KR20220016434A - Purified air circulation flow system for mushroom cultivation house - Google Patents

Abstract

The present invention relates to a mushroom cultivation house, and more specifically, to a purified air circulation flow system for a mushroom cultivation house for purifying circulating air and controlling temperature and humidity while allowing the air inside the mushroom cultivation house to circulate while blocking the inflow of external air. The present invention provides a purified air circulation flow system for a mushroom cultivation house, including: a mushroom cultivation house (10) including a cultivation house temperature sensor (101) for measuring temperature, humidity and carbon dioxide concentration in a cultivation room when cultivating mushrooms, a cultivation house humidity sensor (102), and a cultivation house carbon dioxide sensor (103); a heat exchange device (15) for circulating and supplying air in the mushroom cultivation house (10); an air exhaust fan (122) for allowing the air in the mushroom cultivation house (10) to flow to the heat exchange device (15) through an air exhaust pipe (121); and a purified air supply fan (112) for allowing purified air to flow through a purified air supply pipe (111) between the heat exchange device (15) and the mushroom cultivation house (10), wherein the heat exchange device (15) includes: a cooling heat exchanger (211) for cooling flowing air; a cultivation temperature control heat exchanger (212) for heating or decreasing the temperature of the flowing air; and a heat exchange water supply system (20) for supplying cooling water to the cooling heat exchanger (211) and supplying cold water or hot water to the cultivation temperature control heat exchanger (212).

Description

Purified air circulation flow system for mushroom cultivation {PURIFIED AIR CIRCULATION FLOW SYSTEM FOR MUSHROOM CULTIVATION HOUSE}

The present invention relates to a mushroom cultivation company, and more particularly, to purify the circulating air and control temperature and humidity while allowing the air inside the mushroom cultivation company to circulate while blocking the inflow of external air. It's about the system.

In general, mushrooms grow best in spring and autumn weather in their natural state. In spring and autumn, it rains to some extent, and under conditions of maintaining a certain degree of humidity in the mountains, the temperature is rather hot during the day, while the weather is cool at night. As such, the humidity and temperature conditions are optimal in spring and fall Mushrooms will grow well in the right state.

However, in the natural state, various harmful factors other than weather and humidity can always act, so that only a small part of the spawn grows compared to the spread.

On the other hand, in facilities specializing in mushroom cultivation, various growth conditions are good even for logs, but in the case of log cultivation, since they are not isolated from the external natural environment, various insects, molds, fungi, etc. will be.

Therefore, in recent years, medium mushroom cultivation using mainly oak sawdust is often used. Even in such medium cultivation, although it is isolated from nature, when it is opened for ventilation, a large number of harmful foreign substances are input from the outside.

In general, mushrooms require oxygen like humans, along with temperature and humidity, and emit carbon dioxide (carbon dioxide), so most of the greenhouse growers close overnight and open them in the morning to ventilate the growers to release full carbon dioxide. .

In the case of opening and ventilating the mushroom growing house in this way, although carbon dioxide is discharged to the outside and oxygen is supplied to the grower, foreign substances are introduced from the outside as much as this, which also provides unfavorable conditions for mushroom growth. In other words, most mushroom growers are located in rural areas, but since there are many paddy fields and fields nearby, there is a risk of influx of pesticides or herbicides to these paddy fields and fields. Eco-friendly, pesticide-free cultivation is basic, but it may not be able to overcome this.

In addition, although a closed type mushroom grower is provided, even in the case of such a conventional grower, it is difficult to control the concentration of carbon dioxide along with temperature and humidity.

Therefore, there is an urgent need for a technical composition to improve the mushroom cultivation environment.

Publication No. 10-20 Registered Patent No. 10-

The present invention for solving the above problems is in a state in which it is blocked from the outside, so that the inflow of herbicides or other foreign substances from the outside is blocked, so that mushroom growth can be achieved stably.

And another object of the present invention is to facilitate temperature and humidity control because it operates while continuously circulating the air inside the mushroom cultivation house, while changing the temperature and humidity slightly without rapidly increasing or decreasing the temperature and humidity control.

In addition, another object of the present invention is to prevent damage caused by carbon dioxide concentration because the carbon dioxide concentration is lowered while controlling the temperature and humidity during the process of continuously flowing mushroom cultivation air.

The present invention for achieving the above object is a cultivation area temperature sensor 101, a cultivation area humidity sensor 102 and a cultivation area carbon dioxide gas sensor 103 for measuring the temperature, humidity, and carbon dioxide concentration in the cultivation room in cultivating mushrooms. ), including a mushroom grower (10); a heat exchange device 15 for circulating and supplying air in the mushroom cultivation house 10; an air exhaust fan 122 for allowing the air in the mushroom cultivation house 10 to flow to the heat exchange device 15 through the air exhaust pipe 121; and a purified air supply fan 112 for allowing purified air to flow through the purified air supply pipe 111 between the heat exchange device 15 and the mushroom cultivation company 10, wherein the heat exchange device 15 cools the flowing air Cooling heat exchanger (211); a cultivation temperature control heat exchanger 212 for heating or decreasing the temperature of flowing air; and a heat exchange water supply system (20) for supplying cooling water to the cooling heat exchanger (211) and supplying cold or hot water to the cultivation temperature control heat exchanger (212). provides

In the present invention, the purification temperature sensor 131 is installed in the purified air supply pipe 111 to sense the temperature of the air supplied from the heat exchange device 15 to the mushroom cultivation company (10); and a purified humidity sensor 132 installed in the purified air supply pipe 111 to sense the humidity of the air supplied from the heat exchange device 15 to the mushroom cultivation company 10 .

In the present invention, the heat exchange device 15, the spray pump 16 for supplying the water contained therein to the spray nozzle; a low-temperature spray nozzle 171 that receives water from the spray pump 16 and sprays water in the pasteurization area 151 before the cooling heat exchanger 211 with respect to the air supplied through the air exhaust fan 122; a micro-removal spray nozzle 173 positioned between the micro-removal area 152 between the cooling heat exchanger 211 and the cultivation temperature control heat exchanger 212 to spray water supplied from the spray pump 16; Temperature and humidity control spray nozzle 175 for spraying the water supplied from the spray pump 16 with respect to the air between the temperature and humidity control area 153 supplied to the mushroom cultivation house 10 through the cultivation temperature control heat exchanger 212; a low-temperature spray valve 172 for blocking the water supplied to the low-temperature spray nozzle 171; a micro-removal spray valve 174 for blocking the water supplied to the micro-removal spray nozzle 173; a temperature and humidity control spray valve 176 for shutting off the water supplied to the temperature and humidity control spray nozzle 175; and a sterilization lamp 18 installed in the pasteurization area 151 to sterilize the air supplied from the mushroom grower 10 .

In the present invention, a pasteurization spray nozzle 171 and a sterilization lamp 18 are installed to sterilize the air supplied from the mushroom grower 10, and a pasteurization area 151 for forming a low temperature by the sprayed water. ; a micro-removal area 152 for removing foreign substances contained in the air flowing by the water sprayed from the micro-removal spray nozzle 173; and a temperature/humidity control area 153 for humidifying the air supplied to the mushroom growing company 10 by water sprayed from the temperature/humidity control spray nozzle 175.

In the present invention, the heat exchange water supply system 20 includes a cooler 22 for supplying cold water to the heat exchanger through a cooler supply line 225; a heater 23 for supplying hot water to the heat exchanger through a heater supply line 235; Cooler tank 221 in which the cold water of the cooler 22 is contained; a cooler pump 222 for supplying cold water from the cooler tank 221 to the cooler 22; a heat exchange water supply block (BL-in) 24 for supplying the cold water or hot water of the cooler 22 and the heater 23 to the cooling heat exchanger 211 and the cultivation temperature control heat exchanger 212 side; and heat exchange water for flowing cold water or hot water from the cooling heat exchanger 211 and the cultivation temperature control heat exchanger 212 to the cooler 22 and the heater 23 through the cooler return line 225 and the heater return line 236 . A recovery block (BL-out) 25 is provided.

In the present invention, a cooler bypass line 223 connected between the cooler supply line 225 and the cooler recovery line 226 connected to the cooler 22; a cooler bypass valve 224 connected to the cooler bypass line 223; a heater bypass line 233 connected between the heater supply line 235 and the heater return line 236 connected to the heater 23; and a heater bypass valve 234 connected to the heater bypass line 233 .

In the present invention, the heat exchange water supply block 24 includes a cooler valve 241 for blocking the supply of the cold water of the cooler 22 to the cooling heat exchanger 211 and the cultivation temperature control heat exchanger 212 side; a cooling control valve 242 for controlling the amount of cold water supplied to the cooling heat exchanger 221 of the cooler 22; a heater backflow prevention valve 243 for preventing backflow of water flowing through the heater supply line 235 toward the heater 23; a cooling cultivation control intermediate supply line 244 having one side connected between the cooler valve 241 and the cooling control valve 242 and the other side connected to the heater supply line 235 after the heater non-return valve 243; and a supply intermediate valve 245 coupled to the cooling cultivation control intermediate supply line 244 to supply the cold water of the cooler 22 to the cultivation temperature control heat exchanger 212 .

In the present invention, the heat exchange recovery block 25 includes: a heater recovery shutoff valve 251 connected to a heater recovery line 236 between the cultivation temperature control heat exchanger 212 and the heater 23; a cooling cultivation control intermediate recovery line 254 connected between the heater recovery line 236 and the cooling opportunity recovery line 226 before the heater recovery shutoff valve 251; and a recovery intermediate valve 255 coupled to the cooling cultivation control intermediate recovery line 254 .

In the present invention, the mushroom cultivation company control unit 50 for supplying the purified air to the mushroom cultivation company 10 after exhausting and purifying the air of the mushroom cultivation company 10 is included, and the mushroom cultivation company control unit 50 is , a main controller 51 that flows the air supplied to the mushroom grower 10 and receives a signal detected from each sensor; a memory 52 in which the mushroom grower 10 setting data is stored and read by the main controller 51; a circulation operation unit 54 for receiving the control signal of the main controller 51 and operating the fan and the sterilization lamp 18; a sensor signal receiver 55 that receives signals from sensors installed in the mushroom grower and the flow path of purified air and transmits them to the main controller 51; a spray operation unit 56 for receiving a control signal from the main controller 51 and operating the spray pump 16 and the valve of the heat exchange device 15; a heat exchange device operation unit 57 for receiving a control signal from the main controller 51 and operating the cooler 22 , the heater 23 , and the cooler pump 222 of the heat exchange water supply system 20 ; and a heat exchange valve operation unit 58 for operating the valves of the heat exchange water supply system 20 by receiving a control signal from the main controller 51 to provide a purified air circulation flow system for mushroom cultivation .

Since the present invention configured as described above is in a blocked state from the outside, the inflow of herbicides or other foreign substances from the outside is blocked, so that mushroom growth can be achieved stably.

And another effect of the present invention is to facilitate temperature and humidity control because it operates while continuously circulating the air inside the mushroom cultivation house and changing it slightly without rapidly increasing or decreasing the temperature and humidity control.

In addition, another effect of the present invention is to prevent damage due to the carbon dioxide concentration because the carbon dioxide concentration is lowered while controlling the temperature and humidity during the process of continuously flowing mushroom cultivation air.

In addition, another effect of the present invention is to collect foreign substances by spraying water while continuously flowing the air inside the mushroom grower, but also to remove mushroom spores contained in the air to improve mushroom growth and improve the internal working environment will become

1 is an overall configuration diagram of a mushroom cultivation house and a purification air circulation flow system according to the present invention.
2 is an exemplary configuration diagram of a heat exchange water supply system for mushroom cultivation according to the present invention.
3 is an exemplary diagram of a control configuration of a mushroom grower in the present invention.

Hereinafter, it will be described in detail with reference to the accompanying drawings.

That is, the purified air circulation flow system 100 for mushroom cultivation according to the present invention is a mushroom grower 10 that grows mushrooms from a mushroom medium inside, as shown in FIGS. 1 to 3, etc. This is to purify the air while continuously circulating the air inside.

Thereby, a separate device can be used to control the humidity and temperature together while removing foreign substances contained in the air inside the mushroom cultivation house 10 by such a purified Air Circulation Flow System (PACFS, 100). Since it does not need to be installed inside the grower 10, the cultivation space can be configured in a wide and simple manner, and an environment suitable for mushroom growth is optimally provided.

The detailed configuration of the mushroom cultivation company 10 and the purified air circulation flow system 100 will be looked at.

First, as a mushroom grower 10 in which a mushroom medium and mushrooms growing from the medium are located inside, a grower temperature sensor 101 for measuring the temperature, humidity, and carbon dioxide concentration in the cultivation room in cultivating mushrooms, a cultivation room humidity sensor ( 102) and provides a mushroom cultivation company 10 including a carbon dioxide sensor 103 for cultivation.

Of course, the mushroom grower 10 is preferably insulated to prevent heat or cold air from entering from the outside, and is preferably made of a facility that blocks outside air from entering except for a predetermined route. That is, when air is input from the outside other than the air path circulated by the purified air circulation flow system 100 , the mushroom growth may be reduced due to unexpected pollutants being input.

In addition, the cultivation environment of mushrooms can be closely monitored by providing a cultivation area temperature sensor 101, a cultivation area humidity sensor 102, a cultivation area carbon dioxide sensor 103, and an illuminance sensor installed in the mushroom cultivation house 10.

Next, as a main component of the purified air circulation flow system 10 , a heat exchange device 15 for circulating and supplying air in the mushroom cultivation house 10 is provided.

As a configuration for this, an air exhaust fan 122 for allowing the air in the mushroom grower 10 to flow to the heat exchanger 15 through the air outlet pipe 121 is provided, and between the heat exchanger 15 and the mushroom grower 10 It is to include a purified air supply fan 112 that allows the purified air to flow through the purified air supply pipe 111 of the.

And a purification temperature sensor 131 installed in the purified air supply pipe 111 to sense the temperature of the air supplied from the heat exchange device 15 to the mushroom cultivation house 10, and installed in the purified air supply pipe 111 to heat exchange device By providing a purified humidity sensor 132 that senses the humidity of the air supplied from (15) to the mushroom growing house 10, it is possible to check the temperature and humidity state just before the purified air flows into the mushroom growing house 10 will be.

This compares the temperature, humidity, etc. of the purified air with the inside of the cultivator to check the efficiency of the heat exchange device 15 and the purified air circulation flow system 100 and, if necessary, adjust the heat exchange capability and purification capability.

And the heat exchanger 15 includes a cooling heat exchanger 211 for cooling flowing air, and a cultivation temperature control heat exchanger 212 for warming or decreasing the temperature of flowing air, such a cooling heat exchanger 211 and cultivation. In the temperature control heat exchanger 212, pores are formed, and the air of the mushroom cultivation sand 10 flows through the pores, thereby causing a change in cooling or heating state. Thus, each process will be optimally achieved. For example, when the air supplied from the mushroom grower 10 is cooled by the cooling heat exchanger 211 , carbon dioxide removal in the next step, the micro-removal area 152 , may be efficiently performed. This is because, in the case of carbon dioxide, which is generally water-soluble, the capture ability by water can be improved when the temperature is low.

On the other hand, in the case of the cultivation temperature control heat exchanger 212, the temperature of the air cooled by the cooling heat exchanger 211 is raised or lowered according to the growth conditions of the mushroom cultivation company 10, so that the mushroom growth can be performed well. it will work

Next, a heat exchange water supply system 20 for supplying cooling water to the cooling heat exchanger 211 and supplying cold water or hot water to the cultivation temperature control heat exchanger 212 is included.

In addition, in the heat exchange device 15, a spray pump 16 for supplying the water contained therein to the spray nozzle, and water supplied from the spray pump 16 to the air supplied through the air exhaust fan 122 It includes a low-temperature spray nozzle 171 for spraying water in the pasteurization region 151 before the cooling heat exchanger 211.

a low-temperature spray valve 172 for blocking the water supplied to the low-temperature spray nozzle 171;

And it is installed in the pasteurization area 151 and includes a sterilization lamp 18 for sterilizing the air supplied from the mushroom grower 10.

In this way, the pasteurization spray nozzle 171 and the sterilization lamp 18 are installed to sterilize the air supplied from the mushroom grower 10 and include a pasteurization area 151 for forming a low temperature by the sprayed water. will be. In this pasteurization area 151, the air introduced from the mushroom grower 10 is formed at a low temperature in order to increase the efficiency of collecting foreign substances in the next area, while the air introduced from the mushroom grower 10 contains The process of sterilizing mold and the like by the sterilization lamp 18 is performed.

Next, it is positioned between the micro-removal area 152 between the cooling heat exchanger 211 and the cultivation temperature control heat exchanger 212 and includes a micro-removal spray nozzle 173 for spraying the water supplied from the spray pump 16 . and a micro-removal spray valve 174 for blocking the water supplied to the micro-removal spray nozzle 173.

As such, the micro-removal area 152 for removing foreign substances contained in the air flowing by the water sprayed from the micro-removal spray nozzle 173 is provided.

By removing the foreign substances contained in the air introduced from the mushroom cultivation company 10 by the micro-removal area 152, the foreign materials are collected by the water particles sprayed from the micro-removal spray nozzle 173 and collected in the water. The foreign matter falls down together with the water as it is and is included in the water, so that the foreign material is eventually removed from the flowing air.

In order to increase the collection efficiency of these foreign substances, various types of nozzles that are finely atomized can be applied, so that small foreign substances can be collected by fine-sized water particles as well as foreign substances collected by large particles of water. It will be possible to further increase the efficiency of collecting foreign substances.

In addition, it will be possible to reduce the concentration of carbon dioxide in the air by capturing the carbon dioxide (carbon dioxide gas) contained in the air by the trapping of these foreign substances. Therefore, the growth environment of mushrooms will be improved.

Next, the temperature and humidity control spray nozzle 175 for spraying the water supplied from the spray pump 16 to the air between the temperature and humidity control area 153 supplied to the mushroom cultivation house 10 through the cultivation temperature control heat exchanger 212. , and a temperature and humidity control spray valve 176 for blocking the water supplied to the temperature and humidity control spray nozzle 175 .

As such, the temperature and humidity control area 153 for humidifying the air supplied to the mushroom grower 10 by the water sprayed from the temperature and humidity control spray nozzle 175 is included.

Since the temperature is slightly lowered to increase the efficiency of collecting foreign substances in the micro-removal area 152 , the air flowing into the final mushroom cultivation house 10 will have to match the mushroom growth conditions. Therefore, in the temperature and humidity control area 153, the mushroom growth environment of the mushroom grower 10 is adjusted by adjusting the temperature by the cultivation temperature control heat exchanger 212 and controlling the humidity by the amount of water sprayed from the temperature and humidity control spray nozzle 175. it will be created

Next, the heat exchange water supply system 20 includes a cooler 22 that supplies cold water through a cooler supply line 225 to a heat exchanger such as a cooling heat exchanger 211 and a cultivation temperature control heat exchanger 212 . do.

It also includes a heater 23 for supplying hot water to the heat exchanger through a heater supply line 235 .

In addition, a cooler tank 221 in which the cold water of the cooler 22 is contained, and a cooler pump 222 for supplying the cold water of the cooler tank 221 to the cooler 22 are provided to convert the cold water of the cooler 22 into a heat exchanger. to flow to the side.

Accordingly, a heat exchange water supply block (BL-in) 24 for supplying the cold water or hot water of the cooler 22 and the heater 23 to the cooling heat exchanger 211 and the cultivation temperature control heat exchanger 212 is provided. The heat exchange water supply block 24 provides valves and flow lines for supplying cold or hot water to each heat exchanger.

In addition, heat exchange water for flowing cold water or hot water from the cooling heat exchanger 211 and the cultivation temperature control heat exchanger 212 to the cooler 22 and the heater 23 through the cooler return line 225 and the heater return line 236 . and a recovery block (BL-out) 25 . The heat exchange recovery block 25 is to make a continuous flow circuit configuration by allowing cold water or hot water used in each heat exchanger to flow to each cooler 22 or heater 23, and the like.

In addition, as a configuration for stable operation of each device, a cooler bypass line 223 connected between a cooler supply line 225 connected to the cooler 22 and a cooler recovery line 226 is provided.

In addition, a cooler bypass valve 224 connected to the cooler bypass line 223 is provided to bypass the cooler according to each situation.

In addition, a heater bypass line 233 connected between the heater supply line 235 and the heater return line 236 connected to the heater 23 is provided. It also includes a heater bypass valve 234 connected to the heater bypass line 233 . Thus, the operation by the heater 23 is made smoothly.

Next, looking at the detailed configuration of the heat exchange water supply block 24 (BL-in), the cooler that blocks the supply of the cold water of the cooler 22 to the cooling heat exchanger 211 and the cultivation temperature control heat exchanger 212 side. A valve 241 is provided. That is, it is to control the flow of cold water flowing from the cooler 22 through the cooler supply line 225 .

Next, a cooling control valve 242 for controlling the amount of cold water supplied to the cooling heat exchanger 221 of the cooler 22 is provided. That is, the cooling performance of the cooling heat exchanger 211 can be adjusted by adjusting the amount of the cold water flowing toward the cooling heat exchanger 211 in the cooler 22 .

In addition, it includes a heater non-return valve 243 for preventing backflow of water flowing through the heater supply line 235 toward the heater 23 . That is, it prevents the water flowing through the heater supply line 235 connected to the heater 23 from flowing back into the heater 23 in an unexpected state, and also prevents the water from the heater 23 from being discharged when not in use. will prevent

In addition, one side is connected between the cooler valve 241 and the cooling control valve 242 and the other side is connected to the heater supply line 235 after the heater non-return valve 243. A cooling cultivation control intermediate supply line 244 is provided. do. That is, by such a cooling cultivation control intermediate supply line 244, the cold water of the cooler 22 flows to the cultivation temperature control heat exchanger 212 side, thereby cooling the flowing air.

In addition, it is coupled to the cooling cultivation control intermediate supply line 244 and includes a supply intermediate valve 245 for supplying the cold water of the cooler 22 to the cultivation temperature control heat exchanger 212 . That is, when the cold water of the cooler 22 flows to the cooling heat exchanger 211 side and the hot water of the heater 23 flows only to the cultivation temperature control heat exchanger 212 side, the supply intermediate valve 245 is blocked, and this As another situation, when the cold water of the cooler 22 flows to the cultivation temperature control heat exchanger 212 side, the supply intermediate valve 245 is opened. In this case, the reverse flow to the heater 23 may be prevented by blocking the heater non-return valve 243 .

Next, looking at the detailed configuration of the heat exchange recovery block 25 (BL-out), the heater recovery shutoff valve 251 connected to the heater recovery line 236 between the cultivation temperature control heat exchanger 212 and the heater 23 ) is provided. This opens the heater return shutoff valve 251 when the hot water of the heater 23 is supplied to the cultivation temperature control heat exchanger 212, whereas the cold water of the cooler 22 is supplied to the cultivation temperature control heat exchanger 212. In this case, by blocking the heater return shutoff valve 251 , the cold water flows to the cooler 22 while blocking the supply to the heater 23 .

In addition, the cooling cultivation control intermediate recovery line 254 connected between the heater recovery line 236 and the cooling opportunity recovery line 226 before the heater recovery shutoff valve 251, and the cooling cultivation control intermediate recovery line 254 coupled to It will include a recovery intermediate valve (255).

That is, when the cold water of the cooler 22 is supplied to the cultivation temperature control heat exchanger 212, the recovery intermediate valve 255 is opened to allow the cold water of the cultivation temperature control heat exchanger 212 to connect the cooling cultivation control intermediate recovery line 254. It is to flow to the cooler 22 side through.

In addition, in the mushroom cultivation company 10 and the purified air circulation flow system 100 according to the present invention, after exhausting and purifying the air of the mushroom cultivation company 10, to supply the purified air to the mushroom cultivation company 10 again It will include a mushroom grower control unit (50).

The mushroom grower control unit 50 flows the air supplied to the mushroom grower 10 and receives a signal detected from each sensor, and the main controller 51 and the mushroom grower 10 set data are stored and main It includes a memory 52 that is read by the controller 51 . That is, in the memory 52 , setting data for operating each device of the mushroom grower 10 and the purified air circulation flow system 100 is stored, and data collected from each sensor is also stored.

In addition to this, it includes a circulation operation unit 54 for receiving the control signal of the main controller 51 to operate the fan and the sterilization lamp 18 . Thus, by operating the air exhaust fan 122 for discharging the air of the mushroom grower 10, the purified air supply fan 112 for supplying the purified air to the mushroom grower 10, etc., heat exchange with the mushroom grower 10 It is to allow air to flow continuously between the devices (15).

In addition, by operating the provided sterilization lamp 18 according to the situation, mold and bacteria contained in the air flowing by each fan are sterilized.

Next, a sensor signal receiving unit 55 that receives signals from sensors installed in the flow path of the mushroom grower and purified air and transmits them to the main controller 51 is provided. That is, the cultivation area temperature sensor 101, the cultivation area humidity sensor 102, the cultivation area carbon dioxide sensor 103 provided in the mushroom cultivation company 10, and also the purification temperature sensor 131 installed in the purified air supply pipe 111, the purification humidity sensor ( 132) receives the sensed sensor data and transmits it to the main controller 51 side. When it is necessary to adjust the temperature or humidity by comparing and discriminating the set values with respect to the sensing data, the main controller 51 transmits a control signal to the corresponding devices.

This includes a spray operation unit 56 for receiving a control signal from the main controller 51 to operate the spray pump 16 and the valve of the heat exchange device 15 .

That is, by the spray operation unit 56, the spray pump 16 of the heat exchange device 15 is operated, so that the pasteurization spray nozzle 171, the fine removal spray nozzle 173, the temperature and humidity control spray nozzle 175, etc. By being sprayed, it will be possible to carry out the process of removing foreign substances.

In addition, the spray operation unit 56 operates the pasteurization spray valve 172 to control the amount of water sprayed through the pasteurization spray nozzle 171 . In addition, the spray operation unit 56 controls the amount of water sprayed through the micro-removal spray nozzle 173 by operating the micro-removal spray valve 174, thereby controlling the foreign material collection efficiency.

In addition, the spray operation unit 56 controls the amount of water sprayed through the temperature and humidity control spray nozzle 175 by operating the temperature and humidity control spray valve 176, so that the humidity of the purified air can be adjusted.

Next, receiving a control signal from the main controller 51 and having a heat exchange device operation unit 57 for operating the cooler 22, the heater 23, and the cooler pump 222 of the heat exchange water supply system 20 will be. Accordingly, the cooler 22 , the cooler pump 222 , the heater 23 , etc. can be operated according to the situation to achieve a heat exchange action.

Next, a heat exchange valve operation unit 58 for operating the valves of the heat exchange water supply system 20 by receiving a control signal from the main controller 51 is provided. Thus, it is possible to achieve smooth operation of the heat exchanger by adjusting each valve installed in the heat exchange water supply block 24 and the heat exchange water recovery block 25 for each control condition.

Although the embodiment of the present invention has been described in detail above, since one embodiment has been described so that a person of ordinary skill in the art can easily practice the present invention, by the description of the embodiment, The technical spirit of the present invention should not be construed as being limited.

100: purified air circulation flow system
10: mushroom grower 15: heat exchanger
16: spray pump 20: heat exchange water supply system
22: cooler 23: heater
24: heat exchange water supply block 25: heat exchange water recovery block
50: mushroom grower control unit

Claims (2)

Mushroom grower 10 including a grower temperature sensor 101, a grower humidity sensor 102, and a cultivated dead carbon dioxide sensor 103 for measuring the temperature, humidity, and carbon dioxide concentration in the cultivation room in cultivating mushrooms;
a heat exchange device 15 for circulating and supplying air in the mushroom cultivation house 10;
an air exhaust fan 122 for allowing the air in the mushroom cultivation house 10 to flow to the heat exchange device 15 through the air exhaust pipe 121;
It includes a purified air supply fan 112 that allows purified air to flow through the purified air supply pipe 111 between the heat exchange device 15 and the mushroom grower 10,
The heat exchange device 15,
Cooling heat exchanger 211 for cooling the flowing air;
a cultivation temperature control heat exchanger 212 for heating or decreasing the temperature of flowing air; and
and a heat exchange water supply system (20) for supplying cooling water to the cooling heat exchanger (211) and supplying cold or hot water to the cultivation temperature control heat exchanger (212).
The method of claim 1,
The heat exchange device 15,
a spray pump 16 for supplying the water contained therein to the spray nozzle;
a low-temperature spray nozzle 171 that receives water from the spray pump 16 and sprays water in the pasteurization area 151 before the cooling heat exchanger 211 with respect to the air supplied through the air exhaust fan 122;
a micro-removal spray nozzle 173 positioned between the micro-removal area 152 between the cooling heat exchanger 211 and the cultivation temperature control heat exchanger 212 to spray water supplied from the spray pump 16;
Temperature and humidity control spray nozzle 175 for spraying the water supplied from the spray pump 16 with respect to the air between the temperature and humidity control area 153 supplied to the mushroom cultivation house 10 through the cultivation temperature control heat exchanger 212;
a low-temperature spray valve 172 for blocking the water supplied to the low-temperature spray nozzle 171;
a micro-removal spray valve 174 for blocking the water supplied to the micro-removal spray nozzle 173;
a temperature and humidity control spray valve 176 for blocking the water supplied to the temperature and humidity control spray nozzle 175; and
A purification air circulation flow system for mushroom cultivation, characterized in that it is installed in the pasteurization area (151) and includes a sterilization lamp (18) for sterilizing the air supplied from the mushroom grower (10).

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