RU2125241C1 - Liquid meter - Google Patents

Abstract

FIELD: multijet impeller liquid meters used to measure flow rate and amount of liquid flowing in pipe-line. SUBSTANCE: body housing two-jet measuring mechanism made of sleeve, impeller and cover has shaped partition. One part of it is located on one side of longitudinal axis of body, the other part is on the other side and third part is positioned between sleeve and outlet branch pipe. Partition together with sleeve and walls of body form central space bordering on inlet pipe-line and two side spaces adjoining outlet branch pipe. Thanks to this measured liquid is divided into two streams rotating impeller in one direction and with it unloading its supports from forces interacting with streams. Packing laid in grooves of sleeve ensures leak-tight separation of streams. Invention makes it feasible to prolong operational life of meter to 10-12 years, meter has simplified design and diminished overall dimension along vertical line. Owing to manufacture of measuring mechanism in the form of one module its replacement is possible without dismantling of body from pipe-line. EFFECT: prolonged operational life, simplified design and diminished vertical dimension of meter, possibility of replacement of measuring mechanism without dismantling of body from pipe-line. 1 cl, 10 dwg

Description

 The invention relates to instrumentation, in particular to high-speed multi-jet wing meters of the volumetric amount of liquid, and can be used to measure the flow rate and amount of water or other liquids flowing in the pipelines.

 Known high-speed multi-jet vane fluid meter 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 is to the output, a glass installed in the housing, inside of which a rotatable impeller is located, and one is made a number of inlets communicating with the body cavity adjacent to the inlet pipe, and another row of outlet openings communicating with it adjacent to the an outlet pipe with a body cavity, and a recording device connected to the impeller [1].

 The closest in technical essence is a high-speed multi-jet liquid meter containing a recorder and a housing with inlet and outlet nozzles, in which a glass with an impeller is installed that separates the interior of the housing into the inlet and outlet cavities, and there are three partitions, one of which separates in the outlet cavity housing the first cavity, another separates the second cavity in the entrance cavity of the housing, and the third is located with gaps between the bottom of the housing and the bottom of the glass, the input cavity is connected to the first cavity the gap formed between the bottom of the casing and the third partition, and the second cavity is connected to the outlet cavity by the gap formed between the third partition and the bottom of the cup, the cup has two diametrically inlet openings that connect the cavity of the cup, respectively, to the inlet and first cavities of the casing, and two diametrically located outlet holes that connect the cavity of the glass, respectively, with the second and output cavities of the housing [2].

 The disadvantages of the known liquid meter [2] are the increased dimensions, the complexity of the design and the presence of lateral gaps between the glass and the walls of the housing, on the one hand, the third partition and the walls of the housing, on the other hand, as well as the end leaks between the lower end of the glass, the third partition and persistent protrusions of the body. The flow of part of the measured liquid from the inlet cavity to the outlet, bypassing the glass, leads to an increase in the error and its instability during operation due to changes in the gaps due to clogging or aging of the plastic.

 The task to which this invention is directed is to create a simpler in design, durable, sensitive and stable water meter with the smallest possible error, with an interchangeable universal measuring mechanism and reduced overall dimensions.

 For this, in a liquid meter containing a recorder and a housing with inlet and outlet nozzles, in which there is a partition and a glass with an impeller, dividing the internal space into the inlet and outlet cavities, the glass has two diametrically located inlets and two diametrically located outlet openings, the partition consists of three parts, one located on one side of the longitudinal axis of the housing, the other on the other, and the third part is located between the glass and the outlet pipe, the partition with the glass and the walls of the casing forms a central cavity connecting to the inlet cavity and two side cavities connecting to the outlet cavity, the central cavity has two pockets located on both sides of the glass, one glass inlet connects its cavity to one pocket, the other to the other, and one outlet of the glass connects its cavity to one side cavity of the body, the other to the other side cavity, the glass has a circular groove above the holes, to which four side grooves are located, located on the side There is one groove on the surface between each two adjacent holes, on the end of the cup there are two end grooves that pair the side grooves in pairs, while the side surface and side grooves of the cup smoothly mate with the end and the end grooves respectively, a sealant is placed in the cup grooves, the cup is installed in the housing so that the side grooves and the end grooves connecting them are closed by the surfaces of the neck of the housing in the first and second parts of the partition, while the sealant is in contact with the walls of the ditches approx. glass and the surface of the neck of the body into which the glass is installed. The sealant is made in the form of a circular ring, to which two diametrically located branches adjacent to the circular ring are adjacent, the circular ring is laid in the circular groove of the cup, and both branches are laid in the side grooves and the end grooves connecting them in pairs.

 The proposed invention eliminates the disadvantages of the known meter [2] and allows you to create a simpler in design, durable, sensitive and stable liquid meter with the smallest possible error, with an interchangeable universal measuring mechanism and reduced overall dimensions.

The invention is illustrated by the accompanying drawings and graphs, where
in FIG. 1 shows a longitudinal section of the inventive counter;
in FIG. 2 shows a section along A - B - B - B - B - A;
in FIG. 3 shows a section along A - A;
in FIG. 4 shows a section along G - G;
in FIG. 5 shows a section along D - D;
in FIG. 6 presents a sealant;
in FIG. 7 shows a variant of the counter with an opening in the third part of the partition;
in FIG. 8 shows graphs of pressure drops for two flows arising as a result of their passage through the glass, and their ratios depending on the flow rate of the measured liquid;
in FIG. 9 shows graphs of the test results of four experimental samples of the measuring mechanism in one housing;
in FIG. 10 shows graphs of test results of the same four experimental samples of the measuring mechanism in another housing of the same design.

 The liquid meter consists of a housing 1 with inlet 2 and outlet 3 nozzles, in which a cup 4 with two diametrically located inlet openings 5 and 6 and two outlet openings 7 and 8 is installed perpendicular to the longitudinal axis, all openings are in one plane perpendicular to the axis of rotation of the impeller 9, placed in a glass 4. The glass 4 is closed by a lid 10 sealed with a rubber ring 11. A recorder 12 is installed on the lid 10. A glass 4 and a partition divide the internal space of the housing 1 into the input 13 and output 14 cavities. The partition consists of three parts. One part 15 is located on one side of the longitudinal axis of the housing 1, the other part 16 is on the other, and the third part 17 is located between the cup 4 and the outlet cavity 14. The partition together with the cup 4, the bottom and the walls of the housing 1 forms a central cavity 18 having pockets 19 and 20, located on both sides of the cup 4, and two side cavities 21 and 22, connected to the outlet cavity 14. On the cup 4 above the holes 5, 6, 7 and 8 there is a circular groove 23 in which the annular part of the rubber seal 24 is laid , and on the side surface between the holes and 5, 6, 7, and 8, four lateral grooves 25, 26, 27, and 28 are made adjacent to the circumferential groove 23. Groove 25 is connected to groove 26 by groove 29, and groove 27 is connected to groove 28 by groove 30. Grooves 29 and 30 are made at the end of the cup 4. The end of the cup 4 and the grooves 29 and 30 smoothly mate, respectively, with the side surface of the cup 4 and the grooves 25, 26 and 27, 28, and the neck of the housing 1 for installation of the cup 4 is processed along the contour of the side surface of the cup 4 and its pairing with the bottom end. The seal 24 is made in the form of a circular ring, to which two diametrically spaced branches adjacent to the circular ring are adjacent. The seal 24 is made of an elastic material, such as rubber. The circular ring of the seal 24 is laid in the circular groove 23 of the cup 4. In the grooves 25, 26 and 29 of the cup 4 one branch is laid, and in the grooves 27, 28 and 30 the other. The cup 4 is installed in the housing 1 so that the side grooves and the end grooves connecting them in pairs are closed by the surfaces of the neck of the housing in the first 15 and second 16 parts of the partition wall of the housing 1. The sealant overlaps the gaps between the housing 1 and the glass 4, hermetically separating the central cavity 18 with the side cavities 21 and 22 and excluding parasitic overflow of the measured liquid. The glass 4 is additionally sealed with rings 11 and 31, fixed in the housing 1 by a pin 32 through the hole 33 and secured by a flange 34 and bolts 35. A protective mesh 36 is installed in the inlet pipe 2 of the housing 1. An opening 37 can be made in the third part 17 of the partition wall of the housing 1, connecting the central cavity 18 with the outlet cavity 14. There may be several such openings.

 The fluid meter works as follows.

 The measured liquid through the grid 36 and the inlet pipe 2 enters the inlet cavity 13, the central cavity 18 and the pockets 19 and 20. One part of the flow of the measured liquid from the pocket 19 through the inlet 5 enters the cup 4, rotates the impeller 9 counterclockwise, through the outlet the hole 7 flows from the cup 4 into the right side cavity 21 and through the outlet cavity 14 and the outlet pipe 3 flows into the pipeline. Another part of the flow rate of the measured liquid from the pocket 20 through another inlet 6 enters the cup 4, rotates the impeller 9 also counterclockwise, through the outlet 8 flows from the cup 4 into the left side cavity 22 and through the outlet cavity 14 and the outlet 3 pipeline. The impeller turns 9 are scaled and presented by the recorder 12 as a measure of the measured liquid volume in cubic meters. Setting the counter is carried out by turning the cover 10 and is not accompanied by a loss of accuracy.

 Regulation without loss of accuracy and hermetic sealing of the gaps on the mating surfaces of the glass 4 and the housing 1 solve the problem of creating a stable counter with the least error.

 The task of creating a long-lasting and sensitive counter is solved by reducing the friction forces in the impeller bearings due to unloading from the hydrodynamic forces of its interaction with the measured fluid. This is achieved by dividing the total fluid flow into two streams. One thread rotates the impeller on one side, and the other on the other and in the same direction. As a result, the impeller forces from these flows are directed towards each other and cancel each other out. This is confirmed by the experimental test results shown in FIG. 8, where the curves "a" and "b" respectively represent the pressure drop in the section "pocket 19 - hole 5 - hole 7" and in the section "pocket 20 - hole 6 - hole 8", and curve "c" their quantitative ratio, which does not exceed the value of 1.12 in the flow range of the measured fluid from 0 to 70%. From this it follows that one part of the flow exceeds the other by no more than 12%, and the transverse force acting on the impeller supports 9 is only 9% of the transverse force arising in a single-jet meter of the same size. This solves the problem of increasing the sensitivity and bringing the life of the meter to the physical life of plastics, which is 10 ... 12 years.

 The glass 4, the impeller 9, the cover 10, the seal 24 and the flange 34, structurally integrated into a single module, are the measuring mechanism of the counter. The presence in it of the regulator - cap 10 makes its metrological characteristics independent of the housing, and the design in a single structural module allows its easy replacement directly at the installation site of the meter without removing the housing from the pipeline. This solves the problem of interchangeability of the measuring mechanism and reducing the cost of operating the meter. In the graphs of FIG. 9 and FIG. 10 presents the test results of four measuring mechanisms in two identical cases. On the graphs, the horizontal values of the flow rate in% are plotted, and the vertical values of the relative error in%. A comparative analysis of the graphs shows that when replacing the case, the error curves of all four measuring mechanisms remained almost within the same metrological class “B” [3], [4].

 In the third part 17 of the partition wall of the housing 1, one or more openings 37 can be made. In this case, a third stream arises from the inlet cavity 13 into the central cavity 18, through the opening (s) 37 into the outlet cavity 14. The flow rate of this flow increases the total flow rate of the measured liquid. If, accordingly, the gear ratio of the gearbox of the recorder 12 is changed, then the measuring mechanism can be used to measure the volume of liquid in the increased flow range. This solves the problem of the universality of the measuring mechanism.

 The combination of tasks according to the invention allows you to create a liquid meter with a new consumer quality, manifested in an increase in the calibration interval up to 10 ... 12 years (physical life of plastics) and the ability to replace the measuring mechanism directly at the meter installation site without removing the meter body from the pipeline instead traditional verification. This significantly reduces consumer operating costs.

Sources of information
1. The patent of Germany N 1116419, cl. G 01/03, 1959

 2. RF patent N 1778530, cl. G 01 F 1/06, 1993

 3. GOST P 50193.1 - 92.

 4. ISO 4064 - 1 &

Claims (2)

 1. A liquid meter comprising a recorder and a housing with inlet and outlet nozzles, in which there is a partition and a glass with an impeller is installed in its mouth perpendicular to the longitudinal axis, which separates together with the partition the interior of the housing into the inlet and outlet cavities and has two diametrically located inlets and two diametrically located outlet openings, characterized in that the partition consists of three parts, one of which is located on one side of the longitudinal axis of the housing, the other h part on the other side, and the third part is between the outlet pipe and the glass, which, together with the partition and the walls of the body, form two side cavities connecting to the outlet cavity, and a central cavity connecting to the inlet cavity and having two pockets located on both sides cup, each inlet of which connects its cavity with a corresponding pocket, and each outlet with a corresponding side cavity of the housing, the cup has a circular groove above the inlet and outlet openings, to which four longitudinal grooves are adjacent, located on the side surface of the glass, one groove between each two adjacent holes, and at the end of the glass there are two grooves pairwise connecting the longitudinal grooves, while the side surface and the longitudinal grooves of the glass smoothly mate with the end face and located on it grooves, which together with the longitudinal grooves are closed by the surfaces of the neck of the body, and a sealant is laid in the grooves of the glass for tight separation of the central cavity from the sides cavities.  2. The liquid counter according to claim 1, characterized in that the seal is made in the form of a ring laid in a circular groove of the glass, and two diametrically spaced branches adjacent to the ring and closed on it, laid in longitudinal grooves and pairwise connecting the grooves at the end of the glass .

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