KR101104094B1 - Culturing device for improving the efficient carbon dioxide enrichment - Google Patents

Abstract

The present invention relates to a cultivator for carbonic acid fertilization efficiency enhancement that can increase the residence time of the carbon dioxide gas in the strawberry cultivation space to maintain the concentration of the set value for a long time to increase the cultivation efficiency, more specifically extending in the longitudinal direction, A bed provided with a cultivation space on an open surface; Wind brakes each extending in a height direction along a longitudinal direction at both side ends of the bed; And a supply pipe disposed to be spaced apart from the surface of the bed and having a plurality of injection holes formed therein, wherein carbon dioxide gas flowing in the gas pipe is injected into the cultivation space of the bed through the injection hole.

Bed, carbon dioxide, injection hole, wind break, strawberry

Description

Culturing device for improving the efficient carbon dioxide enrichment

The present invention relates to a cultivator for improving carbonic acid fertilization efficiency, and more specifically, to increase the residence time of the carbon dioxide gas in the strawberry cultivation space can be maintained for a long time at the concentration of the set value cultivator for carbonic acid fertilization efficiency to increase the cultivation efficiency It is about.

Generally Along with modernization, the economic level has risen and the desire to improve the quality of life has led people to consider quality and freshness in their food choices. The consumption of such horticultural crops has increased as the consumption of vegetables and fruits, which were considered decay, is essential for a healthy diet, and the share of cultivating field crops and horticultural crops has increased gradually in domestic agriculture.

In the case of field crops or horticultural crops, equal production of not only the quality of each individual but also the entire crop quality for production is important for excellent commerciality. If the quality of each product is equal, it is easy to pack and sort the product, guaranteeing a low defect rate, and bringing consumer confidence in the producer, and expecting an increase in brand value. In Korea, since the four seasons are distinct and are affected by climate, much care is required to ensure equality according to the season. Therefore, in order to continuously produce crops of equal quality regardless of seasonal changes, the cultivation of facilities in greenhouses and the like gradually increased, and the cultivation area of the facility increased from 8000 ha in the 1980s to more than 70,000 ha in the 2000s. National Statistical Office, 2008). Facility cultivation has the advantage that the producer can arbitrarily control the conditions necessary for the growth of crops such as humidity, light, gas concentration as well as temperature.

Among various environmental factors, carbon dioxide (carbon dioxide gas, CO ₂ ) is an essential element necessary for crop growth, such as inorganic salts, and is a component consumed in photosynthesis process, unlike temperature and humidity. Carbon dioxide gas is generally present in a concentration of about 300 to 500 ppm in the atmosphere, but as the photosynthesis progresses during the day in a closed space such as a greenhouse, the concentration rapidly decreases to inhibit carbon assimilation of crops. Therefore, in the case of facility cultivation, it is common to supply through separate fertilization as a countermeasure against concentration reduction. Crop production according to carbon dioxide concentration under the same insolation conditions has a saturation point for each crop, the growth slows down rather than a certain concentration. In addition, fertilization of excessive carbon dioxide has an adverse effect such as increased production costs and environmental pollution, so it is necessary to adjust the fertilizer to an appropriate level.

The present invention is to solve the above problems, an object of the present invention is to increase the residence time of the carbon dioxide gas in the strawberry cultivation space can be maintained for a long time at the concentration of the set value for carbonic acid fertilization efficiency enhancement that can increase the cultivation efficiency To provide a planter.

In order to achieve the above object of the present invention,

According to one aspect of the invention,

A bed extending in the longitudinal direction and provided with a cultivation space on an upper open surface;

Wind brakes each extending in a height direction along a longitudinal direction at both side ends of the bed; And

A supply pipe is disposed spaced apart from the surface of the bed, the plurality of injection holes formed on the surface,

There is provided a cultivator for carbonic acid fertilization efficiency enhancement, characterized in that the carbon dioxide gas flowing in the pipe is injected into the cultivation space of the bed through the injection hole.

As described above, re-exhaust for carbonic acid fertilization efficiency according to the present invention can increase the residence time of the carbon dioxide gas in the strawberry cultivation space can be maintained for a long time at the concentration of the set value can increase the cultivation efficiency.

Hereinafter, with reference to the accompanying drawings a cultivator for improving carbonic acid fertilization efficiency according to an embodiment of the present invention will be described in detail. The accompanying drawings show exemplary forms of the present invention, which are provided to explain the present invention in more detail, and the technical scope of the present invention is not limited thereto.

1 is a perspective view illustrating main parts of a cultivator (hereinafter, referred to as a “cultivator”) for improving carbonic acid fertilization efficiency according to an embodiment of the present invention.

The grower 10 according to an embodiment of the present invention includes a bed 11, a wind brake 12 and a supply pipe 20.

Here, the bed 11 is extended in the longitudinal direction, the cultivation space is provided on the surface of the upper open type.

The cultivation space may be provided with a cultivated soil (1) including recesses (∪, 1b) and convex (∩, 1a), the strawberry (2) can be grown on the convex portion (1a) of the cultivated soil (1) have.

In addition, the wind brakes 12 are formed at both side end portions of the bed 11 in the height direction along the longitudinal direction, respectively, and the height of the wind brake 12 is to be formed 20 to 40cm higher from the surface of the bed 11. Preferably about 30 cm. If the height is formed lower than the value can not act as a wind brake 12, a change in the flow field of the air may occur a problem that a large amount of carbon dioxide gas must be supplied to maintain a constant concentration, If the height is formed higher than the value, such as strawberries, crops having a height of about 30 cm may cause problems in that the temperature rise and transpiration are not smooth due to almost no air flow in the colony.

The wind brake 12 may be formed of a resin that is lightweight, durable and has good transparency, but is not limited thereto, for example, from the group consisting of polyethylene, vinyl acetate (EVA) and vinyl chloride (PVC). It may be formed of one or more selected, the thickness may be less than 0.3mm, preferably 0.1 to 0.3mm. If the thickness is larger than the above value, the manufacturing cost increases, and a problem may occur that an additional member for supporting the wind brake may be required.

On the other hand, the cultivator 10 according to an embodiment of the present invention is disposed spaced apart from the surface of the bed, and includes a supply pipe 20 formed with a plurality of injection holes 21 on the surface. Here, the supply pipe 20 may be disposed in the main portion of the cultivated soil, the carbon dioxide gas flowing in the supply pipe 20 is injected into the cultivation space of the bed through the injection hole (21).

In other words, the supply pipe is disposed on the recess, so that carbon dioxide gas is injected onto the back side of the leaf of the plant (for example, strawberry) that is being grown on the convex portion.

In addition, the grower 10 according to an embodiment of the present invention may further include a height adjusting means (not shown) for adjusting the height of the wind brake, wherein the height adjusting means is the wind brake And a driving unit for elevating or lowering 12 and an operating unit for manipulating the driving unit.

In addition, the grower 10 according to an embodiment of the present invention includes a carbon dioxide concentration measurement sensor located in the cultivation space; And it may further include a control unit for adjusting the carbon dioxide gas supply amount by comparing the measured value and the reference value, thereby measuring the carbon dioxide gas concentration in the cultivation space, it can be controlled to maintain the required concentration value.

Example

In this study, Fluent (ver 6.3, Fluent Inc, Lebanon, N.H, USA) was used in CFD commercial software to analyze the concentration of carbon dioxide gas supplied over the strawberry growing bed. The design resources were based on the standard, design type and environmental conditions of the strawberry growing greenhouse.

Among the turbulence models provided by the Fluent program, the most commonly used models for natural ventilation flow analysis in greenhouses include the standard k-ε model, renormalization-group (RNG) k-ε model, realizable k-ε model, and Reynolds stress model (RSM). (Fluent, 2007). The basic form of these models is similar, but there are differences in how viscous turbulences are calculated, the number of franchises that determine the turbulent spread of k and ε, and the conditions of formation and extinction in the turbulent diffusion equation. In this study, the RNG k-ε model was selected to calculate the viscous effect according to the small Reynolds number.

The cultivator is configured so that the cultivation space of the bed is 870 mm apart from the floor, the width is 270 mm, and the length is 1020 mm.

In the center of the bed, a circular cross-section feed pipe was designed to pass carbon dioxide directly near the crop, and a carbon dioxide gas was injected through the nozzle at intervals of about 20 cm above the feed pipe. Polyethylene wind brakes were installed on both sides of the bed to reduce the amount of carbon dioxide lost by the wind speed and to increase the gas concentration supplied to the strawberries.

The room temperature was set at 23 ° C, and the average carbon dioxide concentration of the wind velocity flowing from the upper side and the concentration supplied from the injection hole were set to 400 ppm and 1000 ppm, respectively, according to the environmental conditions of the general greenhouse.

In addition, the injection speed of the carbon dioxide gas in the injection hole was set to 0.3 m / s, the wind speed was set to 0.5, 1.0 and 1.5 m / s, respectively.

In order to investigate the effects of carbon dioxide preservation according to the height of the wind brake installation, the variables of the average wind speed and the height of the wind brake in the facility were used as variables. Assuming that the average indoor wind speed caused by the ventilation inside the greenhouse is 1.0 m / s, the structure under the wind speed condition of 0.5 m / s 1.0 m / s 1.5 m / s was analyzed, and the height of the wind brake was not installed. Cases (0 cm), 15 cm, and 30 cm were installed in each of the nine environmental conditions were calculated in a steady state. The nine environmental conditions are as follows.

[Table 1]

division Height of wind brake 0 cm 15 cm 30 cm Wind speed 0.5 m / s case A case B case C 1.0 m / s case D case E case F 1.5 m / s case G case H case I

In order to understand the carbon dioxide preservation effect according to the installation height of the wind brake, the air flow inside the facility was examined for each structure, and the wind speed reduction effect was established. The pressure distribution analysis was then used to determine the rationality of non-uniform air flow, such as the formation of vortices at some locations, and then analyzed the carbon dioxide concentration on the bed. Then, based on these results, the appropriate concentration of carbon dioxide gas required for strawberry growth was determined to be 600 to 800 ppm, and the proper installation height of the wind brake in the designed greenhouse was derived.

Figure 2 shows the air flow field in the CFD measurement results, showing the wind speed distribution on the bed.

Comparing structures D, E, and F, structure D has the air injected from the nozzle toward the left side, while structures E and F have the air injected from the nozzle toward the right. The cause is the difference in flow velocity from the downwind side to the windscreen and over the bed. The average air velocity of air flowing over the bed calculated in the simulation is 0.09 m / s for the structure D, 0.18 m / s for the structure E, and 0.30 m / s for the structure F. When the incoming air collides with 0.3 m / s, which is injected from the nozzle, it shows a different direction of progress depending on which wind direction is the superior wind direction. In the case of the structure D, the inflow air fell to the right side smaller than the speed of the nozzle injection, and in the case of the structures E and F, the inflow air flowed toward the left side of the injection hole at the wind speed enough to overcome the nozzle injection air. Therefore, it can be seen that the direction of injection of carbon dioxide gas is different depending on the wind speed.

In the case of G, H, and I, which have a 30 cm-high windshield installed, there is a flow that flows over the windshield on the lower side of the wind. It affected the flow of carbon dioxide gas from the surrounding air and the nozzle. Therefore, the installation of the 30 cm high windscreen showed a greater effect of preserving carbon dioxide gas on the bed than the 15 cm high windscreen.

In addition, the average wind speed on the bed is shown in the following [Table 2].

TABLE 2

division Weed Brake Height 0 cm 5 cm 10 cm 15 cm 30 cm Wind speed 0.5 m / s - 50 20.5 9.1 9.1 1.0 m / s - 46.1 13.5 5.6 5.6 1.5 m / s - 46.6 14.3 7.5 4.5 Average - 47.6 16.1 7.4 6.4

In all structures, the wind speed was reduced by 93% on average when the windscreen was installed with a height of 15 cm compared to the case where no windscreen was installed, but the installation effect was excellent. However, when a 30cm windscreen was installed, the height was 15 cm. On average, an additional 1% is being reduced, gradually reducing the effect on installation costs. This is because the effect of the height of the windscreen installation does not increase linearly, it was confirmed that an appropriate level of installation height should be selected considering the installation cost.

Figure 3 shows the distribution of carbon dioxide concentration on the bed of the CFD analysis results, on the average 15 cm in height of the installation of the wind brakes had an effect of increasing the carbon dioxide concentration of about 10 times compared to the non-wind brake installation, at an installation height of 30 cm It was found that the wind brake installation is effective for preserving the carbon dioxide concentration because it has an increase effect of about 18 times compared with the non-installation. Preserved carbon dioxide gas, while the difference between wind speeds of 1.0 m / s and 1.5 m / s at the same wind brake height was not as prominent as the 2% change in the air flow field discussed earlier. When the concentrations were compared, the increase in the preservation effect was more obvious at 80%.

Strawberry is generally known to have the highest photosynthesis when the carbon dioxide concentration is 600 to 800 ppm under the same insolation conditions. Therefore, the concentration of carbon dioxide in greenhouses with an average indoor wind speed of 1.0 m / s is assumed to be 650. It was found that a 30 cm wind brake installation suitable for storing about ppm was suitable.

Preferred embodiments of the present invention described above are disclosed for purposes of illustration, and those skilled in the art having various ordinary knowledge of the present invention may make various modifications, changes, and additions within the spirit and scope of the present invention. And additions should be considered to be within the scope of the following claims.

1 is a perspective view showing a main part showing a cultivator for improving carbonic acid fertilization efficiency according to an embodiment of the present invention.

Figure 2 is a graph showing the air flow field of Figure 2 CFD measurement results.

Figure 3 is a graph showing the carbon dioxide concentration distribution on the bed of the CFD analysis results.

Claims (6)

A bed extending in the longitudinal direction and provided with a cultivation space on an upper open surface; Wind brakes each extending in a height direction along a longitudinal direction at both side ends of the bed; A supply pipe spaced apart from the surface of the bed and having a plurality of injection holes formed on the surface thereof; A carbon dioxide concentration measurement sensor located in the cultivation space; And It includes a control unit for adjusting the carbon dioxide gas supply amount by comparing the measured value and the reference value, And a carbon dioxide gas flowing in the pipe is injected into the cultivation space of the bed through the injection hole. The method of claim 1, The height of the wind brake is a cultivator for carbonic acid fertilization efficiency enhancement, characterized in that 20 to 40cm. The method of claim 1, The wind brake is a cultivator for carbonic acid fertilization efficiency enhancement, characterized in that formed of at least one selected from the group consisting of polyethylene, polyvinyl chloride and vinyl acetate. The method of claim 1, Located in the cultivation space, and further comprising cultivated soil including recesses and convex, Strawberry is grown on the convexity of the cultivated soil, the planting apparatus for carbonic acid fertilization efficiency enhancement, characterized in that the supply pipe is disposed in the recess of the cultivated soil. The method of claim 1, Further comprising a height adjustment means for adjusting the height of the wind brake, The height adjusting means, the cultivator for carbonic acid fertilization efficiency enhancement, characterized in that it comprises a drive for raising or lowering the wind brake and the operation for operating the drive. delete

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