RU2680676C1 - Method of testing ultrasonic flow detector and device for its implementation - Google Patents

Abstract

FIELD: defectoscopy.SUBSTANCE: use for testing of ultrasonic flaw detector. Gist of the invention is testing of each of the piezoelectric ultrasonic sensors of an ultrasonic flaw detector is carried out using a device made with a through cylindrical cavity, at the same time, a measure and piezoelectric ultrasonic sensor are installed in the through cylindrical cavity, ensuring their fixation in the device, liquid fills the space between the lens of the piezoelectric ultrasonic sensor and the gauge and checks the operability of the piezoelectric ultrasonic sensor.EFFECT: higher calibration accuracy and enhanced functionality.9 cl, 3 dwg

Description

The invention relates to measuring technique, to calibrating an ultrasonic flaw detector for measuring wall thickness by the immersion method of acoustic contact.

A known sample for tuning an ultrasonic flaw detector (RU 95101085, IPC G01N29 / 04, priority since 01/25/1995), which refers to non-destructive testing methods and is intended to adjust the sensitivity of ultrasonic flaw detectors during ultrasonic testing, as well as for metrological support and verification of ultrasonic flaw detection tools. The sample consists of an arbitrary number of individual prisms. Prisms are joined together in an arbitrary combination along the side faces with the formation of two parallel planes for introducing ultrasonic vibrations.

A known method of calibrating acoustic emission transducers and a device for its implementation (RU 2321849, IPC G01N 29/04, G01N 29/30, priority from 04/14/2005), which consists in the fact that, using an optical interference meter of linear displacements, the system is calibrated, consisting of an acoustic signal source and a monolithic transmitting unit, after which a standard acoustic emission transducer is introduced into acoustic contact with a monolithic transmitting unit, the signal from this transducer is processed and stored For acoustic emission, then the calibrated acoustic emission transducer is installed in place of the standard one, the second signal is recorded and processed in the computer, which is compared with the stored reference one, thereby calibrating the calibrated acoustic emission transducer. Effect: increasing the accuracy of calibration and expanding the functionality of the system as a whole.

A known method for the dynamic calibration of an ultrasonic flaw detector (RU 2550825, IPC G01N29 / 04, priority since 02/19/2014), which consists in conducting a dynamic calibration of an ultrasonic flaw detector containing a row block of electro-acoustic transducers, the first of which is an ultrasonic radiation generator, and the next the transducer or transducers are receivers of ultrasonic radiation, while the threshold level of the flaw detector is set based on the current value of the reference amplitude about the signal radiated specularly with respect to the main probing signal and representing the residual ultrasonic radiation of the generator in the current cycle or forced ultrasonic radiation of the generator in the additional cycle. Effect: improving the accuracy of setting the threshold level of operation of an ultrasonic flaw detector in the control process.

No prototypes of the claimed invention were found. The closest analogue of the claimed invention is a sample for checking the manual tuning of the flaw detector sensitivity for automated ultrasonic testing (Patent RU 140993, IPC G01N29 / 04, priority 09.01.2014) is made in the form of a ring with cylindrical through holes in which standard samples with flat-bottomed artificial reflectors are inserted while the working surfaces of the standard samples are installed flush with the working surface of the ring, the cylindrical holes in the ring are made radial, their axes lie at in one plane, coincide with the radii of the ring, intersect its outer side surface with a constant pitch between adjacent axes, and the holes on this surface are chamfered, which are filled with sealant after installing standard samples. The utility model allows to automatically check the manual tuning of the sensitivity of flaw detection equipment when monitoring products with spherical surfaces by registering artificial reflectors equivalent to defects set according to the defectiveness standards of the product with the same transducer, acoustic unit and manipulator used for automated ultrasonic monitoring of dome-shaped products with spherical surfaces , determine the optimal scanning step of the transducer along the arc second path perpendicular to the rotation of the product during its control and ensure metrological verification of flat reflectors artificial standard samples.

The disadvantage of the aforementioned analogue is that the sample for checking manual tuning of the flaw detector sensitivity for automated ultrasonic testing has specialized industrial applications, as it is designed to automatically check the manual tuning of the sensitivity of flaw detection equipment for monitoring products with spherical surfaces and is not suitable for use in other purposes, namely when checking an ultrasonic flaw detector for measuring the wall thickness of an immersion nnym way acoustic coupling.

The technical result of the present invention is to reduce labor costs when checking an ultrasonic flaw detector for measuring wall thickness by immersion acoustic contact method.

The technical result is achieved by the fact that in the method of testing an ultrasonic flaw detector for measuring the wall thickness of the pipeline by the immersion method of acoustic contact, which includes checking the operability of piezoelectric ultrasonic sensors of an ultrasonic flaw detector using a computer, the results of which judge the operability of an ultrasonic flaw detector, checking each of the piezoelectric ultrasonic sensors of an ultrasonic flaw detector carried out using Lenia performed with a through cylindrical cavity, the cylindrical cavity in through-set measure and a piezoelectric ultrasonic transducer, providing them with a fixing device, the liquid filled space between the lens and the piezoelectric ultrasonic transducer and measure performance check carried piezoelectric ultrasonic probe.

An ultrasonic flaw detector verification tool for measuring pipe wall thickness by an acoustic contact immersion method includes a body with a through cylindrical cavity made with the possibility of installing measures in a through cylindrical cavity from one end of the body and a piezoelectric ultrasonic sensor from the other end of the body, a pressure cover with holes for mounting to the housing, the sealing rings to ensure the fixation of the measure and the piezoelectric ultrasonic sensor in the through cylindrical cavity of the housing, while in the housing there are technological holes for filling the through cylindrical cavity with liquid, and grooves are made on the inner walls of the housing for installing sealing rings in them.

In the particular case of the invention, the device body can be made cylindrical.

The device body on the side of the end, in which the measure is installed, has threaded holes for attaching the pressure cover to the body by means of fasteners.

The device further comprises a set of spacer rings for fixing measures made in the form of hollow cylinders.

The cover clamping can be made in the form of a hollow cylinder with a flange.

The device body and the pressure cover can be made of steel.

The body of the device and the pressure cover can be made of aluminum.

The device body and the pressure cover can be made of plastic reinforced with metal sleeves, with threaded holes for mounting fasteners.

An ultrasonic flaw detector is considered an attorney if the parameters of all piezoelectric ultrasonic sensors installed on it are within the established limits of the threshold values, and all communication channels of the ultrasonic flaw detector are operational. The thickness of each measure in the set corresponds to one of the measured wall thicknesses, and the set of measures corresponds to a set of exemplary ultrasonic measures.

The claimed invention is used for checking in-tube ultrasonic flaw detectors, in-tube combined magneto-ultrasonic flaw detectors in the verification part of the ultrasonic section.

In FIG. 1 shows the implementation of a method for checking an ultrasonic flaw detector.

In FIG. 1 adopted the following notation:

1. Device for checking an ultrasonic flaw detector for measuring wall thickness by immersion acoustic contact method.

2. Measure.

3. Piezoelectric ultrasonic sensor.

4. Ultrasonic section.

5. The fluid.

6. The lens of the piezoelectric ultrasonic sensor.

Figure 2 shows a device for testing an ultrasonic flaw detector for measuring wall thickness by immersion acoustic contact method.

In FIG. 2 adopted the following notation:

2. Measure from a set of verification measures of an ultrasonic flaw detector for measuring wall thickness by immersion acoustic contact method.

7. Case.

8. The cover is clamping.

9. The spacer ring.

10. The ring is sealing.

11. Through cylindrical cavity.

12. Technological openings for filling with liquid the space between the lens of the piezoelectric ultrasonic sensor and the measure.

13. Blind threaded hole.

14. Fasteners.

15. Smooth hole in the pressure cover.

In FIG. 3 depicts a pressure cover in special cases of implementation.

In figure 3, the following notation:

8. The cover is clamping.

15. The hole in the pressure cover.

A method for verifying an ultrasonic flaw detector for measuring wall thickness by an immersion method of acoustic contact includes checking the operability of piezoelectric ultrasonic sensors of an ultrasonic flaw detector using a computer, the results of which judge the operability of an ultrasonic flaw detector, while testing each of the piezoelectric ultrasonic sensors of an ultrasonic flaw detector is carried out using device 1 made with through cylindrical second cavity 11, thus in a through cylindrical cavity 11 is set to measure 2 and the piezoelectric ultrasonic transducer 3 with ensuring their fixing in a fixture, the space 5 is filled with a liquid between the lens piezoelectric ultrasonic probe 3 and the measure is carried out by 2 and operability of the piezoelectric ultrasonic transducer 3.

The ultrasonic flaw detector verification device 1 for measuring the pipe wall thickness by the acoustic immersion method consists of a cylindrical body 7 with a through cylindrical cavity 11, which is configured to install a measure 2 in a through cylindrical cavity 12 from one end of the housing 7 and a piezoelectric ultrasonic sensor from the other the end face of the housing 7, while the housing 7 on the side of the end, in which the measure 2 is installed, has threaded holes 13 for attaching the pressure cover 8 to the core Pusu 7 by means of fasteners 14.

The device 1 for verifying an ultrasonic flaw detector for measuring the wall thickness of the pipeline by the immersion method of acoustic contact also includes a pressure cap with holes 15 for fastening to the casing 7 of the sealing ring 10 to ensure fixation of the measure 2 and the piezoelectric ultrasonic sensor 3 in the through cylindrical cavity 11 of the housing 8, while in the housing 7 there are technological holes 12 for filling the through cylindrical cavity 11 with liquid 5, and on the inner walls of the housing 7 grooves for installing o-rings in them 10.

The device 1 further comprises a set of spacer rings 9 for fixing the measure 2, made in the form of hollow cylinders.

Clamp cover 8 can be made in the form of a hollow cylinder with a flange. The housing 7 and the cover 8 can be made of steel, aluminum or plastic, reinforced with metal bushings, with threaded holes 13 for installing fasteners 14.

Claims (10)

1. The method of verification of an ultrasonic flaw detector for measuring the wall thickness of a pipeline by the immersion method of acoustic contact, including checking the operability of piezoelectric ultrasonic sensors of an ultrasonic flaw detector using a computer, the results of which judge the operability of an ultrasonic flaw detector, characterized in that: the verification of each of the piezoelectric ultrasonic sensors of an ultrasonic flaw detector is carried out using a device made with a through cylindrical cavity, while a measure and a piezoelectric ultrasonic sensor are installed in the through cylindrical cavity to ensure their fixation in the device, the space between the lens of the piezoelectric ultrasonic sensor and the measure is filled with liquid and carried out performance check of a piezoelectric ultrasonic sensor. 2. A device for checking an ultrasonic flaw detector for measuring the wall thickness of a pipeline by the immersion method of acoustic contact according to claim 1, comprising a body with a through cylindrical cavity made with the possibility of installing measures in a through cylindrical cavity from one end of the body and a piezoelectric ultrasonic sensor from the other end of the body, pressure cap with holes for attaching to the housing, o-rings to ensure fixation of the measure and the piezoelectric ultrasonic sensor in a through cylindrical cavity of the housing, while in the housing there are technological holes for filling the through cylindrical cavity with liquid, and grooves are made on the inner walls of the housing for installing sealing rings in them. 3. The device according to claim 2, characterized in that the housing is cylindrical in shape. 4. The device according to claim 2, characterized in that the housing on the side of the end, in which the measure is installed, has threaded holes for attaching the pressure cover to the housing by means of fasteners. 5. The device according to claim 2, characterized in that it further comprises a set of spacer rings for fixing measures made in the form of hollow cylinders. 6. The device according to claim 2, characterized in that the pressure cover is made in the form of a hollow cylinder with a flange. 7. The device according to claim 2, characterized in that the housing and the pressure cover are made of steel. 8. The device according to claim 2, characterized in that the housing and the pressure cover are made of aluminum. 9. The device according to claim 2, characterized in that the housing and the pressure cover are made of plastic reinforced with metal bushings with threaded holes for mounting fasteners.

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