Measuring and testing – Liquid level or depth gauge – Immersible electrode type
Reexamination Certificate
2000-12-20
2002-11-19
Larkin, Daniel S. (Department: 2856)
Measuring and testing
Liquid level or depth gauge
Immersible electrode type
C073S313000, C340S618000
Reexamination Certificate
active
06481276
ABSTRACT:
FIELD OF THE INVENTION
The present invention relates to a device for measuring the filling level of a filling material in a container.
BACKGROUND OF THE INVENTION
In order to determine the filling level of a filling material in a container, use is made of measuring systems which measure different physical variables. The desired information on the filling level is subsequently derived with the aid of these variables. In addition to mechanical scanners, use is made of capacitive, conductive or hydrostatic measuring probes, and of detectors which operate on the basis of ultrasound, microwaves or radioactive radiation.
In the case of capacitive measurements for determining the filling level of a filing material in a container, the capacitive probe and container wall form the electrodes of a capacitor. If the container wall is not conductive, a separate second electrode must be provided inside or outside the container. Depending on the filling level of the medium in the container, either air or a medium is located between the two electrodes, and this is reflected in a change in the measuring capacity because of the different dielectric constants of the two substances. Furthermore, the measuring capacity is, of course, also a function of the respective filling level of the medium in the container, since the two variables of “filling level” and “measuring capacity” depend upon one another functionally. Capacitive probes can therefore be used both in the detection of limit levels and in a continuous determination of filling levels. A capacitive filling level probe has been disclosed, for example, in German Patent No. 195 36 199 C2.
In run-time methods with guided electromagnetic radio-frequency pulses (TDR method or pulsedradar method) or with continuous, frequency-modulated microwaves (for example FMCW radar method), the measuring signals are coupled onto a conductive element or a waveguide and introduced by means of the waveguide into the container in which the filling material is stored. Consideration is given as waveguides to the known variants of Sommerfeld or Goubau surface waveguides or Lecher waveguides.
From a physical point of view, in this measurement method the effect is utilized that because of the sudden change (discontinuity) in the dielectric constants of the two media at the interface between two different media, for example air and oil or air and water, some of the guided radio-frequency pulses or of the guided microwaves are reflected and led back into a receiving device via the conductive element. The reflected component (→useful echo signal) is larger in this case the greater the difference in the dielectric constants of the two media. The distance to the surface of the filling material can be determined with the aid of the run time of the reflected component of the radio-frequency pulses or the CW signals (echo signals).
Certain advantages, but also disadvantages, by comparison with the respective other method are to be seen in a direct comparison between a capacitive measuring system and a measuring system having guided electromagnetic measuring signals. Specifically, measurements of a capacitive sensor are virtually insensitive to a moving surface of the filling material. Furthermore, the measurements are not influenced appreciably either by foaming filling materials nor by the formation of a deposit on the capacitive sensor. However, in order to be able to carry out the filling level measurement with high accuracy it is necessary to calibrate the capacitive measuring system for at least two levels, and this can be very time-consuming, depending on the size of the container and the filling material, or is ruled out in the extreme case of the use of a capacitive sensor. A further disadvantage of capacitive measuring systems is to be seen in that the measurement is a function of the respective dielectric constants in the case of a nonconductive filling material.
The fact that filling level measurements are not possible in the region of the so-called block distance since the useful echo signals disappear here into interference signals is critical in the case of a measuring system with guided high-frequency measuring signals. The interference signals are caused, for example, by reflections of the measuring signals in the region of the coupling of the measuring signals onto the conductive element, or they occur as a consequence of the interaction of the measuring signals with a stub in which the measuring system is fastened (upper block distance). A further interference signal limiting the possible measuring range occurs at the free end of the conductive element (lower block distance).
By contrast, in the case of measuring systems having guided radio-frequency measuring signals it is very advantageous that they deliver highly accurate measurement results, and that there is usually no need for calibration, in particular no two-point calibration as in the case of capacitive measuring systems. Furthermore, measurement by means of guided measuring signals is largely independent of the respective dielectric constant of the filling material; moreover, a measuring system having guided radio-frequency measuring signals still functions acceptably even for relatively small dielectric constants.
SUMMARY OF THE INVENTION
It is the object of the present invention to provide a device which permits optimized determination of the filling. level and/or monitoring of the filling level in a container.
The object is achieved by virtue of the fact that the device comprises a sensor and a control/evaluation unit, the sensor being designed such that it is operated in conjunction with at least two different measurement methods and/or the sensor is operated in at least two different operating modes, the control/evaluation unit operating the sensor respectively according to one of the two measurement methods and/or in one of the two operating modes, and the control/evaluation unit determining the filling level of the filling material in the container with the aid of the measured data of the sensor, which are supplied via at least one measurement method and/or during at least one operating mode. The solution according to the invention provides that the measured values are obtained via the capacitive measurement method or via the method having guided radio-frequency measuring signals either alternatingly, arbitrarily offset in time or simultaneously, that is to say in a quasi-parallel fashion. It is therefore possible, for example, to achieve optimized adaptation of the measuring system to the properties of the filling material respectively to be measured; moreover, it is possible respectively to make use for the purpose of obtaining measured values of that measuring system which delivers the best measurement results under the given conditions. If the measured values from the capacitive measuring system and the measuring system having guided measuring signals occur closely together in time, it is possible, however, even to carry out a plausibility check.
The device according to the invention is distinguished, in particular, by virtue of the fact that highly accurate filling level measurements are possible over the entire height of the container, the measured values respectively used being virtually uninfluenced by the nature and the type of the filling material respectively to be measured. The highly accurate measurements over the entire height of the container are rendered possible by virtue of the fact that one method is, or can be, always replaced by the respective other method whenever the disadvantages of the respective other measuring system come to bear. It is, moreover, possible to correct the measured values which one system delivers with the aid of the measured values which the other measuring system delivers. Furthermore, the possibility is provided of, for example, undertaking to calibrate the capacitive measuring system via the measured values which are delivered by the measuring system having guided measuring signals.
In accordance with a preferred development of the device
Grittke Udo
Krause Michael
Neuhaus Joachim
Wartmann Gerd
Endress + Hauser GmbH + Co.
Jones Tullar & Cooper P.C.
Larkin Daniel S.
Wilson K
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