JP2000107752A - Apparatus for activating water - Google Patents
Apparatus for activating waterInfo
- Publication number
- JP2000107752A JP2000107752A JP10282306A JP28230698A JP2000107752A JP 2000107752 A JP2000107752 A JP 2000107752A JP 10282306 A JP10282306 A JP 10282306A JP 28230698 A JP28230698 A JP 28230698A JP 2000107752 A JP2000107752 A JP 2000107752A
- Authority
- JP
- Japan
- Prior art keywords
- water
- ceramic
- boards
- connection port
- collision
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Pending
Links
Abstract
Description
【0001】[0001]
【産業上の利用分野】本発明は水道水等の生活用水、農
業用水、養殖用水、海水、工業用水等の水を活性化させ
る装置に関する。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for activating water such as tap water or the like, domestic water, agricultural water, aquaculture water, seawater, industrial water and the like.
【0002】[0002]
【従来の技術及びその欠点】従来この種の装置は、イオ
ン交換方式、濾過方式、吸着方式等があったが、これら
は何れも部品の交換等が必要となり、ランニングコスト
が高くなる等の他、触媒が溶解し体内に取り込まれた
り、自然界に放出されるなどの危険性がある。2. Description of the Related Art Conventionally, this type of apparatus has an ion exchange system, a filtration system, an adsorption system, and the like. However, all of these systems require replacement of parts and increase running costs. However, there is a danger that the catalyst dissolves and is taken into the body or is released to the natural world.
【0003】[0003]
【発明が解決しようとする課題】本発明はこれらの欠点
を解消すべく研究されたもので、部品の交換をすること
なく水道水等の生活用水や農業用水、養殖用淡・海水、
工業用水などの水を活性化させ、飲料水としては勿論の
こと動植物の水として、又その他の目的にあった有効な
水を安価に提供しようとするものである。DISCLOSURE OF THE INVENTION The present invention has been studied to solve these disadvantages, and it is possible to replace living parts such as tap water, agricultural water, aquaculture fresh / seawater, without replacing parts.
It aims at activating water such as industrial water and providing inexpensively available water as well as drinking water as well as water for animals and plants and for other purposes.
【0004】[0004]
【課題を解決するための手段】本発明は、給水管に接続
する入力側接続口と出力側接続口をフランジを介して設
けた水流自在な筒体と、該筒体の内部に装填する人工電
気石よりなる近似遠赤外線放射セラミック盤群とよりな
り、近似遠赤外線放射セラミック盤群は、筒体の中心軸
にスペ−サ−を介して多数の近似遠赤外線放射セラミッ
ク盤を回転自在に設置しており、これら近似遠赤外線放
射セラミック盤は多数の流通小孔を設けると共に、その
入力側の側面に衝当羽を設けて水流の衝当によって近似
遠赤外線放射セラミック盤を回転するようにしたもので
ある。SUMMARY OF THE INVENTION The present invention provides a water-flowable tubular body having an input-side connection port and an output-side connection port connected to a water supply pipe via a flange, and an artificial pipe mounted inside the pipe body. Approximate far-infrared radiating ceramic disc group consisting of tourmaline. Approximate far-infrared radiating ceramic disc group is rotatably installed on the center axis of the cylinder via spacers. These approximate far-infrared radiating ceramic discs are provided with a number of small holes, and striking wings are provided on the input side to rotate the approximate far-infrared radiating ceramic disc by striking the water flow. Things.
【0005】[0005]
【実施例】本発明を図示の実施例により詳記すると、水
道管などの給水管(図示せず。)に接続する入力側接続
口1と出力側接続口2をフランジ3、4を介して筒本体
5の鍔部6にボルト7、ナット8により締着した水流自
在な筒体9と、該筒体9の内部に装填する人工電気石よ
りなる近似遠赤外線放射セラミック盤群10とよりな
り、近似遠赤外線放射セラミック盤群10は、両接続口
1、2の基端部の中央部に架設した軸受板11、12に
設けた中心軸13にスペ−サ−14を介して多数の近似
遠赤外線放射セラミック盤15、15…を回転自在に設
置しており、これら近似遠赤外線放射セラミック盤1
5、15…は多数の流通小孔16、16…を設けると共
に、その入力側の側面に複数枚の衝当羽17、17…を
設けて水流の衝当によって近似遠赤外線放射セラミック
盤15、15…を回転するようにしたものである。DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in more detail with reference to the illustrated embodiment. An input side connection port 1 and an output side connection port 2 connected to a water supply pipe (not shown) such as a water pipe are connected via flanges 3 and 4. It comprises a water-flowable cylinder 9 fastened to the flange 6 of the cylinder body 5 with bolts 7 and nuts 8, and a group of approximate far-infrared radiation ceramic boards 10 made of artificial tourmaline loaded inside the cylinder 9. Approximate far-infrared radiation ceramic panel group 10 includes a number of approximations via spacers 14 to center shafts 13 provided on bearing plates 11 and 12 provided at the center portions of base ends of both connection ports 1 and 2. The far-infrared radiation ceramic boards 15, 15... Are rotatably installed.
5, 15 ... are provided with a number of small holes 16, 16 ... and a plurality of striking wings 17, 17 ... are provided on the side of the input side thereof. 15 are rotated.
【0006】人工電気石は、カオリンと酸性白土を主材
料とし、金属釉薬を調合し、表面に塗布して高温焼成し
て作ったものを使用すると良い。The artificial tourmaline is preferably made of kaolin and acid clay as main materials, prepared by mixing a metal glaze, applying the mixture to the surface, and firing at a high temperature.
【0007】図中18はOリング、19はワッシャ−。In the figure, 18 is an O-ring and 19 is a washer.
【0008】[0008]
【作用】本発明は以上のように構成されるもので、これ
を使用するには先ず入力側接続口1と出力側接続口2を
給水管に接続し、入力側接続口1より水が侵入すること
により、水はセラミック盤15、15…に接触しながら
流通小孔16、16…を通過すると共に、衝当羽17、
17…に激しく衝当させてセラミック盤15、15…を
回転させ、水を散流、渦流或は迷流させてセラミック盤
15、15…との接触を可及的に増大させ、セラミック
盤15、15…から放射する近似遠赤外線は常時5ミク
ロンから13ミクロンの波長を放出し、水中の陽、陰イ
オンに反応する。特に水素は自然界では最大量の遠赤外
線の吸収放射体であり、受容供給体でもあるため筒体内
部では急速な水素の活性化が起り水中の他のイオンの励
起をうながし、塩素化合物、次亜塩素酸、臭い物質等の
コロイドを分解し、ミネラル成分又はイオンに置換さ
れ、水和化又は分子化されことにより活性化される。The present invention is constructed as described above. To use the present invention, first connect the input side connection port 1 and the output side connection port 2 to the water supply pipe, and water intrudes from the input side connection port 1. As a result, the water passes through the flow holes 16, 16, while contacting the ceramic plates 15, 15.
17 are violently agitated and the ceramic plates 15, 15 are rotated, and water is scattered, swirled or strayed to increase the contact with the ceramic plates 15, 15 as much as possible. , 15... Always emit a wavelength of 5 to 13 microns and react to positive and negative ions in water. In particular, hydrogen is the largest amount of far-infrared absorbing and radiating substance in the natural world, and it is also an accepting donor, so that rapid activation of hydrogen occurs inside the cylinder, prompting the excitation of other ions in the water, causing chlorine compounds and hypoxia. Colloids such as chloric acid and odorous substances are decomposed, replaced by mineral components or ions, and activated by being hydrated or molecularized.
【0009】[0009]
【効果】本発明は叙上のように、給水管に接続する入力
側接続口と出力側接続口をフランジを介して設けた水流
自在な筒体と、該筒体の内部に装填する人工電気石より
なる近似遠赤外線放射セラミック盤群とよりなり、近似
遠赤外線放射セラミック盤群は、筒体の中心軸にスペ−
サ−を介して多数の近似遠赤外線放射セラミック盤を回
転自在に設置しており、これら近似遠赤外線放射セラミ
ック盤は多数の流通小孔を設けると共に、その入力側の
側面に衝当羽を設けて水流の衝当によって近似遠赤外線
放射セラミック盤を回転自在としたので、水を散流、渦
流或は迷流させてセラミック盤15、15…との接触を
可及的に増大させ、セラミック盤15、15…から放射
する近似遠赤外線は水中の陽、陰イオンに反応し、特に
水素は自然界では最大量の遠赤外線の吸収放射体であ
り、受容供給体でもあるため筒体内部では急速な水素の
活性化が起り水中の他のイオンの励起をうながし、塩素
化合物、次亜塩素酸、臭い物質等のコロイドを分解し、
ミネラル成分又はイオンに置換され、水和化又は分子化
されことにより活性化され、生活用水は勿論のこと農業
用水、養殖用水、工業用水等に使用すればその目的にあ
った有効な効果を発揮し、ことに飲料水としては臭い
や、有害物質の分解、除去等によりのみやすくなり、植
物の成長を促し、養殖においては動物の成長を促進する
効果がある。As described above, according to the present invention, a water-flowable tubular body having an input-side connection port and an output-side connection port connected to a water supply pipe via a flange, and an artificial electric machine mounted inside the tubular body It consists of a group of approximate far-infrared radiating ceramic discs made of stone.
A number of approximate far-infrared radiating ceramic boards are rotatably installed via a server, and these approximate far-infrared radiating ceramic boards are provided with a large number of small holes, and are provided with striking wings on the input side. , The approximate far-infrared radiation ceramic plate is made rotatable by the impact of the water flow, so that the water is scattered, swirled or strayed to increase the contact with the ceramic plates 15, 15 as much as possible. Approximate far-infrared rays radiated from 15, 15, ... react with positive and negative ions in water. In particular, hydrogen is the largest amount of far-infrared absorbing and radiating substance in nature, and it is also a receiving donor, so it has a rapid rate inside the cylinder. Activation of hydrogen occurs, prompting the excitation of other ions in the water, decomposing colloids such as chlorine compounds, hypochlorous acid, and odorous substances,
It is activated by being replaced by mineral components or ions and hydrated or molecularized, and when used in agricultural water, aquaculture water, industrial water, etc. as well as domestic water, it exhibits an effective effect for its purpose. In particular, drinking water is more likely to be obtained only by decomposing and removing odors and harmful substances, and has the effect of promoting plant growth and promoting animal growth in aquaculture.
【0010】更にセラミック盤の水流による回転によっ
て水に含まれているミネラル等はセラミック盤群に付着
しにくく、ミネラル成分等は水和化されて放出される。
又赤錆対策としても有効で、発生しにくいばかりか徐々
に減少していく傾向が認められた。Further, minerals and the like contained in water hardly adhere to the group of ceramic disks due to the rotation of the ceramic disk by the water flow, and the mineral components and the like are hydrated and released.
It was also effective as a countermeasure against red rust, and it was found that it was not easy to generate and tended to gradually decrease.
【0011】[0011]
【実験例】1、検証方法 、水道水を採水する。 、上記と同じ水道水を本発明装置により処理する(以
下BW処理水という。) 、上記、のサンプル
を、O−NMR(酸素核磁気共鳴装置)にて測定す
る。 、上記、のサンプルを、1500ガウスの磁場の
中に5分間さらし、23℃の恒温室で48時間保存す
る。これをサンプル’、’とする。 、この’、’の水を再びO−NMRにて測定す
る。 、と’、と’の数値デ−タを比較する。エネ
ルギ−状態の高いものほど数値の開きがない。 2、結論 神奈川県産業技術総合研究所で行ったデ−タによると、
BW処理水はは117→’は114と2.5%の数
値の差、他方水道原水は109→’は93と14.
7%の数値の差があった。尚この数値は「17酸素スペ
クトルの線幅/Hz」である。つまりBW処理水は処理
前の水道水と比べ約6倍の内部エネルギ−持続力の増加
が確認された。エネルギ−状態の高い(活性度が高
い。)水はクラスタ−の細分化等の変化と、それに伴う
ミネラル粒子の細分化により、外力に対しての修復能力
が高くなっている、それ故、本発明装置で活性化した水
は、磁力線の外力にさらされたの地48時間経過すると
当初のO−NMRの数値に近い数値に戻る結果となった
と考えられる。[Experimental example] 1. Verification method, tap water is sampled. When the same tap water is treated by the apparatus of the present invention (hereinafter referred to as BW treated water), the above sample is measured by O-NMR (oxygen nuclear magnetic resonance apparatus).
You. The above sample is exposed to a magnetic field of 1500 Gauss for 5 minutes and stored in a constant temperature room at 23 ° C. for 48 hours. These are referred to as samples ','. The water of ',' is measured again by O-NMR. , And ', and' are compared. The higher the energy state, the smaller the numerical value. 2. Conclusion According to data conducted at the Kanagawa Prefectural Institute of Advanced Industrial Science and Technology,
For BW treated water, 117 → 'was 114 and 2.5% difference, while raw tap water was 109 →' for 93 and 14.
There was a 7% numerical difference. This numerical value is "line width of 17 oxygen spectrum / Hz". That is, it was confirmed that the BW treated water increased the internal energy sustainability about six times as much as the tap water before the treatment. Water having a high energy state (high activity) has a high ability to repair external forces due to the change in the fragmentation of clusters and the resulting fragmentation of mineral particles. It is considered that the water activated by the apparatus of the present invention returned to a value close to the original value of O-NMR after 48 hours of exposure to the external force of the magnetic field lines.
【図1】本発明装置の分解斜視説明図。FIG. 1 is an exploded perspective view of a device of the present invention.
【図2】近似遠赤外線放射セラミック盤の平面説明図。FIG. 2 is an explanatory plan view of an approximate far-infrared radiation ceramic board.
【図3】図2の近似遠赤外線放射セラミック盤のA−A
線断面説明図。FIG. 3 AA of the approximate far-infrared radiation ceramic disk of FIG. 2;
FIG.
1は入力側接続口 2は出力側接続口 3はフランジ 4はフランジ 5は筒本体 6は鍔部 9は筒体 10は近似遠赤外線放射セラミック盤群 13は中心軸 15は近似遠赤外線放射セラミック盤 16は流通小孔 17は衝当羽 1 is an input side connection port 2 is an output side connection port 3 is a flange 4 is a flange 5 is a cylinder main body 6 is a flange portion 9 is a cylindrical body 10 is a group of approximate far-infrared radiation ceramic boards 13 is a center axis 15 is an approximate far-infrared radiation ceramic Panel 16 is distribution hole 17 is striking feather
Claims (1)
接続口をフランジを介して設けた水流自在な筒体と、該
筒体の内部に装填する人工電気石よりなる近似遠赤外線
放射セラミック盤群とよりなり、近似遠赤外線放射セラ
ミック盤群は、筒体の中心軸にスペ−サ−を介して多数
の近似遠赤外線放射セラミック盤を回転自在に設置して
おり、これら近似遠赤外線放射セラミック盤は多数の流
通小孔を設けると共に、その入力側の側面に衝当羽を設
けて水流の衝当によって近似遠赤外線放射セラミック盤
を回転自在とした水の活性化装置。An approximate far-infrared radiation comprising a water-flowable cylinder provided with an input-side connection port and an output-side connection port connected to a water supply pipe via a flange, and an artificial tourmaline loaded inside the cylinder. The group of ceramic boards is composed of a plurality of ceramic boards. The ceramic boards are provided with a large number of ceramic boards, which are rotatable around a central axis of a cylindrical body via a spacer. A water activation device in which a radiation ceramic board is provided with a number of small holes and an impingement wing is provided on a side face on an input side thereof so that an approximate far-infrared radiation ceramic board can be freely rotated by impact of a water flow.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP10282306A JP2000107752A (en) | 1998-10-05 | 1998-10-05 | Apparatus for activating water |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP10282306A JP2000107752A (en) | 1998-10-05 | 1998-10-05 | Apparatus for activating water |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| JP2000107752A true JP2000107752A (en) | 2000-04-18 |
Family
ID=17650712
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| JP10282306A Pending JP2000107752A (en) | 1998-10-05 | 1998-10-05 | Apparatus for activating water |
Country Status (1)
| Country | Link |
|---|---|
| JP (1) | JP2000107752A (en) |
Cited By (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| WO2007023516A1 (en) | 2005-08-22 | 2007-03-01 | Kikuo Tamura | Water activation piece for use in flow passage, arrangement structure of the water activation piece, and water activation device using the water activation piece and the arrangement structure |
| JP2008045026A (en) * | 2006-08-16 | 2008-02-28 | Toshi Kakugyo Kk | Water-soluble cutting oil and decay prevention method for water-soluble cutting oil |
| JPWO2007072590A1 (en) * | 2005-12-22 | 2009-05-28 | 田村 喜久雄 | Water heater |
| JP2013052383A (en) * | 2011-09-05 | 2013-03-21 | Yoshiko Moriyasu | Device and method for purifying water |
| KR101263135B1 (en) | 2010-04-27 | 2013-05-15 | 키쿠오 타무라 | Water activation apparatus |
| CN110776051A (en) * | 2019-12-09 | 2020-02-11 | 哈尔滨盛世康虹生物技术有限公司 | Composite energy field frequency spectrum water generator |
-
1998
- 1998-10-05 JP JP10282306A patent/JP2000107752A/en active Pending
Cited By (6)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| WO2007023516A1 (en) | 2005-08-22 | 2007-03-01 | Kikuo Tamura | Water activation piece for use in flow passage, arrangement structure of the water activation piece, and water activation device using the water activation piece and the arrangement structure |
| JPWO2007072590A1 (en) * | 2005-12-22 | 2009-05-28 | 田村 喜久雄 | Water heater |
| JP2008045026A (en) * | 2006-08-16 | 2008-02-28 | Toshi Kakugyo Kk | Water-soluble cutting oil and decay prevention method for water-soluble cutting oil |
| KR101263135B1 (en) | 2010-04-27 | 2013-05-15 | 키쿠오 타무라 | Water activation apparatus |
| JP2013052383A (en) * | 2011-09-05 | 2013-03-21 | Yoshiko Moriyasu | Device and method for purifying water |
| CN110776051A (en) * | 2019-12-09 | 2020-02-11 | 哈尔滨盛世康虹生物技术有限公司 | Composite energy field frequency spectrum water generator |
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