Orbital forging, also known as rotary forging, is a forging process where one die rotates relative to the other, gradually deforming the workpiece into the final shape. The tilt angle between the dies determines the amount of forging force applied. While orbital forging requires less force than conventional forging, the process is limited to symmetrical parts due to complex die motions required for asymmetrical shapes. Common applications include gears, hubs, and thin disks. Advantages include lower forces, accuracy, and tooling costs compared to conventional forging.
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ORBITAL FORGING
1. NATIONAL INSTITUTE OF FOUNDRY & FORGE TECHNOLOGY ,
RANCHI
ORBITAL FORGING
- Presented By
SHASHANK KULSHRESTHA
M.TECH (2016-18), FF16M12
FOUNDRY & FORGE TECHNOLOGY
2. ORBITAL FORGING
• Orbital forging is a two-die
forging process that deforms only
a small portion of the workpiece
at a time in a continuous manner.
• Also known as Rotary Forging.
3.
4. Process Details
• In rotary forging the axis of the upper die is
tilted at a slight angle with respect to the axis of
the lower die called tilt angle, causing the
forging force to be applied to only a small area
of the workpiece.
• As one die rotates relative to the other, the
contact area between die and workpiece,
termed the footprint, continually progresses
through the workpiece, gradually deforming it
until a final shape is formed.
5. Significance of Tilt Angle
• The tilt angle between the two dies plays a
major role in determining the amount of
forging force that is applied to the workpiece.
continued….
6. Larger tilt angle
Smaller footprint
Smaller force
required to complete the same deformation as
compared to a larger contact area.
&
vice-versa
Continued…….
7. Can we take too large tilt angle, to decrease the
forging force ?
• The larger the tilt angle the more difficult are the
machine design and maintenance problems,
because the drive and bearing system for the
tilted die is subjected to large lateral loads and is
more difficult to maintain.
• In addition, a larger tilt angle causes greater
frame deflection within the forge, making it
difficult to maintain a consistently high level of
precision.
• So,tilt angles are commonly about 1 to 2°.
9. Rotating Die Forging
• In rotating-die forges, both dies rotate about
their own axis, but neither die rocks or
precesses about the axis of the other die.
10. Rocking Die Forging
• In rocking-die, or orbital, forges, the upper die
rocks across the face of the lower die in a variety
of fashions.
• The most common form is where the upper die
orbits in a circular pattern about the axis of the
lower die.
• In this case, the upper die can also either rotate
or remain stationary in relation to its own axis.
• Other examples of rocking-die motion include the
rocking of the upper die across the workpiece in a
straight, spiral, or planetary pattern.
14. •Orbital (circular) motion - most commonly used,
especially when forging have relatively thin
parts,where high deformation is needed throughout
the whole part volume.
• Planetary Motion- For parts with large ribs and
flanges.
•Spiral motion -suitable for parts in which most
material flow occurs in central region.
•Straight line motion -convenient for long, narrow
parts.
15. Applications
• Rotary forging is generally considered to be a
substitute for conventional drop-hammer or
press forging.
• In addition,rotary forging can be used to
produce parts that would otherwise have to
be completely machined because of their
shape or dimensions.
• Currently, approximately one-quarter to one-
third of all parts that are either hammer or
press forged could be formed on a rotary
forge.
16. • These parts include symmetric and asymmetric
shapes.
• In the current technology, rotating or orbiting
die forges are mainly limited to the production
of symmetrical parts.
• Through a more complex die operation, rocking-
die forges are able to produce both symmetric
and asymmetric pieces.
17. Some typical parts manufactured in
orbital forging process
• Gears
• Hubs
• Flanges
• Cams
• Rings
• Tapered Rollers
• Thin disks & flat shapes
• Hexagonal shapes
18. Some typical parts manufactured
in orbital forging process
HUB Clutch Part
Bevel Gear
19.
20. Workpiece Materials
• Any material, ferrous or nonferrous, that has
adequate ductility and cold-forming qualities
can be rotary forged.
• These materials include -
carbon and alloy steels,
stainless steels,
brass,
aluminum alloys.
21. Advantages
• Low Axial Force - The primary advantage of rotary forging is in the low
axial force required to form a part. Because only a small area of the die is in
contact with the workpiece at any given time, rotary forging requires as little
as one-tenth the force required by conventional forging techniques.
• Lower machine and die deformation & Less die-
workpiece friction- due to smaller forging forces.
• High degree of accuracy - low equipment wear makes rotary
forging a precision production process that can be used to form intricate parts
to a high degree of accuracy.
• Relatively short operation time - Parts that require subsequent
finishing after conventional forging can be rotary forged to net shape in
one step.The average cycle time for a moderately complex part is 10 to
15s
A cycle time in the range of 10 to 15 s will yield approximately 300
pieces per hour.
22. • Lower tooling cost -Tooling costs for rotary forging are often
lower than those for conventional forging. Because of the lower forging
loads, die manufacture is easier, and the required die strength is much
lower. Die change and adjustment times are also much lower; dies can
be changed in as little as 15 min. These moderate costs make the
process economically attractive for either short or long production runs,
thus permitting greater flexibility in terms of machine use and batch
sizes.
• Less environmental hazards & complications -
Because impact is not used in rotary forging, there are fewer
environmental hazards than in conventional forging techniques.
Complications such as noise, vibrations, fumes, and dirt are virtually
non-existent.
• Can be cold forged -The smaller forging forces allow many
parts to be cold forged that would conventionally require hot forging,
resulting in decreased die wear and greater ease in handling parts after
forging. This is in addition to the favorable grain structure that results
from the cold working of metals.
23. Disadvantages
• Relative newness of the current technology- there is a need
for a convenient method of determining whether or not a piece can be
produced by rotary forging. Like other forging processes, the current process is
basically one of trial and error.
• High initial capital investment- A set of dies must be constructed
and tested for each part not previously produced by rotary forging in order to
determine whether or not the part is suitable for rotary forging.
• Constraints due to materials, specific shape & geometry
of parts- rotary forging may not be suitable for a variety of reasons like
the material may experience cracking during the forging process; the
finished part may undergo elastic spring-back; or there may be areas on
the workpiece that do not conform to the die contour, leaving a gap
between die and workpiece, such as central thinning.
24. • Design of rotary forge machines- a major problem lies in
the design of rotary forge machines. The large lateral forces associated
with the unique die motion make the overall frame design of the
machines more difficult. These large forces must be properly supported
by the frame in order for the forge to maintain a consistent level of
accuracy. Conventional forges present a less troublesome design problem
because they do not experience such a wide range of die motion.
25. CONCLUSION
• The rotary forges that are currently in use are
adequate for forming the parts that they
presently produce, but the accuracy of these
parts is not as great as it can be.
• Further research and additional production
experience are necessary before these forges
reach their full practical potential.