JP3645290B2 - Food processing method - Google Patents

Description

注意）０．０１ＣＦ＝２．８×１０^-4ｍ³として計算。
【００４９】
◎イオン濃度
表２のとおりである。
【００５０】
【表２】

【００５１】
表１，表２の結果から、微細水滴と空気イオン（特に負イオン）の存在量を重量比で求めると、以下のとおりとなる。なお、負イオン分子は、Ｏ₂ ^-（Ｈ₂Ｏ）ｎとし、ｎ＝１０と仮定した。
微細水滴（０．１μｍから２μｍまで）の総量 ２〜３×１０^-6 ｇ／ｍ³
負イオン量 ６×１０^-11ｇ／ｍ³
【００５２】
一方、室温２２℃，室内湿度９５％の保管室内の湿潤空気中に含まれる水蒸気重量を空気線図から求めると、約１８ｇ／ｍ³になる。得られた活性空気中に含まれる約１８ｇ／ｍ³の水分量が水クラスターであると考えられる。活性空気の質量スペクトラムは図５に示すとおりである。
【００５３】
遠心力・コリオリ力発生装置は水に高エネルギーを与えるために、慣性系に回転座標系を加味して、遠心力及びコリオリ力を発生させる旋回気流にしたことを特徴としている。この際、高速気流の空塔速度（ｍ／ｓｅｃ）が大きい程これらのエネルギーが増大して水クラスターが多量に発生する。空塔速度を１．８ｍ／ｓｅｃで実施したところ、パーティクル・カウンターで５μｍ粒子が５０個／０．０１ＣＦ検出された。
【００５４】
活性空気の質量分析は以下のように行った。活性空気は、質量分析用に試作した活性空気発生装置により製造し、サイクロンより内径１６ｍｍ以上のステンレス管を用いて質量分析装置のガラス製インターフェースに導入した。活性空気製造時におけるタンクの水温は２３℃であり、活性空気の温度は２５℃，相対湿度は８３％であった。質量分析計は、四重極質量分析計を用い、イオン化は大気圧液体イオン化法を用いた。イオン源としては、コロナ放電を利用した活性アルゴンガスにより行った。図５に上記条件下における活性空気の水クラスターの質量スペクトラムを、図６に活性空気測定の直前に測定した大気中の水クラスターの質量スペクトラムを示す。
【００５５】
（実施例１）活性空気の大豆の加工特性に与える影響を調べた。
【００５６】
◎材料
市販乾燥丸大豆（北海道産，９３／１２／６製造，海成食品（株），埼玉県）
◎操作手順
（１）試料大豆を３群（Ａ，Ｂ，Ｃ）に分け各１００グラムを精秤した。
Ａ群−活性空気雰囲気中（１３℃）に置いて浸透処理をした。
Ｂ群−飽和蒸気デシケーター（１３℃）中に置いた。
Ｃ群−１５〜２３℃の室内に置いた。
（２）各群をそれぞれの条件下で１９時間放置した後、大豆の重量変化及び体積変化を測定した。
（３）試料大豆の８倍重量の水道水を加え、室温で２４時間浸漬した。浸漬後の大豆の重量変化及び体積変化を測定した。
（４）各群から６０ｇを精秤し、５００ｍｌビーカーに入れて３群同時に同じ蒸し器で１３５分間蒸煮した。１５分毎に各群から大豆を２粒ずつとりだし、硬さ，感触，色，形を比較した。
以下に測定結果を示す。
【００５７】
（１）表３に測定した重量及び体積の実測値を示した。
【００５８】
【表３】

【００５９】
（２）表４に重量比（％）及び体積比（％）を示した。
【００６０】
【表４】

【００６１】

【００６２】
（４）浸漬後の液の濁り状態の比較
浸漬を完了した時点での液の濁りの度合はＡ群＜Ｂ群＜Ｃ群の順序であった。
また、この順で泡立ちが多かった。
【００６３】
以上の実験は次のことを示している。
（１）活性空気の水分は、空気中に通常発生する水蒸気の水分に比べて乾燥大豆に浸透しやすいので、活性化処理によって組織が膨潤した。これは、活性空気の水分は水クラスターからなり、その大きさは通常発生する水蒸気のクラスターに比べて小さいためである。活性化処理したものは、既にある程度膨潤しており、浸漬のみによる膨潤は他の群よりもむしろ小さかった。
（２）蒸煮した場合の煮上がり状態が互いに異なった。活性化処理群の方が室温放置群よりも明らかに軟らかく煮上がった。活性空気と大豆組織との間には複雑な相互作用（活性空気による組織内の水の自己組織化促進による生命活動への刺激など）が起こっているためと考えられる。
（３）Ａ群；活性空気雰囲気中で温度；４℃，湿度；９８％で同様の実験を行ったところ、６２時間で同様の吸湿率（％）の結果を得た。又温度；５５℃，湿度；３０％で５時間放置した実験では蛋白変成がみられた。従って、活性雰囲気中で活性化処理を行う場合、温度及び湿度は最適条件を選定する必要がある。
【００６４】
（実施例２）乾燥大豆，乾燥小豆，精白米を活性空気中に放置した時の細胞組織の変化を走査型電子顕微鏡によって観察した。
【００６５】
◎材料
市販乾燥大豆（北海道産，１９９２／１０収穫，１９９４／１／１４包装，帯広川西農協（株），北海道，１９９４／４／２５ヤオコーで購入，１９９４／４／２５開封）
乾燥小豆 （中国産，１９９４／３／８製造，下田商事（株），東京，１９９４／４／２５ヤオコーで購入，１９９４／５／１１開封）
精白米 （日本産，コシヒカリ，１９９４／５／７製造，１９９４／５／１８ヤオコーで購入，１９９４／５／１９開封，カカシ米穀（株），埼玉）
【００６６】
◎操作手順
（１）試料大豆，小豆，精白米をそれぞれ３群に分け各５０ｇを精秤した。
Ａ群−活性空気雰囲気中（１３℃）に置いた。
Ｂ群−飽和水蒸気デシケーター（１３℃）中に置いた。
Ｃ群−１５〜２５℃の室内に置いた。
なお、製品袋中に保存されているものをＤ群とした。製品袋はＣ群と同じ室内に放置した。
（２）各群をそれぞれの条件下で２４時間放置した後、重量変化を測定した。
（３）各群から５ｇ前後をプラスチック製サンプル管に入れて、蓋をパラフィルムでシールし、試料種子の表皮に近い部位を走査型電子顕微鏡で観察した。
【００６７】
◎結果
表５に大豆，小豆，精白米のＡ〜Ｃ群のそれぞれの重量及び重量比（％）を示した。
【００６８】
【表５】

【００６９】
図８〜１９は、大豆，小豆，精白米について、それぞれＡ群，．Ｂ群，Ｃ群，Ｃ群のものの表皮部分の断面を示しており、各図とも（ａ）の倍率は３００倍、（ｂ）は６００倍に拡大したものである。
【００７０】
図８〜１１は大豆、図１２〜１５は小豆、図１６〜１９は精白米について示し、図８，１１，１６はＡ群、図９，１２，１７はＢ群、図１０，１３，１８はＣ群、図１１，１４，１９はＤ群の様子を表わしている。
【００７１】
【発明の効果】
以上のように本発明は、水に高エネルギーを付与して構造変化が生じた水クラスターを含む多湿の活性空気を発生させ、構成分子数の少ない水クラスターを製造することにより、その空気雰囲気中に置くことで、生体の組織内に深く浸透させることが可能となり、生体組織の活性化、特に膨化作用に著しい効果が得られる。
【００７２】
以上示した実施例は、限られたものであるが、水クラスターを含む活性空気の利用，展開の可能性は大きい。例えば、豆乳，豆腐の製造工程において、原料大豆の磨砕の前段階で水浸漬の処理は欠かすことができないが、大豆の水浸漬に要する時間は、夏期１０時間，冬期２０時間である。しかも膨化を早めるために水の温度を上げると発芽の準備が始まり、溶出物が増えるという問題があるが、活性空気で予め処理することによって、浸漬時間を短縮でき、浸漬温度が低くても十分に膨化する。
【００７３】
活性化処理によって水浸漬時間を半減できるだけでもその経済的効果は莫大である。さらに小麦の加工においても、粉砕に先立って小麦に散水し、しばらく放置するテンパリングという操作が行われる。テンパリングにより、小麦の外皮は一層強靱となり、胚乳は一層砕かれやすくなり、両者の分離が容易となる。
【００７４】
したがって、テンパリングに先立って活性化処理を行えば、テンパリングの時間を短縮できることは十分に予想できる。実施例２に示したように現在のところ小豆のような皮の硬い穀類に対しては見るべき膨化効果が認められていないが、いずれ活性化処理条件の設定の問題を解決することによりクリヤすることは可能であると考えられる。
【００７５】
一方、活性化処理が食品の重量増加，体積増加に留まらず、図７に示すように活性空気中に含まれる水クラスターの働きを生体系の自己組織化を復元させる本来の意味の活性化作用であると考えるならば、これは農産食品の加工のための活性化に留まらず、全ての生体の活性化が可能であると考えられる。
【００７６】
【発明の効果】
以上のように本発明は、水に高エネルギーを付与して構造変化が生じた水クラスターを含む活性空気を発生させ、構成分子数の少ない水クラスターを製造することにより、その空気雰囲気中に置くことで、生体の組織内に深く浸透させることが可能となり、生体組織の活性化、特に膨化作用に著しい効果が得られる。
【００７７】
殊に本発明によれば、いわゆるレナード効果，シンプソン効果を利用したものであるため、活性空気中には、あわせて空気イオンが発生し、生体に対する活性作用を一層向上することができる。また、旋回気流中に水を噴出することによって水の分裂と、気液分離の作用を一貫して行うことができる。
【図面の簡単な説明】
【図１】本発明方法を実施する活性空気発生装置の一例を示す図である。
【図２】スクリューガイドの配置例を示す図である。
【図３】水の会合体モデルを示す図である。
【図４】構成分子数の大きさによる名称の違いの表を示す図である。
【図５】活性空気の水クラスターの質量スペクトラムを示す図である。
【図６】大気中の水クラスターの質量スペクトラムを示す図である。
【図７】活性空気の熱力学的効果を示す図である。
【図８】（ａ）は活性化処理した大豆の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図９】（ａ）は飽和水蒸気デシケーター中に放置した大豆の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図１０】（ａ）は室内に放置した大豆の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図１１】（ａ）は製品袋中で保存されている大豆の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図１２】（ａ）は活性化処理した小豆の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図１３】（ａ）は飽和水蒸気デシケーター中に放置した小豆の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図１４】（ａ）は室内に放置した小豆の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図１５】（ａ）は製品袋中に保存されている小豆の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図１６】（ａ）は活性化処理した精白米の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図１７】（ａ）は飽和水蒸気デシケーター中に放置した精白米の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図１８】（ａ）は室内に放置した精白米の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【図１９】（ａ）は製造袋中に保存されている精白米の断面を３００倍に拡大した電子顕微鏡による写真、（ｂ）は、同１５００倍に拡大した電子顕微鏡による写真である。
【符号の説明】
１ 活性空気発生装置
２ 遠心力・コリオリ力発生装置
３ 高速気流発生装置
４ 気液分離装置
５ 吸気口
６ 吸液口
７ 排気口
８ 保管室
９ タンク
１０ ポンプ
１１ 管路
１２ 管路
１３ 空気力輸送管
１４ スクリューガイド
１５ ノズル配管
１６ 水槽
１７ ポンプ
１８ ノズル
１９ 冷却機
２０ 温度調節装置
２１ 空気力輸送管[0001]
[Industrial application fields]
The present invention relates to a method for generating water clusters and activating agricultural foods, particularly rice wheat, millet grains, and beans, using activated air containing the water clusters.
[0002]
[Prior art]
Most agricultural foods are secondarily processed or cooked by the process of “simmering” or “cooking”. For example, taking soybeans as an example, the processing is soy beans. Even if you add water and boil it, the skin won't break, and it's difficult to boil it softly enough to push it with your fingers.
[0003]
The processing of soybeans requires more complicated processing than other beans. Processed soybean products include kure, soy milk, tofu, fried tofu, frozen tofu, yuba, natto, miso, and soy sauce. Soybeans have the property of swelling and softening when immersed in water.
[0004]
Most soy processed products are typically immersed in water to swell and then ground and heated. The time for soaking in water varies depending on the water temperature, but by soaking in water for 15 hours in winter and 8 hours in summer, soybeans swell approximately twice and a half.
[0005]
Soybean swelling is a necessary process for processing or cooking, but seed swelling is on the other hand a preparation for germination and is considered to be an activated state in which the life activity of dormant seeds becomes active. It is done.
[0006]
[Problems to be solved by the invention]
On the other hand, regarding the activation of seeds, it is known that snow melting water has an effect of accelerating seed germination. This phenomenon is explained by Prof. Zenbu Ue of the Korean Academy of Sciences as follows. That is, liquid water is a mixture of three types of clusters of five-membered, six-membered, and five-membered rings as shown in FIG. 3, and is mainly composed of five-membered water near room temperature. When it is lowered, the proportion of the 6-membered ring increases, and the melted snow has a large proportion of the 6-membered ring. It is so-called highly physiological water (Masaharu Kubota “Interesting Water” p287, Nikkan Kogyo Shimbun 1994).
[0007]
Regarding the freshness of food, water is closely related to the taste, texture, and preservability of food, which is considered to be quite similar to water in the living body. Water activity is important in considering the freshness of food. When the water activity in the food is approximately equal to the relative humidity of the outside world, water is not lost from the food, and conversely, the food does not take up water from the outside. All the professors think that if water cyclization progresses, the vapor pressure will drop, and by immersing food in such water, the water in the food will be affected and the cyclization will occur. For example, it is suggested that the interaction between water molecules is strengthened, the vapor pressure is lowered, the water in the food is less likely to evaporate, and the freshness of the food is maintained (Id. P283).
[0008]
However, it is said that the above-mentioned specific physical properties of snow melting water will lose this effect after 4-5 days. Therefore, it seems that the ratio of the cluster of 6-membered rings does not necessarily increase only at a low temperature of water. If this is the case, the above-mentioned specific physical properties of snowmelt may be due to the energy gained during snowfall or thaw.
[0009]
Conventionally, it is said that magnetically treated water, ceramic treated water, and electrically treated water have an effect of maintaining food freshness. Certainly, it is known that the evaporation rate of water treated in this way is generally lower than that of untreated water, but the mechanism has not been elucidated, and there are still directions to question the effect itself. What is said to be Qigong water is the water that the Qigong teacher irradiates with “Qi” (outside air). As a result of measuring Qigong water using NMR (nuclear magnetic resonance apparatus), it is a cluster of water molecules. (5 molecules or more) changed and became larger, and the numerical value indicating the movement of the cluster also became larger (see the wonder of Masaharu Ikegami “Ki” Kodansha).
[0010]
Cluster research has begun in earnest in various countries around the world, and the theoretical consideration is not limited to the future, but at least for water clusters, It must be considered that this structural change occurs.
[0011]
An object of the present invention is to provide a method of generating a cluster by splitting water and activating a food using activated air containing the cluster.
[0017]
[Means for Solving the Problems]
  In order to achieve the above object, in the food processing method according to the present invention,Erupted into the airWater cluster by water splittingIn the airThe food is processed by being generated and placed in an air atmosphere containing the generated water cluster.
  Also,Erupted into the airWater splitting and negative ions by water splittingIn the airThe food is processed by being generated and placed in an air atmosphere containing the generated water clusters and negative ions.
[0018]
[Action]
An aggregate of two to several hundreds of atoms or molecules is called a cluster, and is generally called separately as shown in FIG. If a cluster is classified according to its binding mode, it is generally classified as follows.
(1) Van der Waals cluster
(2) Covalent bond cluster
(3) Hydrogen bond cluster
(4) Metal cluster
(5) Cluster ion
[0019]
By the way, about the structure of water, the form has not been established yet. However, with the accumulation of experiments and sophistication of logical simulation, it has become increasingly clear that water has a cluster structure with hydrogen bonds. Since ancient times, there have been many studies on ice crystals, but liquid water contains hydrogen-bonded clusters that contain part of the ice structure. It is said that 70% of the hydrogen bonds at the time of ice remain in the water vapor boiling at 100 ° C. by heating (see Koji Tsuji, Nobuyuki Nishi Cluster Industrial Book 1994, p64-p78).
[0020]
The phenomenon in which nearby air is ionized when water droplets break up in connection with rain or other precipitation has long been known as the Leonard effect. Leonard discovered a phenomenon in which ions are generated in the nearby air when a water droplet collides with a metal plate and breaks up. After that, Simpson repeated Leonard's experiment, measured using a more precise device, and that the same result as the Leonard effect can occur just by the water droplet breaking up in the air, the ions generated in the air are It has been reported that it is a negative ion regardless of the charge of the water droplet, and that the water droplet gets the same amount of positive charge as the ion generated during the breakup (Meteorological Electrology Hisao Takayama, Minoru Kawano) Iwanami Shoten, 1965, see pages 26-27).
[0021]
Negative ions generated by the Leonard effect and Simpson effect can be taken out by separating them from water droplets. A negative ion generator utilizing the Leonard effect is described in JP-A-4-141179, and a negative ion generator utilizing the Simpson effect is introduced in Japanese Patent Application No. 5-261396. In this device, a liquid is injected into a swirling flow of an air current to break it into fine water droplets, and then gas-liquid separation is performed to extract air containing negative ions as supply air. Is basically humid.
[0022]
In the swirling flow of the air current, the liquid is spouted and divided into fine water droplets, and then the humid air taken out by gas-liquid separation is used for dust removal, sterilization, deodorization and gas component removal effect, humidity control effect, It has been found to have an antistatic effect and positively affect the growth of animals and plants. Initially, these effects were considered to be all due to the effect of generating fine water droplets, and then to the effect of negative ions in the air. Certainly, with regard to the effects of positive ions and negative ions caused by ionization of air, it is generally said that positive ions excite nerves, and negative ions calm nerves. There are reports in the literature that ions in the air refresh the mood (Keiichi Morishita “Water and Life” 1992, p77, Misato Ribo and others).
[0023]
The components generated by the activation treatment were considered to be two types of air ions and fine water droplets, but also include water clusters. According to the classification of FIG. 4, it can be seen that the cluster indicates the structure of a substance composed of two or more atoms or molecules.
[0024]
According to the experiment shown later, most of the components contained in the active air are water vapor, and the amount of negative ions and fine water droplets is negligible compared to the amount of water vapor. Presumably, the majority of water vapor moisture contained in the active air is assumed to be hydrogen-bonded clusters.
[0025]
FIG. 5 shows a mass spectrum of a water cluster of humid air obtained by an activation process in which water is split in a swirling air flow and then gas-liquid separation is performed. FIG. 6 shows a mass spectrum of an atmospheric water cluster. ing. As is clear from comparison between the two figures, the water clusters in the atmosphere are distributed around the number of constituent molecules n = 21, and the mass number m / z 379, whereas in the humid air that has been activated. Are distributed in a region having a small number of constituent molecules centered on mass number m / z 200. This shows that the number of constituent molecules of the water cluster decreases when the energy level is increased by applying mechanical energy by the activation treatment. Conversely, water clusters also show that the number of constituent molecules increases with increasing system randomness.
[0026]
The thermodynamic effect of active air on a living body is considered as follows. As shown in FIG. 7, consider three types of energy levels: active air, water in the living system, and bulk water. As mentioned above, the energy level of active air is considered higher than the energy level of bulk water. Also, the energy level of water in a living system is thought to be lower than the level of active air but higher than the level of bulk. The reason for this is that the water in the living system is bulky due to the presence of inorganic ions in the living body, the structure of biological macromolecules themselves, or the potential change that occurs when they move around based on a certain order due to life activity. This is because some sort of organization is considered to be more than water.
[0027]
According to the second law of thermodynamics, the randomness of the system tends to increase. That is, the active air increases the number of constituent molecules of the cluster, the energy level decreases, and eventually decreases to the bulk energy level. Also, when there is no movement based on life activity, the energy level of water in the living system decreases to the energy level of bulk water. However, when the energy level of the active air decreases, it will be possible to work on other systems and thus increase the energy level of bulk water. Increasing the energy level means that the active air cluster reacts with the bulk water cluster to cause a rearrangement of the cluster structure, creating a system with an energy level similar to that in which the living body is active.
[0028]
As the mechanism by which active air acts on a biological system, direct action and indirect action can be considered. The direct action refers to the case where the active air cluster penetrates directly into the living system and exerts the activating action. The indirect action refers to the structure of the cluster by contacting the active air cluster with the water of the living system. This refers to the case where recombination is gradually permeating and exerting an activation effect. In the former case, small clusters will be able to move more easily than large clusters. In the latter case, a cluster having a higher energy level will be able to exhibit its action more effectively.
[0029]
The surface of a living body usually has fine holes. The same applies to cereals. This fine hole is said to be an “ink bottle” because it has a very small opening and a wide back. In order for water clusters to enter a living body ink bottle, the openings must be very small and the clusters must be small. It is considered that the water cluster contained in the active air is a small cluster having about n = 10 constituent molecules, so that it effectively enters the ink bottle and a so-called ink bottle effect can be obtained.
[0030]
【Example】
Embodiments of the present invention will be described below with reference to the drawings. In the embodiment, a negative ion generator that generates negative ions using the Simpson effect can be used as an active air generator.
[0031]
In FIG. 1, the embodiment shows an example in which an active air generator is attached outside the storage chamber 8. The storage room includes food processing, storage, and animal and plant growth rooms. The active air generator 1 is a combination of a centrifugal force / Coriolis force generator 2 and a gas-liquid separator 4.
[0032]
The centrifugal force / Coriolis force generator 2 has an intake port 5, a liquid suction port 6, and an exhaust port 7. A high-speed airflow generator 3 is connected to the intake port 5 and external air is blown into the exhaust port 7. The air from which the separator 4 is connected and the liquid is separated is fed from the outlet. A tank 9 is connected to the liquid suction port 6 via a pump 10, and the liquid in the tank 9 is supplied. In the embodiment, the output line 11 of the gas-liquid separator 4 and the input line 12 of the high-speed airflow generator 3 are opened to the storage chamber 8 to form a circulation system. In the embodiment, the active air generator 1 is installed outside the storage chamber 8 and connected to the storage chamber 8 through the pipes 11 and 12. Alternatively, the active air generator 1 is installed in the storage chamber 8. It can be installed and used as an indoor installation type by opening the air supply port of the gas-liquid separator 4 and the intake port of the high-speed airflow generator 3 to the storage chamber 8.
[0033]
The centrifugal force / Coriolis force generator 2 is a mechanism for performing liquid ion dissociation processing, droplet activation processing, and gas molecule ionization processing. In the embodiment, in the horizontal aerodynamic transport pipe 13, A spiral screw guide 14 shown in FIG. 2 is disposed along the axial center, a nozzle pipe 15 is provided on the axial center, and a water tank 16 is provided on the lower peripheral surface.
[0034]
Water in the tank 9 is pumped into the water tank 16 by the pump 10, and water in the water tank 16 is pumped up by the pump 17 and sent to the nozzle pipe 15. The tank 9 is equipped with a cooler 19 and adjusts the supply water to a necessary temperature.
[0035]
The screw guide 14 induces an air flow in the aerodynamic transport pipe 13 and turns the pipe axis direction in a spiral shape. The nozzle pipe 15 is located at the axial center of the aerodynamic transport pipe 13, and the gas is swirling around the nozzle pipe 15. Therefore, the guide 14 is not always necessary, but in the embodiment, the guide 14 is used. Therefore, the direction of the swirl direction of the airflow is regulated so that the Coriolis force faces the direction of the angular velocity vector of the earth's rotation. However, if the gas supply direction from the high-speed airflow generator 3 is set tangential to the inner periphery of the aerodynamic transport pipe 13, the airflow direction is automatically set to the clockwise and counterclockwise rotation flow. Is done.
[0036]
A nozzle 18 is opened at a peripheral surface along the axial center of the nozzle pipe 15, and the nozzle 18 ejects the liquid supplied from the water tank 16 into the swirling airflow in the aerodynamic transport pipe 13. Water is ejected from the nozzle 18 at a high pressure, and obtains energy to break up into fine water droplets.
[0037]
The high-speed airflow generation device 3 is a fan for blowing air. In the embodiment, the air in the storage chamber 8 is sucked and blown into the aerodynamic transport pipe 13 through the intake port 5.
[0038]
In the embodiment, the gas-liquid separator 4 uses a cyclone separator. The cyclone separator is effective for the separation of centrifugal force of gas and liquid as long as a certain speed or higher wind speed and pressure can be obtained in the air flow including fine water droplets discharged from the exhaust port 7 of the aerodynamic transport pipe 13. The gas-liquid separated air is introduced into the storage chamber 8 through the pipe line 11. The pipe 11 is provided with a temperature control device (H / E) 20.
[0039]
In the embodiment, the high-speed air flow generating device 3 is activated, the water in the water tank 16 is pumped up by the pump 17, and the strong air current generated in the aerodynamic transport pipe 13 from each nozzle 18 of the nozzle pipe 15 is It blows out against the direction of flow.
[0040]
The water ejected into the aerodynamic transport pipe 13 is subjected to gas pressure, splits in the swirling airflow and is dissociated into ions, splits into fine water droplets, and is transported aerodynamically through the pipe while swirling along the guide 14. The During this time, the water droplets flow in the axial direction while facing the tube wall due to the centrifugal force generated by the swirling flow of the air current and the Coriolis force, and the interface of the water droplets in contact with the gas is activated while breaking into fine water droplets When the dipole is oriented on the surface of the water droplet, oxygen molecules present at the gas side interface are ionized and air is activated.
[0041]
Air containing water droplets flows into the gas-liquid separation device 4 from the exhaust port 7 of the aerodynamic transport pipe 13, water droplets remaining in the gas are removed, and then laminarized, and the temperature control device 20 performs the required operation. After being adjusted to temperature and humidity, it is introduced into the storage chamber 8 from the pipe line 11 as active air. As a result, an atmosphere of humid active air is formed in the storage chamber 8. On the other hand, the air in the storage chamber 8 receives the suction force of the high-speed airflow generation device 3 and is sucked into the pipe 12, and is supplied to the centrifugal force / Coriolis force generation device 2 again with newly introduced outside air if necessary. Pumped.
[0042]
Water droplets adhering to the tube wall of the aerodynamic transport tube 13 and water droplets separated by the gas-liquid separator are returned to the water tank 16. Since this water droplet contains a lot of positive ions, the tube wall is grounded and neutralized.
[0043]
As mentioned above, although the horizontal type centrifugal force / Coriolis force generator is shown in the embodiment, the arrangement direction is not limited at all. The specification of the active air generator is, for example, as follows.
[0044]
◎ Centrifugal force / Coriolis force generator
Dimensions: Diameter 600φ x Length 1,100mm
Entrance superficial velocity: 11-12m / sec
Exit superficial velocity: 9-10m / sec
◎ Gas-liquid separator
Dimensions: Diameter 500φ x Length 900mm
Entrance superficial velocity: 9-10m / sec
Exit superficial velocity: 8.5-9m / sec
◎ Fan
Air volume: Max 3m^Three/ Min
◎ Cooler
Refrigerant: R-12
◎ Temperature control device 2KW heater
[0045]
The active air generator shown in FIG. 1 was operated, and the temperature and humidity in the storage room, the particle size distribution of fine water droplets, and the amount of ions were measured in the immediate vicinity of the active air outlet opening in the storage room.
[0046]
Data on the number distribution of fine water droplets was measured in a single mode using RION particle counters KC-18 and KC-01A. The obtained data had an internal wind speed of 4 m / sec and a water pressure of 0.5 kg / cm.²， Used when using city water. The ion concentration was measured under the same conditions using an ion counter (83-1001A) manufactured by RION.
[0047]
The measurement results are as follows.
◎ Storage room temperature and humidity
Indoor temperature about 22 ℃
Indoor humidity about 95%
◎ Number of fine water droplet size distribution (single mode)
It is as Table 1.
[0048]
[Table 1]

Note) 0.01CF = 2.8 × 10^-Fourm^ThreeAs calculated.
[0049]
◎ Ion concentration
It is as Table 2.
[0050]
[Table 2]

[0051]
From the results of Tables 1 and 2, when the abundance of fine water droplets and air ions (particularly negative ions) is determined by weight ratio, the results are as follows. Negative ion molecules are O₂ ^-(H₂O) n, assuming n = 10.
Total amount of fine water droplets (from 0.1 μm to 2 μm) 2-3 × 10^-6g / m^Three
Negative ion amount 6 × 10^-11g / m^Three
[0052]
On the other hand, when the water vapor weight contained in the humid air in the storage room at room temperature of 22 ° C. and indoor humidity of 95% is determined from the air diagram, it is about 18 g / m 2.^Threebecome. About 18 g / m contained in the obtained active air^ThreeIt is considered that the water content of the water cluster. The mass spectrum of active air is as shown in FIG.
[0053]
The centrifugal force / Coriolis force generator is characterized by a swirling air flow that generates centrifugal force and Coriolis force by adding a rotating coordinate system to the inertial system in order to give high energy to water. At this time, as the superficial velocity (m / sec) of the high-speed air current increases, these energies increase and a large amount of water clusters are generated. When the superficial velocity was 1.8 m / sec, 50 particles / 0.01 CF of 5 μm particles were detected by a particle counter.
[0054]
Mass spectrometry of active air was performed as follows. The active air was manufactured by an active air generator prototyped for mass spectrometry, and introduced into the glass interface of the mass spectrometer using a stainless steel tube having an inner diameter of 16 mm or more from a cyclone. The water temperature of the tank during the production of active air was 23 ° C., the temperature of active air was 25 ° C., and the relative humidity was 83%. As the mass spectrometer, a quadrupole mass spectrometer was used, and the atmospheric pressure liquid ionization method was used for ionization. The ion source was activated argon gas using corona discharge. FIG. 5 shows the mass spectrum of water clusters of active air under the above conditions, and FIG. 6 shows the mass spectrum of water clusters in the atmosphere measured immediately before the measurement of active air.
[0055]
Example 1 The effect of active air on the processing characteristics of soybean was examined.
[0056]
◎ Material
Commercial dried whole soybeans (Hokkaido, 93/12/6 production, Marine Foods, Saitama)
Operation procedure
(1) The sample soybeans were divided into 3 groups (A, B, C), and 100 grams each was precisely weighed.
Group A—Penetration treatment was performed in an active air atmosphere (13 ° C.).
Group B-Placed in a saturated steam desiccator (13 ° C).
Group C was placed in a room at 15 to 23 ° C.
(2) Each group was allowed to stand for 19 hours under each condition, and then the weight change and volume change of soybean were measured.
(3) Tap water of 8 times the weight of the sample soybean was added and immersed for 24 hours at room temperature. The weight change and volume change of soybean after immersion were measured.
(4) 60 g from each group was precisely weighed and placed in a 500 ml beaker, and the 3 groups were steamed for 135 minutes in the same steamer. Every 15 minutes, two soybeans were taken from each group and compared in terms of hardness, feel, color and shape.
The measurement results are shown below.
[0057]
(1) Table 3 shows measured values of weight and volume.
[0058]
[Table 3]

[0059]
(2) Table 4 shows the weight ratio (%) and volume ratio (%).
[0060]
[Table 4]

[0061]

[0062]
(4) Comparison of liquid turbidity after immersion
The degree of turbidity of the liquid when the immersion was completed was in the order of group A <group B <group C.
Moreover, there was much foaming in this order.
[0063]
The above experiment shows the following.
(1) Since the moisture of active air easily penetrates dry soybeans compared to the moisture of water vapor normally generated in the air, the tissue swelled by the activation treatment. This is because the moisture of the active air is composed of water clusters, and the size thereof is smaller than that of normally generated water vapor clusters. The activated material was already swollen to some extent, and the swelling due to immersion alone was rather smaller than the other groups.
(2) The boiled state when steamed was different from each other. The activated group was boiled softer than the room temperature group. This is thought to be due to the fact that a complex interaction between active air and soybean tissue (stimulation of life activity by promoting self-organization of water in the tissue by active air) occurs.
(3) Group A: A similar experiment was conducted at a temperature of 4 ° C. and a humidity of 98% in an active air atmosphere, and the same moisture absorption rate (%) was obtained in 62 hours. In addition, protein modification was observed in an experiment that was allowed to stand at a temperature of 55 ° C. and a humidity of 30% for 5 hours. Therefore, when the activation treatment is performed in an active atmosphere, it is necessary to select optimum conditions for temperature and humidity.
[0064]
(Example 2) Changes in cell tissues when dried soybeans, dried red beans, and polished rice were left in active air were observed with a scanning electron microscope.
[0065]
◎ Material
Commercially available dried soybeans (Hokkaido, 1992/10 harvest, 1994/1/14 packaging, Obihiro Kawanishi Co., Ltd., Hokkaido, 1994/4/25 purchased from Yaoko, 1994/4/25 opened)
Dried red beans (China, 1994/3/8 production, Shimoda Corporation, Tokyo, 1994/4/25 purchased from Yaoko, 1994/5/11 opened)
Refined rice (from Japan, Koshihikari, 1994/5/7 production, 1994/5/18 purchased from Yaoko, 1994/5/19 opened, Kakashi Rice Cereal Co., Ltd., Saitama)
[0066]
Operation procedure
(1) Sample soybeans, red beans, and polished rice were divided into three groups, and 50 g of each was precisely weighed.
Group A-Placed in an active air atmosphere (13 ° C).
Group B-Placed in a saturated steam desiccator (13 ° C).
Group C was placed in a room at 15 to 25 ° C.
In addition, what was preserve | saved in the product bag was made into D group. The product bag was left in the same room as Group C.
(2) Each group was allowed to stand for 24 hours under the respective conditions, and the weight change was measured.
(3) About 5 g from each group was put in a plastic sample tube, the lid was sealed with parafilm, and the part close to the epidermis of the sample seed was observed with a scanning electron microscope.
[0067]
◎ Result
Table 5 shows the weight and weight ratio (%) of each of the A to C groups of soybean, red beans, and polished rice.
[0068]
[Table 5]

[0069]
FIGS. 8 to 19 show groups A,. The cross sections of the epidermis parts of the groups B, C, and C are shown. In each figure, (a) is magnified 300 times and (b) is magnified 600 times.
[0070]
FIGS. 8 to 11 show soybeans, FIGS. 12 to 15 show red beans, FIGS. 16 to 19 show polished rice, FIGS. 8, 11 and 16 show Group A, FIGS. 9, 12, and 17 show Group B, and FIGS. Represents the state of the C group, and FIGS. 11, 14 and 19 represent the state of the D group.
[0071]
【The invention's effect】
  As described above, the present invention includes a water cluster in which structural change is caused by applying high energy to water.HumidBy generating active air and producing a water cluster with a small number of constituent molecules, it is possible to penetrate deeply into living tissue by placing it in the air atmosphere. A remarkable effect can be obtained.
[0072]
Although the embodiments shown above are limited, the possibility of using and deploying active air containing water clusters is great. For example, in the production process of soy milk and tofu, the water soaking treatment is indispensable in the stage before grinding of the raw material soybean, but the time required for soaking the soybean in water is 10 hours in summer and 20 hours in winter. Moreover, if the temperature of water is raised in order to accelerate swelling, preparation for germination starts, and there is a problem that the amount of eluate increases.However, pretreatment with active air can reduce the immersion time, and it is sufficient even if the immersion temperature is low. To swell.
[0073]
Even if the water immersion time can be halved by the activation treatment, the economic effect is enormous. Further, in the processing of wheat, a tempering operation is performed in which water is sprinkled on the wheat before pulverization and left for a while. Tempering makes the wheat skin more tough, endosperm is more easily crushed, and it is easier to separate them.
[0074]
Therefore, if the activation process is performed prior to tempering, it can be sufficiently predicted that the tempering time can be shortened. As shown in Example 2, there is currently no puffing effect to be observed for hard-cemented cereals such as red beans, but it will eventually be cleared by solving the problem of setting the activation treatment conditions. It is considered possible.
[0075]
On the other hand, the activation treatment is not limited to the increase in the weight and volume of the food, but the original activation function that restores the self-organization of the biological system by the action of water clusters contained in the active air as shown in FIG. If this is considered, this is not limited to activation for processing of agricultural foods, and it is considered that all living organisms can be activated.
[0076]
【The invention's effect】
  As described above, the present invention generates active air including a water cluster in which structural change occurs by applying high energy to water.,By producing water clusters with a small number of constituent molecules,By placing it in the air atmosphere,It becomes possible to penetrate deeply into the tissue of a living body, and a remarkable effect is obtained on the activation of the living tissue, particularly the swelling action.
[0077]
In particular, according to the present invention, since the so-called Leonard effect and Simpson effect are used, air ions are generated in the active air, and the active action on the living body can be further improved. Moreover, the water splitting and the gas-liquid separation can be performed consistently by jetting water into the swirling airflow.
[Brief description of the drawings]
FIG. 1 is a diagram showing an example of an active air generator for carrying out the method of the present invention.
FIG. 2 is a view showing an example of arrangement of screw guides.
FIG. 3 is a diagram showing a water aggregate model.
FIG. 4 is a diagram showing a table of name differences according to the number of constituent molecules.
FIG. 5 is a diagram showing a mass spectrum of a water cluster of active air.
FIG. 6 is a diagram showing a mass spectrum of water clusters in the atmosphere.
FIG. 7 shows the thermodynamic effect of active air.
FIG. 8A is a photograph taken with an electron microscope in which the cross section of the activated soybean is magnified 300 times, and FIG. 8B is a photograph taken with an electron microscope magnified 1500 times.
FIG. 9A is a photograph taken with an electron microscope in which a cross section of soybeans left in a saturated water vapor desiccator is magnified 300 times, and FIG. 9B is a photograph taken with an electron microscope magnified 1500 times.
FIG. 10A is a photograph taken with an electron microscope in which a cross section of soybeans left in the room is magnified 300 times, and FIG. 10B is a photograph taken with an electron microscope magnified 1500 times.
11A is a photograph taken with an electron microscope in which a cross section of soybean stored in a product bag is magnified 300 times, and FIG. 11B is a photograph taken with an electron microscope magnified 1500 times.
FIG. 12A is a photograph taken with an electron microscope in which the cross section of the activated red beans is magnified 300 times, and FIG. 12B is a photograph taken with an electron microscope magnified 1500 times.
13A is a photograph taken with an electron microscope in which a cross-section of a red bean left in a saturated water vapor desiccator is magnified 300 times, and FIG. 13B is a photograph taken with an electron microscope magnified 1500 times.
14A is a photograph taken with an electron microscope in which a cross-section of a red bean left in the room is magnified 300 times, and FIG. 14B is a photograph taken with an electron microscope magnified 1500 times.
FIG. 15A is a photograph taken with an electron microscope in which a cross-section of a red bean stored in a product bag is magnified 300 times, and FIG. 15B is a photograph taken with an electron microscope magnified 1500 times.
FIG. 16A is a photograph taken with an electron microscope in which the cross section of the activated polished rice is magnified 300 times, and FIG. 16B is a photograph taken with an electron microscope magnified 1500 times.
FIG. 17A is a photograph taken with an electron microscope in which a cross-section of polished rice left in a saturated water vapor desiccator is magnified 300 times, and FIG. 17B is a photograph taken with an electron microscope magnified 1500 times.
18A is a photograph taken with an electron microscope in which a cross-section of polished rice left in a room is magnified 300 times, and FIG. 18B is a photograph taken with an electron microscope magnified 1500 times.
FIG. 19A is a photograph taken with an electron microscope in which a cross-section of polished rice stored in a production bag is magnified 300 times, and FIG. 19B is a photograph taken with an electron microscope magnified 1500 times.
[Explanation of symbols]
1 Active air generator
2 Centrifugal force / Coriolis force generator
3 High-speed airflow generator
4 Gas-liquid separator
5 Inlet
6 Liquid inlet
7 Exhaust port
8 Storage room
9 tanks
10 Pump
11 pipeline
12 pipelines
13 Pneumatic force transport pipe
14 Screw guide
15 Nozzle piping
16 Aquarium
17 Pump
18 nozzles
19 Cooling machine
20 Temperature controller
21 Pneumatic transport pipe

Claims (2)

A food processing method, comprising: generating water clusters in the air by splitting water ejected into the air; and placing the food in an air atmosphere containing the generated water clusters. A food product characterized in that water clusters and negative ions are generated in the air by splitting water ejected into the air, and the food is processed by placing it in an air atmosphere containing the generated water clusters and negative ions. Processing method.

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