Vibratory limit switch configuration and a process for correcting the switching point of a vibratory limit switch

Abstract

The invention relates to a vibratory limit switch configuration and to a process for operating such a configuration, with a fork (2); a transmitting and/or receiving device (3) for generating a vibration (w(fr)) for the fork as dependent on an exciter signal, and for receiving a vibration from the fork and for generating a reception signal (e) as dependent on the received vibration; and a control device (4) for providing the exciter signal and/or for processing the reception signal, where a device (8, 8*) is provided for detecting the temperature (T) of the fork or the temperature (T) of a space adjacent to the fork.

Description

An exemplary embodiment will next be described in greater detail on the basis of the drawing. Shown are:

FIG. 1 a partial section of a container, with individual components belonging to a vibratory limit switch configuration, to graphically depict the basic principle of operation

FIG. 2 a diagram depicting the influence of immersion depth on the vibrating frequency of a fork

FIG. 3 a fork frequency in air and switching thresholds with and without tracking.

Claims

1. A vibratory limit switch configuration (1) or vibratory fill-level measuring configuration with a vibrating unit (2),a transmitting and/or receiving device (3) for generating a vibration for the vibrating unit as dependent on an exciter signal and for receiving a vibration from the vibrating unit and generating a reception signal as dependent on the received vibration,a control device (4) for providing the exciter signal and/or for processing the reception signal (e), andan evaluation device for processing the vibrating frequency,whereina temperature detector (8, 8*) is provided for detecting the temperature (T) of the vibrating unit, or of a space adjacent to the vibrating unit.

2. A configuration in accordance with claim 1, whereinthe vibrating unit is a fork (2).

3. A configuration according to claim 1, wherein the space adjacent to the vibrating unit is the interior of a container with a filling medium (6), whose limit or fill level is detected by the configuration.

4. A configuration according to claim 2, whereinthe temperature detector is a temperature sensor in the interior of the container.

5. A configuration according to claim 1, whereinthe temperature detector (8) is a temperature sensor which is connected to the vibrating unit or is installed between the vibrating unit and the vibratory transmitter and/or receiver.

6. A configuration according to claim 1, whereina correcting device is provided for correcting a temperature-dependent change in a switching point, such that the correcting device takes the form of the evaluating device.

7. A configuration with a storage device (9) for storing fork parameters associated with the vibrating unit in the form of a fork, inclusive of an elasticity module (E) for the fork material used for executing of the temperature-dependent change in a switching point frequency.

8. A configuration according to claim 5, whereinthe correcting device is designed to incorporate a density change in the filling material (6) as dependent on the temperature (T).

9. A process for correcting the switching point of a vibratory limit switch, in which a control device (4) generates an exciter signal for exciting a vibratory transmitter, such thatthe vibration of the transmitter is transmitted to a vibrating unit (2) in the interior of a container (5), anda correction in the switching point is performed,whereinthe temperature (T) of the vibrating unit, or of the space adjacent to the vibrating unit, is determined and is used by the evaluating device (4) for correcting the switching point frequency.

10. A process according to claim 9, whereinthe vibrating unit is a fork (2).

11. A process according to claim 9, whereina switching point displaced toward the filling material with a rising temperature is corrected by the temperature-dependent compensation of the switching point frequency.

12. A process according to claim 9, whereinan uncovered frequency of the uncovered vibrating unit in the air is identified, and a covered frequency and the switching point frequency are calculated as a dependent on the adjusted density (ρ) of the filling material.

13. A process according to claim 9, whereinthe temperature-dependent elasticity module (E) of the vibrating unit is taken into account in evaluating the reception signal.

14. A process according to claim 9, whereinparameters are stored in a memory (9) in the process of calibrating the vibratory limit switch configuration and/or before customer startup, such that said parameters influence the switching point frequency as dependent on the temperature (T).

15. A process according to claim 9, whereina change in the density (ρ) of the filling material (6) caused by temperature (T) is incorporated into the calculation of the switching point frequency, specifically for that case in which the filling material in the container (5) remains unchanged.