UA20365U - Device for measuring the flow rate of gas or liquid - Google Patents

Abstract

The proposed device for measuring the flow rate of gas or liquid moving through a pipeline contains a cylindrical casing with an inlet branch pipe andan outlet branch pipe, which is installed in the pipeline, a gas or liquid flow rate transducer and a temperature transducer, which are installed in the casing. The casing of the device is installed so that its longitudinal axis is arranged perpendicular to the axis of the pipeline. In the inlet branch pipe, a diaphragm with a calibrated orifice is installed.

Description

Description of the invention

The utility model refers to measuring equipment and can be used to measure the flow rate of 2 fluids in pipelines, mainly liquids or gases in main pipelines.

A known device for measuring gas flow, which implements a method of measuring gas mass flow, which includes a narrowing device installed in a pipeline, first and second bypass tubes connected with inlet ends before and outlet ends after the narrowing device, a turbulent throttle installed in the common outlet ends of the bypass tubes, a laminar throttle installed at the outlet end of the second bypass tube 70, a heat flow meter sensor placed on the first bypass tube (Russian Patent Mo2066850, 19961.

In this device, the flow rate of the entire medium flow is determined by the flow rate of its part that is diverted from the main flow in one place, by recalculating the flow rate of the diverted part to the entire flow, which reduces the accuracy of flow determination due to the influence of the parameters of the bypass tube, the external environment in which 72 it is located, and due to the fact that the parameters of the part of the diverted flow depend on the place where a part of the medium flow is taken to measure the entire flow of the medium.

Another known device for bypass flow measurement in a line containing a narrowing device, an inlet tube, the first section of which is placed in the main pipeline through which the flow of liquid is transported to the narrowing device, parallel to the flow of liquid, and the second section leaves the main pipeline, a flow meter, to which the second section of the inlet pipe is connected, the outlet pipe, the second part of which is located outside the main pipeline and is connected to the flow meter, and the first part is located inside the main pipeline after the narrowing device parallel to the flow of liquid, while the intersection of the inlet and outlet pipes between the sampling and return points of liquid decreases (US Patent Mo5333496, 1995).

In this device, the flow of the medium is also measured by the parameters of the part of the flow of the medium, which is diverted from the main flow, which reduces the accuracy of determining the flow, as in the previously described device. what

In Japanese patent Mo4-34686, 1994, an air flow meter is described, which contains a bypass channel located along the axis of the pipeline along which the air moves, parallel to the air flow, strengthened with the help of racks in the pipeline wall. The bypass channel contains the first and second sensors of the heat flow meter and consists of two tubes, the second of which has a smaller diameter than the first and is located inside the first. at

The inlet end of the bypass channel (inlet) is the first end of the first tube, the side surface of which has outlet holes. The second end of the first tube is hermetically closed, while the second tube has a length shorter than the length of the first and is fixed at the entrance of the first in such a way that for the measured medium o a passage is formed from the inlet end of the bypass channel through the second tube to its end and further through the space Ha" ) between the second and first tube and through the outlet holes into the flow of the transported medium.

All the elements of this device are located inside the pipeline, which allows to reduce the shortcomings of the devices described above, however, even with this implementation, the nature of the distribution of density, pressure, temperature, and flow velocities of the medium across the pipeline section is not taken into account, which leads to a decrease in the accuracy of flow measurement. "

The closest to the claimed device is a device for measuring the flow of the medium, which contains a straight tubular body installed in the main pipeline through which the medium is transported, and the sensor of the heat flow meter is placed in it (Russian Patent Mo2143666, 1999). Tubular

And" the body is hermetically fixed in the wall of the main pipeline in such a way that its outer end, in which the plug is hermetically fixed, is located outside the main pipeline, and is set to the axis of the medium flow at an angle a. The inner end of the tubular housing is open to the main pipeline, reaches the center of the main pipeline and is cut at an angle of 90-1802 to the axis of the medium flow. A tubular rod with a hermetically sealed inner end is installed in the tubular body, in which the sensor of the thermal (a) flow meter is installed. The outer end of the rod is hermetically fixed in the plug, and in the front part of the tubular body near the wall of the main pipeline, an intake hole is made for the inflow of the medium from the main pipeline. The area of this opening is equal to 1-4 cross-sectional areas of the tubular body, and the diameter of the latter

Ge") 20 is equal to 2-3 rod diameters.

In this device, the parameters of the flow inside the tubular body depend on the parameters of the main flow, which is localized near the intake opening in the front wall of the tubular body and near its inner open end. As a result, the nature of the distribution of velocities, densities, pressures, temperatures, and viscosities across the pipeline is not taken into account, which narrows the area of application and reduces the accuracy of flow measurement, 99 especially for multiphase unsteady flows. c The purpose of this useful model is to create an improved device for measuring the flow of a fluid, which will take into account the distributions of velocities, densities, pressures, temperatures and viscosities of the flow of the medium over the entire cross section of the pipeline, and the flow of the medium will be most fully aligned with the zone of greatest sensitivity of the sensor , which will lead to an increase in the accuracy of determining the medium flow rate. because the task is solved due to the fact that in a known device for measuring the flow of a fluid through a pipeline, which contains a tubular body installed in the pipeline with an inlet channel on the front part of the body for medium intake, an outlet channel of the tubular body for the medium to exit the central part of the pipeline, plug to prevent the medium from escaping outside the pipeline and the sensor of the heat flow meter inside the tubular body, in the part located in the bo flow, according to the useful model, the tubular body crosses the longitudinal axis of the pipeline, while the other end of the tubular body, which is inside the pipeline, is also blocked , the inlet channel has an aperture distributed along the entire front wall of the tubular body, and the outlet channel is made on the back surface of the tubular body and exits into the central part of the pipeline.

The aperture of the input channel of the device can be made in the form of a system of holes distributed along the front wall of the tubular body or at least in the form of two holes located symmetrically on both sides of the longitudinal axis of the pipeline. This implementation of the aperture of the inlet channel makes it possible to take the medium in several, by the number of inlet openings, local zones of the flow at its intersection, which leads to an increase in the accuracy of measurements. 70 Each hole can be made in the form of a fan-shaped structure, in which the axes of the holes are deviated from the direction of the flow of the medium by an angle ranging from -602 to 4602. In this case, the sensitivity of the device to the accuracy of the angular orientation of the tubular body relative to the longitudinal axis of the pipeline decreases, the most completely averaged parameters of the transported medium inside the case.

The aperture of the inlet channel of the device can also be made in the form of a longitudinal slit in the front wall 75 of the tubular body, which allows taking into account the parameters of the main flow across the entire cross-section of the pipeline, which also leads to an increase in the accuracy of measurements.

If the length of the sensitive part of the sensor is significantly less than the length of the input channel (point sensor), it is advisable to place the sensor in the central part of the tubular housing, with the sensitive part in the area of the output channel. In this case, the sensor signal will be determined by the parameters of the averaged flow flowing through the outlet, and the accuracy of determining the flow rate increases.

If the sensor is made in such a way that the length of its sensitive part is comparable to the length of the input channel (linear sensor), it will not be in an averaged flow, but in a flow with a real distribution of velocities, densities, pressures, temperatures and viscosities along the pipeline cross-section; this allows for the most complete matching of the parameters of the flow through the tubular body with the characteristics of the sensor, which also leads to an increase in the accuracy of determining the flow rate of the transported medium.

The tubular body can cross the entire cross-section of the pipeline from wall to wall. WITH

The drawings show: in Fig. 1 - a schematic representation of the proposed device for measuring the flow of the medium with a tubular body, which crosses the entire section of the pipeline and an inlet channel in the form of a system of holes on the front surface of the tubular body; Fig. 2 is a schematic representation of the proposed device for measuring medium flow with an inlet channel in the form of a slit on the front surface of the tubular housing and a sensor placed in the central part of the tubular housing in the area of the outlet channel; Fig. 3 shows a device with an input channel in the form of a two-hole system with a fan-shaped structure about the opening. Fig. 4 is a schematic representation of the proposed device for measuring the flow of the medium with an inlet channel in the form of a system of holes on the front surface of the tubular body and a linear sensor (along the entire longitudinal axis of the body through the entire section of the pipeline).

The device for measuring the flow rate of the medium contains a tubular body 1 fixed in the wall of the pipeline 2, through which the medium is transported, the flow rate of which is measured (Fig. 1). Tubular body 1 pc

Ghani crosses the entire section of pipeline 2 from wall to wall. The cavity inside the tubular housing 1 in the part located inside the pipeline 2 is limited by plugs C and 4. The frontal surface of the tubular housing 1 located in the flow (relative to the flow) contains an inlet channel that is symmetrical with respect to the longitudinal axis of the pipeline, with an aperture , which can be made in the form of a system of holes 5, rear - output

Channel in the form of hole 6 in the central part of the case. The inlet channel has a distributed aperture and serves to select the medium along the cross section of the pipeline. The output channel is used to divert the medium from the housing to the central part of the pipeline (Fig. 1-4). o In other versions, the inlet channel is made in the form of a slot 7 in the front wall of the tubular housing 1 (Fig. 2) or in the form of two holes (Fig. 3), placed symmetrically with respect to the longitudinal axis of the pipeline.

In order to reduce the sensitivity of the device to the accuracy of the installation of the tubular body in relation to the longitudinal axis b of the flow, each hole 5 of the inlet channel 1 can be made in the form of a fan-shaped structure, which includes several smaller holes 8, the axes of which are deviated from the axis of the flow by an angle within -602 to 1602 (Fig. 3).

The tubular body 1 can be installed at an angle a to the longitudinal axis of the pipeline.

Inside the tubular housing 1 in the flow of the selected medium, the sensor 9 of the heat flow meter is placed (Fig. 1). If the length of the sensitive part of the sensor 9 is significantly less than the length of the input channel |, then it is advisable to install the sensor 9 in the central part of the tubular housing 1 in the area of the outlet 6 (Fig. 2). In this case, the sensor responds to the averaged flow. If the length of the sensitive part of the sensor 9 is comparable to the length of the input channel Y, then the sensor Y is placed longitudinally of the body 1 on its axis (Fig. 4). In this case, the sensor will respond to the real distribution of flow parameters across the pipeline. because any known heat flow meter sensor can be used in the device, the electrical parameters of which, usually ohmic resistance, depend on the heating current and the parameters of the medium it is washed with.

The device for measuring the consumption of the environment works in the following way.

The transported medium, when moving along the pipeline 2 through the system of holes 5 or slits 7, enters the cavity of the tubular body 1, limited by the plugs 3, 4, and leaves it through the outlet channel 65 b, while washing the sensor of the heat flow meter 9 (Fig. 1, 2, 4).

The flow in the tubular housing that washes the sensor is created mainly due to:

pressure difference at the location of the openings of the inlet channel and the outlet channel; dynamic pressure in the area of the inlet channel.

The point sensor 9, located in the area of the outlet opening 6, will be washed by the averaged flow that enters the body through the system of holes 5 or the gap 7 in the internal wall of the body 1, and which exits through the outlet channel 6 (Fig. 2).

Separate sensitive areas of the linear sensor 9 will be in the area of influence of different flows, selected from different points of the pipeline intersection, as a result of which the signal of such a sensor will contain information about the integrated distribution of flow parameters along the pipeline intersection (Fig. 4). 70 Since the sensor is in the averaged flow or is affected by flows sampled from different pipeline intersections, the sensor signal carries information about the flow with averaged physical characteristics such as density, pressure, temperature, viscosity, velocity, resulting in increased accuracy flow measurement, especially with unstable flows.

Claims (7)

19 Formula of the invention 1. A device for measuring the flow of a fluid through a pipeline, containing a tubular housing installed in the pipeline with an inlet channel on the front part for taking in the internal medium, an outlet channel of the tubular housing for the medium to exit the central part of the pipeline, a plug to prevent the medium from escaping outside the pipeline and the sensor of the heat flow meter inside the tubular body, which is characterized by the fact that the tubular body is made in such a way that it crosses the longitudinal axis, the second end of the tubular body, which is located inside the pipeline, is made muffled, the inlet channel has an aperture distributed along the entire front wall of the tubular body, symmetrically placed relative to of the longitudinal axis of the pipeline, and the outlet channel is made in the central part of the back surface of the tubular body. WITH 2. The device according to claim 1, which is characterized by the fact that the tubular body crosses the entire section of the pipeline from wall to wall. Z. The device according to claim 1, which differs in that the aperture of the input channel is made in the form of a system of holes distributed along the front wall of the tubular body. 4. The device according to item C, which differs in that each hole is made in the form of a fan-shaped structure, in which the axes of the holes are deviated from the direction of the flow of the medium by an angle in the range from -60o2 to 602, so 5. The device according to claim 1, which differs in that the aperture of the inlet channel is made in the form of a longitudinal slot in the front wall of the tubular body. at 6. The device according to any of claims 1-5, which is characterized by the fact that the sensor is placed in the area of the outlet channel of the tubular body. 7. The device according to claim 6, which differs in that the sensor is linear. - and" name) («c) (95) (o) sl 60 b5