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Sheet Metal Forming
Prepared by
Prof. Naman M. Dave
Assistant Professor,
Mechanical Engg. Dept.
Gandhinagar Institute of Technology
Sheet Metal Forming
• For products with versatile shapes and lightweight
• Dates to 5000 B.C.
• Products include metal desks, file cabinets, appliances,
car bodies, beverage cans
• Common materials: low-carbon steel, aluminum or
titanium
• First take sheet plate and cut into pieces by shearing,
slitting, cutting, or sawing or produce from coil
• Then form into shapes by punching, blanking, stamping,
embossing, bending, forming, deep drawing, and a variety
of other processes
Sheet Metal Characteristics
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
flamelike depressions on the sheet 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); also affects material strength.
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.
Wrinkling Caused by compressive stresses in the plane of the sheet; can be objectionable or can be
useful in imparting stiffness to parts; can be controlled by proper tool and die design.
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.
Formability
• Formability is the ability of sheet metal to undergo shape
change without failure by necking
or tearing
• Cupping (Swift or Ericson) tests give
some idea of formability
(a) Yield-point elongation in a sheet-metal specimen. (b) Lueder's
bands in a low-carbon steel sheet. Source: Courtesy of Caterpillar Inc.
(c) Stretcher strains at the bottom of a steel can for household products.
(a) (b) (c)
(a)
Forming-Limit Diagrams (FLD)
• Sheet metal is marked with small circles, stretched over a
punch, and deformation is observed in failure areas
• FLD shows boundary between safe and failure zones
(a) Strains in deformed circular grid patterns.
(b) Forming-limit diagrams (FLD) for various
sheet metals. Although the major strain is
always positive (stretching), the minor strain
may be either positive or negative. In the lower
left of the diagram, R is the normal anisotropy
of the sheet, as described in Section 16.9.2.
Source: S. S. Hecker and A. K. Ghosh.
Shearing
(a) Schematic illustration of shearing with a punch and die, indicating
some of the process variables. Characteristic features of (b) a punched
hole and (c) the slug. Note that the scales of the two figures are different.
• A blank is a properly sized piece
of sheet metal removed from a
much larger sheet or coil by
shearing
• Shearing is cutting by subjecting
a workpiece to shear stresses
• Shearing starts with small cracks
at points A, B, C, D which
eventually grow and meet
• Rough fracture surfaces and
smooth burnished surfaces result
• Shear angles or beveled edges
often used on shearing dies
Shearing Parameters
• Clearance, c, between the punch and die typically
between 2% and 10% of sheet metal thickness
• As clearance increases, sheared edge becomes rougher
and zone of deformation becomes larger – clearances are
smaller for softer metals, thinner sheets, or larger holes
• Ratio of burnished to rough edges increases with:
increasing ductility, decreasing clearance and thickness
• Faster punch speeds cause narrower sheared zones and
less burr formation
• Burr height increases with increasing clearance, ductility,
or dull tools
• Maximum Punch Force, F = 0.7 T L (UTS)
(product of thickness, sheared edge perimeter, and UTS)
Shearing Operations
• Punching – sheared slug is discarded
• Blanking – slug is workpiece, surrounding area discarded
• Die cutting includes perforating (many holes), parting
(separating into multiple pieces), notching (removing
pieces from the edges), and lancing (leaving a tab)
• Fine blanking with 1% clearances produces very smooth
and squared off edges
(a) (b)
(a) Comparison of sheared edges produced by conventional (left) and by fine-blanking (right) techniques.
(b) Schematic illustration of one setup for fine blanking. Source: Feintool U.S. Operations.
Shearing Operations
• Slitting – cutting off with 2 circular blades (can opener)
• Steel rules – a die for shearing soft metals, paper, leather,
and rubber into specific shapes (cookie cutter)
• Nibbling – reciprocating die for successive, overlapping
holes that shears intricate, flexible shapes
• Shaving – trims excess material to clean sheared edges
• Compound and progressive dies perform several operations
Slitting with
rotary knives. Shaving and
compound dies
Other Methods of Cutting Sheet Metal
• Band saw – metal material removal process that produces
chips as in other machining
• Flame cutting – especially for thick steel plates, as in
shipbuilding
• Laser-beam cutting – newer process used with computer
controlled equipment
• Plasma cutting – high energy plasma formed by electric arc
between tool and work material
• Friction sawing – disk or blade that rubs against sheet or
plate at high speeds
• Water-jet cutting – for metallic and non-metallic workpieces
Laser Cutting
Mechanical Stamp Press
Sequential Process Steps
Progressive Die Work
Cut-Off Die
 Design parts with straight parallel edges
and “jig-saw” ends - minimizes scrap and
can be produced on simplest cut-off die
Cut Off Operation
Part-Off Die
Part Off Operation
 Design parts with straight parallel edges - reduces
edge scrap and requires simpler part-off die
Blanking Die
Hole Punching Die
Blank and Punch Die
Multi-stage Stamping
Progressive Die
Processing Limits –minimum hole diameters
Critical Dimensions in Design of Sheet Metal Blank
* All dimensions > 2 x gage thickness
*
*
*
*
*
*
*
Feature Position Limits
* Dimension > 4 x gage thickness
*
Reducing Scrap
• Scrap metal can be as high as 30%
• Computer aided design and planning can minimize scrap
• Tailor-welded blanks are multiple pieces of flat sheet butt-
welded together and simultaneously stamped
Production of an outer
side panel of a car body,
by laser butt-welding
and stamping. Source:
After M. Geiger and T.
Nakagawa.
Reducing Waste Material
CNC Turret Press
Programmable machines for punching sheet metal using a turret of
standard tools and corresponding dies
CNC Turret Press
Turret Presswork
Turret of
standard tools
Tools for corner radii
At least one blow per
hole
Long profiles require
multiple blows
Laser or plasma
cutting often added to
reduce processing
times
Turret Press Part Features
Only possible in the upwards direction
Turret Press Part Layout
Basic Die Bending Operations
Basic Die Bending Operations
• Springback is the elastic recovery
following plastic deformation
during bending
• Bending force is a function of
material strength, length of bend
(L), sheet thickness (T) and size
of die opening (W)
Springback and Bending Forces
W
kYLT
P
2

134
3













ET
YR
ET
YR
R
R ii
f
i
W
LTUTS
P
2
)(

For a V-die
Springback Reduction
Bending Sheet Metal
• In bending, outer fibers are in tension while inner fibers
are in compression
• Bend allowance is the length of the neutral axis in the
bend, Lb = a (R+kT)
• k is a constant that ranges from 0.33 (for R<2T) to 0.5 (for
R>2T)
• Engineering strain during bending:
• As R/T decreases, the
tensile strain at outer fiber
increases and material
eventually cracks
  12
1


T
R
e
Bendability and Minimum Bend Radius
• A 3T minimum bend radius means the smallest radius the
sheet can be bent to without cracking is 3 times thickness
• r is the tensile reduction of area of the sheet metal
(a) and (b) The effect of elongated inclusions (stringers) on cracking, as a function of the direction of
bending with respect to the original rolling direction of the sheet.
(c)
Source: After J. Datsko
and C. T. Yang.(c) Cracks on the
outer surface of an
aluminum strip
bent to an angle of
90o. Note the
narrowing of the
top surface due to
the Poisson effect.
(a) (b)
 1
50


r
TR
Press Brake Forming
Press Brake Forming
Other Bending Operations
• Roll-bending – bending plates with a set of rolls
• Beading – bending the periphery of sheet metal into a
cavity of a die to improve appearance and eliminate
exposed edges
• Flanging – bending edges of sheet metal to 90 degrees
• Dimpling – punching a hole, followed immediately by
flanging the edges
• Hemming – folding the edge of a sheet over itself
• Seaming – joining 2 edges of sheet metal by hemming
• Roll Forming – Multiple rolls to form linear products
similar to extrusion
Roll Forming
Multi-stage rolling process for producing elongated
sectional products from sheet metal
Typical products are rain gutters and down spouts
Competes with extrusion for some products
Deep Drawing Die
Deep Drawing Process
Stresses in Deep Drawing
Compressive hoops stresses in the flange
Drawing Parameters
• Wrinkling is caused by compressive (hoop) stresses that
are induced as the blank moves into the die cavity
• Blankholder (or hold-down ring) pressure must be correct
• Too much pressure causes tearing, too little causes wrinkling
• Typically 0.7-1.0% of the sum of the UTS and yield strength
• If Do-Dp < 5T, deep drawing may
be successfully achieved without
a blankholder
• Clearance is usually 7-14% sheet thickness
• Deep drawability is expressed by the limiting drawing ratio
• Normal anisotropy
• R for rolled sheet metal
Drawing Parameters
t
w
trainThicknessS
nWidthStrai
R



4
2 90450 RRR
Ravg


p
o
D
D
terPunchDiame
nkDiameterMaximumBla
LDR 
• Planar anisotropy determines whether earing will occur
• If DR=0 no ears form
• Ear height increases with DR
• Low DR and high Ravg is desired,
but, tend to increase together
Drawing Parameters
2
2 90450 RRR
R

D
Source: M. Atkinson.
Earing in a drawn steel cup, caused by the
planar anisotropy of the sheet metal.
Redrawing
Forward redrawing Reverse redrawing
Reduces cup diameter and elongates walls
Deep Drawing and Redrawing
Ironing
Elongates and thins walls of
the cup
Deep
Drawing
The metal- forming processes
involved in manufacturing a two-
piece aluminum beverage can
• Products:
pots, food
and
beverage
containers,
kitchen
sinks, car
fuel tanks
Drawing of More Complex Shapes
Numerous products including
kitchen hardware, sinks, car body
parts, etc.
Starting blank shape needs to be
designed
Draw beads are necessary to
control the material inflow
Stretch Forming
• Sheet metal is clamped at edges and stretched over a die
or form block
• Dies made of zinc alloys, steels, plastics, wood
• Little or no lubrication
• Low-volume, versatile, and economic production
Source: Cyril Bath Co.
• Products:
aircraft wing
skin panels,
automobile
door panels,
window
frames
Tube Bending and Bulging
• Bending and forming hollow sections with filler in order to
avoid buckling and folding
• Fill with loose particles (sand), flexible mandrels,
polyurethane, water or other fluid
• Products: barrels, beads on
drums, exhaust pipes, manifolds,
water pitchers, plumbing fittings
Source: J. A. Schey, Introduction to Manufacturing
Processes (2d ed.) New York: McGraw-Hill, 1987.
Other Forming Operations
• Embossing – shallow dies typically for decoration
• Rubber Forming – one of the dies is replaced by a flexible
material, such as polyurethane
• Hydroform or Fluid-forming – pressure over the rubber
membrane is maintained with fluid
• Conventional, shear, and tube spinning – circular blank is
held against a shaped mandrel and rotated
Metal Spinning
•Incremental forming of axisymmetric
hollow shapes
•Motions similar to a metal cutting
lathe
•Manual and CNC controlled
machines available
Metal Spinning
Other Forming Operations
• Superplastic forming
• Explosive forming – controlled use of explosive energy
• p is pressure in psi
• K is a constant (21600 for TNT)
• W is weight of explosive (lbs)
• R distance of explosive from workpiece
• a is a constant (generally 1.15)
a
R
W
Kp 








3
Other Forming Operations
• Peen Forming – surface of sheet metal is exposed to
compressive stresses
• Laser forming and laser assisted forming
• Gas and liquified gases mixtures as energy source
• Electrohydraulic forming
• Magnetic-Pulse Forming
(a) Schematic illustration
of the magnetic-pulse
forming process used to
form a tube over a plug.
(b) Aluminum tube
collapsed over a hexagonal
plug by the magnetic-pulse
forming process.
(a)
(b)

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Sheet metal working 1

  • 1. Sheet Metal Forming Prepared by Prof. Naman M. Dave Assistant Professor, Mechanical Engg. Dept. Gandhinagar Institute of Technology
  • 2. Sheet Metal Forming • For products with versatile shapes and lightweight • Dates to 5000 B.C. • Products include metal desks, file cabinets, appliances, car bodies, beverage cans • Common materials: low-carbon steel, aluminum or titanium • First take sheet plate and cut into pieces by shearing, slitting, cutting, or sawing or produce from coil • Then form into shapes by punching, blanking, stamping, embossing, bending, forming, deep drawing, and a variety of other processes
  • 3. Sheet Metal Characteristics 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 flamelike depressions on the sheet 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); also affects material strength. 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. Wrinkling Caused by compressive stresses in the plane of the sheet; can be objectionable or can be useful in imparting stiffness to parts; can be controlled by proper tool and die design. 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.
  • 4. Formability • Formability is the ability of sheet metal to undergo shape change without failure by necking or tearing • Cupping (Swift or Ericson) tests give some idea of formability (a) Yield-point elongation in a sheet-metal specimen. (b) Lueder's bands in a low-carbon steel sheet. Source: Courtesy of Caterpillar Inc. (c) Stretcher strains at the bottom of a steel can for household products. (a) (b) (c) (a)
  • 5. Forming-Limit Diagrams (FLD) • Sheet metal is marked with small circles, stretched over a punch, and deformation is observed in failure areas • FLD shows boundary between safe and failure zones (a) Strains in deformed circular grid patterns. (b) Forming-limit diagrams (FLD) for various sheet metals. Although the major strain is always positive (stretching), the minor strain may be either positive or negative. In the lower left of the diagram, R is the normal anisotropy of the sheet, as described in Section 16.9.2. Source: S. S. Hecker and A. K. Ghosh.
  • 6. Shearing (a) Schematic illustration of shearing with a punch and die, indicating some of the process variables. Characteristic features of (b) a punched hole and (c) the slug. Note that the scales of the two figures are different. • A blank is a properly sized piece of sheet metal removed from a much larger sheet or coil by shearing • Shearing is cutting by subjecting a workpiece to shear stresses • Shearing starts with small cracks at points A, B, C, D which eventually grow and meet • Rough fracture surfaces and smooth burnished surfaces result • Shear angles or beveled edges often used on shearing dies
  • 7. Shearing Parameters • Clearance, c, between the punch and die typically between 2% and 10% of sheet metal thickness • As clearance increases, sheared edge becomes rougher and zone of deformation becomes larger – clearances are smaller for softer metals, thinner sheets, or larger holes • Ratio of burnished to rough edges increases with: increasing ductility, decreasing clearance and thickness • Faster punch speeds cause narrower sheared zones and less burr formation • Burr height increases with increasing clearance, ductility, or dull tools • Maximum Punch Force, F = 0.7 T L (UTS) (product of thickness, sheared edge perimeter, and UTS)
  • 8. Shearing Operations • Punching – sheared slug is discarded • Blanking – slug is workpiece, surrounding area discarded • Die cutting includes perforating (many holes), parting (separating into multiple pieces), notching (removing pieces from the edges), and lancing (leaving a tab) • Fine blanking with 1% clearances produces very smooth and squared off edges (a) (b) (a) Comparison of sheared edges produced by conventional (left) and by fine-blanking (right) techniques. (b) Schematic illustration of one setup for fine blanking. Source: Feintool U.S. Operations.
  • 9. Shearing Operations • Slitting – cutting off with 2 circular blades (can opener) • Steel rules – a die for shearing soft metals, paper, leather, and rubber into specific shapes (cookie cutter) • Nibbling – reciprocating die for successive, overlapping holes that shears intricate, flexible shapes • Shaving – trims excess material to clean sheared edges • Compound and progressive dies perform several operations Slitting with rotary knives. Shaving and compound dies
  • 10. Other Methods of Cutting Sheet Metal • Band saw – metal material removal process that produces chips as in other machining • Flame cutting – especially for thick steel plates, as in shipbuilding • Laser-beam cutting – newer process used with computer controlled equipment • Plasma cutting – high energy plasma formed by electric arc between tool and work material • Friction sawing – disk or blade that rubs against sheet or plate at high speeds • Water-jet cutting – for metallic and non-metallic workpieces
  • 16.  Design parts with straight parallel edges and “jig-saw” ends - minimizes scrap and can be produced on simplest cut-off die Cut Off Operation
  • 18. Part Off Operation  Design parts with straight parallel edges - reduces edge scrap and requires simpler part-off die
  • 25. Critical Dimensions in Design of Sheet Metal Blank * All dimensions > 2 x gage thickness * * * * * * *
  • 26. Feature Position Limits * Dimension > 4 x gage thickness *
  • 27. Reducing Scrap • Scrap metal can be as high as 30% • Computer aided design and planning can minimize scrap • Tailor-welded blanks are multiple pieces of flat sheet butt- welded together and simultaneously stamped Production of an outer side panel of a car body, by laser butt-welding and stamping. Source: After M. Geiger and T. Nakagawa.
  • 29. CNC Turret Press Programmable machines for punching sheet metal using a turret of standard tools and corresponding dies
  • 31. Turret Presswork Turret of standard tools Tools for corner radii At least one blow per hole Long profiles require multiple blows Laser or plasma cutting often added to reduce processing times
  • 32. Turret Press Part Features Only possible in the upwards direction
  • 34. Basic Die Bending Operations
  • 35. Basic Die Bending Operations
  • 36. • Springback is the elastic recovery following plastic deformation during bending • Bending force is a function of material strength, length of bend (L), sheet thickness (T) and size of die opening (W) Springback and Bending Forces W kYLT P 2  134 3              ET YR ET YR R R ii f i W LTUTS P 2 )(  For a V-die
  • 38. Bending Sheet Metal • In bending, outer fibers are in tension while inner fibers are in compression • Bend allowance is the length of the neutral axis in the bend, Lb = a (R+kT) • k is a constant that ranges from 0.33 (for R<2T) to 0.5 (for R>2T) • Engineering strain during bending: • As R/T decreases, the tensile strain at outer fiber increases and material eventually cracks   12 1   T R e
  • 39. Bendability and Minimum Bend Radius • A 3T minimum bend radius means the smallest radius the sheet can be bent to without cracking is 3 times thickness • r is the tensile reduction of area of the sheet metal (a) and (b) The effect of elongated inclusions (stringers) on cracking, as a function of the direction of bending with respect to the original rolling direction of the sheet. (c) Source: After J. Datsko and C. T. Yang.(c) Cracks on the outer surface of an aluminum strip bent to an angle of 90o. Note the narrowing of the top surface due to the Poisson effect. (a) (b)  1 50   r TR
  • 42. Other Bending Operations • Roll-bending – bending plates with a set of rolls • Beading – bending the periphery of sheet metal into a cavity of a die to improve appearance and eliminate exposed edges • Flanging – bending edges of sheet metal to 90 degrees • Dimpling – punching a hole, followed immediately by flanging the edges • Hemming – folding the edge of a sheet over itself • Seaming – joining 2 edges of sheet metal by hemming • Roll Forming – Multiple rolls to form linear products similar to extrusion
  • 43. Roll Forming Multi-stage rolling process for producing elongated sectional products from sheet metal Typical products are rain gutters and down spouts Competes with extrusion for some products
  • 46. Stresses in Deep Drawing Compressive hoops stresses in the flange
  • 47. Drawing Parameters • Wrinkling is caused by compressive (hoop) stresses that are induced as the blank moves into the die cavity • Blankholder (or hold-down ring) pressure must be correct • Too much pressure causes tearing, too little causes wrinkling • Typically 0.7-1.0% of the sum of the UTS and yield strength • If Do-Dp < 5T, deep drawing may be successfully achieved without a blankholder
  • 48. • Clearance is usually 7-14% sheet thickness • Deep drawability is expressed by the limiting drawing ratio • Normal anisotropy • R for rolled sheet metal Drawing Parameters t w trainThicknessS nWidthStrai R    4 2 90450 RRR Ravg   p o D D terPunchDiame nkDiameterMaximumBla LDR 
  • 49. • Planar anisotropy determines whether earing will occur • If DR=0 no ears form • Ear height increases with DR • Low DR and high Ravg is desired, but, tend to increase together Drawing Parameters 2 2 90450 RRR R  D Source: M. Atkinson. Earing in a drawn steel cup, caused by the planar anisotropy of the sheet metal.
  • 50. Redrawing Forward redrawing Reverse redrawing Reduces cup diameter and elongates walls
  • 51. Deep Drawing and Redrawing
  • 52. Ironing Elongates and thins walls of the cup
  • 53. Deep Drawing The metal- forming processes involved in manufacturing a two- piece aluminum beverage can • Products: pots, food and beverage containers, kitchen sinks, car fuel tanks
  • 54. Drawing of More Complex Shapes Numerous products including kitchen hardware, sinks, car body parts, etc. Starting blank shape needs to be designed Draw beads are necessary to control the material inflow
  • 55. Stretch Forming • Sheet metal is clamped at edges and stretched over a die or form block • Dies made of zinc alloys, steels, plastics, wood • Little or no lubrication • Low-volume, versatile, and economic production Source: Cyril Bath Co. • Products: aircraft wing skin panels, automobile door panels, window frames
  • 56. Tube Bending and Bulging • Bending and forming hollow sections with filler in order to avoid buckling and folding • Fill with loose particles (sand), flexible mandrels, polyurethane, water or other fluid • Products: barrels, beads on drums, exhaust pipes, manifolds, water pitchers, plumbing fittings Source: J. A. Schey, Introduction to Manufacturing Processes (2d ed.) New York: McGraw-Hill, 1987.
  • 57. Other Forming Operations • Embossing – shallow dies typically for decoration • Rubber Forming – one of the dies is replaced by a flexible material, such as polyurethane • Hydroform or Fluid-forming – pressure over the rubber membrane is maintained with fluid • Conventional, shear, and tube spinning – circular blank is held against a shaped mandrel and rotated
  • 58. Metal Spinning •Incremental forming of axisymmetric hollow shapes •Motions similar to a metal cutting lathe •Manual and CNC controlled machines available
  • 60. Other Forming Operations • Superplastic forming • Explosive forming – controlled use of explosive energy • p is pressure in psi • K is a constant (21600 for TNT) • W is weight of explosive (lbs) • R distance of explosive from workpiece • a is a constant (generally 1.15) a R W Kp          3
  • 61. Other Forming Operations • Peen Forming – surface of sheet metal is exposed to compressive stresses • Laser forming and laser assisted forming • Gas and liquified gases mixtures as energy source • Electrohydraulic forming • Magnetic-Pulse Forming (a) Schematic illustration of the magnetic-pulse forming process used to form a tube over a plug. (b) Aluminum tube collapsed over a hexagonal plug by the magnetic-pulse forming process. (a) (b)