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Статті в журналах з теми "Additive Manufacture of Energetic Materials"
Rodriguez, J., J. I. Vicente, J. C. Ezeiza, A. Zuriarrain, P. J. Arrazola, X. Badiola, E. Dominguez, and D. Soler. "Mechanical and electrical properties of additively manufactured copper." IOP Conference Series: Materials Science and Engineering 1193, no. 1 (October 1, 2021): 012034. http://dx.doi.org/10.1088/1757-899x/1193/1/012034.
Повний текст джерелаCañadilla, Antonio, Ana Romero, Gloria P. Rodríguez, Miguel Á. Caminero, and Óscar J. Dura. "Mechanical, Electrical, and Thermal Characterization of Pure Copper Parts Manufactured via Material Extrusion Additive Manufacturing." Materials 15, no. 13 (July 1, 2022): 4644. http://dx.doi.org/10.3390/ma15134644.
Повний текст джерелаDa Cunha, Thammi Queuri Gomes, Pedro Vilela Gondim Barbosa, Pedro Augusto Fonseca Lima, Thalles Santiago Pimentel, Lucas Lemes de Souza Peixoto, and Carlos Roberto Sette Júnior. "CARACTERIZAÇÃO DO RESÍDUO DE MDF E SEU APROVEITAMENTO NA PRODUÇÃO DE PELLETS." Nativa 6, no. 3 (May 22, 2018): 300. http://dx.doi.org/10.31413/nativa.v6i3.5087.
Повний текст джерелаLoaeza, David, Jonathan Cailloux, Orlando Santana Pérez, Miguel Sánchez-Soto, and Maria Lluïsa Maspoch. "Extruded-Calendered Sheets of Fully Recycled PP/Opaque PET Blends: Mechanical and Fracture Behaviour." Polymers 13, no. 14 (July 19, 2021): 2360. http://dx.doi.org/10.3390/polym13142360.
Повний текст джерелаKline, Dylan J., Zaira Alibay, Miles C. Rehwoldt, Alexander Idrogo-Lam, Spencer G. Hamilton, Prithwish Biswas, Feiyu Xu, and Michael R. Zachariah. "Experimental observation of the heat transfer mechanisms that drive propagation in additively manufactured energetic materials." Combustion and Flame 215 (May 2020): 417–24. http://dx.doi.org/10.1016/j.combustflame.2020.01.020.
Повний текст джерелаIlyushin, Mikhail A., Sergey M. Putis, Andrey S. Mazur, Sergey A. Dushenok, and Irina V. Shugalei. "LASER INITIATION OF ENERGETIC MATERIALS." Bulletin of the Saint Petersburg State Institute of Technology (Technical University) 63 (2022): 14–22. http://dx.doi.org/10.36807/1998-9849-2022-63-89-14-22.
Повний текст джерелаLoukaides, Evripides G., Rhodri W. C. Lewis, and Christopher R. Bowen. "Additive manufacture of multistable structures." Smart Materials and Structures 28, no. 2 (January 21, 2019): 02LT02. http://dx.doi.org/10.1088/1361-665x/aae4f6.
Повний текст джерелаLiu, Dan, Boyoung Lee, Aleksandr Babkin, and Yunlong Chang. "Research Progress of Arc Additive Manufacture Technology." Materials 14, no. 6 (March 15, 2021): 1415. http://dx.doi.org/10.3390/ma14061415.
Повний текст джерелаMcparland, Kyle, Zachary Larimore, Paul Parsons, Austin Good, John Suarez, and Mark Mirotznik. "Additive Manufacture of Custom Radiofrequency Connectors." IEEE Transactions on Components, Packaging and Manufacturing Technology 12, no. 1 (January 2022): 168–73. http://dx.doi.org/10.1109/tcpmt.2021.3134603.
Повний текст джерелаCasemiro, R. L., N. C. O. Tapanes, M. C. L. Souza, A. I. C. Santana, and W. C. L. Pinto. "ENERGETIC ESTIMATION OF HEAT-RECOVERY COKE OVEN." Revista de Engenharia Térmica 21, no. 2 (October 9, 2022): 13. http://dx.doi.org/10.5380/reterm.v21i2.87917.
Повний текст джерелаДисертації з теми "Additive Manufacture of Energetic Materials"
Shalchy, Faezeh, Enrique Cuan-Urquizo, Kevin Jose, Neil Ferguson, Claus Ibsen, and Atul Bhaskar. "Mechanics and manufacture of lattice structures & materials." Thesis, Київський національний університет технологій та дизайну, 2021. https://er.knutd.edu.ua/handle/123456789/19222.
Повний текст джерелаJiba, Zetu. "Coating processes towards selective laser sintering of energetic material composites." Diss., University of Pretoria, 2019. http://hdl.handle.net/2263/79246.
Повний текст джерелаDissertation (MSc)--University of Pretoria, 2019.
Chemical Technology
MSc
Unrestricted
Allen, Robert James Anthony. "Investigations into the potential of constructing aligned carbon nanotube composite materials through additive layer manufacture." Thesis, University of Exeter, 2013. http://hdl.handle.net/10871/12301.
Повний текст джерелаMyers, Kyle M. "Structure-Property Relationship of Binder Jetted Fused Silica Preforms to Manufacture Ceramic-Metallic Interpenetrating Phase Composites." Youngstown State University / OhioLINK, 2016. http://rave.ohiolink.edu/etdc/view?acc_num=ysu1464089607.
Повний текст джерела(11189886), Diane Collard. "Enhancing Solid Propellants with Additively Manufactured Reactive Components and Modified Aluminum Particles." Thesis, 2021.
Знайти повний текст джерелаA variety of methods have been developed to enhance solid propellant burning rates, including adjusting oxidizer particle size, modifying metal additives, tailoring the propellant core geometry, and adding catalysts or wires. Fully consumable reactive wires embedded in propellant have been used to increase the burning rate by increasing the surface area; however, the manufacture of propellant grains and the observation of geometric effects with reactive components has been restricted by traditional manufacturing and viewing methods. In this work, a printable reactive filament was developed that is tailorable to a number of use cases spanning reactive fibers to photosensitive igniters. The filament employs aluminum fuel within a printable polyvinylidene fluoride matrix that can be tailored to a desired burning rate through stoichiometry or aluminum fuel configuration such as particle size and modified aluminum composites. The material is printable with fused filament fabrication, enabling access to more complex geometries such as spirals and branches that are inaccessible to traditionally cast reactive materials. However, additively manufacturing the reactive fluoropolymer and propellant together comes attendant with many challenges given the significantly different physical properties, particularly regarding adhesion. To circumvent the challenges posed by multiple printing techniques required for such dissimilar materials, the reactive fluoropolymer was included within a solid propellant carrier matrix as small fibers. The fibers were varied in aspect ratio (AR) and orientation, with aspect ratios greater than one exhibiting a self-alignment behavior in concordance with the prescribed extrusion direction. The effective burning rate of the propellant was improved nearly twofold with 10 wt.% reactive fibers with an AR of 7 and vertical orientation.
The reactive wires and fibers in propellant proved difficult to image in realistic sample designs, given that traditional visible imaging techniques restrict the location and dimensions of the reactive wire due to the necessity of an intrusive window next to the wire, a single-view dynamic X-ray imaging technique was employed to analyze the evolution of the internal burning profile of propellant cast with embedded additively manufacture reactive components. To image complex branching geometries and propellant with multiple reactive components stacked within the same line of sight, the dynamic X-ray imaging technique was expanded to two views. Topographic reconstructions of propellants with multiple reactive fibers showed the evolution of the burning surface enhanced by the geometric effects caused by the faster burning fibers. These dual-view reconstructions provide a method for accurate quantitative analysis of volumetric burning rates that can improve the accessibility and viability of novel propellant grain designs.
(10732050), Patrick D. Bowers. "Direct-Write of Melt-Castable Energetic and Mock materials." Thesis, 2021.
Знайти повний текст джерелаExplosives and rocket fuel are just two prime examples of energetic materials, compounds that contain a combustible fuel and oxidizer within the same substance. Recent advances have enabled the construction of energetic materials through multiple variations of additive manufacturing, principally inkjet, direct-write, fused filament fabrication, electrospray deposition, and stereolithography. Many of the methods used for creating multiple layered objects (three-dimensional) from energetic materials involve the use of highly viscid materials.
The focus of this work was to design a process capable of additively manufacturing three-dimensional objects from melt-castable energetic materials, which are known for their low viscosity. An in-depth printer design and fabrication procedure details the process requirements discovered through previous works, and the adaptations available and used to construct an additive manufacturing device capable of printing both energetic and non-energetic (also referred to as inert) melt-castable materials. Initial characterization of three proposed inert materials confirmed their relative similarity in rheological properties to melt-castable energetic materials and were used to test the printer’s performance.
Preliminary tests show the constructed device is capable of additively manufacturing melt-castable materials reproducibly in individual layers, with some initial successful prints in three-dimensions, up to three layers. An initial characterization of the printer’s deposition characteristics additionally matches literature predictions. With the ability to print three-dimensional objects from melt-castable materials confirmed, future work will focus on the reproducibility of multi-layered objects and the refined formulation of melt-castable energetic materials.
(9148682), Marlon D. Walls Jr. "Investigating the Ability to Preheat and Ignite Energetic Materials Using Electrically Conductive Materials." Thesis, 2020.
Знайти повний текст джерела(9178199), Monique McClain. "ADDITIVE MANUFACTURING OF VISCOUS MATERIALS: DEVELOPMENT AND CHARACTERIZATION OF 3D PRINTED ENERGETIC STRUCTURES." Thesis, 2020.
Знайти повний текст джерелаThe performance of solid rocket motors (SRMs) is extremely dependent on propellant formulation, operating pressure, and initial grain geometry. Traditionally, propellant grains are cast into molds, but it is difficult to remove the grains without damage if the geometry is too complex. Cracks or voids in propellant can lead to erratic burning that can break the grain apart and/or potentially overpressurize the motor. Not only is this dangerous, but the payload could be destroyed or lost. Some geometries (i.e. internal voids or intricate structures) cannot be cast and there is no consistent nor economical way to functionally grade grains made of multiple propellant formulations at fines scales (~ mm) without the risk of delamination between layers or the use of adhesives, which significantly lower performance. If one could manufacture grains in such a way, then one would have more control and flexibility over the design and performance of a SRM. However, new manufacturing techniques are required to enable innovation of new propellant grains and new analysis techniques are necessary to understand the driving forces behind the combustion of non-traditionally manufactured propellant.
Additive manufacturing (AM) has been used in many industries to enable rapid prototyping and the construction of complex hierarchal structures. AM of propellant is an emerging research area, but it is still in its infancy since there are some large challenges to overcome. Namely, high performance propellant requires a minimum solids loading in order to combust properly and this translates into mixtures with high viscosities that are difficult to 3D print. In addition, it is important to be able to manufacture realistic propellant formulations into grains that do not deform and can be precisely functionally graded without the presence of defects from the printing process. The research presented in this dissertation identifies the effect of a specific AM process called Vibration Assisted Printing (VAP) on the combustion of propellant, as well as the development of binders that enable UV-curing to improve the final resolution of 3D printed structures. In addition, the combustion dynamics of additively manufactured layered propellant is studied with computational and experimental methods. The work presented in this dissertation lays the foundation for progress in the developing research area of additively manufactured energetic materials.
The appendices of this dissertation presents some additional data that could also be useful for researchers. A more detailed description of the methods necessary to support the VAP process, additional viscosity measurements and micro-CT images of propellant, the combustion of Al/PVDF filament in windowed propellant at pressure, and microexplosions of propellant with an Al/Zr additive are all provided in this section.
(10732359), Aaron Afriat. "COMBUSTION CHARACTERISTICS OF ADDITIVELY MANUFACTURED GUN PROPELLANTS." Thesis, 2021.
Знайти повний текст джерелаAdditive manufacturing of gun propellants is an emerging and promising field which addresses the limitations of conventional manufacturing techniques. Gun propellants are manufactured using wetted extrusion, which uses volatile solvents and dies of limited and constant geometries. On the other hand, additive techniques are faced with the challenges of maintaining the gun propellant’s energetic content as well as its structural integrity during high pressure combustion. The work presented in this thesis demonstrates the feasibility of producing functioning gun propellant grains using vibration-assisted 3D printing, a novel method which has been shown to extrude extremely viscous materials such as clays and propellant pastes. At first, the technique is compared to screw-driven additive methods which have been used in printing gun propellant pastes with slightly lower energetic content. In chapter two, diethylene glycol dinitrate (DEGDN), a highly energetic plasticizer, was investigated due to its potential to replace nitroglycerin in double base propellants with high nitroglycerin content. A novel isoconversional method was applied to analyze its decomposition kinetics. The ignition and lifetime values of diethylene glycol dinitrate were obtained using the new isoconversional method, in order to assess the safety of using the plasticizer in a modified double base propellant. In chapter three, a modified double base propellant (M8D) containing DEGDN was additively manufactured using VAP. The printed strands had little to no porosity, and their density was nearly equal to the theoretical maximum density of the mixture. The strands were burned at high pressures in a Crawford bomb and the burning was visualized using high speed cameras. The burning rate equation as a function of the M8D propellant as a function of pressure was obtained. Overall, this work shows that VAP is capable of printing highly energetic gun propellants with low solvent content, low porosity, with high printing speeds, and which have consistent burning characteristics at high pressures.
Частини книг з теми "Additive Manufacture of Energetic Materials"
Wei, Yimeng, Areti Markopoulou, Yuanshuang Zhu, Eduardo Chamorro Martin, and Nikol Kirova. "Additive Manufacture of Cellulose Based Bio-Material on Architectural Scale." In Proceedings of the 2021 DigitalFUTURES, 286–304. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-16-5983-6_27.
Повний текст джерела"Manufacture." In Metal-Fluorocarbon Based Energetic Materials, 271–98. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2011. http://dx.doi.org/10.1002/9783527644186.ch18.
Повний текст джерелаMejia, Guilherme Lourenço. "Solid Rocket Motor Internal Ballistics Simulation Considering Complex 3D Propellant Grain Geometries." In Energetic Materials Research, Applications, and New Technologies, 146–69. IGI Global, 2018. http://dx.doi.org/10.4018/978-1-5225-2903-3.ch007.
Повний текст джерелаPrasad G., Sahana Jawahar, Sripad Kulkarni S., Deepika G. N., Mirzada Mahaz Ahmed, and Likitha S. "Influence of Additive Manufacturing in Reentry Launch Vehicle." In Advanced Manufacturing Techniques for Engineering and Engineered Materials, 226–38. IGI Global, 2022. http://dx.doi.org/10.4018/978-1-7998-9574-9.ch013.
Повний текст джерелаMaina, Martin Ruthandi. "Laser Additive Manufacturing of Titanium-Based Implants." In Advances in Civil and Industrial Engineering, 236–47. IGI Global, 2016. http://dx.doi.org/10.4018/978-1-5225-0329-3.ch009.
Повний текст джерелаMaina, Martin Ruthandi. "Laser Additive Manufacturing of Titanium-Based Implants." In Biomedical Engineering, 1028–37. IGI Global, 2018. http://dx.doi.org/10.4018/978-1-5225-3158-6.ch044.
Повний текст джерелаPan, Chi Chun, Carolyn Kim, Jiannan Li, Elaine Lui, Brett Salazar, Stuart B. Goodman, and Yunzhi P. Yang. "Bioprinting for Bone Tissue Engineering." In Additive Manufacturing in Biomedical Applications, 1–9. ASM International, 2022. http://dx.doi.org/10.31399/asm.hb.v23a.a0006854.
Повний текст джерелаBarua, Ranjit, Amit Roychowdhury, and Pallab Datta. "Study of Different Additive Manufacturing Processes and Emergent Applications in Modern Healthcare." In Advanced Manufacturing Techniques for Engineering and Engineered Materials, 239–59. IGI Global, 2022. http://dx.doi.org/10.4018/978-1-7998-9574-9.ch014.
Повний текст джерелаJoseph, Jithin. "Direct Laser Fabrication of Compositionally Complex Materials." In Advances in Civil and Industrial Engineering, 147–63. IGI Global, 2020. http://dx.doi.org/10.4018/978-1-7998-4054-1.ch008.
Повний текст джерелаVargas-Bernal, Rafael. "The Role of Self-Assembly in Additive Manufacturing of Aerospace Applications." In Handbook of Research on Advancements in the Processing, Characterization, and Application of Lightweight Materials, 287–310. IGI Global, 2022. http://dx.doi.org/10.4018/978-1-7998-7864-3.ch013.
Повний текст джерелаТези доповідей конференцій з теми "Additive Manufacture of Energetic Materials"
Ruz-Nuglo, Fidel, Lori Groven, and Jan A. Puszynski. "Additive Manufacturing for Energetic Components and Materials." In 50th AIAA/ASME/SAE/ASEE Joint Propulsion Conference. Reston, Virginia: American Institute of Aeronautics and Astronautics, 2014. http://dx.doi.org/10.2514/6.2014-3894.
Повний текст джерелаDRIEL, CHRIS VAN, MICHIEL STRAATHOF, and JOOST VAN LINGEN. "Developments in Additive Manufacturing of Energetic Materials at TNO." In 30th International Symposium on Ballistics. Lancaster, PA: DEStech Publications, Inc., 2017. http://dx.doi.org/10.12783/ballistics2017/16867.
Повний текст джерелаEsfahani, M. R. Nekouie, M. P. Shuttleworth, R. A. Harris, R. W. Kay, V. Doychinov, I. D. Robertson, J. Marques-Hueso, T. D. A. Jones, A. Ryspayeva, and M. P. Y. Desmulliez. "Hybrid Additive Manufacture of Conformal Antennas." In 2018 IEEE MTT-S International Microwave Workshop Series on Advanced Materials and Processes for RF and THz Applications (IMWS-AMP). IEEE, 2018. http://dx.doi.org/10.1109/imws-amp.2018.8457128.
Повний текст джерелаMahamood, Rasheedat M., Yasuhiro Okamoto, Martin Ruthandi Maina, Stephen A. Akinlabi, Sisa Pityana, Monnamme Tlotleng, and Esther T. Akinlabi. "Wear Resistance Behaviour of Laser Additive Manufacture Materials: An Overview." In 2019 International Conference on Engineering, Science, and Industrial Applications (ICESI). IEEE, 2019. http://dx.doi.org/10.1109/icesi.2019.8863016.
Повний текст джерелаMuhammad, Noorhafiza, Amirul Asyraf Azli, Mohd Shuhidan Saleh, Midhat Nabil Ahmad Salimi, Mohd Fathullah Ghazli, and Shayfull Zamree Abd Rahim. "A review on additive manufacturing in bioresorbable stent manufacture." In PROCEEDINGS OF 8TH INTERNATIONAL CONFERENCE ON ADVANCED MATERIALS ENGINEERING & TECHNOLOGY (ICAMET 2020). AIP Publishing, 2021. http://dx.doi.org/10.1063/5.0051941.
Повний текст джерелаPompidou, Stéphane, Marion Prinçaud, Nicolas Perry, and Dimitri Leray. "Recycling of Carbon Fiber: Identification of Bases for a Synergy Between Recyclers and Designers." In ASME 2012 11th Biennial Conference on Engineering Systems Design and Analysis. American Society of Mechanical Engineers, 2012. http://dx.doi.org/10.1115/esda2012-82106.
Повний текст джерелаLarimore, Zachary J., Paul E. Parsons, Austin Good, Kyle McParland, and Mark Mirotznik. "Materials for Use in the Additive Manufacture of RF Components and Devices." In 2021 International Conference on Electromagnetics in Advanced Applications (ICEAA). IEEE, 2021. http://dx.doi.org/10.1109/iceaa52647.2021.9539699.
Повний текст джерелаKarpagaraj, A., S. Baskaran, T. Arunnellaiappan, and N. Rajesh Kumar. "A review on the suitability of wire arc additive manufacturing (WAAM) for stainless steel 316." In ADVANCES IN MECHANICAL DESIGN, MATERIALS AND MANUFACTURE: Proceeding of the Second International Conference on Design, Materials and Manufacture (ICDEM 2019). AIP Publishing, 2020. http://dx.doi.org/10.1063/5.0004148.
Повний текст джерелаVallejo Melgarejo, Laura Daniela, Jose García, Ronald G. Reifenberger, and Brittany Newell. "Manufacture of Lenses and Diffraction Gratings Using DLP As an Additive Manufacturing Technology." In ASME 2018 Conference on Smart Materials, Adaptive Structures and Intelligent Systems. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/smasis2018-7963.
Повний текст джерелаYadollahi, Aref, Denver Seely, Brian Patton, and Nima Shamsaei. "Microstructural Features and Mechanical Properties of 316L Stainless Steel fabricated by Laser Additive Manufacture." In 56th AIAA/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference. Reston, Virginia: American Institute of Aeronautics and Astronautics, 2015. http://dx.doi.org/10.2514/6.2015-1355.
Повний текст джерелаЗвіти організацій з теми "Additive Manufacture of Energetic Materials"
Slattery, Kevin T. Unsettled Aspects of the Digital Thread in Additive Manufacturing. SAE International, November 2021. http://dx.doi.org/10.4271/epr2021026.
Повний текст джерела