American Journal of Mechanics and Applications
Volume 7, Issue 3, September 2019, Pages: 49-55
Received: Jul. 24, 2019;
Accepted: Sep. 25, 2019;
Published: Oct. 23, 2019
Views 351 Downloads 108
Adam Ruszaj, Institute of Production Engineering, Cracow University of Technology, Cracow, Poland; Institute of Technology, State University of Applied Sciences, Nowy Sącz, Poland
Mariusz Cygnar, Institute of Technology, State University of Applied Sciences, Nowy Sącz, Poland
Grzegorz Budzik, Department Machine Construction, Rzeszów University of Technology, Rzeszów, Poland
Any machine-tool or manufacturing process designed by engineers is not as excellent as plants, animals or processes occurring in natural surroundings, which have been designed by The NATURE in evolution process. The bridge between solutions occurring in natural surroundings and technique create the BIONIC. The bionic (from Greece words “bios – life” and “mimesis – to mimic”) is an interdisciplinary science which investigated alive organisms, materials and processes occurring in the natural surroundings in order to apply results in technical solutions. The bionic achievements have been applied in many branches of technique. Nowadays it is very important to start the intensive research on bio-inspired applications in the area of production engineering. However it is not optimistic that there are many factories and engineers who don’t apply bio-inspirations in their professional activities. The results of investigations presented in this paper can encourage for wider applications of bioinspirations in engineering. So, in the paper there are presented general informations about methodology of bio-inspired design. Then, the practical application and results are presented. The special attention is payed for bio-improvements in manufacturing systems, mechanical parts shape and inside structure designing, special properties of surface layer creation and innovations in drilling and grinding operations. The general idea of the paper is to generate some kind of braking down in the classical view on engineering and manufacturing processes further development.
Biological Inspirations in Details Construction and Manufacturing Processes, American Journal of Mechanics and Applications.
Vol. 7, No. 3,
2019, pp. 49-55.
Lothar W. Isenmann R., Moehrle M. G. Bionic in patents – semantic – based analysis for exploitation of bionic principles in patents. Procedia Engineering 2011; 620-632-9.
Luriie Luke E., Product and technology innovation: What can biomimicry inspire. Biotechnology Advances 2014; 1494-1505-32.
Shu L. H., Ueda K., Chiu I., Cheong H. Biologically inspired design. CIRP – Annals – Manufacturing Technology 2011 673-693-60.
Ruszaj A. Bionic impact on industrial production development. Advancess in Manufacturing Science and Technology 2015 Vol 39 No 4 p. 5-22.
Zhao L., Ma J., Wang T., Xing D., Lighweight designe of mechanical structures based on structural bionic methodology 2010 p. 224-231-Suppl. 7.
Zhao L., Ma J., Chen W., Guo H. Lightweight design and veryfication of gantry machining center crossbeam based on structural bionic. Journal of Bionic Engineering 2011 p. 201-206-8.
Zhao L., Chen W., Ma J., Yang Y. Structural bionic design and experimental veryfication of a machine tool column. Journal of Bionic Engineering 2008 p. 46-52-Suppl.
Li M., Chen D., Zhang S., Tong J. Biommimetic design of a stubble cutting disc using finite element analysis. Journal of Bionic Engineering 2013 p. 118-127-10.
Jia H., Li Ch., Zhang Z., Wang G., Design of bionic saw blade for corn stalk cutting. Journal of Bionic Engineering. 2013 p. 497-505-10.
Kovalev I. The functional role of hollow region of the butterfly *Pyrameis atlanta (L) scale. Journal of Bionic Engineering 2008 p. 224-230-5.
Kovalev I. From butterfly to wind turbine. Wind Engineering 2010, Vol. 34 No 4 p. 351-360.
Chen Z., Lu S., Song X., Zhang H., Yang W., Zhou H. Effect of bionic units on the fatigue wear of gray iron surface with different shapes and distributions. Optics &Laser Technology 2015 p. 166-174-66.
Lu J., Yang Ch., Zhang L., Feng A., Jang Y. Mechanical properties and microstructure of bionic non-smooth stainless steel surface by laser multiple processing. Journal of Bionic Engineering 2009 p. 180-185-6.
Emmelmann C., Sande P., Kranz J., Wycisk E. Laser additive manufacturing and bionics: Redefining lightweight design. Physics Procedia. 2011p. 364-368-12.
Linke B. S., Moreno J. New concept for bio-inspired grinding. Journal of Manufacturing Processes 2015 p. 73-80-19.
Gau K., Sun Y-H., Ren LQ., Cao P-L., Li W-T., Fan H-K. Design and analysis of temary coupling bionic bits. Journal of Bionic Engineering 2008 p. 53-59-Suppl.
Gao Y., Ellery A., Jaddou M., Vincent J., Ecklersley S. Planetary micro-penetrator concept study with biomimetic drill and sampler design. IEEE Transactions on Aerospace and Electronic Systems 2007 Vol. 43 No 3 p. 875-885.
Nakamura T., Kato To., IwanagaT., MuranakaY. Development of peristaltic crawling robot based on eartworm locomotion. Journal of Robotics and Mechatronics 2006 Vol. 18 No 3 p. 299-300.
Li G., Li W., Zhang J., Zhang H. Analysis and design of asymetric oscilation for caterpilar – like locomotion. Journal of Bionic Engineering 2015 p. 190-203-12.
Xu K., Zeng Y., Li P., Zhu D., Study of surface roughness in wire electrochemical micromachining. Journal of Materials Processing Technology 2015 p. 103-109-222.
Zeng Y., Yu Q., Fang X., Xu K., Li H., Qu H. Wire electrochemical machining with monodirectional travelling wire. International Journal of Adv Manuf Technol-published online 07. 01. 2015.
Oczoś K. E., Kawalec A., Kształtowanie metali lekkich, Wydawnictwa Naukowe PWN 2012.
G. Eason, B. Noble, and I. N. Sneddon, “On certain integrals of Lipschitz-Hankel type involving products of Bessel functions,” Phil. Trans. Roy. Soc. London, vol. A247, pp. 529–551, April 1955. (references).
J. Clerk Maxwell, A Treatise on Electricity and Magnetism, 3rd ed., vol. 2. Oxford: Clarendon, 1892, pp. 68–73.
I. S. Jacobs and C. P. Bean, “Fine particles, thin films and exchange anisotropy,” in Magnetism, vol. III, G. T. Rado and H. Suhl, Eds. New York: Academic, 1963, pp. 271–350.
K. Elissa, “Title of paper if known,” unpublished.
R. Nicole, “Title of paper with only first word capitalized,” J. Name Stand. Abbrev., in press.
Y. Yorozu, M. Hirano, K. Oka, and Y. Tagawa, “Electron spectroscopy studies on magneto-optical media and plastic substrate interface,” IEEE Transl. J. Magn. Japan, vol. 2, pp. 740–741, August 1987 [Digests 9th Annual Conf. Magnetics Japan, p. 301, 1982].
M. Young, The Technical Writer's Handbook. Mill Valley, CA: University Science, 198.
Krejcie, R. V. and D. W. Morgan (1970) Determining Sample Sizes for Research Activities. Educational and Psychological Measurement 30, 607-610.
Kass, R. E. and A. E. Raftery (1995). Bayes Factors. Journal of the American Statistical Association 90, 773–794.
Spiegelhalter, D. J., N. G. Best, B. P. Carlin, and A. van der Linde (2002). Bayesian Measures of Model Complexity and Fit (with discussion). Journal of the Royal Statistical Society: Series B 64, 583–639.
Ebenebe, C. I., Anigbogu, C. C., Anizoba, M. A. and Ufele, A. N. (2013). Effect of various levels of Moringa Leaf Meal on the Egg Quality of Isa Brown Breed of Layers. Advances in Life Sciences and Technology 14: 45-49.
Fahey, J. W., Zakmann, A. T., and Talalay, P. (2001). The chemical diversity and distribution of glucosinolates and Isothiocyanates among plants. Corrigendum Phytochemistry, 59: 200-237.
Greg, M. E. (2008). Effect of enzymes on cellulose, European Journal of Applied Microbiology Biotechnology, 40: 167-171.
Onunkwo, D. N and George, O. S (2015). Effects of Moringaoleifera leaf meal on the growth performance and carcass characteristics of broiler birds. IOSR Journal of Agriculture and Veterinary Science, 8 (3II): 63-66.
El Tazi, S. M. A. (2014). Effect of feeding different levels of Moringaoleifera leaf meal on the performance and carcass quality of broiler chicks. International Journal of Science and Research, 3 (5): 147-151.