RU1814857C - Water outlet - Google Patents

Abstract

The invention relates to hydraulic engineering and can be used on racks of closed irrigation networks, as a water-saving structure as a water outlet for supplying water to an irrigation pipe-branch in time. The aim of the invention is to improve operational performance by expanding the range and process of overshooting the flow rate of water from closed pipelines to the outlet and its stability over time at different rates of water consumption. A water outlet installed on a stand of a closed pipeline consists of a body with an inlet and a drain pipe, a diaphragm-membrane, a disk, a power chamber, a shut-off element with a pressure disk, a drain pipe, a float chamber with a float and a needle valve, and a valve consisting of a body with inlet and outlet nozzles, body covers with a hole, valves with axial and N-radial holes, and turnkey flush joints. In the drain pipe connecting the power chamber with the water outlet housing - the low-pressure region, a chamber is placed in series, a float is placed in it with a needle valve for regulating the flow cross section of the drain tube and a valve for regulating the flow of water outflow from the float chamber, consisting of a housing with an inlet and outlet nozzles, body covers, valves with an axial and N-radial orifice for varying the flow rate of the outflow in time, hence for supplying various water flow rates to the tap in time. The diameter of the radial holes in the valve is assigned within the indicative limits. 3 ill. ate C 00 a-b

Description

The invention relates to the field of hydraulic engineering and can be used on racks of closed irrigation networks-pipelines, as a water-saving design as a water outlet for supplying water to an irrigation pipe-branch in time.

The aim of the invention is to improve performance, i.e. expanding the range and the process of overshooting the water flow rate into the outlet and its stability over time at different rates

water consumption regardless of pressure changes in closed pipelines.

In Fig.1 shows a water outlet in the context; figure 2 - valve, section; in Fig.Z - section aa in Fig.2.

The water outlet installed on the outlet 1 of the closed pressure pipe consists of a body 2 with VLIBE 3 and a drain 4 pipe, a diaphragm-membrane 5, a disk 6, a power chamber 7, a cover 8 of the chamber 7, a shut-off valve. 9 with a pressure disk 10, a pipe 11, tightening screw 12 with through calibrated hole 13 for prop

ska of water from under the shutoff valve 9 and into the power chamber 7, i.e. from the high-pressure zone to the supra-membrane chamber, the drain tube 14, the float chamber 15, the float 16 with a needle valve 17, for adjusting the flow area of the drain tube 14 and the valve, which consists of a housing 18 with an inlet 19 and an outlet 20 nozzles, a cover 21 of the housing 18 with a hole 22, a valve 23 with an axial 24 and with a M-radial 25 hole and turnkey flange 26, the hole 24 having an axial arrangement with the outlet pipe 20 of the valve body 18, and in the operating position, i.e. when the valve 23 is installed in the open position, one of the radial holes 25 is aligned with the inlet pipe 19 of the valve body 18, therefore, the working radial hole 25 is aligned with the inlet portion of the drain pipe 14.

The outlet works as follows.

In the absence of water in the closed pressure pipe, the shut-off valve 9 is under its own weight and the weight of the moving parts in operation, i.e. the shut-off valve 8, the pressure disk 10, the tube 11, the disk 6 and the tightening screws 12, are in the lower position and rests over the outlet section of the infusion pipe 3 and overlaps the latter. In this case, the float 16 with a needle valve 17 is in the lower position and abuts against the protrusions of the tube 14 connecting the float chamber 15 with the valve body. At the same time, the inlet section of the drain pipe 14 into the float chamber. -Ru 14 is open. Assume that valve 23 is in the closed position, i.e. the valve 23 is installed in such a position that, through the areas located between the radial holes 25, the passage section of the drain pipe 14 is blocked and there is no outflow of water from the power chamber 7 and the float 15.

When water is supplied to the closed pipeline and its level is increased, the outlet section of the water inlet nozzle 3, part of the water, passes through the calibrated hole 13 of the tightening screws 12 of the tube 11, enters the power chamber 7 and fills the latter.

In this case, water through the drain pipe 14 enters the float chamber 15 and lifts the float 16c with a needle valve 17, which simultaneously serves as a guide to the process. A further influx of water into the chamber 15 causes the buoyant pressure force on the float 16 to increase and the latter, by means of a valve 17, closes the flow area of the drain tube 14 and the inflow of water from the drain chamber 7 to the float chamber 15 by means of a drain tube 14

ceases.

As the static pressure increases in a closed pipeline, the water pressure in the power chamber 7 and transmitted to the diaphragm membrane 5 increases and is transmitted to the shut-off valve 9. Since the area of the diaphragm membrane 5, which acts as a power valve mechanism and accepts water pressure more than the area of the shutoff valve 9, then the last for

5 by counting the pressure difference generated therein, i.e. membrane 5 and valve 9, holds the outlet section of the infusion pipe 3 in the closed position. Therefore, the water supply to the outlet through the drain pipe 4

0 is missing.

The outlet cross-section of the infusion pipe 3 will be closed by means of a shut-off valve 9 until the valve 23 with axial 24 and N-radial 25 holes

5 is set to a different position, i.e. into position openly. Therefore, in order to supply water to the outlet, it is necessary to set the valve 23 to the open position. For this, it is necessary, by means of a key, to turn the valve 23 so that one of the radial holes 25 is aligned with the passage section of the drain pipe 14. In this case, the outflow of water from the float chamber 15 begins

5 tube 14, radial 25 and axial 24 holes of the valve 23 in the housing 2 of the outlet. As a result of the outflow of water from the float chamber 15, the buoyancy force on the float 16 with a needle valve 17 is reduced.

0 and the latter assumes a position in which the balance of labor entering through the calibrated hole 13 into the power chamber 7 and the outflow of water from the latter through the drain pipe are maintained

5 and, regulated by a needle valve 17 onto the float 16. As a result of the constant outflow of water from the power chamber 7, the force of the water pressure in it decreases, therefore, the pressure on

0, the pressure disk 10 and the shut-off valve 9, the perceived pressure from the diaphragm-membrane 5 through the tubes 11, the shut-off valve 9 under the influence of water pressure from the side of the closed pipe with a stand 1 opens to allow the water flow to the outlet in time.

In order to file a different one, i.e. a greater or lesser flow rate of water to the drain in time, different from the original, valve 23 with axial 24 is necessary and

Turn the N-radial 25 holes, using the key, so that under the passage section the drain pipe 14 is aligned coaxially with it, the other radial hole 25 in the valve 23, i.e. radial hole 25 with another cross-sectional diameter. In this case, depending on the established diameter of the radial holes 25 relative to the initial one, the outflow of water from the float 15 and the power chamber 17 sequentially increases or decreases through a drain pipe 14, which is regulated by a valve 23 into the outlet body 2. As a result, the water pressure in the power chamber 7, therefore, on the diaphragm-membrane 5 ’as well as on the shut-off valve 9 transmitted through the tubes 11 is increased if a radial hole 5 of the valve 23 of a smaller diameter is installed coaxially with the passage section of the drain tube 1-4 vice versa. That is, it is reduced if a radial hole 25 of the large diameter valve 23 is installed coaxially with the passage of the drain pipe 14. Therefore, depending on the pressure change in the power chamber 7, the degree of opening of the outlet cross section and the supply of water to the outlet in time through the inlet pipe 3 of the outlet regulated by the shut-off valve 9 also change.

The use of the proposed, in closed irrigation pipelines as a water outlet to a branch allows: to supply a constant water flow rate and a branch in time, regardless of the static pressure fluctuations in closed pipelines; if necessary, it is easy to increase or decrease the throughput capacity of a water outlet in time, facilitate the labor of operators, and increase the reliability of water outlet devices.

Claims (1)

The claims A water outlet comprising a housing with inlet and outlet nozzles, a power chamber connected to the housing by means of an outlet nozzle, a diaphragm, a shut-off valve with a supply tube and a valve, so that, in order to improving operational performance by expanding the control range, a chamber with a float and a shut-off valve for adjusting the flow area of the outlet pipe, and a valve with a multi-way valve having an axial bore rum, equal to the diameter of the discharge tube and radial apertures for the outflow of water changes the flow of power and the float chamber, the diameters of which do not exceed the diameter of the drain pipe. FIG. tpif & 2  Aa