Threading

There are a variety of threading methods and tools suited to different components, thread profiles, and pitches. Each threading method and tool has its own advantages in certain situations. To help you successfully perform productive and high-quality threading, we have provided the following recommendations and tips.

Initial considerations for threading

These initial considerations will affect the choice of threading method and threading tool as well as how they are applied.

The thread

Consider the following dimensions and quality demands of the thread to be machined:

• External or internal thread?
• Thread profile (e.g., metric, UN)
• Thread pitch
• Right- or left-handed thread?
• Number of thread starts
• Tolerance (profile, position)

The component

After considering the features, look at the component:

• Can the component be securely fixed?
• Is chip evacuation or chip control a critical issue?
• Does the material have good chip-breaking properties?
• Component batch size. Mass production of threads may justify using multi-tooth inserts or an optimized Tailor Made tool to maximize productivity
• Single or multi-thread

The thread form

The thread profile defines the geometry of a thread and includes component diameters (major, pitch, and minor), thread profile angle, pitch, and helix angle. See definitions.

The most common thread forms and profiles are shown below.

Application​	Thread form​	Thread type​	Code
General threads		ISO metric American UN	MM UN
Pipe threads		Whitworth, British Standard(BSPT), American National, Pipe Threads, NPT, NPTF	WH, NT PT, NF
Food and fire		Round DIN 405	RN
Aerospace		MJ UNJ	MJ NJ
Oil and gas		API Rounded API ”V” form 60° API Buttres VAM	RD V38, 40, 50 BU
Motion threads		Trapezoidal/DIN 103 ACME Stub ACME	TR AC SA

Threading methods

Each threading method has its own advantages in certain situations.

Thread turning

• Productive threading method
• Threading of rotating components around the center of rotation
• Covers the largest number of thread profiles
• An easy and well-known threading process
• Provides a good surface finish and thread quality

Thread milling

• Threading of non-rotating components and threads outside the center of rotation on rotating components
• Interrupted cuts offer good chip breaking in all materials
• Low cutting forces make it possible to thread in long overhangs and thin-walled components
• Possible to thread close to a shoulder or bottom, no need for a relief groove
• Enables machining of large workpieces that cannot easily be mounted on a lathe
• Enables machining of large thread diameters with low requirements on power and torque

Tapping

• An easy and well-known threading process
• Productive and economical threading method, especially for smaller threads
• Covers the most common thread profiles
• Suitable for all kind of machine tools, both rotating and non-rotating components
• Good chip control thanks to a wide range of material-specific products
• Easy to thread in deep holes
• Form threading possible
• Provides high-quality threads

Thread whirling

• For long, slender components, e.g., screws
• Creates high-quality threads without bending
• Single-pass threading from stock diameter reduces cycle time
• Accurate threads produced by tilt of whirling ring to the helix angle
• Good chip control enabling more continuous and productive machining
• Requires a machine with thread whirling capabilities