The standard, titled "Design of Transmission Shafting," was established to provide a technical foundation for sizing rotating steel shafts under combined reversed-bending and steady torsional loading. Although officially withdrawn by ASME in 1994 , its methodologies remain a staple in mechanical engineering education and are still utilized by industry bodies like the Conveyor Equipment Manufacturers Association (CEMA) . Overview of ASME B106.1M
d=[16nπSe4(M)2+3(T)2]1/3d equals open bracket the fraction with numerator 16 n and denominator pi cap S sub e end-fraction the square root of 4 open paren cap M close paren squared plus 3 open paren cap T close paren squared end-root close bracket raised to the 1 / 3 power (Where is the safety factor, Secap S sub e is the endurance limit, is bending moment, and is torque) . Current Status and Alternatives ASME B106.1M: Shaft Design Standard | PDF - Scribd
: Written for those skilled in shaft design and stress calculations.
The standard, titled "Design of Transmission Shafting," was established to provide a technical foundation for sizing rotating steel shafts under combined reversed-bending and steady torsional loading. Although officially withdrawn by ASME in 1994 , its methodologies remain a staple in mechanical engineering education and are still utilized by industry bodies like the Conveyor Equipment Manufacturers Association (CEMA) . Overview of ASME B106.1M
d=[16nπSe4(M)2+3(T)2]1/3d equals open bracket the fraction with numerator 16 n and denominator pi cap S sub e end-fraction the square root of 4 open paren cap M close paren squared plus 3 open paren cap T close paren squared end-root close bracket raised to the 1 / 3 power (Where is the safety factor, Secap S sub e is the endurance limit, is bending moment, and is torque) . Current Status and Alternatives ASME B106.1M: Shaft Design Standard | PDF - Scribd
: Written for those skilled in shaft design and stress calculations.