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Author: Colin Williams Publisher: ISBN: Category : Languages : en Pages : 0
Book Description
The goal of this research is to find new noninvasive methods to certify the quality of safety-critical additively manufactured (AM) metallic parts for use in industries such as aerospace and defense. Additive manufacturing facilitates rapid prototyping, building, and repairing of custom components with increased agility, production rate, and reduced waste. A recognized barrier to the wide adoption of additive manufacturing is the lack of new approaches for AM part qualification. Our research objective is to exploit the material's linear and nonlinear ultrasonic response - which represents the measurable changes and distortion in elastic waves encountering macroscopic and microscopic defects - to establish links between microstructure and macroscale mechanical properties of AM metals. We measure linear and nonlinear ultrasonic parameters for a series of AM and wrought 316L grade stainless steel samples and compare the obtained parameters against mechanical properties of the samples measured on corresponding coupons. The samples are heat-treated to different temperatures to induce microstructural changes which alter their mechanical properties and ultrasonic response. Two sets of specimens are manufactured, one from the additive manufacturing method Laser Powder Bed Fusion (L-PBF), and the second from a traditional wrought method. Using the nonlinear ultrasonic method of Second Harmonic Generation (SHG), the acoustic nonlinearity parameter is estimated. SHG has been shown to offer a highly sensitive response to microstructural heterogeneities such as dislocations and grain boundaries. A linear ultrasonic parameter, wave speed, is also recorded with pulse-echo testing. Alongside these ultrasonic measurements, mechanical testing parameters including elastic moduli and yield strength are evaluated for the specimens. To accompany the experimental testing, a series of numerical simulations were conducted using commercial finite-element software to study the effects of randomly distributed heterogeneities on wave distortion in a controlled environment. In these simulations, randomly generated heterogeneities are scattered throughout a 2D plate with materials properties different from the bulk material. Ultrasonic wave propagation is simulated within this heterogeneous medium to investigate the effects of the heterogeneities' elastic properties, geometry, and distribution on ultrasonic signals, including distortion measured in terms of higher harmonic generation (HHG). Experimental results indicate correlations between the nonlinearity parameter and both ultimate tensile strength and yield strength, where nonlinearity generally decreases as these mechanical parameters increase, particularly in the AM samples. We hypothesize that microstructural changes in grain size and distribution through the heat treatment process influence these trends in measured nonlinearity. Additionally, substructures at even smaller length scales, such as nanoscale precipitates and dislocations affect the ultrasonic and mechanical behavior. Measurements of elastic moduli and total elongation do not exhibit trends with the nonlinearity parameter. The linear parameter, wave speed, does not correlate well with the mechanical parameters, which is attributed to its lack of sensitivity to detect changes in microscopic features. These results show promising evidence for the feasibility of AM parts qualification using nondestructive nonlinear ultrasonic testing. Results of the simulations indicate that changes in heterogeneity size, volume fraction, and material property deviations from the bulk material affect HHG to varying degrees. As expected, heterogeneities of smaller sizes and volume fractions have a less significant effect. However, at increasingly large values, changes in HHG are more pronounced, and material density and stiffness deviations from the bulk material are shown to have a larger effect on HHG. Future work includes continuing nonlinear ultrasonic testing, as well as comparing results to nonlinear resonant ultrasound spectroscopy (NRUS). New geometries and materials will be tested to expand the dataset. Microstructures will be imaged using scanning and transmission electron microscopy (SEM, TEM) and evaluate our hypotheses, and further complexity in numerical simulations will be implemented to isolate microstructural features and explore their effects on material behavior.
Author: Colin Williams Publisher: ISBN: Category : Languages : en Pages : 0
Book Description
The goal of this research is to find new noninvasive methods to certify the quality of safety-critical additively manufactured (AM) metallic parts for use in industries such as aerospace and defense. Additive manufacturing facilitates rapid prototyping, building, and repairing of custom components with increased agility, production rate, and reduced waste. A recognized barrier to the wide adoption of additive manufacturing is the lack of new approaches for AM part qualification. Our research objective is to exploit the material's linear and nonlinear ultrasonic response - which represents the measurable changes and distortion in elastic waves encountering macroscopic and microscopic defects - to establish links between microstructure and macroscale mechanical properties of AM metals. We measure linear and nonlinear ultrasonic parameters for a series of AM and wrought 316L grade stainless steel samples and compare the obtained parameters against mechanical properties of the samples measured on corresponding coupons. The samples are heat-treated to different temperatures to induce microstructural changes which alter their mechanical properties and ultrasonic response. Two sets of specimens are manufactured, one from the additive manufacturing method Laser Powder Bed Fusion (L-PBF), and the second from a traditional wrought method. Using the nonlinear ultrasonic method of Second Harmonic Generation (SHG), the acoustic nonlinearity parameter is estimated. SHG has been shown to offer a highly sensitive response to microstructural heterogeneities such as dislocations and grain boundaries. A linear ultrasonic parameter, wave speed, is also recorded with pulse-echo testing. Alongside these ultrasonic measurements, mechanical testing parameters including elastic moduli and yield strength are evaluated for the specimens. To accompany the experimental testing, a series of numerical simulations were conducted using commercial finite-element software to study the effects of randomly distributed heterogeneities on wave distortion in a controlled environment. In these simulations, randomly generated heterogeneities are scattered throughout a 2D plate with materials properties different from the bulk material. Ultrasonic wave propagation is simulated within this heterogeneous medium to investigate the effects of the heterogeneities' elastic properties, geometry, and distribution on ultrasonic signals, including distortion measured in terms of higher harmonic generation (HHG). Experimental results indicate correlations between the nonlinearity parameter and both ultimate tensile strength and yield strength, where nonlinearity generally decreases as these mechanical parameters increase, particularly in the AM samples. We hypothesize that microstructural changes in grain size and distribution through the heat treatment process influence these trends in measured nonlinearity. Additionally, substructures at even smaller length scales, such as nanoscale precipitates and dislocations affect the ultrasonic and mechanical behavior. Measurements of elastic moduli and total elongation do not exhibit trends with the nonlinearity parameter. The linear parameter, wave speed, does not correlate well with the mechanical parameters, which is attributed to its lack of sensitivity to detect changes in microscopic features. These results show promising evidence for the feasibility of AM parts qualification using nondestructive nonlinear ultrasonic testing. Results of the simulations indicate that changes in heterogeneity size, volume fraction, and material property deviations from the bulk material affect HHG to varying degrees. As expected, heterogeneities of smaller sizes and volume fractions have a less significant effect. However, at increasingly large values, changes in HHG are more pronounced, and material density and stiffness deviations from the bulk material are shown to have a larger effect on HHG. Future work includes continuing nonlinear ultrasonic testing, as well as comparing results to nonlinear resonant ultrasound spectroscopy (NRUS). New geometries and materials will be tested to expand the dataset. Microstructures will be imaged using scanning and transmission electron microscopy (SEM, TEM) and evaluate our hypotheses, and further complexity in numerical simulations will be implemented to isolate microstructural features and explore their effects on material behavior.
Author: Malcolm J.W. Povey Publisher: Elsevier ISBN: 0080519849 Category : Science Languages : en Pages : 229
Book Description
This book is a comprehensive and practical guide to the use of ultrasonic techniques for the characterization of fluids. Focusing on ultrasonic velocimetry, the author covers the basic topics and techniques necessaryfor successful ultrasound measurements on emulsions, dispersions, multiphase media, and viscoelastic/viscoplastic materials. Advanced techniques such as scattering, particle sizing, and automation are also presented. As a handbook for industrial and scientific use, Ultrasonic Techniques for Fluids Characterization is an indispensable guide to chemists and chemical engineers using ultrasound for research or process monitoring in the chemical, food processing, pharmaceutical, cosmetic, biotechnology,and fuels industries. Appeals to anyone using ultrasound to study fluids Provides the first detailed description of the ultrasound profiling technique for dispersions Describes new techniques for measuring phase transitions and nucleation, such as water/ice and oil/fat Presents the latest ultrasound techniques for particle sizing in concentrated systems Explains new techniques for compressibility measurements in dispersions and fluids, including cell suspensions Contains a detailed treatment of ultrasound scattering theory Written by one of the leading researchers in the field Includes over 350 references to the primary literature
Author: Chi-hau Chen Publisher: World Scientific ISBN: 9812704094 Category : Medical Languages : en Pages : 682
Book Description
Ultrasonic methods have been very popular in nondestructive testing and characterization of materials. This book deals with both industrial ultrasound and medical ultrasound. The advantages of ultrasound include flexibility, low cost, in-line operation, and providing data in both signal and image formats for further analysis. The book devotes 11 chapters to ultrasonic methods. However, ultrasonic methods can be much less effective with some applications. So the book also has 14 chapters catering to other or advanced methods for nondestructive testing or material characterization. Topics like structural health monitoring, Terahertz methods, X-ray and thermography methods are presented. Besides different sensors for nondestructive testing, the book places much emphasis on signal/image processing and pattern recognition of the signals acquired.
Author: Tribikram Kundu Publisher: CRC Press ISBN: 9780203501962 Category : Science Languages : en Pages : 848
Book Description
Most books on ultrasonic nondestructive evaluation (NDE) focus either on its theoretical background or on advanced applications. Furthermore, information on the most current applications, such as guided wave techniques and acoustic microscopy, is scattered throughout various conference proceedings and journals. No one book has integrated these aspe
Author: Daniel R. Foster Publisher: ISBN: Category : Languages : en Pages : 212
Book Description
Although UAM has tremendous engineering potential, the effect of interfacial bonding defects on the mechanical and thermal properties have not be characterized. Incomplete interfacial bonding at the laminar surfaces due to insufficient welding energy can result in interfacial voids. Voids create discontinuities in the structure which change the mechanical and thermal properties of the component, resulting in a structure that has different properties than the monolithic material used to create it.
Author: Tianyang Han Publisher: ISBN: Category : Finite element method Languages : en Pages : 159
Book Description
Ultrasonic additive manufacturing (UAM) is a solid-state manufacturing technology that produces near-net shape metallic parts. UAM has been demonstrated to make robust structures with a variety of material combinations such as Al-Al, Al-Ti, Cu-Cu, and Al-Cu. However, UAM welding of high strength steels has proven challenging. The focus of this work is to develop a fundamental understanding of the structure-property-process relationship of UAM steel welding through experiments and modeling. Process and post-processing methods to improve UAM steel weld quality were investigated. A custom shear test was first developed and optimized to test the mechanical strength of UAM builds. The second study demonstrated the UAM fabrication of stainless steel 410 builds which possess, after post-processing, mechanical properties comparable with bulk 410 material. Fracture surface analyses confirm the weld quality improvement caused by increasing the baseplate temperature and the application of hot isostatic pressing (HIP) post weld. In the third study, a higher weld power is demonstrated by using a cobalt-based sonotrode coating, achieving shear strengths comparable to bulk 4130 material without post treatment. Weld parameters for making UAM 4130 builds were optimized via a design of experiments study. Baseplate temperature of 400 ̊F (204.4 ̊C), amplitude of 31.5 μm, welding speed of 40 in/min (16.93 mm/s), and normal force of 6000 N were identified as optimal within the selected process window. Analysis of variance and main effect plots show that normal force, amplitude, and welding speed are significant for interfacial temperature. Similar analyses show that normal force and amplitude have a statistically significant effect on shear strength. Residual stress in UAM 4130 samples was measured for the first time using neutron diffraction. The maximum tensile residual stress for UAM 4130 is found to be relatively low at 176.5 MPa, which suggests a potentially better fatigue performance of UAM builds compared to fusion-based additive manufactured parts. FE models that describe the stress distribution and predict the fatigue performance of UAM steel builds were developed. The models predict that the fatigue cracking of the interface between the baseplate and the first layer of foil (0th interface) occurs while welding the 10th layer of 4130 steel foil, which agrees with the experimental observation. Further computational analyses indicate that a taller crack-free UAM steel build can be produced if a higher shear strength can be achieved at the 0th interface using a relatively higher welding speed and lower ultrasonic power input. A UAM thermal model predicting the temperature rise due to heat generation from frictional sliding and plastic deformation during the UAM welding process was developed. Computational case studies indicate that a decrease in welding speed, an increase in vibration amplitude, a decrease in normal force, or an increase in baseplate temperature would lead to an increase in the peak temperature. Overall, 26 out of 32 measured peak temperatures fall into the range predicted by the UAM thermal model. The agreement between model predictions and experimental results validates the UAM thermal model.
Author: Giovanni Bruno Publisher: Mdpi AG ISBN: 9783036558134 Category : Technology & Engineering Languages : en Pages : 0
Book Description
This reprint is concerned with the microstructural characterization and the defect analysis of metallic additively manufactured (AM) materials and parts. Special attention is paid to the determination of residual stress in such parts and to online monitoring techniques devised to predict the appearance of defects. Finally, several non-destructive testing techniques are employed to assess the quality of AM materials and parts.
Author: A. Alippi Publisher: Springer Science & Business Media ISBN: 9789024734900 Category : Technology & Engineering Languages : en Pages : 446
Book Description
The purpose of the School, the content of which is reflected in this book, is to bring together experiences and knowledge of those acousticians who are particularly sensible to materials and their properties, specifically to those materials that may be called inhomo geneous. The two things together: acoustics and inhomogeneity, define factually a dimension less parameter, AI a, which is the ratio between the sound wavelength and the spatial length of the material where its physical characteristics notably change. An implicit defmition is, therefore, at hand for an inhomogeneous medium, which has the characteristic of a condi tioned definition and sets a looser constraint to the otherwise strict statement of invariance under translations. Composite, biologicai, porous, stratified materials are in the list of inhomogeneous materials, whose technological or structural interest has grown greatly in recent times. Ul trasonic waves offer a means for their investigation, which is valuable for it can be non destructive, continuous in time, spatially localized, dependent on the size of inhomoge neities.
Author: Colin Williams
Author: Colin Williams
Author: Malcolm J.W. Povey
Author: Chi-hau Chen
Author: Harold Berger
Author: Tribikram Kundu
Author: Daniel R. Foster
Author: Tianyang Han
Author: Giovanni Bruno
Author: A. Alippi
Author: Jeng Tzong Sheu