KR20210062462A - Growing system for tomato plug seedling during winter season and method for cultivation the same - Google Patents

Abstract

The present invention relates to a device for growing a tomato plug seedling during the winter season and a method for cultivating the same, wherein the device comprises: a facility unit that is sealed to have a space inside; a growing unit in which a space for cultivating plants is provided inside the facility unit; a supply unit that is provided inside the facility unit and injects carbon dioxide supplied from one side of the facility unit to the upper part of the growing unit through a nozzle; a sensor for measuring the concentration of carbon dioxide on one side of the growing unit; a valve that is connected to the sensor to control opening and closing of the supply unit; a light supplementing unit provided inside the facility unit and provided above the growing unit; and a control unit that operates the valve according to the concentration of carbon dioxide from the sensor and controls the operation of the light supplementing unit.

Description

Winter season tomato grafting seedling apparatus and its cultivation method {Growing system for tomato plug seedling during winter season and method for cultivation the same}

The present invention relates to a winter season tomato grafting seedling and seeding apparatus and its cultivation method, and more particularly, to a method capable of improving the quality by promoting photosynthetic activity of crops.

In general, increasing the concentration of carbon dioxide in the atmosphere increases the growth and yield of crops by accelerating the rate of photosynthesis of the crops. According to Kimball, as a result of analyzing the effect of increasing atmospheric CO2 in 37 kinds of crops, the current concentration of carbon dioxide in the atmosphere is If it doubles, the crop yield is predicted to increase by 24 to 43%. However, it is thought that the effect of carbon dioxide on crop yield varies slightly depending on the crop.

This is because, when exposed to increased carbon dioxide for a long period of time, starch particles accumulated in the mesophyll tissue pressurize the grana structure of the chloroplast and cause structural deformation, which can cause feedback inhibition on photosynthesis. As a similar report, Lee and Lee observed that when the atmospheric carbon dioxide concentration ^{was increased to 800 μmol mol -1} , starch particles in tomato leaves increased significantly compared to normal (350 μmol mol ^{-1 ).} As a result, the photosynthetic activity gradually decreased after 30 days after planting in ^{the 800 μmol mol -1} treatment with elevated carbon dioxide, and showed lower photosynthetic activity than ^{the control (350 μmol mol -1) on the 50th day.} On the other hand, Ho said that the photosynthetic ability was not significantly different despite the increase in the concentration of carbon dioxide in the atmosphere, but the current velocity of the assimilation product increased.

These differences in crop response may show different patterns depending on the type of crop, or between varieties, even for the same crop.

Registered Patent No. 10-1794622

In order to solve the above-described problem, an object of the present invention relates to a winter season tomato grafting seedling apparatus and a cultivation method thereof capable of promoting plant growth and improving quality through carbon dioxide concentration control and light beam protection.

As for achieving the above object, the facility is sealed and provided with a space therein; A seedling unit provided with a space for growing plants in the facility unit; A supply unit provided inside the facility unit and injecting carbon dioxide supplied from one side of the facility unit to an upper portion of the seedling unit through a nozzle; A sensor measuring the concentration of carbon dioxide at one side of the seedling; A valve connected to the sensor to control opening/closing of the supply unit; A light beam provided inside the facility unit and disposed above the seedling unit; And a control unit that operates the valve according to the carbon dioxide concentration of the sensor and controls the operation of the light beam.

The light beam is characterized in that a metal halide is used, and the luminous intensity is 100 μmol·m ^-2 ·s ^{-1 PPFD.}

The control unit is characterized in that operating the valve so that the carbon dioxide concentration inside the facility ^{unit maintains 700 μmol·mol −1.}

In the winter tomato grafting seedling apparatus manufactured according to claim 1, the tomato grafted seedlings are cultivated in a seedling section provided inside the ^{facility, and the inside of the facility is 100 μmol·m -2} ·s ^-1 PPFD luminous intensity metal halide, etc. It is characterized by rewarding for hours.

The carbon dioxide concentration inside the facility is 700 μmol·mol ^-1 , and the relative humidity is 65 to 75%.

In the winter season tomato seedling seedling apparatus and its cultivation method according to the present invention has the following effects.

It can effectively promote the growth and development of tomatoes even in winter, and has the effect of improving the quality.

Due to the promotion of root initiation, there is an effect that farmers can flexibly adjust the seedling work schedule.

1 is a view showing a winter season tomato grafting seedling seedling apparatus according to the present invention.
Figure 2 is a view showing the growth of the above-ground part of the super sun rod in the winter season tomato grafting seedling seedling apparatus and its cultivation method according to the present invention.
Figure 3 is a view showing the growth of the basement of the supersun road in the winter season tomato grafting seedling seedling apparatus and its cultivation method according to the present invention.
Figure 4 is a view showing the growth of the super sun rod in the winter season tomato grafting seedling seedling apparatus and its cultivation method according to the present invention.
Figure 5 is a view showing the growth of the above-ground part of the super dotaerang in the winter season tomato grafting seedling seedling apparatus and its cultivation method according to the present invention.
Figure 6 is a view showing the growth of the basement of the super dotaerang in the winter season tomato grafting seedling seedling apparatus and its cultivation method according to the present invention.
Figure 7 is a view showing the growth of the super dotaerang in the winter season tomato grafting seedling seedling apparatus and its cultivation method according to the present invention.
8 is a view showing the result of evaluation of rank sum of Super Dotaerang and Super Sun Road in the winter season tomato seedling seedling apparatus and its cultivation method according to the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of a winter season tomato seedling seedling apparatus and a cultivation method thereof according to the present invention will be described in detail.

As shown in FIG. 1, the inventors' winter season tomato grafting seedling apparatus includes a facility unit 100 that is sealed to provide a space therein, and a seedling unit 200 that provides a space for cultivating plants in the facility unit 100. ), a supply unit 300 provided inside the facility unit 100 and spraying carbon dioxide supplied from one side of the facility unit 100 onto the seedling unit 200 through a nozzle 310, and the seedling unit 200 A sensor 400 measuring the concentration of carbon dioxide at one side, a valve 500 connected to the sensor 400 to control opening and closing of the supply unit 300, and provided inside the facility unit 100, and the seedling unit 200 ) It is composed of a light beam detector 600 provided at the top, a control unit 700 that operates the valve 500 according to the carbon dioxide concentration of the sensor 400, and controls the operation of the light beam receiver 600.

First, the facility unit 100 is provided. The facility unit 100 is provided with a space inside, and is blocked from the outside so that it can be sealed. The facility unit 100 may be made of vinyl, but is not limited thereto, but it is preferable to use a material through which sunlight can pass.

A seedling unit 200 is provided inside the facility unit 100. The seedling unit 200 provides a space in which plants can be grown. A space is formed above the seedling part 200 to grow plants, and a plurality of them may be formed.

A supply unit 300 is provided inside the facility unit 100. The supply unit 300 transports carbon dioxide supplied from one side of the facility unit 100. The supply unit 300 may be located above the facility unit 100.

Here, a nozzle 310 may be further provided in the supply unit 300, and the nozzle 310 is positioned above the seedling unit 200 to inject carbon dioxide onto the seedling unit 200. The nozzles 310 may be provided in the same number as the seedling part 200.

A sensor 400 is provided on one side of the seedling part 200. The sensor 400 may measure the carbon dioxide concentration. The sensor 400 may be provided in the same number as the seedling portion 200.

A valve 500 is provided in the supply unit 300. The valve 500 is connected to the sensor 400 and may adjust the carbon dioxide concentration of the facility unit 100 by controlling the opening and closing of the supply unit 300.

A beam beam 600 is provided inside the facility unit 100. The light beam 600 may be provided on the seedling portion 200, and the light beam 600 uses a metal halide, and a light intensity of 100 μmol·m ^-2 ·s ^-1 PPFD is used. I can. The beam beams 600 may be provided in the same number as the seedlings 200.

A control unit 700 is provided to control the operation of the valve 500 and the light beaming unit 600. The control unit 700 maintains the interior of the facility unit 100 under a certain condition.

The control unit 700 controls the light beam unit 600 to operate. The controller 700 may control the light beam 600 to operate for 16 hours per day. In addition, it is possible to control the light beam beam ^{600 to maintain the luminous intensity of 100 μmol·m -2} ·s ^{-1 PPFD.}

The control unit 700 may control the operation of the valve 500 according to the carbon dioxide concentration of the sensor 400. Here, the control unit 700 operates the valve 500 so that the carbon dioxide concentration in the facility unit 100 ^{can be maintained at 700 μmol·mol −1.}

The control unit 700 may adjust the temperature and humidity inside the facility unit 100, and for this purpose, a heater or a humidifier may be further provided inside the facility unit 100. The temperature of the facility unit 100 is preferably 17 to 23° C., 23° C. during the day, and 17° C. at night. In addition, it is preferable that the humidity of the facility unit 100 is 65 to 75%.

Hereinafter, a cultivation method using the winter season tomato grafting seedling apparatus according to the present invention will be described.

Tomato grafted seedlings are cultivated in the seedling unit 200 provided inside the facility unit 100, and cultivated by adjusting the environment inside the facility unit 100. Here, the interior of the facility unit 100 is interpolated for 16 hours with a metal halide having an intensity of ^{100 μmol·m -2} ·s ^{-1 PPFD by the light beaming unit 600.} In addition, the carbon dioxide concentration can be adjusted by the valve 500, and 700 μmol·mol ⁻¹ is maintained.

In addition, the temperature inside the facility unit 100 is adjusted to 17 to 23°C, and the humidity is maintained at 65 to 75%.

Hereinafter, the contents of the experiment in the winter season tomato seedling seedling apparatus and its cultivation method according to the present invention will be described in detail.

1. Growth after treatment of tomato (Super Sunload) cedar seedlings

[Comparative Example 1]

In Comparative Example 1, tomato (Super Sunload) grafted seedlings were grown in a seedling. Here, the inside of the facility was cultivated for 10 days while maintaining 23°C during daytime and 17°C at night, and maintaining 70% humidity.

[Example 1]

In Example 1, tomato (Super Sunload) grafted seedlings were grown in a seedling. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The cultivation was carried out for 10 days while maintaining the carbon dioxide concentration in the facility through a valve of 350 μmol·mol ^−1.

[Example 2]

In Example 2, tomato (Super Sunload) grafted seedlings were grown in a seedling. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with a mixed LED lamp of 100 μmol·m ^-2 ·s ^-1 PPFD intensity, and 10 days while the carbon dioxide concentration inside the facility was maintained ^{at 350 μmol·mol -1 through a valve.} Cultivated during.

[Example 3]

In Example 3, tomato (Super Sunload) grafted seedlings were grown in a seedling. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with a metal halide of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while the carbon dioxide concentration inside the facility was maintained ^{at 350 μmol·mol -1 through a valve.} Cultivated during.

[Example 4]

In Example 4, tomato (Super Sunload) grafted seedlings were grown in a seedling section. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with high-pressure sodium lamp of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while the carbon dioxide concentration inside the facility was maintained ^{at 350 μmol·mol -1 through a valve.} Cultivated during.

[Example 5]

In Example 5, tomato (Super Sunload) grafted seedlings were grown in a seedling section. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The cultivation was carried out for 10 days while maintaining the carbon dioxide concentration inside the facility through a valve of 700 μmol·mol ^−1.

[Example 6]

In Example 6, tomato (Super Sunload) grafted seedlings were grown in a seedling. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with a mixed LED lamp of 100 μmol·m ^-2 ·s ^{-1 PPFD intensity, and the carbon dioxide concentration inside the facility was maintained at 700 μmol·mol -1} through a valve for 10 days. Cultivated during.

[Example 7]

In Example 7, tomato (Super Sunload) grafted seedlings were grown in a seedling. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours a day with a metal halide of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while the carbon dioxide concentration inside the facility was maintained ^{at 700 μmol·mol -1 through a valve.} Cultivated during.

[Example 8]

In Example 8, tomato (Super Sunload) grafted seedlings were grown in a seedling. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours a day with high-pressure sodium, etc. of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while maintaining ^{the carbon dioxide concentration inside the facility through a valve of 700 μmol·mol -1} Cultivated during.

[Example 9]

In Example 9, tomato (Super Sunload) grafted seedlings were grown in a seedling section. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. It was cultivated for 10 days while maintaining the carbon dioxide concentration inside the facility through a valve of 1050 μmol·mol ^−1.

[Example 10]

In Example 10, tomato (Super Sunload) grafted seedlings were grown in a seedling. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with a mixed LED of 100 μmol·m ^-2 ·s ^-1 PPFD intensity, and 10 days while maintaining the carbon dioxide concentration inside the facility through a valve to 1050 μmol·mol ^-1 Cultivated during.

[Example 11]

In Example 11, tomato (Super Sunload) grafted seedlings were grown in a seedling section. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with a metal halide of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while maintaining the carbon dioxide concentration inside the facility through a valve of 1050 μmol·mol ^-1 Cultivated during.

[Example 12]

In Example 12, tomato (Super Sunload) grafted seedlings were grown in a seedling section. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with high-pressure sodium, etc. of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while the carbon dioxide concentration inside the facility was maintained ^{at 1050 μmol·mol -1 through a valve.} Cultivated during.

Figure 2 is a view showing the growth of the above-ground part of the super sun rod in the winter season tomato seedling seedling apparatus and its cultivation method according to the present invention, CK is an experiment without compensation, LED is a mixed LED lamp, MH is a metal halide Etc., HPS high pressure sodium, etc. are used.

As in Example 7, it can be seen that the growth of stems and leaves is best when the light is compensated with metal halide, and the carbon dioxide concentration is 700 μmol·mol ^−1.

In Figure 3 and Bogwang as a metal halide such as a diagram of a below-ground growth of the super line load in winter grafted tomato seedling planting apparatus and its method according to the present invention, Example 7, the carbon dioxide concentration is 700 μmol · mol ^-1 In this case, it can be confirmed that the growth of the root is the best.

FIG. 4 is a diagram showing the growth of a super sun rod in the winter season tomato grafting seedling apparatus and its cultivation method according to the present invention. As in Example 7, when the carbon dioxide concentration is 700 μmol·mol ⁻¹ Showed the best growth results.

2. Growth after treatment of tomato (Super Dotaerang) cedar seedlings

[Comparative Example 2]

In Comparative Example 2, tomato (Super Dotaerang) grafted seedlings were grown in a seedling. Here, the inside of the facility was cultivated for 10 days while maintaining 23°C during daytime and 17°C at night, and maintaining 70% humidity.

[Example 13]

In Example 13, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The cultivation was carried out for 10 days while maintaining the carbon dioxide concentration in the facility through a valve of 350 μmol·mol ^−1.

[Example 14]

In Example 14, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with a mixed LED lamp of 100 μmol·m ^-2 ·s ^-1 PPFD intensity, and 10 days while the carbon dioxide concentration inside the facility was maintained ^{at 350 μmol·mol -1 through a valve.} Cultivated during.

[Example 15]

In Example 15, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with a metal halide of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while the carbon dioxide concentration inside the facility was maintained ^{at 350 μmol·mol -1 through a valve.} Cultivated during.

[Example 16]

In Example 16, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with high-pressure sodium lamp of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while the carbon dioxide concentration inside the facility was maintained ^{at 350 μmol·mol -1 through a valve.} Cultivated during.

[Example 17]

In Example 17, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The cultivation was carried out for 10 days while maintaining the carbon dioxide concentration inside the facility through a valve of 700 μmol·mol ^−1.

[Example 18]

In Example 18, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with a mixed LED lamp of 100 μmol·m ^-2 ·s ^{-1 PPFD intensity, and the carbon dioxide concentration inside the facility was maintained at 700 μmol·mol -1} through a valve for 10 days. Cultivated during.

[Example 19]

In Example 19, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours a day with a metal halide of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while the carbon dioxide concentration inside the facility was maintained ^{at 700 μmol·mol -1 through a valve.} Cultivated during.

[Example 20]

In Example 20, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours a day with high-pressure sodium, etc. of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while maintaining ^{the carbon dioxide concentration inside the facility through a valve of 700 μmol·mol -1} Cultivated during.

[Example 21]

In Example 21, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. It was cultivated for 10 days while maintaining the carbon dioxide concentration inside the facility through a valve of 1050 μmol·mol ^−1.

[Example 22]

In Example 22, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with a mixed LED of 100 μmol·m ^-2 ·s ^-1 PPFD intensity, and 10 days while maintaining the carbon dioxide concentration inside the facility through a valve to 1050 μmol·mol ^-1 Cultivated during.

[Example 23]

In Example 23, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with a metal halide of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while maintaining the carbon dioxide concentration inside the facility through a valve of 1050 μmol·mol ^-1 Cultivated during.

[Example 24]

In Example 24, tomato (Super Dotaerang) grafted seedlings were grown in a nursery. Here, the inside of the facility was maintained at 23℃ during the daytime and 17℃ at night, and the humidity was maintained at 70%. The light beam was compensated for 16 hours per day with high-pressure sodium, etc. of 100 μmol·m ^-2 ·s ^-1 PPFD light intensity, and 10 days while the carbon dioxide concentration inside the facility was maintained ^{at 1050 μmol·mol -1 through a valve.} Cultivated during.

Figure 5 is a view showing the growth of the above-ground part of the super dotaerang in the winter season tomato seedling seedling apparatus and its cultivation method according to the present invention. Etc., HPS high pressure sodium, etc. are used.

As in Example 19, it can be seen that the growth of stems and leaves is best when the light is compensated with metal halide, and the carbon dioxide concentration is 700 μmol·mol ^−1.

In Figure 3, and the like Bogwang metal halide, such as the super drawing diagram showing a below-ground growth of the grafted seedlings taerang in winter tomato seedling planting apparatus and its method according to the present invention, Example 19, the carbon dioxide concentration is 700 μmol · mol ^-1 In this case, it can be confirmed that the growth of the root is the best.

For 4 and Bogwang as a metal halide such as supermarket a diagram showing the growth of taerang, Example 19 in winter grafted tomato seedling planting apparatus and its method according to the present invention, the carbon dioxide concentration is 700 μmol · mol ^-1 Showed the best growth results.

8 is a view showing the evaluation results of the rank sum of super dotaerang and super sun rod in the winter season tomato grafting seedling seedling apparatus and its cultivation method according to the present invention. Because there is a lot of growth data, it is difficult to analyze the results, and a rank sum test was used to facilitate the analysis of the results. All results were summed and ranked by taking the data of the two types of tomatoes, Super Sun Road and Super Dotaerang, as average values, and the reciprocal of the ranking was calculated for ease of understanding.

The best growth result was obtained when the concentration of carbon dioxide was 700 μmol·mol ^{-1, and was compensated with metal halide.}

As described above, it will be understood that the technical configuration of the present invention described above can be implemented in other specific forms without changing the technical spirit or essential features of the present invention by those skilled in the art.

Therefore, the embodiments described above should be understood as illustrative and non-limiting in all respects, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description, and the meaning and scope of the claims and the All changes or modifications derived from the equivalent concept should be construed as being included in the scope of the present invention.

100: facilities 200: nursery
300: supply unit 310: nozzle
400: sensor 500: valve
600: beam light beam 700: control unit

Claims (5)

A facility unit that is sealed to provide a space therein;
A seedling unit provided with a space for growing plants in the facility unit;
A supply unit provided inside the facility unit and injecting carbon dioxide supplied from one side of the facility unit to an upper portion of the seedling unit through a nozzle;
A sensor measuring the concentration of carbon dioxide at one side of the seedling;
A valve connected to the sensor and controlling opening/closing of the supply unit;
A light beam provided inside the facility unit and disposed above the seedling unit;
A control unit for operating the valve according to the carbon dioxide concentration of the sensor, and controlling the operation of the light beaming unit. The method of claim 1,
The beam beam
A winter season tomato grafting seedling apparatus, characterized in that it uses metal halide and has a luminosity of 100 μmol·m ^-2 ·s ^{-1 PPFD.} The method of claim 1,
The control unit,
Tomato seedling seedling apparatus in winter season, characterized in that operating the valve so that the carbon dioxide concentration inside the facility ^{unit maintains 700 μmol·mol -1.} In the winter season tomato seedling seedling apparatus prepared according to claim 1,
Tomato grafted seedlings are cultivated in the seedling section provided inside the facility, and the inside of the facility is covered with a metal halide ^{of 100 μmol·m -2} ·s ^{-1 PPFD for 16 hours.} The method of claim 4,
The carbon dioxide concentration inside the facility is 700 μmol·mol ^-1 , and the relative humidity is 65 to 75%.

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