Cold Extrusion of Steel: Part One

---

Introduction to Cold Extrusion

Extrusion, while one of today's most significant manufacturing processes, remains a relatively recent development in metalworking history. The cold extrusion process involves forcing a billet of material through a die at room or slightly elevated temperatures, producing a continuous product with constant cross-section. This versatile technique accommodates numerous metals including lead, tin, aluminum alloys, copper, titanium, molybdenum, vanadium, and steel.

Applications and Benefits

Cold extrusion enables the production of diverse components such as collapsible tubes, aluminum cans, cylinders, and gear blanks. Parts produced through cold extrusion remain free from oxidation and typically exhibit enhanced mechanical properties due to severe cold working, provided the billet temperature stays below the material's recrystallization point.

Cold Extrusion Technology

Cold extrusion technology allows manufacturers to form parts to precise dimensions by manipulating metal at room temperature into specially designed dies. The process requires sufficient force to exceed the yield strength of materials like stainless steel, ensuring plastic deformation occurs and enabling the metal to completely fill die cavities with extremely tight tolerances.

Primary Cold Extrusion Methods

Although numerous variations exist in cold extrusion operations, all are fundamentally based on three principal approaches:

Forward Extrusion

Forward extrusion forces metal to flow in the same direction as the descending punch and through an opening in the die to create the required shape and dimensions. This method proves especially valuable for manufacturing bolts, screws, stepped shafts, and cylindrical components.

Backward Extrusion

In backward extrusion, metal is forced to flow upwards, surrounding the descending punch. This method typically requires higher extrusion pressures, and proper slug preparation becomes more critical to successful outcomes.

Upsetting

Upsetting involves gathering metal in specific sections along the length of a bar, rod, or wire. During this process, metal flows perpendicular to the motion of the tooling. Manufacturers frequently perform upsetting in conjunction with backward or forward extrusion techniques to achieve complex geometries.

Figure 1: a) Forward extrusion b) Backward extrusion c) Upsetting

Design Considerations

Successful cold extrusion implementation requires careful attention to component design principles that accommodate material flow characteristics and tooling constraints.

Figure 2: Multiple examples of cold extrusion design possibilities showing various component configurations