RU2665715C1 - Gravimetric liquid meter - Google Patents

Abstract

FIELD: measuring equipment.SUBSTANCE: invention relates to the field of measurement technology and can be used in the chemical, oil and other industries to measure the amount of liquid transported through pipelines. Gravimetric liquid meter contains, on its rotary axis and a rigidly coupled two-bucket tilting measuring tray with side walls and one common wall, separating from each other its structurally identical buckets, each with its two communicating chambers, jointly forming their weight when filling the tilting moment of the bucket: a filling chamber in the form of an isosceles trapezium in a cross-section with its overflow wall and a drain chamber behind it with its own drain wall which keeps the liquid from splashing, as well as the rotation limiters of the tray, placed on opposite sides of the turning axis of the tray, and a fill funnel that guides the flow of liquid into the tray buckets and is located above its pivot axis, in it each bucket is additionally provided with a partition fixed in it with the formation of an acute angle between it and the axis of the filling hopper and with the division of its filling chamber into two adjacent zones communicating among themselves: jellied and accumulative, involved in the formation of the tilting moment of the bucket, and the partition itself is made of a rectangular sheet with angled notches on one of its sides, stamped with the possibility of forming them in collection of two shelves displaced by the damage: one shelf with corner cutouts forming assembled overflow windows between the jellied and storage areas of the ladle filling chamber and another baffle shelf eliminating splashing of liquid beyond the bucket when it is being filled, at the same time, the drain chamber of each bucket is located at its open edge behind the overflow wall with its adjoining to it and the location of the center of its gravity with the liquid behind the ladle's fill chamber.EFFECT: reduction of measurement error and increase in their reliability, characterized by reproducibility of measurement results, at the expense of providing the meter with the account of all the liquid poured into it without splashing and filling by the buckets achieved by using in the buckets the counter of the partitions smoothly refracting and inhibiting the flow of liquid in it, as well as forming in them the accumulation zones involved together with its drain chamber in creating the turning moment of each bucket.1 cl, 3 dwg

Description

The invention relates to the field of measuring equipment and can be used in chemical, oil and other industries for measuring the amount of liquid transported through pipelines.

A gravity liquid meter is known, comprising a two-bucket tipping measuring tray located on its rotary axis and rigidly connected with it with side walls and one common wall separating structurally identical ladle buckets, and with their drain walls in each, as well as tray rotation limiters placed parallel above its rotary axis on different sides of it, and a filler funnel that directs fluid flow into the ladles of the tray and is located above the rotary axis of the tray (P. P. Kremlevsky. Flow meter and the number of counters - Leningrad:. Mechanical Engineering, 1975).

This well-known gravitational fluid meter allows to reduce the error of measuring fluid flow by performing each bucket with a cross section in the form of an isosceles trapezoid so that the center of gravity of the fluid mass in the bucket moves along the angle bisector at the apex of the isosceles triangle and the value of the tipping moment Mo depends only on the weight of the fluid and does not depend on its density.

The disadvantages of this known gravimetric liquid meter, however, are the large measurement errors, as well as their unreliability, characterized by the irreproducibility of the results of these measurements, since:

- in the process of filling ladles with a fluid flow, most of it is sprayed due to a direct collision of a high-speed fluid flow with their bottoms and goes beyond the ladles, being unaccounted for, which, in turn, also leads to uneven filling of buckets and their tipping uneven in time;

- the spray of liquid is also the higher, the lower the speed of rotation of the buckets and their return to their original filling position.

Closest to the proposed invention is a gravimetric fluid meter containing a two-bucket tilting measuring tray located on its rotary axis and rigidly connected to it with side walls and one common wall separating its structurally identical buckets, each with its own two chambers communicating with each other forming their weight when filling the tipping moment of the bucket: a loading chamber in the form of an isosceles trapezoid in cross section with its overflow wall and size the drain chamber, which is secured behind it, with its drain wall holding the liquid against splashing, as well as the rotation limiters of the tray placed on opposite sides of the rotary axis of the tray, and the filling funnel directing the liquid flow into the ladles of the tray and located above its rotary axis (Copyright certificate No. 1174755 , prior 29.07.83. publ. 23.08.85, bull. No. 31).

This closest to the proposed invention gravimetric liquid meter can improve the accuracy of measurements by accelerating the rotation of the tray, provided by placing the drain chamber of each bucket separately behind the overflow wall of its loading chamber, because the weight of the liquid in the drain chamber and the removal of its center of gravity from the rotary axis of the tray causes an increase in the moment of overturning of the bucket.

The disadvantages of this gravity counter closest to the invention, however, are also a large measurement error and their unreliability, characterized by the irreproducibility of their results due to the spraying of the liquid being poured out of each bucket, due to a direct impact of the high-speed flow from the funnel into the bottom of the bucket when filling it , as well as the impossibility of each bucket to achieve an increased speed of rotation, due to the lack of structural elements in the bucket that increase its moment overturning, as well as the placement of the drain chamber at a close distance from the rotary axis of the tray, leading to the discharge of liquid from the funnel past the buckets without counting it.

The technical result achieved by the invention is to reduce the measurement error and increase their reliability, characterized by reproducibility of the measurement results, by providing a meter to account for all the liquid poured into it without spraying and pouring past the ladles, achieved by using partitions in the buckets that smoothly refract and inhibit the flow liquids in it, as well as the accumulating zones forming in them, participating together with its drain chamber in creating the turning moment of each a.

The specified technical result is achieved by the fact that the gravimetric fluid meter, containing located on its rotary axis and rigidly connected with it, a two-bucket tilting measuring tray with side walls and one common wall separating its structurally identical buckets, each with its own two communicating with each other cameras that together form their weight when filling the tipping moment of the bucket: a loading chamber in the form of an isosceles trapezoid in cross section with its overflow wall th and the drain chamber located behind it with its drain wall holding the liquid against splashing, as well as the rotation limiters of the tray, located on opposite sides of the rotary axis of the tray, and the filling funnel, directing the liquid flow into the ladles of the tray and located above its rotary axis, ... each bucket is additionally equipped with a partition fixed in it with the formation of an acute angle between it and the axis of the inlet funnel and with the separation of its filling chamber into two adjacent adjacent zones: the filling and accumulating participating in the formation of the overturning moment of the bucket, and the partition itself is made of a rectangular sheet with corner cutouts on one of its sides, stamped with the possibility of forming in the assembly two shelves displaced by the damage: one shelf with corner cutouts forming the overflow windows between the filling and accumulating zones of the bucket’s filling chamber, and another baffle plate, which eliminates the spraying of liquid outside the bucket when filling it, while the drain chamber of each bucket is located at its open that edge of the overflow wall adjacent the location of it and the center of gravity of the fluid inlet chamber of the bucket.

The invention is illustrated by drawings:

FIG. 1 - General view of the gravitational liquid counter in the context;

FIG. 2 - AA in FIG. one;

FIG. 3 - Measuring tray in a perspective view.

The gravity liquid meter contains a tipping two-bucket measuring tray 1 (Fig. 1, 2) located on its rotary axis 2 and rigidly connected with it, as well as rotation limiters 3 and 4 of the buckets 5 located on the sides of the rotary axis 2 of the tray 1, 6 and a filling funnel 7, directing the fluid flow into its buckets 5, 6 and located above the rotary axis 2.

The measuring tray 1 itself contains side walls 8 and 9 (Fig. 3) and one common wall, which separates it structurally identical buckets, wall 10.

Each of the buckets 5, 6 contains two interconnected chambers that together form their weight, each tipping moment of the bucket: the loading chamber 11 in cross section in the form of an isosceles trapezoid with its overflow wall 12, shorter than the common wall 10, and placed behind it drain chamber 13 with its retaining liquid from splashing drain wall 14.

A drain chamber 13 is placed in each bucket at its open edge behind its overflow wall 12 adjacent to it and its center of gravity is located with liquid P ₁ behind the bucket bulk chamber, while the distance from it to the pivot axis of the tray acts as a lever for applying its force gravity P _1, the pivot tray and the corresponding weight of the filled liquid drain chamber 13. The length of the lever arm of length considerably greater if the center of gravity of the filled liquid drain chamber located, as in the prototype, within the inlet chamber bucket, so overturning moment claimed bucket counter significantly above that provides a high speed of rotation, fluid draining from them and return to a filling position below the hopper, preventing the continuous flow of liquid poured from the funnel beyond ladles.

The filling chamber 11 of each bucket contains a partition 15 made of a rectangular sheet with corner cutouts on one of its sides and stamped with the possibility of forming two assembled offset shelves: one shelf 16 with corner cutouts forming complete overflow windows 17 and 18 between the filling and storage zones of the bucket loading chamber, and another baffle plate 19, which eliminates the spraying of liquid outside the bucket when filling it. The partition 15 is fixed in its bucket with the formation of an acute angle междуα between it and the axis of the filler funnel and with the separation of this chamber into two adjacent adjacent zones: the filler zone 20 and the accumulation zone 21, which, when liquid is filled together with the filled drain chamber in the formation its weight P ₂ tipping moment of the bucket.

The gravimetric fluid meter works this way.

The principle of operation of the meter is based on the alternate filling of each of the buckets 5, 6 of the measuring tray 1 and their subsequent tipping over when they reach a certain mass of liquid.

Due to the symmetrical shape of each of the buckets 5, 6 relative to its vertical axis, its center of gravity moves vertically and the value of the tipping moment depends only on the weight of the liquid and does not depend on its density.

Before starting the meter, the buckets 5 and 6 of the measuring tray 1 are calibrated. For this, the measured liquid is poured into these buckets and calibrated with counterweights (not shown). Thus, the dose of liquid poured into buckets 5 and 6 (Fig. 3) remains always constant, independent of its density. The value of this mass is entered in the computing unit of the counter (not shown).

The fluid flow from the inlet manifold (not specified) is sent to the filling funnel 7, and from it successively to the filling zone 20 of the filling chamber 11 of one of the buckets 5.

Getting into the bucket 5, the fluid flow, without reaching its bottom, falls at an acute angle ∠α onto the partition 15 and, being refracted, gradually slows down by it, reducing its speed and thus eliminating the spraying of the liquid outside the bucket. In this case, one part of the fluid flow flows down the partition through the jets, and the other part is repelled from the partition 15 and, breaking, is directed back into the bucket into its filling zone 20. From the filling zone 20, the liquid flows through the overflow windows 17 and 18 into its closed above partition 15, the accumulation zone 21, while the baffle plate 19 of the partition 15 directs droplets detached from the flow back into the filling zone of this bucket. Then, from the filled storage zone 21, the liquid is directed by a laminar flow through the overflow wall 12 into the drain chamber 13 of the bucket 5 and fills its volume without spraying until the weight of the liquid filled drain chamber 13 (P1) and the weight of the liquid filled storage zone 21 (P2) bucket 5, will not create together in this bucket tipping moment. Once this is achieved, the bucket 5 will abruptly turn completely into the rotation limiter 3 and the liquid poured into it will pour out, and another bucket 6 will be installed under the stream of liquid from the funnel and, when filled, the empty bucket 5 will return to its original filling position. Thus, it is the focusing of the center of gravity of the drain chamber behind its loading chamber, at the open edge of the bucket, that makes it possible to create the increased tipping moment of the bucket by the forces of gravity of these sections of the bucket, allowing it to accelerate its turn, drain the liquid from it and return it to its original filling position under the filling funnel preventing the flow of fluid from it past the buckets. Moreover, the moment of the beginning of filling one bucket corresponds to the moment of the beginning of the discharge of another bucket and vice versa.

Each rotation of the tray 1 is fixed and entered into the computing unit (not shown).

The created technical solution, due to the combination of its essential features reflected in the claims, allows to reduce the measurement error of the meter and to ensure their reliability, characterized by the reproducibility of the results of these measurements, due to:

- the use of a partition wall with shelves in the buckets, which allows its design and installation to ensure smooth refraction and braking of the liquid flow poured into the bucket, as well as the formation of a closed storage zone in it, which, together with the drain chamber, participates in the formation of the tipping moment of each bucket, and thereby eliminate spray liquid from it, accelerate its rotation, drain the liquid from it and return to its original filling position under the filling funnel, preventing the liquid flow from it past the bucket th and ensuring its full accounting counter;

- placing in each bucket its drain chamber holding the liquid from spraying with its drain shelf at the open edge of the bucket, behind the overflow wall adjacent to it and the location of its center of gravity with the liquid outside the bucket filling chamber, thereby allowing for an increased turning moment bucket, accelerating the discharge of liquid from it and its return to its original filling position under the filling funnel, and, as a result, prevent the liquid flow from the funnel past the buckets and ensure its full metering.

The gravimetric counter claimed as an invention has been tested at the All-Russian Scientific Research Institute of Flow Metering Federal State Unitary Enterprise and is ready for release at the applicant's enterprise.

Claims (1)

A gravimetric fluid meter containing a two-bucket tilting measuring tray located on its rotary axis and rigidly connected with it with side walls and one common wall separating its structurally identical buckets, each with its own two chambers communicating with each other, together forming its weight at filling the tipping moment of the bucket: the filling chamber in the form of an isosceles trapezoid in cross section with its overflow wall and the discharge chamber located behind it from its holding the liquid from spraying by the drain wall, as well as the rotation limiters of the tray, located on opposite sides of the rotary axis of the tray, and the filling funnel, directing the liquid flow into the ladles of the tray and located above its rotary axis, characterized in that each bucket of the tray is additionally equipped with a partition, fixed in it with the formation of an acute angle between it and the axis of the filling funnel and with the separation of its filling chamber into two adjacent adjacent zones: filling and cumulative, participating in the formation of the test the moment of the bucket, and the partition itself is made of a rectangular sheet with corner cutouts on one of its sides, stamped with the possibility of forming by the assembly two shelves offset from each other by damage, forming one shelf with corner cutouts forming the overflow windows between the filling and storage zones of the bucket’s filling chamber, and another baffle plate, which eliminates the splashing of liquid outside the bucket when filling it, while the drain chamber of each bucket is located at its open edge behind the overflow wall with adjoining to it and the location of the center of gravity with the liquid behind the bucket loading chamber.

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