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JPH0755881B2 - Sterilization / plant growth promotion solution - Google Patents
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JPH0755881B2 - Sterilization / plant growth promotion solution - Google Patents

Sterilization / plant growth promotion solution

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Publication number
JPH0755881B2
JPH0755881B2 JP11110093A JP11110093A JPH0755881B2 JP H0755881 B2 JPH0755881 B2 JP H0755881B2 JP 11110093 A JP11110093 A JP 11110093A JP 11110093 A JP11110093 A JP 11110093A JP H0755881 B2 JPH0755881 B2 JP H0755881B2
Authority
JP
Japan
Prior art keywords
solution
sterilization
plant growth
acidic solution
generated
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.)
Expired - Lifetime
Application number
JP11110093A
Other languages
Japanese (ja)
Other versions
JPH06321719A (en
Inventor
尾 至 明 松
岡 孝 吉 花
Original Assignee
松尾 至明
花岡 孝吉
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by 松尾 至明, 花岡 孝吉 filed Critical 松尾 至明
Priority to JP11110093A priority Critical patent/JPH0755881B2/en
Publication of JPH06321719A publication Critical patent/JPH06321719A/en
Publication of JPH0755881B2 publication Critical patent/JPH0755881B2/en
Anticipated expiration legal-status Critical
Expired - Lifetime legal-status Critical Current

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  • Water Treatment By Electricity Or Magnetism (AREA)
  • Agricultural Chemicals And Associated Chemicals (AREA)

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【産業上の利用分野】本発明は、希薄電解質溶液を電気
分解して生成させた酸性溶液と次亜塩素酸ナトリウムと
を併用することによって生成される溶液と、塩基性溶液
とから成る殺菌・植物育成促進溶液に関するものであ
る。
BACKGROUND OF THE INVENTION The present invention relates to a sterilization / composition consisting of a basic solution and a solution produced by using an acidic solution produced by electrolyzing a dilute electrolyte solution and sodium hypochlorite in combination. The present invention relates to a plant growth promoting solution.

【0002】従来、植物に寄生する細菌類を死滅させる
には、農業用殺菌剤は主に細菌類の呼吸阻害を起こさせ
るSH基阻害や水素の横取りやslater因子阻害や
金属酵素阻害や酸化的リン酸阻害等の呼吸阻害によるも
のであった。また、次亜塩素ナトリウムでみられる塩素
による殺菌方法もすでに知られている。さらに、希薄強
電解質溶液の電解により塩素イオン起因による960m
Vの酸化還元電位を有する酸性電解生成による殺菌も知
られている。
[0002] Conventionally, in order to kill bacteria parasitic on plants, agricultural fungicides have been mainly used for inhibiting SH groups which cause respiratory inhibition of bacteria, stealing of hydrogen, slater factor inhibition, metal enzyme inhibition and oxidative action. This was due to respiratory inhibition such as phosphate inhibition. In addition, a sterilization method using chlorine found in sodium hypochlorite is already known. Furthermore, due to the electrolysis of a dilute strong electrolyte solution, chlorine ion causes 960 m.
Sterilization by acidic electrolysis generation with a redox potential of V is also known.

【0003】[0003]

【発明が解決しようとする課題】しかしながら、前述し
た農業用殺菌剤は、直接的人体への影響あるいは土壌の
汚染や地下水の汚染をもたらし、地球環境保全の立場か
らすると好ましいものとは言えない。また、電解生成溶
液を使用する方法は、土壌や地下水の汚染がなく地球環
境保全の見地からは有益であり、同時に生成される陽極
側の塩基性溶液が水素イオン濃度8以上で水分子集合が
微細化されたいわゆるより小さいクラスターになり、水
和されたイオンの易動度を大きくすることで水と養分の
分布速度を高める効果も知られているが、装置の小型化
やコスト低減が極めて困難であり、特に農業用までには
普及していおらず、時代の趨勢としても低農薬あるいは
無農薬への移行が強く望まれていて問題となっている。
However, the above-mentioned agricultural fungicides are not preferable from the standpoint of global environmental protection because they directly affect the human body or cause soil pollution or ground water pollution. In addition, the method of using the electrolytically generated solution is beneficial from the viewpoint of global environmental conservation because it does not pollute the soil or groundwater, and the basic solution simultaneously produced on the anode side has a hydrogen ion concentration of 8 or more and water molecule aggregates. It is also known that it becomes microscopic so-called smaller clusters, and the mobility of hydrated ions is increased to increase the distribution speed of water and nutrients, but miniaturization of the device and cost reduction are extremely It is difficult, and it has not spread to agricultural use in particular, and as the trend of the times, the shift to low or no pesticides is strongly desired, which is a problem.

【0004】本発明は、上記事情に鑑みてなされたもの
であり、土壌や地下水あるいは直接的人体への悪影響を
極めて低減した電解生成液を比較的低いエネルギーで生
成し、陰極側に生成される酸性溶液にNaClOを添加
して塩素イオンを発生させ酸性溶液内の所定の水素イオ
ン濃度と酸化還元電位を具備させることにより殺菌でき
る酸性溶液と、比較的水素イオン濃度の低い塩基性溶液
でもより小さい水分子のクラスターを実現できることか
ら水素イオン濃度10以内の植物育成促進作用を具備す
る塩基性溶液とを提供するものであり、土壌や地下水あ
るいは直接的人体への悪影響の極めて少ない、しかも投
資効率の低い農業用範囲までも充分採算のとれる安価な
殺菌・植物育成促進溶液を提供することを目的とするも
のである。
The present invention has been made in view of the above circumstances, and produces an electrolytically produced liquid having a significantly reduced adverse effect on soil, groundwater, or directly on the human body with relatively low energy, and is produced on the cathode side. An acidic solution that can be sterilized by adding NaClO to an acidic solution to generate chloride ions and having a predetermined hydrogen ion concentration and redox potential in the acidic solution, and a basic solution having a relatively low hydrogen ion concentration are smaller. The present invention provides a basic solution having a hydrogen ion concentration of 10 or less and a plant growth promoting action that can realize clusters of water molecules, and has very little adverse effect on soil, groundwater, or directly the human body, and has a high investment efficiency. It is an object of the present invention to provide an inexpensive bactericidal / plant growth promoting solution that is sufficiently profitable even in a low agricultural range.

【0005】[0005]

【課題を解決するための手段】上記目的を達成するた
め、本発明は、希薄電解質溶液を隔膜を介して電気分解
し、陰極室側に生成される酸性溶液に電解前又は電解後
にNaClOを添加して成る生成溶液と、陽極室側に生
成される塩基性溶液とから成ることを特徴とするもので
ある。また、希薄電解質溶液を隔膜を介して電気分解
し、陰極室側に生成される酸性溶液にHClとNaCl
Oによって生成される溶液を混合して成る混合溶液と、
陽極室側に生成される塩基性溶液とから成ることを特徴
とするものである。また、前記希薄電解質はNaCl又
はKClであってもよい。さらに、前記酸性溶液中の塩
素濃度は30ppm以上が好適である。
In order to achieve the above object, the present invention electrolyzes a dilute electrolyte solution through a diaphragm and adds NaClO to an acidic solution generated on the cathode chamber side before or after electrolysis. And a basic solution formed on the anode chamber side. In addition, the diluted electrolyte solution is electrolyzed through the diaphragm, and HCl and NaCl are added to the acidic solution generated on the cathode chamber side.
A mixed solution formed by mixing solutions generated by O,
It is characterized by comprising a basic solution generated on the side of the anode chamber. Also, the dilute electrolyte may be NaCl or KCl. Furthermore, the chlorine concentration in the acidic solution is preferably 30 ppm or more.

【0006】[0006]

【作用】上記構成とすることにより、比較的低い分解電
圧によって生成される酸性溶液は生成される塩素濃度が
低いため電解生成酸性溶液中のHClにNaClOを添
加して塩素濃度を高めるか、あるいは電解生成酸性溶液
に予めHClとNaClOより生成される溶液を混合し
て一定濃度つまり30ppm以上の塩素濃度の溶液を得
ることが可能となる。30ppmを下回ると大腸菌や一
般細菌の殺菌力が低下し、一定水準の殺菌効果を低減さ
せることになり、実用性が乏しくなる。また、比較的エ
ネルギー消費の少ない分解電圧によって電解するので陽
極室側に生成される塩基性溶液のpHは10以下となる
が、水分子集合の微細化されるクラスターはpH8程度
でも構成されることから植物育成促進には充分である。
そして、電解装置を小型軽量化し装置コストをより安価
にすることができる。
With the above structure, since the acidic solution produced by a relatively low decomposition voltage has a low chlorine concentration, NaClO is added to HCl in the electrolytically produced acidic solution to increase the chlorine concentration, or It is possible to obtain a solution having a constant concentration, that is, a chlorine concentration of 30 ppm or more by mixing a solution generated from HCl and NaClO in advance with the electrolytically generated acidic solution. If it is less than 30 ppm, the bactericidal activity of Escherichia coli and general bacteria will be reduced, and the bactericidal effect of a certain level will be reduced, resulting in poor practicability. Further, since the electrolysis is carried out by the decomposition voltage which consumes relatively little energy, the pH of the basic solution generated on the anode chamber side becomes 10 or less, but the clusters of water molecule aggregates that are finely divided are also composed of about pH 8. Therefore, it is sufficient for promoting plant growth.
Then, the electrolysis device can be made smaller and lighter, and the device cost can be reduced.

【0007】以下、本発明に係る実施例について述べ
る。図1は本発明の実施例に用いた殺菌・植物育成促進
溶液の製造プロセスを示す構成図である。図1におい
て、NaCl又はKClを4〜5%濃度にした希薄電解
質溶液原水1を隔膜5を備えた電解槽2に移送しながら
電解し、陰極室4側で電解生成される酸性溶液を所定濃
度の塩酸溶液を入れた塩酸溶液槽6に移送し、塩酸溶液
槽6の塩酸溶液と電解生成酸性溶液との混合溶液と、所
定濃度の次亜塩素酸ナトリウムを入れた次亜塩素酸ナト
リウム溶液槽7の次亜塩素酸溶液とをそれぞれ移送ポン
プ8、9で混合酸性溶液槽10に移送する。また、電解
槽2の陽極室3側に生成する塩基性溶液を塩基性溶液槽
11に移送する。
Examples of the present invention will be described below. FIG. 1 is a block diagram showing a manufacturing process of a sterilization / plant growth promoting solution used in an example of the present invention. In FIG. 1, dilute electrolytic solution raw water 1 having a concentration of 4% to 5% NaCl or KCl is electrolyzed while being transferred to an electrolytic cell 2 equipped with a diaphragm 5, and an acidic solution electrolytically produced on the cathode chamber 4 side is given a predetermined concentration. To the hydrochloric acid solution tank 6 containing the hydrochloric acid solution, and a mixed solution of the hydrochloric acid solution in the hydrochloric acid solution tank 6 and the electrolytically generated acidic solution, and a sodium hypochlorite solution tank containing sodium hypochlorite of a predetermined concentration The hypochlorous acid solution of 7 is transferred to the mixed acidic solution tank 10 by transfer pumps 8 and 9, respectively. Further, the basic solution generated on the side of the anode chamber 3 of the electrolytic bath 2 is transferred to the basic solution bath 11.

【0008】混合酸性溶液槽10に移送された塩素濃度
35ppmの混合酸性溶液を発芽5日目のトマトに散布
し、塩基性溶液槽11に移送されたpH8の塩基性溶液
をトマトの根部周辺の土中に表土より浸透させることを
毎日朝夕2回実施し、トマトの葉部の細菌数と葉部と茎
部の成長度をコントロールとして水道水を用いてタカラ
ーゼ活性度にて効果を確かめた。その結果は、以下に示
す表1の如くであった。
The mixed acidic solution having a chlorine concentration of 35 ppm transferred to the mixed acidic solution tank 10 was sprinkled on the tomatoes on the 5th day of germination, and the basic solution having a pH of 8 transferred to the basic solution tank 11 was distributed around the root of the tomato. Soaking from the topsoil into the soil was carried out twice a day every morning and evening, and the effect was confirmed by the tacarase activity using tap water as a control for the bacterial counts of the tomato leaves and the degree of growth of the leaves and stems. The results are shown in Table 1 below.

【0009】[0009]

【表1】 [Table 1]

【0010】次に、前述と同様な方法により混合酸性溶
液槽10に移送された塩素濃度30ppmの混合酸性溶
液を発芽30日目のトマトに散布し、塩基性溶液槽11
にpH8.5の塩基性溶液をトマトの根部周辺の土中に
表土より浸透させることを毎日朝夕2回実施し、トマト
の葉部の細菌数と葉部と茎部の成長度をコントロールと
して水道水を用いてタカラーゼ活性度にて効果を確かめ
た。その結果は、以下に示す表2の如くであった。
Next, the mixed acidic solution having a chlorine concentration of 30 ppm transferred to the mixed acidic solution tank 10 by the same method as described above is sprinkled on the tomatoes on the 30th day of germination, and the basic solution tank 11 is used.
The basic solution of pH 8.5 was infiltrated into the soil around the root of tomato from the topsoil twice daily in the morning and evening, and the number of bacteria in the tomato leaves and the growth rate of the leaves and stems were used as controls. The effect was confirmed by the activity of tacarase using water. The results are shown in Table 2 below.

【0011】[0011]

【表2】 [Table 2]

【0012】さらに、前述と同様な方法により混合酸性
溶液槽10に移送された塩素濃度40ppmの混合酸性
溶液を発芽47日目のトマトに散布し、塩基性溶液槽1
1に移送されたpH9.5の塩基性溶液をトマトの根部
周辺の土中に表土より浸透させることを毎日朝夕2回実
施し、トマトの葉部の細菌数と葉部と茎部の成長度をコ
ントロールとして水道水を用いてタカラーゼ活性度にて
効果及び葉部と茎部と土壌中の塩素残留性を確かめた。
その結果は、以下に示す表3及び表4の如くであった。
Further, the mixed acidic solution having a chlorine concentration of 40 ppm, which was transferred to the mixed acidic solution tank 10 by the same method as described above, was sprayed on the tomatoes on the 47th day of germination to prepare the basic solution tank 1.
The basic solution of pH 9.5 transferred to No. 1 was infiltrated into the soil around the root of the tomato from the topsoil twice daily in the morning and evening. Using tap water as a control, we confirmed the effect of tacarase activity and the residual chlorine in leaves, stems and soil.
The results are shown in Tables 3 and 4 below.

【0013】[0013]

【表3】 [Table 3]

【表4】 [Table 4]

【0014】なお、トマトの中のタカラーゼ活性テスト
においては、トマト幼植物の水浸液の分析は腐植酸を高
分散性の状態で含むフーモフォスの影響下でチーズ状物
質を生成し、タカラーゼの活性を刺激する(植物の酵素
系の強化をもたらす)ものである。
In the tacarase activity test in tomato, analysis of the immersion liquid of tomato seedlings produced a cheese-like substance under the influence of fumophos containing humic acid in a highly dispersible state, and the activity of tacarase was determined. Stimulating (providing the strengthening of the enzyme system of the plant).

【0015】また、テスト結果によれば、上述したよう
に、コントロールとしての水道水を用いた場合を比較す
ると、病原性カビ菌及び一般細菌の菌数が、病原性カビ
菌の殺菌効力80%以上、一般細菌の殺菌効力90%以
上となり、本発明による殺菌効果が顕著に示され、その
有効性が認められた。さらに、葉部と茎部と土壌中の残
留塩素を比較するとほとんど水道水を使用した場合と同
程度であり、塩素の残留性がないことが確認された。こ
れによって、従来行われていた殺菌剤を用いなくとも効
果的に殺菌できるようになった。また、環境保全の見地
からも薬物の残留性がないことで極めて有効に利用でき
ることが判った。
Further, according to the test results, as described above, comparing the case of using tap water as a control, the number of pathogenic fungi and general bacteria was 80%. As described above, the bactericidal effect of general bacteria was 90% or more, the bactericidal effect according to the present invention was remarkably shown, and its effectiveness was confirmed. Furthermore, when residual chlorine in leaves, stems and soil was compared, it was almost the same as when tap water was used, and it was confirmed that there is no residual chlorine. As a result, it has become possible to effectively sterilize without using a conventional bactericide. It was also found from the viewpoint of environmental conservation that the drug could be used very effectively because it has no persistence.

【0016】[0016]

【発明の効果】以上述べた如く、本発明によれば、Na
ClやKClの希薄電解質溶液を隔膜を介して陰極室側
と陽極室側に電極を通して電気分解し、陰極室側に生成
される酸性溶液にNaClOを添加するかあるいは該酸
性溶液にHClとNaClOから生成される溶液を混合
して成る酸性溶液と、陽極室側に生成される塩基性溶液
とから成る構成としたので、殺菌効果が顕著に示される
ことになると共に、葉部や茎部や土壌中の塩素の残留性
がないことから、従来行われていた殺菌剤を用いなくと
も効果的に殺菌できるようになる。また、環境保全の見
地からも薬物の残留性がないことで極めて有効に利用で
きることとなる。しかも装置の小型軽量化が実現できる
と共に、大幅なコスト低減を図ることができる。
As described above, according to the present invention, Na
A dilute electrolyte solution of Cl or KCl is electrolyzed through the electrodes to the cathode chamber side and the anode chamber side through the diaphragm, and NaClO is added to the acidic solution generated on the cathode chamber side, or HCl and NaClO are added to the acidic solution. The acidic solution formed by mixing the produced solution and the basic solution produced on the anode chamber side have a bactericidal effect, and the leaves, stems and soil Since there is no residual chlorine inside, it becomes possible to effectively sterilize without using a conventional bactericide. In addition, from the viewpoint of environmental protection, it is possible to use the drug extremely effectively because there is no persistence of the drug. Moreover, the size and weight of the device can be reduced, and the cost can be significantly reduced.

【図面の簡単な説明】[Brief description of drawings]

【図1】本発明に係る実施例の製造プロセスを示す構成
図である。
FIG. 1 is a configuration diagram showing a manufacturing process of an embodiment according to the present invention.

【符号の説明】[Explanation of symbols]

1 希薄電解質溶液原水 2 電解槽 3 陽極室 4 陰極室 5 隔膜 6 塩酸溶液槽 7 次亜塩素酸ナトリウム溶液槽 8 移送ポンプ 9 移送ポンプ 10 混合酸性溶液槽 11 塩基性溶液槽 1 Diluted Electrolyte Solution Raw Water 2 Electrolyte Tank 3 Anode Chamber 4 Cathode Chamber 5 Diaphragm 6 Hydrochloric Acid Solution Tank 7 Sodium Hypochlorite Solution Tank 8 Transfer Pump 9 Transfer Pump 10 Mixed Acid Solution Tank 11 Basic Solution Tank

Claims (4)

【特許請求の範囲】[Claims] 【請求項1】 希薄電解質溶液を隔膜を介して電気分解
し、陰極室側に生成される酸性溶液に電解前又は電解後
にNaClOを添加して成る生成溶液と、陽極室側に生
成される塩基性溶液とから成ることを特徴とする殺菌・
植物育成促進溶液。
1. A production solution obtained by electrolyzing a dilute electrolyte solution through a diaphragm and adding NaClO to an acidic solution produced on the cathode chamber side before or after electrolysis and a base produced on the anode chamber side. Sterilization characterized by consisting of
Plant growth promotion solution.
【請求項2】 希薄電解質溶液を隔膜を介して電気分解
し、陰極室側に生成される酸性溶液にHClとNaCl
Oによって生成される溶液を混合して成る混合溶液と、
陽極室側に生成される塩基性溶液とから成ることを特徴
とする殺菌・植物育成促進溶液。
2. A dilute electrolyte solution is electrolyzed through a diaphragm, and HCl and NaCl are added to an acidic solution generated on the cathode chamber side.
A mixed solution formed by mixing solutions generated by O,
A sterilization / plant growth promoting solution comprising a basic solution generated on the side of the anode chamber.
【請求項3】 前記希薄電解質がNaCl又はKClで
ある特許請求の範囲第1項又は第2項記載の殺菌・植物
育成促進溶液。
3. The sterilization / plant growth promoting solution according to claim 1 or 2, wherein the dilute electrolyte is NaCl or KCl.
【請求項4】 前記酸性溶液中の塩素濃度が30ppm
以上である特許請求の範囲第1項又は第2項記載の殺菌
・植物育成促進溶液。
4. The chlorine concentration in the acidic solution is 30 ppm.
The sterilization / plant growth promoting solution according to claim 1 or 2 above.
JP11110093A 1993-04-14 1993-04-14 Sterilization / plant growth promotion solution Expired - Lifetime JPH0755881B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP11110093A JPH0755881B2 (en) 1993-04-14 1993-04-14 Sterilization / plant growth promotion solution

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP11110093A JPH0755881B2 (en) 1993-04-14 1993-04-14 Sterilization / plant growth promotion solution

Publications (2)

Publication Number Publication Date
JPH06321719A JPH06321719A (en) 1994-11-22
JPH0755881B2 true JPH0755881B2 (en) 1995-06-14

Family

ID=14552397

Family Applications (1)

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Country Status (1)

Country Link
JP (1) JPH0755881B2 (en)

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
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AU1945197A (en) * 1996-03-21 1997-10-10 Toyo Tanso Co. Ltd. Plant growing material, process for producing the plant growing material, and method of growing plants using the plant growing material

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