JP4183415B2 - Water purification equipment - Google Patents

Description

なお、上述実施例では、特にレジオネラ菌を用いての実験をしていないが、レジオネラ菌は、大腸菌と同じグラム陰性桿菌であることより、大腸菌で代用した。また、有機物は、過マンガン消費量で測定している。
この表からもわかるように、運転開始１時間後には、細菌の除去、有機物何れも、飲料水の基準以下に達していることが判る。また、濁度が大幅に改善されて、おり、使用者の爽快感を与える透明感がある。
【００２０】
【発明の効果】
本発明の請求項１記載の発明では、微細フィルタ等の除去微細濾過器を設けることで、細菌類のうち特に浴槽等で問題となる、レジオネラ菌の生態を研、分析し、その特性のうち親菌は菌自身殻に入っており、さらに、かび、藻、原生動植物等の体内に、寄生、共生、増殖することより、通常の塩素投入や紫外線放射による殺菌方法では効果が期待できないので、これらの原生動植物と一緒に効率的に濾過、除去を行うことが出来、又除去微細濾過器に続けて設けている光触媒細菌分解器により、レジオネラ子菌及び他のバクテリア、ウイルス等を殺菌することが出来、安全に使用することが出来る。また、光触媒細菌分解器、及び活性炭素触媒・分解除去器を用い、汗、ふん尿等の有機物を酸化分解させ、その主成分を炭酸ガスと水に戻す為、２４時間風呂等に用いると更に、効率的である。また、紫外線、オゾンを用いて処理する過程に於いて、処理水の温度低下は５℃程度である。従って、従来の風呂設備に本発明の装置を付加して使用し、使用した湯を補充する運転が出来る為、大がかりな浴室等の改修が必要ない。
又、気泡除去装置、浮遊微細菌死骸除去器によって、処理水の清浄化とオゾンの除去が行われ、透明感のある安全な処理水を得ることが出来る。
【００２１】
請求項２記載の発明により、逆浸透膜を追加又は代替えして使用することで本来の目的であるレジオネラ菌は勿論残留塩素イオン、硝酸イオン等の除去も達成することが出来、後段に設けている活性炭素触媒・分解除去器の負担を軽減することが出来る効果を有する。
更に請求項３記載の発明で光り触媒殺菌分解器として、酸化チタンの光触媒充填等を使用することにより、簡易の構成の装置で有機物の分解等を行うことが出来る。
更に請求項４記載の発明は、気泡除去装置を設けることにより、処理水ないのオゾン浮遊気体を除去し、安全で透明度の高い処理水を得ることが出来る。
【図面の簡単な説明】
【図１】本発明に係る水の複合的浄化装置概略構成図である。
【図２】本発明の浄化運転時の処理水の流れ説明図である。
【図３】本発明の逆洗処理時の処理水の流れ説明図である。
【図４】本発明に使用する光触媒殺菌分解器の説明図である。
【図５】本発明に使用する光触媒殺菌分解器の他の実施例を示す説明図である。
【図６】本発明に使用する気泡除去装置の実施例を示す説明図である。
【図７】オゾン除去に際し、口称径と処理量の関係を示す説明図である。
【符号の説明】
１ 浴槽
１１ 流量計
２ 配管
２０、２２ 逆止弁
２１ ベント弁
３ ポンプ
３１、３２、３３ 三方弁
４ 浮遊物濾過器
５ 微細濾過器
５１ 前段フィルター
５２ 後段フィルター
６ 光触媒殺菌分解器
６０ 内管
６１ 外管
６２ 紫外線ランプ
６３ ポンプ
６４ 逆止弁
７ 気泡除去装置
８ 活性炭素・分解除去器
９ 浮遊微細菌死骸除去器[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a purification apparatus for efficiently treating stored water such as bath water and pool water.
[Prior art]
Conventionally, sterilizers mainly composed of chlorine have been dealt with mainly for bath water, pool water, and the like, but in recent years, circulation-type devices have been provided for purification and sterilization of this water.
This device is a combination of ultraviolet rays and filters, or a single ozone device, and various devices have been proposed mainly for the purpose of sterilizing general bacteria and E. coli.
In other words, as an example of bath water, there is a great demand for a 24-hour bath at the present when it is shifting to an aging society, and a complex water purification device that circulates hot water in the bathtub is indispensable. The The problem in this 24-hour bath is the removal of dirt such as scale, body scum, hair loss, bacteria such as Legionella and staphylococci remaining in the hot water in the bathtub.
For example, Legionella spp. Have a thickness of 0.3 to 0.9 and a length of 2 to 20 μm. When a fine eye filter that removes these bacteria is used, It will cause clogging. Therefore, generally, after removing large dust with a coarse filter, bacteria are sterilized by various sterilization means such as chlorine, metal ions and other chemicals, ultraviolet light, ozone and the like. ing.
Further, when bath water is purified, organic matter such as manure may be contained in the bath water, and it is not sufficient to simply combine the above filters.
[0003]
[Problems to be solved by the invention]
The conventional treatment apparatus can sterilize and remove general bacteria and Escherichia coli, but cannot deal with Legionella sterilization and removal and organic matter decomposition treatment.
The purpose of this study is to study and analyze the ecology of Legionella and to disinfect and remove Legionella parental bacteria and germs, and to decompose organic substances such as ammonia generated from manure contained in the treated water at each stage. The object is to develop a compact, efficient, and high-performance device by configuring the device as a system, and to develop a device capable of sterilizing, removing fungi, and decomposing and removing organic matter.
[0004]
[Means for Solving the Problems]
The invention described in claim 1 according to the present invention includes a pump that draws treated water into the treatment section, a removal microfilter that includes a fine filter that collects suspended matter and relatively large general bacteria and E. coli, and small general bacteria. Sterilization and decomposition of organic substances in treated water with ultraviolet and ozone, followed by bubble removal device for removing air, ozone and other residual gas remaining in treated water, and bubble removal device It consists of activated carbon catalyst / decomposition remover for secondary decomposition of residual organic matter and floating microbe carcass remover. The removal microfilter, photocatalytic sterilization decomposer, bubble removal device, bubble removal device, activated carbon catalyst / decomposition In addition to arranging removers in series, a floating microbe dead body remover is placed at an appropriate position after the photocatalytic sterilization decomposer to disinfect and remove bacteria such as Escherichia coli and Legionella. Decompose organic matter such as sewage, characterized by apparatus characterized by purifying bath water, pool water or the like by removing.
[0005]
According to the first aspect of the present invention, by providing a removal microfilter such as a microfilter, the ecology of Legionella, which is a problem in bacteria, particularly in a bathtub, is studied and analyzed. Among them, the parent fungus is in the shell of the fungus itself, and furthermore, since it is parasitic, symbiotic, and proliferating in the body of fungi, algae, protozoa, etc., the effect of sterilization by normal chlorine input or ultraviolet radiation cannot be expected, It is filtered and removed together with these native plants and animals.
Further, Legionella bacterium and other bacteria, viruses and the like are sterilized by a photocatalytic sterilization decomposer provided after the removal microfilter.
Furthermore, in the photocatalytic sterilization decomposer, the treated water acts to oxidize and decompose organic substances such as sweat and manure by ozone and OH radical reaction by the action of the photocatalyst and ultraviolet rays, and return the main components to carbon dioxide gas and water. .
In addition, a bubble removing device is provided following the photocatalytic sterilization decomposer to remove ozone. This contains a lot of ozone, etc. from the photocatalytic sterilization decomposer, so it can be removed before the ozone bubbles enter the activated carbon filter of the activated carbon catalyst / decomposition remover that decomposes the next residual organic matter secondarily. It is possible to improve the efficiency of decomposition, turbidity treatment of treated water, removal of odors, and the like.
Furthermore, most of the bacteria killed by the photocatalytic sterilization / decomposer can be collected by passing the treated water through the floating micro-bacterial dead body remover, and it acts to obtain cleaner treated water.
[0006]
The invention described in claim 2 according to the present invention is characterized in that a reverse osmosis membrane is used instead of or in addition to the fine filter.
According to this invention, by using a reverse osmosis membrane in addition to or in place of it, it is possible to achieve removal of residual chlorine ions, nitrate ions, etc. as well as Legionella bacteria, which is the original purpose. The burden on the catalyst / decomposing / removing device can be reduced.
[0007]
According to a third aspect of the present invention, a titanium oxide ceramic ball produced by impregnating a porous ceramic ball with titanium oxide and firing it is used as a photocatalytic sterilization decomposer. It is good also as a structure characterized by using the photocatalyst packed tower irradiated with the ultraviolet-ray of a light.
Here, by using a photocatalyst packed tower of titanium oxide, it is possible to decompose organic substances and the like with an apparatus having a simple configuration.
Furthermore, the invention described in claim 4 is characterized in that, as the bubble removing device, there is provided an air bubble removing portion having an open portion in the atmosphere and having a greatly reduced flow velocity compared to the flow rate in the pipe. It acts to remove bubbles such as residual ozone by reducing the flow rate.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
The present invention will be described below with reference to the drawings.
FIG. 1 is a schematic configuration diagram of a combined water purification apparatus according to the present invention, FIG. 2 is an explanatory view showing the flow of treated water, and FIG. 3 shows the flow of treated water during backwashing when cleaning a filter. It is explanatory drawing.
The outline of the composite water purification apparatus of the present invention is as follows: from a bathtub 1 storing treated water, a pump 3 via a pipe 2, a suspended matter filter 4, a removal fine filter 5, and a photocatalyst sterilization decomposer. 6, a bubble removing device 7, an activated carbon catalyst / decomposing / removing device 8, and a floating microbe carcass removing device 9.
[0009]
(Float filter 4)
The floating substance removing device 4 is for removing relatively large garbage such as human hair, lipids, skin, sand, leaves, etc. by filtering the floating substances. For example, the floating substance filter 4 is about 100 mesh in a container. A configuration with a net is sufficient.
[0010]
(Fine filter 5)
The microfilter 5 includes a two-stage microfilter including a front-stage filter 51 and a rear-stage filter 52.
The front-stage filter 51 is composed of a tank tank containing a filter using, for example, a 40 μm fine sintered metal net, and is provided for the purpose of removing insect eggs, for example. And the latter stage filter 52 consists of a tank tank which used the 3 micro precision sintered metal nonwoven fabric as a filter, for example. Focusing on the characteristics of Legionella parental fungus that is parasitic, symbiotic, and proliferating in the body of algae and protozoan animals and plants with the 3μ filter of this latter stage filter 52, the Legionella parental fungi are filtered along with the mold, algae and protozoan animals and plants, Remove.
By installing a removal microfilter such as a fine filter, the ecology of Legionella, which is a problem in bacteria, especially in the bathtub, is studied and analyzed. Among its characteristics, the parent is in the shell itself, Furthermore, it is filtered and removed together with these native plants and animals by parasitism, symbiosis, and multiplication in the body of fungi, algae, and native plants and animals.
In this way, large bacteria can be collected by the microfilter 5.
A reverse osmosis membrane may be used instead of or in addition to the fine filter. This reverse osmosis membrane uses what is generally used, and although not shown in figure, applies a pressure more than an osmotic pressure, moves only a solvent, and removes bacteria etc.
[0011]
(Photocatalytic sterilizer 6)
Next, the treated water exiting the fine filter 5 contains bacteria such as Legionella bacteria and organic substances such as sweat and urine. For the purpose of sterilizing these bacteria and decomposing organic substances, a photocatalyst sterilizer 6 is provided.
For example, as shown in FIG. 4, the photocatalytic sterilization / decomposition unit 6 has a double tube structure of a translucent inner tube 60 and an outer tube 61, and has an inner tube 60 of at least 184.9 nm and 253.7 nm. An ultraviolet lamp 62 having two wavelengths is provided. Then, air is introduced into the inner pipe 60, the oxygen of the air introduced by the pump 63 is changed to ozone at a wavelength of 184.9 nm, and the ozone-containing air is passed through the check valve 64 and the like to the outer pipe. Bubbling is discharged from the lower part of 61, and bacteria in the treated water introduced into the outer tube 61 are sterilized with ozone.
Further, the ultraviolet light having a wavelength of 253.7 nm is irradiated into the outer tube 61 because the inner tube 60 has translucency, and at this wavelength, bacteria in the treated water are sterilized and further organic substances are decomposed. .
As described above, by using the photocatalyst sterilization / decomposition device 6, the Legionella bacterium and other bacteria, viruses and the like are efficiently sterilized with ozone, and the treated water is converted into ozone and OH by the action of the photocatalyst and ultraviolet rays. By radical reaction, organic substances such as sweat and manure are oxidatively decomposed and their main components are returned to carbon dioxide and water.
[0012]
FIG. 5 shows another embodiment of the photocatalytic sterilization decomposer 6.
In this embodiment, particularly organic substances such as ammonia can be efficiently decomposed, and the structure is obtained by using a titanium oxide ceramic ball produced by impregnating a porous ceramic ball with titanium oxide and firing it. In this configuration, the titanium oxide ceramic balls are irradiated with black light ultraviolet rays.
In this irradiation, ammonia is decomposed by ultraviolet rays and a titanium oxide photocatalyst.
In the embodiment using the porous ceramic balls, the photocatalytic sterilization / decomposition device 6 can be manufactured at a relatively low cost.
[0013]
(Bubble removal device 7)
In the bubble removal device 7, the treated water treated by the photocatalytic sterilization decomposer 6 contains a large amount of ozone, a large number of decomposed carbon dioxide, and the like. Therefore, returning this to a bathtub, a pool, or the like as it is may cause a large amount of bubbles and impair the transparency of the treated water. Moreover, it is not preferable for high oxygen state and health.
Therefore, a bubble removing device is provided subsequent to the photocatalyst sterilizing and decomposing device 6 to remove air bubbles, carbon dioxide and the like in ozone and treated water.
A specific configuration is shown in FIG. In the figure, the bubble removing device has a configuration in which a bubble removing unit 70 having a substantially increased cross-sectional area as compared with a pipe through which treated water flows is provided. And it is open | released to air | atmosphere directly or through the air reservoir 71 and the release valve 72 from the part which expanded this cross-sectional area significantly.
As a configuration for greatly increasing the cross-sectional area, for example, as shown in FIG. 6 (a), in addition to a configuration for simply gradually increasing the cross-sectional area, as shown in FIG. The structure which attaches piping to the container which has a big volume may be sufficient.
As shown in FIG. 7, for example, in the case of a caliber of 50 A, the amount of ozone treatment is about 1 m ³ / Hr as shown in FIG. Increases the throughput to about 5 m ³ / Hr.
In the case of the present invention, the pipe is 25A or 32A, and processing of about 5 m ³ / Hr is performed. More than about the size is necessary.
[0014]
Note that the bubble removal mechanism increases the cross-sectional area at the bubble removal unit 70 of the bubble removal device 7, so that the flow velocity in the tube is relatively lowered and the processing amount in the bubble removal unit 70 increases per unit time. It is considered that air and ozone bubbles existing inside the treated water rise due to buoyancy or the like and are removed from the treated water.
In this case, the position of the treated water introduction part and the discharge port to the bubble removing device 7 is set to a position where the treated water does not stay in the bubble removing device 7 and is not drawn into the discharge port. Therefore, the position where the discharge port is provided can be provided at a position below the introduction port.
The time during which the bubble removing device 7 stays is preferably at least about 0.1 to 0.5 seconds or longer. This is because, in the upstream photocatalyst sterilization / decomposer 6, when the air + ozone bubbles are introduced into the treated water, the gas present in the treated water is not uniform, and the treated water that is flowing becomes a pulsating flow. There are many. For this reason, if the flow rate is somewhat reduced, bubbles are not removed, but it is necessary that the flow rate be at least half or less.
The position where the bubble removing device 7 is provided varies depending on the set water pressure of the pump, but is preferably provided at a relatively high horizontal position.
This is because if the bubble removing device 7 is provided at a low position, the water pressure in the pipe is added to the pump pressure, and the water pressure at the height position is applied, so that the removal of bubbles is reduced.
[0015]
(Activated carbon catalyst / decomposition remover 8)
The activated carbon catalyst / decomposition remover 8 is configured to enclose activated carbon inside the container. Unlike ordinary activated carbon filters, the purpose is to decompose organic matter from residual organic matter dissolved water containing dissolved ozone treated with a photocatalytic decomposer and return it to nitrogen and carbon dioxide.
Residual organic substances and the like are secondarily decomposed by an oxygen radical reaction using activated carbon as a catalyst in the activated carbon catalyst / decomposition remover 8.
Furthermore, this activated carbon can filter, adsorb and remove odor, chromaticity, residual chlorine (which causes trihalomethane), etc., and can make treated water more transparent and clean.
The activated carbon catalyst / decomposition remover 8 is provided behind the bubble removing device 7. If this is installed in front of the bubble removing device 7, the remaining ozone bubbles inside the treated water will adhere to the surface of the activated carbon, reducing the surface area of the activated carbon. This is because it is not preferable in the subsequent decomposition treatment.
[0016]
(Floating micro-bacteria dead body remover 9)
The floating microbial dead body remover 9 is installed at an appropriate position of the photocatalytic sterilization / decomposing unit 6 to remove floating bacterial dead bodies, and its configuration is an ultra-fine filter inside, up to 0.8 μm. In addition to the mechanical filtration of the particles, the adsorbing action of the charge is used in combination to eliminate the remaining suspended matter finer than 0.8, and the dead bodies such as bacteria floating in the hot water, fine particles, etc. Is adsorbed by an ultrafine filter medium with a positive potential that has a negative potential.
[0017]
Next, the flow of the treated water of this invention is demonstrated.
The flow of the treated water during the purification operation is drawn from the bathtub 1 as shown by the thick line in FIG. 2, and the treated water from which large debris such as hair has been removed by the suspended matter filter 4 is pressurized by the pump 3, and the flow meter 11 After passing through the check valve 20 and the three-way valve 31, it passes through a micron removal microfilter 5 in which a 40μ front filter 51 and a 3μ rear filter 52 are provided in series to remove large bacteria such as Legionella parent. To do.
Next, the treated water is sent to the photocatalyst sterilization decomposer 6 through the three-way valve 32, and the photocatalyst sterilization decomposer 6 performs sterilization by ozone and ultraviolet rays and decomposition of organic substances.
Next, the treated water discharged from the photocatalytic sterilization decomposer 6 is sent to the bubble removing device 7 to remove the bubbles. At this time, the gas separated from the treated water is released from the vent valve 21 to the atmosphere. Next, the treated water exiting the bubble removing device 7 is subjected to removal of residual organic matter again by the activated carbon catalyst / decomposition remover 8, and finally, through the three-way valve 33, finally, the suspended microbacterial dead body remover 9. Fine suspended matter such as dead microcarcasses is formed, resulting in clean treated water, and the treated water is returned to the bathtub 1 through the three-way valve 34. Thereafter, the purification process is repeated.
[0018]
Next, the present invention treats treated water as described above. However, when continuously carried out, the filter is clogged. Here, the filter part is backwashed once a day. The flow of the treated water at this time is shown by a thick line in FIG.
In the case of performing this backwashing treatment, treated water that has been sufficiently cleaned is usually used. That is, before cleaning, the filter or the like is soiled. Therefore, this backwash process is performed at an appropriate time such as early morning after the purification process is performed for 24 hours or more.
The treated water of the backwash process is drawn from the bathtub 1, is pressurized by the pump 3 through the float filter 4, passes through the flow meter 11, passes through the check valve 22 and the three-way valves 31, 34, and floats finely. Activated carbon / decomposing and removing device 8, bubble removing device 7, photocatalytic sterilizing and decomposing device 6, three-way valve 32, rear-stage filter 52, front-stage filter 51, three-way valve 31, and non-return through bacteria dead body remover 9 and three-way valve 33 At the same time as discharging Legionella bacteria, which are discharged to the outside through the valves 22 and 23 and trapped in the floating microbe dead body remover 9, the rear filter 52, and the front filter 51, the activated carbon / decomposition remover 8 and bubbles The removal device 7 and the photocatalyst sterilization / decomposer 6 are also cleaned at the same time. By performing the backwash process in this way, it was possible to prevent clogging of the filters in each part for more than half a year.
[0019]
(Example)
In the configuration of FIG. 1 described above, sodium oxalate and sodium hypochlorite as organic substances and general bacteria and coliform bacteria as bacteria are added and mixed in a 200 liter bath, and treated water at 1 m ³ / Hr. Purification operation was performed.
The state of treated water in the bathtub is shown in the table below.
[Table 1]

In the above-mentioned Examples, no experiments were conducted using Legionella, but Legionella was replaced with Escherichia coli because it is the same Gram-negative bacillus as Escherichia coli. Organic substances are measured by permanganese consumption.
As can be seen from this table, one hour after the start of operation, it can be seen that both bacteria removal and organic matter have reached the standard for drinking water. Moreover, the turbidity is greatly improved, and there is a transparency that gives the user a refreshing feeling.
[0020]
【The invention's effect】
In the invention according to claim 1 of the present invention, by providing a removal microfilter such as a microfilter, the ecology of Legionella, which is a problem particularly in the bathtub among bacteria, is analyzed and analyzed. The fungus itself is contained in the shell, and since it is parasitic, symbiotic, and proliferating in the body of fungi, algae, protozoa, etc., the effect of sterilization by normal chlorine input or ultraviolet radiation cannot be expected, It is possible to efficiently filter and remove these native plants and animals, and to sterilize Legionella spp. And other bacteria and viruses with a photocatalytic bacterial decomposer provided after the removal microfilter. Can be used safely. In addition, when photocatalytic bacteria decomposer and activated carbon catalyst / decomposition remover are used to oxidize and decompose organic matter such as sweat and manure and return the main components to carbon dioxide gas and water, when used in a bath for 24 hours, etc. Efficient. Moreover, in the process using ultraviolet rays and ozone, the temperature drop of the treated water is about 5 ° C. Accordingly, since the apparatus of the present invention is used by adding the apparatus of the present invention to a conventional bath facility and the used hot water can be replenished, it is not necessary to renovate a large bathroom or the like.
Also, the treated water is purified and ozone is removed by the bubble removing device and the floating microbe dead body remover, so that transparent treated water can be obtained.
[0021]
According to the invention of claim 2, by using a reverse osmosis membrane added or substituted, it is possible to achieve removal of residual chlorine ions, nitrate ions, etc. as well as Legionella bacteria, which is the original purpose, This has the effect of reducing the burden on the activated carbon catalyst / decomposing and removing unit.
Furthermore, by using the photocatalyst filling of titanium oxide or the like as the light catalyst sterilization decomposer in the invention according to the third aspect, it is possible to decompose the organic matter with a device having a simple configuration.
Furthermore, in the invention according to claim 4, by providing a bubble removing device, it is possible to remove ozone floating gas without treated water and obtain treated water with safety and high transparency.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a combined water purification apparatus according to the present invention.
FIG. 2 is an explanatory diagram of the flow of treated water during the purification operation of the present invention.
FIG. 3 is an explanatory view of the flow of treated water during the backwash process of the present invention.
FIG. 4 is an explanatory view of a photocatalytic sterilization decomposer used in the present invention.
FIG. 5 is an explanatory view showing another embodiment of the photocatalytic sterilization decomposer used in the present invention.
FIG. 6 is an explanatory view showing an embodiment of a bubble removing device used in the present invention.
FIG. 7 is an explanatory diagram showing a relationship between a nominal diameter and a processing amount in removing ozone.
[Explanation of symbols]
1 Bath 11 Flow meter 2 Piping 20, 22 Check valve 21 Vent valve 3 Pump 31, 32, 33 Three-way valve 4 Float filter 5 Fine filter 51 Pre-filter 52 Sub-filter 6 Photocatalyst sterilizer 60 Inner pipe 61 Outside Tube 62 Ultraviolet lamp 63 Pump 64 Check valve 7 Bubble removal device 8 Activated carbon / decomposition remover 9 Floating microbacteria dead body remover

Claims (4)

  A pump that draws treated water into the treatment section, a float filter that filters out relatively large debris such as human hair, lipids, skin, sand, leaves, etc., and floats and relatively large general bacteria and E. coli Removal microfilter consisting of a fine filter, etc., which collects water, sterilization of small general bacteria and photocatalytic sterilization decomposer which decomposes organic substances in the treated water with ultraviolet rays and ozone, and air and ozone remaining in the treated water A bubble removing device for removing residual gas, an activated carbon catalyst / decomposing / removing device for secondary decomposition of residual organic matter following the bubble removing device, and a floating microbe carcass removing device, A photocatalyst sterilizer, bubble removal device, activated carbon catalyst / decomposer are placed in series, and a floating microbe carcass remover is placed at an appropriate position after the photocatalyst sterilizer. Combined purification of water characterized by sterilization and removal of bacteria such as Escherichia coli and Legionella, and purification of bath water and pool water by decomposing and removing organic matter such as manure apparatus.   A combined water purification apparatus using a reverse osmosis membrane instead of or in addition to the fine filter according to claim 1. The combined purification apparatus for water according to claim 1 , wherein a photocatalyst packed tower of titanium oxide is used as the photocatalytic sterilization / decomposition device. 2. The combined water purification apparatus according to claim 1, wherein the bubble removing apparatus is provided with a bubble removing section having an open portion in the atmosphere and having a flow velocity greatly reduced compared to the flow rate in the pipe.

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