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授課教師：楊宏智教授
Manufacturing Engineering Technology Sheet-Metal Forming Processes and Equipment
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2. Manufacturing Engineering Technology 機械製造
楊宏智（台大機械系教授）

3. Chapter Outline Introduction Shearing
Sheet-metal Characteristics and Formability
Formability Tests for Sheet Metals
Bending Sheets, Plates, and Tubes
Miscellaneous Bending and Related Operations
Deep Drawing
Rubber Forming and Hydroforming
Spinning
Superplastic Forming
Specialized Forming Processes
Manufacturing of Metal Honeycomb Structures
Design Considerations in Sheet-metal Forming
Equipment for Sheetmetal Forming
Economics of Sheetforming Operations

4. Introduction Products made of sheet metals are common
Pressworking or press forming is used for general sheet-forming operations, as they are performed on presses using a set of dies

5. Introduction
A sheet-metal part produced in presses is called a stamping
Low-carbon steel has low cost and good strength and formability characteristics
Manufacturing processes involving sheet metal are performed at room temperature

6. Sheet Metalworking Defined
Cutting and forming operations performed on relatively thin sheets of metal
Thickness of sheet metal = 0.4 mm (1/64 in) to 6 mm (1/4 in)
Thickness of plate stock > 6 mm
Operations usually performed as cold working

7. Sheet and Plate Metal Products
Sheet and plate metal parts for consumer and industrial products such as
Automobiles and trucks
Airplanes
Railway cars and locomotives
Farm and construction equipment
Small and large appliances
Office furniture
Computers and office equipment

8. Advantages of Sheet Metal Parts
High strength
Good dimensional accuracy
Good surface finish
Relatively low cost
Economical mass production for large quantities

9. Sheet Metalworking Terminology
Punch-and-Die - tooling to perform cutting, bending, and drawing
Stamping press - machine tool that performs most sheet metal operations
Stampings - sheet metal products

10. Three Basic Types of Sheet Metal Processes
1.Cutting (Shearing)
Shearing to separate large sheets
Blanking to cut part perimeters out of sheet metal
Punching to make holes in sheet metal
2.Bending
Straining sheet around a straight axis
3.Drawing
Forming of sheet into convex or concave shapes

11. Sheet Metal Cutting (Shearing)
(1) Just before punch contacts work;
(2) punch pushes into work, causing plastic deformation; (3) punch penetrates into work causing a smooth cut surface; and
(4) fracture is initiated at opposing cutting edges to separate the sheet

12. Shearing
Before a sheet-metal part is made, a blank is removed from a large sheet by shearing
The edges are not smooth and perpendicular to the plane of the sheet

13. Punch and Die Sizes Die size determines blank size Db
Punch size determines hole size Dh
c = clearance

14. Shearing Processing parameters in shearing are
The shape of the punch and die
The speed of punching
Lubrication
The clearance, c, between the punch and the die
When clearance increases, the zone of deformation becomes larger and the sheared edge becomes rougher
Extent of the deformation zone depends on the punch speed
Height, shape, and size of the burr affect forming operations

15. Clearance in Sheet Metal Cutting
Distance between punch cutting edge and die cutting edge
Typical values range between 4% and 8% of stock thickness
If too small, fracture lines pass each other, causing double burnishing and larger force
If too large, metal is pinched between cutting edges and excessive burr results

16. Clearance in Sheet Metal Cutting
Recommended clearance is calculated by:
c = at
where c = clearance;
a = allowance;
and t = stock thickness
Allowance a is determined according to type of metal

17. Sheet Metal Groups Allowances
Metal group a
1100S and 5052S aluminum alloys, all tempers
2024ST and 6061ST aluminum alloys; brass,
soft cold rolled steel, soft stainless steel
Cold rolled steel, half hard; stainless steel,
half hard and full hard

18. Shearing Clearance Clearance control determine quality of its sheared
edges which influence formability of the sheared part
Appropriate clearance depends on:
1. Type of material and temper
2. Thickness and size of the blank
3. Proximity to the edges of other sheared edges
When sheared edge is rough it can be subjected to a
process called shaving

19. Shearing: Characteristics and Type of Shearing Dies
Punch and Die Shape
Punch force increases rapidly during shearing
Location of sheared regions can be controlled by beveling the punch and die surfaces

20. Shearing Punch Force Maximum punch force, F, can be estimated from
Friction between the punch and the workpiece can increase punch force
T = sheet thickness L = total length sheared UTS = ultimate tensile strength of the material

21. Shearing EXAMPLE 16.1 Calculation of Punch Force
Estimate the force required for punching a 25-mm diameter hole through a 3.2-mm thick annealed titanium- alloy Ti-6Al-4V sheet at room temperature.
Solution
UTS for this alloy is 1000 MPa, thus

22. Blanking and Punching
Blanking - sheet metal cutting to separate piece (called a blank) from surrounding stock
Punching - similar to blanking except cut piece is scrap, called a slug

23. Shearing: Shearing Operations
Punching is where the sheared slug is scrap
Blanking is where the slug is the part to be used and the rest is scrap
Die Cutting
Shearing operation consists of:
Perforating: punching holes in a sheet
Parting: shearing sheet into pieces
Notching: removing pieces from the edges
Lancing: leaving a tab without removing any material

24. Shearing: Fine Blanking
smaller clearance used
pressure pad w/ v-shaped stringer locks the sheet metal
movement of punch, pressure pad, cushion are controlled by triple-action hydraulic presses

25. Shearing Operations: Slitting
Shearing operations are through a pair of circular blades, follow either a straight line, a circular path, or a curved path

26. Shearing Operations: Nibbling
A contour is cut by a series of overlapping slits or notches
Simple tools can be used to produce complex shape

27. Shearing: Tailor-welded Blanks
Laser-beam butt welding involves two or more pieces of sheet metal with different shapes and thicknesses
The strips are welded to obtain a locally thicker sheet and then coiled
The welded assembly is then formed into a final shape.
Resulting in:
Reduction in scrap
Elimination of the need for subsequent spot welding
Better control of dimensions
Improved productivity

28. Shearing: Tailor-welded Blanks
EXAMPLE 16.2
Tailor-welded Sheet Metal for Automotive Applications
Production of an outer side panel of a car body is by laser butt welding and stamping

29. Shearing: Tailor-welded Blanks
EXAMPLE 16.2
Tailor-welded Sheet Metal for Automotive Applications
Some of the examples of laser butt-welded and stamped automotive-body components.

30. Characteristics and Type of Shearing Dies
Transfer Dies
Sheet metal undergoes different operations arranged along a straight line or a circular path
Tool and Die Materials
Tool and die materials for shearing are tool steels and carbides
Lubrication is needed for reducing tool and die wear, and improving edge quality

31. Characteristics and Type of Shearing Dies
Progressive Dies
a different operation is performed at the same station with each stroke of a series of punches

32. Characteristics and Type of Shearing Dies
For high product production rates
The part shown below is the small round piece that supports the plastic tip in spray cans

33. Characteristics and Type of Shearing Dies
Compound Dies
Operations on the same sheet may be performed in one stroke with a compound die
Limited to simple shapes due to:
Process is slow
Complex dies is more expensive

34. Shearing: Miscellaneous Methods of Cutting Sheet Metal
Other methods of cutting sheets
Laser-beam cutting
Water-jet cutting
Cutting with a band saw
Friction sawing
Flame cutting

35. Sheet-metal Characteristics and Formability
Yield-point elongation having both upper and lower yield points.
This behaviour results in Luder’s bands
Typically observed with mild-steel sheets
Results in depressions on the sheet surface
Can be eliminated by temple rolling (but sheet must be formed within a certain time after rolling)

36. Sheet-metal Characteristics and Formability
Grain Size
Affects mechanical properties and surface appearance
Smaller the grain size, stronger is the metal
Dent Resistance of Sheet Metals
Dents caused by dynamic forces from moving objects that hit the sheet metal
Dynamic yield stress, instead of static yield stress, should be the significant strength parameter

37. Formability Tests for Sheet Metals
Sheet-metal formability is the ability of the sheet metal to undergo the desired shape change without failure
Sheet metals may undergo 2 basic modes of deformation: (1) stretching and (2) drawing
Cupping Tests
In the Erichsen test, the sheet specimen is clamped and round punch is forced into the sheet until a crack appears
The punch depth is a measure of formability of the sheet
Easy to perform, but does not simulate exact conditions of actual forming, and not reliable for complex parts.

38. Formability Tests for Sheet Metals
Forming-limit Diagrams
To develop a forming-limit diagram, the major and minor engineering strains are obtained
Major axis of the ellipse represents the major direction and magnitude of stretching
Major strain is the engineering strain and is always positive
Minor strain can be positive or negative
Curves represent the boundaries between failure and safe zones

39. Formability Tests for Sheet Metals
Forming-limit Diagrams
Forming-limit diagrams is to determine the formability of sheet metals

40. Forming-Limit Diagram (FLD)
Blank stretched over a punch, deformation observed and measured in the region where failure has occurred
The curves represent the boundaries between failure and safe zones
Different mat'ls have different FLDs, and the higher the curve, the better is the formability
Compressive minor strain is associated with a higher major strain than a tensile minor strain of the same magnitude
The effect of sheet-metal thickness is to raise the curves
Friction, lubrication at punch/sheet-metal interface, and surface scratches, are important factors

41. Bending Sheets , Plates, and Tubes
Bending is a common industrial forming operation
Bending imparts stiffness to the part by increasing its moment of inertia
Outer fibers are in tension, while the inner in compression
Poisson effect cause the width to be smaller in the outer region and larger in the inner region

42. Bending Sheets, Plates, and Tubes
Approximate bend allowance is
For ideal case, k = 0.5,
Minimum Bend Radius
Engineering strain during bending is
Minimum bend radius, R, is

43. Bending Sheets, Plates, and Tubes
Minimum Bend Radius
Increase the bendability by increase their tensile reduction of area
Bendability also depends on the edge condition of the sheet
Improve resistance to edge cracking by removing the cold-worked regions
Cold rolling results in anisotropy by preferred orientation or mechanical fibering

44. Bending Sheets, Plates, and Tubes
Springback
Plastic deformation is followed by elastic recovery when the load is removed, called springback
Springback can be calculated by

45. Bending Sheets, Plates, and Tubes
Compensation for Springback
Springback is compensated for by overbending the part
One method is stretch bending where the part is subjected to tension while being bent
Bending Force
Excluding friction, the maximum bending force, P, is
For a V-die, it is modified to

46. Miscellaneous Bending Operations
Examples of various bending operations
Roll Bending
Plates are bent using a set of rolls.
Curvatures can be obtained by adjusting the distance between the three rolls

47. V-Bending and Edge Bending
Low production
Performed on a press brake
V-dies are simple and inexpensive
Edge-Bending:
High production
Pressure pad required
Dies are more complicated and costly

48. Miscellaneous Bending and Related Operations
Beading
Periphery of the sheet metal is bent into the cavity of a die
The bead imparts stiffness to the part by increasing the moment of inertia of that section

49. Miscellaneous Bending and Related Operations
Flanging
In shrink flanging, the flange is subjected to compressive hoop stresses and cause the flange periphery to wrinkle

50. Bending Operations most common forming operation
paper clip, file cabinet etc

51. Press Brakes – Bending Equipment
Sheet metal or plate can be bent easily with simple fixtures using a press
complex bends
with long narrow bed and short adjustable strokes
metal bent between interchangeable dies

52. Roll Forming Also called contour-roll forming or cold-roll forming
Used for forming continuous lengths of sheet metal and for large production runs
Dimensional tolerances, springback, tearing and buckling of the strip have to be considered

53. Bending of Tube Stock
Stretch bending of tube: (1) start of process and (2) during bending

54. Tube Bending
Large dia. thin wall, with small bend radius tend to cause wrinkle at inner side of the tube
Oldest method of bending a tube is to first pack its inside with loose particles and then bend it into a suitable fixture
Thick tube can be formed to a large bend radius without the use of fillers or plugs

55. Tube Forming
tubular part placed in a split-female die and expanded with a polyurethane or rubber plug
punch retracted; plug returns to its original shape and removed by knockout rod
finished part removed by opening the split die (water pitcher)
production of fitting for plumbing

56. Manufacturing of Bellows
(a) Bulged tube :
Tube bulged at several equidistant locations
(b) Compressed tube :
Bulged tube compressed axially to collapse bulged regions, thus forming bellows

57. Stretch Forming Sheet metal is gripped by two sets of jaws
The jaws stretch the metal sheet and wrap it around a form block (die)
Most of deformation is induced by tensile stretching, and forces on the form block are far less
Very little springback results
Form block often made of wood or low-melting metal
Produce large parts in low or limited quantity

58. Stretch Forming
Sheet metal is clamped along its edges and then stretched over a male die
Die moves upward, downward, or sideways
Used to make aircraft wing-skin panels, fuselages, and boat hulls

59. Deep Drawing
Sheet metal forming to make cup-shaped, box-shaped, or other complex-curved, hollow-shaped parts
Sheet metal blank is positioned over die cavity and then punch pushes metal into opening
Products: beverage cans, ammunition shells, automobile body panels
Also known as deep drawing (to distinguish it from wire and bar drawing)

60. Deep Drawing - a punch forces a flat sheet metal into a die cavity
- depth greater than diameter

61. Deep Drawing
Material beneath punch remains unaffected and becomes cup bottom
Cup wall is formed by pulling the remainder of disk inward the radius of die
- Hoop stress tends to cause buckling or wrinkling
 - Pressure ring is used to suppress wrinkle

62. Deep Drawing
Wrinkling can be reduced if a blankholder is loaded by maximum punch force
The force increases with increasing blank diameter, thickness, strength and the ratio

63. Redrawing
Cup becomes longer as it is redrawn to smaller diameters since volume of the metal is constant
If the shape change is too severe, more than one drawing step is required.
The second drawing step, and any further drawing step is referred as redrawing

64. Ironing
If the clearance between the punch and the die is large, the drawn cup will have thicker walls
Thickness of the cup wall can be controlled by ironing, where drawn cup is pushed through one or more ironing rings

65. Deep Drawing: Deep Drawability
Earing
In deep drawing, the edges of cups may become wavy and the phenomenon is called earing
Earing is caused by the planar anisotropy
Planar anisotropy of the sheet is indicated by

66. Deep-drawing Practice
Earing
Too high a blankholder force increases the punch force and causes the cup wall to tear
Draw beads are needed to control the flow of the blank into the die cavity and reduce the blankholder forces

67. Deep-drawing Practice
CASE STUDY 16.1
Manufacturing of Food and Beverage Cans
Aluminum beverage cans has excellent surface finish
Detail of the can lid is shown

68. Rubber Forming
Dies are made of solid materials, such as steels and carbides
The dies in rubber forming is made of a flexible material (polyurethane membrane)
In the bending and embossing of sheet metal, the female die is replaced with a rubber pad

69. Hydroforming
In the hydroform, or fluid-forming process, the pressure over the rubber membrane is controlled throughout the forming cycle
Control of frictional conditions in rubber forming is a factor in making parts successfully

70. Rubber Forming and Hydroforming
In tube hydroforming metal tubing is formed in a die and pressurized internally by a fluid, usually water
Rubber-forming and hydroforming processes have the advantages of:
Capability to form complex shapes
Flexibility and ease of operation
Low tooling cost

71. Tube Hydroforming CASE STUDY 16.2
Tube Hydroforming of an Automotive Radiator Closure
Figure shows a hydroformed automotive radiator closure
Sequence of operations: (1) tube as cut to length; (2)
afterbending; (3) after hydroforming

72. Spinning
Spinning is a process that involves the forming of axisymmetric parts over a mandrel
A circular blank of flat sheet metal is held against a mandrel (form block of desired shape) and rotated while a rigid tool deforms and shapes the material over the mandrel; Disk of sheet metal progressively shaped by localized pressure with small roller
Suitable for conical and curvilinear shapes

73. Shear Spinning (Forming)
A simplified version of the spinning process in which each element of the blank maintains its distance from the axis of rotation.
Metal flow is entirely in shear and no radial stretch has to take place to compensate for the circumferencial shrinkage

74. Shear Spinning
Also known as power spinning, flow turning, hydrospinning, and spin forging
Use to produce an axisymmetric conical or curvilinear shape while reducing the sheet’s thickness and maintaining its maximum (blank) diameter

75. Tube Spinning Tube Spinning
The thickness of hollow, cylindrical blanks is reduced by spinning them on a solid, round mandrel using rollers
Can be carried out externally or internally
Various external and internal profiles can be produced from cylindrical blanks with constant wall thickness

76. Spinning Incremental Forming
Simplest version is incremental stretch expanding
A rotating blank is deformed by a steel rod with a smooth hemispherical tip to produce axisymmetric parts
CNC incremental forming uses a CNC machine tool to follow contours at different depths across the sheet-metal surface
Advantages are low tooling costs and high flexibility in the product shapes

77. Explosive Forming
Use of explosive charge to form sheet (or plate) metal into a die cavity
Explosive charge causes a shock wave whose energy is transmitted to force part into cavity
Applications: large parts, typical of aerospace industry
(1) Setup, (2) explosive is detonated, and
(3) shock wave forms part and plume escapes water surface

78. Explosive Forming The peak pressure, p, is given by
The mechanical properties of parts similar to those made by conventional forming methods
The dies may be made of aluminum alloys, steel, ductile iron or zinc alloys
p = pressure, psi
K = constant that depends on the type of explosive

79. Explosively Formed Part
Explosive used as a source of energy
Rapid conversion of explosive charge into gas generates a shock wave
Pressure of shock wave is sufficient to form sheet metal
no limit to the size of the workpiece (suitable for low quantity of large parts, ie aerospace application)

80. Electromagnetic Forming
coil current rapidly discharged from capacitor bank
eddy current generated in the tube (workpiece)
repelling force between the coil and the tube
forces generated collapse the tube
Higher the electrical conductivity of the workpiece, the higher the magnetic forces

81. Peen Forming
Used to produce curvatures on thin sheet metals by shot peening one surface of the sheet
Surface of the sheet is subjected to compressive stresses
The process also induces compressive surface residual stresses, which improve the fatigue strength of the sheet

82. Laser Forming
Involves the application of laser beams as a heat source in specific regions of the sheet metal
Process produce thermal stresses, which can cause localized plastic deformation of the sheet
In laser-assisted forming, the laser acts as a localized heat source, thus reducing the strength of the sheet metal at specific locations
Improve formability and increasing process flexibility

83. Superplastic Forming
The behavior of superplastic are where tensile elongations were obtained within certain temperature ranges
Superplastic alloys can be formed into complex shapes by superplastic forming
Have high ductility but low strength
Advantages:
Complex shapes can be formed
Weight and material savings
Little residual stresses
Tooling costs are lower

84. Superplastic Forming Limitations of superplastic forming:
Part will undergo shape changes
Must be formed at sufficiently low strain rates
Diffusion Bonding/Superplastic Forming
Fabricating of complex sheet-metal structures by combining diffusion bonding with superplastic forming (SPF/DB)
Application for aerospace industry
Improves productivity and produces parts with good dimensional accuracy and low residual stresses

85. Specialized Forming Processes
CASE STUDY 16.3
Cymbal Manufacture

86. Manufacturing of Metal Honeycomb Structures
A honeycomb structure has light weight and high resistance to bending forces, used for aircraft and aerospace components
2 methods of manufacturing honeycomb materials:
Expansion process
Corrugation process

87. Manufacturing of Metal Honeycomb Structures
A honeycomb structure consists of a core of honeycomb bonded to two thin outer skins
Has a high stiffness-to-weight ratio and is used in packaging for shipping consumer and industrial goods

88. Design Considerations in Sheet-metal Forming
Blank Design
Poorly designed parts will not nest properly
Blanks should be designed to reduce scrap to a minimum

89. Equipment for Sheet-metal Forming
Press selection for sheet-metal forming operations depends on:
Type of forming operation
Size and shape of workpieces
Number of slides
Maximum force required
Type of mechanical, hydraulic, and computer controls
Features for changing dies
Safety features

90. CNC Turret Press Parts
Sheet metal parts produced on a turret press, showing variety of hole shapes possible (photo courtesy of Strippet Inc.)

91. Economics of Sheet-forming Operations
Sheet-forming operations are versatile and can produce the same part
The costs involved depend on die and equipment costs and labor
For small and simple sheet-metal parts, die costs and lead times to make the dies are low
Deep drawing requires expensive dies and tooling
Equipment costs depend on the complexity of the forming operation