CHAPTER 7 SUMMARY AND RECOMMENDATIONS
7.2 RECOMMENDATIONS
This research establishes some of the ways of performing the predictive modeling of cryogenic machining and the use of FEM simulations to analyze the performance of micropatterned tool. Furthermore, it also presented the potentialities to improve machining efficiency by improving the tool-life. This research process is available to the material based slip-system for plasticity.
Prediction modeling
Cryogenic cooling Micropatterned
cutting tool
FEM simulation Hard turning
Experiment
117
Although this investigation was limited to hard turning process, but the same methodology can be extended to include other complex machining operations such as drilling, milling, grinding etc.
Initially, the influence of cryogenic coolant and micropatterned tool was studied individually.
In later part of the work, the effect of using micropatterned tool as well as cryogenic coolant simultaneously on hard turning was also investigated. This work can be further extended to understand its effect under various coated tool surfaces and also for various flow rate of cryogenic coolant. From the industrial point of view, economic feasibility of this process should also be investigated. Since the cryogenic machining is expensive as compared to conventional machining processes, hence its usage quantity can be optimized to make the process more economical.
Furthermore, there is a need to establish the chip adhesion modeling. From mass production point of view, the efficiency of fabricating micropatterned cutting tool more economically, should be studied.
The effect of different lubrication strategies on micropatterned cutting tool can also be investigated.
118
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