JPH0354536B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a plant cultivation device used for hydroponic cultivation, and particularly to avoiding an increase in the temperature of a nutrient solution.

[Conventional technology]

In contrast to traditional soil cultivation, which uses soil, plants are planted in artificial culture media such as fibrous materials, which provide the necessary nutrients and water to grow the plants. There is hydroponic cultivation, which cultivates by supplying a nutrient solution.

This type of hydroponic cultivation has superior features such as being more hygienic than soil cultivation, allowing optimal conditions to be set for each cultivated plant, and easy cultivation management. , it is extremely important to manage the supply of nutrient solution to plants.

Hydroponic cultivation uses, for example, an irrigation method in which a nutrient solution is dripped or sprayed onto the plants. In this irrigation method, nutrient solution is intermittently supplied to plants at regular intervals. Therefore, plant roots alternate between being in a moist state due to irrigation, and evaporation of the nutrient solution due to stopping irrigation (draining) and contact with the air. In the irrigated state, oxygen is sufficiently absorbed mainly through contact with air, and its growth is promoted.

In the cultivation area, plants are planted in an artificial medium that supports the roots of the plants, and cultivation is carried out by supplying nutrient solution to the medium.The nutrient solution is stored in a tank, and from that tank there is a supply route near the cultivation area. The nutrient solution is pumped through. The pressure-fed nutrient solution is supplied to the plants by being sprayed or dripped by a drip nozzle extending from the supply path to the culture medium.

This method of supplying nutrient solution using a drip nozzle supplies the required amount of nutrient solution, so compared to the recycling method of collecting waste liquid that has passed through the culture medium,
It has advantages such as low power consumption due to the pressure pump and no risk of disease infection due to reusing waste liquid.

[Problem that the invention seeks to solve]

By the way, in such hydroponic cultivation, while the supply of the nutrient solution is stopped, the temperature of the nutrient solution remaining in the supply pipe increases due to sunlight or the like. The temperature increase is particularly significant in the summer.

If such a heated nutrient solution is supplied to a plant, the roots of the plant will be deficient in oxygen, hindering growth, and if the temperature is high, there is a risk that the plant will wither.

Therefore, it is an object of the present invention to provide a plant cultivation device that avoids supplying a nutrient solution at an elevated temperature and always supplies a nutrient solution at an appropriate temperature.

[Means for solving problems]

For example, as shown in FIG. 1, the plant cultivation device of the present invention supplies the nutrient solution Wn, which has been pressure-fed to the medium (sapling medium 88), to the plants 8 in the medium through a supply nozzle (drip nozzle 6). In the cultivation device for plants grown in a plant, a nutrient solution tank 30 for storing the nutrient solution is installed, a supply path (supply pipe 2) is installed for pressure-feeding the nutrient solution from the nutrient solution tank to the supply nozzle side, A return path (return pipe 1
2) is connected to this return path, and adjusts the pressure of the nutrient solution in the supply path to adjust the amount of nutrient solution discharged from the supply nozzle to the culture medium. Means (adjustment valves 10a, 10
b) is installed.

[Effect]

With this configuration, the nutrient solution discharge amount adjusting means (adjusting valves 10a, 10b) installed on the return path (return pipe 12) side connected to the supply path (supply pipe 2)
This allows the pressure of the nutrient solution in the supply path (supply pipe 2) to be adjusted, and for example, the nutrient solution pressure in the supply path (supply pipe 2) can be easily lowered on the nutrient solution tank side, and It is possible to know the discharge status of the heated nutrient solution Wn. Therefore, when the supply of the nutrient solution Wn starts, the supply of the nutrient solution Wn heated in the supply path during the period when the supply of the nutrient solution Wn is stopped is suppressed, and the heated nutrient solution Wn does not affect the cultivated plants. Negative effects can be avoided.

Further, in this plant cultivation apparatus, the nutrient solution discharge amount adjusting means includes the first and second adjusting valves 10.
a and 10b, and by switching the nutrient solution pressure in the supply path (supply pipe 2) stepwise or continuously, the desired nutrient solution pressure can be easily set, and the plant It can contribute to the promotion of cultivation.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows an embodiment of the plant cultivation apparatus of the present invention.

In FIG. 1, raw water Wr consisting of agricultural water such as groundwater and rainwater is filtered to remove impurities by a filter 16, and then is supplied to raw solution tanks 20, 22, 24 through a supply pipe 18. It is supplied to the nutrient solution tank 30 through the nutrient solution tank 30.
The flow rate of raw water Wr is regulated by a valve 32, and the flow rate is electrically detected by a flow rate sensor 34, and M represents the flow rate signal.

In addition, the amount of raw water Wr is measured by a water meter 36, and each raw water tank 20, 22, 2
The supply amount of raw water Wr to 4 is determined by valves 38, 40,
42. Fertilizer is loaded into the stock solution tanks 20, 22, and 24, and the fertilizer and raw water Wr are mixed to form a stock solution Wo. The stock solution Wo ₁ in the stock solution tanks 20, 22, 24,
Wo ₂ and Wo ₃ are float switches 44, 46, 4
8, FSW ₁ , FSW ₂ ,
FSW ₃ represents the capacitive signal. The stock solutions Wo ₁ , Wo ₂ , and Wo ₃ in each stock solution tank 20, 22, and 24 are as follows:
Metering dispensers 50, 52, 5 such as metering valves individually driven by drive signals _PC1 , _PC2 , _PC3
4 to the nutrient solution tank 30. In addition,
The supply of the stock solutions Wo ₁ , Wo ₂ , and Wo ₃ to the nutrient solution tank 30 is adjusted by a ball valve 28 that moves up and down depending on the water level of the nutrient solution Wn in the nutrient solution tank 30 .

Therefore, a predetermined amount of raw water Wr is supplied to the nutrient solution tank 30 from the supply pipe 26, and raw solutions Wo ₁ , Wo ₂ ,
Wo ₃ is supplied and both are mixed to form the nutrient solution Wn, so the nutrient solution Wn is accumulated and the nutrient solution tank 30 is filled with raw water Wr and the nutrient solution Wo ₁ , Wo ₂ , Wo ₃
It also serves as a means of mixing. This nutrient solution tank 30
includes a water level sensor 55 that electrically detects the capacity of the nutrient solution Wn, a temperature sensor 56 that electrically measures the temperature of the nutrient solution Wn, a PH sensor 58 that electrically detects the PH concentration of the nutrient solution Wn, and a PH sensor 58 that electrically detects the PH concentration of the nutrient solution Wn. A concentration sensor 60 that electrically detects the concentration of liquid Wn is provided, where ER represents a water level signal, RW represents a temperature signal, PH represents a PH signal, and EC represents a concentration signal.

Further, branch pipes 64 and 66 are provided in the supply pipe 18 with a valve 62 in between, and valves 68 and 70 are provided in each of the branch pipes 64 and 66 so that the nutrient solution tank 3
The raw water Wr is also supplied to the nutrient solution tank 30 from the branch pipes 64 and 66.

In the nutrient solution tank 30, the nutrient solution is supplied to the cultivation area 4 side.
A supply pipe 2 is provided as a supply path for supplying Wn, and the nutrient solution Wn is passed through the supply pipe 2 to a valve 7.
After passing through 2, a pressure pump 7 as a pressure feeding means
4 to the cultivation area 4. A branch pipe 76 connected to the supply pipe 2 for the raw water Wr is provided on the discharge side of the pressure pump 74, and the raw water Wr can be passed through the supply pipe 2.
The pressure of the nutrient solution pumped by is measured by a pressure gauge 78.

The nutrient solution Wn is sent to the cultivation area 4 after being filtered by a filter 80 installed as a filtration means for filtering solid matter, etc., and the pressure of the nutrient solution is detected electrically as a pressure detection means. The pressure is detected by the pressure switch 10. P ₁ represents the pressure signal.

In addition, the supply pipe 2 is thoroughly piped to a plurality of cultivation beds B ₁ , B ₂ . . .
The plants 8 are individually supplied from a drip nozzle 6 as a supply nozzle branched from the drip nozzle 6 . The nutrient solution Wn that has passed through the supply pipe 2 of the cultivation area 4 is connected to the supply pipe 2 and is connected to the return pipe 1 installed as a return path for the nutrient solution Wn'.
2 and is collected in the nutrient solution tank 30.

As shown in FIG. 2, the cultivation area 4 is set up in a building 86 where a specific environment is set, a bed B is formed as an artificial medium, and a seedling medium 8 is placed on the top surface of the bed B.
Install 8. The bed B and the seedling medium 88 are made of a cultivation medium such as Rotsuwool (trademark), and the plants 8 are planted therein. A drip nozzle 6 as a supply nozzle for guiding the nutrient solution Wn to the plants 8 is installed in the supply pipe 2 for the nutrient solution Wn drawn to the cultivation area 4, and the nutrient solution is passed through the drip nozzle 6.
Drop or spray Wn at the base of plant 8.

In addition, in the cultivation area 4, as environmental sensors for detecting the environmental state in the building 86, a solar radiation sensor 92 that electrically detects solar radiation, a temperature sensor 94 that electrically detects temperature, and an electrical humidity sensor 94 are installed. A humidity sensor 96 for detection is installed. S is the solar radiation signal, T
represents a temperature signal, and W represents a humidity signal. Further, as a culture medium sensor that detects the condition of the cultivation area 4, a temperature sensor 98 that electrically detects the culture medium temperature and a humidity sensor 10 that electrically detects the humidity state of the bed B.
Set 0. R represents a temperature signal, and TW represents a humidity signal.

As shown in FIG. 1, a solar radiation signal S, a temperature signal T, a humidity signal W, a temperature signal R, a humidity signal TW, a flow rate signal M, a capacity signal FSW ₁ obtained from the cultivation area 4 and the pipe system, etc. , FSW ₂ , FSW ₃ , Water level signal ER, Temperature signal RW, PH signal PH, Concentration signal
The EC is added to the cultivation control circuit 102 and the plant 8
Optimal conditions such as the components of the nutrient solution Wn and the feed rate and supply interval of the nutrient solution Wn are calculated or set, and the control signal thereof is supplied to the drive circuit 104. The drive circuit 104 supplies the drive output P ₀ to the pressure pump 74 according to the control signal to drive the pressure pump 74,
Furthermore, the drive signals PC ₁ , PC ₂ , and PC ₃ are supplied to the metering dispenser 5.
0,52,54 and the stock solution Wo ₁ , Wo ₂ ,
The supply of Wo ₃ will be controlled. In this case, the pressure pump 74 is driven at regular time intervals, and the nutrient solution Wn
is sent to cultivation area 4. The sent nutrient solution Wn is dripped onto the plants 8 from the cultivation area 4 by the drip nozzle 6.

In such a cultivation apparatus, the first adjustment is performed as a nutrient solution discharge amount adjusting means for adjusting the nutrient solution pressure in the supply pipe 2 with respect to the return pipe 12 to set the discharge amount of the nutrient solution Wn from the drip nozzle 6. A valve 10a and a second regulating valve 10b are provided in parallel. The adjustment valve 10a may be configured with, for example, a solenoid valve whose opening degree is electrically adjusted, and the adjustment valve 10b may be configured with a valve whose opening degree can be manually adjusted.

Further, the supply pipe 2 and the return pipe 12 are connected to the regulating valve 10b when the regulating valve 10a is in the fully closed state.
By adjusting the opening of the nutrient solution pressure, the discharge amount of the nutrient solution Wn from the drip nozzle 6 can be set to be appropriate.
The pressure of the nutrient solution in the supply pipe 2 can be reduced by adjusting the opening of the drip nozzle 6, and the discharge amount from the drip nozzle 6 can be set to zero or an extremely small amount.

Then, the pressure signal obtained by the pressure switch 10
_P1 is added to a nutrient solution discharge amount control circuit 106 that is linked to the cultivation control circuit 102, and outputs a discharge amount control signal according to the output of the pressure switch 10. In this case, the start signal TS or end signal TN for starting the supply of the nutrient solution Wn is applied from the cultivation control circuit 102 to the nutrient solution output amount control circuit 106, so that the nutrient solution output amount control circuit 106
An opening degree control signal Vo is output for setting the opening degree such that the discharge amount of the nutrient solution Wn from the drip nozzle 6 becomes zero or extremely small, or the opening degree such that the discharge amount is appropriate. Valve drive circuit 108
is the adjustment valve 10a according to the opening control signal Vo.
to output the required opening setting output Do.

Therefore, at a specific time when the supply of the nutrient solution Wn is started, the adjustment valve 10a is set to the required opening degree to reduce the nutrient solution pressure in the supply pipe 2, and the discharge amount of the nutrient solution Wn from the drip nozzle 6 is reduced. can be limited to zero or a trace amount, and the supply of the heated nutrient solution Wn to the plants 8 can be stopped. In this case, the heated nutrient solution Wn is returned to the nutrient solution tank 30 and mixed with the normal temperature nutrient solution Wn.

The control valve 10a is controlled by the supply pipe 2.
The temperature is maintained until the nutrient solution Wn remaining in the tank 30 is collected into the nutrient solution tank 30 and the nutrient solution Wn at an appropriate temperature is circulated. The opening control signal Vo is maintained by setting a specific time for the capacity, and after the specific time has elapsed, the opening control signal Vo is canceled and the regulating valve 10b is closed. In this case, the nutrient solution
The specific time at which Wn supply starts is the time when the heated nutrient solution Wn in the supply pipe 2 is discarded or recovered, and the time is calculated based on the capacity and flow rate in the supply pipe 2. shall be taken as a thing.

When the regulating valve 10a is closed, the pressure of the nutrient solution in the supply pipe 2 is maintained at an appropriate pressure, and an appropriate discharge amount of the nutrient solution Wn is supplied from the drip nozzle 6 to the plants 8.

Therefore, by doing this, it is possible to avoid adverse effects when supplying the heated nutrient solution Wn to the plants 8. In this case, since the capacity of the heated nutrient solution Wn in the supply pipe 2 is usually small compared to the capacity of the nutrient solution tank 30, the nutrient solution Wn in the nutrient solution tank 30 is reduced by the returned nutrient solution Wn. Although the degree of temperature rise is extremely small, a heat exchanger is usually installed in the nutrient solution tank 30 to control the temperature of the nutrient solution Wn.
The temperature of the nutrient solution Wn can be kept constant.

When the heated nutrient solution Wn is circulated in the supply pipe 2, the algae that has grown in the supply pipe 2 and the algae that has adhered to the pipe wall can be washed away by the flow rate of the nutrient solution Wn. Since the circulation of the nutrient solution Wn can be prevented from being discharged from the drip nozzle 6, it is also possible to circulate the nutrient solution Wn when the supply of the nutrient solution Wn is stopped.

In addition, in the embodiment, a mixed solution of water and fertilizer has been described as the nutrient solution Wn, but the present invention can also be applied to the case where water is supplied as the nutrient solution.

In addition, the adjustment valve 1 except the adjustment valve 10b
The return amount of the nutrient solution Wn may be adjusted using only 0a, and the nutrient solution pressure may be set to obtain the required discharge amount.

Further, in the embodiment, the heated nutrient solution Wn is collected into the nutrient solution tank 30, but a branch path may be provided in the return pipe 12 and the nutrient solution Wn may be disposed of outside the nutrient solution tank 30 through the branch path.

The nutrient solution discharge amount control circuit 106 may be configured integrally with the cultivation control circuit 102 to realize control of the nutrient solution discharge amount, or may be configured to control cultivation and the nutrient solution discharge amount using an arithmetic processing device such as a microcomputer. may be controlled.

〔Effect of the invention〕

As explained above, according to the present invention, the nutrient solution, which remains in the supply channel and has increased in temperature between the end of supply of the nutrient solution and the start of supply, is transferred to the plants by adjusting the pressure of the supply channel. Since supply to the nutrient solution can be reliably avoided, it is possible to prevent the adverse effects of the heated nutrient solution on the plants, and to further promote the growth of the plants.

[Brief explanation of drawings]

FIG. 1 is a diagram showing an embodiment of the plant cultivation apparatus of the present invention, and FIG. 2 is a diagram showing a cultivation area in the plant cultivation apparatus of FIG. 1. Wn... Nutrient solution, 2... Supply pipe (supply path), 6...
...drip nozzle (supply nozzle), 8...plant,
10a, 10b...Adjustment valve (nutrient solution discharge amount adjustment means), 12...Return pipe (return path), 30...Nutritional solution tank, 88...Sapling medium (medium).

Claims (1)

[Scope of Claims] 1. A plant cultivation device for cultivating plants in the medium by supplying a nutrient solution pressure-fed to the medium side through a supply nozzle, comprising: a nutrient solution tank for storing the nutrient solution; A supply path is installed to forcefully feed the nutrient solution from the tank to the supply nozzle, and a return path through which the nutrient solution that does not flow out from the supply nozzle flows is connected to this supply path. 1. A plant cultivation apparatus characterized in that a nutrient solution discharge amount adjusting means is installed for adjusting the pressure of the nutrient solution to adjust the discharge amount of the nutrient solution to be supplied to the medium from the supply nozzle. 2 The nutrient solution discharge amount adjusting means includes first and second
2. The plant cultivation device according to claim 1, wherein the plant cultivation device is configured with a regulating valve, and is configured to switch the nutrient solution pressure in the supply path stepwise or continuously.