Freezing begins ends Temperature & Density for Castings B · Manufacturing Processes for Engineering Materials, ... Temperature & Density for Castings ... Manufacturing Processes
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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.
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 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.
FIGURE 5.3 Phase diagram for nickel-copper alloy system obtained by a low rate of solidification. Note that pure nickel and pure copper each have one freezing or melting temperature. The top circle on the right depicts the nucleation of crystals; the second circle shows the formation of dendrites; and the bottom circle shows the solidified alloy with grain boundaries.
FIGURE 5.4 (a) The iron-iron carbide phase diagram. (b) Detailed view of the microstructures above and below the eutectoid temperature of 727°C (1341°F). Because of the importance of steel as an engineering material, this diagram is one of the most important phase diagrams.
FIGURE 5.5 Schematic illustration of three cast structures of metals solidified in a square mold: (a) pure metals, with preferred texture at the cool mold wall. Note in the middle of the figure that only favorable oriented grains grow away from the mold surface; (b) solid-solution alloys; and (c) structure obtained by heterogeneous nucleation of grains.
FIGURE 5.6 Schematic illustration of alloy solidification and temperature distribution in the solidifying metal. Note the formation of dendrites in the semi-solid (mushy) zone.
FIGURE 5.7 Schematic illustration of three basic types of cast structures: (a) columnar dendritic; (b) equiaxed dendritic; and (c) equiaxed nondendritic. Source: After D. Apelian.
FIGURE 5.9 Schematic illustration of cast structures in (a) plane front, single phase, and (b) plane front, two phase. Source: After D. Apelian.
(a) (b) (c)
SolidSolidSolid Liquid Liquid LiquidMoldwall
(a)
Solid LiquidMoldwall Liquid
(b)
FIGURE 5.8 Schematic illustration of three basic types of cast structures: (a) columnar dendritic; (b) equiaxed dendritic; and (c) equiaxed nondendritic. Source: After D. Apelian.
FIGURE 5.12 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: After H.F. Taylor, J. Wulff, and M.C. Flemings.
FIGURE 5.13 Mechanical properties for various groups of cast alloys. Compare with various tables of properties in Chapter 3. Source: Courtesy of Steel Founders' Society of America.
Typical lead time2,3 Days Weeks weeks Days Weeks Weeks Weeks- Monthsmonths
Typical production rate2,3 1-20 5-50 1-20 1-10 1-1000 5-50 2-200 1-1000Minimum quantity2,3 1 100 500 10 10 1000 10,000 10-10,000Notes:1. Relative rating, 1 best, 5 worst. For example, die casting has relatively low porosity, mid- to low shape complexity, high dimensionalaccuracy, high equipment and die costs and low labor costs. These ratings are only general; significant variations can occur dependingon the manufacturing methods used.2. Data taken from Schey, J.A., Introduction to Manufacturing Processes, 3rd ed, 2000.3. Approximate values without the use of rapid prototyping technologies.
FIGURE 5.14 Microstructure for cast irons. (a) ferritic gray iron with graphite flakes; (b) ferritic nodular iron, (ductile iron) with graphite in nodular form; and (c) ferritic malleable iron. This cast iron solidified as white cast iron, with the carbon present as cementite (Fe3C), and was heat treated to graphitize the carbon.
FIGURE 5.15 (a) The continuous-casting process for steel. Note that the platform is about 20 m (65 ft) above ground level. Source: American Foundrymen's Society. (b) Continuous strip casting of nonferrous metal strip. Source: Courtesy of Hazelett Strip-Casting Corp.
FIGURE 5.16 Schematic illustration of the sequence of operations in sand casting. (a) A mechanical drawing of the part, used to create patterns. (b-c) Patterns mounted on plates equipped with pins for alignment. Note the presence of core prints designed to hold the core in place. (d-e) Core boxes produce core halves, which are pasted together. The cores will be used to produce the hollow area of the part shown in (a). (f) The cope half of the mold is assembled by securing the cope pattern plate to the flask with aligning pins, and attaching inserts to form the sprue and risers. (g) The flask is rammed with sand and the plate and inserts are removed. (h) The drag half is produced in a similar manner. (j) The core is set in place within the drag cavity. (k) The mold is closed by placing the cope on top of the drag and securing the assembly with pins. (l) After the metal solidifies, the casting is removed from the mold. (m) The sprue and risers are cut off and recycled, and the casting is cleaned, inspected, and heat treated (when necessary). Source: Courtesy of Steel Founders' Society of America.
Cope ready for sand
Cope after rammingwith sand and
removing pattern,sprue, and risers
Drag readyfor sand
Drag afterremoving pattern
Core halvespasted together
(e) (f) (g) (h) (i)
Sprue
Risers
Flask
Drag with coreset in place
(j)
Cope and drag assembledand ready for pouring
(k)
Cope
Drag
Closingpins
Casting as removedfrom mold; heat treated
(l)
Casting readyfor shipment
(m)
(a)
Mechanical drawing of part Core boxesCope pattern plate Drag pattern plate
FIGURE 5.19 Schematic illustration of the vacuum-casting process. Note that the mold has a bottom gate. (a) before and (b) after immersion of the mold into the molten metal. Source: After R. Blackburn.
FIGURE 5.21 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.
FIGURE 5.22 Microstructure of a rotor that has been investment cast (top) and conventionally cast (bottom). Source: Advanced Materials and Processes, October 1990, p. 25. ASM International.
FIGURE 5.23 The pressure casting process, utilizing graphite molds for the production of steel railroad wheels. Source: Griffin Wheel Division of Amsted Industries Incorporated.
Airtightchamber
Ladle Refractory tube
Molten metal
Air pressure
Railroad wheelGraphite mold
FIGURE 5.24 Schematic illustration of the hot-chamber die-casting process.
FIGURE 5.25 Schematic illustration of the cold-chamber die-casting process. These machines are large compared to the size of the casting, because high forces are required to keep the two halves of the die closed under pressure.
FIGURE 5.26 Schematic illustration of the centrifugal casting process. Pipes, cylinder liners, and similarly shaped hollow parts can be cast by this process.
FIGURE 5.27 (a) Schematic illustration of the semicentrifugal casting process. Wheels with spokes can be cast by this 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.
FIGURE 5.29 Methods of casting turbine blades: (a) directional solidification; (b) method to produce a single-crystal blade; and (c) a single-crystal blade with the constriction portion still attached. Source: (a) and (b) After B.H. Kear, (c) Courtesy of ASM International.
FIGURE 5.30 Two methods of crystal growing: (a) crystal pulling (Czochralski process) and (b) floating-zone method. Crystal growing is especially important in the semiconductor industry. (c) A single-crystal silicon ingot produced by the Czochralski process. Source: Courtesy of Intel Corp.
FIGURE 5.31 (a) Schematic illustration of the melt-spinning process to produce thin strips of amorphous metal. (b) Photograph of nickel-alloy production through melt-spinning. Source: Courtesy of Siemens AG.
FIGURE 5.32 (a) Austenite to pearlite transformation of iron-carbon alloys as a function of time and temperature. (b) Isothermal transformation diagram obtained from (a) for a transformation temperature of 675°C (1247°F). (c) Microstructures obtained for a eutectoid iron-carbon alloy as a function of cooling rate. Source: Courtest of ASM International.
TABLE 5.7 Outline of heat treatment processes for surface hardening.
ElementMetals added to General Typical
Process hardened surface Procedure characteristics applicationsCarburizing Low-carbon
steel (0.2%C), alloy steels(0.08-0.2% C)
C Heat steel at 870-950!(1600-1750!F) in an at-mosphere of carboaceousgases (gas carburizing) orcarbon-containing solids(pack carburizing). Thenquench.
A hard, high-carbon surfaceis produced. Hardness 55-65 HRC. Case depth <0.5-1.5 mm (<0.020 to 0.060 in.).Some distortion of part dur-ing heat treatment.
FIGURE 5.35 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 larger volume of metal, as shown in (c).
FIGURE 5.37 (a) Suggested design modifications to avoid defects in castings. Note that sharp corners are avoided to reduce stress concentrations; (b, c, d) examples of designs showing the importance of maintaining uniform cross-sections in castings to avoid hot spots and shrinkage cavities.
FIGURE 5.39 Economic comparison of making a part by two different casting processes. Note that because of the high cost of equipment, die casting is economical mainly for large production runs. Source: The North American Die Casting Association.
FIGURE 5.40 (a) An engine block for a 60-hp 3-cylinder marine engine, produced by the lost-foam casting process; (b) a robot pouring molten aluminum into a flask containing a polystyrene pattern. In the pressurized lost-foam process, the flask is then pressurized to 150 psi (1000 kPa). Source: Courtesy of Mercury Marine