KR102360373B1 - Mushroom cultivation system - Google Patents

Abstract

The present invention relates to a mushroom cultivation system using geothermal heat, and more particularly, a geothermal supply unit that is buried underground and supplies geothermal water through heat exchange with geothermal heat, and an external air intake unit for sucking external air on one side It is formed, and the other side is provided with an air conditioning room that communicates with the geothermal supply unit and exchanges heat with geothermal heat while passing the external air sucked through the external air intake unit. It relates to a mushroom cultivation system using geothermal heat that can improve mushroom growth while maintaining stable air or environment inside a stabilized cultivation facility.

Description

Mushroom cultivation system using geothermal heat

The present invention relates to a mushroom cultivation system using geothermal heat, and more particularly, a geothermal supply unit that is buried underground and supplies geothermal water through heat exchange with geothermal heat, and an external air intake unit for sucking external air on one side It is formed, and the other side is provided with an air conditioning room that communicates with the geothermal supply unit and exchanges heat with geothermal heat while passing the external air sucked through the external air intake unit. It relates to a mushroom cultivation system using geothermal heat that can improve mushroom growth while maintaining stable air or environment inside a stabilized cultivation facility.

In general, mushrooms grow well in damp and shaded places, and in recent years, efforts have been made to enable mass production by using separate cultivation facilities such as plastic greenhouses for culture.

This is to ensure good mushroom growth by keeping the mushroom medium containing the mushroom spawn in a mushroom container and located in the cultivation facility, and maintaining the constant temperature and humidity inside the facility.

However, as the mushroom grows, the closed cultivation facility will need ventilation as the temperature rises differently from the open field. Alternatively, in a temperature environment that is too hot in summer, there is a limit to just ventilation, so the cooling fan is operated, but the energy used for the cold air is also significant because the outside temperature is too high.

In other words, the temperature of the grower who grows mushrooms requires a temperature of about 10-15°C or higher regardless of the season, so the burden of heating and cooling costs is the biggest problem because it is necessary to control the temperature by using an air conditioner in summer and a heater in winter. is emerging as

Registered Patent No. 10-1625659

The present invention has been devised in view of the above problems, and an object of the present invention is to install a geothermal supply unit that is buried underground and supplies geothermal water through heat exchange with geothermal heat, and external air is provided on one side. An external air intake unit for suction is formed, and the other side is provided with an air conditioning chamber that communicates with the geothermal supply unit and exchanges heat with geothermal heat as the external air sucked through the external air intake unit passes through. It is to provide a mushroom cultivation system using geothermal heat that can improve mushroom growth while maintaining stable air or environment inside a stabilized cultivation facility by supplying it to a mushroom grower.

Another object of the present invention is to rapidly increase the internal temperature of the mushroom grower, which has been raised to 25-30 ℃ (humidity and humidity 90-99%) to form a white flower, 45 to 55% of humidity at 5 ℃ or less without increasing the humidity due to temperature reduction. It is to provide a mushroom cultivation system using geothermal heat capable of cultivating excellent chrysanthemum mushrooms by providing temperature-sensitive and humidified air to maintain

Another object of the present invention is to install an exhaust air heat recovery temperature control unit that exchanges heat with the exhaust air discharged through the air exhaust duct from the mushroom grower to recover waste heat through heat exchange with water heated by the waste heat of the exhaust air. It is to provide a mushroom cultivation system using geothermal heat.

Another object of the present invention is to form an air flow by counter-current through the adjustment of intake and exhaust inside the mushroom grower to uniformly supply appropriate growth air to each medium of the mushroom grower, thereby enabling more efficient mushroom growth. To provide a mushroom cultivation system using

Mushroom cultivation system using geothermal heat for achieving the above objects, the geothermal supply part buried underground and supplying geothermal heat through heat exchange with geothermal heat; An external air intake unit for sucking external air is formed on one side, and a first inflow air temperature control unit that communicates with the geothermal supply unit and exchanges heat with geothermal heat while passing the external air sucked through the external air suction unit is formed on the other side 1 air conditioning room; and a mushroom grower to which air of the first air conditioning room is supplied.

Here, it is preferable to further include a second air conditioning chamber that receives geothermal heat exchange air through the first air conditioning chamber and the geothermal heat exchange air supply duct and supplies the air heat exchanged by geothermal heat to the mushroom grower through the air supply duct.

In addition, the mushroom grower and exhaust air is supplied through the air exhaust duct, it is preferable to further include a third air conditioning room including a temperature control unit for heat recovery of the exhaust air heat-exchanged with the exhaust air as the exhaust air passes.

In addition, a heater unit is formed in the first air conditioning room to further heat the geothermal heat exchanged air to adjust the inside of the mushroom grower to 25 to 30 ° C (humidity 90 to 99%), and the heater unit is located on one side of the second air conditioning room. It is preferable to further include a moisture-reducing unit that adjusts the temperature to 15°C or less (humidity 45-55%) by rapidly reducing and decreasing the temperature of the inside of the mushroom grower raised to 25-30°C (humidity 90-99%) by the

In addition, in front of the moisture-reducing unit of the second air conditioning room, the second air conditioning unit communicates with the exhaust air heat recovery temperature control unit and is heated while passing the air of the first air conditioning room introduced into the second air conditioning room through the geothermal heat exchange air supply duct. It is preferable that the inlet air temperature control unit is further formed.

In addition, the geothermal supply unit is installed in a zigzag form or a matrix form in which a geothermal line through which thermally reduced or heated water flows through heat exchange with geothermal heat, and the first inlet air temperature control unit includes a plurality of air flow holes through which the introduced air flows and and a geothermal water flow line through which the temperature-sensitive or heated water of the geothermal line communicates between the air flow holes, and one end of the geothermal line is connected to a geothermal water supply hose to the geothermal water flow line through a geothermal water pump Preferably, the other end is connected to the geothermal water flow line through a geothermal water discharge hose to supply the reduced temperature or heated geothermal water while the geothermal water circulates between the geothermal supply unit and the first inlet air temperature control unit.

In addition, the exhaust air heat recovery temperature control unit includes a plurality of exhaust air flow holes through which the introduced exhaust air flows, and a heat recovery water flow line through which heated water exchanging heat with the exhaust air communicates between the air flow holes, and , The second inlet air temperature control unit preferably includes a plurality of air flow holes through which the introduced air flows, and a heated water flow line through which the heated water of the heat recovery water flow line communicates between the air flow holes. .

In addition, the moisture reduction unit includes a plurality of air flow holes through which the introduced external air flows, and a refrigerant storage line in which cold water and refrigerant are stored and flowed between the air flow holes, and the air passing through the air flow holes passes through the refrigerant storage line. It is preferable to supply the dehumidified air to the mushroom grower through the air supply duct, which is cooled by heat exchange and at the same time dehumidified by the generation of condensed water.

In addition, in the mushroom grower, two mushroom cultivation shelves formed in upper and lower multi-layered rows are arranged to face each other in the longitudinal direction with respect to the center, and the air supply duct is long formed in the upper center in parallel in the longitudinal direction, and the two mushrooms Two branched air exhaust ducts branched from the air exhaust duct and opposed to each other are formed long in the longitudinal direction at the lowermost side of the ash shelf, and warm air exchanged with geothermal heat is discharged to the lower part of the air supply duct, and the It is preferable to generate countercurrent by sucking the exhaust air passing through the two mushroom cultivation shelves formed in upper and lower multi-layered rows through the two branched open battool ducts from the bottom side.

According to the mushroom cultivation system using geothermal heat according to the present invention as described above, a geothermal supply part that is buried underground and supplies geothermal water through heat exchange with geothermal heat is installed, and an external air intake part for sucking external air is formed on one side, On the other side, there is an air conditioning room that communicates with the geothermal supply unit and exchanges heat with geothermal heat while passing the external air sucked through the external air intake unit. It has the effect of improving mushroom growth while stably maintaining the air or environment inside the facility.

In addition, the internal temperature of the mushroom grower, which has risen to 25~30℃ (humidity 90~99%) for the formation of white flowers, has been reduced and dehumidified to rapidly maintain 45~55% of humidity at 5℃ or lower without increasing the humidity due to temperature reduction. By providing air, there is also the advantage of creating an environment conducive to cultivating excellent chrysanthemum mushrooms.

In addition, by installing an exhaust air heat recovery temperature control unit that exchanges heat with the exhaust air discharged through the air exhaust duct from the mushroom grower, the waste heat can be recovered and utilized through heat exchange with water heated by the waste heat of the exhaust air. .

In addition, there is an effect that more efficient mushroom growth is possible by uniformly supplying appropriate growth air to each medium of the mushroom grower by forming an air flow through countercurrent inside the mushroom grower.

1 is a schematic perspective view of a mushroom cultivation system using geothermal heat according to an embodiment of the present invention.
2 is a schematic explanatory view showing an air supply flow of a mushroom cultivation system using geothermal heat according to an embodiment of the present invention.
3 is a schematic illustration showing a first air conditioning room of the mushroom cultivation system using geothermal heat according to an embodiment of the present invention.
4 is a schematic illustration showing the second and third air conditioning rooms of the mushroom cultivation system using geothermal heat according to an embodiment of the present invention.
5 is a schematic exemplary diagram of an internal structure of a mushroom grower of a mushroom cultivation system using geothermal heat according to an embodiment of the present invention.

The present invention may be embodied in various other forms without departing from its technical spirit or main characteristics. Accordingly, the embodiments of the present invention are merely illustrative in all respects and should not be construed as limiting.

Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms.

The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

When an element is referred to as being “connected” or “connected” to another element, it is understood that it may be directly connected or connected to the other element, but other elements may exist in between. it should be

On the other hand, when it is said that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In the present application, terms such as "comprises" or "comprising", "have" and the like are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one It should be understood that it does not preclude the possibility of the presence or addition of or more other features or numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

Hereinafter, the most preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings in order to describe in detail enough that a person of ordinary skill in the art can easily carry out the present invention. .

1 is a schematic perspective view of a mushroom cultivation system using geothermal heat according to an embodiment of the present invention, FIG. 2 is a schematic explanatory view showing an air supply flow of a mushroom cultivation system using geothermal heat according to an embodiment of the present invention, FIG. is a schematic illustration showing a first air conditioning room of a mushroom cultivation system using geothermal heat according to an embodiment of the present invention, and FIG. 4 is a second and third air conditioning room of the mushroom cultivation system using geothermal heat according to an embodiment of the present invention It is a schematic illustration showing, and FIG. 5 is a schematic illustration of the internal structure of a mushroom grower of a mushroom cultivation system using geothermal heat according to an embodiment of the present invention.

As shown, in the mushroom cultivation system 100 using geothermal heat according to the embodiment of the present invention, a geothermal supply unit 10 is buried underground to supply geothermal heat, and a first air conditioning room 20 in which external air exchanges heat with geothermal heat. , a second air conditioning chamber 30 communicating with the first air conditioning chamber and supplying dehumidified air to the mushroom growers by introducing air from the first air conditioning chamber, and a third air conditioning chamber 40 recovering waste heat by exchanging heat with the exhaust air; and 1 It is made including the mushroom grower 50 to which the air of the air conditioning room 20 is supplied.

In the mushroom cultivation system 100 using geothermal heat according to the embodiment of the present invention, first, as the air in the mushroom grower 50, growth air, which is air at a predetermined temperature for mushroom growth, is not used as in the prior art by a separate hot air fan. The air heat-exchanged by geothermal heat is supplied through the air supply duct 51 through the first air conditioning chamber 20 or the third air conditioning chamber 40 in which external air exchanges heat with geothermal heat without needing to operate a separate device. , such that excessive power consumption is not generated due to this, so that low power operation is made.

Therefore, looking at the 'growing air' mentioned above, it is the air within the mushroom cultivation facility, and in order for mushrooms to grow, the temperature is 15 to 25 ° C (humidity: about 80 to 95%) in summer and in winter It is necessary to keep the temperature at 10-18 °C.

Here, in the mushroom cultivation system 100 using geothermal heat according to the embodiment of the present invention, the geothermal supply unit 10 that is buried underground to supply geothermal heat and the first air conditioning chamber 20 in which external air exchanges heat with geothermal heat are used. In the case of summer, when the high temperature external air of 37 ° C passes through the first air conditioning chamber 20 that exchanges heat with geothermal heat, the temperature can be reduced to 16 to 17 ° C. , and in winter, when the cold and hot external air of -15 ° C also passes through the first air conditioning chamber 20 that exchanges heat with geothermal heat, it can be heated to 14 to 15 ° C. it will be possible

The geothermal supply unit 10 is buried underground and generates and supplies geothermal heat through heat exchange with geothermal heat, and as shown in FIG. ), the geothermal line 11 through which water flows is installed in a zig-zag form or a matrix form to achieve uniform heat exchange with geothermal heat.

In fact, the geothermal line 11 may be installed in a zigzag form or a matrix form in a square box of approximately 90 cm×85 cm and buried underground.

The geothermal line 11 is preferably made of corrugated stainless steel in order to increase the insulating area, and one end of the geothermal line 11 is connected to a geothermal water supply hose 12 through a geothermal water pump 13 . The geothermal water flow of the first inlet air temperature controller 22 is supplied to the geothermal water flow line 24 of the first inlet air temperature controller 22 to be described later, and the other end is the geothermal water flow through the geothermal water outlet hose 14 . It is connected to the line 34 so that geothermal water can be supplied with reduced or heated geothermal water depending on the season while circulating the geothermal water through the geothermal supply unit 10 and the first inlet air temperature control unit 22 .

Here, the geothermal water supply hose 12 and the geothermal water discharge hose 14 are also preferably made of a corrugated stainless pipe in order to increase the insulating area.

The first air conditioning chamber 20 is provided with an external air intake unit 21 for sucking external air on one side, and communicates with the geothermal supply unit 10 on the other side to be sucked through the external air intake unit 21. The first inlet air temperature control unit 22 that exchanges heat with geothermal heat as the external air passes is formed.

The external air intake unit 21 is formed on one side of the first air conditioning chamber 20 to introduce external air into the first air conditioning chamber. Here, a foreign matter filter unit for removing foreign substances from the external air may be further formed in the external air intake unit.

As shown in FIG. 3 , the first inlet air temperature control unit 22 is configured to reduce the temperature of the geothermal line between the plurality of air flow holes 23 through which the introduced external air flows, and the air flow holes 23 . Alternatively, it is made including a geothermal water flow line 24 through which the heated water flows.

The first inlet air temperature control unit 22 may have a configuration similar to that of a radiator for dissipating heat from an engine such as a vehicle. That is, low-temperature cold water supplied from the outside flows through the water flow path as a plurality of cold water tubes, and heat dissipation fins for improving heat exchange may be provided around the cold water tubes. And a through hole (air flow hole) through which air flows is formed between these cold water tubes (water flow path line) and heat dissipation fins for heat exchange. Therefore, the air passing through the first inlet air temperature control unit 22 exchanges heat with the cold water tube and the heat dissipation fin of the water flow path. It will be warmed or reduced to a temperature at which it is in super thermal equilibrium.

That is, the geothermal water flow line 24 is connected to the geothermal water supply hose 12 and the geothermal water discharge hose 14 shown in FIG. It is connected to the geothermal line 11 so that water that has been reduced or heated by geothermal heat can be circulated, so that external air flowing to the right through the air flow hole 23 is naturally heat-exchanged with geothermal heat to reduce or warm the temperature, as described above. In the case of , when the high temperature external air of 37 ℃ passes through the air flow hole 23 of the first air conditioning room 20 that exchanges heat with geothermal heat, the temperature can be reduced to 16-17 ℃, and in winter, the temperature of -15 ℃ When the cold and hot external air also passes through the air flow hole 23 of the first air conditioning room 20 that exchanges heat with geothermal heat, it can be heated to 14 to 15 ° C. will be able to do

In this way, the geothermal heat exchange air that has been reduced or warmed to an optimal temperature by exchanging heat with the geothermal air is connected to the second air conditioning room 30 through the geothermal heat exchange air supply duct 25 (refer to FIG. 2) through a pump (not shown). to supply the geothermal heat exchange air into the second air conditioning chamber 30 .

In addition, a heater unit (not shown) is installed in the first air conditioning chamber 20 to further heat the geothermal heat exchanged air to be heated. Such a heater unit is required to increase the internal temperature of the mushroom grower 50 to 25-30°C (humidity 90-99%) for the formation of white flowers of mushrooms (especially shiitake mushrooms). Of course, such a heater unit can be operated to adjust the temperature of the mushroom grower if necessary in addition to the formation of white flowers.

The heating of the heater unit is made possible by, for example, heating water contained in the lower portion of the first air conditioning chamber to further warm and humidify the geothermal heat exchanged air and supply it to the inside of the mushroom grower 50 .

As shown in FIGS. 2 and 4 , the second air conditioning chamber 30 receives geothermal heat exchange air through the first air conditioning chamber 20 and the geothermal heat exchange air supply duct 25 and heat exchanged air by geothermal heat. to be supplied to the mushroom grower 50 through the air supply duct 51 .

On the other hand, in the second air conditioning room 30, on one side, the internal temperature of the mushroom grower 50 raised to 25-30 ° C (humidity 90-99%) by the heater unit installed in the first air conditioning room 20 is formed as a whitewash. For this purpose, it further includes a moisture-reducing unit 31 for supplying to the mushroom grower 50 by rapidly reducing the temperature and simultaneously reducing the moisture.

That is, when the internal temperature of the mushroom grower 50, which has risen to 25-30°C (humidity 95%), is rapidly reduced to 15°C or less to form a white flower, the humidity of the mushroom grower 50 increases due to condensation. This makes it difficult to form white flowers, but by supplying air that has been rapidly reduced in temperature by the moisture sensing unit 31 installed in the second air conditioning room 30 to the mushroom grower 50, a humidity of 45 to 55% at 15° C. or less By creating an environment to maintain

The moisture sensing unit 31 includes a plurality of air flow holes 32 through which the introduced external air flows, and a refrigerant storage line 33 through which cold water and refrigerant are stored and flowed between the air flow holes 32 .

The high-temperature air passing through the moisture-reducing unit 31 is cooled by heat exchange while passing through the refrigerant storage line 33 , and at the same time it is dehumidified by the generation of condensed water, and the temperature is reduced to the mushroom grower 50 through the air supply duct 51 . Whitening occurs naturally by supplying fresh air to bring the humidity from 25 to 30 ℃ (humidity 90 to 99%) to 45 to 55% at 15 ℃ or less rapidly.

As shown in FIG. 4 , the third air conditioning chamber 40 is connected to the air exhaust duct 52 to supply exhaust air, and an exhaust air heat recovery temperature control unit that exchanges heat with the exhaust air as the exhaust air passes through it. (41) is further provided.

The exhaust air heat recovery temperature control unit 41 includes a plurality of exhaust air flow holes 42 through which the introduced exhaust air flows, and heated water exchanged heat with the exhaust air between the air flow holes communicates with heat recovery water It includes a flow line (43).

On the other hand, on the opposite side (front side) of the second air conditioning room where the moisture sensing unit 31 is located, the second air conditioning unit is in communication with the exhaust air heat recovery temperature control unit and introduced into the second air conditioning unit 30 through the geothermal heat exchange air supply duct 25. A second inlet air temperature control unit 34 is further formed so that the air in the air conditioning chamber is heated while passing through.

The second inlet air temperature control unit 34 includes a plurality of air flow holes 35 through which the introduced air flows, and a heated water flow line through which the heated water of the heat recovery water flow line communicates between the air flow holes. (36) is included.

That is, the heated water flow line 36 is connected to the waste hot water supply hose 44 and the waste hot water discharge hose 46 , and the heat of the exhaust air heat recovery temperature control unit 41 is generated by the operation of the waste hot water pump 45 . It is connected to the recovered water flow line 43 so that the water heated by the waste heat of the exhaust air can be circulated, so that the air flowing to the right through the air flow hole 35 is naturally heated, which can be used when heating of the supply temperature is required. make it possible

The mushroom grower 50 normally heats with external air and geothermal heat through the air supply duct 51, and the reduced or heated proper growth air is introduced, and 25 to 30° C. (humidity 95%) through the heater unit for whitening. ) and the low-temperature and dehumidified air through the humidification unit 31 are cross-supplied.

In addition, the mushroom grower 50 discharges the exhaust air through the air exhaust duct 52, but communicates with the second air conditioning chamber 40, so that heat recovery of the exhaust air is possible as described above.

Here, mushrooms are grown from a mushroom cultivation container 54 placed on a mushroom cultivation shelf 53 provided in the mushroom grower 50 , and the mushrooms are generally air supply ducts 51 containing a mushroom medium in the mushroom cultivation container 54 . The environmental conditions such as temperature, humidity, and illuminance are adjusted to grow from the medium through proper growth air (14-17 degrees) heat-exchanged with external air and geothermal heat.

In addition, when the mushroom grows, the temperature is generated due to the growth of the mycelium, and latent heat is generated in the mushroom medium, which adversely affects the growth of the mycelium, so it must be discharged to the outside.

However, in general, in the internal air of a typical mushroom grower 50, hot air rises and cold air descends due to convection phenomenon, and the latent heat in the medium rises by the warmed air and the flow of air flow is biased. Even if the proper growth air is supplied through the air supply duct 51, it is not uniformly supplied to the multi-layered mushroom grower's medium, which greatly impedes mushroom growth.

However, in the present invention, the air supply duct 51 for supplying relatively warm growth air (14-17 degrees) is formed long in the upper center of the mushroom grower 50 and discharged to the lower side, and two branched air exhaust ducts (52) is formed on the lower side of the mushroom grower 50 with a reference to the center, so that exhaust air is sucked to generate countercurrent so that relatively hot air flows in the downward direction in the mushroom grower 50. (The supply air temperature on the upper side is about 14-17 degrees, which is the growth air temperature, and the temperature of the intake exhaust air on the bottom side becomes about 18-21 degrees, which rises by about 4 degrees considering the latent heat).

Here, the temperature of the air supplied through the air supply duct 51 installed on the upper side of the mushroom grower is approximately 14-17 degrees as appropriate growth air heat-exchanged with geothermal heat, as will be described later, but the temperature of the growth air It will be understood that the range is not limited, and the range is not limited as long as the temperature is suitable for mushroom growth (approximately 10-25° C.), and the temperature is sufficient to generate countercurrent downward as in the present invention.

More specifically, in the mushroom grower 50, as shown in FIG. 5, two mushroom cultivation shelves formed in vertical and multi-layered rows are disposed to face each other in the longitudinal direction with respect to the center, and at the upper center The air supply duct 51 is long formed side by side in the longitudinal direction, and the two branched air exhaust ducts 52 are formed long in the longitudinal direction at the lowermost side (the lowermost inner side (in the lowermost inner side) of the two mushroom trays. .

Here, the end of the ball supply duct 51 formed long in the longitudinal direction in the upper center of the mushroom grower 50 communicates with the third air conditioning chamber 40 and is relatively warm by exchanging heat with external air and geothermal heat. Appropriate growth air (warm temperature of 14-17 degrees) is introduced, and the ends of the two branched air exhaust ducts 52 are opposite to each other around the center on the lowermost side of the two mushroom tray shelves as described above. Combined with a duct, it communicates with the second air conditioning chamber 40 so that the sucked exhaust air can be discharged.

A plurality of intake air outlets (not shown) are formed spaced apart from the lower part of the air supply duct 51 formed in the upper center in the longitudinal direction in the mushroom grower, and the appropriate growth air (14-17 degrees) heat-exchanged with geothermal heat downwards. ) is discharged, and on the lowermost side (lowest inner side) of the two mushroom tray shelves, the outer side (outwardly opposite to each other) of the two branched air exhaust ducts 52 formed to face each other around the center A plurality of exhaust air intakes 52-1 are formed to be spaced apart.

In this way, relatively warm appropriate growth air (14-17 degrees) is forcibly discharged downward through the plurality of intake air outlets of the air supply duct 51 formed in the upper center of the mushroom grower 50, and the mushroom grower ( 50) through a plurality of exhaust air intakes of the two branched air exhaust ducts 52 formed at the lowermost side of the air (latent heat) Including), it is possible to adjust the air flow of the downward airflow rather than the rising of the hot air, so relatively warm suitable growth air (14-17 degrees) flows from the top to the bottom and forms two pears in a multi-layered row. By inhaling the exhaust air passing through the cultivation shelf from the bottom side to generate countercurrent, the multi-layered medium of the mushroom grower is uniformly supplied by the downward flow of warm air by countercurrent, enabling uniform and efficient mushroom growth.

In addition, a plurality of intake air outlets formed at a plurality of spaced apart from the lower portion of the air supply duct 51 can be discharged by adjusting the angle, so that they are arranged in a plurality of groups in the mushroom cultivation shelf 53 formed widely in upper and lower layers. It is also possible to adjust the air supply flow for growing red beans to suit the medium characteristics of each group of mushrooms in the mushroom cultivation container 54 .

This angle adjustment can be integrated control by the mushroom cultivation control unit 60 to be described later.

In addition, in the mushroom grower 50 of the present invention, since hot air flows from the upper side to the lower side due to the countercurrent flow, even if the door (not shown) of the mushroom grower 50 is opened, the outside of the door is more cold air. Since natural convection flows downward, there is an advantage in that external air is not mixed with the inflow.

Reference numeral 60, which is not described, denotes a mushroom cultivation control unit, and the above-described geothermal supply unit 10 and the first inlet air temperature control unit 22 . The heater unit, the humidity sensing unit 31, the second inlet air temperature control unit 34, the exhaust air heat recovery temperature control unit 41, the air supply duct 51, the air discharge duct 52, etc. are set to preset values. According to the integrated control automatically or manually, the optimal mushroom cultivation can be achieved by geothermal heat, waste heat, and temperature reduction.

It will be understood that the present invention is not limited to the forms recited in the above detailed description. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. Moreover, it is to be understood that the present invention covers all modifications, equivalents and substitutions falling within the spirit and scope of the invention as defined by the appended claims.

100: Mushroom cultivation system using geothermal heat
10: geothermal supply
11: Geothermal line 12: Geothermal water supply hose
13: geothermal water pump 14: geothermal water discharge hose
20: first air conditioning room
21: outside air intake 22: first inlet air temperature control unit
23: air flow hole 24: geothermal water flow line
25: geothermal heat exchange air supply duct
30: 2nd air conditioning room
31: moisture sensing unit 32: air flow hole
33: refrigerant storage line 34: second inlet air temperature control unit
35: air flow hole 36: warm water flow line
40: 3rd air conditioning room
41: exhaust air heat recovery temperature control unit 42: exhaust air flow hole
43: heat recovery water flow line
44: waste hot water supply hose 45: waste hot water pump
46: waste hot water discharge hose
50: Mushroom Growers
51: air supply duct
52: air exhaust duct
53: mushroom growing shelf 54: mushroom growing container
60: mushroom cultivation control

Claims (9)

a geothermal supply unit buried underground and supplying geothermal heat through heat exchange with geothermal heat;
An external air intake unit for sucking external air is formed on one side, and a first inflow air temperature control unit communicating with the geothermal supply unit and exchanging heat with geothermal heat while passing the external air sucked through the external air intake unit is formed on the other side 1 air conditioning room;
a mushroom grower to which air of the first air conditioning room is supplied;
a second air conditioning chamber that receives geothermal heat exchange air through the first air conditioning chamber and the geothermal heat exchange air supply duct and supplies the air heat-exchanged by geothermal heat to the mushroom grower through the air supply duct; and
A third air conditioning room is provided, wherein exhaust air is supplied through the mushroom grower and the air exhaust duct, and the exhaust air heat-exchanges with the exhaust air as it passes through a third air conditioning room including a heat recovery temperature control unit,
A heater unit is formed in the first air conditioning room to further heat the geothermal heat exchanged air to adjust the inside of the mushroom grower to a temperature of 25 to 30 ° C and a humidity of 90 to 99%,
In the second air conditioning room, the inside of the mushroom grower adjusted to a temperature of 25-30°C and a humidity of 90-99% by the heater unit on one side is rapidly reduced and humidified to a temperature of 15°C or less and a humidity of 45-55%. Further provided with a moisture-reducing unit to adjust,
A second inlet air that communicates with the exhaust air heat recovery temperature control unit in front of the humidity reduction unit of the second air conditioning room and warms the air while passing the air of the first air conditioning room introduced into the second air conditioning room through the geothermal heat exchange air supply duct. A temperature control unit is further formed,
The geothermal supply unit is installed in a zigzag form or a matrix form in which a geothermal line through which thermally or heated water flows through heat exchange with geothermal heat,
The first inlet air temperature control unit includes a plurality of air flow holes through which the introduced air flows, and a geothermal water flow line through which the temperature-sensitive or heated water of the geothermal line communicates between the air flow holes,
One end of the geothermal line is connected to a geothermal water supply hose and is supplied to the geothermal water flow line through a geothermal water pump, and the other end is connected to the geothermal water flow line through a geothermal water discharge hose so that geothermal water is connected to the geothermal supply unit and the second end. 1 Mushroom cultivation system using geothermal heat, characterized in that the reduced temperature or heated geothermal water is supplied while circulating the inlet air temperature control unit.
delete delete delete delete delete The method of claim 1,
The exhaust air heat recovery temperature control unit includes a plurality of exhaust air flow holes through which the introduced exhaust air flows, and a heat recovery water flow line through which heated water exchanging heat with the exhaust air communicates between the air flow holes,
The second inlet air temperature control unit comprises a plurality of air flow holes through which the introduced air flows, and a heated water flow line through which the heated water of the heat recovery water flow line communicates between the air flow holes. Mushroom cultivation system using geothermal heat.
The method of claim 1,
The moisture reduction unit includes a plurality of air flow holes through which the introduced external air flows, and a refrigerant storage line in which cold water and refrigerant are stored and flowed between the air flow holes, and the air passing through the air flow holes is subjected to heat exchange while passing through the refrigerant storage line. A mushroom cultivation system using geothermal heat, characterized in that the air is cooled by the evaporator and at the same time it is dehumidified by the generation of condensate and the dehumidified air is supplied to the mushroom grower through the air supply duct.
The method of claim 1,
In the mushroom grower, two mushroom cultivation shelves formed in upper and lower multi-layer rows are disposed to face each other in the longitudinal direction with respect to the center, and the air supply duct is long formed in parallel in the longitudinal direction at the upper center, and the two mushroom tray shelves On the lowermost side of the two branched air exhaust ducts branched from the air exhaust duct to face each other are formed long in the longitudinal direction,
The warm air exchanged with geothermal heat is discharged to the lower part of the air supply duct, and the exhaust air that has passed through the two mushroom cultivation shelves formed in upper and lower multi-layer rows through the two branched open battling ducts is sucked from the lower end to flow countercurrently. Mushroom cultivation system using geothermal heat, characterized in that it generates.

Images