JP2011010623A - Related production system for fungus and plant - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a related production system for fungi and plants, cost-advantageously performing the production of fungi such as mushroom and the production of plants such as vegetables.SOLUTION: This related production system is such that a partition 2 divides into upper and lower chambers 3 and 4, a vegetable cultivating part 5 is installed in the lower chamber 4, a mushroom cultivating part 6 is installed in the upper chamber, the upper and lower chambers 3 and 4 are communicated with each other in the outside with a duct 7, and when driving a fan 8, an air circulating flow of sending air in the upper chamber 3 into the lower chamber 4 and sending air in the lower chamber 4 into the upper chamber 3 is formed. A light source 9 for vegetable photosynthesis is installed on an upper side in the lower chamber 4, the partition 2 comprises a blind type openable and closable partition, and when closing the partition 2, light from the light source 9 is obstructed to be supplied to fungi in the upper chamber 3, and when opening the partition 2, light from the light source 9 is supplied to fungi in the upper chamber 3.

Description

  The present invention relates to a fungal and plant related production system.

  For example, vegetables as plants and edible mushrooms as fungi are common in that they are the same agricultural product, but the former performs photosynthesis while the latter does not perform photosynthesis. Therefore, in the past, vegetables were produced at separate plants, such as vegetables produced at vegetable production plants and mushrooms produced at mushroom production plants.

JP-A-9-98665

  However, in the production method as described above, the vegetable production factory must supply carbon dioxide necessary for photosynthesis for the cultivation of vegetables, and the mushroom production factory is used for cultivation of mushrooms. There was a problem that a dedicated lighting facility for supplying the necessary amount of light had to be prepared, and the cost required for cultivation was high.

  In view of the above-described problems, the present invention provides a fungus-plant related production system capable of cost-effectively producing fungi such as mushrooms and vegetables and plants such as vegetables. This is the issue.

The above problem is divided into upper and lower chambers by a partition, a plant cultivation unit is provided in the lower chamber, and a fungus cultivation unit is provided in the upper chamber,
The upper and lower chambers are communicated by an air passage outside the room, and by driving a fan provided in the air passage, the air in the upper chamber is sent to the lower chamber and the air in the lower chamber is sent to the upper chamber The carbon dioxide produced by the upper chamber fungi is used for the photosynthesis of the lower chamber fungi, and the oxygen generated by the photosynthesis of the lower chamber fungus is used for the upper fungus. It is designed to be used for growth,
A light source for plant photosynthesis is provided on the upper side of the lower chamber, and the partition is a blind-type partition that can be opened and closed,
When the partition is closed, the light from the light source is prevented from being supplied to the fungus in the upper chamber, and when the partition is opened, the light from the light source is supplied to the fungus in the upper chamber. It is solved by a related production system of fungi and plants characterized by

  In this system, carbon dioxide generated by the fungi in the upper chamber is used for photosynthesis of the plants in the lower chamber, and oxygen generated by photosynthesis of the plants in the lower chamber is used for the growth of the fungi in the upper chamber. Therefore, it is not necessary to prepare carbon dioxide for the photosynthesis of plants or to prepare oxygen for the growth of fungi, and the cost required for cultivation of these fungi and plants can be kept low.

  Moreover, the partition that divides the upper and lower chambers is a blind-type openable partition, and when the partition is opened, the light from the light source in the lower chamber is also supplied to the fungi in the upper chamber, It is not necessary to prepare a dedicated lighting facility for supplying a small amount of light necessary for the growth of fungi, and the cost required for the cultivation of fungi can be further reduced.

  In the first invention, when the ceiling surface of the upper chamber is formed as a light reflecting surface and the partition is opened, light from the light source is reflected on the ceiling surface of the upper chamber and supplied to the fungus. Good (second invention).

  In this case, the light emitted from the light source in the lower chamber is sent to the upper chamber through the partition, and then is reflected on the ceiling reflecting surface of the upper chamber and supplied to the fungus. Can be effectively supplied.

  In the second invention, when the floor surface of the lower chamber is formed as a light reflecting surface and the partition is opened, the light from the light source reflected by the floor surface of the lower chamber is reflected on the ceiling surface of the upper chamber and becomes fungi. It is good to be made to supply (3rd invention).

  In this case, light emitted downward or downward from the light source in the lower chamber is also reflected by the floor reflecting surface of the lower chamber and sent to the upper chamber, and is reflected by the ceiling reflecting surface of the upper chamber and supplied to the fungus. Therefore, the light necessary for the growth of the fungus can be supplied more effectively by the fungus.

  In 1st-3rd invention, when the lower surface side of the said partition is formed in a light reflection surface and the partition is closed, the light from a light source will be reflected in this light reflection surface, and it is made to be supplied to a plant. Good (fourth invention).

  In this case, in the state where the partition is closed, the light from the light source is reflected on the light reflecting surface on the lower surface side of the partition, so that the light from the light source can be effectively supplied to the plants in the lower chamber.

  In the fourth invention, the upper surface side of the partition is also formed on the light reflecting surface, and when the partition is opened, the light from the light source is reflected on the light reflecting surface and is supplied to the upper chamber ( (5th invention).

  In this case, in a state where the partition is opened, the light from the light source is reflected on the reflecting surface of the partition, so that the light from the light source can be effectively supplied to the upper chamber.

  Since the related production system of fungi and plants of the present invention is as described above, production of fungi such as mushrooms and production of plants such as vegetables can be advantageously performed in terms of cost.

Fig. (A) is a cross-sectional front view showing the related production system of the embodiment, Fig. (B) is a view taken along line II of Fig. (B), and Fig. (C) is a line II-II of Fig. (A). FIG. Fig. (A) is a cross-sectional front view showing the fan operating state, Fig. (B) is a cross-sectional front view showing the light supply state with the partition closed, and Fig. (C) is the light in the state with the partition open. It is a cross-sectional front view which shows a supply state.

  Next, embodiments of the present invention will be described with reference to the drawings.

  In the system of the embodiment shown in FIG. 1A, reference numeral 1 denotes a box, and the box 1 is partitioned into an upper chamber 3 and a lower chamber 4 by a partition 2, and the lower chamber 4 Is provided with a vegetable cultivation section 5 as a plant, and the upper chamber 3 is provided with a planter type cultivation section 6 for edible mushrooms as fungi.

  The vegetable cultivation section 5 is composed of a hydroponics bed and the like, the mushroom cultivation section 6 is composed of a planter and the like, and the mushroom cultivation section 6 is horizontally spaced as shown in FIG. The vegetable cultivation part 5 is provided so as to be spaced from the front and rear walls of the box 1 as shown in FIG.

  The upper and lower chambers 3 and 4 communicate with each other by ducts 7 and 7 serving as ventilation passages outside these chambers, and the fan 8 provided in the duct 7 is driven, as shown in FIG. Then, air in the upper chamber 3 is sent to the lower chamber 4, and a circulating flow of air is sent in which the air in the lower chamber 4 is sent to the upper chamber 3, and carbon dioxide generated by mushrooms in the upper chamber 3 is The oxygen produced by the photosynthesis of the vegetables in the lower chamber 4 is used for the growth of the fungi in the upper chamber 3.

Further, as shown in FIG. 1 (a), a light source 9 made of a fluorescent lamp or LED for photosynthesis is provided on the upper side in the lower chamber 4, and the partition 2 is shown in FIG. 1 (b). As described above, the ceiling type 10 of the upper chamber 3 is formed as a light reflecting surface, and the floor surface 11 of the lower chamber 4 is formed as a highly efficient light reflecting surface. The upper and lower surfaces 12 and 13 are formed on a highly efficient light reflecting surface,
When the partition 2 is closed, as shown in FIG. 2 (b), the light from the light source 9 is directly supplied to the vegetables, and is also reflected by the lower reflective surface 12 of the partition 2 and supplied to the vegetables. Furthermore, the light is reflected on the floor light reflecting surface 11 of the lower chamber 4, reflected on the lower surface reflecting surface 12 of the partition 2, and supplied to the vegetables.
When the partition 2 is opened, as shown in FIG. 2C, the light from the light source 9 is reflected to the ceiling reflecting surface 10 of the upper chamber 3 through the partition 2 and supplied to the mushrooms. Further, the light reflected on the floor reflecting surface 11 of the lower chamber 4 is reflected to the ceiling reflecting surface 10 of the upper chamber 3 through the partition 2 and supplied to the mushrooms, and further, the light from the lower chamber 4 is partitioned. The two reflection surfaces 12, 13 are reflected to the upper chamber 3 to be supplied to the mushrooms.

  Note that the opening and closing of the partition 2 may be performed manually, or may be performed automatically at a specific timing by automatic control.

  In the above system, when the light source 9 is turned on with the partition 2 closed and the fan 8 is driven, carbon dioxide generated by mushrooms in the upper chamber 3 is sent to the lower chamber 4 and used for photosynthesis of vegetables. The oxygen generated by the photosynthesis of the vegetables in the lower chamber 4 is sent to the upper chamber 3 to be used for the growth of the mushrooms in the upper chamber 3, so bother for the photosynthesis of the vegetables. It is not necessary to prepare carbon dioxide or to prepare oxygen for the growth of mushrooms, and the cost required for cultivation of these mushrooms and vegetables can be kept low.

  Moreover, when the partition 2 is opened with the light source 9 in the lower chamber 4 turned on, the light from the light source 9 in the lower chamber 4 is also supplied to the mushrooms in the upper chamber 3. It is no longer necessary to prepare a dedicated lighting facility for supplying a small amount of light necessary for growth, and the cost required for cultivation of mushrooms can be further reduced.

  In particular, the partition 2 that partitions the upper and lower chambers 3 and 4 is constituted by a blind-type partition 2 that can be opened and closed, whereby light from the plant photosynthesis light source 9 in the lower chamber 4 is supplied to the mushrooms in the upper chamber 3 Thus, the light source 9 for plant photosynthesis can be made to function effectively as a light source for mushrooms in the upper chamber 3 with a simple structure.

  In addition, since the structure is provided with various reflecting surfaces 10, 11, 12, and 13, the light supply of the light source 9 to vegetables and mushrooms can be made effective.

  Although the embodiment of the present invention has been described above, the present invention is not limited to this, and various modifications can be made without departing from the spirit of the invention. For example, in the above embodiment, the case where edible mushrooms and vegetables, that is, agricultural products are targeted for production, is not limited to agricultural products, but can be widely used for the production of various fungi and various plants. .

2 ... Partition 3 ... Upper chamber 4 ... Lower chamber 5 ... Vegetable cultivation department (plant cultivation department)
6 ... Mushroom cultivation department (fungi cultivation department)
7 ... Duct (air passage)
8 ... Fan 9 ... Light source 10 ... Reflective surface 11 ... Reflective surface 12 ... Reflective surface 13 ... Reflective surface

Claims (5)

The compartment is divided into upper and lower chambers, a plant cultivation section is provided in the lower chamber, and a fungus cultivation section is provided in the upper chamber,
The upper and lower chambers are communicated by an air passage outside the room, and by driving a fan provided in the air passage, the air in the upper chamber is sent to the lower chamber and the air in the lower chamber is sent to the upper chamber The carbon dioxide produced by the upper chamber fungi is used for the photosynthesis of the lower chamber fungi, and the oxygen generated by the photosynthesis of the lower chamber fungus is used for the upper fungus. It is designed to be used for growth,
A light source for plant photosynthesis is provided on the upper side of the lower chamber, and the partition is a blind-type partition that can be opened and closed,
When the partition is closed, the light from the light source is prevented from being supplied to the fungus in the upper chamber, and when the partition is opened, the light from the light source is supplied to the fungus in the upper chamber. Related production system of fungi and plants characterized by   The ceiling surface of the upper chamber is formed as a light reflecting surface, and when the partition is opened, light from the light source is reflected on the ceiling surface of the upper chamber and supplied to the fungus. Related production system of fungi and plants.   When the floor of the lower chamber is formed as a light reflecting surface and the partition is opened, the light from the light source reflected by the floor of the lower chamber is reflected on the ceiling surface of the upper chamber and supplied to the fungus. The related production system for fungi and plants according to claim 2.   The lower surface side of the partition is formed on a light reflecting surface, and when the partition is closed, light from the light source is reflected by the light reflecting surface and supplied to the plant. The fungal and plant related production system described in 1.   The fungus according to claim 4, wherein the upper surface side of the partition is also formed on the light reflecting surface, and when the partition is opened, the light from the light source is reflected on the light reflecting surface and supplied to the upper chamber. Plant related production system.

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