JP2011073988A - Plant disease controlling functional agent and method of growing plant using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To utilize neutral electrolyzed water as a functional agent for controlling plant diseases. <P>SOLUTION: The functional agent for controlling plant diseases caused by viruses, fungi or insect pests is composed of neutral electrolyzed water obtained by subjecting water 14 to be treated comprising water including 0.1-3 wt.% sodium chloride to electrolysis while causing vibration fluidized agitation of the water 14 to be treated with the use of a vibration agitation means to cause vibration fluidized agitation in the water 14 to be treated by transmitting vibrations generated by a vibrating motor 16d through a vibrating bar 16e to vibrating blades 16f fixed to the vibrating bar to vibrate the vibrating blades and the residual chlorine concentration in the neutral electrolyzed water is 1-500 ppm. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a plant disease control functional agent and a method for growing plants using the same.

  Conventionally, plants affected by various viruses, molds and pests, such as vegetables, flower buds and fruit trees, have been controlled using agricultural chemicals such as general-purpose or dedicated fungicides or insecticides each time. . In addition, general or special pesticides may be sprayed to prevent disease.

  However, general pesticides may have adverse effects on animals and humans living in the environment, and ministerial ordinances that establish standards to be followed by those who use pesticides (Ministry of Agriculture, Forestry and Fisheries / Ministry of Environment No. 5 No.) In Article 6, severe restrictions on the use of pesticides in residential areas are issued. In recent years, from the viewpoint of environmental protection, so-called pesticide-free cultivation that grows plants without using pesticides has been recommended. Thus, when disease control is not performed at all, in addition to a decrease in yield, growth itself may be impossible. Therefore, what has a plant disease control function with little influence on the environment is desired.

  On the other hand, International Publication WO2006 / 041001 [Patent Document 1] discloses neutral electrolyzed water having various functions and a method for producing the same.

International Publication WO2006 / 041001

  Patent Document 1 discloses that the neutral electrolyzed water described therein has a bactericidal action.

  An object of the present invention is to use the neutral electrolyzed water described in Patent Document 1 as a functional agent for controlling plant diseases. That is, not only when suffering from illness, but by spraying a functional agent periodically before illness, the plant can grow healthy.

According to the present invention, the above object is achieved as follows:
A functional agent for controlling plant diseases,
The vibration generated by the vibration generating means is transmitted to the vibration blade attached to the vibration rod through the vibration rod, and the vibration blade is vibrated, so that the water to be treated is vibrated and fluidized. It was obtained by electrolyzing the water to be treated while vibrating and stirring the water to be treated consisting of water containing 0.1% by weight to 3% by weight of sodium chloride using the vibration stirring means. It consists of neutral electrolyzed water (this neutral electrolyzed water is characterized by having chloric acid [specific chlorine compound], which is considered to have a special molecular structure, as the main component),
The residual chlorine concentration in the neutral electrolyzed water is 1 ppm to 500 ppm (this concentration does not decrease over several years),
Plant disease control agent,
Is provided.

  In one aspect of the present invention, the plant disease is caused by a virus, mold or pest.

  In addition, according to the present invention, there is provided a method for controlling plant diseases, characterized in that the above-mentioned functional agent is sprayed onto plants (spreading of this functional agent is completely harmless to animals and plants).

  In one embodiment of the present invention, the functional agent is sprayed by spraying.

  According to the present invention, since neutral electrolyzed water produced by a specific production method and having a residual chlorine concentration of 1 ppm to 500 ppm is used as a functional agent, plant diseases can be controlled substantially without adverse effects on environmental animals.

It is typical sectional drawing which shows an example of the vibration stirring means in the apparatus for manufacturing the functional agent by this invention. It is typical sectional drawing which shows an example of the functional agent manufacturing apparatus using a vibration stirring means.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  The functional agent of the present invention uses neutral electrolyzed water produced by the production method described in Patent Document 1. The manufacturing method described in Patent Document 1 can be manufactured using the manufacturing apparatus described in Patent Document 1. This manufacturing apparatus will be briefly described below.

  FIG. 1 is a schematic cross-sectional view showing an example of a vibration stirring means in an apparatus for producing a functional agent according to the present invention, which is described in FIG. Here, the base 16a is fixed on the mounting base 40 attached to the upper part of the electrolytic cell 10A via the vibration absorbing member 41. Further, a rod-shaped guide member 43 extending upward in the vertical direction is fixed to the base 16a, and the guide member 43 is located in the coil spring 16b. A vibration member 16c spaced from the guide member 43 is placed on the coil spring 16b, and a vibration motor 16d constituting vibration generating means is fixed on the vibration member 16c.

  An upper end of a vibrating bar 16e is attached to the vibrating member 16c, and the vibrating bar 16e extends through the through hole formed in the mounting base 40 into the electrolytic cell 10A. The to-be-processed liquid 14 is accommodated in the electrolytic vessel 10A. Vibrating blades 16f are attached to the portion of the vibrating rod 16e immersed in the liquid to be treated 14 in a plurality of stages by mounting nuts 16j.

  An inverter 35 for controlling the vibration frequency of the vibration motor 16d is interposed between the vibration motor 16d and the rectifier 25 for driving the vibration motor 16d.

  The vibration stirring means will be further described. The above-described inverter 35 causes the vibration motor 16d to vibrate at 10 to 200 Hz, particularly 30 to 45 Hz, and this vibration is transmitted to the vibration blade 16f via the vibration rod 16e to vibrate the vibration blade 16f. Since the vibration blade 16f is bent, the vibration is in a form called fluttering where the tip flutters. The vibration of the vibration blade 16f has, for example, a tip amplitude of 0.01 to 5.0 mm.

  Thereby, a strong flow is generated in the liquid 14 to be processed. Such a flow is called an oscillating flow, and thereby the liquid to be treated is vigorously stirred. That is, the vibration agitating means transmits the vibration generated by the vibration generating means (vibrating motor 16d) to the vibrating blade 16f attached to the vibrating rod 16e via the vibrating rod 16e, and vibrates the vibrating blade. As a result, vibration and flow stirring is caused in the water to be treated 14.

  As the water 14 to be treated, water containing 0.1% to 3% by weight of sodium chloride is used. As water, tap water, ground water, well water, distilled water, soft water, ion exchange water, reverse osmosis membrane water, and the like can be used. Moreover, as the to-be-processed water 14, you may use seawater, after adjusting sodium chloride density | concentration suitably.

FIG. 2 is a schematic cross-sectional view showing an example of a functional agent production apparatus using the vibration stirring means 16 having a function substantially similar to that of the vibration stirring means as described above, and is described in FIG. It is what has been. Here, the anode member 83 and the cathode member 84 constituting the means for electrolysis are supported by the anode bus bar 80 and the cathode bus bar 82, respectively, and are immersed in the water 14 to be treated. A voltage of about 1 to 30 V is applied between the anode member 83 and the cathode member 84 by direct current or pulse current using an electrolysis power source (not shown), and a current density of about 5 to 300 A / dm ^2. Electrolysis is performed at.

  In the vibration agitating means 16, a vibration rod 16e is used with an insulating member 16e "interposed at a position above the surface of the water 14 to be treated. In addition, the vibrating bars 16e and the vibrating blades 16f are made of conductive material and are connected to one electrode of the electrolysis power source via the electric wire 127. Thus, the portion of the vibrating rod 16e and the vibrating blade 16f immersed in the water to be treated 14 can be used as an anode member or a cathode member.

Usually, in the electrolysis of water, H ₂ and O ₂ are generated in a gaseous state. However, in the present invention, since the vibration stirring means is in operation, the generated active gas, H ₂ and O ₂ are dispersed and dissolved in water, and rarely go out of the apparatus as gas.

  When electrolyzing dilute saline solution under vibration flow, the generated gas becomes nano / micro bubbles, and as a result, the main components of the neutral electrolyzed water produced as described above are hypochlorous acid, chlorite. It contains acid and chlorate ions. Although the molecular structure is not clear, chloric acid is considered to be a specific oxidation compound, unlike general chloric acid. The residual chlorine concentration in the neutral electrolyzed water is, for example, 1 ppm to 5000 ppm. In the present invention, a residual chlorine concentration of 1 ppm to 500 ppm is used. Since the residual chlorine concentration in the neutral electrolyzed water increases as electrolysis continues, neutral electrolyzed water having a required residual chlorine concentration can be obtained by adjusting the operation time of the apparatus. The apparatus as described above is characterized in that the salt concentration, current density, and electrolysis time can be freely changed, and neutral electrolyzed water can be produced continuously.

  The hydrogen ion exponent pH of the neutral electrolyzed water as described above is preferably in the range of 6.5 ≦ pH ≦ 8.5, and more preferably in the range of 6.5 ≦ pH ≦ 7.5. preferable.

  As described in Patent Document 1, the neutral electrolyzed water has good bactericidal properties that last for a long time. In particular, those having a residual chlorine concentration of 1 ppm to 500 ppm exhibit a good disease control function with virtually no adverse effect on environmental animals even when sprayed on plants for the control or prevention of diseases as a functional agent. Can do. When the residual chlorine concentration is less than 1 ppm, the required plant disease control action is reduced, and when the residual chlorine concentration exceeds 500 ppm, there is a possibility that the environmental animal may have an adverse effect. The residual chlorine concentration is preferably 5 ppm to 100 ppm.

  The functional agent of the present invention is safe because it is suitable for drinking water and food applications, and since it is neutral, it has little chemical action on various containers and instruments and has long-lasting efficacy, so it fills containers. And can be used little by little at various locations. According to this, workability at the time of controlling plant diseases is particularly good.

  Examples of the plant diseases include those caused by viruses, molds, and pests, such as powdery mildew, mosaic disease, vine blight, and weevil disease in various vegetables.

  The method for controlling plant diseases according to the present invention is carried out by spraying the functional agent as described above on plants. The amount of spraying and the frequency of spraying can be appropriately determined according to the type and degree of the disease to be controlled. Here, the spraying can be performed, for example, by spraying with a sprayer. In addition to extermination when plant diseases actually occur, the above functional agents can be sprayed for disease prevention. In this specification, prevention and extermination are collectively referred to as prevention.

  Hereinafter, the present invention will be described by way of examples.

[Example 1]
In accordance with the method described in Patent Document 1, neutral electrolyzed water was produced as follows. Α-Torino water production apparatus-1 type (30L) (manufactured by Nippon Techno Co., Ltd.) was used as the production apparatus. The characteristics of this device were as follows.

Vibration motor: 75 W, 200 V × 3φ. Vibration blade: Four stainless steel (SUS304) plates. Vibrating bar: 2 stainless steel (SUS304) round bars. Electrolytic tank: a container (30 L) coated with a heat-resistant propylene resin, 500 × 290 × 305 (unit: mm). Anode member: 3 sheets of titanium lath net (platinum plating coating). Cathode member: 4 stainless steel (SUS304) plates. Distance between electrode members: 20 mm. Anode members and cathode members are arranged close to each other. Area of the electrode members, three anode member 12 dm ^2, 4 sheets cathode member 16 dm ^2. Rectifier (transistor type): PEM11-12V-200 manufactured by Chuo Seisakusho Co., Ltd. Inverter: Fuji inverter FVR-E9S manufactured by Fuji Electric.

  As water to be treated, sodium chloride (primary chemical) was dissolved in Tokyo tap water, and the sodium chloride (NaCl) concentration was 5 g / L (0.5 wt%).

  AC 200V × 3 phase was used, and this was converted into a DC current of 12V and 15A by a rectifier. The frequency of the vibration motor was adjusted to 45 Hz by an inverter, and electrolysis was performed while vibrating the treated water for 6 minutes to obtain neutral electrolyzed water. The residual chlorine concentration in this neutral electrolyzed water was 10 ppm. The pH was 7.4.

  By using the obtained neutral electrolyzed water as a recovery-promoting functional agent and applying it to the damaged biological surface layer, it was possible to promote the recovery of the damaged biological surface layer as shown in the following examples. .

[Example 2]
In the same manner as in Example 1 except that α-Torino water production device-2 type (100L) (manufactured by Nippon Techno Co., Ltd.) was used as the production device, and the operation time of the device was adjusted accordingly. Electrolyzed water was obtained. The residual chlorine concentration in this neutral electrolyzed water was 15 ppm. The pH was 7.5.

  By using the obtained neutral electrolyzed water as a recovery-promoting functional agent and applying it to the damaged biological surface layer, it was possible to promote the recovery of the damaged biological surface layer as shown in the following examples. .

[Example 3]
As a manufacturing apparatus, the same as in Examples 1 and 2, except that an insulating member was interposed in a vibrating rod constituting the vibration stirring means, and the operating time of the apparatus was adjusted accordingly. Electrolyzed water was obtained. The residual chlorine concentration in this neutral electrolyzed water was 20 ppm. The pH was 7.5.

  By using the obtained neutral electrolyzed water as a recovery-promoting functional agent and applying it to the damaged biological surface layer, it was possible to promote the recovery of the damaged biological surface layer as shown in the following examples. .

(Case 1: Powdery mildew control)
When the pumpkin leaves were about 50 mm to 100 mm in size, powdery white mold was generated from powdery mildew of powdery mildew. Therefore, the functional agent obtained in Example 1 was added to 0 per 10 cm ² of leaf area. When sprayed at a spraying amount of 5 ml to 1 ml, the white mold disappeared within a few minutes and no mold was generated again. In addition, the pumpkins grew normally without any abnormalities in the leaves and stems, and the fruits could be harvested.

Similarly, for the powdery mildew similar to the above pumpkin, the functional agent obtained in Example 1 was sprayed at a spraying amount of 0.5 ml to 1 ml per 10 cm ² of leaf area. Within a few minutes, the white mold disappeared and no mold occurred again. In addition, cucumbers grew normally without any abnormality in the leaves and stems, and the fruits could be harvested.

  It turns out that the disease control effect of a functional agent is remarkable.

(Case 2: Control of mosaic disease)
In order to confirm the effect of the functional agent on mosaic disease caused by cucumber mosaic virus in cucumber, the following comparative test was conducted.

About 50 samples out of 100 equivalent cucumber seedling samples whose stems were about 20 cm in length and leaves were also aligned, the functional agent obtained in Example 2 was applied once every 6 days. When sprayed at a rate of 0.3 ml to 0.5 ml per 5 cm ² leaf area at a time, no abnormalities were observed in the leaves and stems for all samples, and it grew normally and the fruit I was able to harvest. A part of the sprayed functional agent dropped and penetrated into the soil, but this did not affect the growth of the sample. On the other hand, for the other 50 samples, when the functional agent was not applied, 30 samples suffered from mosaic disease, the leaves withered yellow, the stems could not grow normally, and the fruits could be harvested. There wasn't.

  It turns out that the disease control effect of a functional agent is remarkable.

(Case 3: Control of weevil)
The functional agent obtained in Example 3 above was used to control the 2 to 5 mm long green weevil that is inhabiting at a distribution density of 3 to 4 per 10 cm ^{2 on the} back of cabbage that is normally growing. When sprayed with a spraying amount of 1 ml to 1.5 ml per 10 cm ^{2 of} cabbage leaf area, the movement of the weevil becomes sloppy and eventually stops moving, or after rolling down from the cabbage leaf to the ground, it does not move. And died.

In addition, in order to prevent disease caused by a weevil on a cabbage that is located at a distance of 5 m from the location of the cabbage where the weevil was inhabited and is not inhabited by the weevil, the above-mentioned Example 3 When the functional agent obtained in (1) was sprayed at a spraying amount of 0.5 ml to 1 ml per 10 cm ^{2 of} cabbage leaf area, no disease caused by weevil occurred, and good cabbage could be harvested.

  It turns out that the disease control effect of a functional agent is remarkable.

10A: Electrolyzer 14: Liquid to be treated 16a: Base 16b: Coil spring 16c: Vibration member 16d: Vibration motor 16e: Vibration rod 16e ": Insulation member 16f: Vibration blade 16j: Mounting nut 25: Rectifier 35: Inverter 40: Installation Table 43: Guide member 80: Anode bus bar 82: Cathode bus bar 83: Anode member 84: Cathode member 127: Conducting wire

Claims (4)

A functional agent for controlling plant diseases,
The vibration generated by the vibration generating means is transmitted to the vibrating blade attached to the vibrating rod through the vibrating rod, and the vibrating blade is vibrated, so that the water to be treated is vibrated and fluidized. It was obtained by electrolyzing the water to be treated while vibrating and stirring the water to be treated consisting of water containing 0.1% by weight to 3% by weight of sodium chloride using the vibration stirring means. Made of neutral electrolyzed water,
The residual chlorine concentration in the neutral electrolyzed water is 1 ppm to 500 ppm,
Plant disease control agent.   The plant disease control function agent according to claim 1, wherein the plant disease is caused by a virus, a mold or a pest.   A method for controlling plant diseases, wherein the functional agent according to claim 1 or 2 is sprayed on plants.   The method for controlling plant diseases according to claim 3, wherein the functional agent is sprayed.

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