KR20220087311A - Tunnel for fermentation of mushroom culture medium with easy ventilation - Google Patents

Abstract

A tunnel for medium fermentation in which compost is loaded and sterilized therein, comprising: an intake unit for introducing air outside the tunnel into the tunnel; a first exhaust unit for discharging the air introduced into the tunnel by the pressure inside the tunnel; And based on the temperature of the compost loaded in the tunnel, it includes a second exhaust for discharging the air introduced into the tunnel.

Description

Tunnel for fermentation of mushroom medium with easy ventilation control {TUNNEL FOR FERMENTATION OF MUSHROOM CULTURE MEDIUM WITH EASY VENTILATION}

The present invention relates to a tunnel for fermentation of a mushroom medium.

In the process of making the medium, the first medium (Phase 1) is made by mixing straw, chicken manure, and gypsum with agitation and aerobic fermentation, and pasteurizing this compost medium at 56~60℃ and lowering the temperature (40~44) ℃) The secondary medium (Phase 2) that activates the propagation of low-temperature bacteria and removes ammonia is called the tertiary medium (Phase 3).

In the traditional method, primary medium production is outdoors and secondary and tertiary medium production has been done by mushroom growers. In Europe, it has become a general technology in Western Europe to manufacture the primary medium in the bunker and the secondary and tertiary medium in the tunnel. In Korea, two tunnels and bunkers are installed and operated.

It is an object of the present invention to provide a tunnel for medium fermentation in which ventilation amount can be easily controlled even when not only wheat straw but also rice straw or waste cotton are mixed and used as a medium by increasing the ventilation amount of the tunnel.

In addition, in the case of discharging ammonia in the internal air, it is to provide a tunnel for fermentation of a medium recognized as organic farming using nitrite and nitrifying bacteria.

A medium fermentation tunnel according to an embodiment of the present invention is a medium fermentation tunnel for sterilizing by loading compost therein, comprising: an intake unit for introducing air from the outside of the tunnel into the tunnel; a first exhaust unit for discharging the air introduced into the tunnel by the pressure inside the tunnel; And based on the temperature of the compost loaded in the tunnel, it includes a second exhaust for discharging the air introduced into the tunnel.

In an embodiment, the first exhaust unit includes a check valve for discharging air inside the tunnel and preventing the inflow of contaminated air into the first exhaust unit.

In an embodiment, the check valve is opened when the pressure inside the tunnel is greater than or equal to a preset pressure value.

In one embodiment, the second exhaust unit, an exhaust damper through which the air inside the tunnel is discharged; and a filter for preventing the inflow of polluted air into the second exhaust unit.

In one embodiment, the exhaust damper, when the temperature of the compost is less than a preset temperature, the closed mode, when the temperature of the compost is more than the preset temperature, it is converted to an open mode.

In one embodiment, the check valve and the exhaust damper further comprises a control unit for controlling the open mode, the closing mode.

In an embodiment, the first exhaust part is provided to be spaced apart from the second exhaust part.

In one embodiment, the first exhaust portion is provided to extend to one side of the second exhaust portion.

In an embodiment, the second exhaust part has a larger diameter than the first exhaust part.

In one embodiment, it further comprises a bio-scrava through which the air discharged from the first exhaust unit and the second exhaust unit passes.

In an embodiment, the bio-scrava includes water in which nitrite-oxidizing bacteria and nitrifying bacteria are cultured.

The tunnel for medium fermentation according to another embodiment of the present invention is a tunnel for medium fermentation in which compost is loaded and sterilized therein. donation; a second exhaust for discharging air inside the tunnel when the temperature of the compost is higher than or equal to a preset temperature; and a control unit controlling the first exhaust unit and the second exhaust unit to discharge internal air of the tunnel.

The tunnel for medium fermentation according to another embodiment of the present invention is a tunnel for medium fermentation in which compost is loaded and sterilized therein. exhaust; a second exhaust for discharging air inside the tunnel when the temperature of the compost is higher than or equal to a preset temperature; and a bio-scrava through which the internal air of the tunnel discharged from the first exhaust unit and the second exhaust unit passes, wherein the bio-scrava includes water in which nitrifying bacteria and nitrifying bacteria are cultured.

In one embodiment, the first exhaust part and the second exhaust part include a control unit for controlling the internal air exhaust of the tunnel.

A medium fermentation system according to an embodiment of the present invention is a medium fermentation system for sterilizing by loading compost therein, and when the internal pressure is greater than or equal to a preset pressure value, a first exhaust unit for discharging the internal air; a second exhaust for discharging air inside the tunnel when the temperature of the compost is higher than or equal to a preset temperature; a bioscrava through which the internal air of the tunnel discharged from the first exhaust part and the second exhaust part passes; a control unit controlling the internal air exhaust of the tunnel of the first exhaust part and the second exhaust part; a server capable of communicating with the control unit; and a user terminal capable of communicating with the control unit through the server, wherein the bio-scrava contains water in which nitrite-oxidizing bacteria and nitrifying bacteria are cultured.

The tunnel for medium fermentation according to an embodiment of the present invention can easily ferment a compost medium using rice straw or waste cotton.

The tunnel for medium fermentation according to an embodiment of the present invention can be used in organic agriculture when ammonium nitrate made by collecting ammonia by applying bioscrava is used.

1 is a view showing a side view of a tunnel for fermentation of a medium according to an embodiment of the present invention.
Figure 2a is a view showing a side view of a tunnel for fermentation of a medium according to another embodiment of the present invention.
Figures 2b and 2c is a view showing in detail the exhaust part of the tunnel for fermentation medium according to another embodiment of the present invention.
3 is a view showing a block diagram of a tunnel for medium fermentation according to another embodiment of the present invention.
Figure 4a and Figure 4b is a view showing the exhaust portion of the tunnel for fermentation medium according to another embodiment of the present invention.
5 is a graph showing the temperature change for each medium fermentation process of the tunnel for medium fermentation according to another embodiment of the present invention.
Figure 6 is a view showing the time-dependent temperature change of the tunnel for medium fermentation and the existing grower according to another embodiment of the present invention.
7 is a view showing an example in which the tunnel for fermentation of the medium according to an embodiment of the present invention is applied to a smart farm.

The present invention is a secondary process in which the compost medium is pasteurized at 56 to 60 ° C for 8 hours in a tunnel during the process of making the mushroom medium, and then the temperature is lowered to activate the propagation of low-temperature bacteria at 40 to 44 ° C and remove ammonia. In the process of medium (Phase 2), it relates to a tunnel for medium fermentation that has been improved to suit the domestic environment.

More specifically, in the present invention, unlike Western Europe, which uses only wheat straw as a compost medium, in Korea, rice straw and waste cotton are often used, and the temperature difference between summer and winter is severe. In tunnels developed in Europe, sufficient ventilation is possible only with an overpressure duct installed with only a filter, but straw has a hard tissue and a lot of voids, so it is well ventilated. However, it is difficult to ventilate rice straw and waste cotton, and since the adsorption area for fermenting bacteria is large, the temperature can be lowered only by increasing the ventilation volume. In addition, unlike Europe, when the temperature needs to be raised due to the large annual temperature difference, it is necessary to thoroughly insulate and reduce the inflow of cold air to a minimum.

Accordingly, even when a large amount of air is introduced into the tunnel and the pressure inside the tunnel increases, the high temperature inside air can be quickly discharged based on the temperature and the exhaust part through which the air inside the tunnel is discharged through pressure. By increasing the amount of ventilation through the exhaust through which the air inside the tunnel is discharged, the amount of air outside the tunnel passing through the compost can be greatly increased. Accordingly, even when rice straw or waste noodles are used as a compost medium, the secondary medium (Phase 2) process can be easily applied.

In addition, in purifying ammonia gas, ammonium nitrate is produced as a by-product by using a liquid in which nitrite oxidizing bacteria and nitrifying bacteria are cultured instead of sulfuric acid, and accordingly, ammonium nitrate is used as a nitrogen source for mushroom medium, etc. as a raw material for composting or By using it as agricultural fertilizer, it can be used in organic farming.

Hereinafter, the present disclosure will be described with reference to the accompanying drawings. The present disclosure can make various changes and can have various embodiments, and specific embodiments are illustrated in the drawings and the related detailed description is described. However, this is not intended to limit the present disclosure to specific embodiments, and should be understood to include all modifications and/or equivalents or substitutes included in the spirit and scope of the present disclosure. In connection with the description of the drawings, like reference numerals have been used for like elements.

In the present disclosure, expressions such as “first,” “second,” “first,” or “second,” may modify various components of the disclosure, but do not limit the components. For example, the above expressions do not limit the order and/or importance of corresponding components. The above expressions may be used to distinguish one component from another. For example, both the first user device and the second user device are user devices, and represent different user devices. For example, without departing from the scope of the present disclosure, a first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

1 is a view showing a side view of a tunnel for fermentation of a medium according to an embodiment of the present invention.

Referring to FIG. 1 , the tunnel for medium fermentation according to an embodiment of the present invention is a tunnel for medium fermentation in which compost is loaded and sterilized inside 20 , and includes an intake part 110 and an exhaust part 130 . .

The intake unit 110 is an outside air inlet duct that connects the outside of the tunnel 10 and the inside of the tunnel 20 , and is connected to the inside of the tunnel 20 to introduce air from the outside of the tunnel 10 into the inside of the tunnel 20 . have. In addition, the intake unit 110 may circulate the air inside the tunnel 20 . For example, the intake unit 110 introduces air from the outside of the tunnel 10 into the inside 20 of the tunnel and is introduced by an intake fan 111 and an intake fan 111 that can circulate the air inside the tunnel 20 . It includes an external air damper 113 for controlling the amount of air outside the tunnel 10, and a circulating air damper 115 for controlling the amount of air inside the tunnel 20 circulated by the intake fan 111.

Here, the external air damper 113 and the circulating air damper 115 may be connected to each other, and when the external air damper 113 is open by about 70%, the circulating air damper 115 is about 30% may be open. For example, when it is desired to increase the inflow of air outside the tunnel 10, the open ratio of the external air damper 113 may be increased and the open ratio of the circulating air damper 115 may be lowered. . In addition, when it is desired to reduce the inflow of air outside the tunnel 10 and increase the amount of air circulated inside the tunnel 20 , the open ratio of the circulating air damper 115 is increased, and the outside air damper It is possible to lower the open rate of (113).

However, this is an example, and the open ratio of the external air damper 113 and the circulating air damper 115 may be adjusted according to the operator's control.

Accordingly, the intake unit 110 introduces air from the outside of the tunnel 10 through the intake fan 111 and circulates the air outside the tunnel 10 to control the temperature of the compost loaded into the inside of the tunnel 20 . can be easily adjusted.

In addition, the intake unit 110 is installed on the outside of the external air damper 113 to cool the incoming air outside the tunnel 10, the cooling coil 117 and the air polluted through the air outside the tunnel 10 or At least one intake filter 119 may be included to prevent pests, etc. from entering. For example, at least one intake filter 119 is provided with a coarse mesh filter G2 on the outside to prevent large dust or pests from entering, and fine mesh filters F8 and F9 on the inside of the mesh filter G2. ) to prevent spores of other bacteria from entering.

However, it will be understood that this is an example, and the technical spirit of the present invention is not limited in understanding.

Before the air outside the tunnel 10 introduced through the intake unit 110 is supplied toward the compost in the tunnel inside 20, the air outside the tunnel 10 passes through the internal connection pipe 30 to the inside of the tunnel 20 ), a plenum chamber 21 that stores air in the lower space, a grid-shaped grid bottom 22 that supplies the air stored in the plenum chamber 21 toward compost, and an upper portion of the grid bottom 22 Installed in, it may include a mesh 23 and at least one thermometer 24 for measuring the temperature of the compost to help facilitate the movement of the compost. Here, since the temperature of the thermometer 24 may vary depending on the location of the loaded compost when the compost is loaded, a plurality of thermometers 24 may be disposed at regular intervals.

As air from the outside of the tunnel 10 flows into the inside 20 of the tunnel, the exhaust unit 130 may discharge the air introduced into the inside of the tunnel 20 based on the increased pressure inside the tunnel 20 . . For example, the exhaust unit 130 may include a check valve 131 that is opened when the pressure inside the tunnel 20 is greater than or equal to a preset pressure value, and is normally maintained in a closed state. have.

The check valve 131 may prevent external polluted air from being introduced through the exhaust unit 130 .

As described above, in the tunnel 100 for medium fermentation according to an embodiment of the present invention, when the temperature of the compost is less than the set temperature, the external air damper 113 of the intake unit 100 and the circulation air damper 115 of the Through the control, it is possible to increase the temperature by reducing the inflow of external air and increasing the circulation air, thereby promoting aerobic fermentation of the compost and keeping it warm. In addition, when the temperature of the compost is higher than the set temperature, the temperature of the compost can be easily reduced by increasing the inflow of cold air from the outside and reducing the warm circulating air containing the aerobic fermentation heat.

However, in the tunnel 100 for medium fermentation according to an embodiment of the present invention, when rice straw and waste noodles are used, it is difficult to ventilate the rice straw and the waste noodles, and the adsorption habitat area of fermenting bacteria is large, so that the ventilation amount may be insufficient.

That is, the compost medium using rice huts and waste cotton lacks air permeability and the calorific value is high due to the large adsorption area of fermenting bacteria. However, only the configuration of the exhaust unit 130 discharged through the pressure inside the tunnel 20 according to the embodiment of FIG. 1 may not be suitable for the use of compost medium using rice straw and waste cotton due to insufficient ventilation.

In more detail, since it is difficult to sufficiently lower the temperature inside the tunnel 20 during the lowering process when using rice huts and waste noodles, low-temperature bacteria cannot survive in the conditioning process, and ammonia is not reduced. For example, when the temperature inside the tunnel 20 is 52° C. or higher, ammonia is continuously generated in the compost medium located inside the tunnel 20, and the generated ammonia may not be reduced.

To solve this, in another embodiment of the present invention, the ventilation amount of the tunnel 100 for medium fermentation is increased, and the exhaust unit 130 discharged based on temperature and pressure will be described.

Figure 2a is a view showing a side view of a tunnel for fermentation of a medium according to another embodiment of the present invention.

Figures 2b and 2c is a view showing in detail the exhaust part of the tunnel for fermentation medium according to another embodiment of the present invention.

The tunnel 200 for medium fermentation of FIGS. 2A to 2C is similar to the tunnel 100 for medium fermentation of FIG. 1 . Accordingly, the same or similar components are denoted by the same or similar reference numerals, and overlapping descriptions will be omitted for the sake of brevity.

2A to 2C , the tunnel 200 for fermentation of a medium according to another embodiment of the present invention includes a first exhaust portion 130a and a second exhaust portion 130b.

The first exhaust part 130a has a shape similar to that of the exhaust part 130 of FIG. 1 , and may discharge air introduced into the tunnel interior 20 based on the pressure inside the tunnel 20 .

In addition, the first exhaust part 130a is opened when the pressure inside the tunnel 20 is equal to or greater than a preset pressure value, and a check valve 131a for preventing the inflow of contaminated air into the first exhaust part 130a. ) may be included.

For example, in the check valve 131a of the first exhaust part 130a, when the amount of air outside the tunnel 10 introduced through the intake part 110 increases, the pressure inside the tunnel 20 increases. By doing so, it can be opened. Accordingly, the air existing inside the tunnel 20 may be discharged to the outside 10 of the tunnel.

The second exhaust unit 130b may discharge the air introduced into the tunnel interior 20 based on the temperature of the compost loaded in the tunnel interior 20 .

In addition, the second exhaust part 130b is an exhaust damper 131b having an open mode and a closed mode so that the air inside the tunnel 20 can be discharged, and the inflow of contaminated air into the second exhaust part 130b. It includes an exhaust filter (133b) for preventing the.

The exhaust damper 131b may be converted into a closed mode when the temperature of the compost is less than a preset temperature, and an open mode when the temperature of the compost is greater than or equal to a preset temperature.

For example, when the average temperature of the at least one thermometer 24 disposed in the compost is less than a preset temperature, the exhaust damper 131b may be maintained in the closed mode. In order to increase the temperature of the compost, the intake fan 111 of the intake unit 110 is operated, the external air damper 113 is open to 10% or less, and the circulation air damper 115 is opened to 90% or more ( can be open). In this case, the amount of air outside the tunnel 10 introduced from the outside of the tunnel 10 may be reduced, and the amount of air circulated in the inside of the tunnel 20 may be increased. Accordingly, the temperature may rise due to microbial activity in the compost, and the check valve 131a of the first exhaust unit 130a may be opened based on the pressure inside the tunnel 20 increased by a small amount. have.

As another example, when the average temperature of the at least one thermometer 24 disposed in the compost is equal to or higher than a preset temperature, the exhaust damper 131b may be switched to the open mode. At this time, in order to lower the temperature of the compost, the intake fan 111 of the intake unit 110 is operated with strong wind pressure, the external air damper 113 is open to 90% or more, and the circulation air damper 115 is It may be open to 10% or less. In this case, the amount of cold air outside the tunnel 10 introduced from the outside of the tunnel 10 may increase, and the amount of hot air circulated inside the tunnel 20 may be reduced or limited. Accordingly, the amount of cold air flowing into the compost from the outside of the tunnel 10 may increase, and the pressure inside the tunnel 10 may be very high. In this case, since the amount of air introduced through the intake unit 110 is greater than the amount of air discharged from the first exhaust unit 130a, it may be difficult to maintain the pressure inside the tunnel 20 . Accordingly, the exhaust damper 131b is switched to the open mode so that the hot air inside the tunnel 20 can be discharged based on the temperature of the compost, so that the hot air inside the tunnel 20 can be quickly discharged.

The exhaust filter 133b is disposed outside the exhaust damper 131b, and may prevent external polluted air from flowing into the second exhaust part 130b. For example, the exhaust filter 133b may be a coarse mesh filter G2.

As described above, in the medium fermentation tunnel 200 according to another embodiment of the present invention, when the temperature of the compost is higher than a preset temperature, the wind pressure of the intake fan 111 is strongly operated, and the external air damper 113 is high. It is opened at a rate so that the cool outside air can quickly lower the temperature of the compost. Accordingly, in the secondary medium (Phase 2) process of the fermentation medium tunnel, the speed of the process of rapidly lowering the temperature of the compost can be advanced more rapidly. In addition, when the intake fan 111 is strongly operated and the external air damper 113 is open at a high rate, the air inside the tunnel 20 is discharged from the first exhaust unit 130a by pressure. At the same time, the exhaust damper 131b of the second exhaust unit 130b operates in the open mode, so that the hot air inside the tunnel 20 can be quickly discharged.

More specifically, when the temperature of the compost is higher than or equal to a preset temperature, the intake fan 111 may be strongly operated, and the external air damper 113 may be opened at a rate of 90% or more. At this time, the circulating air damper 115 may be opened at a rate of 10% or less, and when the external air damper 113 is 100% open, the circulating air damper 115 is closed. ) state is also possible. Accordingly, the cold air outside the tunnel 10 can be rapidly supplied toward the compost loaded in the tunnel inside 20 , and the pressure inside the tunnel 20 can also be rapidly increased. Therefore, both the check valve 131a of the first exhaust part 130a and the exhaust damper 131b of the second exhaust part 130b are opened in the open mode, and the hot air present in the tunnel interior 20 is can be expelled quickly.

When the temperature of the compost is lower than the preset temperature, the wind pressure of the intake fan 111 is weakly operated, the external air damper 113 is opened at a low rate, and the circulating air damper 115 is opened at a high rate ( open), so that the circulation of hot air inside the tunnel 20 can be made. Accordingly, the amount of cold air flowing into the tunnel inside 20 from the outside 10 of the tunnel is reduced, and the amount of warm air circulating in the inside of the tunnel 20 is increased, thereby increasing the temperature of the compost. At this time, the air inside the tunnel 20 may be discharged from the first exhaust part 130a according to the pressure inside the tunnel 20 , and the exhaust damper 131b of the second exhaust part 130b is closed. ) mode can be maintained.

More specifically, when the temperature of the compost is less than the preset temperature, the intake fan 111 is weakly operated, and the external air damper 113 may be opened at a rate of 10% or less. At this time, the circulating air damper 115 may be open at a rate of 90% or more, and the external air damper 113 is open at a rate of at least 3% or more to supply oxygen required for aerobic fermentation. It is preferable to have Accordingly, a small amount of air may be introduced into the tunnel interior 20 from the outside 10 of the tunnel, and as a large amount of air circulates in the tunnel interior 20, the temperature of the compost may increase. At this time, since the pressure value inside the tunnel 20 changes in a small amount, the pressure inside the tunnel 20 can be controlled only by discharging the air inside the tunnel 20 through the check valve 131a of the first exhaust unit 130a. It may be possible. Accordingly, the exhaust damper 131b of the second exhaust unit 130b may be maintained in a close mode state.

2A and 2B , the first exhaust part 130a and the second exhaust part 130b according to another embodiment of the present invention are disposed spaced apart from each other on the ceiling portion of the tunnel 200 for fermentation of the medium. can be

Referring to FIG. 2C , the first exhaust part 130a according to another embodiment of the present invention may be disposed to extend to one side of the second exhaust part 130b. In this case, two types of exhaust units 130 may be provided with one perforation in the ceiling portion of the tunnel 200 for fermentation of the medium.

Also, the second exhaust part 130b may be formed to have a larger diameter than the first exhaust part 130a. Accordingly, when the pressure inside the tunnel 20 is high, a small amount of air inside the tunnel 20 is discharged through the first exhaust part 130a, and when the temperature inside the tunnel 20 is high, the second exhaust part ( 130b), a large amount of air can be expelled quickly. For example, when the temperature of the compost is higher than or equal to a preset temperature, the exhaust damper 131b of the second exhaust unit 130b may be converted to an open mode, and accordingly, the hot air inside the tunnel 20 is quickly discharged can be discharged, and since the open ratio of the external air damper 113 is increased, the cold air from the outside of the tunnel 10 is introduced into the inside 20 of the tunnel 20, so the temperature inside the tunnel 20 is easily lowered. can fall In addition, when the temperature of the compost is below the preset temperature, the exhaust damper 131b of the second exhaust unit 130b may be maintained in a closed mode, and warm through the check valve 131a of the first exhaust unit 130a. A small amount of internal air may be vented. The open ratio of the external air damper 113 may be lowered, and the open ratio of the circulating air damper 115 may be increased. In this case, since the warm air circulating inside the tunnel 20 increases more than the cold air flowing in from the outside 10 of the tunnel, the air inside the tunnel 20 is advantageous for thermal insulation.

As described above, the tunnel 200 for medium fermentation according to another embodiment of the present invention uses rice straw or waste cotton as a compost medium as in Korea, and can be easily used even in an environment where the temperature difference between summer and winter is severe. have.

For example, rice straw and waste cotton are difficult to ventilate and the adsorption area for fermenting bacteria is large, so even if a tunnel is used, the amount of ventilation is low and cooling by ventilation is difficult, so the secondary medium (Phase 2) process may be long or impossible. Accordingly, in the tunnel 200 for medium fermentation according to another embodiment of the present invention, based on the first exhaust portion 130a through which the air inside the tunnel 20 is discharged through pressure and the preset temperature, the inside of the tunnel 20 is By increasing the ventilation amount through the second exhaust unit 130b through which the hot air is discharged, the amount of cold air outside the tunnel 10 passing through the compost can be greatly increased.

However, this is only an example, and when the tunnel 200 for medium fermentation according to another embodiment of the present invention is made long, the first exhaust part 130a and the second exhaust part 130b will be provided in plurality. can

3 is a view showing a block diagram of a tunnel for medium fermentation according to another embodiment of the present invention.

2A and 3 , the tunnel 200 for medium fermentation according to another embodiment of the present invention has an intake part 110 , a first exhaust part 130a , a second exhaust part 130b and a control part 170 . ) is included.

The intake part 110 , the first exhaust part 130a , and the second exhaust part 130b are similar to the intake part 110 , the first exhaust part 130a , and the second exhaust part 130b of FIG. 2A . Accordingly, the same or similar components are denoted by the same or similar reference numerals, and overlapping descriptions will be omitted for the sake of brevity.

The control unit 170 may control the operation of the intake fan 111 disposed inside the intake unit 110 . In addition, the controller 170 may adjust the open ratio of the external air damper 113 and the circulating air damper 115 .

As the control unit 170 controls the wind pressure of the intake fan 111 and adjusts the open ratio of the external air damper 113 and the circulating air damper 115, the outside of the tunnel introduced through the intake unit 110 The amount of cold air in (10) and the amount of warm air circulated inside the tunnel (20) can be adjusted.

For example, according to the temperature of the compost, the wind pressure value of the intake fan 111 is adjusted through the control unit 170, and the open ratio of the external air damper 113 and the circulating air damper 115 is adjusted. It is possible to maintain an appropriate compost temperature value during the medium process.

In addition, the control unit 170 can adjust the open mode and the close mode state of the check valve 131a of the first exhaust part 130a and the exhaust damper 131b of the second exhaust part 130b. have. Accordingly, the pressure level inside the tunnel 20 can be adjusted according to the user's manipulation of the control unit 170 .

Figure 4a and Figure 4b is a view showing the exhaust portion of the tunnel for fermentation medium according to another embodiment of the present invention.

4A and 4B, a tunnel 300 for fermentation of a medium according to another embodiment of the present invention is a bio-scrava 150 connecting the first exhaust part 130a and the second exhaust part 130b. includes

The bio-scrava 150 is connected to the first exhaust part 130a and the second exhaust part 130b, and the tunnel interior 20 is discharged through the first exhaust part 130a and the first exhaust part 130b. of air can pass through. For example, one end of the first exhaust part 130a and the second exhaust part 130b is connected to the inside of the tunnel 20 , and the other end is connected to the bioscrava 150 , so that the first exhaust part 130a is connected to the first exhaust part 130a. And the air inside the tunnel 20 discharged through the second exhaust unit 130b may be moved to the bio-scrava (150). Accordingly, the air inside the tunnel 20 discharged through the first exhaust part 130a and the second exhaust part 130b is the liquid in which the nitrite oxidizing bacteria and nitrifying bacteria located inside the bioscrava 150 are cultured. It may pass through and be discharged to the outside of the tunnel 10 .

Accordingly, it is possible to minimize the odor due to the discharge of ammonia, and ammonium nitrate is generated as a by-product, which can be used in organic farming.

Existing scraper using ammonia gas for cleaning is sans scraper using sulfuric acid. When ammonia passes through scraper, ammonium sulfate is generated as a by-product, and when used as a raw material for composting or agricultural fertilizer, it is recognized as organic farming. do not receive

The bio-scrava 150 of the tunnel 300 for fermentation of the medium according to another embodiment of the present invention is the inside of the tunnel 20 discharged through the first exhaust part 130a and the second exhaust part 130b. In passing ammonia generated from air, a liquid in which nitrite-oxidizing bacteria and nitrifying bacteria are cultured may be used. Accordingly, ammonium nitrate may be generated as a by-product. When using the ammonium nitrate generated here as a raw material for composting or agricultural fertilizer, it can be used in organic agriculture.

5 is a graph showing the temperature change for each medium fermentation process of the tunnel for medium fermentation according to an embodiment of the present invention.

1 and 5, the secondary medium (Phase 2) of the medium fermentation process of the medium fermentation tunnel 100 is temperature leveling (leveling), warming, pasteurization, low temperature, conditioning, low temperature for seed inoculation includes the process.

The medium fermentation process of the tunnel 100 for medium fermentation is a medium fermentation process using a compost medium using compaction.

First, in the temperature leveling process, compost is filled in a tunnel, and at least one thermometer is inserted into the compost to check a temperature deviation according to the position of the compost. The temperature of the compost can be leveled until the temperature deviation of the compost is within 3℃. At this time, the temperature of the compost can be adjusted to 44 ~ 46 ℃ through the control unit. In this process, the temperature of the compost can be controlled through the control of the external air damper 113 . For example, when the compost temperature is higher than the preset temperature, increase the open ratio of the external air damper 113, and when the temperature is below the preset temperature, lower the open ratio of the external air damper 113 can In the temperature leveling process, the wind pressure of the intake fan 111 may be operated as the maximum wind pressure.

In another embodiment of the present invention, referring to FIGS. 2A and 3 , unlike using dense as a compost medium in one embodiment, when rice straw and waste cotton are used as a compost medium, ventilation is difficult and the adsorption habitat area of fermenters is wide. It can be seen that the first exhaust part 130a and the second exhaust part 130b are added when the ventilation amount needs to be increased a lot. Even in a compost medium using rice straw and waste cotton, which is difficult to ventilate with a high ventilation amount through the second exhaust unit 130b that is controlled according to the temperature, a temperature leveling process may be performed similarly to using dense as a compost medium.

In the warming up process, the corresponding process can be started when the temperature difference between each part of the compost is less than 3°C during the temperature leveling process. At this time, it is preferable to adjust the compost temperature so that it can rise by 1.2 ~ 1.5 ℃ per hour. In the warming up process, if the open ratio of the external air damper 113 is as low as possible and the open ratio of the circulating air damper 115 is increased as much as possible to reduce the speed of the intake fan 111, microbial activity in the compost This may cause the temperature to rise. At this time, the pasteurization process can be started when the compost and the room temperature are above 56℃.

The pasteurizing process may begin when the room temperature and all compost thermometers 24 show 56°C or higher. By maintaining the room temperature and compost temperature at 56~60℃ for about 8 hours, it is possible to kill germs in the compost. The ammonia concentration at the end of the pasteurization can be measured in the range of 250 to 600 ppm.

In the cooling process for conditioning, the temperature can be lowered by 2-3°C per hour after maintaining the pasteurization for 8 hours. After setting the room temperature to 45 ℃, it is possible to control the outside air damper 113 to introduce cool air into the compost. When the compost temperature reaches 47-49°C, the conditioning process can be performed.

Here, in the case of using rice husks and waste noodles, since it is difficult to sufficiently lower the temperature inside the tunnel 20 during the lowering process, low-temperature bacteria cannot survive in the conditioning process, and ammonia is not reduced. For example, when the temperature inside the tunnel 20 is 52° C. or higher, ammonia is continuously generated in the compost medium located inside the tunnel 20, and the generated ammonia may not be reduced.

In this process, referring to FIGS. 2A to 2C , in the tunnel 200 for medium fermentation according to another embodiment of the present invention, when the temperature of the compost is measured above a preset temperature, the outside air damper 113 is opened. The (open) ratio is increased to the maximum value, and the wind pressure of the intake fan 111 is raised to the maximum value so that the inflow of air outside the tunnel 10 can be made quickly. At this time, as the pressure inside the tunnel 20 increases, the check valve 131a of the first exhaust part 130a is opened, and as the temperature of the compost is measured above a preset temperature, the second exhaust part The exhaust damper 131b of 130b may be operated in the open mode. Accordingly, the air outside the tunnel 10 may be discharged through the first exhaust part 130a and the second exhaust part 130b through the compost quickly. Accordingly, the amount of ventilation of the tunnel 200 for fermentation of the medium is increased, so that the lowering process can be performed quickly.

The temperature during the conditioning period can be maintained at 46-49°C. In this case, the temperature of the compost can be adjusted by adjusting the open ratio of the external air damper 113 and the circulation air damper 115 . The completion of conditioning can be known by measuring ammonia in the compost, and from the second day of conditioning, ammonia measurement can be started using a Drager tube. When the ammonia content is less than 5ppm, it can be known that the compost is ammonia free, and at this time, the compost can be heated and the seed inoculation can be prepared.

In the low temperature process for seed inoculation, the compost can be cooled through the air outside the tunnel 10 by increasing the open ratio of the external air damper 113 . The optimum temperature for seed inoculation is 25, and it can be adjusted to 28°C in cold conditions and 23°C in hot conditions.

Figure 6 is a view showing the time-dependent temperature change of the tunnel for medium fermentation and the existing grower according to another embodiment of the present invention.

6, the graph on the left is a graph showing the compost temperature of the secondary medium (Phase 2) process in the tunnel 100 for medium fermentation according to an embodiment of the present invention, and the graph on the right is a tray ( tray) or a graph showing the compost temperature of the secondary medium (Phase 2) process performed on the fungus.

In the grower, air flows around the compost to lengthen the secondary medium (Phase 2) process, while referring to FIG. 1 , the medium fermentation tunnel 100 according to an embodiment of the present invention blows air into the compost to Both the secondary medium (Phase 2) process can be performed during the period.

In addition, referring to Figure 2a, the medium fermentation tunnel 200 according to another embodiment of the present invention uses rice straw or waste cotton as a compost medium as in Korea, and it is easy even in the case of an environment where the temperature difference between summer and winter is severe. can be used

For example, rice straw and waste cotton are difficult to ventilate and the adsorption area for fermenting bacteria is large, so even if a tunnel is used, the amount of ventilation is low and cooling by ventilation is difficult, so the secondary medium (Phase 2) process may be long or impossible. Accordingly, in the tunnel 200 for medium fermentation according to another embodiment of the present invention, based on the first exhaust portion 130a through which the air inside the tunnel 20 is discharged through pressure and the preset temperature, the inside of the tunnel 20 is By increasing the ventilation amount through the second exhaust unit 130b through which air is discharged, the amount of air outside the tunnel 10 passing through the compost can be greatly increased.

7 is a view showing an example of applying the medium fermentation system according to an embodiment of the present invention to a smart farm.

Referring to FIG. 7 , the medium fermentation system is also applicable to the smart farm 1000 . The smart farm 1000 may include a medium fermentation system, a server 400 , and a user terminal 500 . The medium fermentation system includes an intake part 110 , a first exhaust part 130a , a second exhaust part 130b and a control part 170 , and an intake part 110 , a first exhaust part 130a , and a second Since the exhaust unit 130b and the control unit 170 are the same as the intake unit 110, the first exhaust unit 130a, the second exhaust unit 130b and the control unit 170 shown in FIGS. 1, 2 and 3, A detailed description will be omitted. In one embodiment of the present invention, the medium fermentation system may be arranged in a tunnel. The control unit 170 of the medium fermentation system may communicate with the user terminal 500 through the server 400 .

For example, the user terminal 500 is a smartphone (Smartphone), a smart pad (Smart Pad), a tablet PC, a wearable device, PCS (Personal Communication System), GSM (Global System for Mobile communication), PDC (Personal Digital Cellular) , PHS (Personal Handyphone System), PDA (Personal Digital Assistant), IMT (International Mobile Telecommunication)-2000, CDMA (Code Division Multiple Access)-2000, W-CDMA (W-Code Division Multiple Access), Wibro (WirelessBroadband Internet) It may be any kind of wireless communication device such as a terminal, a desktop computer, and a stationary terminal such as a smart TV.

The server 400 connects the user terminal 500 and the control unit 170 of the medium fermentation system to enable communication with each other.

As described above, the present invention has been described with reference to the illustrated drawings, but the present invention is not limited by the embodiments and drawings disclosed in the present specification. It is obvious that variations can be made. In addition, although the effects according to the configuration of the present invention have not been explicitly described and described while describing the embodiments of the present invention, it is natural that the effects predictable by the configuration should also be recognized.

100, 200, 300: Tunnel for medium fermentation
110: intake
130: exhaust part
130a: first exhaust part
130b: second exhaust unit
150: bioscrava
170: control unit

Claims (15)

In a medium fermentation tunnel for sterilizing by loading compost inside,
an intake unit for introducing air from outside the tunnel into the inside of the tunnel;
a first exhaust unit for discharging the air introduced into the tunnel by the pressure inside the tunnel; and
Based on the temperature of the compost loaded inside the tunnel, the tunnel for medium fermentation comprising a second exhaust for discharging the air introduced into the tunnel. According to claim 1,
The first exhaust unit,
The air inside the tunnel is discharged,
A tunnel for medium fermentation, comprising a check valve for preventing the inflow of polluted air into the first exhaust unit. 3. The method of claim 2,
The check valve is
A tunnel for medium fermentation, which is opened when the pressure inside the tunnel is greater than or equal to a preset pressure value. 3. The method of claim 2,
The second exhaust unit,
an exhaust damper through which air inside the tunnel is discharged; and
A tunnel for medium fermentation, comprising a filter for preventing the inflow of contaminated air into the second exhaust unit. 5. The method of claim 4,
The exhaust damper is
When the temperature of the compost is less than a preset temperature, closed mode,
When the temperature of the compost is above a preset temperature, it is converted to an open mode, medium fermentation tunnel. 5. The method of claim 4,
Further comprising a control unit for controlling the open mode, the closed mode of the check valve and the exhaust damper, medium fermentation tunnel. According to claim 1,
The first exhaust unit,
A tunnel for medium fermentation, which is provided to be spaced apart from the second exhaust. According to claim 1,
The first exhaust unit
A tunnel for medium fermentation that is provided to extend to one side of the second exhaust. According to claim 1,
The second exhaust unit,
The size of the diameter of the first exhaust portion is larger, medium fermentation tunnel. According to claim 1,
The tunnel for fermentation of the medium further comprising a bio-scrava through which the air discharged from the first exhaust part and the second exhaust part passes. 11. The method of claim 10,
The bioscrava is
Tunnel for medium fermentation, containing nitrite and nitrifying bacteria cultured liquid In a medium fermentation tunnel for sterilizing by loading compost inside,
a first exhaust unit discharging the internal air when the internal pressure is greater than or equal to a preset pressure value;
a second exhaust for discharging air inside the tunnel when the temperature of the compost is higher than a preset temperature; and
A tunnel for medium fermentation, comprising a control unit for controlling the first exhaust part and the second exhaust part to discharge the internal air of the tunnel. In a medium fermentation tunnel for sterilizing by loading compost inside,
a first exhaust unit discharging the internal air when the internal pressure is greater than or equal to a preset pressure value;
a second exhaust for discharging air inside the tunnel when the temperature of the compost is higher than a preset temperature; and
and a bio-scrava through which the internal air of the tunnel discharged from the first exhaust part and the second exhaust part passes,
The bioscrava is
A tunnel for medium fermentation, containing a liquid in which nitrite and nitrifying bacteria are cultured. 14. The method of claim 13,
A tunnel for medium fermentation comprising a control unit for controlling the internal air discharge of the tunnel of the first exhaust part and the second exhaust part. In the medium fermentation system for sterilizing by loading compost inside,
a first exhaust unit discharging the internal air when the internal pressure is greater than or equal to a preset pressure value;
a second exhaust for discharging air inside the tunnel when the temperature of the compost is higher than a preset temperature;
a bioscrava through which the internal air of the tunnel discharged from the first exhaust part and the second exhaust part passes;
a control unit controlling the internal air exhaust of the tunnel of the first exhaust part and the second exhaust part;
a server capable of communicating with the control unit; and
and a user terminal capable of communicating with the control unit through the server,
The bioscrava is
A medium fermentation system comprising a liquid in which nitrite-oxidizing bacteria and nitrifying bacteria are cultured.

Images