KR20190064740A - A Plant for Cultivating a Mushroom - Google Patents

Abstract

The present invention relates to a plant factory for mushroom cultivation and, more specifically, to a plant factory for mushroom cultivation which enables mushroom cultivation by artificially creating environment indoors. The plant factory for mushroom cultivation includes: a control module (11) for the control of an operation; beds (13a, 13b) in which at least one mushroom culture medium (131 to 134) is arranged; a water supply means (12) which supplies water; at least one waterway (15, 151, 152) which is formed along the beds (13a, 13b) so that the water supplied from the water supply means (12) forms a flow path; condition formation modules (16, 17) which form a growth environment; and a peripheral wall (10) which forms a growth space.

Description

{Plant for Cultivating a Mushroom}

The present invention relates to a plant for mushroom cultivation, and more particularly, to a plant for mushroom cultivation in which mushroom cultivation is possible by artificially creating an environment indoors.

Studies on various types of mushrooms have revealed the importance of mushroom artificial cultivation techniques as nutritional value and medicinal value of mushrooms are revealed. The mushroom, mushroom, oyster, throat, pine mushroom or similar mushroom can be prepared by preparing the medium, cultivating the seed bacterium, inoculating the medium, cultivating the seed bacterium in the medium for a predetermined period, and harvesting the mushroom cultivated in the medium It can be cultivated through the process. The medium may be made of sawdust or oak depending on the type of mushroom, and the process of cultivation and maturation in the medium needs to be adjusted appropriately according to the species of the mushroom.

It is advantageous that the mushroom is cultivated in an environment where water is continuously supplied at a temperature condition of 10 to 30 DEG C, for example, and humidity of 70 to 80% is maintained. In order to maintain water supply and humidity, the medium should be supplied with water or sprinkled on the medium. However, if the supply of water and the maintenance of humidity are artificially carried out, there arises a problem that it is difficult to maintain proper environmental conditions continuously because a large amount of labor is required.

Although natural or chemical fertilizers do not need to be used separately for the cultivation of mushrooms, it is advantageous to include ingredients which are necessary for the growth of mushrooms and which, at the same time, have a beneficial effect on the human body after ingestion.

Utility Model No. 20-2014-0001356 and Patent Registration No. 10-1514236 disclose a mushroom culture water supply device for supplying water to mushroom culture media. It is advantageous that the cultivation of the mushroom is carried out according to various growth conditions including the supply of water and it is advantageous to have the structure of the plant factory for this purpose. However, the prior art does not disclose the structure of a plant plant in which the formation of appropriate conditions to enable the cultivation of mushrooms such as, for example, mushrooms, is possible.

The present invention has the following problems in order to solve the problems of the prior art.

Prior art 1: Utility model No. 20-2014-0001356 (published by Lee Chang-jung, Mar. 07, 2014) Prior Art 2: Patent Registration No. 10-1514236 (Ko Chan Oh, Announcement on April 22, 2015) Mushroom Badge Water Supply Device

It is an object of the present invention to provide a plant for mushroom cultivation capable of controlling the internal conditions according to the growth process while having various kinds of mushroom growth conditions.

According to a preferred embodiment of the present invention, a plant for mushroom cultivation comprises a control module for control of operation; A bed on which at least one mushroom culture medium is disposed; Water supply means for supplying water; At least one water channel formed along the bed so that water supplied from the water supply means forms a flow path; A conditioning module for forming a growth environment; And a peripheral wall forming a growth space.

According to another preferred embodiment of the present invention, the peripheral wall comprises a clayey layer.

According to another preferred embodiment of the present invention, the water fed to the water channel contains dissolved sulfur components in an amount of 0.001 to 0.10 wt%.

The plant for mushroom cultivation according to the present invention allows various mushrooms including Chamaecyparis obtusa to grow by artificially formed conditions in the room. In this way, the mushroom or similar mushroom can be produced without restriction on the natural condition or the external environment. For example, a part of a farm house or a city house that does not live in a person can be appropriately remodeled and made into a plant for the cultivation of mushrooms. Further, the plant plant according to the present invention has an advantage that it can be produced on various scales from small scale to large scale, and can be operated without any special knowledge.

Fig. 1 shows an embodiment of a plant for mushroom cultivation according to the present invention.
Fig. 2 shows an embodiment of the operating structure of the plant according to the present invention.
FIG. 3 shows an embodiment of a water supply structure applied to a plant plant according to the present invention.
Fig. 4 shows an embodiment of the supply adjusting means applied to the water supply structure according to the present invention.
Fig. 5 shows an embodiment of the structure for supplying water according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so that they will not be described repeatedly unless necessary for an understanding of the invention, and the known components will be briefly described or omitted. However, It should not be understood as being excluded from the embodiment of Fig.

Fig. 1 shows an embodiment of a plant for mushroom cultivation according to the present invention.

1, a plant for mushroom cultivation includes a control module 11 for control of operation; A bed (13a, 13b) in which at least one mushroom culture medium (131 - 134) is disposed; Water supply means (12) for supplying water; At least one water channel (15, 151, 152) formed along the bed (13a, 13b) so that the water supplied from the water supply means (12) forms a flow path; Conditioning modules (16, 17) forming a growth environment; And a peripheral wall 10 forming a growth space.

Plant factories can be applied to the cultivation of various kinds of mushrooms, for example, to cultivate mushrooms, shiitake mushrooms, mushrooms or similar edible mushrooms. Plant factories can be made independently for the cultivation of mushrooms, by converting houses or similar buildings, or by converting parts of houses or buildings.

The operation of the entire facility of the plant plant can be controlled by the control module 11, and in particular, the operation of the power plant, water supply plant, lighting plant, temperature or humidity plant can be controlled. The operation of the control module 11 can be done remotely and the operation can be controlled by a portable electronic device such as, for example, a smart phone. For example, the growth data for each mushroom is prepared in advance, and the growth data can include data on the growth environment required for each mushroom's growth process. The control module 11 can control the operation of the plant factory and the control module 11 can include communication means 111 for wired or wireless communication based on the growth data, The control module 11 can communicate with a management server associated with the management of the portable electronic device or the plant factory.

At least one bed 13a or 13b may be installed in the plant factory and at least one mushroom culture medium 131 or 134 may be arranged in each bed 13a or 13b. The beds 13a and 13b may be disposed on the bottom surface of the plant or in a laminated structure on the arrangement frame and one or more mushroom media 131 to 134 may be disposed on each of the beds 13a and 13b Mushrooms such as mushrooms can be grown. The culture strains of the mushroom culture media 131 to 134 grow mushrooms by the supply of water, and moisture can be supplied from the water channels 15, 151 and 152.

The beds 13a and 13b may have a rectangular plane, and a plurality of the beds 13a and 13b may be arranged side by side. The channels 15, 151 and 152 may be formed along the extending direction of the beds 13a and 13b. For example, the channels 15, 151 and 152 may be formed on the circumferential surfaces or between the beds 13a and 13b . The growth space of the plant plant can form one closed compartment, and the water supply means 12 can be arranged inside or outside the growth space. The water supply means 12 may be, for example, a supply connection means connected to tap water corresponding to a water storage tank or an external water supply means. The water supply means 12 may be connected to the water purifier 14 and the filtered water through the water purifier 14 may be supplied to the water channels 15, The water channels 15, 151 and 152 can form a circulation path and the amount of water flowing along the water channels 15, 151 and 152 can be controlled by the supply control unit 18. [

The water channels 15, 151 and 152 may be connected to the mushroom culture media 131 to 134 by the water induction units S1 to SN. The water induction units S1 to SN may be various means capable of supplying the water of the water channels 15, 151 and 152 to the mushroom culture media 131 to 134, for example, Strands of fibers or similar materials. The supply of water by the capillary phenomenon has the advantage that a constant level of water is supplied while the continuous supply of water is possible. Further, there is an advantage that no separate means for controlling the amount of movement or movement of water or moisture is required. The transfer of water or the supply of water from the water channels 15, 151, 152 to the mushroom culture media 131 to 134 can be achieved by various methods and is not limited to the illustrated embodiment.

The amount of water or the circulation period of water flowing through the water channels 15, 151, 152 can be adjusted by the supply adjustment unit 18, and the supply adjustment unit 18 can be arranged at various positions with various structures.

In order to grow the mushroom, the growth space needs to be controlled in terms of temperature, humidity or amount of light. To this end, the temperature regulation module 16 and the lighting module 17 may be installed in the conditioning modules 16 and 17 . The temperature control module 16 may be a heater, a heater, a fan or a cooling means, and the lighting module 17 may be, for example, but not limited to, an LED module capable of emitting light of various wavelengths . The temperature regulation module 16 may have the structure of an air circulation facility and the temperature of the growth space may be controlled by controlling the temperature of the circulated air. Further, the illumination module 17 may be arranged to emit light of a wavelength band determined by each mushroom culture medium 131 to 134, and the operation time of the illumination module 17 may be preset.

Means for adjusting the humidity inside the growth space may be installed independently or not. Specifically, a sufficient amount of water can be supplied by the water flowing along the channels 15, 151 and 152, and the humidity inside the growth space can be automatically adjusted by the temperature controlled by the temperature control module 16 have. In addition, circulation units 19a and 19b for air inside the growth space can be provided, air circulation inside the growth space can be controlled by the circulation units 19a and 19b, or air circulation can be performed between the inside and outside of the growth space Lt; / RTI > The circulation units 19a and 19b may be operated together with the temperature regulation module 16 or may be integrally formed and the humidity inside the growth space can be controlled by the circulation units 19a and 19b.

The growth space may form a closed space or a similar space, and a peripheral wall 10 may be formed to partition the growth space from the outside. The inner surface of the peripheral wall 10 may include an alveolar layer, and the alveolar layer has a function of reducing the temperature difference at different positions inside the growth space, for example, emitting far-infrared rays or anions. In addition, the loess composition absorbs the harmful components generated during the growth of the mushroom to remove the harmful components that the mushroom can have. The loess forming the loess layer comprises 50 to 70 wt% of silica, 3 to 10 wt% of Fe, 8 to 15 wt% of alumina, 1 to 5 wt% of magnesium, 1 to 3 wt% of sodium, wt% of carly and 5 to 10 wt% of lime. The loess also can include potassium carbonate, quartz, feldspar, mica or calcite. The loess layer containing various components can form the peripheral wall 10, and the present invention is not limited to the embodiments shown.

According to one embodiment of the present invention, sulfur, which may include sulfur components supplied to the respective mushroom culture media 131 to 134, is dissolved in an amount of 0.001 to 0.10 wt% with respect to the total weight of water; Sodium ion in an amount of 0.0001 to 0.05 wt% based on the total weight of water; And 1 to 50 ppm of at least one component selected from the group consisting of K component, Al component, magnesium component, iron component, molybdenum component, silicon component, calcium component, germanium component, phosphorus component, titanium component and niobium component extracted from the mineral And may have a surface tension of 70 to 75 dyne / cm at 25 ° C. The sulfur component supplied to the mushroom culture medium (131 to 134) may be a sulfur component from which toxicity has been eliminated, and preparing sulfur; Preparing a sodium hydroxide solution; Dissolving the sulfur prepared in the sodium hydroxide solution; And adding a mineral component to the solution in which the sulfur is dissolved. Specifically, a sulfur component in the form of powder may be prepared for the production of a sulfur component to be added to water. Sodium hydroxide solution may be prepared when the sulfur of the powder component is prepared. The sodium hydroxide solution can be made by dissolving 200 to 500 g of sodium hydroxide per 1,000 g of water, but is not limited thereto. When the sodium hydroxide solution is prepared in this way, the sulfur prepared in the sodium hydroxide solution can be dissolved. Sulfur can be made in such a way that an amount of 150 to 400 g is added to the amount of sodium hydroxide produced above. It can be dissolved slowly while stirring with the addition of sulfur. If the sulfur is dissolved in the sodium hydroxide solution in such a way, a mineral component can be added.

The addition of the mineral component is carried out, for example, by adding at least one selected from the group consisting of K component, Al component, magnesium component, iron component, molybdenum component, silicon component, calcium component, germanium component, phosphorus component, titanium component and niobium component extracted from the mineral The method comprising extracting a component useful for plant growth from a mineral containing the components of the plant. For extraction of these components from minerals, refined manganese, elvan, zeolite or rare earth minerals may be prepared by refining or washing. And the sulfur-containing sodium hydroxide solution can be diluted, for example the liquid sulfur composition can be diluted to include dissolved sulfur in an amount of 0.001 to 0.10 wt% based on the total weight of water. Thereafter, the refined mineral is immersed in a diluted sulfur-containing sodium hydroxide solution and maintained at a temperature of 20 to 40 DEG C for 24 to 72 hours, whereby a mineral component can be extracted. Or a dilute sulfur composition in which the sulfur-containing sodium hydroxide solution is diluted in the amounts indicated above, to flow the purified mineral. According to the method described above, K, Al, magnesium, iron, molybdenum, silicon, calcium, germanium, phosphorus, titanium and niobium were extracted from the minerals and diluted with sulfuric sodium hydroxide solution Whereby a liquid-phase sulfur composition can be produced. And the liquid sulfur composition contains at least one component selected from the group consisting of a K component, an Al component, a magnesium component, an iron component, a molybdenum component, a silicon component, a calcium component, a germanium component, a phosphorus component, a titanium component and a niobium component It can be included in quantity. Also, the surface tension of the sulfur composition at 25 占 폚 may be 70 to 75 dyne / cm. And the sulfur component containing the mineral component thus produced may be added to the waterways 15, 151 and 152 in the amounts described above. For example, a sulfur storage tank for storing sulfur components may be prepared, and sulfur components may be added to the water channels 15, 151, 152 from the sulfur storage tank in a controlled amount.

Sulfur components can be made in a variety of ways and are not limited to the embodiments shown.

Fig. 2 shows an embodiment of the operating structure of the plant according to the present invention.

2, the operation of the power regulating unit 211, the growth regulating unit 212 or the environment regulating unit 213 can be adjusted by the control module 11. [ The power regulation unit 211 may have a function of regulating power supplied to various operation modules such as a lighting module or a temperature regulation module. Also, the power control unit 211 may have a function of confirming and storing the amount of power supplied to the entire plant plant, and may have a function of storing the amount of power consumed in each module for a predetermined period of time. The growth regulating unit 212 may have a function of confirming the amount of water supplied to each mushroom culture medium. For example, the growth regulating unit 212 may stop the supply of water from the water channel to the mushroom culture medium or start the supply. In addition, the growth regulating unit 212 can confirm and store the amount of water supplied to each mushroom culture medium for a predetermined period of time.

The temperature, humidity or air circulation speed inside the growth space can be adjusted by the environment adjustment unit 213, and the operation time and the wavelength band of the LED illumination can be adjusted. And the value of the growth environment parameter adjusted by the environmental control unit 213 may be stored for a certain period of time, and the environmental parameter may be such as temperature, humidity, circulation period or optical wavelength.

The supply state of the power supply, the operation state of the temperature control module, the supply state of water or the operation state of the lighting module can be detected by the supply environment detection unit 221 and the growth state of the mushroom in the medium by the medium detection unit 222 Can be detected. The media detection unit 222 may include, for example, a camera unit, a moisture measurement unit or an illumination measurement unit, and may detect the growth condition of the mushroom in each medium. Also, the growth environment detection unit 223 can detect temperature, humidity, amount of water in the waterway, amount of light, flow rate of airflow, amount of oxygen or carbon dioxide, etc. in the growth space. The information detected by the supply environment detection unit 221, the medium detection unit 222, and the growth environment detection unit 223 may be transmitted to the information processing unit 23. The information processing unit 23 can classify the information detected by each of the detection units 221, 222 and 223 and transmit it to the analysis unit 24 according to a predetermined period.

The analysis unit 24 may comprise a comparator and the detection information transmitted in the information processing unit 23 may be compared with a predetermined criterion. Depending on the result of the comparison, it is possible to determine whether the malfunction, the setting error or the operation level is corrected. For example, it is judged whether or not the wavelength band is appropriate, and the malfunction of the power supply equipment can be detected. In addition, it can be detected whether the growth condition of the mushroom grown in each medium is appropriate according to the timing. And the comparison and judgment result can be transmitted to the growth data unit 25. [

The growth data may have data on the environmental condition and the supply condition according to the growth period of the mushroom, and such data may be prepared in advance and stored in the growth data unit. The growth data unit 25 can store information on the environmental conditions of the growth space and the growth state of the mushroom according to the timing as reference data. The comparison and determination result is compared with the reference data from the analysis unit 24 and the operation of the power adjustment unit 211, the growth adjustment unit 212 and the environment adjustment unit 213 is determined and the control module 11 ). In addition, the growth data unit 25 can determine whether the growth condition of the mushroom is normal in each mushroom culture medium. Further, the growth data unit 25 can calculate the expected production ratio in each mushroom culture medium, and determine whether each mushroom culture medium is normal or not according to the production ratio. The calculated expected production rate or whether or not the mushroom medium is normal can be stored and periodically transmitted to a portable electronic device such as a smart phone or a management server. The reference data can also be modified to suit the growing space as required.

The control of the plant may be performed in various ways and is not limited to the embodiments shown.

FIG. 3 shows an embodiment of a water supply structure applied to a plant plant according to the present invention.

3, media (MC1, MC2, MC3) for growing mushrooms can be arranged, and media (MC1, MC2, MC3) can be the above-described bed or mushroom medium. The mediums MC1, MC2 and MC3 may be in the form of a box in which a culture medium such as sawdust is received and the channels 15a and 15b may be arranged along the periphery of the mediums MC1, have. And water flowing along the channels 15a and 15b, with or without the liquid sulfur composition. For example, the channels 15a and 15b may extend along both edges of the mediums MC1, MC2 and MC3, may be arranged in the form of receptacles on both sides, or may surround the mediums MC1, MC2 and MC3 . MC1 and MC3 and the water channels 15a and 15b are disposed in such a manner that at least one of the supply control units 31_1 to 31_L is connected to the mediums MC1 to MC3 and the channels 15a and 15b, As shown in FIG. The feed regulating units 31_1 to 31_L may be composed of one or more fiber strands and the water which is received in the water channels 15a and 15b or the flowing water is discharged from the water channels 15a and 15b in the same manner as, (MC1, MC2, MC3). The supply control unit 18 can be disposed in the water channels 15a and 15b as needed. And the supply regulating unit 18 can be connected to the waterways 15a and 15b by the supply conduit 181 to supply water in an adjusted amount or to circulate the water

For example, the medium MC2 may be in the form of a cylinder, and the supply control unit 31 may be configured to feed the medium MC2 through the medium MC2 in the longitudinal direction Shape. Or the medium MC3 is formed into a cylindrical shape, and at least one seeding hole 321, 322 may be formed on the upper surface of the cylindrical shape. And the supply adjusting unit 31 may be arranged to penetrate in the radial direction of the cylindrical shape. The mediums MC1, MC2 and MC3 may be formed into various shapes and the supply control units 31 and 31_1 to 31_L may be formed into seeds inoculated into the mediums MC1, MC2 and MC3, The supply control unit 31, 31_1 to 31_L, which can directly or indirectly supply the moisture through the capillary phenomenon, may be composed of an aggregate of fibers, cellulose or inorganic particles having an absorption capacity, for example, Can be made into a possible capillary structure. For example, the feed regulating units 31, 31_1 to 31_L can be made of one strand or multiple strands of fibers extending in a linear fashion and can be made into a capillary structure in which moisture can flow from one end of the fibers. The supply control units 31 and 31_1 to 31_L allow water to flow into the mediums MC1, MC2 and MC3 from the supply source to which water is supplied and into the mediums MC1, MC2 and MC3. When water flows into the mediums MC1, MC2 and MC3, the water is absorbed by the medium or the mushroom of the growing stage and the absorption capacity of the supply control units 31, 31_1 to 31_L, Can be introduced. When the composition flows into the medium from the supply control units 31 and 31_1 to 31_L, water is supplied from the supply control unit 18 to the inside of the mediums MC1, MC2 and MC3 through the supply control units 31 and 31_1 to 31_L, Lt; / RTI >

The supply control units 31 and 31_1 to 31_L can be made of various materials and can be applied to the media MC1, MC2 and MC3 having various structures to form a moisture supply device.

Fig. 4 shows an embodiment of the supply adjusting means applied to the water supply structure according to the present invention.

Referring to Fig. 4, the supply regulating unit 31 comprises a water immersing locking part 412; A locking portion 411 extending from the locking portion 412; A supply portion 413 disposed in the interior of the delivery frame and extending from the fixed portion 411 and a restriction portion 414 extending from the supply portion 413 to limit the transfer of water.

The supply regulating unit 31 can be made of a small number of strands having a relatively small diameter or a small number of strands depending on the position in which water or moisture can be conveyed by the capillary shape as a whole. The locking piece can be additionally locked in the locking part 412, and the locking piece can be made of a material having a large specific gravity, and can be combined so as to be movable in the locking part 412. The fixing portion 411 can be made of a structure in which a synthetic resin tube is joined to a portion extending from the locking portion 412 as a portion fixed to the side of the ejection frame or another appropriate bracket. Alternatively, it can be made in such a way that it is coated with a waterproof paint or paint along the circumferential surface. The elastic fixing cap 42 described above can be engaged at a proper position of the fixing portion 411. [ The feeding portion 413 may be made of the same or similar material as the locking portion 412 and may be made to have a smaller diameter, the same diameter or a larger diameter as compared to the locking portion 412, Can be made. The restriction portion 414 can be made of a relatively small diameter or a small number of strands, and the restriction portion 414 can be contacted to the detection unit described above.

The feed regulating units 31a, 31b and 31c may be made of various materials or structures and may have the same number of strands of fibers of the same diameter, for example, from the locking portion 412 to the limiting portion 414 Can be made. And if necessary, the peripheral surface of the fixing portion 411 can be made in a coating manner.

Referring to FIG. 4 (b), the supply control units 31a, 31b, and 31c are made of a single filament structure, or the same fiber strands are made into a twisted structure or a structure in which fluffs are formed around twisted strands . The supply regulating units 31a, 31b and 31c can be made into various structures capable of transferring water or moisture by capillary action, and the present invention is not limited to the embodiments shown.

Fig. 5 shows an embodiment of the structure for supplying water according to the present invention.

5, the amount of moisture that must be supplied to the medium through the feed conditioning unit in accordance with the moisture level of the media frame detected by the moisture detection unit 542 or the ambient temperature detected by the temperature detection unit 541 The supply table 52 for determining the supply can be prepared. And a stored batch table 53 of the batch condition and the amount of water supply per hour of the feed adjusting unit disposed in each medium can be prepared. Information detected by the temperature detection unit 541 and the moisture detection unit 542 can be transmitted to the control module 11 and the control module 11 can receive the information stored in the supply table 52 and the arrangement table 53 To determine the amount of water or liquid sulfur composition to be fed to the channel. Once the amount of water or liquid sulfur composition to be supplied to the channel has been determined, the control module 11 may adjust the operation of the valve regulating unit 55 to determine the amount of water or liquid sulfur composition to be fed to the channel. When the water is supplied to the water channel by the valve control unit 55, the water level can be detected by the water level control unit 56. If necessary, various components which are advantageous for the growth of metal components or mushrooms or which are advantageous for the human body can be supplied together with the supply of the liquid sulfur composition.

The temperature control unit 57 can be disposed in the water channel and the surface tension of the water or liquid sulfur composition can be appropriately adjusted by the temperature control unit 57. [ For example, the concentration of the water channel can be detected by the concentration detecting unit 58, and the temperature of the water or liquid sulfur composition can be adjusted by the temperature adjusting unit 57 when the concentration is out of the predetermined range. Thereby adjusting the surface tension of the water or liquid sulfur composition so that the supply control unit is adjusted. Also, the amount of the water or liquid sulfur composition supplied to the water channel by the supply control unit 18 can be appropriately adjusted based on the concentration detected by the concentration detection unit 58. [

The plant for mushroom cultivation according to the present invention allows various mushrooms including Chamaecyparis obtusa to grow by artificially formed conditions in the room. In this way, the mushroom or similar mushroom can be produced without restriction on the natural condition or the external environment. For example, a part of a farm house or a city house that does not live in a person can be appropriately remodeled and made into a plant for the cultivation of mushrooms. Further, the plant plant according to the present invention has an advantage that it can be produced on various scales from small scale to large scale, and can be operated without any special knowledge.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention . The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: peripheral wall 11: control module
12: water supply means 13a, 13b:
14: water purifier 15, 15a, 15b, 151, 152:
16: Temperature control module 17: Lighting module
18: supply control unit 19a, 19b: circulation unit
23: Information processing unit 24: Analysis unit
25: Growth data unit
31, 31a, 31b, 31c, 31_1 to 31_L:
42: Elastic fixed cap 52: Feed table
53: Batch table 55: Valve control unit
56: water level control unit 57: temperature control unit
58: Concentration detection unit 111: Communication means
131 to 134: mushroom medium 181: feed duct
211: power control unit 212: growth control unit
213: environment control unit 221: supply environment detection unit
222: Badge detection unit 223: Growth environment detection unit
321, 322: Inoculation hole 411: Fixed part
412: Locked part 413: Feed part
414: Restriction part 541: Temperature detection unit
542: Moisture detection unit MC1, MC2, MC3: medium
S1 to SN: Water induction unit

Claims (3)

A control module (11) for control of operation;
A bed (13a, 13b) in which at least one mushroom culture medium (131 - 134) is disposed;
Water supply means (12) for supplying water;
At least one water channel (15, 151, 152) formed along the bed (13a, 13b) so that the water supplied from the water supply means (12) forms a flow path;
Conditioning modules (16, 17) forming a growth environment; And
A plant for growing mushrooms comprising a peripheral wall (10) forming a growth space. The plant of claim 1, wherein the peripheral wall (10) comprises a clayey layer. The plant of claim 1, wherein the water supplied to the channel (15, 151, 152) comprises a dissolved sulfur component in an amount of 0.001 to 0.10 wt%.

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