RU2804596C1 - Static flow metering unit - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: device for testing or calibrating equipment for measuring liquid volume, flow, or level. The static flow metering unit consists of pressure tank 3 with connected pipelines - pressure line 4 connected to pumping station 5, drain lines 6 and 7 connected to tank 8 for storing the pressure fluid, and supply line 9 connected to test hydraulic lines 10 located in test box 1, and containing measuring tanks 11 and 12, transfer device 13, time meter 14, scales 15, guide nozzle 16, instrumentation, shut-off and control valves 17, test section 18. In addition, the unit is equipped with equalization tanks 19 and 20, located in pressure tower 2 at the level of pressure tank 3 and hydraulically communicated in the direction of fluid flow with the inlet and the outlet of test section 18, the connection points are made in the form of ring manifolds 21 and 22, covering hydraulic mains 10.

EFFECT: reduced effect of fluid pressure fluctuations on the test results.

3 cl, 3 dwg

Description

The invention relates to the field of physics, in particular, to devices for testing or calibrating equipment for measuring volume, flow or liquid level.

A device for checking flow meters is known, containing a closed hydraulic circuit, which includes a storage tank, interconnected through a pipeline branch with valves with an adjustable main pump and receiver, a section of pipeline for installing the flow meters to be verified, interconnected through a flow distributor with a dynamic flow distributor, installed on individual scales, at least two weighing containers of different volumes, a control panel interconnected with a dynamic flow distributor and weighing containers to ensure the measurement of the filling time of the corresponding container and additionally equipped with at least one adjustable pump installed in a pipeline branch parallel branches of the pipeline of the main pump and interconnected through a pipeline with the receiver, wherein the flow distributor is made in the form of a pipeline branched into at least two branches with a section for installing control flow meters, the storage tank is made load-bearing in the form of a parallelepiped with a certain ratio of internal dimensions and is equipped with a flooring with placed in the last section of the pipeline for installing verified flow meters, a flow distributor, a dynamic flow distributor, weighing tanks installed on scales, a control panel interconnected with adjustable pumps and a section for installing control flow meters, while filters are installed between the storage tank and adjustable pumps (RU, No. 2366906, IPC: G01F 25/00, published 09/10/2009).

The known device relates to in-line flow metering installations, in which the flow of liquid in pipelines, including test sections, is provided directly by pumps. At the same time, long-term practice of conducting comparisons of influent flow metering installations shows low convergence of the characteristics of comparison measures obtained using various instruments (S.O.K. magazine / Plumbing, heating, air conditioning / No. 9 - 2010. Heading: Plumbing and water supply. A. A. Danilov. Pour flow metering installations. The degree of quality of such installations is determined by comparing the metrological characteristics with static flow measuring installations, which are currently considered installations of the highest accuracy and have the status of national (state) standards. The fundamental difference between static flow-measuring installations and others is the presence of a “high-altitude” pressure tank of a constant level with a developed system of gutters, which ensures a break in the injection pressure of the liquid directed to the measuring lines of the measuring instruments being verified from the injection pressure of the pumping station. According to the degree of approximation of the metrological characteristics of known in-line flow measuring installations to the characteristics of high-precision installations, the first are assigned (or not assigned) accuracy ranks - 1 or 2 digits (Interstate standard GOST 8.510 - 2002. State verification scheme for instruments measuring the volume and mass of liquid.) .

Test flow metering installations are known that are currently operating in developed countries (Pavlovsky A.N. Measurements of flow and quantity of liquids, gas and steam. M., Publishing House of the Committee of Standards, Measures and Measuring Instruments under the Council of Ministers of the USSR, 1967, p. pp. 379-391), as well as a generalized typical flow meter installation (ibid., pp. 370-379), selected as a prototype, containing at least one measuring and one weighing tank, a transfer device, a time meter, scales, guide nozzle, shut-off and control valves, test section of the hydraulic line, constant-level pressure tank, pressure pipeline, supply pipeline, drain and limit pipelines connected to the working fluid storage tank, pumping station.

Known installations do not have sufficiently high accuracy of testing due to the fact that they do not prevent pressure fluctuations from the inlet and outlet of the test sections from influencing the flow measuring instruments being verified.

The technical problem to be solved by the present invention is to increase the accuracy of testing (verification, calibration, calibration) of flow measuring instruments by reducing the influence of pressure fluctuations of a hydrodynamic nature on the measuring instruments being verified.

To achieve this technical result in a static flow metering installation, consisting of a test box and a pressure tower, on top of which there is a pressure tank of a constant level, with connected pipelines - pressure, connected to the pumping station, drain - main and limit, connected to the storage tank working fluid, and supply, connected with test hydraulic lines located in the box, and containing measuring, at least one volume and one weight tanks, a transfer device, a time meter, scales, a guide nozzle, instrumentation, a shut-off and control valve fittings, test section, is additionally equipped with at least two equalization tanks, made in the form of vertical pipes and spatially located in the pressure tower at the level of the pressure tank of a constant level and hydraulically communicated in the direction of the fluid flow, one with the entrance to the test section, the other with the exit from the latter, and the connection points are made in the form of ring manifolds covering hydraulic lines.

The length of the perforated section of the annular collector is at least one pipeline caliber.

The surge tank is combined with a graduated measuring tank for testing level gauges.

Distinctive features of the proposed static flow metering installation from the prototype are the additional placement of at least two surge tanks, made in the form of vertical pipes in a pressure tower at the level of a pressure tank of a constant level and hydraulically communicated in the direction of fluid flow, one with the entrance to the test section, the other with an exit from the latter, and the connection points are made in the form of ring manifolds covering hydraulic lines.

Thanks to the presence of these features, the influence on the verified measuring instruments of pressure fluctuations of a hydrodynamic nature, which inevitably arise in connection with the need to turn the flow from a vertically placed pressure tower onto horizontal working hydraulic lines, the presence of shut-off and control valves, pipeline vibrations from the turbulent flow of the working fluid, and mechanical vibrations, is reduced. designs with almost instantaneous switching of the changeover device and propagating both along and against the flow at speeds significantly exceeding the flow speed of the working fluid in the pipeline and comparable in magnitude to the speed of sound propagation in the liquid.

Making the perforated section of the annular manifold at least one pipeline caliber long allows for a more complete influence on fluctuations in the turbulent flow of the working fluid.

In order to expand the functionality, it is advisable to combine a surge tank with a graduated measuring tank for testing level meters.

The proposed static flow metering installation is illustrated by the drawings shown in Fig. 1-3.

In fig. 1 shows a longitudinal section of a static flow metering installation; in fig. 2 - schematic hydraulic diagram of the installation with four test sections, two measuring and two weighing containers for different fluid flow rates; in fig. 3 - view A of Fig. 1. The following notations are used in the figures:

dP ₁ is the difference in static pressure between the constant-level pressure tank and the entrance to the test section;

dP ₂ is the difference in static pressure between the constant level pressure tank and the outlet of the test section.

The static flow metering installation consists of a test box 1 and a pressure tower 2, on top of which there is a pressure tank 3 of a constant level, with connected pipelines - pressure 4, connected to the pumping station 5, drain - main 6 and limit 7, connected to the storage tank 8 working fluid, and supply 9, communicated with test hydraulic lines 10, located in box 1, and containing measuring, at least one volume 11 and one weight 12 tanks, a transfer device 13, a time meter 14, scales 15, a guide nozzle 16 , instrumentation, shut-off and control valves 17, test section 18. The static flow metering installation is equipped with at least two surge tanks 19 and 20, made in the form of vertical pipes and spatially located in the pressure tower 2 at the level of the pressure tank 3 of a constant level and hydraulically communicated in the direction of fluid flow, one 19 with the entrance to the test section 18, the other 20 with the exit from the latter, and the connection points are made in the form of ring manifolds 21 and 22, covering the hydraulic lines of the test sections 18.

The length of the perforated section of each annular manifold 21 and 22 is at least one caliber of the pipeline of the test section 18.

The equalization tank is hydraulically connected to the drain line through taps 23. This makes it possible to calibrate surge tanks 19 and 20 and use them as a graduated measuring tank for testing level gauges.

A static flow-measuring installation containing several test sections is equipped with a distribution manifold 24. The inlet and outlet of the test sections are connected to surge tanks 19 and 20 using taps 25. It is possible to equip each test section (or group several sections) with its own surge tanks.

A static flow meter works as follows.

The working fluid (water) from the reservoir 8, using a pumping station 5 through a pressure pipeline 4, is supplied to a pressure tank 3 at a constant level in an amount exceeding the flow through the test sections 18. In this case, the excess flow of the working fluid from the pressure tank 3 through a developed system of gutters is removed through main drain pipeline 6, ensuring a break in the injection pressure of the liquid sent to the measuring lines of the measuring instruments being verified from the injection pressure of the pumping station, respectively, excluding fluctuations in the pressure of the working fluid associated with the operation of the pumping station 5. The main flow of liquid from the supply pipeline 9 enters through the test hydraulic lines 10 containing test sections 18, shut-off and control valves 17, guide nozzle 16, transfer device 13, into measured volume 11 or weight 12 tanks. In this case, the test section 18 on both sides (at the inlet and outlet), is hydraulically connected with two independent equalization tanks 19 and 20, made in the form of vertical pipes and essentially representing piezometers, the liquid levels in which correspond to the static pressures of the working fluid in the corresponding places of the main line 10, is protected from the propagation of disturbances - the front of the differential pressure wave - to the flow measuring instruments being verified. At the points where equalization tanks 19 and 20 communicate with the test hydraulic lines 10, the inertial pressure (local high or low pressure) is damped by energy dissipation through the perforated sections of the ring collectors 21 and 22.

Making the length of the perforated sections of the annular collectors 21 and 22 at least one caliber of the pipeline of the test section 18 makes it possible to more fully influence the fluctuations of the turbulent fluid flow, preventing the buildup and acceleration of the mass of the working fluid.

It is possible to use surge tanks 19 and 20 as a graduated measuring tank for testing level gauges.

After performing the necessary measurements, the working fluid is drained into tank 8.

The implementation of the set of features described in the proposed static flow measuring installation makes it possible to increase the accuracy of testing (verification, calibration, calibration) of flow measuring devices by reducing the influence of pressure fluctuations of a hydrodynamic nature on the measuring instruments being verified, as well as to expand the functionality.

Claims (3)

1. Static flow metering installation, consisting of a test box and a pressure tower, on top of which there is a pressure tank of a constant level with connected pipelines - pressure, connected to the pumping station, drain - main and limit, connected to the reservoir for storing the working fluid, and supply, communicated with test hydraulic lines located in the box and containing measuring tanks, at least one volumetric and one weight tanks, a transfer device, a time meter, scales, a guide nozzle, instrumentation, shut-off and control valves, a test section, characterized in that , which is additionally equipped with at least two equalization tanks, made in the form of vertical pipes and spatially located in the pressure tower at the level of the pressure tank of a constant level, and hydraulically communicated in the direction of the fluid flow, one with the entrance to the test section, the other with the exit from the latter, wherein the connection points are made in the form of ring manifolds enclosing hydraulic lines. 2. Installation according to claim 1, characterized in that the length of the perforated section of the annular manifold is at least one pipeline caliber. 3. Installation according to claim 1, characterized in that the surge tank is combined with a graduated measuring tank for testing level gauges.