Pengembangan Proses Gerinda Silinder Permukaan Luar

Authors

  • Sony Harbintoro Balai Besar Logam dan Mesin/Metal Industries Development Center (BBLM/MIDC)
  • Agus Sutisna Balai Besar Logam dan Mesin
  • Pujiyanto Pujiyanto Balai Besar Logam dan Mesin
  • Sarip Hidayat Balai Besar Logam dan Mesin
  • Agus Suherman Balai Besar Logam dan Mesin

DOI:

https://doi.org/10.21776/ub.jrm.2020.011.02.14

Keywords:

Abrasive Machining, External Cylindrical Grinding, Lathe Machine, Bird-Cage Strategy

Abstract

The abrasive machining process is called the grinding process using a wheel grinding. The process of abrasive machining is usually in the final stages of making a product or finishing product so that it becomes essential in making products because it determines the final quality of a product. The purpose of this research is to develop the external cylindrical grinding process in column products for one of the components for drilling machines by modifying the grinding process in the lathe machine. The study was conducted using a wheel head of tools sharpening machine that is mounted on a lathe machine. The stages of this research began with the lathe process. Then without removing the product from the lathe, the external surface cylindrical grinding process is carried out so that there is no need to be set up the workpiece because the central inertia axis of the workpiece has one axis with its geometric axis. The measurement results of the external surface cylindrical grinding process are carried out using a bird-cage strategy by dividing the measurement into six segments. From each segment, the data is collected at eight measuring points. Based on the measurement results, in sample no.3 in segments B and D there is an increase in measurement results, that is  Ø 100 + 0.018, but still below the maximum limit of Ø 100 + 0.020.

References

N.C. DERESSE, V. DESPHANDE, dan ISMAIL W.R. TAIFA, “Experimental Investigation of the Effects of Process Parameters on Material Removal Rate Using Taguchi Method in External Cylindrical Grinding Operation,†Engineering Science and Technology, and International Journal, vol. 23, issue 2, pp. 405-420, 2020

F. KLOCKE, S. BARTH, dan P. MATTFELD, “High Performance Grinding,†Procedia CIRP, vol. 46, pp. 266–271, 2016.

D. SIDOROV, S. SAZONOV, dan D. REVENKO, “Building a Dynamic Model of the Internal Cylindri-cal Grinding Process,†Procedia Eng., vol. 150, pp. 400–405, 2016.

J. PANG, C. WU, B. LI, dan Y. ZHOU, “Arc Length Measurement In The Cylindrical,†Procedia Eng .vol. 05023, pp. 1–7, 2016.

P. PEREVERZEV, A. AKINTSEVA, dan M. ALSIGAR, “Improvement of the quality of designed cy-lindrical grinding cycle with traverse feeding based on the use of digital twin options,†Procedia Eng ,vol. 01033, 2018.

DIAN RIDLO PAMUJI, dan NURAINI LUSI, “Optimasi Parameter Proses Bubut Material ST 60 dengan Pendinginan Ramah Lingkungan Menggunakan Metode Taguchi-Grey, Jurnal Rekayasa Mesin, Vol 10. No. 3, Desember, pp. 245–255, 2019.

P. LAJMERT, M. SIKORA, dan D. OSTROWSKI, “A dynamic model of cylindrical plunge grinding process for chatter phenomena investigation,†Procedia Manuf ,vol. 09004, pp. 4–7, 2018.

P. PEREVERZEV, A. AKINTSEVA, dan M. ALSIGAR, “Impact of Metal Removal Features In The Reverse Zones on Shaping of the Machined Surface in the Process of Cylindrical Grinding with Trav-erse Feed,†Procedia Manuf , vol. 01034, 2018.

DWI HADI SULISTYARINI, PUTU HADI SETYARINI, dan AMANDA NUR CAHYAWATI, “Analisis Keandalan Mesin Produksi Tissue Basah†Jurnal Rekayasa Mesin,Vol. 10 No. 1, Mei, pp. 95–104, 2019.

J. LIN dan C. LIN, “Fatigue and Model Analysis of the CNC Cylindrical Grinder,†Procedia Manuf , vol. 04009, pp. 5–7, 2016.

R. V. BRIJ, M. B. R. SRIKANTH, dan R. B. N, “Performance Enhancement of Cylindrical Grinding Process with a Portable Diagnostic System,†Procedia Manuf., vol. 5, pp. 1320–1336, 2016.

T. ROCHIM, Spesifikasi Produk Geometrik - Toleransi geometrik, ISO 1101:2012(E) dan Contoh Teknik Pengukurannya. Bandung: Penerbit ITB, 2016.

B. LINKE, P. HARRIS, dan M. ZHANG, “Development of Desktop Multipurpose Grinding Machine for Educational Purposes,†Procedia Manuf., vol. 1, pp. 740–746, 2015.

L. V SHIPULIN dan A. A. D, “Imitation Model of Forecasting Surface Relief when Forming it During Cylindrical Grinding,†Procedia Eng., vol. 150, pp. 936–941, 2016.

D. JANECKI, J. ZWIERZCHOWSKI, dan L. CEDRO, “A Problem Of Optimal Cylindricity Profile Matching,†Procedia Manuf , vol. 63, no. 3, pp. 771–779, 2015.

S. ADAMCZAK, D. JANECKI, dan K. STĘPIEŃ, “Practical Application Of The Bird-Cage Strategy In Measurements Of Out-Of-Cylindricity,’ XXI IMEKO World Congress : Measurement in Research and Industry August 30 - September 4, 2015, Prague, Czech Republic

J. PANG, B. LI, Y. LIU, dan C. WU, “Heat Flux Distribution Model in the Cylindrical Grinding Contact Area,†Procedia Manuf., vol. 5, pp. 158–169, 2016.

Y. YAN, J. XU, dan M. WIERCIGROCH, “Influence of Workpiece Imbalance on Regenerative and Frictional Grinding Chattersâ€, Procedia IUTAM., Vol. 22, pp 146 -153, 2017.

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Published

2020-08-15

Issue

Vol. 11 No. 2 (2020)

Section

Articles

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