RU124397U1 - CALIBRATION DEVICE FOR ULTRASONIC PROBE - Google Patents

Abstract

A device for calibrating an ultrasonic probe containing a standard sample made in the form of a three-dimensional body having a measuring plane and a supporting plane parallel to it and an internal through-hole, the standard sample is provided with marks for the angles of input of ultrasonic radiation, such that if the point of introduction of ultrasonic radiation of the probe is located on the measuring surface of the standard sample, on the mark α, and the probe has a direction of ultrasonic radiation with an angle α lying in the plane of the probe If the probe is perpendicular to the generating hole, then the ultrasonic radiation of the probe is reflected from the generating hole in the opposite direction, characterized by the presence of a fixed base, a rotary table, a probe holder and marks of the angular position of the rotary table, the rotary table is mounted on the rotation axis fixed in the base, the rotary table has an installation plane perpendicular to the axis of rotation, on which the reference sample is placed, and a guide for linear movement of the reference sample along the reference plate -plane along the sensing plane of the probe holder fixedly mounted on the base and is configured so that the point of input of the ultrasonic probe radiation is at the point of intersection of the measurement standard sample surface with the axis of rotation of the turntable.

Description

The utility model relates to devices for calibrating the sensitive elements of ultrasonic (US) flaw detectors - probes having complex spatial directions of the radiation of ultrasonic sounding signals. Such zones are used to study objects of complex shape, for example, railway rails. The device can be used in the manufacture and operation of ultrasound probes.

When ultrasonic inspection of objects is used electroacoustic transducers (EAP), providing radiation of ultrasonic sounding signals and receiving ultrasonic signals reflected from defects. [one]. To study the entire volume of the object, the EAA is moved along the surface of the object, and sounding is carried out with the step selected based on the requirements for resolution. However, the defects may turn out to be parallel to the sounding direction; then, to detect defects of arbitrary orientation, it is necessary to use several EAPs with different angles for introducing ultrasonic vibrations and structurally integrated into the probe. To change the angle of entry of the ultrasonic vibrations into the object, the EAA is equipped with a refracting prism, which ensures the rotation of the ultrasonic vibrations by an angle α with respect to the axis perpendicular to the surface of the object. As a rule, the indicated angle lies in the plane of the EAP movement.

To study objects of complex shape, for example, rails, it is necessary to use ultrasonic probes in which the EAT are rotated by an angle γ with respect to the direction of movement: [2], [3]. For a reliable study of the condition of the rails, as a rule, several EAPs are required that have different angles of input of the ultrasonic vibrations α and γ directed to a specific section of the rail, to each other, etc.

Ultrasound probes can be performed in different design options: a single EAP, a probe in the form of a “ski” [4] or a wheel [5], [6], [7].

Closest to the claimed is a device for calibrating ultrasonic devices - a standard sample [8], made in the form of a volumetric body having a measuring plane and a supporting plane parallel to it and an internal through hole, the standard sample is provided with marks of the angles of input of ultrasonic radiation, such that if the input point of the ultrasonic radiation of the probe is located on the measuring surface of the standard sample, on the mark α, and the probe has a direction of ultrasonic radiation with angle ohm α, which lies in a sensing plane - perpendicular to the generatrix of the hole, the ultrasonic radiation reflected from the probe forming a hole in the reverse direction.

This device allows you to calibrate the EAA, i.e. to check the accuracy of manufacturing the EAA and the prism, from the point of view of the correctness of the angle α - input ultrasonic vibrations in the standard sample.

The disadvantage of this device is a limited range of tasks - the ability to calibrate only such probes in which the direction of radiation coincides with the direction of movement of the EAP - along one angle α.

The quality of ultrasonic inspection of rails largely depends on the accuracy of radiation / reception of ultrasonic sounding signals. Sources of inaccuracies may be the manufacturing quality of the EAT converter, rotary prism, as well as the accuracy of the installation of the EAP in the probe.

The problem solved by the claimed utility model is the creation of a simple and cheap device that provides calibration of ultrasound probes of various designs with a spatial angle of entry of ultrasonic vibrations {α, γ}.

To solve this problem, a device for calibrating an ultrasonic probe containing a standard sample made in the form of a three-dimensional body having a measuring plane and a supporting plane parallel to it and an inner through cylindrical hole, the standard sample is provided with marks of the angles of input of ultrasonic radiation, such that if the point of entry of ultrasonic the radiation of the probe is located on the measuring surface of the standard sample, on the mark α, and the probe has a direction of ultrasonic radiation with an angle α lying it in the sensing plane - perpendicular to the generating hole, then the ultrasonic radiation of the probe is reflected from the generating hole in the opposite direction, further comprises a fixed base, a rotary table, a probe holder and labels for the angular position of the rotary table, the rotary table is mounted on a rotation axis fixed in the base, rotary the table has an installation plane perpendicular to the axis of rotation, on which the reference sample is placed the reference plane, and a guide for linear movement of the standard sample on the supporting plane along the sensing plane of the probe holder fixedly mounted on the base and is configured so that the point of input of the ultrasonic probe radiation is at the point of intersection of the measurement standard sample surface with the axis of rotation of the turntable.

Significant differences of the claimed device compared to the prototype are:

The presence of a fixed base with a rotary table mounted on a fixed axis of rotation, allows you to change the angular position of the standard sample with respect to the EAA. This circumstance makes it possible to measure not only the angle of entry of ultrasonic vibrations α, but also the angle between the directions of radiation and displacement γ.

In the prototype, only the angle α is measured.

The presence of a guide for linear movement of the standard sample along the reference plane of the turntable along the sounding plane allows for high accuracy of the installation of the EAA and the standard sample, both in angular and linear displacements, and, therefore, calibrates the EAA with high accuracy.

In the prototype, the installation and movement of the EAA is carried out manually "by eye", i.e. not exactly.

The presence of the probe holder fixedly mounted on the base also allows measurements to be made with high accuracy, but according to a scheme fundamentally different from the prototype: in the prototype, the probe is moved relative to the standard sample, and in the inventive device, vice versa.

In addition, in the inventive device, it is possible to calibrate the probe, i.e. devices of various designs, in which the EAP is located. This circumstance allows us to check not only the accuracy of manufacturing the EAA and its prism, but also the build quality of the entire probe.

The prototype is suitable only for calibration of single EAFs. The claimed utility model is illustrated by the following graphic materials:

Figure 1 - device for calibrating the EAP angle α, where:

1. The probe is an electro-acoustic transducer.

2. Standard sample.

3. The measuring plane.

4. The reference plane.

5. The hole.

6. Marks the angles of entry of ultrasonic vibrations α.

7. Base.

8. The rotary table.

9. Probe holder.

10. Marks the angular position of the turntable.

11. The axis of rotation of the turntable.

12. Installation plane.

13. Guides.

14. Label the direction of the EAP radiation.

Figure 2 - device for calibrating the EA by angle γ.

Figure 3 - device for calibrating the probe in the form of a "ski", where:

15. A probe in the form of a "ski".

16. The holder of the "ski".

Figure 4 - device for calibrating the probe in the form of a "wheel", where:

17. The probe in the form of a "wheel".

18. The holder of the "wheel".

Electro-acoustic transducer 1 - the simplest probe is designed to emit sounding signals and receive reflected signals. EAP 1 has a prism with an input angle α for emitting ultrasonic vibrations into the object during operation and into standard sample 2 during calibration. Any EAP has a certain radiation pattern of ultrasonic vibrations. By the direction of radiation we mean the axis of the central lobe, and by the point of entry - the intersection of this axis with the corresponding surface. EAP 1 has, Fig. 1, on the body a marking of the angle of entry of ultrasonic vibrations α and a mark 14 indicating the direction of radiation along the sounding plane. Electro-acoustic transducer 1 is made in the form of a piezoelectric plate capable of converting electrical signals into acoustic waves and vice versa. To ensure acoustic contact EAP 1 can be equipped with a clamping mechanism, for example, a spring, and, in addition, the surface of the standard sample can be wetted with a contacting liquid or a special gel.

Standard sample 2 is intended for receiving through its measuring plane 3 ultrasonic signals from the EAA 1 at an angle α, mirror reflection of this signal from the cylindrical hole 4 (drilling in a standard sample) and receiving the reflected signal EAA 1. Standard sample 2 has labels 6 for installing the EAA 1 probe 1, 14 or 16, which are calibrated at angles α.

The reference plane 4 of the standard sample 2 is intended for its installation on the installation plane 12 of the turntable 8 and the movement of the standard sample 2 along its guide (them) 13, i.e. along the X axis, FIGS. 1, 2.

The probe holder 9 is designed to fix the EAA 1 on the measuring plane 3 of the standard sample 2 on the axis of rotation 11 of the turntable 8. The holder must provide acoustic contact of the EAA 1 with the standard sample. The design of the holder depends on the type of probe and may be in the form of 16, Fig.3 or 18, Fig.4.

Marks of the angular position of the turntable 10 in this case are located on the base 7 and allow you to determine the angle γ - rotation of the standard sample 2 on the turntable 8 relative

The guide 13 in this case is made in the form of parallel sides of the turntable 8.

The probe can be made in the form of a “ski” 15, Fig. 3, in which several multidirectional EAA are placed. Each of them has fasteners for installation. In this case, the probe holder has the form 15.

If the probe is made in the form of a “wheel” 17, FIG. 3, then the EAA 1 is located inside the acoustically transparent shell of the wheel filled with liquid. In this case, the input point of the ultrasonic vibrations is located at the contact point of the wheel 17 with the measuring plane 3 of the standard sample 2. In this case, the probe holder has the form 18.

Consider the operation of the inventive device when calibrating a single EAA 1, figure 1.

Set the standard sample 2 by the reference plane 4 on the installation plane 12 of the turntable 8 along the guides 13. EAP 1 having an angle of entry of ultrasonic vibrations α, is fixed in the probe holder 9, so that the emission center of the EAP 1 is on the axis of rotation 11 of the rotary table 8, and the mark of the direction of radiation 14 on the body of the EAP 1 coincided with the X axis. The standard sample 2 is moved so that the EAP 1 turns out to be 6 along the marks of the angles of input of ultrasonic vibrations on the mark equal to α. EAA 1 ultrasonic vibrations are emitted and ultrasonic signals are received reflected from the hole 5. EAA 1 is moved along the X axis along guides 13 and the EAA 1 is rotated, achieving the maximum amplitude of the reflected signal. Having received such a signal, the actual angle of entry of ultrasonic vibrations α at the measured EAP 1, as well as the accuracy of the mark of its radiation direction, are specified using marks 6. If necessary, adjust the position of the radiation direction label 14. If the angle of radiation declared by the manufacturer does not coincide with the real one, they decide to reject EAP 1. This measurement mode is known and, in principle, coincides with the measurement mode described in [2].

If the calibrated EAF 1 will be used with the radiation direction not along the X axis, but with the angle γ, Fig. 2, then the rotary table 8 is set according to the marks 10 at the required angle γ and the steps described above are repeated. As a result, another mark 14 corresponding to a given angle γ will be set on the EAP 1, and the actual angle of entry of the ultrasonic vibrations α of this EAP 1 will be estimated.

When using “ski” as a probe 1, FIG. 3, it is necessary to fix the “ski” 15 on base 7 using the holder 16 so that the emission center of the EAA 1 is on the rotation axis 11 of the turntable 8. In this case, the longitudinal axis of the “ski” "Must coincide with the axis 19 of the holder 16, figure 2. Moving the standard sample 2 along the X axis along the guides 13 and, rotating the EAF 1, achieve the maximum amplitude of the reflected signal.

When using the "wheels" as a probe - 1, Fig. 4, it is necessary to fix the "wheel" 17 on the base 7 using the holder 18 so that the emission center of the EAA 1 is on the rotation axis 11 of the turntable 8. In this case, the longitudinal axis of the "wheel "Must coincide with the axis 19 of the holder 16, figure 2. Moving the standard sample 2 along the X axis along the guides 13 and, rotating the EAF 1, achieve the maximum amplitude of the reflected signal.

As a result of these manipulations, it becomes possible to more accurately check the quality of the production of EATs and their installation in an ultrasonic probe.

Thus, the inventive device allows you to calibrate both single EAP and ultrasound probes with spatial radiation angles of ultrasonic vibrations α and γ, and thereby improve the quality of inspection of objects of complex shape.

Information sources:

1. Markov A.A. Ultrasonic flaw detection of rails., 2nd ed. reslave. and add. - SPb .: Education - Culture, 2008.283 s.

2. Patent RU 2184960.

3. Patent RU 2184374.

4. Patent GB 1506214.

5. Patent RU 89235.

6. Patent WO 9701094.

7. Patent US 6604421.

8. GOST 18576-96.

Claims (1)

A device for calibrating an ultrasonic probe containing a standard sample made in the form of a three-dimensional body having a measuring plane and a supporting plane parallel to it and an internal through hole, the standard sample is provided with marks for the angles of input of ultrasonic radiation, such that if the point of introduction of ultrasonic radiation of the probe is located on the measuring surface of the standard sample, on the mark α, and the probe has a direction of ultrasonic radiation with an angle α lying in the plane of the probe If the probe is perpendicular to the generating hole, then the ultrasonic radiation of the probe is reflected from the generating hole in the opposite direction, characterized by the presence of a fixed base, a rotary table, a probe holder and marks of the angular position of the rotary table, the rotary table is mounted on the rotation axis fixed in the base, the rotary table has an installation plane perpendicular to the axis of rotation, on which the reference sample is placed the reference plane, and a guide for linear movement of the reference sample along the reference plate -plane along the sensing plane of the probe holder fixedly mounted on the base and is configured so that the point of input of the ultrasonic probe radiation is at the point of intersection of the measurement standard sample surface with the axis of rotation of the turntable.

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