Mechanical Engineering Materials Book Pdf Free 52
Thechosen Wong
Materials Science and Mechanical Engineering at Harvard School of Engineering ranges from fundamental work in solid and fluid mechanics to diverse studies in materials, mechanical systems, and biomechanics. Characterizing the performance of such systems often depends on understanding behavior at several scales, requiring, for example, the mechanics of dislocations and other imperfections, grain boundaries, interfaces, and material heterogeneity.
Materials scientists and mechanical engineers at Harvard are pursuing work in the mechanics of materials structures; geophysical and biological systems involved in phenomena such as elasticity, plasticity, buckling, fracture, and wave motion; biological control, or the self-organizing behavior of living systems, in particular the brain, to develop novel control strategies and biologically-inspired machines; and biomedical instrumentation, teleoperated robots, and intelligent sensors.
Mechanical engineering covers a wide range of activities, including research in dynamics, fluids, materials, solids, and thermodynamics. Research is strongly interdisciplinary, with many connections to Applied Mathematics, Applied Physics, Earth and Planetary Sciences, and Chemistry and Chemical Biology.
Engineering materials refers to the group of materials that are used in the construction of manmade structures and components. The primary function of an engineering material is to withstand applied loading without breaking and without exhibiting excessive deflection. The major classifications of engineering materials include metals, polymers, ceramics, and composites. The important characteristics of the materials within each of these classes are discussed on this page, and tables of material properties are also provided.
Metals are the most commonly used class of engineering material. Metal alloys are especially common, and they are formed by combining a metal with one or more other metallic and/or non-metallic materials. The combination usually occurs through a process of melting, mixing, and cooling. The goal of alloying is to improve the properties of the base material in some desirable way.
Ferrous alloys have iron as the base element. These alloys and include steels and cast irons. Ferrous alloys are the most common metal alloys in use due to the abundance of iron, ease of production, and high versatility of the material. The biggest disadvantage of many ferrous alloys is low corrosion resistance.
Carbon steels are basically just mixtures of iron and carbon. They may contain small amounts of other elements, but carbon is the primary alloying ingredient. The effect of adding carbon is an increase in strength and hardness.
Low-carbon steel has less than about 0.30% carbon. It is characterized by low strength but high ductility. Some strengthening can be achieved through cold working, but it does not respond well to heat treatment. Low-carbon steel is very weldable and is inexpensive to produce. Common uses for low-carbon steel include wire, structural shapes, machine parts, and sheet metal.
Medium-carbon steel contains between about 0.30% to 0.70% carbon. It can be heat treated to increase strength, especially with the higher carbon contents. Medium-carbon steel is frequently used for axles, gears, shafts, and machine parts.
Low-alloy steels, also commonly called alloy steels, contain less than about 8% total alloying ingredients. Low-alloy steels are typically stronger than carbon steels and have better corrosion resistance.
Some low-alloy steels are designated as high-strength low-alloy (HSLA) steels. What sets HSLA steels apart from other low-alloy steels is that they are designed to achieve specific mechanical properties rather than to meet a specific chemical composition.
Tool steels are primarily used to make tooling for use in manufacturing, for example cutting tools, drill bits, punches, dies, and chisels. Alloying elements are typically chosen to optimize hardness, wear resistance, and toughness.
Stainless steels have good corrosion resistance, mostly due to the addition of chromium as an alloying ingredient. Stainless steels have a chromium composition of at least 11%. Passivation occurs with chromium content at or above 12%, in which case a protective inert film of chromic oxide forms over the material and prevents oxidation. The corrosion resistance of stainless steel is a result of this passivation.
Austenitic stainless steel is the most common form of stainless steel. It has the highest general corrosion resistance among stainless steels. It is also the most weldable of the stainless steels due to its low carbon content. It can only be strengthened through cold work. Austenitic stainless steels are generally more expensive than other stainless steels due to nickel content. Austenitic stainless steels are not magnetic, although ferritic and martensitic stainless steels are. Common applications include fasteners, pressure vessels, and piping.
Ferritic stainless steel has high chromium content and medium carbon content. It has good corrosion resistance rather than high strength. It generally cannot be strengthened through heat treatment, and can only be strengthened via cold work.
Martensitic stainless steel has high carbon content (up to 2%) and low chromium content. This higher carbon content is the primary difference between ferritic and martensitic stainless steels. Due to the high carbon content, it is difficult to weld. It can be strengthened through heat treatment. Common applications include cutlery and surgical instruments.
Duplex stainless steel contains both austenitic and ferritic phases. It can have up to twice the strength of austenitic stainless steel. It also has a high toughness, corrosion resistance, and wear resistance. Duplex stainless steel is generally as weldable as austenitic, but it has a temperature limit.
Precipitation-hardenable stainless steel can be strengthened through precipitation hardening, which is an age hardening process. These materials have high strength as well as high resistance to corrosion and temperature.
Cast iron is a ferrous alloy containing high levels of carbon, generally greater than 2%. The carbon present in the cast iron can take the form of graphite or carbide. Cast irons have a low melting temperature which makes them well suited to casting.
Gray cast iron is the most common type. The carbon is in the form of graphite flakes. Gray cast iron is a brittle material, and its compressive strength is much higher than its tensile strength. The fracture surface of gray cast iron has a gray color, which is how it got its name.
The addition of magnesium to gray cast iron improves the ductility of the material. The resulting material is called nodular cast iron because the magnesium causes the graphite flakes to form into spherical nodules. It is also called ductile cast iron. Nodular cast iron has good strength, ductility, and machinability. Common uses include crankshafts, gears, pump bodies, valves, and machine parts.
White cast iron has carbon in the form of carbide, which makes the material hard, brittle, and difficult to machine. White cast iron is primarily used for wear-resisting components as well as for the production of malleable cast iron.
Pure aluminum is soft and weak, but it can be alloyed to increase strength. Pure aluminum has good corrosion resistance due to an oxide coating that forms over the material and prevents oxidation. Alloying the aluminum tends to reduce its corrosion resistance.
Aluminum is a widely used material, particularly in the aerospace industry, due to its light weight and corrosion resistance. Despite the fact that aluminum alloys are generally not as strong as steels, they nevertheless have a good strength-to-weight ratio.
Aluminum alloys are named according to a 4-digit number, where the first number indicates the major alloying element. A processing code follows the 4-digit number, which indicates the condition and treatment of the material.
Copper alloys are generally characterized as being electrically conductive, having good corrosion resistance, and being relatively easy to form and cast. While they are a useful engineering material, copper alloys are also very attractive and are commonly used in decorative applications.
Copper alloys primarily consist of brasses and bronzes. Zinc is the major alloying ingredient in brass. Tin is a major alloying element in most bronzes. Bronzes may also contain aluminum, nickel, zinc, silicon, and other elements. The bronzes are typically stronger than the brasses while still maintaining good corrosion resistance.
The aluminum bronze alloys are very hard and have good wearing properties, and so are commonly used in bearing applications. The beryllium copper alloys have good strength and fatigue properties, and good wear resistance when lubricated properly. Beryllium copper is commonly used for springs, bearings, and bushings.
Titanium alloys are light, strong, and have high corrosion resistance. Their density is much lower than steel, and their strength-to-weight ratio is excellent. For this reason, titanium alloys are used fairly commonly, especially in the aerospace industry. One primary downside of titanium alloys is the high cost.
There are three categories of titanium alloys: alpha alloys, beta alloys, and alpha-beta alloys. Alpha alloys do not respond to heat treatment and are instead strengthened through solid-solution strengthening processes. The beta and alpha-beta alloys can be strengthened by heat treatment, primarily through precipitation hardening.
Polymers are materials that consist of molecules formed by long chains of repeating units. They may be natural or synthetic. Many useful engineering materials are polymers, such as plastics, rubbers, fibers, adhesives, and coatings. Polymers are classified as thermoplastic polymers, thermosetting polymers (thermosets), and elastomers.
The classification of thermoplastics and thermosets is based on their response to heat. If heat is applied to a thermoplastic, it will soften and melt. Once it is cooled, it will return to solid form. Thermoplastics do not experience any chemical change through repeated heating and cooling (unless the temperature is high enough to break the molecular bonds). They are therefore very well suited to injection molding.
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