Reaming

Compiled 2026-04-04 · 50 chunks, 15 posts · hole-making · finishing · precision · surface-finish · tolerance

Summary

Reaming is a precision hole finishing operation that removes small amounts of material (typically 0.002-0.020") from pre-drilled holes to achieve accurate diameter, improved surface finish, and tight tolerances. Unlike [[drilling]], which creates holes from solid material, or [[boring]], which can correct hole position and straightness, reaming follows the existing hole centerline while refining size and finish. This operation is essential for achieving tolerances tighter than ±0.002" and surface finishes of 30-60 RMS in steel, with specialized PCD reamers achieving as fine as 8 RMS in aluminum.

Speeds and Feeds by Material

Steel (Low-Medium Carbon)

SFM Range: 40-80 SFM for HSS, 100-150 SFM for carbide
Feed Rate: 0.002-0.005 IPT (inches per tooth)
Shop Floor Reality: Forum users consistently run lower than manufacturer specs. For 0.5" HSS reamer in mild steel, actual practice shows 165 RPM (≈22 SFM) with hand feeding on manual mills for best finish.

[[4140-Steel]]

SFM Range: 30-60 SFM for HSS
Feed Rate: 0.001-0.003 IPT
Notes: EN24T (similar to 4140) requires very conservative approach - use plenty of coolant and hand feed on manual lathes

[[304-Stainless]]

SFM Range: 230 SFM for carbide (manufacturer spec), 40-80 SFM typical shop practice
Feed Rate: 0.002 IPT for reaming operation, 0.0007 IPT for spot facing
Real Experience: 303 SS allows higher speeds, but standard 304 benefits from slower approach to prevent work hardening

[[Aluminum-6061]]

SFM Range: 200-400 SFM
Feed Rate: 0.003-0.008 IPT
Finish Challenge: For mirror finish on 0.530" hole, bore to 0.520" then ream at 250 RPM with 0.013 feed. PCD reamers achieve best results.

[[Cast-Iron]]

SFM Range: 60-120 SFM
Feed Rate: 0.003-0.006 IPT
Surface Finish: Expect 50-80 RMS finish

Hole Preparation Guidelines

Stock Removal Limits:

Maximum removal: 0.020" on diameter
Optimal removal: 0.005-0.010" on diameter
Minimum removal: 0.002" (must remove drill marks)

Pre-drill Sizing:

Standard practice: Drill 0.010-0.015" under final size
Deep holes (L/D > 4): Consider boring to 0.002-0.005" under, then ream
Intersecting holes: Always drill main hole first before cross holes

Recommended Tooling

HSS Reamers

Best for: Manual operations, smaller quantities, softer materials
Advantages: Lower cost, can be resharpened easily
Typical life: 8-20 parts in tool steel before replacement needed

Carbide Reamers

Best for: CNC operations, higher volume, consistent finishes
Coatings: TiCN for extended life in steel applications
Example: SCT 406219 for SAE ports (carbide tipped, coated, thru-coolant)

Floating Holders

Critical for: Tight tolerances, CNC operations
Benefit: Compensates for minor spindle misalignment
Recommendation: Essential for tolerances tighter than ±0.001"

Specialized Reamers

Adjustable: For non-standard sizes, custom fits
Shell Reamers: Larger diameters, replaceable cutting sections
Tapered Reamers: Morse taper, custom angles

Common Problems

Poor Surface Finish

Symptoms: Rough walls, visible tool marks, inconsistent diameter Causes:

Insufficient stock removal (not cutting below drill marks)
Too high feed rate or RPM
Dull reamer
Inadequate coolant/lubrication Solutions: Reduce speed, increase feed slightly, ensure adequate stock removal, verify reamer sharpness

[[Chatter-Vibration]]

Symptoms: Audible vibration, poor finish, dimensional variations Causes: Excessive speed, insufficient rigidity, harmonic resonance Solutions: Reduce RPM (try 450 RPM instead of manufacturer's 750 RPM), hand-adjust spindle speed during operation, use shorter/more rigid toolholders

Reamer Breakage

Symptoms: Tool failure, especially during retraction Causes: Excessive feed, material closing on reamer, inadequate clearance Solutions: Never reverse reamer in hole under power, ensure adequate coolant, reduce feed rates, check for proper hole preparation

Size Variations

Symptoms: Holes measuring oversize or inconsistent Causes: Tool wear, deflection, temperature effects, improper setup Solutions: Use floating holders, monitor tool wear patterns, maintain consistent coolant temperature

Shop Floor Tips

Manual Machine Techniques

Hand Feeding: More consistent than power feed for finish quality
RPM Adjustment: Manually adjust spindle speed during operation to find sweet spot and eliminate harmonics
Coolant Flow: High flow rate more important than pressure - 50 PSI adequate with proper orifice sizing

CNC Programming

Approach: Always approach from same direction to eliminate backlash effects
Dwelling: Use brief dwell at full depth for consistent finish
Retraction: Program spindle stop before retraction, optional reverse spindle at 10,000 RPM to clear stringers

Setup Considerations

Workholding: Soft jaws prevent distortion on thin-wall parts
Alignment: Critical for tool life - check spindle tram regularly
Sequence: Complete all drilling operations before any reaming to prevent breakthrough issues

Troubleshooting Workflow

Start Conservative: Begin with 50% of recommended speeds
Increase Gradually: Raise speed until finish degrades, then back off 20%
Feed Adjustment: If chatter persists, try slightly higher feed to increase chip load
Tool Path: For intersecting holes, ensure reamer stays fully engaged or completely clears openings

Material-Specific Tricks

Stainless: Use sharp tools, maintain consistent feed to prevent work hardening
Aluminum: Remove all cutting fluid buildup frequently, consider climb reaming
Tool Steel: Peck if depth exceeds 3x diameter, use sulfurized cutting oil

[[drilling]] — preliminary hole creation before reaming
[[boring]] — alternative for positional accuracy and large size corrections
[[surface-finish-problems]] — diagnosis of reaming finish issues
[[tolerance-fits]] — determining required hole sizes for assemblies
[[toolholder-selection]] — floating vs rigid mounting considerations
[[chatter-vibration]] — eliminating reaming vibration problems
[[work-hardening]] — preventing material hardening in stainless steels