1. MAE Course 3344 Lecture 8 Sheet Metal Shaping and Forming
Professor John J. Mills
Mechanical and Aerospace Engineering
The University of Texas at Arlington
This lecture covers material describing how sheet metal is shaped and formed.
It covers chapter 16 of Kalpakjian
Professor John J. Mills: Tel (817)

2. Material Transformation Processes
Assembly
SLS
Powders
Special
Pressing
Firing/
Sintering
Injection
Molding
Stamping
Sheet metal
forming
Raw Material
Continuous
Casting/Rolling
Rolling
Forging/
Press forming
Finishing
Ingot
casting
Molten
Material
Extruding
This figure is the overview with the topic highlighted by light blue rectangle with rounded corners
Casting
Shapes
Machining
Single crystal
pulling
Blow
molding
Current lecture
Increasing level of detail
Professor John J. Mills: Tel (817)

3. Overview of Sheet Metal Forming
Shearing to make blanks
Fundamentals of forming sheet metal
These are the topics covered in this lecture. Items highlighted in red have links the appropriate pages. To activate you need to be in slide show mode or on the browser
Professor John J. Mills: Tel (817)

4. Sheet Metal Forming History
Very old process - back to 5000 BC
Original sheet obtained by hammering over a stone anvil
Cut to shape with a knife
Formed over stone or wooden dies by hammering
Now sheet produced by sheet mills
Cutting to shape and forming is by machines
Sheet metal forming is concerned with the cutting and forming of relatively thin sheet. Large plates with a small value of the ratio of thickness to any other dimension are what is meant by "sheet". Sheet is formed by rolling which is described in lecture 3
Professor John J. Mills: Tel (817)

5. General Practices Most common commercial material is carbon steel
Most common aircraft and aerospace materials are aluminum and titanium
Aluminum increasingly found in automobiles
Sheet metal forming consists of three basic processes;
Cutting to form a shape (blank)
Forming by bending and stretching
Finishing
Professor John J. Mills: Tel (817)

6. Sheet Metal Forming Processes
Punching
Blanking
Fine Blanking
Stamping
Embossing
Shearing
Slitting
Cutting
Sawing
Deburring
Cleaning
Coating
Sheet, Plate
Blank
Bending
Roll forming
Stretch forming
Deep drawing
Rubber forming
Spinning
Peen forming
Superplastic forming
Explosive forming
Magnetic pulse forming
This illustrates the overall process. Sheet is cut up by various processes into blanks and then formed by bending stretching etc into shapes. Blanks can also be shapes stamped out by punches and dies and used without further forming. Finishing is an important part of sheet metal forming because the cut edges often have to have their sharp edges removed - a process known as deburring.
Making blanks
forming
finishing
Professor John J. Mills: Tel (817)

7. Sheet Metal Advantages and Disadvantages
light weight,
versatile shapes,
low cost
Disadvantages
tooling costs (for high production runs)
sheet metal may not be appropriate to design function
This lists the advantages and disadvantages of sheet metal for use in products
Professor John J. Mills: Tel (817)

8. Shearing Needed to cut rough blanks from the large sheets
A blank is the term for the rough shape needed to form the final part
Rectangular blanks created by shears, saws, rotary cutters
These blanks can
be further sheared into more complex shapes
be further formed (bent, deep drawn, etc) into more complex shapes
also be the final product
Shearing is the basic process by which all sheet is cut. Shearing can be carried out by a pair of manual shears, linear shearing equipment (which is essentially a giant pair of scissors) or shaped punches and dies. The basic process is the same, the resulting shape differs. The term "shearing," however, is usually employed to describe linear cutting. Cutting of complex shape with shaped punches and dies is called stamping.
Professor John J. Mills: Tel (817)

9. The Basic Shearing Process
Like cutting paper with scissors but using a machine
Shearing starts with cracks developed on top and bottom of sheet by exceptionally high shear stresses
A fracture process
The Punch is typically the moving part
The Die is the stationary part.
The basic shearing process is essentially one of fracture. For small clearances between the punch and the die, the fracture occurs almost instantaneous with the first impact of the punch on the material. If the gap is larger, but still smaller than the thickness of the sheet, the material is substantially deformed before fracture occurs. If the clearance is only slightly smaller than the thickness `the material may not shear at all but be drawn down with the punch. This is the basis of deep drawing a process discussed later. Shearing always results in two parts (except for slitting and lancing, see later). The part which is wanted is the blank. The other is scrap.
Professor John J. Mills: Tel (817)

10. The Basic Shearing Process Results
Typically creates rough fracture surfaces
Smoothing of this surface occurs by rubbing on the shear blades or the die
Shears, the machine for cutting metal can operate up to thickness of several inches
Professor John J. Mills: Tel (817)

11. Effect of die clearance on deformation zone
Smaller the clearance, the better the edge
This figures shows how with small clearances, fracture occurs almost immediate upon contact of the punch with the material, where as with large clearances, material is pulled into the gap. The pulling of material into the gap is used in the ironing process (a drawing process) discussed later
Professor John J. Mills: Tel (817)

12. Simple Shearing Advantages and Disadvantages
Minimal tooling
Stops for dimensions
Disadvantages
Only simple shapes (rectangles)
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13. Shearing Operations for more complex shapes
Punching
More complex shapes than simple shearing
Made by punch and die set
Internal part (slug) discarded
Blanking
Same basic process as Punching but
Internal part (slug) retained
Fine blanking - a specialized kind of blanking
Other operations include
Parting Stamping Notching Embossing
Lancing Perforating Slitting Nibbling
Shaving Steel rules (soft materials only)
There are a variety of shearing operations. Punching essentially creates a hole in the required part, whereas blanking creates the required part. The others do various things as illustrated on page 448 of kalpakjian.
Professor John J. Mills: Tel (817)

14. Other shearing processes
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15. Punching Circular blanks created by punch and die Punch Workpiece Die
The circle is a view looking down on the punch and die. To create flat blanks, a flat die as illustrated is required. Shaped dies to reduce punching force gives deformed blanks.
Workpiece
Die
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16. A Punched Hole
This figure shows an enlarge cross-section of the hole in the workpiece. The rollover depth can be almost invisible. And the fracture edge can be burnished or polished by the punch and die set.
Professor John J. Mills: Tel (817)

17. Process variables in shearing with a punch and die and punch force
F = 0.7 T L (UTS)
where
F force
T workpiece thickness
L total sheared length (the circumference in this case)
UTS Ultimate tensile strength of workpiece material
This illustrates a typical cylindrical punch and die and movement of the material under the shearing forces. It also provides and equation for the punch force required.
Professor John J. Mills: Tel (817)

18. Major Processing Factors in Shearing Die Design
Punch shape
Bevel
Reduces shear forces and noise
Double bevel
Reduces lateral forces of bevel shear
Convex shear
All produce at least one part (e.g. the blank) which is bent.
If a shaped punch were perfectly flat the impact of the punch on the material being stamped will be large and any misalignment of the punch with the die could be disastrous, resulting in major damage to the punch or the die. Most punches have convex or concave edges to spread the cutting force out and to help with alignment of the punch and die. Note that these shapes all induce bending in one either the blank or the scrap. The amount of bending depends on the size of the part and the bevel angle . The trick is to make sure that the bent part is always scrap (the slug, see later), or expensive operations will be needed to straighten up the blank. To create flat blanks, we must use a flat punch
Professor John J. Mills: Tel (817)

19. The Blank
This illustrates the bending that occurs as mentioned earlier. The amount of dishing depends on a number of parameters, including the shape of the punch, the diameter of the punch, the thickness of the material. This figure is for a flat die.
Professor John J. Mills: Tel (817)

20. Major Processing Factors in Shearing
Independent parameters
Dependent parameters
Punch and Die
Shape
Material
Clearance between punch and die
Increased clearance
Workpiece ductility and thickness
Increased ductility
Decreased thickness
Dulled tools
Speed of punch/shear
Decreased speed
Increased Lubrication
Rougher edge Larger deformation zone
Increased burr height
Greater ratio of burnished to rough areas
Decrease max. punch force
This figure attempts to summarize various statements in Kalpakjian p It attempts to show the empirically observed relationships between the various operational parameters and the nature of the cut edge.
Professor John J. Mills: Tel (817)

21. Major Processing Factors in Shearing Die Design
Clearances
Depends on
Workpiece material
Thickness
Size of hole
Proximity of hole to sheet edge
Small holes required larger clearances than large holes
Typically range form 2-8% of sheet thickness
Can range from 1%(Fine Blanking) to 30%
These parameters, spread over the next few slides are factors which influence the nature of the cut, its edges and the forrces invovled
Professor John J. Mills: Tel (817)

22. Fine Blanking
A device called a V-shaped Stinger locks the sheet in place
Prevents distortion at sheared edges
Very tight (<1%) clearances)
Therefore tight tolerances possible
Professor John J. Mills: Tel (817)

23. Other Methods of Cutting Sheet Metal
Band saw
Very versatile but not very precise
Used a lot in job shops
Flame cutting
Used mostly on thick steel sheet
Can cut quite complex shapes but is not precise
Leaves a very rough edge and often a heat affected zone
Laser-beam cutting
Very popular since it can be readily programmed to cut complex shapes
Leaves a fine heat affected zone (much smaller than flame cutting)
In addition to shearing, sheet can be cut by other methods. Flame cutting is mostly for cutting up thick sheets for further processing. It leaves a nasty edge which must be removed but is often the only way to cut thick sheets.
Lasers are a modern development in which the laser simple melts the material and a gas jet blows it out of the cut.
Professor John J. Mills: Tel (817)

24. Other Methods of Cutting Sheet Metal
Friction sawing
Cut-off saw
Uses abrasive disk
Versatile but inaccurate
Water jet
Uses high pressure jet of water to cut
Leaves nice finished edge
Limited in materials that can be cut
Abrasive water jet
Like water jet but with abrasives contained in jet
Cuts anything
Leaves nice edge and is precise
Programmable and can cut almost any shape
Water jet is often used in pastry shops to cut dough. Abrasive water jet cutting is frequently used for composites since it leaves a clean edge unlike machining and shearing which leave frayed edges and laser bean which leave a burned edge.
Professor John J. Mills: Tel (817)

25. Equipment
Shears
A long stationary blade (lower) and a moveable top blade with a table to support the material. Upper blade can be at an angle to reduce forces but this gives a curved blank
Professor John J. Mills: Tel (817)

26. Equipment Saws Punch presses Band Cut-off
A continuous blade that moves at high speeed through a hole in the table which supports the work piece. The material is moved around while the blade is stationary
Cut-off
Can be band type or a circular rotating blade. The material is clamped to a table and the weight of the blade holder forces the moving blade through the material
Punch presses
Like forging machines but can provide high repetition rates
Professor John J. Mills: Tel (817)

27. Equipment Presses CNC nibblers Automated punch presses
Used for shaped punches and dies
Precision
Fast acting
Often combine forming operations as well
CNC nibblers
Can create many shapes using nibbling tools
Automated punch presses
moves large sheet around to position a specific location over a punch and die which is automatically changed to deliver a variety of shapes and diameters of holes
Professor John J. Mills: Tel (817)

28. Equipment Flame, laser and water jet cutting systems
Typically are robots that have the cutting device on the end of the robot arm (the end effector)
The robots are programmed to cut a shape
The robot can be a simple as a linear mechanism to move the end effector over a straight line to cut large slabs
Professor John J. Mills: Tel (817)

29. Fundamentals of Sheet Metal Forming
Professor John J. Mills: Tel (817)

30. Sheet Metal Forming
The sheet metal forming process includes bending, stretching, drawing and otherwise deforming sheet with tools and machines to create a product or component.
To form sheet metal it must have a yield point and exhibit plastic flow
Brittle materials such as ceramics and carbides cannot be formed this by these processes
We must understand the mechanical properties of the sheet before deforming it
Yield stress, elongation, anisotropy,surface finish, grain size, edge conditions
Sheet metal forming differs from rolling forging and extrusion is that the amount of deformation is much more limited. In rolling, forging and extrusion almost all of the material is deformed massively. In sheet metal forming, deformation is often limited to a specific area (e.g. the bend). Deformation in sheet metal is also mostly tensile in nature where as in rolling forging and extrusion it is mostly compressive.
Professor John J. Mills: Tel (817)

31. Basic modes of deformation
Bending
Folding the sheet
The most common operation
The only deformation occurs at the bend
Stretching
Characterized by uniaxial or biaxial uniform strain
Typically the material is grasped by the edges and pulled over a die
Drawing
Characterized by deforming the sheet into a die with a punch or by other means.
Bending can be thought of as a subset of stretching Bending is also mostly carried out in a linear fashion in that bends are mostly made over a straight line. Two dimensional bending also occurs.
Drawing is similar to wire or rod drawing in that the material is mostly under tensile stress, but it is often two dimensional (bi-axial strains) rather than one dimensional(uni-axial strains) for wire drawing.
Professor John J. Mills: Tel (817)

32. Sheet Metal Characteristics for Forming
Important properties
Elongation
Need high uniform elongation
True strain at which necking occurs (= strain hardening coeff.)
Need large strain hardening exponent
This slide lists and describes the important metal characteristics for forming sheet metals.
Without a large uniform deformation, the possible shapes that can be created are limited.
Non-uniform elongation or yield point elongation gives rise to Lueders bands which is a surface defect. This only occurs in certain materials.
Anisotropy arise in the rolling process. Grains are oriented along the rolling direction. This means that a sheet may be bent further in one direction than in the other.
Large grain influence mostly the appearance of the product
Professor John J. Mills: Tel (817)

33. Sheet Metal Characteristics for Forming
Yield point elongation (important for low carbon steels and Al/Mg alloys)
Non-uniform elongation
Restricts the amount of deformation possible during forming
Some parts yield while others do not
Leuders bands
Professor John J. Mills: Tel (817)

34. Sheet Metal Characteristics for Forming
Important properties
Anisotropy
Produces non-uniform deformation
Gives ears during deformation
Two kinds
Planar
Normal
Grain size
Influences strength of product
Influences surface finish
Large grains give mottled appearance
State of the sheared edges
Rough edges cause premature failure during forming
State of the sheet surface
Professor John J. Mills: Tel (817)

35. Failure mechanisms include:
Necking
As occurs at the ultimate tensile stress
Tearing
As it sounds
Professor John J. Mills: Tel (817)

36. Formability
The term "Formability" integrates the important properties into one word
Definition
The ability of sheet to undergo the required shape change or deformation without failure
Formability is essentially an empirical way of measuring how the material deforms under specific conditions.
Professor John J. Mills: Tel (817)

37. Generic Formability Tests
Tests to measure the formability of the metal
Tensile testing
Universal test method - stress and strain to failure under uniaxial stress
Biaxial tensile testing
More generic and representative of forming conditions
Very difficult and hence expensive to do properly
Cupping
A simple generic test for all forms of sheet metal forming
Tensile testing gives only a general indication of formability because so many sheet metal forming processes are biaxial. True biaxial testing is very difficult to do properly and small misalignments can lead to misleading data. Therefor the cupping test was developed. None of these is any help in determining bending limits, There for the bend test was developed..
Professor John J. Mills: Tel (817)

38. Cupping Test and Formability Diagram
The Cupping test
Push a round steel punch into firmly held sheet until a crack appears
Metric is the amount of deformation when crack appears measures the formability
Use Cupping test on various widths to change the strain conditions to provide data on forming limits
Narrow widths undergo simple uniaxial tension
Large widths undergo equal biaxial stretching
The forming limits as a function of major and minor strain is the Forming Limit Diagram
The cupping test measures formability by using the measured deformation of circles inscribed on a sheet which has a spherical shape impressed on it. The changes in the circle dimensions along the major and minor axes when failure occurs are plotted as shown in figure 16.14, p 457 to form a forming limit diagram. This diagram can then be used to determine the maximal strains that a specific forming process can have.
Professor John J. Mills: Tel (817)

39. Cupping test
Professor John J. Mills: Tel (817)

40. Forming Limit Diagram
This is a very complicated figure which is difficult to explain clearly. Essentially it predicts the limits of failure for a given set of major and minor strains. If the major and minor strain conditions of forming lie above the curve for a particular material, it will fail during forming. Note that a compressive minor strain (I.e a negative minor strain) is beneficial in that greater major strains can be achieved without failure. Many processes take advantage of that phenomenon.
Professor John J. Mills: Tel (817)

41. Forming Limit Diagram
Give the limits of major and minor stress for cracking and tearing
Carbon steel and brass have higher limits than high strength steel and aluminum alloys and are more formable
Increased thickness raises the curves BUT
Thicker material difficult to bend around tight radii - see later
Note that having a compressive (negative) minor strain is advantageous
need special tooling
Professor John J. Mills: Tel (817)

42. Other forming tests Depend on the specific forming method Bending
Stretching
Drawing. etc
Professor John J. Mills: Tel (817)

43. Summary Characteristic Importance
Elongation Determines the capability of the sheet metal to stretch without necking and failure; high strain-hardening exponent (n) and strain-rate sensitivity exponent (m) desirable.
Yield-point elongation Observed with mild-steel sheets; also called Lueder’s bands and stretcher strains; causes flame like depressions on the sheets surfaces; can be eliminated by temper rolling, but sheet must be formed within a certain time after rolling.
Anisotropy (planar) Exhibits different behavior in different planar directions; present in cold-rolled sheets because of preferred orientation or mechanical fibering; causes earing in drawing; can be reduced or eliminated by annealing but at lowered strength.
Anisotropy (normal) Determines thinning behavior of sheet metals during stretching; important in deep-drawing operations.
Grain size Determines surface roughness on stretched sheet metal; the coarser the grain, the rougher the appearance (orange peel).
Professor John J. Mills: Tel (817)

44. Summary Characteristic Importance
Residual stresses Caused by nonuniform deformation during forming; causes part distortion when sectioned and can lead to stress-corrosion cracking; reduced or eliminated by stress relieving.
Springback Caused by elastic recovery of the plastically deformed sheet after unloading; causes distortion of part and loss of dimensional accuracy; can be controlled by techniques such as overbending and bottoming of the punch.
Quality of sheared edges Depends on process used; edges can be rough, not square, and contain cracks, residual stresses, and a work-hardened layer, which are all detrimental to the formability of the sheet; quality can be improved by control of clearance, tool and die design, fine blanking, shaving, and lubrication.
Surface condition of sheet Depends on rolling practice; important in sheet forming as it can cause tearing and poor surface quality; see also Section 13.3.
Professor John J. Mills: Tel (817)

45. Sheet Metal Forming Processes
Punching
Blanking
Fine Blanking
Stamping
Embossing
Shearing
Slitting
Cutting
Sawing
Deburring
Cleaning
Coating
Sheet, Plate
Blank
Bending
Roll forming
Stretch forming
Deep drawing
Rubber forming
Spinning
Peen forming
Superplastic forming
Explosive forming
Magnetic pulse forming
This is a transition slide to the next topic, forming of the blanks created.
Professor John J. Mills: Tel (817)

46. Summary Shearing of sheet to form flat shapes
The fundamentals of changing that flat shape into a three dimensional one
Next lecture discusses different sheet metal forming processes
Professor John J. Mills: Tel (817)