A hybrid approach for manufacturability analysis

• Autorzy: Stryczek R.

Warianty tytułu

PL

Hybrydowa metoda analizy produktywności

• Języki publikacji: EN

Abstrakty

EN

The paper describes a practical solution for knowledge acquisition of expert process planners and/or experienced machinists with sets of heuristic rules. This fuzzy approach enables to perform manufacturability analysis. Therefore, proposed knowledge system can help in identifying of potential manufacturing problems early in design stage and in determining of machining precedence constraints (hard constraints) in situation of feature volumetric interaction. Special class Weighted Priority Petri Nets and Genetic Algorithms have been used to analyse and optimize the results. Finally, an illustrative example of hole making has been used to demonstrate the proposed methodology.

PL

W pracy przedstawiono praktyczne rozwiązanie problemu akwizycji wiedzy eksperta w projektowaniu procesów i/lub doświadczonych operatorów obrabiarek, reprezentowanej w postaci zbioru heurystycznych reguł. Rozmyte podejście pozwala na prowadzenie analizy technologiczności proponowanego rozwiązania. Opracowana metoda jest pomocna w identyfikacji potencjalnych problemów wytwórczych już na etapie projektowania konstrukcyjnego. Pozwala określić ograniczenia krytyczne dla relacji procedencji, wynikające z wzajemnych objętościowych interakcji pomiędzy formami elementarnymi występującymi w projektowanym wyrobie. Użyto specjalnych klas wagowych, priorytetowych sieci Petriego i algorytmu genetycznego dla analizy i optymalizacji wyników. Zaproponowane podejście przedstawiono na przykładzie ustalania sekwencji obróbki otworów, uwzględniającej technologiczność rozwiązania.

Słowa kluczowe

EN

computer aided process planning; CAPP; design for manufacturing; Petri nets; computational intelligence; CI

PL

komputerowo wspomagane planowanie procesów; CAPP; projektowanie procesu technologicznego; sieci Petriego; inteligencja obliczeniowa; CI

• Wydawca: Komitet Budowy Maszyn PAN ; De Gruyter
• Czasopismo: Advances in Manufacturing Science and Technology
• Rocznik: 2011
• Tom: Vol. 35, nr 3
• Strony: 55--70
• Opis fizyczny: Bibliogr. 41 poz., rys., tab.

Twórcy

autor

Stryczek R.

• University of Bielsko-Biała, Willowa 2 Street, 43-309 Bielsko-Biała, phone (+48 33) 8279213,

Bibliografia

• [1] N. XU, S.H. HUANG, K. RONG: Automatic setup planning: current state-of-the-art and future perspective. Int. Journal of Manufacturing Technology and Management, 11(2007)2, 103-208.
• [2] L. ALTING, H.C. ZHANG: Computer aided process planning: the state-of-the-art survey. Int. Journal of Production Research, 27(1989), 553-585.
• [3] S.H. HUANG, H.C. ZHANG: Neural-hybrid approach for intelligent manufacturing: a survey. Computers in Industry, 26(1995), 107-126.
• [4] D. KIRITSIS: A review of knowledge-based expert systems for process planning. Methods and Problems. Int. Journal of Advanced Manufacturing Technology, 10(1995), 240-261.
• [5] H.C. LEUNG: Annotated bibliography on computer-aided process planning. Int. Journal of Advanced Manufacturing Technology. 12(1996), 309-329.
• [6] J. WANG, A. KUSIAK (ed.): Computational intelligence in manufacturing handbook. Boca Raton: CRC Press LLC; 2001.
• [7] N. AHMAD, A.F.M.A. HAQUE, A.A. HASIN: Current trend in computer aided process planning. Proc. Int. Conf. The Institution of Engineers, Bangladesh 2001, 81-92.
• [8] R. STRYCZEK: Computational intelligence in computer aided process planning -a review. Advances in Manufacturing Science and Technology, 31(2007)4, 77-92.
• [9] H.C. ZHANG, S.H. HUANG: A fuzzy approach to process plan selection. Int. Journal of Production Research, 32(1994)6, 1265-1275.
• [10] S.M. AMAITIK, S.E. KILIÇ: An intelligent process planning system for prismatic parts using STEP features. Int. Journal of Advanced Manufacturing Technology, 31(2007), 978-993.
• [11] T.N. WONG, C.F. CHAN, H.C.W. LAU: Machining process sequencing with fuzzy expert system and genetic algorithms. Engineering with Computers. 19(2003), 191-202.
• [12] X. ZHOU, Y. QIU, G. HUA, H. WANG, X. RUAN: A feasible approach to the integration of CAD and CAM. Computer-Aided Design, 39(2007), 324-338.
• [13] S. DEB, K. GHOSH, S.R. DEB: Machining process planning for rotational components by using a neural network approach. Proc. 29th Int. Conference on Computers and Industrial Engineering, Montreal 2001.
• [14] G.M. KNAPP, H.P. WANG: Acquiring, Storing and utilizing process planning knowledge using neural networks. Journal of Intelligent Manufacturing, 5(1992), 333-344.
• [15] N. AHMAD, A.F.M.A. HAQUE: Artificial neural network based process selection for cylindrical surface machining. Proc. Int. Conf. on Manufacturing, ICM 2002, Dhaka 2002, 321-326.
• [16] S. DEB, K. GHOSH, S. PAUL: A neural network based methodology for machining operations selection in computer-aided process planning for rotationally symmetrical parts. Journal of Intelligent Manufacturing, 7(2006), 557-569.
• [17] J. JOO, S. PARK, H. CHO: Adaptive and dynamic process planning using neural networks. Int. Journal of Production Research, 39(2001)2, 2923-2946.
• [18] X.G. MING, K.L. MAK: Intelligent setup planning in manufacturing by neural networks based approach. Journal of Intelligent Manufacturing, 11(2000), 311-331.
• [19] S.K. GUPTA, D. DAS, W.C. REGLI, D. NAU: Automated manufacturability analysis: a survey. Research in Engineering Design, 9(1997)3, 168-190.
• [20] D.M. ANDERSON: Design for manufacturability & concurrent engineering. СІМ Press, 2006.
• [21] J. MADAN, P.V.M. RAO, T.K. KUNDRA: Computer aided manufacturability analysis of die-cast parts. Computer Aided Design & Application, 4(2007), 147-158.
• [22] S.C. PARK: Knowledge capturing methodology in process planning. Computer-Aided Design, 35(2003), 1109-1117.
• [23] J.P. KRUTH, J. DETAND, G. VAN ZEIR, J. KAMPENAERS, J. PINTE: Methods to improve the response time of CAPP system that generate non-linear process plans. Advances in Engineering Software, 25(1996), 9-17.
• [24] H. XING, S.H. HUANG, J. SHI: Rapid development of knowledge-based systems via integrated knowledge acquisition. Artificial Intelligence for Engineering Design, Analysis and Manufacturing, 17(2003), 221-234.
• [25] C. GRABOWIK, R. KNOSALA: The method of knowledge representation for a CAPP System. Journal of Materials Processing Technology, 133(2003), 90-98.
• [26] K.H. LEE, M.Y. JUNG: Flexible process sequencing using Petri net theory. Computers & Industrial Engineering, 28(1995)2, 279-290.
• [27] Y. HAO, J. MA: A knowledge-based auto-reasoning methodology in hole-machining process planning. Computers in Industry, 57(2006), 297-304.
• [28] D.N. SORMAZ, P. KHURANA, A. WADATKAR: Rule-based process selection of hole making operation for integrated process planning. Proc. ASME 2005 Int. Design Engineering Technical Conferences & Computers and Information in Engineering Conference, Long Beach, DETC2005-85062.
• [29] A. CHEP, L TRICARICO, P. BOURDET, L. GALANTUCCIO: Design of object-oriented database for the definition of machining operation sequences of 3D workpieces. Computers & Industrial Engineering, 34(1998)2, 257-279.
• [30] B.M. COLOSIMO, Q. SEMERARO, T. TOLIO: Rule based system for non linear process plan generation. Studies in Informatics Control, 9(2000)2 133-143.
• [31] M.K. TIWARI, K. RAMA KOTAIAH, S. BHATNAGAR: A case-based computer-aided process-planning system for machining prismatic components. Int. Journal of Advanced Manufacturing Technology, 17(2001), 400-411.
• [32] M. SADAIAH, D.R. YADAV, P.V. MOHANRAM, P. RADHAKRISHAN: A generative computer-aided process planning system for prismatic components. Int. Journal of Advanced Manufacturing Technology, 20(2002), 709-719.
• [33] W. XIANG, C.W. CHUEN, C.M. WONG, L.H. YAM: A generative feature-based system for hydraulic manifold blocks. Int. Journal of Advanced Manufacturing Technology, 19(2002), 805-811.
• [34] A. WADATKAR: Process selection for hole operations using rule based approach. Thesis, Ohio University (2004).
• [35] S.H. HUANG, N. XU: Automatic set-up planning for metal cutting: an integrated methodology. Int. Journal of Production Research, 41(2003)18, 4339-4356.
• [36] S. CHAMPATI, W.F. LU, A.C. LIN: Automated operation sequencing in intelligent process planning: A case-based reasoning approach. Int. Journal of Advanced Manufacturing Technology, 12(1996), 21-36.
• [37] D.N. SORMAZ, B. KHOSHNEVIS: Generation of alternative process plans in integrated manufacturing systems. Journal of Intelligent Manufacturing, 14(2003), 509-526.
• [38] Z. LIU, L. WANG: Sequencing of interacting prismatic machining features for process planning. Computers in Industry, 58(2007), 295-303.
• [39] SJ. FEGHHI: A learning approach toward integration of design and process planning. MS thesis, School of Electrical Engineering, West Lafayette, IN 1989.
• [40] I.B. TURKSEN: Measurement of membership functions and their acquisition. Fuzzy Sets and Systems, 40(1991), 5-38.
• [41] H.C. ZHANG, E. LIN: A hybrid-graph approach for automated setup planning in CAPP. Robotics and Computer-Integrated Manufacturing, 15(1999), 89-100.