Powder Metallurgy is one of the continuously and rapidly evolving
technology relating with most metallic and alloy material, and a wide range of
shape and sizes. Powder Metallurgy is a very developed way of manufacturing
reliable ferrous and non-ferrous products. The Europe Market single-handed has an
annual turnover of over Six Billion Euro, with annual metal powder production
exceeding one million tons.
Economical Advantage:
The rise of the P/M industry during the past few decade is highly recognizable to the cost savings related with net shape processing compared to other metal
working technique, such as casting or forging. In some case, the conversion of
a cast component to powder metal provides a cost savings of 40% or higher.
PM typically uses more than 97% of the starting raw material in the finished
part and is especially suited to high volume components production
requirements.
In the automotive sector, which consumes about 80% of structural PM part
production, the reason for choosing PM is, in the majority of cases, an
economic one.
PM process enables products to be made that are capable of absorbing up to 35%
of selected fluids.
Energy Savings
PM process:
Forging and
machining :
Cost Comparison
between PM and Forging:
Powder Metallurgy is one of the continuously and rapidly evolving
technology relating with most metallic and alloy material, and a wide range of
shape and sizes. Powder Metallurgy is a very developed way of manufacturing
reliable ferrous and non-ferrous products. The Europe Market single-handed has an
annual turnover of over Six Billion Euro, with annual metal powder production
exceeding one million tons.
Created by mixing elemental or alloy powders and compacting the mixture
in a die, the resultant shapes are then heated or "sintered" in a
controlled atmosphere furnace to bond the particles metallurgical. The high
precision forming capability of PM generates components with near net shape,
intricate features and good dimensional precision pieces are often finished
without the need of machining.
By producing parts with a homogeneous structure the PM process enables
manufacturers to make products that are more consistent and predictable in
their behavior across a wide range of applications. In addition the PM Process
has a high degree of flexibility allowing the tailoring of the physical
characteristics of a product to suit your specific property and performance
requirements. These include:
§ Structural pieces
with complex shapes
§ Controlled Porosity
§ Controlled
performance
§ Good performance in
stress and absorbing of vibrations
§ Special properties
such as hardness and wear resistance
§ Great precision and
good surface finish
§ Large series of
pieces with narrow tolerances
The unique flexibility of the PM process enables products to be made
from materials that are tailored to your specific needs. By using specially
selected materials this capability enables refinements to be engineered into
the mechanical properties of the part.
Economical Advantage:
The rise of the P/M industry during the past few decade is highly recognizable to the cost savings related with net shape processing compared to other metal
working technique, such as casting or forging. In some case, the conversion of
a cast component to powder metal provides a cost savings of 40% or higher.
PM typically uses more than 97% of the starting raw material in the finished
part and is especially suited to high volume components production
requirements.
There are two principal reasons for using a powder metallurgy product:
1.
cost savings compared with alternative processes, and
2.
unique properties attainable only by the PM route
In the automotive sector, which consumes about 80% of structural PM part
production, the reason for choosing PM is, in the majority of cases, an
economic one.
PM process enables products to be made that are capable of absorbing up to 35%
of selected fluids.
Why then is PM more
cost effective?
Better material utilization with close dimensional tolerances. Conventional
metal forming or shaping processes, against which PM competes, generally
involve significant machining operations from bar stock or from forged or cast
blanks.
These machining operations can be costly and are wasteful of material
and energy. This is illustrated in the figure below which shows that material
utilization in excess of 95% can be achieved with close dimensional tolerances.
Raw material utilization and energy requirements of various
manufacturing processes.
This is a comparison between various manufacturing processes (Casting,
Cold or Warm Extrusion, Hot Drop Forging, and Machining Processes) and PM
-sintering for a production of notch segments for truck transmission.
The PM process has:
§ The highest raw
material utilization (over 95%)
§ and the lowest
energy requirement per Kg of finished part
§ comparing with the
other manufacturing processes
Energy Savings
The energy savings alone contribute significantly to the economic
advantage offered by PM..
An example is given below for a notch segment used in a truck
transmission, where PM consumes only around 43% of the energy compared with
forging and machining and the number of process steps has been greatly reduced.
.
Comparison of the
PM Process and Forging and Machining (energy requirements and number of process
steps)
This is an example for a notch segment used in a truck transmission,
where:
§ PM consumes only around
43% of the energy compared with forging and machining, and
§ the number of
process steps has been greatly reduced
PM process:
Forging and
machining :
Cost Comparison
between PM and Forging:
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