JP2017184619A - Eco-cultivation system and plant cultivation house - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a very ecological cultivation system and a plant cultivation house which make best use of solar energy and rainwater and can cultivate plants even in places without electricity and water.SOLUTION: An eco-cultivation system and plant cultivation house having a sunlight panel attached as a roof of a plant cultivation house using solar light, a conveyance part for conveying a storage tray 41 on which a plant cultivation all-round pot 40 is placed to the gondolas 2 and 3, and an elevation part utilizing the principle of lever and utilizing rainwater for the storage tray, and a reflective sheet attached to the floor/north side inner wall are provided, wherein by cultivating plants while conveying them using the plant cultivation all-round pot 40 and the storage tray 41, light is evenly applied to activate photosynthesis, air current caused by moving as well as moderate shaking and vibration are useful for air-conditioning and pollination of cultivated plants, and rain water falling on the solar panel is gathered to use for hydroponic nutrient solution and water of power source.SELECTED DRAWING: Figure 1

Description

In the present invention, the amount of solar energy is about 20% to 30% under the roof of a solar panel of a solar power plant (Patent Document Japanese Patent Application Laid-Open No. 2014-201987). By changing the cultivation recipe without changing the system at more than double, it is possible to carry out many types of plant hydroponics, and the labor involved in cultivation can be reduced from the yield per unit area.
Furthermore, emphasis is placed on plant cultivation basics (photosynthesis, root function, stem function, leaf function, element management necessary for plant cultivation, etc.) for each plant seedling, without using electricity. The plant hydroponic cultivation was realized in the solar-powered plant cultivation house using rainwater.
That is, all the electric power obtained by solar power generation is purchased and sold to the electric power company.

In order to realize the preceding item, a plant cultivation universal pot and storage tray (Patent Document Japanese Patent Application Laid-Open No. 2016-21958) and low cost are possible for plant hydroponics in a place where the amount of sunlight of a solar power plant is small. An eco-cultivation system and a plant cultivation house are required.
A strawberry in a plant cultivation universal pot and storage tray (Patent Document Japanese Patent Application Laid-Open No. 2016-21958), an eco cultivation system and a plant cultivation greenhouse in an environment where the amount of light is less than 10% under a solar panel in Chiba Prefecture (December) The demonstration experiment of hydroponics (-May) and hydroponics of green soybeans (May-November) has been conducted since February 2015 using the same cultivation system.

Plants can be cultivated under solar panels at solar power plants only by planting plants with a large amount of light at the expense of negative plants or a large amount of power generation.
Still, power generation, quality of cultivated plants, production volume, labor force, investment effect, etc. are not going as expected, and solar sharing (agricultural solar power generation) is mainly in open field cultivation. Do not spread.

What is important in plant cultivation is how one plant seedling can exert its ability.
In the current plant cultivation, it is not possible to carry out management cultivation for each plant seedling.

JP-A-6-225647 JP-A-8-126438 Japanese Patent Laid-Open No. 2008-253241 JP 2011-188773 A JP 2011-239700 A JP 2013-118842 A W02013 / 108620 JP 2013-535959 A JP 2013-214644 A JP 2014-117195 A JP 2014-131518 A Japanese Unexamined Patent Publication No. 2015-17489 Japanese Patent Laying-Open No. 2015-128416

Under a solar panel of a solar power plant, plant hydroponics from many kinds of positive plants to negative plants is performed with a light amount as low as 20% to 30% of solar energy.
It is important to develop many new kinds of plants in this hydroponics.
And it manages the cultivation environment such as photosynthesis, nutrient solution, air flow, temperature, humidity, illness and pests.

While producing electricity even in depopulated areas of Japan, it uses rainwater without electricity and cultivates plants that are necessary for human food.
And for the future of Japan, local production and consumption of electricity and food throughout the country.

In order to grow many plants under 20% to 30% of solar energy under a solar panel of a solar power plant, a cultivation system and an environment for cultivation are required.
Therefore, a plant cultivation universal pot and storage tray (Patent Document JP 2016-21958), a low-cost eco-cultivation system, and plant cultivation under the roof of a solar panel of a solar power plant (Patent Document JP-A-2014-201987) I need a house.
The eco-cultivation system moves storage trays with multiple plant pots in two or more even levels, from north to south, south to north using natural slopes, from top to bottom, from bottom to bottom. Raise and lower using rainwater and move the plant cultivation universal pot to plant hydroponics.
Moving the plant cultivation universal pot provides sunlight uniformly to the plant, creating an air flow in the plant cultivation house, making the environment in the plant cultivation house uniform, and photosynthesis of the plant with moderate shaking and vibration It is possible to pollinate without using bees.
Since rainwater is used as the power source, it is easy to adjust temperature and humidity by spraying mist.
The solar power plant has a solar panel roof (the south side has a low tilt angle of 10 degrees), so walls, doors and windows are attached to the solar panel mount with transparent polycarbonate, transparent glass, etc. About 20m x depth 5m x height (north side) 3m (power generation amount about 10kWh) is the standard, and it is made into a plant cultivation house.
This plant cultivation house is arranged according to the area of the solar power plant, and the necessary number of buildings is arranged.
A waterproof sheet is drawn on the floor, and a reflective sheet is placed on the inner wall and floor on the north side to effectively use less sunlight.
Rainwater is collected at the rain gutter on the south side of the solar panel with a width of about 20m, stored at the highest possible position, and then drained from high to low to be used for the eco-cultivation system.
In one standard plant cultivation house, 15 eco-cultivation systems (72 pots / unit of universal plant cultivation pots) are arranged in about 1080 pots.

  Under the roof of the solar panel of the solar power plant (Patent Document JP2014-201987), the plant cultivation universal pot and storage tray (Patent Document JP2016-21958), the low cost eco-cultivation system and the plant cultivation house The problem can be solved by managed cultivation with three elements.

  In the present invention, when a solution is found that can manage and cultivate each plant seedling, Japanese electric energy and food can be self-sufficient, and many people can be employed in agriculture.

In the present invention, the ability to grow plants with a minimum reduction (20% to 30%) per unit area in the amount of power generated by a solar power plant is a great plus for Japan, which cannot be self-sufficient in electric energy.
The generated electricity can be sold 100%, and plant cultivation can have a great investment effect.

The present invention has great potential for new and innovative plant hydroponics.
For example, it is possible to change cultivated plants in units of universal pots for plant cultivation, but it becomes difficult, so it is also possible to change cultivated plants in units of eco-cultivation systems, but it is a problem to cultivate different types of plants in plant cultivation houses Is difficult.
It is most suitable to change the cultivated plant by plant cultivation house unit.
It is possible to grow only the required amount of cultivated plants when necessary, and it is suitable for local production and local consumption with different cultivation recipes.
If it thinks so, one kind of cultivated plant can be mass-produced, and the production method can be selected each time.

The present invention does not waste solar energy, which is a natural boon, as electricity and plant cultivation, and water (rainwater) is returned to the ground after use as a power source for nutrient solution and eco-cultivation system.
A large number of plants to be disposed of are easily collected and managed in one place, and can also be used for biomass power generation. It helps a lot.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Fig. 1 shows what kind of plant cultivation system should be developed for eating in an environment where the amount of light under the solar panel 101 of the solar power plant is only 20% to 30%. This is a low-cost eco-cultivation system 1.

Figure 1 thinks that it is necessary to move plants according to the movement of the sun in order to grow plants in low light, and move from north to south, south to north, and the yield per unit area In order to increase further, it was moved from the top to the bottom and from the bottom to the top.
As a result, by moving plants, we discover wonderful effects on photosynthesis, root function, pollination, temperature, humidity, air flow, etc.
Furthermore, the power generation amount of the solar power plant is 100% sold and the eco-cultivating system 1 can be operated using rainwater without using electricity so that the eco-cultivation system 1 can be operated.
However, some electricity is required for automation and unmanned operation.

The basic configuration of the eco-cultivation system 1 in FIG. 1 is a frame 2, a south gondola 3, a north gondola 4, a first floor anti-back stopper 5, a second floor anti-back stopper 6, a first floor free conveyor 12, and a second floor free conveyor 13. is there.
The south side sprocket 7 (having more teeth than the north side sprocket 8) is attached to the left and right, and two points on the left and right sides of the south gondola 3 are hung at the south end of one side of the chain operated by the south side sprocket 7.
An actuator for operating the south gondola lowering brake device 32 is attached to the opposite end of the chain that suspends the left side of the south gondola 3 and operates at a lower limit of 100 mm before the south gondola 3.
The north side sprocket 8 (having fewer teeth than the south side sprocket 7) is attached to the left and right, and the left and right points of the north side gondola 4 are suspended at the north end of one side of the chain operated by the north side sprocket 8.
An actuator for operating the north gondola descending brake device 33 is attached to the opposite end of the chain that suspends the left side of the north gondola 4 so that it operates 100 mm before the lower limit of the north gondola 4.
Gondola right sprocket 9 (the right side of the south side sprocket 7 and the north side sprocket 8), a central sprocket 10 (connecting the south side gondola 3 and the north side gondola 4 so as to pull the upper side of the chain) and a gondola left sprocket 11 (the south side sprocket 7 and the north side) The left side gondola 3 and the north side gondola 4 always move up and down in reverse.

  The original position of the eco-cultivation system 1 in FIG. 1 is that the south gondola 3 is in the ascending limit and the north gondola 4 is in the descending limit, and there is no storage tray 41 in both the north and south gondola.

  Even when the operation of the eco-cultivation system 1 is stopped in FIG. 1, the south side gondola water supply stop valve 128 is closed to stop the original position.

When the south side gondola water supply stop valve 128 of FIG. 1 is opened, the operation starts, the south side gondola water supply device 129 operates, and rainwater is supplied to the south side gondola water tank 21.
It can be changed slightly by adjusting the south side gondola water supply stop valve 128 and the south side gondola water supply device 129, but when the weight of the supplied water reaches the north side gondola 4 in about 15 minutes, the south side and the north side of the south side gondola 3 The left gondola left side locking mechanism 23 attached to the two locations confirms that the storage tray 41 is not seated, and the south gondola 3 can be lowered. The north gondola left side lowering position locking device 24 installed confirms that the storage tray 41 is not present, the south gondola 3 is lowered, and the north gondola 4 is raised.

The south gondola 3 descending in FIG. 1 is provided with a south gondola descending brake device 32 that softens the acceleration due to the spring before the descending limit 100 mm and reduces the impact.
At that time, the storage tray 41 is full on the first-floor free conveyor 12 and the second-floor free conveyor 13, and the first-floor anti-back stopper 5 is attached to the south gondola 3 by the first-floor anti-back stopper opening / closing device 16. The storage tray 41 at the front end of the first-floor free conveyor 12 is opened and carried into the south gondola 3.
At the same time, the second floor anti-back type stopper opening / closing device 17 opens the second floor anti-back type stopper 6 and the storage tray 41 at the tip of the second floor free conveyor 13 is about to be carried into the north side gondola 4. The first-floor seating confirmation interlock device 14 confirms that the first-floor storage tray 41 has been carried into the south gondola 3, and the second-floor free conveyor 13 tip storage tray 41 is the second-floor anti-back stopper opening lock device. The second floor anti-back stopper 6 is opened by the operation of 18 and is carried into the north gondola 4.

  Since the system of FIG. 1 uses the lever principle, if the storage tray 41 is loaded into the south gondola 3 on the first floor and the storage tray 41 is loaded into the north gondola 4 on the second floor, it falls due to the weight. However, the south side gondola 3 and the north side gondola 4 are respectively connected by the south side gondola left side rising position locking device 23, the north side gondola left side falling position locking device 24, the south side gondola right side falling position locking device 25, and the north side gondola right side rising position locking device 26. The structure is such that the ascending / descending operation confirms the seating of the storage tray 41 and operates safely.

In FIG. 1, the north gondola water supply device 130 is operated at the ascending limit of the north gondola 4, and rainwater is supplied to the north gondola water tank 22.
At this time, the worker 31 can work in a posture in which the worker 31 can easily work on the plant in the plant cultivation universal pot of the storage tray 41 carried into the north side gondola 4 in about 15 minutes.
Although the place where the worker 31 can work can be anywhere around the eco-cultivation system 1, the place described above is the easiest to work.
It can be changed slightly by adjusting the north side gondola water supply device 130, but if the weight of the water supplied in about 15 minutes reaches the south side gondola 3, two places are installed on the south side and the north side of the north side gondola 4 The north gondola right side rising position lock device 26 confirms that the storage tray 41 is present, the north side gondola 4 can be lowered, and the south side gondola 3 has two locations on the south side and the north side. The lowering position locking device 25 confirms that the storage tray 41 is present, the north side gondola 4 is lowered, and the south side gondola 3 is raised.
At this time, only when the south gondola 3 is rising, the mist spraying device 131 of the ratchet mechanism operates to spray the mist onto the cultivated plant and simultaneously adjust the temperature and humidity in the plant cultivation house.

The north gondola 4 descending in FIG. 1 is provided with a north gondola descending brake device 33 that softens the acceleration due to the spring before the descending limit 100 mm and reduces the impact.
At that time, one storage tray 41 is empty on the first floor free conveyor 12 and the second floor free conveyor 13, and the first floor and the second floor can receive the storage tray 41 from the gondola. It is in a state.
The storage tray 41 tries to carry out at the lower limit of the north side gondola 4, but the second floor south side gondola storage tray carry-out interlock device 15 enters a standby state.
At the same time, the south side storage tray lock release device 34 releases the south side storage tray lock device 19 to carry out the storage tray 41 at the upper limit of the south side gondola 3, and the storage tray 41 passes through the second floor south side gondola storage tray carry-out interlock device 15 to the north side. The storage tray 41 of the gondola 4 is released by the north storage tray lock releasing device 35 and the storage tray 41 is unloaded by the north storage tray locking device 20.

In FIG. 1, the eco-cultivation system 1 is now in the original position.
From now on, the unmanned automatic operation is repeated until the south side gondola water supply stop valve 128 is closed and the original position is stopped.

FIG. 2 is an overall view of the south side gondola 3 and the north side gondola 4. The basic structure of the gondola is a two-point suspended main body with a south side gondola water tank 21 and a north side gondola water tank 22 at the bottom. There are two square holes, and the water supply to the tank can be supplied anywhere in the square hole.
The transport of the storage tray 41 is the same as the free conveyor used on the 1st and 2nd floors, and the south side gondola free conveyor 27 is installed on the square side of the south side gondola water tank 21 avoiding the square holes, the north side A gondola free conveyor 28 is mounted on the north side gondola water tank 22 so as to avoid the square hole.
The south side gondola 3 has a fixing stopper for the storage tray 41 at the south end, and the north side gondola 4 has a fixing stopper for the storage tray 41 at the north end.
Then, the south side gondola 3 hits the storage tray 41 fixing stopper and is simultaneously locked by the south side storage tray locking device 19 to prevent it from dropping, and is released by the south side storage tray unlocking device 34 at the ascending limit, and the storage tray 41 is carried out.
The north side gondola 4 collides with the fixed stopper for the storage tray 41 and is simultaneously locked by the north side storage tray locking device 20 to prevent dropping, and is released by the north side storage tray lock releasing device 35 at the lower limit, and the storage tray 41 is carried out.
The south gondola 3 and the north gondola 4 have four locking devices, respectively. The south gondola left side rising position locking device 23 (south side and north side 2) and the north side gondola left side down position locking device 24 (south side / north side 2) ) And south side gondola right side down position locking device 25 (2 locations on the south side and north side) and north side gondola right side up position locking device 26 (2 locations on the south side and north side). Each place is configured to operate safely by checking the presence of the storage tray 41 ascending and descending.
The water supply to the south side gondola 3 is supplied by the south side gondola water supply device 129 near the rising limit.
The water supply to the north side gondola 4 is supplied by the north side gondola water supply device 130 near the rising limit.
The south side gondola 3 drains near the descending limit, the south side gondola drainage device 29 opens and drains as much as possible, so the locking device attached to the south side gondola drainage device 29 locks, and the lock device closes to the rising middle position. It is released by the attached release device, the south gondola drainage device 29 is closed, and the drainage stops.
The north side gondola 4 drains near the lowering limit, the north side gondola drainage device 30 opens and drains as much as possible, so the lock device attached to the north side gondola drainage device 30 locks, and the lock device closes to the middle position of the ascent. It is released by the attached release device, the north side gondola drainage device 30 is closed, and the drainage stops.

Fig. 3 is an overall view of the anti-back stopper that moves the storage tray 41 one by one to the gondola and stops the next storage tray 41.
When the south side gondola 3 descends, the first floor anti-back type stopper opening / closing device 16 operates, and the storage tray 41 at the tip of the first floor free conveyor 12 is carried into the south side gondola 3.
At that time, the second storage tray 41 from the front end of the first floor free conveyor 12 is stopped by the first floor anti-back type stopper opening / closing device 16.
When the south gondola 3 rises, the first-floor anti-back stopper opening / closing device 16 returns to its original position, and the storage tray 41 that has been stopped moves by one.
When the north side gondola 4 rises, the second floor anti-back type stopper opening / closing device 17 operates, and the storage tray 41 at the tip of the second floor free conveyor 13 is carried into the north side gondola 4.
At that time, the second storage tray 41 from the front end of the second floor free conveyor 13 is stopped by the second floor anti-back stopper opening / closing device 17.
Furthermore, it is confirmed that the storage tray 41 on the first floor has been carried into the south gondola 3 by the interlock device 14 on the first floor by another interlock, and the storage tray 41 at the tip of the second floor free conveyor 13 has 2 The floor anti-back type stopper opening lock device 18 is actuated to carry in the north gondola 4.
When the north side gondola 4 descends, the second-floor anti-back stopper opening / closing device 17 returns to its original position, and the storage tray 41 that has been stopped moves by one.

FIG. 4 is an overall view of the plant cultivation universal pot 40 and the storage tray 41, which is a plant cultivation universal pot and a storage tray (Japanese Patent Application Laid-Open No. 2016-21958).
Furthermore, a plant cultivation universal pot heat-retaining part 42 such as styrene foam is attached to a plant that is vulnerable to low temperatures, such as strawberry cultivation, to provide a heat retaining effect.

FIG. 5 is an overall view of the plant cultivation house 100. The basic configuration is that a solar panel 101 (Patent Document Japanese Patent Application Laid-Open No. 2014-201987) of a solar power plant is arranged on the roof, and a plant in the east, west, north, and south is used using a solar stand. The cultivation house side wall 102 is surrounded by transparent polycarbonate, glass, etc., the plant cultivation house floor 103 is pasted with a waterproof sheet, the entrance door 104, the north window 105 and the south window 106 are attached, and insect openings are attached to all openings. We will try to prevent the infestation of pests and diseases and make it as close to aseptic as possible.
Reflective sheets are placed on the inner wall and floor on the north side to effectively use less sunlight. By using the double-sided power generation type solar panel 101, a synergistic effect that increases the amount of power generation is aimed.

  FIG. 6 is a configuration diagram of rainwater which is a power source of the eco-cultivation system 1, and includes the eco-cultivation system 1, a solar panel 101, a south side gutter 110, a rainwater storage tank 111, and a rainwater underground tank 112.

  FIG. 7 is a rainwater system diagram, F1 rainwater storage inlet filter 120, F2 rainwater underground inlet filter 121, underground tank to water tank pumping pump 122, eco-cultivation system rainwater supply pipe 123, eco-cultivation system rainwater supply stop valve 124, and eco-cultivation. System rainwater supply filter 125, eco-cultivation system rainwater tank 126, eco-culture system rainwater tank automatic water level adjustment device 127, south gondola water supply stop valve 128, south gondola water supply device 129, north side gondola water supply device 130, mist spraying device 131, and south side gondola It comprises a drainage tray 132, a north side gondola drainage tray 133, an eco-cultivation system rainwater drainage pipe 134, a south side rain gutter overflow drainage pipe 135, a storage tank to an underground tank overflow drainage pipe 136, and an underground tank overflow drainage pipe 137. .

In FIG. 7, rainwater falling on the solar panel 101 is filtered through the F1 rainwater storage inlet filter 120 and stored in the rainwater storage tank 111.
The rainwater stored in the rainwater storage tank 111 is supplied to the ecoculture system 1 through the ecoculture system rainwater supply pipe 123, and the rainwater that has overflowed when the rainwater storage tank 111 is full is stored in the storage tank to the underground tank overflow drain pipe 136. Move to underground tank 112.
The rainwater that overflows when the rainwater underground tank 112 becomes full is drained by the underground tank overflow drain pipe 137, and the rainwater that overflows when the south gutter 110 becomes full is drained by the south gutter overflow drain pipe 135 and is discharged to the ground. Give it back.

The rainwater stored in the rainwater storage tank 111 of FIG. 7 is supplied by the ecoculture system rainwater supply pipe 123, and the rainwater is stored in the ecoculture system rainwater tank 126 of the ecoculture system 1, and the ecoculture system rainwater tank automatic water level is stored. The water level is kept constant by the adjusting device 127.
Using the head from the eco-cultivation system rainwater tank 126, the water is supplied to the south gondola water supply device 129, the north side gondola water supply device 130, and the mist spraying device 131.

    The rainwater drained by the south gondola 3 in FIG. 7 falls to the south gondola drain tray 132, the rainwater drained by the north gondola 4 falls to the north gondola drain tray 133, and the south gondola drain tray 132 and the north gondola drain tray 133 are piped. The rainwater filtered by the eco-cultivation system rainwater drainage pipe 134 through the F2 rainwater underground entrance filter 121 flows to the rainwater underground tank 112.

    Pumping from the underground rainwater tank 112 to the rainwater storage tank 111 with the underground tank to the storage tank pumping pump 122 is possible, but it can be done manually.

FIG. 1 is an overall view of an eco-cultivation system. FIG. 2 is an overall view of the gondola. FIG. 3 is an overall view of the anti-back type stopper. FIG. 4 is an overall view of a plant cultivation universal pot and a storage tray. FIG. 5 is an overall view of the plant cultivation house. FIG. 6 is a block diagram showing a rainwater system. FIG. 7 is a system diagram of the rainwater system.

1 Eco-cultivation system 2 Frame 3 South side gondola 4 North side gondola 5 1st floor anti-back stopper 6 2nd floor anti-back stopper 7 South side sprocket 8 North side sprocket 9 Gondola right sprocket 10 Central sprocket 11 Gondola left sprocket 12 1st floor free conveyor 13 2 Free conveyor on the first floor 14 Interlock device on the 1st floor 15 Interlock device on the 2nd floor anti-back type stopper Opening and closing device on the 1st floor 17 Anti-back stopper device on the 2nd floor 18 Opening anti-stop stopper on the 2nd floor 18 Device 19 South side storage tray lock device 20 North side storage tray lock device 21 South side gondola water tank 22 North side gondola water tank 23 South side gondola left position lock device 24 North side gondola Side-going position locking device 25 South-side gondola right-side down position locking device 26 North-side gondola right-side lifting position locking device 27 South-side gondola-free conveyor 28 North-side gondola-free conveyor 29 South-side gondola drainage device 30 North-side gondola drainage device 31 Worker 32 South-side gondola descending brake device 33 North side gondola lowering brake device 34 South side storage tray unlocking device 35 North side storage tray unlocking device 40 Plant cultivation universal pot 41 Storage tray 42 Plant cultivation universal pot heat retaining part 100 Plant cultivation house 101 Solar panel 102 Plant cultivation house side wall 103 Plant Cultivation house floor 104 Entrance door 105 North side window 106 South side window 110 South side gutter 111 Rainwater storage tank 112 Rainwater underground tank 120 F1 Rainwater storage inlet filter 121 F2 Rainwater underground entrance filter 22 Underground tank to storage tank pumping pump 123 Eco-cultivation system rainwater supply piping 124 Eco-cultivation system rainwater supply stop valve 125 Eco-cultivation system rainwater supply filter 126 Eco-cultivation system rainwater tank 127 Eco-cultivation system rainwater tank automatic water level adjustment device 128 South side gondola water supply Stop valve 129 South side gondola water supply device 130 North side gondola water supply device 131 Mist spraying device 132 South side gondola drainage tray 133 North side gondola drainage tray 134 Eco-cultivation system rainwater drainage pipe 135 South side rain gutter overflow drainage pipe 136 Water storage tank to underground tank overflow drainage pipe 137 Underground tank overflow drain piping

Claims (7)

  A storage tray with a universal pot for plant cultivation on a frame built in two levels is transported from north to south and from south to north by a free conveyor, using a natural conveyor. The lifting and lowering part of the gondola that lifts and lowers by changing the weight using the lever principle using rainwater from the top to the bottom, the bottom to the top, and the transport part to which the anti-back type stopper attached to the Eco-cultivation system characterized by being configured. The first floor of the transport section is equipped with a first floor anti-back stopper that passes the storage trays one by one to the south gondola at the south end of the first floor free conveyor where the storage tray carried from the north side gondola descends from north to south. In addition, there is a first floor anti-back type stopper opening / closing device that opens the first floor anti-back type stopper when the south side gondola comes to a lowered position.
Further, a first-floor presence confirmation interlock device is attached to the first-floor anti-back stopper to manage the movement of the storage tray.
The second floor of the transport section is a second-floor free conveyor in which the storage tray transported from the south side gondola descends from south to north, and a second-floor south side gondola storage tray carry-out interlock device is attached to the place where it has flowed a little. Yes.
A second-floor anti-back stopper is attached at the north end to pass the storage tray to the north gondola one by one, and the second-floor anti-back stopper opens when the north gondola is in the raised position. There is a type stopper opening and closing device.
The eco-cultivation system according to claim 1, further comprising another second-floor anti-back type stopper opening lock device for opening the second-floor anti-back type stopper. The elevator unit includes the south side gondola and the north side gondola.
The south side gondola and the north side gondola always operate in reverse, and the state where the south side gondola is in the raised position and the north side gondola is in the lowered position and the storage tray is not seated in either position is the original position.
When the south gondola is in the ascending position, there is a south gondola water supply device, and when the amount of water for raising the north gondola is supplied to the south gondola water tank attached to the bottom of the south gondola, the south gondola descends.
The descending south gondola is equipped with a south gondola descending brake device that softens the acceleration due to the springs before the descending limit of about 100 mm and reduces the impact.
The south side gondola is loaded with the storage tray at the lowered position, and there is a south side storage tray lock device at the bottom. The south side gondola water tank is drained so that it can be emptied as much as possible by the south side gondola drainage device. To do.
When the south side gondola goes to the raised position, the south side storage tray lock device is released by the south side storage tray lock release device, and the storage tray is carried out.
Furthermore, a south side gondola left side rising position locking device and a south side gondola right side lowering position locking device for checking the seating of the storage tray at each of the rising position and the lowering position of the south side gondola and locking the raising and lowering of the south side gondola are provided. Yes.
When the north side gondola is in the raised position and there is a north side gondola water supply device, and the north side gondola water tank attached to the bottom of the north side gondola is supplied with the amount of water to raise the south side gondola, the north side with the storage tray mounted The gondola descends.
The descending north side gondola is equipped with a north side gondola descending brake device that softens the acceleration due to the springs before the descending limit of about 100 mm and reduces the impact.
The north side gondola is in the ascending position and the first floor anti-back type stopper is the first floor seating confirmation interlock device of the storage tray, and the second floor anti-back type stopper opening lock device is unlocked and the second floor anti-back type When the stopper is opened, the storage tray is carried in, and the storage tray lock device on the north side is located where the storage tray is moved, the north side gondola goes to the lowered position, and the water in the north side gondola water tank is as empty as possible with the north side gondola drainage device. The second floor south side gondola storage tray carry-out interlock device releases the north side storage tray lock device, and the storage tray is carried out.
In addition, there is a north side gondola left side down position lock device and a north side gondola right side lift position lock device that confirm the seating of the storage tray at each of the raised position and the lowered position of the north side gondola and lock the raising and lowering of the north side gondola. The eco-cultivation system according to claim 1 or 2, characterized by being.   The rainwater is collected in the south side rain gutter with a height of about 20m in width of the solar array, stored at the highest possible position, and the water flows from the high place to the low place, and enters the eco-cultivation system rainwater tank of the eco-cultivation system. The eco-cultivation system rainwater tank automatic water level adjustment device is attached to automatically manage the water level of the eco-cultivation system rainwater tank, using the rainwater of the eco-cultivation system rainwater tank, the south side gondola water supply device and the The eco-cultivation system according to claim 1, wherein the rainwater is supplied to a north side gondola water supply device and a mist spraying device. The plant-cultivated universal pot is a hydroponics plant that can manage the cultivation of a single seedling of a cultivated plant and can be cultivated relatively easily compared to other cultivation methods, enabling mobile cultivation of the eco-cultivation system. ing.
Further, when the south gondola rises, it can rotate the manual pump of the mist spraying device, spray the mist, rejuvenate the plant, and manage the temperature and humidity.
As the plants move, the roots of the cultivated plants are stimulated by photosynthesis, moderate shaking and vibration, and the cultivated plants that are not susceptible to pollination and pests that do not use bees are energized, and the air flow, temperature and humidity The eco-cultivation system according to claim 1, wherein management is enabled.   The eco-cultivation system that can cultivate positive and negative plants under the solar panel of a solar power plant with a light intensity of 20% to 30% and uses the rainwater without using electricity as a power source A plant cultivation house characterized by the fact that multiple units can be arranged and 100% of the electricity generated can be sold. The rainwater is collected at the roof of the solar panel, a transparent plant cultivation house side wall is attached to the outside of the column of the solar mount, a low cost is realized, a waterproof sheet is pasted on the plant cultivation house floor, the north side inner wall and floor In order to compensate for a small amount of light, a reflective sheet is attached to assist the photosynthesis of the cultivated plant, maintain the cultivation environment, prevent the invasion of pests and diseases, and assist the plant hydroponics with the eco-cultivation system.
Furthermore, if the model which carries out double-sided power generation is used for the solar panel by sticking the reflective sheet, it is good for the plant hydroponics with a synergistic effect, but the amount of power generation also increases. 6. The plant cultivation house according to 6.