﻿<?xml version="1.0" encoding="utf-8" ?>
<XML>
  <ISCJOURNAL>
    <YEAR>2022</YEAR>
    <VOL>4</VOL>
    <NO>12</NO>
    <MOSALSAL>12</MOSALSAL>
    <PAGE_NO>4</PAGE_NO>
    <ARTICLES>
      <ARTICLE>
        <LANGUAGE_ID>1</LANGUAGE_ID>
        <TitleF/>
        <TitleE>Optimization of the parameters of ultrasonic aided drilling of Al/SiC composite by genetic algorithm</TitleE>
        <URL>https://jourcc.com/index.php/jourcc/article/view/jcc432</URL>
        <DOI>10.52547/jcc.4.3.2</DOI>
        <DOR/>
        <ABSTRACTS>
          <ABSTRACT>
            <LANGUAGE_ID>1</LANGUAGE_ID>
            <CONTENT>The surface quality of the industrial samples is one of the important factors in manufacturing industry, especially in drilling processes. It is well-known that ultrasonic vibrations can help to improve surface roughness and eliminate the pleat in drilled holes. The use of ultrasonic waves in the machining process also increases the dimensional accuracy of the produced pieces. In this study, the effect of few parameters including rotational speed, feed speed and amplitude of the vibration on the roughness of the drilled walls in the process of drilling with the aid of ultrasonic vibration was performed on Al/SiC composite material. Based on the experimental data, the fitness function was designed and modeled and using the genetic algorithm technique, optimal machining variables were obtained to improve the surface finish of the machined work piece. The results showed that by increasing the amplitude of the vibration and the rotational speed of the tool, a smoother surface can be achieved. The results obtained from the genetic algorithm as well as the experiments showed the ability of the genetic algorithm technique to optimize the machining process of the aluminum silicon carbide composite.</CONTENT>
          </ABSTRACT>
        </ABSTRACTS>
        <PAGES>
          <PAGE>
            <FPAGE>145</FPAGE>
            <TPAGE>148</TPAGE>
          </PAGE>
        </PAGES>
        <AUTHORS>
          <AUTHOR>
            <Name/>
            <MidName/>
            <Family/>
            <NameE>Behzad</NameE>
            <MidNameE/>
            <FamilyE>Abbaszadeh</FamilyE>
            <Organizations>
              <Organization>University of Mohaghegh Ardabili</Organization>
            </Organizations>
            <Countries>
              <Country>Iran</Country>
            </Countries>
            <EMAILS>
              <Email>abbaszadeh7676@gmail.com</Email>
            </EMAILS>
          </AUTHOR>
          <AUTHOR>
            <Name/>
            <MidName/>
            <Family/>
            <NameE>Mahdi</NameE>
            <MidNameE/>
            <FamilyE>Eskandarzade</FamilyE>
            <Organizations>
              <Organization>University of Mohaghegh Ardabili</Organization> 
            </Organizations>
            <Countries>
              <Country>Iran</Country>
            </Countries>
            <EMAILS>
              <Email>info@jourcc.com</Email>
            </EMAILS>
          </AUTHOR>
        </AUTHORS>
        <KEYWORDS>
          <KEYWORD>
            <KeyText>Ultrasonic aided machining</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Optimization</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Genetic algorithm</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Surface smoothness</KeyText>
          </KEYWORD>
          <KEYWORD>
            <KeyText>Experimental design</KeyText>
          </KEYWORD>
        </KEYWORDS>
        <PDFFileName>Article2.pdf</PDFFileName>
        <REFRENCES>
          <REFRENCE>
            <REF>[1] Deshmukh, Suhas P., Ramakant Shrivastava, and Chetan M. Thakar. “Machining of composite materials through advance machining process.” Materials Today: Proceedings 52 (2022): 1078-1081.##[2] Srinivasan, S., S. Thirumurugaveerakumar, N. Nagarajan, N. Mohammed Raffic, and K. Ganesh Babu. “A review of optimization techniques in machining of composite materials.” Materials Today: Proceedings 47 (2021): 6811-6814.##[3] Asmael, Mohammed, Babak Safaei, Qasim Zeeshan, Omid Zargar, and Abubakar Abdussalam Nuhu. “Ultrasonic machining of carbon fiber–reinforced plastic composites: a review.” The International Journal of Advanced Manufacturing Technology 113, no. 11 (2021): 3079-3120.##[4] Surappa M. K. (2003) Aluminum matrix composites: Processing and Properties, Sadhana, pp. 319-334,.##[5] Sonmezal B. A., Derel T. and Filizi. H. (1999) Dynamic optimization of multipass milling operation via geometric programming, International journal of machine Tools and Manufacturing 39, 297-320.##[6] Azarhoushang B. and Akbari J. (2007) Ultrasonic-assisted drilling of Inconel 738-LC, InternationalJournal of Machine Tools and Manufacture, 12(1), 1027-1033.##[7] Ic, Y.T. Güler, E.S. Sezer, B. Taş, B.S. and Şahin, H.S. (2021) Multi-objective Optimization of Turning Parameters for SiC-or Al 2 O 3-Reinforced Aluminum Matrix Composites Process Integration and Optimization for Sustainability, 21, 1-15.##[8] Chandra N., Rahman M. and Andrew S.K. (2007) A study on ultrasonic vibration cutting of low alloy steel, Journal of Materials Processing Technology, 11, 192–193.##[9] Zhong Z.W. and Lin G. (2007) Ultrasonic assisted turning of an aluminium-based metal matrix composite reinforced with SiC particles, International Journal of Adv. Manuf. Technol 27,1077–1081.##[10] Kadivar M. A. Yousefi R. Akbari J. Rahi A. and Nikouei S. M. (2012) Burr Size Reduction in Drilling of Al/SiC Metal Matrix Composite by Ultrasonic Assistance, Advanced Materials Research, 410, 279-282.##[11] Yazdi. M. Bakhshi .A. Aslani. A. and Razavi.A. (2010) Optimization of Milling AL6061-T6using Genetic Algoritm, Tenth Conference of manufacturing engineering, Singapore.##[12] Yang W.H. and Tarng Y. S. (1998) Design Optimization of Cutting Parameters for Turning Operations Based on the Taguchi Method, Journal of Materials Processing Technology, 84, 122-129.##[13] Kopac J. Bahor M. and Sokovic M. (2002) Optimal Machining Parameters for Achieving the Desired Surface Roughness in Fne Turning of Cold Pre-formed Steel Workpieces, International Journal of Machine Tools and Manufacture, 42, 707-716.##[14] Chien W.T. and Tsai C.S. (2003) The Investigation on the Prediction of Tool Wear and the Determination of Optimum Cutting Conditions in Machining 17-4PH Stainless Steel, Journal of Materials Processing Technology, 140, 340-345.##[15] Nalbaant, M., Gokkaya, H. and sur, G. (2007) Application oftaguchi Method in the optimization of Cutting parameters for Surface Roughness in Turning, Materials and Design, 28, 1379-1385.##[16] Aslan, E., Camuscu, N. and Birgoren, B. (2007) Design Optimization of Cutting parameters When Turning Hardened AISI 4110 Steel (63 HRC) With AL203+TiCN Mixed Ceramic Tool, Materials and Design, 28, 1618-1622.##[17] Kabil, A. O. Yu, S. U. Kaynak, F. Saruhan, H. and Benafan, O. (2021) Multi-objective Optimization of Cutting Parameters for Machining Process of Ni-Rich NiTiHf High-Temperature Shape Memory Alloy Using Genetic Algorithm, Shape Memory and Superelasticity, 12(1) 1-10.##[18] Muthukrishnana, N.and Davim, P.D. (2009) Optimization of Machining Parameters of AL/SIC-MMC with ANOVA and ANN analysis, Journal of materials processing technology, 209, 225-232.##[19] Kini, M.V. and chincholkar, A.M. (2010) Effect of machining parameters on Roughness and Material Removal Rate in finsh turning of 30 Glass fibre Reinforced Polymer Pipes, Materials and Design, 31, 3590-3598.##[20] Ross P. j. (1998) Taguchi technique for quality engineering،Newyork, McGraw Hill.large.</REF>
          </REFRENCE>
        </REFRENCES>

      </ARTICLE>
    </ARTICLES>
  </ISCJOURNAL>
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