SU1071802A1 - Bed for testing pumps - Google Patents

Abstract

STAND FOR TESTS OF PUMPS, mainly submersible, containing a sealed tank with a bottom, suction pipe connected to the test pump and tank and equipped with a shut-off body pressure pipelines, the outlet section of the latter of which is perforated and located in the tank cavity, and a pressurized system connected to the tank, characterized by that, in order to expand the range and increase the accuracy of testing for liquids with mechanical impurities, the suction pipe is connected to the bottom of the tank and provided with a shut-off organ, pipeline sections to the locking bodies are interconnected by a hydraulic line with a bypass valve. (L | 00 oo

Description

The invention relates to hydraulic engineering and can be used for testing submersible pumps in liquids with mechanical impurities.

A known test bench for pumps, containing a tank connected to the test pump and tank suction and pressure pipelines [1].

However, this stand does not allow testing pumps under high pressure.

The closest to the invention in terms of technical nature and the achieved result is a pump test stand comprising a sealed tank with a bottom, pressure pipelines suction and equipped with a shut-off element connected to the test pump and tank, the outlet section of the latter being perforated and located in the tank cavity, and boost system connected to the tank [2].

However, the known stand does not provide the required range and high accuracy of tests on liquids with mechanical impurities. In particular, at a well-known stand it is impossible to conduct tests simulating the processes of stopping the pump and its start.

The purpose of the invention is to expand the range and improve the accuracy of tests on liquids with mechanical impurities.

This goal is achieved by the fact that in the test bench for pumps, mainly submersible, containing a sealed tank with a bottom, pressure pipelines that are connected to the test pump and tank and are equipped with a shut-off element, the outlet section of the last of which is perforated and located in the tank cavity, and connected pressurization system to the tank, the suction pipe is connected to the bottom of the tank and is equipped with a shut-off element, and sections of pipelines in front of the shut-off elements are interconnected by means of Sewage hydraulic line with valve.

The drawing shows a diagram of a bench for testing pumps.

The test bench for pumps contains a sealed tank 1 with a bottom 2, connected to the test pump 3 and tank 1, the suction pipe 4 and the pressure pipe equipped with a shutoff body 5. The output section 7 of the pipeline 6 is perforated and is located in the cavity of the tank 1. A pressurization system 8 is connected to the tank 1. The suction pipe 4 is connected to the bottom 2 of the tank 1 and is equipped with a shut-off element 9, and sections 10 and 11 of the pipelines 4 and 6, respectively, in front of the shut-off bodies 9 and 5 are interconnected by a bypass hydraulic line 12 with a valve 13.

The submersible pump 3 can be located in the pit 14, simulating a well and having in the upper part an extension forming an additional tank 15. A flow meter 16 can be located in the suction pipe 4, and a drain pipe 17 with a shut-off element 18 can be connected to the said pipe 4. Tank 1 is provided with a valve 19, the bottom 2 can be made in the form of a cone, and the suction pipe 4 is connected to the top of the latter.

Stand for testing pumps works as follows.

Before testing, the hydraulic system of the stand is filled with the pumped liquid with a given content of mechanical impurities.

To test the pump 3 in the starting mode, characterized by a low resistance of the pressure pipe 6, close the shut-off element 9 and valves 13 and 19 and open the shut-off element 5. Start the pump 3, which pumps the fluid with mechanical impurities from the additional tank 15 and the suction pipe 4 into the tank 1, As the tank 1 is filled, the pressure in the gas cushion of the latter and, therefore, at the outlet of the pump 3 will increase, thus simulating the filling of the shut-off pipe 6 in a real well.

When testing at nominal conditions, the shut-off element 9 is additionally opened, and using the boost system 8, the set pressure in the tank 1 is maintained.

The fluid with mechanical impurities is collected by the pump from tank 1 and pumped into the same tank. The combination of the perforated outlet section 7, located in the cavity of the tank 1 with connected to the bottom 2 of the last suction pipe 4, provides a uniform distribution of impurities in the volume of the tank 1 and the constancy of their concentration in the pumped liquid during the test.

To test the pump 3 in stop mode, close the shut-off element 9 and open the shut-off element 5 and valve 13. A fluid with mechanical impurities from the tank 1 is supplied to the outlet of the pump 3. It passes through the latter and is discharged into an additional tank 15 or is discharged through the drain pipe 17. Thus In this way, the process of stopping pump 3 under real conditions without a check valve at the outlet is simulated) when a large amount of liquid with an increased concentration of impurities passes through the pump for a relatively short time.

In the proposed stand, it is possible to test the pump in all operating modes, including the start and stop modes, and increase the accuracy of the test by maintaining a constant concentration of impurities in the liquid.

Claims (1)

STAND FOR PUMP TESTS, mainly submersible, containing a sealed tank with a bottom, pressure pipelines suction and equipped with a shut-off element connected to the test pump and tank, the outlet section of the latter made perforated and located in the tank cavity, and a pressurization system connected to the tank, characterized the fact that, in order to expand the range and improve the accuracy of tests on liquids with mechanical impurities, the suction pipe is connected to the bottom of the tank and equipped with a shut-off element, and ki pipelines in front of the locking elements are interconnected via a bypass hydraulic line with a valve.