Browse Topic: Materials

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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
Low Cycle Thermo-Mechanical Fatigue Life of Solder Joints using Cohesive Zone Model2024-28-0253To be published on 12/05/2024
A temperature dependent cohesive zone model considering the thermo-mechanical fatigue loadings are used to simulate and predict the failure process of solder joint interface in power electronics modules. Cohesive Zone Models (CZMs) are gaining popularity for modeling the fracture and fatigue behavior in various class of materials such as metals, polymers, ceramics, and their composite materials. Unlike the traditional fracture mechanics which considers concept of infinitesimal crack, CZMs assume a fracture process zone in which external energy is distributed in vicinity to propagating crack. In order to predict the fatigue-fracture process under thermo-mechanical cyclic loading, a damage accumulation variable is utilized. The calculation of damage is performed using a progressive mechanism, and the cohesive zone model is updated to reflect the present level of damage. The existing cohesive forces are influenced by both the current damage status and the extent of separation
Singh, Praveen KumarSahu, AbhishekChirravuri, BhaskaraMiller, Ronald
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
Development of a Method to Model Flexible Hose in FE Linear Dynamics Simulations2024-28-0254To be published on 12/05/2024
Linear dynamics simulations are performed on engine components to ensure structural integrity under dynamic loading. The FE model of the engine assembly must be prepared accurately to avoid under or over design of the engine components. Flexible hoses are present at pipe routings and modeling them in simulations is a challenge because the stiffness of the composite is not known. Current method includes using linear mass and spring elements instead of the hose with assumed stiffness, which leads to lack of confidence in the FE model. The hose under study in this paper is a rubber composite with a knitted reinforcement layer. This work involves a multiscale modelling approach using Representative Volume Element (RVE) for homogenization of yarn and rubber material properties to model composite hose in FEA. A RVE geometry is created which is a unit cell representation of the composite consisting of the knitted yarn and surrounding rubber. Orthotropic elastic properties are established at
Ashodiya, Jay VirendraJayachandran, JanarthananSanthosh, B
Technical Paper
Influence of Discrete Load Cases on Optimization of Chain Guide Design of Crawler Dozers under Various Ground Conditions2024-28-0270To be published on 12/05/2024
The undercarriage is a critical component in machines like Crawlers, Excavators, and Compact Track Loaders. Undercarriage includes vital elements of the machine such as Track Frame, Chain Guides, Rollers, Track Chains, Idler, Carrier Rollers, Final Drive, and Sprockets. Among all the machines, Crawler Dozers encounter harsh environments with various ground conditions. During operations, the chains are subjected to traverse and side loads due to which the chains tend to slip out of the bottom rollers. The chain guide plays a crucial role in assisting and maintaining the chain in the correct position. The forces acting on chain guides are influenced by factors like track chain tension, roller wear, chain link wear, impact loading (especially side impact), and counter rotation, where one track moves forward while the other moves in reverse. This study is focused on analyzing various load cases to determine the necessary number of chain guides, the optimal spacing between each chain guide
Masane, NishantBhosale, DhanajiSarma, Neelam K
Technical Paper
An experimental Study of Clutch Wear profile on a vehicle with automated manual transmission and simulating the same on test bench for future applications2024-28-0193To be published on 12/05/2024
Clutch wear is a significant factor affecting vehicle performance and maintenance costs, and understanding its dynamics is crucial for original equipment manufacturers (OEMs) to enhance product reliability and customer satisfaction. It is important to predict the clutch wear to enable the customer to understand the clutch condition and how much clutch life is available to avoid the sudden breakdown of vehicle. This paper explains the approach of measuring clutch wear profile measurement on actual vehicle and simulating the same launches on powertrain test bench with establishment of correlation in clutch wear profile
Chopra, ChandanKumar, VarunMamidigumpula, Mohan Kumar Reddy
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
Optimization of Additive Manufacturing (Fused Deposition Modeling) of PETG Material Using Taguchi Grey Relational Analysis2024-28-0234To be published on 12/05/2024
Additive Manufacturing (AM), specifically Fused Deposition Modeling (FDM), has become a highly promising method for creating intricate shapes using different materials. Polyethylene Terephthalate Glycol (PETG) is a highly utilized thermoplastic that is recognized for its exceptional strength, resistance to chemicals, and effortless processing. This study aims to optimize the process parameters of the FDM technique for PETG material using Taguchi Grey Relational Analysis (GRA). An empirical study was carried out to examine the impact of various FDM process parameters, such as layer thickness, infill density, printing speed, and nozzle temperature, on important outcome variables like dimensional accuracy, surface quality, and mechanical properties. The Taguchi method was used to systematically design a series of experiments, while GRA was used to optimize the process parameters and performance characteristics. The results unveiled the most effective parameter combinations for attaining
Natarajan, ManikandanPasupuleti, ThejasreeKiruthika, JothiD, PalanisamySilambarasan, R
Technical Paper
Influences of porosity shapes and sizes on stress and strain fields in the Casted Aluminum using Finite Element Modelling2024-28-0159To be published on 12/05/2024
Porosity is a common issue in Aluminum casting. The contemporary casting technologies have succeeded to some extent in predicting and controlling the casting defects. It is still impossible to eliminate various defects such as porosity, voids, and inclusions. It is also difficult to predict the exact shape and size of defect. Consequently, a key challenge in designing casted components is to validate durability by predicting accurate stress, strain, and strength by considering casting defects. In the present work, a set of static elastic-plastic finite element analyses (FEA) performed to obtain the stress and strain fields distribution near the voids/pores, and their resultant impact on tensile strength of Aluminum under tensile testing is studied. Using FEA, the stress and strain fields are determined for simple tensile test samples/specimens without and with voids/discontinuities modeled under a uniform displacement applied at a far field. The stress concentration is evaluated as a
T, KalingaSahu, AbhishekChirravuri, BhaskaraMiller, RonaldXu, Siguang
Technical Paper
Development of new generation battery cooling hoses with TPV material2024-28-0161To be published on 12/05/2024
The market for battery-fitted electric cars continues to experience robust growth globally as well as Indian market. During the charging process heat generation happen because of internal resistance of the battery cells and electrical connectors. Making an efficient battery cooling system is vital for all electric vehicles. One common cause of battery overheating is cooling efficiency, highlighting the importance of scientifically designing coolant circuits and selecting appropriate hose materials. Currently, EPDM (ethylene propylene diene monomer) material is widely used for battery cooling hoses due to its design flexibility, compatibility with a 50:50 glycol-water mixture, and resistance to thermal and ozone cracking. This study benchmarked EPDM's technical properties against leading EV battery cooling plastic hose materials, such as polyamide, TPEs (thermoplastic elastomers), and TPVs (thermoplastic vulcanizates). Comparative experiments, including burst pressure, vacuum collapse
Murugesan, Annarajan
Technical Paper
Synthesis and characterization of advanced multi nanoparticle based nanofluid stabilized by surfactants2024-28-0139To be published on 12/05/2024
Recently, there has been a growing emphasis on Thermal Management Systems (TMS) for Lithium-ion battery packs due to safety concerns related to fire risks when temperatures exceed operating limits. Elevated temperatures accelerate electrochemical reactions, leading to cell degradation and reduced electronic system performance. These conditions can cause localized hotspots and hinder heat dissipation, increasing the risk of thermal runaway due to high temperatures, flammable gases, and heat-producing reactions. To tackle these issues, many automotive manufacturers employ indirect liquid cooling techniques to maintain battery pack and electronic system temperatures within safe limits. Engineered nanofluids, particularly those containing multi-nanoparticles dispersed in water and ethylene glycol, are being explored to enhance thermo-physical properties. This paper focuses on the experimental characterization of nanofluid containing Titanium Dioxide (TiO2), Copper Oxide (CuO), Aluminum
Nahalde, SujayHonrao, GauravMore, Hemant
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
Application of TOPSIS approach for Optimization on Additive Manufacturing (Fusion Deposition Modeling) of TPU Material: A Systematic Approach for Process Enhancement2024-28-0232To be published on 12/05/2024
Additive Manufacturing (AM), specifically Fusion Deposition Modeling (FDM), has transformed the manufacturing industry by allowing the creation of complex structures using a wide range of materials. The objective of this study is to enhance the FDM process for Thermoplastic Polyurethane (TPU) material by utilizing the Technique for Order of Preference by Similarity to Ideal Solution (TOPSIS) optimization method. The study examines the influence of FDM parameters, such as layer height, nozzle temperature, and infill density, on important characteristics of the printing process, such as tensile strength, flexibility, and surface finish. The collection of experimental data is achieved by conducting systematic FDM printing trials that cover a variety of parameter combinations. The TOPSIS optimization method is utilized to determine the optimal parameter settings by evaluating each parameter combination against the ideal and anti-ideal solutions. This method determines the optimal parameter
Pasupuleti, ThejasreeNatarajan, ManikandanKiruthika, JothiRamesh Naik, MudeSilambarasan, R
Technical Paper
Crash Simulation of Steel-Wood Hybrid Road Safety Barrier with Perforated Post Design: Car Test Evaluation2024-28-0162To be published on 12/05/2024
Research area in Road furniture has become important due to the rising incidence of road accidents and fatalities. Enhancing road attributes such as crash barriers, crash cushions, crash poles, and emergency communication systems can significantly reduce these fatalities. Among these, crash barriers promise particular attention as they serve as immediate safety mechanisms. When a vehicle loses control, crash barriers can effectively mitigate the severity of accidents by restraining the vehicle and preventing more severe outcomes. This paper focuses on the performance of a novel steel-wood hybrid crash barrier with perforated post parallel to vehicles direction, designed to enhance road safety in hilly areas. Utilizing finite element analysis (FEA) in LS-DYNA software, renowned for simulating structural deformation under loading, we evaluated the structural response and crashworthiness of the hybrid barrier under various impact scenarios. Our simulations assessed the barrier's
Bendre, SagarDas, AlakenduJaiswal, Manish
Technical Paper
Evaluating the Thermal Behavior of Miniature Battery Packs Encapsulated with Diverse Potting Materials through Simulation and Experimentation2024-28-0224To be published on 12/05/2024
Electric vehicles represent a pivotal shift in the automotive sector, offering a sustainable alternative to conventional gasoline-powered vehicles. Lithium-ion batteries are extensively chosen as the primary energy source for these vehicles due to their exceptional energy density and extended operational lifespan. Achieving thermal stability during normal battery pack operations is imperative for ensuring both safety and efficiency in electric vehicle technology. Various encapsulants are used to fill the gaps between the cells, providing not only structural rigidity on undulating roads but also enhancing heat transfer capabilities among the cells, thereby maintaining a uniform temperature gradient inside the battery pack. This study explores the effectiveness of three distinct commercially available potting materials—polyurethane (PU) foam, silicone, and silicone-based epoxy—as encapsulants for lithium-ion battery packs. A 3x3 cell configuration is modeled as a battery pack using 18650
Somarajupalli, ShanmukhadevVedantam, SrikanthGupta, ShubhamJha, Kaushal Kumar
Technical Paper
Optimization of Additive Manufacturing (Fused Deposition Modeling) of PLA Material Using TOPSIS Approach2024-28-0233To be published on 12/05/2024
Additive Manufacturing (AM), specifically Fused Deposition Modeling (FDM), has transformed the manufacturing industry by allowing the creation of intricate shapes using different materials. Polylactic Acid (PLA) is a biodegradable thermoplastic that is commonly used in additive manufacturing (AM) because of its environmentally friendly nature, affordability, and ease of processing. This study aims to optimize the parameters of Fused Deposition Modeling (FDM) for PLA material using the Technique for Order Preference by Similarity to Ideal Solution (TOPSIS) approach. The researchers performed experimental trials to examine the impact of important FDM parameters, such as layer thickness, infill density, printing speed, and nozzle temperature, on critical outcomes, including dimensional accuracy, surface finish, and mechanical properties. The methodology of design of experiments (DOE) enabled a systematic exploration of parameters. The TOPSIS approach, a technique for making decisions
Natarajan, ManikandanPasupuleti, ThejasreeKiruthika, JothiKatta, Lakshmi NarasimhamuSilambarasan, R.
Technical Paper
Development of ANFIS Predictive Model for Wire Electrical Discharge Machining of Cupronickel Material2024-28-0239To be published on 12/05/2024
Wire Electrical Discharge Machining (WEDM) is an essential manufacturing process used to shape complex geometries in conductive materials such as cupronickel, which is valued for its corrosion resistance and electrical conductivity. The objective of this study is to improve the efficiency and precision of machining by creating a specialized predictive model using an Adaptive Neuro-Fuzzy Inference System (ANFIS) for cupronickel material. The study examines the intricate correlation between process parameters of the WEDM (Wire Electrical Discharge Machining) technique, such as pulse-on time, pulse-off time, and discharge current, and crucial machining responses, including surface roughness, material removal rate. Data is collected through systematic experimentation in order to train and validate the ANFIS predictive model. The ANFIS model utilizes the collective learning capabilities of neural networks and fuzzy logic systems to precisely forecast machining responses by considering input
Pasupuleti, ThejasreeNatarajan, ManikandanKiruthika, JothiKatta, Lakshmi NarasimhamuSilambarasan, R.
Technical Paper
Optimization and ANFIS Predictive Modeling of Additive Manufacturing (Fused Deposition Modeling) for PLA Material2024-28-0240To be published on 12/05/2024
Additive Manufacturing (AM), specifically Fused Deposition Modeling (FDM), has become a revolutionary technology for creating intricate shapes using different materials. Polylactic Acid (PLA) is a biodegradable thermoplastic that is commonly used in additive manufacturing (AM) because of its environmentally friendly properties, affordability, and ease of use. The objective of this study is to optimize the FDM parameters for PLA material and create predictive models using the Adaptive Neuro-Fuzzy Inference System (ANFIS) to forecast printing performance. An investigation was carried out through experimental trials to examine the impact of important FDM parameters, such as layer thickness, infill density, printing speed, and nozzle temperature, on critical outcomes such as dimensional accuracy, surface finish, and mechanical properties. The utilization of design of experiments (DOE) methodology enabled a methodical exploration of parameters. A predictive model using ANFIS was created to
Pasupuleti, ThejasreeNatarajan, ManikandanKiruthika, JothiRamesh Naik, MudeSilambarasan, R
Technical Paper
Research on Multi-Mode Switching Strategy for Electromagnetic Suspension2024-01-700511/15/2024
This study proposes a multi-mode switching control strategy based on electromagnetic damper suspension (EMDS) to address the different performance requirements of suspension systems on variable road surfaces. The working modes of EMDS are divided into semi-active damping mode and energy harvest mode, and the proposed mode switching threshold is the weighted root mean square value of acceleration. For the semi-active damping mode, a controller based on LQR(Linear Quadratic Regulator) was designed, and a variable resistance circuit was also designed to meet the requirements of the semi-active mode, which optimized the damping effect relative to passive suspension. For the energy harvest mode, an energy harvest circuit was designed to recover vibration energy. In order to reduce the deterioration of suspension performance caused by frequent mode switching in the mode switching strategy, as frequent system switching can lead to system disorder, deterioration of damping effect, and
Zeng, ShengZhang, BangjiTan, BohuanQin, AnLai, JiewenWang, Shichen
Technical Paper
SOUCY COMPOSITE RUBBER TRACK TECHNOLOGY2024-01-359211/15/2024
ABSTRACT Rubber tracks are now extremely competitive for vehicles up to 50 tons and fully fielded on 39 ton vehicles. They represent the best of what technology can offer for tracked vehicles, in terms of high durability, performance and low life cycle cost. This is mainly attributed to the optimization through the five (5) technological tools described in this paper. Better from its numerous distinctive advantages, rubber tracks can be adapted to suit virtually any specific need. This ductile rubber track technology can be shaped to match today’s requirements, with the help of advanced rubber compounding and computer simulations
Marcotte, Tommy
Technical Paper
RESEARCH OF THE EFFECTS OF INTEGRATION INTO ARMOR ON THE PERFORMANCE OF SPINTRONIC MICROWAVE DETECTORS2024-01-333411/15/2024
ABSTRACT The authors studied the effects of different types of armor on the performance of spin-torque microwave detectors (STMD). Working prototypes of novel nano-sized spintronic sensors of microwave radiation for battlefield anti-radar and wireless communications applications are being integrated into Sensor Enhanced Armor (SEA) and Multifunctional Armor (MFA) and tested in SEA-NDE Lab at TARDEC. The preliminary theoretical estimations have shown that STMD based on the spin-torque effect in magnetic tunnel junctions (MTJ), when placed in the external electromagnetic field of a microwave frequency, can work as diode detectors with the maximum theoretical sensitivity of 1000 V/W. These STNO detectors could be scaled to sub-micron size, are frequency-selective and tunable, and are tolerant to ionizing radiation. We studied the performance of a STMD in two different dynamical regimes of detector operation: in well-known traditional in-plane regime of STMD operation and in recently
Bankowski, ElenaMeitzler, ThomasPesys, Tomas
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
A PASSIVE SOLUTION FOR TRANSIENT HEAT LOAD ISSUES USING PHASE CHANGE MATERIALS2024-01-353711/15/2024
ABSTRACT Thermal management systems (TMS) of armored ground vehicle designs are often incapable of sustained heat rejection during high tractive effort conditions and ambient conditions. The use of a latent heat energy storage system that utilizes Phase Change Materials (PCMs) is an effective way of storing thermal energy and offers key advantages such as high-energy storage density, high heat of fusion values, and greater stability in temperature control. Military vehicles frequently undergo high-transient thermal loads and often do not provide adequate cooling for powertrain subsystems. This work outlines an approach to temporarily store excess heat generated by the transmission during high tractive effort situations through use of a passive PCM retrofit thereby extending the operating time, reducing temperature transients, and limiting overheating. A numerical heat transfer model has been developed based around a conceptual vehicle transmission TMS. The model predicts the
Putrus, Johnathon P.Jones, Stanley T.Jawad, Badih A.Schihl, Peter
Technical Paper
Adaptive Graphite Coatings Improve Fit and Function of Pistons, Turbos and Other Precision Devices2024-01-374711/15/2024
ABSTRACT Additive/Abradable Powder Coatings (AAPC’s) are field proven, thick, solid film graphite coatings that wear in to the ideal functional geometry of mechanical components. Lubed or dry, devices lap in and run with minimized clearance and friction for highest efficiency, quietest operation, and longest life in sandy environments. AAPC’s will improve military readiness, reduce sustainment costs, and cut components logistics and fuel consumption. Processing is easy, robust and effective on new and used components in prototyping, production and remanufacturing. Worn components can be restored in theater to achieve durable, ‘better than new’ performance levels. Applications include turbos, IC pistons, lube pumps, hydraulics, roots blowers, screw compressors, refrigerant compressors, lip seal seats, and others. This paper will focus on the AAPC benefits observed on pistons and turbo compressor housings
Suman, Andrew
Technical Paper
ROAD WHEEL READINESS EXPERIMENT2024-01-357811/15/2024
ABSTRACT Tracks and wheels are some of the top constituents of ground vehicle mobility and sustainment cost. Even small improvements in performance parameters and support strategies can go a long way. Analyzing equipment sustainment models can help identify these opportunities in conjunction with maintaining a situational awareness of R&D activities. Specifically, understanding component failure analysis, characterizing production road wheel material properties, conducting component testing, and benchmarking diverse manufacturing capabilities provides a roadmap to establishing and identifying “Best in Class” road wheel materials. Establishing and executing an R&D compounding plan to deliver 5X-10X durability improvement is hypothesized. Leveraging the Defense Mobility Enterprise (DME) and its authority under the 10 USC 2370 Section 845 Ground Vehicle Systems Other Transaction Agreement will allow the government to rapidly determine the technical feasibility of realizing such colossal
Patria, Garett S.Rescoe, StuBradford, WilliamMynderse, James A.
Technical Paper
LIGHT-WEIGHT DRAPABLE ANTI-CORROSION COVERS2024-01-404711/15/2024
ABSTRACT At the onset of the Second World War, it was noticed that equipment being shipped overseas to the frontlines arrived corroded. The Department of Defense rapidly escalated the use of corrosion inhibitors in packaging materials to reduce the severity of the corrosion of those assets. This paper provides an overview of vapor corrosion inhibitors, describes how they are incorporated into anti-corrosion covers, and summarizes field test results showing typical protection provided to Department of Defense assets. The paper describes the environmental conditions that warrant the use of anti-corrosion covers and presents independent ground vehicle focused return-on-investment analysis. Citation: David J. Sharman, Robert R. Danko, Bill Scheible, “Light-weight drapable anti-corrosion covers,” In Proceedings of the Ground Vehicle Systems Engineering and Technology Symposium (GVSETS), NDIA, Novi, MI, Aug. 15-17, 2023
Sharman, David JDanko, Robert R.Schieble, Bill
Technical Paper
Scan Sequence Optimization for Reduced Residual Stress and Distortion in LPBF Additive Manufacturing – An AISI 316L Case Study2024-01-405111/15/2024
ABSTRACT Laser powder bed fusion (LPBF) additive manufacturing often results in defective parts due to non-uniform temperature distribution during fabrication. To mitigate this issue, the authors recently introduced SmartScan, an intelligent method that employs modeling and optimization to generate scan sequences that improve temperature uniformity. However, the previous version of SmartScan could only be applied to single layers. This paper presents an extension of SmartScan to three-dimensional parts by adjusting the thermal model and optimization objective. Through simulations and experiments involving fabricating AISI 316L stainless steel parts, the study demonstrates that the proposed SmartScan approach significantly improves temperature uniformity, reduces part distortion, and mitigates residual stress, as compared to conventional heuristic sequences. Citation: C. He, C. E. Okwudire, “Scan Sequence Optimization for Reduced Residual Stress and Distortion in PBF Additive
He, ChuanOkwudire, Chinedum E.
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
A Modeling Methodology for the Analysis of Abradable Powder Piston Skirt Coatings2024-01-395311/15/2024
Abstract Line2Line’s patented abradable powder surface coatings are a mechanism by which clearance between mating components is reduced, and the tribological properties of the interacting surfaces can be improved. The following discussion presents the modeling efforts targeting the numerical analysis of abradable powder piston skirt coatings. This study employs the Cylinder-Kit Analysis System for Engines (CASE) by Mid-Michigan Research to model the performance enhancements offered by abradable powder coatings as applied to piston skirts. Two piston models were generated for the purposes of this analysis, one with the post-run stock reference geometry and coating, as supplied by the manufacturer, and the second having the Line2Line post-run coated geometry. The pistons modeled had been installed within two separate Cummins R2.8 L turbo diesel engines, both of which were subject to several hours of runtime. The primary finding of the current study is that the Line2Line abradable powder
Nicklowitz, DanielSchock, HaroldSuman, AndyLowe, JimWood, Ai LeGrande
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
SIMULATION OF THERMAL SIGNATURE OF TIRES AND TRACKS2024-01-337211/15/2024
ABSTRACT Rubber is the main element of tires and the outside layer of tracks. Tire and track heating is caused by hysteresis effects due to the deformation of the rubber during operation. Tire temperatures can depend on many factors, including tire geometry, inflation pressure, vehicle load and speed, road type and temperature and environmental conditions. The focus of this study is to develop a finite element approach to computationally evaluate the temperature field of a steady-state rolling tire and track. The 3D thermal analysis software Radtherm was applied to calculate the average temperature of tread and sidewall, and the results of Radtherm agreed with ABAQUS results very well. The distributions of stress and strain energy density of the rolling tracks were investigated by ABAQUS as well. The future works were finally presented
Tang, TianJohnson, DanielLedbury, EmilyGoddette, ThomasFelicelli*, Sergio D.Smith, Robert E.
Technical Paper
Developing Performance and Operating Requirements for Energy Attenuation (EA) Roof Liners for all U.S. Army Military Vehicles2024-01-390411/15/2024
ABSTRACT The primary focus of this effort is to evaluate the roof liner technology’s ability to reduce the head injury criteria (HIC) and head acceleration to mitigate vertical impact related injures to mounted crew injures which may occur during top and bottom threat events. In an effort to reduce the likelihood of head injury during top and bottom threat attacks, an adequate roof liner is needed to reduce the force exerted on the solider. The roof liners were able to pass all system level tests. The successful system level testing confirmed the blast mat technology’s TRL-6 recommendation. Citation: J. Klima, “Developing Performance and Operating Requirements for Energy Attenuating (EA) Roof Liner for all U.S. Army Military Vehicles”, In Proceedings of the Ground Vehicle Systems Engineering and Technology Symposium (GVSETS), NDIA, Novi, MI, Aug. 10-12, 2021
Klima, Julie
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
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
NOVEL METAL-FOAM FLOW FIELDS FOR PEM FUEL CELLS WITH ENHANCED PERFORMANCE2024-01-378611/15/2024
ABSTRACT Flow fields in bipolar plates of Proton Exchange Membrane fuel cells distribute fuel and oxidant over the reactive sites of the membrane electrode assembly. Bipolar plates are typically graphite with parallel or serpentine channels as flow fields. Drawbacks of graphite include weight, fabrication inaccuracy, cost, porosity, and brittleness. In this paper, open-cell metal foam is experimentally investigated as a flow field for a new bipolar plate design. Using experiments, the performance of the conventional bipolar plate/flow field was directly compared to that of the metal-foam designs at the same operational conditions. Results show that the cell current, voltage and power density were improved and temperature and pressure distribution on the membrane were even. As importantly, the conversion efficiency was higher for the metal-foam design, and the weight was reduced significantly. Citation: Nihad Dukhan, PhD, Yussef Awin, “Novel Metal-Foam Flow Fields for PEM Fuel Cells
Dukhan, NihadAwin, Yussef
Technical Paper
BALLISTIC VALIDATION TEST STATISTICS AND CONFIDENCE LEVELS2024-01-383911/15/2024
ABSTRACT Ballistic validation testing typically involves firing multiple shots at a nominal velocity and ensuring the target stops every round with only partial penetrations, no completes. This testing is specified as a consequence of the binary nature of the test, and the need to meet a particular probability of penetration at a specified velocity with a certain confidence level. This legacy process has significant shortcomings owing to both the test procedures involved as well as the nature of the statistical interpretation of the results. This paper describes an alternative test and analysis procedure that produces the required level of performance and confidence information at a specified velocity, as well as the confidence over a wide range of other velocities and performance levels. In addition, this procedure eliminates many of the shortcomings associated with the legacy “no penetration” test protocol, and requires no more shots at the target. Citation: J. Eridon, S. Mishler
Eridon, JamesMishler, Scott
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
OPTIMIZATION/INTEGRATION OF METALLIC AND NON-METALLIC FOAMS FOR STRUCTURE, THERMAL DISIPATION, MINE BLAST PROTECTION, AND BUOYANCY FOR AMPHIBIOUS MILITARY VEHICLES2024-01-361111/15/2024
ABSTRACT For this particular effort, the U.S. Army Tank Automotive Research Development and Engineering Center (TARDEC) Center for Systems Integration (CSI) was tasked to develop a buoyancy/survivability kit that would serve multiple functions. The underbody kit would meet or surpass current required protection levels. Plus the kit was to ensure that the LAV-25A2 (Light Armored Vehicle) continues to meet the swim requirement. However, the overarching objective is to meet the survivability, ground mobility, and water mobility requirements. Combining the accomplishments in the TARDEC & PM-LAV (Program Manager for the Light Armored Vehicle) survivability program in 2013-2014 with the TARDEC & PM-LAV buoyancy/survivability kit developed in 2015-2016, the overall weight is decreased, water mobility is improved, and survivability is significantly improved. This is a unique challenge as a combination of buoyancy, mine blast, and structural requirement on a ground military vehicle is novel
Capouellez, JamesVunnam, MadanKhatib-Shahidi, BijanTison, NathonLee, In-HoDunbar, PatrickHelsel, FloydKerr, SteveHarowitz, Jack
Technical Paper
New Applications of Plasma Propulsion Engines and Advanced Nanomaterials in Low-Altitude Aircraft: Theoretical Advances2024-01-702211/15/2024
This paper explores the groundbreaking applications of plasma propulsion engines and advanced nanomaterials in low-altitude aircraft, addressing the challenges and recent technological advancements that make such applications feasible. Traditional space plasma thrusters operate effectively in near-vacuum conditions by taking advantage of the ease of plasma ignition at low pressures. However, these thrusters face significant difficulties when operated at near-atmospheric pressures found in low-altitude environments, where plasma ignition is challenging. This paper highlights recent breakthroughs in high-pressure plasma glow discharge technology and the integration of nanomaterials, which together enable the use of plasma propulsion engines in low-altitude aircraft. These innovations offer substantial advantages over conventional engines, including higher efficiency, reduced emissions, and the potential to fundamentally change the propulsion systems of low-altitude aircraft
Ma, XinDing, ShuitingPan, YilunLiu, JinshuoQiao, HuizheYang, Jincai
Technical Paper
PREDICTING THE LIFE OF MILITARY VEHICLE COMPONENTS IN THE PRESENCE OF DEFECTS2024-01-320011/15/2024
ABSTRACT When the components of a military vehicle are designed, consideration is given to long term durability under repeated mission applications. In reality, surface and subsurface defects have always existed in weldments, forgings, and castings. These defects came from the manufacturing process or nucleated during the life of the vehicle. These defects may grow under repeated operations, resulting in ultimate failure of parts well before the design life is achieved. In such situations, a design based on crack initiation alone will not suffice, and a fracture mechanics based fatigue should also be included to predict the design life of a part accurately. In this paper a methodology is given on how to predict the available design life given the presence of defects in different parts of a military vehicle. An example will be provided with the process to demonstrate each step of the process
Porter, William De
Technical Paper
Reduced-Order Modeling Method for Fatigue Life Predictions of Hybrid Electric Vehicle Batteries2024-01-337311/15/2024
ABSTRACT The goal of this work is to develop an efficient numerical modeling method for the structural dynamic response of hybrid electric vehicle (HEV) batteries in order to support fatigue life predictions. The dynamics of HEV battery packs are known to feature very high modal density in many frequency bands. The high modal density combined with small, random structural variations among the cells (which are unavoidable in practice) can lead to drastic changes in the structural dynamics. Therefore, it may be important to perform probabilistic simulations of the structural dynamic response with cell-to-cell parameter variations in order to accurately predict the fatigue life of a battery pack. However, the computational time for obtaining forced response results for just a single sample of parameter variations with a finite element model can be on the order of a day. One approach to overcome this challenge is to generate parametric reduced-order models (PROMs). The novel approach is
Hong, Sung-KwonEpureanu, Bogdan I.Castanier, Matthew P.
Technical Paper
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