RU177926U1 - HYDROPONIC INSTALLATION - Google Patents

Abstract

The utility model relates to agricultural production, and in particular to means for hydroponic plant cultivation. The hydroponic plant contains the main container for the nutrient solution, a system for supplying (draining) the nutrient solution into the vegetation vessel, the bottom of which is higher than the main container, but below the bottom of the additional container. The additional container is open in the upper part for supplying the nutrient solution and has at least one opening in the lower part for draining the nutrient solution. The hole for draining the nutrient solution in an additional container has a cross-sectional area that allows the nutrient solution to flow out between irrigations in a volume less than the volume required to fill the bottom of the roots, but greater than the estimated total flow rate for evaporation and absorption by the plant. Using the proposed device can improve the efficiency of growing by improving the aeration of the lower part of the roots between watering in hydroponic plants, reliably preserving the viability of plants in case of accidents. 3 s.p. f-ly, 2 ill.

Description

The utility model relates to agricultural production, namely, means for hydroponic plant cultivation.

In hydroponic cultivation without a substrate, an important problem is the preservation of plant viability in case of accidents (power outages and / or equipment breakdowns). This problem is especially relevant when grown by periodic flooding without a substrate, a thin nutrient layer and aeroponics. When a power outage and / or equipment failure occurs, the plants wither in less than 1 hour. Currently, this problem is not satisfactorily resolved.

Known hydroponic plant growing plant [RU 1319806], containing the main container for the nutrient solution, a system for supplying (draining) the nutrient solution into the vegetation vessel, an additional container, with an opening in the upper part for entry and with an opening in the lower part for draining the nutrient solution. A disadvantage of the known hydroponic plant growing plant is the unreliability of the emergency drain system of the nutrient solution in the event of a power outage, because The installation does not provide for automatic locking.

This drawback is deprived of a hydroponic plant [RU 2060644], equipped with a non-return solenoid valve between the container for the nutrient solution and the vegetation vessels, while the valve is connected to the control unit.

A disadvantage of the known device is the unreliability of emergency drain during mechanical failure of the pump or the control unit. Moreover, negative consequences are especially fast manifested in the event of an accident just before irrigation.

Hydroponic plants [RU 1606035, US 8065833], in which during the period between irrigations the nutrient solution from the vegetation vessel is not completely drained and the lower part of the roots are constantly in solution, maintain the viability of plants during accidents.

The closest in technical essence to the claimed technical solution and adopted by us for the prototype is a hydroponic plant [Description of the invention to the copyright certificate RU 1606035. Device for hydroponic plant growing, publication date 1990.11.15], including the main container for the nutrient solution, located below the vegetation vessel , a system for supplying (draining) a nutrient solution to a vegetation vessel, an additional container, the bottom of which is located above the bottom of the vegetation vessel, with the upper part open For entry and with holes in the bottom for draining the nutrient solution. In this case, the nutrient solution is not completely drained from the vegetation vessel, which allows the lower part of the roots to absorb the nutrient solution during an emergency power outage or during mechanical breakdown of nodes and / or parts.

A disadvantage of the known hydroponic installation is that the total cross-sectional area of the holes in the bottom of the additional tank allows the nutrient solution to flow out in the volume between irrigations in a volume greater than the volume necessary for filling the lower part of the roots. This leads to a deterioration of aeration of the lower part of the roots in the periods between irrigation. This is due to the fact that when the nutrient solution is not completely drained from the vegetation vessel, the lower part of the roots is in the nutrient solution not only during irrigation, but also in the period between irrigation. This makes it difficult to aerate the lower part of the roots (since aeration is difficult in the solution). Moreover, the lower part of the roots consists of young and most physiologically active cells that require the most active gas exchange.

Moreover, the more nutrient solution remains in the vegetation vessel between irrigations, the more aeration is difficult for most of the roots, and the less solution remains in the vegetation vessel, the less time the plants remain viable in case of accidents.

The problem to which the claimed technical solution is directed is to increase efficiency by improving aeration of the lower part of the roots between watering in hydroponic plants that reliably maintain the viability of plants in case of accidents.

This task is achieved due to the fact that the hydroponic installation contains the main container for the nutrient solution, a system for supplying (draining) the nutrient solution into the vegetation vessel, the bottom of which is higher than the main container, but lower than the bottom of the additional container, which is open in the upper part for the nutrient solution and has at least one hole in the lower part for draining the nutrient solution, which has a cross-sectional area that allows the nutrient solution to flow out in the volume between the irrigations in a volume less than the volume m, necessary for pouring the lower part of the roots, but more than the estimated total volume of consumption for evaporation and absorption by the plant.

To increase the time to maintain plant viability during accidents, the volume of the additional capacity is from 1/4 to 3/4 of the volume of the vegetation vessel.

For favorable conditions for aeration of all roots in the upper part of the vegetation vessel during periods between irrigation, an additional container is isolated from the roots.

For the possibility of growing various crops that differ in the rate of absorption of the nutrient solution, the hole for draining the nutrient solution from the additional tank has a valve that controls the rate of flow of the solution.

The technical result provided by the given set of features is to increase efficiency by improving the aeration of the lower part of the roots between watering in hydroponic plants that reliably maintain the viability of plants in case of accidents.

In addition, the period is prolonged during which the plants remain viable during accidents due to an increase in the volume of additional capacity from 1/4 to 3/4 of the volume of the vegetation vessel.

The technical solution is illustrated by the drawing, where in FIG. 1 shows a longitudinal section through a hydroponic plant during irrigation; FIG. 2 is a longitudinal section of a hydroponic installation in an accident.

The proposed installation contains the main tank 1 (Fig. 1, 2), for the nutrient solution 12, above which the vegetation vessel 2 is placed, above the bottom of which an additional container 3 for the nutrient solution is located. The bottom of the additional tank 3 has at least one drain hole 13, the cross-sectional area of which allows the nutrient solution to flow out during irrigation in a volume less than the volume needed to fill the bottom of the roots, but greater than the estimated total volume of the solution evaporation and absorption by the plant. The drain hole 13 for draining the nutrient solution from the additional tank 3 has a valve (not shown in the diagram) that controls the rate of flow of the solution. The vegetation vessel 2 has a lid 4 with an opening 5 for the plant 6, fixed with foam rubber 7. A drain pipe 8 prevents overflow of the nutrient solution 12 from the vegetation vessel 2. The timer 10 is connected to a pump 11, which is connected to the vegetation vessel 2 by a siphon 9.

The device operates as follows. The nutrient solution is poured into the main tank 1, above which the vegetation vessel 2 is placed. Plant 6 is strengthened with foam rubber 7 in the hole 5 of the cover 4 of the vegetation vessel 2. When turned on by timer 10, the pump 11 fills (5 min) nutrient solution 12 through a siphon 9 of the vegetation vessel 2. When the upper edge of the additional container 3 is reached, it is filled with nutrient solution 12. Excess nutrient solution from the vegetation vessel 2 through a drain pipe 8 flows by gravity into the main container 1. After a specified time (5 min ) the timer 10 turns off the pump 11 and the nutrient solution 12 from the vegetation vessel by gravity (5 min) completely drains through the siphon 9 into the main tank 1. This allows the lower sections of the roots of the plant 6 to make gas exchange in the air before the next irrigation cycle. At the same time, in the additional container 3, the nutrient solution 12 remains, which gradually drains through the drain hole 13 (3–20 hours) to the bottom of the vegetation vessel 2 by gravity (Fig. 2). At the same time, the opening 13 for draining the nutrient solution 12 from the additional tank 3 has a cross-sectional area that allows the nutrient solution to flow out between irrigations in a volume less than the volume required to fill the bottom of the roots, but greater than the estimated total volume of the solution’s consumption for evaporation and absorption by the plant. After a predetermined time (30 min), the timer 10 again turns on the pump 11 and the cycle repeats.

In case of an accident (power failure or breakdown of the timer or pump), the nutrient solution 12 from the additional container 3 through the drain hole 13 continues to flow by gravity from the additional container 3 and fills the bottom of the vegetation vessel 2 so that the lower part of the roots absorbs the nutrient solution in an amount sufficient to preservation of the viability of the plant 6. In this case, the plant 6 remains viable until the entire volume of the solution 12 in the additional container 3 is consumed. Therefore, the larger the volume of the additional volume bone 3, the longer the plant 6 remains viable in accidents. When changing the irrigation mode, the cross-sectional area of the drain hole 13 is changed using a valve (not shown in the diagram).

Using the proposed device during trouble-free operation allows you to improve aeration of the lower part of the roots between watering, and in case of accidents (power outages or breakdowns of the pump or timer), it is possible to reliably maintain the viability of the plants.

In addition, the proposed device allows to increase the survival time of plants in accidents.

Claims (4)

1. A hydroponic plant containing a main container for the nutrient solution, a supply system - discharge - of the nutrient solution into the vegetation vessel, the bottom of which is higher than the main container, but below the bottom of the additional container, which is open in the upper part for the supply of nutrient solution and has at least one a hole in the lower part for draining the nutrient solution, characterized in that the hole for draining the nutrient solution in an additional container has a cross-sectional area that allows pits to flow out between waterings solid solution in a volume less than the volume needed to fill the lower part of the roots, but greater than the estimated total volume of consumption for evaporation and absorption by the plant. 2. Hydroponic installation according to claim 1, characterized in that the volume of the additional capacity is from 1/4 to 3/4 of the volume of the vegetation vessel. 3. The hydroponic installation according to claim 1, characterized in that the additional container is isolated from the roots. 4. Hydroponic installation according to paragraphs. 1, 2 or 3, characterized in that the hole for draining the nutrient solution from the additional tank has a valve that regulates the cross-sectional area of the hole.

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