Nondestructive Inspection Of Materials Research Articles

Current status of perovskite in X-ray detection for medical imaging technology

The X-ray imaging is a powerful tool used in medical diagnostics, non-destructive material inspection, security checks, nuclear plants and research field. Perovskites is considered as a promising candidate for X-ray detection owning to its remarkably improved sensitivity, low-cost synthesis, detection limit, response time and better special resolution. In this review paper the challenges and future scope of the reported work in the lead based and lead free single and polycrystalline perovskites is studied. Most of the reported results are based on single pixel detection. Hence, it is proposed that an interdisciplinary collaborative work will only facilitate its practical implementation in state-of-the-art X-ray imaging technology.

Variable Zoom technique for X-Ray Computed Tomography

X-ray Computed Tomography has proven its unprecedented objectivity for nondestructive inspection of materials and structures. However, high-resolution nondestructive evaluation of small critical flaws in structures with large in-plane dimensions has been a fundamental challenge for the CT techniques. This work presents a novel Variable Zoom X-ray CT technique that can significantly improve defect resolution for structures with large in-plane dimensions. The details of the scanning technique and the reconstruction method essential for achieving accurate high-resolution results are provided. Superior performance and accuracy of the technique is demonstrated on the dimensional and sharpness measurements of known features in the artificial phantom and in X-ray CT of composite panel with large in-plane dimensions. Application of the new approach is demonstrated on the detection of complex structural damage due to low-velocity impact in large and thin composite laminate panels, which is among the worst-case scenario for the conventional CT methods.

3-D Imaging of Materials at 0.1 THz for Inner- Defect Detection Using a Frequency-Modulated Continuous-Wave Radar

This article reports a novel 3-D imaging approach for remote, nondestructive material inspection at depth. The approach is based on a frequency-modulated continuous-wave (FMCW) radar system operating in the 75-110-GHz frequency band. Time-domain spectroscopy (TDS) measurements demonstrate that such a frequency band has manage-able attenuation levels in centimeter-long materials, thereby offering an advantageous resolution-versus-measurement-depth tradeoff compared with higher frequencies. The proposed setup includes a long delay on the reference signal in order to cancel redundant signals that would otherwise degrade the measurement. Furthermore, specific signal-processing techniques used to improve the performance of the system, which requires stringent component performances in terms of radio-frequency nonlinearity and return loss, are presented. Radio-frequency nonlinearity correction is based on a reference measurement, and the impact of deleterious reflections is reduced by averaging measurements conducted on a target at different longitudinal positions. As a result, an improvement of the signal-to-noise (S/N) ratio up to 20 dB is demonstrated. Tomography experiments were conducted on building materials showing 3-D imaging with theoretically limited longitudinal and transverse resolutions of 5 and 20 mm, respectively, thus opening the door to civil infrastructure monitoring applications.

Magnetic hysteresis and magnetic flux patterns measured by acoustically stimulated electromagnetic response in a steel plate

Magnetic hysteresis loops are measured by ultrasonic techniques and used in visualizing the magnetic-flux distribution in a steel plate. The piezomagnetic coefficient determines the amplitude of acoustically stimulated electromagnetic (ASEM) fields, yielding the hysteresis behavior of the intensity of the ASEM response. By utilizing the high correspondence of the ASEM response to the magnetic-flux density, we image the specific spatial patterns of the flux density formed by an artificial defect in a steel plate specimen. Magnetic-flux probing by ultrasonic waves is thus shown to be a viable method of nondestructive material inspection.

Efficient Geodesic Attribute Thinnings Based on the Barycentric Diameter

An attribute opening is an idempotent, anti-extensive and increasing operator, which removes from an image connected components which do not fulfil a given criterion. When the increasingness property is dropped, we obtain a—more general—attribute thinning. In this paper, we propose efficient grey scale thinnings based on geodesic attributes.Given that the geodesic diameter is time consuming, we propose a new geodesic attribute, the barycentric diameter to speed up the computation time. Then, we give the theoretical error bound between these two attributes, and we note that in practice, the barycentric diameter gives very similar results in comparison with the geodesic diameter. Finally, we present the algorithm with further optimisations, to obtain a 60× speed up.We illustrate the use of these thinnings in automated non-destructive material inspection: the detection of cracks. We discuss the advantages of these operators over other methods such as path openings or the supremum of openings with segments.

High quality electron beam produced by laser: A new tool for science

The use of ultra short laser pulses delivered by powerful laser systems has permitted the emergence of new approaches for generating energetic particle beams. By focusing these laser pulses onto matter, extremely large electric fields can be generated, reaching the TV/m level well in excess than those produced by conventional accelerators. As a result, the distance over which particles extracted from the target can be accelerated to hundreds of MeV is reduced to distances on the order of millimetres. These laser-produced electron beams have a number of interesting properties and could lead themselves to applications in many fields, including medicine (radiotherapy), radiobiology (short-time-scale, low dose irradiation), chemistry (radiolysis), non-destructive material inspection by radiography, and accelerator physics.

Staged concept of laser-plasma acceleration toward multi-GeV electron beams

The concepts of the laser-plasma based accelerator and injector are discussed here. The recent tests done at LOA as well as design studies of high-quality GeV electron beam production with low energy spread (1%) are presented. These laser-produced particle beams have a number of interesting properties and could lend themselves to applications in many fields, including medicine (radiotherapy), chemistry (radiolysis), and accelerator physics. They could be used as a source for the production of $\ensuremath{\gamma}$ ray beams for nondestructive material inspection by radiography, or for future compact X-free electron laser machines.

Improved vibroacoustography imaging for nondestructive inspection of materials

We report a method to improve image quality in the nondestructive investigation and visualization of defects using vibroacoustography (VA). Vibroacoustography is an ultrasound-based imaging technique that uses the dynamic (oscillatory) radiation force of low-frequency excitation (within kilohertz range) to remotely vibrate objects and detect the ensuing acoustic emission. This technique is nondestructive and noncontact and has shown numerous capabilities to produce high-resolution images of different types of materials. However, for reflective materials, ultrasound reflects back and forth between the object and transducer, thus establishing standing waves. This phenomenon produces an artifact in the shape of false contours in the VA images. The goal of this study is to investigate the formation of the standing wave artifacts and develop a process called chirp imaging to improve defect visibility and flaw detection capability. Chirp VA experiments are performed on a flawed fiber-reinforced ceramic composite plate and on an electronic chip. To assess the efficacy of the chirp imaging process in removing the standing-wave artifact, the resulting chirp images are compared to “fixed frequency” VA images. Results show that the false contour can be significantly reduced in the image, thus remarkably improving image quality and flaw detection.

Laser-plasma accelerators: a new tool for science and for society

The recent and continuous development of powerful laser systems has permitted the emergence of new approaches for generating energetic electron beams. By focusing light pulses containing a few joules of energy in a few tens of femtoseconds onto gas jets, extremely large electric fields can be generated, reaching the terravolts per metre level. Such fields are 10 000 times greater than those produced in the radio-frequency cavities of conventional accelerators. As a result, the length over which electrons extracted from the target can be accelerated to hundreds of MeV is reduced to a few millimetres. The reduction of the size and the cost of laser-plasma accelerators is a promising consequence, but these electron beams also reveal original properties, which make them a wonderful tool for science. By adjusting the interaction parameters, the electron energy distribution can be tuned from a maxwellian-like distribution to a quasi-monoenergetic one. The new properties of these laser-based particle beams are well suited to many applications in different fields, including medicine (radiotherapy), chemistry (ultrafast radiolysis), material science (non-destructive material inspection using radiography) and, of course, for accelerator physics.

Analysis of neutron attenuation in boron-alloyed stainless steel with neutron radiography and JEN-3 gauge

This paper concerns the neutron attenuation behavior of boron-alloyed stainless steels, and quantitative estimations of secondary effects on the neutron transmission measurements, such as beam hardening, background and micro-structure of neutron absorber causing a decrease in the total macroscopic cross-sections. Systematic thermal neutron transmission measurements of boron-alloyed steel plates have been performed at different neutron radiography facilities and at a portable gauge called JEN-3, which is a practical neutron transmission setup for industrial demands in non-destructive material inspection. In addition, MCNP (Monte Carlo Neutron Particle transport) simulations were performed for a better understanding of the experimental results, the secondary factors affecting the total macroscopic cross-sections, and the characteristics of the JEN-3 gauge. The detectable thickness limit for 1.88wt% natural boron-alloyed steel plates was determined as 1–1.5cm depending on the contributions of the secondary factors in each facility.

A unit for inspection of materials using differential gamma-ray scattering technique

The main objectives of this research were to develop a prototype unit using the differential gamma-ray scattering technique (DGST) and to demonstrate its possible use in nondestructive inspection of materials. The unit consisted of a 5 mCi (185 MBq) 137Cs gamma-ray source positioned perpendicularly to a 5 cm × 5 cm BGO detector. The gamma-ray beam was collimated by a 5 cm thick lead collimator with 1 cm ∅ opening while the detector was only side shielded allowing scattered gamma-rays to reach the detector from different angles. The unit was then tested with 20 cm × 20 cm × 20 cm concrete mortar containing four rebars at its corners. It was found that the integral of the differential spectrum changed corresponding to the size and position of the rebar which was in front of the source and the detector. It was also found that the integral of the differential spectrum increased with increasing degree of corrosion of the rebar. The results indicated that a portable DGST unit could be designed to be used as a tool in nondestructive inspection but the interpretation of the differential spectrum still needs further investigation.

Work of the N E Bauman Moscow State Technical University in the area of non-destructive inspection of materials and components

(2003). Work of the N E Bauman Moscow State Technical University in the area of non-destructive inspection of materials and components. Welding International: Vol. 17, No. 6, pp. 497-500.

Work of the N E Bauman Moscow State Technical University in the area of non-destructive inspection of materials and components

Work of the N E Bauman Moscow State Technical University in the area of non-destructive inspection of materials and components

Wireline Integrity Inspection Methods to Prevent Wire Breakage

Abstract The structural integrity and predictable usability of slickline wire has perplexed wireline crews since wireline services were first developed. Miscalculation of wire condition can cause wire failures and costly fishing operations. However, the available alternative-premature replacement of still-usable wire to avoid the first scenario-increases operational costs, especially when the newer corrosion- and embrittlement-resistant nickel and cobalt alloy wires that are commonly used in H2S, CO2, and hot chloride environments are involved. These wires often are ten times as costly as carbon steel and stainless steel alloy wires, and in most cases,. early replacement would not be economically feasible. Until recently, operators have had to rely on experience, "rules of thumb," visual inspection, and destructive tests to determine wire integrity. However, these methods could only provide spot checks; no methods have been capable of accurately assessing the condition of the entire length of spooled wire. This paper will review currently used inspection procedures and a concept that incorporates an existing, non-destructive material inspection technology into a real-time method that can provide the information to determine wire condition over its entire length. Use of this eddy current system can:Evaluate integrity of new wire as it is being spooled onto the reel.Avoid costly replacement of still-usable wire.Facilitate general wire-life assessment.Inspect wire during critical service operations where well environment or operating conditions can cause rapid degradation of the wire. Test results and field operational history are used to illustrate the capabilities and significance of the system. Introduction Slickline is a single-strand wire that can be made of various carbon steel, stainless alloy, and more exotic nickel and cobaltbased alloys and is available in varying lengths and diameters. Slickline lengths are generally between 4,572 to 9,144 m (15,000 and 30,000 ft.), and the most popular outside diameters (OD) are 2.34,2.67,2.74, and 3.18 mm (0.092,0.105,0.108, and 0.125 in.). "Braided line," "mono-conductor," or "multi-conductor" electric wireline consist of braids or multiple strands of smaller-OD wire, which are also available in various carbon steel, stainless and more exotic alloys in varying lengths and diameters. Braidedline and mono-conductor line lengths are generally between 4,572 to 7,620 m (15,000 and 25,000 ft.) with outside diameters of 4.76 or 5.56 mm (3116- or 7h2-in.). Multi-conductor line lengths are generally between 4,572 to 7,620 m (15,000 and 25,000 ft.) with outside diameters of 11.11 or 11.90 mm (7116- or 15h2-in.). Typical Wireline Operation In a wireline operation, tools are attached to the end of a wire and lowered into the wellbore. Once the tools reach their desired depth, they are manipulated in a series of upward and downward motions to perform the desired operation. The wire is stored on a reel in a truck or skid and is generally run through or around a counter wheel and several sheaves (Figure 1). The counter wheel is used to measure the length of the wire deployed into the well.

Use of Microwaves for Nondestructive Material Inspection

AbstractWideband S-parameter measurements have been used to investigate the properties of electrically non-conductive materials using a vector network analyzer. Using S21 scattering parameters, amplitude and phase shift measurements were taken for a variety of both homogeneous and heterogeneous materials. With these initial S-parameter measurements as a reference, surface defects were modeled on the test samples and the S-parameter measurements were reevaluated. The effect of varying levels of moisture absorption in certain materials was also investigated. The results of this study indicate that there is indeed potential for the use of a vector network analyzer as a nondestructive testing tool to evaluate the structural integrity and/or moisture content of electrically non-conductive materials through the transmission of microwave energy.

Optical Tomography for Three-Dimensional Spectroscopy

Fundamental to the development of many scientific fields is the need for quantitative observation of a specimen in three dimensions. Examples include the nondestructive inspection of materials to locate defects, measurement of atmospheric pollutants, determination of the distribution of a dye in a cell, or in vivo measurements of metabolic activity in tissue. For these type of analyses, optical measurements to determine concentration of the probe molecule are commonly employed.

REMOTE THICKNESS MEASUREMENT OF OIL SLICKS ON WATER BY LASER-ULTRASONICS

ABSTRACT At the National Research Council of Canada Industrial Materials Institute, research is in progress on the application of laser-ultrasonics to remote measurement of the thickness of oil on water. Laser-ultrasonics is a novel technique developed for the nondestructive inspection of materials. It uses a short pulse laser for the generation of ultrasonic waves in the oil layer and a second laser, coupled to an optical interferometer, for the remote detection of the ultrasonic surface motion. Direct measurement of the time of flight of the ultrasonic wave provides the value of the thickness of the oil layer. Application of this technique to thickness measurement of oil on water has been studied in small and large scale laboratory tests. Small scale tests demonstrate the direct and unambiguous determination of the oil layer thickness. Accuracy is essentially limited by the knowledge of the acoustic properties of the oil. Large scale tests show that a distance of almost 37 meters does not severely impede the method, so airborne application appears possible. Surface motion such as that caused by sea waves does not reduce the accuracy of the thickness determination but does limit the measurement rate. Preliminary airborne tests with a single laser probe confirm that laser-ultrasonics monitoring of the thickness of an oil spill is feasible.

Application of Ultrasound to NDE of Materials

Absrract-A review of state of the art applications of ultrasonics to the nondestructive inspection of materials for defects is given along with some of the limitations associated with the present state of the art. These limitations include 1) the inability to determine defect dimensions quantitatively, 2) the lack of suitable reference standards, 3) the general lack of equipment for the inspection of parts with complex geometries, 4) the nonreproducibility of transducer characteristics, and 5) the lack of a sound theoretical foundation for ultrasounddiscontinuity interaction. Some of the current research and development work in the use of digital computers for scanning parts with complex geometries and in signal processing to increase inspection reliability and defect detection is also described.