RU22236U1 - TACHOMETER FLOW METER - Google Patents

Abstract

1. A tachometric flowmeter comprising a flowmeter body, inside which a fairing with an internal channel is installed, a primary transducer consisting of a jet swirler, a sensing element in the form of a ball, a signal pick-up unit, and a radial pipe for installing the primary transducer is made in the flowmeter body, and the latter is made in in the form of an annular chamber with tangential inlets forming a jet swirler with a ball located in it, while the fairing is made in the form of a sleeve with an internal channel, I narrow flow and serving to bypass the main stream, and the sleeve is rigidly attached to the body of the flowmeter and installed coaxially with it, and between its outer surface and the inner wall of the housing formed by the measuring channel, characterized in that the upper end surface of the annular chamber is removed from the upper edge of the tangential of inputs at a distance that ensures, when the fluid flow rate increases, the ball leaves the zone of flow pulsating in the radial plane, for a ring of rotationless contactless wall ball, and the lower restrictive end surface of the annular chamber is conical, tapering in flow, and the density of the ball ρ and the density of the liquid ρ filling the flowmeter are related by either ρ / ρ <1, or ρ / ρ> 1, and the average radius of rotation of the ball R and the average radius the input tangential channels R are connected by the ratio of 0.85 <R / R <1, while the largest radius of the input tangential channels R is associated with the inner radius of the jet swirl R by the ratio of 0.9 <R / R <1.2. The tachometric flow meter according to claim 1, characterized in that the outer surface�

Description

TACHOMETER FLOW METER

The technical solution proposed as a utility model relates to measuring technique and can be used to measure fluid flow.

A well-known ball flow meter (USSR author's certificate No. 1117448, MKI 3: O 01 F 1/06, BI No. 37, 1984) containing a measuring section of the pipeline with a spacer contained in it by a primary transducer consisting of a cylindrical body, a directing device, a flow rectifier and ball, a constricting device mounted coaxially in front of the primary transducer, and a channel for bypassing part of the flow, as well as a signal pickup unit. The housing of the primary transducer is made with a diameter smaller than the diameter of the measuring pipeline, the channel for bypassing part of the flow is formed between the housing of the primary transducer and the measuring pipeline, the primary transducer is mounted with the possibility of axial displacement relative to the constricting device, and the diameter of the opening of the constricting device is made not less than the maximum diameter of the primary transducer body. In this technical solution, it is possible to use one standard size of a primary ball flow transducer for measuring fluid flow in a wide range of flow rates.

The disadvantage of this flow meter is the design complexity, complicated settings for different measurement ranges.

Known tachometric flowmeter (USSR author's certificate No. 690297, MKI 2: G 01 F 1/05, G 01 F 1/10, BI No. 37, 1979), containing the casing, in which a flow directing device is installed at the flow inlet, at the flow outlet - flow straightener, ball sensitive element, restrictive

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elements and signal pickup unit. The restrictive elements are made in the form of input and output fairings located behind the jet guide, forming a radial gap with their internal end surfaces, turning into an axial gap formed by at least one (input) fairing with the body wall, and at least one (output ) The fairing has an internal channel.

This flowmeter has a complex structure, and its maintainability is limited, especially in hard-to-reach places.

Known tachometric flowmeter (RF patent No. 2066848, IPC 6: G 01 F 1/05, BI No. 26, 1996), selected as a prototype, comprising a flowmeter housing, inside of which a cowl is installed in the form of a sleeve with an internal channel that narrows downstream and serving for bypassing the main stream, the primary transducer, made in the form of an annular chamber with tangential inputs forming a jet swirler, and a ball located in it, and a signal pickup unit. To install the primary transducer in the flowmeter housing, a radial nozzle is made; moreover, the sleeve is rigidly attached to the body of the flowmeter and is mounted coaxially with it, and a measuring channel is formed between its outer surface and the inner wall of the body.

The disadvantage of this solution is the possible jamming of the ball when a certain shape and size of debris enters the annular chamber, as well as the radial pulsation of the ball that occurs at some rotation frequencies, which leads to wear on the surfaces of the annular chamber and the ball.

The utility model is based on the task of creating a tachometric flowmeter, which would have a simple, easy to repair and operate design, the most unified

for various instrument sizes with a constant proportionality coefficient over a wide range of flow measurements.

The problem is solved in that in a tachometric flowmeter, as well as in the prototype, comprising a flowmeter body, inside of which a fairing with an internal channel is installed, a primary transducer consisting of a jet swirler, a sensing element in the form of a ball, a signal pickup unit, and in the flowmeter body a radial pipe for installing the primary transducer, and the latter is made in the form of an annular chamber with tangential inlets forming a jet swirler with a ball located in it, while fairing is made as a sleeve with an inner channel narrowing downstream and serves to bypass the main flow, said sleeve fixedly attached to the housing and the meter is installed coaxially with it and between its outer surface and the inner wall of the housing formed by the measurement channel.

According to the utility model, unlike the prototype, the upper end surface of the annular chamber is removed from the upper edge of the tangential inlets by a distance that ensures, when the fluid flow rate increases, the outlet of the ball from the zone of the flow pulsating in the radial plane, formed by the tangential inlet of the jet swirler for the ball rotating without contact with the walls of the annular chamber and the lower bounding end surface of the annular chamber is cone-shaped, tapering downstream, and the density of the ball p, and the density p fluid filling flowmeter connected sootnoscheniem or Pm / Px 1 or Pm / Px 1 and the average sphere radius of rotation of Ku and the average radius R of the input of the tangential channels are related by:

the largest radius of the input tangential channels is associated with the inner radius of the jet swirl R by the ratio:

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In addition, the outer surface of the fairing is made in the form of input and output truncated cones fastened together in the region of large bases, and their smaller bases are directed, respectively, in the direction of entry and exit of the flow meter.

The end surfaces of the annular chamber are in the form of bodies of revolution and, together with the conical protrusion of the converter housing located in the axial outlet pipe of the annular chamber, form restrictive elements.

The measuring channel contains an inlet cavity formed by the inner wall of the flowmeter body and the outer surface of the primary transducer body, and an outlet cavity formed by the outer surface of the outlet cone and the inner surface of the flowmeter body.

Studies have established that with a certain combination of the position of the axis of the input channels, the number of channels and the geometry of the annular chamber, there is a stable region of rotation frequencies when conditions are created for the ball to rise in the axial direction proportional to the increase in the flow rate, and the ball rises along the axis of rotation without touching the walls of the ring cameras and without pulsations of the average radius of rotation of the ball, which prevents wear of the elements of the device.

It has been experimentally established that, when rh, the ball does not have a stable average rotation path with a constant flow rate, but occupies a completely arbitrary position in the annular chamber and, therefore, has a variable speed for a given flow rate.

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provide contactless stable rotation of the ball in a given range of fluid flow rates.

Due to the presence of the above distinctive features, the proposed technical solution allowed us to create a simple, unified, technologically advanced and maintainable design that works in a wide range of flow measurement.

As shown by experimental verification, the proposed design provides a sufficiently high degree of constancy of the coefficient of proportionality (cubic meters / pulse) in a wide range of flow measurement. For example, for a device with a diameter (nominal bore) of a pipe on which a mm flowmeter is installed, when the flow rate changes from 1.0 to 30 cubic meters / hour (greater than other similar devices), the proportionality coefficient changes no more than ± 1.5 %

The essence of the proposed device is illustrated in the drawing, where in FIG. 1 schematically shows the proposed flow meter in longitudinal section; figure 2 shows a structural diagram of the Converter in the context with the location of the elements in its housing; on Fig.3 schematically shows an annular chamber in section.

The tachometric flow meter comprises a cylindrical body 1 of the flow meter, within which a cowl 2 and a primary transducer 3 are placed. The cowl 2 is made in the form of a conical sleeve having an internal main channel 4, tapering downstream and serving to bypass the main stream.

In the body 1 of the flow meter, a radial nozzle 5 is made for installing the primary transducer 3, the cowl 2 is attached rigidly to the body 1 of the flow meter and is installed coaxially with it. Between the outer surface of the fairing 2 and the inner wall of the housing 1, a measuring channel 6 is formed.

The primary transducer 3 comprises a housing 7 having an annular chamber 8 with a sensing element located therein in the form of a ball 9, a jet swirler 10, and a signal pickup unit 11.

The axis of the primary transducer 3 is located vertically so that the plane of rotation of the ball in the annular chamber is horizontal; in this case, the requirements for precision manufacture of the ball will be less stringent.

The annular chamber 8 is made with tangential inlets 12 having an upper edge 13 and forming a jet swirler 10.

The conical lower 14 and flat upper 15 end surfaces having the shape of a body of revolution form the lower and upper restrictive elements of the annular chamber 8.

To ensure uniform entry of the measuring flow into the annular chamber 8 along the tangential channels 12 between the outer surface of the housing 7 of the primary transducer 3 and the inner cylindrical wall of the radial pipe 5, a buffer chamber 16 is formed.

The conical surface 17 of the housing 7 of the primary transducer 3, as well as the cylindrical surface turning into a conical 18, paired with the lower supporting surface 14, form an axial outlet pipe connected to the cavity 19 adjacent to the displacement chamber 20, in which the main and measuring are connected at the outlet of the flowmeter streams.

The flow meter operates as follows. The flow of the measured liquid enters the flowmeter and enters the fairing 2, rigidly mounted in the body of the flowmeter 1. In this case, the flow is divided into the measuring 6 and the main 4. The main flow passes through the tapering stream of the internal main channel 4 of the cowling 2. The measuring flow passes through channel 6 , a buffer chamber 16, through the channels 12 of the jet swirler 10 into the annular chamber 8. Twisted

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with a swirler 10, the measuring current acts on the ball 9 installed in the annular chamber 8 in the tangential direction (to give it a rotational motion) and radial (to balance the centripetal force) and exits through the axial outlet pipe into the cavity 19, where due to the ejection effect, the outflow stability is ensured and the constancy of the relationship between the amount of fluid passed through the device and the number of revolutions of the ball. In the mixing chamber 20, the measuring stream is connected to the main stream and exits the flow meter. The ball 9 rotating in the annular chamber, due to the lifting force, rises in proportion to the flow rate along the axis of the annular chamber towards the upper bounding end surface and each revolution passing by the signal pickup unit 11 excites an electric pulse in it, which is recorded and processed by a secondary device, for example, a frequency meter that converts it into a current or voltage proportional to the measured flow. The rise of the ball along the axis of the annular chamber ensures the exit of the ball from the zone of the pulsating flow formed by the presence of discretely arranged circumferentially channels 12 of the jet swirler 10.

The proposed utility model can be widely used in the manufacture of flowmeters, liquid meters with different diameters of nominal bore. The devices built on the basis of this technical solution are characterized by high efficiency, manufacturability, and a high degree of unification.

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Claims (4)

1. A tachometric flowmeter comprising a flowmeter body, inside which a fairing with an internal channel is installed, a primary transducer consisting of a jet swirler, a sensing element in the form of a ball, a signal pick-up unit, and a radial pipe for installing the primary transducer is made in the flowmeter body, and the latter is made in in the form of an annular chamber with tangential inlets forming a jet swirler with a ball located in it, while the fairing is made in the form of a sleeve with an internal channel, I narrow downstream and serving to bypass the main stream, and the sleeve is rigidly attached to the body of the flowmeter and installed coaxially with it, and between its outer surface and the inner wall of the housing a measuring channel is formed, characterized in that the upper end surface of the annular chamber is removed from the upper edge of the tangential of inputs at a distance that ensures, when the fluid flow rate increases, the ball leaves the zone of the flow pulsating in the radial plane, for a ringless chamber of rotation that is contactless with the walls ball, and the lower restrictive end surface of the annular chamber is conical, tapering in flow, and the density of the ball ρ _W and the density of the liquid ρ _W filling the flow meter are related by
or ρ _w / ρ _w <1,
or ρ _w / ρ _w > 1,
and the average radius of rotation of the ball R _W and the average radius of the input tangential channels R are related by
0.85 <R _w / R <1,
the largest radius of the input tangential channels R _max associated with the inner radius of the jet swirl R
0.9 <R _max / R <1.  2. The tachometric flow meter according to claim 1, characterized in that the outer surface of the fairing is made in the form of input and output truncated cones fastened together in the region of large bases, and their smaller bases are directed respectively in the direction of entry and exit of the flow meter.  3. The tachometric flow meter according to claim 1, characterized in that the end surfaces of the annular chamber are in the form of bodies of revolution and, together with the conical protrusion of the transducer housing located in the axial outlet pipe of the annular chamber, form restrictive elements. 4. The tachometric flow meter according to claim 1, characterized in that the measuring channel comprises an inlet cavity formed by the inner wall of the flowmeter body and the outer surface of the primary transducer body, and an outlet cavity formed by the outer surface of the outlet cone and the inner surface of the flowmeter body.