GB2479744A - Ultrasonic transducer - Google Patents

Abstract

An ultrasonic transducer includes a wear plate 2, an active element 8 arranged rearwards of the wear plate and a rigid block 16 arranged rearwards of the active element and configured to provide a non-resonant backing mass for the active element. The wear plate extends across the active element and rearwards so as to provide a cap over the active element and sides 25 of at least a forward portion 24 of the rigid block. A heat extracting strip 5 may be provided between the plate 2 and other components. The arrangement increases the efficiency and operating temperature range of the transducer.

Description

Ultrasonic transducer

Description

The present invention relates to an ultrasonic transducer particularly, but not exclusively, for use in inspecting pipes using guided ultrasonic waves.

Ultrasonic waves can be used for inspecting a structure, such as a pipe, to identify defects and flaws within the structure. Examples of ultrasonic inspection devices can be found in WO 96/12951 A, WO 2007/125308 A2 and EP 1 394 538 Al WO 96/12951 A describes an apparatus for inspecting elongate members, such as pipes. The apparatus includes a ring of angularly-spaced transducers (or "exciters") clamped to the outside wall of a pipe. Each transducer includes a pie2oelectric element, a metal block adhesively bonded to the piezoelectric element, and a thin faceplate shim secured to the face of the piezoelectric element to provide a wear plate.

In the prior art transducer, the piezoelectric element and wear plate are stacked in a recess in the metal block and secured using an epoxy adhesive. This arrangement can have disadvantages.

Firstly, the sides of the vear plate may be constrained by the sides of the recess.

This can decrease the efficiency of the transducer.

Secondly, the metal block is near the pipe. If the pipe is hot, then the metal block can absorb heat radiated by the pipe and heat the piezoelectric element and the epoxy adhesive. Piezoelectric elements and epoxy adhesives have a maximum operating temperature and so this arrangement can limit the maximum temperature of pipe that can be inspected using the transducer.

Thirdly, when inspecting a hot pipe, both the front of the metal block and the wear plate are exposed to high temperatures. If the metal block and wear plate are made from different materials, then they may expand at different rates dues to different coefficients of thermal expansion. This can limit the maximum operating temperature of the transducer and reduce the number of operational cycles.

Finally, the bond line between the metal block and the wear plate is at the front of the transducer and so is usually exposed to the environment. This can limit the lifetime of the transducer and/or make it less reliable due to exposure to the environment, for example due to ingress of sea water. Furthermore, if the pipe is hot, then the epoxy adhesive is directly exposed to heating.

The present invention seems to provide an improved ultrasonic transducer.

According to the present invention there is provided an ultrasonic transducer including a wear plate, an active element arranged rearwards of the wear plate and a rigid block arranged rearwards of the active element and which is configured to provide a backing mass for the active element, wherein the wear plate extends across the active element and rearwards so as to provide a cap over the active element and sides of at least a forward portion of the rigid block.

This transducer can have one or more advantages. The arrangement can allow the wear plate to move more freely and, thus, increase the efficiency of the transducer.

Furthermore, the wear plate can shield the metal block from a hot structure, such as a hot pipe. Thus, if the wear plate is made from a material which is a poor thermal conductor, this can allow a hotter structure to be inspected. Moreover, the region of the transducer which is closest to the structure under inspection is made from the same material which can help to reduce the problem of different parts expanding at different rates. In addition, a larger active element can be used since it is not constrained by the size of a recess in the backing mass.

The wear plate can have a forward face and rearwards face, wherein the forward face is shaped to provide a knife (that is, sharp) edge. This can allow the wear plate to cut through or pierce a coating covering a pipe and contact an underlying structure.

The wear plate can comprise a ceramic. This can help to reduce heating of the active element if the transducer is in contact with a hot object.

The wear plate may comprise a laminate including a layer of ceramic and/or metal or metal alloy.

The ultrasonic transducer may further comprise a thermally-conductive element disposed between the wear plate and the active element for conducting heat absorbed by the wear plate. The thermally-conductive element comprises a layer of thermally-conductive material disposed on a rearward surface of the wear plate and thermally connected to something cooler than the wear plate. This layer can help to reduce heating of the active element if the transducer is in contact with a hot object.

The active element comprises a piezoelectric element, such as a shear polarised piezoelectric element.

The ultrasonic transducer may further comprise another active element. The other active element may be arranged between the active element and the rigid block in a stack. Thus, different orientations or magnitudes of motion can be generated.

The ultrasonic transducer may further comprise a filler, such as an adhesive, arranged to encapsulate the active element and the forward portion of the rigid block in order to provide enhanced environmental protection.

According to a second aspect of the present invention there is provided an apparatus for inspecting an elongate member, the apparatus comprising a plurality of ultrasonic transducers, the ultrasonic transducers may be arranged in a band or bands around the elongate member.

The apparatus may be configured to inspect a pipe and the ultrasonic transducers may be angularly spaced in a ring around the wall of the pipe.

Certain embodiments of the present invention will now be described, by way of example, with reference to the accompanying drawings in which: Figure 1 is an exploded perspective view of an ultrasonic transducer assembly; Figure 2 is a part cutaway perspective view of the ultrasonic transducer shown in Figure 1; Figure 2a is a perspective view of the ultrasonic transducer shown in Figure 1; Figure 3 is a cross sectional view of the ultrasonic transducer shown in Figure 1 taken along the line A-A'; Figure 4 is a part cutaway perspective view of an encapsulated ultrasonic transducer; Figure 5 is a perspective view of a wear plate having a knife edge contact region from above; Figure 6 is a perspective view of the wear plate shown in Figure 5 from below; Figure 7 is a perspective view of a wear plate having a blunt contact region from above; Figure 8 is a perspective view of the wear plate shown in Figure 7 from below; Figure 9 is a part cutaway perspective view of an ultrasonic transducer without a heat-extracting strip; Figure 10 is a part cutaway perspective view of an ultrasonic transducer with a single active element and a heat-extracting strip; and Figure 11 is a part cutaway perspective view of an ultrasonic transducer with a single active element and without a heat-extracting strip.

In the following, like parts are denoted by like reference numerals.

Referring to Figures 1, 2, 2a, 3 and 4, an ultrasonic transducer assembly 1 (herein simply referred to as an "ultrasonic transducer") is shown.

The ultrasonic transducer 1 includes a wear plate 2 (which may also be referred to as a "face plate" or "contact head") having a front surface 3 which, in use, is pressed into contact with an object or structure (not shown) under inspection, and a rear surface 4 (Figure 6). The wear plate 2 is made from a ceramic. However, in some embodiments, the wear plate 2 can be made from a metal or a metal alloy. An arched heat-extracting strip 5 (or "heat sink") runs behind the wear plate 2. The strip 5 comprises a thermally highly-conductive material, such as copper, aluminium, gold or silver. The far end of this heat extracting strip may be attached to a heat sink that is typically cooler than the faceplate, for example the rigid block 16 or an external finned heat sink, in order to allow higher temperature structures to be inspected. The heat-extracting strip 5 can be omitted, particularly if the object or structure under inspection is at or close to ambient temperature.

The ultrasonic transducer 1 includes a first transducer stack 6 which comprises a first earth electrode 7 which is closest to the wear plate 2, a first active layer 8 in the form of a shear polarized piezoelectric layer and a first signal electrode 9.

A first electrical insulating layer or plate 10 separates the first transducer stack 6 from a second transducer stack 11. The second transducer stack 11 comprises a second earth electrode 12, a second active 13 layer also in the form a shear polarized piezoelectric layer and a second signal electrode 14.

A second electrical insulating layer 15 separates the second transducer stack 11 from a rigid block 16 which provides a non-resonant backing mass. The rigid block 16 is preferably made of steel or other dense material so as to provide a high mass. The material may be chosen so as to have a low coefficient of thermal expansion or one which is matched to the wear plate.

First and second miniature coaxial cables 17, 18 provide connections to the first and second pairs of electrodes 7, 9, 12, 14 respectively. The cables 17, 18 sit in recesses 19,20 running down opposite sides of the rigid block 16.

As shown in Figure 1, the piezoelectric elements 8, 13 are stacked such that their polarizations cross, e.g. perpendicularly, by rotating the direction of one layer 8 relative to the other 13 and are separately controlled. Since they are separately controlled, it is possible to either excite only one piezoelectric element 8, 13 at a time or both piezoelectric elements 8, 13 at the same time, but with different amplitudes and/or phases to create any orientation of shear motion in the x-y plane.

Being able to generate different orientations of shear motion, e.g. along the x-axis or along the y-axis, allows different types of guided wave modes to be generated and received by the transducer 1, thereby avoiding the need for two different sets of transducer elements for the different orientations.

Notwithstanding this, the piezoelectric elements 8, 13 can be stacked having the same polarization and wired in parallel in order to increase the maximum deflection generated by a givcn voltage. This can increase the signal-to-noise ratio by injecting larger signals into the pipe.

Moreover, as will be shown later, the transducer need only have one piezoelectric element. Thus, for example, the second transducer stack 11, second electrical insulating layer 15 and second coaxial cable 18 can be omitted. Similarly, mote than two piezoelectric elements can be stacked by adding more insulating layers and electrical connections.

Referring in particular to Figure 3, the wear plate 2 passes in front (as shown, the top) of the rest of the transducer and to the rear (as shown, down) to provide a cap over a forward-most portion of the heat-extracting strip 5, the transducer stacks 6, 11 and the insulating plates 10, 15. The wear plate 2 also extends beyond a front face 24 of the rigid block 16 and along the sides 24 of a forward portion (as shown, a top portion) of the rigid block 16.

The wear plate 2 is shaped to provide a space or recess 27 in which the forward-most portion of the heat-extracting strip 5, the transducer stacks 6, 11, the insulating plates 10, 15 and the top part of the rigid block 16 sit. The wear plate 2 may be machined or moulded.

Referring in particular to Figure 4, the rest of the space 27 (Figure 3) is filled with a flexible filler 28 hereing also referred to as an "encapsulate"), for example an epoxy adhesive or potting compound, so as to encapsulate the forward-most portion of the heat-extracting strip 5, transducer stacks 6, 11, insulating plates 10, 15 and the top part of the rigid block 16.

Referring still to Figures 1, 2, 2a, 3 and 4, the transducer 1 can be used in an apparatus or method for inspecting pipes as described in WO 96/1295 1 A and WO 2007/125308 A2 which are incorporated herein by reference.

The transducer 1 can offer several advantages, particularly when inspecting hot pipe and/or being used in harsh environments.

When the front 3 of the wear plate 2 is presented to a hot object, such as a hot pipe, the wear plate 2 can shield the rigid block 16 from heat. Furthermore, the part of the transducer I that is closest to the hot pipe -and which suffers the largest rapid temperature rise -is made from the same material. Thus, it is possible to sustain a large temperature gradient across the thickness (along the z-direction) of the wear plate 2.

The heat-extracting strip 5 allows heat to be transmitted away from the piezoelectric layers 8, 13. One or both ends of the strip 5 can be connected to the rigid block, an external heat sink or heat exchange (not shown). This arrangement can help to protect sensitive piezoelectric layers 8, 13 from high temperatures.

The underside of the wear plate 2, the forward-most portion of the heat-extracting strip 5, transducer stacks 6, 11, insulating plates 10, 15 and forward-most portion of the rigid block 16 can be encapsulated to provide a watertight seal. In fact, the entire transducer, with the exception of a small portion of the wear plate 2 around a contact region, can be completely encapsulated to further enhance environmental protection.

Because the active element is not fitted inside a recess in the rigid block, a larger active element can be used. For example, the area of the active element can be as large as the rigid block. This can aid assembly, as well as improving efficiency of the transducer.

The front 3 of the wear plate 2 can be shaped to have a specific profile. For example, this can provide greater freedom of movement for the wear plate 2.

Furthermore, the shape of the front 3 of the wear plate 2 can be optimised to maximise the use of air flow (or flow of some other fluid) to cool the transducer 1.

For example, the shape of the front 3 of the wear plate 2 can be arranged so as maximise its surface area. Thus, air can be blown across the front 3 of the wear plate 2 to cool it. Moreover, the profile of the front 3 of the wear plate 2 can be configured, e.g. by keeping it smooth, to reduce turbulent air flow which can generate noise.

The shape of the front 3 of the wear plate 2 can be changed in order to modify the contact area with a pipe provided that the thickness along the z-axis between the active piezoelectric element and the structure being tested remains a small (for example <10%) proportion of the wavelength of a shear wave in the wear plate.

Referring in particular to Figure 5, the wear plate 2 can be shaped to provide a sharp contact area 30, for example, in the form of a knife edge or sharp ridge. This allows the wear plate 2 to cut through or pierce a soft coating (not shown) covering a pipe (not shown) and contact an underlying metal wall of the pipe (not shown).

Preferably, the wear plate 2 comprises a tough material, such as a hard, non-brittle ceramic, a metal or metal alloy, such as stainless steel or tungsten carbide. The wear plate 2 can be a laminate, e.g. comprising a metal layer and an overlying layer of ceramic.

In Figure 6, the wear plate 2 is shown from the rear. The rear surface 4 of the wear plate 2 provides a recess having a stepped wall.

The axial contact length can be smaller than the diameter of the rigid block 16 (Figure 1) A narrow or convex contact profile allows the transducer to be tilted more.

Referring in particular to Figure 7, a modified wear plate 2' is shown which is shaped to provide a wide contact area 30'. This can be used to increase coupling between the pipe and the transducer.

As explained earlier, the transducer need not include a heat-extracting strip 5 (Figure 1) or a second piezoelectric layer 13 (Figure 1). For example, the heat-extracting layer can be omitted if the transducer is to be used to inspect cool objects.

Figure 9 shows another transducer 1'. The transducer 1' is similar to the transducer 1 (Figure 1) described earlier, but does not have a heat-extracting layer.

Figure 10 shows yet another transducer 1". The transducer 1" is similar to the transducer 1 (Figure 1) described earlier, but has only one piezoelectric layer 10.

Thus, the transducer 1" does not have a second transducer stack 11 including the second eatth electrode 12, the second active 13 layer and the second signal electrode 14. The transducer 1" also does not have a second electrical insulating layer 15 and a second coaxial cable 18.

Figure 11 shows still yet another transducer 1". The transducer 1" is similar to the transducer 1" (Figure 10) described earlier, but does not have a heat-extracting layer.

It will be appreciated that many modifications may be made to the embodiments hereinbefore described.

For example, in some of the embodiments, a heat-extracting strip is used.

Additionally or alternatively, the rear 4 (Figure 3) of the faceplate 2 can be coated, e.g. by electroplating, with a highly thermally-conductive coating, such as copper. -10-

Claims (12)

1. Claims 1. An ultrasonic transducer including: a wear plate; an active element arranged rearwards of the wear plate; and a rigid block arranged rearwards of the active element and configured to provide a backing mass for the active element; wherein the wear plate extends across the active element and rearwards so as to provide a cap over the active element and sides of at least a forward portion of the rigid block.
2. 2. An ultrasonic transducer according to claim 1, wherein the wear plate has a forward face and rearwards face, wherein the forward face is shaped to provide a knife edge.
3. 3. An ultrasonic transducer according to claim 1 or 2, wherein the wear plate comprises a ceramic.
4. 4. An ultrasonic transducer according to any preceding claim, further comprising a thermally-conductive element disposed between the wear plate and the active element for conducting away heat absorbed by the wear plate.
5. 5. An ultrasonic transducer according to claim 4, wherein thermally-conductive element comprises a layer of thermally-conductive material disposed on rearwards surface of the wear plate.
6. 6. An ultrasonic transducer according to any preceding claim, wherein the active element comprises a piezoelectric element.
7. 7. An ultrasonic transducer according to any preceding claim, wherein the active element is a shear polarised piezoelectric element.

   -11 -
8. 8. An ultrasonic transducer according to any preceding claim, further comprising another active element.
9. 9. An ultrasonic transducer according to claim 8, wherein the other active element is arranged between the active element and the rigid block in a stack.
10. 10. An ultrasonic transducer according to any preceding claim, further comprising a filler, such as an adhesive, arranged to encapsulate the active element and the forward portion of the rigid block.
11. 11. Apparatus for inspecting an elongate member, the apparatus comprising a plurality of ultrasonic transducers according to any preceding claim, the ultrasonic transducers arranged in a band around the elongate member.
12. 12. Apparatus according to claim 11, wherein the apparatus is configured to inspect a pipe and the ultrasonic transducer are angularly spaced in a ring around an exterior wall of the pipe.