RU1778530C - Liquid meter - Google Patents

Abstract

SUMMARY OF THE INVENTION A liquid meter comprises a housing, an inlet and an outlet nozzle, a glass with a coaxial impeller, three partitions. The partitions, together with the housing and the glass, form two cavities. These cavities are connected with the glass cavity by two pairs of diametrically opposite openings, which will allow to divide the input stream into two, send it to the impeller blades and then connect it into one in the outlet cavity. 4 ill.

Description

The invention relates to instrumentation, in particular to high-speed multi-jet vane meters of volumetric volume of liquids, and can be used to measure the amount of water or other liquids.

Known is a high-speed multi-jet vane counter for the volumetric amount of liquid, consisting of a housing, the internal cavity of which is divided by a partition with an opening into two parts, one of which is adjacent to the inlet pipe of the housing, and the other to the output, located in the opening of the glass partition, closed by a lid and enclosing internally rotatable krylchatka, and also having in the qi / indric part a number of eccentric relative to the axis of the glass inlet openings connecting the inner cavity to that part in the morning of the housing which is adjacent to the inlet and outlet openings connecting the inner cavity of the cup with the interior of the housing part which adjoins the

an outlet pipe, wherein the row of outlet openings is offset relative to the row of inlet openings along the axis of the beaker and a recording device connected to the impeller.

The closest in technical essence is a high-speed multi-jet vane meter for the volumetric amount of liquid containing a housing, the inner space of which is divided by a partition into two cavities, one of which is adjacent to the inlet of the housing, and the other to the outlet, a glass installed in the housing of which the impeller is rotatable and one of a number of inlet openings is made, communicating with the body cavity adjacent to the inlet pipe, and displaced relative to it along the axis Kan second series of outlet apertures communicating with the outlet nozzle adjacent to the cavity of the housing and connected to a recording device impeller g

The disadvantage of the well-known high-speed multi-jet vane counter

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volumetric amount of liquid is that the separation of the fluid flow into several inlet openings is accompanied by greater energy losses than if the entire flow rate passed through one, for example, aperture. Therefore, in order to ensure a normalized pressure drop across a multi-jet meter, the penetration in the inlet openings is essentially lower than it would be if, for example, a single opening, and this limits the sensitivity of the multi-jet meters. Another disadvantage of the known high-speed multi-jet vane volumetric liquid meter is the effect of axial force on the impeller due to the presence of the axial component of the velocity of water flowing through the glass, due to the fact that the glass inlet openings are offset relative to the outlet openings along the glass axis.

An object of the invention is to increase sensitivity and durability.

The goal is achieved in that in a liquid meter containing a housing with inlet and outlet nozzles, in which a glass with a coaxial impeller is installed perpendicular to the longitudinal axis, dividing the internal space of the housing into the input and output cavities, the glass has an inlet opening communicating the inlet cavity housing with a glass cavity, and an outlet that communicates the glass cavity with the output cavity of the housing, and a recording device, three partitions are made inside the housing, the first of which is located on the outlet side the bottom of the nozzle and together with the glass and the wall of the body forms the first cavity, and the second is located on the side of the inlet pipe and together with the glass and the wall of the body forms the second cavity, the second inlet is made in the glass, which is axisymmetric to the first inlet and connects the first cavity with the cavity of the glass, and the second outlet, diametrically opposite to the first outlet and connecting the cavity of the glass with the second cavity, all the holes of the glass are located in one plane, erpendikul molecular axis of rotation of the impeller, the inlet chamber of the casing communicates with the first cavity and the second cavity is connected with the outlet cavity housing independent channels formed third partition located between the bottom of the housing and the bottom cup at a distance from them.

In FIG. 1 is a longitudinal section through an inventive meter; in FIG. 2 is a section AA in FIG. 1, in FIG. 3 is a section BB in FIG. 2; in FIG. 4 is a section AA in FIG. 2.

The liquid meter consists of a housing 1 with input 2 and output 3 nozzles, in

in which a cup 4 is installed perpendicular to the longitudinal axis, in which two axisymmetric inlet 5, 6 and two axisymmetric outlet 7, 8 openings are made, made in one plane perpendicular to the axis of rotation of the impeller 9. mounted coaxially in the cup 4. The glass divides the inner space case on the input 10 and output 11 of the cavity, above the impeller is installed recording

5 device 12. Inside the body 1, partitions 13, 14 are made. The partition 14 is located on the side of the outlet pipe 3 and together with the glass 4 and the body wall form the first cavity 15, the partition 13 is located on the side of the inlet pipe 2 and together with the glass 4 and the wall of the housing forms a second cavity 16.

The inlet 5 of the cup 4 connects the inlet cavity 10 with the cavity of the cup 4, and the outlet 7 of the cup 4 communicates the cavity of the cup 4 with the outlet cavity 11.

The second inlet b glass 4

о connects the first cavity 15 to the cavity of the cup 4, and the second outlet 8 connects the cavity of the cup 4 to the second cavity 18. A partition 17 is formed between the bottom of the housing 1 and the bottom of the cup 4, forming independent channels 18 and 19, using the channel 19 the input cavity 10 of the housing communicates with the first cavity 15, and through the channel 18, the output cavity 11 communicates with the second cavity 16.

The liquid meter works as follows.

The measured liquid through the inlet pipe 2 enters the inlet cavity 10 of the housing 1. From the inlet cavity 10, one part

C-stream through the holes 5 and 7 of the cup 4 passes into the outlet cavity 11, falling onto the impeller 9 and rotating it, and then through the outlet pipe 3 flows into the pipeline (not shown in the drawing). Another part of the flow from the inlet cavity 10 through the channel 19 passes into the first cavity 15, then through the openings 6 and 8 of the cup 4 passes into the second cavity 16 and from this cavity through the channel 18 enters the outlet cavity 11 and through the outlet pipe 3 into the pipeline. In this case, a second stream of liquid is formed inside the cup 4, moving from hole 6 to hole 8, rotating the impeller 9 in the same direction as the first jet formed by holes 5 and 6.

5

the rotational speed of the impeller is recorded by the device 12

Both parts of the flow are equal to each other. This is ensured by the fact that the cross-sectional areas of holes 5 and 7 on the one hand and 6 and 8 on the other hand are equal to each other, and the speeds in the channels 18 and 19 are small, which makes the hydraulic resistance of the channels which pass both parts of the flow, almost the same. Therefore, both jets rotating the impeller are identical and the impeller does not experience lateral forces, due to which its friction bearings are unloaded from transverse forces. Since the holes of the cup 5-8 are located in the same plane perpendicular to the axis of rotation of the impeller 9, the axial component of the interaction forces of the jets of the measured flow with the impeller is practically zero

This eliminates the radial and axial wear of the impeller axis, which leads to an increase in durability

Claims (1)

Claims A liquid meter comprising a recorder and a housing with inlet and outlet nozzles, in which a cup with a coaxial impeller is installed perpendicular to the longitudinal axis, dividing the interior of the housing into the inlet and outlet cavities, wherein the cup has an inlet and an outlet opening, characterized in that that, in order to increase sensitivity and durability, the casing is equipped with three partitions, the first of which is located on the side of the outlet pipe and together with the glass and the wall of the casing forms the first cavity, and the second is located on the side of the inlet pipe and together with the glass and casing wall forms a second cavity, a second inlet is made in the glass, diametrically opposite to the first inlet and connecting the first cavity with the glass cavity, and a second outlet of diameter opposite the outlet and connecting the cavity of the glass with the second cavity, all the holes in the glass are located in the same plane perpendicular to the axis of rotation of the impeller, the input cavity of the housing communicates with the first cavity of the housing, and the second cavity communicates with the output cavity of the housing by independent channels formed by the third partition, located with gaps between the bottom of the housing and the bottom of the glass. P I fff Ph.Z f FIG. 4