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A method wherein vortices are produced in a flowing fluid by means of a bluff body and the repetition frequency with which the vortices are produced is determined. The repetition frequency is used to determine a flow rate measurement value, which represents a volume flow or a flow velocity. Additio

A method wherein vortices are produced in a flowing fluid by means of a bluff body and the repetition frequency with which the vortices are produced is determined. The repetition frequency is used to determine a flow rate measurement value, which represents a volume flow or a flow velocity. Additionally, pressures p1 and p2 acting in the flowing fluid at two measurement points separated from one another in the flow direction are registered. At least one of these pressures changes at least as a function of the repetition frequency. The registered pressures p1, p2 are used to produce a pressure measurement value, which represents an average dynamic pressure acting in time average at least partly in the flow direction. The pressure measurement value and the flow rate measurement value are used to determine a mass flow rate value for the fluid.

대표청구항 ▼

What is claimed is: 1. A method for determining a mass flow rate of a fluid flowing in a pipe, comprising the steps of: producing vortices, especially Karman vortices, in the flowing fluid by means of a bluff body around which the fluid flows, the bluff body having at least two separation edges, an

What is claimed is: 1. A method for determining a mass flow rate of a fluid flowing in a pipe, comprising the steps of: producing vortices, especially Karman vortices, in the flowing fluid by means of a bluff body around which the fluid flows, the bluff body having at least two separation edges, and determining a repetition frequency with which the vortices are produced; producing, on the basis of the determined repetition frequency, a flow rate measurement value, which represents a volume flow rate or a flow velocity; local registering of a first pressure, p1, acting in the flowing fluid at a first measurement point, which is located, with reference to the flow direction, by the two separation edges of the bluff body or downstream from at least one of the separation edges; local registering of a second pressure, p2, acting in the flowing fluid at a second measurement point separated from the first measurement point in the flow direction: wherein, by the action of the generated vortices, at least one of the registered pressures, p 1, p2, changes periodically at least with the repetition frequency; and producing, using the registered first pressure, p1, and the registered second pressure, p2, a pressure measurement value that represents an average dynamic pressure acting, averaged over time, at least partly in the flow direction, as well as producing, using the pressure measurement value and the flow rate measurement value, a mass flow rate measurement value a mass flow rate measurement value representing the mass flow. 2. The method as claimed in claim 1, wherein: the repetition frequency, with which the vortices are produced, is determined on the basis of at least one of the registered pressures p1, p2. 3. The method as claimed in claim 1, wherein: at least one of the measurement points is arranged at the bluff body or inside of the same. 4. The method as claimed in claim 1, wherein: a pressure difference between the two locally registered pressures is determined for producing the pressure measurement value. 5. The method as claimed in claim 3, wherein: a differential pressure sensor, especially one arranged within the bluff body, is exposed, especially simultaneously, to the first and second pressures, p1, p2, for registering the pressure difference. 6. The method as claimed in claim 4, wherein: a pressure difference signal is derived from the locally registered pressures, p1, p2, to represent the pressure difference. 7. The method as claimed in claim 6, wherein: the pressure difference signal is digitized for producing the pressure measurement value. 8. The method as claimed in claim 6, wherein: the pressure measurement value and/or flow rate measurement value is/are determined on the basis of a spectral analysis, especially a digital spectral analysis, of the pressure difference signal. 9. The method as claimed in claim 1, wherein: one of the locally registered pressures p1, p2 is a total pressure acting in the flow direction and/or a static pressure acting in the fluid. 10. The method as claimed in claim 1, wherein: a sensor element in the form of an oscillating body arranged within, or downstream from, the bluff body is used for determining the pressure difference. 11. A method for determining a viscosity of a fluid flowing in a pipe, which method includes the steps of: producing vortices, especially Karman vortices, in the flowing fluid by means of a bluff body around which the fluid flows, the bluff body having at least two separation edges; local registering of a first pressure, p1, acting in the flowing fluid at a first measurement point, which is located, with reference to the flow direction, by the two separation edges of the bluff body or downstream from at least one of the separation edges; local registering of a second pressure, p2, acting in the flowing fluid at a second measurement point separated from the first measurement point in the flow direction, wherein, by action of the generated vortices, at least one of the registered pressures p1, p2, changes periodically at least with a repetition frequency with which the vortices are produced; and producing, using the registered first pressure, p1, and the registered second pressure, p2, a pressure measurement value that represents an average dynamic pressure acting, averaged over time, at least partly in the flow direction, as well as producing, using the pressure measurement value, a viscosity measurement value representing the viscosity to be measured. 12. The method as claimed in claim 11, further comprising steps of: oscillating a sensor element, which is disposed in the pipe downstream from the separation edges, with said repetition frequency; determining a deflection of said sensor element and producing a deflection measurement value, which represents a instantaneous deflection of said sensor element; and using said deflection measurement value to determine said viscosity measurement value. 13. The method as claimed in claim 12, further comprising a step of: dividing said deflection measurement value by said pressure measurement value. 14. The method as claimed in claim 12, wherein: the deflection measurement value represents a maximum deflection of said sensor element.