RU150883U1 - STAND FOR CALIBRATION AND VERIFICATION OF RADAR LEVELS - Google Patents

Abstract

1. A stand for calibrating and calibrating radar level gauges, including a plate with a stand fixed to it, which is configured to mount a radar level gauge on the stand, a reflector, and means for measuring the distance from the reference point to the reflector, characterized in that the said distance measuring means is made in a laser rangefinder mounted on a rack with the ability to project a laser beam onto the surface of the reflector. 2. The stand according to claim 1, characterized in that the stand is configured to mount a radar waveguide level gauge on it. 3. The stand according to claim 2, characterized in that the plate is equipped with dielectric stops to accommodate a sensitive element of the radar waveguide level gauge on it. 4. The stand according to claim 2, characterized in that the reflector is arranged to accommodate a radar waveguide level gauge on a sensitive element and to move horizontally along the sensitive element.

Description

The utility model relates to means for calibrating and calibrating radar range meters and can be used to determine the metrological characteristics of radar waveguide level gauges.

As the closest analogue of the claimed technical solution, a stand for calibration and calibration of radar level gauges was adopted, comprising a movable stand mounted on a plate of a horizontal displacement device and configured to mount a level gauge, a fixed stand, a reflector mounted on a fixed stand perpendicular to a straight line passing through the centers of the reflector and a level gauge, and a means of measuring the distance from the movable stand (from the origin) to the reflector, made in the form of a measuring tape. The reference points on the measuring tape are determined using two sighting plumb lines, one of which is connected to the level gauge, and the second to the reflector [Description of the calibration stand of the IGND.407619.001 level gauges. State register of measuring instruments No. 18237-99].

A disadvantage of the known stand is the low accuracy of calibration and verification, due to the large error in measuring the distance between the level gauge and the reflector when using a measuring tape and sighting plummet.

The technical result of the utility model is to increase the accuracy of calibration and verification of radar level gauges by reducing the error in measuring the distance between the radar level gauge and the reflector.

The specified technical result is achieved by the fact that in the stand for calibration and calibration of radar level gauges, including a plate with a rack mounted on it, which is configured to mount a radar level gauge on the rack, a reflector and means for measuring the distance from the reference point to the reflector, said distance measuring means in the form of a laser range finder mounted on a rack with the possibility of projecting a laser beam onto the surface of the reflector.

The specified technical result is also achieved by the fact that the rack is configured to install a radar waveguide level gauge on it.

The specified technical result is also achieved by the fact that the plate is equipped with dielectric stops to accommodate a sensitive element of the radar waveguide level gauge on it.

The specified technical result is also achieved by the fact that the reflector is arranged to place a radar waveguide level gauge on the sensitive element and to move horizontally along the sensitive element.

The utility model is illustrated in the figure. In FIG. 1 schematically shows a stand for calibration and calibration of radar level gauges.

The stand includes a plate 1 with a stationary rack 2 vertically mounted on it for mounting on a rack 2 of a radar level gauge, for example, a radar waveguide level gauge 3. In this case, the radar waveguide level gauge 3 is attached to the rack 2 with its flange, and an extended sensitive element (steel waveguide) 4 the level gauge 3 is located horizontally above the plate 1 and supported on it by means of dielectric stops 5, evenly distributed along the length of the sensing element 4.

A flat metal reflector 6 is placed on the sensing element 4 by means of the upper and lower brackets 7 and is in contact with it. The upper bracket 7 may be part of the reflector 6.

The reflector 6 is made in such a way that its frontal plane is simultaneously reflective for an electromagnetic pulse of low tension and short duration (fractions of a nanosecond) propagating along a sensitive element (waveguide) 4 and for a laser beam.

In the upper part of the rack 2, a laser range finder 8 is installed with a wide measuring range (for example, up to 15 m) and a small measurement error, for example, no worse than ± 0.05 mm / m, projecting a laser beam onto the surface of the reflector 6. When installing the range finder 8, the reference plane of the reference distance to the installation plane of the flange of the level gauge 3.

The inventive stand works as follows.

A low-intensity electromagnetic pulse lasting in fractions of a nanosecond propagates along the sensitive element (waveguide) 4 of the level gauge 3. When reaching the reflector 6, the pulses are reflected from it and returned back, the level gauge records the propagation time of the pulse (pulse travel time “back and forth”).

The distance from the reference point (from the mounting plane of the flange of the level gauge) to the plane of the reflector 6 is measured using a laser range finder 8, taking into account the previously known distance from the output plane of the range finder (from the "reference point") to the mounting plane of the flange of the level gauge, and the distance thus determined is set in accordance with the pulse propagation time. The result is a point on the calibration curve of the level gauge.

Next, the reflector 6 moves along the length of the sensing element 4 and the above procedure is repeated for other points of the measuring range of the level gauge. Based on the results obtained, a calibration curve is constructed or a level gauge is calibrated.

The use of a laser range finder as a means of measuring the distance between the level gauge and the reflector allows, in comparison with the closest analogue, to significantly reduce the distance measurement error and, as a result, to increase the accuracy of calibration and calibration of radar level gauges, in particular, waveguide radar level gauges.

Claims (4)

1. A stand for calibration and verification of radar level gauges, including a plate with a stand fixed on it, which is configured to mount a radar level gauge on the stand, a reflector, and a means for measuring the distance from the reference point to the reflector, characterized in that said distance measuring means is made in a laser rangefinder mounted on a rack with the ability to project a laser beam onto the surface of the reflector. 2. The stand according to claim 1, characterized in that the stand is made with the possibility of installing a radar waveguide level gauge on it. 3. The stand according to claim 2, characterized in that the plate is equipped with dielectric stops to accommodate a sensitive element of the radar waveguide level gauge on it. 4. The stand according to claim 2, characterized in that the reflector is arranged to accommodate a radar waveguide level gauge on a sensitive element and to move horizontally along the sensitive element.

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