JP2016042798A - Sprouts cultivation method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a sprouts cultivation method that can shorten a cultivation period and extend an expiration date.SOLUTION: The present invention relates to a sprouts cultivation method that uses ozone nanobubble water and ethylene nanobubble water in combination, and a sprouts cultivation system comprising an ozone nanobubble water supply device and an ethylene nanobubble water supply device.SELECTED DRAWING: None

Description

  The present invention relates to a method for cultivating sprout.

  Sprout is a collective term for plant shoots, but is known to be a nutrient-rich food containing a variety of vitamins and other nutrients that did not exist in the dry seed state.

  In the conventional sprout cultivation method, sodium hypochlorite or chlorine dioxide has been used to sterilize general viable bacteria and molds adhering at the time of seed harvesting when the sprout is immersed. However, there were consumer opposition to organic farming and safety issues for long-term use.

  Ethylene is a natural plant hormone, has a sprout maturation promoting action (makes the sprout thicker), and is used for cultivation of sprout. Ethylene was sprayed directly onto the sprout as ethylene gas. Since ethylene is a gas, it is difficult to control, and if the amount is small, sprout maturation is poor. Moreover, since ethylene gas is flammable, there was also a safety problem.

  Furthermore, since the number of general bacteria does not decrease even when washed with water alone at the time of shipment of sprout, it is generally washed and sterilized using sodium hypochlorite or acetic acid, but there is a problem of residual odor. Therefore, in this method, it was necessary to remove chlorine by washing with water at the end. Disinfection and washing at the time of shipping brings about a decrease in shelf life even when performed at low temperatures, and since water is attached at the time of washing, there is also a problem of allowing general viable bacteria and mold to grow, causing the progression of decay and generating a strange odor there were.

  Devices that generate small bubbles (bubbles) in water have been researched and developed. Generally, small bubbles with a diameter of 10 micrometers to several tens of micrometers are microbubbles, and small bubbles with a diameter of several hundred nanometers to less than 10 micrometers. Are called micro-nano bubbles and small bubbles of less than a few hundred nanometers are called nano-bubbles.

  The water containing nanobubbles is called nanobubble water, and is sterilized (Patent Documents 1 to 3), water purification (Patent Documents 4 to 7), and biological activation (Patent Documents 8 to 10 and Non-Patent Document 1). It is reported that there are effects such as.

  However, none of the cited documents describes any sprouts cultivation method using ozone nanobubble water and ethylene nanobubble water in combination.

Japanese Patent Application Laid-Open No. 2011-120995 JP 2010-207778 JP2009-29283A JP 2010-279862 A JP 2010-1119940 JP 2010-46632 A JP 2010-42338 A JP2011-110028 JP 2010-75180 A JP 2008-178440 A

Yukihiro Hojo, Material Integration 22 (5), 44-48, 2009-05

  This invention provides the cultivation method of a sprout which eliminated the conventional trouble.

As a result of diligent research to solve the conventional problems, the present inventor has surprisingly found that a sproud cultivation method using a combination of ozone nanobubble water and ethylene nanobubble water has a shortened cultivation period and an extended shelf life. The present invention has been completed. That is, the present invention is as follows.
[1] Crop cultivation method using ozone nanobubble water and ethylene nanobubble water in combination,
[2] The method according to [1], wherein ozone nanobubble water is sprinkled during the sprout growth period.
[3] The method according to [1] or [2], wherein ethylene nanobubble water is sprinkled during sprout maturity.
[4] The method according to any one of [1] to [3], wherein the ozone concentration of ozone nanobubble water is 0.01 to 0.3 ppm.
[5] The method according to any one of [1] to [4], wherein the ethylene concentration of ethylene nanobubble water is 0.1 to 10 ppm.
[6] The method according to any one of [1] to [5], wherein the seed is immersed in ozone nanobubble water before germination.
[7] The method according to any one of [1] to [6], wherein the immersion time is 6 to 24 hours,
[8] The method according to any one of [1] to [7], wherein ozone nanobubble water is sprinkled at the time of sprout harvesting.
[9] Sprout is selected from the group consisting of mung bean sprouts, soybean sprouts, alfalfa, fenugreek, radish, broccoli, purple cabbage, mustard, cress, bean seedlings, buckwheat, mustard, white pepper and green curd, [1]-[ 8], the method according to any one of
[10] A sprout cultivation system for use in the methods [1] to [9], comprising an ozone nanobubble water supply device and an ethylene nanobubble water supply device,
[11] A sprout obtained by the method of [1] to [9].

  The method of the present invention makes it possible to shorten the cultivation period and extend the shelf life.

  In the present invention, the nanobubble water has a maximum bubble diameter (mode value) of 250 nm or less, preferably 1 to 250 nm, more preferably 10 to 200 nm, still more preferably 50 to 180 nm, and particularly preferably 100 to 160 nm. Water that contains a bubble.

  The method for measuring the bubble diameter is not limited, but can be measured by a dynamic light scattering method, Nanoparticle Tracking Analysis (NTA), or the like. Examples of the measuring device include NANOSIGHT LM10-HS manufactured by Nippon Quantum Design Co., Ltd. The NTA method irradiates the sample water horizontally with a laser and visualizes the measured scattered light from the nanoparticles with an objective lens, thereby visualizing the Brownian motion of the nanoparticles and automatically automating the Brownian motion. In this method, the movement speed of the particles is calculated by tracking, and the particle diameter and amount are measured by the Stokes-Einstein equation from the movement speed of the particles and the temperature and viscosity of the sample.

  The amount of bubbles contained in water includes 5000000 or more, preferably 40000000 or more, and more preferably 100000000 or more as the number of bubble particles per 1 mL of water.

  The amount of bubbles contained in water can be measured by a dynamic light scattering method, Nanoparticle Tracking Analysis (NTA), or the like. Examples of the measuring apparatus include NANOSIGHT LM10-HS manufactured by Nippon Quantum Design Co., Ltd.

  The water is not limited as long as it can form bubbles. Preferably, tap water, drinking water, distilled water, ultrapure water (reverse osmosis membrane water), industrial water and the like can be mentioned.

  Commercially available ethylene and ozone can be used.

  The method for producing nanobubble water is not limited as long as it is a method for producing nanobubbles in water. For example, a gas-liquid two-phase swirl method created by stirring water and gas; a sufficient amount of gas at a certain high pressure There is a pressure dissolution (pressurization-depressurization) method using supersaturation, in which a large amount of bubbles is generated in water after the pressure is dissolved in water.

  Nano bubble water production apparatuses include, for example, Ishida Giken Co., Ltd. (IOH-P-2), Asp Co., Ltd. (MA2, MA2FS, ASK3, SMX115, SMX554), REO Laboratories, and Nanocus Corporation. (NanoQuick), IDEC Corporation (nanoGALF GAS LIQUID FOAM), Kyowa Machine Co., Ltd. (Bavitas), Bubble Tank Company (BT-50 type) and the like.

  The sprout cultivation method of the present invention can include germinating seeds and growing and maturing the germinated seeds.

  When ozone nanobubble water is sprinkled, an ozone atmosphere (0.1 ppm or less) in the growth room is formed, but ozone gas within one hour is decomposed.

  The growth of sprout can be finely adjusted by ozone nanobubble water. In addition, the growing period can be greatly shortened by watering with ozone nanobubble water.

  If ozone nanobubble water is not used, it takes about one week before it becomes 5 cm or more (edible part) that can be shipped, but if ozone nanobubble water is used, it can be shipped in at least the fifth day.

  In some cases, the reason for the extended shelf life by washing with ozone nanobubble water at the time of shipment is to suppress the growth of general bacteria and mold that cause spoilage, and to suppress the generation of ethylene gas from the sprout and to delay ripening . In addition, the sprout can be sterilized by using it at the time of washing and packaging of the sprout, and the shelf life can be greatly improved and the quality can be improved.

  In the present invention, since ethylene gas or ethylene mixed gas is not directly diluted and sprayed on the sprout, but the ethylene gas is mixed with nanobubble water and used, the action can be controlled very delicately.

  Preferably, the ozone concentration of ozone nanobubble water is 0.01 to 0.3 ppm.

  Preferably, the ethylene concentration of ethylene nanobubble water is 0.1 to 10 ppm.

  Preferably, the sprout is immersed in ozone nanobubble water for 6 to 24 hours before emergence. As a result, germination can be prevented and bacteria and molds can be prevented from growing during the growth and maturation period of the sprout.

  Preferably, ozone nanobubble water is sprinkled for about 20 minutes every 2 to 3 hours in the growing room when the sprout grows.

  Preferably, watering is performed using a shower device (a hole having a diameter of 0.5 mm or less and 100 holes or more).

  Preferably, sprout growth is maintained at room temperature 22-28 ° C, humidity 70-90%, and water temperature 18-22 ° C.

  Preferably, ozone nanobubble water is sprinkled alternately during sprout germination and growth, and ozone nanobubble water is sprinkled alternately during sprout maturation and ozone nanobubble water is sprinkled for sterilization.

Sprouts were produced using commercially available mung beans.
Nano bubble water (nano water): manufactured using an Ishida Giken apparatus (IOH-P-2). In the production of nano water, first, the apparatus was immersed in tap water, and the operation was repeated for 40 minutes and stopped for 20 minutes.
Ozone nanobubble water was produced by inhaling ozone into nanobubble water at 2 ml / min. The ozone concentration was 0.2 mg / ml (calculated as ozone molecular weight 48, 20 ° C., 1 ppm = 1 mg / L).
Ethylene nanobubble water was produced by inhaling ethylene into nanobubble water at 122 mg / min. The ethylene concentration was 4 ppm.
Mung beans were immersed in nanobubble water for 6 hours for sterilization and germination.
Watering was performed 8 times a day (20 minutes / time, average interval 206 minutes / day). On the first to third days, ozone nanobubble water was sprinkled eight times, and on the fourth to fifth days, ozone nanobubble water was sprinkled four times and ethylene nanobubble water was sprinkled four times. One time of watering, 3000 L was performed for 20 minutes. As a control, a group sprinkled with tap water was provided. Watering was performed 8 times a day (20 minutes / time, average interval 206 minutes / day).
The sprout length on each cultivation day was measured.
In the group cultivated with nanobubble water, no growth of bacteria and mold was observed. In addition, the harvested sprout was fattened thicker in the group cultivated with nano-bubble water, and it was chewy and excellent in texture. Furthermore, the shelf life of the product could be extended by sprinkling ozone nanobubble water at the time of harvest (in the present invention, it was 10 days compared with 7 days from shipment in tap water). .

  As is apparent from the above table, according to the method of the present invention, on the 4th day of cultivation, the plant grew to a length exceeding the sprout length at the time of harvesting by the conventional method. Therefore, according to the method of the present invention, a sprout exceeding the conventional size can be manufactured in half the conventional number of days.

  The present invention is useful for cultivation of sprout.

Claims (11)

A sproud cultivation method using a combination of ozone nanobubble water and ethylene nanobubble water. The method according to claim 1, wherein ozone nanobubble water is sprinkled during the sprout growth period. The method of Claim 1 or 2 which waters ethylene nano bubble water in the sprout maturity stage. The method according to any one of claims 1 to 3, wherein the ozone concentration of ozone nanobubble water is 0.01 to 0.3 ppm. The method of any one of Claims 1-4 whose ethylene concentration of ethylene nano bubble water is 0.1-10 ppm. The method according to claim 1, wherein the seeds are immersed in ozone nanobubble water before germination. The method according to any one of claims 1 to 6, wherein the immersion time is 6 to 24 hours. The method according to any one of claims 1 to 7, wherein ozone nanobubble water is sprinkled during sprout harvesting. The sprout is selected from the group consisting of mung bean sprout, soy bean sprout, alfalfa, fenugreek, radish, broccoli, purple cabbage, mustard, cress, bean seedling, buckwheat, mustard, white pepper and green curd. The method according to item 1. The sprout cultivation system for using for the method of Claims 1-9 provided with an ozone nano bubble water supply apparatus and an ethylene nano bubble water supply apparatus. A sprout obtained by the method of claims 1-9.