前苏联专利SU1438629A3 Tangential turbine liquid flowmeter

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专利摘要:
A fluid flow meter having a paddle wheel rotatably mounted in a cylindrical cavity and an inlet conduit and an outlet conduit tangentially aligned with the periphery of the cavity for directing a fluid to flow through it. The paddle wheels's axis of rotation is displaced from the cavity's centerline, in the direction of the inlet conduit and substantially perpendicular to the flow of fluid entering the cavity, such that the flow meter operates effectively over an extended range of Reynolds numbers, spanning both turbulent and laminar flows.
公开号:SU1438629A3
申请号:SU833557635
申请日:1983-02-25
公开日:1988-11-15
发明作者:Паундер Эдвин；Павловский Майкл；Дж.Арена Алан；М.Тоттен Адриан
申请人:Дзе Кока-Кола Компани (Фирма)；
IPC主号:

专利说明:

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This invention relates to instrumentation engineering and can be used to measure the flow rate of liquids flowing through a pipeline.
The purpose of the invention is to improve accuracy.
FIG. 1 shows the design of the flow meter in FIG. 2; a flow diagram of the fluid for the turbulent regime; Q in FIG. 3 - the same for laminar flow.
The tangential turbine flowmeter includes a housing 1 with a cylindrical cavity 2. For supplying fluid j to the housing, an inlet channel 3 is provided, and an outlet channel 4 is provided for removal. Both channels are parallel to one another tangentially to the cylindrical cavity 2 in such a way passed through the cavity along the arc 180 in the same plane. In the cylindrical cavity 2 there is a crink 5, with four blades, the speed of which is measured by an optical sensor 6 located near the cavity 2 and producing signaling
The axis of rotation of the pinch 5 is displaced; FROM the longitudinal axis of the cylindrical-Q: bore 2 towards the inlet: channel 3, essentially perpendicular to the p-I-axis of the longitudinal axis of the inlet, | Part of the impeller projects into an imaginary continuation of the inlet to the cavity. The displacement of the impeller from the axis extends the range of Reynolds numbers in which the flow meter operates efficiently, and, in particular, provides the possibility of efficient operation of the flow meter, as in the case of a turbulent one, and in the case of a laminar flow regime. The inlet 3 and outlet 4 channels have a circular cross section, with the diameter of the inlet channel being approximately half the height of the cylindrical cavity 2, and the diameter of the exhaust channel is essentially equal to the height of the cavity. This difference in size minimizes throttling and reduces pressure losses during the passage of fluid through the flow meter.
The lump 5 has a diameter of about 60 percent of the diameter of a cylindrical cavity 2 and rotates around an axis that is offset from the center of the cavity towards the inlet channel 3. The axis of rotation is displaced by about one third of the distance
50
55
Q
0 5
Q Q
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five
the center of the cavity to the rim, shown by the dashed lyre 7, an imaginary continuation of the inlet channel. Thus, the impeller protrudes approximately half into the spectrum of the stream coming from the inlet channel 3,
The optical sensor 6 contains a light source 8 in the form of a light-emitting diode and a photodiode 9j located adjacent to each other in a recess 10 formed in the housing
1. The body is preferably made of transparent polycarbonate, which transmits light from said light source.
The flow meter works as follows.
The flow of fluid, the passage of the passage through the inlet (tangential) channel 3, causes the rotation of the crutch 5.
When the pinwheel 5 rotates, the ends (apexes) of its blades successively reflect light from the light emitting diode 8 to the photodiode 9. The frequency of the sitals at the output of the photodiode thus shows the angular velocity of the rotating wheel. Making the edge of a material with a high reflectance or coloring the ends of the blades with a paint with a high reflection coefficient increases the light intensity; reflected to the photodiode, and improves the sensor, especially when the fluid passing through the cavity 2 is opaque.
The displacement of the crinkle from the center of the cavity towards the inlet channel greatly expands the range of Reynolds numbers in which the flow meter operates efficiently in both the turbulent and laminar flow regimes. Moving the axis of rotation of the eyelet towards the inlet channel 3 expands the operating range of the flowmeter to currents with lower Reynolds numbers.
FIG. 2 and 3 schematically show views of a cylindrical cavity.
2, showing the flow pattern for a very large Reynolds number and turbulent flow (FIG. 2), for a very small Reynolds number well below the critical Reynolds number (the transition numbers between the lami- nard and turbulent regimes are; flows), You can see that with turbulent flow, a vortex is created in the cavity, whereas with laminar flow with
with a small Reynolds number, there is no vortex and the fluid flows directly from the inlet channel 3 to the outlet channel 4. Placing the impeller 5 in the indicated position ensures its rotation by the moving fluid in the same counterclockwise direction for currents covering the entire range of states shown in FIG. 2 and 3,
F
ten
formula of invention
The tangential turbine flowmeter of the fluid, comprising a housing with a cy- 15 intersects the impeller blade in its lindric cavity and the tangentially middle part.
5I are separated by inlet and outlet cylindrical connections to it, in the housing cavity on the following: four-bladed crinkles are located on the supports, and the signal pickup assembly is located on the building where the axis of rotation of the impeller is offset relative to the axis of the cylindrical cavity at 1/3 of the distance between it and the line, which is a continuation of the nearest wall of the inlet nozzle, in this case indicated
0
5 crosses the impeller blade in its middle part.
5I spaced to it by spaced inlet and outlet cylindrical nozzles, in the housing cavity on the podsphniko: four-bladed crinkle is located on the supports, and on the body there is a signal pickup unit, a cylindrical cavity 1/3 the distance between it and the line, which is a continuation of the nearest wall of the inlet nozzle, with the indicated line
(fms.2
Compiled by V.Andreev Editor A.Makovska -Tehred M.Uodanić
Order 5975/59
Circulation 717
, VNIIPI USSR State Committee
for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5
- 3
cftasS
Proofreader N.Korol
Subscription

权利要求:
Claims (1)
[1]
The claims of the tangential turbine fluid flow meter containing a housing with a cylindrical cavity and tangentially
I438629 spaced inlet and outlet cylindrical pipes located to it, in the body cavity on the bearing bearings there is a four-bladed impeller, and on the body there is a signal pickup unit, characterized in that, in order to improve accuracy, the rotation axis of the impeller Yu is 1 relative to the axis of the cylindrical cavity / 3 the distance between it and the line, which is a continuation of the nearest wall of the inlet pipe, while the specified line 15 intersects the impeller blade in its middle part.

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同族专利:

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US4440030A|1984-04-03|

AT23060T|1986-11-15|

AU1092983A|1983-09-01|

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DE3367119D1|1986-11-27|

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ZA83935B|1984-09-26|

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US1070470A|1912-06-26|1913-08-19|Hixon Automatic Valve Company|Water-meter.|

US1397502A|1920-11-17|1921-11-22|Cormany Ralph Blancett|Combined recorder and register|

BE631002A|1959-06-29|

US3329021A|1964-10-05|1967-07-04|Itt|Fluid flow meter|

US3546940A|1968-07-18|1970-12-15|Combustion Eng|Turbine meter|

GB1402159A|1972-12-13|1975-08-06|Rhodes & Son Ltd B|Rotary fluid flowmeter|

DE2502599A1|1975-01-23|1976-07-29|Werner Kuerlemann|Flow-meter for IC engine's fuel supply - has rotor positioned in chamber with tangential input and output|

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US4173144A|1978-04-03|1979-11-06|Transdynamics|Low flow rate transducer construction|US4467660A|1982-03-29|1984-08-28|Mcmillan Jr Robert D|Turbine wheel flow measuring transducer|

US4590805A|1984-10-26|1986-05-27|Baird Controls, Inc.|Ultrasonic impeller flowmeter|

US4821925A|1987-05-14|1989-04-18|The Coca-Cola Company|Narrow, multiflavor beverage dispenser valve assembly and tower|

US4825708A|1987-10-19|1989-05-02|Sevick Peter M|Fiber optic velocity sensor/flow meter|

US5381926A|1992-06-05|1995-01-17|The Coca-Cola Company|Beverage dispensing value and method|

GB9412043D0|1994-06-16|1994-08-03|Powell Anthony|Liquid dispensers|

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US8069719B2|2009-02-11|2011-12-06|Ecolab Usa Inc.|Gear flow meter with optical sensor|

US8166828B2|2010-08-06|2012-05-01|Ecolab USA, Inc.|Fluid flow meter|

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US10598682B2|2016-02-12|2020-03-24|Board Of Trustees Of Michigan State University|Laser system for measuring fluid dynamics|

US10260918B2|2017-04-21|2019-04-16|Pixart Imaging Inc.|Flow amount measuring apparatus, material mixing system and non transitory computer readable medium performing material mixing method|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

US06/352,534|US4440030A|1982-02-26|1982-02-26|Fluid flow meter|

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