RU2581184C1 - Plant for hydraulic research - Google Patents

Abstract

FIELD: hydraulics.

SUBSTANCE: invention relates to hydraulics and test equipment and can be used to determine hydraulic characteristics of different devices: intrasoil sprinklers, drippers, narrowing devices, washers, nozzles, throttles, nozzles, etc. Invention can be used for laboratory work. Invention aims to improve efficiency and accuracy of measurements and allowing study of hydraulic characteristics and resistance of different devices at high pressure. Set task is achieved by pressure water tank previously filled with water and has a measuring scale. Measuring scale is used to determine volume of water in pressure water tank, for which it is calibrated. To generate hydraulic pressure, unit is equipped with tyres with a metal disc inside. For this tyre with a metal plate is filled with electric pump air to required pressure. Pressure in pressure water tank creates air from vehicle tyres, which is connected to water pressure tank by means of air pressure hose. Pressurised water tank for ease of investigation is set on a tripod, and an air pressure hose has an air valve, which regulates air flow. Analysed element is connected to pressure water tank by water pressure hose. For measurement of water pressure, plant is equipped with a pressure gauge with water valves.

EFFECT: plant for hydraulic research enables to create pressure in system of up to 8÷9 atm or higher and is completely safe in operation.

4 cl, 1 dwg

Description

The invention relates to the field of hydraulics and instrumentation and can be used to determine the hydraulic characteristics of various devices: subsoil sprinklers, droppers, narrowing devices, washers, nozzles, throttles, nozzles, etc. The invention can also be used for laboratory work.

A known installation for bench studies of the flow characteristics of hydraulic resistances [1], including a flow tank with a pressure meter installed on it, a level gauge and valve, and a drain tank with a pressure meter installed on it. The tanks are interconnected by four lines: working, overflow, as well as gas supply and discharge lines. The working line includes a series-installed valve, a primary heat exchanger, a filter, a flow meter, a secondary heat exchanger, as well as a test element, at the input of which pressure and temperature meters are installed, and at the output, a temperature meter. A differential pressure sensor is also installed on the test element. The overflow line includes a valve. The gas supply line to the tanks includes an electromagnetic valve and a valve. The gas discharge line includes an electromagnetic valve and a valve. The supply and drain tanks are equipped with thermostatic shirts.

The disadvantage of the installation is the complexity of the design solution; the inability to create high pressures on it.

The closest technical solution is the installation for the study of hydraulic resistance [2]. The installation comprises a fixed Mariotte vessel with a drain channel connected to a horizontally arranged pipeline made with bending at an acute angle and containing a throttle washer installed after the turning section. A valve is installed at the end of the pipeline by means of a threaded connection. Also, four piezometers located at a distance of one meter from each other are tightly fixed on the pipeline.

The disadvantage of the installation is the impossibility of creating high pressures on it for carrying out hydraulic studies.

The aim of the invention is to increase the efficiency and accuracy of measurement and providing the opportunity to study the hydraulic characteristics and resistances of various devices at high pressures.

This goal is achieved in that a tire is connected to the pressure water tank through a pressure air hose with an air valve. The tank is pre-filled with water and has a measuring scale (Fig. 1). On a measuring scale, you can determine the volume of water in the pressure water tank, for this it is calibrated. Knowing the volumes of leaked water and time, you can determine the costs.

where Q is the flow rate of water flowing from the pressure water tank; ΔV is the volume of water flowing out of the pressure tank during time T.

To create pressure, the hydraulic unit is equipped with a tire with a metal disc inside. For this, a tire with a metal disk is filled with air by an electric pump to the required pressure. The pressure in the pressure water tank creates air from the tire, which is connected to the water pressure tank with an air pressure hose. The total pressure on the test element will be equal to

P ₂ = P ₁ + ρgh,

where P ₂ , P ₁ - respectively, the pressure on the test element and the free surface of the water in the pressure water tank; h is the height of the water column; ρ is the density of water; g is the acceleration of gravity.

For the convenience of research, the pressure water tank is mounted on a tripod, and the air pressure hose has an air valve that regulates the air supply.

A pressure water hose with a water valve is connected to the bottom of the pressure water tank. The test element is connected to the pressure water tank using a water pressure hose. To measure the water pressure, the installation is equipped with a pressure gauge with water valves. Water from the test element is discharged or fed to the plant for irrigation. The element under study is an intra-soil irrigator, which may already be known or just developed. The dropper may also be the test item.

In FIG. 1 shows a diagram of an installation for hydraulic research.

The installation for hydraulic research contains a plant 1, which receives water from the test element 2. The test element 2 is connected to the pressure water tank 3 using a water pressure hose 4. The pressure in the installation is created by a tire 5 with a metal disk 6 connected to the water pressure tank 3 s using an air pressure hose 7. To measure the water pressure, the installation is equipped with a manometer 8 with water valves 9. The pressure water tank 3 is mounted on a tripod 10, and the air pressure hose has an air valve 11. Pressure water tank 3 is equipped with a graduated scale 12.

Installation for hydraulic research works as follows. The pressure water tank 3 is pre-filled with water, and the tire 5 with a metal disk 6 is filled with air by an electric pump to the required pressure (Fig. 1). The pressure in the pressure water tank 3 creates air from the tire 5, which is connected to the water pressure tank 3 using an air pressure hose 7.

The pressure water tank 3 for convenience of research is mounted on a tripod 10, and the air pressure hose has an air valve 11, which controls the air supply. Pressure water tank 3 is equipped with a graduated scale 12.

The test element 2 is connected to the pressure water tank 3 using a water pressure hose 4. To measure the water pressure, the unit is equipped with a pressure gauge 8 with water valves 9. Water from the test element 2 is discharged or fed to plant 1 for irrigation.

Installation for hydraulic research allows you to create a pressure in the system up to 8 ÷ 9 or more atmospheres and is completely safe to use.

Information sources

1. Patent of the Russian Federation No. 2164667, IPC G01F 25/00. Installation for bench research of flow characteristics of hydraulic resistance / Vezhnovets P.D., Maklakov N.N., Zverev V.M., Golikov A.N., Popov A.V. Claim 06/17/1999; publ. 03/27/2001, Bull. No. 6 (Analog).

2. Patent of the Russian Federation No. 102397, IPC G01D 11/00. Installation for the study of hydraulic resistance / Solodovnikov A.V., Pavlik V.A., Shamanov V.D., Belyaev Yu.G., Migachev A.S. Claim 10/27/2010; publ. 02/27/2011 (Prototype).

Claims (4)

1. Installation for hydraulic research, containing a pressure water tank, characterized in that on top of the pressure water tank through a pressure air hose with an air valve a tire filled with air is connected with an internal metal disk, and a pressure water hose is connected to the bottom of the pressure water tank with a water valve equipped with a pressure gauge and to the end of which a test element is connected. 2. Installation for hydraulic research according to claim 1, characterized in that the element under study is an intra-soil irrigator. 3. Installation for hydraulic research according to claim 1, characterized in that the test element is a dropper. 4. Installation for hydraulic research according to claim 1, characterized in that there is a measuring scale on the pressure water barrel, and the tank itself is calibrated.

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