Research Article
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DESIGN OPTIMIZATION of a BRACKET PLATE for an AMMUNITION FEED MECHANISM of a MEDIUM CALIBER CANNON

Year 2022, Issue: 050, 137 - 149, 30.09.2022

Abstract

Topology optimization has been one of the major concerns for mechanical engineers over the years. With increasing utilization of the finite element method, mechanical analyses can be done easily these days and their results are quite reliable. In weapon systems, high loads act on system components. Due to high loads, every component must be designed to operate without any failure. While designing them, attention must be given in order to avoid excessive weights. So, topology optimization is needed in weapon system components. In this study, design with topology optimization of a bracket plate of an ammunition feed mechanism were investigated using the finite element method. By utilizing topology optimization concept, the dimensions, material and the number of mounting holes of the bracket plate of an ammunition feed mechanism were changed to see their effects on the elemental Von-Mises stress and nodal displacement values. The results show that the increase in mounting hole number and the thickness of the material with selecting a material having higher strength properties decreases the elemental Von-Mises stress and nodal displacement values. According to the results, a safer bracket plate for an ammunition feed mechanism was designed to operate in the given working conditions without any failures.

Supporting Institution

ASELSAN A.Ş.

Thanks

In this study, special thanks to Aselsan Inc. for continuous support.

References

  • [1] Herbst, J., (2006), The History of Weapons (1st ed.), Minneapolis: Twenty-First Century Books, 5-7.
  • [2] Williams, G. A. and Gustin, E., (2004), Flying Guns of the Modern Era (1st ed.), Marlborough: The Crowood Press Ltd., 100-120.
  • [3] Williams, G. A., (2003), Rapid Fire: The Development of Automatic Cannon, Heavy Machine Guns and Their Ammunition for Armies, Navies and Air Forces (1st ed.), Marlborough: The Crowood Press Ltd., 50-60.
  • [4] Reddy, J. N., (2019), Introduction to the Finite Element Method (4th ed.), New York: McGraw Hill Education, 1-2.
  • [5] Rao, S. S., (2018), The Finite Element Method in Engineering (6th ed.), Oxford: Butterworth-Heinemann, 3.
  • [6] Babuska, I. and Strouboulis, T., (2001), The Finite Element Method and its Reliability (1st ed.), Oxford: Oxford University Press, 5.
  • [7] Dhatt, G., Touzot, G. and Lefrançois, E., (2012), Finite Element Method (1st ed.), London: ISTE Ltd., Hoboken, NJ: John Wiley and Sons, Inc., 1.
  • [8] Liu, G. R. and Quek, S. S., (2014), The Finite Element Method a Practical Course (2nd ed.), Oxford: Butterworth-Heinemann, 3.
  • [9] Bendsoe, M. P. and Sigmund, O., (2003), Topology Optimization Theory, Methods, and Applications (2nd ed.), Berlin: Springer-Verlag, 1.
  • [10] Zhou, M., Fleury, R., Shyy, Y. K., Thomas, H. and Brennan, J. M., (2002), Progress in topology optimization with manufacturing constraints, 9th AIAA/ISSMO Symposium on Multidisciplinary Analysis and Optimization, AIAA 2002-5614.
  • [11] Jikai, L. and Yongsheng, M., (2016), A survey of manufacturing oriented topology optimization methods, Advances in Engineering Software, 100, 161-175.
Year 2022, Issue: 050, 137 - 149, 30.09.2022

Abstract

References

  • [1] Herbst, J., (2006), The History of Weapons (1st ed.), Minneapolis: Twenty-First Century Books, 5-7.
  • [2] Williams, G. A. and Gustin, E., (2004), Flying Guns of the Modern Era (1st ed.), Marlborough: The Crowood Press Ltd., 100-120.
  • [3] Williams, G. A., (2003), Rapid Fire: The Development of Automatic Cannon, Heavy Machine Guns and Their Ammunition for Armies, Navies and Air Forces (1st ed.), Marlborough: The Crowood Press Ltd., 50-60.
  • [4] Reddy, J. N., (2019), Introduction to the Finite Element Method (4th ed.), New York: McGraw Hill Education, 1-2.
  • [5] Rao, S. S., (2018), The Finite Element Method in Engineering (6th ed.), Oxford: Butterworth-Heinemann, 3.
  • [6] Babuska, I. and Strouboulis, T., (2001), The Finite Element Method and its Reliability (1st ed.), Oxford: Oxford University Press, 5.
  • [7] Dhatt, G., Touzot, G. and Lefrançois, E., (2012), Finite Element Method (1st ed.), London: ISTE Ltd., Hoboken, NJ: John Wiley and Sons, Inc., 1.
  • [8] Liu, G. R. and Quek, S. S., (2014), The Finite Element Method a Practical Course (2nd ed.), Oxford: Butterworth-Heinemann, 3.
  • [9] Bendsoe, M. P. and Sigmund, O., (2003), Topology Optimization Theory, Methods, and Applications (2nd ed.), Berlin: Springer-Verlag, 1.
  • [10] Zhou, M., Fleury, R., Shyy, Y. K., Thomas, H. and Brennan, J. M., (2002), Progress in topology optimization with manufacturing constraints, 9th AIAA/ISSMO Symposium on Multidisciplinary Analysis and Optimization, AIAA 2002-5614.
  • [11] Jikai, L. and Yongsheng, M., (2016), A survey of manufacturing oriented topology optimization methods, Advances in Engineering Software, 100, 161-175.
There are 11 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Research Articles
Authors

Cihan Turan 0000-0003-2849-8368

Hacı Abdullah Taşdemir 0000-0002-2836-5488

Publication Date September 30, 2022
Submission Date July 7, 2022
Published in Issue Year 2022 Issue: 050

Cite

IEEE C. Turan and H. A. Taşdemir, “DESIGN OPTIMIZATION of a BRACKET PLATE for an AMMUNITION FEED MECHANISM of a MEDIUM CALIBER CANNON”, JSR-A, no. 050, pp. 137–149, September 2022.