SU356474A1 - STAND FOR VERIFICATION OF FLOWMETERS AND COUNTER FLUID - Google Patents

Description

The invention relates to instrumentation and is intended, in particular, to work with aggressive, poisonous, volatile, flammable, especially valuable, supercooled cryogenic and other liquids, the handling of large quantities of which is dangerous and is associated with technical difficulties.

A test stand is known for the calibration of liquid flow meters and fluid meters, comprising an instrument and a piston installation.

However, high throughput test benches require large volumes of the measuring section of the pipe.

The construction of such stands requires significant costs.

To reduce the cost by reducing the size of the storage tanks, reducing the volume of the measuring section of the pipe and reducing the amount of liquid required for the stand, while maintaining the accuracy of the test, the proposed stand is equipped with a cavitational proportional flow divider installed behind the inlet nozzle, two output nozzles and several cavitation tubes, each of which is connected to the inlet nozzle and to one of the outlet nozzles, - and one of the output

the nozzle divider is connected to a piston-piston installation, and the other is connected to a storage tank.

The cavitation proportional divider provides continuous division of the flow into two parts with a given cost ratio, defined by the expression:

Q,

i-l

Q;

I.; l -1-1

15 The total flow rate of the liquid through the divider is defined by the expression:

LA, V

QI + Q2 2gr

2., ..

20

where QI - fluid flow through the first outlet;

Qz - fluid flow through the second outlet;

PI - fluid pressure at the inlet to the divider;

f is the area of the compressed section of the cavitation tube.

Indices from 1 to m refer to tubes connected to the first; outlet pipe; The indices from n + 1 to m refer to tubes connected to the second outlet.

The separation of the flow into proportional parts does not depend on the pressure at the outlet of the cavitation tubes and the kind of liquid. To ensure the operation of the divider in the cavitation mode, it is necessary that the pressure differential across the cavitation tubes should be at least 10% of the total cavitation reserve Ra Ra, where I in - the absolute pressure at the inlet

cavitation tube; Ra - vapor pressure of the liquid.

The drawing is a schematic diagram of the proposed stand containing a storage tank 1, a pump 2, a rotatable counter 3, a pipe piston installation 4. The storage tank / is connected to the pump 2 by a suction pipe 5. A pressure pipe 6 is connected to the pump 2, in which a heat exchanger 7 is installed check counter 3.

Truboporshiyev installation 4 contains a pipe 8 with a porous 9 located in it. At the ends of the pipe 8, sensors 10 are mounted. Sensors 10 are coupled to an electronic pulse counter. A rotatable counter 3 is also connected to counter 11.

Truboporshneva installation 4 is equipped with shut-off valves 12-15. In the pressure line 6 of the stand, a valve 16 of smooth flow control and a cavitation proportional divider 17 are installed. The divider 17 includes a supply pipe

18 and discharge pipes 19, 20, as well as cavitation tubes 21 connected to supply line 18. Before entering

, a shut-off valve 22 is installed in each cavitation tube 21.

One cavitation tube is connected to its outlet through a discharge pipe

19 with a piston installation 4, and the rest through a discharge pipe 20 connected to the storage tank /.

The stand works as follows.

The liquid from the storage tank / is supplied by the pump 2 through the heat exchanger 7 to the rotatable counter 3. Next, the liquid enters the cavitation divider 17, in which the flow is divided into two parts. A smaller part of the liquid through the pipeline 19 is fed to the pipe-stopper unit 4, and a large part through the pipeline 20 to the storage tank /.

During operation of the piston-piston installation 4, the Porsche 9, moving under pressure of fluid through the pipe 5, triggers the first sensor 10, while the counter 11 is switched on, recording signals from the counter 5. When the piston 9 reaches the second sensor 10, the counter 11 turns off. from right to left, the shut-off valves 12, 14 are open, the valves 13, 15 are closed, and during the reverse movement of the casing 9, the shut-off valves 13, 15 are open, and the valves 12, 14 are closed.

The bench allows the meter to be calibrated at several flow rates, for example, at the nominal flow rate and at the flow rates corresponding to the upper and lower limits of the measurements. Step adjustment of the flow rate is achieved by closing one or more valves 22, and smoothly by valve 16.

The actual amount of fluid counted by the meter

d

where - the coefficient of flow distribution in the divider, Vt - the volume of the measuring section

pipe, n - the number of moves Porshn.

Subject invention

A bench for checking flow meters and liquid meters containing a storage tank and a pump, a heat exchanger, a hover instrument, a pipe-mounting device, connected to it by pipelines, characterized in that, in order to reduce the cost by reducing the size of the storage tank, pipe-piston installation and reducing the amount of liquid necessary for the operation of the stand, the latter is equipped with a cavitational proportional flow divider installed behind the instrument to be tested and made of the inlet nozzle, two output nozzles and several cavitation tubes, each of which is connected to the inlet pipe and to one of the outlet pipes, one of the outlet pipes of the splitter is connected to the pipe-piston installation, and the other to the storage tank.

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