RU79014U1 - EJECTOR NODE FOR IRRIGATION SYSTEMS - Google Patents

Abstract

The utility model relates to agriculture for the mechanization of irrigation and the introduction of fertilizer solutions with irrigation water, as well as macro - and micronutrients, herbicides, pesticides and other chemicals. A device for irrigation, contains an ejector, inlet and outlet connecting tubes. One end of the inlet connecting tube is connected to the direct passage pipe, and the second end to the ejector inlet, one end of the outlet connecting pipe is connected to the ejector outlet, and the second end to the direct passage pipe, the ejector being equipped with a suction hose in which a non-return valve and a strainer are integrated and on the pipe of direct passage between the inlet and outlet connecting tubes installed control valve.

Description

The utility model relates to agriculture for the mechanization of irrigation and the application of fertilizer solutions with irrigation water, as well as macro- and microelements, herbicides, pesticides and other chemicals.

A known installation for the preparation and application of fertilizer solutions with irrigation water in drip irrigation systems [Patent RU2219698], consisting of a mixer with a device for moving the source components, which is connected to a water supply pipe connected to a water source, storage tanks, suction line, discharge pipe , branch pipes and return pipelines, hydrocyclones, a line for removing precipitation, transport pipeline. Dosing devices connected to the irrigation network are mounted on the transport pipeline.

The disadvantages of this installation is the difficulty of integrating it into the irrigation system, as well as its use only in drip irrigation systems.

The closest in technical essence to the proposed utility model is a device for irrigation [Patent RU2015661], consisting of a distribution and irrigation pipe, storage tank, siphon and siphon trigger mechanism, and the siphon trigger mechanism is made in the form of interconnected liquid level sensor tubes, ejectors and a manifold with inlet and outlet nozzles (inlet and outlet connecting tubes).

The disadvantages of this installation are the complexity of the design and the lack of purification of fertilizer solutions.

The technical result of the proposed utility model is

reducing the complexity of embedding the ejector unit in the irrigation system, as well as cleaning fertilizer solutions.

This technical result is provided by the ejector unit (device for irrigation) containing the ejector, the input and output connecting tubes. One end of the inlet connecting tube is connected to the direct passage pipe, and the second end to the ejector inlet, one end of the outlet connecting tube is connected to the ejector exit, and the other end to the direct passage pipe. The ejector is equipped with a suction hose in which a check valve and a strainer are integrated. On the pipe of direct passage between the inlet and outlet connecting tubes installed control valve.

Figure 1 shows the ejector unit integrated in the direct-acting irrigation system, where the ejector unit 1 consists of an ejector 2 and an input and output connecting tubes 3, 4. One end of the input connecting tube 3 is connected to the straight pipe 5, and the second end with the inlet of the ejector 2. One end of the output connecting tube 4 is connected to the outlet of the ejector 2, and the other end with the straight pipe 5. The ejector 2 is equipped with a suction hose 6 with an integrated non-return valve 7. The intake hose 6 is equipped with a strainer 8. On the straight pipe 5 me dy inlet and outlet connecting tubes 3, 4 is installed an adjusting valve 9. The end of the intake hose 6 is lowered into a container with fertilizing solution 10. The ends of the pipes 5 equipped with a direct passage of couplings 11 for insertion of the ejector unit 1 into the pipeline 12 downstream of the water pump 13.

Figure 2 shows the ejector unit integrated in the drip irrigation system, where the ejector unit 1 consists of an ejector 2 and an input and output connecting pipes 3, 4. One end of the input connecting pipe 3 is connected to a straight pipe 5, and the second end to the input of the ejector 2. One end of the output connecting tube 4 is connected to the output of the ejector 2, and the second end to the pipe of direct passage 5.

The ejector 2 is equipped with a suction hose 6 with a built-in non-return valve 7. The intake hose 6 is equipped with a strainer 8. An adjustment valve 9 is installed on the straight passage pipe 5 between the inlet and outlet connecting pipes 3, 4. The end of the suction hose 6 is lowered into the container with fertilizer solution 10 The ends of the straight passage pipe 5 are equipped with couplings 11 for embedding the ejector unit 1 in the main pipe 12 between the water pump 13 and the drip irrigation tape 14. In the main pipe 12 between the ejector unit 1 and the flax 14 second drip irrigation main filter 15 is mounted a working mixture.

Figure 3 shows the ejector unit integrated in the spray irrigation system, where the ejector unit 1 consists of an ejector 2 and an input and output connecting pipes 3, 4. One end of the input connecting pipe 3 is connected to the straight pipe 5, and the second end to the inlet of the ejector 2. One end of the output connecting tube 4 is connected to the outlet of the ejector 2, and the other end to the straight pipe 5. The ejector 2 is equipped with a suction hose 6 with an integrated non-return valve 7. The intake hose 6 is equipped with a strainer 8. On the straight pipe 5 me waiting for the inlet and outlet connecting pipes 3, 4, an adjustment valve 9. An end of the intake hose 6 is lowered into the container with fertilizer solution 10. The ends of the straight passage pipe 5 are equipped with connectors 11 for embedding the ejector unit 1 in the main pipe 12 between the water pump 13 and the system spray irrigation 14. In the main pipe 12 between the ejector unit 1 and the spray irrigation system 14 is mounted a main filter 15 of the working mixture.

Consider the examples of the operation of the ejector unit as part of a system for direct irrigation, as part of a system for drip irrigation and as part of a spray irrigation system.

For the operation of the ejector unit as part of a direct irrigation system

using the couplings 11, the ejector unit 1 is mounted in the main pipe 12 after the water pump 13. The end of the intake hose 6 is lowered into the container with the fertilizer solution 10. In order to direct the water flow through the ejector unit 1, it is necessary to partially or completely shut off the control valve 9 to direct passage pipe 5. In this case, the water pressure in the inlet connecting pipe 3 and the water flow rate in the ejector 2 increase, which leads to the formation of vacuum in it, through which through the intake hose 6, the main Equipped with a mesh filter 8, the fertilizer solution is sucked from the fertilizer tank 10. The mesh filter 8 prevents the insoluble particles of the fertilizer solution from entering the ejector 2. In the outlet connecting pipe 4 at the outlet of the ejector 2, the fertilizer solution is uniformly mixed with water, resulting in a working mixture.

For the operation of the ejector unit as part of the drip irrigation system, the ejector unit 1 is mounted in the main pipe 12 between the water pump 13 and the drip irrigation tape 14 using the couplings 11. The end of the intake hose 6 is lowered into the container with the fertilizer solution 10. In order to direct the water flow through the ejector unit 1, it is necessary to partially or completely shut off the control valve 9 on the straight passage pipe 5. This increases the water pressure in the inlet connecting pipe 3 and the flow rate of water into the ejection ore 2, which leads to the formation of a vacuum in it, through which through the intake hose 6, equipped with a strainer 8 is the suction of the fertilizer solution from the tank with fertilizers 10. The strainer 8 thus prevents the insoluble particles of the fertilizer solution into the ejector 2. In the output connecting the tube 4 at the outlet of the ejector 2 due to the turbulent movement of water there is a uniform mixing of the fertilizer solution with water, resulting in the formation of a working mixture, which enters

main filter 15 for cleaning and preventing clogging of drip holes (not shown in Fig.) drip irrigation tape 14.

For the operation of the ejector unit as part of a spray irrigation system, the ejector unit 1 is mounted in the main pipe 12 between the water pump 13 and the spray irrigation system 14 using the couplings 11. The end of the intake hose 6 is lowered into a container with a fertilizer solution 10. In order to direct the water flow through the ejector unit 1, it is necessary to partially or completely shut off the control valve 9 on the straight passage pipe 5. In this case, the water pressure in the inlet connecting pipe 3 and the flow rate in ode in the ejector 2, which leads to the formation of vacuum in it, through which through the intake hose 6, equipped with a strainer 8, the fertilizer solution is sucked from the fertilizer tank 10. The strainer 8 thus prevents the insoluble particles of the fertilizer solution from entering the ejector 2. B the outlet connecting tube 4 at the outlet of the ejector 2 due to the turbulent movement of water, the fertilizer solution is uniformly mixed with water, as a result of which a working mixture is formed, which enters agistralny filter 15 for cleaning and prevention of clogging of spray irrigation system 14.

When the use of the ejector 2 is not required, the control valve 9 is in the open position and normal watering without fertilizer is carried out. In this case, the water flow is distributed through the main pipe 12 through the direct passage pipe 5 and through the inlet and outlet connecting pipes 3, 4. In order to avoid water losses through the intake hose 6, a check valve 7 is installed on it.

Thus, the design of the ejector unit allows you to integrate it into various irrigation systems without any design changes in the irrigation systems themselves, which reduces the complexity

embedding an ejector unit in irrigation systems. In addition, a mesh filter integrated in the ejector unit allows the cleaning of fertilizer solutions from undissolved particles, which increases the life of the ejector and reduces the risk of clogging of irrigation systems.

Claims (1)

An irrigation device comprising an ejector, an input and an output connecting tube, characterized in that one end of the input connecting pipe is connected to a direct passage pipe, and the second end is connected to the ejector inlet, one end of the output connecting pipe is connected to the ejector outlet, and the second end with a direct passage pipe, the ejector being equipped with an intake hose into which a check valve and a strainer are integrated, and an adjustment valve is installed on the direct passage pipe between the inlet and outlet connecting pipes.