A B C D E F G H I J K L M N O P Q R S T U V W X Y Z All
H, Santhosh
- Modelling and Analysis of The Effect of Plateau Honing Operation on Cylinder Liners
Authors
1 Department of Mechanical Engineering, M S Ramaiah Institute of Technology, Bangalore 560054., IN
Source
Journal of Mines, Metals and Fuels, Vol 70, No 10A (2022), Pagination: 355-362Abstract
Honing is an abrasive procedure that removes material and creates grooves by employing three simultaneous motions of abrasive stones. Because honing is an abrasive operation, predicting the process outcome analytically is challenging. The steep peaks of a surface are eliminated during the plateau honing process, producing a reasonably plateau finish along with cross hatch pattern for retaining oil and increased bearing area. A cylinder liner is installed in an engine block to provide a cylindrical chamber where the piston may move extremely smooth. To obtain a honing pattern and good surface roughness, the machine setting plays an important role which includes many machine parameters like honing force, number of stokes, feed rate, processing time etc. So, in order to obtain an optimal machine set up, multiple trails on cylinder liners are done, which takes more time, and for each trail, one cylinder liner specimen is utilised, which results in the consumption of more cylinder liner solely for trail purposes. In this work, the key parameters effecting the surface roughness of cylinder liner are identified and optimal honing parameters (machine setup) are selected. FEA analysis is carried out to find the effect of pressure on the walls of cylinder liners. Based on the results of experiment, the optimal setting for honing machine is obtained for the selected surface roughness with less ovality and taper and also has less effect on cylinder liners.
Keywords
Plateau Honing Operation, Surface Roughness, Honing Machine, Grid Size of Honing Stick.References
- Sivatte-Adroer, M., Llanas-Parra, X., Buj-Corral, I. and Vivancos-Calvet, J, Indirect model for roughness in rough honing processes based on artificial neural networks, Precision Engineering. 43 (2016) 505-513. https://doi.org/10.1016/j.jmapro.2017.05.016
- K. Prakash Babu, M. B, Determining Optimal Parameters for Surface Roughness of Cylinder Liners During Honing Process by Taguchi Methodology – A Case Study, International Journal of Innovations in Engineering and Technology (IJIET). 8(3) (2017) 7887. http://dx.doi.org/10.21172/ijiet.83.012
- Pankaj S. Chavan, P. M, Effect Of Honing Process Parameters On Surface Quality Of Engine Cylinder, International Journal of Engineering Research & Technology (IJERT). 2(4) (2013, April) 98-107.
- Buj-Corral, I., Vivancos-Calvet, J. and Coba-Salcedo, M, Modelling of surface finish and material removal rate in rough honing, Precision Engineering. 38(1) (2014) 100-108. https://doi.org/10.1016/j.precisioneng.2013.07.009
- Irene Buj-Corral, L. R.-D.-L.-A, Use of results from honing test machines to determine roughness in industrial honing machines, Journal of Manufacturing Processes. 28 (2017) 60-69. https://doi.org/10.1016/ j.jmapro.2017.05.016
- Kim, E. S., Kim, S. M., & Lee, Y. Z, The effect of plateau honing on the friction and wear of cylinder liners, Wear. 400–401 (2017) 207–212. https://doi.org/10.1016/ j.wear.2017.09.028
- K.V. Narasaiah, M. N, Design and Analysis of Dry Cylinder Liner With FEA, International Research Journal of Engineering and Technology (IRJET). 5(6) (2018, June) 616-622.
- Pawlus, P., Cieslak, T. and Mathia, T, The study of cylinder liner plateau honing process, Journal of Materials Processing Technology. 209(20) (2009) 6078– 6086. https://doi.org/10.1016/j.jmatprotec. 2009.04.025
- Pawlus, P., Reizer, R. and Wieczorowski, M, Analysis of surface texture of plateau-honed cylinder liner – A review, Precision Engineering. 72 (2021) 807–822.https://doi.org/10.1016/j.precisioneng.2021.08.001
- Urville, C., Souvignet, T., Dimkovski, Z., & Cabanettes,F, Honing process parameters influence on surfacetopographies, Procedia CIRP. 108 (2022) 448–453.https://doi.org/10.1016/j.procir.2022.03.070
- Development of IoT Based Pneumatic Punching Machine
Authors
1 Department of Mechanical Engineering, M S Ramaiah Institute of Technology, Bangalore 560054., IN
Source
Journal of Mines, Metals and Fuels, Vol 70, No 10A (2022), Pagination: 363-367Abstract
Building effective industrial systems are now possible with the help of the Internet of Things abbreviated as IoT. In nowadays automatic systems are recommended over manual systems. IoT is the latest and rising internet technology. IoT is a developing network of everyday products, from industrial machinery to consumer goods which exchange information and carry out tasks while consumers are attending to other responsibilities. A machine tool is used to punch sheet metals to increase the static stability of the section of the sheet. The movement of the piston in the pneumatic punching machine is from the compressed air which generates high pressure on the piston. The focus of this project is on the development of an IoTenabled sheet metal punching machine. The main objective of this project is to develop an IoT-based pneumatic punching machine that is capable of monitoring the production parameters of the pneumatic punching machine through an easily manageable web interface. Additionally this technology is innovative in that it allows the control of the punching machine through the Internet of Things as well as the tracking of production data or production values.
Keywords
IoT (Internet of Things), Pneumatic Punching Machine, Production Monitoring, Arduino.References
- Nutan Bhalerao, Aishwarya Dhamale, Ashwini Dhamale, Dhananjay Gaikwad Chandrashekhar kols, Design and Fabrication of Pneumatic Punching Machine, International Journal of Emerging Technologies and Innovative Research, Vol.6, Issue 2, 2019, pp.98-101.
- Gwo-Lianq Chern, Shun-Feng Liu, Ying-Jeng Engin Wu, Development of a micro-punching machine and study on influence of vibration machining in micro EDM, Journal of Material Processing Technology, Volume 180, Issues 1–3, 2006, pp. 102-109.
- M. Kumari, R. Singhal, A. Kumar, Design and Analysis of IoT-Based Intelligent Robot for real time Monitoring and Control, International Conference on Power Electronics & IoT Applications in Renewable Energy and its Control, 2020, pp. 549-552.
- Lukas Malburg, Ralph Bergmann, Ronny Seiger, Patrick Klein, Manfred-Peter Rieder, Object Detection for Smart Factory Processes by Machine Learning, Procedia Computer Science, Volume 184, 2021, pp. 581588.
- Lukas Malburg, Manfred-Peter Rieder, Ronny Seiger, Patrick Klein, Ralph Bergmann, Object Detection for Smart Factory Processes by Machine Learning, Procedia Computer Science, Volume 184, 2021, pp. 581588.
- S. Malhão, P. Torres, R. Dionísio, Industrial IoT Smartbox for the Shop Floor, Experiment International Conference, 2019, pp. 258-25.
- Mourtzis, D, Vlachou, A, Milas, N, An Internet of Things-Based Monitoring System for Shop-Floor Control, Comput. Inf. Sci. Eng. 2018.
- Dimitris Mourtzis, Nikos Panopoulos, John Angelopoulos, Design and development of IoT enabled platform for remote monitoring and predictive maintenance of industrial equipment, Procedia Manufacturing, Volume 54, 2021, pp.166-171.
- E.B. Priyanka, Thangavel, C. Maheswari, IoT based field parameters monitoring and control in press shop assembly, Internet of Things, Volumes 3–4, 2018, pp.1-11.
- Ranjeeta Singh, H.K. Verma, Development of a PLC based controller for pneumatic pressing machine in engine bearing manufacturing plant, Procedia Computer Science,Volume 125, 2018, pp. 449-458.
- NG Yen Ting, LOW Jonathan Sze Choong, Tan Yee Shee, Internet of Things for Real-time Waste Monitoring and Benchmarking Waste Reduction in Manufacturing Shop Floor, Procedia CIRP, Volume 61, 2017, pp. 382-386.
- H. G. Sunithkumar, H. Manjunath, Harisha N.Vinayagam, S. K, Design of IoT based smart shop floor-an exploratory case study, International Conference on Energy, Communication, Data Analytics and Soft Computing, 2017, pp. 1231-1237.
- X Wu, L. Zhang, S. Tian and, The Internet of Things Enabled Shop Floor Scheduling and Process Control Method Based on Petri Nets, in IEEE access, vol 7,2019, pp. 27432-27442.
- Ming Yang, smart metal forming with digital process and IoT, International Journal of Lightweight Materials and Manufacture, Volume 1, Issue 4, 2018,pp. 207-214.
- Guoqing Zhang, Tatsushi Nishi, Fawzat Alawneh,Yiqin Yang Xiaoting Shang, Integrated production planning and warehouse storage assignment,International Journal of Production Economics, Volume 234, 2021.