Multielements ultrasonic contact transducer

Communications – electrical: acoustic wave systems and devices – Transmitter systems – With beam forming – shaping – steering – or scanning

Reexamination Certificate

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C367S155000, C367S128000

Reexamination Certificate

active

06424597

ABSTRACT:

DESCRIPTION
1. Technical Field
This invention relates to an ultrasonic contact transducer with multiple elements.
It is particularly applicable to medicine and nondestructive destructive testing of mechanical parts, and particularly parts with a complex shape or irregular surface condition, for example due to grinding.
2. State of Prior Art
In many industrial fields, and particularly in the case of nuclear power stations, testing by an ultrasonic contact transducer plays an important role in material inspection.
This technique consists of moving this ultrasonic transducer directly into contact with a part to be inspected. For each of its positions, the transducer emits ultrasonic pulses and records echoes reflected by the structure and possibly part defects.
However, many geometric aspects make the use of ultrasounds difficult; restricted access (particularly for connections), variable surface conditions and profile variations. Transducers used during these inspections are conventional transducers that cannot optimize the examination.
For example, depending on the areas, sensitivity variations can be observed caused by bad contact between the transducer and the inspected part, or inaccurate positioning may occur due to incorrect orientation of the transducer pressed in contact with the part, or a weld may be only partially covered when the transducer is prevented from moving by the surface configuration.
Therefore, many difficulties are observed during inspections carried out on parts with complex configurations. They illustrate the limits to the performances of conventional ultrasonic contact transducers:
1) Variation of the Thickness of the Coupling Layer
Contact is not optimal when the ultrasonic transducer passes over an area with a nonconforming surface condition or with configuration variations. Thus, the coupling layer located between the surface of the test piece being inspected and the emitting surface of the transducer has a variable thickness. Therefore the delay due to passing through this layer is different for ultrasonic waves emitted from different points on the transducer surface.
Furthermore, complex interference phenomena between the different successively reflected waves occur in this layer. The result is a deterioration of the ultrasonic beam resulting in a loss of sensitivity of the inspection. The capacity of the transducer to detect defects is thus limited.
2) Incorrect Transducer Orientations
The orientation of a transducer pressed on a test piece while being used to make an inspection of a test piece with profile variations, varies during the inspection. Thus, the direction of propagation of the ultrasonic wave in the test piece cannot be controlled since it changes as the transducer is displaced along the profile.
During an inspection carried out in manual mode, the operator cannot make the displacement along a perfectly straight line, which causes another disorientation of the transmitted ultrasonic beam. Information about the position of the defect in the test piece is then lost since the direction of propagation of the beam in this test piece is unknown.
3) Restricted Access
In some cases, the configuration of a part to be inspected makes it impossible to move the transducer along the full length of this part. The area to be inspected can only be partially covered.
We will now examine known solutions for solving these problems.
The ultrasonic beam is controlled by focusing the transmitted beam in the inspected part at a predetermined focusing depth and orientation.
The focusing principle consists of applying delays to the emitting surface such that contributions reach the required focal point in phase.
In the case of monolithic transducers, delays are physically distributed by applying a phase shifting lens formed on the emission surface. Therefore this type of system is fixed, and can only be satisfactory if there are no configuration variations on the part surface.
Dynamic shaping of the ultrasonic beam requires the use of transducers with multiple elements or multi-element transducers. Delays are electronically assigned to each element in the transducer, so that the characteristics of the ultrasonic beam generated by a single element can be modified, and therefore the beam focus can be controlled, and at the same time deformations caused by surfaces with a variable configuration can be compensated.
1) Immersed Multi-element Transducers
An inspection of a part with a variable profile can be carried out using a multi-element transducer immersed in a coupling liquid, for example water. In this case, the transducer is no longer placed in direct contact with the part, but is separated from it by a sufficiently thick layer of water so that interference phenomena between the different ultrasonic waves successively reflected in the coupling layer (a water layer in the example considered) are strongly reduced.
During the inspection of a part with a complex geometry, the ultrasonic beam is focused by calculating the path in water and the material from which this part is made (for example steel) of ultrasonic waves limited by the different elements of the transducer to the focal point, for each position of the transducer.
This solution causes serious difficulties. The adapted delay law cannot be calculated without knowledge of the exact configuration of the part and the position and orientation of the transducer with respect to the part.
Furthermore, this inspection mode cannot always be used in an industrial environment. Local immersion of the part may be difficult, particularly due to restricted access.
2) Multi-element Contact Transducers
Multi-element contact transducers are also used. However, degradations to the transmitted field due to an unsuitable contact are present during the inspection of parts with complex configurations.
Algorithmic techniques have been developed to compensate for this degradation, but they are not very satisfactory because they require that known defects should be present in the part.
One recently developed solution consists of using a multi-element contact transducer with a deformable emitting surface to adapt to the exact surface of the part. In this case contact is optimal, the coupling layer between the emitting surface and the inspected part remains sufficiently thin and uniform to not disturb transmission of the wave.
One particular transducer is obtained from rigid piezoelectric wafers (made of ceramic) embedded in a flexible substrate that is passive to ultrasounds and is described in the following documents:
D. J. Powell, and G. Hayward “Flexible ultrasonic transducer arrays for Nondestructive evaluation applications PART I: The theoretical modeling approach”, IEEE transactions on ultrasonics, ferroelectrics, and frequency control, vol. 43, No. 3, May 1996, pages 385 to 392;
D. J. Powell and G. Hayward, “Flexible ultrasonic transducer arrays for nondestructive evaluation applications PART II: Performance assessment of different array configurations”, IEEE transactions on ultrasonic, ferroelectrics, and frequency control, vol. 43, No. 3, May 1996, pages 393-402; and
Internal patent application WO 94/13411, international publication date: Jun. 23, 1994 for “Ultrasonic transducer”, invented by G. Hayward and D. J. Powell.
However in this case, control of the transmitted ultrasonic beam in order to optimize characterization of defects requires exact knowledge of the geometry of the inspected part and the position and orientation of the transducer with respect to this part.
DESCRIPTION OF THE INVENTION
This invention is designed to improve the performance of the ultrasound inspection of a part with a complex geometry (mechanical part or even part of the human body) in order to better detect, localize and characterize defects in this object.
Improvement of this performance requires control of the ultrasonic beam transmitted in the object, particularly concerning the focusing depth and orientation of this beam.
More precisely, the purpose of this invention is an ultrasonic contact transducer with multiple elements, each e

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