Advanced Lathe Techniques
Tool geometry, parting off, chuck types, back rake angles, follower rests, and cutting speed optimization.
- Explain tool geometry including rake and relief angles
- Describe parting off procedures and common problems
- Identify chuck types and workholding methods
- Calculate cutting speeds for ACME thread operations
Lesson 1
Tool Geometry & Rake Angles
Cutting Tool Angles
The performance of a lathe cutting tool depends on its geometry. The key angles are:
- Back rake angle - the angle of the tool face measured from the top. Positive back rake produces a shearing action that reduces cutting force and heat
- Side rake angle - the angle of the tool face measured from the side. Directs chip flow away from the workpiece
- End relief angle - clearance between the tool end and the workpiece. Prevents rubbing
- Side relief angle - clearance between the tool side and the workpiece
Rake Angle Effects
Positive Rake
Action: Shearing - low cutting force
Finish: Better surface quality
Best for: Ductile materials (steel, aluminum)
Weakness: Weaker cutting edge
Zero Rake
Action: Neutral - moderate force
Finish: Good
Best for: Brass, bronze (prevents grabbing)
Note: Standard for cast iron
Negative Rake
Action: Compression - high force
Finish: Rougher
Best for: Hardened steel, interrupted cuts
Strength: Strongest cutting edge
Exam Tip - Brass and Zero Rake
When the exam asks about machining brass or bronze, the correct tool has zero (0-degree) rake. Positive rake causes brass to grab and dig in. Zero rake prevents this by eliminating the shearing action.
Use positive rake for ductile materials like steel and aluminum. Use zero rake for brass and bronze to prevent grabbing. Negative rake provides the strongest edge for hard materials and interrupted cuts.