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Quiz 7

Quiz 7. Write down the 5 important steps involved in Powder Metallurgy. Grinding and Non-traditional machining. Grinding This is traditional Mfg. Application. Grinding uses abrasives which are small, hard particles having sharp edges (but irregular shapes).

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Quiz 7

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  1. Quiz 7 • Write down the 5 important steps involved in Powder Metallurgy

  2. Grinding and Non-traditionalmachining

  3. Grinding This is traditional Mfg. Application • Grinding uses abrasives which are small, hard particles having sharp edges (but irregular shapes). • Small amount of metal can be removed as tiny metal chips • Machine heat treated parts • Ceramic, glass • Weld beads • Semi-machined die surfaces

  4. Temperature rise • Very high temperature (3000oF) • Chips carry away the heat • Larger fraction of heat is conducted into workpiece • Effect of temp rise • More pronounced than metal cutting • Excessive temp rise caused by grinding can temper or soften hardened metal

  5. Centered cylindrical grinding Flat surface grinding

  6. Centerless grinding

  7. Grinding

  8. t = grain depth of cut l = length of undeformed chip

  9. Grinding wheels are made of abrasive powder such as • Aluminum Oxide (Al2O3) • Silicon Carbide (SiC) • CBN, Diamond, etc. • Cutting edges are extremely small. • Grain size is measured as grit size (100 – fine, 500 – very fine) • Grinding wheels have thousands of abrasive cutting edges

  10. Several types of bond is used to hold abrasive grains • Vitrified, Resinoid, Rubber, Metal bonds • Differences between single point cutting and grinding • Individual grain has an irregular geometry and is spaced randomly along the edge. • Radial position of the grains vary • Rake angle is negative (-60o), Shear angle is low. • Cutting Speed is very high (6000 ft/min)

  11. Burning- surface burning can occur (blemish color / oxidation) • Metallurgical burning can also occur – Martensite formation in high carbon steel • Thermal cracks • Residual Stresses • Temp change and gradient within the workpiece cause it. • Plastic deformation due to sliding of wear flat

  12. NONTRADITIONAL (OR) UNCONVENTIONAL MACHINING

  13. The requirements that lead to the development of nontraditional machining. • Very high hardness and strength of the material. (above 400 HB.) • The work piece is too flexible or slender to support the cutting or grinding forces. • The shape of the part is complex, such as internal and external profiles, or small diameter holes. • Surface finish or tolerance better than those obtainable conventional process. • Temperature rise or residual stress in the work piece are undesirable.

  14. Chemical Machining (CM) • Oldest nontraditional machining process. • material is removed from a surface by chemical dissolution using chemical reagents or etchants like acids and alkaline solutions. • Types of chemical machining 1. chemical Milling By selectively attacking different areas of work piece with chemical reagents shallow cavities can be produced on plates, sheets, forging and extrusion. 2. chemical blanking It is similar to blanking in sheet metals except material is removed by chemical dissolution rather than by shearing. Used in bur free etching of printed circuit boards, decorative panels etc.

  15. CHEMICAL MACHINING

  16. 3. Photochemical blanking This process is effective in blanking fragile work pieces and materials. Material is removed using photographic techniques. Applications are electric motor lamination, flat springs, masks for color television, printed circuit cards etc.

  17. ELECTROCHEMICAL MACHINING

  18. Electrochemical Machining • Reverse of electroplating • An electrolyte acts as a current carrier and high electrolyte movement in the tool-work-piece gap washes metal ions away from the work piece (anode) before they have a chance to plate on to the tool (cathode). • Tool – generally made of bronze, copper, brass or stainless steel. • Electrolyte – salt solutions like sodium chloride or sodium nitrate mixed in water. • Power – DC supply of 5-25 V.

  19. Advantages of ECM • Process leaves a burr free surface. • Does not cause any thermal damage to the parts. • Lack of tool force prevents distortion of parts. • Capable of machining complex parts and hard materials ECM systems are now available as Numerically Controlled machining centers with capability for high production, high flexibility and high tolerances.

  20. ELECTROCHEMICAL GRINDING

  21. Electrochemical Grinding (ECG) • Combines electrochemical machining with conventional grinding. • The equipment used is similar to conventional grinder except that the wheel is a rotating cathode with abrasive particles. The wheel is metal bonded with diamond or Al oxide abrasives. • Abrasives serve as insulator between wheel and work piece. A flow of electrolyte (sodium nitrate) is provided for electrochemical machining. • Suitable in grinding very hard materials where wheel wear can be very high in traditional grinding.

  22. ELECTRICAL DISCHARGE MACHINING

  23. Electrical discharge machining (EDM) • Based on erosion of metals by spark discharges. • EDM system consist of a tool (electrode) and work piece, connected to a dc power supply and placed in a dielectric fluid. • when potential difference between tool and work piece is high, a transient spark discharges through the fluid, removing a small amount of metal from the work piece surface. • This process is repeated with capacitor discharge rates of 50-500 kHz.

  24. dielectric fluid – mineral oils, kerosene, distilled and deionized water etc. role of the dielectric fluid 1. acts as a insulator until the potential is sufficiently high. 2. acts as a flushing medium and carries away the debris. 3. also acts as a cooling medium. • Electrodes – usually made of graphite. • EDM can be used for die cavities, small diameter deep holes,turbine blades and various intricate shapes.

  25. WIRE EDM

  26. Wire EDM • This process is similar to contour cutting with a band saw. • a slow moving wire travels along a prescribed path, cutting the work piece with discharge sparks. • wire should have sufficient tensile strength and fracture toughness. • wire is made of brass, copper or tungsten. (about 0.25mm in diameter).

  27. LASER BEAM MACHINING

  28. Laser beam machining (LBM) • In LBM laser is focused and the work piece which melts and evaporates portions of the work piece. • Low reflectivity and thermal conductivity of the work piece surface, and low specific heat and latent heat of melting and evaporation – increases process efficiency. • application - holes with depth-to-diameter ratios of 50 to 1 can be drilled. e.g. bleeder holes for fuel-pump covers, lubrication holes in transmission hubs.

  29. ELCTRON BEAM MACHINING

  30. Electron beam machining (EBM) • similar to LBM except laser beam is replaced by high velocity electrons. • when electron beam strikes the work piece surface, heat is produced and metal is vaporized. • surface finish achieved is better than LBM. • Used for very accurate cutting of a wide variety of metals.

  31. WATER JET MACHINING

  32. Water jet machining (WJT) • Water jet acts like a saw and cuts a narrow groove in the material. • Pressure level of the jet is about 400MPa. • Advantages - no heat produced - cut can be started anywhere without the need for predrilled holes - burr produced is minimum - environmentally safe and friendly manufacturing. • Application – used for cutting composites, plastics, fabrics, rubber, wood products etc. Also used in food processing industry.

  33. ABRASIVE JET MACHINING

  34. Abrasive Jet Machining (AJM) • In AJM a high velocity jet of dry air, nitrogen or CO2 containing abrasive particles is aimed at the work piece. • The impact of the particles produce sufficient force to cut small hole or slots, deburring, trimming and removing oxides and other surface films.

  35. ULTRASONIC MACHINING

  36. ULTRASONIC MACHINING (UM) • In UM the tip of the tool vibrates at low amplitude and at high frequency. This vibration transmits a high velocity to fine abrasive grains between tool and the surface of the work piece. • material removed by erosion with abrasive particles. • The abrasive grains are usually boron carbides. • This technique is used to cut hard and brittle materials like ceramics, carbides, glass, precious stones and hardened steel.

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