Aeronautical and Space-Rocket Engineering
DOI: 10.34759/vst-2023-1-45-53
Аuthors
1*, 1**, 21. Komsomolsk-on-Amur State University (KnASU), 27, Lenin str., Komsomolsk-on-Amur, 681013, Russia
2. Komsomolsk-na-Amure State University, 27, Lenina str., Komsomolsk-on-Amur, 681013, Russia
*e-mail: aleksey_yz@mail.ru
**e-mail: maryinsb@mail.ru
Abstract
Airframe units mating is a vital stage of the aircraft final assem-bly, which should ensure high accuracy of the aircraft external aerodynamic surfaces. As of today, two foreign-made systems of civil aircraft jig-free assembly are being operated in Russia: technological process of detachable wing part and fuselage of the SSJ-100NEW is being realized in Komsomolsk-on-Amur with the BROTJE automated bench, and the German «ThyssenKrupp» production line is being employed for the MC-21 aircraft in Irkutsk. As for domestic equipment, production line for the Il76MD-90A aircraft automated assembly is functioning in Ulianovsk at the «Aviasatar-SP» aircraft building plant.
In the presented article, the authors consider technological process of detachable wing part to the aircraft fuselage mating employing an automated bench. This con-tributes to reduction of the number of personnel in charge of the routine technological operations of material production.
Process automation is being implied as the industrial robotics applica-tion, much as the numerical control machine tools were employed as the production automation tools. With account for the fact that robotics operate on the assumption of the electronic information, managing programs are being written, products electronic models are being developed and processes are being modeled for it. The article gives an account of the method for the product compliance with design documentation validating, and describes the employed rigging necessary for the bench operation and ensuring high accuracy of measurements. The basic structure of the technological process of the wing detachable part mating with fuselage is presented in the form of the table with the basic operations description. The process of the automated bench with measuring bases is described. The authors propose to employ the considered operation principle of the automated bench while creating a mobile version of the mating bench. The article gives an account of the requirements to the mobile bench structure and its basic technical characteristics.
Application of the automated bench mobile version will allow increasing the volume of released production with the possibility of producing various aircraft configurations at the single production site.
Keywords:
aircraft assembly units mating, automotive mating bench, outer wing, fuselage, aerodynamic contours precision, datum pointReferences
- Bratukhin A.G. (scientific ed.) Prioritety aviatsionnykh tekhnologii. V 2 kn. (Priorities in aviation technologies. In 2 books). Moscow, MAI, 2004. Book 1. Chapters 1–12, pp. 294–295.
- Qi R., Tang Y., Zhang K. Accuracy Improvement Calibrations for the Double-Position 4-PPPS Aircraft Docking System. Mathematical Problems in Engineering, 2020, no. 4, pp. 1–14. DOI: 10.1155/2020/4358901
- Mosqueira G., Apetz J., Santos K. et al. Analysis of the indoor GPS system as feedback for the robotic alignment of fuselages using laser radar measurements as comparison. Robotics and Computer-Integrated Manufacturing, 2012, vol. 28, no. 6, pp. 700–709. DOI: 10.1016/j.rcim.2012.03.004
- Krysin V.N. Tekhnologicheskaya podgotovka aviatsionnogo proizvodstva (Technological preparation of aviation production), Moscow, Mashinostroenie, 1984, pp. 162–167.
- Guseva R.I., Mar’in S.B. Proektirovanie i montazh sborochnykh prisposoblenii (Design and installation of assembly devices), Komsomol’sk-na-Amure, KnAGU, 2022, 99 p.
- Molchanov I.V., Guseva R.I. Materialy IV Vserossiiskoi natsional’noi nauchnoi konferentsii studentov, aspirantov i molodykh uchenykh «Molodezh’ i nauka: aktual’nye problemy fundamental’nykh i prikladnykh issledovanii» (12–16 April 2021; Komsomol’sk-na-Amure), pp. 286–288.
- Guseva R.I. Uchenye zapiski Komsomol’skogo-na-Amure gosudarstvennogo tekhnicheskogo universiteta, 2011, no. 1—1(5), pp. 16–22.
- Feoktistov S.I., Mar’in S.B., Makarova E.A. Sovremennye metody i sredstva avtomatizatsii kontrolya osnastki i izdelii v samoletostroenii (Modern automation methods and means for equipment and products control in aircraft building), Komsomol’sk-na-Amure, KnAGTU, 2003, 78 p.
- Zaitsev G.N. Upravlenie kachestvom v protsesse proizvodstva (Quality management in the production pro-cess), Moscow, RIOR: INFRA, 2016, 164 p. URL: https://znanium.com/read?id=259578
- Kovalev A.A., Rogov N.V. Evaluation of quality indicator dispersion depending on technological process parameters. Aerospace MAI Journal, 2021, vol. 28, no. 1, pp. 175–186. DOI: 10.34759/vst-2021-1-175-186
- Zagorodnii A.E, Mar’in S.B. Materialy XV Vserossiiskoi studencheskoi nauchnoi shkoly «Aerokosmicheskaya dekada» (3–8 October 2022; Yaropolets, MO, MAI), Moscow, Pero, 2022, pp. 90–95.
- Cheng L., Wang Q., Li J., Ke Y. Variation modeling for fuselage structures in large aircraft digital assembly. Assembly Automation, 2015, vol. 35, no. 2, pp. 172–182. DOI: 10.1108/AA-07-2014-069
- Wang C., Wang W. Development of Control System of Aircraft Fuselage Docking Based on PLC. 3rd International Conference on Advances in Materials, Machinery, Elec-tronics (AMME 2019). 2073, no. 1. DOI: 10.1063/1.5090678
- Drouot A., Zhao R., Irving L. et al. Measurement Assisted Assembly for High Accuracy Aerospace Manu-facturing. 16th IFAC Symposium on Information Control Problems in Manufacturing (INCOM 2018). 5, no. 11, pp. 393–398.
- Krivtsov V.S., Pavlenko V.N., Voronko V.V., Vorobjev Y.A., Shostak I.V. Complex approach to robotic automation of assembly processes in aircraft manufacturing based on fuzzy logic. Aerospace MAI Journal, 2013, vol. 20, no. 3, pp. 32–39.
- Qu L., Dong Z., Zhou H. Study on the Measurement Adied Assembly Technology of Aircraft Flexible Assembly Tool. IEEE International Conference on Control Science and Systems Engineering (29–30 December 2014; Shenyang, Liaoning, China), pp. 66–69.
- Mei Z., Maropoulos P.G. Review of the application of flexible, measurement-assisted assembly technology in aircraft manufacturing. Journal of Engineering Manufacture, 2014, vol. 228, no. 10, pp. 1185–1197. DOI: 10.1177/ 0954405413517387
- Zhu W., Zhang A., Mei B., Ke Y. Automatic stepping for circumferential splice drilling in aircraft fuselage assembly. Industrial Robot, 2016, vol. 43, no. 2, pp. 144–152. DOI: 10.1108/IR-06-2015-0114
- Conte J., Santolaria J., Majarena A.C. et al. Laser Tracker error modeling and kinematic calibration strategy. Key Engineering Materials, 2014, vol. 615, pp. 63–69. DOI: 10.4028/www.scientific.net/KEM.615.63
- Li S., Huang Z., Zeng Q., Huang X. Study of a transferring system for measurements in aircraft assembly. Journal of Intelligent Manufacturing and Special Equipment, 2022, vol. 3, no. 1, pp. 31–47. DOI: 10.1108/JIMSE-01-2022-0001
- Zhu Y., Huang X., Fang W., Li S. Trajectory Planning Algorithm Based on Quaternion for 6-DOF Aircraft Wing Automatic Position and Pose Adjustment Method. Chinese Journal of Aeronautics, 2010, vol. 23, no. 6, pp. 707–714. DOI: 10.1016/S1000-9361(09)60273-9
- Milyukov I.A., Rogalev A.N., Sokolov V.P. Approaches to design engineering and technological designing integration. Aerospace MAI Journal, 2020, vol. 27, no. 4, pp. 59–70. DOI: 10.34759/vst-2020-4-59-70
- Sun W., Wei Z., Cao L. A Triple-laser Trackers Automatic Measurement System for Large-scale Parts Assembly. 9th International Conference on Electronic Measurement & Instruments (16-18 August 2009; Beijing, China), vol. 2, pp. 540–543. DOI:10.1109/ICEMI.2009.5274530
- Li Y., Zhang L., Wang Y. An optimal method of posture adjustment in aircraft fuselage joining as-sembly with engineering constraints. Chinese Journal of Aeronautics, 2017, vol. 30, no. 6, pp. 2016–2023. DOI: 10.1016/j.cja.2017.05.006
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