The invention relates to a method for determining volume- or mass-flow, e.g. volume- or mass-flow rate, of a medium in a pipeline, or in a measuring tube, via a sound entrainment method.
From U.S. Pat. No. 3,940,985, an ultrasonic flow measuring device is known, in which volumetric flow rate of a medium flowing in a pipeline is measured radius-dependently. In this known solution, a plurality of pairs of ultrasonic sensors are arranged on the periphery of a measuring tube. These ultrasonic sensors deliver measurement data concerning flow velocity of the medium in different segments of the measuring tube. For ascertaining the volume flow of the medium through the pipeline, the measurement data from the individual measuring paths are integrated with suitable weighting.
From WO 97/19326, an ultrasonic flow measuring method is known, in which velocity of a medium flowing in a pipeline is ascertained along different measuring paths of an ultrasonic flow measuring device. In order to improve measurement accuracy, viscosity changes measurement are considered in the flow measurement. Changes in viscosity of a medium are caused by temperature changes, for example. In order to take such into consideration, it is proposed in WO 97/19326 to determine, by measuring the Reynolds number, a correction factor, with which the flow profile dependence of the flow measuring device can be compensated. For ascertaining the Reynolds number in WO 97/19326, the ratio of the flow velocities measured in the different measuring paths is used. In this known solution, a correction of the flow profile dependent measurement error is, thus, only possible, when, first, the Reynolds number is explicitly ascertained or measured. Such a method is relatively complex, both in the calibration phase and in the subsequent, measurement operation.
An object of the invention is to provide a cost-effective method for highly accurate ascertaining of volume- or mass-flow through a pipeline by means of a flow measuring device utilizing a plurality of measuring paths.
The object is achieved by the following features: That ultrasonic measuring signals are transmitted and/or received along a plurality of defined measuring paths of a pipeline, or measuring tube; that, in the pipeline, or measuring tube, successive, different, flow profiles of a measured medium are established; and that, for each flow profile, a defined volume flow, or a defined mass flow, is ascertained. Each flow profile established in the pipeline, or measuring tube, is described by a characteristic parameter set on the basis of measured values ascertained in the individual measuring paths. On the basis of the ascertained measured values in the individual measuring paths, a measured volume- or mass-flow is derived. Additionally, for each flow profile, on the basis of the defined volume- or mass-flow, and on the basis of the measured volume- or mass-flow, a flow profile dependent correction factor is calculated, with which, subsequently, in measurement operation, a volume- or mass-flow of the flow measuring device ascertained via the parameter set is corrected. The method of the invention rests, stated in basic terms, on an analytic description of the flow profile of the medium flowing through the pipeline.
Especially, it is provided that the flow profile ascertained on the basis of the measured values in the individual measuring paths is approximated by a function. In the simplest case, the flow profile is described by a polynomial. For example, a rotationally symmetric flow profile can be described by a function of the form v(r)=(vmax, a1, . . . , an with nεN). Here, v(r) is the flow velocity of the medium at a distance r from the longitudinal axis of the measuring tube, vmax is the maximum flow velocity of the medium in the region of the longitudinal axis of the pipeline, and a1, . . . , an are the parameters of a suitable fit-function describing the flow profile with sufficient accuracy. Basic forms, or ansätze, for suitable functions are available in the literature. For example, various ansätze are presented in the book of Gätke entitled “Akustische Strömungs- und Durchfluss-messung” (“Acoustical Flow-Measurements”).
During the calibration phase, the velocities vx(r1) . . . vx(rm) in the flow paths are ascertained for each flow profile x, where m stands for the number of measuring paths. These measured velocities thus correspond to the velocities of the medium in the individual m segments of the pipeline, or measuring tube. On the basis of the m measured values, a fit-curve with the parameters a1, . . . , an can be determined with the desired accuracy via an error balancing calculation, such as a least squares method. Successively, for each flow profile vx(r), a corresponding parameter set a1, . . . , an is determined. Via a calibration with a second measuring device having a defined accuracy of measurement, a correction factor MF(a1, . . . , an) is determined for each parameter set a1, . . . , an. Via this correction factor MF(a1, . . . , an), it is possible to compensate the flow dependence of the flow measuring device. Of course, a sensible number of parameters a1, . . . , an depends on the number of measuring paths available. In principle, it can be said that the function is a better description of the actual flow profile, the more measuring paths are available for measuring the flow velocity and thus for measuring the flow profile.
The invention will now be explained in greater detail on the basis of the drawing, the figures of which show as follows:
According to the invention, the measured values, delivered from the different measuring paths m and describing the flow profile of the medium 2 sufficiently accurately, are approximated by a fit-curve, which, in turn, is describable sufficiently accurately by a parameter set a1, . . . , an. In the case of a rotationally symmetric flow profile, the fit-curve has preferably the form v(r)=(vmax, a1, . . . , an with nεN), wherein vmax represents the flow velocity of the measured medium 2 in the region of the longitudinal axis.
By means of an ultrasonic flow measuring device 6 utilizing a plurality of measuring paths m, at point 11 the radius-dependent flow profile vx(r) is ascertained; at point 12, each flow profile vx(r) is described by a suitable fit-curve, or by a suitable parameter set. On the basis of the measured flow profile vx(r), the currently measured volume flow is ascertained.
Then, at program point 13, the volume flow ascertained by means of the plural-path flow measuring device 6 is compared with a reference volume flow of a reference flow measuring device. In the case of a difference between the measured volume flow and the volume flow defined via the calibration, a correction factor MF(a1, . . . , an) for the corresponding flow profile v(r), or for the parameter set a1, . . . , an describing the flow profile v(r) is determined and appropriately stored. This method step occurs at program point 14.
Number | Date | Country | Kind |
---|---|---|---|
102005018396.4 | Apr 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2006/061684 | 4/20/2006 | WO | 00 | 1/5/2009 |