JP2003189745A - Cultivation facility utilizing natural energy - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cultivation facility which maximally uses energies capable of being used in an area having the facility set thereto, thereby enabling the minimization of cultivation energy supplied from outer suppliers. <P>SOLUTION: This cultivation facility for cultivating crops in the cultivation medium of a cultivation bed is characterized by disposing a heat transmission device for heating or cooling the cultivation medium in the bottom or inner portion of the cultivation bed and giving one or more heat energies from an electric power transmitted from a solar battery or a wind power plant set to an area where the cultivation bed is placed, or from an underground dam or an ice storage tank to the heat transmission device, thereby directly heating or cooling the cultivation medium. It is desirable to pass water stored in the underground dam or a heat medium subjected to a heat exchange with the water through the heat transmission device to directly heat or cool the cultivation medium. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cultivation facility for cultivating crops such as vegetables and flowers. The present invention relates to a cultivation facility that can maintain the temperature, and in particular, to a cultivation facility that can keep the crop at an appropriate temperature by making maximum use of the unique natural energy in the area where the facility is located.

[0002]

2. Description of the Related Art In facility cultivation using greenhouses or vinyl greenhouses, in order to adjust the growth environment of the crop, the cultivation space is covered by covering the space where the crop is grown with a glass plate, sheet-shaped or plate-shaped vinyl resin material. To maintain the temperature inside the facility properly and to eliminate the effects of rainfall and wind, but in general, to prevent damage to plants due to low temperatures in winter and to prevent growth inhibition, I try to heat the cultivation room. Furthermore, in the facility cultivation of high-grade crops, in addition to the heating heater, a cooler may be provided in order to keep the temperature inside the facility always appropriate.

As a means for adjusting the temperature inside the facility, it is common to burn oil or gas and directly introduce the hot exhaust gas into the facility, or to provide a radiator along the inner wall of the facility. there were. In addition, as a special example, in the case of a culture mode in which a large amount of culture solution is circulated to the crop, such as in hydroponic culture, the circulation amount of the culture solution is large, so that the temperature of the culture solution can be adjusted It is also practiced to control the temperature of.

[0004] Such institutional cultivation makes it easier to maintain the cultivation environment in the most suitable condition for the growth of the crop as compared with the natural cultivation environment, and the desired crop can be grown and harvested regardless of the season. In regions where there are four seasons and large year-to-year changes in climate, it is an excellent means of supplying vegetables stably and can be shipped during the off-season when the supply of crops from open field cultivation decreases, so the unit price of harvested vegetables is also high. Moreover, productivity is high because the cultivation environment is properly maintained. For this reason, cultivation may be performed such that the temperature of the facility is maintained even if the amount of fuel that exceeds the income of open-field cultivation is consumed.

[0005]

[Problems to be Solved by the Invention] In the conventional facility cultivation, a heat transfer panel is installed in the facility along the floor surface, or a method of controlling the temperature in the facility for performing heating by directly blowing hot air is used. It requires a great deal of heat energy, which is also expensive. In such a facility, the temperature inside the facility has a considerable difference from the temperature of the outside air, so heat is exchanged between the outside air and the room air on the surface of the glass plate or vinyl resin sheet that is the outer wall. .

As in the prior art, the temperature of the air provided by the heater placed above the surface of the medium is slightly higher than the desired in-plant temperature in the case of heating, and
In the case of cooling, it will be slightly lower. In other words, this means that hot or cold air is locally brought from the heater / cooler, and the air directly contacts the glass plate or vinyl resin sheet covering the facility. There will be a large amount of heat exchange between and. Moreover, in the facility, since the air is agitated so that the internal temperature is as uniform as possible, heat exchange is further promoted. For this reason, in conventional facility cultivation, a large amount of energy was required to adjust the temperature of the facility.

Furthermore, in order to make the temperature in the cultivation facility uniform and to save heat energy, if hot air or cold air is blown into the cultivation facility with a blower or the like, it is circulated.
The wind may cause damage such as damage to hepatorenal crops, inhibition of growth, and deformation of shape and shape, especially near the outlet.

[0008] Further, in a facility for circulating a large amount of culture solution, a large amount of polluted liquid is discharged to the surroundings when the culture solution is discarded, which is not preferable. Furthermore, circulating the culture solution increases the number of working steps. One of the reasons is that sterilization is necessary because bacteria can easily reproduce when circulated. The other is that the component balance of the culture broth is disrupted by the absorption by the crops, so it is necessary to adjust the culture broth. There is also a problem in that it costs money if the number of work processes increases.

Such a cultivation facility is not necessary in a region where the natural environment is warm and can be cultivated in an open field.
In the tropics and cold regions, it is desirable to provide it for the daily consumption of vegetables. However, in such a region, the temperature is far from the optimum temperature of the vegetables to be cultivated, so if the temperature of the cultivation facility is controlled under the condition of maintaining the optimum cultivation temperature, a large amount of energy is consumed as described above. Since it is necessary, it is desired to construct a cultivation facility in which vegetables can be grown with minimum energy consumption. For that purpose, it is necessary to control the conditions so that the closed space like a greenhouse becomes the same environment as the local environment (temperature, humidity, rainfall, etc.) suitable for growing vegetables. It is required to break free. At that time, it is desired that the conditions obtained in the land be utilized to the maximum in terms of cost reduction.

The present invention has been made in view of such conventional problems, and it is possible to maintain the crop at an appropriate temperature with less energy and to reduce the drip amount of the culture broth to maintain the temperature of the facility. It is an object of the present invention to provide a cultivation facility that can minimize energy and maximize the energy available in the area where the facility is located, thereby minimizing the cultivation energy that needs to be supplied from the outside. It is what

[0011]

[Means for Solving the Problems] The inventors of the present invention have conducted diligent studies to achieve the above-mentioned object, maximize the energy available in the area where the facility is located, and Abandoning the idea that it must be maintained under conditions suitable for cultivation, select a medium for the cultivation bed that is suitable for the cultivation of plants, and select a medium for the cultivation bed that is easy to maintain such conditions. As a result, they have found that all of the above problems can be solved, and have completed the present invention based on such findings.

That is, the present invention is for saving energy for temperature adjustment as compared with a conventional cultivation facility, and has the following configuration. (1) A heat transfer facility that uses a porous solid medium as a culture medium for a cultivation bed, cultivates a crop by dropping a culture solution, and heats or cools the temperature of the medium at the bottom or inside of the cultivation bed. A cultivation facility using natural energy, characterized by comprising a device for directly heating or cooling a culture medium by passing the stored water of an underground dam or a heat medium exchanged with it through the heat transfer device. (2) The cultivation facility according to (1), wherein the water used to apply heat to the heat transfer device is returned to an underground dam. (3) A heat transfer facility for heating or cooling the temperature of the medium to the bottom or inside of the cultivation bed, which is a cultivation facility in which a porous solid medium is used as the medium for the cultivation bed and the culture solution is dropped to cultivate the crop. The apparatus is provided with a solar cell installed in the adjacent area of the cultivation floor, electric power from a wind power generation facility, or an underground dam, a direct culture medium by giving one or more of thermal energy from an ice reservoir to the heat transfer device. A cultivation facility characterized by being heated or cooled.

In the present invention, the basic point is to minimize the energy purchased from the outside for use in the cultivation facility by maximally utilizing the natural energy that can be obtained in the area of the cultivation facility. It is intended to be able to be suppressed to. That is, as one of the concrete means, the water of the underground dam is used as a heat source or a cold heat source of the cultivation facility. For example, on Miyakojima, one of the islands of Okinawa,
Although there is a large amount of rainfall of 000 mm (360 million tons), the entire island is a highly water-permeable “Ryukyu limestone island” that is 40% of it. % (140 million tons) was immediately infiltrated into the Ryukyu limestone layer from the soil surface to become groundwater, and it was flowing out to the sea as it was. However, when the geological formation was investigated in Miyakojima, as shown in Fig. 3, there is an impermeable layer 32 called "Shimajiri layer" under the Ryukyu limestone layer 31, so water accumulates on it and the Ryukyu limestone layer 31 It has been found that the aquifer 34 is formed in the water and the water can be used.

In order to utilize this groundwater, the underground dam 3 is constructed by providing a water stop weir 33 in the Ryukyu limestone layer 31 at the end of the groundwater basin since 1979, as shown in FIG. Is being done. In this underground dam 3, the Ryukyu limestone layer 31 is an aquifer 34, and it is said that the Sunagawa Dam can store 9.5 million tons of water. The water of this underground dam is mainly used as agricultural water. For water intake from the underground dam, a number of wells 37 for water intake are provided in the aquifer 34, and the submersible pump 3 is provided in each intake well.
8 is provided to take water from the well, and these are connected by the main water supply pipe, and a water supply pump is provided at the water intake facility 36 that is integrated by the water intake gate 39, and a farm provided at a high place via the water supply passage 40. Pump up to 4 pounds. The water that has entered the farm pond 4 is used for irrigation, etc. from the main canal 41 through the branch canal.

The temperature of the underground dam water taken in is about 21 to 23 ° C. throughout the year, and since the temperature is close to the optimum cultivation temperature of the vegetables to be cultivated in the cultivation facility, it is used as a heat source of the cultivation facility. It can be said that this is very preferable as a cold heat source. Moreover, the amount of underground dam water sent to Farm Pond is very large,
There is also an advantage that it can be used very stably as a cold heat source.
Thus, the present invention, in the case of Miyako Island, the summer is very hot, and the control of the cultivation temperature of the cultivation facility can be easily performed by using the underground dam water, without using commercial power. It can be carried out.

Even if there is an underground dam, pumping it up and using it as a cold heat source for a cultivation facility is the same as simply pumping up groundwater, and the power cost for pumping is considerably large, but in the case of Miyakojima, There is no pumping cost for pumping because there is pumping for sending to Farm Pond. When this underground dam water is used as a cold heat source, it is not appropriate to send it directly to the heat exchange device of the cultivation facility, and it is preferable to exchange heat with the heat medium. At the time of heat exchange, from the viewpoint of heat exchange efficiency, a flexible pipe type is preferable, but since these have large pressure loss and increase the power cost for sending to the farm pond, those with the structure with the least pressure loss, for example, It is preferable to use a plate type heat exchanger.

In the present invention, the use of underground dam water for the temperature control of cultivation facilities is the main point, but underground dam water is one of the natural energy sources that can be used in the area, so it is more broadly defined. By using the total amount of natural energy available in the area, they can further reduce the amount of energy obtained from the outside. As such natural energy, for example, in the case of Miyakojima, it is possible to use the power from a solar power generation facility that uses strong sunlight and a wind power generation facility that uses a strong wind from the open sea for the island. May be used to adjust the temperature of the cultivation facility, but the power to drive the pump required to circulate the heat medium to the heat exchanger with the underground dam water,
It is preferable to apply the power required for the control device of the cultivation facility. Other natural energy sources available in the area include tidal power generation facilities and geothermal power generation facilities, which can be combined in a comprehensive manner.

Further, as the heat source obtained by the area,
The material is not limited to the above, and various materials can be used. Note that the "heat source" is not limited to one that heats, but one that cools is the same in the sense of a negative heat source ("cold heat source"), so that it is also included. In that sense, the water of the above-mentioned underground dam is an important heat source as cooling water, and depending on the region, the cold heat source of the ice storage that stores snow and ice in winter can be used.

In the present invention, even for the purpose of minimizing the heat energy required in the cultivation facility,
The cultivation facility or method itself must be able to minimize the thermal energy required to grow the crop. In this sense, cultivation room (greenhouse)
Maintaining the entire interior of the plant (ie, including the medium) at optimum conditions for the crops it cultivates requires a great deal of heat energy, and so is a new approach. In the present invention, it is intended to control the temperature of the culture medium of the cultivation bed to an optimum temperature, paying attention to the condition of the root part, particularly the temperature, which is very related to the growth of the crop, and therefore the underground of the cultivation bed is used for that purpose. Alternatively, a heat exchange device is installed in the ground to control the temperature of the cultivation bed. In particular, when the cultivation floor is supported by columns and kept away from the soil surface, it is no longer related to the temperature of the ground, and the influence of air temperature is greater, but since it is separated from the soil, the temperature of the cultivation floor is Easy to manage.

That is, conventionally, in the cultivation of crops, the space around the crop has the greatest influence on the growth of the crop. Therefore, as in the case of a greenhouse, for example, emphasis is placed on controlling the temperature and humidity in the room. However, in an environment such as a subtropical region, it is important to control the temperature of the culture medium of the cultivation bed to an optimum temperature, and the temperature of the space where the leaves of the crop have no significant effect. Check it in and use it. Explaining it with an example of a typical crop, it is necessary to select the temperature condition so that the best growth can be achieved in cultivation, but the optimum or preferable cultivation condition is that in the case of spinach, the medium temperature is 18 At 24 ℃, 18-24 ℃ at night, in the case of tomato, the medium temperature is 2
It is said to be around 5 ℃ and around 20 ℃ at night. On the other hand, the cultivable temperature is, in the case of spinach, the medium temperature is 13 to 24 ° C in the daytime and 13 to 24 ° C at night, and in the case of tomato, the medium temperature is 18 to 28 ° C in the daytime and 18 to 25 ° C at night.
It is said to be ℃. For example, in the case of spinach, it is said that if the root portion becomes 13 ° C. or lower, the growth is adversely affected, so it is necessary to prevent such temperature.

From this, in the present invention, the cultivation is carried out so that the temperature of the medium in the cultivation bed is in the optimum or preferable cultivation condition described above. Of course, the temperature condition of the space where the leaves of the crop, which is the upper part of the above-mentioned cultivation bed, does not have to be arbitrary, but since it does not affect the growth as much as the root part of the crop, it has some tolerance. Looking at the cultivation conditions of spinach and tomato, which are typical crops in greenhouse cultivation, the temperature in the greenhouse is 10 to 30 ° C during the day and 10 to 30 ° C during the night. Possible temperatures are 10 to 30 ° C during the day and 10 to 30 ° C at night. In addition, optimum or suitable cultivation conditions are 26 to 28 during the day in the case of tomatoes.
C., 13-15.degree. C. at night, and it is said that spinach is lower than tomato. From this point of view, controlling by the medium temperature is easier than controlling by the temperature inside the greenhouse.

The control for maintaining the cultivation conditions of such a cultivation bed depends largely on the climatic conditions of the area where the cultivation facility is provided. For example, in the case of Okinawa region, the temperature in Naha According to the data, the monthly average of daily maximum temperature is 31.1 ° C in July, 30.7 ° C in August, 9
Monthly high temperature of 29.9 ℃, monthly average temperature is 26.2 ℃ in June,
July 28.3 ° C, August 28.1 ° C, September 27.1 ° C, 1
It is high at 24.5 ℃ in October. In the Okinawa region, according to the present invention, in order to be able to maintain the above-mentioned optimum or suitable conditions for cultivation by means of medium cooling, in the case of spinach, the period is from June to October during the day and from July to September during the night. It was found necessary to carry out cooling during the period. In the case of tomatoes, the period is June-September during the daytime and 4-
It has been found necessary to provide cooling during the November period.

In the case of Honshu, greenhouses are used to raise the temperature above the ambient temperature in the winter, such as greenhouse cultivation, but in the Okinawa region it is a subtropical region, so it cools in the summer. It is necessary to adjust the temperature. The use of the above-mentioned underground dam water as a cold heat source for that purpose gives more preferable results because the water temperature is 21 to 23 ° C. That is, the optimum or suitable condition for cultivation is the temperature as described above in the case of spinach and tomato for the medium temperature, and therefore it is close to the water temperature of the underground dam water and can be used as it is as a cold heat source. Since the temperature is low, the temperature of the cultivation bed does not change depending on the location. Furthermore, in the above, the case of cooling in the summer was explained, but in Naha, the monthly average of the daily maximum temperature in January was 18.6 ° C and the monthly average of the daily minimum temperature was 13.6 ° C. Since it is 16.6 ° C, there is a possibility that the growth of roots of spinach may be adversely affected. In that case, means for heating the medium can be taken using the underground dam water as a heat source.

Further, in the present invention, it is preferable to use a porous pumice medium as the medium for controlling the temperature of the cultivation bed so as to control the temperature of the cultivation bed medium to an optimum temperature. Since such a porous pumice medium has a small specific gravity, it has a small heat capacity, and the temperature can be easily adjusted by the heat exchange device. Furthermore, when pumice medium is used, the method of supplying the culture solution also adopts a drip flow method, but when this method is used, only the minimum amount of liquid necessary for the growth of the crop is supplied, so the water content of the pumice medium is As the amount is extremely small and the heat capacity of water is large,
Since the heat capacity of the entire medium including water is small, it becomes easy to control the temperature by the heat exchange device.

In the present invention, the pumice medium has a saturated hydraulic conductivity of 0.3 to 0.8 cm / sec and an aeration coefficient of 15 to 40 cm / sec for dry and wet samples.
It is preferable to be composed of granular pumice. further,
The pumice medium has a cation exchange capacity of 3.0 to 4.0 meq / 100 g, and is preferably 1.0 to 5.6 mm granular pumice. This granular pumice stone is preferably subjected to a drying process after mining and adjusted so as to have a water content of 0.4% or less.

In the present invention, the cultivation facility may not be covered with a glass or vinyl resin sheet, but when the outside temperature has a large difference from the suitable cultivation temperature of the crop,
It is preferably covered with a glass or vinyl resin sheet. Further, various heating devices or cooling devices can be used as the heat transfer device provided at the bottom or inside of the cultivation floor. As the energy that can be used for the heat transfer device,
Various heat sources (including cooling) can be used, but it is preferable to use one having a low cost as much as possible. As such a material, one having a low energy density can be used, and for example, residual heat of heating, treated water having a slightly higher temperature in the treatment of village wastewater, hot springs, etc. can be used to keep the cost low. When the heat transfer device is provided at the bottom of the cultivation floor, it is preferable to take measures such as laying a heat insulating mat under the bottom and installing the heat transfer device on the mat.

[0027]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Specific embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a technical conceptual diagram of the present invention, and shows the case of implementation on Miyakojima as an example. The cultivation facility 1 of the present invention is
It has a culture medium temperature control system 2, which is connected to a heat exchanger 6 provided in the middle of a conduit for underground dam water 5 that is pumped in large quantities from an underground dam 3 to a farm pond 4. It is possible to exchange the cold and heat sources of the underground dam water 5 at a temperature of ~ 23 ° C.
The system 2 is also connected to the ice regenerator 7 so that the cold heat can be used when the underground dam water 5 cannot be used or when it is not enough. It should be noted that the ice regenerator 7 can save the energy when surplus power is generated in the power system described later, and in an area connected to the commercial power 10, the surplus power at night is used to inexpensively generate heat. Energy can be used.

This cultivation facility 1 is supplied with various electric power for circulating the heat medium to the heat exchanger 6 in the culture medium temperature control system 2, operating the control system control equipment, supplying the culture solution to the cultivation bed, and the like. As required, these can be used to create a source of electrical power around the cultivation facility and to supply it from there. For example, in the case of Miyakojima, since the sunlight is intense, the solar cell 10 is installed in a place such as a passage of a cultivation facility that does not block sunlight on the cultivation floor, a roof of a management building, and a solar power generation facility is installed. , As a power source. Furthermore, since it is an island, the wind power generation facility 11 is provided in the adjacent land by utilizing the natural environment in which the wind is strong, and electric power can be obtained by the power generation facility using natural energy. In addition, as a power generation facility that uses natural energy, there are those that use tide difference and those that use wave energy.

In the present invention, the electric power from the power generation equipment using natural energy is utilized. However, the quality of the electric power obtained from these is not the same, and the obtained time zone is large. In order to supply the cultivation facility as a stable electric power, the electric power systems are linked together to make a constant voltage and the surplus is stored.
Alternatively, it may be sold to a commercial power supply company and taken out from a power storage when the power is insufficient, or commercial power 12
Must be controlled so that they can be supplied with.

In FIG. 1, a system linkage board 13 is provided to comprehensively control electric power from electric power sources such as the solar cell 10, the wind power generation facility 11, and the commercial electric power 12. By controlling the system linkage board 13 as a center, natural energy can be utilized to the maximum extent, and energy required for operating the cultivation facility can be minimized. This is because, for example, even if it is far from an industrial area such as Miyakojima, it is blessed with a natural environment. Therefore, by utilizing the natural energy of that area, the energy from other areas is minimized under optimal conditions. You will be able to make crops.

FIG. 2 is a schematic view illustrating the cultivation facility of the present invention. An isolation tray 17 is supported by a large number of struts 16 in an outer cover 15 such as a glass plate or a vinyl resin sheet. The isolation tray 17 is filled with a medium 18 containing pumice such as shirasu as a main component for isolation. Forming the floor. A heat transfer pipe 19 which is a heat transfer tool is inserted inside the medium 18 in the isolation tray 17, and brine heated or cooled from a cold heat source 20 is circulated in the heat transfer pipe 19 to separate the floor. Heating or cooling the temperature of. In the culture medium 18 of the isolation bed, the culture solution whose components and concentrations are adjusted from the culture solution supply device 21 is provided with a water conduit 22 and water discharge small holes connected to the water conduit 22 at predetermined intervals in the longitudinal direction on the peripheral wall. Droplets are supplied by drip tubes 23 (perforated water discharge pipes) scattered in a row. The drip tube 23
Is equipped with a dripper with pressure compensation mechanism inside. With this simple structure, the culture solution is supplied in a drip manner through a large number of water discharge small holes of the drip tube 23 arranged horizontally. In such a drip-type institutional cultivation, the amount of the culture solution dropped is small and the energy for fertilizer management is small.

Further, in this cultivation facility, the medium 18 of the isolated bed is used.
As such, it is preferable to use pumice such as shirasu as a main component, but pumice such as shirasu has a low fertilizing ability, and therefore the culture solution must be supplied dropwise in a relatively short cycle. However, the amount of the culture solution dropped as a whole is an amount commensurate with the surface evaporation of the medium and the surface evaporation of the crop, and can be extremely small. Since the supply of the culture solution to the medium has a great influence on the growth of the crop, it is necessary to control the growth so that the growth is the best. Although there are various measuring means for measuring the water content of the medium due to the supply of the culture solution, it is optimal to use a means based on the pF value. The pF value is preferably in the range of 1.7 to 3, for example. When the pumice medium is used, the pF value is set to be smaller than the above range because the supply of the culture solution is reduced. The pF value is difficult to measure when the medium is a pumice medium, but can be determined by using the FDR method or the like previously proposed by the present inventor as an auxiliary means. As a material for the medium, inorganic foams such as vermiculite known as a soil substitute for horticulture and perlite known as a soil mixture can be considered, but the strength and the specific gravity required for holding a crop are small. It is not as good as pumice stone because it is too strong and weak in strength compared to pumice stone. Furthermore,
Although open-cell type foamed plastics such as urethane foam can be used, pumice is the most preferable material because it is not only expensive because it is an organic material, but also inferior to pumice in terms of durability. The culture medium 18 of the isolation bed, which has a small amount of water retention, has a small specific heat and thus requires a small amount of heat to raise and lower its temperature. Will be easier.

Further, in the case of pumice, the medium 18 preferably has a particle size of about 1 to 5.6 mm, and in this case, the voids between the medium particles are also larger than the voids of the soil in the general open field. Has become. Moreover, as described above, if the dropping amount of the culture solution is an amount commensurate with evaporation, since the medium is always maintained in a dry state, not only there is no possibility of root rot, but the excess culture solution hardly appears, There is no concern about environmental pollution in the area around the cultivation facility due to discharge of excess culture solution.

In FIG. 2, cold air or warm air from the heat transfer pipe 19 inserted in the culture medium 18 is transferred to the entire isolation bed by heat transfer and convection mainly by air flow. As the heat medium for heating or cooling, hot water, cold water, or the like can be used, and as the heating or cooling means, various things such as electricity or steam can be used. For example, groundwater in the installation area can be used, and if there is a combustion facility such as an incinerator at an adjacent position, exhaust gas can also be used.

Considering a means for saving energy by using the simplest heat transfer means in a cultivation facility having a glass plate or a vinyl resin sheet outer cover, the cultivation in the form of dropping the culture solution Considering the method of transferring heat through the liquid, since the heat energy that is accompanied by the culture liquid and brought to the medium is small, it is not possible to maintain the temperature inside the facility appropriately by supplying the culture liquid, To prevent the influence of temperature, it is necessary to adjust the temperature by a heat source other than the culture solution. Thus, in the present invention, for heating or cooling facility cultivation using pumice having a particle size of approximately 1 to 5.6 mm as a medium,
When the heating or cooling medium is inserted into the medium to control the temperature of the facility, the heat source or cooling source in the facility serves as an isolation bed, and it is not only the place closest to the crop but also the place apart from the outside air. Since it is located, the amount of heat exchange between the inside and outside of the facility in the outer cover is minimized, and since the medium particles have large voids, heating or cooling by convection is carried out quickly, and the amount of culture solution drip is small. In addition, it has the effect of minimizing the temperature maintenance energy and cultivation energy of the facility.

[0036]

The present invention will be described in detail with reference to the following examples. However, the present invention is not limited to this embodiment.

Example 1 When cultivating tomatoes on Miyako Island, Okinawa Prefecture, comparative cultivation was carried out by heating the medium according to the present invention and not heating the medium for comparison. The cultivation floor was installed in a greenhouse to prevent it from being affected by weather such as rain, but it was connected to the outside air so that the temperature of the environment was the same as the outside air. Ambient temperature of cultivation bed: The maximum temperature, the minimum temperature, and the average temperature of the day were almost the same as the monthly average temperature such as the daily maximum temperature in Naha during the cultivation period.

(Cultivation by heating the medium)   The cultivation conditions are shown below. 1. Medium Pumice stone with a particle size of 1 to 5.6 mm (cultivation box) 2. Medium heating method The temperature of the medium at a depth of 8 cm in the cultivation box is 20 ° C.                 However, the actual average temperature was about 21 ° C. (Plant                 Heat exchange with underground dam water with a water temperature of 21-23 ° C in the cultivation box piping                 To circulate hot water with a water temperature of 20 ℃ at a flow rate of 23 liters / minute                 More heating was done. ) 3. Raising seedlings Raising seedlings in a seedling box 4. Transplantation Transplant in 9 cm pot 5. Cultivation box with planting medium heating device (vertical 250 mm x horizontal 400 m                 m x depth 180mm) 1 plant each 6. Watering method Drip the culture solution 7. Number of surveyed shares 5 shares 8. Cultivated items Tomato (variety: House Momotaro) 9. Cultivation history ・ Sowing on September 29, 2000                   ・ Transplanted on October 10, 2000                   ・ Planted on November 18, 2000                   ・ Beginning of harvest on February 11, 2001                   ・ End of harvest on June 14, 2001 10. Heating period December 14, 2000-March 31, 2001 11. Yield 6.8kg / share

Comparative Example 1 (Cultivation by not heating the medium) Cultivation conditions are shown below. The medium, seedling raising method, transplantation, planting, irrigation method, number of investigated strains, cultivated items, and cultivation history were exactly the same as in Example 1. 2. Medium temperature The medium temperature was measured without heating the medium and at a depth of 8 cm. There are some differences depending on the month, but from February to March
The average temperature of the medium from 18:00 in the month to 8:00 the next day was about 15.7 ° C. 11. Yield 4.9 kg / share

By comparing the yields of Example 1 and Comparative Example 1, it was found that medium-heated tomato cultivation in winter is effective. Under the same conditions in the above-ground part of tomatoes, there was a clear difference in the yield due to the difference in cultivation temperature in the underground part. Compared to non-heating of the medium, cultivation of heating the medium increased the yield of tomatoes by about 38%. In this case, because the heat of the underground dam water that is pumped in large quantities from the underground dam can be used to heat the medium, separate heat energy is not required, and heat exchange with the underground dam water and the medium heating device of the cultivation facility The motive energy required to circulate hot water in between was sufficient.

Example 2 When spinach was cultivated in Okinawa Prefecture, comparative culture was carried out in which the medium according to the present invention was cooled and the medium was not cooled for comparison. The cultivation bed was installed in the greenhouse so as not to be affected by weather such as rain, but communicated with the outside air so that the temperature of the environment was the same as the outside air.

(Cultivation by cooling the medium) The cultivation conditions are shown below. 1. Medium Pumice stone with a particle size of 1 to 5.6 mm (cultivation box) 1. Medium cooling method The temperature of the medium at a depth of 6 cm in the cultivation box was controlled to be 20 ° C, but the actual average temperature was about 21 ° C. (Cooling was performed by circulating water with a water temperature of 20 ° C that exchanged heat with underground dam water with a water temperature of 21-23 ° C in the cultivation box piping at a flow rate of 23 liters / minute.) 3. 3. Seedling raising method Seedling raising in cell tray (2 seeds per hole, 130 seeds per 0.5 m ² ) 4. 4. Fixed planting Fixed planting in a cultivation bed equipped with a medium heating device (15 fixed cells with 5 cells). Irrigation method The culture solution is flowed by drip. Cultivated area 1.5m ² 7. Cultivated items Spinach (variety: Suncrest) 8. Cultivation history ・ Seeding on July 20, 2000 ・ Planting on August 1, 2000 (11 days after sowing) ・ Harvesting on September 8, 2000 (38 days after planting) 9. Cooling period August 1, 2000-September 8, 2000 10. Yield 2057g / m ²

Comparative Example 2 (Cultivation by not cooling the medium) Cultivation conditions are shown below. Media, seedling method, planting, irrigation method, cultivation items, cultivation history,
The same as in Example 2. 2. Medium temperature The medium temperature was measured at a depth of 6 cm without cooling the medium. The average temperature of the medium from 7:00 to 19:00 in August is about 30.8, although there are some differences depending on the month.
It was ℃. 10. Yield 230g / m ²

By comparing the yields of Example 2 and Comparative Example 2, it was found that medium-cooled spinach cultivation in the summer is effective. Under the same conditions in the above-ground part of spinach, there was a clear difference in the yield due to the difference in cultivation temperature in the underground part. In contrast to the non-cooling of the medium, in the culture of cooling the medium, the yield is increased by about 795%.

[0045]

EFFECTS OF THE INVENTION According to the present invention, in a cultivation facility for cultivating crops such as vegetables and flowers, the natural energy in the area where the cultivation facility is located is utilized to the maximum, and the crop is heated to a proper temperature with a small amount of energy. With regard to the cultivation facilities that can be maintained at, the crop can be maintained at an appropriate temperature by making maximum use of the natural energy peculiar to the area where the facilities are located. Especially in subtropical regions, when underground dam water is used as a cold and heat source, the heat can be used simply because the underground dam water is pumped as agricultural water, so energy for pumping is not required. Moreover, due to the water temperature of the underground dam, as a cold heat source in summer,
In addition, it can be used as a heat source in winter and can be cultivated with a small amount of energy.

Furthermore, according to the present invention, in order to heat or cool the cultivation in the facility, the heat transfer device for letting the heating or cooling medium pass through is inserted into the medium of the cultivation bed to control the temperature of the facility. Can be used as the optimum temperature condition for cultivating the crop, so that the temperature condition in the air in the facility is not the optimum condition for cultivating the crop, and even if the temperature condition is suitable or does not hinder the growth Therefore, it is possible to obtain a significant reduction in energy consumption as compared with the conventional temperature control method that makes the entire indoor space of the cultivation facility into the optimum temperature condition for cultivation of crops. Moreover, when pumice stone is used as the medium, the heat insulating effect is great and the heat given by the heat transfer device is hard to escape, so that the heat efficiency is good. Further, when the medium particles having a large particle size are used, since the medium particles have large voids, heating or cooling by convection is promptly performed. Further, as a method of supplying the culture solution, when the so-called drip flow-through method of dropping the culture solution is adopted, the water content in the medium is small due to the small drip amount of the culture solution. Since the amount of heat required to raise the temperature of water is small, the thermal energy required for controlling the temperature of the cultivation bed is minimized.

[Brief description of drawings]

FIG. 1 is a general explanatory view of a cultivation system having a power interconnection system using natural energy of the present invention.

FIG. 2 is a schematic cross-sectional explanatory view showing an example of the cultivation facility of the present invention.

FIG. 3 shows a conceptual explanatory view of an underground dam used in the present invention.

[Explanation of symbols]

1 cultivation facility 2 Cultivation temperature control system 3 underground dam 4 farm pounds 5 underground dam water 6 heat exchanger 7 Ice heat storage 8 Cold heat supply 9 Eco-vegetable system 10 solar cells 11 Wind power generation equipment 12 Commercial power 13 system linkage board 14 Power supply 15 Outer cover 16 props 17 isolation tray 18 medium 19 heat transfer pipe 20 cold heat source 21 Culture liquid supply device 22 water conduit 23 Infusion tube 31 Limestone formation 32 Impermeable layer (Shimajiri layer) 33 Water stop wall 34 Aquifer 35 full water level 36 Water intake facility 37 wells 38 pumps 39 Water intake gate 40 waterways 41 main waterway 42 sea level

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Hidemitsu Otsuka             11-1 Haneda Asahi-cho, Ota-ku, Tokyo Co., Ltd.             Inside the EBARA CORPORATION F term (reference) 2B027 NB01 NC15 NC42 ND01 NE01                       QD10 TA09 UA04 UA14 UB09                       UB12 UB16                 2B029 KA06 RA18 SA02 SA04 SA05                       SA06 SD07 SD09 SD17 SD23                       SD24 SD27 SD28 SE05                 2B314 MA35 NC07 PB19 PC19 PD45                       PD47 PD51 PD52

Claims (3)

[Claims] 1. A cultivation facility for cultivating a crop in a culture medium of a cultivation bed, comprising a heat transfer device for heating or cooling the temperature of the culture medium at the bottom or inside of the cultivation bed, which is installed in an area where the cultivation bed is located. Characterized in that the medium is directly heated or cooled by applying to the heat transfer device one or more of the power from the solar power generation facility, the wind power generation facility, or the thermal energy from the underground dam or ice reservoir. A cultivation facility that uses natural energy. 2. The medium is directly heated or cooled by passing the stored water of an underground dam or a heat medium that has exchanged heat therewith through the heat transfer device.
Cultivation facility described. 3. The cultivation facility according to claim 1 or 2, wherein a porous solid medium is used as a medium for the cultivation bed, and a culture solution is dropped to grow the crop.