1. Unit 6 Manufacturing Processes: Machining and Joining CUTTING, SHAPING METALS MACHINE TOOL OPERATIONS

2. Cutting Sheet Metal – Manual Shear  A bench shear, also known as a lever shear, is a bench mounted shear with a compound mechanism to increase the mechanical advantage. It is usually used for cutting rough shapes out of medium sized pieces of sheet metal, but cannot do delicate work. It mostly designed for a wide field of applications. Light weight and easy efficient operation, yet very sturdy in construction. The cutting blades fitted are carefully and accurately ground to give easy, clean quick cuts, and free of burrs. These special features help the operators save a great deal of their energy. But some shearing machines can cut sheet bar and flat bar up to 10mm.bench

3. Cutting Sheet Metal – Laser Cutting  Sheet metal can be cut in various ways, from hand tools called tin snips up to very large powered shears. With the advances in technology, sheet metal cutting has turned to computers for precise cutting. Many sheet metal cutting operations are based on computer numerically controlled (CNC) laser cutting or multi-tool CNC punch press.tin snips  CNC laser involves moving a lens assembly carrying a beam of laser light over the surface of the metal. Oxygen, nitrogen or air is fed through the same nozzle from which the laser beam exits. The metal is heated and burnt by the laser beam, cutting the metal sheet. The quality of the edge can be mirror smooth and a precision of around 0.1 mm can be obtained. Cutting speeds on thin 1.2 mm sheet can be as high as 25 m (82 ft) a minute. Most of the laser cutting systems use a CO2 based laser source.

4. Cutting Sheet Metal – Laser Cutting http://www.youtube.com/watch?v=UeGVbtrrHjE&NR=1&feature=fvw p

5. Manual Press – Bending Sheet Metal  In press brake forming, a work piece is positioned over the die block and the die block presses the sheet to form a shape.Usually bending has to overcome both tensile stresses and compressive stresses. When bending is done, the residual stresses cause the material to spring back towards its original position, so the sheet must be over-bent to achieve the proper bend angle. The amount of spring back is dependent on the material, and the type of forming. When sheet metal is bent, it stretches in length. The bend deduction is the amount the sheet metal will stretch when bent as measured from the outside edges of the bend. The bend radius refers to the inside radius. The formed bend radius is dependent upon the dies used, the material properties, and the material thickness.tensile stressescompressive stresses

6. Bending Sheet Metal http://www.youtube.com/watch?v=HiCZh_TFHCM&feature=related

7. Punching Sheet Metal  Punching is performed by placing the sheet of metal stock between a punch and a die mounted in a press. The punch and die are made of hardened steel and are the same shape. The punch just barely fits into the die. The press pushes the punch against and into the die with enough force to cut a hole in the stock. In some cases the punch and die "nest" together to create a depression in the stock. In progressive stamping a coil of stock is fed into a long die/punch set with many stages. Multiple simple shaped holes may be produced in one stage, but complex holes are created in multiple stages. In the final stage, the part is punched free from the "web".progressive stamping

8. Punching Sheet Metal  A typical CNC turret punch has a choice of up to 60 tools in a "turret" that can be rotated to bring any tool to the punching position. A simple shape (e.g., a square, circle, or hexagon) is cut directly from the sheet. A complex shape can be cut out by making many square or rounded cuts around the perimeter. A punch is less flexible than a laser for cutting compound shapes, but faster for repetitive shapes (for example, the grille of an air-conditioning unit). A CNC punch can achieve 600 strokes per minute.turret punch  A typical component (such as the side of a computer case) can be cut to high precision from a blank sheet in under 15 seconds by either a press or a laser CNC machine.press

9. Punching Sheet Metal http://www.youtube.com/watch?v=93IBQSUNWCU&feature=related

10. Tube Bending and Polishing  is the umbrella term for metal forming processes used to permanently form pipes or tubing. One has to differentiate between form-bound and freeform-bending procedures, as well as between heat supported and cold forming procedures.metal formingpipestubing  Form bound bending procedures like “press bending” or “rotary draw bending” are used to form the work piece into the shape of a die. Straight tube stock can be formed using a bending machine to create a variety of single or multiple bends and to shape the piece into the desired form. This processes can be used to form complex shapes out of different types of ductile metal tubing. [1] Freeform-bending processes, like three-roll-pushbending, shape the workpiece kinematically, thus the bending contour is not dependent on the tool geometry.die [1]

11. Automated Tube Polishing  Generally, round stock is what is used in tube bending. However, square and rectangular tubes and pipes may also be bent to meet job specifications. Other factors involved in the tube bending process is the wall thickness, tooling and lubricants needed by the pipe and tube bender to best shape the material and its also used in different ways e.g.( tube,pipe wires)

12. Automated Tube Bending http://www.youtube.com/watch?v=k-F_az5nyAo

13. Machine Tool Operations  Basic Machine Tools  Metal Saw Operations  Drill Presses  Lathes  Milling Machines

14. Basic Machine Tools 1. Metal Sawing Operations:  Used to cut stock materials to useable lengths for specific part manufacturing  Band Saws (Vertical)  Figure 13.2, page 250 TB  Cutoff Saws  Horizontal  Figure 13.5 and 13.6, page 251 TB  Reciprocating – Also known as a power hacksaw

15. Basic Machine Tools 2. Drilling Machines and Equipment  Primarily used for making holes, counterboring, spotfacing, reaming, and tapping.  Drill Presses  Sensitive  Upright Heavy Duty  Radial Arm

16. Basic Machine Tools 2. Drilling Machines and Equipment  Sensitive Drill Presses – Figure 13.7, page 252  So named because the operator “senses” or “feels” the cutting action of drill while holding the handle that feeds the drill into the work  Maximum hole size ~ ½ inch  Sized by the largest diameter of a circular piece in which a centered hole can be drilled

17. Basic Machine Tools 2. Drilling Machines and Equipment Upright Heavy Duty -- Figure 13.8, page 253 TB  Have power feeds and reversing capability  Most have tapping accessories  Coolant pumps supply cutting fluid  Hole Sizes: ¼ to 3 ½ inches

18. Basic Machine Tools 2. Drilling Machines and Equipment  Radial Arm – Figure 13.9, page 253 TB  Sized by the diameter of the column and length of the arm as measured from the center of the spindle  The drilling “head” can be positioned over the work and clamped in place  Coolant pumps supply cutting fluid  Large holes made with flat spade drills

19. Cutting Tools: Drills High Speed Twist Drills Most Common General purpose Twisted flutes provide for chip clearance and removal

20. Cutting Tools: Drills Straight Flute Drills Use for plastics, brass, bronze Zero “rake” prevents material from “grabbing”

21. Cutting Tools: Drills Spade Drills Primarily for holes > 1 inch Very rigid shank allows for heavier cuts Use stepped blade to produce a bevel

22. Cutting Tools: Drills Gun Drills Capable of very precise holes up to many feet deep Used for holes in automotive engine blocks

23. Cutting Tools: Special Tools Counterbores  Used to enlarge existing holes Countersinks  Provided a bevel to receive certain bolt heads Spotfacing  Provides a machined seat for bolt heads or nuts

24. Cutting Tools: Taps  Taps  Hardened thread cutting tools with flutes to collect chips. Taps are very brittle.  Taper  Plug  Bottoming

25. Basic Machine Tools 3. Turning Machines and Equipment  Engine Lathes (horizontal spindle)  Vertical Spindle Machines  Vertical Turret Machines

26. Basic Machine Tools 3. Turning Machines and Equipment  Engine Lathes – Figures 13.26, 13.29, 13.30  Principal Function: to remove unwanted material to form cylindrical and conical shapes  Accomplished in a “turning” operation using a single-point tool  Range in size from small jeweler’s lathes to machines that turn massive forgings

27. Basic Machine Tools 3. Turning Machines and Equipment  Engine Lathes  Turning Operations on Lathes  Turning Cuts  Facing  Boring / Reaming  Shaping  Internal / External Grooves and Threads

28. Basic Machine Tools 3. Turning Machines and Equipment  Turret Lathes  Similar to engine lathes, but are arranged for repetitive, rapid production and are capable of performing several operations in succession  The “turret” is usually six sided and holds different tools (drills, taps, turning tools, knurling tools, etc.)  Operator moves levers to change tools  Operators are usually less skilled than engine lathe operators

29. Basic Machine Tools 4. Milling Machines and Equipment  Horizontal Spindle Mills – Figure 13.74, page 271  Use various milling cutters: Plain milling cutters for slab milling Side milling cutters or staggered tooth cutters for deep slots Saws or slitting cutters for grooves Face mills for milling flat surfaces

30. Basic Machine Tools 4. Milling Machines and Equipment  Vertical Spindle Mills – Figure 13.75, page 271 Very versatile Utilize tools ranging from end mill cutters to face mills and fly cutters Used for drilling, reaming, and boring operations Usually numerically controlled for precise drilling of hole patterns in flat or bar stock and other milling operations

31. Basic Machine Tools 4. Milling Machines and Equipment  Horizontal Spindle Mills – Figure 13.74, page 271  Use various milling cutters: Plain milling cutters for slab milling Side milling cutters or staggered tooth cutters for deep slots Saws or slitting cutters for grooves Face mills for milling flat surfaces

32. Basic Machine Tools 5. Shapers – Figure 13.78, page 272  A machine tool that utilizes a reciprocating motion of the cutting tool rather than the more common rotary motion to make repeated machining cuts.  A “ram” moves back and forth holding the tool that cuts the stationary work-piece.

33. Basic Machine Tools 6. Broaching – Figure 13.78, page 272  The precision cutting of a material by a tool incorporating a series of progressively stepped teeth.  Flat surfaces, contours, internal splines, and external splines are some of the shapes produced.

34. Basic Machine Tools 7. Abrasive Machining  Grinding processes remove metal by using abrasive grains as cutting tools.  Figures 13.111, 13.112, 13.113, and 13.114 on page 283 of the TB are examples of different grinding machines.

35. Basic Machine Tools 8. Honing, Lapping, and Superfinishing  When smooth internal finishes are required (for example: tubing for hydraulic cylinders), Honing is a preferred method of finishing.  Honing is a finishing process that utilizes a rotating and oscillating abrasive tool.  Figure 13.125 shows the honing of a cylinder in an engine block.

36. Unit 6 Manufacturing Processes: Machining and Joining NONTRADITIONAL MANUFACTURING PROCESSES

37. Nontraditional Machining Processes 1. Electrodischarge Machining (EDM) 2. Electrochemical Machining (ECM) 3. Electrolytic Grinding (ELG) 4. Laser Machining 5. Ultrasonic Machining 6. Water Jet Machining 7. Electron Beam Machining (EBM) 8. Plasma Cutting

38. Nontraditional Machining Processes Electrochemical Machining (ECM)  Essentially a reverse metal-plating process  The process takes place in a conducting fluid called electrolyte that is pumped in under pressure between the electrode and the work piece.  As the work piece material is de- plated it is flushed away by the flow of electrolyte. The residue from the work piece is filtered from the electrolyte.

39. Nontraditional Machining Processes Electrolyte  A nonmetallic conductor, usually a fluid, in which electric current is carried by the movement of ions.  The electrode and the work-piece are immersed in the fluid, the arc then creates a small glob of melted metal which is solidified and carried away by the fluid

40. Nontraditional Machining Processes Plasma Technology  Plasma Cutting is an extremely fast process for cutting, welding, and machining nonferrous metals and stainless steel.  Plasma is created by passing a gas through an electric arc.  The gas is ionized by the arc, and an extremely high temperature ( can be > 40,000 degrees F )

41. Nontraditional Machining Processes Plasma Technology  When the superheated gas is forced through a venturi, a high-velocity jet is created that instantly melts metals on contact and blows the molten material away from the cut.

42. Nontraditional Machining Processes Plasma  An ionized gas of extremely high temperature achieved by passing an inert gas through an electric arc.  Plasma arcs are used in welding, cutting, and machining processes.

43. Joining Processes  Manufacturing processes commonly require assembly involving several different pieces made of the same or different materials.  In manufacturing, it is almost always necessary to join the materials at some point in the process.

44. Joining Processes  Joining processes can be divided into the following categories: 1. Mechanical Fasteners 2. Adhesive Bonding 3. Welding 4. Brazing and Soldering

45. Joining Processes 1. Mechanical Fasteners  Threaded fasteners  Nails and Staples  Rivets  Stitching, Tying, Snaps  Pins, Retaining Rings  Pressing, Crimping

46. Joining Processes 2. Adhesive Bonding  Natural Adhesives  Vegetable / animal glues and caseins  Sodium silicate  Natural gums  Plastic Resin Adhesives  Thermosets  Thermoplastics

47. Joining Processes 3. Welding Processes  Oxifuel Welding and Cutting  Electric Arc Welding  Shielded Metal Arc Welding  Inert Gas Shielded Arc Welding  Gas Metal Arc Welding (GMAW / MIG)  Gas Tungsten Arc Welding (GTAW/TIG)  Submerged Arc Welding  Plasma Arc Welding

48. Joining Processes 3. Welding Processes  Resistance Welding  Stud Welding  Induction Welding  Solid State Welding Processes  Forge Welding  Ultrasonic Welding

49. Joining Processes 3. Welding Processes  Flux: A solid, liquid, or gaseous material that is applied to solid or molten metal in order to clean and remove oxides or other impurities.  Shield Gas: Usually an inert gas used to displace air from around a weld zone, thus keeping the weld uncontaminated.

50. Joining Processes 4. Brazing and Soldering  Brazing processes use filler material with a melting temperature above 840 degrees F and below the melting temperature of the base metal.  Soldering processes use filler material with a melting temperature below 840 degrees F and below the melting temperature of the base metal.