RU2811322C1 - Ultrasonic separate-combined transducer - Google Patents

Abstract

FIELD: acoustics.

SUBSTANCE: separate-combined transducers. The ultrasonic separate-combined transducer is a prefabricated structure, including a base on which the following are installed in series: a housing of the radiating unit, in which a prism of the radiating piezoelectric element is placed with at least one radiating piezoelectric element fixed on it; an insulating screen that contains at least one shielding layer - acoustic or electromagnetic, or simultaneously several shielding layers in their various combinations and pairings; the housing of the receiving unit, in which the prism of the receiving piezoelectric element is placed with at least one receiving piezoelectric element fixed to it, while all structural elements are rigidly connected to each other using a fixing element. In addition, elements of a working fluid supply system can also be installed on the same base, ensuring acoustic contact of the ultrasonic separate-combined transducer with the surface of the test object.

EFFECT: increase in operational characteristics, namely the reliability and maintainability of an ultrasonic separate-combined transducer.

2 cl, 1 dwg

Description

The invention relates to the field of non-destructive testing, and can be used for ultrasonic testing of pipes, billets, sheets and long products.

Separately combined ultrasonic transducers are known from the prior art, used to build systems for manual, automated and automatic ultrasonic testing of materials (see the publication of the book: Non-destructive testing. Book 2. Acoustic testing methods. Edited by V.V. Sukhorukov. M.: Higher School, 1991, pp. 102-106).

A typical design of a separate-combined ultrasonic transducer contains a housing and the following located in it:

- a prism with at least one radiating piezoelectric element;

- a prism with at least one receiving piezoelectric element;

- at least one acoustic insulating screen (IE) absorbing acoustic energy; - at least one electromagnetic screen (EE) providing electromagnetic shielding between the radiating and receiving piezoelements.

This design of a separate-combined ultrasonic transducer, in comparison with other types of ultrasonic transducers, can significantly reduce the uncontrolled area near the surface of the test object. This is achieved due to the fact that the emitting part of the transducer (a prism with one or more radiating piezoelements glued to it) and the receiving part of the transducer (a prism with one or more receiving piezoelements glued to it) electrically (due to the use of EE) and acoustically (due to IE applications) are isolated from each other.

In order to obtain high flaw detection properties of the transducer, its prisms are usually made of a material with low hardness, for example, plexiglass. However, during the operation of the transducer, the degree of acoustic insulation decreases, which leads to a gradual degradation of the useful properties of the transducer, in particular, to a decrease in its sensitivity and an increase in the dead zone.

One of the main factors leading to a weakening of the insulating properties of the IE material is its gradual saturation with contact liquid (for example, water), which leads to a decrease in the attenuation of the energy of elastic waves in the IE, and, as a consequence, to an increase in the acoustic coupling between the emitting and receiving parts converter

Another factor leading to the degradation of the properties of the converter is the destruction of its working surface, which occurs due to mechanical and erosive wear of the prisms and the separating element. Moreover, this wear occurs, as a rule, unevenly. At the same time, the most important part from the point of view of preserving the properties of the converter, the central part of its working surface, is most susceptible to wear. This is because the transducer body is typically more rigid than prisms and IEs. Therefore, the rate of its destruction is significantly less than the rate of destruction of prisms and IE. As a result of such uneven wear of the working surface of the transducer, its flaw detection properties deteriorate, which, as a consequence, leads to a decrease in the quality and reliability of ultrasonic testing in general.

There are also known technical solutions in which the transducer prisms are equipped with protectors made of wear-resistant material, for example, glass or ceramics.

For example, wear-resistant SENDAST transducers produced by 3T LLC are known, equipped with a ceramic protector (see publication on the Internet at the link: https://3tsensor.com/p111-sendast).

Such converters are more resistant to wear, but in some cases they do not provide the necessary flaw detection characteristics. This is due to the fact that solid materials have a higher acoustic impedance and do not match well with the acoustic impedance of water or other liquid that provides acoustic contact between the transducer and the test object. As a result, the sensitivity of the transducer to the working gap increases, as well as to distortions in the spectrum of ultrasonic signals. The latter leads to reverberation noise, expansion of the dead zone of the converter and a decrease in its ray resolution. The instability of the characteristics of such transducers, as a rule, does not allow their use as part of highly sensitive multichannel ultrasonic testing systems.

Thus, wear-resistant hard prisms have high acoustic impedance and are unsuitable for use in multichannel ultrasonic testing systems, while prisms made of soft material, which in principle have high flaw detection characteristics, quickly degrade.

At the same time, repair of converters, including restoration of the shape of the working surface of the prisms, is very expensive and not effective enough. After several restorations, such converters, as a rule, completely lose their flaw detection characteristics.

As a prototype of the proposed technical solution, an ultrasonic separate-combined transducer was selected, described in the RF patent for invention No. 2718129, publ. 03/30/2020, IPC H04R 17/00.

The known design of an ultrasonic separate-combined transducer has good durability and reliability, while it provides high flaw detection properties.

These characteristics are achieved by the fact that the ultrasonic separate-combined transducer contains a housing, a radiating prism with a radiating piezoelectric element fixed on it, a receiving prism with a receiving piezoelectric element fixed on it, and an electroacoustic screen installed between the prisms, including at least one insulating layer, with In this case, the electroacoustic screen also additionally contains a reflective screen installed parallel to the insulating layer immediately after it in the direction of the ultrasonic waves, and which is designed to return acoustic energy back to the insulating layer and, further, to the radiating prism. As an embodiment of the invention, a reflective screen can also be installed between two insulating layers.

In this case, the reflective screen is made of a wear-resistant material, for example, of a dielectric (ceramics, ferrites) or metal, with a hardness exceeding the hardness of the material of the prisms and/or the insulating layer, and satisfying the condition: (RS) _OE> >(RS) _IS, Where:

(RS) _OE - the product of the specific gravity of the reflecting screen material and the velocity of the longitudinal elastic wave in this material;

(RS) _IS - the product of the specific gravity of the insulating layer material and the velocity of the longitudinal elastic wave in this material.

The nature of the wear of prisms in the case of using such a system is due to the division of the wearing surface of the prisms into two parts, due to which the wear of the prisms occurs separately in each of these two parts. However, since the electroacoustic screen includes a solid element - a reflective screen, it continues to retain its insulating properties even with relatively severe wear of the prisms.

However, such a converter also loses its operational properties over time, which requires its complete replacement even if only one of its elements is destroyed or has lost its flaw detection properties. This is due to the fact that all three elements - the receiving and emitting prisms, as well as the electroacoustic screen - are glued into a housing that combines them into a single, non-separable structure.

The technical problem solved with the help of the proposed technical solution is the insufficient reliability or low maintainability of the known designs of ultrasonic separate-combined transducers, due to which they cannot be used, for example, in automatic multichannel ultrasonic testing systems.

The technical result of the claimed invention is to increase the performance characteristics, namely the reliability and maintainability of an ultrasonic separate-combined transducer, which can be used, in particular, in an automatic multichannel ultrasonic testing system.

The specified technical result is achieved due to the design of an ultrasonic separate-combined transducer, which is a collapsible structure, including a base on which the following are installed in series: the body of the radiating block, in which the prism of the radiating piezoelectric element is placed with at least one radiating element fixed on it piezoelectric element; an insulating screen that contains at least one shielding layer - acoustic or electromagnetic, or simultaneously several shielding layers in their various combinations and combinations; the housing of the receiving unit, in which the prism of the receiving piezoelectric element is placed with at least one receiving piezoelectric element fixed to it, with all structural elements rigidly connected to each other using a locking element.

In addition, elements of a working fluid supply system can also be installed on the same base, ensuring acoustic contact of the ultrasonic separate-combined transducer with the surface of the test object.

Thus, the inventive collapsible design of the ultrasonic separate-combined transducer makes it possible to easily replace or repair damaged parts and fully restore the functionality of the transducer without the need for its complete replacement.

For example, a common reason for replacing an ultrasonic split-combined transducer is damage to the isolation shield, which is typically a flat plate and is a relatively inexpensive part. In this case, the damaged insulating screen can be replaced with a working one, or its functionality can be easily restored by rotating it at an angle of 90º or 180º, or by removing (trimming) its damaged part.

If one of the prisms is damaged, replacing it is also a simple technological operation, and the cost of such a replacement will be half as much as the cost of replacing the entire converter.

The inventive design of an ultrasonic separate-combined transducer is illustrated by the image in Fig. 1, on which the following positions are indicated:

(1) - object of control;

(2) - base;

(3) - body of the radiating unit;

(4) - prism of the radiating piezoelectric element;

(5) - radiating piezoelectric element;

(6) - insulating screen;

(7) - housing of the receiving unit;

(8) - prism of the receiving piezoelectric element;

(9) - receiving piezoelectric element;

(10) - fixing element;

(11) - details of the contacting liquid supply system.

An ultrasonic separate-combined transducer installed at the test object (1) is shown.

At the same time, the ultrasonic separate-combined transducer is a collapsible structure, including a base (2), on which the following are installed in series:

the housing of the radiating block (3), in which the prism of the radiating piezoelectric element (4) is placed with at least one radiating piezoelectric element (5) fixed on it;

an insulating screen (6), which contains at least one shielding layer - acoustic or electromagnetic, or simultaneously several such layers in their various combinations and combinations;

the body of the receiving unit (7), in which the prism of the receiving piezoelectric element (8) is placed with at least one receiving piezoelectric element (9) fixed to it.

In this case, all structural elements are rigidly connected to each other using a fixing element (10), for example, using a screw.

In addition, elements of a contacting liquid supply system (11) can also be installed on the base (2), providing acoustic contact of the ultrasonic separate-combined transducer with the surface of the test object (1).

The inventive design works as follows. Before conducting research, the assembled ultrasonic separate-combined transducer is installed on the surface of the test object (1).

In this case, depending on the task, the required gap is established in advance between the working surface of the prisms (4) and (8) and the surface of the test object (1), and also ensures that the insulating screen (6) adheres to the surface of the test object (1).

In order to ensure acoustic contact, a contacting liquid is supplied to the working area using its supply system (11) and then ultrasonic examinations of the test object (1) are carried out in accordance with a given program.

In case of damage during operation of the ultrasonic separate-combined transducer to its structural elements, for example, prisms (4), (8) or an insulating screen (6), the transducer is disassembled, for which the fixing element (10) is released, after which the damaged element is replaced and the structure is connected again using the fixing element (10).

Laboratory tests of the proposed design have proven its operability and the possibility of use in automatic multichannel ultrasonic testing systems used at metallurgical industry enterprises.

Thus, making the ultrasonic separate-combined transducer collapsible, providing the ability to replace one or several main structural elements at once: prisms or an insulating screen, increases its reliability and maintainability, and also leads to a reduction in costs associated with servicing industrial equipment, for example, conveyor systems for automatic multichannel ultrasonic testing, used in quality control of products such as pipes, sheets or bars.

Claims (2)

1. An ultrasonic separate-combined transducer, which is a collapsible structure, including a base on which the following are installed in series: a housing of the radiating block, in which a prism of the radiating piezoelectric element is placed with at least one radiating piezoelectric element fixed on it; an insulating screen that contains at least one shielding layer - acoustic or electromagnetic, or simultaneously several shielding layers in their various combinations and combinations; the housing of the receiving unit, in which the prism of the receiving piezoelectric element is placed with at least one receiving piezoelectric element fixed to it, while all structural elements are connected to each other using a fixing element. 2. Ultrasonic separate-combined transducer according to claim 1, characterized in that elements of a working fluid supply system are installed on the base, ensuring acoustic contact of the ultrasonic separate-combined transducer with the surface of the test object.