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Turning GFRP composites with multi-response optimisation using TOPSIS method
https://orcid.org/http://orcid.org/0000-0001-7365-9410
The use of Glass fiber reinforced polymer composite is well known in various mechanical as well as aerospace domain. However, GFRP poses a problem while machining the material owing to issues such as matrix deboning, fiber delamination, pull-out, tool life, and the creation of powder-like particles during the machining process. Present work combines, the Taguchi (T) method with TOPSIS, a multi-criteria optimization model, in order to determine the optimum range of process parameters in order to make machining of GFRP less cumbersome. Material removal rate (MRR) and cutting power (P) were chosen as optimization targets during the turning of GFRP compounds. The machining was performed on an all geared lathe utilising a polycrystalline diamond (PCD) cutting tool insert. To start with, A Taguchi L25 orthogonal matrix was developed using various input process parameters viz. the cutting depth, feed rate, speed, as well as the orientation angle of the work piece. The MRR and Cutting power were assessed at aforementioned input parameters on all geared lathe. The results of the key outcome plot indicate that cutting speed has the most significant influence on both MRR and cutting power. The MRR and the cutting power are both put to the test during the confirmation phase of the procedure. To optimize the machining outputs, an attempt has been made to use TOPSIS in conjunction with the Taguchi approach method for order inclination by comparison to the perfect result.
Turning GFRP composites with multi-response optimisation using TOPSIS method
https://orcid.org/http://orcid.org/0000-0001-7365-9410
The use of Glass fiber reinforced polymer composite is well known in various mechanical as well as aerospace domain. However, GFRP poses a problem while machining the material owing to issues such as matrix deboning, fiber delamination, pull-out, tool life, and the creation of powder-like particles during the machining process. Present work combines, the Taguchi (T) method with TOPSIS, a multi-criteria optimization model, in order to determine the optimum range of process parameters in order to make machining of GFRP less cumbersome. Material removal rate (MRR) and cutting power (P) were chosen as optimization targets during the turning of GFRP compounds. The machining was performed on an all geared lathe utilising a polycrystalline diamond (PCD) cutting tool insert. To start with, A Taguchi L25 orthogonal matrix was developed using various input process parameters viz. the cutting depth, feed rate, speed, as well as the orientation angle of the work piece. The MRR and Cutting power were assessed at aforementioned input parameters on all geared lathe. The results of the key outcome plot indicate that cutting speed has the most significant influence on both MRR and cutting power. The MRR and the cutting power are both put to the test during the confirmation phase of the procedure. To optimize the machining outputs, an attempt has been made to use TOPSIS in conjunction with the Taguchi approach method for order inclination by comparison to the perfect result.
Turning GFRP composites with multi-response optimisation using TOPSIS method
https://orcid.org/http://orcid.org/0000-0001-7365-9410
The use of Glass fiber reinforced polymer composite is well known in various mechanical as well as aerospace domain. However, GFRP poses a problem while machining the material owing to issues such as matrix deboning, fiber delamination, pull-out, tool life, and the creation of powder-like particles during the machining process. Present work combines, the Taguchi (T) method with TOPSIS, a multi-criteria optimization model, in order to determine the optimum range of process parameters in order to make machining of GFRP less cumbersome. Material removal rate (MRR) and cutting power (P) were chosen as optimization targets during the turning of GFRP compounds. The machining was performed on an all geared lathe utilising a polycrystalline diamond (PCD) cutting tool insert. To start with, A Taguchi L25 orthogonal matrix was developed using various input process parameters viz. the cutting depth, feed rate, speed, as well as the orientation angle of the work piece. The MRR and Cutting power were assessed at aforementioned input parameters on all geared lathe. The results of the key outcome plot indicate that cutting speed has the most significant influence on both MRR and cutting power. The MRR and the cutting power are both put to the test during the confirmation phase of the procedure. To optimize the machining outputs, an attempt has been made to use TOPSIS in conjunction with the Taguchi approach method for order inclination by comparison to the perfect result.
Turning GFRP composites with multi-response optimisation using TOPSIS method
Int J Interact Des Manuf
Hussain, Syed Altaf (author) / Panchal, Manoj (author) / Meshram, Kundan (author) / Srinivas, R (author) / Rajak, Upendra (author) / Kumar, Rajan (author) / Gupta, Manish (author)
2025-02-01
13 pages
Article (Journal)
Electronic Resource
English
GFRP composites , Polycrystalline diamond tool insert , Optimization , TOPSIS Engineering , Materials Engineering , Engineering, general , Engineering Design , Mechanical Engineering , Computer-Aided Engineering (CAD, CAE) and Design , Electronics and Microelectronics, Instrumentation , Industrial Design
Turning GFRP composites with multi-response optimisation using TOPSIS method
| Springer Verlag | 2025
| British Library Online Contents | 2018
| British Library Online Contents | 2015