JP2013094156A - Greenhouse cultivation method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a greenhouse cultivation method by which the various functions of carbon dioxide can suitably and efficiently be utilized.SOLUTION: The greenhouse cultivation method for supplying carbon dioxide from the outside to adjust the concentration of the carbon dioxide in the greenhouse for the growth of plants is characterized in that: two or more carbon dioxide concentration regions are formed to a time axis in a range exceeding 400 ppm on the adjustment of the carbon dioxide in the greenhouse; and the two or more carbon dioxide concentration regions do not overlap each other, express specific functions in the concentration regions, respectively, and include a concentration region for expressing a bird damage-repelling function and/or an insect pest -repelling function except a concentration region for expressing a plant growth-promoting function.

Description

  The present invention relates to a greenhouse cultivation method, and more particularly, to a greenhouse cultivation method for growing plants by adjusting the carbon dioxide concentration in the greenhouse by supplying carbon dioxide from the outside.

  In Patent Document 1, in order to solve the problem that the carbon dioxide in the plant cultivation house is insufficient and adversely affects the growth of the plant, the carbon dioxide concentration in the plant cultivation house is less than a predetermined lower limit value. In addition, it is described that carbon dioxide is supplied into the plant cultivation house, and control for terminating the supply of carbon dioxide is performed when a predetermined upper limit value is exceeded.

JP 2010-124802 A

  The inventor has conducted research on the function of carbon dioxide in plant cultivation.

  As a result, it has been found that carbon dioxide can express various functions effective for plant cultivation, such as the promotion of plant growth and the repellent function of pests and predators, depending on the concentration.

  At this time, it was found that a preferable concentration range for expressing one function does not necessarily coincide with a preferable concentration range for expressing another function.

  For example, it was confirmed that a carbon dioxide concentration range suitable for the expression of the repellent function of pests and predatory birds, on the other hand, may inhibit the expression of the plant growth promoting function.

  The present inventor has further earnestly studied a method for effectively and effectively using various functions of carbon dioxide, and has reached the present invention.

  Then, the subject of this invention is providing the greenhouse cultivation method which can each effectively utilize the various functions which a carbon dioxide has.

  Other problems of the present invention will become apparent from the following description.

  The above problems are solved by the following inventions.

(Claim 1)
In the greenhouse cultivation method of growing plants by adjusting the carbon dioxide concentration in the greenhouse by supplying carbon dioxide from the outside,
When adjusting the carbon dioxide concentration in the greenhouse, in the range exceeding 400 ppm, form a carbon dioxide concentration region of 2 or more with respect to the time axis,
The two or more carbon dioxide concentration ranges do not overlap each other and express a function specific to each concentration range, and in addition to a concentration range that expresses a plant growth promoting function, a concentration range that expresses a pest repellent function And the greenhouse cultivation method characterized by including the density | concentration range which expresses the repellent function of a pest.
(Claim 2)
2. The greenhouse cultivation method according to claim 1, wherein the concentration range expressing the repellent function of pests and / or the repellent function of pests is a higher concentration range than the concentration range expressing the plant growth function.
(Claim 3)
When forming the carbon dioxide concentration region, carbon dioxide separated from biogas obtained by biomass fermentation and / or carbon dioxide contained in exhaust gas combusted with biogas is used. The greenhouse cultivation method according to 1 or 2.

  ADVANTAGE OF THE INVENTION According to this invention, the greenhouse cultivation method which can each effectively utilize the various functions which a carbon dioxide has can be provided.

The figure which shows an example of the timing chart used in order to implement the greenhouse cultivation method of this invention The figure explaining an example of schematic structure of the control apparatus for enforcing the greenhouse cultivation method of this invention

  In the greenhouse cultivation method for growing plants, the present invention forms two or more carbon dioxide concentration regions with respect to the time axis when adjusting the carbon dioxide concentration in the greenhouse.

  In the present invention, the two or more carbon dioxide concentration ranges do not overlap with each other and express functions peculiar to each concentration range. In addition to the concentration range that expresses the plant growth promoting function, the repelling function of harmful birds is provided. It includes a concentration range that expresses and / or a concentration range that expresses a pest repellent function.

  Such a concentration range configuration is effective in dealing with a case where a preferable concentration range for expressing one function does not necessarily match a preferable concentration range for expressing another function.

  That is, according to the present invention, by forming two or more carbon dioxide concentration ranges with respect to the time axis, the concentration range for expressing one function does not continue the state of inhibiting the expression of other functions. This makes it possible to effectively use various functions of carbon dioxide in each concentration range.

  The present inventor, for example, has a relatively high concentration range suitable for the expression of the repellent function of pests and predators, and a relatively low concentration range suitable for the expression of the plant growth promoting function. Continuing the concentration range suitable for the knowledge that they are different and the expression of the repellent function of pests and predators not only makes it difficult for the plant to promote growth, but also may cause abnormal growth in the plant. I found the knowledge.

  Based on this knowledge, the present inventor forms a carbon dioxide concentration range of 2 or more with respect to the time axis when adjusting the carbon dioxide concentration in the greenhouse, thereby expressing the repelling function of pests and predators. It is possible to adjust the carbon dioxide concentration in the greenhouse so that the concentration range is suitable for expression of the plant growth promoting function by rounding up the concentration range suitable for plant pests and predatory birds. It was confirmed by a test that both the function and the plant growth promoting function can be effectively used effectively, and the present invention has been achieved.

  In the present invention, the two or more carbon dioxide concentration regions are formed in a concentration in the outside air, that is, a concentration exceeding the normal carbon dioxide concentration (350 ppm to 400 ppm) in air, that is, a concentration range exceeding 400 ppm.

  In the present invention, the two or more carbon dioxide concentration ranges are formed so as not to overlap each other by defining at least one of the upper limit and the lower limit, or both by a predetermined concentration.

  In the cultivation method of the present invention, for example, when adjusting the carbon dioxide concentration in the greenhouse, a timing chart set in advance such that two or more carbon dioxide concentration regions are continued for each predetermined time with respect to the time axis, etc. It can implement suitably by considering.

  FIG. 1 is a diagram illustrating an example of a timing chart.

In the example of FIG. 1, the three concentration ranges C1 to C3 and the carbon dioxide concentration C _Air in the outside air are set so as to be continued for a predetermined time, respectively, in a one-day cycle.

  In the example of FIG. 1, the three concentration ranges C1 to C3 are each a concentration range C1 of carbon dioxide for favorably expressing the function of promoting plant growth, and dioxide dioxide for favorably expressing the repelling function of pests. This corresponds to the carbon concentration range C2 and the carbon dioxide concentration range C3 for suitably expressing the repelling function of harmful birds.

  Hereinafter, an example of setting a preferable density range in the present invention will be described. In the following description, the specific concentration of carbon dioxide refers to the concentration when carbon dioxide is uniformly dispersed in the greenhouse.

In the present invention, the carbon dioxide concentration range C1 for suitably expressing the function of promoting plant growth is preferably 0.050% or more and 0.20% or less in a time zone in which photosynthesis is relatively active. It is to be set within the range. On the other hand, it is preferable that the time zone when photosynthesis is not relatively active is the outside air concentration C _Air of about 0.035% to 0.040%. Here, the time when photosynthesis is relatively active is usually daytime, and the time zone when photosynthesis is not relatively active is usually nighttime, but when cultivating under controlled light irradiation conditions etc. It is not limited to this, and it is preferable to set appropriately according to the control. Oxygen respiration by plants can be promoted by the outside air concentration C _Air during a time period in which photosynthesis is not relatively active.

  The carbon dioxide concentration range for suitably expressing the function of promoting plant growth may vary depending on the type of plant to be cultivated, fertilization conditions, etc. it can.

  On the other hand, the carbon dioxide concentration ranges C2 and C3 for suitably expressing the repellent function of pests and harmful birds are higher than the carbon dioxide concentration range C1 for suitably expressing the function of promoting plant growth. Exists.

  In the present invention, the carbon dioxide concentration range C2 for suitably expressing the pest repellent function is preferably in the range of 0.5% to 5%, more preferably in the range of 1% to less than 3%. Is to be set. The concentration range C2 is preferably maintained in the range of 1 to 10 hours, more preferably in the range of 3 to 7 hours. Here, the pests are not particularly limited, but preferred examples include beetle larvae (strawberry buoys) against strawberries, whiteflies against tomatoes, ticks such as spider mites and tomato rust mites. The optimum conditions may vary depending on the type of pest, but can be set as appropriate by conducting a test or the like in advance.

  In the present invention, the concentration range C3 of carbon dioxide for suitably expressing the repelling function of harmful birds is preferably set in the range of 3% to 7%, more preferably in the range of 4% to 5%. Is Rukoto. The concentration range C3 is preferably maintained in the range of 1 minute to 1 hour, more preferably in the range of 5 minutes to 30 minutes. Here, the harmful birds are not particularly limited, but preferred are birds such as starlings that prey on pollinating insects such as insect retina moths (bees), and birds that cause damage to cultivated plants. It can be illustrated. The optimum conditions may vary depending on the type of pest, but can be set as appropriate by conducting a test or the like in advance.

The carbon dioxide concentration in the greenhouse is, for example, a carbon dioxide concentration range C1 for favorably expressing the function of promoting plant growth in the daytime in the normal period, and the outside air concentration C _Air at night. A concentration range C2 of carbon dioxide for suitably expressing the repellent function of pests at a frequency of about 0.2 to 2 times per day, and a repellent function of pests at a frequency of about 1 to 10 times per day The carbon dioxide concentration range C3 for suitably expressing the above can be obtained.

  FIG. 2 is a diagram illustrating an example of a schematic configuration of a control device for carrying out the cultivation method of the present invention.

  In FIG. 2, 1 is a greenhouse for growing plants, 2 is a concentration measuring means for measuring the carbon dioxide concentration in the greenhouse 1, 3 is a control device for controlling the carbon dioxide concentration in the greenhouse 1, and 4 is a greenhouse 1 It is a concentration adjusting means for adjusting the carbon dioxide concentration in the inside.

  The control device 3 includes a control unit 31 and a memory 32 that stores a timing chart as shown in FIG.

  The control unit 31 refers to the monitoring value of the carbon dioxide concentration in the greenhouse 1 input from the concentration measuring means 2 and the concentration range indicated in the timing chart of the memory 32, and the monitoring value is indicated in the timing chart. The density adjusting means 4 is operated so as to be in the density range.

  Specifically, the concentration adjusting means 4 is a means for executing a method for increasing or decreasing the carbon dioxide concentration in the greenhouse 1, and the method is not particularly limited in the present invention.

  Increasing the carbon dioxide concentration in the greenhouse can be preferably realized by supplying a gas having a higher carbon dioxide concentration than in the greenhouse by a blowing means such as a blower. Alternatively, a chemical reaction may be generated in the greenhouse to generate carbon dioxide, or carbon dioxide may be released from a liquid containing carbon dioxide. The carbon dioxide used for raising the carbon dioxide concentration in the greenhouse will be described in detail later, but preferably contains carbon dioxide derived from biogas obtained by fermentation of biomass.

  On the other hand, when lowering the carbon dioxide concentration in the greenhouse, it can be realized by utilizing the fact that carbon dioxide in the greenhouse is naturally consumed by metabolic reactions of plants, etc. However, it is preferable to forcibly lower the carbon dioxide concentration by supplying a gas (air or the like) having a low carbon dioxide concentration.

  Conventionally, a method of forcibly lowering the concentration of carbon dioxide after supplying carbon dioxide has not been used from the viewpoint of consuming the supplied carbon dioxide to a plant for effective use. On the other hand, in the present invention, since the preferable carbon dioxide concentration for expressing one function does not overlap with the preferable concentration for expressing another function, the carbon dioxide concentration is forcibly set. By lowering, the transition between the respective concentration ranges is performed quickly, and various functions of carbon dioxide can be effectively and effectively utilized.

  As a method of supplying gas having a lower carbon dioxide concentration than in the greenhouse, it is possible to simply open the ventilation port and take in the outside air by natural convection, but in order to lower the carbon dioxide concentration more forcibly, a blower, etc. It is preferable to blow the outside air or a gas whose carbon dioxide concentration is higher than the outside air and lower than the inside of the greenhouse into the greenhouse.

  In the present invention, for example, the carbon dioxide concentration range C1 for suitably expressing the function of promoting plant growth and the carbon dioxide concentration range C2 for suitably expressing the pest repellent function are preliminarily shown in the time chart. It is set, and when the entry of a harmful bird into the greenhouse is detected, the control according to the timing chart is interrupted so that the carbon dioxide concentration range C3 for suitably expressing the harmful bird repelling function for a predetermined time is set. It is also preferable to control this.

  In this example, the control for shifting the three concentration ranges C1 to C3 is exemplified, but the present invention is not necessarily limited to this, and may be one for shifting the concentration range of 2 or 4 or more.

  When performing two or more steps of changing the carbon dioxide concentration to a high concentration of preferably 3% or more, such as the manifestation of a repellent function of pests or harmful birds, it is performed at predetermined time intervals, preferably at intervals of 1 hour or more. It is preferable from the viewpoint of more reliably preventing plant growth inhibition.

  In the present invention, from a relatively high concentration side concentration range, such as when expressing a repellent function of a pest or a harmful bird, toward a relatively low concentration side concentration range, such as when expressing a plant growth promoting function. In the case of changing the carbon dioxide concentration in the greenhouse, in particular, a gas having a lower carbon dioxide concentration than that in the greenhouse may be supplied to forcibly reduce the carbon dioxide concentration. This is because it is preferable from the viewpoint of more reliably preventing plant growth inhibition by high-concentration carbon dioxide.

  In addition, when changing the carbon dioxide concentration to a high concentration of 3% or more, such as the manifestation of the repellent function of pests or birds, protect the pollinating insects from carbon dioxide by isolating them from the air in the greenhouse. Is preferred.

  In the above description, the concentration of carbon dioxide is the concentration when carbon dioxide is uniformly dispersed in the greenhouse. In the present invention, the concentration of carbon dioxide is, for example, the concentration at a specific observation point in the greenhouse, Alternatively, it can be defined based on the amount of carbon dioxide supplied and the concentration calculated from the volume in the greenhouse (for example, the concentration when carbon dioxide is uniformly dispersed in the greenhouse), etc. Any standard may be used as long as it is consistent with the concentration range shown in the timing chart to be referred to.

  In the present invention, the carbon dioxide used when forming the carbon dioxide concentration range is not particularly limited, but (A) carbon dioxide separated from biogas obtained by fermentation of biomass and / or (B) biogas It is preferable to use carbon dioxide contained in the exhaust gas combusted.

  Carbon dioxide derived from biogas is so-called carbon neutral, and even if it is released into the atmosphere, it does not mean that greenhouse gas has been newly released. In particular, in the present invention, since carbon dioxide is effectively utilized (absorbed) by plants, even if unused carbon dioxide is released to the atmosphere, it has an extremely excellent environmental adaptability.

  In addition, if it is derived from biogas, carbon dioxide for increasing the concentration of carbon dioxide can be suitably covered even when a large amount of carbon dioxide needs to be supplied, such as the manifestation of the repellent function of pests or birds. Furthermore, for example, an effect that impurities such as carbon monoxide due to incomplete combustion are hardly contained like an exhaust gas obtained by directly burning biomass can be obtained.

  The case where carbon dioxide separated from the biogas obtained by (A) biomass fermentation is used will be specifically described in detail.

  The method for separating carbon dioxide from biogas is not particularly limited, and a method in which carbon dioxide in biogas is dissolved and separated in a liquid such as water or fermentation liquid (digested liquid) by gas-liquid contact is preferable. It can be illustrated. The carbon dioxide dissolved in the liquid in this way may be supplied into the greenhouse after being separated from the liquid, or may be supplied into the greenhouse as the liquid and diffused and supplied in the greenhouse. .

  In the present invention, it is possible to improve the efficiency of dissolution and release by setting conditions so that the solubility of carbon dioxide is relatively large when contacting gas and liquid, and the solubility of carbon dioxide is relatively small when releasing. preferable. As conditions for changing the setting in order to change the solubility, it is preferable to use pH, electric potential, etc. in addition to temperature and pressure from the viewpoint of further improving the efficiency of dissolution and dissipation. It is also preferable to further promote dissolution and diffusion by combining these plural conditions. In the present invention, it may be necessary to supply a large amount of carbon dioxide in a short time, such as the manifestation of the repellent function of insect pests or birds, but carbon dioxide is suitably covered by improving the efficiency of dissolution and release. The effect which becomes possible is produced.

  Specifically, for example, when contacting with gas and liquid, the solubility in the liquid of carbon dioxide is improved by contacting with gas and liquid under pressure in the range of preferably 0.15 MPa or more and less than 1.00 MPa, and then released. Sometimes lowering the pressure can lower the solubility and promote release.

  Also, for example, at the time of gas-liquid contact, by reducing the hydrogen ion concentration of the liquid by dialysis, the solubility of carbon dioxide in the liquid is increased, and then the hydrogen ion concentration of the liquid at the time of release is increased. By raising it, the solubility can be lowered and the emission can be promoted. Slow-speed electrodialysis is a suitable means for this purpose.

  In the present invention, it is preferable to perform a hydrogen sulfide removal treatment from the viewpoint of preventing hydrogen sulfide derived from biogas from entering the greenhouse. Hydrogen sulfide removal treatment may be provided for either biogas before separation of carbon dioxide from biogas or carbon dioxide after separation from biogas, but preferably carbon dioxide is separated from biogas. The hydrogen sulfide in the biogas should be removed before starting. Although it does not specifically limit as a hydrogen sulfide removal process, The biological desulfurization process using a biological desulfurization tower etc. can be illustrated preferably. It is also preferable to perform desulfurization with a hydrogen sulfide concentration of sub-ppm, and such a technique has already been technically established, for example, for application of biogas to a fuel cell. Although not particularly limited, for example, the desulfurization techniques described in Japanese Patent Application Laid-Open Nos. 2008-127407, 2008-13649, 2007-106900, 2006-282826, and the like can be preferably used.

  Next, (B) the case where carbon dioxide contained in the exhaust gas burned with biogas is used will be described in detail.

  Carbon dioxide contained in the exhaust gas produced by burning biogas includes carbon dioxide produced by combustion of fuel gas such as methane in addition to carbon dioxide originally contained in biogas.

  Carbon dioxide can be supplied to the greenhouse after it has been separated from the exhaust gas, but since substances undesirable for plant growth such as methane and hydrogen sulfide in biogas are decomposed by combustion, they can also be supplied as exhaust gas. This is preferable.

  Also in the case of (B), it is preferable that the biogas before combustion is provided in advance to the hydrogen sulfide removal treatment in the same manner as in the above (A). It is because it can prevent suitably that sulfur dioxide arises in the exhaust gas after combustion by removing the hydrogen sulfide in the biogas before combustion.

  In addition, about sulfur dioxide, it is generally known as a harmful substance for plants, and in the present invention, it is preferable to reduce it to the ppb level. As described above, hydrogen sulfide removal treatment that can realize this is performed. Preferably it is done. A trace amount of sulfur dioxide can also be used as a measure against pests, but in general, prolonged aeration may adversely affect crops.

  In the case of (B), hydrogen sulfide is not limited to be removed at the biogas stage. For example, sulfur dioxide, which is an oxide of hydrogen sulfide, is removed from the gas after burning the biogas. Can also be supplied to the greenhouse. It is also preferable to combine the removal of hydrogen sulfide and the removal of sulfur dioxide from the viewpoint of reliably preventing inhibition of plant growth.

  In the case of (B), the carbon dioxide originally contained in the biogas is usually separated and removed to increase the calorie of the biogas, but in the present invention, it is effectively used for plant cultivation. In view of the above, it is preferable to burn without containing the carbon dioxide originally contained in the biogas without providing the carbon dioxide separation and removal step. In particular, if the combustion means for burning biogas is a heat generating device such as a gas boiler, even biogas that has not been subjected to carbon dioxide separation and removal can be suitably used. It is also preferable in the present invention to warm the greenhouse using the heat energy generated by the heat generating device.

  In the case of (A) and / or (B) described above, the biomass as a fermentation raw material for producing biogas is not particularly limited, but the waste part of the plant cultivated in the greenhouse ( Non-edible parts etc.) can be preferably used. In the present invention, for example, using a specified biomass such as a non-edible part such as a tomato leaf produced in tomato cultivation can easily adjust the carbon / nitrogen ratio (C / N ratio) in the fermentation raw material. Is preferable.

  In the present invention, the carbon dioxide to be supplied into the greenhouse is preferably stored by the storage means, so that it can be quickly supplied into the greenhouse as required for control. As the storage means, for example, a gas holder can be used if carbon dioxide is stored as gas, and a storage tank can be used if stored in a state dissolved in a liquid.

  In the present invention, the greenhouse in which plants are cultivated only needs to be shielded from the outside air to such an extent that the difference in carbon dioxide concentration from the outside air can be maintained, and is not necessarily in a completely sealed state.

  In the present invention, the greenhouse for cultivating plants is not particularly limited, and a house covered with a resin sheet or the like, a general greenhouse or the like can be preferably exemplified.

  The cultivated plant to which the present invention can be applied is not particularly limited, and is not limited to vegetables such as tomatoes, but preferably cereals and fruit trees.

  In the present invention, for example, a plurality of greenhouses that are shielded from each other are formed in one house, and carbon dioxide is supplied to each greenhouse to prevent uneven distribution of the supplied carbon dioxide. This is preferable from the viewpoint. Thereby, even if it is a density | concentration change especially in a short time, the effect that a function can be expressed more reliably is acquired.

  In the present invention, the volume in the greenhouse is not particularly limited, and can be applied, for example, from a test tube level to a huge cultivation facility having a site area of several hundred ha or more. When the volume is large, for example, it is also preferable to supply carbon dioxide from a plurality of carbon dioxide supply means arranged in a distributed manner to one greenhouse.

  Examples of the present invention will be described below, but the present invention is not limited to such examples.

Example 1
The effect of carbon dioxide concentration on pests and pests was examined, and it was verified that the carbon dioxide concentration that suitably expressed the repelling function was different between pests and pests.

1. Effect of carbon dioxide concentration on pests [Test 1]
Carbon dioxide was supplied into a small greenhouse for plant cultivation, and the indoor carbon dioxide concentration was kept at 1%. The carbon dioxide concentration was measured by the Orzart method after carbon dioxide was uniformly dispersed in a small greenhouse.

  Changes in the total average number of pests such as spider mites and tomato rust mites adhering to the tomato leaflets were measured over time.

[Test 2]
In Test 1, mites were measured in the same manner as Test 1 except that the indoor carbon dioxide concentration was maintained at 3%.

[Test 3]
In Test 1, mites were measured in the same manner as Test 1 except that the indoor carbon dioxide concentration was kept at 4%.

[Test 4]
In Test 1, mites were measured in the same manner as Test 1 except that the indoor carbon dioxide concentration was maintained at 5%.

  The results of tests 1 to 4 are shown in Table 1.

<Evaluation>
It can be seen that the expression state of the pest repellent function changes with the concentration of carbon dioxide in the greenhouse. It can be seen that a sufficient repellent effect can be obtained in a relatively short time at a high concentration, whereas a relatively long time is required at a low concentration.

  In addition, when the carbon dioxide concentration in the greenhouse was less than 1%, the repellent function of pests did not remarkably appear, and discoloration was observed in some leaves when the concentration exceeding 5% was maintained for 10 hours or more.

  Since pests move slowly, the repellent effect tends to require a longer time compared to the repellent effect of birds, which will be described later. Considering the growth inhibition on plants, the concentration is in the range of 1% to less than 3%. It can be judged that it is preferable to carry out with this.

2. Effects of carbon dioxide concentration on harmful birds The bird cages were covered with a polyethylene sheet opened in one direction, and the repelling behavior of the birds gathering in the cages was observed.

  Birds were found to be repellent when exposed to more than 3% carbon dioxide-containing gas. It was confirmed that more rapid repellent behavior was achieved by adjusting the concentration to 4-5%.

  It was confirmed that a sufficient effect was observed in 1 minute for maintaining the concentration, and a remarkable effect was obtained in about 5 minutes to several tens of minutes (about 30 minutes).

<Evaluation>
For pests, it is confirmed that the effect can be obtained in a short time compared to the pest repellent behavior, and if it is such a short time, the effect on the plant is very small, so 4% or more and 5% or less It can be judged that it is preferable to carry out at a concentration in the range of.

3. Difference in carbon dioxide concentration that preferably expresses repelling function From the comparison of the evaluation results of “1. Effect of carbon dioxide concentration on pests” and “2. Effect of carbon dioxide concentration on harmful birds” It can be seen that the carbon dioxide concentration expressed differs between pests and pests.

  In addition, it is an additional experiment that the carbon dioxide concentration that suitably expresses the pest or bird repellent function is located higher than the carbon dioxide concentration suitable for promoting the growth of plants and is different. Confirmed by

1: Greenhouse 2: Concentration measuring means 3: Control device 31: Control unit 32: Memory 4: Concentration adjusting means C1 to C3: Carbon dioxide concentration range C _Air : Carbon dioxide concentration in the outside air

Claims (3)

In the greenhouse cultivation method of growing plants by adjusting the carbon dioxide concentration in the greenhouse by supplying carbon dioxide from the outside,
When adjusting the carbon dioxide concentration in the greenhouse, in the range exceeding 400 ppm, form a carbon dioxide concentration region of 2 or more with respect to the time axis,
The two or more carbon dioxide concentration ranges do not overlap each other and express a function specific to each concentration range, and in addition to a concentration range that expresses a plant growth promoting function, a concentration range that expresses a pest repellent function And the greenhouse cultivation method characterized by including the density | concentration range which expresses the repellent function of a pest.   2. The greenhouse cultivation method according to claim 1, wherein the concentration range expressing the repellent function of pests and / or the repellent function of pests is a higher concentration range than the concentration range expressing the plant growth function.   When forming the carbon dioxide concentration region, carbon dioxide separated from biogas obtained by biomass fermentation and / or carbon dioxide contained in exhaust gas combusted with biogas is used. The greenhouse cultivation method according to 1 or 2.

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