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SWIRL NUMBER MEASUREMENTS USING INTAKE PORTS PRODUCED BY ADDITIVE MANUFACTURING

SWIRL NUMBER MEASUREMENTS USING INTAKE PORTS PRODUCED BY ADDITIVE MANUFACTURING

MARTIOLI, G. F. ; MASSARANI, M. ;

Artigo Completo:

The present work proposes to execute bench test swirl number measurements using a modular device and cylinder head intake ports from a diesel engine manufactured via additive manufacturing (AM). Swirl number measurements with intake ports produced by AM, bring the following advantages: Tests reproducibility, since having the geometric model (CAD) of tested models is enough to re-build the geometry analyzed in the bench test. Easy to measure the swirl number variances in consequence of potential manufacturing process deviations and time reduction to the development of new intake ports geometry. The research is experimental, one sample of the investigated cylinder head was sent to the Polytechnic School of Sao Paulo (EPUSP) laboratory, and the swirl number was measured and recorded for later results comparison with proposed method. This cylinder head sample was then sectioned and digitalized as to know to have the same internal geometry in the intake ports produced via AM. All tests were performed in the same rig and with the same control system aiming to reduce the external variables during data acquisition. When the swirl number results between the complete cylinder head and modular device using AM were compared, no statistically significant changes were found.

Artigo Completo:

The present work proposes to execute bench test swirl number measurements using a modular device and cylinder head intake ports from a diesel engine manufactured via additive manufacturing (AM). Swirl number measurements with intake ports produced by AM, bring the following advantages: Tests reproducibility, since having the geometric model (CAD) of tested models is enough to re-build the geometry analyzed in the bench test. Easy to measure the swirl number variances in consequence of potential manufacturing process deviations and time reduction to the development of new intake ports geometry. The research is experimental, one sample of the investigated cylinder head was sent to the Polytechnic School of Sao Paulo (EPUSP) laboratory, and the swirl number was measured and recorded for later results comparison with proposed method. This cylinder head sample was then sectioned and digitalized as to know to have the same internal geometry in the intake ports produced via AM. All tests were performed in the same rig and with the same control system aiming to reduce the external variables during data acquisition. When the swirl number results between the complete cylinder head and modular device using AM were compared, no statistically significant changes were found.

Palavras-chave: swirl number measurements,

Palavras-chave:

DOI: 10.5151/engpro-simea2017-18

Referências bibliográficas
  • [1] INTERNATIONAL ENERGY AGENCY. Excerpt from CO2 emissions from fuel combustion. 2016.
  • [2] DE STEFANO, M. C.; MONTES-SANCHO, M. J.; BUSCH, T. A natural resourcebased view of climate change: Innovation challenges in the automobile industry. Journal of Cleaner Production v.139, p. 1436-1448, 2016.
  • [3] SÖDER, M., Creation and destruction of in-cylinder flows; Large eddy simulations of the intake and the compression strokes. 2015. Thesis (Doctoral) – Mechanical Engineering, KTH Royal Institute of Technology, Stockholm.
  • [4] BRUNETTI, F. Motores de Combustão Interna. Vol. 1. São Paulo: Blucher, 2012.
  • [5] HEYWOOD, J. B. Internal Combustion Engine Fundamentals. McGraw-Hill, 1988. [6] PULKRABEK, W. W. Engineering fundamentals of the internal combustion engine. Prentice Hall – Upper Saddle River, 1997.
  • [6] [7] VANHAELST, R.; CZAJKA, J. Development of an optical sensor for determination of swirl level in diesel engines.2nd Conference on Engine Processes Proceedings, Jul/2015, Berlin.
  • [7] [8] CASTILLA, A.; FERNÁNDEZ, J.; MONTANERO, J.M. Influence of the manufacturing process tolerance on the swirl number of a low-capacity engine. Journal of Manufacturing Systems, v. 41, p. 157–164, 2016.
  • [8] [9] LU, Z.; WANG, T.; LIU, S.; LIN, Z.;HAN, Y. Experimental and modeling study of the effect of manufacturing deviations on the flow characteristics of tangential intake port in a diesel engine. Journal of Engineering for Gas Turbines and Power 2014, v.136/112101.
  • [9] [10] ASTM. ASTM F2792–10 standard terminology for additive manufacturing Technologies.
  • [10] [11] GUO, N.; LEU, M.C. Additive manufacturing: technology, applications and research needs. Front. Mech. Eng. 8(3): 215–243, 2013.
  • [11] [12] BOGUE, R. 3D printing: the dawn of a new era in manufacturing? Assembly Automation, Vol. 33 Iss 4 pp. 307 -311, 2013.
  • [12] [13] GÜNTHER, D. et al. Continuous 3D-printing for additive manufacturing. Rapid Prototyping Journal, Vol. 20 Iss 4 pp. 320 – 327, 2014.
  • [13] [14] PITCHER, G. et.al. LDA and PIV Analysis and Comparison of In-Cylinder Flow Structures under Steady Flow Conditions. 15th Int. Symp on Application of Laser Techniques to Fluid Mechanics, Lisbon, 2010.
  • [14] [15] FERGUSON, C.R.; KIRKPATRICK, A.T., Internal combustion engines: applied thermodynamics. John Wiley & Sons, Inc., 2001.
  • [15] [16] PASTOR, J.V.; MARGOT, X.; GIL, A.; DONAYRE, J.C. A methodology to estimate the swirl number at TDC in DI diesel engines: through the combination of CFD and steady flow rig results. SAE Technical Paper 2004-01-1876, 2004.
  • [16] [17] STONE, C. R.; LADOMMATOS. The Measurement and Analysis of Swirl in Steady Flow. SAE paper No. 921642, 1992.
  • [17] [18] FORTE, C. et. al. Numerical Evaluation of the Applicability of Steady Test Bench Swirl Ratios to Diesel Engine Dynamic Conditions. 69th Conference of the Italian Thermal Engineering Association, ATI 2014.
  • [18] [19] SWIFT, K. G.; BOOKER, J. D. Process Selection: from design to manufacture. 2 ed. Oxford: Butterworth-Heinemann, 2003.
  • [19] [20] GALETA, T.; ŠIMUNOVIĆ, G.; MAZUREK, M. Impact of strengthening fluids on roughness of 3D printed models. Metallurgy, v. 54, p. 231-234, 2015.
  • [20] [21] LFS. Available in: . Last access: 2017/05/24
  • [21] [22] CCI-MP. Available in: . Last access: 2017/05/24
  • [22] [23] MARTIOLI, G. F. Medição do número de swirl utilizando dutos de admissão do cabeçote de um motor diesel produzidos via prototipagem rápida. 2017. Dissertation (Master’s degree) - Mechanical Engineering: Automotive Engineering Centre, EPUSP, São Paulo.
  • [23] [24] COSTA NETO, P. L. O. Estatística, 2 ed. São Paulo: Edgard Blücher, 2002
  • [24] [25] Available in: . Last access: 2017/05/24
  • [25] [26] IBM Corp. Released 2011. IBM SPSS Statistics for Windows, Version 20.0. Armonk, Nova Iorque: IBM Corp.
Como citar:

MARTIOLI, G. F.; MASSARANI, M.; "SWIRL NUMBER MEASUREMENTS USING INTAKE PORTS PRODUCED BY ADDITIVE MANUFACTURING", p. 235-251 . In: . São Paulo: Blucher, 2017.
ISSN 2357-7592, DOI 10.5151/engpro-simea2017-18

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