![Using the Taylor equation for tool life and letting n = 0.5 and C= 400, calculate the percentage increase in tool life when the cutting speed is reduced by 50%.a)100%b)No changec)400%d)300%Correct answer Using the Taylor equation for tool life and letting n = 0.5 and C= 400, calculate the percentage increase in tool life when the cutting speed is reduced by 50%.a)100%b)No changec)400%d)300%Correct answer](https://edurev.gumlet.io/ApplicationImages/Temp/dbc2cf1c-ac9d-4041-9592-b309423a780c_lg.jpg?w=360&dpr=2.6)
Using the Taylor equation for tool life and letting n = 0.5 and C= 400, calculate the percentage increase in tool life when the cutting speed is reduced by 50%.a)100%b)No changec)400%d)300%Correct answer
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Failure of cutting tools and tool life Major Causes and Modes of Failure of Cutting Tools Cutting tools generally fail by : i) Mechanical breakage due. - ppt download
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