SU1014539A1 - Method and apparatus for mineral supply of plants and microorganisms - Google Patents

Abstract

1. A method of mineral nutrition of plants and microorganisms, including the regulation of the mineral: composition of the nutrient solution, the pH value and the total electrical conductivity by adding mineral elements in the form of three solutions that differ in a given pH value, characterized in that in order to separately control the content of ammonia and nitrate forms of nitrogen in the nutrient solution, with the first solution nitrogen is introduced in the form of ammonium compounds, with the second in the form of nitrate compounds. the first pact thief is supplied in discrete portions according to the change in the sign of the first i derivative of the nutrient pH function (L of the solution, the second solution is fed to achieve the specified pH value pi from the tattoo solution, and the third solution is fed to achieve the specified value} and total electrical conductivity pH pH

Description

i 2. A device for mineral nutrition of plants and microorganisms, containing a tank for a nutrient solution, connected through a pH meter and a conductometer with three tanks for solutions of mineral elements, equipped with dispensers, which are connected with pipelines for a nutrient solution, about l and ; that is, it is provided with a differentiator and elements: And, and the pH meter output is connected to

the input of the differentiator, the output of the latter is connected to the input of the dispenser of one of the tanks and the inputs of the elements, when this output of the pH meter is also connected directly to the input of the element I, the output of the latter is connected to the input of the dispenser of the second tank, and the output of the conductometer from the other one element And, the output of which is connected to the inlet of the dispenser of the third tank.

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The invention relates to the refining of plants and microorganisms under controlled conditions and can be used in protected soil, as well as in production. SRI-protein by cultivating hydrogen-oxidizing bacteria.

The known method of mineral nutrition of plants and microorganisms, including the regulation of the mineral composition of the nutrient solution for pH. A device for the mineral nutrition of plants and microorganisms is known, which contains a tank for a nutrient solution, connected through a pH meter to a reservoir for a solution of mineral elements, provided with a dose of II.

The disadvantage of this method is that when adjusting the mineral composition of the nutrient solution its overall electrical conductivity is not taken into account, therefore the concentration of the mineral elements in the nutrient solution can vary over a wide range. A disadvantage of the known device is that it does not contain elements and connections that take into account the overall electrical conductivity of the nutrient solution.

The known method is mineral (nutrition of plants and microorganisms, including regulation of the mineral composition of the nutrient solution by the pH value and the total electrical conductivity by introducing mineral elements in the form of three solutions that differ in a given pH value.

A device for mineral nutrition of plants and microorganisms is known. The base contains a nutrient solution tank, which is connected through a pH meter, and a conductivity meter with three reservoirs for mineral solutions. elements equipped with dispensers which are connected by pipelines with a container for nutrient solution 2.

The disadvantage of the known method and device is that they do not provide separate control of the content of ammonia and nitrate forms of nitrogen in the nutrient solution.

The purpose of the invention is to separate; regulation of the content of ammonia and nitrate forms of nitrogen in the feed solution.

The goal is achieved by the fact that with the first solution nitrogen is introduced in the form of ammonium compounds, with the second in the form of nitrate compounds,

5, salts of the remaining mineral elements are added with a third solution, the first solution being fed in discrete portions according to the change in the sign of the first derivative of the pH of the nutrient solution, the second: the solution is fed until the desired pH of the nutrient solution is reached, and the Third solution is fed until the desired value is reached the values of the total electrical conductivity, as well as the fact that the device for mineral nutrition of the plant and microorganisms is equipped with a differentiator and elements And, the output of the pH meter is connected to the input differentiator output

the latter is connected to the inlet of the dispenser of one of the reservoirs and to the input of the elements, And, while the pH-meter output is also connected directly to the input (AND element, the output of the latter is connected to the input of the dispenser of the second tank, and the output of the conductometer And, the output of which is connected to the inlet of the dispenser of the third reservoir:.

FIG. K shows the change in pH of the nutrient solution by the method mi; nutrition of plants and micro- / organisms after adding a discrete portion of the solution containing nitrogen in the form of ammonium compounds (ammonium hydroxide 7, with a single feed; fig.2 - the same with multiple feeding of discrete portions; Fig. 3 - changing the pH of the nutrient solution according to the method of mineral nutrition of plants and microorganisms after adding a portion of the solution containing nitrogen in the form of urea, with repeated supply of discrete doses; figure 4 is a diagram of the device for mineral nutrition of plants and microorganisms.

The method of mineral nutrition of plants and microorganisms is carried out with the following.

During the cultivation of plants and microorganisms, nitrogen is introduced into the nutrient solution with the first solution in the form of ammonium compounds, for example ammonium hydroxide or urea, with the second solution in the form of nitrate compounds, and salts of the remaining mineral elements are added with the third solution.

The first solution is introduced as a discrete portion, and the pH of the nutrient solution first shifts to the fir-tree area, and then as the plants consume and ammonium microorganisms, the pH of the nutrient solution gradually shifts to the sour region. A pH shift occurs as long as one portion of the first solution is consumed. In this case, the nutrition of plants and microorganisms switches to nitrate nitrogen, which corresponds to a change in the sign of the first derivative of the function of the pH of the nutrient solution.

FIG. 1-3. The x-axis shows the time, the y-axis is the pH value of the nutrient solution.

Positions 1 and 2 correspond to a change in the sign of the first derivative of the function of pH, the nutrient solution.

When the sign of the first derivative of the function of the pH of the nutrient solution changes, a new discrete portion of the first solution is supplied. If at the simultaneous consumption of ammonia and nitrate nitrogen, the pH of the nutrient solution shifts above a predetermined value, a second solution containing nitrogen in the form of nitrates, for example nitric acid, is supplied until the desired pH value of the nutrient solution is reached. As the value of total electrical conductivity decreases, a third solution is supplied, with which salts of the remaining mineral elements are added before reaching the specified value of total electrical conductivity.

P ROME. er 1. The cultivation was wheat, which was grown on a permanent nutrient solution, alternately heating the root system. To compensate for evaporation, water was added by level. With the first solution, nitrogen in the form of urea was added in discrete portions of 7 g, corresponding to a change in the sign of the first derivative of the pH function of the nutrient solution. At the same time, a second solution containing nitrogen was added in the form of nitric acid to lower the pH to a predetermined value of 5.0. With a decrease in the total electrical conductivity of the nutrient solution below a predetermined size of 2 cm / m, a solution of KOH, Ca (NOz, MgSO. 7II2P,.) Was applied in a ratio repeating the removal of mineral elements with wheat biomass. The duration of the experiment was 7 days. dry total wheat biomass corresponded to 50.5 g / day. Changes in the pH values of the nutrient solution corresponded to the graphs, the period was 12 hours, and the amplitude of fluctuations

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EXAMPLE 2 Hydrogen bacteria Hydrogenorronus eutropha Z-1 were the object of cultivation. With the first solution, nitrogen in the form of urea was added in discrete portions of 70 g, corresponding to a change in the sign of the first derivative of the pH function of the nutrient solution. At the same time

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a second solution containing nitric acid was added, lowering the pH to the desired value of 7.3. Harvesting was carried out with a flow of culture from the f, enmenter with a flow rate of 150 l / h, while compounds, CRC, KOH, as well as iron nitrate and trace elements were added to the nutrient solution to increase the total conductivity to a predetermined value. The duration of the experiment 5 hours

. The biomass concentration is 2 g / l, the dry mass productivity is 7/2 kg / day. The change in the pH values of the nutrient solution corresponded to the graphs,

Moreover, the period was 66 minutes, and the amplitude of the pH fluctuations was 0.3. The device for carrying out the method contains a tank 1 for a nutrient solution connected through a pH meter 2 and a conductivity meter 3 with three tanks for mineral element solutions equipped with dispensers that are connected with pipes to the tank. 1 for nutrient solution. The device is equipped with a differentiator 7 and elements 8 and 9 The output of the pH meter 2 is connected to the input of the differentiator 1, the output of which is connected to the inlet of the dispenser k of one of the tanks and to the inputs of the elements 8 and 9. The output of the pH meter 2 is also connected directly to the input element And 8, the output element And 8 is connected to the inlet of the dispenser 5 in the second re-, zervuar. The output of the conductometer 3 is connected to the input element And 9, the output of which is connected to the input of the dispenser

. 6 warm tank.

A device for mineral nutrition of plants and microorganisms works as follows.

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In the process of cultivation of plants and microorganisms, POT occurs.

Their reduction of Mineral elements, which leads to a change in the given pH value 5 and the total electrical conductivity of the nutrient solution in the tank 1.

I In this case, the pH signal (t) goes to pH meter 2. When the pH value rises, indicating that nitrogen is present in the nutrient solution only in nitrate form, differentiator 7 includes dispenser A, and in tank 1 the solution is fed from tank, with which t nitrogen in the form of ammonium compounds, for example ammonium hydroxide or urea. At the same time, the same signal resolves the operation of the chains: element 8 and the dispenser 5 supplying the solution from the second tank, with which nitrogen is introduced in the form of nitrate compounds, for example nitric acid, and element 9, the dispenser 6i supplying the solution from the third tank make salts of the remaining mineral elements. Dispenser 5 is put into operation under conditions. VII, if the pH value of the nutrient solution in the tank 1 is higher than the specified value, which indicates the consumption of nitrates by the plants and microorganisms, the Batcher 6 is put into operation, provided that with the conductometer 3 a signal is received that the total conductivity of the nutrient solution in the tank 1 is lower than the specified value.

Thus, the method of mineral nutrition of plants and microorganisms and a device for its implementation provide separate control of the content of ammonia and nitrate forms of nitrogen.

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Claims (2)

1 · The method of mineral nutrition of plants and microorganisms, including regulating the mineral composition of the nutrient solution, according to the pH value and the total electrical conductivity by adding mineral elements in the form of three solutions differing in a given pH value, characterized in that, for the purpose of separate regulation of the ammonia and nitrate forms of nitrogen in a nutrient solution, with the first solution make nitrogen in the form of ammonium compounds, with the second - in the form of nitrate compounds, with the third solution make the remaining mineral salts x elementrv, 'wherein the first solution is fed in discrete portions, respectively a change of sign of the first derivative function of pH of the nutrient solution, the second solution is fed to achieve a given pH value pi' tatelnoGo solution and the third solution is fed until reaching a predetermined value of the total electrical conductivity. „.SU .... 1014539 1 .1014539.2 '2. A device for the mineral nutrition of plants and microorganisms, containing a container for a nutrient solution connected through a pH meter and conductivity meter * with three reservoirs for solutions of mineral elements equipped with dispensers, which are connected by pipelines to a container for a nutrient solution, about t and: moreover * in that it is equipped with a differentiator and elements' AND, with the output of the pH meter connected to the input of the differentiator, the output of the latter connected to the input of the dispenser of one of the tanks and to the inputs of the elements'I, while od pH-meter is also connected directly to the input of AND, vyhrd latter is connected to the input of the dispenser of the second tank, and soybeans conductometer output of the connections to the input of another element [AND, whose output is connected to the 'input of the third dispenser reservoir.