Home
Back
Torque To Axial Force Formula:
| From: | To: |
The Torque To Axial Force formula calculates the axial force generated from applied torque, taking into account the torque coefficient and diameter. This is particularly useful in mechanical engineering applications involving fasteners and rotational systems.
The calculator uses the Torque To Axial Force formula:
Where:
Explanation: The formula converts rotational torque into linear axial force based on the mechanical advantage provided by the diameter and the efficiency represented by the torque coefficient.
Details: Accurate axial force calculation is crucial for proper fastener tensioning, structural integrity analysis, and ensuring mechanical systems operate within safe load limits.
Tips: Enter torque in lb-in, torque coefficient as a decimal value, and diameter in inches. All values must be valid positive numbers.
Q1: What is a typical torque coefficient value?
A: Torque coefficients typically range from 0.15 to 0.30 for most standard fasteners, but can vary based on material and surface conditions.
Q2: Why is diameter important in this calculation?
A: Diameter affects the mechanical advantage - larger diameters require less force to achieve the same torque, and vice versa.
Q3: Can this formula be used for metric units?
A: Yes, but all units must be consistent (e.g., N·m for torque, mm for diameter, and N for force).
Q4: What factors affect the torque coefficient?
A: Surface finish, lubrication, thread pitch, material properties, and installation speed can all influence the torque coefficient.
Q5: Is this formula applicable to all types of fasteners?
A: While the basic principle applies to most threaded fasteners, specific applications may require adjustments for thread type, pitch, and other geometric factors.