KR20190103115A - A Plant for Cultivating a Mushroom - Google Patents

Abstract

The present invention relates to a plant factory for mushroom cultivation. Specifically, the present invention relates to a plant factory for mushroom cultivation to enable the cultivation of mushroom by artificially creating an environment indoors. The plant factory for mushroom cultivation comprises: a control module (11) for controlling operations; beds (13a, 13b) in which at least one mushroom medium (131 to 134) is disposed; a water supply means (12) for supplying water; at least one water channel (15, 151, 152) formed along the beds (13a, 13b) such that the water supplied from the water supply means (12) forms a flow path; condition-forming modules (16, 17) for forming a growth environment; and a circumferential wall (10) forming a growth space.

Description

A Plant for Cultivating a Mushroom

The present invention relates to a mushroom cultivation plant factory, and more particularly, to a mushroom cultivation plant plant that enables the cultivation of mushrooms by artificially creating an environment in the room.

As the results of research on various kinds of mushrooms reveal the nutritional value and medicinal value of mushrooms, the importance of the artificial cultivation technology of mushrooms is increasing. Mushrooms, shiitake, zelkova, sore throat, matsutake or similar mushrooms may be prepared by preparing the medium, inoculating the seed by inoculating the medium, incubating the seed inoculated in the medium for a period of time, and harvesting the mushrooms grown in the medium. It can be grown through the process. The medium may be made of a material such as sawdust or oak depending on the type of mushroom, and the process of culturing and maturing in the medium needs to be properly adjusted according to the species of the mushroom.

Mushrooms are advantageously cultivated in an environment in which humidity is maintained at 70 to 80% while the water is continuously supplied at a temperature of 10 to 30 ° C., for example. In order to supply moisture and maintain humidity, the medium should be supplied with water or sprayed on the medium. However, when the supply of water and the maintenance of humidity artificially require a lot of labor, there is a problem that it is difficult to continuously maintain proper environmental conditions.

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

Utility Model Publication No. 20-2014-0001356 and Patent Registration No. 10-1514236 disclose a mushroom medium moisture supply apparatus for supplying moisture to the mushroom medium. Cultivation of mushrooms is advantageously made according to a variety of growth conditions, including the supply of water, and for this purpose it is advantageous to have a plant factory structure. However, the prior art does not disclose the structure of a plant factory that is capable of forming suitable conditions such that, for example, cultivation of mushrooms, such as champignon mushrooms, is possible.

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

Prior Art 1: Utility Model Publication No. 20-2014-0001356 (Lee Chang-jeong, published on March 07, 2014) Mushroom medium moisture supply device Prior Art 2: Patent Registration No. 10-1514236 (Go Chan Oh, April 22, 2015 announcement) Mushroom medium moisture supply device

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

According to a preferred embodiment of the present invention, a mushroom plant plant is provided with a control module for regulation of operation; A bed in which at least one mushroom medium is disposed; Water supply means for supply of water; At least one channel formed along the bed such that water supplied from the water supply means forms a flow path; A condition forming module for forming a growth environment; And a perimeter wall forming a growth space.

According to another suitable embodiment of the invention, the circumferential wall comprises an ocher layer.

According to another suitable embodiment of the present invention, the water supplied to the canal contains dissolved sulfur components in an amount of 0.001 to 0.10 wt%.

Mushroom plant for plant cultivation according to the present invention is to allow a variety of mushrooms, including champignon mushroom to be grown by artificially created conditions in the room. This allows the truncated mushrooms or similar mushrooms to be produced without restriction on natural conditions or the external environment. For example, part of an uninhabited farmhouse or a city house may be properly adapted to a plant factory for mushroom cultivation. In addition, the plant factory according to the present invention can be made in a variety of scale from small to large scale, and has the advantage that it can be operated without additional specialized knowledge.

1 illustrates an embodiment of a mushroom plant for plant growth according to the present invention.
Figure 2 shows an embodiment of the operating structure of the plant factory according to the present invention.
Figure 3 illustrates an embodiment of a water supply structure applied to the plant factory according to the present invention.
Figure 4 shows an embodiment of a supply control means applied to the water supply structure according to the present invention.
5 illustrates an embodiment of a structure for supplying water according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the embodiments set forth in the accompanying drawings, but the embodiments are provided for clarity of understanding and the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, and thus are not repeatedly described unless necessary for understanding of the invention, and well-known components are briefly described or omitted. It should not be understood to be excluded from the embodiment of.

1 illustrates an embodiment of a mushroom plant for plant growth according to the present invention.

Referring to FIG. 1, the mushroom plant plant includes a control module 11 for regulation of operation; Beds 13a and 13b in which at least one mushroom medium 131 to 134 is disposed; Water supply means 12 for supplying water; At least one water channel (15, 151, 152) formed along the beds (13a, 13b) such that the water supplied from the water supply means (12) forms a flow path; Condition forming modules 16 and 17 to form a growth environment; And a circumferential wall 10 forming a growth space.

Plant plants can be applied to the cultivation of a variety of mushrooms, for example, cultivation of champignon, shiitake, oyster mushroom or similar edible mushrooms. Plant plants may be made independently for the cultivation of mushrooms, by remodeling a house or similar building, or by remodeling a house or part of a building.

The control module 11 may control the operation of the entire plant of the plant factory, and in particular, the operation of the power plant, water supply plant, lighting plant, temperature or humidity plant. The operation of the control module 11 can be done remotely, for example, the operation can be controlled by a portable electronic device such as a smartphone. For example, growth data for each mushroom may be generated in advance, and the growth data may include data on the growth environment required for the growth of each mushroom. And based on the growth data, the control module 11 may control the operation of the plant factory, the control module 11 may include a communication means 111 for wired or wireless communication, the communication means 111 Through the control module 11 is capable of communicating with the management server associated with the management of a portable electronic device or plant factory.

At least one bed 13a, 13b may be installed inside the plant factory, and at least one mushroom medium 131 to 134 may be disposed in each bed 13a, 13b. The beds 13a and 13b may be arranged on the bottom side of the plant factory or in a stacked structure in a placement frame, and one or more mushroom media 131 to 134 may be disposed on each bed 13a and 13b. Mushrooms such as champignon mushrooms can be grown. The culture strain of the mushroom medium (131 to 134) is to grow the mushroom by the supply of moisture, the moisture may be supplied from the channels 15, 151, 152.

The beds 13a and 13b may have a rectangular plane, and a plurality of beds may be arranged next to each other. 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 between or around the circumferential surfaces of the beds 13a and 13b. Can be formed accordingly. The growth space of the plant factory may form one closed compartment, and the water supply means 12 may be arranged inside or outside the growth space. The water supply means 12 can be, for example, a supply connection means connected with 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 may be supplied to the water channels 15, 151, and 152 through the water purifier 14. The channels 15, 151, 152 may form a circulation path, and the amount of water flowing along the channels 15, 151, 152 may be regulated by the supply control unit 18.

The channels 15, 151, and 152 may be connected to the mushroom mediums 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 waterways 15, 151, and 152 to the mushroom mediums 131 to 134, and for example, to move the water by capillary action. It may be made of strand fibers or similar materials. Supplying water by the capillary phenomenon has the advantage of allowing a constant level of water to be supplied. It also has the advantage that no separate means for the movement of water or moisture or for the control of the amount of movement is required. The movement of water or the supply of water from the channels 15, 151, 152 to the mushroom medium 131-134 can be accomplished in a variety of ways and is not limited to the embodiments shown.

The amount of water flowing through the channels 15, 151, 152 or the circulation cycle of the water can be regulated by the supply control unit 18, and the supply control unit 18 can be arranged at various locations with various structures.

For the cultivation of mushrooms, the growth space needs to be adjusted in temperature, humidity or amount of light, and for this purpose, the temperature control module 16 and the lighting module 17 may be installed as the condition forming modules 16 and 17. . The temperature control module 16 may be such as a heater, a heater, a hot air heater or a cooling means, and the lighting module 17 may be, for example, an LED module capable of emitting light of various wavelengths, but is not limited thereto. . The temperature control module 16 may have a structure of an air circulation system, and adjust the temperature of the growth space by adjusting the temperature of the air circulated. In addition, the lighting module 17 may be arranged to emit light of a predetermined wavelength band to each mushroom medium 131 to 134, and the operating time of the lighting 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 moisture may be supplied by the water flowing along the channels 15, 151, and 152, and the humidity in the growth space may be automatically adjusted by the temperature controlled by the temperature control module 16. have. In addition, circulation units 19a and 19b for air in the growth space may be installed, and air circulation is regulated in the growth space by the circulation units 19a and 19b, or air circulation is provided between the growth space and the outside. Can be done. The circulation units 19a and 19b may work together with or be integrally formed with the temperature control module 16 and the humidity inside the growth space may be controlled by the circulation units 19a and 19b.

The growth space can form a hermetic or similar space, and a circumferential wall 10 can be formed that partitions the growth space from the outside. And the inner face of the circumferential wall 10 may comprise an ocher layer, which has the function of reducing the temperature difference at different locations inside the growth space, for example emitting far infrared rays or anions. In addition, the ocher component absorbs harmful components generated during the growth of the mushroom and has a function of removing harmful components that the mushroom may have. The ocher forming the ocher layer is 50 to 70 wt% silica, 3 to 10 wt% Fe component, 8 to 15 wt% alumina, 1 to 5 wt% magnesium, 1 to 3 wt% sodium, 0.5 to 3 wt% kali and 5 to 10 wt% lime. Ocher may also include potassium carbonate, quartz, feldspar, mica or calcite. An ocher layer comprising various components may form the circumferential wall 10, and the present invention is not limited to the embodiments shown.

According to one embodiment of the present invention, each of the mushroom medium (131 to 134) may include a sulfur component, specifically dissolved sulfur in an amount of 0.001 to 0.10 wt% based on the total weight of water; Sodium ions, in amounts 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 and niobium component extracted from minerals And a surface tension of 25 to 75 dyne / cm at 25 ° C. The sulfur component supplied to the mushroom medium 131 to 134 may be a sulfur component from which the toxicity is removed, and preparing sulfur; Preparing a sodium hydroxide solution; Dissolving the prepared sulfur in sodium hydroxide solution; And it can be made through the step of adding a mineral component to the sulfur dissolved solution. Specifically, the sulfur component in powder form may be prepared for the preparation of the sulfur component added to water. Once the powdered sulfur is ready, a sodium hydroxide solution can be prepared. The sodium hydroxide solution may be made by dissolving 200 to 500 g of sodium hydroxide relative to 1,000 g of water, but is not limited thereto. When the sodium hydroxide solution is prepared in this manner, the prepared sulfur may be dissolved in the sodium hydroxide solution. Sulfur may be made in such a way that an amount of 150 to 400 g is added to the amount of sodium hydroxide made above. It can be slowly dissolved while stirring with the addition of sulfur. In this way, when sulfur is dissolved in the sodium hydroxide solution, the mineral component may be added.

The addition of the mineral component is 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 and niobium component extracted from the mineral, for example. It can be made by extracting a component useful for plant growth from the mineral containing the component of. For the extraction of these components from minerals, purified clouds, elvan, zeolite or rare earth minerals can be prepared by refining or washing. And the sulfur containing sodium hydroxide solution may be diluted, for example, the liquid sulfur composition may be diluted to include dissolved sulfur in an amount of 0.001 to 0.10 wt% based on the total weight of water. After dipping the purified mineral in dilute sulfur-containing sodium hydroxide solution and maintained for 24 to 72 hours at a temperature of 20 to 40 ℃, whereby the mineral component can be extracted. Alternatively, a dilute sulfur composition, diluted with the sulfur containing sodium hydroxide solution in the amounts set forth above, may be passed through the refined mineral. The sulfur-containing sodium hydroxide solution was extracted and diluted from minerals by K, Al, magnesium, iron, molybdenum, silicon, calcium, germanium, phosphorus, titanium and niobium. Mixing, whereby a liquid sulfur composition can be made. And the liquid sulfur composition comprises at least 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 and niobium component. It can be included in amounts. The surface tension can also be 70 to 75 dyne / cm at 25 ° C. of the sulfur composition. The sulfur component comprising the mineral component thus made may be added to the channels 15, 151, 152 to the amount described above. For example, a sulfur storage tank may be prepared for storing the sulfur component, and sulfur components may be added to the channels 15, 151, 152 in controlled amounts from the sulfur storage tank.

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

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

Referring to FIG. 2, the operation of the power regulation unit 211, the growth regulation unit 212, or the environmental regulation unit 213 may be controlled 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. In addition, the power control unit 211 may have a function of checking and storing the amount of power supplied to the entire plant factory, and may have a function of storing the amount of power consumed in each module for a certain period of time. The growth control unit 212 may have a function of checking the amount of water supplied to each mushroom medium. For example, the growth control unit 212 may stop or initiate the supply of water from the channel to the mushroom medium. In addition, the growth control unit 212 may check and store the amount of water supplied to each mushroom medium for a period of time.

By the environmental control unit 213, the circulation rate of temperature, humidity or air in the growth space can be adjusted, and the operating time and wavelength band of the LED lighting can be adjusted. And the value of the growth environmental parameter adjusted by the environmental control unit 213 may be stored for a period of time, the environmental parameter may be such as temperature, humidity, circulation cycle or light wavelength.

The supply state of the power supply, the operating state of the temperature control module, the water supply state or the operating state of the lighting module may 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 medium detection unit 222 may include, for example, such as a camera unit, a moisture measuring unit or a roughness measuring unit, and may detect the growth state of the mushroom in each medium. In addition, the growth environment detection unit 223 may detect the temperature, humidity, the amount of water in the channel, the amount of light, the flow rate of the air flow, the amount of oxygen or carbon dioxide, and the like within the growth space. Information detected by the supply environment detection unit 221, the badge detection unit 222, and the growth environment detection unit 223 may be transmitted to the information processing unit 23. The information processing unit 23 may classify the information detected by each detection unit 221, 222, 223 and transmit it to the analysis unit 24 according to a predetermined period.

The analyzing unit 24 may comprise a comparator, and the detection information transmitted from the information processing unit 23 may be compared with a predetermined criterion. Based on the results of the comparison, you can determine whether to correct malfunctions, misconfigurations, and operational levels. For example, it may be determined whether the wavelength band is appropriate, and whether a power supply facility is malfunctioning may be detected. It may also be detected whether the growth of the mushrooms grown in each medium is appropriate over time. And the comparison and determination results can be transmitted to the growth data unit 25.

The growth data may have data on environmental conditions and feeding conditions according to the mushroom growth time, and such data may be made in advance and stored in the growth data unit. The growth data unit 25 may make and store the information on the environmental conditions of the growth space and the growth state of the mushrooms as reference data. The comparison and determination results from the analysis unit 24 are compared with the reference data, and the control module 11 is determined by determining whether to adjust the operation of the power regulation unit 211, the growth regulation unit 212 and the environmental regulation unit 213. ) Can be sent. The growth data unit 25 may also determine whether the growth state of the mushrooms in each mushroom medium is normal. In addition, the growth data unit 25 may calculate the expected production rate in each mushroom medium, and may determine whether each mushroom medium is normal according to the production rate. Whether the calculated expected production rate or whether the mushroom medium is normal or not can be stored, and periodically sent to a portable electronic device such as a smart phone or management server, for example. You can also modify the reference data to suit your growing space as needed.

Control of the plant factory may be made in various ways and is not limited to the embodiments shown.

Figure 3 illustrates an embodiment of a water supply structure applied to the plant factory according to the present invention.

Referring to Figure 3, the medium (MC1, MC2, MC3) for the cultivation of mushrooms can be arranged, the medium (MC1, MC2, MC3) may be a bed or mushroom medium described above. The medium (MC1, MC2, MC3) may be a box shape containing a culture medium such as sawdust therein, the channels 15a, 15b can be disposed along or around the circumference of the medium (MC1, MC2, MC3) have. Water along the channels 15a and 15b may or may not flow with the liquid sulfur composition. For example, the channels 15a and 15b may extend along both edges of the medium MC1, MC2, MC3, be arranged in the shape of a receiving container on both sides, or may be arranged to surround the medium MC1, MC2, MC3. Can be. When the medium MC1, MC2, MC3 and the channels 15a, 15b are arranged in this manner, the at least one supply control unit 31_1 to 31_L is connected to the medium MC1, MC2, MC3 and the channels 15a, 15b. It may be arranged in the form of connecting with each other. The supply control units 31_1 to 31_L may consist of one or more fiber strands, the water contained in the channels 15a, 15b, or flowing water may be discharged from the channels 15a, 15b in the same manner as capillary action, for example. It may be arranged to be supplied to (MC1, MC2, MC3). If necessary, the supply regulation unit 18 may be arranged in the channels 15a and 15b. In addition, the supply control unit 18 may be connected to the channels 15a and 15b by the supply conduit 181 to supply water in a regulated amount or to circulate the water.

The medium MC1, MC2, MC3 can be made in various shapes, for example, the medium MC2 can be cylindrical, and the supply control unit 31 penetrates the medium MC2 along the longitudinal direction. It can be made in shape. Alternatively, the medium MC3 may be formed in a cylindrical shape, and at least one inoculation hole 321 or 322 may be formed in the upper surface of the cylindrical shape. And the supply control unit 31 may be arranged to penetrate in the radial direction of the cylindrical shape. The medium (MC1, MC2, MC3) can be made in a variety of shapes, the supply control unit (31, 31_1 to 31_L) is a medium material to the seed inoculated in the medium (MC1, MC2, MC3) or mushrooms grown after inoculation The supply control units 31, 31_1 to 31_L, which can supply moisture directly or indirectly, may be composed of agglomerates of absorbent fibers, cellulose or inorganic particles, for example, the movement of the composition through capillary action. Possible capillary structures can be made. For example, the supply control units 31, 31_1 to 31_L may consist of one or multiple strands of fibers extending linearly, and may be made of a capillary structure in which moisture may flow from one end of the fibers. The supply control units 31, 31_1 to 31_L allow water to flow into the mediums MC1, MC2, and MC3 from the source from which the water is supplied to the inside of the mediums MC1, MC2, and MC3. When water is introduced into the medium MC1, MC2, MC3, the water is absorbed by the medium material or the mushroom in the growth stage and the composition is transferred to the medium due to the difference in the absorption power of the supply control units 31, 31_1 to 31_L. Can be introduced. When the composition is introduced into the medium from the supply control units 31 and 31_1 to 31_L, the water flows from the supply control unit 18 through the supply control units 31 and 31_1 to 31_L to the inside of the medium MC1, MC2, and MC3. Can be introduced into.

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

Figure 4 shows an embodiment of a supply control means applied to the water supply structure according to the present invention.

Referring to FIG. 4, the supply adjustment unit 31 includes a locking portion 412 submerged in the channel; A fixed portion 411 extending from the locked portion 412; It may be composed of a supply portion 413 which extends from the fixing portion 411 and disposed inside the discharge frame and a restriction portion 414 which extends from the supply portion 413 and restricts the transfer of moisture.

The supply control unit 31 can be made of a small number of strands or relatively small diameter depending on the placement position while water or water can be transferred by the capillary shape as a whole. The locking portion 412 may be additionally arranged to be locked, the locking weight may be made of a material having a high specific gravity, and may be coupled to allow the positional movement in the locking portion 412. The fixing portion 411 may be made of a structure in which a tube of synthetic resin material is coupled to a portion extending from the locking portion 412 as a portion fixed to the side of the discharge frame or another suitable bracket. Alternatively, it can be made in such a way that it is coated with a waterproofing paint or paint along the circumferential surface. The elastic fixing cap 42 described above may be coupled to a suitable position of the fixing portion 411. The supply 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 larger diameter than the locking portion 412, or to have a different number of strands. Can be made. The restricting portion 414 may be made of a relatively small diameter or a small number of strands, and the restricting portion 414 may be in contact with the detection unit described above.

The feed control units 31a, 31b, 31c can be made of various materials or structures, for example to have the same number of strands of fibers of the same diameter from the locked portion 412 to the restricting portion 414. Can be made. And if necessary, the peripheral surface of the fixing portion 411 may be made in such a way that the coating.

Referring to Figure 4 (b), the supply control unit (31a, 31b, 31c) may be made of a single filament structure, the same fiber strands are made in a twisted form, or the structure is formed with a fluff around the twisted strands Can be. The supply control units 31a, 31b, 31c can be made of various structures capable of transporting water or moisture by capillary action, and the present invention is not limited to the embodiments shown.

5 illustrates an embodiment of a structure for supplying water according to the present invention.

Referring to FIG. 5, the amount of moisture to be supplied to the medium through the supply control unit according to the moisture level of the medium frame detected by the moisture detection unit 542 or the ambient temperature detected by the temperature detection unit 541. A supply table 52 may be prepared to determine. And a stored batch table 53 of the batch state of the feed control unit and the water supply amount per hour can be prepared. Information detected by the temperature detection unit 541 and the moisture detection unit 542 may be transmitted to the control module 11, which controls the information stored in the supply table 52 and the placement table 53. Reference can be made to determine the amount of water or liquid sulfur composition to be supplied to the channel. Once the amount of water or liquid sulfur composition to be supplied to the water channel is determined, the control module 11 may control the operation of the valve regulating unit 55 to determine the amount of water or liquid sulfur composition to be supplied to the water channel. When water is supplied to the water channel by the valve adjusting unit 55, the water level may be detected by the water level adjusting unit 56. If necessary, with the supply of the liquid sulfur composition, various components that are advantageous for the growth of metal components or mushrooms or for the human body may be supplied together.

The temperature control unit 57 may be arranged in the water channel, and the surface tension of the water or liquid sulfur composition may be appropriately adjusted by the temperature control unit 57. For example, the concentration of the channel can be detected by the concentration detection unit 58, and the temperature of the water or liquid sulfur composition can be adjusted by the temperature control unit 57 if the concentration is outside the predetermined range. This allows the surface tension of the water or liquid sulfur composition to be controlled so that the feed control unit is controlled. The amount of water or liquid sulfur composition supplied to the channel by the supply control unit 18 may also be appropriately adjusted based on the concentration detected by the concentration detection unit 58.

Mushroom plant for plant cultivation according to the present invention is to allow a variety of mushrooms, including champignon mushroom to be grown by artificially created conditions in the room. This allows the truncated mushrooms or similar mushrooms to be produced without restriction on natural conditions or the external environment. For example, part of an uninhabited farmhouse or a city house may be properly adapted to a plant factory for mushroom cultivation. In addition, the plant factory according to the present invention can be made in a variety of scale from small to large scale, and has the advantage that it can be operated without additional specialized knowledge.

Although the present invention has been described in detail above with reference to the presented embodiments, those skilled in the art may make various modifications and modifications without departing from the technical spirit of the present invention with reference to the presented embodiments. . The invention is not limited by the invention as such variations and modifications but only by the claims appended hereto.

10: perimeter wall 11: control module
12: water supply means 13a, 13b: bed
14: water purifier 15, 15a, 15b, 151, 152: water channel
16: temperature control module 17: lighting module
18: supply regulation 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: supply regulating unit
42: elastic fixing cap 52: supply table
53: Placement Table 55: Valve Adjustment Unit
56: level control unit 57: temperature control unit
58: concentration detection unit 111: communication means
131 to 134: mushroom medium 181: feed conduit
211: power control unit 212: growth control unit
213: environmental 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 portion 413: supply portion
414: restriction part 541: temperature detection unit
542: moisture detection unit MC1, MC2, MC3: medium
S1 to SN: moisture induction unit

Claims (1)

A control module 11 for regulation of operation;
Beds 13a and 13b in which at least one mushroom medium 131 to 134 is disposed;
Water supply means 12 for supplying water;
At least one water channel (15, 151, 152) formed along the beds (13a, 13b) such that the water supplied from the water supply means (12) forms a flow path;
Condition forming modules 16 and 17 to form a growth environment; And
A perimeter wall 10 comprising an ocher layer forming a growth space,
The channel 15, 151, 152 and the mushroom medium (131 to 134) are connected by a water induction unit (S1 to SN) made of a plurality of strands of fiber to move water by capillary action,
The plant for mushroom cultivation, characterized in that the water supplied to the channels (15, 151, 152) comprises a sulfur composition dissolved in an amount of 0.001 to 0.10 wt%.

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