Hydrojet-based parameter control method for aerospace manufacturing processes
Authors: Leun E.V., Sysoev V.K., Shalay V.V., Lomonova E.E., Shakhanov A.E., Vyatlev P.A.
Published in issue: #9(69)/2017
DOI: 10.18698/2308-6033-2017-9-1675
Category: Aviation and Rocket-Space Engineering | Chapter: Design, construction and production of aircraft
The article presents a newly developed hydrojet-based method for controlling manufacturing process parameters. Fluid jets (for instance, those of cutting fluid) directed towards the gauged workpiece form a so-called liquid optical fiber. The workpiece surface reflects the optical radiation that propagates along the jet towards the workpiece and back. We determine fundamental relations between various parameters, such as optical, hydrodynamic, metrological and others, for different operation modes of the hydrojet-based manufacturing process parameter control method during in-process workpiece dimension gauging.
References
[1] Tarasov V.A., Galinovskiy A.L. Inzhenernyy zhurnal: nauka i innovatsii - Engineering Journal: Science and Innovation, 2013, no. 3. Available at: http://engjournal.ru/catalog/machin/rocket/636.html (accessed December 29, 2016).
[2] Leun E.V. Gidrostruynyy interferometricheskiy sposob kontrolya razmerov izdeliy [Hydrojet interferometry-based workpiece dimension control method]. Materialy X Mezhdunarodnoy nauchno-tekhnicheskoy konferentsii Dinamika sistem, mekhanizmov i mashin [Dynamics of systems, mechanisms and machines. Proc. of the 10th International scientific and engineering conference], 2016, no. 1, vol. 2, Omsk, 2016, pp. 101-109.
[3] Leun E.V. Osobennosti postroeniya perspektivnykh lazernykh sposobov aktivnogo kontrolya razmerov izdeliy [Specifics of developing promising laser techniques of in-process workpiece dimension control]. Materialy X Vseross. nauchn. konf. pamyati glavnogo konstruktora PO Polet A.S. Klinyshkova [Proc. of the 10th pan-Russian scientific conference in memory of A.S. Klinyshkov, Chief Designer of Production Association Polyot]. Omsk, 2016, pp. 68-74.
[4] Agaev K.E., Duzhiy A.B., Novoselov A.G. Nauchnyy zhurnal NIUITMO. Ser. Protsessy i apparaty pishchevykh proizvodstv - Scientific Journal NRUITMO. Processes and Food Production Equipment, 2012, no. 1. Available at: http://elibrary.ru/item.asp?id=20317052 (accessed December 29, 2016).
[5] Leun V.I., Tignibidin A.V. Omskiy nauchnyy vestnik - Omsk Scientific Bulletin, 2010, no. 2 (90), pp. 165-169.
[6] Leun E.V. Tekhnologiya mashinostroeniya - Journal "Tekhnologiya mashi-nostroeniya" [Mechanical engineering technology], 2002, no. 5, pp. 33-39.
[7] Ivanov V.V., Kaygorodov A.S., Khrustov V.R., Paranin S.N., Spinn A.V. Rossiyskie nanotekhnologii - Nanotechnologies in Russia, 2006, vol. 1, no. 1-2, pp. 201-207.
[8] Bonk M.A., Bublik V.T., Vilkova M.Yu., Kulebyakin A.V. et al. Izvestiya vysshikh uchebnykh zavedenii. Materialy Elektronnoy Tekhniki - Materials of Electronics Engineering, 2014, no. 1 (65), pp. 58-64.
[9] Zhestkie tonkie endoskopy (boroskopy) proizvodstva OOO NPP EKOMP (Respublika Belarus) [Thin rigid endoscopes (borescopes) manufactured by ECOMP Ltd. (Belarus Republic)]. Available at: http://www.nppecomp.ru/rus/dok/h_end.htm (accessed December 28, 2016).
[10] Ivanov V.V. Razvitie metodov nizkokogerentnoy volokonno - opticheskoy interferometrii. Avtoref diss. ... kand. fiz.-mat. nauk [Development of low-coherence fiber optic interferometry techniques. Autoref. cand. phys.-math. sc. diss.], 01.04.01. Nizhny Novgorod, 2005, p. 20.
[11] Volkov P.V. Razvitie interferentsionnykh i polyarizatsionnykh metodov izmereniya fizicheskikh parametrov tverdykh tel. Avtoref. dis. ... kand. fiz.-mat. nauk [Development of interferometry- and polarization-based techniques for measuring physical parameters of solids. Autoref. cand. phys.-math. sc. diss.], 01.04.01. Nizhny Novgorod, 2009, p. 20.