KR101547864B1 - Mushroom Cultivation Equipment having Solar Energy Collection Unit - Google Patents

Abstract

The present invention relates to a mushroom cultivation facility having a solar energy collection unit, and more particularly, to an efficient production environment for mushroom cultivation by creating an ideal growth environment according to various kinds of mushrooms, , Which is fixed on the ground and has a structure open to all sides and has a cultivation space capable of cultivating mushrooms on the inside so as to enable solar power generation and solar heating by utilizing solar energy (sunlight, solar heat) A frame; A greenhouse installed to open and close the cultivation space of the support frame and forming a wall surface of a triple structure so as to maintain the cultivation space of the mushroom in a greenhouse; And a solar energy collector fixed to the upper portion of the support frame to close the upper side of the greenhouse and collecting solar energy. A mushroom cultivation facility having a solar energy collecting unit including open / close control means provided therein.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a mushroom cultivation facility having a solar energy collection unit,

The present invention relates to a mushroom cultivation facility having a solar energy collecting unit, and more particularly, to an efficient production environment for mushroom cultivation by creating an ideal growth environment according to various kinds of mushrooms, The present invention relates to a mushroom cultivation facility having a solar energy collecting unit capable of cultivating and utilizing solar energy (sunlight, solar heat) for solar power generation and solar heating.

Generally, mushroom is a fruiting body of a size that can be visually recognized among fungi, and it occurs in various colors and shapes and is divided into various kinds such as mushroom mushroom, shiitake mushroom, oyster mushroom, and top mushroom, They grow in decayed trees, and multiply by chance. Furthermore, mushrooms are found to contain a large amount of useful substances such as protein and mineral nutrients and antioxidants, and are used for edible and medicinal purposes, and their production and consumption are increasing.

Here, the cultivation of mushrooms is somewhat different depending on the kind of the mushroom. However, the cultivation of the mushroom is performed by mixing raw materials, cultivating the mushroom with clay and rice straw, mixing a plurality of media such as sawdust and cottonseed, Mushrooms are mushrooms grown in a variety of mediums, so that mushrooms are produced. Therefore, it is important to form an environment in which mycelium can achieve reproduction and growth. Therefore, the amount of light, temperature, And mushrooms are cultivated in the cultivation facility where the proper cultivation environment such as humidity is established.

These mushroom cultivation facilities include simple growers that make up the cultivation by vinyl, styrofoam, and heat cover, and permanent growers that make up the cultivation by the bricks, blocks, and panels. In general, to be.

However, in the conventional mushroom cultivation facilities, only the greenhouse covered with the outside environment is simply covered with vinyl or lid, so that it is difficult to ventilate in a state where the four sides are closed and the greenhouse efficiency and the sunlight blocking efficiency are insufficient. There is a problem that it is difficult to create an environment. It is also difficult to maintain the internal temperature of the facility at the optimal temperature required by the mushroom. In the case of the simple cultivation, it is difficult to maintain the internal temperature of the mushroom at the optimal temperature. The maintenance cost of the facility is increased.

As a conventional technique disclosed to solve the above problems, Korean Patent Application Publication No. 48672 (May 11, 2010) discloses a floor including a soil layer and a gravel layer, A greenhouse wall forming a wall, and a light-shielding roof installed on the greenhouse wall, so that temperature and humidity inside the greenhouse can be kept constant.

However, the above-mentioned prior art is a permanent grower using bricks, which requires a lot of construction costs and is difficult to apply to general farm households, and there is a limit to the place where the facility can be constructed, and the inside space is closed everywhere, It is difficult to form an optimum growth environment for mushrooms.

In recent years, interest in solar energy has increased due to global warming and high oil prices. For this reason, companies are increasingly purchasing large-scale farmland and establishing separate solar power plants. However, there is a problem in that, when a photovoltaic power generation facility is installed in cultivable farmland where crops are cultivated, it can not be used as a farmland, and the place for cultivating crops becomes insufficient.

Therefore, it is urgently required to develop a cultivation facility capable of cultivating the mushroom, which is a crop, in farmland, and solar heating and solar heating.

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a triple greenhouse having a cultivation space in which mushrooms can grow, and to construct a cultivation facility having an energy utilization system capable of power generation and heating by solar energy, It also provides a mushroom cultivation facility equipped with a solar energy collecting unit that can generate electricity and generate heat at the same time as mushroom production in one place as well as self-power generation and heating in a cultivation facility to create an optimal cultivation environment for mushroom It has its purpose.

The present invention relates to a method for producing a mushroom-containing mushroom, which comprises a three-ply wall having a structure capable of opening and closing four walls of a greenhouse in which mushrooms are grown, thereby allowing the interior space where mushrooms are grown to be ventilated from outside, And to provide a mushroom cultivation facility with a solar energy collection unit that can be kept constant.

A mushroom cultivation facility having a solar energy collecting unit proposed by the present invention comprises: a support frame fixedly installed on the ground and having a four-sided open structure and having a cultivation space for cultivating mushrooms on the inside; A greenhouse installed to open and close the cultivation space of the support frame and forming a wall surface of a triple structure so as to maintain the cultivation space of the mushroom in a greenhouse; And a solar energy collector fixed to the upper portion of the support frame to close the upper side of the greenhouse and collecting solar energy. And an opening / closing control means provided therein.

The wall surface of the greenhouse is composed of a three-layered barrier rib which overlaps with each other so as to control light quantity and temperature of the internal cultivation space and to block inflow of rainwater.

The three-ply wall film is constructed so that a light-shielding film, a vinyl film, and a nonwoven film film are sequentially disposed.

The three-ply wall film is configured to be openable and closable for each of the individual wall films among the three-ply wall films from the opening / closing control means.

Wherein the opening and closing control means comprises a roll bar provided at the upper end of the wall portion of the greenhouse and rotatably formed so as to wind a wall surface thereof and a rotating means connected to one end of the roll bar and controlling rotation operation of the roll bar .

The turning means of the opening / closing control means can be configured as a passive type having a chain-like shape including a plurality of beads or a chain shape so as to be operated by pulling action of a worker.

The turning means of the opening / closing control means may be of an automatic type comprising a driving motor for rotationally driving the roll bar.

The solar energy collecting unit includes solar power generating means for receiving sunlight of the solar energy from the upper portion of the support frame to generate electric energy, a solar heat collecting unit for collecting solar heat in the upper part of the support frame, And heating means.

The photovoltaic power generation means comprises a photovoltaic module installed on the upper part of the support frame to receive sunlight to produce electricity, and a charging device operable to charge electricity generated from the photovoltaic module.

The solar heating means includes a heat collecting member installed on the support frame for collecting solar heat to raise the temperature of the heat medium, and a heat storage device for storing heat by moving the heated heat medium from the heat collecting member.

According to the mushroom cultivation facility having the solar energy collecting unit according to the present invention, since the solar power generation facility and the solar heat heating facility are built together in the mushroom cultivation facility, the power and heating energy can be produced simultaneously with the mushroom in one place, It is effective not only to increase the efficiency of utilization but also to prevent farmland shortage, and to generate electricity and heating energy required for cultivation of mushroom, thereby greatly reducing the maintenance cost of the facility.

In addition, the mushroom cultivation facility equipped with the solar energy collecting unit according to the present invention optimizes the growth environment of the mushroom while minimizing the use of the heating device because the greenhouse where the mushroom is grown is composed of the triple structure wall surface, It is effective to increase the productivity of the product and grow high quality mushrooms.

Further, the mushroom cultivation facility having the solar energy collecting unit according to the present invention is constructed of a three-ply wall which can open and close the wall of the greenhouse, so that the cultivation space can be ventilated naturally, thereby maximizing the growth efficiency of the mushroom have.

In addition, the mushroom cultivation facility equipped with the solar energy collecting unit according to the present invention has a simple structure compared to the permanent cultivation, so that the construction cost is drastically reduced and the spreading to the general farm household can be enhanced.

1 is a perspective view schematically showing an embodiment according to the present invention;
2 is a side sectional view schematically showing an embodiment according to the present invention.
3 is a plan sectional view schematically showing an embodiment according to the present invention.
4 is an enlarged view schematically showing a wall surface of a greenhouse according to an embodiment of the present invention.
5 (a) and 5 (b) are diagrams schematically showing first and second embodiments of the opening and closing control means, respectively, according to an embodiment of the present invention.
6 is a block diagram conceptually showing a solar energy collector according to an embodiment of the present invention.
7 is a side view schematically showing another embodiment of a solar energy collector in an embodiment according to the present invention.

The present invention relates to a method of producing a mushroom, comprising: a support frame fixedly installed on the ground and having a structure in which mushrooms can be grown inside; A greenhouse installed to open and close the cultivation space of the support frame and forming a wall surface of a triple structure so as to maintain the cultivation space of the mushroom in a greenhouse; And a solar energy collector fixed to the upper portion of the support frame to close the upper side of the greenhouse and collecting solar energy. And a mushroom cultivation facility having a solar energy collecting unit including open / close control means provided therein.

The mushroom cultivation facility is equipped with a solar energy collecting unit having a wall surface of the greenhouse, which is composed of a three-ply wall film layered in layers so as to control light quantity and temperature of an internal cultivation space and to prevent inflow of rainwater.

Further, the mushroom cultivation facility having the solar energy collecting unit in which the light-shielding film, the vinyl film, and the nonwoven fabric film are sequentially disposed is characterized by the technical construction.

The mushroom cultivation facility includes a solar energy collecting unit in which the three-ply wall membrane is openable and closable for each of the individual wall membranes among the three-ply wall membranes from the opening / closing control means.

The opening and closing control means may include a roll bar provided at the upper end of the wall portion of the greenhouse and rotatably formed so as to wind the wall thereof, a rotating means connected to one end of the roll bar, And a mushroom cultivation facility having a solar energy collecting unit that includes a solar energy collecting unit.

Further, the turning means of the opening / closing control means is characterized by a mushroom cultivation facility having a passive type solar energy collecting unit configured in a chain form or a chain form including a plurality of beads to operate by pulling action of a worker do.

And the turning means of the opening and closing control means is a mushroom cultivation facility having an automatic solar energy collecting unit composed of a drive motor for driving the roll bar to rotate.

The solar energy collecting unit includes solar power generating means for receiving sunlight of the solar energy from the upper part of the support frame and converting the sunlight into electric energy, a solar heating unit for collecting solar heat in the upper part of the support frame to convert it into thermal energy And a mushroom cultivation facility having a solar energy collecting unit including means for collecting mushrooms.

The solar power generating means may include a solar energy collecting unit installed on the upper portion of the support frame and including a solar module for receiving solar light to generate electricity and a charging device for charging electricity generated from the solar module A mushroom cultivation facility is characterized by its technical composition.

The solar heating means may include a solar collecting unit installed on the support frame and collecting solar heat to raise the temperature of the heat medium and a heat storage device for storing heat of the heat medium heated from the heat collecting member, The mushroom cultivation facility which is provided is characterized by the technical composition.

Next, a preferred embodiment of a mushroom cultivation facility having a solar energy collecting unit according to the present invention will be described in detail with reference to the drawings.

1 and 2, a mushroom cultivation facility having a solar energy collecting unit according to the present invention includes a support frame 10 and a greenhouse 20 And a solar energy collecting unit 40. The solar energy collecting unit 40 includes:

As shown in FIG. 2, the support frame 10 is the most basic frame structure supporting the overall structure of the facility including the solar energy collector 40, and includes a cultivation space 5 in which mushrooms can be grown inside A plurality of frames are interconnected with each other.

The support frame 10 is fixed on the ground, and has a structure in which four sides are opened. That is, the support frame 10 includes only a frame capable of supporting the facility, and is installed in a structure in which the front and rear sides, the left and right side surfaces, and the upper side ceiling are both opened.

In order to install the support frame 10, it is preferable that the support frame 10 is fixedly installed on the bottom surface by placing the reinforced concrete on the ground so as to form a foundation floor.

The greenhouse 20 is configured so that the cultivation space 5 can be partitioned into an interior space divided from the outside to form an environment in which mushrooms can be cultivated. That is, the greenhouse 20 optimizes the temperature, light quantity, and ventilating action at which the mushroom can grow, so that it functions to create a mushroom cultivation environment.

As shown in FIGS. 2 and 3, the greenhouse 20 forms a wall surface 21 of a triple structure so as to maintain the cultivation space 5 of the mushroom in a greenhouse state.

The wall surface 21 of the greenhouse 20 is supported by a frame structure in which a plurality of pipes are connected and fixed to each other and three wall surfaces are positioned at a predetermined distance from each other.

For example, a wall surface 21 located at an outermost one of the wall surfaces 21 having a triple structure of the greenhouse 20 is provided in contact with the support frame 10, And two wall surfaces 21 are further provided at a distance of 500 mm toward the inside with respect to the center.

As shown in FIG. 4, the wall surface 21 of the greenhouse 20 is formed of a three-layered barrier rib 23 that is stacked in layers so as to control light quantity and temperature of the internal cultivation space 5 and to block the inflow of rainwater .

The three-ply wall film 23 is made of different materials, and is formed by sequentially arranging a light-shielding film, a vinyl film, and a nonwoven film, each of which forms a rectangular shape from a beveled end curled like a scroll.

The light-shielding film of the barrier film 23 is provided to be able to control the quantity of light according to the cutoff of direct sunlight due to sunlight and the amount of sunshine. The vinyl film and the nonwoven film prevent foreign matter such as rainwater, And to maintain the temperature.

The wall surface 21 of the greenhouse 20 is installed to open and close the cultivation space 5 of the support frame 10. That is, the wall surface 21 of the greenhouse 20 is configured to adjust the temperature, humidity, and light amount of the cultivation space 5 and to open or close the wall surface 21 so as to allow ventilation, do.

The wall surface 21 of the greenhouse 20 includes an upper ceiling wall together with the sidewall of the greenhouse 20 so that both the side wall and the ceiling wall of the wall surface 21 can be opened and closed, And the ceiling wall can be individually opened and closed.

The opening and closing control means 30 provided in the greenhouse 20 is provided at an upper end of the wall surface 21 so as to control opening and closing of the wall surface 21 of the greenhouse 20.

The opening and closing control means 30 is preferably provided for each of the wall surfaces 21 so as to control opening and closing of the triple wall surface 21 of the greenhouse 20.

For example, the opening / closing control means 30 may be mounted on the wall surface 21 of the greenhouse 20, so that any one of the triple wall surfaces 21 of the greenhousing 20 from the opening / The control unit 30 controls the greenhouse unit 20 to open only the wall surface 21 of the greenhouse unit 20 so that the greenhouse unit 20 is made up of only the double wall surface 21 or the two wall surfaces 21 are opened from the opening / It is possible to control only the single wall surface 21.

The opening and closing control means 30 opens and closes the three-layer wall film 23 constituting the wall surface 21 and opens and closes the respective one of the three wall membranes 23 from the opening and closing control means 30 .

For example, the opening / closing control means 30 can selectively open / close only the barrier film among the barrier films 23, or open / close only the vinyl film or the nonwoven film to open / close the three-fold barrier film. That is, even if all the three-ply wall films 23 are opened and closed, the individual wall films 23 are controlled by the open / close control means 30.

5, the opening / closing control means 30 includes a roll bar 31 installed at the upper end of the wall surface 21 of the greenhouse 20 and a roll bar 31 connected to one end of the roll bar 31 And a rotating means (33).

The roll bar 31 is rotatably formed so that the wall surface 21 of the greenhouse 20 can be wound. That is, the wall surface 21 of the greenhouse 20 is opened or closed by the rotation of the roll bar 31.

The roll bar 31 may be constructed using a hollow pipe or the like.

The pivoting means (33) is connected to at least one of the opposite ends of the roll bar (31) and is installed to control the rotation operation of the roll bar (31).

5 (a), the turning means 33 of the opening / closing control means 30 can be configured as a passive type so as to operate by the pulling action of the operator.

In this case, the rotating means 33 may be an embodiment such as a chain shape including a plurality of beads, a chain shape, or the like. Here, although not shown in the drawing, a connecting portion contacting the roll bar 31 may be formed as a fastening groove (not shown) so as to transmit rotational force to the roll bar when the rotating means 33 is in the form of a chain including a plurality of beads When the rotating unit 33 is in the form of a chain, the connecting part contacting the roll bar 31 may be formed in the form of a sprocket so that the roll bar 31 can be engaged with the rotating bar 31 .

The turning means 33 of the opening and closing control means 30 may be configured to automatically rotate the roll bar 31 as shown in Fig. 5 (b).

In this case, the rotating unit 33 is generally composed of a motor used for transmitting power, and can be implemented by applying a gear box.

When the open / close control means 30 is configured as an automatic type, the open / close control means 30 is automatically controlled by the temperature sensor, the rainfall amount meter, the timer, It is preferable to configure it so that it can be used.

The solar energy collector 40 is fixed to the upper portion of the support frame 10 so that the upper side of the greenhouse 20 is closed.

As shown in FIG. 6, the solar energy collector 40 is configured to collect solar energy to generate electric energy and thermal energy, and includes solar power generation means 41 and a solar heating means 43.

The photovoltaic power generation means 41 receives sunlight of solar energy from the upper portion of the support frame 10 and performs power generation by electric energy.

The solar photovoltaic unit 41 includes a solar module 41a installed on the support frame 10 to receive sunlight to produce electricity, And a charging device 41b for charging the battery.

In the above description, the solar module 41a is meant to include a solar panel or a solar photovoltaic cell configured to receive light energy of the sun so as to be used for general solar power generation.

The photovoltaic module 41a of the photovoltaic power generation means 41 is installed on the upper part of the support frame 10 to be able to receive sunlight smoothly, thereby forming a ceiling of the facility.

The photovoltaic module 41a is configured to block the transmission of sunlight to direct sunlight and receive sunlight to generate electricity.

It is preferable that the solar module 41a has a size and an area that can achieve the ceiling according to the scale of the cultivation facility.

Although not shown in the drawing, the charging device 41b is provided with a controller for controlling the operation of electricity together with a rechargeable battery by the charging device 41b so as to operate the electricity generated by the solar module 41a do.

The charging device 41b charges the electricity generated by the solar module 41a.

The charging device 41b charges electricity generated from the photovoltaic module 41a and supplies electric power necessary for operation of a mushroom grower such as a driving device of a cultivation facility, temperature regulation (heating and cooling), and lighting device, Surplus power is connected to supply to the utility.

The solar heating means 43 collects solar heat of the solar energy at the upper portion of the support frame 10 and converts it into thermal energy.

The solar heating means 43 includes a heat collecting member 43a installed on the upper portion of the support frame 10 and collecting solar heat to raise the temperature of the heat collecting body 43a, And a heat storage device 43b for storing the heat.

The heat collecting member 43a is formed together with the solar module 41a so as to form a ceiling of the cultivation facility.

In this case, the heating medium is formed to be able to transmit heat of a high temperature from the heat collecting member 43a, and a movable gas or liquid is used.

Although not shown in the drawing, the heat accumulating device 43b is provided with a conveying path along which the heating medium can be moved together with a conveying means capable of continuously circulating, and a control roller for controlling the temperature.

Here, the solar energy collecting unit 40 forming the ceiling of the cultivation facility can be configured as a one-directional type having slopes which are uniformly inclined only in one direction as shown in Fig. 7 (a).

The solar energy collector 40 is preferably designed in consideration of the path of the sun depending on the latitude and the longitude of the earth. In other words, the sun is designed so that the inclined slope of the solar energy collecting unit 40 is directed to the south in consideration of the angle of the sunlight located at noon due to the nature of passing from the east to the south through the west.

Also, the solar energy collector 40 may be configured as a bi-directional type having a sloped slope of a symmetrical structure as shown in Fig. 7 (b).

As described above, if the ceiling of the cultivation facility is constructed in a bidirectional manner, even if the building can not be constructed due to the local conditions in which the cultivation facility is located, the solar energy collection unit 40 can be configured as a south / It is possible to do.

That is, according to the mushroom cultivation facility having the solar energy collecting unit according to the present invention constructed as above, the solar power generation facility and the solar heat heating facility are built together in the cultivation facility of the mushroom, It is possible to increase the utilization efficiency of the land and to prevent the agricultural land shortage phenomenon and to further reduce the maintenance cost by self-generated power and heating energy required for mushroom cultivation.

In addition, the present invention improves the greenhouse efficiency by constructing a greenhouse in which the mushroom is grown to have a triple structure wall surface, thereby optimizing the growth environment of the mushroom while minimizing the use of the heating device, thereby enhancing the productivity of the product and cultivating high quality mushrooms It is possible.

In addition, the present invention can maximize the growth efficiency of mushrooms by constructing a wall of the greenhouse as a three-ply wall which can be opened and closed to provide a natural ventilation space.

Further, since the present invention has a simple structure compared to permanent cultivation, it is possible to greatly reduce the construction cost and promote the spread to the general farmhouse.

Although the preferred embodiment of the mushroom cultivation facility having the solar energy collecting unit according to the present invention has been described above, the present invention is not limited thereto, and various modifications and changes may be made within the scope of the claims, the specification and the accompanying drawings. And this is also within the scope of the present invention.

5: Cultivation space 10: Support frame
20: greenhouse part 21: wall surface
23: wall film 30: opening / closing control means
31: roll bar 33: rotating means
40: solar energy collector 41: solar power generator
41a: Solar module 41b: Charging device
43: Solar heating means 43a:
43b: heat storage device

Claims (10)

A support frame fixedly installed on the ground and having a structure in which the mushrooms can be cultivated on the inside of the support frame,
A greenhouse which is provided to be able to open and close the cultivation space of the support frame and which forms a wall surface of a three-layered wall so as to control light quantity and temperature of the cultivation space and to prevent inflow of rainwater to keep the cultivation space in a greenhouse;
And a solar energy collector fixed to the upper portion of the support frame and collecting solar energy to close the upper side of the greenhouse,
The three-ply wall film of the greenhouse portion is formed by sequentially arranging a light-shielding film, a vinyl film, and a non-
Wherein the greenhouse includes opening and closing control means provided at an upper portion of each of the individual wall films so as to individually control opening and closing of the three-
Wherein the opening and closing control means comprises a roll bar provided at an upper end of a wall of the greenhouse wall and rotatable so that a wall of the wall can be sensed, a rotating means connected to one end of the roll bar, ≪ / RTI >
The rotating means may be a passive type in which the roll bar is rotationally driven by a pulling action of a worker in a form of a chain or a chain including a plurality of beads, or an automatic type in which the roll bar is rotationally driven by a driving motor under,
The solar energy collecting unit includes solar power generating means for receiving sunlight of the solar energy from the upper part of the support frame and converting the sunlight into electric energy, a solar heating unit for collecting solar heat in the upper part of the support frame, And means,
The solar photovoltaic device includes a solar module installed on the support frame to receive sunlight to produce electricity and a charging device for charging electricity generated from the solar module,
The solar heating means includes a heat collecting member installed on the support frame and collecting solar heat to raise the temperature of the heat medium and a heat storage device for storing heat of the heat medium heated from the heat collecting member Mushroom cultivation facility with solar energy collection unit. delete delete delete delete delete delete delete delete delete

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