JP2014039487A - Raising method of plant using alkaline electrolyzed water containing nanobubble, and production device of alkaline electrolyzed water containing nanobubble - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a raising method of plant using alkaline electrolyzed water containing nanobubbles promoting the growth of plant, and a production device of the alkaline electrolyzed water containing nanobubbles.SOLUTION: In an electrolyzed water production device 1, alkaline electrolyzed water is filled in an alkaline electrolyzed water main tank 6 and an alkaline electrolyzed water sub-tank 24, and acidic electrolytic water is filled in an acidic electrolyzed water main tank 10 and an acidic electrolyzed water sub-tank 30. A nanobubble production device 13 is connected to the alkaline electrolyzed water main tank 6. The alkaline electrolyzed water is circulated between the nanobubble production device 13 and the alkaline electrolyzed water main tank 6, and alkaline electrolyzed water containing nanobubbles is stored in the alkaline electrolyzed water main tank 6. An alkaline electrolyzed water main exhaust valve 22A is opened, and the alkaline electrolyzed water containing nanobubbles is taken out and given to plant.

Description

  The present invention relates to a plant growing method using alkaline electrolyzed water containing nanobubbles and an apparatus for producing alkaline electrolyzed water containing nanobubbles.

  In recent years, for the purpose of reducing environmental load, etc., farming methods that give electrolyzed water to crops instead of chemical fertilizers and pesticides have attracted attention. In addition, a cleaning and sterilization method using nanobubble electrolyzed water containing minute bubbles (nanobubbles) for cleaning and sterilizing plants is also known (see, for example, Patent Document 1).

JP 2004-121962 A

  By the way, in the prior art described in Patent Document 1, nanobubble electrolyzed water is brought into contact with a plant to perform washing and sterilization, but the relationship with plant growth has not been sufficiently studied.

  The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to provide a plant growing method using alkaline electrolyzed water containing nanobubbles that promotes plant growth and an apparatus for producing alkaline electrolyzed water containing nanobubbles. It is to provide.

  In order to solve the above problems, in the method for growing plants using alkaline electrolyzed water containing nanobubbles according to the invention of claim 1, the amount of saturated dissolved oxygen is more than 10 mg-O / L at 27 ° C., and the pH is 10 to 10. The plant is fed with alkaline electrolyzed water containing nanobubbles of 13 to the plant.

  In the invention of claim 2, the alkaline electrolyzed water contains potassium.

  Moreover, in the apparatus for producing alkaline electrolyzed water containing nanobubbles according to the invention of claim 3, the electrolyzed water generating apparatus for generating alkaline electrolyzed water and acidic electrolyzed water from tap water, and the electrolyzed water generating apparatus are connected to the electrolyzed water generating apparatus. An alkaline electrolyzed water main tank that stores the alkaline electrolyzed water supplied from the generator, and an acidic electrolyzed water main tank that is connected to the electrolyzed water generator and stores the acidic electrolyzed water supplied from the electrolyzed water generator A nanobubble generator connected to the alkaline electrolyzed water main tank, generating nanobubbles in the alkaline electrolyzed water stored in the alkaline electrolyzed water main tank, and returning the alkaline electrolyzed water containing nanobubbles to the alkaline electrolyzed water main tank; Connected to the alkaline electrolyzed water main tank and the alkaline electrolyzed water main The alkaline electrolyzed water subtank, which is disposed at a position lower than the tank and stores the alkaline electrolyzed water supplied from the alkaline electrolyzed water main tank with a smaller capacity than the alkaline electrolyzed water main tank, and the acidic electrolyzed water main tank The acidic electrolyzed water that is disposed at a position lower than the acidic electrolyzed water main tank and stores the acidic electrolyzed water supplied from the acidic electrolyzed water main tank with a smaller capacity than the acidic electrolyzed water main tank It has a sub tank.

  According to a fourth aspect of the present invention, an alkaline electrolyzed water main discharge valve for discharging the alkaline electrolyzed water to the outside is connected to the alkaline electrolyzed water main tank, and the acidic electrolyzed water main tank includes the acidic electrolyzed water. An acidic electrolyzed water main discharge valve for discharging the alkaline electrolyzed water to the outside is connected, and the alkaline electrolyzed water sub-tank has a smaller discharge flow rate than the alkaline electrolyzed water main discharge valve, and discharges the alkaline electrolyzed water to the outside. An alkaline electrolyzed water sub-discharge valve is connected to the acidic electrolyzed water sub-tank. The acidic electrolyzed water sub-tank has a smaller dischargeable flow rate than the acidic electrolyzed water main discharge valve, and the acidic electrolyzed water sub-drain discharges the acidic electrolyzed water to the outside. The valve is connected and provided.

  In the invention of claim 5, when the alkaline electrolyzed water main discharge valve is opened, the alkaline electrolyzed water main tank discharges the alkaline electrolyzed water to the outside based on free fall, and the acidic electrolyzed water main discharge valve When the valve is opened, the acidic electrolyzed water main tank discharges the acidic electrolyzed water to the outside based on free fall.

  According to invention of Claim 1, the growth of a plant can be accelerated | stimulated by supplying the alkaline electrolyzed water containing nanobubble to a plant.

  According to invention of Claim 2, since alkaline electrolyzed water contains potassium, potassium can be utilized as a plant fertilizer and can further promote the growth of a plant.

  According to the invention of claim 3, since the nanobubble generator is connected to the alkaline electrolyzed water main tank, the alkaline electrolyzed water containing nanobubbles can be returned to the alkaline electrolyzed main tank and stored by the nanobubble generator. For this reason, compared with the case where a nanobubble generator is connected to an alkaline electrolyzed water subtank, more alkaline electrolyzed water containing nanobubbles can be stored.

  Moreover, the alkaline electrolyzed water main tank and the acidic electrolyzed water main tank are disposed at a position higher than the alkaline electrolyzed water subtank and the acidic electrolyzed water subtank. For this reason, from the alkaline electrolyzed water main tank, alkaline electrolyzed water containing nanobubbles can be supplied to water supply devices such as water spray tank trucks, sprayer cars, etc. by free-fall, eliminating the need for power associated with the supply of electrolyzed water. In addition, the time delay associated with driving the power source can be eliminated. Similarly, water can be quickly supplied from the acidic electrolyzed water main tank.

  On the other hand, the alkaline electrolyzed water subtank and the acidic electrolyzed water subtank are disposed at a position lower than the alkaline electrolyzed water main tank and the acidic electrolyzed water main tank. For this reason, when using a small amount of electrolyzed water, for example, alkaline electrolyzed water or acidic electrolyzed water can be supplied from these sub tanks.

  According to the invention of claim 4, the alkaline electrolyzed water sub-discharge valve has a flow rate that can be discharged smaller than the alkaline electrolyzed water main discharge valve. For this reason, when a large amount of alkaline electrolyzed water is used, the alkaline electrolyzed water can be taken out from the alkaline electrolyzed water main tank by opening the alkaline electrolyzed water main discharge valve, and when a small amount of alkaline electrolyzed water is used. The alkaline electrolyzed water can be taken out from the alkaline electrolyzed water subtank by opening the alkaline electrolyzed water sub-discharge valve.

  Similarly, since the acidic electrolyzed water sub-discharge valve has a smaller dischargeable flow rate than the acidic electrolyzed water main discharge valve, a large amount of acidic electrolyzed water main tank is opened by opening the acidic electrolyzed water main discharge valve. Electrolyzed water can be taken out, and a small amount of acidic electrolyzed water can be taken out from the acidic electrolyzed water sub-tank by opening the acidic electrolyzed water sub-discharge valve.

  According to the invention of claim 5, when the alkaline electrolyzed water main discharge valve is opened, the alkaline electrolyzed water sub-tank discharges the alkaline electrolyzed water to the outside based on free fall. That is, since the alkaline electrolyzed water main tank is arranged at a higher position than the alkaline electrolyzed water sub-tank, the alkaline electrolyzed water in the alkaline electrolyzed water main tank can be discharged using the head, and the electrolyzed water can be discharged. A large amount of alkaline electrolyzed water can be easily taken out without providing power associated with the discharge. Similarly, when the acidic electrolyzed water main discharge valve is opened, the acidic electrolyzed water main tank can easily discharge a large amount of acidic electrolyzed water to the outside based on free fall.

It is a whole block diagram which shows the manufacturing apparatus of the alkaline electrolyzed water containing the nano bubble by embodiment of this invention. It is a circuit diagram which shows the manufacturing apparatus of alkaline electrolyzed water containing the nano bubble in FIG. It is explanatory drawing which shows the glass container etc. which were used for the growth experiment of silkworm radish.

  Hereinafter, an apparatus for producing alkaline electrolyzed water containing nanobubbles according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

  In FIG. 1 and FIG. 2, reference numeral 1 denotes an electrolyzed water generator, and this electrolyzed water generator 1 includes a water softener 2 and an electrolyzer 3. A water pipe 4 provided with a supply valve 4A is connected to the water softener 2, and tap water is supplied by opening the supply valve 4A. The water softener 2 softens the tap water supplied from the water pipe 4 and supplies it to the electrolysis apparatus 3.

  The electrolyzer 3 is configured by using a diaphragm / three-chamber electrolytic cell that performs electrolysis without mixing an additive as an electrolyte and raw water, for example, and electrolyzes the soft water supplied from the water softener 2 to perform alkaline electrolysis. Generate water and acidic electrolyzed water. Here, for example, potassium chloride is used as the additive. For this reason, potassium used as a fertilizer is mixed in alkaline electrolyzed water. The electrolysis apparatus 3 includes, for example, two discharge pumps (not shown). One discharge pump discharges alkaline electrolyzed water toward the alkaline electrolyzed water main tank 6 and the other discharge pump uses acidic electrolyzed water. Acidic electrolyzed water is discharged toward the main tank 10.

  Moreover, the electrolyzed water generating apparatus 1 is accommodated in a box-shaped casing 5 together with an alkaline electrolyzed water subtank 24, an acidic electrolyzed water subtank 30, and the like which will be described later. At this time, the electrolyzed water generating apparatus 1 is disposed above the sub tanks 24 and 30.

  The electrolyzer 3 is not necessarily configured using a three-chamber electrolytic cell, and may be configured using a two-chamber electrolytic cell, for example. The electrolyte is not limited to potassium chloride, and may be sodium chloride, magnesium chloride, calcium chloride, or the like.

  Reference numeral 6 denotes an alkaline electrolyzed water main tank connected to the outflow side of the electrolyzer 3 by a water supply line 7 made of, for example, a resin pipe. The alkaline electrolyzed water main tank 6 has a large capacity of several hundred liters (for example, 600 liters). And is made of a resin material having resistance to alkaline electrolyzed water.

  Here, the alkaline electrolyzed water main tank 6 is mounted on a tank mounting table 8 made of a frame structure having a predetermined strength such as a metal material. For this reason, the alkaline electrolyzed water main tank 6 is disposed at a position having a height dimension H of about several meters (for example, 2 m to 5 m) with respect to the ground. Thereby, the alkaline electrolyzed water main tank 6 is arrange | positioned in the position higher than the water supply opening | mouth of water supply object, such as a water tank car, a sprayer car, etc., for example.

  The alkaline electrolyzed water main tank 6 is provided with an outside air inlet 6A for taking in outside air, and an overflow outlet 6B for discharging surplus electrolyzed water when the main tank 6 becomes full. Further, the alkaline electrolyzed water main tank 6 is provided with a high liquid level sensor 9 for detecting the height position of the liquid level, and the high liquid level sensor 9 is connected to the electrolyzed water generating apparatus 1. When the amount of alkaline electrolyzed water stored in the main tank 6 is reduced to a predetermined amount (for example, 600 liters, which is the full water amount of the main tank 6), the level of the alkaline electrolyzed water according to the predetermined amount is reduced. Lower than a predetermined height position. For this reason, when the liquid level height position of the alkaline electrolyzed water detected by the high liquid level sensor 9 is lower than the predetermined height position, the electrolyzed water generating device 1 starts generating electrolyzed water, The alkaline electrolyzed water main tank 6 is replenished.

  The alkaline electrolyzed water main tank 6 is provided with a discharge port 6C for discharging alkaline electrolyzed water located on the lower side, and alkaline electrolyzed water containing nanobubbles discharged from a nanobubble generator 13 described later. Is provided with an inflow port 6D.

  Reference numeral 10 denotes an acidic electrolyzed water main tank connected to the outflow side of the electrolyzer 3 by a water supply line 11 made of, for example, a resin pipe. The acidic electrolyzed water main tank 10 is substantially the same as the alkaline electrolyzed water main tank 6, It is formed of a resin material having a large capacity of about 100 liters (for example, 600 liters) and having resistance to acidic electrolyzed water.

  The acidic electrolyzed water main tank 10 is arranged at a position adjacent to the alkaline electrolyzed water main tank 6 and is placed on the tank mounting table 8. For this reason, the acidic electrolyzed water main tank 10 is also disposed at a position higher than a water supply target water supply port such as a water spray tank car or a sprayer car.

  The acidic electrolyzed water main tank 10 is also provided with an outside air inlet 10A, an overflow outlet 10B, an outlet 10C and an inflow port 10D, and a high liquid level sensor 12 as in the alkaline electrolyzed water main tank 6. It has been. And when the liquid level height position of the acidic electrolyzed water detected by the high liquid level sensor 12 falls below the predetermined height position, the electrolyzed water generating device 1 starts generating electrolyzed water and makes the acidic electrolyzed water acidic. The electrolytic water main tank 10 is replenished.

  The predetermined height position detected by the high liquid level sensor 12 may be the same position as the predetermined height position detected by the high liquid level sensor 9 or may be a different position. These predetermined height positions are appropriately set in consideration of the amount of alkaline electrolyzed water and acidic electrolyzed water used.

  Further, the electrolyzed water is not always insufficient in both the main tanks 6 and 10, and there is a case where only one of the electrolyzed water is insufficient. Even in this case, when the shortage of electrolyzed water is detected by the high liquid level sensors 9 and 12, the electrolyzed water generating apparatus 1 discharges both alkaline electrolyzed water and acidic electrolyzed water. For this reason, the one of the main tanks 6 and 10 that has been filled up first discharges excess electrolyzed water from the overflow outlets 6B and 10B.

  Moreover, the capacity | capacitance and the height dimension H of the main tanks 6 and 10 are set suitably according to water supply object etc. not only in the illustrated value.

  Reference numeral 13 denotes a nanobubble generator that generates nanobubbles having a diameter of, for example, 1 μm or less (for example, about several tens of nanometers to several hundreds of nanometers) in the electrolyzed water and returns the electrolyzed water containing nanobubbles to one of the main tanks 6 and 10. . The nanobubble generator 13 includes a nanobubble generating pump 14 that generates nanobubbles in the electrolyzed water and discharges electrolyzed water containing nanobubbles, an inflow side pressure sensor 15 that measures the pressure on the inflow side of the nanobubble generating pump 14, and nanobubble generation. An inflow side pressure sensor 16 that measures the pressure on the outflow side of the pump 14 is provided. Further, the nanobubble generator 13 is placed on a pump mounting table 17 that is located below the main tanks 6 and 10 and is lower than the tank mounting table 8.

  Further, the nanobubble generation pump 14 includes an inflow valve 14A and an outflow valve 14B, and by opening them, nanobubbles are generated in the electrolytic water flowing in from the inflow valve 14A and flow out from the outflow valve 14B. At this time, the nanobubble generation pump 14 discharges the electrolyzed water at a predetermined discharge pressure, and returns the electrolyzed water containing nanobubbles into the main tanks 6 and 10.

  Here, the discharge port 6C of the alkaline electrolyzed water main tank 6 is connected to the inflow valve 14A through the alkaline electrolyzed water supply line 18, and the discharge port 10C of the acidic electrolyzed water main tank 10 is connected through the acidic electrolyzed water supply line 19. It is connected. At this time, an alkaline selection valve 18 </ b> A is provided in the middle of the alkaline electrolyzed water supply line 18, and an acidic selection valve 19 </ b> A is provided in the middle of the acidic electrolyzed water supply line 19.

  On the other hand, the outflow valve 14B is connected to the inlet 6D of the alkaline electrolyzed water main tank 6 through the alkaline electrolyzed water circulation line 20 and to the inlet 10D of the acidic electrolyzed water main tank 10 through the acidic electrolyzed water circulation line 21. Yes. At this time, an alkaline selection valve 20 </ b> A is provided in the middle of the alkaline electrolyzed water circulation line 20, and an acidic selection valve 21 </ b> A is provided in the middle of the acidic electrolyzed water circulation line 21.

  For this reason, when nano bubbles are generated in the alkaline electrolyzed water, the alkaline selection valves 18A and 20A are opened, and the acidic selection valves 19A and 21A are closed. In this state, the inflow valve 14A and the outflow valve 14B are opened. Thereby, since the alkaline electrolyzed water in the alkaline electrolyzed water main tank 6 is supplied to the nanobubble generating pump 14, the nanobubble generating pump 14 discharges alkaline electrolyzed water containing nanobubbles and returns it to the alkaline electrolyzed water main tank 6. . For example, when the discharge flow rate of the nanobubble generation pump 14 is set to about several tens of liters / minute (for example, 20 liters / minute), the circulation operation is performed over, for example, several tens of minutes to several hours, thereby The content of nanobubbles can be increased.

  When nano bubbles are generated in the acidic electrolyzed water, the acidic selection valves 19A and 21A are opened, and the alkaline selection valves 18A and 20A are closed. In this state, the inflow valve 14A and the outflow valve 14B are opened. Thereby, since the acidic electrolyzed water in the acidic electrolyzed water main tank 10 is supplied to the nanobubble generating pump 14, the nanobubble generating pump 14 discharges the acidic electrolyzed water containing nanobubbles and returns it to the acidic electrolyzed water main tank 10. .

  Thus, the nanobubble generator 13 is configured such that the alkaline electrolyzed water main tank 6 and the acidic electrolyzed water main tank 10 are connected in parallel, and either one can be selected and connected. For this reason, a single nanobubble generator 13 can generate nanobubbles in both alkaline electrolyzed water and acidic electrolyzed water.

  Reference numeral 22 denotes an alkaline electrolyzed water main discharge line connected to the discharge port 6C of the alkaline electrolyzed water main tank 6, and an alkaline electrolyzed water for discharging the alkaline electrolyzed water to the outside in the middle of the alkaline electrolyzed water main discharge line 22. A main discharge valve 22A is provided. For this reason, by opening the alkaline electrolyzed water main discharge valve 22A, from the alkaline electrolyzed water discharge port 22B made of a flexible hose or the like provided at the tip of the alkaline electrolyzed water main discharge line 22, for example, a water tank truck, Alkaline electrolyzed water containing nanobubbles can be supplied toward a water supply port of a sprayer vehicle or the like. Here, the maximum discharge flow rate of the alkaline electrolyzed water main discharge valve 22A is set to a value of, for example, about 200 liters / minute so that a large amount of alkaline electrolyzed water can flow out in a short time.

  Reference numeral 23 denotes an acidic electrolyzed water main discharge line connected to the discharge port 10 </ b> C of the acidic electrolyzed water main tank 10, and the acidic electrolyzed water main discharge line 23 is configured in substantially the same manner as the alkaline electrolyzed water main discharge line 22. For this reason, in the middle of the acidic electrolyzed water main discharge line 23, an acidic electrolyzed water main discharge valve 23A for discharging acidic electrolyzed water to the outside is provided, and at the tip of the acidic electrolyzed water main discharge line 23 is flexible. An acidic electrolyzed water discharge port 23B made of a conductive hose or the like is provided. Further, the maximum discharge flow rate of the acidic electrolyzed water main discharge valve 23A is set to a value almost the same as that of the alkaline electrolyzed water main discharge valve 22A.

  Note that the maximum discharge flow rate of the acidic electrolyzed water main discharge valve 23A does not necessarily need to match the maximum discharge flow rate of the alkaline electrolyzed water main discharge valve 22A, and may be a different value. Further, the maximum discharge flow rate of the main discharge valves 22A and 23A is not limited to the exemplified values, and is appropriately set according to the required specifications.

  Reference numeral 24 denotes an alkaline electrolyzed water subtank connected to the discharge port 6C of the alkaline electrolyzed water main tank 6 by a water supply line 25 made of, for example, a resin pipe. The alkaline electrolyzed water subtank 24 has a smaller capacity than the alkaline electrolyzed water main tank 6. For example, it is formed of a resin material having a capacity of half or less of the alkaline electrolyzed water main tank 6 and having resistance to alkaline electrolyzed water. For this reason, the capacity | capacitance of the alkaline electrolyzed water subtank 24 is set to the value of about several tens to several hundred liters (for example, 100 liters), for example.

  The alkaline electrolyzed water sub-tank 24 is positioned below the electrolyzed water generating device 1 and mounted in the casing 5, and is disposed at a position lower than the alkaline electrolyzed water main tank 6, for example, near the ground. For this reason, when the alkaline electrolyzed water sub-tank 24 is not full, the alkaline electrolyzed water is replenished from the alkaline electrolyzed water main tank 6 toward the alkaline electrolyzed water sub-tank 24.

  Accordingly, when both the alkaline electrolyzed water main tank 6 and the alkaline electrolyzed water subtank 24 are not full, the alkaline electrolyzed water subtank 24 is first filled with alkaline electrolyzed water, and then the alkaline electrolyzed water main tank 6 is filled with alkaline electrolyzed water. Is filled. For this reason, the alkaline electrolyzed water filled in the alkaline electrolyzed water sub-tank 24 does not necessarily contain nanobubbles.

  The alkaline electrolyzed water subtank 24 is provided with a ball tap 26 serving as a constant water level valve for keeping the internal water level constant (full water state). For this reason, when the alkaline electrolyzed water sub-tank 24 becomes non-full, the ball tap 26 opens, and the alkaline electrolyzed water sub-tank 24 is filled with alkaline electrolyzed water from the alkaline electrolyzed water main tank 6. On the other hand, when the alkaline electrolyzed water sub-tank 24 is full, the ball tap 26 is closed so that no more alkaline electrolyzed water is filled in the alkaline electrolyzed water sub-tank 24. Further, the alkaline electrolyzed water sub-tank 24 is provided with a low liquid level sensor 27 for detecting whether or not the liquid level has reached the lowest position where water can be supplied to the outside. A discharge port 24A is provided on the lower side.

  Reference numeral 28 denotes an alkaline electrolyzed water sub-discharge line connected to the discharge port 24A of the alkaline electrolyzed water sub-tank 24. An alkaline electrolyzed water sub for discharging the alkaline electrolyzed water to the outside is provided in the middle of the alkaline electrolyzed water sub-discharge line 28. A discharge pump 29 is provided on the upstream side (sub tank 24 side) of the discharge valve 28A and the alkaline electrolyzed water sub-discharge valve 28A.

  Therefore, by opening the alkaline electrolyzed water sub-discharge valve 28A, the alkaline electrolyzed water discharge port 28B provided at the tip of the alkaline electrolyzed water sub-discharge line 28 is directed toward a small-capacity container such as a portable resin tank. Alkaline electrolyzed water can be dispensed. Here, the discharge flow rate of the discharge pump 29 and the maximum discharge flow rate of the alkaline electrolyzed water sub-discharge valve 28A are smaller than the maximum discharge flow rate of the alkaline electrolyzed water main discharge valve 22A (for example, about 20 liters / minute). Is set.

  Further, a detection signal from the low liquid level sensor 27 is input to the dispensing pump 29. For this reason, the discharge pump 29 automatically stops discharging the alkaline electrolyzed water when the liquid level in the alkaline electrolyzed water sub-tank 24 decreases and reaches the lowest position.

  Reference numeral 30 denotes an acidic electrolyzed water subtank connected to the discharge port 10C of the acidic electrolyzed water main tank 10 by a water supply line 31 made of, for example, a resin pipe. The acidic electrolyzed water subtank 30 has a smaller capacity than the acidic electrolyzed water main tank 10. And is formed of a resin material having resistance to acidic electrolyzed water.

  The acidic electrolyzed water sub-tank 30 is adjacent to the alkaline electrolyzed water sub-tank 24 on the lower side of the electrolyzed water generating device 1, is mounted in the casing 5, and is disposed at a position lower than the acidic electrolyzed water main tank 10. For this reason, when the acidic electrolyzed water subtank 30 is not full, the acidic electrolyzed water is replenished from the acidic electrolyzed water main tank 10 toward the acidic electrolyzed water subtank 30.

  The acidic electrolyzed water subtank 30 is also provided with a ball tap 32 and a low liquid level sensor 33, similarly to the alkaline electrolyzed water subtank 24. Further, a discharge port 30 </ b> A is provided on the lower side of the acidic electrolyzed water sub-tank 30.

  34 is an acidic electrolyzed water sub-discharge line connected to the discharge port 30A of the acidic electrolyzed water sub-tank 30, and an acidic electrolyzed water sub for discharging the acidic electrolyzed water to the outside in the middle of the acidic electrolyzed water sub-discharge line 34. A discharge pump 35 is provided on the upstream side (sub tank 30 side) of the discharge valve 34A and the acidic electrolyzed water sub-discharge valve 34A.

  Therefore, by opening the acidic electrolyzed water sub-discharge valve 34A, the acidic electrolyzed water is discharged from the acidic electrolyzed water discharge port 34B provided at the tip of the acidic electrolyzed water sub-discharge line 34 toward the small capacity container. be able to. Here, the discharge flow rate of the discharge pump 35 and the maximum discharge flow rate of the acidic electrolyzed water sub-discharge valve 34A are smaller than the maximum discharge flow rate of the acidic electrolyzed water main discharge valve 23A (for example, about 20 liters / minute). Is set.

  Further, a detection signal from the low liquid level sensor 33 is input to the dispensing pump 35. For this reason, the discharge pump 35 automatically stops discharging the acidic electrolyzed water when the liquid level in the acidic electrolyzed water sub-tank 30 decreases and reaches the lowest position.

  Note that the discharge flow rates of the discharge pumps 29 and 35 and the maximum discharge flow rates of the sub discharge valves 28A and 34A are not limited to the exemplified values, and are appropriately set according to the required specifications.

  The apparatus for producing alkaline electrolyzed water according to the present embodiment is configured as described above, and the operation thereof will be described next.

  First, when the apparatus for producing alkaline electrolyzed water is activated, the electrolyzed water generator 1 discharges alkaline electrolyzed water and acidic electrolyzed water, fills the alkaline electrolyzed water main tank 6 and the alkaline electrolyzed water subtank 24 with alkaline electrolyzed water, The acidic electrolyzed water main tank 10 and the acidic electrolyzed water subtank 30 are filled with acidic electrolyzed water. At this time, the alkaline electrolyzed water has a value of about 10 to 13, for example, and the acidic electrolyzed water has a value of about 1 to 3, for example. Then, the sub tanks 24 and 30 are filled with water, and the main tanks 6 and 10 are filled with electrolyzed water to a desired water level (for example, full water), and then the electrolyzed water generator 1 is stopped.

  Next, with the acidic selection valves 19A and 21A closed, the alkaline selection valves 18A and 20A are opened, the inflow valve 14A and the outflow valve 14B are opened, and the nanobubble generator 13 is driven. Thereby, alkaline electrolyzed water circulates between the alkaline electrolyzed water main tank 6 and the nanobubble generator 13, and the content of nanobubbles in the alkaline electrolyzed water increases. When the nanobubble generator 13 is driven for a predetermined time, the nanobubble generator 13 is stopped by a timer (not shown) or the like. At this time, the predetermined time is set based on the amount of saturated dissolved oxygen in the alkaline electrolyzed water. For this reason, the amount of saturated dissolved oxygen in alkaline electrolyzed water becomes larger than a desired value (for example, 10 mg-O / L at 27 ° C.). When the nanobubble generator 13 stops, the alkaline selection valves 18A and 20A, the inflow valve 14A, and the outflow valve 14B are all closed.

  And when using alkaline electrolyzed water containing nanobubbles, the alkaline electrolyzed water main discharge valve 22A is opened. Thereby, the alkaline electrolyzed water containing nanobubbles is discharged from the alkaline electrolyzed water discharge port 22B toward the water supply port of the water tank truck or the like. For this reason, an operator conveys alkaline electrolyzed water containing nanobubbles using a tank tank for watering, and waters the plant for the purpose of growth.

  In addition, nanobubble can also be contained in the acidic electrolyzed water in the acidic electrolyzed water main tank 10 by opening the acidic select valves 19A and 21A with the alkaline select valves 18A and 20A closed. For this reason, after adding nanobubble to acidic electrolyzed water and improving effects, such as washing | cleaning and sterilization of acidic electrolyzed water, it can also water on a plant.

  Further, when a small amount of electrolyzed water is used, alkaline electrolyzed water or acidic electrolyzed water filled in the sub tanks 24 and 30 can be used. In this case, by opening the alkaline electrolyzed water sub-discharge valve 28A and driving the discharge pump 29, the alkaline electrolyzed water in the alkaline electrolyzed water sub-tank 24 is directed from the alkaline electrolyzed water discharge port 28B toward the small capacity container. Can be paid out. Similarly, by opening the acidic electrolyzed water sub-discharge valve 34A and driving the discharge pump 35, the acidic electrolyzed water in the acidic electrolyzed water sub-tank 30 is directed from the acidic electrolyzed water discharge port 34B toward the small-capacity container. Can be paid out. An operator can carry the electrolyzed water filled in the container to a place where cleaning, cleaning, sterilization, or the like is necessary, and perform various operations such as cleaning using the electrolyzed water.

  Next, the effect when plants are grown using alkaline electrolyzed water containing nanobubbles will be described.

  In addition to the alkaline electrolyzed water containing nanobubbles generated by the above-described manufacturing apparatus, alkaline electrolyzed water not containing nanobubbles, acidic electrolyzed water containing nanobubbles, acidic electrolyzed water not containing nanobubbles, and a total of 5 types of water for 9 days The growth state was observed. Here, the water, alkaline electrolyzed water, acidic electrolyzed water pH, and saturated dissolved oxygen concentration used for the growth of silkworm radish are as shown in Table 1 below.

  The growth experiment of silkworm radish was performed using the glass container G shown in FIG. Specifically, a box-shaped glass container G having an open top was prepared, and a sponge-like water-absorbing sheet S was laid on the bottom surface of the glass container G, and then seeds T of several tens of silk radish seeds were sown. In this state, water, alkaline electrolyzed water, acidic electrolyzed water, etc. were given every morning around 8: 30-9: 30, and the growth situation was observed. The results at this time are shown in Table 2 below. In addition, the growth degree in Table 2 shows the length dimension from the root (bottom surface of the container) to the tip of the golden radish from the sowing to the ninth day.

  When the growth situation was observed, there was a slight difference in the degree of growth from about the third day after the start of growth, and there was a variation for each seed T, but the growth degree of the one given with alkaline electrolyzed water containing nanobubbles was It was better than the ones. Even in the observation state on the seventh day, the growth of the alkaline electrolyzed water containing nanobubbles was the best and the stem was solid, so it grew straight without breaking in the middle.

  As shown in the results of Table 2, it was found that plant growth can be promoted by supplying alkaline electrolyzed water containing nanobubbles to the plant. The reason for this is that the alkaline electrolyzed water containing nanobubbles increases the amount of saturated dissolved oxygen compared to the alkaline electrolyzed water that does not contain nanobubbles. Conceivable. In addition, since the amount of dissolved oxygen in the soil also increases, it is thought to be useful for preventing root decay due to lack of oxygen. As a result, healthy and healthy plants are cultivated, are less likely to become ill, and no pesticides or reduced pesticides are possible, which can contribute to the reduction of the environmental burden. Moreover, since the alkaline electrolyzed water used for the above-mentioned cultivation contains potassium, potassium can be used as a plant fertilizer. For this reason, it is considered that the growth of plants can be further promoted.

  Acidic electrolyzed water has the characteristics of high sterilization and bactericidal effects, and high deodorizing and bleaching effects. The acidic electrolyzed water containing nanobubbles can be expected to improve sterilization and bactericidal effects. For this reason, for example, in plants that are easily infected with bacteria, in addition to alkaline electrolyzed water containing nanobubbles, acidic electrolyzed water containing nanobubbles may be used in combination, or acidic electrolyzed water not containing nanobubbles may be used in combination. Even when acidic electrolyzed water is used, as with alkaline electrolyzed water, no pesticides or pesticides can be reduced, which can contribute to the reduction of environmental burden. The watering method is appropriately selected from existing watering methods such as spraying and hose spraying according to the situation.

  Thus, in this embodiment, since the nanobubble generator 13 is connected to the alkaline electrolyzed water main tank 6, the alkaline electrolyzed water containing nanobubbles is returned to the alkaline electrolyzed water main tank 6 and stored by the nanobubble generator 13. Can do. For this reason, compared with the case where the nanobubble generator 13 is connected to the small-capacity alkaline electrolyzed water sub-tank 24, more alkaline electrolyzed water containing nanobubbles can be stored.

  Moreover, the alkaline electrolyzed water main tank 6 and the acidic electrolyzed water main tank 10 were disposed at a position higher than the alkaline electrolyzed water subtank 24 and the acidic electrolyzed water subtank 30. That is, since the alkaline electrolyzed water main tank 6 is arranged at a higher position than the alkaline electrolyzed water sub-tank 24, the alkaline electrolyzed water in the alkaline electrolyzed water main tank 6 can be discharged using the head. For this reason, alkaline electrolyzed water containing nanobubbles can be supplied to a water supply device such as a water spray tank car, sprayer car, etc. by free fall, and the power associated with the supply of electrolyzed water can be made unnecessary, and the power source can be driven. The time delay involved can be eliminated. Similarly, water can be quickly supplied from the acidic electrolyzed water main tank 10.

  On the other hand, the alkaline electrolyzed water subtank 24 and the acidic electrolyzed water subtank 30 were arranged at a position lower than the alkaline electrolyzed water main tank 6 and the acidic electrolyzed water main tank 10. For this reason, when using a small amount of electrolyzed water, for example, alkaline electrolyzed water or acidic electrolyzed water can be supplied from these sub tanks 24 and 30.

  Further, the alkaline electrolyzed water sub-discharge valve 28A has a smaller flow rate that can be discharged than the alkaline electrolyzed water main discharge valve 22A. For this reason, when a large amount of alkaline electrolyzed water is used, the alkaline electrolyzed water can be taken out from the alkaline electrolyzed water main tank 6 by opening the alkaline electrolyzed water main discharge valve 22A, and a small amount of alkaline electrolyzed water is used. In doing so, the alkaline electrolyzed water can be taken out of the alkaline electrolyzed water subtank 24 by opening the alkaline electrolyzed water sub-discharge valve 28A.

  Similarly, since the acidic electrolyzed water sub-discharge valve 34A has a smaller flow rate that can be discharged than the acidic electrolyzed water main discharge valve 23A, the acidic electrolyzed water main tank 10 is opened by opening the acidic electrolyzed water main discharge valve 23A. A large amount of acidic electrolyzed water can be extracted from the acidic electrolyzed water sub-discharge valve 34A, and a small amount of acidic electrolyzed water can be extracted from the acidic electrolyzed water subtank 30.

  In the above-described embodiment, the growth promotion effect has been described by taking an example of a fast-growing radish as a plant. However, the present invention is not limited to this and is applied to any plant that can be grown by hydration. be able to.

  Moreover, in the said embodiment, pH of alkaline electrolysis water and saturation dissolved oxygen concentration showed an example, and this invention is not limited to this. For example, the pH of the alkaline electrolyzed water may be 10 to 13, and the saturated dissolved oxygen concentration is a value of about 120% to 160% of this reference value, based on the saturated dissolved oxygen concentration of normal water not containing nanobubbles. But you can.

DESCRIPTION OF SYMBOLS 1 Electrolyzed water production | generation apparatus 6 Alkaline electrolyzed water main tank 10 Acidic electrolyzed water main tank 13 Nano bubble generator 18 Alkaline electrolyzed water supply line 18A Alkaline selection valve 19 Acidic electrolyzed water supply line 19A Acidic selection valve 20 Alkaline electrolyzed water circulation line 20A Alkaline selection valve 21 Acidic electrolyzed water circulation line 21A Acidic selection valve 22 Alkaline electrolyzed water main discharge line 22A Alkaline electrolyzed water main discharge valve 22B Alkaline electrolyzed water discharge port 23 Acidic electrolyzed water main discharge line 23A Acidic electrolyzed water main discharge valve 23B Acidic electrolyzed water discharge port 24 Alkaline electrolyzed water sub-tank 28 Alkaline electrolyzed water sub-discharge line 28A Alkaline electrolyzed water sub-discharge valve 28B Alkaline electrolyzed water outlet 30 Acidic electrolyzed water sub-tank 34 Acidic electrolyzed water sub-discharger Down 34A acidic electrolyzed water sub-discharge valve 34B acidic electrolyzed water payout opening

Claims (5)

  The alkaline electrolyzed water containing nanobubbles having a saturated dissolved oxygen amount of more than 10 mg-O / L at 27 ° C. and a pH of 10 to 13 containing nanobubbles was given to the plant, and the alkaline electrolyzed water containing nanobubbles for growing the plant was used. Plant growth method.   The method for growing plants using alkaline electrolyzed water containing nanobubbles according to claim 1, wherein the alkaline electrolyzed water comprises potassium. An electrolyzed water generator for generating alkaline electrolyzed water and acidic electrolyzed water from tap water;
An alkaline electrolyzed water main tank that is connected to the electrolyzed water generator and stores the alkaline electrolyzed water supplied from the electrolyzed water generator;
An acidic electrolyzed water main tank that is connected to the electrolyzed water generator and stores the acidic electrolyzed water supplied from the electrolyzed water generator;
A nanobubble generator connected to the alkaline electrolyzed water main tank, generating nanobubbles in the alkaline electrolyzed water stored in the alkaline electrolyzed water main tank, and returning alkaline electrolyzed water containing nanobubbles to the alkaline electrolyzed water main tank;
The alkaline electrolyzed water that is connected to the alkaline electrolyzed water main tank, disposed at a position lower than the alkaline electrolyzed water main tank, and supplied from the alkaline electrolyzed water main tank with a smaller capacity than the alkaline electrolyzed water main tank. The alkaline electrolyzed water sub-tank to be stored;
The acidic electrolyzed water connected to the acidic electrolyzed water main tank, disposed at a position lower than the acidic electrolyzed water main tank, and supplied from the acidic electrolyzed water main tank with a smaller capacity than the acidic electrolyzed water main tank An apparatus for producing alkaline electrolyzed water containing nanobubbles comprising the acidic electrolyzed water subtank to be stored. The alkaline electrolyzed water main tank is connected to an alkaline electrolyzed water main discharge valve for discharging the alkaline electrolyzed water to the outside,
The acidic electrolyzed water main tank is connected to an acidic electrolyzed water main discharge valve for discharging the acidic electrolyzed water to the outside,
The alkaline electrolyzed water sub-tank is connected to an alkaline electrolyzed water sub-discharge valve that discharges the alkaline electrolyzed water to the outside with a smaller flow rate that can be discharged than the alkaline electrolyzed water main discharge valve,
The acidic electrolyzed water sub-tank is configured to be connected to an acidic electrolyzed water sub-discharge valve that discharges the acidic electrolyzed water to the outside with a smaller flow rate that can be discharged than the acidic electrolyzed water main discharge valve. An apparatus for producing alkaline electrolyzed water containing the nanobubbles described in 1. When the alkaline electrolyzed water main discharge valve is opened, the alkaline electrolyzed water main tank discharges the alkaline electrolyzed water to the outside based on free fall,
The alkaline electrolyzed water containing nanobubbles according to claim 4, wherein when the acidic electrolyzed water main discharge valve is opened, the acidic electrolyzed water main tank discharges the acidic electrolyzed water to the outside based on free fall. manufacturing device.

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