RU2308182C1 - Apparatus for application of chemical means with irrigation water in discrete irrigation systems - Google Patents

Abstract

FIELD: mechanization of agriculture, in particular, multiple-purpose utilization of discrete irrigation systems for application into soil of chemical solutions with irrigation water.

SUBSTANCE: apparatus has open reservoir for chemical solution, said reservoir being positioned at the level of irrigation water accumulator and equipped with closed measuring and auxiliary vessels positioned slightly lower than reservoir and slightly higher than the level at which irrigation pipelines are joined to receiver-collector. Measuring vessel is communicated through hydraulic channels to reservoir for chemical solution, to upper part of receiver-collector and through auxiliary vessel to lower part of receiver-collector. Lower part of auxiliary vessel cavity is connected to receiver-collector, and upper part to upper part of measuring vessel cavity through J-shaped communication channel, whose knee portion is arranged higher than maximum level of chemical solution in said reservoir. Lower part of measuring vessel cavity is connected with upper part of receiver-collector through J-shaped communication channel, whose knee portion is positioned higher than maximum level of chemical solution in reservoir. There is calibrated opening in upper branch of communication channel, at the side of receiver-collector, said opening being arranged lower than the level of knee portion. Upper part of measuring vessel cavity is communicated through J-shaped communication channel with lower part of reservoir for chemical solution. End of communication channel is positioned within measuring vessel for axial displacement. Length of short run of J-shaped communication channel is greater than length of longer run of J-shaped communication channel. Volume of auxiliary vessel is smaller than volume of measuring vessel, but said volume is much greater than total volume of hydraulic communication channels.

EFFECT: increased efficiency in utilizing of chemicals due to dosed feeding thereof with irrigation water for each accumulation-irrigation cycle of discrete irrigation system, and provision for alternating usage of various kinds of soluble chemicals for short time interval by volumetric regulation of doses.

6 cl, 3 dwg

Description

The invention relates to the field of mechanization of agriculture, in particular to the multi-purpose use of discrete irrigation irrigation systems for introducing solutions of chemicals to the soil with irrigation water.

A device for irrigation is known, containing a supply tube with a tap, a storage tank connected to irrigation pipelines through a siphon and equipped with a mixer in communication with a storage tank through a siphon tube, one end of which is located at the bottom of the mixer, and the other end is directed up and placed in the storage containers below the upper level of the liquid level sensor tube [1].

The disadvantage of this device for irrigation and the application of soluble mineral fertilizers with irrigation water is a continuous decrease in the concentration of the solution from cycle to cycle without changing its volume, which requires a long operating time of the device for the complete removal of the solution from the mixer and supply to the irrigated area. A long period of removal also complicates the use of various soluble fertilizers in the phase of active development of plants, when in a short period of time it is required to introduce several types of fertilizer alternately into the soil.

The closest technical solution (prototype) is a device for introducing chemicals with irrigation water on discrete irrigation systems, containing a storage of irrigation water, a container for solutions of chemicals for mixing (mixer), a connecting hose and pipelines, while the container for chemicals is made in the form of a closed volume with a measuring cylinder located in its upper part, is located below the irrigation water accumulator in which the siphon is located, and is connected to the accumulator in the area of the siphon suction nozzle [2].

The disadvantages of this device for introducing chemicals with irrigation water are the long period of removal of the solutions of chemicals from the mixer due to the continuous decrease in the concentration of the solution from cycle to cycle without changing its volume, the impossibility of applying different types of soluble fertilizers at the request of a plant from - due to the continuous decrease in the concentration of the solution from cycle to cycle and low quality distribution of fertilizers when serving large areas. When servicing large areas to improve the quality of distribution of irrigation water in the area, the served area is divided into sections and irrigated in sections cyclically. A uniform distribution of chemicals on these systems according to the principle of operation of the prototype is impossible due to the constant decrease in the concentration of the solution of chemicals. This device delivers solutions to irrigation water during the entire time of the irrigation phase, which reduces the uniformity of its distribution over the irrigated area due to an unsteady irrigation regime at the beginning and end of the irrigation phase.

The aim of the invention is to increase the efficiency of the use of chemical means by dosing them with irrigation water for each cycle of accumulation-irrigation of a discrete irrigation system, as well as providing the possibility of using different types of soluble chemical means in a short period of time alternately by volume control of doses.

- образный канал связи, поворотное колено которой расположено выше максимального уровня раствора в емкости для средств химизации, нижняя часть полости мерной емкости соединена с верхней частью приемника-коллектора через

- образный канал связи, поворотное колено которой расположено выше максимального уровня раствора в емкости для средств химизации, а на ветви канала связи со стороны приемника-коллектора выполнено калиброванное отверстие ниже уровня колена, верхняя часть полости мерной емкости через

- образный канал связи сообщена с нижней частью емкости для растворов средств химизации, причем конец канала связи расположен в мерной емкости с возможностью осевого перемещения, длина короткой ветви

- образного канала связи выполнено большим, чем длина длинной ветви

- образного канала связи и с целью исключения возможности утечки сжатого воздуха из мерной емкости во время вытеснения раствора средств химизации из нее в приемник-коллектор и увеличения точности дозируемой подачи раствора объем вспомогательной емкостей выполнен меньшим объема мерной емкости, но многократно превышающим суммарный объем гидравлических каналов связи.This goal is achieved by the fact that the tank for the solution of chemicals for chemicalization is made open, installed at the level of the irrigation water storage tank, equipped with a closed measuring and auxiliary tanks, installed respectively slightly below the level of the tank for solutions of chemicals and slightly higher than the level of connection of irrigation pipelines to the receiver-collector, while the measured capacity of the hydraulic communication channels is communicated with the capacity of the means of chemicalization of the upper part of the receiver-collector and through the auxiliary tank with lower part of the receiver-collector, the lower part of the cavity of the auxiliary capacity is connected to the receiver-collector, and the upper part is connected to the upper part of the cavity of the measured capacity through

- a shaped communication channel, the swivel of which is located above the maximum level of the solution in the tank for chemicals, the lower part of the cavity of the measuring tank is connected to the upper part of the receiver-collector through

- a shaped communication channel, the rotary elbow of which is located above the maximum level of the solution in the tank for chemicals, and on the branch of the communication channel from the side of the receiver-collector, a calibrated hole is made below the level of the knee, the upper part of the cavity of the measuring tank through

- a shaped communication channel is in communication with the lower part of the tank for solutions of chemicals, and the end of the communication channel is located in a measuring tank with the possibility of axial movement, the length of the short branch

- shaped communication channel is made larger than the length of a long branch

- a shaped communication channel and in order to exclude the possibility of compressed air leakage from the measuring tank during the displacement of the solution of chemical means from it into the collector receiver and to increase the accuracy of the dosed solution supply, the volume of auxiliary tanks is smaller than the volume of the measured tank, but many times exceeding the total volume of hydraulic communication channels .

The invention is shown in the drawings, where

figure 1 - schematic hydraulic diagram indicating the lower (NU) and upper (VU) levels in the tank for irrigation water and the upper (U1) and lower (U2) levels in the measuring tank;

figure 2 - schematic hydraulic diagram of the device in the phase of the "pause" (the accumulation of irrigation water in the storage tank);

figure 3 - schematic hydraulic diagram of the device in the phase of "irrigation" (emptying the storage tank for irrigation water).

A device for introducing chemicals with irrigation water contains a drive 1 of irrigation water with a siphon 2 operating in automatic mode, a supply pipe 3 with a tap 4, a collector 5, irrigation pipes 6 with outlets 7, hydraulic communication channels 8, 9, 10 and 11 with a calibrated hole 12 and a tank for chemical means 13. Moreover, the tank 13 is equipped with a measured 14 and auxiliary 15 closed containers installed respectively slightly below the level of the tank 13 and slightly above the level of connection of the irrigation pipes 6 to the receiver-call Whoru 5. The upper part of the cavity of the measuring tank 14 is communicated through the communication channel 10 with the capacity 13 and through the communication channel 9 with the upper part of the cavity of the auxiliary tank 15 and then through the communication channel 8 with the lower part of the receiver-collector 5, and the lower part of its cavity is communicated by the channel connection 11 with the upper part of the receiver-collector 5.

For normal operation of the device for introducing chemicals with irrigation water, it is necessary to fill the tank 13 with a solution of chemicals for water, supply water to the reservoir 1 with a certain flow rate using a tap 4 and observe the following conditions:

where W ₁₃ is the geometric volume of the tank for chemical means 13;

W ₁₄ is the geometric volume of the measuring tank 14;

W ₁₅ is the geometric volume of the auxiliary tank 15;

∑W _9.10.11 - the total volume of communication channel 9, a short branch of a communication channel 10 and a long branch of a communication channel 11;

N is the distance from the bottom of the auxiliary tank 15 to the level of irrigation water in the receiver-collector 5 when emptying the irrigation water storage device 1 (“irrigation” phase);

H ₁ - the distance from the lower level (U2) in the measuring tank 14 to the upper level of the knee of the communication channel 11;

H ₂ is the distance from the lower level of the knee of the communication channel 10 to the end of its smaller branch.

A device is operating for introducing chemicals with irrigation water in a cyclic mode, alternating with each other by the phases of "accumulation" and "irrigation", as follows.

Irrigation water from the water source through the supply tube 3 and the tap 4 with a small flow rate enters the reservoir 1 and slowly accumulates in it (the beginning of the cycle, the phase of "accumulation"). When the water level in it reaches the upper level (WU), siphon 2 automatically starts up and starts to discharge the accumulated volume of water from the accumulator 1 into the collector 5 and then through the irrigation pipes 6 with outlets 7 to the irrigated area to the root zones plant systems (“watering” phase). When the water level in accumulator 1 reaches the lower level (NU), siphon 2 automatically stops working (end of the “watering” phase, end of the “accumulation – watering” cycle) and a new accumulation of irrigation water in accumulator 1 begins (new “accumulation – watering” cycle) )

Thus, irrigation occurs in a cyclic mode with long pauses (period of accumulation of water in accumulator 1) and short-term irrigation (period of discharge of the accumulated volume from accumulator 1).

Solutions of chemicalization chemicals are supplied to irrigation water from a tank of 13 doses in cycles with the phases "preparation" and "supply" of doses as follows.

In the “accumulation” phase, the solution from the tank 13, regardless of its quantity in it, by gravity for a short period of time compared to the length of the time of the “accumulation” phase, passes through the communication channel 10 to the measured tank 14 and, filling it, also fills the cavity of the ends of the channels communication 11 and 9 from the measuring tank to the level of the solution in the tank 13, since the other ends of these channels are freely connected to the atmosphere through the receiver-collector 5 (phase "preparation" of the dose of the solution). At the beginning of the “watering” phase, at the point of connection of the auxiliary tank 15 to the receiver-collector 5, a piezometric pressure is formed along the rise and reaches a maximum value of H when a steady-state watering regime is established on the system. Due to condition (3), air from the auxiliary tank 15 under pressure of increasing piezometric pressure until a steady-state irrigation regime is established on the system is displaced through the communication channel 9 into the measured tank 14. At the same time, under the pressure of compressed air, the volume of the solution above the level (U1) through the channel connection 10 is pushed back into the tank 13, since the elbow of the communication channel 11 with the calibrated hole 12 is located above the level of the solution in the tank 13. After the steady-state irrigation regime has been established on the system, the volume of solution yaschiysya lower level (U1) in a measuring vessel 14 under the action of compressed air slowly through the communication passage 11 is forced into the upper cavity of the collector receiver 5 to a level (V2) as H ₁ <H ₂ (phase "feed" dose solution for irrigation water). After displacing the volume of the solution between the levels U1 and U2 (dose of the solution), compressed air with pressure H ₁ remains in the measuring container and remains until the end of the “watering” phase (condition (2)). After the completion of the “watering” phase, the piezometric pressure in the receiver-collector 5 disappears. Under the action of compressed air in the tank 14, water from the auxiliary tank 15 is forced into the cavity of the collector 5 and then through the irrigation pipes 6 and outlets 7 to the irrigated area. Measured tank 14 communicates with the atmosphere through communication channel 9, auxiliary tank 15, communication channel 8 and receiver-collector 5. The pressure in the measured tank 14 and in communication channels 10 and 11 drops to atmospheric pressure. The solution from the tank 13 by gravity begins to flow into the measuring tank 14 and the cavity of the ends of the communication channels 9, 11, connected with the measuring tank 14, to the level of the solution in the tank 13 (the beginning of the preparation of the next dose of the solution for supply to irrigation water in the next cycle “accumulation - irrigation "). Further, the preparation of doses of the solution and its supply to irrigation water continues in a cyclic mode synchronously with the phases of "accumulation" and "irrigation".

The duration of the phases of “preparation and feeding” of the solution is much shorter, respectively, the duration of the phases of “accumulation and“ irrigation ”, which excludes the influence of transients of the phase“ irrigation ”on the uniform distribution of the solution over the irrigated area.

The dose of the solution supplied for the “accumulation of watering” cycle is adjusted by changing the position of the end of the communication channel 10 in the measuring tank 14 by moving it up and down on the axis.

обеспечивает равномерное распределение растворов средств химизации по орошаемому участку, при случае, когда участок полива разбит на отдельные секции, и полив осуществляется посекционно последовательно. Условие позволяет произвести полив с раствором всех секций многократно, что практически выравнивает их количество поливов и повышает коэффициент равномерного распределения раствора по всей площади полива.Condition

provides uniform distribution of solutions of chemicals for the irrigated area, in the case when the irrigation section is divided into separate sections, and the irrigation is carried out section by section. The condition allows watering with a solution of all sections repeatedly, which practically equalizes their number of irrigations and increases the coefficient of uniform distribution of the solution over the entire irrigation area.

Thus, by supplying the tank 13 for chemical measuring means 14 and auxiliary 15 with closed tanks installed respectively below the tank 13 and above the level of connection of the irrigation pipelines to the collector 5, performing a special mutual arrangement and interconnection of the hydraulic communication channels 9, 10, 11 and cavities receiver-collector 5, measured 14 and auxiliary 15 containers and containers 13, high reliability of dispensing the solution supply to irrigation water is achieved for each accumulation-irrigation cycle, regardless of the level of solution in a container 13 for solutions of chemicals. The process of dispensing the solution and its supply to the irrigation water is carried out using a mechanism that does not contain moving parts, which greatly increases the reliability of the device for introducing chemicals with irrigation water in general.

An experimental model of a device for introducing chemicals with irrigation water was made in the production conditions of the workshops of the Federal State Research Institute of Raduga and tests were carried out in laboratory conditions.

The test results are positive. The deviation of the dose of the solution per cycle from its average value, with multiple cycles of "accumulation-watering" and, as a result, changes in the level of the solution in the tank 13 from maximum to minimum, did not exceed ± 3%.

The application of the invention in the national economy will significantly increase both the reliability of the device for making chemicals with irrigation water, and the effectiveness of the use of chemicals with irrigation water for growing crops.

Information sources

1. RF patent No. 2015661, cl. A01G 25/02, A01M 7/00, bull. No. 13, 1994, paragraph 4 of the claims, figure 2 and 3.

2. RF patent No. 2181935, cl. A01C 21/00, 23/00, 23/04, bull. No. 13, 2002, paragraph 2 of the claims - Device for introducing chemicals with irrigation water on discrete irrigation systems (prototype).

Claims (6)

1. A device for introducing chemicals with irrigation water on discrete irrigation systems, containing an irrigation water reservoir with an automatic siphon and a feed pipe with a tap, a collector receiver, irrigation pipes with water outlets, hydraulic communication channels and a container for solution solutions chemicalization, characterized in that the capacity for the solution of chemicals means is made open, installed at the level of the irrigation water storage, equipped with a closed measuring and auxiliary tanks, installed in accordance continuously below the tank solutions of chemicals and above the level of the irrigation piping connections to the receiver-collector, the capacitance measuring hydraulic communication channels communicated with the capacity of chemicals, the upper part of the collector and the receiver via the auxiliary tank to a lower portion of the collector receiver. 2. The device according to claim 1, characterized in that the lower part of the cavity of the auxiliary capacity is connected to the receiver-collector, and the upper part is connected to the upper part of the cavity of the measured capacity through

-shaped communication channel, the swivel of which is located above the maximum level of the solution in the tank for chemicals. 3. The device according to claim 1, characterized in that the lower part of the cavity of the measuring capacitance is connected to the upper part of the receiver-collector through

-shaped communication channel, the rotary knee of which is located above the maximum solution level in the tank for chemicals, and on the branch of the communication channel from the receiver-collector, a calibrated hole is made below the level of the knee. 4. The device according to claim 1, characterized in that the upper part of the cavity of the measured capacity through

-shaped communication channel is in communication with the lower part of the tank for solutions of chemical means, and the end of the communication channel is located in a measuring tank with the possibility of axial movement. 5. The device according to claim 1, characterized in that the length of the short branch

-shaped communication channel is made larger than the length of a long branch

-shaped communication channel. 6. The device according to claim 1, characterized in that the volume of auxiliary tanks is made smaller than the volume of the measured capacity, but many times greater than the total volume of the hydraulic communication channels.

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