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Bases para el desarrollo de Micromáquinas Herramienta Paralelas

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Bases para el desarrollo de Micromáquinas Herramienta Paralelas

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Yáñez Valdez, R. (2014). Bases para el desarrollo de Micromáquinas Herramienta Paralelas. Revista Iberoamericana de Automática e Informática industrial. 11(2):212-223. https://doi.org/10.1016/j.riai.2014.02.004

Por favor, use este identificador para citar o enlazar este ítem: http://hdl.handle.net/10251/144185

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Título: Bases para el desarrollo de Micromáquinas Herramienta Paralelas
Otro titulo: Basis for the development of micro-parallel kinematic machines
Autor: Yáñez Valdez, Ricardo
Fecha difusión:
Resumen:
[ES] El presente trabajo pretende sentar las bases del desarrollo de micromáquinas herramienta paralelas. Se plantean condiciones básicas y se propone un proceso de selección de configuraciones paralelas con miras a su ...[+]


[EN] This work aims to establish the development basis of parallel configurations based micromachine tools. Basic conditions are identified from typical micromachine tools in order to propose a selection process of parallel ...[+]
Palabras clave: Decoupled motion , Force isotropy , Micromachine tool , Microparallel kinematic machine , Performance indices , Reachable workspace , Selection method , Type synthesis , Desacoplamiento cinemático , Espacio de trabajo , Índices de desempeño , Isotropía de fuerzas , Mecanismo paralelo , Micromáquina herramienta , Proceso de selección , Síntesis de tipo
Derechos de uso: Reserva de todos los derechos
Fuente:
Revista Iberoamericana de Automática e Informática industrial. (issn: 1697-7912 ) (eissn: 1697-7920 )
DOI: 10.1016/j.riai.2014.02.004
Editorial:
Elsevier
Versión del editor: https://doi.org/10.1016/j.riai.2014.02.004
Código del Proyecto:
info:eu-repo/grantAgreement/UNAM/PAPIME/PE105909/
info:eu-repo/grantAgreement/CONACyT//60895/
Agradecimientos:
Se agradece a los coordinadores del grupo de Micromecánica y Mecatrónica del CCADET-UNAM, Dr. Leopoldo Ruiz Huerta y Dr. Alberto Caballero Ruiz, por sus valiosos comentarios y la oportunidad de desarrollar el trabajo de ...[+]
Tipo: Artículo

References

Angeles, J. 2004. The qualitative synthesis of parallel manipulators. Mechanical Design 126(4) pp. 617-624.

Aracil, R., Saltarén, R., Sabater, J. Reinoso, O. 2006. Robots paralelos: máquinas con un pasado para una robótica del futuro. Revista Iberoamericana de Automática e Informática Industrial 3(1) pp. 26-28.

Arakelian, V., Briot, S., Guegan, S., Le Flecher, J. 2005. Design and prototyping of new 4, 5 and 6 degrees of freedom parallel manipulators based on the copying properties of the pantograph linkage. Proceedings of 36th International Symposium on Robotics ISR, Tokyo, Japan. [+]
Angeles, J. 2004. The qualitative synthesis of parallel manipulators. Mechanical Design 126(4) pp. 617-624.

Aracil, R., Saltarén, R., Sabater, J. Reinoso, O. 2006. Robots paralelos: máquinas con un pasado para una robótica del futuro. Revista Iberoamericana de Automática e Informática Industrial 3(1) pp. 26-28.

Arakelian, V., Briot, S., Guegan, S., Le Flecher, J. 2005. Design and prototyping of new 4, 5 and 6 degrees of freedom parallel manipulators based on the copying properties of the pantograph linkage. Proceedings of 36th International Symposium on Robotics ISR, Tokyo, Japan.

Ataka, T. 1999. The experimental microfactory system in japanese national R&D project. R&D Department, Scientific Instruments Division, Seiko Instruments Inc. 36-1.

Beltrami, I., Joseph, C., Clavel, R., Bacher, J.P., Bottinelli, S. 2004. Micro- and nanoelectric-discharge machining. Materials Processing Technology, 149(1-3) pp. 263-265.

Clavel, R. 1988. DELTA, a fast robot with parallel geometry. International Symposium on Industrial Robots. 12-17 Lausanne, pp. 91-100.

Chablat, D., Wenger, Ph. 2003. Architecture optimization of a 3-DOF translational parallel mechanism for machining applications, the orthoglide. IEEE Transactions on Robotics and Automation 19(3) pp. 403-410.

Dario, P., Menciassi, A., Stefanini, C., Accoto, D. 2002. Miniaturization of biomedical micromachines. 2nd. Annual International IEEE- EMBS Special Topic Conference on Micrtechnologies in Medicine & Biology. IEEE. Madison, Wisconsin USA, pp. 291-296.

Dario, P., Valleggi, R., Carrozza, M.C., Montesit M. C., and Coccot M. 1992. Microactuators for microrobots: A critical survey. Micromechanic and Microengineering 2, pp. 141-157.

Denton, M. 2009. Hexapod CNC router strolls into action. Micro manufacturing, http://www.micromanufacturing.com/showthread.php? p=734. accessed: Octubre 2009.

Detter, H., Popovic G. 2000. Industrial demands on micromechanical products. IEEE Proc. 22nd International Conference on Microelectronics, NIS, Serbia, 14-17 May, pp. 61-67.

Dhanorker, A., Özel, T. 2008. Meso-micro scale milling for micro manufacturing. Mechatronics and Manufacturing Systems 1(1) pp. 23-42.

Dornfeld, D., Min, S., Takeuchi, Y. 2006. Recent advances in mechanical micromachining. Manufacturing Technology 55(2) pp. 745-768.

Ehmann, K.F., DeVor, R.E., Kapoor, S.G., Cao, J. 2008. Design and analysis of micro/meso-scale machine tools. Wang, L. and Xi, J. (Eds.) Smart Devices and Machines for Advanced Manufacturing. Springer, pp. 283-318.

Frazier, A.B. 1995. The miniaturization technologies: Past, present, and future. IEEE Transactions on Industrial Electronics 42(5) pp. 423-430.

Fujita, H., Toshiyoshi, H., Hashiguchi, G., Wada, Yasou. 2001. Micromachined tools for nano technology. RIKEN Review. Focused on Science and Technology in Micro/Nano Scale (36) pp. 12-15.

Gogu, G. 2004. Structural synthesis of fully-isotropic translational parallel robots via theory of linear transformations. European Journal of Mechanics A/Solids 23, pp. 1021-1039.

Gogu, G. 2008. Structural synthesis of Parallel Robots, Part 1: Methodology. Springer, Solid Mechanics and its applications Vol. 149. pp. 275.

Gosselin, C., Masouleh, M., Duchaine, V., Richard, P-L., Foucault, S., Kong, X. 2007. Parallel mechanisms of the multipteron family: Kinematic Architectures and Benchmarking. International Conference on Robotics and Automation. IEEE. Roma, Italy, 10-14 April, pp. 555-560.

Gosselin, C.M., Kong, X. 2004. Cartesian parallel manipulators, US Patent No. 6,729,202 B2.

Heikkilä, H.R., Karjalainen, I.T., Uusitalo, J.J., Vuola, A.S., Tuokko, R. O. 2007. Possibilities of a microfactory in the assembly of small part and products-first result of the M4-project. Proceedings of the International Symposium on Assembly and Manufacturing, Ann Arbor, Michigan, USA.

Jang, S.H., Jung, Y.M., Hwang, H.Y., Choi, Y.H., Park, J.K. 2008. Development of a reconfigurable micro machine tool for microfactory. International Conference on Smart Manufacturing Application. KINTEX. Gyeonggi-do, Korea, pp. 190-195.

Jin, Y., Chen, I.M., Yang, G. 2006. Kinematic design of a 6-DOF parallel manipulator with decoupled translation and rotation. IEEE Transactions on Robotics 22(3) pp. 545-551.

Kang, D.S., Seo, T.W., Yoon, Y.H., Shin, B.S., Liu, X-J., Kim, J. 2006 A micro positioning parallel mechanism platform with 100 degree tilting capability. Manufacturing Technology 55(1) pp. 377-380.

Kawahara, N., Suto, T., Hirano, T., Ishikawa, Y., Kitahara, T., Ooyama, N., Ataka T. 1997. Microfactories; new applications for micromachine technology to the manufacture of small products. Microsystem Technologies 3(2) pp. 37-41.

Kong, X., Gosselin, C.M. 2002. Type synthesis of linear translational parallel manipulators. J. Lenarcic, F. Thomas (Eds.), Advances in Robot Kinematics: Theory and Applications, Kluwer Academic Publishers, pp. 453-462.

Kussul, E., Baidyk, T., Ruiz-Huerta, L., Caballero-Ruiz, A., Velasco, G. 2006. Scaling down of microequipment parameters. Precision Engineering 30(2) pp. 211-222.

Kussul, E., Baidyk, T., Ruiz-Huerta, L., Caballero-Ruiz, A., Velasco, G., Kasatkina, I. 2002. Development of micromachine tool prototypes for microfactories. Micromechanics and Microengineering 12(6) pp. 795-812.

Kussul, E., Rachkovskij, D., Baidyk, T., Talayev, S. 1996. Micromechanical engineering: a basis for the low-cost manufacturing of mechanical microdevices using microequipment. Micromechanical and Microengineering 6(4) pp. 410-425.

Kussul, E., Ruiz-Huerta, L., Caballero-Ruiz, A., Kasatkin, A., Kasatkiana, L., Baidyk, T., Velasco, G. 2004. CNC machine tools for low cost micro devices manufacturing. Journal of applied research and technology 2(1) pp. 76-91.

Li, H., Lai, X., Li, C., Lin, Z., Miao, J., Ni, J. 2008. Development of meso-scale milling machine tool and its performance analysis. Frontiers of Mechanical Engineering in China 3(1) pp. 59-65.

Li, X., Wang, J., Li, W. 2007. Current state and prospect of micro- machining. Proceedings of the IEEE International Conference on Automation and Logistics, Jinan, China, pp. 1414-1419.

Li, Y., Bone, G. 2001. Are parallel manipulators more energy efficient? Proceedings of the International Symposium on Computational Intelligence in Robotics and Automation, Alberta, Canada, pp. 41-46.

Liang, Y., Zhaol, Y., Bai Q., Wang, S., Wang, B., Chen, M., Dou, J. 2006. Study on micromachine tools in fabrication of microparts. Proceedings of the 1st IEEE International Conference on Nano/Micro Engineered and Molecular Systems, Zhuhai, China, pp. 856-859.

Mekid, S., Gordon, A., Nicholson, P. 2004. Challenges and rationale in the design of miniaturised machine tool. Proceedings of the 34th International MATADOR Conference at UMIST, Springer, pp. 456-471.

Merlet, J.P. 2006. Parallel Robots. Springer. ISBN-10: 1-4020-4132-2.

Moreno, H., Saltaren, R., Carrera, I., Puglisi, L., Aracil R. 2012. Índices de desempeño de robots manipuladores: una revisión del Estado del Arte. Revista Iberoamericana de Automática e Informática industrial 9(2) pp. 111-122.

Okazaki, Y., Kitahara, T. 2000. Micro-lathe equipped with closed-loop numerical control. 2nd International Workshop on Microfactories. Fribourg Switzerland, Oct 9-10, pp. 87-90.

Okazaki, Y., Mishima, N, and Ashida, K. 2002. Microfactory and micro machine tools. First Kore-Japan Conference on Positioning Technology, pp. 1-6.

Perroud, S., Codourey, A., Mussard Y. 2003. A miniature robot for the microfactory. Switzerland, CSEM Centre Suisse d’Electronique et de Microtechnique.

PI. 2013. Physik Instrumente. Accessed: April 2013, www.physikinstrumente.com/.

Press, W., Teukolsky, S., Vetterling, W., Flannery, B. 2002. Numerical recipes in C, The art of scientific computing. Cambridge University Press.

Rehsteiner, F., Neugebauer, R., Spiewak, S., Wieland, F. 1999. Putting parallel kinematics machines (PKM) to productive work. Manufacturing Technology 48(1) pp. 345-350.

Ruiz, L. 2000. Desarrollo de microtecnología mecánica para aplicaciones de instrumentación. Memoria SOMI XV Congreso Nacional de Instrumentación. Guadalajara, Jalisco México.

Singh, K. 2008. Expect changes when entering ‘micro’ world. Micro Manufacturing 1(1).

Slocum, A.H. 1992. Precision machine design: Macromachine design philosophy and its applicability to the design of micromachines. Proceedings of Micro Electro Mechanical Systems, MEMS ‘92. An Investigation of Micro Structures, Sensors, Actuators, Machines and Robot., Travemunde, Germany, pp. 37-42.

Sparacino, F., Hervé, J. 1993. Synthesis of parallel manipulators using lie-groups Y-star and H-robot. International Workshop on Advanced Robotics, Tsukuba, Japan, November 8-9, pp. 75-80.

Staffetti, E., Bruyninckx, H., De Schutter, J. 2002. On the invariance of manipulability indices. J. Lenarcic, Thomas, F. (Eds.) Advances in Robot Kinematics, Kluwer Academic Publishers, pp. 57-66.

Tanaka, M. 2001. Development of desktop machining microfactory. RIKEN review: Focused on Advances on Micro Mechanical Fabrication Techniques, No. 34, pp. 46-49.

Tlusty, J., Ziegert, J., Ridgeway, S. 1999. Fundamental comparison of the use of serial and parallel kinematics for machines tools. Manufacturing Technology 48(1) pp. 351-356.

Tsai, L.W. 1997. Multi-degree-of-freedom mechanisms for machine tools and the like, US Patent No. 5,656,905.

Tsai, L.W. 1998. Systematic enumeration of parallel manipulator. Technical Research Report. T. R. 98-33, pp. 1-11.

Wang, Y., Zou, H., Zhao, Y., Li, M. 1997. Design and kinematics of a parallel manipulator for manufacturing. Manufacturing Technology 46(1) pp. 297-300.

Wu, Z., Rizk, R., Fauroux, J.C., Gogu, G. 2007. Numerical simulation of parallel robots with decoupled motions and complex structure in a modular design approach. Tichkiewitch, S., Tollenaere, M., Ray, P., (Eds.) Advances in Integrated Design and Manufacturing in Mechanical Engineering II, Springer. Part 3 pp. 129-144.

Yangmin, L., Qingsong, X. 2006. A new approach to the architecture optimization of a general 3-puu translational parallel manipulator. Intelligent & Robotic Systems 46(1) pp. 59-72.

Yoshikawa, T. 1985. Manipulability of robotic mechanism. The International Journal of Robotic Research 4(2) pp. 3-9.

Youssef, H., El-Hofi, H. 2008. Machining technology. Machine tools and operations. CRC Press.

Zanganeh, K., Angeles, J. 1997. Kinematic isotropy and the optimum design of parallel manipulators. Journal of Robotics Research 16(2) pp. 185-197.

Zhang, D. 2009. Parallel robotic machine tools, Springer. ISBN: 978-1-4419-1116-2.

Zhang, D., Xi, F., Mechefske, C.M., Lang, S. 2004. Analysis of parallel kinematic machine with kinetostatic modelling method. Robotics and Computer-Integrated Manufacturing 20(2) pp. 151-165.

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