|
|
|
Home > Education > CES EduPack > Software > Sample records
High Pressure Die casting
General
| DESIGNATION |
Casting: die casting |
| THE PROCESS |
In PRESSURE DIE CASTING, molten metal is injected
under high pressure into a metal die through a system of sprues and runners
and pressure is maintained during solidification.
Afterwards, the die halves are opened and the casting is ejected. Because of
the high pressures involved, the two die halves are held together by a high force
and locked with toggle clamps.
The dies are precision machined from heat resistant steel and are water-cooled.
They often include several movable parts and are therefore complex and expensive.
Two types of die casting machines are used. In the 'hot chamber' or gooseneck
process, the molten metal is held in a furnace in which a gooseneck chamber is
submerged. Upon each cycle, the gooseneck is filled with metal which is then
forced into the die.
Because of the prolonged contact between the metal and the injection system,
this process is restricted to zinc-base alloys.
In the 'cold chamber' process (see figure above), metal is melted in a separate
furnace and then transported to the die casting machine. The cold chamber process
can be used for a variety of alloys.
Because of internal porosity, die castings cannot be heat-treated. The process
is very competitive for producing large quantities of thin-walled castings. |
 |
Pressure die casting |
| PHYSICAL ATTRIBUTES |
| Mass range |
0.05 |
- |
15 |
kg |
Range of section thickness |
1 |
- |
8 |
mm |
| Tolerance |
0.15 |
- |
0.5 |
mm |
| Roughness |
0.8 |
- |
1.6 |
µm |
| Adjacent section ratio |
1 |
- |
2 |
|
| Aspect ratio |
1 |
- |
30 |
|
| Minimum hole diameter |
2 |
|
|
mm |
| Minimum corner radius |
0.25 |
|
|
mm |
| Quality factor (1-10) |
1 |
- |
6 |
|
| ECONOMIC ATTRIBUTES |
Economic batch size (mass) |
4000 |
- |
8e5 |
kg |
Economic batch size (units) |
5000 |
- |
1e6 |
|
| |
| COST MODELLING |
Relative cost index (per unit) |
13.74 |
- |
80.76 |
|
Parameters: Material
Cost = 5.437GBP/kg, Component Mass = 1kg, Batch Size = 1000,
Overhead Rate = 62.95GBP/hr, Capital Write-off Time = 5yrs, Load
Factor = 0.5
 |
Capital cost |
1.079e5 |
- |
5.394e5 |
GBP |
Lead time |
4 |
- |
8 |
week(s) |
Material utilization fraction |
0.75 |
- |
0.85 |
|
Production rate (mass) |
16 |
- |
480 |
kg/hr |
Production rate (units) |
2e4 |
- |
1e6 |
/hr |
Tool life (mass) |
1.6e4 |
- |
8e5 |
kg |
Tool life (units) |
2e4 |
- |
1e6 |
|
Tooling cost |
4855 |
- |
7.012e4 |
GBP |
| |
| PROCESS CHARACTERISTICS |
Primary
|
True |
Secondary
|
False |
Tertiary
|
False |
Prototyping
|
False |
Discrete
|
True |
Continuous
|
False |
| |
| SHAPE |
Circular prismatic |
True |
Non-circular prismatic |
True |
Solid 3-D |
True |
Hollow 3-D |
True |
| |
SUPPORTING INFORMATION |
Design guidelines |
|
|
|
|
Shape complexity can be high, but
elaborate movable cores increase tooling cost. |
| |
Technical notes |
Usually restricted to lower melting
point alloys (Tm<1200K); most usually aluminum and zinc alloys.
High melting point alloys can be processed with a variant called
the Ferro Di process
Wall thicknesses should be as uniform as possible. Excellent surface
detail. Die castings are not renowned for their metallurgical integrity.
Turbulent filling and fast cycles mean that castings exhibit gas
and shrinkage porosity. |
| |
Typical uses |
Automotive applications: carburetor
and distributor bodies, clutch and gearbox housings; electrical
applications: motor frames and cases, switchgear housings; general
applications: pulleys, rotating parts, record player parts, etc. |
| |
The economics |
Tooling cost range covers small,
simple to large, complex dies. Production rate depends on complexity
of component and number of cavities. |
Links |
MaterialUniverse
|
| Reference |
Shape |
Structural Sections |
No warranty is given for the accuracy
of this data. Values marked * are estimates. |
|
|
Print this article 