The document provides an overview of the metal spinning process. It discusses the history and classification of different metal spinning techniques. The basic metal spinning process involves clamping a metal blank between a spinning mandrel and follower, and using specially designed tools to form the blank into an axially symmetric product while it rotates at high speeds. Key aspects covered include the mechanics of cone spinning, use of multi-pass spinning for small cone angles, mandrel and tool design, lubricants, common spinning machines, advantages over other forming processes, and applications.
3. THE BASIC IDEA…
Metal Spinning process is a cold forming process in which the blank metal appears to flow
somewhat like a piece of clay on a potter's wheel.
5. INTRODUCTION
HOW DO WE DEFINE THIS?
Here, we basically have a metal
disk or cylinder , rotated at high
speed on CNC lathe or on hand
and by using specially designed
tools, we get axially symmetric
products
E.g.
WHERE DO WE USE THIS?
to manufacture low cost, rapid
prototypes in metals.
bell shaped curves are ideal for
spinning as metals can deform
smoothly around them
easy to create concentric ribs to
strengthen parts
Almost all metal in sheet form can
be spun
Specially used when the product
requires mirror sheen
6. EVERYDAY EXAMPLES
I always wondered how
these commonly seen
objects are made….now
finally I got my
answers!!....
7. CRITICAL QUESTIONS
1)
2)
3)
WHEN METAL SPINNING PROCESSES?
Is the metal you are working with DUCTILE?
Is the final product AXISYMETRIC?
Is the product to be used for artistic application or commercial
applications like BELL, ROCKET NOSE, COOKING WARE?
4) Is the time you have is less and production
RELAX!!
number is high?
We use metal
spinning
5) Do you need mirror sheen?
processes
YES
8. HISTORY
One of the oldest techniques for chip -less
production of circular hollow metal components .
introduced in 1 840 and was fir st used almost
exclusively for the production of fine gold, silver
and pewter hollow -ware and chalices.
Only sof t nonferrous metals were employed in
industrial applications as late as the 1st World
War.
Around 1920, the industr y began to experiment
with tougher materials, heavier gauges, and larger
diameters.
CHALICE
9. CLASSIFICATION OF METAL SPINNING
TECHNIQUES
•
Metal Spinning
Used for prototype manufacture or in
production runs less than 1000 pieces.
Metal is deformed using high shear
forces.
•
Use of automated CNC machines.
•
Significant thinning of metal preforms.
•
Suitable for high production runs.
•
Tube Spinning
Involves no significant thinning of work
metal; essentially a shaping process.
•
Power Spinning
•
•
Manual (Conventional)
Spinning
Practiced by pressing a tool against a
circular metal preform.
Thickness of cylindrical parts reduced by
spinning them on cylindrical mandrel
rollers.
11. THE PROCESS OF SPINNING
A disc of metal is revolved at controlled speeds on a machine
similar in design to a machine lathe .
Instead of the clamping chuck common on a machine lathe, a
wood or metal mandrel is used.
12. PROCESS OF METAL SPINNING
The external shape of the mandrel corresponds to the internal
contour of the part to be produced.
The blank is clamped between spinning mandrel and a follower
on the tailstock spindle.
The mandrel, blank, and follower are then set in rotation at
controlled speeds.
13. PROCESS OF METAL SPINNING
Spinning tools or spinning rollers are forced against the
rotating blank either by hand or by auxiliary power or both.
Employing a series of axial and radial (swivel) strokes, the
blank is spun onto the mandrel causing the metal to flow to
the shape of the desired part.
14. STEPS IN SPINNING PROCESS
Step 1 :
Metal Forming
This step involves the laying down of the material onto the mandrel.
It is accomplished with short inside to outside moves.
Material gets easier to form as the part is closer to completion
•
•
•
Step 2 :
Trimming
Parts having been spun are trimmed at the end to blunt sharp edges and also to bring the component to the
desired length.
Step 3 :
•
•
Finishing
Finishing is done at very high RPMs (1200+) so that a minimum of force need be applied and very
smooth strokes can be used.
The flat side of Duckbill spinning tool is used for straight surfaces and rounded side for curves and radii.
15. MECHANICS OF CONE SPINNING
•
The most common application of metal spinning is for conical shapes, in
which the metal is volumetricall y displaced in the axial direction.
•
Metal deformation during spinning occur s in accordance with the sine
law .
•
The sine law relates the wall thickness of the star ting blank , t 1 , and the
wall thickness of the finished product, t 2 , as t 2 = t 1 (sin α ), where α is the
semi-apex angle of the cone.
•
The thickness of the component in axial direction is the same as the
thickness of the star ting blank .
•
When spinning metal cones of smaller apex angles, it is generally
convenient to use multiple spinning passes with dif ferent cone angles for
each pass.
•
Deviations from the sine law that can occur, are usually expressed in
terms of over-reduction or under -reduction .
In over-reducti on, final thickness of work -piece is lesser than that
indicated by sine law, while in under -reduction the thickness is greater .
16. SINGLE AND MULTI-PASS SPINNING
OPERATION
Single Pass Spinning
T h e m a n d r e l d i a m ete r i s 7. 5 i n c h
(188mm).
The thickness of the pre -form is 0.5
inch.
T h e i n c l ud e d s e m i - a p ex a n g l e o f t h e
cone is 30 degree.
Wa l l t h i c k n e s s o f f i n i s h e d c o m p o n e n t
is 0.25 inch.
Multiple Pass Spinning
T h e s e m i - a p ex a n g l e o f t h e c o n e i s
less than 15 degree.
The thickness of the finished
c o m p o n e n t i s r e d u c e d s u c c e s s i ve l y i n
a c c o r d a n c e w i t h t h e s i n e l aw, to
0 .1 2 5 i n c h .
O r i g i n al b l a n k d i a m ete r i s r et a i n e d a t
the big end of the cone.
17. MANDREL
Mild steel mandrel
Stepped wooden mandrel
T h e m a n d r e l o r b u c k i s t h e f o r m o v e r w h i c h t h e s h e et m et a l b l a n k i s f o r m e d .
M o r e c o m p l ic a te d t h e f o r m o f t h e c o m p o n e n t , t h e g r e a te r t h e n e e d f o r c a r e i n
m a c hi n i n g t h e m a n d r e l .
C a n b e m a c h i n e d f r o m a v a r i et y o f m a te r i a l s , w o o d b e i n g t h e c h e a p e s t .
M a n d r e l s c a n a l s o b e m a d e o f m i l d s te e l o r a l u m i n i um, w h e n c l o s e to l e r a n c e s a r e
required.
I t i s i m p o r t a n t to d e s i g n t h e m a n d r e l w i t h a t l e a s t a 1 d e g r e e d r a f t a n g l e s o t h a t t h e
p a r t c a n b e r e m o v e d f r o m t h e m a n d r e l a f te r s p i n n i n g .
18. TOOLS
W i d e v a r i et y o f to o l p r o f i l e s c a n b e i m p l em e n te d f o r s p i n n i n g t h e m a te r i al i n to
d i f fe r e n t s h a p e s .
To o l s a r e p r o v i d e d w i t h l o n g h a n d l e s to p r o v i d e a m p l e l ev e r a g e to w o r k t h e
m a te r i al d o w n t h e m a n d r e l .
To o l s c a n b e u p to 3 f e et l o n g w i t h a 1 i n c h d i a m ete r s te e l r o d f o r g e d i n to t h e
p r e f e r r e d to o l t i p .
S p i n ni n g s h o p s m a ke u s e o f to o l s w i t h r o l l e r s m o u n ted o n t h e l o n g h a n d l e .
T h e p r i m ar y to o l s a r e t h e S h e e p ’s n o s e u s e d f o r m o s t o f t h e f o r m i n g a n d t h e
D u c k ’ s b i l l u s e d f o r f i n i s hi n g o p e r a t i o n .
Duck’s bill
Sheep’s nose
Roller-ended tool
19. LUBRICANTS
Lu b r i c a n t s a r e e s s e n t i a l i n a l l m et a l s p i n n i n g o p e r a t i on s , r e g a r d l e s s o f t h e
p r e f o r m s h a p e o r c o m p o s i t i o n o r t h e t y p e o f m et a l s p i n n i n g to o l s t h a t a r e b e i n g
used.
Fa c i l i t a te s e a s y r e m o va l o f t h e p a r t f r o m t h e m a n d r e l a n d a l s o h e l p i m p r ove
surface finish of finished component.
P a r t s a r e l u b r i c a te d b o t h b e fo r e a n d d u r i n g t h e s p i n n i n g o p e r a t i o n .
C o m m o n l y u s e d l u b r i ca n t s i n c l ud e w a x , t a l l ow s , s o a p s a n d g r e a s e .
I n s e l e c t i o n o f t h e m o s t s u i t a b l e l u b r i c a n t , t h e e a s e o f r e m o va l o f t h e s a m e a f te r
t h e f o r m i n g p r o c e s s h a s to b e c o n s i d e r e d .
Cup Grease
Tallow
20. MACHINES FOR SPINNING
Machines for spinning are specified by the diameter and length of the
largest component that can be spun.
They are also specified by the maximum load that can be applied to the
work .
The capacity of spinning machines ranges from 0.455m in diameter and
0.380m in length to 6m in diameter and 6m in length.
Metal spinning machines can be both ver tical or horiz ontal .
Machines used for spinning large diameter s, such as 1 .8m or more are
usually ver tical.
Mostly lathe based machine tools ( both conventi onal and CNC -based) are
employed for spinning operation.
Most modern machines used for spinning are at least semi-automated ;
that is, they are loaded and unloaded by the operator, but the entire
spinning cycle is controlled automaticall y.
21. Schematic diagrams of a vertical arrangement employed for spinning of large diameter cones.
22. SPINNING MACHINES
Horizontal lathe and mandrel
arrangement for spinning large-diameter
cone. Courtesy of Leifeld USA Metal
Spinning, Inc.
CNC metal spinning machine
Courtesy: Draft-Air India Pvt. Ltd.
Photograph of a 4m diameter cone and dish-shaped components
produced by the Leifeld Company.
23. COMPARISON WITH OTHER FORMING
PROCESSES
Low tooling cost compared to other forming techniques.
Conventional spinning also wastes a considerably smaller
amount of material than other methods .
The standard method of press forming the part requires eight
steps, as opposed to only three steps for spinning.
24. MERITS
P r o v i d e s n a t u r a l m et a l l ur g i c al b e n e f i t s , w i t h a r e f i n e d a n d s t r e n g t h e n e d g r a i n
s t r uc t ur e .
C o l d w o r k i n g o f t h e m et a l a l s o i n c r e a s e s te n s i l e p r o p e r t i e s a p p r e c i a b l y.
U n l i ke a c a s t i n g , a s p u n p a r t w i l l n o t b e d i s c a r d e d b y a h i d d e n b l o w h o l e o r i n c l us i o n .
A s p u n s h e l l c o u l d b e m a d e i n h a l v e s a n d w e l d e d to f o r m a s i n g l e u n i t w i t h o ut
c o m p l ex , ex p e n s i ve to o l i n g .
T h e to o l i n g c o s t s a n d c a p i t al i nv e s t m e n t s a r e r e l a t i v el y s m a l l .
T h e s et u p t i m e i s l e s s .
D e s i g n c h a n g e s i n t h e w o r k p i e c e c a n b e a c c o m m o d a te d a t r e l a t i ve l y l o w c o s t s .
C a n b e e a s i l y a u to m a te d a n d i s a n e f f e c t iv e p r o d uc t i o n m et h o d f o r p r o to t yp e s a s
w e l l a s h i g h p r o d uc t io n r u n s .
S i n c e t h e r e i s n o r e m o v al o f m et a l b y f o r m a t i o n o f c h i p s , t h e r e i s n o m a te r i a l
w a s t a g e a n d t h e p r o c e s s i s e c o n o m i c al .
25. DE-MERITS
Requirement of highly trained operators in manual spinning
process, for, the uniformity of the product depends to a large
degree on the skill of the operator.
Manual metal spinning is usually significantly slower than
press forging.
Deformation loads allowable are much lower in metal
spinning than in press forging.
26. APPLICATIONS
The following are examples of products that
can be manufactured by metal spinning:
Vases, baskets, basins and bowls.
Bottoms for tanks, hoppers and kettles.
Housings for blowers, fans, filters and fly wheels.
Ladles, nozzles, orifices and tank outlets.
Cones, cover s and cups.
Funnels, cylinder s, domes and drums.
Rings, hemispheres and shells.
Vents, venturis and fan wheels.
27. CONCLUSIONS
Metal spinning techniques and mechanics have been
presented.
Equipment for spinning is based on lathe technology.
Wide range of products can be obtained using this technique.
Metal Spinning is competitive with other forming processes
such as pressing and deep drawing.
It is an economical technique to produce both simple and
complicated parts for single application, low -volume
production as well as mass productions.
Process technology, equipment and tooling for spinning have
been discussed.