JPWO2019230766A1 - Tomato fruit shape control method - Google Patents

Abstract

An object of the present invention is to provide a method for controlling the shape of tomato fruit, which can control the shape at a high level. The tomato fruit shape control method is a tomato fruit shape control method in which nanobubble water is applied to tomatoes on which tomato fruits are produced.

Description

The present invention relates to a method for controlling the shape of tomato fruits.

In recent years, as the demand for tomatoes has increased, it has become possible to grow tomatoes throughout the year in a cultivation house using sunlight with the progress of cultivation facilities.
In addition, as a cultivation method in a cultivation house, a low-stage dense planting cultivation method, which is expected to increase the yield, is attracting attention.
This low-stage dense planting cultivation method is a method in which tomatoes are cultivated by densely concentrating the plants (for example, the distance between the plants is about 15 cm) and setting the number of harvesting stages to about 3 to 5 stages, and the cultivation density can be increased. Since the number of harvests per year can be increased, it is expected that the yield will be improved.

However, in this low-stage dense planting cultivation method, the leaves of adjacent plants are overlapped with each other, and the amount of light required for photosynthesis is insufficient. There is a problem that growth disorders such as phenomena occur frequently. In particular, when the hollowing phenomenon occurs, there is a problem that the shape of the fruit becomes non-uniform.

In response to such a problem, for example, Patent Document 1 states that "a method of densely planting and cultivating tomatoes using a long cultivation bed, in which in each seedling, a bunch is cultivated with respect to the main stem. The main stem of the seedling is arranged so as to be located in the longitudinal direction of the bed, and in a state where the tuft is located in the longitudinal direction of the cultivation bed, the leaves located substantially opposite to the tuft across the main stem are placed. A method for low-stage dense planting of tomatoes, which is characterized by removing the tomatoes. ”([Claim 1]).

Japanese Patent No. 6132451

The present inventor examined conventionally known tomato cultivation methods such as the cultivation method described in Patent Document 1, and found that any cultivation was performed for controlling the shape of tomato fruits (for example, homogenization and quality improvement). It was clarified that there is room for improvement in the method.

Therefore, it is an object of the present invention to provide a method for controlling the shape of tomato fruits, which can control the shape at a high level.

As a result of diligent studies to achieve the above problems, the present inventor has found that the shape of tomato fruits can be controlled by applying nanobubble water to tomatoes on which tomato fruits are produced, and completed the present invention. I let you.
That is, the present inventor has found that the above problems can be achieved by the following configuration.

[1] A method for controlling the shape of tomato fruits by applying nanobubble water to tomatoes on which tomato fruits are produced.
[2] The method for controlling the shape of tomato fruits according to [1], wherein at least one of watering using the nanobubble water and supply of the culture solution diluted with the nanobubble water to the medium is carried out.
[3] The method for controlling the shape of a tomato fruit according to [1] or [2], wherein the most frequent particle size of bubbles contained in the nanobubble water is 10 to 500 nm.
[4] The tomato fruit according to any one of [1] to [3], wherein the bubbles contained in the nanobubble water contain at least one gas selected from the group consisting of oxygen, nitrogen, carbon dioxide and ozone. Shape control method.
[5] The method for controlling the shape of a tomato fruit according to any one of [1] to [4], wherein the nanobubble water has 1 × 10 ⁸ to 1 × 10 ^{10 bubbles / mL.}

According to the present invention, it is possible to provide a method for controlling the shape of a tomato fruit, which can control the shape at a high level.

It is a schematic diagram which shows an example of the nano bubble generation apparatus. It is an image which shows the sample of the tomato fruit of the special A product. It is an image which shows the sample of the tomato fruit of product A. It is an image which shows the sample (oval type) of the tomato fruit of product B. It is an image which shows the sample (Momiji manju type) of the tomato fruit of product B. It is an image which shows the sample (pointed type) of the tomato fruit of product B. It is an image which shows the sample (chuck type) of the tomato fruit of product C.

Hereinafter, the present invention will be described in detail.
The description of the constituent elements described below may be based on typical embodiments of the present invention, but the present invention is not limited to such embodiments.
In the present specification, the numerical range represented by using "~" means a range including the numerical values before and after "~" as the lower limit value and the upper limit value.

The tomato fruit shape control method of the present invention (hereinafter, also abbreviated as “the shape control method of the present invention”) is a tomato fruit shape control method in which nanobubble water is applied to tomatoes on which tomato fruits are produced.
In the present specification, "tomato" means tomato as a plant belonging to fruit vegetables, and "tomato fruit" means a fruit grown on tomato.
The nanobubble water and arbitrary components used in the shape control method of the present invention will be described in detail below.

[Nano bubble water]
The nanobubble water used in the shape control method of the present invention is water containing bubbles having a diameter of less than 1 μm, and is water in which the bubbles are mixed. The term "water mixed with the above-mentioned bubbles" is intended to exclude water containing the above-mentioned bubbles that is inevitably contained due to water used for generating nanobubble water (for example, well water containing impurities). Is.
Here, the diameter of the bubbles (particle size) contained in the nanobubble water, the most frequent particle size of the bubbles and the number of bubbles, which will be described later, determine the Brownian motion movement rate of the bubbles in the water using the nanoparticle tracking analysis method. These are the measured values, and in this specification, the values measured by the nanoparticle analysis system Nanosite Series (manufactured by NanoSight) are adopted.
In the nanoparticle analysis system Nanosite series (manufactured by NanoSight), the diameter (particle size) can be calculated from the rate of Brownian motion of particles, and the most frequent particle size exists. It can be confirmed as a mode diameter from the particle size distribution of nanoparticles.

In the present invention, the most frequent particle size of the bubbles contained in the nanobubble water is preferably 10 to 500 nm, preferably 30 to 300 nm, for the reason that the shape of the tomato fruit can be more controlled (particularly homogenized). Is more preferable, and 70 to 130 nm is further preferable.

The gas constituting the bubbles contained in the nanobubble water is not particularly limited, but a gas other than hydrogen is preferable from the viewpoint of remaining in the water for a long time, and specifically, for example, air, oxygen, nitrogen, fluorine, and carbon dioxide. , And ozone and the like.
Of these, it is preferable to contain at least one gas selected from the group consisting of oxygen, nitrogen, carbon dioxide and ozone, and particularly plants. It is more preferable to contain oxygen because the growth of the body is good and bubbles can remain for a longer period of time.
Here, the inclusion of oxygen means that the concentration is higher than the oxygen concentration in the air. The same applies to nitrogen and carbon dioxide. The oxygen concentration is preferably 30% by volume or more, preferably more than 50% by volume and 100% by volume or less in the bubbles.

^{The nanobubble water preferably has 1 × 10 8} to 1 × 10 ¹⁰ bubbles / mL for the reason that the shape of the tomato fruit can be controlled (particularly homogenized), and in particular, the formation of bubbles. It is more preferable to have more ^{than 1 × 10 8} bubbles / mL and less than 1 × 10 ¹⁰ bubbles / mL for the reason that the balance between time and the residualness of bubbles is good, and ^{5 × 10 8} ~. It is more preferable to have 5 × 10 ^{9 bubbles / mL.}

Examples of the method for producing nanobubble water include a static mixer method, a Venturi method, a cavitation method, a steam agglomeration method, an ultrasonic method, a swirling flow method, a pressure dissolution method, and a micropore method.
Here, the shape control method of the present invention may have a generation step of generating the nanobubble water before applying the nanobubble water. That is, the shape control method of the present invention includes, for example, a generation step of taking water from a water source such as a water storage tank, a well, or agricultural water into a nanobubble generator to generate nanobubble water, and an application step of applying the generated nanobubble water. It may be a control method having. As a method of taking the water from the water source into the nanobubble generator, for example, a method of supplying the water pumped from the water source to the nanobubble generator using a tub or a pump, and between the water source and the nanobubble generator. Examples thereof include a method in which the laid channel is connected to the nanobubble generator and water is directly sent from the channel to the nanobubble generator.

Further, as the method for producing nanobubble water, a method for producing nanobubble water using an apparatus that does not intentionally generate radicals is preferable. Specifically, for example, [0080] to [0080] to [0080] to [0080] to [0080] to [0080] 0100] A method of generating using the nanobubble generating apparatus described in the paragraph can be mentioned. The above contents are incorporated in the present specification.

Other nanobubble generators that do not intentionally generate radicals include, for example, a liquid discharger that discharges water and a gas mixer that pressurizes and mixes gas into the water discharged from the liquid discharger. A fine bubble generator having a fine bubble generator that generates fine bubbles in water by passing water mixed with gas inside, and the gas mixing machine is the liquid discharger and the above. Examples thereof include a fine bubble generator characterized in that a gas is pressurized and mixed with a liquid flowing toward the fine bubble generator in a pressurized state among the fine bubble generators. Specifically, a method of generating using the nanobubble generating apparatus shown in FIG. 1 can be mentioned.
Here, the nano bubble generation device 10 shown in FIG. 1 includes a liquid discharger 30, a gas mixer 40, and a nano bubble generation nozzle 50 inside.
Further, the liquid discharger 30 is composed of a pump, and takes in raw water (for example, well water) of nanobubble water and discharges it. The gas mixer 40 has a container 41 filled with compressed gas and a substantially tubular gas mixer main body 42, and while flowing water discharged from the liquid discharger 30 into the gas mixer main body 42, The compressed gas in the container 41 is introduced into the gas mixer main body 42. As a result, gas-mixed water is generated in the gas-mixing machine main body 42.
Further, the nanobubble generation nozzle 50 generates nanobubbles in the gas-mixed water according to the principle of pressure dissolution by passing the gas-mixed water through the inside thereof, and its structure is described in JP-A-2018-15715. The same structure as the nanobubble generation nozzle described in the above can be adopted. The nanobubble water generated in the nanobubble generation nozzle 50 is ejected from the tip of the nanobubble generation nozzle 50, then flows out from the nanobubble generation device 10, and is sent to a predetermined destination through a flow path (not shown).
As described above, in the nanobubble generation device 10, the gas mixing machine 40 is compressed into water (raw water) flowing toward the nanobubble generation nozzle 50 in a pressurized state between the liquid discharger 30 and the nanobubble generation nozzle 50. Mix gas. This makes it possible to avoid problems such as cavitation that occur when gas is mixed with water on the suction side (suction side) of the liquid discharger 30. Further, since the gas is mixed in the water in a pressurized (compressed) state, the gas can be mixed against the pressure of the water at the gas mixing location. Therefore, it is possible to appropriately mix the gas into the water without generating a negative pressure at the gas mixing location.
Further, a flow path of water supplied from a water source such as a well or a water supply is connected to the suction side of the liquid discharger 30, and flows into the liquid discharger 30 from the upstream side of the liquid discharger 30 in the flow path. The water pressure (that is, the water pressure on the suction side) should be positive. In this case, the above configuration becomes more meaningful. That is, when the water pressure (suction pressure) on the upstream side of the liquid discharger 30 becomes a positive pressure, gas is mixed into the water on the downstream side of the liquid discharger 30, so that the downstream side of the liquid discharger 30 However, the configuration of the nanobubble generator 10 capable of appropriately mixing the gas with water becomes more conspicuous.

The water used to generate the nanobubble water is not particularly limited, and for example, rainwater, tap water, well water, agricultural water, distilled water and the like can be used.
Such water may have been subjected to other treatments before being subjected to the generation of nanobubble water. Other treatments include, for example, pH adjustment, precipitation, filtration, and sterilization (sterilization). Specifically, for example, when agricultural water is used, typically, agricultural water after precipitation and at least one of filtration may be used.

In the present invention, the mode in which the nanobubble water is applied to tomatoes on which tomato fruits are produced is not particularly limited because it differs depending on the tomato cultivation method. For example, in soil cultivation, the mode in which the nanobubble water is sprinkled, soil. In the mode of spraying the pesticide diluted with the nano bubble water in the cultivation, it was diluted with the nano bubble water in the hydroponic cultivation (hydroponics, spray cultivation or solid medium cultivation) or the hydroponic soil cultivation (irrigation simultaneous fertilization cultivation). Examples thereof include a mode in which the culture solution is supplied to the medium, and a mode in which the nanobubble water is watered (irrigated) by itself in hydroponic soil cultivation.
Of these, at least of the watering using the nanobubble water and the supply of the culture solution diluted with the nanobubble water, because the shape of the tomato fruit can be controlled (particularly homogenized) by a simple operation. It is preferable to carry out one of them.
The method of "watering", which is one aspect of application, is not particularly limited, and when the cultivation method is soil cultivation, for example, a method of spraying water over the entire plant or a part of the plant ( For example, a method of spraying water on a stem or a leaf), a method of spraying water on the soil in which a plant is planted, and the like can be mentioned. When the cultivation method is hydroponic cultivation, watering by irrigation may be used as described above.

Further, in the present invention, the time at which the nanobubble water is applied to tomatoes on which tomato fruits are produced is not particularly limited because it differs depending on the tomato cultivation method. For example, in the case of hydroponics, from installation to harvesting. It is preferable to apply it for the entire period of.

<Other ingredients>
The nanobubble water may further contain other components.
Examples of the other components include pesticides, fertilizers, surfactants, antifreeze agents, antifoaming agents, preservatives, antioxidants, thickeners and the like. The type and content of other components are not particularly limited and can be selected according to the purpose.
However, in the present invention, it is preferable that radicals are not substantially contained in the nanobubble water as the other components. The phrase "substantially free of radicals" is intended to exclude that radicals are inevitably contained due to the water used to generate the nanobubble water (for example, well water containing impurities). It is intended to exclude the mixing of radicals generated by some operation.

〔tomato〕
In the present invention, the varieties of tomatoes to which the nanobubble water is applied are not particularly limited, and may be any varieties such as mini tomatoes, medium-sized tomatoes, and large-sized tomatoes.

Hereinafter, the present invention will be described in more detail with reference to examples. The materials, amounts used, ratios, treatment contents, treatment procedures, etc. shown in the following examples can be appropriately changed as long as they do not deviate from the gist of the present invention. Therefore, the scope of the present invention should not be construed as limiting by the examples shown below.

<Contents of the test>
The test was conducted in the following categories at an agricultural house of tomatoes (variety: grace) cultivated in Sagamihara City, Kanagawa Prefecture from February to July 2017.
Test group I: Nano bubble water produced by the following method was used for diluting the culture solution in hydroponic cultivation of tomatoes (medium: water).
Test Group II: Tap water was used for dilution of the culture solution in hydroponic cultivation of tomatoes (medium: water), and nanobubble water was not used.
Each test plot was divided into one agricultural house, and 500 tomatoes were cultivated in the test plot I and 14,500 tomatoes were cultivated in the test plot II.
The culture solution and amount were appropriately changed according to the growing condition of tomatoes, the weather, etc. according to a conventional method, but were adjusted so as to be substantially the same in both test plots.

<Method of generating nano bubble water>
For nano bubble water, bubbles (nano bubbles) are generated in water by a pressure dissolution method using a nano bubble generator [Kakuichi Seisakusho Co., Ltd. Aqua Solution Division (currently Aqua Solution Co., Ltd.), 200V, 10L / min type]. It was generated by letting it.
Tap water was used as the water used for producing nanobubble water, and oxygen (industrial oxygen, concentration: 99.5% by volume) was used as the gas constituting the bubbles.
Further, the conditions for generating nanobubbles using the above-mentioned nanobubble generator were performed under the conditions that the analysis result by the nanoparticle analysis system Nanosite LM10 (manufactured by NanoSight) was as follows.
-Number of bubbles per 1 mL of water: 5 x 10 ⁸ cells / mL
-Moderate particle size of bubbles: 100 nm

<Evaluation of shape control>
In each test plot, the total amount of tomatoes harvested was visually confirmed and evaluated according to the criteria shown below. The results are shown below.
(Evaluation criteria)
Special product A: Equivalent to the tomato fruit sample shown in Fig. 2 Product A: Equivalent to the tomato fruit sample shown in Fig. B Product B: Equivalent to the tomato fruit sample shown in FIGS. 4A to 4C C product: Fig. Equivalent to the tomato fruit sample shown in 5 (evaluation result)
Test group I: Tomatoes of special A product and A product evaluation were present in 90% of the total number of harvested tomatoes.
Test group II: Tomatoes evaluated as B product and C product were scattered, and tomatoes evaluated as special A product and A product accounted for only 83% of the total number of harvested tomatoes.
From these results, it was found that by applying nanobubble water to tomatoes on which tomato fruits are produced, the shape of tomatoes satisfying Evaluation A can be made uniform at a high level.

10 Nano bubble generator 30 Liquid discharger 40 Gas mixer 41 Container 42 Gas mixer body 50 Nano bubble generation nozzle

Claims (5)

A method for controlling the shape of tomato fruits by applying nanobubble water to tomatoes on which tomato fruits grow. The method for controlling the shape of tomato fruits according to claim 1, wherein at least one of watering using the nanobubble water and supply of the culture solution diluted with the nanobubble water to the medium is carried out. The method for controlling the shape of a tomato fruit according to claim 1 or 2, wherein the most frequent particle size of the bubbles contained in the nanobubble water is 10 to 500 nm. The method for controlling the shape of a tomato fruit according to any one of claims 1 to 3, wherein the bubbles contained in the nanobubble water contain at least one gas selected from the group consisting of oxygen, nitrogen, carbon dioxide and ozone. The method for controlling the shape of a tomato fruit according to any one of claims 1 to 4, wherein the nanobubble water has 1 × 10 ⁸ to 1 × 10 ^{10 bubbles / mL.}

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