RU81277U1 - HIGH PRESSURE CRANE - Google Patents

Abstract

The utility model relates to valve engineering, namely to stop valves, and can be used as a shut-off and adjusting body when testing various products for tightness by internal hydrostatic pressure.

The purpose of the utility model is to simplify the design and increase reliability.

The crane contains a housing with inlet and outlet fittings, a pressure supply channel, a plug for closing the latter, a pressure gauge and a drain valve in the form of an additional (drainage) channel communicating with the main channel and an additional (drainage) tube installed behind the main tube and overlapping the main and additional channels .

The technical result of the utility model, in comparison with the prototype, is to simplify the design by replacing the complex drain valve with a simple drain plug, as well as increase the reliability by duplicating the overlap of the main pressure supply channel with an additional (drain) plug.

Description

The utility model relates to valve engineering, namely to stop valves, and can be used as a shut-off and adjusting body when testing various products for tightness by internal hydrostatic pressure.

The purpose of the utility model is to simplify the design and increase reliability.

State of the art

Known shut-off valves, each of which contains a housing with inlet and outlet nozzles, various design sealing and locking elements and their drives. USSR patent No. 5990, Cl. 47g, 8, 1927, publ. 07/31/1928 [1], USSR Patent No. 40871, Cl. 47g, 22, 1931, publ. 12/31/1934 [2], A.S. USSR No. 78707, Cl. 47g ¹ , 1 ₀₂ , 1949, publ. 02/28/1950 [3], A.S. USSR No. 148685, Cl. 47g, 20 ₀₁ , 1960, publ. Bull. No. 13, 1962 [4], A.S. USSR No. 344201, M. cl. F16K 5/06, 1970, publ. Bull. No. 21, 1972 [5], A.S. USSR No. 380893, M. cl. F16K 5/04; 5/06, 1971, publ. Bull. No. 21, 1973 [6], A.S. USSR No. 391325, M. cl. F16K 5/06; 31/54, 1971, publ. Bull. No. 31, 1973 [7], A.S. USSR No. 609014, M.C. ² F16K 5/00, 1975, publ. Bull. No. 20, 1978 [8], A.S. USSR No. 739298, M. Cl. ² F16K 5/06, 1976, publ. Bull. No. 21, 1980 [9], A.S. USSR No. 830066, M.Kl. ³ F16K 5/06, 1978, publ. Bull. No. 18, 1981 [10], A.S. USSR No. 1479775, MKI ⁴ F16K 5/06, 1987, publ. Bull. No. 18, 1989 [11], A.S. USSR No. 1605068, MKI ⁵ F16K 5/06, 1988, publ. Bull. No. 41, 1990 [12], A.S. USSR No. 1629667, MKI ⁵ F16K 5/06, 1989, publ. Bull. No. 7,

1991 [13], A.S. USSR No. 1756712, MKI ⁵ F16K 5/06; 5/20, 1990, publ. Bull. No. 31, 1992 [14].

Overlapping or adjusting the flow of liquid or gas is carried out by moving the locking element by means of a drive.

A disadvantage of the known devices, when used in high pressure valves for hydrostatic testing, is the lack of a drainage system to relieve pressure and, as a result, the possibility of a water hammer on the pressure injection system.

Known check valves, each of which contains a housing, a locking member with a central shaft, sealing elements, a passage channel with inlet and outlet pipes, as well as a bypass channel with a bypass screw valve. USSR patent No. 3788, Cl. 47g, 8, 1926, publ. 10/31/1927 [15] and USSR Patent No. 12845, Cl. 47g, 8, 1928, publ. 01/31/1930 [16].

By moving the locking member in the housing along the central shaft, press it against one of the sealing elements, thereby blocking or opening the fluid flow.

The described non-return valves are intended for centrifugal pumps, are installed on the discharge pipe and are connected in one housing with bypass valves, which serve to fill the pump and the intake pipe.

The disadvantages of the known valves, when used in high pressure valves for hydrostatic testing, is the inability to relieve pressure into the atmosphere bypassing the discharge system (in this case, a centrifugal pump) and, as a result, the possibility

water hammer on the latter, as well as the complexity of their designs.

The crane closest in technical essence and achieved result was selected according to the USSR Author's Certificate No. 327354, M. cl. F16K 5/06, 1970, publ. Bull. No. 5, 1972 [17].

The crane selected as a prototype contains a housing, an inlet and outlet nozzles, a locking member (ball plug), sealing rings (seats) and, connected to the housing cavity, a drain valve in which the locking member interacts with two axially spaced apart guaranteed clearance, plungers (pistons), the sub-plunger space of each of which is connected by pipelines to the cavities of the inlet and outlet pipes. In addition, there are drainage holes in the drain valve body that communicate with the atmosphere or with the drain pipes.

Work with the crane - the prototype is as follows.

If there is pressure at the inlet to the tap (in the cavity of the inlet pipe), the working medium acts on one of the plungers (in this case, the lower one) and presses the shut-off element of the drain valve against the sealing ring of the central cavity of the crane through the second plunger (upper). The drainage system is closed.

When the medium is supplied from the opposite side of the valve (cavity of the outlet pipe), the pressure acts on both the upper and lower plungers. In this case, the upper plunger connected to the cavity of the outlet pipe acts on the shut-off element of the drain valve, and the lower plunger connected to the cavity of the inlet pipe is pressed down and out of mechanical contact with the said upper plunger.

When the medium is supplied from both sides in the cavity of the inlet and outlet nozzles or with the crane fully open, the lower plunger is balanced, and the upper one acts on the shut-off element of the drain valve and closes the drain channel.

Thus, at any supply of working fluid pressure to the tap, its cavity (shutter cavity) is closed by a shut-off element of the drain valve when it is exposed to only one plunger.

In the absence of pressure on both sides of the shut-off element (cavity of the inlet and outlet nozzles), the shut-off element of the drainage valve does not block the drainage channel and the working medium can freely leave the tap cavity (shutter cavity) into the atmosphere through the drainage openings of the said valve.

The disadvantages of the prototype crane are the complexity of the design, due to the presence of an extremely complex drain valve, consisting of a body, two movable plungers, a shut-off element and a piping system, in addition, the shut-off element of the drain valve is not used to block the main (working) channel of the tap (duplication of overlap), which reduces the reliability of the crane as a whole.

The purpose of the utility model is to simplify the design and increase reliability.

This goal is achieved by the fact that in the crane containing the housing with inlet and outlet fittings (nozzles), a pressure supply channel, a plug (shut-off member) of the latter, a pressure gauge and a drain valve, the latter is made in the form of an additional (drain) channel communicating with the main the (working) channel and the additional (drainage) tube installed behind the main tube and overlapping the main (working) and additional (drainage) channels.

Utility Model Disclosure

When conducting leak tests of various parts and assemblies (heat exchangers, pipelines, etc., hereinafter referred to as test samples), internal hydrostatic pressure requires:

- to assemble a hydraulic circuit, namely to connect in series a source of hydraulic pressure (in this case, a hydraulic pump), a high-pressure valve and a test sample, using pipelines with union nuts and nipples;

- pump the working fluid (antifreeze, water, oil, etc.) with a pressure of 0.29-0.39 MPa (3-4 kgf / cm ² ) into the internal cavity of the test sample until the air is completely displaced from the working volume (until cavitation disappears bubbles);

- at the indicated pressure, plug the outlet of the test sample;

- create a test pressure of 2.9-3.9 MPa (30-40 kgf / cm ² ) in the working volume of the test sample using a hydraulic pump, shut off the fluid flow, and maintain the sample under this pressure for a set time - 1.0-2.0 hours;

- visually control the absence of leaks or pressure drop in the closed working volume of the sample by the pressure gauge;

- relieve test pressure;

- re-inject the fluid and create a higher pressure relative to the test pressure of 5.85-6.8 MPa (60-70 kgf / cm ² ) that simulates an emergency situation of the sample and maintain it under this pressure for 20-30 minutes;

- also, visually monitor the absence of leaks or pressure drop by the manometer;

- relieve high blood pressure;

The test sample shall be considered to have passed the test if there was no moisture (leakage) on the surface of the sample or if there was no pressure drop on the pressure gauge.

However, the pressure source has inertia and it is not possible to accurately determine the required pressure, so the injection is carried out with some “margin”, and then the drain plug makes precise adjustment (± 5%) with the main plug closed, eliminating the water hammer on the discharge system (in this case, by hydraulic pump or by its shut-off valve). In addition, the discharge of test and high pressures through the plug of the test sample is inconvenient and not always possible due to design features and safety rules, and therefore pressure relief should also be carried out not through the main (working) pressure channel, but through an additional (drainage) channel channel (with bypassing the main one) into the atmosphere to prevent failure of the pressure source.

Thus, a high-pressure valve for testing various products for tightness with internal hydrostatic pressure must be able to connect to a pressure source and the test sample and shut off the pressure pumped into the sample for a set time, and also have an additional drainage channel with a drainage plug for precise adjustment and discharge pressure after testing. In addition, the design should be simple and technologically advanced to manufacture, as well as an additional drainage plug that should block, in addition to the drainage channel, the main (working) channel (overlapping overlap) to increase the reliability of the crane as a whole.

When implementing the utility model, a positive effect can be obtained consisting in simplifying the design by replacing the complex drain valve with a simple drain plug, and also in improving the reliability of the crane by duplicating the overlap of the main (working)

channel additional (drainage) plug installed behind the main plug and overlapping at the same time the main (working) and additional (drainage) channels.

Brief Description of the Drawings

The drawing shows a high pressure valve, a longitudinal section, dashed - dotted lines show the test sample, arrows indicate the movement of the working fluid.

The high pressure valve contains a housing 1, inlet and outlet fittings 2 and 3, a pressure supply channel 4, a plug 5 for closing the latter, a pressure gauge 6 and a drain valve in the form of an additional (drainage) channel 7 and an additional (drainage) plug 8 installed behind the main plug 5 and overlapping the primary and secondary channels 4 and 7;

Work with the crane as follows. To conduct the leak test of the test sample (not indicated in the drawing), the following is carried out using internal hydrostatic pressure:

- the hydraulic circuit is assembled, namely, a hydraulic pressure source (not shown) is connected in series to the inlet fitting 2 of the crane, and to the outlet fitting 3 — the test sample, using pipelines with union nuts and nipples (not shown in the drawing);

- open the main (working) channel 4 by partially moving the main and additional plugs 5 and 8, while excluding the release of working fluid into the atmosphere, and only the line “pressure source - main (working) channel - test sample” remains open;

- pump the working fluid with the usual main pressure into the internal cavity of the test

sample until air is completely displaced from the working volume;

- drown out the outlet of the test sample technological plug (not shown);

- create a test pressure with some “margin” in the tap and, accordingly, in the test sample using a pressure source;

- close the main stopper 5, and make precise pressure control with an additional stopper 8, control the pressure by the pressure gauge 6;

- close the additional plug 8;

- maintain the test sample under test pressure for a specified time;

- visually control the absence of leaks or pressure drop in the closed working volume of the test sample by pressure gauge 6;

- open the plug 8 and dump the test pressure into the atmosphere, while the main plug 5 remains closed;

- re-injection of the working fluid and create increased, relative to the test, pressure, simulating the emergency situation of the sample;

- maintain the test sample under high pressure for a specified time;

- visually monitor for the absence of leaks or pressure drop by pressure gauge 6;

- open the plug 8 and dump the increased pressure into the atmosphere, while the plug 5 remains closed;

- disassemble the hydraulic circuit and remove the working fluid from the system;

The test sample is considered to have passed the test if there was no moisture (leakage) on the surface of the sample or if there was no pressure drop on the pressure gauge 6.

Utility Model Implementation

The design of a high pressure crane has been developed.

The crane consists of a housing 1, inlet and outlet fittings 2 and 3, a pressure supply channel 4, plugs 5 for closing the latter, a pressure gauge 6 and a drain valve.

The housing 1 is a steel parallelepiped with dimensions of 100 × 40 × 76 mm, inside which the main channel 4 is made with a diameter of 6 mm with horizontal and vertical sections communicating with each other. Moreover, the horizontal sections have inlet and outlet openings with a tapered inch thread according to GOST 6111-52 K3 / 8 "(input) and K1 / 4" (output) for installation of inlet and outlet fittings 2 and 3, and vertical - outlet openings with thread on GOST 9150-59 Ml 2 × 1.25 - for installing plug 5 and M20 × 1.5 - for gauge 6. In addition, there is an additional (drainage) channel 7 with a diameter of 6 mm, communicating with channel 4 and the atmosphere, and the outlet with a cylindrical part with a diameter of 14 mm and a threaded one - M12 × 1.25 - for installing a cork 8.

The inlet fitting 2 is a steel rod with a diameter of 38 and a length of 50 mm with a hole with a diameter of 8 mm, on one side of which there is an external thread M27 × 1.5 for connecting a source of hydraulic pressure (in this case, a hydraulic pump, not shown in the drawing), and on the other, a tapered inch thread K3 / 8 "- for installation in the inlet of the housing 1.

The outlet fitting 3 is a steel rod with a diameter of 22 and a length of 50 mm with a hole with a diameter of 6 mm, on one side of which there is an external thread M12 × 1.25 for connecting the test sample (not indicated in the drawing), and on the other a tapered inch thread K 1/4 "- for installation in the outlet of the housing 1.

Cork 5 is a steel rod 60 mm long, including a S17 hex head 10 mm thick, a cylindrical part 14 mm in diameter, 20 mm long with a groove of 3 × 2.2 mm for the seal, a threaded part M12 × 1.25 20 mm long and a conical part with a slope of 6 ° with a length of 10 mm to lock the pressure supply channel 4. As a seal, a ring 2 - 9.6-2.4-3012 OST B 38.0529-86 (not indicated in the drawing) is used.

Gauge 6 is a purchased product of MTP-160 GOST 2405 - 72, designed for a maximum hydraulic pressure of 15.6 MPa (160 kgf / cm) with a division value of -0.2 MPa (2 kgf / cm ² ) and an installation shank with M20 thread × 1.5.

The drain valve, in turn, is an additional (drain) channel 7 with a diameter of 6 mm (see the description of the housing 1) and an additional (drain) stopper 8, similar to stopper 5, and designed to simultaneously lock the main and additional channels 4 and 7.

Work with a high-pressure tap is described in the sections “Disclosure of a Utility Model” and “Brief Description of Drawings”.

Claims (1)

A high pressure valve comprising a housing with inlet and outlet fittings, a pressure supply channel, a plug for shutting off the latter, a pressure gauge and a drain valve in communication with the atmosphere, characterized in that the drain valve is made in the form of an additional channel communicating with the main channel and an additional tube, installed behind the main plug and overlapping the main and secondary channels.