RU2298770C1 - Test bench for testing and tuning radar level meters - Google Patents

Abstract

FIELD: radio engineering; radar quality control.

SUBSTANCE: device has upright 1 bearing level gauge 2 fastened on it, support 3, flat reflector 4 fixed on support 3, horizontal motion device 7 having platform, means 8 for measuring distance (8) from selected reference mark (O) to flat reflector 4, additional reflector 9 and screen 10 manufactured from radioabsorbing material. Support 3 is placed on platform of horizontal motion device 7 for changing distance (8) from a reference mark (O) to flat reflector 4. The screen 10 is mounted on carriage means 11 for horizontally moving it, the carriage being rigidly connected to horizontal motion device 7 via connector 12. Additional reflector 9 having quadric surface shape is mounted on upright 1. To reduce the number of reflections from additional reflector 9, two auxiliary screens as radioabsorbing curtains 14 are introduced. Chambers and their costs at simultaneous reduction of an error of measurements.

EFFECT: reduced test bench and anechoic chamber sizes; reduced production costs.

8 cl, 3 dwg

Description

The invention relates to antenna technology and can be used for certification, verification and calibration of radar range meters.

A known installation for primary and periodic verification of industrial level gauges "MICROPILOT" containing a measuring tape, a support for the level gauge, made with the possibility of discrete movement and orientation of the level gauge normal to the reflective wall [1].

The specified installation does not provide the performance necessary in an industrial environment and cannot provide a measurement of the resolution of the level gauge in range.

A number of measuring devices are known for measuring the scattering characteristics of radar targets [2, 3], containing reflectors of a given shape, placed on weakly reflecting supports covered by radar absorbing material (RPM), radar meters and devices for changing the coordinates of reflectors.

The listed measuring installations cannot provide a low error in measuring the accuracy characteristics of level gauges in a wide range of ranges. For industrial level gauges, the permissible measurement error is units and fractions of millimeters, and the required range of measured ranges is from tens of centimeters to tens of meters, which significantly exceeds the size of the working zones of known measuring systems.

The closest set of essential features to the proposed device is the NIIIS stand IGND.407619.001 for adjusting and calibrating radar level gauges, comprising a movable stand mounted on a plate of a horizontal moving device and configured to mount a level gauge, a support (or other stand) made with the possibility of stationary installation, a flat reflector mounted on a support perpendicular to a straight line passing through the centers of the flat reflector and the antenna aperture ovnemera during its calibration, the measurement means the distance from the rack to a plane reflector in the form of a measuring tape [4].

A well-known stand for many level gauges has insufficient measurement accuracy in a wide range of ranges. The indicated drawback is common for measuring installations and is caused by the scattering of waves on a support with a flat reflector and the reflection of waves from the surfaces of the bench hall or anechoic chamber. It is known that in order to ensure a measurement error equal to units and fractions of a millimeter, the level of the parasitic reflected field should not exceed -40 ...- 60 decibels. It is also known [3, p.138-143] that it is almost impossible to perform a non-reflective support with a horizontal movement device, the strength of which can provide a measurement error not exceeding fractions of a millimeter. It is known [2] that in order to reduce reflections from the walls of the anechoic chamber, it is necessary, first of all, to increase its size in proportion to the size of the working area, which leads to an increase in cost and, in addition, to the need to increase the height of the support with a flat reflector. However, an increase in the height of the support should be accompanied by an increase in its strength, an increase in the level of the reflected interfering field, and, accordingly, an increase in the error.

The technical result of the invention is to reduce the size of the stand, anechoic chamber and their cost while reducing measurement error.

The technical result is achieved by the fact that in the calibration test stand of the level gauges, comprising a stand made with the possibility of fastening the level gauge, a support, a flat reflector, a flat reflector mounted on a support perpendicular to a straight line passing through the centers of the flat reflector and the aperture of the level gauge’s antenna during its adjustment and verification, the device horizontal movement, a means of measuring the distance from the reference to the flat reflector, an additional reflector and a screen made of radar absorbing material are introduced, the support is placed on the horizontal movement device for discrete changes in the distance from the reference point to the flat reflector, the screen is made with the possibility of horizontal movement simultaneously with the movement of the support to shield its surface below the flat reflector, and the distance from the flat reflector to the screen is at least two resolution distances of the level gauge, an additional reflector is mounted on a rack and made in the form of a second-order surface with a radius of curvature 2-4 times greater than m the maximum distance between the centers of the flat and additional reflectors, and the rack and additional reflector are made with corresponding through holes for mounting the antenna of the level gauge.

Preferably, the additional reflector is made in the form of a spherical mirror with an aperture size twice the size of a flat reflector.

It is possible to make an additional reflector in the form of a cylindrical mirror with a vertical aperture size twice the vertical size of a flat reflector and a horizontal size equal to the horizontal size of a flat reflector.

It is preferable to install the screen with the ability to change the distance to the flat reflector by an amount not less than half the maximum wavelength of the level gauge at an arbitrary fixed distance between the flat reflector and the stand.

It is advisable to introduce two auxiliary screens, the total dimensions of which exceed the dimensions of the additional reflector, and these screens are installed in front of the additional reflector with the possibility of moving parallel to its aperture.

It is advisable to introduce at least one intermediate screen mounted between the screen and an additional reflector.

Preferably, the rack is made in the form of a vertical plate.

It is advisable to select the lower plane of the antenna flange of the level gauge to be verified for the reference point.

The analysis of the prior art, including a search by patent and scientific and technical sources of information and identification of sources containing information about analogues of the claimed invention, allows us to establish that the applicant has not found technical solutions characterized by features identical to all the essential features of the claimed invention. The definition from the list of identified analogues of the prototype made it possible to identify a set of essential (with respect to the technical result perceived by the applicant) distinctive features in the claimed object set forth in the claims. Therefore, the claimed technical solution meets the requirement of "novelty" under the current law. Information about the fame of the distinguishing features in the totality of the characteristics of the known technical solutions with the achievement of the same as the claimed device, there is no positive effect. Based on this, it was concluded that the proposed technical solution meets the criterion of "inventive step".

The last conclusion can be clarified by the following information. It is widely known to use screens of radar absorbing materials [for example, 2, 3], however, as indicated in known sources, it is not possible to produce a screen with the required degree of reduction of the reflected field. In addition, a significant contribution to the error is made by the waves scattered by the support and the moving device, which are diffracted at the edges of the screens. Moreover, increasing the distance between the reflector and the screen reduces the component of the error, which is due to the waves reflected from the screen by reducing the mutual influence of the spectra of signals reflected by the reflector and the screen. And at the same time, the error component caused by diffracting waves increases. The combination of geometric dimensions and the installation of a screen that is closest to the reflector with the ability to change the distance to the reflector along the direction to the level gauge by at least half the maximum wavelength of the level gauge at an arbitrary fixed distance from the reflector to the level gauge can significantly reduce the error due to several measurements with subsequent averaging of the results. Significant reduction in error while reducing size and cost leads to placement on the rack, made in the form of a vertical plate, an additional reflector. In the known technical solutions there is no information about the fame of the features characterizing the additional reflector with the achievement of the specified technical result.

Figure 1 schematically shows the proposed stand adjustment and calibration of radar level gauges. Figure 2 depicts an additional reflector and curtains in the position of adjustment and calibration of level gauges operating at distances exceeding the dimensions of the stand. Figure 3 shows the position of the curtains during adjustment and calibration of level gauges operating at distances not exceeding the dimensions of the stand.

The stand (Fig. 1) for adjusting and calibrating radar level gauges comprises a rack 1 configured to mount a level gauge 2, a support 3, a flat reflector 4 mounted on a support 3 perpendicular to a straight line 5 passing through the center (B) of the flat reflector 4 and the center (D ) the aperture of the antenna 6 of the level gauge 2 during its adjustment and verification, a horizontal movement device 7 made with a platform, means 8 for measuring the distance (S) from the selected reference point (O) to a flat reflector 4, an additional reflector 9 and a screen 10 from the radio absorption material. The support 3 is placed on the platform of the horizontal moving device 7 to change the distance (S) from the reference point (O) to the flat reflector 4. The screen 10 is mounted on its horizontal moving means 11, made in the form of a cart, rigidly connected by a connector 12 to the horizontal moving device 7 . This allows horizontal movement of the screen 10 simultaneously with the movement of the support 3 to shield its surface 13 below the flat reflector 4.

The distance (L) from the flat reflector 4 to the screen 10 is at least two resolution distances of the radar level gauge 2, which can significantly reduce the error due to several measurements with subsequent averaging of the results. With a shorter distance (L), the error component increases, which is caused by waves reflected from the screen 10 (due to a decrease in the mutual influence of the spectra of signals reflected by the flat reflector 4 and the screen 10).

The additional reflector 9 is mounted on the rack 1 and is made in the form of a second-order surface with a radius (R) of curvature 2-4 times greater than the maximum distance (S) between the centers (B, C) of the flat and additional reflectors 4, 9, respectively. R / S ratios of more than four (R / S> 4) begin to increase the error caused by reflections from the walls of the anechoic chamber. This error component decreases with a decrease in the R / S ratio to a value of 2. With a further decrease in the R / S ratio, the systematic error in determining the distance to a flat reflector 4 begins to increase, due to the deviation of the shape of the additional reflector 9 from the plane. When the ratio R / S <2, the nonlinearity of the relationship between the electrodynamic and geometric ranges begins to appear, which leads to the difficulty of processing the measurement results due to the need to introduce corrective corrections that depend nonlinearly on the measured distance.

The additional reflector 9 can be made, for example, in the form of a spherical mirror (Fig. 1) with an aperture size (A) twice the size (H) of the flat reflector 4, or in the form of a cylindrical mirror (not shown in Fig.) With a vertical size aperture twice the vertical size of the flat reflector 4, and a horizontal size equal to the horizontal size of the flat reflector 4.

The screen 10 is installed with the ability to change the distance (L) to the flat reflector 4 by an amount of at least half the maximum wavelength of the level gauge 2 at an arbitrary fixed distance (S) between the flat reflector 4 and the rack 1.

To reduce reflections from the additional reflector 9, two auxiliary screens are introduced in the form of curtains 14 made of radar absorbing material, the total dimensions of which exceed the dimensions of the additional reflector 9, and these screens 14 are installed in front of the additional reflector 9 with the possibility of moving parallel to its aperture (A).

To reduce reflections from the floor 15 of the anechoic chamber between the screen 10 and the additional reflector 9, at least one intermediate screen 16 is installed. Figure 1 shows a stand with two intermediate screens 16.

The practical implementation of the proposed stand is not difficult, which is confirmed by the successful testing of a prototype of the stand at the enterprise. Rack 1 is a vertical plate. At the same time, the rack 1 and the additional reflector 9 have corresponding openings and are arranged so that when they are connected, through holes 18 are formed (Fig. 2) for mounting the antenna 6 of the level gauge 2.

The support 3 can be made, for example, in the form of a foam column. The device 7 for horizontal movement of the support 3 can be performed, for example, in the form of a trolley mounted on the guide rails.

The screen 10 and the intermediate screens 16 are made of radar absorbing material. The intermediate screens 16 are mounted on additional carts 17. The device 7 for horizontal movement of the flat reflector 4, the means 11 for horizontal movement of the screen 10 and additional carts 17 for moving the intermediate screens 16 are mounted on common guide rails (not shown), which ensure their movement in the direction of the antenna 6 level gauge 2.

The connector 12 provides the ability to change the distance (L) between the flat reflector 4 and the screen 10 closest to it and can be made, for example, in the form of a screw pair connecting the horizontal movement device 7 and the horizontal movement means 11.

The reference point (O) when measuring distances to a flat reflector 4 after its discrete displacements is, for example, the lower plane of the flange of the antenna 6 of the level gauge 2. A means 8 for measuring the distance between the reference point (O) and a flat reflector 4 can be performed, for example, in the form measuring tape.

The proposed stand is used as follows. When adjusting and checking the level gauges operating at distances not exceeding the dimensions of the stand, they close the additional reflector 9 with curtains 14 (Fig. 3). In accordance with the verification procedure of the calibrated level gauge 2 using the horizontal movement device 7 and the associated horizontal movement means 11, a flat reflector 4 and a screen 10 are successively mounted in a predetermined number of fixed points. At each of the given points, a horizontal displacement device 7 is fixed and a series of distance measurements are made by a level gauge 2 at several discrete distances (S ₁ , S ₂ ... S _n ) between the flat reflector 4 and the screen 10. The measurement results are averaged, and the difference is calculated. The difference in the measurement results characterizes the sensitivity of the level gauge to the resolved interfering low-level noise created by the interfering reflection from the screen.

To adjust and verify the level gauge, which works at distances exceeding the dimensions of the stand, open an additional reflector 14 (figure 2), the distance to the flat reflector 4 is set within 0.5-1 from the maximum and use double reflection of the waves between the flat reflector 4 and additional reflector 9. In this case, due to the above form of the additional reflector 9, the use of double reflection of waves and the focusing properties of the additional reflector 9 with increasing distance to the flat reflector 4 increases the power of the useful signal and the power of the signal reflected by the support 3 and the structural elements of the anechoic chamber decreases. As a result, as the distance increases, the error decreases.

Tests and operation of the inventive level gauge calibration bench showed that the measurement error due to the structural elements of the bench when measuring the characteristics of continuous-wave level gauges and periodic triangular frequency modulation of the probe waves does not exceed 0.002δ _R , where δ _R = c / 4Δf is the value of the discrete error, c is the speed of light, Δf is the frequency modulation range. The longitudinal size of the anechoic chamber is 17 m. With a greater distance for checking the level gauge, the cost of the proposed stand is at least 4 times less than the cost of a known stand [4].

Information sources

1. Microwave level meters "MICROPILOT". Verification technique. G.R. No. 17672-02. State system for ensuring the uniformity of measurements. All-Russian Research Institute of Metrological Service (VNIIMS), Moscow, 2002.

2. Mitsmakher M.Yu., Torgovanov V.A. Microwave anechoic chambers. - M .: Radio and communications, 1982. - 128 p.

3. Mayzels E.N., Torgovanov V.A. Measuring the dispersion characteristics of radar targets. Ed. M.A. Kolosova. - M .: Soviet Radio, 1972, p.232, p.138-143.

4. Description of the calibration bench of the IGND.407619.001 level gauges (developed by NIIIS), State Register No. 18237-99 - prototype.

Claims (8)

1. The stand for adjustment and calibration of radar level gauges, comprising a stand made with the possibility of mounting a level gauge, a support, a flat reflector mounted on a support perpendicular to a straight line passing through the centers of a flat reflector and the aperture of the level gauge antenna when adjusting and checking it, horizontal movement device, measuring instrument the distance from the reference point to the flat reflector, characterized in that an additional reflector and a screen made of radar absorbing material are introduced; There is a horizontal movement device on the platform for changing the distance from the reference point to the flat reflector, the screen is made with the possibility of horizontal movement simultaneously with the movement of the support to shield its surface below the flat reflector, and the distance from the flat reflector to the screen is at least two resolution distances of the level gauge, additional the reflector is mounted on a stand and made in the form of a second-order surface with a radius of curvature 2-4 times greater than the maximum the distance between the centers of the flat and the additional reflector, wherein the rack and the additional reflector are formed with respective through-holes for mounting the transmitter antenna. 2. The stand according to claim 1, characterized in that the additional reflector is made in the form of a spherical mirror with an aperture size that is twice the size of a flat reflector. 3. The stand according to claim 1, characterized in that the additional reflector is made in the form of a cylindrical mirror with a vertical aperture size twice the vertical size of a flat reflector and a horizontal size equal to the horizontal size of a flat reflector. 4. The stand according to claim 1, characterized in that the screen is mounted with the ability to change the distance to the flat reflector by an amount not less than half the maximum wavelength of the level gauge at an arbitrary fixed distance between the flat reflector and the stand. 5. The stand according to claim 1, characterized in that two auxiliary screens are introduced, the total dimensions of which exceed the dimensions of the additional reflector, said screens being installed in front of the additional reflector with the possibility of moving parallel to its aperture. 6. The stand according to claim 1, characterized in that at least one intermediate screen is inserted, installed between the screen and an additional reflector. 7. The stand according to claim 1, characterized in that the stand is a vertical plate. 8. The stand according to claim 1, characterized in that the reference point is the lower plane of the antenna flange of the calibrated level gauge.

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