Your search keyword '"Vlastimil Kunc"' showing total 6 results

1. Large-scale reactive thermoset printing: Complex interactions between temperature evolution, viscosity, and cure shrinkage

Author

Stian K. Romberg, Christopher J. Hershey, John M. Lindahl, William G. Carter, Justin Condon, Vlastimil Kunc, and Brett G. Compton

Subjects

Control and Systems Engineering, Mechanical Engineering, Industrial and Manufacturing Engineering, Software, Computer Science Applications

Published

2022

2. Stiff and strong, lightweight bi-material sandwich plate-lattices with enhanced energy absorption

Author

Meng-Ting Hsieh, H. Felix Wu, Chan Soo Ha, Vlastimil Kunc, Zhenpeng Xu, Xiaoyu Zheng, and Seokpum Kim

Subjects

Shock wave, Technology, Work (thermodynamics), Materials science, Materials Science, 0204 Condensed Matter Physics, Elastomer, INTERPENETRATING PHASE COMPOSITES, FRACTURE-TOUGHNESS, STRENGTH, medicine, General Materials Science, Composite material, 0912 Materials Engineering, Absorption (electromagnetic radiation), Materials, chemistry.chemical_classification, Mechanical Engineering, Isotropy, Stiffness, POLYMER, Polymer, Condensed Matter Physics, Finite element method, chemistry, Mechanics of Materials, FOAMS, medicine.symptom, BEHAVIOR, 0913 Mechanical Engineering

Abstract

Plate-based lattices are predicted to reach theoretical Hashin–Shtrikman and Suquet upper bounds on stiffness and strength. However, simultaneously attaining high energy absorption in these plate-lattices still remains elusive, which is critical for many structural applications such as shock wave absorber and protective devices. In this work, we present bi-material isotropic cubic + octet sandwich plate-lattices composed of carbon fiber-reinforced polymer (stiff) skins and elastomeric (soft) core. This bi-material configuration enhances their energy absorption capability while retaining stretching-dominated behavior. We investigate their mechanical properties through an analytical model and finite element simulations. Our results show that they achieve enhanced energy absorption approximately 2–2.8 times higher than their homogeneous counterparts while marginally compromising their stiffness and strength. When compared to previously reported materials, these materials achieve superior strength-energy absorption characteristics, making them an excellent candidate for stiff and strong, lightweight energy absorbing applications. Graphic Abstract: [Figure not available: see fulltext.] Published version

Published

2021

3. The influence of dynamic rheological properties on carbon fiber-reinforced polyetherimide for large-scale extrusion-based additive manufacturing

Author

Ahmed Arabi Hassen, Vlastimil Kunc, Zeke Sudbury, Lonnie J. Love, Brian K. Post, John Lindahl, Vidya Kishore, Chad E. Duty, and Christine Ajinjeru

Subjects

chemistry.chemical_classification, 0209 industrial biotechnology, Shear thinning, Materials science, Thermoplastic, Rheometry, Mechanical Engineering, Plastics extrusion, 02 engineering and technology, 021001 nanoscience & nanotechnology, Polyetherimide, Industrial and Manufacturing Engineering, Computer Science Applications, chemistry.chemical_compound, Viscosity, 020901 industrial engineering & automation, chemistry, Rheology, Control and Systems Engineering, Extrusion, Composite material, 0210 nano-technology, Software

Abstract

Printing high-performance thermoplastics on large scale extrusion-based additive manufacturing platforms requires stability over a range of processing conditions. However, studies on the melt dynamics and processing conditions of these thermoplastics in big area additive manufacturing (BAAM) are limited. This study characterizes the dynamic rheological behavior of polyetherimide (PEI), a high-performance thermoplastic, as well as carbon fiber (CF)-reinforced PEI composites as a BAAM feedstock material. The viscoelastic properties, such as the storage and loss moduli and complex viscosity, are investigated in relation to the BAAM extrusion process. The results show that CF-PEI composites behave like a viscous liquid during BAAM extrusion. The addition of CF to PEI enhances the shear thinning effect and significantly increases the complex viscosity (2.5× increase for 20% CF, and 3× for 30% CF). The increased viscosity increases the torque on the extruder, which may be alleviated by increasing the material processing temperature.

Published

2018

4. An assessment of additive manufactured molds for hand-laid fiber reinforced composites

Author

Robert M. Springfield, Vlastimil Kunc, Chad E. Duty, and Thomas Zeke Sudbury

Subjects

0209 industrial biotechnology, Materials science, Mechanical Engineering, Composite number, High stiffness, 02 engineering and technology, Surface finish, Fiber-reinforced composite, engineering.material, 021001 nanoscience & nanotechnology, medicine.disease_cause, Durability, Industrial and Manufacturing Engineering, Manufacturing engineering, Computer Science Applications, Low volume, 020901 industrial engineering & automation, Coating, Control and Systems Engineering, Mold, medicine, engineering, Composite material, 0210 nano-technology, Software

Abstract

Composite materials are currently in high demand because of their unique properties, such as high stiffness, light weight, and distinctive appearance. A composite material composed of fibers and a resin can be manufactured through a variety of methods. One such method typically used for low production volume and custom applications is the hand layup method, which involves manually combining fibers and resin on a mold surface. For large quantity manufacturing and production of composites, molds are typically made out of a highly durable material like aluminum or steel. The initial investment of the mold is recovered through the manufacturing of numerous parts. However, in low volume and one-off productions, molds are typically handmade by a composite technician, which increases the cost to manufacture a part. The objective of this project was to use large area additive manufacturing, commonly known as 3-D printing, to create molds for these small scale production runs and assess the ability to use them for hand layup composites. After printing, some molds were treated with various surface coatings, and others were machined by a CNC mill. The finished molds were used for hand laying of fiberglass parts in order to assess the durability and resulting surface quality. It was found that printed molds could be an effective approach for limited production runs (4–5) of fiber reinforced composite parts, depending upon the mold shape, surface finish, and coating composition.

Published

2016

5. Big Area Additive Manufacturing of High Performance Bonded NdFeB Magnets

Author

J. Ormerod, Orlando Rios, Brian K. Post, M. Parans Paranthaman, Ikenna C. Nlebedim, Robert Fredette, Angelica Tirado, Edgar Lara-Curzio, Richard R. Lowden, Ling Li, Vlastimil Kunc, and Thomas A. Lograsso

Subjects

010302 applied physics, Multidisciplinary, Materials science, Composite number, 02 engineering and technology, Coercivity, Disorders of movement Donders Center for Medical Neuroscience [Radboudumc 3], 021001 nanoscience & nanotechnology, 01 natural sciences, Article, Neodymium magnet, Ferromagnetism, Remanence, Magnet, 0103 physical sciences, Ultimate tensile strength, Magnetic nanoparticles, Composite material, 0210 nano-technology

Abstract

Additive manufacturing allows for the production of complex parts with minimum material waste, offering an effective technique for fabricating permanent magnets which frequently involve critical rare earth elements. In this report, we demonstrate a novel method - Big Area Additive Manufacturing (BAAM) - to fabricate isotropic near-net-shape NdFeB bonded magnets with magnetic and mechanical properties comparable or better than those of traditional injection molded magnets. The starting polymer magnet composite pellets consist of 65 vol% isotropic NdFeB powder and 35 vol% polyamide (Nylon-12). The density of the final BAAM magnet product reached 4.8 g/cm3, and the room temperature magnetic properties are: intrinsic coercivity Hci = 688.4 kA/m, remanence Br = 0.51 T, and energy product (BH)max = 43.49 kJ/m3 (5.47 MGOe). In addition, tensile tests performed on four dog-bone shaped specimens yielded an average ultimate tensile strength of 6.60 MPa and an average failure strain of 4.18%. Scanning electron microscopy images of the fracture surfaces indicate that the failure is primarily related to the debonding of the magnetic particles from the polymer binder. The present method significantly simplifies manufacturing of near-net-shape bonded magnets, enables efficient use of rare earth elements thus contributing towards enriching the supply of critical materials.

Published

2016

6. Failure Analysis of Adhesively Bonded Structures: From Coupon Level Data to Structural Level Predictions and Verification

Author

Raymond G. Boeman, Anthony M. Waas, De Xie, Vlastimil Kunc, Jaeung Chung, Jessica A. Schroeder, Khaled W. Shahwan, and Lynn B. Klett

Subjects

Carbon fiber reinforced polymer, Strain energy release rate, Materials science, Carbon steel, Test fixture, business.industry, Computational Mechanics, Structural engineering, engineering.material, Strain energy, Crack closure, Fracture toughness, Mechanics of Materials, Modeling and Simulation, Mode coupling, engineering, Composite material, business

Abstract

This paper presents a predictive methodology and verification through experiment for the analysis and failure of adhesively bonded, hat stiffened structures using coupon level input data. The hats were made of steel and carbon fiber reinforced polymer composite, respectively, and bonded to steel adherends. A critical strain energy release rate criterion was used to predict the failure loads of the structure. To account for significant geometrical changes observed in the structural level test, an adaptive virtual crack closure technique based on an updated local coordinate system at the crack tip was developed to calculate the strain energy release rates. Input data for critical strain energy release rates as a function of mode mixity was obtained by carrying out coupon level mixed mode fracture tests using the Fernlund–Spelt (FS) test fixture. The predicted loads at failure, along with strains at different locations, were compared with those measured from the structural level tests. The predictions were found to agree well with measurements for multiple replicates of adhesively bonded hat-stiffened structures made with steel hat/adhesive/steel and composite hat/adhesive/steel, thus validating the proposed methodology for failure prediction.

Published

2005