Fundamentals of Metal Forming Chapter 18 Manufacturing Processes, MET 1311 Dr Simin Nasseri Southern Polytechnic State University (© Fundamentals of Modern Manufacturing; Materials, Processes and Systems, by M. P. Groover)
FUNDAMENTALS OF METAL FORMING Overview of Metal Forming Material Behavior in Metal Forming Temperature in Metal Forming
Metal Forming Large group of manufacturing processes in which plastic deformation is used to change the shape of metal workpieces The tool, usually called a die, applies stresses that exceed the yield strength of the metal The metal takes a shape determined by the geometry of the die
Stresses in Metal Forming Stresses to plastically deform the metal are usually compressive Examples: rolling, forging, extrusion However, some forming processes Stretch the metal (tensile stresses) Others bend the metal (tensile and compressive) Still others apply shear stresses
Material Properties in Metal Forming Desirable material properties: Low yield strength High ductility T Ductility Yield Strength These properties are affected by temperature: Ductility increases and yield strength decreases when work temperature is raised
Basic Types of Deformation Processes Bulk deformation Rolling Forging Extrusion Wire and bar drawing Sheet metalworking Bending Deep drawing Cutting Miscellaneous processes
Bulk Deformation
Bulk Deformation Processes Characterized by significant deformations and massive shape changes "Bulk" refers to workparts with relatively low surface area‑to‑volume ratios Starting work shapes include cylindrical billets and rectangular bars
Rolling The slab is heated in a furnace and rolled between powered rollers until the plate is made with desirable thickness. Figure 18.2 Basic bulk deformation processes: (a) rolling
Forging Forging is the process of forming the metal by impacting and/or squeezing a preheated part between two halves of a die. A succession of dies may be needed to achieve the final shape. Figure 18.2 Basic bulk deformation processes: (b) forging
Extrusion Billets are preheated and forced by a ram through one or more dies to achieve the desired cross-section. The product is long in relation to its cross-sectional dimensions and has a cross section other than that of rod and bar and pipe and tube. Aluminum part Figure 18.2 Basic bulk deformation processes: (c) extrusion
Wire and Bar Drawing Drawing is an operation in which the cross-section of solid rod, wire or tubing is reduced or changed in shape by pulling it through a die. Figure 18.2 Basic bulk deformation processes: (d) drawing
Sheet Metal Working
Sheet Metalworking Forming and related operations performed on metal sheets, strips, and coils High surface area‑to‑volume ratio of starting metal, which distinguishes these from bulk deformation Often called pressworking because presses perform these operations Parts are called stampings Usual tooling: punch and die
Sheet Metal Bending Straining of a metal sheet or plate to take an angle. Figure 18.3 Basic sheet metalworking operations: (a) bending
Deep Drawing Forming of a flat metal sheet into a hollow or concave shape, by stretching the metal. Figure 18.3 Basic sheet metalworking operations: (b) drawing
Shearing of Sheet Metal Shearing operation which cuts the work by using a punch and die. Figure 18.3 Basic sheet metalworking operations: (c) shearing
Test yourself! Name the metal forming process used for each object (bulk deformation or sheet metalworking). sheet metalworking
Test yourself! Name the metal forming process used for each object. sheet metalworking sheet metalworking
Test yourself! Bulk deformation Name the metal forming process used for each object. Bulk deformation
Test yourself! sheet metalworking Name the metal forming process used for each object. sheet metalworking
Test yourself! Forging (Bulk deformation) Name the metal forming process used for each object. Forging (Bulk deformation)
Test yourself! Extrusion (bulk deformation)
Test yourself! Gutter sheet metalworking Bending Deep drawing
Temperature in Metal Forming
Temperature in Metal Forming Any deformation operation can be accomplished with lower forces and power at elevated temperature Three temperature ranges in metal forming: Cold working Warm working Hot working
Temperature in Metal Forming Cold working refers to plastic deformation that occurs usually, but not necessarily, at room temperature. Warm working: as the name implies, is carried out at intermediate temperatures. It is a compromise between cold and hot working. Hot working refers to plastic deformation carried out above the recrystallization temperature.
Temperature in Metal Forming Increasing temperature Melting temperature Room temperature 0.3 Tm 0.5 Tm Tm Above Tm Casting Hot working Cold working Warm Working Recrystallization
Cold Working Performed at room temperature or slightly above Cold Forming is the primary manufacturing operation of the fastener industry. Many cold forming processes are important mass production operations These operations are near net shape or net shape processes (Minimum or no machining usually required)
Advantages of Cold Forming Better accuracy, closer tolerances Better surface finish No heating of work required Cold forming can make tiny, complex precision parts in one machining step. Tolerances of 0.0005 in. are possible.
Disadvantages of Cold Forming Higher forces and power required in the deformation operation Ductility and strain hardening limit the amount of forming that can be done In some cases, metal is simply not ductile enough to be cold worked
Warm Working Performed at temperatures above room temperature but below recrystallization temperature Dividing line between cold working and warm working often expressed in terms of melting point: 0.3Tm, where Tm = melting point (absolute temperature) for metal
Advantages of Warm Working Lower forces and power than in cold working More complex work geometries possible
Hot Working Deformation at temperatures above the recrystallization temperature Capability for substantial plastic deformation of the metal ‑ far more than possible with cold working or warm working Recrystallization temperature = about one‑half of melting point In practice, hot working usually performed somewhat above 0.5Tm (Metal continues to soften as temperature increases above 0.5Tm, enhancing advantage of hot working above this level)
Advantages of Hot Working Workpart shape can be significantly altered Lower forces and power required Metals that usually fracture in cold working can be hot formed
Disadvantages of Hot Working Lower dimensional accuracy Higher total energy required (due to the thermal energy to heat the workpiece) Shorter tool life