Abstract
A new technique for examining composites by means if ultrajet diagnostics is considered. The scientific approach is based on imitating material fatigue tests in accelerated mode and evaluating composites for adhesive strength at alternate loads. Ultrajet diagnostics will allow ensuring the performance adequacy of resource strength calculations while designing items from composites by rapidly determining the necessary parameters of physical mechanical properties in the course of their design and process development. A Ti6Al4V titanium alloy powder sample made by selective laser melting is used as an example to show that the geometric parameters of hydroerosion are associated with the surface defects of the sample, its stress–strain state and the in-growth path and direction followed by the scanning laser beam.
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REFERENCES
A. Alderson, K. L. Alderson, G. D. Hudson, and D. E. Skertchly, GB Patent No. 2430119 (2011).
K. R. Loui, K. Dzhain, and E. K. Stivenson, RU Patent No. 2540411, Byull. Izobret., No. 4 (2015).
Parvesh Anti, Sarbjit Singh, and Alakesh Manna, “Glass fibers/SiCp reinforced epoxy composites: Effect of environmental conditions,” J. Compos. Mater. 52 (9), 1253–1264 (2017).
C. Scarponi and G. Briotti, “Ultrasonic technique for the evaluation of delaminations on CFRP, GFRP, KFRP composite materials,” Composites, Part B 31 (3), 237–243 (2000).
G. Beckermann, “Nanofibre beils for high-performance composites,” JEC Compos., No. 102, 39–42 (2016).
M. G. R. Sause, “Acoustic emission signal propagation in damaged composite structures,” J. Acoust. Emiss. 31 (1), 1–18 (2013).
M. Gorman, “Modal AE analysis of fracture and failure in composite materials, and the quality and life of high composite pressure vessels,” J. Acoust. Emiss. 29, 1–28 (2011).
Kazuhiro Sakat, Naomi Kishitani, and Giochi Ben, “Development of molding method and compressive properties of CFRP cylindrical shells reinforced with isogrid,” J. Jpn. Soc. Compos. Mater. 37 (3), 111–118 (2011).
Satoshi Kobayashi, Mari Kawahara, and Tatsuro Kosaka, “Effect of lamination thickness on the damage behavior in FW-CFRP composite pipes subjected to out-of plane loading,” J. Jpn. Soc. Compos. Mater. 36 (4), 138—150 (2010).
F. Aymerich and S. Meili, “Ultrasonic evaluation of matrix damage in impacted composite laminates,” Composites, Part B 31 (1), 1–6 (2000).
S. Gholizadeh, “A review of non-destructive testing methods of composite materials,” in Conference: XV Portuguese Conference on Fracture (Pacço de Arcos, 2016), Vol. 1.
V. V. Murashov, “Quality control of products made of polymer composite materials by acoustic methods,” Kontrol, Diagn., No. 12, 16–29 (2016).
R. Teti, “Ultrasonic identification and measurement of defects in composite material laminates,” CIRP Ann. 39 (1), 527–530 (1990).
V. E. Barsuk, G. G. Anokhin, L. N. Stepanova, et al., “Strength tests of elements of aircraft structures made of carbon fiber using the method of acoustic emission and tensometry,” Polet, No. 7, 53–60 (2016).
L. N. Stepanova, I. S. Ramazanov, and V. V. Chernova, “Wavelet analysis of the structure of acoustic emission signals during strength tests of samples made of carbon fiber,” Kontrol, Diagn., No. 7, 54–62 (2015).
L. N. Stepanova, G. G. Anokhin, and V. V. Chernova, “The use of the acoustic emission method in cyclic testing of CFRP specimens with different types of monolayer stacking,” Kontrol, Diagn., No. 2, 66–74 (2016).
L. N. Stepanova, V. A. Bataev, and V. V. Chernova, “Investigation of the fracture of CFRP specimens under static loading using acoustic emission and fractography methods,” Defektoskopiya, No. 6, 26–33 (2017).
A. L. Galinovskii, A. V. Gurevskii, and G. A. Zhigaroev, Ultrajet and Laser Technologies in Rocket and Space Engineering (Mosk. Gos. Tekh. Univ. im. N. E. Baumana, Moscow, 2010) [in Russian].
V. A. Troitskii, M. N. Karmanov, and N. V. Troitskaya, “Nondestructive quality control of composite materials,” Tekh. Diagn. Nerazrushayushchii Kontrol, No. 3, 29–33 (2014).
A. L. Galinovskii, S. K. Sal’nikov, R. R. Saifutdinov, I. N. Chornyi, S. A. Novozhilov, and A. K. Medvedeva, “Ultrajet technology for processing and diagnostics of ceramic and composite materials,” in Current Problems of the Development of National Cosmonautics: Proc. XXXIV Academic Readings on Astronautics (Komissiya Ross. Akad. Nauk, Moscow, 2010), pp. 558–559.
M. I. Abashin, A. A. Barzov, A. L. Galinovskii, and V. A. Moiseev, “Feasibility study of control and diagnostic operations,” Fundam. Prikl. Probl. Tekh. Tekhnol., No. 1, 133–139 (2015).
A. A. Barzov, A. L. Galinovskii, E. S. Golubev, N. N. Sysoev, A. A. Fedyanin, and A. S. Filimonov, “Ultrajet express diagnostics of the anisotropy of the surface layer of materials and products of rocket and space technology,” in Current Problems of Development of Rocket and Space Technology and Weapons Systems: Scientific Papers Dedicated to the 80th Anniversary of the Faculty “Special Mechanical Engineering” Bauman Moscow State Technical University (Moscow, 2018), pp. 297–308 [in Russian].
A. A. Barzov, A. L. Galinovskii, E. S. Golubev, N. N. Sysoev, A. A. Fedyanin, and A. S. Filimonov, “Ultrajet express diagnostics of the anisotropy of the surface layer of materials and products of rocket and space technology,” Inzh. Zh.: Nauka Innovatsii, No. 6, 4 (2018).
V. A. Tarasov and A. L. Galinovskii, “Problems and prospects of development of hydrojet technologies in rocket and space technology,” in Current Problems of Development of Rocket and Space Technology and Weapons Systems: Scientific Papers (Moscow, 2013), pp. 272–283 [in Russian].
A. A. Barzov, A. L. Galinovskii, and M. I. Abashin, “Factor model of ultrajet hydro-erosion,” Izv. Vyssh. Uchebn. Zaved., Mashinostr., No. 10, 63–68 (2012).
A. A. Kovalev, L. A. Tishchenko, and F. A. Savenkov, “On the development of a model for ultrajet express diagnostics of materials,” Nauka Obraz., No. 10, 23–34 (2013).
M. I. Abashin, A. L. Galinovskii, and A. V. Sgibnev, “Technological support of the procedure for the accelerated determination of the quality parameters of the surface layer of the material of products of rocket and space technology,” Izv. Vyssh. Uchebn. Zaved., Mashinostr., No. 3, 73–79 (2013).
A. A. Barzov and A. L. Galinovskii, Ultrajet Technology and Materials Diagnostics (Mosk. Gos. Tekh. Univ. im. N.E. Baumana, Moscow, 2009) [in Russian].
M. I. Abashin, A. A. Barzov, A. L. Galinovskii, O. I. Kazakova, A. A. Kovalev, V. I. Kolpakov, S. G. Mulyar, S. A. Novozhilov, and N. N. Sysoev, Numerical Modeling of Hydrophysical Processes in the Zone of Shock-Dynamic Interaction of Ultrajet of Liquid with Solid Target (Mosk. Gos. Univ., 2011).
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Bochkarev, S.V., Barzov, A.A. & Galinovskii, A.L. Ensuring the Informational Effectiveness of Ultrajet Diagnostics for Quality Control of Composites. Polym. Sci. Ser. D 14, 269–273 (2021). https://doi.org/10.1134/S1995421221020052
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DOI: https://doi.org/10.1134/S1995421221020052