Browse Topic: Metals

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Characterization of Cut and Chip Damage in Ultra Low Rolling Resistance Tire for Electric Vehicles2024-28-0175To be published on 12/05/2024
Since the inception of battery driven electric vehicles in the automotive world, there has been a constant challenge in maximizing the range of an electric vehicles through various means including battery technology, vehicle weight optimization, low drag coefficients etc. The tires being a viscoelastic composite material have now become a vital to the range performance of an EV. The rolling resistance of a tire is now become a hotter topic than ever. The rolling resistance coefficient (RRC) is the measure of energy loss during rolling due to viscoelastic dissipation in the tire. The viscous dissipation in tire arises due to hysteresis in the various components of a tire including tread, sidewall, inner liner, apex etc rubber compounds. The internal friction between layers of body ply, steel belts and tread crown ply also contribute to the internal heat generation. Therefore, the development of ultra-low RRC tires is a serious challenge for tire engineers. Nevertheless, the recent
Mishra, NitishSingh, Ram Krishnan
Technical Paper
Evaluation of Mechanical Properties of Reduced Stress Localized Aluminium Composites for Automobile Applications2024-28-0241To be published on 12/05/2024
The modern-day development in the field of mobility demands the development of advanced engineering materials for various engineering applications. Composite materials play a pivotal role in the advancement of mobility by achieving overall weight reduction and thereby contributing to the sustainability of the environment. Metal matrix composites has played a crucial role over the last few decades in the automotive industry replacing the conventional metal in achieving a better strength to weight ratio. Metal matrix composites can be a combination of a metal and a ceramic combined at a macroscopic level to achieve better mechanical and tribological properties at a reduced weight to strength ratio. Aluminium being one of the largest metals widely used in automobiles, are gradually being replaced with Aluminium metal matrix composites. Aluminium – silicon carbide composite is a key interest among the researchers due to the attractive mechanical and tribological properties that enhance the
Valsan, Ashray
Technical Paper
Development of an Assessment Methodology for synchronizer ring (CuZn Alloy) wear durability2024-28-0185To be published on 12/05/2024
An optimized gear shift feeling throughout the life of a MT Gearbox is one of the major challenges during transmission development. Synchronizer ring’s function during its intended life play important role to get optimized gear shifting effort. Any undesired synchronizer ring (CuZn Alloy) wear causes high effort in gear engagement during vehicle running and discomfort to the driver. High wear rate reduces the life span on synchronizer ring. Current paper explains the experimental approach for study of critical parameters on synchronizer ring wear and Coefficient of friction (COF) under controlled temperature environment on test bench. Gear shift loading conditions based on Reflected Inertia (kgm2), shifting time (sec), shifting load (N) on gear knob and speed difference (rpm) between gears were calculated on synchronizer ring level and accordingly the loading conditions such as sliding speed (m/s), axial pressure (N/mm2) and synchro energy (J) were decided. As synchro wear rate and
Singh, ParamjeetYadav, Sanjay Kumar
Technical Paper
Effect of Temperature on Aluminum Alloy (Al4032) using Textured Surface2024-28-0160To be published on 12/05/2024
Larger domain of surface texture geometry and other input variables related to engine operation i.e. elevated temperature has remained to be studied for finding suitable surface texture for real-time engine operations. In previous efforts to find suitable surface texture geometry and technique, the tribological performance of the piston material (Al4032) with dimples of varying diameters (90 to 240 µm) was evaluated under mixed lubrication conditions in a pin-on-disk configuration. The disc was textured using a ball nose end mill cutter via conventional micromachining techniques. The area density and aspect ratio (depth to diameter) of the dimples were kept constant at 10% and 1/6, respectively. SAE 20W-40 oil was used as a lubricant with three separate drop volumes. The experiments were conducted in oscillating motion at a temperature of 150°C. Conventional micromachining achieved improved dimensional precision and minimized thermal damage. Textured surfaces have shown reduced
Sahu, Vikas KumarShukla, Pravesh ChandraGangopadhyay, Soumya
Technical Paper
A Facile Synthesis and molecular characterization of Electroactive Polyaniline Nanocomposites materials based on Sliver Embedded Poly Aniline copolymers for application in automobile industries2024-28-0158To be published on 12/05/2024
In-situ chemical oxidative polymerization was used to develop a new series of functional electroactive nanocomposites based on HCl doped and silver embedded poly (aniline-co-3-chloroaniline). In order to investigate these copolymer nanocomposites, FTIR, UV-visible spectroscopy, X-ray diffraction (XRD), scanning electron microscopy (SEM), and a conventional four probe conductivity approach were all used. The developed copolymer has excellent solubility in widely used organic solvents like DMF, THF, and NMP. The spectral value at 341nm is related to π-π* electronic transition of benzenoid ring and peak at 624 nm is attributed to n-π* electronic transition of quinoid ring. The band at 1300 cm-1 has been accredited to the combination of C-N in quinoid and benzenoid sequences. X-ray diffraction (XRD) reveals the crystalline nature of copolymer. Surface morphological studies exhibit nanoneedle like appearance with average particle size of 150-300 nm. Applications of Composites based on PANI
Pachanoor, VijayanandMoorthi, Bharathiraja
Technical Paper
Analyzing effect of reinforcement on stir casted 7075 Aluminum alloy2024-28-0165To be published on 12/05/2024
Growing demand for fuel-efficient vehicles and lower CO2 emissions has led to the development of lightweight materials. Aluminum composites are being used to achieve light weighting in order to improve performance, efficiency, and sustainability across various industries. The unique properties of aluminum composites make them an attractive choice for researchers and designers looking to optimize their products. Reinforcement materials play a vital role in the development of these composites, acting as barriers to dislocation movement within the aluminum matrix. This effectively strengthens the material and prevents deformation under load, resulting in increased tensile strength and fatigue resistance. Additionally, aluminum composites exhibit improved thermal and electrical conductivity, making them suitable for automotive applications. In this study, metal matrix composites (MMCs) of aluminum 7075 alloy were developed using silicon carbide (SiC) and fly ash as reinforcements. Three
Manwatkar, Asmita AshokSantosh Jambhale, MedhaMahagaonkar, NitinSharma, Dipesh
Technical Paper
A comprehensive review of advancement in anode material with modified architecture for lithium-ion batteries2024-28-0142To be published on 12/05/2024
Anode material, responsible for the critical storage and release of lithium ions during charge and discharge cycles, holds paramount importance. By strategically altering the material design and composition of the current graphite, researchers aim to significantly improve fast charging capabilities, energy density, cycling stability and overall electrochemical kinetics within Lithium ion battery. Anode materials operate through three primary mechanisms: insertion/de-insertion that is allowing for reversible lithium ion accommodation within the host structure; alloying, where lithium ions form chemical bonds with the anode material; and conversion reactions, involving the creation of new phases during charge/discharge cycles. This review delves into a captivating array of advanced anode materials with the potential to surpass the limitations of traditional graphite. Carbon-based nanomaterials like graphene and its derivative, reduced graphene oxide, offer exceptional conductivity and
Borkar, ShwetaNahalde, SujayRuban J S, AlwinMore, Hemant
Technical Paper
Evaluation of joining performance of different coated steel sheets used in automotive applications2024-28-0163To be published on 12/05/2024
To meet corrosion target of automotive vehicles, different coated steel sheets are used in various parts of body in white, chassis and powertrain. Hot dip galvanized (GI) and hot hip galvannealed(GA) are the two most commonly used steel sheets across world. Other coatings such as Zn-Ni, Al-Si , Zn plating and electro galvanized zing coating are application specific coating, which are used suitably to meet different performance requirement. To meet robust corrosion and performance requirement, there is trend of increase in coated steel sheet use in automotive vehicle. While different coated steels are having different corrosion performance, they also exhibit different joining and paint adhesion performance. Spot welding is the most common technique used for joining automotive parts. Joint strength majorly depends on steel base material grade, chemistry and properties. However, coating on base material also influence joining performance. Major challenge is faced when different coated
Jain, VikasMisal, SwapnaliDeshmukh, MansiPaliwal, Lokesh
Technical Paper
Microstructural characterization of aluminum alloys used in automotive body parts2024-28-0157To be published on 12/05/2024
To meet light-weighting and safety target of automotive vehicles, different aluminum alloys are used in various body parts. Apart from conventional manufacturing process of gravity die casting (GDC), advanced manufacturing process such as low pressure die casting (LPDC), high pressure die casting (HPDC) and extrusion processes are also used to form complex automotive body parts. Steel parts are majorly used in automotive applications across world. However, steel has limitations with respect to light-weighting. To achieve light-weighting, now a days, there is trend to use these complex aluminum parts in automotive industry to replace steel and integrate multiple parts into single part. Aluminum has emerges as great potential for light-weighting and reducing complexity of handling multiple parts at automotive plant. Aluminum provide additional benefits of high durability and crash performance. There is challenge to identify suitable etchant for microstructural characterization of
Deshmukh, MansiJain, VikasMisal, SwapnaliPaliwal, Lokesh
Technical Paper
Anodic Treatment of Aluminum Alloys Sulfuric Acid Process, Dyed CoatingsAMS2472J (Current)11/21/2024
This specification establishes the requirements for dyed anodic coatings on aluminum alloys
AMS B Finishes Processes and Fluids Committee
Material Specification
Aluminum Alloy, Hand Forgings 7.7Zn - 2.4Mg - 1.6Cu - 0.16Cr (7049-T7352) Solution Heat Treated, Stress Relieved by Compression, and Precipitation Heat TreatedAMS4247D (Current)11/21/2024
This specification covers an aluminum alloy in the form of hand forgings up to 5.000 inches (127.00 mm), inclusive, in nominal thickness at the time of heat treatment, procured to inch/pound dimensions (see 8.6
AMS D Nonferrous Alloys Committee
Material Specification
Nickel Alloy, Corrosion and Heat-Resistant, Bars, Forgings, Rings and Forging and Flash-Welded Ring Stock 64Ni - 5.0Cr - 24.5Mo - 5.5Fe (Alloy W) Solution Heat TreatedAMS5755H (Current)11/21/2024
This specification covers a corrosion- and heat-resistant nickel alloy in the form of bars, forgings, flash-welded rings, and stock for forging or flash-welded rings
AMS F Corrosion and Heat Resistant Alloys Committee
Material Specification
HIGH MN, HIGH AL STEELS FOR THICK PLATE ARMOR APPLICATIONS2024-01-373911/15/2024
ABSTRACT FeMnAlC alloys exhibit lower density (6.5-7.2 g/cm3) than traditional military steels (7.9 g/cm3) while maintaining similar energy absorption capabilities. Material substitutions in legacy systems must meet existing form/fit/function requirements, limiting opportunities for lightweighting of existing designs. This study examines production and material properties of thick plate with a nominal chemistry of 30% Mn, 9%Al and 1%C, in the wrought condition. Due to the high aluminum and carbon content, there are unique challenges to large scale (45+ ton heat) production versus typical armor steel chemistries. Lab-scale wrought and production material are characterized, comparing microstructure, and mechanical properties. Processing practices including teeming flux and rolling temperature are discussed. The high manganese content of this alloy presents challenges for welding and machining practices, such as limited compatibility of weld wires and substantial work hardening during
Sebeck, KatherineToppler, IanRogers, MattLimmer, KristaCheeseman, BryanHowell, RyanHerman, William
Technical Paper
Compositional Sensitivity of High Mn, High Al Lightweight Steels2024-01-381511/15/2024
ABSTRACT The family of lightweight high Mn, high Al steels (FeMnAl) exhibit lower density (6.5-7.2 g/cm3) than traditional military steels (7.9 g/cm3). These alloys are precipitation hardened, with κ-carbide dominating hardening performance. This carbide has an E21 perovskite structure with a nominal composition of (Fe,Mn)3AlC. In the literature, a number of studies have examined the sensitivity of mechanical properties to changing a single element in the composition. However, the covariance of the major elements has not been systematically explored. In this study, a series of small ingots were prepared according to a two-factor design of experiments, in addition to analysis of previously generated compositions. Methods of measuring alloy composition will be discussed, along with aging kinetics and key mechanical properties. Citation: K. Sebeck, I. Toppler, K. Limmer, D. Field, D. Wagner, A. Gafner, “Compositional Sensitivity of High Mn, High Al Steels”, In Proceedings of the Ground
Sebeck, KatherineToppler, IanLimmer, KristaField, DanielWagner, DanielGafner, Alyssa
Technical Paper
EFFECT OF PRE-BENDING AND HYSTERESIS OF A METAL PLATE ON BLAST-LOADING DEFORMATION: DATA VS. NUMERICAL SIMULATION2024-01-364111/15/2024
ABSTRACT V-shaped hulls for vehicles, to mitigate buried blast loads, are typically formed by bending plate. Such an approach was carried out in fabricating small test articles and testing them with buried-explosive blast load in Southwest Research Institute’s (SwRI) Landmine Test Fixture. During the experiments, detailed time dependent deflections were recorded over a wide area of the test article surface using the Dynamic Deformation Instrumentation System (DDIS). This information allowed detailed comparison with numerical simulations that were performed with LS-DYNA. Though in general there is good agreement on the deflection, in the specific location of the bends in the steel the agreement decreases in the lateral cross section. Computations performed with empirical blast loads developed by SwRI and by more computationally intensive ALE methods in LS-DYNA produced the same results. Computations performed in EPIC showed the same result. The metal plate was then bent numerically so
Walker, James D.Chocron, SidneyMoore, Thomas Z.Bradley, Joseph H.Carpenter, Alexander J.Weiss, CarlGerlach, Charles A.Grosch, Donald J.Grimm, MattBurguess, Victor W.
Technical Paper
Tech Pub Qualification Scheme Development for Arc Directed Energy Deposition Additive Manufacturing2024-01-380811/15/2024
ABSTRACT A prescriptive qualification scheme was completed for Arc Directed Energy Deposition (DED) metal Additive Manufacturing (AM) processes for austenitic single-sided builds. Robotic arc DED AM qualification builds used stainless steel consumables with the gas metal arc welding - pulse (GMAW-P) process. A matrix of standard qualification builds were made to develop, evaluate, and recommend the preferred process qualification build schemes. The qualification scheme explored a range of heat inputs, deposit sizes, and deposition rates; and the effects of interpass temperature that can be a limiting productivity factor for robotic arc DED metal AM builds. The standard qualification builds evaluated the effects of thickness (thin and thick geometric build features) where the process deposit (heat input) and process build thermal features (preheat and interpass temperature) are controlled over smaller ranges. The builds were examined with both ultrasonic and radiographic inspection, and
Harwig, D.DMohr, W.Hovanec, S.Rettaliata, J.Hayleck, R.Handler, EFarren, J.
Technical Paper
FORMING AND WELDING INNOVATIONS FOR ARMOR STEELS2024-01-374011/15/2024
ABSTRACT This paper reviews research that has been conducted to develop inductively assisted localized hot forming bending technologies, and to use standardized welding tests to assess the practicality and potential benefits of adopting stainless based consumables to weld both existing and evolving armor alloys. For the titanium alloy Ti6Al4V it was determined that warming the plate to circa 600°F would improve the materials ductility (as measured by reduction of area) from ~18 to 40% without exposing the material to a temperature at which atmospheric contamination would be significantly deleterious. For the commercial alloy BB and class 1 armor alloy it was found that there was little effect on the charpy impact toughness and the proof strength as a result of processing at 900 °F with either air cool or water quench and there was an added benefit of lower residual stresses in the finished bends compared to cold formed bends. Heating “alloy BB” to 1600 °F followed by water quench
Lawmon, JohnAlexandrov, BoianDuffey., MatthewNgan., Tiffany
Technical Paper
STRUCTURAL ADHESIVE WITH COMBINED HIGH STRENGTH AND DUCTILITY FOR MULTIMATERIAL JOINING AND GALVANIC ISOLATION2024-01-373511/15/2024
ABSTRACT A newly developed structural adhesive demonstrates a unique combination of high strength (43 ± 2 MPa) and displacement (4.7 ± 1.2 mm) in aluminum lap joint testing. Bulk material characterization of the prototype adhesive reveals its extreme ductility, with nearly 80% shear strain before failure and a 2.5-fold increase in strain energy density as compared to commercial structural adhesives. The prototype adhesive is found to maintain 67 to 82% of its initial strength under extreme environmental conditions, including at high temperatures (71°C), after high humidity (63°C hot water soak, 2 weeks), and after corrosive conditions (B117 salt spray, 1000 hours). The prototype structural adhesive is shown to also generate high strength bonds with multiple substrates, including steel, carbon fiber, and mixed material joints, while also providing galvanic isolation
Pollum, MarvinKriley, JosephNakajima, MasaTan, Kar TeanStalker, JeffreyFleischauer, RichardRearick, Brian
Technical Paper
Investigation of Hot Cracking Phenomena in Light-Weight Armor Steel Based on the FeMnAl-C Alloy System2024-01-373811/15/2024
ABSTRACT The US Army TARDEC has been researching an alternative to current armor steel that is both tough, and light-weight. The studied alloy is based on the Fe-Mn-Al-C system. This study was conducted to investigate and quantify this alloy’s susceptibility to hot cracking phenomena related to casting and welding. Very little research has been done on general weldability of this alloy system, so the results of these tests will be compared to other high Mn steels, and alloys that have undergone cast pin tear testing. Testing will be conducted utilizing button melting tests, autogenous spot welds, and cast pin tear testing. The cast pin tear testing was conducted to measure this alloys susceptibility to weld solidification cracking. The spot welds were used to quantify the susceptibility of the weld heat affected zone (HAZ) to liquation cracking, as well as to observe the solidification structure of the fusion zone. The testing results showed that the FeMnAl system in its current form
Evans, WilliamRamirez, Antonio J.Sebeck, Katherine
Technical Paper
EVALUATION OF CANDIDATE METHODS FOR WELDING STEEL TO OTHER STRUCTURAL LIGHTWEIGHT METALS2024-01-374111/15/2024
ABSTRACT This paper addresses candidate technologies for attaching steels to selected lightweight materials. Materials of interest here include aluminum and titanium alloys. Metallurgical challenges for the aluminum-to-steel and titanium-to-steel combinations are first described, as well as paths to overcome these challenges. Specific joining approaches incorporating these paths are then outlined with examples for specific processes. For aluminum-to-steel joining, inertia, linear, and friction stir welding are investigated. Key elements of success included rapid thermal cycles and an appropriate topography on the steel surface. For titanium-to-steel joining, successful approaches incorporated thin refractory metal interlayers that prevented intimate contact of the parent metal species. Specific welding methods employed included resistance mash seam and upset welding. In both cases, the process provided both heat for joining and a relatively simple strain path that allowed significant
Gould, Jerry E.Eff, MichaelNamola, Kate
Technical Paper
ADDITIVE MANUFACTURING REPAIR METHODS FOR METALLIC COMPONENTS2024-01-374211/15/2024
ABSTRACT As metallic parts are used, wear, fracture, galling, warpage, and other forms of obsolescence occur. When these issues progress beyond a predefined level, the parts are either replaced or repaired. Replacement leads to undesirable logistics requirements, especially for those parts requiring difficult-to-source, expensive and/or long-lead-time materials. Repair options are often limited due to strict performance requirements of the parts or concern over the quality of the repair. Two relatively new additive manufacturing (AM) process options exist to complete repairs, including repairs required in theater. Hybrid repair via metal AM followed by precision machining within a single setup offers unique repair options not previously available. Though somewhat limited with respect to the number of alloys currently tested, hybrid AM via directed energy deposition (i.e., powder sprayed into a laser-heated liquid metal pool) offers the possibility to quickly, economically and
Sabo, Kenneth M.Golesich, Brock T.Tims, Michael L.
Technical Paper
DEVELOPMENT OF A SCALABLE THERMOMECHANICAL PROCESS (TMP) FOR THICK BAINITIC ARMOR STEEL2024-01-374511/15/2024
ABSTRACT A bainite phase-based alloy and associated thermomechanical process were developed to produce (2.5 to over 5 cm) thick armor-grade steel with uniform through-thickness high hardness and strength. The alloy composition and the final-critical (austenite to bainite) isothermal transformation step were specifically designed to utilize a simple and versatile air-cool/quench method to keep a low upfront capital cost and to provide the ability to continuously control the cooling rate in real time, in order to produce maximum volume fraction of bainite phase, and promote uniformly distributed strength and hardness. Final thickness of 1.9 cm and 5.7 cm steel plates were fabricated for characterization, testing and evaluation and found to possess uniform through-thickness hardness between 53 to 55 HRC and dynamic compressive strength of up to 2 GPa
Chu, Henry S.Lillo, Thomas M.Anderson, Jeffrey A.Zagula, Thomas A.
Technical Paper
RELIABILITY OF POWERTRAIN COMPONENTS EXPOSED TO EXTREME TRIBOLOGICAL ENVIRONMENTS2024-01-317511/15/2024
ABSTRACT Results are presented from tests on a formulated 15W-40 mil-spec engine/transmission fluid to examine the impact of additives on improving its reliability and durability under extreme tribological conditions. A block-on-ring (BOR) configuration was used to measure the effect of five additives (an emulsion-based boric acid, tricresyl phosphate, particulate-based boron nitride, particulate-based MoS2, and particulate-based graphite) on the critical scuffing load as a function of additive concentration and time to scuff during oil-off tests (starved lubrication). A four-ball configuration was used to evaluate the impact of simulated engine grit/sand on the abrasive wear of steel as a function of grit size and loading. The results demonstrated that the additives increased the load for scuffing by 50 to 100% for the formulated oil and by 50 to 150% for the unformulated base fluid used in the formulated oil. Two of the additives (emulsion-based boric acid and tricresyl phosphate
Fenske, G. R.Ajayi, O. O.Erck, R. A.Lorenzo-Martin, C.Masoner, AshleyComfort, A. S.
Technical Paper
FLASH® BAINITE: ROOM TEMPERATURE WELDABLE ULTRA HARD 600, HIGH HARD 500, AND ADVANCED HIGH STRENGTH STEEL FOR A-CAB2024-01-374311/15/2024
ABSTRACT Flash® Bainite Processing employs rapid thermal cycling (<10s) to strengthen commercial off the shelf (COTS) steel sheet, plate, and tubing into Ultra Hard 600 Armor, High Hard 500 Armor, and advanced high strength steel (AHSS). In a continuous process, induction technology heats a narrow segment of the steel cross section in just seconds to atypically high temperature (1000-1300°C). Quenching substantially immediately follows. A report by Benet Labs and Picatinny Arsenal, investigating a less mature flash technology in 2011, surmised that the novel flash bainite process for steels has the potential to reduce cost and weight while also enhancing mechanical performance [1]. Receiving five financial grants, the US Dept of Energy has greatly matured flash technology in the last few years and its metallurgical understanding in collaboration with Oak Ridge National Lab and others. DOE has named Flash Bainite as the “SBIR Small Business of the Year” in May 2018 and awarded a Phase 3
Cola, Gary M
Technical Paper
Rigorous Accelerated Approach to Thermomechanical Processing Optimization for New Ballistic Protection Alloys2024-01-380711/15/2024
ABSTRACT The armor research and development community needs a more cost-effective, science-based approach to accelerate development of new alloys (and alloys never intended for ballistic protection) for armor applications, especially lightweight armor applications. Currently, the development and deployment of new armor alloys is based on an expert-based, trial-and-error process, which is both time-consuming and costly. This work demonstrates a systematic research approach to accelerate optimization of the thermomechanical processing (TMP) pathway, yielding optimal microstructure and maximum ballistic performance. Proof-of-principle is being performed on titanium alloy, Ti-10V-2Fe-3Al, and utilizes the Hydrawedge® unit of the Gleeble 3800 System (a servo-hydraulic thermomechanical testing device) to quickly evaluate mechanical properties and simulate rolling schedules on small samples. Resulting mechanical property and microstructure data are utilized in an artificial intelligence (AI
Lillo, ThomasChu, HenryAnderson, JeffreyWalleser, JasonBurguess, Victor
Technical Paper
DISSIMILAR FRICTION STIR WELDING OF A SOLID SOLUTION-STRAIN HARDENED ALUMINUM 5083 ALLOY AND PRECIPITATION STRENGTHENED ALUMINUM 2139 AND ALUMINUM 70852024-01-374411/15/2024
ABSTRACT Friction stir welding is a solid state joining technique in which no melting of the metals is involved. The technique is very attractive for aluminum alloys due to the low heat input involved in the process, which leads to improved mechanical properties as compared to conventional fusion welds. In this work, different aluminum series alloys were friction stir welded together. The aluminum alloys consisted of a solid solution/strain hardened aluminum alloy 5083-H131, and precipitation strengthened aluminum alloys 2139-T8 and aluminum 7085-T721. The joint combinations were aluminum alloys 5083-H131 to 7085-T721, aluminum alloys 2139-T8 to 7085-T721, and aluminum alloys 5083-H131 to 2139-T8. Their mechanical properties were analyzed and compared to base metal properties. Optical microscopy was used to analyze the grains in the welds. Good mixing of the different aluminum alloys was optically observed in all of the welds, which lead to good joint properties, opening the
Martinez, NelsonMcDonnell, Martin
Technical Paper
MICROSTRUCTURAL ANALYSIS AND CREEP BEHAVIOR OF 25MM THICK FRICTION STIR WELDED AA2139-T82024-01-373711/15/2024
ABSTRACT Most studies conducted on friction stir welded (FSW) Al alloys are on plates that are 2.5-7 mm thick. However, the U.S. Army utilizes materials that are 25 mm thick and greater for structure and armor. In order to properly apply FSW to Al-Cu-Mg-Ag alloys for use in next generation ground vehicles, data must be generated and available for model and simulation databases. One key type of data is the tensile-creep behavior of FSW AA 2139-T8. Creep is the time dependent, plastic deformation of a material under a constant load, usually observed at a constant temperature where T>0.3Tm. The objective of this study is to provide information regarding the tensile-creep behavior of the stir zone in comparison to the heat affected zone (HAZ) through the depth of the weld. The results from this research provide information on the effect of FSW processing on the microstructure and creep behavior. Pre- and post-deformation samples were analyzed via SEM and TEM and the results are discussed
Okeke, UchechiBoehlert, Carl
Technical Paper
Magnesium Alloy and Silicon Nitrides Composite Study: Synthesis and Abrasive Water Jet Machining Behavior and Optimization05-18-02-001411/15/2024
Related to traditional engineering materials, magnesium alloy-based composites have the potential for automobile applications and exhibit superior specific mechanical behavior. This study aims to synthesize the magnesium alloy (AZ61) composite configured with 0 wt%, 4 wt%, 8 wt%, and 12 wt% of silicon nitride micron particles, developed through a two-step stir-casting process under an argon environment. The synthesized cast AZ61 alloy matrix and its alloy embedded with 4 wt%, 8 wt%, and 12 wt% of Si3N4 are subjected to an abrasive water jet drilling/machining (AJWM) process under varied input sources such as the diameter of the drill (D), transverse speed rate (v), and composition of AZ61 composite sample. Influences of AJWM input sources on metal removal rate (MRR) and surface roughness (Ra) are calculated for identifying the optimum input source factors to attain the best output responses like maximum MRR and minimum Ra via analysis of variant (ANOVA) Taguchi route with L16 design
Venkatesh, R.
Journal Article
A Demonstration of Noise and Vibration Reduction Techniques For Zero Rare-Earth Magnet Integrated Starter-Generators Used In Military Vehicle Applications2024-01-371511/15/2024
ABSTRACT Due to the recent fluctuations in the rare-earth magnet pricing and availability demands, switched reluctance machines (SRMs) have gained significant interest to be used in automotive and military applications. SRMs are known to have high power density/efficiency, low cost, easy manufacturability, wide constant power region, robust structure and high reliability. On the other hand, high acoustic noise and torque ripple have limited their wide spread usage in the past. This paper investigates the analyses, design and experimental verification of various acoustic noise reduction techniques for SRMs. The prototypes of 100 kW SRMs for military ground vehicles have been built with the implemented acoustic noise reduction techniques and were tested using a dynamometer special for electric and hybrid vehicle testing
Sozer, YilmazTylenda, JoshuaKutz, JohnWright, Ronnie L.
Technical Paper
USE OF CORROSION PRODUCT FOR DIGITAL IMAGE CORRELATION MEASUREMENTS2024-01-373311/15/2024
ABSTRACT This paper describes the results of work performed to assess the use of corrosion product for Digital Image Correlation (DIC) measurements. DIC was recently evaluated for its capability to measure contour, strain and deflection of metals using the corrosion product instead of a painted speckle pattern. The DIC system, consisting of two cameras with zoom lenses, was set up at an angle to the specimen, enabling both cameras to image multiple sides of a specimen simultaneously. This provides a more direct measurement of in-plane and out-of-plane deformation and strains. Aluminum and steel dogbones were placed in a salt spray chamber for up to 10 days. Contour measurements were then taken at various evaluation settings as an initial assessment of the use of the corrosion product for DIC measurements. Multiple tensile tests were then performed to assess the capability of using corrosion product for strain and deflection measurements while a material is under applied load. System
Sia, Bernard
Technical Paper
FLASH® 600 ULTRA HIGH HARD: ROOM-TEMP ER120S-1 WELDABILITY TEKKEN, H-PLATE, BALLISTIC, & FSP DATA FOR IMPROVED SURVIVABILITY2024-01-390011/15/2024
ABSTRACT Survivability of a welded vehicle hull is directly tied to the performance of the grade of steel armor used. Selecting the highest performing grade of armor that can be welded into a specific location on a vehicle will improve survivability. While rolled homogeneous armor is the simplest to weld, challenges in welding high hard, and especially ultra high hard, are well known. Preventative measures to avoid weld cracking in vehicle structures can lead to increased costs during fabrication. Cracking of welds, both seen and unseen, in deployed vehicles directly impacts the survivability of the vehicle. Weld cracking during deployment further magnifies repair costs and leads to non-mission capable status. This analysis examines the weldability, ballistic/blast performance, and underlying metallurgy of Flash® Processed steels that have been tested by Army, Academia, and Industry. Citation: G. Cola, “Flash® 600 Ultra High Hard: Room-Temp ER120S-1 Weldability Tekken, H-Plate
Cola, Gary M
Technical Paper
AN IMPROVED METHOD TO MORE ACCURATELY ASSESS THE JOHNSON-COOK HIGH STRAIN-RATE DEFORMATION MATERIAL MODEL PARAMETERS - PART I2024-01-355311/15/2024
ABSTRACT Two relevant materials found in ground vehicle underbody armor/hull designs are Aluminum 2139-T8 and RHA Steel (Class I). These are 2 very important materials that need a thorough understanding of their high-strain rate behavior. The Johnson-Cook Deformation (JC-D) model at this time is the most preferred constitutive material model to utilize for high-strain (large deformation) blast simulations. The JC-D Model contains five empirically-based input parameters which can be determined traditionally through a series of uniaxial laboratory tests where each target parameter is isolated, while the remaining parameters are held constant. There are many criticisms and problems with this approach. The objective of this two part paper is to present and adopt a more accurate approach with less criticism to the determination of these five input parameters through both a sensitivity study to determine which input parameters are the most sensitive to a particular chosen response which in
Hause, TerrySheng, Jianping
Technical Paper
Program Overview: Extra-Large, Metal Additive Manufacturing System, Targeted Towards Army Ground Vehicle Systems2024-01-392411/15/2024
ABSTRACT The Applied Science and Technology Research Organization of America (ASTRO America), Ingersoll Machine Tool (Ingersoll), MELD Manufacturing (MELD), Siemens Digital Industries (Siemens), The American Lightweight Materials Manufacturing Innovation Institute (ALMII), and the US Army CCDC-GVSC have partnered to show the feasibility of fabricating very large metal parts using a combination of additive and subtractive manufacturing technologies. The Army seeks new manufacturing technology to support supply chain strategy objectives to replace costly inventories and reduce lead times. While additive manufacturing (AM) has demonstrated production of metallic parts for military applications, the scale of these demonstrations is much smaller than required for large vehicle components and/or complete vehicle hull structures. Leveraging AM for large scale applications requires enhancements in the size, speed, and precision of the current commercially available state-of-the-art equipment
Rodriguez, Ricardo X.Wells, CorrineCarter, Robert H.LaLonde, Aaron D.Goffinski, Curtis W.Cox, Chase D.Bell, Tim S.Kott, Norbert J.Gorey, Jason S.Czech, Peter A.Hoffmann, KlausHolmes, Larry (LJ) R.
Technical Paper
LOW DISTORTION TITANIUM ALLOY IN LASER POWDER BED FUSION ADDITIVE MANUFACTURING2024-01-398811/15/2024
ABSTRACT Titanium and its alloys offer superior strength at a fraction of the weight of steel or nickel-based alloys. Some α-β titanium alloys such as Ti-6Al-4V have been widely used in laser powder bed fusion additive manufacturing applications due to the historical cast-wrought data sets and the availability of this alloy in powder form, however this alloy presents challenges during the laser-based printing process of components due to the high residual stress in the material. Alternative β-rich Ti alloys such ATI Titan 23™ can offer superior printability, lower residual stress, and higher mechanical properties than Ti-6Al-4V in additive manufacturing applications. This study covers the assessment of ATI Titan 23™ as an alternative printable Ti alloy and the resulting microstructure, mechanical properties, and residual stress of the printed material. Citation: Garcia-Avila, Foltz, “Low Distortion Titanium Alloy in Laser Powder Bed Fusion Additive Manufacturing System,” In Proceedings
Garcia-Avila, MatiasFoltz, John
Technical Paper
High-Power, Low Temperature Li-Metal Battery Cell for Military Vehicle Applications2024-01-401511/15/2024
ABSTRACT Cornerstone Research Group (CRG) developed a lithium metal (Li-metal) battery cell for military applications. Utilizing a Li-metal anode, high energy density cathode, and an advanced low-temperature fluorinated electrolyte, the cell was designed and developed to provide high-power and low temperature capabilities. The 1.5 Ah Li-metal pouch cell had a specific energy of 247 Wh/kg and was able to discharge at ultra-low temperatures (-57 °C). Moreover, the Li-metal cell demonstrated extremely high-power by fully discharging at 10 C while maintaining over 70% its initial capacity. To demonstrate the Li-metal cell’s utility for military vehicle use, CRG modeled the cell into the 6T battery platform. A novel module housing was designed to evenly apply compression to the Li-metal cells to improve cell performance. Based on these projections, the Li-metal 6T battery could have a capacity of 163 Ah with a specific energy of 179 Wh/kg. Citation: J. Hondred, F. Zalar, P. Nikolaev, B
Hondred, JohnZalar, FrankNikolaev, PashaHenslee, Brian
Technical Paper
UTILIZING ADDITIVE MANUFACTURING TO ENABLE LOW-COST, RAPID FORMING OF HIGH TEMPERATURE LIGHTWEIGHT GROUND VEHICLE STRUCTURES2024-01-392611/15/2024
ABSTRACT Barriers to the introduction of composite materials for ground vehicle applications include material property selection and cost effective material processing. Advancements in processing of thermoplastic composites for use in applications for semi structural and structural applications have created opportunities in “Out of Autoclave” processing utilizing preconsolidated unidirectional reinforced tapes. Traditional tooling for the bending formation of high temperature reinforced structural thermoplastic laminates typically involves matched metal tooling consisting of steel or aluminum and are costly and heavy. In this research, a comparative analysis was performed to evaluate the use of a large scale 3D printed forming tool in comparison to a traditional metallic mold. Material processing considerations included the development of a technique for localized laminate heating to achieve optimized energy input in the forming process. Considerations in tooling development included
Erb, DavidDwyer, BenjaminRoy, JonathanYori, WilliamLopez-Anido, Roberto A.Smail, AndrewHart, Robert
Technical Paper
MONOCOQUE ALUMINUM STRUCTURE DESIGN FOR LIGHT TACTICAL VEHICLE WITH EMPHASIS ON DEFEATING UNDER BODY BLAST EVENT AND IMPROVING CREW SURVIVABILITY2024-01-348611/15/2024
ABSTRACT In order to defeat under body blast events and improve crew survivability, a monocoque aluminum cab structure has been designed as a drop on solution based on the current M1151A1 (HMMWV) chassis. The structure is comprised of all 5083-H131 Aluminum alloy armor plates with various thicknesses. The structure design consists of the following new features: (1) Robust joining design utilizing interlocking ballistic joints and mechanical interlocking features, (2) unique B-pillar gusset design connects roof & floor with B-pillar & tunnel, and (3) “Double V” underbody shaping design. The TARDEC designed, integrated & built vehicle achieved no crew core body injuries for a vehicle of this weight class and demonstrated meeting the crew survivability objective when subjected to a 2X blast during the live fire underbody blast tests. These efforts help to not only baseline light tactical vehicle capabilities, but also validate the possibility of meeting aggressive blast objectives for
Lee, Chu-HwaLacap, Demetrio M.Keller, Shawn J.
Technical Paper
CAM-7/LTO LITHIUM-ION CELLS FOR BATTERIES WITH HIGH CHARGE/DISCHARGE PERFORMANCE AT EXTREME LOW TEMPERATURE2024-01-336411/15/2024
ABSTRACT TIAX is developing laminated prismatic lithium-ion (Li-ion) cell technology capable of rapid charging at low temperature (to -50 °C) to replace current lead-acid vehicle batteries. The novel cells are based on TIAX’s high energy, high power CAM-7 cathode material, high rate capability lithium titanate (LTO) anode material, and novel electrolyte formulation, and target cell-level energy content greater than 90 Wh/kg and 250 Wh/l. CAM-7 cathode material promises significant boost in power and run time of Li-Ion batteries for a wide range of DoD applications, and is now being commercialized by a separate company, CAMX Power, which is scaling up production in a 50 metric ton per year plant installed in Massachusetts
Ofer, DavidDalton-Castor, SharonNation, LeahPullen, AdrianRempel, JaneBarnett, BrianSriramulu, Suresh
Technical Paper
ZERO RARE-EARTH MAGNET INTEGRATED STARTER-GENERATOR DEVELOPMENT FOR MILITARY VEHICLE APPLICATIONS2024-01-340711/15/2024
ABSTRACT The demand for increased export power generation and ground vehicle electrification are escalating trends due to the warfighter’s expanding mission requirements. Today’s low-voltage alternators used in some fielded ground vehicle’s power systems supply up to 650ADC, or 18kW. Future demand for vehicle export power generation is expected to reach and exceed 100kW. A majority of electric machines capable of meeting this level of power generation rely on rare-earth elements such as Neodymium (Nd), Samarium (Sm), Dysprosium (Dy) and Terbium (Tb). Due to diminished reserves in the United States, availability abroad and price volatility, continued use of rare-earth permanent magnet materials may not be viable. The expanding demand for vehicle power is on a trajectory which surpasses the U.S. ability to reliably harvest or procure rare-earth magnet materials. As such, electric machine topologies that utilize zero rare-earth magnet materials are being considered for ISG (integrated
Riley, KatherineConway, ShanShanLee, Seong T.Jung, Yong-BaeZanardelli, Wesley G.Wright, Ronnie L.
Technical Paper
ADVANCED FUNCTIONALLY GRADED PLATE-TYPE STRUCTURES IMPACTED BY BLAST LOADING2024-01-322711/15/2024
ABSTRACT The foundation of the theory of functionally graded plates with simply supported edges, under a Friedlander explosive air-blast, are developed within the classical plate theory (CPT). Within the development of the theory, the two constituent phases, ceramic and metal, vary across the wall thickness according to a prescribed power law. The theory includes the geometrical nonlinearities, the dynamic effects, compressive tensile edge loadings, the damping effects, and thermal effects. The static and dynamic solutions are developed leveraging the use of a stress potential with the Extended-Galerkin method and the Runge-Kutta method. Validations with simpler cases within the specialized literature are shown. The analysis focuses on how to alleviate the effects of large deformations through proper material selection and the proper gradation of the constituent phases or materials
Hause, Terry
Technical Paper
Feasibility of Joining Wrought Homogenized Armor Steel with Friction Stir Welding2024-01-381111/15/2024
Abstract The United State Army employs several advanced armored combat vehicles, in a wide array of different environments, and applications. Armor steels are hard and are required to meet certain conditions to stay within the military’s specifications for armored steels. Vehicle armor is typically joined using arc welding methods. Joining via arc welding degrades armor material below specification, so alternate joining methods are being explored like Friction Stir Welding (FSW). FSW is a solid-state joining technique that utilizes a rotating pin to stir plasticized material and use a tool shoulder to forge the material into the joint. The advantages come from the reduction in peak temperature, an increase in mechanical performance, and a decrease in possible defects that occur. In this study FSW parameters were developed and used to weld Wrought Homogenous Armor (HRA) steel. The welds were subject to hardness indention, and metallographic analysis to observe an early prediction of
Evans, WilliamRamirez, AntonioMcDonnell, MartinEff, Mike
Technical Paper
STRUCTURAL REPAIR FOR STRYKER HH STEEL BODY PANELS USING COLD SPRAY2024-01-381411/15/2024
ABSTRACT Corrosion damage to military ground vehicles costs the U.S. Army around $1.6B per year. A large part of that cost is related to keeping vehicles like the Stryker at their full fighting capability. Corrosion damage has been a common finding on Stryker vehicles and even light corrosion damage, which often reaches 10% of the body thickness or more, can degrade its armor protection rating and require replacement. Recently, cold spray deposition has been shown to be capable of restoring the full ballistic resistance of corrosion damaged high hard steel armor panels. These repairs can be done on-vehicle in depot facilities, using mobile high-pressure cold spray systems. This repair capability can reduce the number of entire side, roof, and floor panels that need to be cut out and re-welded in, which is the only currently approved repair operation for corrosion damage that exceeds allowable depths. Citation: V.K. Champagne, C.A. Widener, A.T. Nardi, G.D. Ferguson, “Structural Repair
Champagne, Victor K.Widener, Christian A.Nardi, Aaron T.Ferguson, Gehn D.
Technical Paper
Test the Corrosion Effect on High Hard Steel Armor MIL-DTL-46100 Coated with Stellite 6 Applied by Direct Energy Deposition Method2024-01-381311/15/2024
ABSTRACT The U.S. Army - GVSC Materials Characterization and Failure Analysis team conducted a preliminary study in FY18 to address the issue of galvanic and pitting corrosion of U.S. Army ground vehicle system (GVS) structural surfaces. The objective of this study was to develop a permanent coating solution to supplement the existing corrosion protective coating of zinc rich primer and CARC paint, and extend the lifecycle of the armor. Twenty-five permanent, 0.1 inch layer, additively manufactured (AM) coated coupons of deposited Stellite 6 cobalt alloy on MIL-STD-46100 High Hard (HH) armor steel blocks were produced for cyclic testing using an un-optimized set of parameters. These coupons were subjected to a twenty-four week study in accelerated corrosive conditions of a fog spray chamber alongside primer-CARC coated and uncoated coupons. The resulting study showed no signs of pitting corrosion in the surface of the AM coated coupons, and minimal galvanic corrosion. Citation: I
Toppler, Ian JSchleh, Daniel CRomero, Claudio Gutierrez
Technical Paper
Microstructure analysis of TIG welded additively manufactured prepared joints of Ni-based superalloys produced by Laser Powder Bed Fusion2024-01-405011/15/2024
ABSTRACT Laser powder bed fusion (L-PBF) of entire assemblies is not typically practical for technical and economic reasons. The build size limitations and high production costs of L-PBF make it competitive for smaller, highly complex components, while the less complex elements of an assembly are manufactured conventionally. This leads to scenarios that use L-PBF only where it’s beneficial and requires integration and joining to form the final product. Today the welding process requires complex welding fixtures and tack welds to ensure correct alignment and positioning of parts for repeatable results. In this paper, both L-PBF and milled weld preparations are presented to simplify Tungsten inert gas (TIG) welding of rotationally symmetrical geometries using integrated features for alignment and fixation. All welds produced in this study passed the highest evaluation group B according to DIN 5817. Citation: Ole Geisen, Tad Steinberg, “Microstructure analysis of TIG welded additively
Geisen, OleSteinberg, Tad
Technical Paper
SIMULATION AND VALIDATION OF METAL-FOAM COOLING DESIGN2024-01-342511/15/2024
ABSTRACT The open-cell metal foams have an internal structure is a web of connected ligaments. Foams are made from pure or alloys of aluminum, nickel, steel, magnesium, titanium and copper. In addition to being light weight, the foams exhibit excellent stiffness-to-weight ratios. Some foams can be resilient materials in harsh environments and have high impact resistance. The foams have high conductivities and large surface area per unit volume. All of these attributes make metal foam an attractive core for heat exchange. For example, cooling of power electronics and for thermal management of ground vehicles can employ metal-foam designs. Numerical simulation of convection heat transfer due to airflow inside commercial aluminum foam is conducted in a commercial numerical package. For validation, actual air temperatures were locally measured inside heated commercial aluminum foam, and cooled by forced air flow using a specially-developed technique. Good agreement between the modeling and
Dukhan, NihadSULEIMAN, AHMED S.AL-RAMMAHI, MUNTADHER A.
Technical Paper
NMP–free Lithium Ion for Sustainable Manufacturing in Silent-Watch Applications2024-01-394611/15/2024
ABSTRACT PPG formulates N-methyl pyrrolidone free (NMP−free) cathodes for Li−ion batteries capable of delivering sufficient power for automotive starting, lighting and ignition (SLI) as well as adequate charge capacity for powering auxiliary electronics. In this paper, NMP−free energy cathodes and power cathodes were formulated using developmental binders, and refinement of carbon/binder ratio and slurry mix procedure. Learnings from the energy and power cathode development were conceptually combined in the formulation of capacity enhanced power cathodes. These cathodes were evaluated electrochemically via power capability and rate capability testing in battery coin cells, as well as in 0.5 Ah multilayer pouch cells. Carbon content was found to be a critical factor in attaining high cold crank performance. This work represents significant steps toward potential commercialization of NMP−free cathode coated foil for Li−ion batteries. Citation: S. Esarey, A. Kizzie, C. Woodley, I. Matts
Esarey, Samuel L.Kizzie, AustinWoodley, ChristopherMatts, IanHellring, StuartZhou, ZhilianTerrago, Gina
Technical Paper
SUPERIOR BALLISTIC AND BLAST RESISTANCE IN ATI TITAN 27™ ALLOY WITH A NOVEL DEFORMATION MECHANISM2024-01-398611/15/2024
ABSTRACT α-β titanium alloys are used in armor plate applications due to their capability to defend against ballistic threats while having a 40% lower density than steel. ATI 425® was developed as a cold-deformable alternative to Ti-6Al-4V with similar ballistic properties and improved blast performance owing to the alloy’s higher damage tolerance. ATI Titan 27™ is an evolutionary step forward on ATI 425® Alloy, and is being developed as a higher-performance titanium armor alloy owing to its greater than 10% improvement in strength with similar ductility and formability. Recent work has demonstrated a novel deformation mechanism that explains the improved cold deformation observed in both alloys over Ti-6Al-4V. This mechanism, a twinning of α-phase coinciding with slip in the β-phase, is unique among high-strength titanium alloys. Moreover, twinning is well known to be suppressed with high oxygen content, and ATI Titan 27™ Alloy has one of the highest oxygen targets across high
Foltz, JohnRuiz-Aparicio, LuisBerry, DavidPorter, Rick
Technical Paper
TITANIUM ROAD WHEELS: A COST-EFFECTIVE LOW-RISK ALTERNATIVE FOR LEGACY AND NEXT GENERATION COMBAT VEHICLES2024-01-378111/15/2024
ABSTRACT The U.S. Army identified the use of advanced materials in next generation combat vehicles design as a focal technology area of interest and urged industry to develop replacements that realize weight, sustainment, and cost savings. An initial life cycle analysis suggests that using Titanium road wheels as an alternative to legacy road wheels could cut 555.6 lbs. and reduce cost by $39,760.00 per each M-1 tank over a life cycle of 8,000 mi, resulting with $71.72 savings per each pound reduced. Secondary side-effects of the weight reduction achieved by the Titanium road wheels include improvements such as fuel economy, mobility, transportability, and risk-reduction in the inclusion of emerging metal matrix composite technologies in next generation combat vehicles. The paper recommends conducting field evaluation and considering the application of Titanium road wheels in the M-1/M-88, M-109, AMPV, MPF, OMFV, DLP/FDL, and RCV (H) platforms Citation: R. Paytan, R. Mazor, “Titanium
Paytan, RonnenMazor, Ronen
Technical Paper
HIGH PERFORMANCE CONTROLLERS BASED ON REAL PARAMETERS TO ACCOUNT FOR PARAMETER VARIATIONS DUE TO IRON SATURATION2024-01-339111/15/2024
ABSTRACT With the increase in electric power on military ground vehicle platforms, electrically driven accessories are replacing existing hydraulic, belt, and gear-driven loads. Permanent Magnet Synchronous Machines (PMSM) are often selected to drive these accessories, and are under consideration for the main engine generator, due to their torque density and efficiency being among the highest available. To maximize the efficiency of a PMSM, accurate knowledge of its parameters is required across the entire operating range. Efficient control of the onboard electric drives will help reduce fuel consumption in the ground vehicle fleet. This paper presents the effects of iron saturation on the performance of a PMSM drive. Iron saturation depends on the amount of current injected into the motor and it restricts the amount of flux linkage that can be generated. PMSMs are controlled using a two axis space vector representation. Ideally, the control is decoupled, such that the flux linkage
Cintron-Rivera, Jorge G.Foster, Shanelle N.Zanardelli, Wesley G.Strangas, Elias G.
Technical Paper
Detection of Cut-Out in Aluminum Plate Using Ultrasonic Guided Waves: A Finite Element Analysis01-17-03-001911/09/2024
Aluminum alloys serve a critical role in the aerospace industry, accounting for a significant amount of commercial aircraft weight. Despite the growing use of composite materials, aluminum remains important in airframe construction due to its lightweight, cost-effectiveness, and high strength potential. Structural integrity is critical in modern engineering, necessitating early diagnosis and localization of damage. To detect the flaws, cracks, and cut-out in the structures, structural health monitoring (SHM) systems are essential, with non-destructive testing (NDT) methodologies playing critical roles. Among these technologies, ultrasonic guided wave testing (UGWT) has gained popularity because of its capacity to propagate over long distances and detect subsurface faults. This article investigates the use of UGWs to identify cut-outs in aluminum plates. The numerical investigation has been carried out using commercially available finite element software Abaqus. The ultrasonic lamb
Rajput, ArunPatil, Vaibhav KailasBhosale, AniketYadav, RiteshGhatge, AdityarajPandey, Anand Ji
Journal Article
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