RU2389979C2 - Cassette flow metre - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: flow metre corresponds to set of branches inbuilt into pipeline 1 and creating axial symmetrical system wherein one branch is central, while surrounding it others ones are peripheral. A turbine converter of flow with communicating cable 13 is installed in cylinder measuring section 4.5 of each branch; the cable is led outside through cover 11 of a side hatch and is connected to recording equipment. Segments 8 are put on the branches forming tight rings; the branches are set on split bearing space plates 14 and are tied with split bands 7. Elastic shell 9 filled with medium under pressure is installed in a slit between the external surface of segments 8 and internal surface of pipelines. Value of medium flow in the pipeline is determined as sum of results of measurements with each turbine converter. According to one version of the design the branches are assembled in a flange section of the pipeline at ends of which there are installed diaphragms overlapping whole section of the pipeline and having apertures through which the branches pass. In another version of the design diaphragms instead of turbine converters are installed in all periphery branches except one.

EFFECT: upgraded accuracy of measurement, increased flow capacity and convenience of flow metre assembly.

3 cl, 7 dwg

Description

The invention relates to measuring equipment and applied metrology and can be used to transfer the size of a unit of consumption of the material medium from the flow meter, which is the subject of the present invention, to a working flow meter, permanently mounted on the pipeline.

Closest to the invention in technical essence is a portable flow meter [1]. According to [1], a primary flow transducer with a diameter smaller than the diameter of the pipeline is built into the pipeline through the side hatch and installed coaxially with the pipeline. In the annular space between the outer surface of the flow transducer and the inner surface of the pipeline, an elastic, shell-shaped shell is placed into which the medium is supplied under pressure. Thus, the entire flow of matter moving in the pipeline passes through the primary flow transducer. The measurement results are transmitted via a communication cable, which is connected to the passage connector mounted on the side hatch cover.

This flow meter has the following disadvantages.

Since the entire flow of the substance moving through the pipeline passes through the primary flow transducer, it should be large enough. The mass of the transducer is proportional to the linear cube. The large dimensions and mass of the primary transducer make it difficult to move through the side hatch. With large sizes, the primary converter becomes complicated, and sometimes it becomes impossible to ensure the reliability of its readings, since a standard of the appropriate size is required. According to the laws of hydrodynamics, the formation of a steady velocity profile of the measured medium requires a certain length of the nozzle containing the flow transducer, which is proportional to the diameter. With a large diameter, a large length of the pipe is required, which also complicates the installation of the converter built into the pipeline. The elastic shell of the device [1] has large dimensions and complex shape.

The present invention addresses these drawbacks.

The technical result created by the proposed device consists in increasing the convenience of mounting the flowmeter in the pipeline, increasing its throughput, reducing the length of the nozzle containing the flow transducer, reducing the size and simplifying the shape of the elastic shell, simplifying the task of comparing the built-in flow transducer with the reference, and increasing the accuracy of measurements.

Cassette flowmeter, made with the possibility of mounting in the pipeline through the side hatch, is a system of cylindrical nozzles, one of which is central, and the rest, located around it, are peripheral. The nozzles have an inlet cylindrical section, a conical transition section and a cylindrical measuring section, and the diameters of the inlet sections are selected so that the cross-sections of the pipes make up the maximum possible part of the cross-section of the pipeline. The peripheral nozzles are the same size and are distributed evenly around the circumference. Between the central and peripheral nozzles installed split annular supporting spacers. The peripheral tubes are externally pulled together by two split bandages. The connection and screed parts of the bandage is carried out after placing them in the pipeline. On the outside of the bandages there are threaded holes containing mating screw rods. The protruding length of the screw rods can be adjusted so that the rods abut against the pipeline. The ends of the peripheral nozzles facing the oncoming flow are equipped with segments that form an assembled cylindrical ring that fits snugly against the central nozzle. An annular gap is formed between the outer surface of the segment ring and the inner surface of the pipeline, into which the elastic sheath is placed. The shell is filled with a medium under pressure supplied through a hose passing through the cover of the side hatch of the pipeline. Turbine flow converters are mounted in the peripheral pipes, the communication cables of which also pass through the flange of the side cover of the pipeline.

The described device is illustrated by drawings in figure 1, figure 2, figure 3.

Figure 1 shows a longitudinal section of a cassette flowmeter. Positions on the figure mean the following: 1 - pipeline into which the cassette flowmeter is built-in, 2 - screw rods installed in the pipeline in opposition, 3 - turbine flow converter housing, 4 - cylindrical measuring section of the central pipe, 5 - cylindrical measuring section of the peripheral pipe, 6 - an inlet cylindrical section of the peripheral pipe, 7 - bandages, 8 - segments, 9 - elastic shell, 10 - side hatch, 11 - side hatch cover, 12 - flexible shell hose, 13 - turbine conversion communication cables flow collectors, 14 - support spacers between the central and peripheral nozzles.

Figure 2 shows a cassette flowmeter in the direction of arrow A. Names of the positions are the same as in Figure 1, additional position: 23 - impeller of the turbine flow transducer.

Figure 3 shows a cross-section of the cassette flowmeter on the plane 1-1 indicated in Figure 1. In addition to the previously indicated positions, Fig. 3 shows the positions: 15 — bolt tie of the brace, 16 — upper half of the brace, 17 — articulation of the lower and upper parts of the brace, 18 — lower part of the brace.

A cassette flowmeter, configured to be mounted in a pipeline through a side hatch, is assembled and put into operation as follows.

The screw rods of the lower part of the brace are released to the desired length depending on the diameter of the pipeline. The lower part of the bandage is placed inside the pipeline with support on screw rods. On the installed part of the bandage, peripheral pipes with segments worn on them are laid. Turbine converters are mounted inside these nozzles. Stacked pipes make up the lower half of the set of pipes. On the segments forming a half ring, put on an elastic shell in a deflated state. On the laid pipes, the lower parts of the split support spacers are installed, on the central part of which the central pipe is laid. Then install the upper parts of the split support spacers. The remaining peripheral pipes with segments worn on them are installed on the split support spacers. The segments of these pipes are brought under a deflated elastic shell. The upper parts of the brace are attached to the installed lower part of the brace on both sides by means of a swivel joint. Screw rods are also screwed into these parts. The assembled bandage has the shape of a circle cut at the top point. With the help of a bolted connection, the bandage is pulled together, ensuring rigidity of the entire structure. The screw rods of the upper part of the brace are unscrewed all the way into the pipe wall. Communication connectors of turbine transducers are connected to the through-hole connectors of the side hatch cover from the inside, and a pressure hose for supplying an elastic sheath is connected to the straight-through fitting. The side hatch is closed. They apply pressure to the elastic sheath, communication cables are connected to the recording equipment of the turbine flow transducers. When a medium flows into the pipeline, the entire medium passes through a combination of turbine flow converters. The flow rate of the medium in the pipeline is obtained by summing the readings of all turbine flow transducers.

The convenience of mounting the cassette flowmeter is due to the fact that the flowmeter consists of a set of elements having relatively small dimensions and weight. The total cross-sectional area of the peripheral pipes is much larger than the cross-sectional area of one pipe, which can be placed inside the pipeline through the side hatch. Since the diameter of the peripheral pipe is significantly smaller than the alternative pipe described in [1], its required length is also significantly smaller. To ensure the accuracy of the readings of the turbine flow transducer installed in the peripheral branch pipe, a standard much smaller is required than for a single flow transducer in the device [1]. The elastic shell also has significantly smaller sizes and a simpler shape than in the device [1]. The increase in measurement accuracy is due to the fact that the total result is always more accurate than a single term by averaging the random errors of each term.

The second type of cassette flowmeter, which can be mounted in the pipeline through the side hatch, is a structure consisting of the set of nozzles described above but incorporating only two turbine flow converters, one of which is installed in the central nozzle, and the second in one of the peripheral branch pipes. In the remaining peripheral nozzles, diaphragms with a central hole are installed, the purpose of which is to equalize the hydraulic resistance of the peripheral nozzles containing the diaphragms with the hydraulic resistance of the peripheral nozzle containing the turbine flow transducer. If the hydraulic resistance of all peripheral pipes is equal, the flow rate of the flowing medium through them has the same value, determined using a turbine flow transducer.

The described device is illustrated by drawings in Fig.4, Fig.5.

Figure 4 shows a longitudinal section of a cassette flow meter with a turbine flow transducer in the central nozzle, a turbine flow transducer in one of the peripheral nozzles and diaphragms in the remaining peripheral nozzles. Figure 5 shows a view along arrow B. In both figures, the position 19 indicates the diaphragm installed in the peripheral nozzle.

The assembly in the pipeline of this type of cassette flowmeter is similar to the assembly described above for the cassette flowmeter of the first variety.

When the medium flows into the pipeline, the entire medium passes through the central and peripheral nozzles. The value of the flow rate of all peripheral nozzles is obtained by multiplying the flow rate measured by the peripheral turbine flow transducer by the number of peripheral nozzles. The value of the flow rate of the medium in the pipeline is obtained as the sum of the flow rate measured by the central turbine flow transducer and the flow rate for all peripheral pipes.

The third type of cassette flowmeter is a design consisting of the above-described set of nozzles, each of which contains a turbine flow converter, but the nozzles are mounted in a separate flanged section of the pipeline.

At the inlet and outlet of the flange section of the pipeline installed diaphragms with an axisymmetric system of holes. Pipes front and rear ends fit tightly into the holes of the diaphragms. The flanged section of the pipeline has side hatches located evenly around the circumference. Through the covers of these hatches pass the communication cables of the turbine flow converters.

The described device is illustrated by drawings in Fig.6, Fig.7. The positions indicated in FIG. 6 and FIG. 7 mean the following: 20 — flange segment of the pipeline, 21 — front diaphragm with holes for nozzles, 22 — side flange, 23 — rear diaphragm with holes for nozzles.

A cassette flowmeter mounted in a flange segment of a pipeline is assembled and put into operation as follows.

At the ends of the flanged section of the pipeline, diaphragms with holes for the nozzles are installed. Pipes with turbine flow converters mounted in them are inserted into the holes of the diaphragms. Through the open side hatches to the turbine flow transducers connect communication cables. Side hatches are closed, communication cables are connected to the recording equipment. A flange segment of the pipeline with a cassette flowmeter is installed in the pipeline in which it is necessary to measure the flow rate of the medium.

When a medium flows into the pipeline, the entire medium passes through a combination of turbine flow converters. The flow rate of the medium in the pipeline is obtained by summing the readings of all turbine flow transducers.

Information sources

1 Patent RU 2255310 C2, 02.07.2002.

Claims (3)

1. A cassette flow meter containing a pipe, a turbine flow transducer with a communication cable passing through the side hatch cover in the pipeline for mounting the flow meter and connected to the recording equipment, an elastic sheath with a hose for supplying pressure medium passing through the side hatch cover in the mounting pipe flow meter, characterized in that it contains additionally introduced nozzles, while all nozzles form a nozzle system, which is assembled in the pipeline in the form of an axisymmetric design with the central and peripheral nozzles, the peripheral nozzles are the same and are located uniformly around the circumference relative to the central nozzle, the nozzles have an inlet cylindrical section, a conical transition section and a cylindrical measuring section, in the cylindrical measuring section of each pipe there is a corresponding turbine flow transducer with its communication cable passing through the side hatch cover and connected to the recording equipment, to the ends of the peripheral pipes facing to the flowing medium, segments that are in contact with each other and with the central nozzle with the formation of a tight ring are put on, the nozzles with the segments put on them are mounted on split support spacers, the nozzle system is pulled together by split bandages, screw rods are installed between the bandages and the pipeline, in the annular gap between the outer cylindrical surface of the segments and the inner surface of the pipeline is an elastic shell filled with a medium under pressure. 2. Cassette flow meter containing a pipe, a turbine flow transducer with a communication cable passing through the side hatch cover in the pipeline for mounting the flow meter and connected to recording equipment, an elastic sheath with a hose for supplying pressure medium passing through the side hatch cover in the mounting pipe flow meter, characterized in that it contains additionally introduced nozzles, while all nozzles form a nozzle system, which is assembled in the pipeline in the form of an axisymmetric design with the central and peripheral nozzles, the peripheral nozzles are the same and are arranged uniformly around the circumference relative to the central nozzle, the nozzles have an inlet cylindrical section, a conical transition section and a cylindrical measuring section, in the cylindrical measuring section of the central pipe and one of the peripheral pipes there is a corresponding turbine flow transducer with its a communication cable passing through the side hatch cover and connected to the recording equipment, in each m from the remaining peripheral nozzles there is a corresponding diaphragm with a central hole, which ensures equality of the hydraulic resistance of the corresponding peripheral nozzle and the hydraulic resistance of the peripheral nozzle, in which the turbine flow transducer is placed, on the ends of the peripheral nozzles facing the incoming flow of the medium, segments that are in contact with each other are worn another and with a central branch pipe with the formation of a dense ring, branch pipes with segments worn on them are set Lena on split support the spacer, the split pipes system strapped bandages, bandages and vraspor between conduit set screw rods, into the annular gap between the outer cylindrical surface of the segments and the inner surface of the pipeline arranged elastic shell filled with a pressurized medium. 3. A cassette flow meter containing a nozzle, a turbine flow transducer with a communication cable passing through the side hatch cover in the flange section of the pipeline and connected to the recording equipment, characterized in that it contains additionally introduced nozzles, while all nozzles form a nozzle system that is assembled into flanged section of the pipeline in the form of an axisymmetric design with central and peripheral nozzles, the peripheral nozzles are the same and are located uniformly around the circumference of the relative but the central branch pipe, the branch pipes have an inlet cylindrical section, a conical transition section and a cylindrical measuring section, in the cylindrical measuring section of each pipe there is a corresponding turbine flow transducer with its communication cable passing through the side hatch cover and connected to the recording equipment at the ends of the flange section of the pipeline diaphragms are installed that cover the entire cross section of the pipeline and have openings through which the nozzles pass.

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