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授課教師:楊宏智教授 1 【本著作除另有註明外,採取創用 CC 「姓名標示 -非商業性-相同方式分享」台灣 3.0 版授權釋出】創用 CC 「姓名標示 -非商業性-相同方式分享」台灣 3.0 版 【本著作除另有註明外,採取創用 CC 「姓名標示 -非商業性-相同方式分享」台灣 3.0 版授權釋出】創用 CC 「姓名標示 -非商業性-相同方式分享」台灣 3.0 版 【本著作除另有註明外,採取創用 CC 「姓名標示 -非商業性-相同方式分享」台灣 3.0 版授權釋出】創用 CC 「姓名標示 -非商業性-相同方式分享」台灣 3.0 版
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楊宏智(台大機械系教授) 2
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PART III: Forming and Shaping Processes and Equipment “Forming” indicates changing the shape of an existing solid body
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PART III: Forming and Shaping Processes and Equipment For forming processes, the starting material may be in the shape of a plate, sheet, bar, rod, wire, or tubing of various cross sections Shaping processes involve the molding and casting of molten materials and the finished product is near the final desired shape Molten metalis cast into individual ingots or continuously cast into slabs, rods, or pipes Cast structures are converted to wrought structures by plastic-deformation processes
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Cast Structure and Wrought Structure cast structure - solidification front moves thr the molten metal from the mold walls towards the center - at the mold walls the metal cools rapidly and produces solidified skin, or shell - brittle grain boundaries and internal defects are formed wrought structure - converted from cast structure by hot rolling - gives finer grains and enhanced ductility, improved strength resulting from breaking up brittle grain boundaries and closing up internal defects 5
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Chapter 13: Metal-Rolling Processes and Equipment
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Chapter Outline Introduction The Flat-rolling Process Flat-rolling Practice Rolling Mills Various Rolling Processes and Mills
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Introduction Rolling is the process of reducing the cross section of a long workpiece by compressive forces applied through a set of rolls ( 本圖表請參考 Manufacturing Engineering Technology in SI Units, 6th P.317 Figure 13.1 ) Slab: rectangular shape Billet: (< 6”) square or circular Bloom: (> 6”)
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Plates and Sheets Plates: 300mm>t>6mm reactor vessels(150mm) tanks (125mm) boiler supports (300mm) Sheets: t<6mm B747 (1.8mm) sedan (1.2-0.7mm) can (0.1mm) Al foil (0.008mm) Slab, Billet and Bloom
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The Flat-rolling Process Flat-rolling process is shown Friction forces act on strip surfaces Roll force, F, and torque, T, acts on the rolls ( 本圖表請參考 Manufacturing Engineering Technology in SI Units, 6th P.319 Figure 13.2 )
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The Flat-rolling Process As the surface speed of the rigid roll is constant, there is relative sliding between the roll and the strip along the arc of contact in the roll gap, L At neutral point or no-slip point, the velocity of the strip is the same as that of the roll The maximum possible draft is defined as the difference between the initial and final strip thicknesses From the relationship, higher the friction and the larger the roll radius, the greater the maximum possible draft becomes
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The Flat-rolling Process: Roll Force, Torque, and Power Requirements Rolls apply pressure on the flat strip to reduce its thickness, resulting in a roll force, F Roll force in flat rolling can be estimated from Total power (for two rolls) is L = roll-strip contact length w = width of the strip Y avg = average true stress of the strip
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Types of Rolling Based on workpiece geometry Flat rolling - used to reduce thickness of a rectangular cross section Shape rolling - square cross section is formed into a shape such as an I-beam Based on work temperature Hot Rolling – can achieve significant deformation Cold rolling – produces sheet and plate stock
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Hot Rolling process of reducing the thickness or changing the cross-section of a long workpiece by compressive forces thr a set of rolls Performed above recrystallization temp converted from cast structure to wrought structure gives finer grains and enhanced ductility, improved strength resulting from breaking up brittle grain boundaries and closing up internal defects
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Grain Structure During Hot Rolling ( 本圖表請參考 Manufacturing Engineering Technology in SI Units, 6th P.323 Figure 13.6 )
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The Flat-rolling Process: Roll Force, Torque, and Power Requirements Reducing Roll Force Roll forces can cause deflection and flattening of the rolls The columns of the roll stand may deflect under high roll forces Roll forces can be reduced by: 1. Reducing friction at the roll–workpiece interface 2. Using smaller diameter rolls 3. Reduce the contact area 4. Rolling at elevated temperatures 5. Applying front and/or back tensions to the strip
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The Flat-rolling Process: Roll Force, Torque, and Power Requirements ( 本圖表請參考 Manufacturing Engineering Technology in SI Units, 6th P.321 Figure 13.3 )
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The Flat-rolling Process: Geometric Considerations Roll forces will bend the rolls elastically during rolling crown: strip thicker at center - wavy edges or fractures in center Use of a “crowned” roll for compensation, When the roll bends, the strip has a constant thickness along its width
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The Flat-rolling Process: Geometric Considerations Equipment is massive and expensive Rolling mill configurations: Two-high – two opposing rolls Three-high – work passes through rolls in both directions Four-high – backing rolls support smaller rolls Cluster mill – multiple backing rolls on smaller rolls Tandem rolling mill – sequence of two-high mills
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Rolling Mill Configurations two-high rolling mill two-high reversing - used for hot rolling in initial breakdown passes on cast ingots or in continuous casting, with the direction of material movement is reversed after each pass. - drawbacks are the energy waste in reversing the roll rotation and time consuming in adjusting the roll gap
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Rolling Mill Configurations four-high rolling mill - smaller rolls require lower force (fig 18-4) to reduce spread and roll deflection - the smaller cross-section however provides reduced stiffness - when worn or broken smaller rolls replaced at lower cost - large back-up rolls are used to provide the necessary support for the smaller work rolls (reduce crown problem)
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Rolling Mill Automated mills produce close-tolerance, low cost and high quality plates and sheets at high production rates ( 本圖表請參考 Manufacturing Engineering Technology in SI Units, 6th P.326 Figure 13.10 )
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Rolling Mills Two-high rolling mills are used for hot rolling in initial breakdown passes (cogging mills) on cast ingots or in continuous casting In tandem rolling, the strip is rolled continuously through a number of stands to thinner gages with each pass
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Flat-rolling Practice: Defects in Rolled Plates and Sheets Defects may be present on the surfaces or there may be internal structural defects They are undesirable as they compromise surface appearance and adversely affect strength, formability, and other manufacturing characteristics Surface defects may be caused by inclusions and impurities in the original cast material Wavy edges on sheets are the result of roll bending Cracks are due to poor material ductility at the rolling temperature
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Flat-rolling Practice: Other Characteristics of Rolled Metals Residual Stresses Residual stresses develop in rolled plates and sheets due to nonuniform deformation of materials in roll gap
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The Flat-rolling Process: Geometric Considerations Spreading Increase in width is called spreading Spreading increases with: 1. Decreasing width-to-thickness ratio of the entering strip 2. Increasing friction 3. Decreasing ratio of the roll radius to the strip thickness
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The Flat-rolling Process: Vibration and Chatter Vibration and chatter have effects on product quality and the productivity of metalworking operations Chatter defined as self-excited vibration Occur in rolling and in extrusion, drawing, machining, and grinding operations Chatter results from interactions between the structural dynamics of the mill stand and the dynamics of the rolling operation Chatter can be reduced by increasing the roll radius, strip-roll friction and incorporating dampers in the roll supports
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Flat-rolling Practice: Other Characteristics of Rolled Metals Dimensional Tolerances Thickness tolerances for cold-rolled sheets range from ±0.1~0.35 mm Flatness tolerances are within ±15 mm/m for cold rolling and ±55 mm/m for hot rolling Surface Roughness Cold rolling can produce a very fine surface finish Cold-rolled sheets products may not require additional finishing operations
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Rolling Mills Roll Materials Basic requirements for roll materials are strength and resistance to wear Forged-steel rolls have higher strength, stiffness, and toughness than cast-iron rolls Rolls made for cold rolling should not be used for hot rolling as they may crack from thermal cycling (and spalling Lubricants Hot rolling of ferrous alloys do not need lubricants Water-based solutions are used to cool the rolls
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Various Rolling Processes and Mills Shape Rolling Straight and long structural shapes are formed at elevated temperatures by shape rolling
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Various Rolling Processes and Mills Tube Rolling Diameter and thickness of pipes and tubing can be reduced by tube rolling, which utilizes shaped rolls
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Shape Rolling Work is deformed into a contoured cross section rather than flat (rectangular) Accomplished by passing work through rolls that have the reverse of desired shape Products Construction shapes such as I-beams, L-beams, and U-channels Rails for railroad tracks Round and square bars and rods
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Various Rolling Processes and Mills Thread Rolling Thread rolling is a cold-forming process by which straight or tapered threads are formed on round rods or wire Threads are formed with rotary dies at high production rates
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Various Rolling Processes and Mills Thread Rolling Thread-rolling process has the advantages of generating threads with good strength without any loss of material Internal thread rolling can be carried out with a fluteless forming tap, produces accurate internal threads with good strength
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Thread Rolling Bulk deformation process used to form threads on cylindrical parts by rolling them between two dies Important process for mass producing bolts and screws Performed by cold working in thread rolling machines Advantages over thread cutting (machining): Higher production rates (80 pieces/sec) Better material utilization Surface finish is very smooth Stronger threads and better fatigue resistance
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Various Rolling Processes and Mills Ring Rolling A thick ring is expanded into a large-diameter thinner one Thickness is reduced by bringing the rolls closer together as they rotate Short production times, material savings and close dimensional tolerances
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Ring Rolling Deformation process in which a thick-walled ring of smaller diameter is rolled into a thin-walled ring of larger diameter As thick-walled ring is compressed, deformed metal elongates, causing diameter of ring to enlarge Hot working process for large rings and cold working process for smaller rings Products: ball and roller bearing races, steel tires for railroad wheels, and rings for pipes, pressure vessels, and rotating machinery
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Various Rolling Processes and Mills Rotary Tube Piercing Also known as the Mannesmann process It is a hot-working operation for making long, thick- walled seamless pipe and tubing The round bar is subjected to radial compressive forces while tensile stresses develop at the center of the bar
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Mannesmann Mills principle: -when round bar subjected to radial compressive forces tensile stresses developed at the center of the bar - radial compressive force + bar roll, then gives cyclic compressive stresses cavity formed at the center of the bar
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Mannesmann Mills arrangement: - skew rolls pull the round bar by the axial component of the rotary motion - internal mandrel assists the expanding of the hole and sizing of the tube inside diameter
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Various Rolling Processes and Mills Roll Forging Cross section of a round bar is shaped by passing it through a pair of rolls with profiled grooves
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Various Rolling Processes and Mills Skew Rolling Similar to roll forging and used for making ball bearings Another method is to shear pieces from a round bar and then upset them in headers between two dies with hemispherical cavities
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