JP6602920B1 - Concrete mushroom cultivation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a concrete cultivation system that has excellent durability against wind and the like and load resistance against snow, etc., can be used as a shelter in a disaster, and can keep running costs low. A concrete cultivation system of the present invention is a cultivation system having an internal space in which plants can be cultivated, and is provided with a concrete tunnel-like structure and a tunnel-like structure. A heating means and a cultivation rack disposed in the tunnel-like structure are provided. The tunnel-like structure can be configured by connecting a plurality of portal concrete members, for example. The tunnel-like structure can be provided with a circulating means for circulating the internal air. A long exothermic heater can be used as the heating means. In this case, it can be arranged below the cultivation rack. [Selection] Figure 1

Description

  The present invention is for cultivation of mushrooms such as jellyfish, shiitake mushrooms, eringi, enokitake mushrooms, shimeji mushrooms, maitake mushrooms, mushrooms, matsutake mushrooms, fruit vegetables such as udo and leafy vegetables (hereinafter collectively referred to as "plants"). The present invention relates to a cultivation system having a concrete structure that can be used (hereinafter referred to as a “concrete cultivation system”).

  Conventionally, a vinyl house is known as a cultivation system used for cultivation of plants. The vinyl house has the advantage that it can manage indoor temperature, humidity, etc., and can cultivate various plants regardless of the season. On the other hand, a general vinyl house has a structure in which a vinyl film is put on the outside of a frame made by assembling a frame material, and may be collapsed by a typhoon or heavy snow. In addition to vinyl houses, in recent years, cultivation equipment using aluminum boxes for the purpose of cultivation of mushrooms (Patent Document 1), and agricultural houses made of polystyrene foam for the purpose of shortening the construction period and reducing costs (patents) Document 2) has also been developed.

JP 2003-180158 A International Publication No. 2007/017922

  Although the cultivation apparatus described in Patent Document 1 is considered to have higher durability against large winds such as typhoons than vinyl houses, there is still room for improvement in terms of load resistance. Moreover, although it is thought that the agricultural house of patent document 2 is excellent at the point of shortening of a construction period and cost reduction, in the point of durability or load-bearing property, like the cultivation apparatus of patent document 1, it is an improvement. There is room for it.

  An object of the present invention is to provide a concrete cultivation system that is excellent in durability against large winds and the like and load-bearing against snow and the like, can be used as a shelter in a disaster, and can keep running costs low. It is in.

  The concrete cultivation system of the present invention includes a concrete tunnel-like structure (excluding those provided with an opening through which fresh concrete can be circulated at the lower end), and a heating means disposed in the tunnel-like structure. And a cultivation rack disposed in the tunnel-like structure. The tunnel-like structure is installed so as to be exposed to the ground without being buried in the ground. A concrete tunnel-like structure can be constituted by connecting a plurality of portal concrete members, for example.

The concrete cultivation system of the present invention has the following effects.
(1) Since a concrete tunnel-like structure is used, it is superior in durability against wind and load resistance against snow, etc., as compared to vinyl houses, aluminum houses, and polystyrene foam houses.
(2) Due to the use of concrete tunnel-like structures that are less permeable to sunlight, the internal temperature is less likely to rise in summer compared to vinyl houses, aluminum houses, and polystyrene foam houses, and in winter Since it is difficult to lower the temperature (temperature after heating in the case of heating), the cost for air conditioning can be kept low.
(3) Since a tunnel-like structure made of concrete with a long service life (Calvert has a service life of nearly 100 years) is used, it will be used continuously for a longer period of time than vinyl houses, aluminum houses, polystyrene foam houses, etc. Long-term cost reduction.

The external view of the concrete cultivation system of this invention. (A) is XX sectional drawing of FIG. 1, (b) is YY sectional drawing of FIG. (A) is sectional drawing which shows an example of the portal concrete member which embedded the heat insulating material in the zenith part, (b) is sectional drawing which shows an example of the portal concrete member which embedded the heat insulating material in the zenith part and the side wall part. Explanatory drawing of the water storage container on the exothermic heater arrange | positioned under the cultivation rack and the exothermic heater. An example of a heating means (exothermic heater) is shown, (a) is a perspective view which shows a part of exothermic heater, (b) is explanatory drawing of the exothermic heater wound around the bobbin.

(Embodiment)
An example of an embodiment of a concrete cultivation system of the present invention will be described with reference to the drawings. FIG. 1 is an external view of a concrete cultivation system of the present invention, FIG. 2A is a sectional view taken along line XX in FIG. 1, and FIG. 2B is a sectional view taken along line YY in FIG. In FIG. 1, 1 is a tunnel-like structure, 2 is a solar cell array, 3 is a control part, 4 is a vent hole, and 5 is a door. 2 (a) and 2 (b), 6 is a cultivation rack, 7 is a heating means, 8 is a water storage container, 9 is a circulation means, and 10 is a fungus bed of jellyfish.

  The said tunnel-like structure 1 is a structure used as the main body of the concrete cultivation system of this invention. The tunnel-like structure 1 of this embodiment is composed of a plurality of (ten in this embodiment) portal concrete members 1a having the same shape. The plurality of portal concrete members 1 a are arranged so that the openings of the adjacent portal concrete members 1 a communicate with each other, and the adjacent portal concrete members 1 a are connected to each other by a connecting metal 11. Inside the connected gate-shaped concrete member 1a, a space having a size in which the cultivation rack 6 and the like can be installed is formed. The inside of the tunnel-like structure 1 can be divided into two or more by a curtain, a door, or the like. The number of portal concrete 1a to be connected may be more or less than ten. When the method of connecting the portal concrete 1a and configuring the tunnel-like structure 1 as in this embodiment is adopted, the portal concrete 1a can be increased or decreased later, and the production volume is increased or decreased. There is a merit that it is easy to cope with expansion and contraction of facilities.

  For example, an existing culvert can be used for the portal concrete member 1a. In this embodiment, a culvert having an inner width of 3000 mm, an inner height of 2500 mm, an effective length of 1500 mm, and a concrete thickness of 230 mm is used as the portal concrete member 1a. A culvert having a size other than this can also be used.

  A new portal concrete member 1a can be manufactured for the concrete cultivation system of the present invention. In this case, a portal concrete member 1a having a heat insulating material 12 embedded therein can be used. The heat insulating material 12 can be provided only at the zenith part of the portal concrete 1a as shown in FIG. 3A, or can be provided at the zenith part and the side wall part of the portal concrete 1a as shown in FIG. The heat insulating material 12 can also be provided by sticking to the outer surface or inner surface of the portal concrete 1a. The portal concrete member 1a is precast at the factory, transported to the installation location by a truck, etc., and suspended by a crane for installation work. Prior to the installation of the portal concrete 1a, the base B for smoothing the installation location can be made. Base B can be made of concrete or the like. In this case, the portal concrete member 1a does not need to be integrated with the base B.

  In this embodiment, the openings on both the front side and the rear side in the depth direction of the tunnel-like structure 1, that is, the openings of the portal concrete members 1a at both ends constituting the tunnel-like structure 1 are opened and closed. A door 5 is provided. In this embodiment, a two-structure door (so-called double door) is used as the door 5, but the door 5 may be a normal single door. A curtain (not shown) may be provided in place of or together with the door 5. The door 5 and the curtain can be either light-shielding or translucent.

  The door 5 and the curtain can be provided at the end of the tunnel-like structure 1, but can also be provided on the inner side from the end of the tunnel-like structure 1 by about 1000 mm to 1500 mm. In this case, a space is secured outside the door 5 and the curtain, and the space can be used as a storage space or a rain guard. In this embodiment, the door 5 is provided on the inner side about 1500 mm from the end of the tunnel-like structure 1, and a space is secured on the front side. A control unit 3 used for controlling the indoor environment (for example, temperature and humidity) of the tunnel-like structure 1 is provided on the inner surface of the side wall of the portal concrete member 1a constituting the space. A vent hole 4 communicating with the inside and outside of the tunnel-like structure 1 is provided in the wall portion above the door 5.

  A solar cell array 2 is installed on the upper part of the tunnel-like structure 1. In this embodiment, although three pieces are installed at intervals in the longitudinal direction of the tunnel-like structure 1, the number of solar cell arrays 2 may be more or less than three. Although not shown, the solar cell array 2 is connected to an existing junction box, power conditioner, distribution board, storage battery, monitor, and the like, and a solar power generation device is configured by these. The electric power generated by the solar cell array 2 can be used as a power source for various devices used for cultivation such as the heating means 7 and air conditioning equipment.

  Inside the tunnel-like structure 1, a cultivation rack 6 is installed along the longitudinal direction thereof. As shown to Fig.2 (a), in this embodiment, the cultivation rack 6 is provided in three rows (the left cultivation rack 6a, the right cultivation rack 6b, and the middle cultivation rack 6c). The cultivation rack 6 may be more or less than three rows. In this embodiment, nine racks having a width of 300 mm, a height of 2400 mm, and a depth of 1500 mm (for convenience of explanation, individual racks constituting a row are referred to as “single racks”) are arranged in a row in the longitudinal direction of the tunnel-like structure 1. The cultivation rack 6 is provided. Single racks constituting each row can be connected.

  In this embodiment, the left cultivation rack 6a and the right cultivation rack 6b are fixed, and the middle cultivation rack 6c is movable. The cultivation rack 6 can be all fixed or movable. The cultivation rack 6 can be movable in units of rows, or can be movable in units of single racks constituting the rows. As a method of making the cultivation rack 6 movable, there are a method of moving on a rail installed on the floor, a method of moving by hanging on the ceiling side, a method of moving by providing casters, and the like. When the cultivation rack 6 is movable, it can be manual or electric. In some cases, a switching type that can be switched between manual operation and electric operation may be employed.

Each cultivation rack 6 is provided with a plurality of stages (six stages in this embodiment) of shelf boards 13 on which the fungus bed 10 is placed at intervals in the vertical direction. There may be more or less shelves 13 than six. Each shelf board 13 of the cultivation rack 6 can be provided with a lighting tool (not shown) that irradiates the fungus bed 10 disposed on the lower side. In addition to LEDs (for example, blue LEDs, white LEDs, red LEDs, etc.), fluorescent lamps and the like can be used as the illumination tool. The lighting fixtures can be provided on all the shelf boards 13, but can also be provided only on any shelf board 13. As shown in FIG. 4, the shelf board 13 has a lattice shape having a large number of spaces 17.

  In this embodiment, although the case where the cultivation rack 6 is comprised using a single rack is taken as an example, the structure of the cultivation rack 6 may be other than this, for example, a plurality of long single pipes are appropriately used. A simple one connected by a clamp can be used instead. Depending on the object to be cultivated, a cultivation bed for hydroponics can be used.

  As shown in FIGS. 2 (a), 2 (b) and 4, heating means 7 is installed below the left cultivation rack 6a and the right cultivation rack 6b. In this embodiment, a heating heater (square heating heater) having a rectangular shape in cross section as shown in FIGS. 5A and 5B is used as the heating means 7. This exothermic heater is a long linear heater having a length of about 40 m to 200 m, and is traded and managed while being wound around the bobbin 14 as shown in FIG. The exothermic heater can be used by being pulled out from the bobbin 14 and cut to a desired length, and by connecting electrodes (not shown) for connecting a power source and lead wires to both ends in the longitudinal direction of the exothermic heater. A general-purpose electrode metal material is used for the electrode, and it can be attached to the power input side and output side of the heating element. A commercial power source can be used as the power source.

The exothermic heater is inserted through each of a plurality of tubular members 15 disposed on the floor surface side of the tunnel-like structure 1, specifically, below the left cultivation rack 6 a and the right cultivation rack 6 b. . Although not shown, an electrode and a lead wire are connected to the end of the heating heater inserted through the tubular member 15 so that external power can be supplied from the electrode and the lead wire. In this embodiment, the water storage container 8 is installed on the tubular member 15 provided with the heat generating heater, and the tunnel-like structure is formed by evaporating the water in the water storage container 8 with the heat of the heat generating heater. The inside of the object 1 can be humidified. In the tunnel-like structure 1, another humidifier can be installed instead of the water storage container 8 or together with the water storage container 8. The plurality of tubular members 15 are arranged with a space portion 16 therebetween as shown in FIG.

  In this embodiment, a plurality of circulation means 9 for circulating indoor air are installed inside the tunnel-like structure 1. An existing circulator or the like can be used as the circulation means 9. The circulation means 9 is installed above the cultivation rack 6, in other words, at a position close to the ceiling of the tunnel-like structure 1. By providing at such a position, warm air rising upward in the room is circulated so that temperature unevenness and humidity unevenness do not occur in the room.

  Although illustration is omitted, the tunnel-like structure 1 may be provided with air-conditioning equipment or watering means that can heat or cool the room. The tunnel-like structure 1 is provided with a thermometer, a hygrometer, etc. in addition to a temperature sensor that detects the temperature in the tunnel-like structure 1 and a humidity sensor that detects the humidity in the tunnel-like structure 1. You can also. In this embodiment, a temperature sensor and a humidity sensor are provided in the room, and the air conditioning equipment is controlled based on a detection signal from the sensor so that the room temperature and humidity are maintained at a predetermined temperature and a predetermined humidity. is there.

  In this embodiment, a fungus bed 10 of fungus is used as the fungus bed 10. As the fungus bed 10 of the fungus, an existing one can be used. Specifically, it is possible to use a block-shaped medium obtained by mixing a woody base material such as sawdust with a nutrient source such as rice bran in a plastic bag. A cut is formed in the plastic bag of the fungus bed 10 in the vertical direction so that moisture can be replenished from the cut. The grown jellyfish emerges from the cut. The fungus bed 10 is not limited to the fungus bed 10 of fungus, but may be a fungus bed of various mushrooms such as shiitake mushrooms. In this embodiment, the fungus beds 10 are placed in two rows on each shelf 13. The fungus beds 10 can be arranged in a row or in three or more rows.

  In the said embodiment, although the case where a jellyfish is cultivated using the concrete cultivation system of this invention is taken as an example, the concrete cultivation system of this invention is a mushroom other than a jellyfish (Shiitake, Eringhi, Enokitake, Shimeji, Nameko) , Maitake mushrooms, mushrooms, matsutake, etc.), and can also be used for the cultivation of various plants such as fruit and vegetables such as udo and leafy vegetables. In particular, it can be suitably used for cultivation (production) of plants that do not require light (such as jellyfish, shiitake mushrooms, and udo).

  In the said embodiment, although the case where fungal bed cultivation is performed using the concrete cultivation system of this invention is taken as an example, the concrete cultivation system of this invention is other than fungus bed cultivation such as raw wood cultivation, hydroponics, and container cultivation. It can also be used for cultivation by this method.

  In the said embodiment, although the case where the movable portal concrete member 1a is connected and the tunnel-shaped structure 1 is comprised is taken as an example, the tunnel-shaped structure 1 can also be constructed | assembled by on-site driving | operation. In this case, the length (depth) of the tunnel-like structure 1 can be designed as appropriate.

  The concrete cultivation system of the present invention can be used as a cultivation system, and can also be used as a shelter during a disaster.

DESCRIPTION OF SYMBOLS 1 Tunnel-like structure 1a Gate-shaped concrete member 2 Solar cell array 3 Control part 4 Vent hole 5 Door 6 Cultivation rack 6a Left cultivation rack 6b Right cultivation rack 6c Medium cultivation rack 7 Heating means (heating heater)
8 Water storage container 9 Circulating means 10 Bacteria bed 11 Connecting bracket 12 Heat insulating material 13 Shelf 14 Bobbins
15 tubular members
16 Space (of tubular member)
17 Space B base (shelf)

Claims (7)

In a cultivation system with an internal space where plants can be cultivated,
A tunnel-like structure made of concrete ( excluding those with an opening through which ready-mixed concrete can be distributed at the lower end) (1) ;
Heating means (7) disposed in the tunnel-like structure (1) ;
A cultivation rack (6) disposed in the tunnel-like structure (1) ,
The tunnel-like structure (1) is installed so as to be exposed to the ground without being buried in the ground ,
The plants are mushrooms that can be cultivated on fungi,
A plurality of the cultivation racks (6) are arranged, and each cultivation rack (6) has a plurality of tubular members (15) arranged in the lower stage, and a shelf (13 in the upper stage from the tubular member (15). ) Has multiple steps with vertical spacing,
The tubular members (15) are arranged with a space (16) in the arrangement direction lateral direction,
Each of the multi-stage shelf boards (13) can carry two or more bacteria beds (10), and the bacteria bed (10) placed on the shelf boards (13) is wide enough not to fall off. It has a space (17),
The heating means (7) has a water storage container (8) placed on the plurality of tubular members (15), and a linear heating heater is inserted into each of the long tubular members (15). The inside of the tunnel-like structure (1) can be heated by the heat generated by the heater, and the water storage container (8) installed on the plurality of tubular members (15) The inside of the tunnel-like structure (1) can be humidified by evaporating water and raising it through the space (16) of the plurality of tubular members (15).
Concrete mushroom cultivation system characterized by that. In the concrete mushroom cultivation system according to claim 1,
A concrete tunnel-like structure (1) is formed by connecting a plurality of portal concrete members (1a) ,
The portal concrete member (1a) includes two opposing side wall portions (except for those provided with an opening through which ready concrete can be circulated at the lower end portion), and a zenith portion provided on the upper end sides of both side wall portions. , With openings formed on both side walls and the top of the zenith,
The plurality of portal concrete members (1a) are arranged so that the openings communicate with each other, and are installed so that the side wall portions of the respective portal concrete members are exposed to the ground.
Concrete mushroom cultivation system characterized by that. In the concrete mushroom cultivation system according to claim 1 or claim 2,
Air tunnel-like structure (1) in, with a circulation means for circulating the tunnel-like structure (1) in (9),
Concrete mushroom cultivation system characterized by that. In the concrete mushroom cultivation system according to any one of claims 1 to 3 ,
A door (5) or a curtain is provided at both the opening side of the tunnel-like structure (1) in the depth direction on the front side and the back side, or any one of them, and can be opened and closed.
Concrete mushroom cultivation system characterized by that. In the concrete mushroom cultivation system according to any one of claims 1 to 4 ,
A solar power generation device including a solar cell array (2) ,
At least the solar cell array (2) is installed at the outer zenith of the tunnel-like structure,
Concrete mushroom cultivation system characterized by that. In the concrete mushroom cultivation system according to any one of claims 1 to 5 ,
Two or more cultivation racks (6) are provided,
At least one of the two or more cultivation racks (6) is movable.
Concrete mushroom cultivation system characterized by that. In the concrete mushroom cultivation system according to any one of claims 2 to 6 ,
A heat insulating material (12) is embedded or affixed to the portal concrete member (1a) ,
Concrete mushroom cultivation system characterized by that.