RU1793231C - Device for checking integral flow of liquid in pipeline - Google Patents

Abstract

Usage: in the field of measurement technology for measuring integral flow. SUMMARY OF THE INVENTION: in the presence of liquid leakage in the pipe 2 at the inlet 4, a pressure exceeds the pressure at the inlet of the pipe 7 by the magnitude of the pressure head in the pipe 2. As a result, through the channel 4, and the flexible pipe 5, part of the liquid enters from the pipe 2, which is gravity drained through the flexible pipe 9 into a storage tank 1. The determination of the integral liquid flow in the pipe 2 for a given period of time is reduced to measuring the liquid level at the beginning and end of this period of time, respectively, in tank 6 and tank 1. calculation based on the results of measurements of the volumes of accumulation of liquid in them and their conversion to the diameter of the pipeline 2. 1 il w yo

Description

The invention relates to the field of measurement technology and can be used to take into account the total volume of liquid supplied through a pipeline for a given period of time.

A device of a similar purpose is known, comprising a storage tank and installed in a given section of the pipeline and a Pitot-Prantl pipe.

A disadvantage of the known device is the complexity of operation associated with the need to manually control the measurement processes,

A device is known for controlling the integral fluid flow rate in a pipeline, comprising a bulk storage tank located above the pipeline, as well as pitot and Prantl inlets which are located in a predetermined section of the pipeline, with a flexible pipe connected to the outlet of the pitot tube.

The disadvantage of this known device is the long measurement time for flow control, associated with the need to repeatedly measure the volume of liquid.

The aim of the invention is to increase the speed of the device.

This goal is achieved in that a device for controlling the integral flow rate of a liquid in the pipeline, containing a storage tank located above the pipeline, and also Pitot and Prantl tubes, the inlets of which are located in a given section of the pipeline, and a flexible pipe is connected to the output of the Pitot tube, it additionally contains above the pipelines of the storage tank, the pool tank and the floating tank located inside its bottom part of which is oriented along the liquid level of the bass ynoy capacitance and is connected through an optional flexible hose with mernoiakopitelnoy container and via a first flexible hose - with a yield of Pitot tube, and the outlet tube Prantl connected to the bottom part of the basin capacity.

The drawing shows a diagram of the proposed device.

The device for monitoring the integral flow rate of the liquid in the pipeline contains a cumulative tank 1 and a Pitot and Prantl tube 3 installed in a given section of the pipeline 2. A flexible pipe 5 is connected to the output 4 of the Pitot tube (to channel 4). At a level exceeding the upper part of the pipe 2, a basin 6 is installed in the alignment of the placement of the Pitot and Prantl tubes 3, hydraulically connected to the input 7 of the Prantl tube. The second end of the flexible pipe 5 is connected to one part of the floating tank 8 located in the tank 6, and the plane of the bottom of the floating

capacity 8 is displaced with its swimming plane. The bottom of the floating tank 8 through the flexible drainage pipe 9 can also be communicated with the storage tank 1.

0 The device operates as follows.

Since the reservoir 6 is hydraulically in communication with the pipeline 2 through the channel 7, in the absence of a fluid current, the fluid level in the reservoir 6 is set corresponding to the pressure at the inlet of the Prantl tube (channel 7 is connected to the output of the latter), i.e. the pressure in the pipeline 2. In this case, the tank 6 is installed at a mark that excludes the discharge of liquid from it at the maximum pressure in the pipeline 2, and its height is calculated from the condition of ensuring the normal operation of the flexible elements 5 and 9

5 at a minimum pressure in line 2, i.e. with a minimum liquid level in the tank 6, the additional influence of the flexible elements 5 and 9 on the conditions of melting of the tank 8 should be excluded (an additional effect on the buoyancy of the tank 8 can be exerted with a strong bending of the flexible elements 5 and 9).

In the absence of fluid flow in the pipeline 2, the pressure at the inlet of channel 4 (i.e.,

5 inlet of the Pitot tube), the same is equal to the pressure in the pipeline 2. Therefore, no liquid enters the tank 8.

In the presence of a liquid current in the pipe 2 at the inlet 4, a pressure arises that exceeds the pressure at the inlet of the pipe 4 by the value of the pressure head in the pipe 2. As a result, part of the liquid from the pipe 2 enters through the channel 4 and the flexible pipe 5 into the tank 8.

5 The liquid entering the tank 8 is drained by gravity through the flexible pipe 9 into a mercury-accumulating tank 1.

Determination of the integral fluid flow in the pipeline 2 for a given

0 the period of time using the device is reduced to measuring the liquid level at the beginning and at the end of this period of time, respectively, in the tank after tank 1, calculated by the results of volume measurements

5 of the liquid accumulated in them and their conversion to the diameter of the pipeline 2. Moreover, if for a given period of time the container 8 was emptied, this is taken into account when determining the volume of accumulated liquid in the container 8.

Claims (1)

The claims A device for monitoring the integral fluid flow rate in a pipeline, which contains a storage tank located above the pipeline, as well as pitot and Prandtl tubes, the inlets of which are located in a given section of the pipeline, and a flexible pipe is connected to the output of the pitot tube, characterized in , | which, in order to improve performance, i. .-. it additionally contains a basin tank located above the pipeline and the storage tank and a floating vessel located inside it, the bottom of which is oriented along the liquid level of the base tank and is connected through the second flexible pipe to the storage tank and through the first flexible pipe to the exit of the Pitot tube, and the Prandtl tube outlet is connected to the bottom of the basin.