KR20140019195A - A cooling system for cultivation plant - Google Patents

Abstract

Provided is a structure of a cooling system for a plant factory, wherein the cooling system comprises: a plant factory for providing a sealed space in which plants are cultivated; an air collector for collecting air inside the plant factory at the upper side of the plant factory; a heat exchanger installed outside the plant factory to exchange heat; a cold air pipe arranged on the inner bottom of the plant factory to transfer cold air, which is output from the heat exchanger, to the plant factory, wherein the cold pipe has a plurality of through holes to uniformly distribute the cold air; a warm air pipe for transferring warm air, which is output from the air collector, to the heat exchanger; and a coolant pipe for circulating a coolant to the heat exchanger. According to the present invention, the energy cost is low since LNG cold and heat, deep seawater, or underground water is used. Further, only an air outlet is installed on the ground, thereby improving the spatial efficiency of a greenhouse and maintaining the temperature during the summer season at an appropriate temperature suitable for the growth of the plant root part, resulting in an increase in plant productivity and thus an increase in farm income. [Reference numerals] (110) Air collector; (200) Heat exchanger; (300) Warm air pipe; (400) Coolant pipe; (AA) Ground; (BB) Underground

Description

Cooling System for Plant Plants {a cooling system for cultivation plant}

The present invention relates to a cooling system, and specifically, to be installed in a greenhouse or a closed room for cultivating a cold-cooling plant (plants growing around 20 ° C) to maintain a proper growing temperature at a low energy cost, thereby reducing costs. It is about the structure of a plant factory cooling system that can contribute significantly.

In general, plant growth and growth takes place under conditions of ideal temperature, moisture, light and nutritional balance, and during ideal growth the plant is neither infected with pathogens nor subjected to invasion by insects or pests.

These ideal temperatures vary from plant to plant. Cultivation facilities such as glass greenhouses and plastic houses have played a prominent role in improving the productivity of plants by improving environmental conditions unsuitable for plant growth such as excessive low or high temperatures and suppressing the occurrence of diseases caused by rainfall. .

However, even in such a facility, even if it is possible to precisely control the artificial cultivation environment, in summer, except in case of rain, it may be stored in a cultivation facility such as a glass greenhouse or a plastic house during the day (hereinafter referred to as a "plant factory"). It is necessary to lower the internal temperature due to the long time to shine strong sunlight due to excessive increase in the internal temperature of the plant factory.

In addition, there is a case in which the fall of the case when the normal plant cultivation is difficult due to the high cost or technical limitations to lower the internal temperature of the plant factory.

In particular, as the global warming, the abnormal climate is frequent, and the high temperature lasts for a long time, the cultivation of plants such as frosted leafy vegetables is very difficult during the high temperature.

On the other hand, although light is an essential environmental factor for plant cultivation, excessive temperature rise inside by strong light makes plant cultivation difficult, and methods for lowering internal temperature have been developed and used.

One of the methods for lowering the internal temperature may be a method of ventilation. Ventilation is a method of forcibly discharging the heated air due to solar transmission in a glass greenhouse, and is easy to install a facility such as a fan and an installation cost. This is inexpensive, but has a disadvantage of small cooling capacity.

In addition, evaporative cooling methods such as fan n fog, fan n mist, and fan n pad require a lot of equipment cost and may increase indoor humidity.

Electrical cooling, though technically possible, is difficult to afford the energy costs and is only used for special purposes.

Temperature management is one of the most important cultivation techniques because it affects the growth and productivity of plants, and not only temperature control but also geothermal management directly affects plant root elongation and root group formation. It is important for plant cultivation management because it is involved in absorption and indirectly affects the growth of soil microorganisms.

In recent years, plants are cultivating plants without affecting the seasons by adjusting the environment such as temperature and humidity, but in the summer, cultivation of cold-cooled plants (plants growing around 20 ° C) takes a lot of cooling energy costs. Is impossible.

 Vegetables, Chinese cabbage, cabbage, Chinese cabbage, mushrooms, etc. are classified as a cold-cooled plant. There is an urgent need to study cooling systems that can manage frost-cooled plants from high temperatures below summer to low temperatures and low temperatures.

The present invention has been invented to solve the above problems, the purpose is to circulate the cooling air in the pipes arranged on the floor to maintain a constant internal temperature of the plant factory, even in the summer without the heat-resistant plants are harmed The purpose is to provide a plant plant cooling system structure characterized in that the planting and cultivation is possible.

The present invention for achieving the above technical problem is a plant factory which is a closed space for growing plants; An air collecting unit collecting air from the upper side of the plant factory; A heat exchanger installed outside the plant factory to exchange heat; A cold engine having a plurality of through-holes arranged on an inner bottom of the plant factory and having a plurality of through-holes to distribute the cold air from the heat exchanger to the plant factory; A heat engine configured to transfer hot air from the air collector to the heat exchanger; A refrigerant pipe through which a refrigerant is circulated to the heat exchange unit; And a control unit.

In addition, the cold engine, it is characterized in that the buried to a predetermined depth in the ground so as not to affect the cultivation of plants under the bottom of the plant factory and connected to the through hole so that only the outlet of the air to come out on the ground.

The refrigerant circulated through the refrigerant pipe is characterized by using LNG cooling heat.

In addition, the refrigerant circulated through the refrigerant pipe is characterized in that the use of deep sea water.

In addition, the coolant circulated through the coolant pipe is characterized by using ground water.

According to the structure of the plant factory cooling system of the present invention, using LNG cooling, deep sea water, ground water, the energy cost is low, only the outlet of the air to the ground to increase the spatial efficiency of the greenhouse, summer temperature to the growth of plants By maintaining the proper temperature, it is possible to increase the yield of plants and contribute to the income increase of farms.

1 is a schematic diagram of a plant factory cooling system structure according to the present invention
Figure 2 is a schematic diagram showing a state in which the cold engine shown in Figure 1 buried a predetermined depth underground

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Further, detailed descriptions of well-known functions and configurations that may be unnecessarily obscured by the gist of the present invention are omitted.

First, as shown in FIG. 1, the structure of a plant factory cooling system according to the present invention includes a plant factory 100 which is an enclosed space in which plants are grown; An air collecting unit 110 collecting air from the upper side of the plant factory 100; A heat exchanger 200 installed outside the plant factory 100 to exchange heat; In order to deliver cold air from the heat exchange part 200 to the plant factory 100, a plurality of through-holes 360 are formed on the inner bottom of the plant factory 100 and have a plurality of through-holes 360 to distribute the cold air evenly. ); A heat engine (300) for delivering hot air from the air collecting unit (110) to the heat exchange unit (200); A refrigerant pipe 400 through which refrigerant is circulated to the heat exchange part 200; It consists of.

The air collecting unit 110 collects hot air from the upper side of the plant factory 100 and delivers the hot air to the heat exchange unit 200 through the warm pipe 300.

The heat exchanger 200 includes a heat exchanger 210, circulates a refrigerant inside the heat exchanger 210, and fans hot air of the plant factory transferred from the air collector 110 to an outside thereof. By circulating to 220 to exchange heat to generate cold air, the generated cold air is supplied to the plant factory 100 through the cold pipe 350 again.

In this case, when the plant factory 100 needs to be lowered to a required temperature for cultivating a cold-cooled plant, it may be controlled at the speed of the fan 220 provided in the heat exchange unit 200.

The cold pipe 350 is arranged on the bottom of the plant factory 100 and a plurality of through holes 360 in the middle of the pipe are formed to discharge the cold air to be evenly distributed to cool the surroundings, and the warmed air naturally goes up. Ascends and follows the circulation route structure that is collected in the air collecting unit 110 and sent to the heat exchange unit 200 through the warm pipe 300 to cool again.

In making cold air with the heat exchanger 210 and supplying it to the bottom of the plant factory 100 through a pipe, a plant can be planted at the bottom of the plant factory 100 and a passage for moving a person must be secured. There is not much.

Therefore, as shown in Figure 2, buried a pipe in the ground to a predetermined depth without affecting the cultivation of plants under the bottom of the plant factory 100 and connected to the through-hole 360 so that only the air outlets come out on the ground To increase the spatial efficiency of the plant factory (100).

In this case, not only the internal temperature of the plant factory 100 but also geothermal (地 溫) is managed to directly affect the growth of the plant roots and the root group can help indirectly grow.

In order to change the hot air from the air collecting unit 110 to cold in the heat exchange unit 200, plants can be grown by utilizing LNG vaporization heat, deep sea water or ground water as cooling energy.

First, LNG is liquefied natural gas (NG), the main component of methane, at -162 ℃ under atmospheric pressure. It is a colorless, transparent, odorless, clean liquid that removes impurities contained in natural gas of gas field and then liquefies at cryogenic temperature.

 In Korea, liquefied from LNG plants in natural gas fields overseas are introduced into LNG carriers, which are then gasified in LNG plants, which are then gasified and supplied to power plants or consumers through pipes.

Currently, seawater is used as a heat source for vaporizing LNG. In other words, the LNG cold heat utilization process, the LNG is first boosted to 15kg / ㎠ by the primary pump and then pressurized to 75kg / ㎠ by the secondary pump. Pressurized LNG is achieved by absorbing heat through heat exchange with seawater while passing through a high pressure vaporizer. At this time, seawater that exchanges heat with LNG loses heat. Cold heat utilization is to recover the LNG cold heat by using the heat medium in the cold heat recovery heat exchanger instead of the high pressure vaporizer for sea water, and apply the cold heat of the heat medium to the cold-cooled plant cultivation requiring low temperature.

Unlike other countries, in spite of the good conditions of having very low temperature LNG, Korea is throwing away all of the LNG cooling heat into the sea. Therefore, if LNG is used, two purposes, the generation of cold air and the evaporation of LNG, can be achieved simultaneously. It will be very efficient in terms of

Since the cost of generating low temperature cold air exists as cold heat in LNG instead of conventional electric cooling, it is effective to utilize the cold heat generated when regasifying LNG to use properly. Esau will be essential.

Deep sea water is a natural water that is rich in minerals and is not contaminated with bacteria. In the present invention, the deep sea water is circulated to the refrigerant pipe 400 to be used as cooling energy.

In addition, since the outside air temperature is much higher than the temperature of the ground water (about 12-15 ° C.) or the river water in a high temperature period such as summer, when the ground water is circulated to the refrigerant pipe 400 and used as a refrigerant, the plant factory ( 100) It can cool the inside.

Embodiment of the structure of the plant factory cooling system of the present invention described above is merely exemplary, and those skilled in the art to which the present invention pertains that various modifications and equivalent other embodiments are possible. You will know well. Therefore, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

100: plant factory 110: air collector
200: heat exchanger 210: heat exchanger
220: fan 300: heat pipe
350: cold engine 360: through hole
400: refrigerant pipe

Claims (5)

Plant factory 100 is a closed space for growing plants;
An air collecting unit 110 collecting air from the upper side of the plant factory 100;
A heat exchanger 200 installed outside the plant factory 100 to exchange heat;
In order to deliver cold air from the heat exchange part 200 to the plant factory 100, a plurality of through-holes 360 are formed on the inner bottom of the plant factory 100 and have a plurality of through-holes 360 to distribute the cold air evenly. );
A heat engine (300) for delivering hot air from the air collecting unit (110) to the heat exchange unit (200);
A refrigerant pipe 400 through which refrigerant is circulated to the heat exchange part 200;
Structure of the plant factory cooling system, characterized in that comprises a; The method of claim 1,
The cold engine 350,
Structure of the plant factory cooling system, characterized in that buried to a predetermined depth in the ground so as not to affect the cultivation of plants under the bottom of the plant factory 100 and connected to the through hole 360 so that only the outlet of the air comes out on the ground, 3. The method according to claim 1 or 2,
The refrigerant circulated through the refrigerant pipe 400 is
The structure of the cooling plant cooling system, characterized in that using LNG cooling heat 3. The method according to claim 1 or 2,
The refrigerant circulated through the refrigerant pipe 400 is
Structure of a plant factory cooling system, characterized by using deep ocean water, 3. The method according to claim 1 or 2,
The refrigerant circulated through the refrigerant pipe 400 is
Structure of a plant factory cooling system, characterized by the use of ground water.

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