

Here, a modified example (claims 1 and 2) of the present embodiment will be described. This is different from the present embodiment in that the third filter is omitted as described above. That is, in the modified example of the present embodiment, the ground water or tap water is filtered by the first filter 2 and the second filter 5. Then, the mixed purified water is made by mixing the first purified water with the second purified water (Claim 1), and the mixed purified water is subjected to ozone treatment as required (Claim 2). The effects of the common parts (devices and the like) are the same as those of this embodiment, and the same applies to the interpretation of the wording in the description.

[0048]

EFFECTS OF THE INVENTION By using the water purifying apparatus and the water purifying method according to the present invention, it is possible to provide purified water satisfying a certain water quality standard (safety) and having good taste. Therefore, even in ordinary households, groundwater or tap water can be converted into safe and delicious water.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a configuration of a water purification apparatus according to the present invention.

FIG. 2 is a schematic diagram of an ozone processing apparatus.

FIG. 3 is a schematic view of an ultraviolet irradiation device.

[Explanation of symbols]

 1 Water Supply Valve 2 First Filter 3 Water Stop Valve 4 Pressurizing Pump 5 Second Filter 6 Third Filter 7 Flow Controller 8 Waste Water Pipe 9 Water Supply Tank 10 Mixing Room 11 Water Transmission Line 12 Check Valve 13 Water Volume Control Valve 14 Ozone treatment device 15 Conductivity meter (detection means) 16 Check valve 17 Water line 18 Water tap 19 Water line 20 UV pipe (sterilization room) 23 Ultraviolet irradiation device 24 Lid 25 UV germicidal lamp 26 Glass tube

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Claims (7)

[Claims] 1. A first filter for filtering at least a precipitate remaining in groundwater or tap water to produce first purified water, and at least a second filter for filtering an organic compound remaining in the first purified water. A second filter provided downstream of the first filter in order to produce purified water, the first purified water is fed through a water feed rate adjusting valve to the second filter. A water purification device configured to make mixed water by mixing it with water. 2. The water purification apparatus according to claim 1, further comprising an ozone supply device for ozone treatment of the mixed water or an ultraviolet irradiation device for ultraviolet treatment. 3. A first filter for filtering a precipitate remaining in groundwater or tap water to produce a first purified water, and a second filter for filtering at least an organic compound remaining in the first purified water. A second filter provided downstream of the first filter for producing purified water, and a third filter for producing a third purified water by filtering a contaminant remaining in the second purified water by a reverse osmosis phenomenon. In the water purification device including the filter, the first purified water or the second purified water is configured to form a mixed purified water by feeding the first purified water or the second purified water through a water feed amount adjusting valve to mix with the third purified water. Water purification equipment. 4. The water purifier according to claim 3, further comprising a pressurizing unit that pressurizes the first purified water or the second purified water. 5. The water purification apparatus according to claim 3 or 4, further comprising an ozone supply device for ozone treatment of the mixed purified water or an ultraviolet irradiation device for ultraviolet treatment. 6. The detection means for detecting the water quality of the mixed purified water is provided, and the opening degree of the water feed rate adjusting valve is adjusted based on the detection result. The water purification device described in any one of 5. 7. A method for purifying groundwater or tap water, which comprises the following steps. (A) A first step of filtering the sediment remaining in groundwater or tap water with a sediment filter to make a first purified water. (B) The organic compound remaining in the first purified water is treated with a carbon filter. At least filtered by activated carbon adsorption of the second
Second step of producing purified water of (c) Third step of producing third purified water by at least filtering the contaminants remaining in the second purified water by a reverse osmosis phenomenon by a reverse osmosis membrane filter (d) The first step Process of (e) ozone treatment or ultraviolet treatment of the mixed purified water by mixing the third purified water by sending the purified water or the second purified water through a water feed amount adjusting valve to mix the purified water Fifth step