KR20140059370A - Apparatus for storaging plant - Google Patents

Abstract

An apparatus for storing plants of the present invention comprises: a storage container for storing the plants at a low temperature; and a growth adjusting unit connected to the storage container for equalizing the photosynthesis and the respiration of the plants. The present invention: maintains the temperature inside the storage container at a low temperature for a long time, thereby reducing the photosynthesis of the plants; adjusts and controls luminous intensity of a light emitting member for equalizing the photosynthesis and the respiration of the plants and maintaining a light compensation level for a long time, thereby minimizing the photosynthesis of the plants, equalizing the respiration of the plants with the photosynthesis, and maintaining the quality of the plants for a long time by maximally controlling the growth of the plants.

Description

Apparatus for storaging plant

The present invention relates to a plant storage device, and more particularly, to a plant storage device that suppresses plant growth as much as possible in order to maintain the quality of the plant.

Generally, grafted seedlings are a technique used for stable production because of their high resistance to roots by being tied with crops of a desired crop and root resistance.

As an example, when tomatoes, watermelons and melons are cultivated in soil, many grafted seedlings are used, but the time of planting is almost constant and a large number of grafted seedlings are needed at one time.

However, when the seedlings are specialized, the space for cultivation is limited, and at times when the demand for grafted seedlings reaches the peak, supply is always less than demand.

However, there are limitations in the supply of large numbers of grafted seedlings due to various difficulties during a certain period of this formal period.

It is an object of the present invention to provide a plant storage device which is stored at a low temperature so as to minimize the plant growth to maintain the quality of the plant and adjusts the light intensity to the optical compensation point in order to maintain the quality of the plant .

According to an aspect of the present invention, there is provided a plant storage device comprising: a storage container in which plants are housed at low temperatures; And a growth regulating means connected to the storage container, the plant regulating means being configured such that the photosynthesis amount and the respiration amount of the plant become equal to each other.

Specifically, the growth regulating means comprises: a sensing unit for sensing a relative size of a photosynthesis amount and a respiration amount of a plant; And an adjustment control unit for adjusting a photosynthesis amount and a respiration amount of the plant according to the detection result of the sensing unit.

Here, the sensing unit may include: a gas supply line for supplying carbon dioxide to the storage container at a predetermined concentration; A gas discharge line through which carbon dioxide is discharged from the storage container; And a concentration measuring sensor for measuring a concentration of carbon dioxide supplied and discharged to the gas discharge line.

Further, the adjustment control unit may include: a light emitting member for emitting light to the plant; And a control member electrically connected to the concentration measuring sensor and the light emitting member, respectively, for controlling the luminous intensity of the light emitting member according to the concentration of the carbon dioxide.

In this case, the control member may include a power supply for supplying power to the light emitting member, the power supply for controlling the voltage; And a controller electrically connected to the concentration measuring sensor and the power supply, respectively, for controlling the supply voltage of the power supply by comparing the concentration of carbon dioxide supplied to the storage container with the measured value of the concentration measuring sensor .

The plant storage apparatus according to the present invention reduces the amount of photosynthesis of plants by maintaining the interior of the storage vessel at a low temperature for a long period of time and at the same time controls the luminous intensity of the light emitting member so that the photosynthesis amount and the respiration amount of the plant become equal, , Minimizing the photosynthesis of plants, and thus having the same amount of respiration, the plants are inhibited as much as possible, thereby maintaining long-term quality.

1 is a schematic view showing a plant storage apparatus according to a preferred embodiment of the present invention.
FIG. 2 is a graph showing the concentration and luminous intensity of carbon dioxide for each light source when plants in the plant storage device of FIG. 1 are maintained at a light compensation point for a long period.

The plant storage device of the present invention is characterized in that the plant is stored at a low temperature so as to minimize the plant growth to maintain the quality of the plant, and the light intensity is adjusted to the optical compensation point.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a schematic view showing a plant storage apparatus according to a preferred embodiment of the present invention.

Referring to the drawings, the present invention includes a storage vessel 10 in which a plant 1 is accommodated, and a growth regulating means for regulating the growth of the plant 1 in the storage vessel 10.

Here, the plant (1) can be applied to any plant (1) including grafted seedlings, and since the growth regulating means does not deteriorate the quality over a long period of time by controlling the growth of the plant (1) So that a large amount of supply can be made.

Here, the storage container 10 has a proper space for accommodating the plant 1 therein, and the specific structure and arrangement of the storage container 10 are not limited to the present invention.

At this time, the interior of the storage container 10 may be configured to maintain a low temperature state.

The higher the temperature of the plant (1), the more active the photosynthesis becomes, so that the quality of the plant (1) may gradually decrease with time.

To prevent this, the present invention can be configured to lower the temperature inside the storage vessel 10 in order to reduce photosynthesis activity to minimize the growth on the growth side of the plant (1).

In order to lower the temperature in the storage container 10, a cooler or the like may be mounted on the storage container 10 and driven. The cooling device for cooling the cooler and the cooling control for the cooling device are not limited to the present invention, Of course, can be utilized.

The growth regulating means is connected to the storage container 10 so that the amount of photosynthesis and the amount of respiration of the plant 1 can be equalized in order to suppress the growth of the plant 1 as much as possible.

Specifically, the growth regulating unit may include a sensing unit installed in the storage container 10 and an adjustment control unit electrically connected to the sensing unit.

The sensing unit may be configured to sense a relative magnitude of the amount of photosynthesis and respiration of the plant (1).

Plant (1) is said to have an intensity of light equal to the amount of photosynthesis and respiration, which is referred to as an optical compensation point. At such an optical compensation point, the growth of plant (1) is suppressed as much as possible.

Accordingly, in order to maintain the intensity of light for the plant 1 at the light compensation point, it is necessary to first reach the light compensation point. To this end, it is necessary to continuously check the current state of the photosynthesis amount and the volume of the plant 1 do.

The sensing unit of the present invention is configured to sense the relative size of the photosynthesis amount and the respiration amount for the plant 1, and specifically includes a gas supply line 21 for supplying carbon dioxide to the storage container 10, And a concentration measurement sensor (S) mounted on the gas discharge line (22) to measure the concentration of carbon dioxide coming from the storage container (10).

The gas supply line 21 comprises a supply pump (not shown) for supplying carbon dioxide from the outside and a supply pipe leading from the supply pump to the storage container 10 in order to supply a gas of a predetermined concentration into the storage container 10 .

The concentration measuring sensor S may be mounted on a gas discharging line 22 through which carbon dioxide is discharged from the storage container 10 as a sensor for measuring carbon dioxide gas.

It is needless to say that such a concentration measuring sensor S only needs to accurately measure the gas of carbon dioxide, but it is not limited to the present invention and any existing sensor can be utilized.

On the other hand, the adjustment control unit is configured to adjust the amount of photosynthesis and the amount of respiration of the plant 1 according to the detection result of the sensing unit.

Specifically, the adjustment control unit may include a light emitting member 31 for emitting light to the plant 1, and a control member for controlling and controlling the light intensity of the light emitting member 31.

Here, the light emitting member 31 is a member configured to irradiate the plant 1 with light, and examples thereof include LED blue light, LED led light, OLED, Dark can be distinguished. At this time, the dark state indicates that no light irradiation is performed.

The control member is electrically connected to the concentration measuring sensor S and the light emitting member 31 to adjust and control the light intensity of the light emitting member 31 according to the concentration of carbon dioxide.

Such a control member may include a power supply P capable of supplying voltage to the light emitting member 31 and capable of controlling the voltage and a controller C for controlling the voltage adjustment of the power supply P. [

The power supply P is electrically connected to the light emitting member 31 to supply the power to the light emitting member 31 so as to irradiate the light to the plant 1, The voltage can be adjusted so that the light intensity of the light emitting member 31 can be changed.

In addition, the controller C is electrically connected to the power supply P to control the power supply voltage adjustment.

At this time, the controller C receives the concentration of carbon dioxide which is electrically connected to the gas supply line 21 and supplied to the storage container 10 through the gas supply line 21, and the concentration sensor S The concentration of carbon dioxide which is electrically connected and discharged from the storage container 10 is received.

This controller C can adjust the voltage of the power supply P according to the comparison result by comparing the concentration of the supplied carbon dioxide with the concentration of the discharged carbon dioxide.

Hereinafter, the process of suppressing the growth of the plant 1 by the plant storage apparatus of the present invention constituted as described above will be described in detail.

First, a predetermined concentration of carbon dioxide is supplied in a predetermined amount through a gas supply line 21 connected to one side of the storage container 10.

Due to the supply of carbon dioxide, a pressure load is generated in the storage vessel 10, so that carbon dioxide is discharged through the gas discharge line 22 connected to the other side of the storage vessel 10.

At this time, the controller C receives the set concentration of the carbon dioxide supplied through the gas supply line 21, and the concentration of the carbon dioxide discharged through the gas discharge line 22 is received from the concentration measurement sensor S.

Next, the controller (C) can adjust the voltage of the power supply (P) according to the comparison result by comparing the concentration of the supplied carbon dioxide and the concentration of the discharged carbon dioxide.

Specifically, when the concentration of the discharged carbon dioxide is lower than the concentration of the supplied carbon dioxide, the amount of photosynthesis of the plant 1 is relatively large. If the concentration of the discharged carbon dioxide is higher than the concentration of the supplied carbon dioxide, will be.

At this time, if the amount of photosynthesis is large, the controller C lowers the supply voltage of the power supply P to lower the luminous intensity of the light emitting member 31. If the amount of light is large, the controller C increases the supply voltage of the power supply P So that the photosynthesis amount and the respiration amount of the plant 1 become equal to each other (the luminous intensity of the light emitting member 31 reaches the light compensation point)

As described above, the controller C controls the voltage of the power supply P to regulate the light intensity of the light emitting member 31 to reach the light compensation point, so that the amount of photosynthesis and the volume of the plant 1 become equal to each other, ) As much as possible.

Of course, at this time, the interior of the storage container 10 is configured to be kept at a low temperature, so that the amount of photosynthesis is remarkably reduced and the amount of breathing is also reduced.

As a result, the present invention reduces the amount of photosynthesis of the plant 1 by keeping the interior of the storage vessel 10 at a low temperature for a long period of time, and simultaneously adjusts the light intensity of the light emitting member 31 so that the photosynthesis amount and the respiration amount of the plant 1 become the same By maintaining the optical compensation point for a long time, the amount of photosynthesis of the plant (1) is minimized, and at the same time, the volume of the plant (1) is suppressed as much as possible.

For reference, referring to FIG. 2, the concentration and luminous intensity of carbon dioxide for each light source will be examined when plants in the plant storage device of FIG. 1 are maintained for a long time as an optical compensation point.

First, the four graphs on the left are graphs showing the concentration of the carbon dioxide discharged from the storage vessel according to the time during which the plants are stored.

That is, the concentration of carbon dioxide discharged from the other side of the storage container is continuously measured by setting the concentration of carbon dioxide supplied to one side of the storage container to 400 ppm.

At this time, the same concentration of carbon dioxide as the supplied carbon dioxide concentration (400 μmol mol ^-1 ) means that the amount of respiration and the amount of photosynthesis are the same, and the value is maintained at the same value for 3 weeks or more (21 days).

Here, the light sources of the light emitting members may be divided into LED blue light, LED led light, OLED, and dark from the upper side. At this time, since darkness indicates a state of not irradiating light, the respiration amount is relatively large, and the concentration of carbon dioxide discharged is higher than 400 μmol mol ^-1 .

The four graphs on the right side are graphs showing the luminous intensity of the light emitting member according to the days (days) during which the plants are stored. This shows the value of light intensity by the theory that photosynthesis of plants increases photosynthesis in proportion to the number of quanta (particles) of light.

The lowering of the luminosity value over time means that the plants are purified to the environment, thus reducing the amount of respiration and thus the required amount of photosynthesis. This value is in a weak light intensity, the concentration of carbon dioxide emissions of the storage vessel 400μmol mol ^- It can be seen from those that can be tailored to ^one. In other words, the photosynthesis and respiration are minimized under low temperature and low light conditions in plants.

Accordingly, the present invention can suppress the growth of plants to the utmost and maintain the quality for a long period of time.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

1: plant 10: storage container
21: gas supply line 22: gas discharge line
31: light emitting member S: density measuring sensor
P: Power supply C: Controller

Claims (5)

A storage vessel (10) in which the plant (1) is housed at a low temperature; And
A growth regulating means associated with the storage container 10, the plant regulating means being configured to equalize the amount of photosynthesis and volume of the plant 1;
≪ / RTI >
The method according to claim 1,
The growth regulating means comprises:
A sensing unit for sensing a relative size of a photosynthesis amount and a respiration amount of the plant (1); And
An adjustment control unit for adjusting the amount of photosynthesis and the amount of respiration of the plant according to the detection result of the sensing unit;
And a plant storage device for storing the plant storage device.
3. The method of claim 2,
The sensing unit includes:
A gas supply line (21) for supplying carbon dioxide to the storage container (10) at a predetermined concentration;
A gas discharge line (22) through which carbon dioxide is discharged from the storage container (10); And
A concentration measuring sensor (S) for measuring the concentration of carbon dioxide supplied and discharged to the gas discharge line (22);
And a plant storage device for storing the plant storage device.
The method of claim 3,
The adjustment control unit,
A light emitting member (31) for emitting light to the plant (1); And
A control member electrically connected to the concentration measuring sensor S and the light emitting member 31 to respectively control the light intensity of the light emitting member 31 according to the concentration of carbon dioxide;
And a plant storage device for storing the plant storage device.
5. The method of claim 4,
Wherein the control member comprises:
A power supply (P) capable of supplying power to the light emitting member (31) and capable of controlling voltage; And
The concentration of the carbon dioxide supplied to the storage container 10 is compared with the measured value of the concentration measurement sensor S by electrically connecting the concentration measurement sensor S and the power supply P, A controller (C) for controlling the supply voltage of the power supply;
And a plant storage device for storing the plant storage device.

Images