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Chapter 5: MetalCasting Processes and Equipment Heat Treatment

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FIGURE 5.1 (a) Temperature as a function of time for the ... ( b) Continuous strip casting of nonferrous metal strip. Source: Hazelett Strip Casting Corp. ... – PowerPoint PPT presentation

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Title: Chapter 5: MetalCasting Processes and Equipment Heat Treatment


1
Chapter 5 Metal-Casting Processes and
Equipment Heat Treatment
2
Solidification of Pure Metals
  • FIGURE 5.1 (a) Temperature as a function of
    time for the solidification of pure metals. Note
    that freezing takes place at a constant
    temperature. (b) Density as a function of time.

3
Grains of a Two-Phase System
  • FIGURE 5.2 (a) Schematic illustration of
    grains, grain boundaries, and particles dispersed
    throughout the structure of a two-phase system,
    such as lead-copper alloy. The grains represent
    lead in a solid solution of copper, and the
    particles are lead as a second phase. (b)
    Schematic illustration of a two-phase system
    consisting of two sets of grains dark and light.
    Dark and light grains have their own compositions
    and properties, respectively.

4
Iron-Iron-Carbide Phase Diagram
  • FIGURE 5.4 The iron-iron-carbide phase diagram.
    Because of the importance of steel as an
    engineering material, this diagram is one of the
    most important phase diagrams.

5
Open and Closed Molds
6
Sand Casting Sequence
7
Features of a Sand Mold
  • FIGURE 5.14 Schematic illustration of a sand
    mold, showing various features.

8
Types of Patterns Used in Sand Casting
9
Temperature Distribution at Mold Wall in Casting
  • FIGURE 5.15 Temperature distribution at the
    mold wall and liquid-metal interface during
    solidification of metals in casting.

10
Solidified Skin on Steel Casting
  • FIGURE 5.16 Solidified skin on a steel casting.
    The remaining molten metal is poured out at the
    times indicated in the figure. Hollow ornamental
    and decorative objects are made by a process
    called slush casting, which is based on this
    principle. Source H. F. Taylor, J. Wulff, and M.
    C. Flemings.

11
Volumetric Solidification Contraction
  • TABLE 5.1 Volumetric solidification contraction
    or expansion percentages for various cast metals.

12
Shrinkages in the Casting
13
Shrinkage in Casting
14
Various Types of Chills Used in Castings to
Eliminate Porosity
  • FIGURE 5.17 Various types of (a) internal and
    (b) external chills (dark areas at corners), used
    in castings to eliminate porosity caused by
    shrinkage. Chills are placed in regions where
    there is a large volume of metal, as shown in
    (c).

15
(No Transcript)
16
Continuous Casting
  • FIGURE 5.21 (a) The continuous-casting process
    for steel. Typically, the solidified metal
    descends at a speed of 25mm/s (1 in/s).Note that
    the platform is about 20 m (65 ft) above ground
    level. Source Metalcasters Reference and Guide,
    American Foundrymans Society. (b) Continuous
    strip casting of nonferrous metal strip. Source
    Hazelett Strip Casting Corp.

17
A Semipermanent Composite Mold
Operation Sequence of Making a Ceramic Mold
  • FIGURE 5.22 Schematic illustration of a
    semipermanent composite mold. Source Steel
    Castings Handbook, 5th ed., Steel Founders
    Society of America, 1980.

FIGURE 5.23 Sequence of operations in making a
ceramic mold. Source Metals Handbook, 8th ed.,
Vol. 5 Forging and Casting, Materials Park, OH
ASM International, 1970.
18
Vacuum-Casting Process
  • FIGURE 5.24 Schematic illustration of the
    vacuum-casting process. Note that the mold has a
    bottom gate. (a) Before and (b) after immersion
    of the mod into the molten metal. Source After
    R. Blackburn.

19
Investment Casting
  • FIGURE 5.25 Schematic illustration of
    investment casting (lost-wax process). Castings
    by this method can be made with very fine detail
    and from a variety of metals. Source Steel
    Founders Society of America.

20
Pressure-Casting Process
  • FIGURE 5.27 The pressure-casting process uses
    graphite molds for the production of steel
    railroad wheels. Source Griffin Wheel Division
    of Amsted Industries Incorporated.

21
Die Casting in Hot-Chamber Process
  • FIGURE 5.28 Sequence of steps in die casting of
    a part in the hot-chamber process. Source
    Courtesy of Foundry Management and Technology.

22
Die Casting in Cold-Chamber Process
  • FIGURE 5.29 Sequence of operations in die
    casting of a part in the cold-chamber process.
    Source Courtesy of Foundry Management and
    Technology.

23
Centrifugal Casting Process
  • FIGURE 5.30 Schematic illustration of the
    centrifugal casting process. Pipes, cylinder
    liners, and similarly shaped parts can be cast by
    this process.

24
Semicentrifugal Casting Process
  • FIGURE 5.31 (a) Schematic illustration of the
    semicentrifugal casting process. (b) Schematic
    illustration of casting by centrifuging. The
    molds are placed at the periphery of the machine,
    and the molten metal is forced into the molds by
    centrifugal forces.

25
Squeeze-Casting Process
  • FIGURE 5.32 Sequence of operations in the
    squeeze-casting process. This process combines
    the advantages of casting and forging.

26
Melt-Spinning Process
  • FIGURE 5.35 Schematic illustration of the
    melt-spinning process to produce thin strips of
    amorphous metal.

27
Casting Processes
TABLE 5.8 Casting processes, and their
advantages and limitations.
28
Guidelines for Casting Design
  • Risers Major concern is the size and placement
    of risers. Based on experience and considerations
    of fluid flow and heat transfer.
  • Corners, angles and section thickness Sharp
    cornes, angles and fillets should be avoided,
    because they may cause cracking and tearing
    durinf solidfication of the metal.
  • Flat Areas Large flat areas should be avoided,
    they cause warp, poor surface finish.
  • Shinkage Allowance for shrinkage should be
    provided to avoid cracking. Pattern makers
    shrinkage allowance 10 to 20 mm/m.
  • Parting Lines Should be along a flat plane,
    rather than contoured, should be at the corners
    or edges, rather than on flat surface in the
    middle of the casting.
  • Drafter (taper) is provided in sand-mold pattern
    to enable remove of the pattern. Draft angle
    0.50 20.
  • Machining Allowance increasing with the size and
    section thickness as usually from 2 5 mm for
    small to more than 25 mm for large castings.

29
Design Modifications to Avoid Defects in Castings
  • FIGURE 5.39 (a) Suggested design modifications
    to avoid defects in castings. Note that sharp
    corners are avoided to reduce stress
    concentrations. (b)-(d) Examples of designs that
    show the importance of maintaining uniform
    cross-sections in castings to avoid hot spots and
    shrinkage cavities.

30
Casting Design Modifications
  • FIGURE 5.40 Examples of casting design
    modifications. Source Steel Castings Handbook,
    5th ed., Steel Founders Society of America,
    1980. Used with permission.

31
Design Practices for Die-cast Parts
  • FIGURE 5.41 Examples of undesirable and
    desirable design practices for die-cast parts.
    Note that section-thickness uniformity is
    maintained throughout the part. Source Courtesy
    of The North American Die Casting Association.

32
Costs Comparison for Different Casting Processes
  • FIGURE 5.42 Economic comparison of making a
    part by different casting processes. Note that
    because of the high cost of equipment, die
    casting is economical for large production runs.
    Source The North American Die Casting
    Association.
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