Exploring Advanced Manufacturing Technologies. Steve Krar. Читать онлайн. Newlib. NEWLIB.NET

Автор: Steve Krar
Издательство: Ingram
Серия:
Жанр произведения: Техническая литература
Год издания: 0
isbn: 9780831191573
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at which the parts are fed through the machine.

      ▪The diamond setover is calculated for proper contact line across the regulating wheel.

      Work Blade Setup

      Most work is centerless ground with its center above the centerline of the grinding wheel, Fig. 2-3-8. However, factors such as the part diameter, its physical characteristics, type, and diameter of the grinding wheel influence this setting. Generally for parts up to 1.00 in. diameter, adjust the blade until the part center is above the wheel center about one-half the part diameter. For larger diameter parts, the part center should rarely exceed .50 in.

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      If the part being ground is too high above the centerline of the wheels, chatter generally occurs. This is caused by the tendency of the wheels to raise the part out of contact with the workrest blade. If the height of the part above the center is reduced too much, the part is ground with three high spots.

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      The graph in Fig. 2-3-9 shows the Machine Power while the graph in Fig. 2-3-10 shows the Static Stiffness of the sample part ground in this example.

      For more information on GRINDING SIMULATOR e-mail: [email protected]

       CUTTING TOOLS AND ACCESSORIES

      Over the past three to four decades industry in the United States has been affected by intense global competition from industries using the latest technologies in their manufacturing methods. Superabrasive tooling, designed to increase productivity, produce better quality products, and reduce manufacturing costs, can cut and grind the hardest materials known.

      The fundamental cutting processes in machining - those of bringing the work into contact with the cutting tool - should remain mainstays of the industry. One of the most important components in the machining process is the cutting tool and its performance determines the efficiency of the operation. Modern tooling systems that can accommodate increased spindle speeds, higher feed rates, increased radial loads, modular adaptability, and profitable short part runs are required by manufacturers to stay competitive.

       SUPERABRASIVE TECHNOLOGY

      (Michael Flaman – Portland Community Colllege)

      Over the past three to four decades, industry in the United States has been greatly affected by intense global competition from offshore industries that are using the latest technologies in their manufacturing methods. Even though the United States continues to lead in the development of new technologies, other countries research, test, and implement them far sooner. Improved productivity and quality result in a larger share of the world market. Products that were previously produced in the United States are now being produced offshore; this has reduced employment opportunities in this country. U.S. industry must take advantage of the benefits of new technology as quickly as possible in order to maintain its leadership in manufacturing.

      The superabrasives, Diamond and Cubic Boron Nitride, possess properties unmatched by conventional grinding wheels and cutting tools for grinders, lathes, and machining centers. The hardness, abrasion resistance, compressive strength, and thermal conductivity of superabrasives makes them the logical choice for many difficult grinding, sawing, lapping, machining, drilling, wheel dressing, and wire drawing applications. Superabrasives can cut and grind the hardest materials known, making difficult material-removal applications routine operations. Superabrasive cutting tools are designed to meet the challenge of today by increasing productivity, producing better quality products, and reducing manufacturing costs.

      BACKGROUND

      In 1954, The General Electric Company (GE), after years of research, produced Man-Made® Diamond in the laboratory. Carbon and a catalyst, such as iron, chromium, cobalt, and nickel, were subjected to tremendous heat and pressure to form diamond crystals, Fig. 3-1-1. Because the temperature, pressure, and catalyst solvent can be varied, it is possible to produce diamond abrasive of various sizes, shapes, and crystal structure to suit a range of grinding applications on nonferrous and nonmetallic materials.

      In 1969, GE introduced an entirely new material, BORAZON® cubic boron nitride (CBN). Cubic boron nitride is synthesized in crystal form from hexagonal boron nitride and a catalyst using the same high pressure, high temperature technology perfected to produce diamond, Fig. 3-1-2. CBN, second only to diamond in hardness, is used for the grinding of hard alloy steels and other difficult to grind ferrous materials.

      MANUFACTURED DIAMOND

      Diamond is used for truing and dressing grinding wheels and for the manufacture of diamond wheels. The need for a reliable source of diamond during World War II was realized when natural diamond was not readily available.

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      To produce diamond by a manufacturing process, the conditions of pressure and temperature found far below the earth’s surface had to be duplicated. This required a high-pressure, high-temperature belt apparatus capable of reproducing the conditions necessary for diamond growth. Graphite (a form of carbon) and a catalyst (such as iron, chromium, cobalt, and nickel) were subjected to high temperatures (2550° to 4260°F, or 1400° to 2350°C) and high pressures (800,000 to 1,900,000 lbs./sq. in. of 55,000 to 130,000 atmospheres) to form diamond crystals, Fig. 3-1-3. Under these conditions, the graphite is transformed into diamond and remains that way when it is cooled and the pressure is removed.

      Types of Manufactured Diamond

      There are many different types of manufactured diamond to suit various grinding applications.