JPH0630664A - Nutritive liquor formulation system - Google Patents

Abstract

PURPOSE:To provide system designed to efficiently grow plants without suspending the circulation of a nutritive liquor to raising beds and without the need for preparing additional tanks. CONSTITUTION:The electrical conductivity of a nutritive liquor 8 to be used for plant raising is determined by an electrical conductivity meter 12; when the resultant electrical conductivity value is out of a specified range, an acid- alkali feeder 3, liquid fertilizer feeder 9 and water feeder 4 are selectively actuated respectively for a specified time so that the electrical conductivity value fall within the specified range through a controller 2, and concurrently, electrical conductivity control is performed to check its value at every specified time so that such value does not get out of the specified range; a nutritive liquor is replenished under the above actions.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a nutrient solution blending device used for nutrient solution cultivation of plants.

[0002]

2. Description of the Related Art In a nutrient solution blending apparatus used when cultivating a plant using a nutrient solution, pH, conductivity, etc. are measured and the nutrient solution is managed by using each of these measurement results as an index. .

In this case, for example, when the water level in the nutrient solution tank falls below a certain low level, the circulation of the nutrient solution to the cultivation bed is temporarily stopped, and then dilution water is injected to the high level to the nutrient solution tank. At the same time, high-concentration liquid fertilizer is injected so that the conductivity of the nutrient solution in the nutrient solution tank falls within a predetermined range.

Alternatively, a spare tank is provided in addition to the nutrient solution tank, and the nutrient solution supported by the spare tank is injected into the nutrient solution tank.

[0005]

However, in the above-mentioned conventional nutrient solution mixing device, it is necessary to suspend the circulation of the nutrient solution to the cultivation bed, or to provide a spare tank in addition to the nutrient solution tank. There was a problem.

In view of the above-mentioned circumstances, the present invention provides a nutrient solution preparation device capable of efficiently growing plants without suspending the circulation of the nutrient solution to the cultivation bed and without preparing an extra tank. The purpose is to provide.

[0007]

To achieve the above object, the present invention provides a conductivity meter for measuring conductivity in a nutrient solution used for plant cultivation, and a conductivity measured by the conductivity meter. When the rate is out of a predetermined range, the conductivity control is performed in a nutrient solution blending device including a conductivity control unit that replenishes a plurality of liquid fertilizers or dilution water to match the conductivity in the nutrient solution with a target value. At the time of replenishing the nutrient solution, the department checks the conductivity every certain time so that the conductivity falls within a predetermined range, and conducts conductivity control by operating various liquid fertilizer supply systems and dilution water supply systems for a certain time. Characterize.

Further, a conductivity meter for measuring conductivity in a nutrient solution used for plant cultivation, a pH meter for measuring pH in the nutrient solution, and ions for measuring various ion concentrations in the nutrient solution When the conductivity measured by the analyzer and the conductivity meter is out of a predetermined range, a conductivity control unit that replenishes a plurality of liquid fertilizers or dilution water to match the conductivity with a target value,
When the pH value measured by the pH meter is out of a predetermined range, a pH control unit for replenishing the pH value with a target value by replenishing an appropriate one of a plurality of alkaline solutions or a plurality of acid solutions. And when the concentration of a certain ion analyzed by the ion analyzer is out of the predetermined concentration range, the mixing ratio of a plurality of liquid fertilizers is changed or diluting water or an acid / alkaline solution is supplemented appropriately. Then, in the nutrient solution blending device provided with an ion concentration control unit that puts the various ion concentrations within a predetermined range, the conductivity control unit, at a constant time so that the conductivity falls within a predetermined range when the nutrient solution is replenished. While conducting the conductivity control by operating various liquid fertilizer supply systems and dilution water supply systems for a certain time while checking the above, the pH control unit or the ion concentration control unit is performing the conductivity control. , PH also worn various ion concentration if outside the predetermined range, which comprises carrying out the control of pH or various ion concentrations.

[0009]

In the above structure, when the conductivity in the nutrient solution used for plant cultivation is measured by the conductivity meter and the conductivity measured by the conductivity meter is out of the predetermined range,
The conductivity control unit operates various liquid fertilizer supply systems and dilution water supply systems for a certain period of time so that the conductivity falls within a predetermined range, and the conductivity control is performed so that the conductivity of the nutrient solution falls within the predetermined range. The nutrient solution is replenished while being checked at regular intervals so as not to come off.

If the pH or various ion concentrations are out of a predetermined range during the conductivity control, the pH or various ion concentrations are controlled.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a block diagram showing an embodiment of a nutrient solution mixing device according to the present invention.

The hydroponic cultivation apparatus shown in this figure has a sensor unit 1
A controller 2, an acid / alkali supply unit 3, a liquid fertilizer supply unit 9, and a water supply unit 4, and an NFT cultivation panel 7, that is, a tank 5 by a circulation pump 6.
Various ion concentrations of the nutrient solution 8 supplied to the cultivating panel 7 of a system in which the nutrient solution 8 in the inside is pumped out and supplied to the cultivating panel 7, and the nutrient solution 8 flowing out from the cultivating panel 7 is returned to the tank 5. The plants on the cultivation panel 7 are effectively grown while the waste of the nutrient solution 8 is eliminated by optimally controlling the conductivity, the pH, and the like.

The sensor unit 1 has various ion analyzers 10 for measuring various ion concentrations of the nutrient solution 8 in the tank 5.
A pH meter 11 for measuring the pH of the nutrient solution 8 and a conductivity meter 12 for measuring the conductivity of the nutrient solution 8.
Various ion concentrations of the nutrient solution 8 detected by these various ion analyzers 10, pH meters 11, and conductivity meters 12,
The pH and conductivity are supplied to the controller 2.

The controller 2 generates a signal for controlling the supply of various acid liquids, various alkali liquids, and various liquid fertilizers based on the detection results supplied from the sensor unit 1, and supplies them to the acid / alkali supply. The process of supplying to the unit 3 and the liquid fertilizer supply unit 9 and the process of generating a drive signal for controlling the supply of water and supplying this to the water supply unit 4 are performed.

The acid / alkali supply unit 3 includes a plurality of acid tanks 13 for storing various acid solutions, and the controller 2
A plurality of pumps 14 for selectively pumping out any one of the various acid solutions stored in each of the acid tanks 13 and supplying it to the tank 5 based on a signal supplied from A plurality of alkaline tanks 15
A plurality of pumps 16 for selectively pumping out any of various alkaline liquids stored in each of the alkaline tanks 15 and supplying the alkaline liquids to the tank 5 based on a signal supplied from the controller 2; One of various acid solutions based on the signal supplied from the controller 2,
Alternatively, one of various alkaline liquids is selected and supplied to the tank 5.

In this case, the acid solution is, for example, HNO ₃ solution, H ₃ PO ₄ solution, H ₂ solution for adjusting the main component ions.
SO ₄ liquid is used, and H is used for adjustment of trace component ions.
₃ BO ₃ solution and H ₂ MO ₄ solution is used.

As the alkaline liquid, for example, KOH liquid or Ca (OH) ₂ liquid for adjusting the main component ions,
Mg (OH) ₂ liquid, NH ₄ OH liquid, etc. are used, and Fe (OH) ₂ liquid and Fe (O
H) ₃ solution, Mn (OH) ₂ solution, Zn (OH) ₂ solution, C
A u (OH) ₂ solution or the like is used.

The liquid fertilizer supply unit 9 includes a plurality of liquid fertilizer tanks 19 storing various liquid fertilizers, and the controller 2
A plurality of pumps 20 for selectively pumping out any of the various liquid fertilizers stored in the liquid fertilizer tanks 19 and supplying the liquid to the tanks 5 based on a signal supplied from the controller 2. One of various liquid fertilizers is selected on the basis of the signal to be supplied to the tank 5.

The water supply unit 4 is the controller 2
An electromagnetic valve 18 for controlling passage of water supplied through the water faucet 17 on the basis of a signal from is supplied and is supplied through the water faucet 17 when a drive signal is supplied from the controller 2. Water is passed through and supplied to the tank 5.

Next, the operation of this embodiment will be described with reference to FIG.

First, when the nutrient solution 8 required for cultivation is newly prepared, for example, when the level of the tank 5 becomes Low,
The controller 2 sets a control target range of conductivity (Eh is the upper limit value and El is the lower limit value) and the current conductivity of the nutrient solution 8 (EC is the value) determined according to the time zone. Compare with.

When the current conductivity EC exceeds the upper limit value Eh (EC> Eh), the concentration of the nutrient solution 8 is higher than the target range, so the solenoid valve 18 is opened for a certain time A.
Water is supplied to the tank 5 to dilute the nutrient solution 8. On the other hand, when the current conductivity EC is below the lower limit value El (El> EC), the concentration of the nutrient solution 8 is lower than the target range, and therefore the pump 20
Is operated for a certain time B to supply the liquid fertilizer to the tank 5.

When Eh>EC> El, the nutrient solution 8
Since the concentration of is within the target range, the pump 20 is operated for a fixed time B, and at the same time, the solenoid valve 18 is opened for a fixed time A. In this case, the constant times A and B may be the same, but they are usually different, and the electromagnetic valve 18 and the pump 20 are respectively set to the constant times A and B, respectively.
If only B is operated, the newly added nutrient solution is set to fall within the control target range of conductivity.

Then, after the solenoid valve 18 is operated for a fixed time A or the pump 20 is operated for a fixed time B, it waits for a fixed time for stirring the nutrient solution 8. After the standby time has elapsed, the current conductivity EC is again compared with the upper limit value Eh and the lower limit value El of the control target range, and either the solenoid valve 18 or the pump 20 or both are operated. This operation is performed until the level of the tank 5 becomes High.

At this time, the upper limit value El and the lower limit value El of the conductivity control target range may be the same. In this case, the current conductivity EC of the nutrient solution 8 is EC> Eh = El, or Eh
= El> EC, and the same processing as described above is performed.

The above-described operation of the pump 20 may be performed by the pumps 14 and 16 instead of the above, or may be operated simultaneously to prepare the nutrient solution.

The above is the case of preparing a new nutrient solution while controlling the conductivity. Next, the relationship between pH control and ion control will be described.

The pH control is started when the current pH of the nutrient solution 8 is out of the pH control target range. The ion control is started in the same manner as the pH when the current ion concentration of the nutrient solution 8 is changed. This is the time when the ion concentration is out of the control target range. The start timing is as follows: 1) when the conductivity control is completed, 2) the pump 20 (14, 16) operates for a certain time B and the solenoid valve 18 for a certain time B during the conductivity control, and then waits for a certain time. , Before again comparing the current conductivity of the nutrient solution 8 with the target range of the conductivity control, 3) at any time during the conductivity control. Further, in this device, these selections can be easily made by the user.

Further, in pH control and ion control,
The pumps 14 and 16 and the solenoid valve 18 are used, but like the conductivity control, a certain period of time is provided for small-scale control,
The conductivity control, the pH control, and the ion control can be sequentially performed by sequentially providing them.

The starting point of preparing the nutrient solution 8 while controlling the conductivity may be at a certain time or when the current conductivity of the nutrient solution 8 is out of the target control range of the conductivity.

Further, the ion analyzer in each of the above-mentioned embodiments may be ion chromatography, titration, absorption spectrometry, etc. in addition to the ion electrode method capable of measuring in real time. After the analysis is performed once, the result may be stored in the controller 2 and an acid, an alkali, or a liquid fertilizer may be selectively used when controlling the EC or pH from the next time.

In each of the above embodiments, NT
Although the F method of hydroponic cultivation has been described, the present invention may be applied to other methods such as rock wool method and DFT method for controlling the nutrient solution.

[0033]

As described above, in the invention described in claim 1, the conductivity of the nutrient solution can be optimally controlled, and the circulation to the cultivation panel is stopped when the nutrient solution is replenished. There is no need for an extra tank, and plants can be effectively grown. Further, in the invention according to claim 2, it is possible to eliminate waste of the nutrient solution by optimally managing various ion concentrations, conductivity, and pH of the nutrient solution, and to circulate it to the cultivation panel when supplementing the nutrient solution. There is no pause, and no additional tanks are needed, allowing plants to grow effectively.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an embodiment of a nutrient solution mixing device according to the present invention.

[Explanation of symbols]

 1 Sensor Section 2 Controller 3 Acid / Alkali Supply Section 4 Water Supply Section 5 Tank 7 Cultivation Panel 8 Nutrient Solution 9 Liquid Fertilizer Supply Section 10 Various Ion Analyzer 11 pH Meter 12 Conductivity Meter 13 Acid Tank 14 Pump 15 Alkaline Tank 16 Pump 17 Water tap 18 Solenoid valve 19 Liquid fertilizer tank 20 Pump

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Internal reference number FI Technical display location G05D 21/00 A 7314-3H C 7314-3H 21/02 7314-3H

Claims (2)

[Claims] 1. A conductivity meter for measuring conductivity in a nutrient solution used for plant cultivation, and a plurality of liquid fertilizers or dilution water when the conductivity measured by the conductivity meter is out of a predetermined range. In a nutrient solution blending device including a conductivity control unit that replenishes and matches the conductivity in the nutrient solution with a target value, the conductivity control unit has a conductivity within a predetermined range during nutrient solution replenishment. Thus, the nutrient solution preparing device is characterized in that the conductivity control is performed by operating various liquid fertilizer supply systems and dilution water supply systems for a constant time while checking at regular intervals. 2. A conductivity meter for measuring conductivity in a nutrient solution used for plant cultivation, and a pH for measuring pH in the nutrient solution.
Meter, an ion analyzer for measuring various ion concentrations in the nutrient solution, and when the conductivity measured by the conductivity meter is out of a predetermined range, the conductivity is replenished with a plurality of liquid fertilizers or dilution water. When the pH value measured by the pH meter is out of a predetermined range, the conductivity control unit that matches the target value with is adjusted by replenishing an appropriate one of a plurality of alkaline solutions or a plurality of acid solutions. When a concentration of a certain ion analyzed by the ion analyzer is out of a predetermined concentration range, a pH control unit for adjusting the pH value to a target value is changed, or the mixing ratio of a plurality of liquid fertilizers is changed, or dilution water or acid is added. -In the nutrient solution blending device including an ion concentration control unit that replenishes any one of the alkaline solutions to bring the various ion concentrations into a predetermined range, the conductivity control unit Conducts conductivity control by operating various liquid fertilizer supply systems and dilution water supply systems for a certain period of time while checking the conductivity every certain period of time so that the conductivity falls within a predetermined range. The nutrient solution preparation device, wherein the control unit controls the pH or various ion concentrations if the pH or various ion concentrations fall outside a predetermined range during the conductivity control.