Zinc - The easiest alloy to cast, it offers high ductility,zinc die casting high impact strength and is easily plated. Zinc is economical for small parts, has a low melting point and promotes long die life.

Aluminum - This alloy is lightweight, while possessing high dimensional stability for complex shapes and thin walls. Aluminum has good corrosion resistance and mechanical properties, high thermal and electrical conductivity, as well as strength at high temperatures.Aluminum die casting

Magnesium - The easiest alloy to machine, magnesium has an excellent strength-to-weight ratio and is the lightest alloy commonly die cast.

Copper - This alloy possesses high hardness, high corrosion resistance and the highest mechanical properties of alloys cast. It offers excellent wear resistance and dimensional stability, with strength approaching that of steel parts.die casting

Lead and Tin - These alloys offer high density and are capable of producing parts with extremely close dimensions. They are also used for special forms of corrosion resistance.al die casting.

Die casting  vs. sand casting - Die casting produces parts with thinner walls, closer dimensional limits and smoother surfaces.al die casting Production is faster and labor costs per casting are lower. Finishing costs are also less.

Die casting  vs. permanent mold - Die casting  offers the same advantages versus permanent molding as it does compared with sand casting.

Die casting  vs. forging -Die casting produces more complex shapes with closer tolerances, al die casting thinner walls and lower finishing costs. Cast coring holes are not available with forging.

Die casting vs. stamping - Die casting produces complex shapes with variations possible in section thickness. al die casting One casting may replace several stampings, resulting in reduced assembly time. zinc die casting

Die casting vs. screw machine products -Die casting produces shapes that are difficult or impossible from bar or tubular stock, while maintaining tolerances without tooling adjustments.Die casting requires fewer operations and reduces waste and scrap.

High-speed production - Die casting provides complex shapes within closer tolerances than many other mass production processes. Little or no machining is required and thousands of identical al die castings can be produced before additional tooling is required.

Dimensional accuracy and stability - Die casting produces parts that are durable and dimensionally stable, while maintaining close tolerances. They are also heat resistant.

Strength and weight - Die cast parts are stronger than plastic injection moldings having the same dimensions. Thin wall castings are stronger and lighter than those possible with other casting methods. Plus, because die castings do not consist of separate parts welded or fastened together, the strength is that of the alloy rather than the joining process al die casting.

Multiple finishing techniques - Die cast parts can be produced with smooth or textured surfaces, and they are easily plated or finished with a minimum of surface preparation.

Simplified Assembly - Die castings provide integral fastening elements, such as bosses and studs. Holes can be cored and made to tap drill sizes, or external threads can be cast.

Die casting is an efficient, economical process offering a broader range of shapes and components than any other manufacturing technique. Parts have long service life and may be designed to complement the visual appeal of the surrounding part. Designers can gain a number of advantages and benefits by specifying die cast parts.

High-speed production - Die casting provides complex shapes within closer tolerances than many other mass production processes. Little or no machining is required and thousands of identical al die castings can be produced before additional tooling is required.

Dimensional accuracy and stability - Die casting produces parts that are durable and dimensionally stable, while maintaining close tolerances. They are also heat resistant.

Strength and weight - Die cast parts are stronger than plastic injection moldings having the same dimensions. Thin wall castings are stronger and lighter than those possible with other casting methods. Plus, because die castings do not consist of separate parts welded or fastened together, the strength is that of the alloy rather than the joining process al die casting.

Multiple finishing techniques - Die cast parts can be produced with smooth or textured surfaces, and they are easily plated or finished with a minimum of surface preparation.

Simplified Assembly - Die castings provide integral fastening elements, such as bosses and studs. Holes can be cored and made to tap drill sizes, or external threads can be cast.

Vacuum die casting utilizes a controlled vacuum to extract
gases from the die cavities and runner system during metal injection.
This process works to minimize the quantities of Entrained and
Lube as defined in Equation 1.3. Porosity due to entrapped gases
is virtually eliminated.al die casting
Squeeze casting is characterized by the use of a large gate area
and planar filling of the metal front within the die cavity. As with
vacuum die casting, this process works to minimize the quantities
of Entrained and Lube as noted in Equation 1.3. The mechanism,
however, is much different. Planar filling allows gases to escape
from the die, as vents remain open throughout metal injection.
Furthermore, the large gate area allows metal intensification pressure
to be maintained throughout solidification, reducing the magnitude
of V* as defined in Equation 1.2. Both porosity from
entrapped gas and solidification shrinkage are reduced by using
squeeze casting.
Semi-solid metalworking is the most complex of the high integrity
die casting processes. During semi-solid metalworking a
partially liquid–partially solid metal mixture is injected into the
die cavity. The fill front is planar, minimizing gas entrapment, as
in squeeze casting. Moreover, solidification shrinkage is greatly
reduced, as a significant portion of the metal injected into the die
cavity is already solid. Semi-solid metalworking addresses both
sides of the porosity relationship defined in Equation 1.1.
In addition to reducing porosity, a unique microstructure is generated
during semi-solid metalworking. The mechanical properties
inherent to this microstructure are superior to those created in
conventionally die cast components.al die casting
Products produced using high integrity die casting processes
have little or no porosity. Moreover, the mechanical properties are
much improved in comparison to conventional die cast components.
This is due to reduced levels of porosity, the viability of
subsequent heat treating, and formation of microstructures not
possible with the conventional zinc die casting process.

al die casting ,zinc die casting ,die casting ,machining components , ikd

train. machining Components,Note in Figure 2 that the keyway and close-fitting bore also were made with the abrasive
waterjet.
Figure 3 is a planetary gear system in which the round holes
in the planets are used to carry workpieces in a lapping
machine. The total time to make the entire system in 1/8-in.
steel was less than 40 minutes.machining Components
Figure 4 is an internal gear driven by a spur gear for an
application in a winch. In this case, the key is built into the
spur gear rather than using a keyway. Note that the ratchet
and pawl also are abrasive waterjet machine-made parts.
Even odd-shaped gears can be made by an abrasive
waterjet, which also can form racks and mating gear sectors
in a manner that easily facilitates a linear motion by pulling a
lever.
Sprockets and Chains
Ordinarily you would not make your own chain, but what if
you wanted to lift 300 tons? You then would be forced to make your own. Links in the chain in
shown in Figure 5 were made with an abrasive waterjet and assembled into a chain that can lift a
300-ton object.machining Components
It would be more common to make a sprocket and
buy the chain. Sprocket geometry can be found in
Machinery's Handbook, and it is quite easy to
follow the specifications, machining Components,draw the desired sprocket,
and produce it with an abrasive waterjet.
Cams
With the advent of low-cost servo drives and
control systems, cams are used less than they
were in earlier times, but they still provide a lowcost
means of making particular motion profiles.
Cams also can be used as wedging mechanisms
for locking movable elements in place.
Cams can be made very quickly on an abrasive
waterjet. The major portion of the work is
determining the desired cam shape. Once the
shape is known, making the cam is as simple as
loading the CAD file into the machine and pressing
go[START?].machining Components
Figure 6 shows a cam ready to be cut according to the function:
R = 2 + Sin(Theta)
machining Components,A hole with a keyway has been added so the cam can provide a reciprocating motion.
Springs and Flexures
Two types of springs can be made on an abrasive waterjet. One type flexes normal to the plane of
the X-Y table, and the other flexes parallel to it. Figure 7 shows a spiral spring typically made from
a thin sheet of heat-treated spring stock. The spring is held on its outer diameter, and the moving
member is attached to the central hole. machining Components,The spring is very rigid in the radial direction, but quite
flexible in the axial direction. If two such springs are placed a short distance apart, one above the
other, they provide a quite good flexural bearing for limited motion.

An article published previously on
thefabricator.com, How one shop benefited from
abrasive waterjet technology, presented novel
construction techniques that can be implemented
effectively with an abrasive waterjet machining Components to
lower the costs of building fabricated structures.
But abrasive waterjet machines can be used to
make machining Components, too, such as gears and parts
with gear segments; sprockets and chains; cams;
ratchets; springs and flexures; keys and keyways;
wrenches; hand wheels; clamps; brake disks; and
even signs and labels that might be added to a
structure to form a completed machine. These
machining Components, which formerly may have been made
using conventional machining techniques, now can
be made cost-effectively in a fabrication shop with
an abrasive waterjet.
The key to producing many of these machine elements successfully is using precision waterjet
equipment. Many components also require the taper-free cutting discussed in the article Improving
waterjet cutting precision by eliminating taper.
Since most modern abrasive waterjet machining Components make parts directly from a CAD file (usually a 2-D
dxf file), the ease of making the part depends on how easy it is to make the CAD file. Many good
CAD programs are available. This article presents design ideas only and is not intended to promote
a particular CAD program.
Gearing
An abrasive waterjet usually is not thought of as a gear-making machining Components, but a gear tooth is just
one particular shape that can be made easily with an abrasive waterjet. A precision abrasive
waterjet often can stay within 0.001 in. of the desired contour, and an ordinary machine can stay
within 0.005 in. For many applications this tolerance is sufficient.